Show, if f : X → X is continuous, X is compact, and f does not...

Show, if f : X → X is continuous, X is compact, and f does not...

Show, if f : X → X is continuous, X is compact, and f does not have a fixed point, then there is an > 0 such that d(x, f(x)) ≥ for all x ∈ X.

Let f(x) be a continuous, everywhere differentiable function. What kind information does f'(x) provide regarding f(x)?...

Let f(x) be a continuous, everywhere differentiable function. What kind information does f'(x) provide regarding f(x)? Let f(x) be a continuous, everywhere differentiable function. What kind information does f''(x) provide regarding f(x)? Let f(x) be a continuous, everywhere differentiable function. What kind information does f''(x) provide regarding f'(x)? Let h(x) be a continuous function such that h(a) = m and h'(a) = 0. Is there enough evidence to conclude the point (a, m) must be a maximum or a minimum?...

If f is continuous on ( a , b ) and f ( x ) ≠...

If f is continuous on ( a , b ) and f ( x ) ≠ 0 for all x in ( a , b ), then either f ( x ) > ______ for all x in ( a , b ) or f ( x ) < _________ for all x in ( a , b ). A function f is said to be continuous on the _______ at x = c if lim x → c +...

4a). Let g be continuous at x = 0. Show that f(x) = xg(x) is differentiable...

4a). Let g be continuous at x = 0. Show that f(x) = xg(x) is differentiable at x = 0 and f'(0) = g(0). 4b). Let f : (a,b) to R and p in (a,b). You may assume that f is differentiable on (a,b) and f ' is continuous at p. Show that f'(p) > 0 then there is delta > 0, such that f is strictly increasing on D(p,delta). Conclude that on D(p,delta) the function f has a differentiable...

Let (X, d) be a compact metric space and F: X--> X be a function such...

Let (X, d) be a compact metric space and F: X--> X be a function such that d(F(x), F(y)) < d(x, y). Let G: X --> R be a function such that G(x) = d(F(x), x). Prove G is continuous (assume that it is proved that F is continuous).

Let X and Y be metric spaces. Let f be a continuous function from X onto...

Let X and Y be metric spaces. Let f be a continuous function from X onto Y, that is the image of f is equal to Y. Show that if X is compact, then Y is compact

Let (X, d) be a compact metric space and let A ⊆ X. Suppose that A...

Let (X, d) be a compact metric space and let A ⊆ X. Suppose that A is not compact. Prove that there exists a continuous function f : A → R, from (A, d) to (R, d|·|), which is not uniformly continuous.

If X is a continuous random variable with pdf f(x) on the interval [a,b] then show...

If X is a continuous random variable with pdf f(x) on the interval [a,b] then show that a<E(X)<b.

Suppose K is a nonempty compact subset of a metric space X and x∈X. Show, there...

Suppose K is a nonempty compact subset of a metric space X and x∈X. Show, there is a nearest point p∈K to x; that is, there is a point p∈K such that, for all other q∈K, d(p,x)≤d(q,x). [Suggestion: As a start, let S={d(x,y):y∈K} and show there is a sequence (qn) from K such that the numerical sequence (d(x,qn)) converges to inf(S).] Let X=R^2 and T={(x,y):x^2+y^2=1}. Show, there is a point z∈X and distinct points a,b∈T that are nearest points to...

Let a > 0 and f be continuous on [-a, a]. Suppose that f'(x) exists and...

Let a > 0 and f be continuous on [-a, a]. Suppose that f'(x) exists and f'(x)<= 1 for all x2 ㅌ (-a, a). If f(a) = a and f(-a) =-a. Show that f(0) = 0. Hint: Consider the two cases f(0) < 0 and f(0) > 0. Use mean value theorem to prove that these are impossible cases.