You need to use the power-coefficient rule first.
The flaw in your reasoning is that you have assumed that 7 ln 2 was the correct answer, but it is not. 7 ln 2 would be the answer if the question was 7(ln 6 - ln 3).

The simpler equivalent would be 7(6) - 3. Obviously, you'd need to make that into 42 - 3 = 39, but the flawed way of doing it would be to make it 7(6-3) = 7(2) = 14.

Heres the first problem:

gold is being mined at a rate of R(t) = 7/t ounces per hour. How much gold is removed between the third hour and the six hour of operation?

The gold removed equals rate of removal multiplied by the time spent working. Therefore, its the area under the curve of 7/t at the intervals 3 and 6.

So lets integrate. 7/t : 7 ln t

Area =     7 ln 6 - 7 ln 3

= 7 (ln 6 - ln 3)

Yeah I must have forgotten the 7 on one of those.

Still, what about the one I just mentioned? (e^x - e^-x)/2 = 7 ?

Last edited by mikau (2005-12-14 12:18:10)

Not only that, but evaluation of that answer does not seem to produce 7. Perfect! X_X

Last edited by mikau (2005-12-14 17:42:01)

hooray!!!  i solved it!!!

(e^x - e^-x)/2 = 7

e^x - e^-x = 14                             multiply everything by e^x

e^x(e^x - e^-x) = 14e^x

e^2x - 1 = 14e^x

(e^x)² - 14e^x - 1 = 0                   let w=e^x

w² - 14w - 1 = 0                            using the quadratic formula, i obtain

     14±(200)^1/2)
w= ------------------                        which simplifies to
            2

w= 7±(50)^(1/2)                           plug w back in w=e^x

7±(50)^(1/2) = e^x

ln(7±(50)^(1/2)) = x                     but lnx > 0

ln(7+(50)^(1/2)) = x

But I'm not sure I see the mistake I made which you pointed out.

  e^x = e^-x + 14

Oh... your saying I have to take the ln of both sides, not the ln of each term. Just like squaring or taking the square root of both sides.

e^x = ln (e^-x + 14)

Now I remember. Thanks for that, man!