Since we are “squishing” the integrand,
the integral has a value of . As food for thought, how do we change the integrand so
that the two integrals above are equal?
Two students consider substitution geometrically.
- Devyn
- Riley! We should be able to figure some integrals geometrically using transformations of functions.
- Riley
- That sounds like a cool idea. Maybe, since we know the graph of is a semicircle, we get an ellipse defined on just by stretching the graph of by a factor of horizontally. The equation of this ellipse would be
- Devyn
- Exactly! So since we know that geometrically…
- Riley
- And we know that the area under from is twice the under …
- Devyn and Riley
- We must have
- Devyn and Riley
- Jinx!
- Devyn
- It is kind of like we just stretched out our whole coordinate system, and that helped us solve an integral.
- Riley
- In this case, everything got stretched out by a constant factor of in the horizontal direction. I wonder if we could ever say anything useful about cases where we stretch the -axis by a different amount at each point?
- Devyn
- Whao, that is a wild thought. That seems really hard. Since derivatives measure how much a function stretches a little piece of the domain, maybe the derivative will come into play here?
- Riley
- Hmmmm, but I do not see exactly how. Maybe we should ask our TA about this?