Let G be a group and a be an element of G. Let φ:Z→G be a...

Let G be a cyclic group; an element g ∈ G is called a generator of...

Let G be a cyclic group; an element g ∈ G is called a generator of G if G<g>. Let φ : G → G be an endomorphism of G, and let g be a generator of G. Show that φ is an automorphism if and only if φ(g) is a generator of G. Use this to find Aut(Z).

Let C be a normal subgroup of the group A and let D be a normal...

Let C be a normal subgroup of the group A and let D be a normal subgroup of the group B. (a) Prove that C × D is a normal subgroup of A × B (b) Prove that the map φ : A × B → (A/C) × (B/D) given by φ((m, n)) = (mC, nD) is a group homomorphism. (c) Use the fundamental homomorphism theorem to prove that (A × B)/(C × D) ∼= (A/C) × (B/D)

Let φ : G → G′ be an onto homomorphism and let N be a normal...

Let φ : G → G′ be an onto homomorphism and let N be a normal subgroup of G. Prove that φ(N) is a normal subgroup of G′.

Let G be a group and suppose H = {g5 : g ∈ G} is a...

Let G be a group and suppose H = {g5 : g ∈ G} is a subgroup of G. (a) Prove that H is normal subgroup of G. (b) Prove that every element in G/H has order at most 5.

Let G be an Abelian group. Let k ∈ Z be nonzero. Define φ : G...

Let G be an Abelian group. Let k ∈ Z be nonzero. Define φ : G → G by φ(x) = x^ k . (a) Prove that φ is a group homomorphism. (b) Assume that G is finite and |G| is relatively prime to k. Prove that Ker φ = {e}.

Let H be a subgroup of a group G. Let ∼H and ρH be the equivalence...

Let H be a subgroup of a group G. Let ∼H and ρH be the equivalence relation in G introduced in class given by x∼H y⇐⇒x−1y∈H, xρHy⇐⇒xy−1 ∈H. The equivalence classes are the left and the right cosets of H in G, respectively. Prove that the functionφ: G/∼H →G/ρH given by φ(xH) = Hx−1 is well-defined and bijective. This proves that the number of left and right cosets are equal.

4. Let f : G→H be a group homomorphism. Suppose a∈G is an element of finite...

4. Let f : G→H be a group homomorphism. Suppose a∈G is an element of finite order n. (a) Prove that f(a) has finite order k, where k is a divisor of n. (b) If f is an isomorphism, prove that k=n.

Let G be a group and define the center (of G) Z(G) = {a ∈ G...

Let G be a group and define the center (of G) Z(G) = {a ∈ G | xa = ax, ∀ x ∈ G} a. Prove that Z(G) forms a subgroup of G. b. If G is abelian, show that Z(G) = G. c. What is the center of S3

Let G be a group and define the center Z9G) = {a ∈ G | xa...

Let G be a group and define the center Z9G) = {a ∈ G | xa = ax, ∀ x ∈ G}. a. Prove that Z(G) forms a subgroup of G. b. What is the center of Z7?

Let G be an Abelian group and let H be a subgroup of G Define K...

Let G be an Abelian group and let H be a subgroup of G Define K = { g∈ G | g3 ∈ H }. Prove that K is a subgroup of G .