Let be a differentiable function such that for all . Then the area of the region bounded by and the coordinate axes is](streamdown:incomplete-link)
- A
- B
- C
- D
Let be a differentiable function such that for all . Then the area of the region bounded by and the coordinate axes is](streamdown:incomplete-link)
Correct answer:B
Standard Method
Given:
with differentiable.
Find: The area of the region bounded by and the coordinate axes.](streamdown:incomplete-link)
Differentiate the given relation. Write
So,
From the original equation,
Substituting this in the differentiated equation gives
Hence,
Now use the initial condition from the original equation at :
Solve the linear differential equation using integrating factor :
Integrating,
Using the working from the solution,
so
Applying , we get . Therefore,
The curve meets the axes at and . Thus the bounded region is a right triangle with base and height .
Therefore, the correct option is B.
Differentiate and convert to ODE
Given: .
Find: The area enclosed by the graph of and the coordinate axes.
A useful substitution is
Then
and the given equation becomes
Differentiate both sides:
Since
we obtain
From
we have
Substitute into the derivative equation:
Therefore,
At , the integral vanishes, so
Now solve
with initial condition .
Using integrating factor ,
Integrating gives
which implies
From , we get , hence
So the graph is a straight line cutting the axes at and . The enclosed area is
Hence the area is , so the correct option is B.
Differentiating incorrectly by ignoring the dependence on both the upper limit and the factor . This is wrong because Leibniz rule must be applied carefully. Rewrite the integral as before differentiating.
Using the first extracted solution step directly. That misses the substitution from the original equation and leads to an incorrect function. Instead, replace by to obtain the correct ODE .
Trying to find area by integrating from to . This is wrong because the bounded region with the coordinate axes ends at the positive -intercept, not at infinity. First find where , then compute the finite enclosed area.
Get unlimited AI-adaptive practice, mastery tracking, and an AI tutor that explains every step — free to start.