![]() Don’t forget to replace your substitution at the end! Then we can make our substitutions and solve the integral. The best way I’ve found to deal with mismatched constants is to divide them from both sides of the differential. However there is no constant 2 in the original integral. Then the differential would be: du = 2 x dx. The best choice for substitution would be the exponent of e. Ok let’s see if we can use the method of integration by substitution in a few examples. The final step is to replace every u by its expression in x, namely the function g( x) that you chose back in Step 1. Replace the SubstitutionĪssuming you made it this far, you now have a function of the variable u (plus a constant of integration). Hopefully the result is a much simpler integral (in the variable u) than the one you started with (in x).Ĭan we integrate it? Yes we can! Image by JD Hancock. Simplify the integrand as much as possible. However if there are only expressions of u, and if the differential is du, then you can move on to the integration step. If there are any leftover x‘s anywhere, or if the old differential dx is still in the integral, then the substitution is not complete. Next, check to see what variables are represented in the integral. We’ll see more about this point in the examples below. The only catch is that you have to have a perfect match in order to make the trade. In fact, those leftover expressions can be traded out using du = g ‘( x) dx. Replace g( x) by u, hopefully making the integrand a little simpler.īut don’t be worried if there are still expressions in the integral involving x. Now you get to change the form of the integral. The reason you should do this step is that the differential provides a link between the “ dx” from the original integral and the new integral, which will have “ du” instead. So the differential of u = g( x) is du = g ‘( x) dx, ![]() Remember, the differential of a function of x is just its derivative times dx. Once you’ve decided on your substitution, the next step is to find its differential.
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