Prove that limz->∞ f(z) = ∞ if and only if limz->0 1/ (f(1/z)) = 0.

1. Let a, b ∈ Z. Define f : Z → Z by f(n) = an...

1. Let a, b ∈ Z. Define f : Z → Z by f(n) = an + b. Prove that f is one to one if and only if a does not equal 0.

Let f : Z → Z be a ring isomorphism. Prove that f must be the...

Let f : Z → Z be a ring isomorphism. Prove that f must be the identity map. Must this still hold true if we only assume f : Z → Z is a group isomorphism? Prove your answer.

Prove that Z ×{ 0 , 1 , 2 , 3 } is countably infinite by...

Prove that Z ×{ 0 , 1 , 2 , 3 } is countably infinite by finding a bijection f : Z → Z ×{ 0 , 1 , 2 , 3 } . ( Hint: Consider the division algorithm

Let f: Z→Z be the functon defined by f(x)=x+1. Prove that f is a permutation of...

Let f: Z→Z be the functon defined by f(x)=x+1. Prove that f is a permutation of the set of integers. Let g be the permutation (1 2 4 8 16 32). Compute fgf−1.

2. Define a function f : Z → Z × Z by f(x) = (x 2...

2. Define a function f : Z → Z × Z by f(x) = (x 2 , −x). (a) Find f(1), f(−7), and f(0). (b) Is f injective (one-to-one)? If so, prove it; if not, disprove with a counterexample. (c) Is f surjective (onto)? If so, prove it; if not, disprove with a counterexample.

1. A function f : Z → Z is defined by f(n) = 3n − 9....

1. A function f : Z → Z is defined by f(n) = 3n − 9. (a) Determine f(C), where C is the set of odd integers. (b) Determine f^−1 (D), where D = {6k : k ∈ Z}. 2. Two functions f : Z → Z and g : Z → Z are defined by f(n) = 2n^ 2+1 and g(n) = 1 − 2n. Find a formula for the function f ◦ g. 3. A function f :...

. Let f : Z → N be function. a. Prove or disprove: f is not...

. Let f : Z → N be function. a. Prove or disprove: f is not strictly increasing. b. Prove or disprove: f is not strictly decreasing.

o prove that if p(x) ∈ F[x], and a ∈ F, then p(a) = 0 if...

o prove that if p(x) ∈ F[x], and a ∈ F, then p(a) = 0 if and only if x − a divides p(x).

Let f: Z -> Z be a function given by f(x) = ⌈x/2⌉ + 5. Prove...

Let f: Z -> Z be a function given by f(x) = ⌈x/2⌉ + 5. Prove that f is surjective (onto).

Prove that f(z) = ez is continuous everywhere.

Prove that f(z) = ez is continuous everywhere.