Answer:Z
cos x dx = sin x + C
Z
sec2 x dx = tan x + C
Z
sec x tan x dx = sec x + C
Z
1
1 + x2
dx = arctan x + C
Z
1
√
1 − x2
dx = arcsin x + C
8.1 Substitution
Needless to say, most problems we encounter will not be so simple. Here’s a slightly more
complicated example: find
Z
2x cos(x
2
) dx.
This is not a “simple” derivative, but a little thought reveals that it must have come from
an application of the chain rule. Multiplied on the “outside” is 2x, which is the derivative
of the “inside” function x
2
. Checking:
d
dx sin(x
2
) = cos(x
2
)
d
dxx
2 = 2x cos(x
2
),
so Z
2x cos(x
2
) dx = sin(x
2
) + C.
Even when the chain rule has “produced” a certain derivative, it is not always easy to
see. Consider this problem:
Z
x
3
p
1 − x
2 dx.
There are two factors in this expression, x
3
and p
1 − x
2, but it is not apparent that the
chain rule is involved. Some clever rearrangement reveals that it is:
Z
x
3
p
1 − x
2 dx =
Z
(−2x)
−
1
2
(1 − (1 − x
2
))p
1 − x
2 dx.
This looks messy, but we do now have something that looks like the result of the chain
rule: the function 1 − x
2 has been substituted into −(1/2)(1 − x)
√
x, and the derivative
Step-by-step explanation:Z
cos x dx = sin x + C
Z
sec2 x dx = tan x + C
Z
sec x tan x dx = sec x + C
Z
1
1 + x2
dx = arctan x + C
Z
1
√
1 − x2
dx = arcsin x + C
8.1 Substitution
Needless to say, most problems we encounter will not be so simple. Here’s a slightly more
complicated example: find
Z
2x cos(x
2
) dx.
This is not a “simple” derivative, but a little thought reveals that it must have come from
an application of the chain rule. Multiplied on the “outside” is 2x, which is the derivative
of the “inside” function x
2
. Checking:
d
dx sin(x
2
) = cos(x
2
)
d
dxx
2 = 2x cos(x
2
),
so Z
2x cos(x
2
) dx = sin(x
2
) + C.
Even when the chain rule has “produced” a certain derivative, it is not always easy to
see. Consider this problem:
Z
x
3
p
1 − x
2 dx.
There are two factors in this expression, x
3
and p
1 − x
2, but it is not apparent that the
chain rule is involved. Some clever rearrangement reveals that it is:
Z
x
3
p
1 − x
2 dx =
Z
(−2x)
−
1
2
(1 − (1 − x
2
))p
1 − x
2 dx.
This looks messy, but we do now have something that looks like the result of the chain
rule: the function 1 − x
2 has been substituted into −(1/2)(1 − x)
√
x, and the derivative