Please select a subject first
Advertisements
Advertisements
\[\text{ Let } P\left( n \right) \text{ be the statement } : 2^n \geq 3n . \text{ If } P\left( r \right) \text{ is true, then show that } P\left( r + 1 \right) \text{ is true . Do you conclude that } P\left( n \right)\text{ is true for all n } \in N?\]
Concept: undefined >> undefined
Show by the Principle of Mathematical induction that the sum Sn of then terms of the series \[1^2 + 2 \times 2^2 + 3^2 + 2 \times 4^2 + 5^2 + 2 \times 6^2 + 7^2 + . . .\] is given by \[S_n = \binom{\frac{n \left( n + 1 \right)^2}{2}, \text{ if n is even} }{\frac{n^2 \left( n + 1 \right)}{2}, \text{ if n is odd } }\]
Concept: undefined >> undefined
Advertisements
Prove that the number of subsets of a set containing n distinct elements is 2n, for all n \[\in\] N .
Concept: undefined >> undefined
\[\text{ A sequence } a_1 , a_2 , a_3 , . . . \text{ is defined by letting } a_1 = 3 \text{ and } a_k = 7 a_{k - 1} \text{ for all natural numbers } k \geq 2 . \text{ Show that } a_n = 3 \cdot 7^{n - 1} \text{ for all } n \in N .\]
Concept: undefined >> undefined
\[\text { A sequence } x_1 , x_2 , x_3 , . . . \text{ is defined by letting } x_1 = 2 \text{ and } x_k = \frac{x_{k - 1}}{k} \text{ for all natural numbers } k, k \geq 2 . \text{ Show that } x_n = \frac{2}{n!} \text{ for all } n \in N .\]
Concept: undefined >> undefined
\[\text{ A sequence } x_0 , x_1 , x_2 , x_3 , . . . \text{ is defined by letting } x_0 = 5 and x_k = 4 + x_{k - 1}\text{ for all natural number k . } \]
\[\text{ Show that } x_n = 5 + 4n \text{ for all n } \in N \text{ using mathematical induction .} \]
Concept: undefined >> undefined
Concept: undefined >> undefined
\[\text{ The distributive law from algebra states that for all real numbers} c, a_1 \text{ and } a_2 , \text{ we have } c\left( a_1 + a_2 \right) = c a_1 + c a_2 . \]
\[\text{ Use this law and mathematical induction to prove that, for all natural numbers, } n \geq 2, if c, a_1 , a_2 , . . . , a_n \text{ are any real numbers, then } \]
\[c\left( a_1 + a_2 + . . . + a_n \right) = c a_1 + c a_2 + . . . + c a_n\]
Concept: undefined >> undefined
If A, B, C are three sets such that \[A \subset B\]then prove that \[C - B \subset C - A\]
Concept: undefined >> undefined
For any two sets A and B, prove that \[\left( A \cup B \right) - B = A - B\]
Concept: undefined >> undefined
For any two sets A and B, prove that \[A - \left( A \cap B \right) = A - B\]
Concept: undefined >> undefined
For any two sets A and B, prove that \[A - \left( A - B \right) = A \cap B\]
Concept: undefined >> undefined
For any two sets A and B, prove that
\[A \cup \left( B - A \right) = A \cup B\]
Concept: undefined >> undefined
For any two sets A and B, prove that \[\left( A - B \right) \cup \left( A \cap B \right) = A\]
Concept: undefined >> undefined
If A and B are two sets such that \[n \left( A \cup B \right) = 50, n \left( A \right) = 28 \text{ and } n \left( B \right) = 32\]\[n \left( A \cap B \right)\]
Concept: undefined >> undefined
If P and Q are two sets such that P has 40 elements, \[P \cup Q\]has 60 elements and\[P \cap Q\]has 10 elements, how many elements does Q have?
Concept: undefined >> undefined
In a school there are 20 teachers who teach athematics or physics. Of these, 12 teach mathematics and 4 teach physics and mathematics. How many teach physics?
Concept: undefined >> undefined
In a group of 70 people, 37 like coffee, 52 like tea and each person likes at least one of the two drinks. How many like both coffee and tea?
Concept: undefined >> undefined
Let A and B be two sets such that :\[n \left( A \right) = 20, n \left( A \cup B \right) = 42 \text{ and } n \left( A \cap B \right) = 4\] Find\[n\left( B \right)\]
Concept: undefined >> undefined
In a group of 950 persons, 750 can speak Hindi and 460 can speak English. Find:
how many can speak both Hindi and English:
Concept: undefined >> undefined
