Prove that, as a subspace of R with its usual topology, Z has the discrete topology.

Prove that in R^n with the usual topology, if a set is closed and bounded then...

Prove that in R^n with the usual topology, if a set is closed and bounded then it is compact.

TOPOLOGY Prove that a subspace of a first countable space is first countable and that countable...

TOPOLOGY Prove that a subspace of a first countable space is first countable and that countable product (product topology) of first countable spaces is first countable.

Prove the conjecture or provide a counterexample: Let U ∈ in the usual topology, and let...

Prove the conjecture or provide a counterexample: Let U ∈ in the usual topology, and let F be a finite set. Then (U−F) ∈ in the usual topology.

Consider two copies of the real numbers: one with the usual topology and one with the...

Consider two copies of the real numbers: one with the usual topology and one with the left-hand-side topology. Endow the plane with the product topology determined by these two topologies. Describe and give three examples of the open sets of the topological subspace { (x,y)| y=x}.

Determine if W is a subspace of R^3 under the usual addition and scalar multiplication. Either...

Determine if W is a subspace of R^3 under the usual addition and scalar multiplication. Either show algebraically that it is or show how it isn't algebraically. W= {(x1, x2, x3) ∈ R^3 x1 = x2 and x2 = 2x3 }

Prove or provide a counterexample Let f:R→R be a function. If f is T_U−T_C continuous, then...

Prove or provide a counterexample Let f:R→R be a function. If f is T_U−T_C continuous, then f is T_C−T_U continuous. T_U is the usual topology and T_C is the open half-line topology

Prove that the singleton set {0} is a vector subspace of the space P4(R) of all...

Prove that the singleton set {0} is a vector subspace of the space P4(R) of all polynomials of degree at most 3 with real coefficients.

Find the closure of the eventually zero sequences in R^ω in the product topology where ω=Z+

Find the closure of the eventually zero sequences in R^ω in the product topology where ω=Z+

If X and Y are discrete topological spaces, how do I prove X x Y is...

If X and Y are discrete topological spaces, how do I prove X x Y is also discrete? How would I prove the converse is true, could I ? Very interested. Please explain. Like to please break down into steps that would make sense. Not sure if I have to use facts of product topology and discrete topology and how to use them.

What is the highest possible dimension of a subspace of M_n (R) (set of n×n matrices...

What is the highest possible dimension of a subspace of M_n (R) (set of n×n matrices with real coefficients with its usual vector space structure) that only contains invertible matrices (and 0) ?