Tuesday, April 26, 2016

algebra precalculus - How do we get from $ln A=ln P+rn$ to $A=Pe^{rn}$ and similar logarithmic equations?



I've been self-studying from the amazing "Engineering Mathematics" by Stroud and Booth, and am currently learning about algebra, particularly logarithms.




There is a question which I don't understand who they've solved. Namely, I'm supposed to express the following equations without logs:



$$\ln A = \ln P + rn$$



The solution they provide is:



$$A = Pe^{rn}$$



But I absolutely have no idea how they got to these solutions. (I managed to "decipher" some of the similar ones piece by piece by studying the rules of logarithms).


Answer




The basic idea behind all basic algebraic manipulations is that you are trying to isolate some variable or expression from the rest of the equation (that is, you are trying to "solve" for $A$ in this equation by putting it on one side of the equality by itself).



For this particular example (and indeed, most questions involving logarithms), you will have to know that the logarithm is "invertible"; just like multiplying and dividing by the same non-zero number changes nothing, taking a logarithm and then an exponential of a positive number changes nothing.



So, when we see $\ln(A)=\ln(P)+rn$, we can "undo" the logarithm by taking an exponential. However, what we do to one side must also be done to the other, so we are left with the following after recalling our basic rules of exponentiation:
$$
A=e^{\ln(A)}=e^{\ln(P)+rn}=e^{\ln(P)}\cdot e^{rn}=Pe^{rn}
$$


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