Let f : R → R be a function satisfying |f(x) − f(y)| ≤ 3|x −...

Let f(x, y) = x^3 − 4xy^2 , x, y ∈ R. Use the definition of...

Let f(x, y) = x^3 − 4xy^2 , x, y ∈ R. Use the definition of differentiability to show that f(x, y) is differentiable at (2, 1).

Let y be the solution of the equation a) y ′ = 2 x y, satisfying...

Let y be the solution of the equation a) y ′ = 2 x y, satisfying the condition y ( 0 ) = 1. Find the value of the function f ( x ) = ln ⁡ ( y ( x ) ) at the point x = 2. b) Let y be the solution of the equation y ′ = sqrt(1 − y^2) satisfying the condition  y ( 0 ) = 0. Find the value of the function  f ( x...

Let f: R --> R be a differentiable function such that f' is bounded. Show that...

Let f: R --> R be a differentiable function such that f' is bounded. Show that f is uniformly continuous.

A joint density function of the continuous random variables x and y is a function f(x,...

A joint density function of the continuous random variables x and y is a function f(x, y) satisfying the following properties. f(x, y) ≥ 0 for all (x, y) ∞ −∞ ∞ f(x, y) dA = 1 −∞ P[(x, y)  R] =    R f(x, y) dA Show that the function is a joint density function and find the required probability. f(x, y) = 1 8 ,   0 ≤ x ≤ 1, 1 ≤ y ≤ 9 0,   elsewhere P(0 ≤...

a) Let y be the solution of the equation y ′ − [(3x^2*y)/(1+x^3)]=1+x^3 satisfying the condition  y...

a) Let y be the solution of the equation y ′ − [(3x^2*y)/(1+x^3)]=1+x^3 satisfying the condition  y ( 0 ) = 1. Find y ( 1 ). b) Let y be the solution of the equation y ′ = 4 − 2 x y satisfying the condition y ( 0 ) = 0. Use Euler's method with the horizontal step size  h = 1/2 to find an approximation to the value of the function y at x = 1. c) Let y...

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,...

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).

1. Let W be the set of all [x y z}^t in R^3 such that xyz...

1. Let W be the set of all [x y z}^t in R^3 such that xyz = 0. Is W a subspace of R^3? 2. Let C^0 (R) denote the space of all continuous real-valued functions f(x) of x in R. Let W be the set of all continuous functions f(x) such that f(1) = 0. Is W a subspace of C^0(R)?

1. Let f : R2 → R2, f(x,y) = ?g(x,y),h(x,y)? where g,h : R2 → R....

1. Let f : R2 → R2, f(x,y) = ?g(x,y),h(x,y)? where g,h : R2 → R. Show that f is continuous at p0 ⇐⇒ both g,h are continuous at p0

Let F ( x , y ) = 〈 e^x + y^2 − 3 , −...

Let F ( x , y ) = 〈 e^x + y^2 − 3 , − e ^(− y) + 2 x y + 4 y 〉. a) Determine if F ( x , y ) is a conservative vector field and, if so, find a potential function for it. b) Calculate ∫ C F ⋅ d r where C is the curve parameterized by r ( t ) = 〈 2 t , 4 t + sin ⁡ π...