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COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION )

COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION ). The computation of anti-derivatives is just an in- tellectual challenge, we know how to take deriv-atives , but … can we invert the process? We call this Computing the indefinite integral .

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COMPUTING ANTI-DERIVATIVES (Integration by SUBSTITUTION )

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  1. COMPUTINGANTI-DERIVATIVES(Integration by SUBSTITUTION) The computation of anti-derivatives is just an in-tellectual challenge, we know how to takederiv-atives, but … can we invert the process? We call this Computing the indefinite integral . In the last presentation we have seen a few indefinite integrals (we called them bricks), but they did not include the anti-derivative of many functions! We are going to try and do better !

  2. It pays off to look at differentiation and integration as inverse processes, that is, if we apply each in order we end up (essentially) where we started. First D then I gives us “where we started + C”

  3. First I then D gives us “where we started.” This very simple observation is going to give us a fair amount of power, because we know how D works, and we can essentially take advantage of “undoing” it ! Here we go.

  4. We know how the chain rule works. It says: Apply to both sides (remember that where you started (never mind C !). We get Replacing the symbol with we get Since we men- tally put

  5. And get the following Rule of Integration by Substitution: If is differentiable, and is differentiable, then where and . We say we use the substitution . The advantage is that the integral may be a lot easier than the one we started with.

  6. An example is in order. Let’s compute When using substitution there are several choices for what to call (I have dropped !) You will only learn which choices are smart and which ones are not by doing very, very many ex-amples, making very, very many not so smart choices. I have already gone through that, so I know that the smart choice here is . We get

  7. And therefore The last integral is easy! Putting the pieces together (writing ) We get (Check it out !) More examples on the board.

  8. Here are a few: and the hardest

  9. How do we use substitution to compute ? (a definite integral) Two choices. • The formula gives rise to

  10. Or • Use the answer you got (in ), evaluate at and as usual. More examples on the board.

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