proof of 'f : R->R is concave if f''(x) <= 0 for all 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.

A function f : R → R is called additive if f(x + y) = f(x)...

A function f : R → R is called additive if f(x + y) = f(x) + f(y) for all x, y ∈ R. Is the set of all additive functions a subspace of F(R, R)? Give a proof of counter example.

Suppose that f : R → R such that, the lim h→0 [f(x) − f(x −...

Suppose that f : R → R such that, the lim h→0 [f(x) − f(x − h)] = 0 for all x ∈ R, then is f continuous in this case?

Let g from R to R is a differentiable function, g(0)=1, g’(x)>=g(x) for all x>0 and...

Let g from R to R is a differentiable function, g(0)=1, g’(x)>=g(x) for all x>0 and g’(x)=<g(x) for all x<0. Proof that g(x)>=exp(x) for all x belong to R.

Suppose that f(x)=4x2ln(x),x>0.f(x)=4x2ln⁡(x),x>0. (A) List all the critical values of f(x)f(x). Note: If there are no...

Suppose that f(x)=4x2ln(x),x>0.f(x)=4x2ln⁡(x),x>0. (A) List all the critical values of f(x)f(x). Note: If there are no critical values, enter 'NONE'. (B) Use interval notation to indicate where f(x)f(x) is increasing. Note: Use 'INF' for ∞∞, '-INF' for −∞−∞, and use 'U' for the union symbol. If there is no interval, enter 'NONE'. Increasing: (C) Use interval notation to indicate where f(x)f(x) is decreasing. Decreasing: (D) List the xx values of all local maxima of f(x)f(x). If there are no local...

Let f : R → R be defined by f(x) = x^3 + 3x, for all...

Let f : R → R be defined by f(x) = x^3 + 3x, for all x. (i) Prove that if y > 0, then there is a solution x to the equation f(x) = y, for some x > 0. Conclude that f(R) = R. (ii) Prove that the function f : R → R is strictly monotone. (iii) By (i)–(ii), denote the inverse function (f ^−1)' : R → R. Explain why the derivative of the inverse function,...

Consider the function f defined on R by f(x) = ?0 if x ≤ 0, f(x)...

Consider the function f defined on R by f(x) = ?0 if x ≤ 0, f(x) = e^(−1/x^2) if x > 0. Prove that f is indefinitely differentiable on R, and that f(n)(0) = 0 for all n ≥ 1. Conclude that f does not have a converging power series expansion En=0 to ∞[an*x^n] for x near the origin. [Note: This problem illustrates an enormous difference between the notions of real-differentiability and complex-differentiability.]

Let f: R -> R and g: R -> R be differentiable, with g(x) ≠ 0...

Let f: R -> R and g: R -> R be differentiable, with g(x) ≠ 0 for all x. Assume that g(x) f'(x) = f(x) g'(x) for all x. Show that there is a real number c such that f(x) = cg(x) for all x. (Hint: Look at f/g.) Let g: [0, ∞) -> R, with g(x) = x2 for all x ≥ 0. Let L be the line tangent to the graph of g that passes through the point...

If f:R→R satisfies f(x+y)=f(x) + f(y) for all x and y and 0∈C(f), then f is...

If f:R→R satisfies f(x+y)=f(x) + f(y) for all x and y and 0∈C(f), then f is continuous everywhere.

Let f(x)=sin x-cos x,0≤x≤2π Find all inflation point(s) of f. Find all interval(s) on which f...

Let f(x)=sin x-cos x,0≤x≤2π Find all inflation point(s) of f. Find all interval(s) on which f is concave downward.