Let s1 := 1 and Sn+1 := 1 + 1/sN n element N Show that (Sn)...

Let H ={σ∈Sn |σ(n) = n}. Show that H ≤ Sn and H∼= Sn-1.

Let H ={σ∈Sn |σ(n) = n}. Show that H ≤ Sn and H∼= Sn-1.

let A = {1/n : n element N} show that every point of A is a...

let A = {1/n : n element N} show that every point of A is a boundary point in R but 0 is the only cluster point of A in R.

Let n ≥ 2. Show that exactly half of the permutations in Sn are even ,...

Let n ≥ 2. Show that exactly half of the permutations in Sn are even , by finding a bijection from the set of all even permutations in Sn to the set of all odd permutations in Sn.

Let P be a subgroup of Sn of prime order, and suppose the element x in...

Let P be a subgroup of Sn of prime order, and suppose the element x in Sn normalizes but does not centralize P. Show that x fixes at most one point in each orbit of P. Help with a solution would be appreciated.

1. Find the first six terms of the recursively defined sequence Sn=3S(n−1)+2 for n>1, and S1=1...

1. Find the first six terms of the recursively defined sequence Sn=3S(n−1)+2 for n>1, and S1=1 first six terms =

Do not use binomial theorem for this!! (Real analysis question) a) Let (sn) be the sequence...

Do not use binomial theorem for this!! (Real analysis question) a) Let (sn) be the sequence defined by sn = (1 +1/n)^(n). Prove that sn is an increasing sequence with sn < 3 for all n. Conclude that (sn) is convergent. The limit of (sn) is referred to as e and is used as the base for natural logarithms. b)Use the result above to find the limit of the sequences: sn = (1 +1/n)^(2n) c)sn = (1+1/n)^(n-1)

Show that Sn = <(1, 2), (1, 2 , ..., n)>

Show that Sn = <(1, 2), (1, 2 , ..., n)>

Let N be a normal subgroup of G. Show that the order 2 element in N...

Let N be a normal subgroup of G. Show that the order 2 element in N is in the center of G if N and Z_4 are isomorphic.

   Let {Xi} be i.i.d. random variables with P(Xi=−1) = P(Xi= 1) = 1/2. Let Sn=...

   Let {Xi} be i.i.d. random variables with P(Xi=−1) = P(Xi= 1) = 1/2. Let Sn= 1 +X1+. . .+Xn be symmetric simple random walk with initial point S0 = 1. Find the probability that Sn eventually hits the point 0. Hint: Define the events A={Sn= 0 for some n} and for M >1, AM = {Sn hits 0 before hitting M}. Show that AM ↗ A.

If sn = 1+ 1/2 + 1/3 + 1/4 +···+ 1/n show that S 2^n ≥...

If sn = 1+ 1/2 + 1/3 + 1/4 +···+ 1/n show that S 2^n ≥ 1+n/2 for all n. Elementary Real Analysis