show that E is a finite open interval in R if and only if x +...

Let T be the half-open interval topology for R, defined in Exercise 4.6. Show that (R,T)...

Let T be the half-open interval topology for R, defined in Exercise 4.6. Show that (R,T) is a T4 - space. Exercise 4.6 The intersection of two half-open intervals of the form [a,b) is either empty or a half-open interval. Thus the family of all unions of half-open intervals together with the empty set is closed under finite intersections, hence forms a topology, which has the half-open intervals as a base.

Define:   x0  = [  r/ (r+2)]  x+r .  Show that  x0   is biased for   µ  in finite            &

Define:   x0  = [  r/ (r+2)]  x+r .  Show that  x0   is biased for   µ  in finite                            samples,  but that it is unbiased for  µ  asymptotically ( as  r  tends to  infinity.).

Let X be finite set . Let R be the relation on P(X). A,B∈P(X) A R...

Let X be finite set . Let R be the relation on P(X). A,B∈P(X) A R B Iff |A|＝|B| prove R is an equivalence relation

show that each subset of R is not compact by describing an open cover for it...

show that each subset of R is not compact by describing an open cover for it that has no finite subcover . [1,3) , also explain a little bit of finite subcover, what does it mean like a finite.

Let X be a topological space with topology T = P(X). Prove that X is finite...

Let X be a topological space with topology T = P(X). Prove that X is finite if and only if X is compact. (Note: You may assume you proved that if ∣X∣ = n, then ∣P(X)∣ = 2 n in homework 2, problem 2 and simply reference this. Hint: Ô⇒ follows from the fact that if X is finite, T is also finite (why?). Therefore every open cover is already finite. For the reverse direction, consider the contrapositive. Suppose X...

Show that if X is an infinite set, then it is connected in the finite complement...

Show that if X is an infinite set, then it is connected in the finite complement topology. Show that in the finite complement on R every subspace is compact.

1. Suppose that ? is a finite dimensional vector space over R. Show that if ???(?...

1. Suppose that ? is a finite dimensional vector space over R. Show that if ???(? ) is odd, then every ? ∈ L(? ) has an eigenvalue. (Hint: use induction). (please provide a detailed proof) 2. Suppose that ? is a finite dimensional vector space over R and ? ∈ L(? ) has no eigenvalues. Prove that every ? -invariant subspace of ? has even dimension.

(a) Show that GLn(F) is finite if and only if F is finite. (b) Show that...

(a) Show that GLn(F) is finite if and only if F is finite. (b) Show that if |F| = q then |GLn(F)| ≤ q^n2. (c) Show that GLn(F) is nonabelian if n > 2 (regardless of the field F.)

a. Assume E[X] is finite for a non-negative continuous random variable X. Prove that 1 −...

a. Assume E[X] is finite for a non-negative continuous random variable X. Prove that 1 − Fx (a) ≤ E[X]/a . b. Assume the MX(t) exists for a continuous random variable X. Prove that 1−Fx(a)≤ Mx(t)/eta

Show that each non-empty open interval in R contains uncountably many irrational numbers

Show that each non-empty open interval in R contains uncountably many irrational numbers