Engineering-Mathematics
Question 1 |
A class of 30 students occupy a classroom containing 5 rows of seats, with 8 seats in each row. If the students seat themselves at random, the probability that the sixth seat in the fifth row will be empty is
1/5 | |
1/3 | |
1/4 | |
2/5 |
Question 1 Explanation:
Step-1: Given, 5 rows with 8 seats in each row.
Total number of seats = 5*40
= 40 seats
Total number of students= 30
Step-2: Given constraint that, 6th seat in the fifth row is empty
When we are deleting 6th seat, 30 students have 39 choices of seats
Step-3: Total number of choices = 39C30
Total ways to choose = 40C30
Step-4: Final probability = 39C30 / 40C30
= 1/4
Total number of seats = 5*40
= 40 seats
Total number of students= 30
Step-2: Given constraint that, 6th seat in the fifth row is empty
When we are deleting 6th seat, 30 students have 39 choices of seats
Step-3: Total number of choices = 39C30
Total ways to choose = 40C30
Step-4: Final probability = 39C30 / 40C30
= 1/4
Question 2 |
The domain of the function log( log sin(x) ) is
0 < x < π | |
2nπ < x < (2n+1)π , for n in N | |
Empty set | |
None of the above |
Question 2 Explanation:
→ The range of sinx value lies between -1 and 1 and whereas log(sinx) value will be the positive value.
→ So the domain of log(log sin(x)) is undefined which is empty Set.
→ So the domain of log(log sin(x)) is undefined which is empty Set.
Question 3 |
( G, *) is an abelian group. Then
x = x-1, for any x belonging to G | |
x = x2, for any x belonging to G | |
(x * y )2 = x2 * y2, for any x, y belonging to G | |
G is of finite order |
Question 3 Explanation:
An abelian group is a commutative group. As per the above options, option C is the correct answer because it follows commutative property.
(x * y )2 = x2 * y2, for any x, y belonging to G
(x * y )2 = x2 * y2, for any x, y belonging to G
Question 4 |
Consider the following C code segment
Of the following, which best describes the growth of f(x) as a function of x?
Linear | |
Exponential | |
Quadratic | |
Cubic |
Question 4 Explanation:
Question 5 |
The number of edges in a regular graph of degree d and n vertices is
maximum of n and d | |
n + d | |
nd | |
nd / 2 |
Question 5 Explanation:
Sum of degree of vertices = 2 × no. of edges
d * n = 2 * |E|
∴ |E| = d*n/2
d * n = 2 * |E|
∴ |E| = d*n/2
Question 6 |
A graph with n vertices and n-1 edges that is not a tree, is
Connected | |
Disconnected | |
Euler | |
A circuit |
Question 6 Explanation:
Consider a graph with two nodes(n1&n2) and number of edges are 1, There may be chance self edge with node n1 then graph is disconnected.
Consider the graph with three nodes(n1,n2&n3) and has 2 edges.
n1-->n2 and n2--->n1 then the graph is disconnected.
Consider the graph with three nodes(n1,n2&n3) and has 2 edges.
n1-->n2 and n2--->n1 then the graph is disconnected.
Question 7 |
If a graph requires k different colours for its proper colouring, then the chromatic number of the graph is
1 | |
k | |
k-1 | |
k/2 |
Question 7 Explanation:
The chromatic number of a graph is the smallest number of colors needed to color the vertices of so that no two adjacent vertices share the same color and if a graph requires k different colours for its proper colouring, then k is the chromatic number of the graph.
Question 8 |
Identify the correct translation into logical notation of the following assertion.
Some boys in the class are taller than all the girls
Note: taller (x, y) is true if x is taller than y.
(∃x)(boy(x) → (∀y)(girl(y) ∧ taller(x, y))) | |
(∃x)(boy(x) ∧ (∀y)(girl(y) ∧ taller(x, y))) | |
(∃x)(boy(x) → (∀y)(girl(y) → taller(x, y))) | |
(∃x)(boy(x) ∧ (∀y)(girl(y) → taller(x, y))) |
Question 8 Explanation:
Don't confuse with '∧' and '→'
'∧' → predicts statements are always true, no matter the value of x.
'→' → predicts there is no need of left predicate to be true always, but whenever it becomes true, then right predicate must be true.
Option D:
There exists a some boys who are taller than of all girls y.
'∧' → predicts statements are always true, no matter the value of x.
'→' → predicts there is no need of left predicate to be true always, but whenever it becomes true, then right predicate must be true.
Option D:
There exists a some boys who are taller than of all girls y.
Question 9 |
Eigenvectors of
are
are
 | |
 | |
 | |
 | |
None Of the Above |
Question 9 Explanation:
Explanation: Excluded for evaluation
Question 10 |
The set of all Equivalence Classes of a set A of Cardinality C
is of cardinality 2c | |
have the same cardinality as A | |
forms a partition of A | |
is of cardinality C2 |
Question 10 Explanation:
The set of ll equivalence class of a set A of cardinality C forms a partition of A
Note: Ambiguous between answer with option D
Note: Ambiguous between answer with option D
Question 11 |
Company X shipped 5 computer chips, 1 of which was defective and company Y shipped 4 computer chips, 2 of which were defective. One computer chip is to be chosen uniformly at a random from the 9 chips shipped by the companies. If the chosen chip is found to be defective, what is the probability that the chip came from the company Y?
2/9 | |
4/9 | |
2/3 | |
1/2 |
Question 11 Explanation:
Probability that chip came chosen from company X = 5/9
Probability that chip came chosen from company Y = 4/9
Number of Defective chips from company X = 1
Number of Defective chips from company Y = 2
Probability that chip is defective from company X = 5/9 * 1/5
Probability that chip is defective from company Y = 4/9 * 2/4
Probability that chip is defective = 5/9 * 1/5 + 4/9 * 2/4
Given chip is defective, probability that it came from the company
Y = P(Defective Company Y)/ P(Defective)
= (4/9 * 2/4) / (5/9 * 1/5 + 4/9 * 2/4)
= 2/3
Probability that chip came chosen from company Y = 4/9
Number of Defective chips from company X = 1
Number of Defective chips from company Y = 2
Probability that chip is defective from company X = 5/9 * 1/5
Probability that chip is defective from company Y = 4/9 * 2/4
Probability that chip is defective = 5/9 * 1/5 + 4/9 * 2/4
Given chip is defective, probability that it came from the company
Y = P(Defective Company Y)/ P(Defective)
= (4/9 * 2/4) / (5/9 * 1/5 + 4/9 * 2/4)
= 2/3
Question 12 |
A program consists of two modules executed sequentially. Let f1(t) and f2(t) respectively denote the probability density functions of time taken to execute the two modules. The probability density function of the overall time taken to execute the program is given by
f1(t) + f2(t) | |
∫t0 f1(x), f2(x) dx | |
∫t0 f1(x), f2(t-x) dx | |
max (f1(t), f2(t)) |
Question 12 Explanation:
The two modules executed sequentially. The total runtime of the program is the sum of runtime of the two module. Probability density function of overall time taken
∫t0 f1(x), f2(t-x) dx
∫t0 f1(x), f2(t-x) dx
Question 13 |
If A is a skew-symmetric matrix, then AT
diagonal matrix | |
A | |
-A | |
0 |
Question 13 Explanation:
→ In mathematics, particularly in linear algebra, a skew-symmetric (or antisymmetric or antimetric) matrix is a square matrix whose transpose equals its negative, that is, it satisfies the condition.
→ If A is skew symmetric matrix then AT = -A
→ In terms of the entries of the matrix, if aij denotes the entry in the ith row and jth column, then the skew-symmetric condition is equivalent to
→ If A is skew symmetric matrix then aji=-aij
→ If A is skew symmetric matrix then AT = -A
→ In terms of the entries of the matrix, if aij denotes the entry in the ith row and jth column, then the skew-symmetric condition is equivalent to
→ If A is skew symmetric matrix then aji=-aij
Question 14 |
If A and B be two arbitrary events, then
P(A∩B) = P(A)P(B) | |
P(A∪B) = P(A) + P(B) | |
P(A|B) = P(A ∩ B) + P(B) | |
P(A∪B) <= P(A) + P(B) |
Question 14 Explanation:
(A) Happens when A and B are independent.
(B) Happens when A and B are mutually exclusive.
(C) Not happens.
(D) P(A∪B) ≤ P(A) + P(B) is true because P(A∪B) = P(A) + P(B) - P(A∩B).
(B) Happens when A and B are mutually exclusive.
(C) Not happens.
(D) P(A∪B) ≤ P(A) + P(B) is true because P(A∪B) = P(A) + P(B) - P(A∩B).
Question 15 |
Using Newton Raphson method, a root correct to 3 decimal places of the equation x3 – 3x – 5 = 0
2.222 | |
2.275 | |
2.279 | |
None of the above |
Question 15 Explanation:
Here f(x)= x3-3x-5 and f1(x) = 3x2-3
The Newton-Raphson iterative formula is
Since x3 and x4 are identical upto 3 places of decima,we take x4=2.279 as the required root, correct to three places of the decimal.
The Newton-Raphson iterative formula is
Since x3 and x4 are identical upto 3 places of decima,we take x4=2.279 as the required root, correct to three places of the decimal.
Question 16 |
The symmetric difference of sets A = {1, 2, 3, 4, 5, 6, 7, 8} and B = {1, 3, 5, 6, 7, 8, 9} is
{1, 3, 5, 6, 7, 8} | |
{2, 4, 9} | |
{2, 4} | |
{1, 2, 3, 4, 5, 6, 7, 8, 9} |
Question 16 Explanation:
Symmetrical Difference of A and B=(A–B)∪(B–A)
Question 17 |
Which one of the following Boolean expressions is NOT a tautology?
((a → b) ∧ (b → c)) → (a → c) | |
(a ↔ c) → ( ¬b → (a ∧ c)) | |
(a ∧ b ∧ c) → (c ∨ a) | |
a → (b → a) |
Question 17 Explanation:
Tautology: A universal truth in formal logic.
Note: Above (A↔C) →( ¬B→(A∧C)) is not tautology.
Note: Above (A↔C) →( ¬B→(A∧C)) is not tautology.Question 18 |
If a square matrix A satisfies AAT = I, then the matrix, A is
Idempotent | |
Symmetric | |
Orthogonal | |
Hermitian |
Question 18 Explanation:
A square matrix A is an orthogonal matrix if its transpose is equal to its inverse. An orthogonal matrix A is necessarily invertible and unitary.
Conditions for an orthogonal matrix:
AT= A-1 and
A AT = AT A = I,
where I is an Identity matrix
Question 19 |
Consider the graph shown in the figure below:
Which of the following is a valid strong component?
Which of the following is a valid strong component?a, c, d | |
a, b, d | |
b, c, d | |
a, b, c |
Question 19 Explanation:
A directed graph is strongly connected if there is a path between all pairs of vertices. A strongly connected component (SCC) of a directed graph is a maximal strongly connected subgraph.
The graph has (a, b, c) as a strongly connected component.
The graph has (a, b, c) as a strongly connected component.
Question 20 |
If the two matrices
have the same determinant, then the value of x is
have the same determinant, then the value of x is1/2 | |
√2 | |
± 1/2 | |
± 1/√2 |
Question 20 Explanation:
Determinant of 1st Matrix = X2 – 1
Determinant of 2nd Matrix = X2– X
Since the determinants are equal:
X2 - 1 = X2 - 1.
X2 + X - 1 = 0
X = 1/2
Option (A) is correct
Determinant of 2nd Matrix = X2– X
Since the determinants are equal:
X2 - 1 = X2 - 1.
X2 + X - 1 = 0
X = 1/2
Option (A) is correct
Question 21 |
Suppose A is a finite set with n elements. The number of elements and the rank of the largest equivalence relation on A is
{n,1} | |
{n, n} | |
{n2, 1} | |
{1, n2} |
Question 21 Explanation:
Let us assume a set with 4 elements
S={1,2,3,4}
→ If a set is said to be equivalence, then the set must be
i) Reflexive
ii) Symmetric
iii) Transitive
i) Reflexive Relation: A relation ‘R’ on a set ‘A’ is said to be reflexive if (xRx)∀x∈A.
A = {1,2,3}
R = {(1,1), (2,2), (3,3)}
R = {(1,1), (2,2)} It is false.
R = {(1,1), (2,2), (3,3), (1,2)}
ii) Symmetric Relation: A relation on a set A is said to be symmetric if (xRy). Then (yRx)∀x,y∈A i.e., if ordered pair (x,y)∈R. Then (y,x)∈R ∀x,y∈A.
A={1,2,3}
R1={(1,2), (2,1)}
R2={(1,1), (2,2), (3,3), (1,2), (2,1), (2,3), (3,2)}
Transitive Relation:
A relation ‘R’ on a set ‘A’ is said to be transitive if (xRy) and (yRz), then (xRz)∀(x,y,z∈A).
A={1,2,3}
R1={ }
R2={(1,1)}
R3={(1,2), (3,1)}
R4={(1,2), (2,1), (1,1)}
⇾ A={1,2,3,4}
Largest ordered set is
S×S={(1,1),(1,2),(1,3),(1,4),(2,1),(2,2),(2,3),(2,4),(3,1),(3,2),(3,3),(3,4),(4,1),(4,2),(4,3),(4,4)}
⇒ Total = 16 = 42 = n2
Smallest ordered set = {(1,1),(2,2),(3,3),(4,4)}
⇒ Total=4=n
Note: In question, they are clearly mentioned that Rank of an Equivalence relation is equal to the number of induced Equivalence classes. Since we have maximum number of ordered pairs(which are reflexive, symmetric and transitive ) in largest Equivalence relation, its rank is always 1.
S={1,2,3,4}
→ If a set is said to be equivalence, then the set must be
i) Reflexive
ii) Symmetric
iii) Transitive
i) Reflexive Relation: A relation ‘R’ on a set ‘A’ is said to be reflexive if (xRx)∀x∈A.
A = {1,2,3}
R = {(1,1), (2,2), (3,3)}
R = {(1,1), (2,2)} It is false.
R = {(1,1), (2,2), (3,3), (1,2)}
ii) Symmetric Relation: A relation on a set A is said to be symmetric if (xRy). Then (yRx)∀x,y∈A i.e., if ordered pair (x,y)∈R. Then (y,x)∈R ∀x,y∈A.
A={1,2,3}
R1={(1,2), (2,1)}
R2={(1,1), (2,2), (3,3), (1,2), (2,1), (2,3), (3,2)}
Transitive Relation:
A relation ‘R’ on a set ‘A’ is said to be transitive if (xRy) and (yRz), then (xRz)∀(x,y,z∈A).
A={1,2,3}
R1={ }
R2={(1,1)}
R3={(1,2), (3,1)}
R4={(1,2), (2,1), (1,1)}
⇾ A={1,2,3,4}
Largest ordered set is
S×S={(1,1),(1,2),(1,3),(1,4),(2,1),(2,2),(2,3),(2,4),(3,1),(3,2),(3,3),(3,4),(4,1),(4,2),(4,3),(4,4)}
⇒ Total = 16 = 42 = n2
Smallest ordered set = {(1,1),(2,2),(3,3),(4,4)}
⇒ Total=4=n
Note: In question, they are clearly mentioned that Rank of an Equivalence relation is equal to the number of induced Equivalence classes. Since we have maximum number of ordered pairs(which are reflexive, symmetric and transitive ) in largest Equivalence relation, its rank is always 1.
Question 22 |
Consider the set of integers I. Let D denote “divides with an integer quotient” (e.g. 4D8 but 4D7). Then D is
Reflexive, not symmetric, transitive | |
Not reflexive, not antisymmetric, transitive | |
Reflexive, antisymmetric, transitive | |
Not reflexive, not antisymmetric, not transitive |
Question 22 Explanation:
Reflexive Relation:
A relation ‘R’ on a set ‘A’ is said to be reflexive if (xRx)∀x∈A.
Example: 4 D 8, 4 D 12, 4 D16, 4 D20…….(Here, D means divide)
8 D 16, 8 D 24……….
In this example, we didn’t get 4D4. So, it is not reflexive.
AntiSymmetric Relation:
For all x ∈ I, R(x,y) and R(y,x) then x=y is antisymmetric. We can easily make a violation as R(-2,2) and R(2,-2) are not antisymmetric.
It is violating. So, not antisymmetric relation.
Transitive relation:
A relation ‘R’ on a set ‘A’ is said to be transitive if (xRy) and (yRz), then (xRz)∀(x,y,z∈A).
Example: 4D8, 4D12, 4D16, 4D20…….(Here, D means divide)
8D16, 8D24……….
{ 4D8, 8D16, 1D16}. So, it is satisfied.
A relation ‘R’ on a set ‘A’ is said to be reflexive if (xRx)∀x∈A.
Example: 4 D 8, 4 D 12, 4 D16, 4 D20…….(Here, D means divide)
8 D 16, 8 D 24……….
In this example, we didn’t get 4D4. So, it is not reflexive.
AntiSymmetric Relation:
For all x ∈ I, R(x,y) and R(y,x) then x=y is antisymmetric. We can easily make a violation as R(-2,2) and R(2,-2) are not antisymmetric.
It is violating. So, not antisymmetric relation.
Transitive relation:
A relation ‘R’ on a set ‘A’ is said to be transitive if (xRy) and (yRz), then (xRz)∀(x,y,z∈A).
Example: 4D8, 4D12, 4D16, 4D20…….(Here, D means divide)
8D16, 8D24……….
{ 4D8, 8D16, 1D16}. So, it is satisfied.
Question 23 |
A bag contains 19 red balls and 19 black balls. Two balls are removed at a time repeatedly and discarded if they are of the same colour, but if they are different, black ball is discarded and red ball is returned to the bag. The probability that this process will terminate with one red ball is
1 | |
1/21 | |
0 | |
0.5 |
Question 23 Explanation:
Given data,
Step-1: Bag contains 19 Red(R) and 19 Blue(B) balls.
BB (or) RR happen we are discarded.
If we get BR (or) RB then B is discarded and R is returned.
Step-2: There are some conditions that,
→ If black balls will either come with black then both black balls are discarder.
→ If it will come with red then only black balls will be discarded.
→ Suppose 2 red balls will come together means we are discarding both red balls.
Step-3: As per the above constraints, total 19 Red balls it means odd number.
→ Among 19 only 18 will be discarded.
Step-3: Final content of bag at second last trail will be either R,B (or) R,R,R and finally in last
trail bag will left with one red ball in both the cases.
Step-1: Bag contains 19 Red(R) and 19 Blue(B) balls.
BB (or) RR happen we are discarded.
If we get BR (or) RB then B is discarded and R is returned.
Step-2: There are some conditions that,
→ If black balls will either come with black then both black balls are discarder.
→ If it will come with red then only black balls will be discarded.
→ Suppose 2 red balls will come together means we are discarding both red balls.
Step-3: As per the above constraints, total 19 Red balls it means odd number.
→ Among 19 only 18 will be discarded.
Step-3: Final content of bag at second last trail will be either R,B (or) R,R,R and finally in last
trail bag will left with one red ball in both the cases.
Question 24 |
If x = -1 and x = 2 are extreme points of f(x) = α log |x| + βx2 + x then
α = -6, β = -1/2 | |
α = 2, β = -1/2 | |
α = 2, β = 1/2 | |
α = -6, β =1/2 |
Question 24 Explanation:
Given data,
Step-1: x= -1 and x=2
f(x) = α log |x| + β x2 + x
f'(x)= α/x + 2βx + 1 = 0
Step-2: for extreme points f'(x)=0
α/x + 2βx + 1=0
Step-3: For x= -1 then we will get α+2β= 1 → (i)
For x= 2: then we will get α+8β= 2 → (ii)
from (i) and (ii) we can get the value of α=2 and β= -1/2
Step-1: x= -1 and x=2
f(x) = α log |x| + β x2 + x
f'(x)= α/x + 2βx + 1 = 0
Step-2: for extreme points f'(x)=0
α/x + 2βx + 1=0
Step-3: For x= -1 then we will get α+2β= 1 → (i)
For x= 2: then we will get α+8β= 2 → (ii)
from (i) and (ii) we can get the value of α=2 and β= -1/2
Question 25 |
Let f(x) = log|x| and g(x) = sin x . If A is the range of f(g(x)) and B is the range of g(f(x)) then A ∩ B is
[-1, 0] | |
[-1, 0) | |
[-∞, 0] | |
[-∞,1] |
Question 25 Explanation:
Given data,
Step-1: f(x) = log|x| and given range is [-∞ to +∞]
g(x) = sin(x) and given range is [-1,1]
Step-2: Given 2 variables are A and B
A= f(g(x))
= log|g(x)|
= log|sin(x)|
So, we will get A range is [-∞ ,0]
Step-3: B= g(f(x))
= sin(f(x))
= sin(log|x|)
So, we will get B range is [-1, 1]
Step-4: Common in both A and B is A∩B
A∩B = [-1, 0]
Key point: Ranges [ -1 ≤ sin(x) ≤ 1 and -∞ ≤ log|x| ≤ ∞ ]
Step-1: f(x) = log|x| and given range is [-∞ to +∞]
g(x) = sin(x) and given range is [-1,1]
Step-2: Given 2 variables are A and B
A= f(g(x))
= log|g(x)|
= log|sin(x)|
So, we will get A range is [-∞ ,0]
Step-3: B= g(f(x))
= sin(f(x))
= sin(log|x|)
So, we will get B range is [-1, 1]
Step-4: Common in both A and B is A∩B
A∩B = [-1, 0]
Key point: Ranges [ -1 ≤ sin(x) ≤ 1 and -∞ ≤ log|x| ≤ ∞ ]
Question 26 |
The proposition (P⇒Q)⋀(Q⇒P) is a
tautology | |
contradiction | |
contingency | |
absurdity |
Question 26 Explanation:
A proposition that is neither a tautology nor a contradiction is called a contingency.
Question 27 |
If T(x) denotes x is a trigonometric function, P(x) denotes x is a periodic function and C(x) denotes x is a continuous function then the statement “It is not the case that some trigonometric functions are not periodic” can be logically represented as
¬∃(x) [ T(x) ⋀ ¬P(x) ] | |
¬∃(x) [ T(x) ⋁ ¬P(x) ] | |
¬∃(x) [ ¬T(x) ⋀ ¬P(x) ] | |
¬∃(x) [ T(x) ⋀ P(x) ] |
Question 27 Explanation:
Option A implies "It is not the case that some trigonometric functions are not periodic”.
Hence it is correct .
Option B implies "It is not the case that some are trigonometric functions or they are not periodic”.
Option C implies "It is not the case that some of not trigonometric functions are not periodic”.
Option D implies "It is not the case that some trigonometric functions are periodic”.
Hence it is correct .
Option B implies "It is not the case that some are trigonometric functions or they are not periodic”.
Option C implies "It is not the case that some of not trigonometric functions are not periodic”.
Option D implies "It is not the case that some trigonometric functions are periodic”.
Question 28 |
The number of elements in the power set of { {1,2}, {2,1,1}, {2,1,1,2} } is
3 | |
8 | |
4 | |
2 |
Question 28 Explanation:
Given data,
Step-1: Total number of elements in power set of given set with ‘n’ elements = 2n
Example: {1,2}
{{∅},{1},{2},{1,2}} → Total 4 possibilities.
Step-2: The given set in question contains 3 elements({1,2},{2,1,1}, {2,1,1,2} }. So, number of elements in power set of given set is 23 =8.
Step-3: The power set is {{∅},{X}} or {{∅},{1,2}}.
Step-1: Total number of elements in power set of given set with ‘n’ elements = 2n
Example: {1,2}
{{∅},{1},{2},{1,2}} → Total 4 possibilities.
Step-2: The given set in question contains 3 elements({1,2},{2,1,1}, {2,1,1,2} }. So, number of elements in power set of given set is 23 =8.
Step-3: The power set is {{∅},{X}} or {{∅},{1,2}}.
Question 29 |
The function f: [0,3]→[1,29] defined by f(x) = 2x3 – 15x2 + 36x + 1 is
injective and surjective | |
surjective but not injective | |
injective but not surjective | |
neither injective nor surjective |
Question 29 Explanation:
Question 30 |
2/5 | |
2 | |
3 | |
5/2 |
Question 30 Explanation:
Given data,
Step-1: It is clearly showing that two vectors are perpendicular. If two vectors are perpendicular
we are using dot product is zero. a.b =0
Step-2: Calculating dot product is “i is multiplied with i” and “j is multiplied with coefficient of j”
Step-3: we can write like this,
= (2i+λj+k).(i-2j+3k)=0
= 2-2λ+3 =0
-2λ = -5
λ=5/2
Step-1: It is clearly showing that two vectors are perpendicular. If two vectors are perpendicular
we are using dot product is zero. a.b =0
Step-2: Calculating dot product is “i is multiplied with i” and “j is multiplied with coefficient of j”
Step-3: we can write like this,
= (2i+λj+k).(i-2j+3k)=0
= 2-2λ+3 =0
-2λ = -5
λ=5/2
Question 31 |
If G is a graph with e edges and n vertices, the sum of the degrees of all vertices in G is
e | |
e/2 | |
e2 | |
2 e |
Question 31 Explanation:
Handshaking theorem states that the sum of degrees of the vertices of a graph is twice the number of edges.
If G=(V,E) be a graph with E edges,then-
Σ degG(V) = 2E
This theorem applies even if multiple edges and loops are present.
Since the given graph is undirected, every edge contributes as twice in sum of degrees. So the sum of degrees is 2e.
Question 32 |
If the pdf of a Poisson distribution is given by f(x) = (e-22x)/x!, then its mean is
2x | |
2 | |
-2 | |
1 |
Question 32 Explanation:
Given the function f(x) = (e-22x)/x!
Poisson Formula. Suppose we conduct a Poisson experiment, in which the average number of successes within a given region is μ.
Then, the Poisson probability is: P(x; μ) = (e-μ) (μx) / x!
where x is the actual number of successes that result from the experiment, and e is approximately equal to 2.71828.
From the given function the “μ” value is 2 which is the mean.
Poisson Formula. Suppose we conduct a Poisson experiment, in which the average number of successes within a given region is μ.
Then, the Poisson probability is: P(x; μ) = (e-μ) (μx) / x!
where x is the actual number of successes that result from the experiment, and e is approximately equal to 2.71828.
From the given function the “μ” value is 2 which is the mean.
Question 33 |
If the mean of a normal frequency distribution of 1000 items is 25 and its standard deviation is 2.5, then its maximum ordinate is
(1000/√2π).e-25 | |
1000/√2π | |
(1000/√2π ).e-2.5 | |
400/√2π |
Question 33 Explanation:
Question 34 |
The cubic polynomial y(x) which takes the following values:
y(0) = 1,
y(1) = 0,
y(2) = 1,
y(3) = 10 is
y(0) = 1,
y(1) = 0,
y(2) = 1,
y(3) = 10 is
x3 +2 x2 + 1 | |
x3 + 3x2 + 1 | |
x3 + 1 | |
x3 – 2 x2 + 1 |
Question 34 Explanation:
Substitute the values of x (0,1,2 and 3) in the options and check which option gives the corresponding y(x) values. The function x3 – 2 x2 + 1 gives the required values.
x = 0: y(x) = 1
x = 1: y(x) = 0
x = 2: y(x) = 8 - 8 + 1 = 1
x = 3: y(x) = 27 - 18 + 1 = 10
x = 0: y(x) = 1
x = 1: y(x) = 0
x = 2: y(x) = 8 - 8 + 1 = 1
x = 3: y(x) = 27 - 18 + 1 = 10
Question 35 |
x = a cos(t), y = b sin(t) is the parametric form of
Ellipse | |
Hyperbola | |
Circle | |
Parabola |
Question 35 Explanation:
An ellipse can be defined as the locus of all points that satisfy the equations
x = a cos t
y = b sin t
where:
x,y are the coordinates of any point on the ellipse,
a, b are the radius on the x and y axes respectively,
t is the parameter, which ranges from 0 to 2π radians
x = a cos t
y = b sin t
where:
x,y are the coordinates of any point on the ellipse,
a, b are the radius on the x and y axes respectively,
t is the parameter, which ranges from 0 to 2π radians
Question 36 |
The value of x at which y is minimum for y = x2 − 3x + 1 is
-3/2 | |
3/2 | |
0 | |
-5/4 |
Question 36 Explanation:
Given function is y = x2 – 3x + 1
To find the minimum value, calculate the derivative until at what point given function is minimum value.
Applying First order derivative to the function y is y’ = 2x – 3
Again applying derivative of y ’is y” = 2 (Since y” > 0, it has a minimum value)
So the minima value at that point is (2x – 3) = 0 and x = 3/2
To find the minimum value, calculate the derivative until at what point given function is minimum value.
Applying First order derivative to the function y is y’ = 2x – 3
Again applying derivative of y ’is y” = 2 (Since y” > 0, it has a minimum value)
So the minima value at that point is (2x – 3) = 0 and x = 3/2
Question 37 |
A graph in which all nodes are of equal degree, is known as
Multigraph | |
Non regular graph | |
Regular graph | |
Complete graph |
Question 37 Explanation:
Question 38 |
In a graph G there is one and only one path between every pair of vertices then G is a
Path | |
Walk | |
Tree | |
Circuit |
Question 38 Explanation:
A graph is a tree if and only if there is exactly one path between every pair of its vertices.
Let G be a graph and let there be exactly one path between every pair of vertices in G. So G is connected. Now G has no cycles, because if G contains a cycle, say between vertices u and v, then there are two distinct paths between u and v, which is a contradiction. Thus G is connected and is without cycles, therefore it is a tree.
A tree is a minimally connected graph i.e. removing a single edge will disconnect the graph. A tree with n vertices has n−1 edges and only one path exists between every pair of vertices.
Let G be a graph and let there be exactly one path between every pair of vertices in G. So G is connected. Now G has no cycles, because if G contains a cycle, say between vertices u and v, then there are two distinct paths between u and v, which is a contradiction. Thus G is connected and is without cycles, therefore it is a tree.
A tree is a minimally connected graph i.e. removing a single edge will disconnect the graph. A tree with n vertices has n−1 edges and only one path exists between every pair of vertices.
Question 39 |
A simple graph ( a graph without parallel edge or loops) with n vertices and k components can have at most
n edges | |
n-k edges | |
(n − k)(n − k + 1) edges | |
(n − k)(n − k + 1)/2 edges |
Question 39 Explanation:
Let G be a graph with k components. Let ni be the number of vertices in the ith component, where 1 ≤ i ≤ k. Then, the number of edges in G is equal to sum of the edges in each of its components.
So, G has maximum number of edges if each component is a complete graph.
Hence, the maximum possible number of edges in the graph G is:
And in every case, (n − k)(n − k + 1)/2 will be greater than or equal to the above expression.
So, at maximum, there can be (n − k)(n − k + 1)/2 edges in a simple graph with n vertices and k components.
So, G has maximum number of edges if each component is a complete graph.
Hence, the maximum possible number of edges in the graph G is:
And in every case, (n − k)(n − k + 1)/2 will be greater than or equal to the above expression.
So, at maximum, there can be (n − k)(n − k + 1)/2 edges in a simple graph with n vertices and k components.
Question 40 |
Consider the polynomial, p(x) = a0 + a1X + a2X2 + a3X3 where ai ≠ 0, ∀i . The minimum number of multiplications needed to evaluate p on an input X is:
3 | |
4 | |
6 | |
9 |
Question 40 Explanation:
P(X)=a0+a1+a2X2+a3X3
=a0+X(a1+X(a2+a3X))
↓ ↓ ↓
③ ② ①
Here, minimum 3 multiplication needed
=a0+X(a1+X(a2+a3X))
↓ ↓ ↓
③ ② ①
Here, minimum 3 multiplication needed
Question 41 |
A square matrix A is called orthogonal if A’A =
I | |
A | |
-A | |
-I |
Question 41 Explanation:
An orthogonal matrix is a square matrix whose columns and rows are orthogonal unit vectors (i.e., orthonormal vectors), i.e. AAT=ATA =I (Identity matrix)
This leads to the equivalent characterization: a matrix Q is orthogonal if its transpose is equal to its inverse: AT=A-1
This leads to the equivalent characterization: a matrix Q is orthogonal if its transpose is equal to its inverse: AT=A-1
Question 42 |
If two adjacent rows of a determinant are interchanged, the value of the determinant
becomes zero
| |
remains unaltered | |
becomes infinitive | |
becomes negative of its original value |
Question 42 Explanation:
If any two rows (or columns) of a determinant are interchanged, then sign of determinant changes.
The value of the determinant remains unchanged if both rows and columns are interchanged.
The value of the determinant remains unchanged if both rows and columns are interchanged.
Question 43 |
If A, B, C are any three matrices, then A’+ B’+ C’ is equal to
a null matrix | |
A+B+C | |
(A+B+C)’ | |
-(A+B+C) |
Question 43 Explanation:
Question 44 |
The shift operator E is defined as E[f(xi)] = f(xi + h) and E'[f(xi)] = f(xi – h) then △ (forward difference) in terms of E is
E-1 | |
E | |
1 – E-1 | |
1 – E |
Question 44 Explanation:
Question 45 |
The formula:
is called
is called
Simpson rule | |
Trapezoidal rule | |
Romberg’s rule | |
Gregory’s formula |
Question 45 Explanation:
The above formula is for trapezoidal rule.
Question 46 |
The image
Newton’s backward formula | |
Gauss forward formula | |
Gauss backward formula | |
Stirling’s formula |
Question 46 Explanation:
The above formula is NEWTON’S GREGORY BACKWARD INTERPOLATION FORMULA
Question 47 |
2 | |
3 | |
4 | |
5 |
Question 47 Explanation:
From the given data is determinant = 3
The determinant of 2x2 matrix is (ad-bc), If the elements are a,b,c and d.
From the given matrix, a=3,b=3,c=x and d=5 then ad-bc =15-3x
15-3x=3 ⇒ 3x=12 ⇒ x=4
The determinant of 2x2 matrix is (ad-bc), If the elements are a,b,c and d.
From the given matrix, a=3,b=3,c=x and d=5 then ad-bc =15-3x
15-3x=3 ⇒ 3x=12 ⇒ x=4
Question 48 |
779 | |
679 | |
0 | |
256 |
Question 48 Explanation:
Determinant of any symmetric matrix is zero
Question 49 |
Let f(x) be the continuous probability density function of a random variable x, the probability that a < x ≤ b, is
f (b − a) | |
f (b) − f (a) | |
 | |
 |
Question 49 Explanation:
A non-discrete random variable X is said to be absolutely continuous, or simply continuous, if its distribution function may be represented as
Question 50 |
Let G be an arbitrary graph with n nodes and k components. If a vertex is removed from G, the number of components in the resultant graph must necessarily lie down between
k and n | |
k-1 and k+1 | |
k-1 and n-1 | |
k+1 and n-k |
Question 50 Explanation:
→ While a vertex is removed from a graph then that can be itself be forms a new component. The minimum number of components is k-1.
→ If a vertex is removed then it results that all the components are also be disconnected. So removal can create (n-1) components
→ If a vertex is removed then it results that all the components are also be disconnected. So removal can create (n-1) components
Question 51 |
A root of equation f(x) = 0 can be computed to any degree of accuracy if a ‘good’ initial approximation x0 is chosen for which
f (x0) > 0 | |
f (x0) f (x0)” > 0 | |
f (x0) f (x0)” < 0 | |
f (x0)” > 0 |
Question 52 |
Which of the following statement is correct
△(UkVk) = Uk△Vk + Vk△Uk | |
△(UkVk) = Uk+1△Vk + Vk+1△Uk | |
△(UkVk) = Vk+1△Uk + Uk△Vk | |
△(UkVk) = Uk+1△Vk + Vk△Uk |
Question 53 |
Which of the following is true?
√3 + √7 = √10 | |
√3 + √7 ≤ √10 | |
√3 + √7 < √10 | |
√3 + √7 > √10 |
Question 53 Explanation:
√3 + √7=1.7320508075688772935274463415059 + 2.6457513110645905905016157536393
=4.3778021186334678840290620951451
√10=3.1622776601683793319988935444327
So, √3 + √7 > √10 is true.
=4.3778021186334678840290620951451
√10=3.1622776601683793319988935444327
So, √3 + √7 > √10 is true.
Question 54 |
A given connected graph is a Euler Graph if and only if all vertices of are of
same degree | |
even degree | |
odd degree | |
different degree |
Question 54 Explanation:
A given connected graph is a Euler Graph if and only if all vertices of are of even degree.
Proof:
→ Let G(V, E) be an Euler graph. Thus G contains an Euler line Z, which is a closed walk.
→ Let this walk start and end at the vertex u ∈ V. Since each visit of Z to an intermediate vertex v of Z contributes two to the degree of v and since Z traverses each edge exactly once, d(v) is even for every such vertex.
→ Each intermediate visit to u contributes two to the degree of u, and also the initial and final edges of Z contribute one each to the degree of u. So the degree d(u) of u is also even.
Proof:
→ Let G(V, E) be an Euler graph. Thus G contains an Euler line Z, which is a closed walk.
→ Let this walk start and end at the vertex u ∈ V. Since each visit of Z to an intermediate vertex v of Z contributes two to the degree of v and since Z traverses each edge exactly once, d(v) is even for every such vertex.
→ Each intermediate visit to u contributes two to the degree of u, and also the initial and final edges of Z contribute one each to the degree of u. So the degree d(u) of u is also even.
Question 55 |
The maximum number of edges in a n-node undirected graph without self loops is
n2 | |
n(n-1)/2 | |
n-1 | |
n(n+1)/2 |
Question 55 Explanation:
The set of vertices has size n, the number of such subsets is given by the binomial coefficient C(n,2)⋅C(n,2)=n(n-1)/2.
Question 56 |
If A and B are square matrices with same order and A is symmetric, then BTAB
Skew symmetric | |
Symmetric | |
Orthogonal | |
Idempotent |
Question 56 Explanation:
For a Symmetric matrix, A’ = A
So, BTAB = B'.A.B
Taking transpose of B’.A.B
(B'.A.B)' = B'.A'.(B')' = B'.A.B // (B')' = B
So, it is a symmetric matrix.
So, BTAB = B'.A.B
Taking transpose of B’.A.B
(B'.A.B)' = B'.A'.(B')' = B'.A.B // (B')' = B
So, it is a symmetric matrix.
Question 57 |
n-th derivative of xn is
n xn-1 | |
nn . n! | |
nxn ! | |
n! |
Question 57 Explanation:
Question 58 |
Three coins are tossed simultaneously. The probability that they will fall two heads and one tail is
5/8 | |
1/8 | |
2/3 | |
3/8 |
Question 58 Explanation:
Three coins tossed means , total number of combinations(possibilities) are 23=8
The combinations are (HHH,HHT,HTH,HTT,TTT,TTH,THT,THH)
The number of combinations with two heads and one tail is HHT,HTH,THH
The the probability is the number of combinations of the event/ total combinations of the event = 3/8
The combinations are (HHH,HHT,HTH,HTT,TTT,TTH,THT,THH)
The number of combinations with two heads and one tail is HHT,HTH,THH
The the probability is the number of combinations of the event/ total combinations of the event = 3/8
Question 59 |
How many edges are there in a forest with v vertices and k components?
(v+1)−k | |
(v+1)/2 −k | |
v−k | |
v+k |
Question 59 Explanation:
Method-1:
→ Suppose, if each vertex is a component, then k=v, then there will not be any edges among them. So, v-k= 0 edges.
Method-2:
→ According to pigeonhole principle, every component have v/k vertices.
→ Every component there will be (v/k)-1 edges.
→ Total k components and edges= k*((v/k)-1)
= v–k
→ Suppose, if each vertex is a component, then k=v, then there will not be any edges among them. So, v-k= 0 edges.
Method-2:
→ According to pigeonhole principle, every component have v/k vertices.
→ Every component there will be (v/k)-1 edges.
→ Total k components and edges= k*((v/k)-1)
= v–k
Question 60 |
Which one of the following is true?
R ∩ S = (R ∪ S) − [(R − S) ∪ (S − R)] | |
R ∪ S = (R ∩ S) − [(R − S) ∪ (S − R)] | |
R ∩ S = (R ∪ S) − [(R − S) ∩ (S − R)] | |
R ∩ S = (R ∪ S) ∪ (R − S) |
Question 60 Explanation:
This is direct formula for set theory.
R∩S = (R ∪ S) − [(R − S) ∪ (S − R)]
R∩S = (R ∪ S) − [(R − S) ∪ (S − R)]
Question 61 |
What is the matrix that represents the rotation of an object by θ degree about the origin in 2D?
 | |
 | |
 | |
 |
Question 61 Explanation:
→The matrix representation of a counter-clockwise rotation by θ degrees about the origin.
Question 62 |
The number of edges in a ‘n’ vertex complete graph is ?
n * (n-1) / 2 | |
n * (n+1) / 2 | |
n2 | |
n * (n+1) |
Question 62 Explanation:
Complete graph is an undirected graph in which each vertex is connected to every vertex, other than itself. If there are ‘n’ vertices then total edges in a complete graph is n(n-1)/2
Question 63 |
The number of elements in the power set of the set {{A,B},C} is
7 | |
8 | |
3 | |
4 |
Question 63 Explanation:
For ‘n’ elements in a set, there are 2n elements in the corresponding power set.
Given set = {{A, B},C}
Power set = { {{A, B}}, {C}, {{A, B}, C}}, ϕ}
So, total 4 elements are present in the power set.
Given set = {{A, B},C}
Power set = { {{A, B}}, {C}, {{A, B}, C}}, ϕ}
So, total 4 elements are present in the power set.
Question 64 |
Let P(E) denote the probability of the occurrence of event E. If P(A) = 0.5 and P(B) = 1, then the values of P(A/B) and P(B/A) respectively are
0.5, 0.25 | |
0.25, 0.5 | |
0.5, 1 | |
1, 0.5 |
Question 64 Explanation:
Given data is
→P(E) denote the probability of the occurrence of event E
→P(A) = 0.5 and P(B) = 1
→Conditional probability is a measure of the probability of an event (some particular situation occurring) given that another event has occurred.
→If the event of interest is A and the event B is known or assumed to have occurred, "the conditional probability of A given B", or "the probability of A under the condition B", is usually written as P(A | B), or PB(A)
→P(A/B) = P(A ∩ B)/P(B)
→If two events A and B are independent, then the probability of both events is the product of the probabilities for each event: P(A ∩ B) = P(A)P(B)
→P(A/B) = P(A) * P(B) / P(B)
→P(A/B) = 0.5
→Similarly, P(B/A) = P(A) * P(B) / P(A) and P(B/A) = 1
→P(E) denote the probability of the occurrence of event E
→P(A) = 0.5 and P(B) = 1
→Conditional probability is a measure of the probability of an event (some particular situation occurring) given that another event has occurred.
→If the event of interest is A and the event B is known or assumed to have occurred, "the conditional probability of A given B", or "the probability of A under the condition B", is usually written as P(A | B), or PB(A)
→P(A/B) = P(A ∩ B)/P(B)
→If two events A and B are independent, then the probability of both events is the product of the probabilities for each event: P(A ∩ B) = P(A)P(B)
→P(A/B) = P(A) * P(B) / P(B)
→P(A/B) = 0.5
→Similarly, P(B/A) = P(A) * P(B) / P(A) and P(B/A) = 1
Question 65 |
What is the least value of the function f(x) = 2x2– 8x – 3 in the interval [ 0 , 5] ?
-15 | |
7 | |
-11 | |
-3 |
Question 65 Explanation:
One method is trial and error method
Substitute all the value of x from 0 to 5
The value of f(x) is -3 when x=0
The value of f(x) is -9 when x=1
The value of f(x) is -11 when x=2
The value of f(x) is -9 when x=3
The value of f(x) is -3 when x=4
The value of f(x) is -7 when x=5
so the least value is -11
Second method:
→We can solve this one by using derivatives.
→Given function is f(x) = 2x2 -8x -3
→ f'(x)=4x-8 (first derivative)
a f''(x)=4 (Second derivative)
Here we got constant value which means that it has minimal value at the point x=2
So we can find the minimum value by substituting value 2 in place of “x” in the given function.
Minimum value is 2⨉(2)2 -8⨉(2) -3= -11
Substitute all the value of x from 0 to 5
The value of f(x) is -3 when x=0
The value of f(x) is -9 when x=1
The value of f(x) is -11 when x=2
The value of f(x) is -9 when x=3
The value of f(x) is -3 when x=4
The value of f(x) is -7 when x=5
so the least value is -11
Second method:
→We can solve this one by using derivatives.
→Given function is f(x) = 2x2 -8x -3
→ f'(x)=4x-8 (first derivative)
a f''(x)=4 (Second derivative)
Here we got constant value which means that it has minimal value at the point x=2
So we can find the minimum value by substituting value 2 in place of “x” in the given function.
Minimum value is 2⨉(2)2 -8⨉(2) -3= -11
Question 66 |
Let R be the radius of the circle. What is the angle subtended by an arc of length at the center of the circle?
1 degree | |
1 radian | |
90 degrees | |
π radians |
Question 66 Explanation:
A degree (in full, a degree of arc, arc degree, or arc degree), usually denoted by ° (the degree symbol), is a measurement of a plane angle, defined so that a full rotation is 360 degrees.
It is not an SI unit, as the SI unit of angular measure is the radian, but it is mentioned in the SI brochure as an accepted unit.Because a full rotation equals 2π radians.
The radian (SI symbol rad) is the SI unit for measuring angles, and is the standard unit of angular measure used in many areas of mathematics. The length of an arc of a unit circle is numerically equal to the measurement in radians of the angle that it subtends;
It is not an SI unit, as the SI unit of angular measure is the radian, but it is mentioned in the SI brochure as an accepted unit.Because a full rotation equals 2π radians.
The radian (SI symbol rad) is the SI unit for measuring angles, and is the standard unit of angular measure used in many areas of mathematics. The length of an arc of a unit circle is numerically equal to the measurement in radians of the angle that it subtends;
Question 67 |
The number of bit strings of length 8 that will either start with 1 or end with 00 is?
32 | |
128 | |
160 | |
192 |
Question 67 Explanation:
→ Number of bit strings of length 8 that start with 1: 27 = 128.
→ Number of bit strings of length 8 that end with 00: 26 = 64.
→ Number of bit strings of length 8 that start with 1 and end with 00: 25 = 32.
→ Applying the subtraction rule, the number is 128+64−32 = 160
→ Number of bit strings of length 8 that end with 00: 26 = 64.
→ Number of bit strings of length 8 that start with 1 and end with 00: 25 = 32.
→ Applying the subtraction rule, the number is 128+64−32 = 160
Question 68 |
The conic section that is obtained when a right circular cone is cut through a plane that is parallel to the side of the cone is called
parabola | |
hyperbola | |
circle | |
ellipse |
Question 68 Explanation:
Question 69 |
The rank of a matrix A =
0 | |
1 | |
2 | |
3 |
Question 69 Explanation:
Given matrix
Question 70 |
What is the median of data if its mode is 15 and the mean is 30?
30 | |
25 | |
22.5 | |
27.5 |
Question 70 Explanation:
In a moderately symmetric distribution, the mean, median and mode are connected by the formula:
Mode = 3 Median – 2 Mean
15 = 3 Median - 2(30)
Median = 25
Mode = 3 Median – 2 Mean
15 = 3 Median - 2(30)
Median = 25
Question 71 |
Let A be a finite set having x elements and let B be a finite set having y elements. What is the number of distinct functions mapping B into A.
xy | |
2 (x+y) | |
yx | |
y! / (y-x)! |
Question 71 Explanation:
A function on a set involves running the function on every element of the set A, each one producing some result in the set B. So, for
the first run, every element of A gets mapped to an element in B. Take this
example, mapping a 2 element set A, to a 3 element set B. There are 9 different
ways, all beginning with both 1 and 2, that result in some different combination of
mappings over to B.
Question 72 |
The probability that two friends are born in the same month is?
1/6 | |
1/12 | |
1/144 | |
1/24 |
Question 72 Explanation:
Probability of a person to be born in a one month out of 12 months is 1/12
Probability of both friends born in a same month is (1/12) * (1/12)
Suppose, they born in january = 1/12 * 1/12
Suppose, they born in february = 1/12 * 1/12
; ; Suppose, they born in December = 1/12 * 1/12
Probability that two friends are born in the same month is= 12*(1/12)*(1/12)
= 1/12
Probability of both friends born in a same month is (1/12) * (1/12)
Suppose, they born in january = 1/12 * 1/12
Suppose, they born in february = 1/12 * 1/12
; ; Suppose, they born in December = 1/12 * 1/12
Probability that two friends are born in the same month is= 12*(1/12)*(1/12)
= 1/12
Question 73 |
A cube of side 1 unit is placed in such a way that the origin coincides with one of its top vertices and the three axes along three of its edges. What are the coordinates of the vertex which is diagonally opposite to the vertex whose coordinates are (1,0,1)?
(0, 0, 0) | |
(0, -1, 0) | |
(0, 1, 0) | |
(1, 1, 1) |
Question 73 Explanation:
Question 74 |
To guarantee correction of upto t errors, the minimum Hamming distance dmin in a block code must be
t+1 | |
t−2
| |
2t−1 | |
2t+1 |
Question 74 Explanation:
For detect t-bit errors a hamming distance of t+1 bit is needed but to correct the t-bit error the hamming distance of 2t+1 bit is needed.
Question 75 |
Consider the following statements :
-
(a) False╞ True
(b) If α╞ (β ∧ γ) then α╞ β and α╞ γ.
Which of the following is correct with respect to the above statements ?
Both statement (a) and statement (b) are false. | |
Statement (a) is true but statement (b) is false. | |
Statement (a) is false but statement (b) is true.
| |
Both statement (a) and statement (b) are true.
|
Question 75 Explanation:
(a) False╞ True is nothing but False=False|True (or) False=False V True
(b) α╞ (β ∧ γ) also write αV(β ∧ γ)
α╞ β and α╞ γ also write (αVβ)∧(αVγ)
Finally, we proved as LHS=RHS. αV(β ∧ γ) = (αVβ)∧(αVγ)
So, both the statements are correct.
(b) α╞ (β ∧ γ) also write αV(β ∧ γ)
α╞ β and α╞ γ also write (αVβ)∧(αVγ)
Finally, we proved as LHS=RHS. αV(β ∧ γ) = (αVβ)∧(αVγ)
So, both the statements are correct.
Question 76 |
Consider the following English sentence :
“Agra and Gwalior are both in India”.
A student has written a logical sentence for the above English sentence in First-Order Logic using predicate In(x, y), which means x is in y, as follows :
In(Agra, India) ⋁ In(Gwalior, India)
Which one of the following is correct with respect to the above logical sentence ?
It is syntactically valid but does not express the meaning of the English sentence. | |
It is syntactically valid and expresses the meaning of the English sentence also.
| |
It is syntactically invalid but expresses the meaning of the English sentence. | |
It is syntactically invalid and does not express the meaning of the English sentence. |
Question 76 Explanation:
• In(Agra, India) means Agra is in india.
• In(Gwalior, India) means Gwalior is in india.
• In(Agra, India) ⋁ In(Gwalior, India), in this statement “⋁” means “or” So the entire gives the meaning of Either Agra is in india or Gwalior is in india.
• The statement is not expressing the meaning of English sentence.
• In(Gwalior, India) means Gwalior is in india.
• In(Agra, India) ⋁ In(Gwalior, India), in this statement “⋁” means “or” So the entire gives the meaning of Either Agra is in india or Gwalior is in india.
• The statement is not expressing the meaning of English sentence.
Question 77 |
Consider the following two sentences :
- (a) The planning graph data structure can be used to give a better heuristic for a planning problem.
(b) Dropping negative effects from every action schema in a planning problem results in a relaxed problem.
Which of the following is correct with respect to the above sentences ?
Both sentence (a) and sentence (b) are false. | |
Both sentence (a) and sentence (b) are true.
| |
Sentence (a) is true but sentence (b) is false.
| |
Sentence (a) is false but sentence (b) is true. |
Question 77 Explanation:
• Negative effects put restrictions on the action schema. When these restrictions are put into place, then the number of actions that can be taken to get to the next time step decreases because with each addition of a restriction, the actions that do not meet the restriction are filtered out.
• When these negative effects are dropped, then the number of actions increase and dropping all of the negative effects from the action schema results in a relaxed problem.
• A planning graph is a directed graph organized into levels: first a level S0 for the initial state, consisting of nodes representing each fluent that holds in S0; then a level A0 consisting of nodes for each ground action that might be applicable in S0; then alternating levels Si followed by Ai ; until we reach a termination condition.
• As a tool for generating accurate heuristics, we can view the planning graph as a relaxed problem that is efficiently solvable.
• When these negative effects are dropped, then the number of actions increase and dropping all of the negative effects from the action schema results in a relaxed problem.
• A planning graph is a directed graph organized into levels: first a level S0 for the initial state, consisting of nodes representing each fluent that holds in S0; then a level A0 consisting of nodes for each ground action that might be applicable in S0; then alternating levels Si followed by Ai ; until we reach a termination condition.
• As a tool for generating accurate heuristics, we can view the planning graph as a relaxed problem that is efficiently solvable.
Question 78 |
A knowledge base contains just one sentence, ∃x AsHighAs (x, Everest). Consider the following two sentences obtained after applying existential instantiation.
- (a) AsHighAs (Everest, Everest)
(b) AsHighAs (Kilimanjaro, Everest)
Which of the following is correct with respect to the above sentences ?
Both sentence (a) and sentence (b) are sound conclusions.
| |
Both sentence (a) and sentence (b) are unsound conclusions. | |
Sentence (a) is sound but sentence (b) is unsound.
| |
Sentence (a) is unsound but sentence (b) is sound.
|
Question 78 Explanation:
• The ∃x AsHighAs (x, Everest) means there is one element which as highest as Everest.
• In the statement (a) AsHighAs (Everest, Everest), both are Everest then we can’t compare.
• The statement (b) AsHighAs (Kilimanjaro, Everest) means there kilimanjaro which is as highest as Everest So this valid statement.Because we are comparing Kilimanjaro with Everest.
• In the statement (a) AsHighAs (Everest, Everest), both are Everest then we can’t compare.
• The statement (b) AsHighAs (Kilimanjaro, Everest) means there kilimanjaro which is as highest as Everest So this valid statement.Because we are comparing Kilimanjaro with Everest.
Question 79 |
Consider the set of all possible five-card poker hands dealt fairly from a standard deck of fifty-two cards. How many atomic events are there in the joint probability distribution ?
2,598,960
| |
3,468,960 | |
3,958,590
| |
2,645,590
|
Question 79 Explanation:
→ Joint probability distribution:
Given random variables X, Y, …, that are defined on a probability space, the joint probability distribution for X, Y, … is a probability distribution that gives the probability that each of X, Y, … falls in any particular range or discrete set of values specified for that variable. In the case of only two random variables, this is called a bivariate distribution, but the concept generalizes to any number of random variables, giving a multivariate distribution.
Given data,
- Total cards = 52
- poker hand = 5 cards of all possibilities
Step-1: This problem, we are simply finding combinations of 52C5
= C(n,r) = C(52,5)
= 52! / (5!(52-5)!)
= 2598960
Given random variables X, Y, …, that are defined on a probability space, the joint probability distribution for X, Y, … is a probability distribution that gives the probability that each of X, Y, … falls in any particular range or discrete set of values specified for that variable. In the case of only two random variables, this is called a bivariate distribution, but the concept generalizes to any number of random variables, giving a multivariate distribution.
Given data,
- Total cards = 52
- poker hand = 5 cards of all possibilities
Step-1: This problem, we are simply finding combinations of 52C5
= C(n,r) = C(52,5)
= 52! / (5!(52-5)!)
= 2598960
Question 80 |
Which of the following statements is false about convex minimization problem ?
If a local minimum exists, then it is a global minimum
| |
The set of all global minima is convex set
| |
The set of all global minima is concave set | |
For each strictly convex function, if the function has a minimum, then the minimum is unique |
Question 80 Explanation:
Properties of convex optimization problems:
1. Every local minimum is a global minimum
2. The optimal set is convex
3. If the objective function is strictly convex, then the problem has at most one optimal point.
These results are used by the theory of convex minimization along with geometric notions from functional analysis (in Hilbert spaces) such as the Hilbert projection theorem, the separating hyperplane theorem, and Farkas' lemma.
1. Every local minimum is a global minimum
2. The optimal set is convex
3. If the objective function is strictly convex, then the problem has at most one optimal point.
These results are used by the theory of convex minimization along with geometric notions from functional analysis (in Hilbert spaces) such as the Hilbert projection theorem, the separating hyperplane theorem, and Farkas' lemma.
Question 81 |
The following LPP
-
Maximize z = 100x1 + 2x2 + 5x3
Subject to 14x1 + x2 − 6x3 + 3x4 = 7
32x1 + x2 − 12x3 ≤ 10 3x1 − x2 − x3 ≤ 0 x1 , x2 , x3 , x4 ≥ 0 has
Solution : x1 = 100, x2 = 0, x3 = 0
| |
Unbounded solution | |
No solution
| |
Solution : x1 = 50, x2 = 70, x3 = 60
|
Question 81 Explanation:
An unbounded solution of a linear programming problem is a situation where objective function is infinite.
A linear programming problem is said to have unbounded solution if its solution can be made infinitely large without violating any of its constraints in the problem.
A linear programming problem is said to have unbounded solution if its solution can be made infinitely large without violating any of its constraints in the problem.
Question 82 |
Digital data received from a sensor can fill up 0 to 32 buffers. Let the sample space be S = {0, 1, 2, .........., 32} where the sample j denote that j of the buffers are full and P(i) = 1/561 (33-i).
Let A denote the event that the even number of buffers are full. Then p(A) is:0.515 | |
0.785 | |
0.758 | |
0.485 |
Question 82 Explanation:
• Probability of ith buffer getting full = p(i) = 1/562(33−i)
• Probability of all even number of buffers are full is P(A).
• We are going find the values of P(0),P(2),P(4),P(6) …. P(16).
• P(0) is 1/562 (33-0)
• P(2) is 1/562 (33-2)
• …
• P(16) is 1/562 (33-32)
• The probability of all even number of buffers are full is P(A) which is equal to P(0)+P(2)+P(4)+P(6)+ …. P(16).
• P(A) = 1/562(33+31+29+27+....+1)
• P(A) = 1562×289 = 0.51423
• Probability of all even number of buffers are full is P(A).
• We are going find the values of P(0),P(2),P(4),P(6) …. P(16).
• P(0) is 1/562 (33-0)
• P(2) is 1/562 (33-2)
• …
• P(16) is 1/562 (33-32)
• The probability of all even number of buffers are full is P(A) which is equal to P(0)+P(2)+P(4)+P(6)+ …. P(16).
• P(A) = 1/562(33+31+29+27+....+1)
• P(A) = 1562×289 = 0.51423
Question 83 |
The equivalence of ¬∃ x Q(x) is :
∃x ¬Q(x) | |
∀x ¬Q(x) | |
¬∃ x ¬Q(x) | |
∀x Q(x) |
Question 83 Explanation:
We can write it as ¬∃x Q(x) = ∀x ¬Q(x).
Question 84 |
If Ai = {−i, ... −2,−1, 0, 1, 2, . . . . . i} then 
is:
is:Z | |
Q | |
R | |
C |
Question 84 Explanation:
• In mathematics, there are multiple number sets: the natural numbers N, the set of integers Z, all decimal numbers D, the set of rational numbers Q, the set of real numbers R and the set of complex numbers C.
Z number set:
• Z is the set of integers, ie. positive, negative or zero.
• Example: ..., -100, ..., -12, -11, -10, ..., -5, -4, -3, -2, - 1, 0, 1, 2, 3, 4, 5, ... 10, 11, 12, ..., 100, ...
• The set N is included in the set Z (because all natural numbers are part of the relative integers).
• The set A consists of Positive, negative and zero numbers.
Z number set:
• Z is the set of integers, ie. positive, negative or zero.
• Example: ..., -100, ..., -12, -11, -10, ..., -5, -4, -3, -2, - 1, 0, 1, 2, 3, 4, 5, ... 10, 11, 12, ..., 100, ...
• The set N is included in the set Z (because all natural numbers are part of the relative integers).
• The set A consists of Positive, negative and zero numbers.
Question 85 |
Match the following in List-I and List-II, for a function f :
List-I List-II (a) ∀x∀y(f(x)=f(y)⟶x=y) (i) Constant (b) ∀y∃x(f(x)=y) (ii) Injective (c) ∀xf(x)=k (iii) Surjective
(a)-(i), (b)-(ii), (c)-(iii)
| |
(a)-(iii), (b)-(ii), (c)-(i) | |
(a)-(ii), (b)-(i), (c)-(iii) | |
(a)- (ii), (b)-(iii), (c)-(i)
|
Question 85 Explanation:
• The function is injective (one-to-one) if each element of the codomain is mapped to by at most one element of the domain. An injective function is an injection. Notationally:
x, x' ∈ X, f(x) = f(x') ⇒ x = x'
Or, equivalently (using logical transposition),
x, x' ∈ X, x ≠ x' f(x) ≠ f(x')
• The function is surjective (onto) if each element of the codomain is mapped to by at least one element of the domain. (That is, the image and the codomain of the function are equal.) A surjective function is a surjection. Notationally:
∀y ∈ Y, ∃x ∈ X such that y = f(x)
A constant function is a function whose (output) value is the same for every input value.
For example, the function y(x) = 4 is a constant function because the value y(x) is 4 regardless of the input value x.
x, x' ∈ X, f(x) = f(x') ⇒ x = x'
Or, equivalently (using logical transposition),
x, x' ∈ X, x ≠ x' f(x) ≠ f(x')
• The function is surjective (onto) if each element of the codomain is mapped to by at least one element of the domain. (That is, the image and the codomain of the function are equal.) A surjective function is a surjection. Notationally:
∀y ∈ Y, ∃x ∈ X such that y = f(x)
A constant function is a function whose (output) value is the same for every input value.
For example, the function y(x) = 4 is a constant function because the value y(x) is 4 regardless of the input value x.
Question 86 |
Which of the relations on {0, 1, 2, 3} is an equivalence relation ?
{ (0, 0) (0, 2) (2, 0) (2, 2) (2, 3) (3, 2) (3, 3) } | |
{ (0, 0) (1, 1) (2, 2) (3, 3) }
| |
{ (0, 0) (0, 1) (0, 2) (1, 0) (1, 1) (1, 2) (2, 0) } | |
{ (0, 0) (0, 2) (2, 3) (1, 1) (2, 2) }
|
Question 86 Explanation:
→ A relation on a set A is called an equivalence relation if it is reflexive, symmetric, and transitive.
1. Reflexivity: f(x) = f(x)
True, as given the same input, a function always produces the same output.
2. Symmetry: if f(x) = f(y) then f(y) = f(x)
True, by the definition of equality.
3. Transitivity: if f(x) = f(y) and f(y) = f(z) then f(x) = f(z)
True, by the definition of equality.
Option-2: { (0,0), (1,1), (2,2), (3,3) }
Has all the properties, thus, is an equivalence relation.
Option-1: { (0,0), (0,2), (2,0), (2,2), (2,3), (3,2), (3,3) }
Not reflexive: (1,1) is missing
Not transitive: (0,2) and (2,3) are in the relation, but not (0,3)
Option-3: { (0,0), (0,1) (0,2), (1,0), (1,1), (1,2), (2,0), (2,2), (3,3) }
Not symmetric: (1,2) is present, but not (2,1).
Not transitive: (2,0) and (0,1) are in the relation, but not (2,1).
Option-4: Similarly, option-4 also not TRUE
1. Reflexivity: f(x) = f(x)
True, as given the same input, a function always produces the same output.
2. Symmetry: if f(x) = f(y) then f(y) = f(x)
True, by the definition of equality.
3. Transitivity: if f(x) = f(y) and f(y) = f(z) then f(x) = f(z)
True, by the definition of equality.
Option-2: { (0,0), (1,1), (2,2), (3,3) }
Has all the properties, thus, is an equivalence relation.
Option-1: { (0,0), (0,2), (2,0), (2,2), (2,3), (3,2), (3,3) }
Not reflexive: (1,1) is missing
Not transitive: (0,2) and (2,3) are in the relation, but not (0,3)
Option-3: { (0,0), (0,1) (0,2), (1,0), (1,1), (1,2), (2,0), (2,2), (3,3) }
Not symmetric: (1,2) is present, but not (2,1).
Not transitive: (2,0) and (0,1) are in the relation, but not (2,1).
Option-4: Similarly, option-4 also not TRUE
Question 87 |
Which of the following is an equivalence relation on the set of all functions from Z to Z ?
{(f, g) | f(x) - g(x) = 1 ∀ x∈Z}
| |
{(f, g) | f(0) = g(0) or f(1) = g(1)} | |
{(f, g) | f(0) = g(1) and f(1) = g(0)}
| |
{(f, g) | f(x) - g(x) = k for some k∈Z}
|
Question 87 Explanation:
An equivalence relation is a binary relation that is reflexive, symmetric and transitive.
The relation "is equal to" is the canonical example of an equivalence relation, where for any objects a, b, and c:
a = a (reflexive property),
if a = b then b = a (symmetric property), and
if a = b and b = c then a = c (transitive property)
The relation "is equal to" is the canonical example of an equivalence relation, where for any objects a, b, and c:
a = a (reflexive property),
if a = b then b = a (symmetric property), and
if a = b and b = c then a = c (transitive property)
Question 88 |
Which of the following statements is true ?
(Z, ≤) is not totally ordered
| |
The set inclusion relation ⊆ is a partial ordering on the power set of a set S | |
(Z, ≠) is a poset | |
Question 88 Explanation:
Option 1: (Z, ≤)is false because
Option 2: This is TRUE, because the set inclusion relation ⊆ is a partial ordering on the power set of S.
Example: Suppose the set S = {a,b}, the maximum possibilities are {φ, a, b, ab}
Option 3: (z,≠)is false, because if violates reflexive relation.
Option 4: FALSE.
Option 2: This is TRUE, because the set inclusion relation ⊆ is a partial ordering on the power set of S.
Example: Suppose the set S = {a,b}, the maximum possibilities are {φ, a, b, ab}
Option 3: (z,≠)is false, because if violates reflexive relation.
Option 4: FALSE.
Question 89 |
____ number of undirected graphs can be constructed using V=(v1,v2,..vn).
n3 | |
2n(n-1)/2 | |
n-½ | |
2(n-1)/2 |
Question 89 Explanation:
→ With n vertices no. of possible edges = nC2
→ Each subset of these edges will be form a graph.
→ Number of possible undirected graphs is 2(nC2) 2(n(n-1)/2)
→ Each subset of these edges will be form a graph.
→ Number of possible undirected graphs is 2(nC2) 2(n(n-1)/2)
Question 90 |
Consider the set S={1,w,w 2 }, where w and w 2 are cube roots of unity. If * denotes the multiplication operation, the structure (S,*) forms:
A group | |
A ring | |
An integral domain | |
A field |
Question 90 Explanation:
A Group is an algebraic structure which satisfies
1) closure
2) Associativity
3) Have Identity element
4) Invertible
Over ‘*’ operation the S = {1, ω, ω 2 } satisfies the above properties.
The identity element is ‘1’ and inverse of 1 is 1, inverse of ‘w’ is 'w 2 ' and inverse of 'w 2 ' is 'w'.
1) closure
2) Associativity
3) Have Identity element
4) Invertible
Over ‘*’ operation the S = {1, ω, ω 2 } satisfies the above properties.
The identity element is ‘1’ and inverse of 1 is 1, inverse of ‘w’ is 'w 2 ' and inverse of 'w 2 ' is 'w'.
Question 91 |
Two eigenvalues of a 3X3 real matrix P are (2+ √ -1) and 3. The determinant of P is___
0 | |
1 | |
15 | |
-1 |
Question 91 Explanation:
If an eigenvalue of a matrix is a complex number, then there will be other eigenvalue, which is conjugate of the complex eigenvalue.
So, For the given 3×3 matrix there would be 3 eigenvalues.
Given eigenvalues are : 2+i and 3.
So the third eigenvalue should be 2-i.
As per the theorems, the determinant of the matrix is the product of the eigenvalues. So the determinant is (2+i)*(2-i)*3 = 15.
So, For the given 3×3 matrix there would be 3 eigenvalues.
Given eigenvalues are : 2+i and 3.
So the third eigenvalue should be 2-i.
As per the theorems, the determinant of the matrix is the product of the eigenvalues. So the determinant is (2+i)*(2-i)*3 = 15.
Question 92 |
What is the possible number of reflexive relation on a set of 5 elements?
210 | |
215 | |
220 | |
225 |
Question 92 Explanation:
Let set = ‘A’ with ‘n’ elements,
Definition of Reflexive relation:
A relation ‘R’ is reflexive if it contains xRx ∀ x∈A
A relation with all diagonal elements, it can contain any combination of non-diagonal elements.
Eg:
A={1, 2, 3}
So for a relation to be reflexive, it should contain all diagonal elements. In addition to them, we can have possible combination of (n 2 -n)non-diagonal elements (i.e., 2 n2-n )
Ex:
{(1,1)(2,2)(3,3)} ----- ‘0’ non-diagonal element
{(1,1)(2,2)(3,3)(1,2)} ----- ‘1’ non-diagonal element
{(1,1)(2,2)(3,3)(1,2)(1,3)} “
___________ “
___________ “
{(1,1)(2,2)(3,3)(1,2)(1,3)(2,1)(2,3)(3,1)(3,2)} (n 2 -n) diagonal elements
____________________
Total: 2 (n2 -n)
For the given question n = 5.
The number of reflexive relations =2 (25-5) =2 20
Definition of Reflexive relation:
A relation ‘R’ is reflexive if it contains xRx ∀ x∈A
A relation with all diagonal elements, it can contain any combination of non-diagonal elements.
Eg:
A={1, 2, 3}
So for a relation to be reflexive, it should contain all diagonal elements. In addition to them, we can have possible combination of (n 2 -n)non-diagonal elements (i.e., 2 n2-n )
Ex:
{(1,1)(2,2)(3,3)} ----- ‘0’ non-diagonal element
{(1,1)(2,2)(3,3)(1,2)} ----- ‘1’ non-diagonal element
{(1,1)(2,2)(3,3)(1,2)(1,3)} “
___________ “
___________ “
{(1,1)(2,2)(3,3)(1,2)(1,3)(2,1)(2,3)(3,1)(3,2)} (n 2 -n) diagonal elements
____________________
Total: 2 (n2 -n)
For the given question n = 5.
The number of reflexive relations =2 (25-5) =2 20
Question 93 |
Mala has a colouring book in which each english letter is drawn two times. She wants to point each of these 52 prints with one of k colours, such that the colour-pairs used to colour ay two letters are different. Both prints of a letter can also be coloured with the same colour. What is the minimum value of k that satisfies this requirement?
9 | |
8 | |
7 | |
6 |
Question 93 Explanation:
No. of letters from A-Z is = 26
Each is printed twice the no. of letters = 26×2 = 52
If Mala has k colours, she can have k pairs of same colours.
She also can have k C 2 different pairs in which each pair is having different colours.
So total no. of pairs that can be coloured = k+ k C 2
k+ k C 2 ≥ 26
k+k(k-1)/2 ≥ 26
k(k+1)/2 ≥ 26
k(k+1) ≥ 52
k(k+1) ≥ 7*8
k≥7
Each is printed twice the no. of letters = 26×2 = 52
If Mala has k colours, she can have k pairs of same colours.
She also can have k C 2 different pairs in which each pair is having different colours.
So total no. of pairs that can be coloured = k+ k C 2
k+ k C 2 ≥ 26
k+k(k-1)/2 ≥ 26
k(k+1)/2 ≥ 26
k(k+1) ≥ 52
k(k+1) ≥ 7*8
k≥7
Question 94 |
In propositional logic, which of the following is equivalent to p → q?
~p → q | |
~p V q | |
~p V ~q | |
p → ~q |
Question 94 Explanation:
We can use a truth table to determine if two compound propositions are logically equivalent, i.e if they always have the same truth values.
Question 95 |
Which of the following is FALSE?
Read ⋀ as AND, ⋁ as OR, ~ as NOT, → as one way implication and ⬌ as two way implication?
Read ⋀ as AND, ⋁ as OR, ~ as NOT, → as one way implication and ⬌ as two way implication?
((x→ y)⋀ x)->y | |
((~x→ y)⋀(~x⋀~y)) → x | |
(x→ (x ⋁ y)) | |
((x ⋁ y) ⬌ (~x ⋁ ~y)) |
Question 95 Explanation:
Question 96 |
If f:{a,b}* → {a,b}* be given by f(n)=ax for every value of n∈{a,b}, then f is
{a,b,ab,aa} | |
{a,b,ba,bb} | |
{a,b} | |
{aa,ab,ba,bb} |
Question 96 Explanation:
f:{a,b}* → {a,b}* be given f(n)=ax
→ In option B and D, "ba" is presented which is generated by f. So, we can conclude based on this, option B and D are false.
→ "ab" can be generated by f but which is not present in the option C. So, we can conclude option C is wrong.
→ Option A satisfying all the favorable cases which is generated by f.
→ In option B and D, "ba" is presented which is generated by f. So, we can conclude based on this, option B and D are false.
→ "ab" can be generated by f but which is not present in the option C. So, we can conclude option C is wrong.
→ Option A satisfying all the favorable cases which is generated by f.
Question 97 |
Consider the vocabulary with only four propositions A, B, C and D. How many models are there for the following sentence?
(⌐A∨⌐B∨⌐C∨⌐D)8 | |
7 | |
15 | |
16 |
Question 97 Explanation:
Here, number of models is nothing but number of TRUEs in final statement. In this proposition logic we got total 15 number of models.
Question 98 |
The number of substrings that can be formed from string given by
“a d e f b g h n m p” is
10 | |
45 | |
56 | |
55 |
Question 98 Explanation:
If we have no repetition in a string then the number of substrings can be found using the formula :
n*(n+1)/2 + 1
We have added 1 because it may include a NULL string also.
The number of substrings = 10*(11)/2 + 1
The number of substrings = 56
n*(n+1)/2 + 1
We have added 1 because it may include a NULL string also.
The number of substrings = 10*(11)/2 + 1
The number of substrings = 56
Question 99 |
Match the List 1 and List 2 and choose the correct answer from the code given below
LIST 1 LIST 2 (a) Equivalence (i) p ⇒ q (b) Contrapositive (ii) p ⇒ q : q ⇒ p (c) Converse (iii) p ⇒ q : ∼q ⇒ ∼p (d) Implication (iv) p ⇔ qCode:
(a)-(i), (b)-(ii), (c)-(iii), (d)-(iv)
| |
(a)-(ii), (b)-(i),(c)-(iii), (d)-(iv) | |
(a)-(iv), (b)-(iii), (c)-(ii), (d)-(i) | |
(a)-(iii), (b)-(iv), (c)-(ii), (d)-(i)
|
Question 99 Explanation:
Propositions r and s are logically equivalent if the statement r ↔ s is a tautology.
∼q⇒ ∼p
According to above table,
equivalence means p ⇔ q
Contrapositive means p⇒ q : ∼q⇒ ∼p
Converse means p ⇒ q : q ⇒ p
Implication means p ⇔ q
∼q⇒ ∼p
According to above table,
equivalence means p ⇔ q
Contrapositive means p⇒ q : ∼q⇒ ∼p
Converse means p ⇒ q : q ⇒ p
Implication means p ⇔ q
Question 100 |
The K-coloring of an undirected graph G = (V, E) is a function
C: V ➝ {0, 1, ......, K-1} such that c(u)≠c(v) for every edge (u,v) ∈ E
Which of the following is not correct?
G has no cycles of odd length
| |
G has cycle of odd length
| |
G is 2-colorable
| |
G is bipartite
|
Question 100 Explanation:
• A k-colouring of a graph G consists of k different colours and G is then called k-colourable.
• A cycle of length n ≥ 3 is 2-chromatic if n is even and 3-chromatic if n is odd.
• A graph is bi-colourable (2-chromatic) if and only if it has no odd cycles.
• A nonempty graph G is bicolourable if and only if G is bipartite
• A cycle of length n ≥ 3 is 2-chromatic if n is even and 3-chromatic if n is odd.
• A graph is bi-colourable (2-chromatic) if and only if it has no odd cycles.
• A nonempty graph G is bicolourable if and only if G is bipartite
Question 101 |
If a graph (G) has no loops or parallel edges and if the number of vertices(n) in the graph is n≥3, then the graph G is Hamiltonian if
- (i) deg(v) ≥ n/3 for each vertex v
(ii) deg(v) + deg(w) ≥ n whenever v and w are not connected by an edge.
(iii) E(G) ≥ 1/3(n-1)(n-2) + 2
Choose the correct answer for the code given below:
Code:(i) and (iii) only
| |
(ii) and (iii) only
| |
(iii) only
| |
(ii) only |
Question 101 Explanation:
Option-2 is correct.
→ Dirac's theorem on Hamiltonian cycles, the statement that an n-vertex graph in which each vertex has degree at least n/2 must have a Hamiltonian cycle.
→ Dirac's theorem on chordal graphs, the characterization of chordal graphs as graphs in which all minimal separators are cliques.
→ Dirac's theorem on cycles in k-connected graphs, the result that for every set of k vertices in a k-vertex-connected graph there exists a cycle that passes through all the vertices in the set.
→ Dirac's theorem on Hamiltonian cycles, the statement that an n-vertex graph in which each vertex has degree at least n/2 must have a Hamiltonian cycle.
→ Dirac's theorem on chordal graphs, the characterization of chordal graphs as graphs in which all minimal separators are cliques.
→ Dirac's theorem on cycles in k-connected graphs, the result that for every set of k vertices in a k-vertex-connected graph there exists a cycle that passes through all the vertices in the set.
Question 102 |
A survey has been conducted on methods of commuter travel. Each respondent was asked to check Bus, Train or Automobile as a major methods of travelling to work. More than one answer was permitted. The results reported were as follows :
Bus 30 people; Train 35 people; Automobile 100 people; Bus and Train 15 people; Bus and Automobile 15 people; Train and Automobile 20 people; and all the three methods 5 people. How many people complete the survey form ?
160 | |
120 | |
165 | |
115 |
Question 103 |
A full joint distribution for the Toothache, Cavity and Catch is given in the table below:
Which is the probability of Cavity, given evidence of Toothache ?
< 0.2, 0.8 >
| |
< 0.6, 0.8 >
| |
< 0.4, 0.8 >
| |
< 0.6, 0.4 >
|
Question 104 |
In mathematical logic, which of the following are statements ?
- (i) There will be snow in January
(ii) What is the time now ?
(iii) Today is Sunday
(iv) You must study Discrete Mathematics.
Choose the correct answer from the code given below :
Code :(iii) and (iv) | |
(i) and (ii)
| |
(i) and (iii) | |
(ii) and (iv)
|
Question 104 Explanation:
In mathematical logic, the term statement is variously understood to mean either:
(a) a meaningful declarative sentence that is true or false, or
(b) the assertion that is made by a true or false declarative sentence.
From the above four statements, statement 2 and 4 wont give meaning like true or false answers and statements 1 and 3 will give either true or false answers.
(a) a meaningful declarative sentence that is true or false, or
(b) the assertion that is made by a true or false declarative sentence.
From the above four statements, statement 2 and 4 wont give meaning like true or false answers and statements 1 and 3 will give either true or false answers.
Question 105 |
Consider the statements below :
“There is a country that borders both India and Nepal.“
Which of the following represents the above sentence correctly ?
∃c Border(Country(c), India ∧ Nepal)
| |
∃c Country(c) ∧ Border(c, India) ∧ Border(c, Nepal)
| |
[∃c Country(c)] ⇒ [Border(c,India) ∧ Border(c, Nepal)]
| |
∃c Country(c) ⇒ [ Border(c, India) ∧ Border(c, Nepal)]
|
Question 105 Explanation:
→ ∃c Country(c) which represents there is one country “c”
→ Border(c, India) which represents border between c and india
→ Border(c, Nepal) which represents border between c and Nepal
→ “∧” represents both
Option-2 represents the sentence “There is a country that borders both India and Nepal".
→ Border(c, India) which represents border between c and india
→ Border(c, Nepal) which represents border between c and Nepal
→ “∧” represents both
Option-2 represents the sentence “There is a country that borders both India and Nepal".
Question 106 |
Use Dual Simplex Method to solve the following problem :
- Maximize z = -2x1 - 3x2
subject to:
x1 + x2 ≥ 2
2x1 + x2 ≤ 10
x1 + x2 ≤ 8
x1, x2 ≥ 0
x1 = 6, x2 = 2 and z = -18 | |
x1 = 2, x2 = 6 and z = -22
| |
x1 = 2, x2 = 0 and z = -4
| |
x1 = 0, x2 = 2 and z = -6
|
Question 106 Explanation:
→ One simple method is substitute the option values in the maximize equation Z to know the maximum value of the problem and remaining equations to satisfies the conditions which are given in the problem statement.
→ Option 3 satisfies all conditions and maximize property in the given problem
→ Option 3 satisfies all conditions and maximize property in the given problem
Question 107 |
A box contains six red balls and four green balls. Four balls are selected at random from the box. What is the probability that two of the selected balls will be red and two will be green ?
1/35 | |
1/14
| |
1/9 | |
3/7 |
Question 107 Explanation:
→ Total red balls are 6
→ Green balls are 4
→ Total 10 balls in the box. We need to select 4 balls from 10 balls in which two red balls out of 6 red balls and two green balls from 4 green balls.
→ Total of number of ways for selecting 4 balls out of 10 balls is C(10,4)
→ Number of ways for selecting two red balls from 6 and two green balls from 4 is C(6,2)*C(4,2)
→ Probability of selecting two balls is number of ways for selecting four balls / total number of ways P = C(6,2)*C(4,2) / C(10,4)
= C(6,2) is 6x5/2 = 15
= C(4,2) is 4x3/2 = 6
= C(10,4) is (10x9x8x7) / (4x3x2x1) = 210
P = C(6,2)*C(4,2) / C(10,4)
= 15x6/210
= 3/7, So option 4 is correct
→ Green balls are 4
→ Total 10 balls in the box. We need to select 4 balls from 10 balls in which two red balls out of 6 red balls and two green balls from 4 green balls.
→ Total of number of ways for selecting 4 balls out of 10 balls is C(10,4)
→ Number of ways for selecting two red balls from 6 and two green balls from 4 is C(6,2)*C(4,2)
→ Probability of selecting two balls is number of ways for selecting four balls / total number of ways P = C(6,2)*C(4,2) / C(10,4)
= C(6,2) is 6x5/2 = 15
= C(4,2) is 4x3/2 = 6
= C(10,4) is (10x9x8x7) / (4x3x2x1) = 210
P = C(6,2)*C(4,2) / C(10,4)
= 15x6/210
= 3/7, So option 4 is correct
Question 108 |
Which of the following statements is/are TRUE for an undirected graph?
P: Number of odd degree vertices is even
Q: Sum of degrees of all vertices is even
P: Number of odd degree vertices is even
Q: Sum of degrees of all vertices is even
P only | |
Q only | |
Both P and Q | |
Neither P nor Q |
Question 108 Explanation:
Euler’s Theorem 3:
The sum of the degrees of all the vertices of a graph is an even number (exactly twice the number of edges).
In every graph, the number of vertices of odd degree must be even.
The sum of the degrees of all the vertices of a graph is an even number (exactly twice the number of edges).
In every graph, the number of vertices of odd degree must be even.
Question 109 |
Consider the following graph L and find the bridges, if any.
No bridges | |
{d,e} | |
{c,d} | |
{c,d} and {c,f} |
Question 109 Explanation:
A bridge, ut-edge, or cut arc is an edge of a graph whose deletion increases its number of connected components.
Equivalently, an edge is a bridge if and only if it is not contained in any cycle.
A graph is said to be bridgeless or isthmus-free if it contains no bridges.
If we remove {d,e} edge then there is no way to reach e and the graph is disconnected.
The removal of edges {c,d} and {c,f} makes graph disconnect but this forms a cycle.
Equivalently, an edge is a bridge if and only if it is not contained in any cycle.
A graph is said to be bridgeless or isthmus-free if it contains no bridges.
If we remove {d,e} edge then there is no way to reach e and the graph is disconnected.
The removal of edges {c,d} and {c,f} makes graph disconnect but this forms a cycle.
Question 110 |
The following graph nas no Euler circuit because
It has 7 vertices | |
It is even-valent(all vertices have even valence) | |
It is not connected | |
It does not have a Euler circuit |
Question 110 Explanation:
An Eulerian trail or Euler walk in an undirected graph is a walk that uses each edge exactly once. If such a walk exists, the graph is called traversable or semi-eulerian.
Important Properties:
→ An undirected graph has an Eulerian cycle if and only if every vertex has even degree, and all of its vertices with nonzero degree belong to a single connected component.
→ An undirected graph can be decomposed into edge-disjoint cycles if and only if all of its vertices have even degree. So, a graph has an Eulerian cycle if and only if it can be decomposed into edge-disjoint cycles and its nonzero-degree vertices belong to a single connected component.
→ An undirected graph has an Eulerian trail if and only if exactly zero or two vertices have odd degree, and all of its vertices with nonzero degree belong to a single connected component.
→ A directed graph has an Eulerian cycle if and only if every vertex has equal in degree and out degree, and all of its vertices with nonzero degree belong to a single strongly connected component. Equivalently, a directed graph has an Eulerian cycle if and only if it can be decomposed into edge-disjoint directed cycles and all of its vertices with nonzero degree belong to a single strongly connected component.
→ A directed graph has an Eulerian trail if and only if at most one vertex has (out-degree) − (in-degree) = 1, at most one vertex has (in-degree) − (out-degree) = 1, every other vertex has equal in-degree and out-degree, and all of its vertices with nonzero degree belong to a single connected component of the underlying undirected graph
Important Properties:
→ An undirected graph has an Eulerian cycle if and only if every vertex has even degree, and all of its vertices with nonzero degree belong to a single connected component.
→ An undirected graph can be decomposed into edge-disjoint cycles if and only if all of its vertices have even degree. So, a graph has an Eulerian cycle if and only if it can be decomposed into edge-disjoint cycles and its nonzero-degree vertices belong to a single connected component.
→ An undirected graph has an Eulerian trail if and only if exactly zero or two vertices have odd degree, and all of its vertices with nonzero degree belong to a single connected component.
→ A directed graph has an Eulerian cycle if and only if every vertex has equal in degree and out degree, and all of its vertices with nonzero degree belong to a single strongly connected component. Equivalently, a directed graph has an Eulerian cycle if and only if it can be decomposed into edge-disjoint directed cycles and all of its vertices with nonzero degree belong to a single strongly connected component.
→ A directed graph has an Eulerian trail if and only if at most one vertex has (out-degree) − (in-degree) = 1, at most one vertex has (in-degree) − (out-degree) = 1, every other vertex has equal in-degree and out-degree, and all of its vertices with nonzero degree belong to a single connected component of the underlying undirected graph
Question 111 |
For the graph shown, which of the following paths is a Hamilton circuit?
ABCDCFDEFAEA | |
AEDCBAF | |
AEFDCBA | |
AFCDEBA |
Question 111 Explanation:
A Hamiltonian cycle, also called a Hamiltonian circuit, Hamilton cycle, or Hamilton circuit, is a graph cycle (i.e., closed loop) through a graph that visits each node exactly once. A graph possessing a Hamiltonian cycle is said to be a Hamiltonian graph.
Here, Option A: A,F and E are repeated several times.
Option B: It is not a cycle. It means, not closed walk
Option C: It is closed walk and all vertex traversed. So this is final answer.
Option D: It’s not a closed walk.
Here, Option A: A,F and E are repeated several times.
Option B: It is not a cycle. It means, not closed walk
Option C: It is closed walk and all vertex traversed. So this is final answer.
Option D: It’s not a closed walk.
Question 112 |
If G is an undirected planar graph on n vertices with e edges then
e<=n | |
e<=2n | |
e<=en | |
None of the option |
Question 112 Explanation:
Euler's formula: states that if a finite, connected, planar graph is drawn in the plane without any edge intersections, and v is the number of vertices, e is the number of edges and f is the number of faces (regions bounded by edges, including the outer, infinitely large region), then
v − e + f = 2.
→ For a simple, connected, planar graph with v vertices and e edges and faces, the following simple conditions hold for v ≥ 3:
Theorem 1. e ≤ 3v − 6;
Theorem 2. If there are no cycles of length 3, then e ≤ 2v − 4.
Theorem 3. f ≤ 2v − 4.
Theorem (The handshaking theorem):
Let G be an undirected graph (or multigraph) with V vertices and N edges. Then
Exercise:
Suppose a simple graph has 15 edges, 3 vertices of degree 4, and all others of degree 3. How many vertices does the graph have?
3*4+(x-3)*3=30
v − e + f = 2.
→ For a simple, connected, planar graph with v vertices and e edges and faces, the following simple conditions hold for v ≥ 3:
Theorem 1. e ≤ 3v − 6;
Theorem 2. If there are no cycles of length 3, then e ≤ 2v − 4.
Theorem 3. f ≤ 2v − 4.
Theorem (The handshaking theorem):
Let G be an undirected graph (or multigraph) with V vertices and N edges. Then
Exercise:
Suppose a simple graph has 15 edges, 3 vertices of degree 4, and all others of degree 3. How many vertices does the graph have?
3*4+(x-3)*3=30
Question 113 |
Choose the most appropriate definition of plane graph.
A simple graph which is isomorphic to hamiltonian graph | |
A graph drawn in a plane in such a way that if the vertex set of graph can be partitioned into two non-empty disjoint subset X and Y in such a way that each edge of G has one end in X and one end in Y | |
A graph drawn in a plane in such a way that any pair of edges meet only at their end vertices | |
None of the option |
Question 113 Explanation:
In graph theory, a planar graph is a graph that can be embedded in the plane, i.e., it can be drawn on the plane in such a way that its edges intersect only at their endpoints.
In other words, it can be drawn in such a way that no edges cross each other. Such a drawing is called a plane graph or planar embedding of the graph.
In other words, it can be drawn in such a way that no edges cross each other. Such a drawing is called a plane graph or planar embedding of the graph.
Question 114 |
Which of the following propositions is tautology.
(p Vq) → q | |
p V(q → p) | |
pV(p → q) | |
Both B) and C) |
Question 114 Explanation:
Question 115 |
Using Mid Point algorithm, the new coordinates of the point P(x,y) having slope ‘m’ and constant and ‘b’ is calculated using:
F(x,y)=mx+b-y | |
F(x,y)=mx-y+b | |
F(x,y)=mx+b | |
F(x,y)=mx-y+b-y |
Question 115 Explanation:
In order to check this, we need to consider the implicit equation:
F(x,y) = mx + b - y
For positive m at any given X,
If y is on the line, then F(x, y) = 0
If y is above the line, then F(x, y) < 0
If y is below the line, then F(x, y) > 0
F(x,y) = mx + b - y
For positive m at any given X,
If y is on the line, then F(x, y) = 0
If y is above the line, then F(x, y) < 0
If y is below the line, then F(x, y) > 0
Question 116 |
The correct order of the degrees of vertices that would form the connected graph as eulerian is:
1,2,3 | |
2,3,4 | |
2,4,5 | |
1,3,5 |
Question 116 Explanation:
→ Suppose a graph has n vertices with degrees d1,d2,d3,...,dn. Add together all degrees to get a new number d1 + d2 + d3 + ...+ dn = Dv. Then Dv =2e.
→ In words, for any graph the sum of the degrees of the vertices equals twice the number of edges. Stated in a slightly different way, Dv =2e says that Dv is ALWAYS an even number
→ 1+2+3=6
→ In words, for any graph the sum of the degrees of the vertices equals twice the number of edges. Stated in a slightly different way, Dv =2e says that Dv is ALWAYS an even number
→ 1+2+3=6
Question 117 |
A planar graph is defined as:
A graph drawn in a plane in such a way that any pair of edges meet only at their end vertices | |
A graph drawn in a plane in such a way that if the vertex set of graph can be partitioned into two non-empty disjoint subset X and Y in such a way that each edge of G has one end in X and one end in Y. | |
A simple graph which is Isomorphism to Hamiltonian graph. | |
A function between the vertex sets of two graphs that maps adjacent vertices to adjacent vertices |
Question 117 Explanation:
→ In graph theory, a planar graph is a graph that can be embedded in the plane, i.e., it can be drawn on the plane in such a way that its edges intersect only at their endpoints.
→ In other words, it can be drawn in such a way that no edges cross each other. Such a drawing is called a plane graph or planar embedding of the graph.
→ A plane graph can be defined as a planar graph with a mapping from every node to a point on a plane, and from every edge to a plane curve on that plane, such that the extreme points of each curve are the points mapped from its end nodes, and all curves are disjoint except on their extreme points.
→ In other words, it can be drawn in such a way that no edges cross each other. Such a drawing is called a plane graph or planar embedding of the graph.
→ A plane graph can be defined as a planar graph with a mapping from every node to a point on a plane, and from every edge to a plane curve on that plane, such that the extreme points of each curve are the points mapped from its end nodes, and all curves are disjoint except on their extreme points.
Question 118 |
Consider an undirected random graph of 16 vertices. The probability that there is an edge between a pair of vertices is ½. What is the expected number of unordered cycles of length three?
70 | |
280 | |
120 | |
45 |
Question 118 Explanation:
Among available ‘16’ vertices, we need to identify the cycles of length ‘3’.
So, the total probability that all three edges of the above exists
= 1/2 × 1/2 × 1/2 (as they are independent events)
= 1/8
Total number of ways in which we can select ‘3’ such vertices among ‘16’ vertices = 16C3 = 560
Total number of cycles of length ‘3’ out of 16 vertices = 560 × 1/8 = 70
So, the total probability that all three edges of the above exists
= 1/2 × 1/2 × 1/2 (as they are independent events)
= 1/8
Total number of ways in which we can select ‘3’ such vertices among ‘16’ vertices = 16C3 = 560
Total number of cycles of length ‘3’ out of 16 vertices = 560 × 1/8 = 70
Question 119 |
A polynomial p(x) is such that p(0)=5, p(1)=4, p(2)=9 and p(3)=20 The minimum degree it can have is
1 | |
2 | |
3 | |
4 |
Question 119 Explanation:
Let's take p(x) = ax + b
p(0) = 5 ⇒ b = 5
p(1) = 4 ⇒ a+b = 4 ⇒ a = -1
p(2) = 9 ⇒ 40+b = 9 ⇒ -4+5 = 9, which is false.
So degree 1 is not possible.
Let's take p(x) = ax 2 + bx +c
p(0) = 5 ⇒ c = 5
p(1) = 4 ⇒ a+b+c = 4 ⇒ a+b = -1 -----(1)
p(2) = 9 ⇒ 4a+2b+c = 9 ⇒ 2a+b = 2 -----(2)
(2) - (1)
⇒ a = 3, b = -1-1 = -4
p(3) = 20 ⇒ 9a+3b+c = 20
⇒ 27-12+5 = 20
⇒ 20 = 20, True
Hence, minimum degree it can have.
p(0) = 5 ⇒ b = 5
p(1) = 4 ⇒ a+b = 4 ⇒ a = -1
p(2) = 9 ⇒ 40+b = 9 ⇒ -4+5 = 9, which is false.
So degree 1 is not possible.
Let's take p(x) = ax 2 + bx +c
p(0) = 5 ⇒ c = 5
p(1) = 4 ⇒ a+b+c = 4 ⇒ a+b = -1 -----(1)
p(2) = 9 ⇒ 4a+2b+c = 9 ⇒ 2a+b = 2 -----(2)
(2) - (1)
⇒ a = 3, b = -1-1 = -4
p(3) = 20 ⇒ 9a+3b+c = 20
⇒ 27-12+5 = 20
⇒ 20 = 20, True
Hence, minimum degree it can have.
Question 120 |
If S be an infinite set and S 1 ..., S n be sets such that S 1 U S 2 U...U S n =S, then
At least one of the set S i is a finite set | |
not more than one of the sets S i can be finite | |
At least one of the sets S i is an infinite set | |
not more than one of the sets S i can be infinite |
Question 120 Explanation:
Given sets are finite union of sets. One set must be infinite to make whole thing to be infinite.
Question 121 |
The number of independent loops for a network with n nodes and b branch is
n-1 | |
b-n | |
b-n+1 | |
independent of "the number of nodes |
Question 121 Explanation:
● A loop is a closed path in a circuit. Loop counts starting at a node passing through a set of nodes and returning to the starting node without passing through any node more than once.
● A loop is said to be independent if it contains at least one branch which is not a part of any other independent loop.
● A network with ‘b’ branches, ‘n’ nodes and ‘L’ independent loops will satisfy the fundamental theorem of network topology.
b=L+n−1
L=b−n+1
● A loop is said to be independent if it contains at least one branch which is not a part of any other independent loop.
● A network with ‘b’ branches, ‘n’ nodes and ‘L’ independent loops will satisfy the fundamental theorem of network topology.
b=L+n−1
L=b−n+1
Question 122 |
Which of the following is/are tautology?
a V b → b ⋀ c | |
a ⋀ b → b V c | |
a V b → (b → c) | |
a → b → (b → c) |
Question 122 Explanation:
Question 123 |
The number of circuits in a tree with 'n' nodes is
Zero | |
One | |
n-1 | |
n/2 |
Question 123 Explanation:
● A tree (e.g. a binary tree) has a root, branches (nodes), and leaf nodes.
● A circuit in such a tree is impossible (unless you have some other data structure as well such as a linked list or you just program the tree so badly it ends up with circuits).
● A circuit in such a tree is impossible (unless you have some other data structure as well such as a linked list or you just program the tree so badly it ends up with circuits).
Question 124 |
A complete graph with "n" vertices is
2-chromatic | |
(n/2) chromatic | |
(n-1) chromatic | |
n-Chromatic |
Question 124 Explanation:
Question 125 |
Minimum number of colours required to colour the vertices of a cycle with n nodes in such a way that no two adjacent nodes have the same colour is
2 | |
3 | |
4 | |
n-2⌈(n/2)⌉+2 |
Question 125 Explanation:
We need 3 colors to color a odd cycle and 2 colors to color an even cycle.
Question 126 |
(PVQ) ⋀ (P → R) ⋀ (Q → R) is equivalent to
P | |
Q | |
R | |
True≅T |
Question 126 Explanation:
Question 127 |
Consider the vocabulary with only four propositions A,B,C and D. How many models are there for the following sentence?
( ⌐ A ∨ ⌐ B ∨ ⌐ C ∨ ⌐ D)
( ⌐ A ∨ ⌐ B ∨ ⌐ C ∨ ⌐ D)
8 | |
7 | |
15 | |
16 |
Question 127 Explanation:
Here, number of models is nothing but number of TRUEs in final statement. In this proposition logic we got total 15 number of models.
Question 128 |
Match the List 1 and List 2 and choose the correct answer from the code given below
(a)-(i), (b)-(ii), (c)-(iii), (d)-(iv) | |
(a)-(ii), (b)-(i),(c)-(iii), (d)-(iv) | |
(a)-(iv), (b)-(iii), (c)-(ii), (d)-(i) | |
(a)-(iii), (b)-(iv), (c)-(ii), (d)-(i) |
Question 128 Explanation:
Propositions r and s are logically equivalent if the statement r ↔ s is a tautology. ∼q⇒ ∼p
According to above table,
equivalence means p ⇔ q
Contrapositive means p⇒ q : ∼q⇒ ∼p
Converse means p⇒ q : q⇒ p
Implication means p ⇔ q
According to above table,
equivalence means p ⇔ q
Contrapositive means p⇒ q : ∼q⇒ ∼p
Converse means p⇒ q : q⇒ p
Implication means p ⇔ q
Question 129 |
Consider the following statements related to AND-OR Search algorithm.
S 1 : A solution is a subtree that has a goal node at every leaf.
S 2 : OR nodes are analogous to the branching in a deterministic environment
S 3 : AND nodes are analogous to the branching in a non-deterministic environment.
Which one of the following is true referencing the above statements?
Choose the correct answer from the code given below:
S 1 : A solution is a subtree that has a goal node at every leaf.
S 2 : OR nodes are analogous to the branching in a deterministic environment
S 3 : AND nodes are analogous to the branching in a non-deterministic environment.
Which one of the following is true referencing the above statements?
Choose the correct answer from the code given below:
S1- False, S2- True, S3- True | |
S1- True, S2- True, S3- True | |
S1- False, S2- True, S3- False | |
S1- True, S2- True, S3- False |
Question 129 Explanation:
● An and–or tree is a graphical representation of the reduction of problems (or goals) to conjunctions and disjunctions of subproblems (or subgoals).
● A solution in an AND-OR tree is a sub tree whose leaves are included in the goal set
● A solution in an AND-OR tree is a sub tree whose leaves are included in the goal set
Question 130 |
The K-coloring of an undirected graph G=(V,E) is a function C: V➝{0,1,......,K-1} such that c(u)≠c(v) for every edge (u,v) ∈ E
Which of the following is not correct?
G has no cycles of odd length | |
G has cycle of odd length | |
G is 2-colorable | |
G is bipartite |
Question 130 Explanation:
● A k-colouring of a graph G consists of k different colours and G is then called k-colourable.
● A cycle of length n ≥ 3 is 2-chromatic if n is even and 3-chromatic if n is odd.
● A graph is bi-colourable (2-chromatic) if and only if it has no odd cycles.
● A nonempty graph G is bicolourable if and only if G is bipartite
● A cycle of length n ≥ 3 is 2-chromatic if n is even and 3-chromatic if n is odd.
● A graph is bi-colourable (2-chromatic) if and only if it has no odd cycles.
● A nonempty graph G is bicolourable if and only if G is bipartite
Question 131 |
If a graph (G) has no loops or parallel edges and if the number of vertices(n) in the graph is n≥3, then the graph G is Hamiltonian if
(i) deg(v) ≥n/3 for each vertex v
(ii) deg(v) + deg(w) ≥ n whenever v and w are not connected by an edge.
(iii) E (G) ≥ 1/3 (n − 1 )(n − 2 ) + 2
(i) deg(v) ≥n/3 for each vertex v
(ii) deg(v) + deg(w) ≥ n whenever v and w are not connected by an edge.
(iii) E (G) ≥ 1/3 (n − 1 )(n − 2 ) + 2
(i) and (iii) only | |
(ii) and (iii) only | |
(iii) only | |
(ii) only |
Question 131 Explanation:
→ Dirac's theorem on Hamiltonian cycles, the statement that an n-vertex graph in which each vertex has degree at least n/2 must have a Hamiltonian cycle
→ Dirac's theorem on chordal graphs, the characterization of chordal graphs as graphs in which all minimal separators are cliques
→ Dirac's theorem on cycles in k-connected graphs, the result that for every set of k vertices in a k-vertex-connected graph there exists a cycle that passes through all the vertices in the set
→ Dirac's theorem on chordal graphs, the characterization of chordal graphs as graphs in which all minimal separators are cliques
→ Dirac's theorem on cycles in k-connected graphs, the result that for every set of k vertices in a k-vertex-connected graph there exists a cycle that passes through all the vertices in the set
Question 132 |
A survey has been conducted on methods of commuter travel. Each respondent was asked to check Bus, Train or Automobile as a major methods of travelling to work. More than one answer was permitted. The results reported were as follows : Bus 30 people; Train 35 people; Automobile 100 people; Bus and Train 15 people; Bus and Automobile 15 people; Train and Automobile 20 people; and all the three methods 5 people. How many people complete the survey form ?
160 | |
120 | |
165 | |
115 |
Question 132 Explanation:
Let “A” denotes people travelled by Bus.
Let “B” denotes people travelled by Train.
Let “C” denotes people travelled by Automobile.
Let “(A⋂B)” denotes people travelled by Bus and Train.
Let “(A⋂C)” denotes people travelled by Bus and Automobile.
Let “(B⋂C)” denotes people travelled by Train and Automobile.
Let “(A⋂B⋂C)” denotes people travelled by Bus, Train and Automobile.
Number of people completed the survey = A+B+C-(A⋂B)-(A⋂C)-(B⋂C)+(A⋂B⋂C)
= 30+35+100-15-15-20+5
= 120
Let “B” denotes people travelled by Train.
Let “C” denotes people travelled by Automobile.
Let “(A⋂B)” denotes people travelled by Bus and Train.
Let “(A⋂C)” denotes people travelled by Bus and Automobile.
Let “(B⋂C)” denotes people travelled by Train and Automobile.
Let “(A⋂B⋂C)” denotes people travelled by Bus, Train and Automobile.
Number of people completed the survey = A+B+C-(A⋂B)-(A⋂C)-(B⋂C)+(A⋂B⋂C)
= 30+35+100-15-15-20+5
= 120
Question 133 |
A full joint distribution for the Toothache, Cavity and Catch is given in the table below:
Which is the probability of Cavity, given evidence of Toothache ?
Which is the probability of Cavity, given evidence of Toothache ?
< 0.2, 0.8 > | |
< 0.6, 0.8 > | |
< 0.4, 0.8 > | |
< 0.6, 0.4 > |
Question 133 Explanation:
Probability cavity given that toothache
P(Cavity/Toothache)=P(Cavity ⋀ Toothache) / P(toothache)
=(0.108 + 0.012) / (0.108 + 0.012 + 0.016 + 0.064)
=(0.12)/(0.2)
=0.6
P(~Cavity / Toothache) = (0.016 + 0.064) / 0.2
= 0.4
P(Cavity/Toothache)=P(Cavity ⋀ Toothache) / P(toothache)
=(0.108 + 0.012) / (0.108 + 0.012 + 0.016 + 0.064)
=(0.12)/(0.2)
=0.6
P(~Cavity / Toothache) = (0.016 + 0.064) / 0.2
= 0.4
Question 134 |
In mathematical logic, which of the following are statements ?
(i) There will be snow in January
(ii) What is the time now ?
(iii) Today is Sunday
(iv) You must study Discrete Mathematics.
(i) There will be snow in January
(ii) What is the time now ?
(iii) Today is Sunday
(iv) You must study Discrete Mathematics.
(iii) and (iv) | |
(i) and (ii) | |
(i) and (iii) | |
(ii) and (iv) |
Question 134 Explanation:
In mathematical logic, the term statement is variously understood to mean either:
(a) a meaningful declarative sentence that is true or false, or
(b) the assertion that is made by a true or false declarative sentence.
From the above four statements , statement 2 and 4 wont give meaning like true or false answers and statements 1 and 3 will give either true or false answers
(a) a meaningful declarative sentence that is true or false, or
(b) the assertion that is made by a true or false declarative sentence.
From the above four statements , statement 2 and 4 wont give meaning like true or false answers and statements 1 and 3 will give either true or false answers
Question 135 |
Consider the statements below :
“ There is a country that borders both India and Nepal. “
Which of the following represents the above sentence correctly ?
“ There is a country that borders both India and Nepal. “
Which of the following represents the above sentence correctly ?
∃c Border(Country(c), India ∧ Nepal) | |
∃c Country(c) ∧ Border(c, India) ∧ Border(c, Nepal) | |
[∃c Country(c)] ⇒ [Border(c,India) ∧ Border(c, Nepal)] | |
∃c Country(c) ⇒ [ Border(c, India) ∧ Border(c, Nepal)] |
Question 135 Explanation:
→ ∃c Country(c) which represents there is one country “c”
→ Border(c, India) which represents border between c and india
→ Border(c, Nepal) which represents border between c and Nepal
→ “∧” represents both
Option-2 represents the sentence “ There is a country that borders both India and Nepal.
→ Border(c, India) which represents border between c and india
→ Border(c, Nepal) which represents border between c and Nepal
→ “∧” represents both
Option-2 represents the sentence “ There is a country that borders both India and Nepal.
Question 136 |
Use Dual Simplex Method to solve the following problem :
Maximize z= -2x 1 -3x 2
subject to:
x 1 + x 2 ≥ 2
2x 1 + x 2 ≤ 10
x 1 + x 2 ≤ 8
x 1 , x 2 ≥ 0
Maximize z= -2x 1 -3x 2
subject to:
x 1 + x 2 ≥ 2
2x 1 + x 2 ≤ 10
x 1 + x 2 ≤ 8
x 1 , x 2 ≥ 0
x 1 =6, x 2 =2 and z = -18 | |
x 1 =2, x 2 =6 and z = -22 | |
x 1 =2, x 2 =0 and z= -4 | |
x 1 =0, x 2 =2 and z= -6 |
Question 136 Explanation:
→ One simple method is substitute the option values in the maximize equation Z to know the maximum value of the problem and remaining equations to satisfies the conditions which are
given in the problem statement.
→ Option 3 satisfies all conditions and maximize property in the given problem
→ Option 3 satisfies all conditions and maximize property in the given problem
Question 137 |
A box contains six red balls and four green balls. Four balls are selected at random from the box. What is the probability that two of the selected balls will be red and two will be green ?
1/35 | |
1/14 | |
1/9 | |
3/7 |
Question 137 Explanation:
→ Total red balls are 6
→ Green balls are 4
→ Total 10 balls in the box. We need to select 4 balls from 10 balls in which two red balls out of 6 red balls and two green balls from 4 green balls.
→ Total of number of ways for selecting 4 balls out of 10 balls is C(10,4)
→ Number of ways for selecting two red balls from 6 and two green balls from 4 is C(6,2)*C(4,2)
→ Probability of selecting two balls is number of ways for selecting four balls / total number of ways P= C(6,2)*C(4,2) / C(10,4) = C(6,2) is 6x5/2=15
= C(4,2) is 4x3/2=6
= C(10,4) is (10x9x8x7) / (4x3x2x1)=210
P=C(6,2)*C(4,2) / C(10,4)
=15x6/210=
= 3/7, So option 4 is correct
→ Green balls are 4
→ Total 10 balls in the box. We need to select 4 balls from 10 balls in which two red balls out of 6 red balls and two green balls from 4 green balls.
→ Total of number of ways for selecting 4 balls out of 10 balls is C(10,4)
→ Number of ways for selecting two red balls from 6 and two green balls from 4 is C(6,2)*C(4,2)
→ Probability of selecting two balls is number of ways for selecting four balls / total number of ways P= C(6,2)*C(4,2) / C(10,4) = C(6,2) is 6x5/2=15
= C(4,2) is 4x3/2=6
= C(10,4) is (10x9x8x7) / (4x3x2x1)=210
P=C(6,2)*C(4,2) / C(10,4)
=15x6/210=
= 3/7, So option 4 is correct
Question 138 |
Let G be a simple undirected planar graph on 10 vertices with 15 edges. If G is a connected graph, then the number of bounded faces in any embedding of G on the plane is equal to:
3 | |
4 | |
5 | |
6 |
Question 138 Explanation:
v - e + f = 2
‘v’ is number of vertices and ‘e’ is number of edges
‘f’ is number of faces including bounded and unbounded
10 - 15 + f = 2
f = 7
There is always one unbounded face, so the number of bounded faces = 6
‘v’ is number of vertices and ‘e’ is number of edges
‘f’ is number of faces including bounded and unbounded
10 - 15 + f = 2
f = 7
There is always one unbounded face, so the number of bounded faces = 6
Question 139 |
Let A,B,C,D be nxn matrices, each with non-zero determinant. If ABCD=1, then B(-1) is:
D(-1)C(-1)A(-1) | |
CDA | |
ADC | |
Does not necessarily exist |
Question 139 Explanation:
Given
ABCD = I
Multiply LHS, RHS by A −1
A −1 ABCD = A −1 I (position of A −1 on both sides should be left)
⇒ B CD = A −1
⇒ BCDD −1 = A −1 D −1
⇒ B C = A −1 D −1 ⇒BCC −1 = A −1D −1C −1
⇒ B = A −1 D −1 C −1
⇒ B = A −1 D −1 C −1
Now, B −1 = (A −1 D −1 C −1 )−1
B −1 = C DA
ABCD = I
Multiply LHS, RHS by A −1
A −1 ABCD = A −1 I (position of A −1 on both sides should be left)
⇒ B CD = A −1
⇒ BCDD −1 = A −1 D −1
⇒ B C = A −1 D −1 ⇒BCC −1 = A −1D −1C −1
⇒ B = A −1 D −1 C −1
⇒ B = A −1 D −1 C −1
Now, B −1 = (A −1 D −1 C −1 )−1
B −1 = C DA
Question 140 |
Consider the function f(x)=sin(x) in the interval [ π /4, 7 π /4]. The number and location(s) of the minima of this function are:
One, at π/2 | |
One, at 3 π /2 | |
Two, at π /2 and 3 π /2 | |
Two, at π /4 and 3 π /2 |
Question 140 Explanation:
The local minima is at x =3π/2
This is very obvious from the graph of f (x) = sin x
On a second look at the graph below, I believe x =π/4
is also a local minimum. This is because it is lesser than all other values within its locality.
Thus we have two local minima: x = π /4 , 3π
This is very obvious from the graph of f (x) = sin x
On a second look at the graph below, I believe x =π/4
is also a local minimum. This is because it is lesser than all other values within its locality.
Thus we have two local minima: x = π /4 , 3π
Question 141 |
Which one of the following is NOT necessarily a property of a group?
Commutativity | |
Associativity | |
Existence of inverse for every element | |
Existence of identity |
Question 141 Explanation:
The axioms (basic rules) for a group are:
1. CLOSURE: If a and b are in the group then a • b is also in the group.
2. ASSOCIATIVITY: If a, b and c are in the group then (a • b) • c = a • (b • c).
3. IDENTITY: There is an element e of the group such that for any element a of the group
a • e = e • a = a.
4. INVERSES: For any element a of the group there is an element a -1 such that ○ a • a -1 = e
and
○ a -1 • a = e
1. CLOSURE: If a and b are in the group then a • b is also in the group.
2. ASSOCIATIVITY: If a, b and c are in the group then (a • b) • c = a • (b • c).
3. IDENTITY: There is an element e of the group such that for any element a of the group
a • e = e • a = a.
4. INVERSES: For any element a of the group there is an element a -1 such that ○ a • a -1 = e
and
○ a -1 • a = e
Question 142 |
How many onto(or surjective) functions are there from an n-element(n>=2) set to a 2-element set?
2 n | |
2 n -1 | |
2 n -2 | |
2(2 n -2) |
Question 142 Explanation:
The number of onto functions from set of m elements to set of n elements, if m>n is
n m – (2 n – 2)
i.e., 2 n – (2 2 – 2) = 2 n – 2
If there are 'm' elements in set A, 'n' elements in set B then
The number of functions are : n m The number of injective or one-one functions are n P m
The number of surjective functions are:
If m If m>n, then n! * m C n
Given that m=n, n=2
2! * n C 2
n m – (2 n – 2)
i.e., 2 n – (2 2 – 2) = 2 n – 2
If there are 'm' elements in set A, 'n' elements in set B then
The number of functions are : n m The number of injective or one-one functions are n P m
The number of surjective functions are:
If m If m>n, then n! * m C n
Given that m=n, n=2
2! * n C 2
Question 143 |
Given an undirected graph G with V vertices and E edges, the sum of the degrees of all vertices is
E | |
2E | |
V | |
2V |
Question 143 Explanation:
Theorem (Sum of Degrees of Vertices Theorem):
Suppose a graph has n vertices with degrees d 1 , d 2 , d 3 , ..., d n.
Add together all degrees to get a new number
d 1 + d 2 + d 3 + . .. + d n = D v . Then D v = 2 e .
In words, for any graph the sum of the degrees of the vertices equals twice the number of edges.
Suppose a graph has n vertices with degrees d 1 , d 2 , d 3 , ..., d n.
Add together all degrees to get a new number
d 1 + d 2 + d 3 + . .. + d n = D v . Then D v = 2 e .
In words, for any graph the sum of the degrees of the vertices equals twice the number of edges.
Question 144 |
A path in graph G, which contains every vertex of G and only Once?
Euler circuit | |
Hamiltonian path | |
Euler Path | |
Hamiltonian Circuit |
Question 144 Explanation:
● Hamiltonian path, also called a Hamilton path, is a graph path between two vertices of a graph that visits each vertex exactly once. If a Hamiltonian path exists whose endpoints are adjacent, then the resulting graph cycle is called a Hamiltonian cycle (or Hamiltonian cycle)
● An Euler path is a path that uses every edge of a graph exactly once. An Euler circuit is a circuit that uses every edge of a graph exactly once.
● An Euler path starts and ends at different vertices.
● An Euler circuit starts and ends at the same vertex.
● An Euler path is a path that uses every edge of a graph exactly once. An Euler circuit is a circuit that uses every edge of a graph exactly once.
● An Euler path starts and ends at different vertices.
● An Euler circuit starts and ends at the same vertex.
Question 145 |
Considering the following graph, which one of the following set of edged represents all the bridges of the given graph?
(a,b)(e,f) | |
(a,b),(a,c) | |
(c,d)(d,h) | |
(a,b) |
Question 145 Explanation:
● A bridge ,cut-edge, or cut arc is an edge of a graph whose deletion increases its number of connected components.
● Equivalently, an edge is a bridge if and only if it is not contained in any cycle.
● The removal of edges (a,b) and (e,f) makes graph disconnected.
● Equivalently, an edge is a bridge if and only if it is not contained in any cycle.
● The removal of edges (a,b) and (e,f) makes graph disconnected.
Question 146 |
Which of the following statements is/are TRUE?
S1: The existence of an Euler circuit implies that an euler path exists.
S2: The existence of an Euler path implies that an Euler circuit exists.
S1: The existence of an Euler circuit implies that an euler path exists.
S2: The existence of an Euler path implies that an Euler circuit exists.
S1 is true | |
S2 is true | |
S1 and S2 both are true | |
S1 and S2 both are false |
Question 146 Explanation:
An Euler circuit in a graph G is a simple circuit containing every edge of G exactly once
An Euler path in G is a simple path containing every edge of G exactly once.
An Euler path starts and ends at different vertices.
An Euler circuit starts and ends at the same vertex.
An Euler path in G is a simple path containing every edge of G exactly once.
An Euler path starts and ends at different vertices.
An Euler circuit starts and ends at the same vertex.
Question 147 |
A connected planar graph divides the plane into a number of regions. If the graph has eight vertices and these are linked by 13 edges, then the number of regions is:
5 | |
6 | |
7 | |
8 |
Question 147 Explanation:
Use Euler's formula ,V−E+R=2
Where V is the number of vertices, E is the number of edges, and R is the number of regions.
R=2-V+E=2-8+13=7
Where V is the number of vertices, E is the number of edges, and R is the number of regions.
R=2-V+E=2-8+13=7
Question 148 |
Power set of empty set has exactly__subset
One | |
Two | |
Zero | |
Three |
Question 148 Explanation:
● The collection of all subsets of a set A is called the power set of A.
● The empty set is the unique set having no elements; its size or cardinality (count of elements in a set) is zero
● Common notations for the empty set include "{}", " ", and "∅".
● The empty set is the unique set having no elements; its size or cardinality (count of elements in a set) is zero
● Common notations for the empty set include "{}", " ", and "∅".
Question 149 |
What is the cartesian product of A={1,2} and B={a,b}?
{(1,a),(1,b),(2,a),(b,b)} | |
{(1,1),(2,2),(a,a),(b,b)} | |
{(1,a),(2,a),(1,b),(2,b)} | |
{(1,1),(a,a),(2,a),(1,b)} |
Question 149 Explanation:
● A Cartesian product is a mathematical operation that returns a set (or product set or simply product) from multiple sets. That is, for sets A and B, the Cartesian product A × B is the set of all ordered pairs (a, b) where a ∈ A and b ∈ B.
● In the question, Set A consists of two elements and Set B consists of two elements. So the total ordered pairs are four.
● Each ordered pair consists of one element from Set-A and another element from Set-B.
● In the question, Set A consists of two elements and Set B consists of two elements. So the total ordered pairs are four.
● Each ordered pair consists of one element from Set-A and another element from Set-B.
Question 150 |
What is the cardinality of the power set of the set {0,1,2}?
8 | |
6 | |
7 | |
9 |
Question 150 Explanation:
The cardinality of a set is defined as the total number of distinct items in that set and power set is defined as the set of all subsets of a set.
Power set consists of {}, {0}, {1}, {2}, {0,1}, {0,2}, {1,2}, {0,1,2}
So power set consists of all unique items then cardinality is 8
Power set consists of {}, {0}, {1}, {2}, {0,1}, {0,2}, {1,2}, {0,1,2}
So power set consists of all unique items then cardinality is 8
Question 151 |
Let G be a simple connected planar graph with 13 vertices and 19 edges. then the number of faces in the planar embedding of the graph is
6 | |
8 | |
9 | |
13 |
Question 151 Explanation:
● Use Euler's formula ,V−E+R=2
● Where V is the number of vertices, E is the number of edges, and R is the number of regions.
● R=2-V+E=2-13+19=8
● We can also term region as face
● Where V is the number of vertices, E is the number of edges, and R is the number of regions.
● R=2-V+E=2-13+19=8
● We can also term region as face
Question 152 |
Which of the following statements is false?
(P⋀Q)V(~P⋀Q)V(P⋀~Q) is equal to ~Q⋀~P | |
(P⋀Q)V(~P⋀Q)V(P⋀~Q) is equal to QVP | |
(P⋀Q)V(~P⋀Q)V(P⋀~Q) is equal to QV(P⋀~q) | |
(P⋀Q)V(~P⋀Q)V(P⋀~Q) is equal to PV(Q⋀~p) |
Question 152 Explanation:
One simple method is, by using truth table we can find the statement is true or not.
The last two columns of the above table are different. So option A is false.
The last two columns of the above table are different. So option A is false.
Question 153 |
There are four bus lines between A and B; And three bus lines between B and C The number of way a person roundtrip by bus from A to C by way of B will be
12 | |
7 | |
144 | |
264 |
Question 153 Explanation:
The number of bus lines between a and b =4
The number of bus lines between b and c =3
The number of possible combinations between a and c going through b are 4 * 3 = 12.
if you're talking about round trip, he has 12 possible ways to get there and 12 possible ways to get back, so the total possible ways is 12 * 12 = 144.
The number of bus lines between b and c =3
The number of possible combinations between a and c going through b are 4 * 3 = 12.
if you're talking about round trip, he has 12 possible ways to get there and 12 possible ways to get back, so the total possible ways is 12 * 12 = 144.
Question 154 |
The number of diagonals that can be drawn by joining the vertices of an octagon is
28 | |
48 | |
20 | |
None of the option |
Question 154 Explanation:
Octagon consists of the 8 vertices and we can draw 5 diagonals
So, we can construct 5*8 = 40 diagonals.
But we have constructed each diagonal twice, once from each of its ends. Thus there are 20 diagonals in a regular octagon.
So, we can construct 5*8 = 40 diagonals.
But we have constructed each diagonal twice, once from each of its ends. Thus there are 20 diagonals in a regular octagon.
Question 155 |
A partial ordered relation is transitive, reflexive and
Antisymmetric | |
bisymmetric | |
anti reflexive | |
Asymmetric |
Question 155 Explanation:
● Let R be a binary relation on a set A.
● R is antisymmetric if for all x,y A, if xRy and yRx, then x=y.
● R is a partial order relation if R is reflexive, antisymmetric and transitive.
● R is antisymmetric if for all x,y A, if xRy and yRx, then x=y.
● R is a partial order relation if R is reflexive, antisymmetric and transitive.
Question 156 |
If B is a Boolean algebra, then which of the following is true?
B is a finite but not complemented lattice | |
B is a finite, Complemented and distributive lattice | |
B is a finite,distributive but not complemented lattice | |
B is not distributive lattice |
Question 156 Explanation:
Distributive property of boolean algebra
(i)a.(b + c) =a.b + a.c
(ii) a+(b.c) = (a + b).(a + c)
Boolean algebra properites:
(i)a.(b + c) =a.b + a.c
(ii) a+(b.c) = (a + b).(a + c)
Boolean algebra properites:
Question 157 |
If A and B are two sets and A U B = A ∩ B then
A= ∅ | |
B= ∅ | |
A != B | |
A=B |
Question 157 Explanation:
● For example, Set A={1,2,3} and Set B={1,2,3}
● AUB={1,2,3}
● A ∩ B ={1,2,3}
● If two sets consists of same elements then A U B = A ∩ B
● AUB={1,2,3}
● A ∩ B ={1,2,3}
● If two sets consists of same elements then A U B = A ∩ B
Question 158 |
The relation {(1,2),(1,3)(3,1),(1,1),(3,3),(3,2),(1,4),(4,2),(3,4)} is
Reflexive | |
Transitive | |
Symmetric | |
Asymmetric |
Question 158 Explanation:
Given set consists of elements a,b, and c.
The following conditions need to satisfy for each property.
a = a (reflexive property),
if a = b then b = a (symmetric property), and
if a = b and b = c then a = c (transitive property).
an asymmetric relation is a binary relation on a set X where:For all a and b in X, if a is related to b, then b is not related to a
The above relation is not reflexive because there is no ordered pairs (2,2) and (4,4)
The above relation is not Symmetric because if (1,2) present means the relation should consists of (2,1) but there is no such ordered pair in the relation.
Asymmetric property also invalid because of (1,3) and (3,1) ordered pairs.
The following conditions need to satisfy for each property.
a = a (reflexive property),
if a = b then b = a (symmetric property), and
if a = b and b = c then a = c (transitive property).
an asymmetric relation is a binary relation on a set X where:For all a and b in X, if a is related to b, then b is not related to a
The above relation is not reflexive because there is no ordered pairs (2,2) and (4,4)
The above relation is not Symmetric because if (1,2) present means the relation should consists of (2,1) but there is no such ordered pair in the relation.
Asymmetric property also invalid because of (1,3) and (3,1) ordered pairs.
Question 159 |
The probability that top and bottom cards of a randomly shuffled deck are both aces is:
4/52 X 4/52 | |
4/52 X 3/52 | |
4/52 X 3/51 | |
4/52 X 4/51 |
Question 159 Explanation:
E 1 : First card being ace
E 2 : Last card being ace
Note that E 1 and E 2 are dependent events, i.e., probability of last card being ace if first is ace will be lesser than the probability of last card being ace if first card is not ace.
So, probability of first card being ace = 4/52
Probability of last card being ace given that first card is ace is,
P(E 2 / E 1 ) = 3/51
∴ P(E 1 and E 2 ) = P(E 1 ) ⋅ P(E 2 / E 1 ) = 4/52 * 3/51
E 2 : Last card being ace
Note that E 1 and E 2 are dependent events, i.e., probability of last card being ace if first is ace will be lesser than the probability of last card being ace if first card is not ace.
So, probability of first card being ace = 4/52
Probability of last card being ace given that first card is ace is,
P(E 2 / E 1 ) = 3/51
∴ P(E 1 and E 2 ) = P(E 1 ) ⋅ P(E 2 / E 1 ) = 4/52 * 3/51
Question 160 |
Let L be a lattice. Then for every a and b in L which one of the following is correct?
aVb = a ⋀ b | |
aV(bVc)=(aVb)Vc | |
aV(b ⋀ c)=a | |
aV(bVc)=b |
Question 160 Explanation:
Distributive lattice is satisfies this condition aV(bVc)=(aVb)Vc
A distributive lattice is a lattice in which the operations of join and meet distribute over each other.
A distributive lattice is a lattice in which the operations of join and meet distribute over each other.
Question 161 |
Let N={1,2,3,...} be ordered by divisibility, which of the following subset is totally ordered?
(2,6,24) | |
(3,5,15) | |
(2,9,16) | |
(4,15,30) |
Question 161 Explanation:
A binary relation R on a set A is a total order on A iff R is a connected partial order on A.
Question 162 |
Let P, Q and R be three atomic prepositional assertions, and
- X : (P ∨ Q) → R
Y : (P → R) ∨ (Q → R)
Which one of the following is a tautology?
X → Y
| |
Y → X | |
X ≣ Y | |
~Y → X
|
Question 162 Explanation:
Question 163 |
For what values of k, the points(-k+1, 2k),(k, 2-2K) and (-4-k, 6-2k) are collinear?
0, 1
| |
-1, 1 | |
-1, 1/2
| |
1/2, -1/2
|
Question 163 Explanation:
There is a restrictions for 3 points to be colLinear and that is
1/2[X1(Y2 - Y3) + X2(Y3 - Y1) + X3(Y1 - Y2)] = 0
Here, X1 = -k + 1, Y1 = 2k, X2 = k, Y2 = 2 – 2k, X3 = -4 - k, Y3 = 6 – 2k
1/2[-k + 1(2 – 2k - 6 + 2k) + k(6 – 2k - 2k) - 4 -k(2k - 2 + 2k)] = 0
1/2[-k + 1(-4) + k(6 - 4k) -4 - k(4k - 2)] = 0
1/2[4k - 4 + 6k - 4k2 - 16k + 8 - 4k2 + 2k)] = 0
1/2(-8k2 - 4k + 4) = 0
-8k2 - 4k + 4 = 0
-8k2 - 8k + 4k + 4 = 0
-8K(k + 1) + 4(k + 1) = 0
(k + 1) (4 - 8k) = 0
k + 1 = 0
k = -1
4 - 8k = 0
k = 4/8
k = 1/2
So, the value of k is -1 and 1/2 .
1/2[X1(Y2 - Y3) + X2(Y3 - Y1) + X3(Y1 - Y2)] = 0
Here, X1 = -k + 1, Y1 = 2k, X2 = k, Y2 = 2 – 2k, X3 = -4 - k, Y3 = 6 – 2k
1/2[-k + 1(2 – 2k - 6 + 2k) + k(6 – 2k - 2k) - 4 -k(2k - 2 + 2k)] = 0
1/2[-k + 1(-4) + k(6 - 4k) -4 - k(4k - 2)] = 0
1/2[4k - 4 + 6k - 4k2 - 16k + 8 - 4k2 + 2k)] = 0
1/2(-8k2 - 4k + 4) = 0
-8k2 - 4k + 4 = 0
-8k2 - 8k + 4k + 4 = 0
-8K(k + 1) + 4(k + 1) = 0
(k + 1) (4 - 8k) = 0
k + 1 = 0
k = -1
4 - 8k = 0
k = 4/8
k = 1/2
So, the value of k is -1 and 1/2 .
Question 164 |
If a connected graph G has planar embedding with 4 faces and 4 vertices, then what will be the number of edges in G?
7 | |
6 | |
4 | |
3 |
Question 164 Explanation:
Euler's Formula for Planar Graphs:
For any(connected) planar graph with v vertices, e edges and faces, we have
V - E + F = 2
= 4 - E + 4 =2
E = 4 - 2 + 4
E = 6
For any(connected) planar graph with v vertices, e edges and faces, we have
V - E + F = 2
= 4 - E + 4 =2
E = 4 - 2 + 4
E = 6
Question 165 |
What is the area bounded by the parabola 2y = x2 and the line x = y - 4?
18 | |
36 | |
72 | |
6 |
Question 165 Explanation:
Given parabola 2y = x2 --- (1)
and the line x = y – 4 ------ (2)
Then y = x+4
Now, Substitute Y value in Equation-(1)
x2 = 2 ( x + 4 ) ------ (3)
Solving equation-3 we get x = 4, - 2.
Place Values of x in equation (1) and (2) we will get y = 8, 2.
Then the points of intersection are (8, 4), (2, –2).
After solving the integration, we will get 18.
and the line x = y – 4 ------ (2)
Then y = x+4
Now, Substitute Y value in Equation-(1)
x2 = 2 ( x + 4 ) ------ (3)
Solving equation-3 we get x = 4, - 2.
Place Values of x in equation (1) and (2) we will get y = 8, 2.
Then the points of intersection are (8, 4), (2, –2).
After solving the integration, we will get 18.
Question 166 |
What is the possible number of reflexive relations on a set of 5 elements?
225
| |
215 | |
210
| |
220
|
Question 166 Explanation:
Step-1: To find number of reflexive relation we have standard formula is 2(n2-n)
Step-2: The possible number of reflexive relations on a set of 5 elements 2(n2-n) which is 220 for n=5.
Step-2: The possible number of reflexive relations on a set of 5 elements 2(n2-n) which is 220 for n=5.
Question 167 |
Which one of the following is most affected by the presence of outliers in sample data?
Variance
| |
Mean
| |
Median
| |
Mode
|
Question 167 Explanation:
Let's examine what can happen to a data set with outliers.
For the sample data set:
1, 1, 2, 2, 2, 2, 3, 3, 3, 4, 4
We find the following mean, median, mode, and standard deviation:
Mean = 2.58
Median = 2.5
Mode = 2
Standard Deviation = 1.08
If we add an outlier to the data set:
1, 1, 2, 2, 2, 2, 3, 3, 3, 4, 4, 400
The new values of our statistics are:
Mean = 35.38
Median = 2.5
Mode = 2
Standard Deviation = 114.74
Note: Outliers often has a significant effect on your mean and standard deviation.
For the sample data set:
1, 1, 2, 2, 2, 2, 3, 3, 3, 4, 4
We find the following mean, median, mode, and standard deviation:
Mean = 2.58
Median = 2.5
Mode = 2
Standard Deviation = 1.08
If we add an outlier to the data set:
1, 1, 2, 2, 2, 2, 3, 3, 3, 4, 4, 400
The new values of our statistics are:
Mean = 35.38
Median = 2.5
Mode = 2
Standard Deviation = 114.74
Note: Outliers often has a significant effect on your mean and standard deviation.
Question 168 |
Consider the matrix A defined as follows:
What is the eigenvalue of 3A3 + 5A2 - 6A + 21, where I is an identity matrix?
4, 110, 10
| |
1, 27, -8
| |
1, 9, 4
| |
4, 27, 9
|
Question 168 Explanation:
The eigenvalues of A are 1, 3, –2 ( ∵ The given matrix is upper triangular)
Eigenvalues of A3 are 1, 27 and –8.
Eigenvalues of A2 are 1, 9 and 4.
Eigenvalues of A are 1, 3 and –2.
Eigenvalues of I are 1, 1 and 1.
∴ The eigenvalues of 3A3 + 5A2 – 6A + 2I.
First eigenvalue = 3(1) + 5(1) – 6(1) + 2(1) = 4
Second eigenvalue = 3(27) + 5(9) – 6(3) + 2(1) = 110
Third eigenvalue = 3(–8) + 5(4) – 6(–2) + 2(1) = 10
∴ The required eigenvalues are 4, 110, and 10.
Eigenvalues of A3 are 1, 27 and –8.
Eigenvalues of A2 are 1, 9 and 4.
Eigenvalues of A are 1, 3 and –2.
Eigenvalues of I are 1, 1 and 1.
∴ The eigenvalues of 3A3 + 5A2 – 6A + 2I.
First eigenvalue = 3(1) + 5(1) – 6(1) + 2(1) = 4
Second eigenvalue = 3(27) + 5(9) – 6(3) + 2(1) = 110
Third eigenvalue = 3(–8) + 5(4) – 6(–2) + 2(1) = 10
∴ The required eigenvalues are 4, 110, and 10.
Question 169 |
If A and B are sets and AUB = A∩B, then which of the following is correct?
A=B | |
A=∅
| |
B=∅ | |
A⊂B
|
Question 169 Explanation:
For this let x belongs to A implies x belongs to A U B
= x belongs to A intersection B
= x belongs to A and x Belongs to B
= x belongs to B
so A subset of B --- (2)
Now we will let y belong to B which implies y belongs to A U B
= y belongs to A intersection B
= y belongs to A and y belongs to B
= y belongs to A
Therefore, B subset of A --- (3) from (2) and (3) we get A=B.
= x belongs to A intersection B
= x belongs to A and x Belongs to B
= x belongs to B
so A subset of B --- (2)
Now we will let y belong to B which implies y belongs to A U B
= y belongs to A intersection B
= y belongs to A and y belongs to B
= y belongs to A
Therefore, B subset of A --- (3) from (2) and (3) we get A=B.
Question 170 |
Which of the following statements is/are correct?
-
(i) If the rank of the matrix of given vectors is equal to the number of vectors, then the vectors are linearly independent.
(ii) If the rank of the matrix of given vectors is less than the number of vectors, then the vectors are linearly dependent.
Both (i) and (ii)
| |
Only (ii)
| |
Only (i) | |
Neither (i) nor (ii) |
Question 170 Explanation:
The Rank of a Matrix
→ You can think of an r x c matrix as a set of r row vectors, each having c elements; or you can think of it as a set of c column vectors, each having r elements.
→ The rank of a matrix is defined as (a) the maximum number of linearly independent column vectors in the matrix or (b) the maximum number of linearly independent row vectors in the matrix. Both definitions are equivalent.
For an r x c matrix,
1. If r is less than c, then the maximum rank of the matrix is r.
2. If r is greater than c, then the maximum rank of the matrix is c.
→ The rank of a matrix would be zero only if the matrix had no elements. If a matrix had even one element, its minimum rank would be one.
→ You can think of an r x c matrix as a set of r row vectors, each having c elements; or you can think of it as a set of c column vectors, each having r elements.
→ The rank of a matrix is defined as (a) the maximum number of linearly independent column vectors in the matrix or (b) the maximum number of linearly independent row vectors in the matrix. Both definitions are equivalent.
For an r x c matrix,
1. If r is less than c, then the maximum rank of the matrix is r.
2. If r is greater than c, then the maximum rank of the matrix is c.
→ The rank of a matrix would be zero only if the matrix had no elements. If a matrix had even one element, its minimum rank would be one.
Question 171 |
Every cut set of a connected euler graph has____
An odd number of edges
| |
At least three edges
| |
An even number of edges | |
A single edge |
Question 171 Explanation:
If every minimal cut has an even number of edges, then in particular the degree of each vertex is even. Since the graph is connected, that means it is Eulerian.
Question 172 |
A fair coin is tossed 6 times. What is the probability that exactly two heads will occur?
11/32 | |
1/64 | |
15/64
| |
63/64 |
Question 172 Explanation:
Step-1: We want to calculate the probability of getting exactly k "success" results using Bernoulli's Scheme.
The probability can be calculated as:
n is a total number of experiments
k is an expected number of successes
p is the probability of a success
Step-2: The first task can be simply solved by calculating the probability of 2 successes:
A "success" is "tossing heads in a single toss".
A "failure" is "tossing tails in a single toss".
Step-3: The probability of a success is ½
The number of all experiments is n=6.
The number of successes is k=2
The probability can be calculated as:
n is a total number of experiments
k is an expected number of successes
p is the probability of a success
Step-2: The first task can be simply solved by calculating the probability of 2 successes:
A "success" is "tossing heads in a single toss".
A "failure" is "tossing tails in a single toss".
Step-3: The probability of a success is ½
The number of all experiments is n=6.
The number of successes is k=2
Question 173 |
How many solutions does the equation x + y - z = 11 have, where x, y and z are non negative integers?
120 | |
78 | |
156 | |
130 |
Question 173 Explanation:
→ For any pair of natural numbers n and k, the number of distinct n-tuples of non-negative integers whose sum is k is given by the binomial coefficient.
Here, n=3 and k=11, giving you
Here, n=3 and k=11, giving you
Question 174 |
A graph G is dual if and only if G is a ___
Euler graph
| |
Regular graph | |
Complete graph | |
Planar graph
|
Question 174 Explanation:
Definition Given a plane graph G, the dual graph G* is the plane graph whose vtcs are the faces of G.
→ The correspondence between edges of G and those of G* is as follows:
if e∈E(G) lies on the boundaries of faces X and Y, then the endpts of the dual edge e*∈(G*) are the vertices x and y that represent faces X and Y of G.
→ The correspondence between edges of G and those of G* is as follows:
if e∈E(G) lies on the boundaries of faces X and Y, then the endpts of the dual edge e*∈(G*) are the vertices x and y that represent faces X and Y of G.
Question 175 |
Which of the given options is the logical translation of the following statement, where F(x) and P(x) express the terms friend and perfect, respectively?
“None of my friends are perfect”?
∃x(~F(x)∧P(x))
| |
∃x(F(x)∧ ~P(x))
| |
~∃x(F(x)∧P(x)) | |
∃x(~F(x)∧~P(x))
|
Question 175 Explanation:
F(x) represents x is friend.
P(x) represents x is perfect.
Given statement is “None of my friends are perfect”.
F(x)∧P(x) ---> X is both Friend and perfect.
~∃x ----> There is exist no one.
We can also write the above statement as follows
∀x[F(x) ⟹ ¬P(x)]
≡ ∀x[¬F(x) ∨ ¬P(x)]
≡∀x¬[F(x) ∧ P(x)]
≡¬∃x[F(x) ∧ P(x)]
P(x) represents x is perfect.
Given statement is “None of my friends are perfect”.
F(x)∧P(x) ---> X is both Friend and perfect.
~∃x ----> There is exist no one.
We can also write the above statement as follows
∀x[F(x) ⟹ ¬P(x)]
≡ ∀x[¬F(x) ∨ ¬P(x)]
≡∀x¬[F(x) ∧ P(x)]
≡¬∃x[F(x) ∧ P(x)]
Question 176 |
The average rate of convergence of the bisection method is ____.
1/2 | |
3 | |
2 | |
1 |
Question 176 Explanation:
The average rate of convergence of the bisection method is 1/2.
Question 177 |
What is the chromatic number of an n-vertex simple connected graph, which does NOT contain any odd-length cycle?
N | |
N-1 | |
2 | |
3 |
Question 177 Explanation:
→ If n ≥ 2 and there are no odd length cycles, Then it is bipartite graph.
→ A bipartite graph has the chromatic number 2.
Eg: Consider a square, which has 4 edges. It can be represented as bipartite ,with chromatic number 2.
→ A bipartite graph has the chromatic number 2.
Eg: Consider a square, which has 4 edges. It can be represented as bipartite ,with chromatic number 2.
Question 178 |
Considering an undirected graph, which of the following statements is/are true?
- (i) Number of vertices of odd degree is always even
(ii) Sum of degrees of all the vertices is always even
Neither (i) nor (ii)
| |
Both (i) and (ii) | |
Only (ii) | |
Only (i)
|
Question 178 Explanation:
True: Number of vertices of odd degree is always even.
True: Sum of degrees of all the vertices is always even.
True: Sum of degrees of all the vertices is always even.
Question 179 |
Select the option that best describes the relationship between the following graphs:
G and H are directed | |
G and H are isomorphic
| |
G and H are homomorphic | |
G and H are not isomorphic |
Question 179 Explanation:
If G1 ≡ G2 then
1. |V(G1)| = |V(G2)|
2. |E(G1)| = |E(G2)|
3. Degree sequences of G1 and G2 are same.
4. If the vertices {V1, V2, ... Vk} form a cycle of length K in G1, then the vertices {f(V1), f(V2), … f(Vk)} should form a cycle of length K in G2.
→ Graph G and H are having same number of vertices and edges. So, it satisfied first rule.
→ u1 degree 2, u2 degree 3, u3 degree 3, u4 degree 2, u5 degree 3, u6 degree 3.
→ V1 degree 2, V2 degree 3, V3 degree 3, V4 degree 2, V5 degree 3, V6 degree 3.
→ But it violates the property of number of cycles. The number of cycles are not same.
1. |V(G1)| = |V(G2)|
2. |E(G1)| = |E(G2)|
3. Degree sequences of G1 and G2 are same.
4. If the vertices {V1, V2, ... Vk} form a cycle of length K in G1, then the vertices {f(V1), f(V2), … f(Vk)} should form a cycle of length K in G2.
→ Graph G and H are having same number of vertices and edges. So, it satisfied first rule.
→ u1 degree 2, u2 degree 3, u3 degree 3, u4 degree 2, u5 degree 3, u6 degree 3.
→ V1 degree 2, V2 degree 3, V3 degree 3, V4 degree 2, V5 degree 3, V6 degree 3.
→ But it violates the property of number of cycles. The number of cycles are not same.
Question 180 |
Consider the following statements. Which one is/are correct?
- (i) The LU decomposition method fails if any of the diagonal elements of the matrix is zero.
(ii) The LU decomposition is guaranteed when the coefficient matrix is positive definite.
Both (i) and (ii) | |
Only (i)
| |
Neither (i) nor (ii) | |
Only (ii) |
Question 180 Explanation:
Lower–Upper (LU) decomposition or factorization factors a matrix as the product of a lower triangular matrix and an upper triangular matrix. The product sometimes includes a permutation matrix as well. LU decomposition can be viewed as the matrix form of Gaussian elimination. Computers usually solve square systems of linear equations using LU decomposition, and it is also a key step when inverting a matrix or computing the determinant of a matrix.
1. The LU decomposition method fails if any of the diagonal elements of the matrix is zero.
2. The LU decomposition is guaranteed when the coefficient matrix is positive definite.
1. The LU decomposition method fails if any of the diagonal elements of the matrix is zero.
2. The LU decomposition is guaranteed when the coefficient matrix is positive definite.
Question 181 |
Which of the following Hasse diagrams is are lattice(s)?
Only (a), (b) and (c) | |
Only (a) and (b)
| |
Only (b) and (c)
| |
Only (a) and (c)
|
Question 181 Explanation:
A Hasse diagram is a type of mathematical diagram used to represent a finite partially ordered set, in the form of a drawing of its transitive reduction.
Question 182 |
Choose the option that correctly matches each element of LIST-1 with exactly one element of LIST-2:
LIST-1 LIST-2 (i) Newton-Raphson method (a) Solving nonlinear equation (ii) Simpson’s rule (b) Solving ordinary differential equations (iii)Runge-Kutta method (c) Numerical integration (iv) Gauss elimination (d) Interpolation
(i)-(b), (ii)-(d), (iii)-(a), (iv)-(c) | |
(i)-(a), (ii)-(b), (iii)-(c), (iv)-(d)
| |
(i)-(a), (ii)-(c), (iii)-(d), (iv)-(b)
| |
(i)-(d), (ii)-(c), (iii)-(b), (iv)-(a)
|
Question 182 Explanation:
Newton-Raphson method→ Interpolation
Simpson’s rule→ Numerical integration
Runge-Kutta method→ Solving ordinary differential equations
Gauss elimination→ Solving nonlinear equation
Simpson’s rule→ Numerical integration
Runge-Kutta method→ Solving ordinary differential equations
Gauss elimination→ Solving nonlinear equation
Question 183 |
How many ways are there to arrange the nine letters of the word ALLAHABAD?
4560
| |
4000
| |
7560
| |
7500
|
Question 183 Explanation:
Step-1: There are 4A, 2L, 1H, 1B and 1D.
Step-2: Total number of alphabets! / alphabets are repeating using formula (n!) / (r1! r2!..).
Step-3: Repeating letters are 4A's and 2L's
= 9! / (4!2!)
= 7560
Step-2: Total number of alphabets! / alphabets are repeating using formula (n!) / (r1! r2!..).
Step-3: Repeating letters are 4A's and 2L's
= 9! / (4!2!)
= 7560
Question 184 |
How many bit strings of length eight (either start with a 1 bit or end with the two bits 00) can be formed?
64 | |
255 | |
160 | |
128 |
Question 184 Explanation:
Use the subtraction rule.
1. Number of bit strings of length eight that start with a 1 bit: 27 = 128
2. Number of bit strings of length eight that end with bits 00: 26 = 64
3. Number of bit strings of length eight that start with a 1 bit and end with bits 00: 25 = 32
The number is 128+64+32 = 160
1. Number of bit strings of length eight that start with a 1 bit: 27 = 128
2. Number of bit strings of length eight that end with bits 00: 26 = 64
3. Number of bit strings of length eight that start with a 1 bit and end with bits 00: 25 = 32
The number is 128+64+32 = 160
Question 185 |
Which of the following statements are logically equivalent?
- (i) ∀x(P(x))
(ii) ~∃x(P(x))
(iii) ~∃x(~P(x))
(iv) ∃x(~P(x))
Only (ii) and (iv) | |
Only (ii) and (iii)
| |
Only (i) and (iv)
| |
Only (i) and (ii) |
Question 185 Explanation:
∀x(P(x)) = ~∃x(~P(x))
Question 186 |
What is the solution of the recurrence relation an = 6an-1 - 9an-2 with initial conditions a0=1 and a1=6?
an = 3n + 3n2
| |
an = 3n + n3n
| |
an = 3n + 3nn
| |
an = n3 + n3n
|
Question 186 Explanation:
→ Let c1, c2, ..., ck be real numbers.
→ Suppose that the characteristic equation rk −c1rk−1 −···−ck = 0 has k distinct roots r1, r2, ..., rk.
→ Then, a sequence {an} is a solution of the recurrence relation: an = c1an−1 + c2an−2 + ··· + ckan−k
→ if and only if an = α1rn1 + α2rn2 + ··· + αk rnk for n = 0,1,2,..., where α1, α2, ..., αk are constants.
→ r2 − 6r + 9 = 0 has only 3 as a root.
→ So the format of the solution is an = α13n + α2n3n.
→ Need to determine α1 and α2 from initial conditions:
a0 = 1 = α1
a1 = 6 = α13 + α23
Solving these equations we get α1=1 and α2=1
Therefore, an = 3n + n3n.
→ Suppose that the characteristic equation rk −c1rk−1 −···−ck = 0 has k distinct roots r1, r2, ..., rk.
→ Then, a sequence {an} is a solution of the recurrence relation: an = c1an−1 + c2an−2 + ··· + ckan−k
→ if and only if an = α1rn1 + α2rn2 + ··· + αk rnk for n = 0,1,2,..., where α1, α2, ..., αk are constants.
→ r2 − 6r + 9 = 0 has only 3 as a root.
→ So the format of the solution is an = α13n + α2n3n.
→ Need to determine α1 and α2 from initial conditions:
a0 = 1 = α1
a1 = 6 = α13 + α23
Solving these equations we get α1=1 and α2=1
Therefore, an = 3n + n3n.
Question 187 |
Which of the following statements about the Newton-Raphson method is/are correct?
- (i) It is quadratic convergent
(ii) If f'(x) is zero, it fails
(iii) It is also used to obtain complex root
(i), (ii) and (iii)
| |
only (i) and (iii)
| |
only (i) and (ii) | |
only (i)
|
Question 187 Explanation:
Above all statements are true for Newton-Raphson method.
Note: Newton-Raphson method is mainly used for Interpolation.
Note: Newton-Raphson method is mainly used for Interpolation.
Question 188 |
What is the minimum number of students in a class to be sure that three of them are born in the same month?
24 | |
12 | |
25 | |
13 |
Question 188 Explanation:
With the help of Pigeonhole principle we can get the solution. The idea is that if you n items and m possible containers. If n > m, then at least one container must have two items in it. So, total 13 minimum number of students.
Question 189 |
M is a square matrix of order 'n' and its determinant value is 5, If all the elements of M are multiplied by 2, its determinant value becomes 40. he value of 'n' is
2 | |
3 | |
5 | |
4 |
Question 189 Explanation:
M has n rows. If all the elements of a row are multiplied by , the determinant value becomes 2*5. Multiplying all the n rows by 2, will make the determinant value 2 n *5=40. Solving n= 3.
Question 190 |
The convergence of the bisection method is
Cubic | |
Quadratic | |
Linear | |
none |
Question 190 Explanation:
The convergence of the bisection method is very slow. Although the error, in general, does not decrease monotonically, the average rate of convergence is 1/2 and so, slightly changing the definition of order of convergence, it is possible to say that the method converges linearly with rate 1/2.
Note:For the bisection you simply have that ε i+1 /ε i =1/2, so, by definition the order of convergence is 1 (linearly).
Note:For the bisection you simply have that ε i+1 /ε i =1/2, so, by definition the order of convergence is 1 (linearly).
Question 191 |
The solution of the recurrence relation a r =a r-1 +2a r-2 with a 0 =2,a 1 =7
a r =(3) r +(1) r | |
2a r =(2) r /3 -(1) r | |
a r =3 r+1 -(-1) r | |
a r =3(2) r -(-1) r |
Question 191 Explanation:
Given the recurrence relation a r =a r-1 +2a r-2 and a 0 =2,a 1 =7.
For r =2, a 2= a 2-1 +2a 2-2 =a 1 +2a 0 =7+2*2=7+4=11
For r=3,a 3= a 3-1 +2a 3-2 =a 2 +2a 1 =11+2*7=11+14=25
From the above options , Substitute the r values 0,1,2,3 then option -D gives the solution to recurrence relation.
For r =2, a 2= a 2-1 +2a 2-2 =a 1 +2a 0 =7+2*2=7+4=11
For r=3,a 3= a 3-1 +2a 3-2 =a 2 +2a 1 =11+2*7=11+14=25
From the above options , Substitute the r values 0,1,2,3 then option -D gives the solution to recurrence relation.
Question 192 |
Using bisection method, one root of X4-X-1 lies between 1 and 2. After second iteration the root may lie in interval:
(1.25,1.5) | |
(1,1.25) | |
(1,1.5) | |
None of the options |
Question 192 Explanation:
Given data.
root= X4-X-1.
Root lies Between 1 and 2,
After second iteration=?
Using bisection method.
f(1)=X4-X-1
=1-1-1
= -1
f(2)=X4-X-1
= 24 -2 -1
=13
Given constraint that “root lies between 1 and 2”
Iteration-1: x1=(a+b)/2
=(1+2)/2
= 1.5
f(1.5) = 2.5625
Iteration-2: x2=(a+b)/2
=(1+1.5)/2
=1.25
f(1.25)=0.19140625 >0
Root may lie in between (1, 1.25)
Algorithm - Bisection Scheme
Given a function f (x) continuous on an interval [a,b] and f (a) * f (b) < 0
Do
c=(a+b)/2
if f(a)*f(c)< 0 then b=c
else a=c
while (none of the convergence criteria C1, C2 or C3 is satisfied)
More info:
Bisection method is the simplest among all the numerical schemes to solve the transcendental equations. This scheme is based on the intermediate value theorem for continuous functions .
Consider a transcendental equation f(x)=0 which has a zero in the interval [a,b] and f(a)*f(b)<0. Bisection scheme computes the zero, say c, by repeatedly halving the interval [a,b]. That is, starting with
c = (a+b) / 2
The interval [a,b] is replaced either with [c,b] or with [a,c] depending on the sign of f (a) * f (c) . This process is continued until the zero is obtained. Since the zero is obtained numerically the value of c may not exactly match with all the decimal places of the analytical solution of f (x) = 0 in the interval [a,b]. Hence any one of the following mechanisms can be used to stop the bisection iterations :
C1. Fixing a priori the total number of bisection iterations N i.e., the length of the interval or the maximum error after N iterations in this case is less than | b-a | / 2N.
C2. By testing the condition | ci - c i-1| (where i are the iteration number) less than some tolerance limit, say epsilon, fixed a priori.
C3. By testing the condition | f (ci ) | less than some tolerance limit alpha again fixed a priori.
http://mat.iitm.ac.in/home/sryedida/public_html/caimna/transcendental/bracketing%20methods/bisection/bisection.html
root= X4-X-1.
Root lies Between 1 and 2,
After second iteration=?
Using bisection method.
f(1)=X4-X-1
=1-1-1
= -1
f(2)=X4-X-1
= 24 -2 -1
=13
Given constraint that “root lies between 1 and 2”
Iteration-1: x1=(a+b)/2
=(1+2)/2
= 1.5
f(1.5) = 2.5625
Iteration-2: x2=(a+b)/2
=(1+1.5)/2
=1.25
f(1.25)=0.19140625 >0
Root may lie in between (1, 1.25)
Algorithm - Bisection Scheme
Given a function f (x) continuous on an interval [a,b] and f (a) * f (b) < 0
Do
c=(a+b)/2
if f(a)*f(c)< 0 then b=c
else a=c
while (none of the convergence criteria C1, C2 or C3 is satisfied)
More info:
Bisection method is the simplest among all the numerical schemes to solve the transcendental equations. This scheme is based on the intermediate value theorem for continuous functions .
Consider a transcendental equation f(x)=0 which has a zero in the interval [a,b] and f(a)*f(b)<0. Bisection scheme computes the zero, say c, by repeatedly halving the interval [a,b]. That is, starting with
c = (a+b) / 2
The interval [a,b] is replaced either with [c,b] or with [a,c] depending on the sign of f (a) * f (c) . This process is continued until the zero is obtained. Since the zero is obtained numerically the value of c may not exactly match with all the decimal places of the analytical solution of f (x) = 0 in the interval [a,b]. Hence any one of the following mechanisms can be used to stop the bisection iterations :
C1. Fixing a priori the total number of bisection iterations N i.e., the length of the interval or the maximum error after N iterations in this case is less than | b-a | / 2N.
C2. By testing the condition | ci - c i-1| (where i are the iteration number) less than some tolerance limit, say epsilon, fixed a priori.
C3. By testing the condition | f (ci ) | less than some tolerance limit alpha again fixed a priori.
http://mat.iitm.ac.in/home/sryedida/public_html/caimna/transcendental/bracketing%20methods/bisection/bisection.html
Question 193 |
Find the smallest number y such that y*162 (y multiplied by 162) is perfect cube:
24 | |
27 | |
36 | |
38 |
Question 193 Explanation:
Prime factorize: 162
⇒162 =2×3×3×3×3 = 33×(2×3)
For (2×3) to be a perfect cube, it should be multiplied by (22×32)
∴ Required number = y = 22×32 = 36
⇒162 =2×3×3×3×3 = 33×(2×3)
For (2×3) to be a perfect cube, it should be multiplied by (22×32)
∴ Required number = y = 22×32 = 36
Question 194 |
In how many ways 8 girl and 8 boys can sit around a circular table so that no two boys sit together?
(7!)2 | |
(8!)2 | |
7!8! | |
15! |
Question 194 Explanation:
→ First fix one boy and place other 7 in alternative seats so total ways is 7! Because they are seated in circular table. (n-1)!.
→ Now place each girl between a pair of boys. So, total ways of seating arrangement of girls is 8!
→ Finally, 7!8! Possible ways are possible.
→ Now place each girl between a pair of boys. So, total ways of seating arrangement of girls is 8!
→ Finally, 7!8! Possible ways are possible.
Question 195 |
Let u and V be two vectors in R 2 whose euclidean norms satisfy |u|=2|v|. What is the value α such that w=u+αv bisects the angle between u and v?
2 | |
1 | |
1/2 | |
-1 |
Question 195 Explanation:
Let u, v be vectors in R2, increasing at a point, with an angle θ.
A vector bisecting the angle should split θ into θ/2,θ/2
Means ‘w’ should have the same angle with u, v and it should be half of the angle between u and v.
Assume that the angle between u, v be 2θ (thus angle between u,w=θ and v,w=θ) Cosθ=(u∙w)/(∥u∥ ∥w∥) ⇾①
Cosθ=(v∙w)/(∥v∥ ∥w∥) ⇾②
①/②⇒1/1=((u∙w)/(∥u∥ ∥w∥))/((v∙w)/(∥v∥ ∥w∥))⇒1=((u∙w)/(∥u∥))/((v∙w)/(∥v∥))
⇒(u∙w)/(v∙w)=(∥u∥)/(∥v∥) which is given that ∥u∥=2 ∥v∥
⇒(u∙w)/(v∙w)=(2∥v∥)/(∥v∥)=2 ⇾③
Given ∥u∥=2∥v∥
u∙v=∥u∥ ∥v∥Cosθ
=2∙∥v∥2 Cosθ
w=u+αv
(u∙w)/(v∙w)=2
(u∙(u+αv))/(v∙(u+αv))=2
(u∙u+α∙u∙v)/(u∙v+α∙v∙v)=2a∙a=∥a∥2
4∥v∥2+α∙2∙∥v∥2 Cosθ=2(2∥v∥2 Cosθ+α∙∥v∥2/sup>)
4+2αCosθ=2(2Cosθ+α)
4+2αCosθ=4Cosθ+2α⇒Cosθ(u-v)+2α-4=0
4-2α=Cosθ(4-2α)
(4-2α)(Cosθ-1)=0 4-2α=0
Question 196 |
Let G be a complete undirected graph on 8 vertices of G are labelled, then the number of distinct cycles of length 5 in G is equal to:
15 | |
30 | |
56 | |
60 |
Question 196 Explanation:
Given data,
8 vertices and distinct cycles length=5
Step-1: To find number of distinct cycles
C(n,r)=C(8,5)
=8! / (5!(8−5)!)
= 56
8 vertices and distinct cycles length=5
Step-1: To find number of distinct cycles
C(n,r)=C(8,5)
=8! / (5!(8−5)!)
= 56
Question 197 |
Which one is the correct translation of the following statement into mathematical logic?
"None of my friends are perfect"
"None of my friends are perfect"
~∃x(p(x) ⋀ q(x)) | |
∃x(~p(x) ⋀ q(x)) | |
∃x(~p(x) ⋀ ~q(x)) | |
∃x(p(x) ⋀ ~q(x)) |
Question 197 Explanation:
F(x) ⇒ x is my friend
P(x) ⇒ x is perfect
There doesn't exist any person who is my friend and perfect
P(x) ⇒ x is perfect
There doesn't exist any person who is my friend and perfect
Question 198 |
The number of integers between 1 and 500(both inclusive) that are divisible by 3 or 5 or 7 is__
269 | |
20 | |
271 | |
272 |
Question 198 Explanation:
Let A = number divisible by 3
B = numbers divisible by 5
C = number divisible by 7
We need to find “The number of integers between 1 and 500 that are divisible by 3 or 5 or 7" i.e.,|A∪B∪C|
We know,
|A∪B∪C|=|A|+|B|+C-|A∩B|-|A∩C|-|B∩C|+|A∩B|
|A|=number of integers divisible by 3
[500/3=166.6≈166=166]
|B|=100
[500/5=100]
|C|=71
[500/7=71.42]
|A∩B|=number of integers divisible by both 3 and 5 we need to compute with LCM (15)
i.e.,⌊500/15⌋≈33
|A∩B|=33
|A∩C|=500/LCM(3,7) 500/21=23.8≈28
|B∩C|=500/LCM(5,3) =500/35=14.48≈14
|A∩B∩C|=500/LCM(3,5,7) =500/163=4.76≈4
|A∪B∪C|=|A|+|B|+|C|-|A∩B|-|A∩C|-|B∩C|+|A∩B∩C|
=166+100+71-33-28-14+4
=271
Question 199 |
When the sum of all possible two digit numbers formed from three different one digit natural numbers are divided by sum of the original three numbers, the result is:
26 | |
24 | |
20 | |
22 |
Question 199 Explanation:
Let a,b,c be 3 different digits, the sum of the different 2 digit numbers formed with them is
=(a*10+b)+(b*10+a)+(a*10+c)+(c*10+a)+(b*10+c)+(c*10+b)
=2(a+b+c)(10+1)
=22
=(a*10+b)+(b*10+a)+(a*10+c)+(c*10+a)+(b*10+c)+(c*10+b)
=2(a+b+c)(10+1)
=22
Question 200 |
Consider two matrices M1 and M2 with M1*M2 =0 and M1 is non singular. Then which of the following is true?
M2 is non singular | |
M2 is null Matrix | |
M2 is the identity matrix | |
M2 is transpose of M1 |
Question 200 Explanation:
M2 is null Matrix
The easiest way we can prove this is by looking at the determinant, since det(AB)=det(A)det(B)
and a matrix A is singular iff det(A)=0
The easiest way we can prove this is by looking at the determinant, since det(AB)=det(A)det(B)
and a matrix A is singular iff det(A)=0
Question 201 |
Let G be a simple undirected graph on n=3x vertices (x>=1) with chromatic number 3, then maximum number of edges in G is:
n(n-1)/2 | |
nn-2 | |
nx | |
n |
Question 201 Explanation:
Given undirected graph on n=3x vertices (x>=1) with chromatic number 3.
→ Maximum number of edges are=n.
→ Maximum number of edges are=n.
Question 202 |
Total number of simple graphs that can be drawn using six vertices are:
215 | |
214 | |
213 | |
212 |
Question 202 Explanation:
To get total number of simple graphs, we have a direct formula is 2(n(n-1)/2).
=26(5)/2
=215
=26(5)/2
=215
Question 203 |
If a planner graph, having 25 vertices divides plane into 17 different regions. Then how many edges are used to connect the vertices in this graph
20 | |
30 | |
40 | |
50 |
Question 203 Explanation:
Euler’s Formula : For any polyhedron that doesn’t intersect itself (Connected Planar Graph),
F(faces) + V(vertices) − E(edges) = 2.
Here as given, F=?,V=25 and E=17
→ F+25-17=2
→ 40
Here as given, F=?,V=25 and E=17
→ F+25-17=2
→ 40
Question 204 |
If a random coin is tossed 11 times, then what is the probability that for 7th toss head appears exactly 4 times?
5/32 | |
15/128 | |
35/128 | |
None of the options |
Question 204 Explanation:
→ To find probability that for the 7th toss head appears exactly 4 times. We have find that past 6 run of tosses.
→ Past 6 tosses, What happen we don’t know. But according to 7th toss, we will find that head appeared for 3 times.
→ Any coin probability of a head=½ and probability of a tail=½
→ If we treat tossing of head as success,then this leads to a case of binomial distribution.
→ According to binomial distribution, the probability that in 6 trials we get 3 success is
6C3*(½)3 *(½)3= 5/16 (3 success in 6 trials can happen in 6C3 ways). → 7th toss, The probability of obtaining a head=1/2
→ In given question is not mention that what happens after 7 tosses.
→ Probability for that for 7th toss head appears exactly 4 times is =(5/16)*(1/2)
=5/32.
→ Past 6 tosses, What happen we don’t know. But according to 7th toss, we will find that head appeared for 3 times.
→ Any coin probability of a head=½ and probability of a tail=½
→ If we treat tossing of head as success,then this leads to a case of binomial distribution.
→ According to binomial distribution, the probability that in 6 trials we get 3 success is
6C3*(½)3 *(½)3= 5/16 (3 success in 6 trials can happen in 6C3 ways). → 7th toss, The probability of obtaining a head=1/2
→ In given question is not mention that what happens after 7 tosses.
→ Probability for that for 7th toss head appears exactly 4 times is =(5/16)*(1/2)
=5/32.
Question 205 |
The number of the edges in a regular graph of degree 'd' and 'n' vertices is____
Maximum of n,d | |
n+d | |
nd | |
nd/2 |
Question 205 Explanation:
Sum of degree of vertices = 2*no. of edges
d*n = 2*|E|
∴ |E| = (d*n)/2
d*n = 2*|E|
∴ |E| = (d*n)/2
Question 206 |
The convergence of the bisection method is
Cubic | |
Quadratic | |
Linear | |
none |
Question 206 Explanation:
The convergence of the bisection method is very slow. Although the error, in general, does not decrease monotonically, the average rate of convergence is 1/2 and so, slightly changing the definition of order of convergence, it is possible to say that the method converges linearly with rate 1/2.
Note:For the bisection you simply have that ε i+1 /ε i =1/2, so, by definition the order of convergence is 1 (linearly).
Note:For the bisection you simply have that ε i+1 /ε i =1/2, so, by definition the order of convergence is 1 (linearly).
Question 207 |
What is the maximum value of the function f(x)=2x 2 -2x +6 in the interval [0,2]?
6 | |
10 | |
12 | |
5,5 |
Question 207 Explanation:
An open interval does not include its endpoints, and is indicated with parentheses. For example, (0,1) means greater than 0 and less than 1.
A closed interval is an interval which includes all its limit points, and is denoted with square brackets. For example, [0,1] means greater than or equal to 0 and less than or equal to 1.
A half-open interval includes only one of its endpoints, and is denoted by mixing the notations for open and closed intervals. (0,1] means greater than 0 and less than or equal to 1, while [0,1) means greater than or equal to 0 and less than 1.
Given function f(x)=2x 2 -2x +6 and the given interval is [0,2]
According to the given interval , we need to check the function at the values 0,1,2.
f(0)=2x0-2x0+6=6
f(1)=2x1 2 -2x1+6=2-2+6=6
f(2)=2x2 2 -2x2+6=8-4+6=10
A closed interval is an interval which includes all its limit points, and is denoted with square brackets. For example, [0,1] means greater than or equal to 0 and less than or equal to 1.
A half-open interval includes only one of its endpoints, and is denoted by mixing the notations for open and closed intervals. (0,1] means greater than 0 and less than or equal to 1, while [0,1) means greater than or equal to 0 and less than 1.
Given function f(x)=2x 2 -2x +6 and the given interval is [0,2]
According to the given interval , we need to check the function at the values 0,1,2.
f(0)=2x0-2x0+6=6
f(1)=2x1 2 -2x1+6=2-2+6=6
f(2)=2x2 2 -2x2+6=8-4+6=10
Question 208 |
The value of the integral
(x+2)/2 | |
2/(π-2) | |
π-2 | |
π+2 |
Question 208 Explanation:
The integral value of x 2 sin(x)dx is [−x 2 cos(x)+2xsin(x)+2cos(x)+C] with the interval [π/2,0]
=[−( π/2) 2 cos( π/2 )+2 π/2 sin( π/2 )+2cos( π/2 )+C] - [−( 0) 2 cos( π/2 )+2(0)sin( π/2 )+2cos( 0 )+C]
=[0+ π+0+C-2-C]
=π-2
=[−( π/2) 2 cos( π/2 )+2 π/2 sin( π/2 )+2cos( π/2 )+C] - [−( 0) 2 cos( π/2 )+2(0)sin( π/2 )+2cos( 0 )+C]
=[0+ π+0+C-2-C]
=π-2
Question 209 |
The solution of the recurrence relation a r =a r-1 +2a r-2 with a 0 =2,a 1 =7
a r =(3) r +(1) r | |
2a r =(2) r /3 -(1) r | |
a r =3 r+1 -(-1) r | |
a r =3(2) r -(-1) r |
Question 209 Explanation:
● Given the recurrence relation a r =a r-1 +2a r-2 and
a 0 =2,a 1 =7.
● For r =2, a 2= a 2-1 +2a 2-2 =a 1 +2a 0 =7+2*2=7+4=11 ● For r=3,a 3= a 3-1 +2a 3-2 =a 2 +2a 1 =11+2*7=11+14=25
● From the above options ,Substitute the r values 0,1,2,3 then option -D gives the solution to recurrence relation.
● For r =2, a 2= a 2-1 +2a 2-2 =a 1 +2a 0 =7+2*2=7+4=11 ● For r=3,a 3= a 3-1 +2a 3-2 =a 2 +2a 1 =11+2*7=11+14=25
● From the above options ,Substitute the r values 0,1,2,3 then option -D gives the solution to recurrence relation.
Question 210 |
M is a square matrix of order 'n' and its determinant value is 5. If all the elements of M are multiplied by 2, Its determinant value becomes 40. The value of 'n' is
2 | |
3 | |
5 | |
4 |
Question 210 Explanation:
● From the matrix property :
If each element of a row (or a column) of a determinant is multiplied by a constant k, then its value gets multiplied by k.
● Consider matrix order is 3, there are 3 rows and each row is multiplied by 2 means we need to multiply 8 to the existing determinant.
● The given existing determinant is 5 and each row multiplied by 2 means 8 *5 =40.
● Consider matrix order is 3, there are 3 rows and each row is multiplied by 2 means we need to multiply 8 to the existing determinant.
● The given existing determinant is 5 and each row multiplied by 2 means 8 *5 =40.
Question 211 |
The figure below represents a
Hilbert curve order 3 | |
Hilbert curve order 2 | |
Hilbert curve of order 1 | |
Hilbert curve of order 4 |
Question 211 Explanation:
→ The Hilbert Curve is a space filling curve that visits every point in a square grid.
→ The path taken by a Hilbert Curve appears as a sequence - or a certain iteration - of up, down, left, and right.
→ The path taken by a Hilbert Curve appears as a sequence - or a certain iteration - of up, down, left, and right.
Question 212 |
If the mean of a poisson distribution is m, then standard deviation of the distribution is:
m2 | |
m | |
2*m | |
√m |
Question 212 Explanation:
Mean and Variance of the Poisson distribution.
There is also a formula for the standard deviation, σ, and variance, σ2.
Question 213 |
The standard deviation of binomial distribution with n observations and probability of success p, probability of failure is q is:
√npq
| |
Pq | |
Np | |
√pq |
Question 213 Explanation:
Mean and Variance of the Binomial Distribution:
The binomial distribution for a random variable X with parameters n and p represents the sum of n independent variables Z which may assume the values 0 or 1. If the probability that each Z variable assumes the value 1 is equal to p, then the mean of each variable is equal to l*p + 0*(l-p) = p, and the variance is equal to p(l-p).
By the addition properties for independent random variables, the mean and variance of the binomial distribution are equal to the sum of the means and variances of the n independent Z variables, so
These definitions are intuitively logical. Imagine, for example 8 flips of a coin. If the coin is fair, then p = 0.5. One would expect the mean number of heads to be half the flips, or np = 8*0.5 = 4.
The variance is equal to np(l-p) = 8*0.5*0.5 = 2.
The binomial distribution for a random variable X with parameters n and p represents the sum of n independent variables Z which may assume the values 0 or 1. If the probability that each Z variable assumes the value 1 is equal to p, then the mean of each variable is equal to l*p + 0*(l-p) = p, and the variance is equal to p(l-p).
By the addition properties for independent random variables, the mean and variance of the binomial distribution are equal to the sum of the means and variances of the n independent Z variables, so
These definitions are intuitively logical. Imagine, for example 8 flips of a coin. If the coin is fair, then p = 0.5. One would expect the mean number of heads to be half the flips, or np = 8*0.5 = 4.
The variance is equal to np(l-p) = 8*0.5*0.5 = 2.
Question 214 |
The normal curve is symmetrical about its:
Standard deviation | |
Mean
| |
Variance | |
Probability
|
Question 214 Explanation:
Symmetrical distribution occurs when the values of variables occur at regular frequencies and the mean, median and mode occur at the same point. In graph form, symmetrical distribution often appears as a bell curve. If a line were drawn dissecting the middle of the graph, it would show two sides that mirror each other.
The probability density of the normal distribution is
Where
• μ is the mean or expectation of the distribution (and also its median and mode).
• σ is the standard deviation, and
• 2 is the variance
The probability density of the normal distribution is
Where
• μ is the mean or expectation of the distribution (and also its median and mode).
• σ is the standard deviation, and
• 2 is the variance
Question 215 |
The density of uniform distribution over the interval -⍺ < a < b < ⍺ is given by:
f(x) = λe-λx , x>=0
| |
f(x) = qkp | |
f(x) = 1/(b-a), a | |
f(x) = (⍺/c)x⍺-1
|
Question 215 Explanation:
The probability density function of the continuous uniform distribution is:
The values of f(x) at the two boundaries a and b are usually unimportant because they do not alter the values of the integrals of f(X) dX over any interval, not of X f(X) dX or any higher moment. Sometimes they are chosen to be zero, and sometimes chosen to be 1/(b – a). The latter is appropriate in the context of estimation by the method of maximum likelihood. In the context of Fourier analysis, one may lake the value of f(a) to be 1|2(b – a), since then the inverse transform of may integral transform of this uniform function will yield back the function itself, rather than a function which equal ‘almost everywhere’, i.e except on a set of points with zero measure. Also, it is consistent with the sign function which has no such ambiguity.
In terms of mean and variance σ2, the probability density may be written as:
The values of f(x) at the two boundaries a and b are usually unimportant because they do not alter the values of the integrals of f(X) dX over any interval, not of X f(X) dX or any higher moment. Sometimes they are chosen to be zero, and sometimes chosen to be 1/(b – a). The latter is appropriate in the context of estimation by the method of maximum likelihood. In the context of Fourier analysis, one may lake the value of f(a) to be 1|2(b – a), since then the inverse transform of may integral transform of this uniform function will yield back the function itself, rather than a function which equal ‘almost everywhere’, i.e except on a set of points with zero measure. Also, it is consistent with the sign function which has no such ambiguity.
In terms of mean and variance σ2, the probability density may be written as:
Question 216 |
Exponential distribution is special case of ____ distribution.
Theta | |
Alpha | |
Beta | |
Gamma |
Question 216 Explanation:
The exponential distribution is not the same as the class of exponential families of distributions, which is a large class of probability distributions that includes the exponential distribution as one of its members, but also includes the normal distribution, binomial distribution, gamma distribution, Poisson, and many others.
Question 217 |
The algebraic sum of the deviations of all the variables from their mean i.e.,
is:
is:0 | |
1 | |
-1 | |
⍺ |
Question 217 Explanation:
The sum of the deviations from the mean is zero. This will always be the case as it is a property of the sample mean, i.e., the sum of the deviations below the mean will always equal the sum of the deviations above the mean. However, the goal is to capture the magnitude of these deviations in a summary measure.
Question 218 |
The mean, mode and median are connected by the empirical relationship:
Mean-mode = 2(mean-median)
| |
Mean-mode = 3(mean-median) | |
Mean-mode = (mean-mode)/2
| |
Mean-mode = (mean-mode)/3
|
Question 218 Explanation:
A distribution in which the values of mean, median and mode coincide (i.e. mean = median = mode) is known as a symmetrical distribution. Conversely, when values of mean, median and mode are not equal the distribution is known as asymmetrical or skewed distribution. In moderately skewed or asymmetrical distribution a very important relationship exists among these three measures of central tendency. In such distributions the distance between the mean and median is about one-third of the distance between the mean and mode, as will be clear from the diagrams 1 and 2. Karl Pearson expressed this relationship as:
Mode = mean - 3 [mean - median]
Mode = 3 median - 2 mean
and Median = mode + ⅔ [mean-mode]
Mode = mean - 3 [mean - median]
Mode = 3 median - 2 mean
and Median = mode + ⅔ [mean-mode]
Question 219 |
If a random variable takes a finite set of values it is called:
Continuous variate | |
Normal variate
| |
Discrete variate
| |
Exponential variate |
Question 219 Explanation:
→ A discrete variable is a variable whose value is obtained by counting.
Examples:
number of students present
number of red marbles in a jar
number of heads when flipping three coins
students’ grade level
→ A discrete random variable X has a countable number of possible values.
Example:
Let X represent the sum of two dice.
→ A discrete random variable is one which may take on only a countable number of distinct values such as 0,1,2,3,4,........ Discrete random variables are usually (but not necessarily) counts. If a random variable can take only a finite number of distinct values, then it must be discrete.
Examples of discrete random variables include the number of children in a family, the Friday night attendance at a cinema, the number of patients in a doctor's surgery, the number of defective light bulbs in a box of ten.
Examples:
number of students present
number of red marbles in a jar
number of heads when flipping three coins
students’ grade level
→ A discrete random variable X has a countable number of possible values.
Example:
Let X represent the sum of two dice.
→ A discrete random variable is one which may take on only a countable number of distinct values such as 0,1,2,3,4,........ Discrete random variables are usually (but not necessarily) counts. If a random variable can take only a finite number of distinct values, then it must be discrete.
Examples of discrete random variables include the number of children in a family, the Friday night attendance at a cinema, the number of patients in a doctor's surgery, the number of defective light bulbs in a box of ten.
Question 220 |
The root mean square deviation when measured from the mean is:
Greatest
| |
Positive
| |
Least
| |
Negative
|
Question 220 Explanation:
The root mean square deviation when measured from the mean is least value.
Question 221 |
The values which divide the frequency into four equal parts are called:
Coefficient of variance
| |
Range | |
Dispersion | |
Quartiles
|
Question 221 Explanation:
The values of a variable that divide a distribution into four equal parts are called quartiles. Since three values are needed to divide a distribution into four parts, there are three quartiles, viz. Q1, Q2 and Q3, known as the first, second and the third quartile respectively. For a discrete distribution, the first quartile (Q1) is defined as that value of the variate such that at least 25% of the observations are less than or equal to it and at least 75% of the observations are greater than or equal to it.
Question 222 |
How many 3 digit numbers are there with all different odd digits?
16 | |
48 | |
54 | |
60 |
Question 222 Explanation:
• Three digit odd numbers implies the numbers would only be made of digits 1 , 3 , 5 , 7 , 9 With repetition of digits we would have had 5 * 5 * 5 = 125
• But for every hundreds, maximum of 4 tens is possible (avoiding the duplicate of digit used in hundreds)
• And each of these 4 tens, maximum of 3 units is possible (avoiding the duplicate of digits used in tens)
• 5 * 4 * 3 = 60
• But for every hundreds, maximum of 4 tens is possible (avoiding the duplicate of digit used in hundreds)
• And each of these 4 tens, maximum of 3 units is possible (avoiding the duplicate of digits used in tens)
• 5 * 4 * 3 = 60
Question 223 |
In how many ways can a committee of 4 people be chosen from a group of 12?
495 | |
595
| |
395
| |
295
|
Question 223 Explanation:
As the order of people does not matter, it is C4 12
C(n,r) = C(12,4)
= 12! / [(4!(12−4)!)]
= 495
Hence, a committee of 4 people be selected from a group of 12 people in 495 ways.
C(n,r) = C(12,4)
= 12! / [(4!(12−4)!)]
= 495
Hence, a committee of 4 people be selected from a group of 12 people in 495 ways.
Question 224 |
A straight line which cuts a curve on two points at an infinite distance from the origin and yet is not itself wholly at infinity is called:
Spiral
| |
Asymptote
| |
Parallel
| |
Polar
|
Question 224 Explanation:
A straight line which cuts a curve in two points at an infinite distance from the origin, but which is not itself wholly at infinity, is called an asymptote to a curve.
Question 225 |
If k parallel lines of a determinant Δ become identical when x=a, then ____ is a factor of Δ.
(x-a)+(k+1)
| |
(x-a)/(k-1)
| |
(x-a)*(k+1)
| |
(x-a)(k-1)
|
Question 225 Explanation:
• If a determinant D vanishes for x = a, then (x - a) is a factor of D, in other words, if two rows (or two columns) become identical for x = a, then (x-a) is a factor of D.
• In general, if k rows (or k columns) become identical (x=a) when a is substituted for x, then (x-a)r-1 is a factor of D.
• In general, if k rows (or k columns) become identical (x=a) when a is substituted for x, then (x-a)r-1 is a factor of D.
Question 226 |
A minimal subgraph G’ of G such that V(G’)=V(G) and G’ is connected is called:
A spanning tree
| |
A connected graph
| |
A directed graph
| |
A biconnected component |
Question 226 Explanation:
Given a connected graph G, a connected subgraph that is both a tree and contains all the vertices of G is called a spanning tree for G.
Question 227 |
Rank of nonsingular square matrix of order r is:
r | |
0 | |
r-1 | |
1 |
Question 227 Explanation:
• A square matrix of order ’r’ is nonsingular if its determinant is non zero and therefore its rank is “r”. It's all rows and columns are linearly independent and it is invertible.
• Rank of singular matrix is less than “r”.
• Rank of singular matrix is less than “r”.
Question 228 |
The newton’s Raphson iterative formula for finding 1/N is:
½(xn + N/xn) | |
xn(1 - Nxn)
| |
½(xn+1/Nxn) | |
1/k((k-1)xn + N/xnk-1)
|
Question 228 Explanation:
• Newton's method is a method for finding successively better approximations to the roots (or zeroes) of a real-valued function. It is one example of a root-finding algorithm.
• The iterations xk+1 = xk − ( f(xk)/ f ′(xk) ) are called Newton’s iterations.
• The iterations xk+1 = xk − ( f(xk)/ f ′(xk) ) are called Newton’s iterations.
Question 229 |
Portability is not a quality factor of:
Software coding
| |
Software design
| |
Software Process | |
Software testing
|
Question 229 Explanation:
McCall’s Quality Factors:
This model classifies all software requirements into 11 software quality factors. The 11 factors are grouped into three categories – product operation, product revision, and product transition factors.
1. Product operation factors − Correctness, Reliability, Efficiency, Integrity, Usability.
2. Product revision factors − Maintainability, Flexibility, Testability.
3. Product transition factors − Portability, Reusability, Interoperability.
This model classifies all software requirements into 11 software quality factors. The 11 factors are grouped into three categories – product operation, product revision, and product transition factors.
1. Product operation factors − Correctness, Reliability, Efficiency, Integrity, Usability.
2. Product revision factors − Maintainability, Flexibility, Testability.
3. Product transition factors − Portability, Reusability, Interoperability.
Question 230 |
The number of strips required in simpson’s 3/8th rule is a multiple of:
1 | |
2 | |
3 | |
6 |
Question 230 Explanation:
Simpson’s 3/8th rule is also known as Simpson's 2nd rule:
Area = 3h/ 8 [( a + 3 b + 3 c + d )]
Simpson's Second Rule:
Multipliers:
Area = 3h/ 8 [( a + 3 b + 3 c + d )]
Simpson's Second Rule:
Multipliers:
Question 231 |
A declarative sentence which is either true(1) or false(0) is called:
Lattice
| |
Tautology
| |
Contradiction
| |
Proposition
|
Question 231 Explanation:
• Declarative sentences are propositions.
• Sentences that assert a fact that could either be true or false.
• Sentences that assert a fact that could either be true or false.
Question 232 |
The points at which the function attains extreme values are called:
Turning points | |
End points
| |
Higher points | |
Extreme points
|
Question 232 Explanation:
The value of the function, the value of y, at either a maximum or a minimum is called an extreme value. The points at which the function attains extreme values are called Turning points.
Question 233 |
If f(x) = ax2 + bx + c the f(x-(b/2a)) is:
An even function for all a except a=0
| |
An even function for all a
| |
Neither even nor odd
| |
An odd function for all a except a=0 |
Question 233 Explanation:
• A function f is even if the graph of f is symmetric with respect to the y-axis. Algebraically, f is even if and only if f(-x) = f(x) for all x in the domain of f.
• A function f is odd if the graph of f is symmetric with respect to the origin. Algebraically, f is odd if and only if f(-x) = -f(x) for all x in the domain of f.
• A function f is odd if the graph of f is symmetric with respect to the origin. Algebraically, f is odd if and only if f(-x) = -f(x) for all x in the domain of f.
Question 234 |
The sum of n terms of 1/(1*2) + 1/(2*3) + 1/(3*4) + ... is
(n+1)/n
| |
n/(n+1)
| |
n/(2n+1)
| |
(2n+1)/n
|
Question 234 Explanation:
Sum upto n terms = 1/(1*2) + 1/(2*3) + 1/(3*4) + ........ + 1/(n*(n+1))
where
1st term = 1/(1*2)
2nd term = 1/(2*3)
3rd term = 1/(3*4)
.
.
.
.
n-th term = 1/(n*(n+1))
n-th term = 1/(n*(n+1))
i.e. the k-th term is of the form 1/(k*(k+1))
which can further be written as k-th term = 1/k - 1/(k+1)
So, sum upto n terms can be calculated as:
(1/1 - 1/1+1) + (1/2 - 1/2+1) + (1/3 - 1/3+1) + ......... + (1/n-1 - /1n) + (1/n - 1/n+1)
= (1 - 1/2) + (1/2 - 1/3) + (1/3 - 1/4) + ......... + (1/n-1 - 1/n) + (1/n - 1/n+1)
= 1 - 1/n+1
= ((n+1) - 1)/n+1
= n/n+1
where
1st term = 1/(1*2)
2nd term = 1/(2*3)
3rd term = 1/(3*4)
.
.
.
.
n-th term = 1/(n*(n+1))
n-th term = 1/(n*(n+1))
i.e. the k-th term is of the form 1/(k*(k+1))
which can further be written as k-th term = 1/k - 1/(k+1)
So, sum upto n terms can be calculated as:
(1/1 - 1/1+1) + (1/2 - 1/2+1) + (1/3 - 1/3+1) + ......... + (1/n-1 - /1n) + (1/n - 1/n+1)
= (1 - 1/2) + (1/2 - 1/3) + (1/3 - 1/4) + ......... + (1/n-1 - 1/n) + (1/n - 1/n+1)
= 1 - 1/n+1
= ((n+1) - 1)/n+1
= n/n+1
Question 235 |
How many integers are between 1 and 200 which are divisible by any one of the integers 2,3 and 5(Hint: use set operation)?
125 | |
145 | |
146 | |
136 |
Question 235 Explanation:
A) numbers divisible by 2: 200/2 = 100
B) numbers divisible by 3: 200/3 = 66
C) numbers divisible by 5: 200/5 = 40
Counting twice:
AB) numbers divisible by 6: 200/6 = 33
AC) numbers divisible by 10: 200/10 = 20
BC) numbers divisible by 15: 200/15 = 13
Counting 3 times:
ABC) numbers divisible by 30: 200/30 = 6
Total of numbers = A + B + C - AB - AC - BC + ABC = 100 + 66 + 40 - 33 - 20 -13 + 6 = 146
B) numbers divisible by 3: 200/3 = 66
C) numbers divisible by 5: 200/5 = 40
Counting twice:
AB) numbers divisible by 6: 200/6 = 33
AC) numbers divisible by 10: 200/10 = 20
BC) numbers divisible by 15: 200/15 = 13
Counting 3 times:
ABC) numbers divisible by 30: 200/30 = 6
Total of numbers = A + B + C - AB - AC - BC + ABC = 100 + 66 + 40 - 33 - 20 -13 + 6 = 146
Question 236 |
In algebra of logic, the conjunction of two tautologies is:
Contradiction
| |
Tautology
| |
Negation | |
Disjunction
|
Question 236 Explanation:
Some properties are tautologies:
1. The negation of a contradiction is a tautology.
2. The disjunction of two contingencies can be a tautology.
3. The conjunction of two tautologies is a tautology.
1. The negation of a contradiction is a tautology.
2. The disjunction of two contingencies can be a tautology.
3. The conjunction of two tautologies is a tautology.
Question 237 |
The partial differential equation ∂2z/∂t2 = c2(∂2z/∂x2) represents:
Harmonic function | |
Laplace equation
| |
Wave equation
| |
Homogeneous
|
Question 237 Explanation:
Let us derive the d’Alembert’s formula in an alternate way.
Note that the wave equation can be factored as
Note that the wave equation can be factored as
Question 238 |
The number of two digit numbers divisible by the product of digits is:
8 | |
14 | |
13 | |
5 |
Question 238 Explanation:
11=1*1=1 which is a factor of 11
12=1*2=2 which is a factor of 12
15=1*5=5 which is a factor of 15
24=2*4=8 which is a factor of 24
36=3*6=12 which is a factor of 36
12=1*2=2 which is a factor of 12
15=1*5=5 which is a factor of 15
24=2*4=8 which is a factor of 24
36=3*6=12 which is a factor of 36
Question 239 |
If a relation < from A={1,2,3,4} to B={1,3,5} i.e., (a,b)∈R if a < b, then R-1 is:
{(1,3)(1,5)(2,3)(2,5)(3,5)(4,5)}
| |
{(3,1)(5,1)(3,2)(5,2)(5,3)(5,4)} | |
{(3,3)(3,5)(5,3)(5,5)}
| |
{(3,3)(3,4)(4,5)} |
Question 239 Explanation:
The relation R is {(1,3), (1,5),(2,3),(2,5),(3,5),(4,5) } where (a,b) ∈ R if a
The R-1 is { (3,1),(5,1),(3,2),(5,2),(5,3),(5,4) } where (a,b) ∈ R-1 if a>b.
Question 240 |
If a lattice (L,R) has a greatest and least element then it is said to be:
Sub Lattice | |
Complemented Lattice
| |
Bounded Lattice
| |
Distributive Lattice
|
Question 240 Explanation:
→ In a Lattice if Upper Bound and Lower exists then it is called Bounded Lattice.
→ A bounded lattice is an algebraic structure of the form (L, ∨, ∧, 0, 1) such that (L, ∨, ∧) is a lattice, 0 (the lattice's bottom) is the identity element for the join operation ∨, and 1 (the lattice top) is the identity element for the meet operation ∧.
→ Let 'L' be a lattice w.r.t R if there exists an element I∈L such that (aRI)∀x∈L, then I is called Upper Bound of a Lattice L.
Similarly, if there exists an element O∈L such that (ORa)∀a∈L, then O is called Lower Bound of Lattice L.
→ A bounded lattice is an algebraic structure of the form (L, ∨, ∧, 0, 1) such that (L, ∨, ∧) is a lattice, 0 (the lattice's bottom) is the identity element for the join operation ∨, and 1 (the lattice top) is the identity element for the meet operation ∧.
→ Let 'L' be a lattice w.r.t R if there exists an element I∈L such that (aRI)∀x∈L, then I is called Upper Bound of a Lattice L.
Similarly, if there exists an element O∈L such that (ORa)∀a∈L, then O is called Lower Bound of Lattice L.
Question 241 |
The sum of the series: (1/2) + (1/3) + (1/4) - (1/6) + (1/8) + (1/9) + (1/16) - (1/12) + ... + α is:
(1/2) - log(√2)3
| |
1 + log(√2)3
| |
3/2 | |
1/2 + log(√2)3
|
Question 241 Explanation:
The sum of the series: (1/2) + (1/3) + (1/4) - (1/6) + (1/8) + (1/9) + (1/16) - (1/12) + ... + α is 1 + log(√2)3.
Question 242 |
Find the boolean product A⊙B of the two matrices.
 | |
 | |
 | |
 |
Question 242 Explanation:
In this problem, they given boolean product A⊙B of two matrices.
The boolean product truth table is
According to the truth table, we have to perform matrix multiplication.
The boolean product truth table is
According to the truth table, we have to perform matrix multiplication.
Question 243 |
How many distinguishable permutations of the letters in the word BANANA are there ?
720 | |
120 | |
60 | |
360 |
Question 243 Explanation:
Total distinguishable permutations means no repetition.
BANANA= 6 letters
B is appearing 1 time
A is appearing 3 times
N is appearing 2 times
So, = 6! / (3! * 2!)
= 60
BANANA= 6 letters
B is appearing 1 time
A is appearing 3 times
N is appearing 2 times
So, = 6! / (3! * 2!)
= 60
Question 244 |
Let P and Q be two propositions, ¬ (P ↔ Q) is equivalent to:
(I) P ↔ ¬ Q
(II) ¬ P ↔ Q
(III) ¬ P ↔ ¬ Q
(IV) Q → P
(I) P ↔ ¬ Q
(II) ¬ P ↔ Q
(III) ¬ P ↔ ¬ Q
(IV) Q → P
Only (I) and (II) | |
Only (II) and (III) | |
Only (III) and (IV) | |
None of the above |
Question 244 Explanation:
So, (I) and (Ii) are TRUE.
Question 245 |
Negation of the proposition ∃x H(x) is:
∃x ⌐H(x) | |
∀x ⌐H(x) | |
∀x H(x) | |
⌐x H(x) |
Question 245 Explanation:
∃x H(x) = ∀x ⌐H(x)
Question 246 |
Consider a sequence F 00 defined as : F 00 (0) = 1, F 00 (1) = 1
F 00 (n) = ((10 ∗ F 00 (n – 1) + 100)/ F 00 (n – 2)) for n ≥ 2 Then what shall be the set of values of the sequence F 00 ?
F 00 (n) = ((10 ∗ F 00 (n – 1) + 100)/ F 00 (n – 2)) for n ≥ 2 Then what shall be the set of values of the sequence F 00 ?
(1, 110, 1200) | |
(1, 110, 600, 1200) | |
(1, 2, 55, 110, 600, 1200) | |
(1, 55, 110, 600, 1200) |
Question 246 Explanation:
Given data,
Sequence F 00 defined as
F 00 (0) = 1,
F 00 (1) = 1,
F 00 (n) = ((10 ∗ F 00 (n – 1) + 100)/ F 00 (n – 2)) for n ≥ 2
Let n=2
F 00 (2) = (10 * F 00 (1) + 100) / F 00 (2 – 2)
= (10 * 1 + 100) / 1
= (10 + 100) / 1
= 110
Let n=3
F 00 (3) = (10 * F 00 (2) + 100) / F 00 (3 – 2)
= (10 * 110 + 100) / 1
= (1100 + 100) / 1
= 1200
Similarly, n=4
F 00 (4) = (10 * F 00 (3) + 100) / F 00 (4 – 2)
= (12100) / 110
= 110
F 00 (5) = (10 * F 00 (4) + 100) / F 00 (5 – 2)
= (10*110 + 100) / 1200
= 1
The sequence will be (1, 110, 1200,110, 1).
Sequence F 00 defined as
F 00 (0) = 1,
F 00 (1) = 1,
F 00 (n) = ((10 ∗ F 00 (n – 1) + 100)/ F 00 (n – 2)) for n ≥ 2
Let n=2
F 00 (2) = (10 * F 00 (1) + 100) / F 00 (2 – 2)
= (10 * 1 + 100) / 1
= (10 + 100) / 1
= 110
Let n=3
F 00 (3) = (10 * F 00 (2) + 100) / F 00 (3 – 2)
= (10 * 110 + 100) / 1
= (1100 + 100) / 1
= 1200
Similarly, n=4
F 00 (4) = (10 * F 00 (3) + 100) / F 00 (4 – 2)
= (12100) / 110
= 110
F 00 (5) = (10 * F 00 (4) + 100) / F 00 (5 – 2)
= (10*110 + 100) / 1200
= 1
The sequence will be (1, 110, 1200,110, 1).
Question 247 |
The functions mapping R into R are defined as : f(x) = x 3 – 4x, g(x) = 1/(x 2 + 1) and h(x) =
x 4 . Then find the value of the following composite functions : hog(x) and hogof(x)
(x 2 + 1)4 and [(x 3 – 4x) 2 + 1] 4 | |
(x 2 + 1)4 and [(x 3 – 4x) 2 + 1] -4 | |
(x 2 + 1)-4 and [(x 3 – 4x) 2 + 1] 4 | |
(x 2 + 1)-4 and [(x 3 – 4x) 2 + 1] -4 |
Question 247 Explanation:
Step-1: Given data,
f(x) = x 3 – 4x, g(x) = 1/(x 2 + 1) and h(x) = x 4
hog(x)=h(1/(x 2 + 1))
=h(1/(x 2 )+1) 4
= 1/(x 2 +1) 4
= (x 2 +1) -4
hogof(x)= hog(x 3 -4x)
= h(1/(x 3 -4x) 2 +1)
= h(1/(x 3 -4x) 2 +1) 4
= h((x 3 -4x) 2 +1) -4
So, option D id is correct answer.
f(x) = x 3 – 4x, g(x) = 1/(x 2 + 1) and h(x) = x 4
hog(x)=h(1/(x 2 + 1))
=h(1/(x 2 )+1) 4
= 1/(x 2 +1) 4
= (x 2 +1) -4
hogof(x)= hog(x 3 -4x)
= h(1/(x 3 -4x) 2 +1)
= h(1/(x 3 -4x) 2 +1) 4
= h((x 3 -4x) 2 +1) -4
So, option D id is correct answer.
Question 248 |
How many multiples of 6 are there between the following pairs of numbers ?
0 and 100 and –6 and 34
0 and 100 and –6 and 34
16 and 6 | |
17 and 6 | |
17 and 7 | |
16 and 7 |
Question 248 Explanation:
Method-1:
0 and 100 → Counting sequentially:
0,6,12,18,24,30,36,42,48,54,60,66,72,78,84,90,96 Total=17
–6 and 34 → Counting sequentially: -6,0,6,12,18,24,30
Total=7
Method-2: 0 and 100 → Maximum number is 100. Divide ⌊100/6⌋ = 16+1 =17
Here, +1 because of 0.
–6 and 34 → Maximum number is 34. Divide ⌊34/6⌋ = 5+1+1 =7
Here, +1 because of 0 and +1 for -6
0 and 100 → Counting sequentially:
0,6,12,18,24,30,36,42,48,54,60,66,72,78,84,90,96 Total=17
–6 and 34 → Counting sequentially: -6,0,6,12,18,24,30
Total=7
Method-2: 0 and 100 → Maximum number is 100. Divide ⌊100/6⌋ = 16+1 =17
Here, +1 because of 0.
–6 and 34 → Maximum number is 34. Divide ⌊34/6⌋ = 5+1+1 =7
Here, +1 because of 0 and +1 for -6
Question 249 |
Consider a Hamiltonian Graph G with no loops or parallel edges and with |V(G)| = n ≥ 3. Then which of the following is true ?
deg(v) ≥n/2 for each vertex v. | |
|E(G)| ≥1/2(n – 1) (n – 2) + 2 | |
deg (v) + deg(w) ≥ n whenever v and w are not connected by an edge | |
All of the above |
Question 249 Explanation:
With the help of dirac’s theorem, we can prove above three statements.
Question 250 |
In propositional logic if (P → Q) ∧ (R → S) and (P ∨ R) are two premises such that
P ∨ R | |
P ∨ S | |
Q ∨ R | |
Q ∨ S | |
None of These |
Question 250 Explanation:
Option-A: Let P be TRUE and R be false, then the conclusion PVR will be TRUE. Now if we make Q as false then premises (P→Q)∧(R→ S)will be false because P→ Q is false. Hence this option is not correct.
Option-B: Let P be TRUE and S be false then the conclusion PVS is TRUE. Now, if we make R as TRUE then the premises (P→ Q)∧(R→ S) will be false because (R→ S) will be false. Hence this option is not correct.
Option-C: Let Q be false, R be TRUE then conclusion QVR will be TRUE. Now if we make S as FALSE then Premises (P→ Q)∧(R→ S) will be FALSE because (R→ S) will be false. Hence, this option is not correct.
Option-D: Let Q be TRUE and S be FALSE then conclusion QVS will be TRUE. Now if we make R as TRUE then premises (P→ Q)∧(R→ S) will be FALSE because (R→ S) will be false.
Therefore None of the given options are correct.
Note: As per UGC NET key, given option D as correct answer.
Option-B: Let P be TRUE and S be false then the conclusion PVS is TRUE. Now, if we make R as TRUE then the premises (P→ Q)∧(R→ S) will be false because (R→ S) will be false. Hence this option is not correct.
Option-C: Let Q be false, R be TRUE then conclusion QVR will be TRUE. Now if we make S as FALSE then Premises (P→ Q)∧(R→ S) will be FALSE because (R→ S) will be false. Hence, this option is not correct.
Option-D: Let Q be TRUE and S be FALSE then conclusion QVS will be TRUE. Now if we make R as TRUE then premises (P→ Q)∧(R→ S) will be FALSE because (R→ S) will be false.
Therefore None of the given options are correct.
Note: As per UGC NET key, given option D as correct answer.
Question 251 |
Let A and B be sets in a finite universal set U. Given the following:
|A – B|, |A ⊕ B|, |A| + |B| and |A ∪ B|
Which of the following is in order of increasing size ?
|A – B| ≤ |A ⊕ B| ≤ |A| + |B| ≤ |A ∪ B| | |
|A ⊕ B| ≤ |A – B| ≤ |A ∪ B| ≤ |A| + |B| | |
|A ⊕ B| ≤ |A| + |B| ≤ |A – B| ≤ |A ∪ B| | |
|A – B| ≤ |A ⊕ B| ≤ |A ∪ B| ≤ |A| + |B| |
Question 251 Explanation:
Step-1: Let A and B be sets in a finite universal set U.
Step-2: |A–B| we can also write into |A|-|A ∩ B| and equivalent Venn diagram is
Step-3: |A⊕B| We can also write into |A|+|B|- 2|A∩B| and equivalent Venn diagram is
Step-4: |A| + |B| We can represented into |A| + |B| and equivalent Venn diagram is
Step-5: |A∪B| We can also write into |A|+|B|- |A∩B| and equivalent Venn diagram is
Step-6: |A – B| ≤ |A ⊕ B| ≤ |A ∪ B| ≤ |A| + |B| is correct order.
Step-2: |A–B| we can also write into |A|-|A ∩ B| and equivalent Venn diagram is
Step-3: |A⊕B| We can also write into |A|+|B|- 2|A∩B| and equivalent Venn diagram is
Step-4: |A| + |B| We can represented into |A| + |B| and equivalent Venn diagram is
Step-5: |A∪B| We can also write into |A|+|B|- |A∩B| and equivalent Venn diagram is
Step-6: |A – B| ≤ |A ⊕ B| ≤ |A ∪ B| ≤ |A| + |B| is correct order.
Question 252 |
What is the probability that a randomly selected bit string of length 10 is a palindrome?
1/64 | |
1/32 | |
1/8 | |
1⁄4 |
Question 252 Explanation:
Palindrome is a number that remains the same when its digits are reversed.
Ex: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 22, 33, 44, 55, 66, 77, 88, 99, 101, 111, 121...,
Step-1: Here, string length is 10. If we consider first 5 numbers as random choices like 0 or 1.
Remaining 5 numbers are fixed. Total number of possibilities are 2 10 . But we are only considering first 5 choices. The probability is 2 5 .
Step-2: The probability 2 5 /2 10
= 1/2 5
= 1/32
Ex: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11, 22, 33, 44, 55, 66, 77, 88, 99, 101, 111, 121...,
Step-1: Here, string length is 10. If we consider first 5 numbers as random choices like 0 or 1.
Remaining 5 numbers are fixed. Total number of possibilities are 2 10 . But we are only considering first 5 choices. The probability is 2 5 .
Step-2: The probability 2 5 /2 10
= 1/2 5
= 1/32
Question 253 |
Given the following graphs:
Which of the following is correct?
Which of the following is correct?
G 1 contains Euler circuit and G 2 does not contain Euler circuit. | |
G 1 does not contain Euler circuit and G 2 contains Euler circuit. | |
Both G 1 and G 2 do not contain Euler circuit. | |
Both G 1 and G 2 contain Euler circuit. |
Question 253 Explanation:
Step-1: G1 have odd number of vertices. So, it is not euler circuit.
Step-2: G2 also have odd number of vertices. So, it not euler circuit.
Question 254 |
How many different equivalence relations with exactly three different equivalence classes are there on a set with five elements?
10 | |
15 | |
25 | |
30 |
Question 254 Explanation:
Step-1: Given number of equivalence classes with 5 elements with three elements in each class will be 1,2,2 (or) 2,1,2 (or) 2,2,1 and 3,1,1.
Step-2: The number of combinations for three equivalence classes are
2,2,1 chosen in ( 5 C 2 * 3 C 2 * 1 C 1 )/2! = 15
3,1,1 chosen in( 5 C 2 * 3 C 2 * 1 C 1 )/2! = 10
Step-3: Total differential classes are 15+10
=25.
Step-2: The number of combinations for three equivalence classes are
2,2,1 chosen in ( 5 C 2 * 3 C 2 * 1 C 1 )/2! = 15
3,1,1 chosen in( 5 C 2 * 3 C 2 * 1 C 1 )/2! = 10
Step-3: Total differential classes are 15+10
=25.
Question 255 |
The number of different spanning trees in complete graph, K 4 and bipartite graph, K 2,2 have ______ and _______ respectively.
14, 14 | |
16, 14 | |
16, 4 | |
14, 4 |
Question 255 Explanation:
Step-1: Given complete graph K 4 .To find total number of spanning tree in complete graph using standard formula is n (n-2)
Here, n=4
=n (n-2)
= 4 2
=16
Step-2: Given Bipartite graph K 2,2 . To find number of spanning tree in a bipartite graph K m,n having standard formula is m (n-1) * n (m-1) .
m=2 and n=2
= 2 (2-1) * 2 (2-1)
= 2 * 2
= 4
=n (n-2)
= 4 2
=16
Step-2: Given Bipartite graph K 2,2 . To find number of spanning tree in a bipartite graph K m,n having standard formula is m (n-1) * n (m-1) .
m=2 and n=2
= 2 (2-1) * 2 (2-1)
= 2 * 2
= 4
Question 256 |
Suppose that R 1 and R 2 are reflexive relations on a set A.
Which of the following statements is correct ?
R 1 ∩ R 2 is reflexive and R 1 ∪ R 2 is irreflexive. | |
R 1 ∩ R 2 is irreflexive and R 1 ∪ R 2 is reflexive. | |
Both R 1 ∩ R 2 and R 1 ∪ R 2 are reflexive. | |
Both R 1 ∩ R 2 and R 1 ∪ R 2 are irreflexive. |
Question 256 Explanation:
A binary relation R over a set X is reflexive if every element of X is related to itself. Formally, this may be written ∀ x ∈X : xRx.
Ex: Let set A={0,1}
R 1 ={(0,0),(1,1)} all diagonal elements we are considering for reflexive relation.
R 2 ={(0,0),(1,1)} all diagonal elements we are considering for reflexive relation.
R 1 ∩ R 2 must have {(0,0),(1,1)} is reflexive.
R 1 ∪ R 2 must have {(0,0),(1,1)} is reflexive.
Ex: Let set A={0,1}
R 1 ={(0,0),(1,1)} all diagonal elements we are considering for reflexive relation.
R 2 ={(0,0),(1,1)} all diagonal elements we are considering for reflexive relation.
R 1 ∩ R 2 must have {(0,0),(1,1)} is reflexive.
R 1 ∪ R 2 must have {(0,0),(1,1)} is reflexive.
Question 257 |
There are three cards in a box. Both sides of one card are black, both sides of one card are red, and the third card has one black side and one red side. We pick a card at random and observe only one side.
What is the probability that the opposite side is the same colour as the one side we observed?
3/4 | |
2/3 | |
1/2 | |
1⁄3 |
Question 257 Explanation:
Given data,
-- 3 cards in a box
-- 1 st card: Both sides of one card is black. The card having 2 sides. We can write it as BB.
-- 2 nd card: Both sides of one card is red. The card having 2 sides. We can write it as RR.
-- 3rd card: one black side and one red side. We can write it as BR.
Step-1: The probability that the opposite side is the same colour as the one side we observed is 2⁄3 because total number of cards are 3
-- 3 cards in a box
-- 1 st card: Both sides of one card is black. The card having 2 sides. We can write it as BB.
-- 2 nd card: Both sides of one card is red. The card having 2 sides. We can write it as RR.
-- 3rd card: one black side and one red side. We can write it as BR.
Step-1: The probability that the opposite side is the same colour as the one side we observed is 2⁄3 because total number of cards are 3
Question 258 |
A clique in a simple undirected graph is a complete subgraph that is not contained in any larger complete subgraph. How many cliques are there in the graph shown below?
2 | |
4 | |
5 | |
6 |
Question 258 Explanation:
Definition of clique is already given in question.
Definition: A clique in a simple undirected graph is a complete subgraph that is not contained in any larger complete subgraph.
Step-1: b,c,e,f is complete graph.
Step-2: ‘a’ is not connected to ‘e’ and ‘b’ is not connected to ‘d’. So, it is not complete graph.
Definition: A clique in a simple undirected graph is a complete subgraph that is not contained in any larger complete subgraph.
Step-1: b,c,e,f is complete graph.
Step-2: ‘a’ is not connected to ‘e’ and ‘b’ is not connected to ‘d’. So, it is not complete graph.
Question 259 |
Which of the following statement(s) is/are false ?
(a) A connected multigraph has an Euler Circuit if and only if each of its vertices has even degree.
(b) A connected multigraph has an Euler Path but not an Euler Circuit if and only if it has exactly two vertices of odd degree.
(c) A complete graph (K n ) has a Hamilton Circuit whenever n ≥ 3.
(d) A cycle over six vertices (C 6 ) is not a bipartite graph but a complete graph over 3 vertices is bipartite.
(a) A connected multigraph has an Euler Circuit if and only if each of its vertices has even degree.
(b) A connected multigraph has an Euler Path but not an Euler Circuit if and only if it has exactly two vertices of odd degree.
(c) A complete graph (K n ) has a Hamilton Circuit whenever n ≥ 3.
(d) A cycle over six vertices (C 6 ) is not a bipartite graph but a complete graph over 3 vertices is bipartite.
(a) only | |
(b) and (c) | |
(c) only | |
(d) only |
Question 259 Explanation:
(a)TRUE: A connected multigraph has an Euler Circuit if and only if each of its vertices has even degree.
(b)TRUE: A connected multigraph has an Euler Path but not an Euler Circuit if and only if it has exactly two vertices of odd degree.
(c)TRUE: A complete graph (K n ) has a Hamilton Circuit whenever n ≥ 3. (d) FALSE: A cycle over six vertices (C 6 ) is not a bipartite graph but a complete graph over 3 vertices is bipartite.
(b)TRUE: A connected multigraph has an Euler Path but not an Euler Circuit if and only if it has exactly two vertices of odd degree.
(c)TRUE: A complete graph (K n ) has a Hamilton Circuit whenever n ≥ 3. (d) FALSE: A cycle over six vertices (C 6 ) is not a bipartite graph but a complete graph over 3 vertices is bipartite.
Question 260 |
Which of the following is/are not true?
(a) The set of negative integers is countable.
(b) The set of integers that are multiples of 7 is countable.
(c)The set of even integers is countable.
(d)The set of real numbers between 0 and 1⁄2 is countable.
(a) The set of negative integers is countable.
(b) The set of integers that are multiples of 7 is countable.
(c)The set of even integers is countable.
(d)The set of real numbers between 0 and 1⁄2 is countable.
(a) and (c) | |
(b) and (d) | |
(b) only | |
(d) only |
Question 260 Explanation:
(a)TRUE: The set of negative integers is countable.
Suppose negative integers set size is 10.
Ex: -1, -2, -3,.....,-10 is countable
(b)TRUE: The set of integers that are multiples of 7 is countable.
Suppose set of integers size is 10.
Ex: 1*7, 2*7, 3*7, .....,10*7 is countable
(c)TRUE: The set of even integers is countable.
Suppose set of even integers size is 10.
Ex: 2,4,6,8,10,....,20
(d) FALSE: The set of real numbers between 0 and 1⁄2 is countable. We can’t count real numbers.
Ex: 0.1, 0.2, 0.3, .....,0.∞
Suppose negative integers set size is 10.
Ex: -1, -2, -3,.....,-10 is countable
(b)TRUE: The set of integers that are multiples of 7 is countable.
Suppose set of integers size is 10.
Ex: 1*7, 2*7, 3*7, .....,10*7 is countable
(c)TRUE: The set of even integers is countable.
Suppose set of even integers size is 10.
Ex: 2,4,6,8,10,....,20
(d) FALSE: The set of real numbers between 0 and 1⁄2 is countable. We can’t count real numbers.
Ex: 0.1, 0.2, 0.3, .....,0.∞
Question 261 |
Consider the graph given below: The two distinct sets of vertices, which make the graph bipartite are:
(v 1 , v 4 , v 6 ); (v 2 , v 3 , v 5 , v 7 , v 8 ) | |
(v 1 , v 7 , v 8 ); (v 2 , v 3 , v 5 , v 6 ) | |
(v 1 , v 4 , v 6 , v 7 ); (v 2 , v 3 , v 5 , v 8 ) | |
(v 1 , v 4 , v 6 , v 7 , v 8 ); (v 2 , v 3 , v 5 ) |
Question 261 Explanation:
A bipartite graph (or bigraph) is a graph whose vertices can be divided into two disjoint and independent sets U and V such that every edge connects a vertex in U to one in V. Vertex sets U and V are usually called the parts of the graph. Equivalently, a bipartite graph is a graph that does not contain any odd-length cycles.
→ The two sets U and V may be thought of as a coloring of the graph with two colors.
Option A: FALSE because V 5 , V 7 and V 3 are adjacent. So, it not not bipartite graph.
Option-B FALSE because V 5 , V 6 and V 2 are adjacent. So, it not not bipartite graph.
Option-C TRUE because it follows properties of bipartied and no two colours are adjacent.
Option-D FALSE because because V 4 , V 6 and V 8 are adjacent. So, it not not bipartite graph.
→ The two sets U and V may be thought of as a coloring of the graph with two colors.
Option A: FALSE because V 5 , V 7 and V 3 are adjacent. So, it not not bipartite graph.
Option-B FALSE because V 5 , V 6 and V 2 are adjacent. So, it not not bipartite graph.
Option-C TRUE because it follows properties of bipartied and no two colours are adjacent.
Option-D FALSE because because V 4 , V 6 and V 8 are adjacent. So, it not not bipartite graph.
Question 262 |
A tree with n vertices is called graceful, if its vertices can be labelled with integers 1, 2,....n such that the absolute value of the difference of the labels of adjacent vertices are all different. Which of the following trees are graceful?
(a)
(b)
(c)
(a)
(b)
(c)
(a) and (b) | |
(b) and (c) | |
(a) and (c) | |
(a), (b) and (c) |
Question 262 Explanation:
Above all graphs are graceful.
Question 263 |
Which of the following arguments are not valid ?
(a) “If Gora gets the job and works hard, then he will be promoted. If Gora gets promotion, then he will be happy. He will not be happy, therefore, either he will not get the job or he will not work hard”.
(b) “Either Puneet is not guilty or Pankaj is telling the truth. Pankaj is not telling the truth, therefore, Puneet is not guilty”.
(c) If n is a real number such that n >1, then n 2 >1. Suppose that n 2 >1, then n >1.
(a) “If Gora gets the job and works hard, then he will be promoted. If Gora gets promotion, then he will be happy. He will not be happy, therefore, either he will not get the job or he will not work hard”.
(b) “Either Puneet is not guilty or Pankaj is telling the truth. Pankaj is not telling the truth, therefore, Puneet is not guilty”.
(c) If n is a real number such that n >1, then n 2 >1. Suppose that n 2 >1, then n >1.
(a) and (c) | |
(b) and (c) | |
(a), (b) and (c) | |
(a) and (b) |
Question 264 |
Match the following terms:
(i)(ii)(iii)(iv) | |
(ii)(iii)(i)(iv) | |
(iii)(ii)(iv)(i) | |
(iv)(iii)(ii)(i) |
Question 264 Explanation:
→ Vacuous proof is a proof that the implication p → q is true based on the fact that p is false.
→ Trivial proof is a proof that the implication p → q is true based on the fact that q is true.
→ Direct proof is a proof that the implication p → q is true that proceeds by showing that q must be true when p is true.
→ Indirect proof is a proof that the implication p → q is true that proceeds by showing that p must be false when q is false.
→ Trivial proof is a proof that the implication p → q is true based on the fact that q is true.
→ Direct proof is a proof that the implication p → q is true that proceeds by showing that q must be true when p is true.
→ Indirect proof is a proof that the implication p → q is true that proceeds by showing that p must be false when q is false.
Question 265 |
Consider the compound propositions given below as:
(a)p ∨ ~(p ∧ q)
(b)(p ∧ ~q) ∨ ~(p ∧ q)
(c)p ∧ (q ∨ r)
Which of the above propositions are tautologies?
(a)p ∨ ~(p ∧ q)
(b)(p ∧ ~q) ∨ ~(p ∧ q)
(c)p ∧ (q ∨ r)
Which of the above propositions are tautologies?
(a) and (c) | |
(b) and (c) | |
(a) and (b) | |
only (a) |
Question 265 Explanation:
Question 266 |
Which of the following property/ies a Group G must hold, in order to be an Abelian group?
(a)The distributive property
(b)The commutative property
(c)The symmetric property
(a)The distributive property
(b)The commutative property
(c)The symmetric property
(a) and (b) | |
(b) and (c) | |
(a) only | |
(b) only |
Question 266 Explanation:
An abelian group is a set, A, together with an operation • that combines any two elements a and b to form another element denoted a • b. The symbol • is a general placeholder for a
concretely given operation. To qualify as an abelian group, the set and operation, (A, •), must satisfy five requirements known as the abelian group axioms:
Closure: For all a, b in A, the result of the operation a • b is also in A.
Associativity: For all a, b and c in A, the equation (a • b) • c = a • (b • c) holds.
Identity element: There exists an element e in A, such that for all elements a in A, the equation e • a = a • e = a holds.
Inverse element: For each a in A, there exists an element b in A such that a • b = b • a = e, where e is the identity element.
Commutativity: For all a, b in A, a • b = b • a.
A group in which the group operation is not commutative is called a "non-abelian group" or "non-commutative group".
Closure: For all a, b in A, the result of the operation a • b is also in A.
Associativity: For all a, b and c in A, the equation (a • b) • c = a • (b • c) holds.
Identity element: There exists an element e in A, such that for all elements a in A, the equation e • a = a • e = a holds.
Inverse element: For each a in A, there exists an element b in A such that a • b = b • a = e, where e is the identity element.
Commutativity: For all a, b in A, a • b = b • a.
A group in which the group operation is not commutative is called a "non-abelian group" or "non-commutative group".
Question 267 |
How many solutions are there for the equation x + y + z + u = 29 subject to the constraints that x ≥ 1, y ≥ 2, z ≥ 3 and u ≥ 0?
4960 | |
2600 | |
23751 | |
8855 |
Question 267 Explanation:
Given data,
-- The equation x+y+z+u = 29
-- Constraints are x ≥ 1, y ≥ 2, z ≥ 3 and u ≥ 0
-- Possible solutions?
Step-1: Combine all constraints (1+2+3+0) =6
Step-2: Subtract all constraints values with total equation number 29-6 =23.
Possibility to get repetition of a numbers of x,y and z but no chance for ‘u’ because its value is 0.
Step-3: So, Subtract repeated values into total equation value
= 29-3
= 26
Step-4: Possible solutions= 26 C 23
= 2600
-- The equation x+y+z+u = 29
-- Constraints are x ≥ 1, y ≥ 2, z ≥ 3 and u ≥ 0
-- Possible solutions?
Step-1: Combine all constraints (1+2+3+0) =6
Step-2: Subtract all constraints values with total equation number 29-6 =23.
Possibility to get repetition of a numbers of x,y and z but no chance for ‘u’ because its value is 0.
Step-3: So, Subtract repeated values into total equation value
= 29-3
= 26
Step-4: Possible solutions= 26 C 23
= 2600
Question 268 |
How many strings of 5 digits have the property that the sum of their digits is 7?
66 | |
330 | |
495 | |
99 |
Question 268 Explanation:
→ From the given question, there should be string with 5 digits and sum of that digits should be 7
→ There is no specification about positive,negative digits and also repetition of digits.
→ We are assuming the positive digits which is greater than or equal to 0.
→ The starting digit of the string should not be zero. We will also consider the repetition of digits.
→ Example of such strings are 70000,61000,60100,60010..,
→ The possible number of strings are C((n+r-1),(r-1))
→ From the given data n=7,r=5 then We have to fine C(11,4) which is equal to 330
→ There is no specification about positive,negative digits and also repetition of digits.
→ We are assuming the positive digits which is greater than or equal to 0.
→ The starting digit of the string should not be zero. We will also consider the repetition of digits.
→ Example of such strings are 70000,61000,60100,60010..,
→ The possible number of strings are C((n+r-1),(r-1))
→ From the given data n=7,r=5 then We have to fine C(11,4) which is equal to 330
Question 269 |
Consider an experiment of tossing two fair dice, one black and one red. What is the probability that the number on the black die divides the number on red die?
22 / 36 | |
12 / 36 | |
14 / 36 | |
6 / 36 |
Question 269 Explanation:
→ From the given data, there are two dice and each dice the possible ways are 6. So total possible ways are 6*6=36 ways.
→ The possible ways are 1,2,3,4,5,6
→ The possible ways of one number divides another number are (1,1) (1,2), (1,3), (1,4), (1,5), (1,6), (2,2), (2,4), (2,6), (3,3), (3,6), (4,4), (5,5) and (6,6).
→ The probability is the number of outcomes / total outcomes = 14/36
→ The possible ways are 1,2,3,4,5,6
→ The possible ways of one number divides another number are (1,1) (1,2), (1,3), (1,4), (1,5), (1,6), (2,2), (2,4), (2,6), (3,3), (3,6), (4,4), (5,5) and (6,6).
→ The probability is the number of outcomes / total outcomes = 14/36
Question 270 |
In how many ways can 15 indistinguishable fish be placed into 5 different ponds, so that each pond contains at least one fish ?
1001 | |
3876 | |
775 | |
200 |
Question 270 Explanation:
→ We know that if we have “n” identical items which will be distributed in “r” distinct groups where each must get at least one then the number of way is C(n−1,r−1)
→ From the given question, n=15, r=5 We need to calculate C(14,4) and it’s value is 1001.
→ From the given question, n=15, r=5 We need to calculate C(14,4) and it’s value is 1001.
Question 271 |
Consider a Hamiltonian Graph (G) with no loops and parallel edges. Which of the following is true with respect to this Graph (G) ?
(a) deg (v) ≥ n / 2 for each vertex of G
(b) |E(G)| ≥ 1 / 2 (n - 1) (n - 2) + 2 edges
(c) deg (v) + deg (w) ≥ n for every n and v not connected by an edge.
(a) deg (v) ≥ n / 2 for each vertex of G
(b) |E(G)| ≥ 1 / 2 (n - 1) (n - 2) + 2 edges
(c) deg (v) + deg (w) ≥ n for every n and v not connected by an edge.
(a) and (b) | |
(b) and (c) | |
(a) and (c) | |
(a), (b) and (c) |
Question 271 Explanation:
→ According to Dirac's theorem on Hamiltonian cycles, the statement that an n-vertex graph in which each vertex has degree at least n/2 must have a Hamiltonian cycle.
→ According to ore’s theorem,Let G be a (finite and simple) graph with n ≥ 3 vertices. We denote by deg v the degree of a vertex v in G, i.e. the number of incident edges in G to v. Then, Ore's theorem states that if deg v + deg w ≥ n for every pair of distinct non adjacent vertices v and w of G, then G is Hamiltonian.
→ A complete graph G of n vertices has n(n−1)/2 edges and a Hamiltonian cycle in G contains n edges. Therefore the number of edge-disjoint Hamiltonian cycles in G cannot exceed (n − 1)/2. When n is odd, we show there are (n − 1)/2 edge-disjoint Hamiltonian cycles.
So the statement(b) is false and statement a and c are true.
→ According to ore’s theorem,Let G be a (finite and simple) graph with n ≥ 3 vertices. We denote by deg v the degree of a vertex v in G, i.e. the number of incident edges in G to v. Then, Ore's theorem states that if deg v + deg w ≥ n for every pair of distinct non adjacent vertices v and w of G, then G is Hamiltonian.
→ A complete graph G of n vertices has n(n−1)/2 edges and a Hamiltonian cycle in G contains n edges. Therefore the number of edge-disjoint Hamiltonian cycles in G cannot exceed (n − 1)/2. When n is odd, we show there are (n − 1)/2 edge-disjoint Hamiltonian cycles.
So the statement(b) is false and statement a and c are true.
Question 272 |
“If my computations are correct and I pay the electric bill, then I will run out of money. If I don’t pay the electric bill, the power will be turned off. Therefore, if I don’t run out of money and the power is still on, then my computations are incorrect.”
Convert this argument into logical notations using the variables c, b, r, p for propositions of computations, electric bills, out of money and the power respectively. (Where ¬ means NOT)
Convert this argument into logical notations using the variables c, b, r, p for propositions of computations, electric bills, out of money and the power respectively. (Where ¬ means NOT)
if (c Λ b)→r and ¬b→p, then (¬r Λ p)→¬c | |
if (c ∨ b)→r and ¬b→¬p, then (r Λ p)→c | |
if (c Λ b)→r and ¬p→b, then (¬r ∨ p)→¬c | |
if (c ∨ b)→r and ¬b→¬p, then (¬r Λ p)→¬c |
Question 272 Explanation:
We can represent ,
“c” for my computations are correct
“b” for I pay the electric bill.
“r” for I will run out of money
“p” for the power is on.
(c Λ b) means my computations are correct and I pay the electric bill.
(¬r Λ p) means I don’t run out of money and the power is still on.
According to the statement , the option -(A) is correct.
“c” for my computations are correct
“b” for I pay the electric bill.
“r” for I will run out of money
“p” for the power is on.
(c Λ b) means my computations are correct and I pay the electric bill.
(¬r Λ p) means I don’t run out of money and the power is still on.
According to the statement , the option -(A) is correct.
Question 273 |
Match the following:
(a)-(i), (b)-(ii), (c)-(iii), (d)-(iv) | |
(a)-(ii), (b)-(iii), (c)-(i), (d)-(iv) | |
(a)-(iii), (b)-(ii), (c)-(iv), (d)-(i) | |
(a)-(iv), (b)-(ii), (c)-(iii), (d)-(i) |
Question 273 Explanation:
→ In logic, contraposition is an inference that says that a conditional statement is logically equivalent to its contrapositive. The contrapositive of the statement has its antecedent and consequent inverted and flipped: the contrapositive of P → Q is thus as ~Q → ~P.
→ The equivalence relation translates verbally into "if and only if" and is symbolized by a double-lined, double arrow pointing to the left and right (↔). If A and B represent statements, then A ↔ B means "A if and only if B."
→ The exportation rule is a rule in logic which states that "if (P and Q), then R" is equivalent to "if P then (if Q then R)".
→ The exportation rule may be formally stated as: (P ∧ Q) → R is equivalent to P → (Q →R)
→ A mode of argumentation or a form of argument in which a proposition is disproven by following its implications logically to an absurd conclusion. Arguments that use universals such as, “always”, “never”, “everyone”, “nobody”, etc., are prone to being reduced to absurd conclusions. The fallacy is in the argument that could be reduced to absurdity -- so in essence, reductio ad absurdum is a technique to expose the fallacy.
→ The equivalence relation translates verbally into "if and only if" and is symbolized by a double-lined, double arrow pointing to the left and right (↔). If A and B represent statements, then A ↔ B means "A if and only if B."
→ The exportation rule is a rule in logic which states that "if (P and Q), then R" is equivalent to "if P then (if Q then R)".
→ The exportation rule may be formally stated as: (P ∧ Q) → R is equivalent to P → (Q →R)
→ A mode of argumentation or a form of argument in which a proposition is disproven by following its implications logically to an absurd conclusion. Arguments that use universals such as, “always”, “never”, “everyone”, “nobody”, etc., are prone to being reduced to absurd conclusions. The fallacy is in the argument that could be reduced to absurdity -- so in essence, reductio ad absurdum is a technique to expose the fallacy.
Question 274 |
Consider a proposition given as :
“ x ≥ 6, if x 2 ≥ 5 and its proof as:
If x ≥ 6, then x 2 = x.x ≥ 6.6 = 36 ≥ 25
Which of the following is correct w.r.to the given proposition and its proof?
(a)The proof shows the converse of what is to be proved.
(b)The proof starts by assuming what is to be shown.
(c)The proof is correct and there is nothing wrong.
“ x ≥ 6, if x 2 ≥ 5 and its proof as:
If x ≥ 6, then x 2 = x.x ≥ 6.6 = 36 ≥ 25
Which of the following is correct w.r.to the given proposition and its proof?
(a)The proof shows the converse of what is to be proved.
(b)The proof starts by assuming what is to be shown.
(c)The proof is correct and there is nothing wrong.
(a) only | |
(c) only | |
(a) and (b) | |
(b) only |
Question 274 Explanation:
The proof which is described in the question is wrong because for a given “x” value , x 2 >=5 but in the proof they mentioned 36>=25 which is wrong.
Question 275 |
Match the following:
(a)-(ii), (b)-(iii), (c)-(iv), (d)-(i) | |
(a)-(iii), (b)-(iv), (c)-(ii), (d)-(i) | |
(a)-(iv), (b)-(i), (c)-(iii), (d)-(ii) | |
(a)-(iv), (b)-(iii), (c)-(ii), (d)-(i) |
Question 275 Explanation:
Forward Reference Table → Uses linked list data structure
Mnemonic Table → Contains machine OP code
Segment Register Table → Uses array data structure
EQU → Assembler directive.
The EQU directive gives a symbolic name to a numeric constant, a register-relative value or a PC-relative value.
Mnemonic Table → Contains machine OP code
Segment Register Table → Uses array data structure
EQU → Assembler directive.
The EQU directive gives a symbolic name to a numeric constant, a register-relative value or a PC-relative value.
Question 276 |
AVA=A is called :
Identity law | |
De Morgan’ s law | |
Idempotent law | |
Complement law |
Question 276 Explanation:
→ De Morgan’s Laws:
(i). (A V B)’ = A' ∧ B'
(ii). (A ∧ B)’ = A' V B'
→ Identity Law :
(i). 1 AND A = A
(ii). 0 OR A = A
→ Complement law:
(i). A AND A'=1
(ii). A OR A'=0
→ Idempotent law:
The idempotence in the context of elements of algebras that remain invariant when raised to a positive integer power, and literally means "(the quality of having) the same power", from idem + potence (same + power).
(i). A V A=A
(ii). A ∧ A=A
According to boolean algebra
(i). (A V B)’ = A' ∧ B'
(ii). (A ∧ B)’ = A' V B'
→ Identity Law :
(i). 1 AND A = A
(ii). 0 OR A = A
→ Complement law:
(i). A AND A'=1
(ii). A OR A'=0
→ Idempotent law:
The idempotence in the context of elements of algebras that remain invariant when raised to a positive integer power, and literally means "(the quality of having) the same power", from idem + potence (same + power).
(i). A V A=A
(ii). A ∧ A=A
According to boolean algebra
Question 277 |
If f(x) = x+1 and g(x)=x+3 then f0 f0 f0 f is :
g | |
g+1 | |
g 4 | |
None of the above |
Question 277 Explanation:
Given data,
f(x)=x+1
g(x)=x+3
Constraint is f0 f0 f0 f
Step-1: We can write into fo fo fo f is f(f(f(x+1)))
We can write into f(f(x+2)) and f(x+3).
Step-2: Above constraint is equal to "x+4" because f(x+3)+1
Step-3: We can also write into fog(x)=x+4 and gof(x)=x+4.
So, g+1 is appropriate answer.
f(x)=x+1
g(x)=x+3
Constraint is f0 f0 f0 f
Step-1: We can write into fo fo fo f is f(f(f(x+1)))
We can write into f(f(x+2)) and f(x+3).
Step-2: Above constraint is equal to "x+4" because f(x+3)+1
Step-3: We can also write into fog(x)=x+4 and gof(x)=x+4.
So, g+1 is appropriate answer.
Question 278 |
The following lists are the degrees of all the vertices of a graph :
(i) 1, 2, 3, 4, 5
(ii) 3, 4, 5, 6, 7
(iii) 1, 4, 5, 8, 6
(iv) 3, 4, 5, 6
then
(i) 1, 2, 3, 4, 5
(ii) 3, 4, 5, 6, 7
(iii) 1, 4, 5, 8, 6
(iv) 3, 4, 5, 6
then
(i) and (ii) | |
(iii) and (iv) | |
(iii) and (ii) | |
(ii) and (iv) |
Question 278 Explanation:
Every graph is following basic 2 properties:
1. Sum of degrees of the vertices of a graph should be even.
2. Sum of degrees of the vertices of a graph is equal to twice the number of edges.
Statement-(i) is violating property-1.
= 1+2+3+4+5
= 15 is odd number.
Statement-(ii) is violating property-1.
= 3+4+5+6+7
= 25 is odd number.
Statement-(iii) is violating property-1.
= 1+4+5+8+6
= 24 is even number
Statement-(iv) is violating property-1
= 3+4+5+6
= 18 is even number
1. Sum of degrees of the vertices of a graph should be even.
2. Sum of degrees of the vertices of a graph is equal to twice the number of edges.
Statement-(i) is violating property-1.
= 1+2+3+4+5
= 15 is odd number.
Statement-(ii) is violating property-1.
= 3+4+5+6+7
= 25 is odd number.
Statement-(iii) is violating property-1.
= 1+4+5+8+6
= 24 is even number
Statement-(iv) is violating property-1
= 3+4+5+6
= 18 is even number
Question 279 |
If I m denotes the set of integers modulo m, then the following are fields with respect to the operations of addition modulo m and multiplication modulo m :
(i) Z 23
(ii) Z 29
(iii) Z 31
(iv) Z 33
Then
(i) Z 23
(ii) Z 29
(iii) Z 31
(iv) Z 33
Then
(i) only | |
(i) and (ii) only | |
(i), (ii) and (iii) only | |
(i), (ii), (iii) and (iv) |
Question 280 |
T is a graph with n vertices. T is connected and has exactly n-1 edges, then :
T is a tree | |
T contains no cycles | |
Every pairs of vertices in T is connected by exactly one path | |
All of these |
Question 280 Explanation:
This is little bit tricky question.
Step-1:
n= number of vertices
n-1 = number of edges
Example: n=5 vertices and n-1=4 edges
Step-2: The above graph T won’t have cycle then we are calling as tree. Here, every pairs of vertices in T is connected by exactly one path.
Note: The above properties is nothing but minimum spanning tree properties.
Step-1:
n= number of vertices
n-1 = number of edges
Example: n=5 vertices and n-1=4 edges
Step-2: The above graph T won’t have cycle then we are calling as tree. Here, every pairs of vertices in T is connected by exactly one path.
Note: The above properties is nothing but minimum spanning tree properties.
Question 281 |
If the proposition ¬ P → Q is true, then the truth value of the proportion ¬ PV (P → Q) is:
True | |
Multi - Valued | |