Let F be a σ-algebra. Show that if A and B are in F, then A...

Let X be a set and A a σ-algebra of subsets of X. (a) A function...

Let X be a set and A a σ-algebra of subsets of X. (a) A function f : X → R is measurable if the set {x ∈ X : f(x) > λ} belongs to A for every real number λ. Show that this holds if and only if the set {x ∈ X : f(x) ≥ λ} belongs to A for every λ ∈ R. (b) Let f : X → R be a function. (i) Show that if...

Show that the completion of the Borel σ-algebra gives the collection of Lebesgue measurable subsets of...

Show that the completion of the Borel σ-algebra gives the collection of Lebesgue measurable subsets of R (with respect to Lebesgue measure)

Let F be continuous, show that f([a,b]) is a closed interval.

Let F be continuous, show that f([a,b]) is a closed interval.

Let F be a field. Prove that if σ is an isomorphism of F(α1, . ....

Let F be a field. Prove that if σ is an isomorphism of F(α1, . . . , αn) with itself such that σ(αi) = αi for i = 1, . . . , n, and σ(c) = c for all c ∈ F, then σ is the identity. Conclude that if E is a field extension of F and if σ, τ : F(α1, . . . , αn) → E fix F pointwise and σ(αi) = τ (αi)...

Let f: [a,b] to R be continuous and strictly increasing on (a,b). Show that f is...

Let f: [a,b] to R be continuous and strictly increasing on (a,b). Show that f is strictly increasing on [a,b].

Let x ∼ N(μ,σ) and z = x−μ/σ. Show that a. E{z} = 0 b. E{(z...

Let x ∼ N(μ,σ) and z = x−μ/σ. Show that a. E{z} = 0 b. E{(z − E{z})2} = 1.

Using Algebra, find the compliment of F = x(y'z') + yz Then show that FF' =...

Using Algebra, find the compliment of F = x(y'z') + yz Then show that FF' = 0 and F + F' = 1

good evening if Ω is a sample space, τ is a σ-algebra over Ω and Ω’...

good evening if Ω is a sample space, τ is a σ-algebra over Ω and Ω’ is a non-empty subset of Ω. Show that the following set is also a σ-algebra over Ω’ τ’ = {Α n Ω’ : Α belongs to τ} I’m stucked in the compliment part, if B is in τ’ then compliment of B is in τ’. Could you please help me!

Show that the center of an algebra is a subspace of that algebra. If the algebra...

Show that the center of an algebra is a subspace of that algebra. If the algebra is associative, then its center is a subalgebra.

Let f be a monotonic increasing function on a closed interval [a, b]. Show that f...

Let f be a monotonic increasing function on a closed interval [a, b]. Show that f is Riemann integrable on [a, b].