Find the first partial derivatives of the function.
F(a, ß) = (" V3 + 1 dt [ :
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> Find the differential of the function. L = xze-y 2-z2
> Find and sketch the domain of the function. In(2 — х) g(x, y) = 1- x² – y?
> Find the differential of the function. T = 1+ uvw
> Find the differential of the function. m = p5q3.
> Find the differential of the function. u = Jx? + 3y2 %3D
> Find the differential of the function. z = e-2x cos 2πt.
> Verify the linear approximation at (0, 0). ex cos (xy) ≈ x + 1
> Explain why the function is differentiable at the given point. Then find the linearization L(x, y) of the function at that point. f (x, y) = 4 arctan (xy), (1, 1)
> Explain why the function is differentiable at the given point. Then find the linearization L(x, y) of the function at that point. f(x, y) =+Y, 1+ x (1, 3)
> Explain why the function is differentiable at the given point. Then find the linearization L(x, y) of the function at that point. fu, y) — Vху, (1,4)
> (a). If a particle moves along a straight line, what can you say about its acceleration vector? (b). If a particle moves with constant speed along a curve, what can you say about its acceleration vector?
> Explain why the function is differentiable at the given point. Then find the linearization L(x, y) of the function at that point. f (x, y) = 1 + x ln (xy – 5), (2, 3)
> The diffusion equation where D is a positive constant, describes the diffusion of heat through a solid, or the concentration of a pollutant at time t at a distance x from the source of the pollution, or the invasion of alien species into a new habitat.
> If u = e4+4; ,++4,, where af + až + . + a; = 1, show that Fu ax? + = u ax? ax?
> If f and t are twice differentiable functions of a single variable, show that the function u (x, t) = f (x + at) + t (x – at) is a solution of the wave equation given in Exercise 78. Exercise 78: Show that each of the following functions is a solution
> A particle has position function r(t). If r'(t) = c × r(t), where c is a constant vector, describe the path of the particle.
> Find the indicated partial derivative(s). u = x*y*z*; ax dy² az³ .3
> Find the indicated partial derivative(s). a³w aw у+ 22 дг ду дх" дх? ду
> Find the indicated partial derivative(s). V = In(r + s² + t); ar as at
> Find the indicated partial derivative(s). W = Ju + v?; 2 au dv
> Find the indicated partial derivative(s). g (r, s, t) = er sin (st); grst
> Find the indicated partial derivative(s). f (x, y) = x4y2 - x3y; fxxx, fxyx
> Verify that the conclusion of Clairaut’s Theorem holds, that is, uxy = uyx. u = ln (x + 2y)
> Determine the signs of the partial derivatives for the function f whose graph is shown. (a). fx (21, 2) (b). fy (21, 2)
> Verify that the conclusion of Clairaut’s Theorem holds, that is, uxy = uyx. u = x4y3 - y4
> Find all the second partial derivatives. w = V1 + uv? ,2
> Find all the second partial derivatives. v = sin (s2 - t2)
> Find all the second partial derivatives. y 2х + Зу
> Find all the second partial derivatives. f (x, y) = ln (ax + by)
> Determine the signs of the partial derivatives for the function f whose graph is shown. (a). fx (1, 2) (b). fy (1, 2)
> Use the definition of partial derivatives as limits (4) to find fx (x, y) and fy (x, y). f(x, y) = x + y?
> Use the definition of partial derivatives as limits (4) to find fx (x, y) and fy (x, y). f (x, y) = xy2 - x3y
> Find the indicated partial derivative. f (x, y, z) = xyz; fz (e, 1, 0)
> Find the indicated partial derivative. 1- f(x, y, z) = In Vx? + y² + z? 1+ Jx? + y? + z² f,(1, 2, 2)
> Find the indicated partial derivative. f (x, y) = y sin-1 (xy); fy (1, 1 2 )
> Find the indicated partial derivative. R (s, t) = tes/t; Rt (0, 1)
> Find the first partial derivatives of the function. u = sin (x1 + 2x2 + ∙ ∙ ∙ + nxn)
> Find the first partial derivatives of the function. Vx} + x} + .… + x금 u =
> Find the first partial derivatives of the function. ах + By? yz + 8t? Ф(х, у, г, 1) -
> A ball with mass 0.8 kg is thrown southward into the air with a speed of 30 m/s at an angle of 30° to the ground. A west wind applies a steady force of 4 N to the ball in an easterly direction. Where does the ball land and with what speed?
> Find the first partial derivatives of the function. u = xy/z
> Find the first partial derivatives of the function. p = Vt4 + u? cos v
> Find the first partial derivatives of the function. w = y tan (x + 2z)
> Find the first partial derivatives of the function. w = ln (x + 2y + 3z)
> Find the first partial derivatives of the function. f (x, y, z) = xy2e-xz
> Find the first partial derivatives of the function. f (x, y, z) = x3yz2 + 2yz
> Find the first partial derivatives of the function. F(x, y) = [" cos(e') dt
> Find the first partial derivatives of the function. f (x, y) = xy
> Find the first partial derivatives of the function. R (p, q) = tan-1(pq2)
> A ball is thrown eastward into the air from the origin (in the direction of the positive x-axis). The initial velocity is 50 i + 80 k, with speed measured in feet per second. The spin of the ball results in a southward acceleration of 4 ft/s2, so the acc
> Find the first partial derivatives of the function. g (u, v) = (u2v - v3)5
> Find the first partial derivatives of the function. e" w и + u + v? 2
> Find the first partial derivatives of the function. ах + by f(x, y) = сх + dy Cx
> Use Clairaut’s Theorem to show that if the third-order partial derivatives of f are continuous, then fxyy = fyxy = fyyx
> Find the first partial derivatives of the function. f(x, y) (x + y)?
> Find the first partial derivatives of the function. f(x, y) = y
> Find the first partial derivatives of the function. z = x sin (xy)
> Find the first partial derivatives of the function. z = ln (x + t2)
> Show that a projectile reaches three-quarters of its maximum height in half the time needed to reach its maximum height.
> The table gives coordinates of a particle moving through space along a smooth curve. (a). Find the average velocities over the time intervals [0, 1], [0.5, 1], [1, 2], and [1, 1.5]. (b). Estimate the velocity and speed of the particle at t = 1. t y
> The kinetic energy of a body with mass m and velocity v is K = 1 2 mv2. Show that aK dK = K am dv?
> Find the first partial derivatives of the function. f(x, t) = /3x + 4t
> Find the first partial derivatives of the function. f (x, t) = t2e-x
> Find the first partial derivatives of the function. f (x, y) = x2y - 3y4
> Find the first partial derivatives of the function. f (x, y) = x4 + 5xy3
> The wind-chill index is modeled by the function W = 13.12 + 0.6215T - 11.37v0.16 + 0.3965Tv 0.16 where T is the temperature (°C) and v is the wind speed (km/h). When T − 215°C and v − 30 km/h, by how much would you expect the apparent temperature W to
> For the ideal gas of Exercise 88, show that Exercise 88: The gas law for a fixed mass m of an ideal gas at absolute temperature T, pressure P, and volume V is PV = mRT, where R is the gas constant. Show that ,aP av = mR aT ƏT aP av əT -1 av aT əP
> The gas law for a fixed mass m of an ideal gas at absolute temperature T, pressure P, and volume V is PV = mRT, where R is the gas constant. Show that aP av əT -1 av aT əP
> A medieval city has the shape of a square and is protected by walls with length 500 m and height 15 m. You are the commander of an attacking army and the closest you can get to the wall is 100 m. Your plan is to set fire to the city by catapulting heated
> Find the limit, if it exists, or show that the limit does not exist. x²y + xy² lim x² – y² (x, y)(2, -1) x – y?
> Find the limit, if it exists, or show that the limit does not exist. (x²y³ – 4y²) (х, у)— (3, 2)
> At the beginning of this section we considered the function and guessed on the basis of numerical evidence that f (x, y) → 1 as (x, y) → (0, 0). Use polar coordinates to confirm the value of the limit. Then graph the f
> Determine the set of points at which the function is continuous. F(x, y) 1+ x² + y? 1– x² – y2
> Determine the set of points at which the function is continuous. F(x, y) = cos /1 + x – y
> Find h (x, y) = g (f (x, y)) and the set of points at which h is continuous. g(t) = t² + JT, ƒ(x, y) = 2x + 3y – 6
> A batter hits a baseball 3 ft above the ground toward the center field fence, which is 10 ft high and 400 ft from home plate. The ball leaves the bat with speed 115 ft/s at an angle 508 above the horizontal. Is it a home run? (In other words, does the ba
> Use a computer graph of the function to explain why the limit does not exist. lim (x, y) (0, 0) 2.x? + 3xy + 4y² 3x? + 5y?
> Find the limit, if it exists, or show that the limit does not exist. x?y?z? lim (3, x 2(0, 0, 0) x? + y? + z?
> Find the limit, if it exists, or show that the limit does not exist. ху + yz lim (x, y, z-(0,0,0) x² +: y? + z?
> Find the limit, if it exists, or show that the limit does not exist. lim (x, y, 2)-(m, 0, 1/3) e tan(xz)
> Find the limit, if it exists, or show that the limit does not exist. x² + y? lim (x, y)-(0, 0) x² + y² + I – 1
> Find the limit, if it exists, or show that the limit does not exist. ху lim (x, y)-(0, 0) x* + y4
> Find the limit, if it exists, or show that the limit does not exist. xy cos y lim + y* .2 (x, y) (0, 0) x
> Describe the level surfaces of the function. f (x, y, z) = y2 + z2
> Describe the level surfaces of the function. f (x, y, z) = x2 + 3y2 + 5z2
> Describe the level surfaces of the function. f (x, y, z) = x + 3y + 5z
> A rifle is fired with angle of elevation 36°. What is the muzzle speed if the maximum height of the bullet is 1600 ft?
> Match the function (a) with its graph (labeled A–F below) and (b) with its contour map (labeled I–VI). Give reasons for your choices. B D E II III IV VI yA (OKO C O O O O).O O O) O O KO C O OD O x- y 1+ x² + y²
> Draw a contour map of the function showing several level curves. f(x, y) = xy
> A contour map of a function is shown. Use it to make a rough sketch of the graph of f.
> Match the function (a) with its graph (labeled A–F below) and (b) with its contour map (labeled I–VI). Give reasons for your choices. z = sin (x – y) B D E II III IV VI yA (OKO C O O O O).O O O
> Match the function (a) with its graph (labeled A–F below) and (b) with its contour map (labeled I–VI). Give reasons for your choices. z = ex cos y B D E II III IV VI yA (OKO C O O O O).O O O) O O KO C O OD O
> A contour map of a function is shown. Use it to make a rough sketch of the graph of f. y.
> Use a computer to graph the function using various domains and viewpoints. Get a printout of one that, in your opinion, gives a good view. If your software also produces level curves, then plot some contour lines of the same function and compare with the
> Use a computer to graph the function using various domains and viewpoints. Get a printout of one that, in your opinion, gives a good view. If your software also produces level curves, then plot some contour lines of the same function and compare with the
> Use a computer to graph the function using various domains and viewpoints. Get a printout of one that, in your opinion, gives a good view. If your software also produces level curves, then plot some contour lines of the same function and compare with the
> A contour map of a function is shown. Use it to make a rough sketch of the graph of f. 14, * 13 12