Let f and g be continuous functions on the reals and let S={x in R |...

Let f be a continuous from a topological space X to the reals. Let a be...

Let f be a continuous from a topological space X to the reals. Let a be in the reals and let A = {x in X : f(x)=a} Show that A is closed inX.

Let D ⊆ R, a ∈ D, let f, g : D −→ R be continuous...

Let D ⊆ R, a ∈ D, let f, g : D −→ R be continuous functions. If limx→a f(x) = f(a) and limx→a g(x) = g(a) with f(a) < g(a), then there exists δ > 0 such that x ∈ D, 0 < |x − a| < δ =⇒ f(x) < g(x).

Let S be the set R∖{0,1}. Define functions from S to S by ϵ(x)=x, f(x)=1/(1−x), g(x)=(x−1)/x....

Let S be the set R∖{0,1}. Define functions from S to S by ϵ(x)=x, f(x)=1/(1−x), g(x)=(x−1)/x. Show that the collection {ϵ,f,g} generates a group under composition and compute the group operation table.

Let S be the set R\{0,1,2}. Define functions from S to S by f(x) = 2−x,...

Let S be the set R\{0,1,2}. Define functions from S to S by f(x) = 2−x, g(x) = 2/x . Find the group multiplication table for the group generated by <f,g> under composition.

Let f, g : [a, b] ---> R continuous such that (f(a) - g(a)) (f(b) -...

Let f, g : [a, b] ---> R continuous such that (f(a) - g(a)) (f(b) - g(b)) < 0. a) Show that sup{|f(x) - g(x)| : x ϵ [a, b]} is strictly positive and achieved (is a maximum).

Let f, g : [a, b] ---> R continuous such that (f(a) - g(a)) (f(b) -...

Let f, g : [a, b] ---> R continuous such that (f(a) - g(a)) (f(b) - g(b)) < 0. b) Show that inf {|f(x) - g(x)| : x ϵ [a,b]} = 0 and is achieved (is a minimum).

Let f, g : X −→ C denote continuous functions from the open subset X of...

Let f, g : X −→ C denote continuous functions from the open subset X of C. Use the properties of limits given in section 16 to verify the following: (a) The sum f+g is a continuous function. (b) The product fg is a continuous function. (c) The quotient f/g is a continuous function, provided g(z) != 0 holds for all z ∈ X.

. Let f and g : [0, 1] → R be continuous, and assume f(x) =...

. Let f and g : [0, 1] → R be continuous, and assume f(x) = g(x) for all x < 1. Does this imply that f(1) = g(1)? Provide a proof or a counterexample.

Let f and g be measurable unsigned functions on R^d . Assume f(x) ≤ g(x) for...

Let f and g be measurable unsigned functions on R^d . Assume f(x) ≤ g(x) for almost every x. Prove that the integral of f dx ≤ Integral of g dx.

let F : R to R be a continuous function a) prove that the set {x...

let F : R to R be a continuous function a) prove that the set {x in R:, f(x)>4} is open b) prove the set {f(x), 1<x<=5} is connected c) give an example of a function F that {x in r, f(x)>4} is disconnected