Linear Algebra Prove that Q, the set of rational numbers, with the usually addition and multiplication,...

Recall that Q+ denotes the set of positive rational numbers. Prove that Q+ x Q+ (Q+...

Recall that Q+ denotes the set of positive rational numbers. Prove that Q+ x Q+ (Q+ cross Q+) is countably infinite.

Prove that the only ring homomorphism from Q (rational numbers) to Q (rational numbers) is the...

Prove that the only ring homomorphism from Q (rational numbers) to Q (rational numbers) is the identity map.

Consider the finite set of whole numbers {0,1,2}. Define addition and multiplication such that this set...

Consider the finite set of whole numbers {0,1,2}. Define addition and multiplication such that this set forms a field. Check each axiom for fields.

Show that the group Q^+ of positive rational numbers under multiplication is not definitely generated

Show that the group Q^+ of positive rational numbers under multiplication is not definitely generated

prove that the linear space of rational numbers is not a Banach Space

prove that the linear space of rational numbers is not a Banach Space

Prove the following: (By contradiction) If p,q are rational numbers, with p<q, then there exists a...

Prove the following: (By contradiction) If p,q are rational numbers, with p<q, then there exists a rational number x with p<x<q.

Consider the set Q(√3) ={a+b√3| a,b∈Q}. We have the associative properties of usual addition and usual...

Consider the set Q(√3) ={a+b√3| a,b∈Q}. We have the associative properties of usual addition and usual multiplication from the field of real number R. a)Show that Q (√3) is closed under addition, contains the additive identity (0,zero) of R, each element contains the additive inverses, and say if addition is commutative. What does this tell you about (Q(√3,+)? b) Prove that Q(√3) is a commutative ring with unity 1 c) Prove that Q(√3) is a field by showing every nonzero...

6. Define S={q∈Q:−√3< q <√3}, where Q denotes the rational numbers. Prove that S can not...

6. Define S={q∈Q:−√3< q <√3}, where Q denotes the rational numbers. Prove that S can not be the set of subsequential limits of any sequence (sn) of reals. Please be very verbose. I already have the answer to this question as a contradiction. It is okay if you use a contradiction, however please explain thoroughly.

prove that the family of set of {x: x>a, a rational} or {x:x<a, a rational} forms...

prove that the family of set of {x: x>a, a rational} or {x:x<a, a rational} forms a subbasis of the standard topology on the real numbers. prove that the standard topology generated by this basis is countable.

Prove or disprove: GL2(R), the set of invertible 2x2 matrices, with operations of matrix addition and...

Prove or disprove: GL2(R), the set of invertible 2x2 matrices, with operations of matrix addition and matrix multiplication is a ring. Prove or disprove: (Z5,+, .), the set of invertible 2x2 matrices, with operations of matrix addition and matrix multiplication is a ring.