Determine whether the binary operation * gives a group structure on the given set. If no...

Determine whether the binary operation * gives a group structure on the given set Let *...

Determine whether the binary operation * gives a group structure on the given set Let * be defined on 2Z={2n|n element Z} by letting a*b=a+b

Decide whether each of the given sets is a group with respect to the indicated operation....

Decide whether each of the given sets is a group with respect to the indicated operation. If it is not a group, state a condition in the definition of group that fails to hold. (a) The set Z+ of all positive integers with operation multiplication. (b) For a fixed integer n, the set of all complex numbers x such that xn = 1 (That is, the set of all nth roots of 1), with operation multiplication. (c) The set Q'...

Decide whether each of the given sets is a group with respect to the indicated operation....

Decide whether each of the given sets is a group with respect to the indicated operation. If it is not a group, state a condition in the definition of group that fails to hold. (a) The set {[1],[3],[5]}⊂Z8 with the operation multiplication. (b) The set {[0],[2],[4],[6],[8]}⊂Z10 with operation addition.

The following are attempts to define a binary operation on a set, are they actually binary...

The following are attempts to define a binary operation on a set, are they actually binary operations on the given set? If yes, prove it and if not please provide an explanation. 1) a*b = a-b on S, S is the set Z of integers. 2) a*b = a log b on S, S is the set R+ of positive real numbers 3) a*b = |a+b| on S, S is the set of Real numbers. what I want to know...

Q 1 Determine whether the following are real vector spaces. a) The set C with the...

Q 1 Determine whether the following are real vector spaces. a) The set C with the usual addition of complex numbers and multiplication by R ⊂ C. b) The set R2 with the two operations + and · defined by (x1, y1) + (x2, y2) = (x1 + x2 + 1, y1 + y2 + 1), r · (x1, y1) = (rx1, ry1)

Let (G,·) be a finite group, and let S be a set with the same cardinality...

Let (G,·) be a finite group, and let S be a set with the same cardinality as G. Then there is a bijection μ:S→G . We can give a group structure to S by defining a binary operation *on S, as follows. For x,y∈ S, define x*y=z where z∈S such that μ(z) = g_{1}·g_{2}, where μ(x)=g_{1} and μ(y)=g_{2}. First prove that (S,*) is a group. Then, what can you say about the bijection μ?

Let (G,·) be a finite group, and let S be a set with the same cardinality...

Let (G,·) be a finite group, and let S be a set with the same cardinality as G. Then there is a bijection μ:S→G . We can give a group structure to S by defining a binary operation *on S, as follows. For x,y∈ S, define x*y=z where z∈S such that μ(z) = g_{1}·g_{2}, where μ(x)=g_{1} and μ(y)=g_{2}. First prove that (S,*) is a group. Then, what can you say about the bijection μ?

There are two parts of this problem. State whether each statement is true or false. Please...

There are two parts of this problem. State whether each statement is true or false. Please give a clear explanation of each. a. Let G be a group and g in G. Define f : G → G by f(a) = (g-1)(a)(g) or f(a) = g-1ag, for all a in G.Then f is a permutation on G. b. Let G/H be the set of left cosets of the subgroup H in G. If the operation given by the formula aHbH...

Fix a positive real number c, and let S = (−c, c) ⊆ R. Consider the...

Fix a positive real number c, and let S = (−c, c) ⊆ R. Consider the formula x ∗ y :=(x + y)/(1 + xy/c^2). (a)Show that this formula gives a well-defined binary operation on S (I think it is equivalent to say that show the domain of x*y is in (-c,c), but i dont know how to prove that) (b)this operation makes (S, ∗) into an abelian group. (I have already solved this, you can just ignore) (c)Explain why...

For each of the following, determine whether it is a vector space over the given field....

For each of the following, determine whether it is a vector space over the given field. (i) The set of 2 × 2 matrices of real numbers, over R. (ii) The set of 2 × 2 matrices of real numbers, over C. (iii) The set of 2 × 2 matrices of real numbers, over Q.