Approximate integration

Matterwave

1. The problem statement, all variables and given/known data
This is technically an E&M question, but I've reduced it to a calculus problem. Basically I have to evaluate:

[tex]B_0(\int_{-H_{max}}^{H_{max}}{tanh(\frac{H+H_c}{H_0})dH - \int_{-H_{max}}^{H_{max}}{tanh(\frac{H-H_c}{H_0})dH)[/tex]

Where [tex]H_{max}>>H_C, H_0[/tex].

2. Relevant equations

3. The attempt at a solution

I'm looking at this and I have no idea how to go about approximating this integral...I suppose I could just brute force the integrals and keep all the H_max and stuff, and then later see if i can approximate something...but the expressions are really quite long and I'd like to avoid that if I can. Is there a way?

tiny-tim

Hi Matterwave!

Are H_c and H₀ constants?

If so, that's just ∫tanh(Ax + b) dx …

and ∫tanh is ln(cosh)

D H

You can eliminate the second integral (it's just the additive inverse of the first; prove it). Per tiny-tim's hint, you can compute the integral. Simplify and finally use the fact that H_max>>H_c , H₀ to arrive at an approximate value.

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tiny-tim Blog Entries: 27 Recognitions: Gold Member Homework Help Science Advisor	Hi Matterwave! Are H_c and H₀ constants? If so, that's just ∫tanh(Ax + b) dx … and ∫tanh is ln(cosh)

D H Mentor	You can eliminate the second integral (it's just the additive inverse of the first; prove it). Per tiny-tim's hint, you can compute the integral. Simplify and finally use the fact that H_max>>H_c , H₀ to arrive at an approximate value.