Let H be a group acting on A. Prove that the relation ∼ on A defined...

a) Let R be an equivalence relation defined on some set A. Prove using induction that...

a) Let R be an equivalence relation defined on some set A. Prove using induction that R^n is also an equivalence relation. Note: In order to prove transitivity, you may use the fact that R is transitive if and only if R^n⊆R for ever positive integer ​n b) Prove or disprove that a partial order cannot have a cycle.

Let ​R​ be an equivalence relation defined on some set ​A​. Prove using mathematical induction that...

Let ​R​ be an equivalence relation defined on some set ​A​. Prove using mathematical induction that ​R​^n​ is also an equivalence relation.

Let G be a group. Prove that the relation a~b if b=gag^-1 for some g in...

Let G be a group. Prove that the relation a~b if b=gag^-1 for some g in G is an equivalence relation on G.

Let R be the relation on Z defined by: For any a, b ∈ Z ,...

Let R be the relation on Z defined by: For any a, b ∈ Z , aRb if and only if 4 | (a + 3b). (a) Prove that R is an equivalence relation. (b) Prove that for all integers a and b, aRb if and only if a ≡ b (mod 4)

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 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 g be a group. let h be a subgroup of g. define a~b. if ab^-1...

let g be a group. let h be a subgroup of g. define a~b. if ab^-1 is in h. prove ~ is an equivalence relation on g

13. Let R be a relation on Z × Z be defined as (a, b) R...

13. Let R be a relation on Z × Z be defined as (a, b) R (c, d) if and only if a + d = b + c. a. Prove that R is an equivalence relation on Z × Z. b. Determine [(2, 3)].

Let G be a group, and H a subgroup of G, let a,b?G prove the statement...

Let G be a group, and H a subgroup of G, let a,b?G prove the statement or give a counterexample: If aH=bH, then Ha=Hb

Let N* be the set of positive integers. The relation ∼ on N* is defined as...

Let N* be the set of positive integers. The relation ∼ on N* is defined as follows: m ∼ n ⇐⇒ ∃k ∈ N* mn = k2 (a) Prove that ∼ is an equivalence relation. (b) Find the equivalence classes of 2, 4, and 6.