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Hi guys, I encountered these questions while attempting some trial papers and I have no idea how to do them. It would be greatly appreciated if you could work them out and explain how to do it. (Also, if you're looking for some rather challenging questions these may be it) If I enounter more questions I can't do, I'll post them up as well.
1)
i) Find the probability that 6 throws of a fair die result in exactly 3 even scores
ii) Find the probability that 6 throws of a fair die result in exactly 3 even scores, all of which are different
iii) Find the probability that exactly 6 throws of a fair die are needed in order to obtain 3 even scores
iv) Find the probability that at least 6 throws of a fair die are needed in order to obtain 3 even scores
2)
n letters L(1), L(2), L(3),…, L(n) are to be placed at random into n addressed envelopes E(1), E(2), E(3),…, E(n), each bearing a different address, where E(i) bears the correct address for letter L(i) for i = 1, 2, 3,…., n. Let U(n) be the number of arrangements where no letter is placed in the correct envelope for n, a positive integer where n ≥ 2.
i) Show that U(2) = 1 and U(3) = 2
ii) Deduce that U(k + 1) = k(U(k) + U(k – 1)) for k = 4, 5, 6,…
iii) Use the results from (i) to calculate U(4) and U(5).
iv) Show by mathematical induction that U(n) = n! [1/2! – 1/3! + 1/4! – …… + (-1)ⁿ/n!]
v) If there are 5 letters and envelopes:
a) Explain why the probability no letter is placed in the correct envelope is U(5)/120
b) Show that the probability that exactly one letter is placed in the correct envelope is 5U(4)/120 and calculate this probability as a fraction
vi) Deduce that (from k = 2 to n)∑ nCk. U(k) = n! – 1
3)
An unbiased die is thrown six times. Find the probabilities that the six scores obtained will:
i) be 1, 2, 3, 4, 5, 6 in some order
ii) have a product which is an even number
iii) consist of exactly two 6’s and four odd numbers
iv) be such that a 6 occurs only on the last throw and exactly three of the first five throws result in odd numbers
4)
n co-planar lines are such that the number of intersection points is a maximum.
i) How many intersection points are there?
ii) If n such lines divide the plane into U(n) regions, show that U(n) = U(n – 1) + n. Hence deduce that
U(n) = 1 + n(n+ 1)/2. How many of these regions have finite area?
5)
By considering the stationary value of the function f(x) = x – ln x, show that for x > 0, ln x ≤ x – 1:
i) Deduce that if a(1), a(2), …. , a(n) are positive numbers and A = 1/n (from 1 to n)∑ a(n) then
(from 1 to a)∑ ln [a(n)/A] ≤ (from 1 to a)∑ a(n)/A – n = 0.
ii) Hence deduce that [a(1) + a(2) + a(3) + …….. + a(n)]/n ≥ [a(1).a(2).a(3)…..a(n)]^(1/n) .
iii) Hence or otherwise prove that if u, v, w are positive and u + v +w = 1 then 1/u² + 1/v² + 1/w² ≥ 27.
6)
A sequence of numbers a(1), a(2), a(3),….. is such that a(n+ 1) – a(n) = brⁿ where r =/= 0, 1. Given that a(n) can be expressed in the form p + qrⁿ, where p and q are independent of n, find the values of p and q in terms of a, b and r. Verify that the numbers 1, 4, 10, 22, …. Begin a sequence of the above type. Obtain a formula for the nth term of this sequence and find the sum of first n terms of the sequence
7)
In a triangle ABC, b, c and B are given such that two distinct triangles ABC are possible. Show that the difference between the two possible values of the third sides of the two triangles is 2√(b² - c²sin²B)
8)
i) If x ≥ 0, show that 2x/1 + x² ≤ 1
ii) Show that eª ≥ 1 + a² for a ≥ 0
9)
Prove that if n is positive integer and x > 0 then x^(n) + x^(–n) > x^(n –1) + x^(1–n) provided that x =/= 1
10)
The positive integers are bracketed as follows: (1), (2,3), (4,5,6), ….. where there are r integers in the rth bracket. Prove that the sum of integers in rth bracket is r(r² + 1)/2
Enjoy!...
1)
i) Find the probability that 6 throws of a fair die result in exactly 3 even scores
ii) Find the probability that 6 throws of a fair die result in exactly 3 even scores, all of which are different
iii) Find the probability that exactly 6 throws of a fair die are needed in order to obtain 3 even scores
iv) Find the probability that at least 6 throws of a fair die are needed in order to obtain 3 even scores
2)
n letters L(1), L(2), L(3),…, L(n) are to be placed at random into n addressed envelopes E(1), E(2), E(3),…, E(n), each bearing a different address, where E(i) bears the correct address for letter L(i) for i = 1, 2, 3,…., n. Let U(n) be the number of arrangements where no letter is placed in the correct envelope for n, a positive integer where n ≥ 2.
i) Show that U(2) = 1 and U(3) = 2
ii) Deduce that U(k + 1) = k(U(k) + U(k – 1)) for k = 4, 5, 6,…
iii) Use the results from (i) to calculate U(4) and U(5).
iv) Show by mathematical induction that U(n) = n! [1/2! – 1/3! + 1/4! – …… + (-1)ⁿ/n!]
v) If there are 5 letters and envelopes:
a) Explain why the probability no letter is placed in the correct envelope is U(5)/120
b) Show that the probability that exactly one letter is placed in the correct envelope is 5U(4)/120 and calculate this probability as a fraction
vi) Deduce that (from k = 2 to n)∑ nCk. U(k) = n! – 1
3)
An unbiased die is thrown six times. Find the probabilities that the six scores obtained will:
i) be 1, 2, 3, 4, 5, 6 in some order
ii) have a product which is an even number
iii) consist of exactly two 6’s and four odd numbers
iv) be such that a 6 occurs only on the last throw and exactly three of the first five throws result in odd numbers
4)
n co-planar lines are such that the number of intersection points is a maximum.
i) How many intersection points are there?
ii) If n such lines divide the plane into U(n) regions, show that U(n) = U(n – 1) + n. Hence deduce that
U(n) = 1 + n(n+ 1)/2. How many of these regions have finite area?
5)
By considering the stationary value of the function f(x) = x – ln x, show that for x > 0, ln x ≤ x – 1:
i) Deduce that if a(1), a(2), …. , a(n) are positive numbers and A = 1/n (from 1 to n)∑ a(n) then
(from 1 to a)∑ ln [a(n)/A] ≤ (from 1 to a)∑ a(n)/A – n = 0.
ii) Hence deduce that [a(1) + a(2) + a(3) + …….. + a(n)]/n ≥ [a(1).a(2).a(3)…..a(n)]^(1/n) .
iii) Hence or otherwise prove that if u, v, w are positive and u + v +w = 1 then 1/u² + 1/v² + 1/w² ≥ 27.
6)
A sequence of numbers a(1), a(2), a(3),….. is such that a(n+ 1) – a(n) = brⁿ where r =/= 0, 1. Given that a(n) can be expressed in the form p + qrⁿ, where p and q are independent of n, find the values of p and q in terms of a, b and r. Verify that the numbers 1, 4, 10, 22, …. Begin a sequence of the above type. Obtain a formula for the nth term of this sequence and find the sum of first n terms of the sequence
7)
In a triangle ABC, b, c and B are given such that two distinct triangles ABC are possible. Show that the difference between the two possible values of the third sides of the two triangles is 2√(b² - c²sin²B)
8)
i) If x ≥ 0, show that 2x/1 + x² ≤ 1
ii) Show that eª ≥ 1 + a² for a ≥ 0
9)
Prove that if n is positive integer and x > 0 then x^(n) + x^(–n) > x^(n –1) + x^(1–n) provided that x =/= 1
10)
The positive integers are bracketed as follows: (1), (2,3), (4,5,6), ….. where there are r integers in the rth bracket. Prove that the sum of integers in rth bracket is r(r² + 1)/2
Enjoy!...
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