Unit 1: Integration




          dw = w’ (d= –sind                                                            Notes
          So
          –dw = sind
          Therefore

                                   w
                                                
                  d
            e cos    sin  – e  w (–dw )–(–1) e dw – e w   C    e  cos   C
                     
                                 
                               e t
                 Example: Find    dt .
                              1  e t
          Solution:
                                         t
                                            t
                                                             t
          Observing that the derivative of 1 + e  is e , we notice w = 1 + e  is a good quality choice. Then
               t
          dw = e  dt, so that
             e t      1  t     1
              t  dt      t  e dt     dw   1n w   C
           1  e    1  e     w
                                     n
                                    1 1  e t  C
          As the numerator is e dt, we might also have attempted w = e . This substitution leads to the
                                                             t
                            t
                 
          integral 1/(1 w dw   )  , which is better than the original integral but needs another substitution,
          u = 1 + w, to terminate. There are frequently several different methods of doing an integral by
          substitution.



             Notes  Observe the pattern in the preceding example: having a function in the denominator
             and its derivative in the numerator shows  a natural logarithm. The next example follows
             the similar pattern.


                             
                 Example: Find  tan d .
          Solution:
          Remember that  tan =(sin    (cos  . If w = cos, then dw = –sin d, so

                    sin     dw
                                    n
            tan d =   d =     1 cos  C
              
                    cos      w
                                  2  2
                                    x
                 Example: Compute   0   xe dx
          Solution:
          To assess this definite integral by means of the Fundamental Theorem of Calculus, we first want
                                                                                 2
                                                              2
          to find an antiderivative of  ( )f x   xe x 2  . The inside function is x , so we consider w = x . Then
          dx = 2x dx, so
           1
            dx   xdx .
           2






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