Prove the product rule for derivatives of complex-valued functions.

L20 - 5 ex. Find dy if y =n( xy). dx We can also use “Implicit Diﬀerentiation” to ﬁnd the derivative of inverse functions. For example, (sin −1x)= √ 1 . dx 1 − x2

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Linear Algebra With Applications - 4 Edition - Chapter 9.2 - Problem 35

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Linear Algebra With Applications - 4 Edition - Chapter 9.2 - Problem 35

ISBN: 9780136009269
434

Linear Algebra with Applications | 4th Edition

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Linear Algebra with Applications | 4th Edition

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Problem 35

Prove the product rule for derivatives of complex-valued functions.

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##### Textbook: Linear Algebra with Applications

##### Edition: 4

##### Author: Otto Bretscher

##### ISBN: 9780136009269

Step 1 of 3

L20 - 5 ex. Find dy if y =n( xy). dx We can also use “Implicit Diﬀerentiation” to ﬁnd the derivative of inverse functions. For example, (sin −1x)= √ 1 . dx 1 − x2

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###### Chapter 9.2, Problem 35 is Solved

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This textbook survival guide was created for the textbook: Linear Algebra with Applications, edition: 4. The answer to “Prove the product rule for derivatives of complex-valued functions.” is broken down into a number of easy to follow steps, and 9 words. This full solution covers the following key subjects: . This expansive textbook survival guide covers 41 chapters, and 2394 solutions. The full step-by-step solution to problem: 35 from chapter: 9.2 was answered by , our top Math solution expert on 03/15/18, 05:20PM. Linear Algebra with Applications was written by and is associated to the ISBN: 9780136009269. Since the solution to 35 from 9.2 chapter was answered, more than 232 students have viewed the full step-by-step answer.

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Prove the product rule for derivatives of complex-valued functions