Let G = Z6 and H = {0, 3}. Then [G : H] = 3. Verify...

Let h(x) = f (g(x) − (x^2 + 1)) . If f(0) = 3, f(2) =...

Let h(x) = f (g(x) − (x^2 + 1)) . If f(0) = 3, f(2) = 5, f ' (0) = −5, f ' (2) = 11, g(1) = 2, and g ' (1) = 4. What is h(1) and h ' (1)?

Let G be an abelian group, let H = {x in G | (x^3) = eg},...

Let G be an abelian group, let H = {x in G | (x^3) = eg}, where eg is the identity of G. Prove that H is a subgroup of G.

In Z, let I=〈3〉and J=〈18〉. Show that the group I/J is isomorphic to the group Z6...

In Z, let I=〈3〉and J=〈18〉. Show that the group I/J is isomorphic to the group Z6 but that the ring I/J is not ring-isomorphic to the ring Z6 .

Let h belong to H ≤ G; prove that hH=H=hH. and Let a, b ∈ G...

Let h belong to H ≤ G; prove that hH=H=hH. and Let a, b ∈ G = group and H ≤ G; prove that if aH = Hb, then aH = Ha and bH = Hb.

Let H, K be two groups and G = H × K. Let H = {(h,...

Let H, K be two groups and G = H × K. Let H = {(h, e) | h ∈ H}, where e is the identity in K. Show that G/H is isomorphic to K.

Let G and H be groups, and let G0 = {(g, 1) : g ∈ G}...

Let G and H be groups, and let G0 = {(g, 1) : g ∈ G} . (a) Show that G0 ≅ G. (b) Show that G0 is a normal subgroup of G × H. (c) Show that (G × H)/G0 ≅ H.

Let G be a finite group and H a subgroup of G. Let a be an...

Let G be a finite group and H a subgroup of G. Let a be an element of G and aH = {ah : h is an element of H} be a left coset of H. If B is an element of G as well show that aH and bH contain the same number of elements in G.

Let f: Z6 --> Z2 X Z3 be the function given by f([a]6) = ([a]2,[a]3). (a)...

Let f: Z6 --> Z2 X Z3 be the function given by f([a]6) = ([a]2,[a]3). (a) Show that f is well-defined; that is, show that if [a]6=[b]6, then f([a]6) = f([b]6). (b) Prove that f is an isomorphism.

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.

Let G be an Abelian group and H a subgroup of G. Prove that G/H is...

Let G be an Abelian group and H a subgroup of G. Prove that G/H is Abelian.