(a) Let f(x, y, z) be a function, let r(t) = (x(t), y(t), z(t)) be a parametric curve, and set g(t) = f(r(t)). Write an expression for dg at a point to. Your final answer must contain a directional derivative, and it may not contain dx, dy, or dz. %3D (b) Let r(t) = (t sin(t), t cos(t), 0). Use linear approximation to estimate the distance from r(t) to the point (0, 0, 1) at t near a. Your answer should be a function of a and t. (c) Find a number a such that the error associated to the linear approximation you found in part (b) in the interval (a – 1, a + 1) is < 0.01. Justify your answer using - Taylor's formula.

Advanced Engineering Mathematics
10th Edition
ISBN:9780470458365
Author:Erwin Kreyszig
Publisher:Erwin Kreyszig
Chapter2: Second-order Linear Odes
Section: Chapter Questions
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A, B, C
**Problem Statement:**

(a) Let \( f(x, y, z) \) be a function, let \( \mathbf{r}(t) = \langle x(t), y(t), z(t) \rangle \) be a parametric curve, and set \( g(t) = f(\mathbf{r}(t)) \). Write an expression for \( dg \) at a point \( t_0 \). Your final answer must contain a directional derivative, and it may not contain \( dx, dy, \) or \( dz \).

(b) Let \( \mathbf{r}(t) = \langle t \sin(t), t \cos(t), 0 \rangle \). Use linear approximation to estimate the distance from \( \mathbf{r}(t) \) to the point \( (0, 0, 1) \) at \( t \) near \( a \). Your answer should be a function of \( a \) and \( t \).

(c) Find a number \( a \) such that the error associated with the linear approximation you found in part (b) in the interval \( (a - 1, a + 1) \) is \( < 0.01 \). Justify your answer using Taylor's formula.
Transcribed Image Text:**Problem Statement:** (a) Let \( f(x, y, z) \) be a function, let \( \mathbf{r}(t) = \langle x(t), y(t), z(t) \rangle \) be a parametric curve, and set \( g(t) = f(\mathbf{r}(t)) \). Write an expression for \( dg \) at a point \( t_0 \). Your final answer must contain a directional derivative, and it may not contain \( dx, dy, \) or \( dz \). (b) Let \( \mathbf{r}(t) = \langle t \sin(t), t \cos(t), 0 \rangle \). Use linear approximation to estimate the distance from \( \mathbf{r}(t) \) to the point \( (0, 0, 1) \) at \( t \) near \( a \). Your answer should be a function of \( a \) and \( t \). (c) Find a number \( a \) such that the error associated with the linear approximation you found in part (b) in the interval \( (a - 1, a + 1) \) is \( < 0.01 \). Justify your answer using Taylor's formula.
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