Use each definition of a continuous function to prove that every function f: Z --> R...

We know that any continuous function f : [a, b] → R is uniformly continuous on...

We know that any continuous function f : [a, b] → R is uniformly continuous on the finite closed interval [a, b]. (i) What is the definition of f being uniformly continuous on its domain? (This definition is meaningful for functions f : J → R defined on any interval J ⊂ R.) (ii) Given a differentiable function f : R → R, prove that if the derivative f ′ is a bounded function on R, then f is uniformly...

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

Prove that if f(x) is a continuous function and f(x) is not zero then g(x) =...

Prove that if f(x) is a continuous function and f(x) is not zero then g(x) = 1/f(x) is a continuous function.   Use the epsilon-delta definition of continuity and please overexplain and check your work before answering.

Using only definition 4.3.1 (continuity), prove that f(x)=x2+3x+4 is continuous on R.

Using only definition 4.3.1 (continuity), prove that f(x)=x2+3x+4 is continuous on R.

Use ε − δ definition to prove that the function f (x) = 2x/3x^2 - 2...

Use ε − δ definition to prove that the function f (x) = 2x/3x^2 - 2 is continuous at the point p = 1.

Part I) Prove that if f and g are continuous at a, then f+g is continuous...

Part I) Prove that if f and g are continuous at a, then f+g is continuous at a using the epsilon-δ definition. Part II) Let a, L ∈ R. Prove that if a ≥ L− ε for all positive, then a ≥ L.

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

A function f : A −→ R is uniformly continuous and its domain A ⊂ R...

A function f : A −→ R is uniformly continuous and its domain A ⊂ R is bounded. Prove that f is a bounded function. Can this conclusion hold if we replace the "uniform continuity" by just "continuity"?

Prove that the function f : R \ {−1} → R defined by f(x) = (1−x)...

Prove that the function f : R \ {−1} → R defined by f(x) = (1−x) /(1+x) is uniformly continuous on (0, ∞) but not uniformly continuous on (−1, 1).

Let f : [a,b] → R be a continuous function such that f(x) doesn't equal 0...

Let f : [a,b] → R be a continuous function such that f(x) doesn't equal 0 for every x ∈ [a,b]. 1) Show that either f(x) > 0 for every x ∈ [a,b] or f(x) < 0 for every x ∈ [a,b]. 2) Assume that f(x) > 0 for every x ∈ [a,b] and prove that there exists ε > 0 such that f(x) ≥ ε for all x ∈ [a,b].