Antiderivative of e^-x & cos(mx): Discover the Solutions Here!

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Homework Help Overview

The discussion revolves around finding the antiderivatives of the functions e^-x and cos(mx), where m is a constant. Participants are exploring the correctness of their attempts and the underlying concepts of antiderivatives.

Discussion Character

  • Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • The original poster attempts to find the antiderivatives and seeks validation of their results. Some participants suggest checking the correctness of antiderivatives through differentiation. Others discuss the role of the constant C in the general solution of antiderivatives.

Discussion Status

The discussion is active, with participants providing guidance on verifying antiderivatives and clarifying definitions. There is an exploration of the implications of the constant C in the context of antiderivatives, but no explicit consensus has been reached.

Contextual Notes

Participants are engaging with the definitions and properties of antiderivatives, including the importance of the constant C, but there may be some uncertainty regarding its application in the original poster's context.

sapiental
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antiderivative of e^-x

I get -e^-x

antiderivative of cos(mx) where m is a constant

I get \frac {1}{m} \sin x

Please let me know if my attempts are correct. Thanks a lot!
 
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If you can calculate an ordinary derivative, you can always check whether the anti derivative you found is correct. For instance,

\frac{d}{dx}(-e^{-x}) = (-1)(-e^{-x})=e^{-x}

So your antiderivative is correct. Actually, the most general antiderivative to e^-x is -e^-x + C, where C is a constant. Do you see why?
 
because the constant C changes the y value by a certain amount moving the functuion vertically on the graph?

This is what I know of the top of my head and am not quite sure how it relates to your question though.:confused:
 
An antiderivative of a function f(x) is a function F(x) such that F'(x) = f(x). Is that your definition of antiderivative also? If it is, then suppose you found just such an antiderivative F(x). Then F(x) + C is also an anti derivative of f(x) because

\frac{d}{dx}(F(x)+C) = F'(x) + \frac{d}{dx}C = F'(x) + 0 =f(x)
 

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