Areas, Integrals, and Antiderivatives

Integrals, Antiderivatives, and Applications

The antiderivative method of evaluating definite integrals can also be used when we need to find an "area", and it is useful for solving applied problems.

Example 5: A robot has been programmed so that when it starts to move, its velocity after $t$ seconds will be $3 t^{2}$ feet/second.

(a) How far will the robot travel during its first 4 seconds of movement?

(b) How far will the robot travel during its next 4 seconds of movement?

Solution:

(a) The distance during the first 4 seconds will be the area under the graph (Fig. 8) of velocity , $\mathrm{f}(t)=t$ from $t= 0$ to $t = 4$ , and that area is the definite integral $\int_{0}^{4} 3 t^{2} \mathrm{dt}$ . An antiderivative of $3 t^{2} \text { is } t^{3} \text { so } \int_{0}^{4} 3 t^{2} \mathrm{dt}=\left.t^{3}\right|_{0} ^{4}=(4)^{3}-(0)^{3}=64$ feet.

(b) $\int_{4}^{8} 3 t^{2} \mathrm{dt}=\left.t^{3}\right|_{4} ^{8}=(8)^{3}-(4)^{3}=512-64=448$ feet.

(c) This part is different from the other two parts. Here we are told the lower integration endpoint, $t = 0$ , and the total distance, 729 feet, and we are asked to find the upper endpoint. Calling the upper endpoint $T$ , we know that $729=\int_{0}^{\mathrm{T}} 3 t^{2} \mathrm{dt}=\left.t^{3}\right|_{0} ^{\mathrm{T}}=(\mathrm{T})^{3}-(0)^{3}=\mathrm{T}^{3}, \text { so } \mathrm{T}=\sqrt[3]{729}=9$ seconds.

Practice 4: (a) How far will the robot move between $t = 1$ second and $t = 5$ seconds? (b) How many seconds before the robot is 343 feet from its starting place?

Example 6: Suppose that $t$ minutes after putting 1000 bacteria on a Petri plate the rate of growth of the population is 6t bacteria per minute. (a) How many new bacteria are added to the population during the first 7 minutes? (b) What is the total population after 7 minutes? (c) When will the total population be 2200 bacteria?

Solution:

(a) The number of new bacteria is the area under the rate of growth graph (Fig. 9), and one antiderivative of $6t$ is $3 t^{2}$ (check that $\mathrm{D}\left(3 t^{2}\right)=6 t$ ) so new bacteria = $\int_{0}^{7} 6 t \mathrm{dt}=\left.3 t^{2}\right|_{0} ^{7}=3(7)^{2}-3(0)^{2}=147$ .

(b) The new population = {old population} + {new bacteria} = 1000 + 147 = 1147 bacteria

(c) If the total population is 2200 bacteria, then there are 2200 – 1000 = 1200 new bacteria, and we need to find the time T needed for that many new bacteria to occur.

1200 new bacteria = $\int_{0}^{\mathrm{T}} 6 t \mathrm{dt}=\left.3 t^{2}\right|_{0} ^{\mathrm{T}}=3(\mathrm{~T})^{2}-3(0)^{2}=3 \mathrm{~T}^{2} \text { so } \mathrm{T}^{2}=400$ and $T = 20$ minutes. After 20 minutes, the total bacteria population will be 1000 + 1200 = 2200.

Practice 5: (a) How many new bacteria will be added to the population between $t = 4$ and $t = 8$ minutes? (b) When will the total population be 2875 bacteria? (Hint: How many are new?)