An initial condition is like the \(y\)-intercept of a line, which determines one particular line among all lines with the same slope. The graphs of the antiderivatives of \(f(x)\) are all parallel (see Figure 5.28 in Section 5.3), and the initial condition determines one of them.

Example 1

Solve \(\frac{dy}{dx}=4x^7\) subject to the initial condition \(y(0) = 4\).

Solution First, find the general antiderivative:

Then choose \(C\) so that the initial condition is satisfied: \(y(0) = 0 + C = 4\). This yields \(C = 4\), and our solution is \(y = \frac{1}{2}x^8+4\).

Example 2

Solve the initial value problem \(\frac{dy}{dt}=\sin(\pi t)\), \(y(2) = 2\).

Solution First find the general antiderivative:

Then solve for \(C\) by evaluating at \(t = 2\):

The solution of the initial value problem is \(y(t)=-\frac{1}{\pi}\cos(\pi t) + 2 +\frac{1}{\pi}\).

Example 3

A car traveling with velocity \(24\text{ m/s}\) begins to slow down at time \(t = 0\) with a constant deceleration of \(a = -6\text{ m/s}^{2}\). Find

(a) the velocity \(v(t)\) at time \(t\), and

(b) the distance traveled before the car comes to a halt.

Solution

(a) The derivative of velocity is acceleration, so velocity is the antiderivative of acceleration:

The initial condition \(v(0) = C = 24\) gives us \(v(t) = -6t + 24\).

(b) Position is the antiderivative of velocity, so the car’s position is

where \(C_{1}\) is a constant. We are not told where the car is at \(t = 0\), so let us set \(s(0) = 0\) for convenience, getting \(C_{1} = 0\). With this choice, \(s(t) = -3t^{2} + 24t\). This is the distance traveled from time \(t = 0\).

The car comes to a halt when its velocity is zero, so we solve

The distance traveled before coming to a halt is \(s(4) = -3(4^{2}) + 24(4) = 48\text{ m}\).

THEOREM 1 The Integral of Velocity

For an object in linear motion with velocity v(t), then

EXAMPLE 4

A particle has velocity v(t) = t³ −10t² + 24t m/s. Compute:

• (a) Displacement over [0, 6]
• (b) Total distance traveled over [0, 6]

Indicate the particle’s trajectory with a motion diagram.

Solution First, we compute the indefinite integral:

• (a) The displacement over the time interval [0, 6] is
  
• (b) The factorization v(t) = t(t − 4)(t − 6) shows that v(t) changes sign at t = 4. It is positive on [0, 4] and negative on [4, 6] as we see in Figure 6.44. Therefore, the total distance traveled is
  

  Figure 6.44: Graph of v(t) = t³ − 10t² + 24t. Over [4, 6], the dashed curve is the graph of |v(t)|.
  

We evaluate these two integrals separately:

The total distance traveled is

Figure 6.45 is a motion diagram indicating the particle’s trajectory. The particle travels during the first 4 s and then backtracks over the next 2 s.

Figure 6.45: Path of the particle along a straight line.

“For those who want some proof that physicists are human, the proof is in the idiocy of all the different units which they use for measuring energy.”

—Richard Feynman,

The Character of Physical Law

DEFINITION Work

The work performed in moving an object along the \(x\)-axis from \(a\) to \(b\) by applying a force of magnitude \(F(x)\) is \[ \begin{equation} \boxed{\bbox[#FAF8ED,5pt]{W = \int_a^b F(x)\, dx}}\tag {2} \end{equation} \]

EXAMPLE 5 Hooke's Law

Assuming a spring constant of \(k = 400 \mathrm{N\text{/}m}\), find the work required to

1. Stretch the spring 10 cm beyond equilibrium.
2. Compress the spring 2 cm more when it is already compressed 3 cm.

Solution A force \(F(x) = 400x\) N is required to stretch the spring (with \(x\) in meters). Note that centimeters must be converted to meters.

1. The work required to stretch the spring 10 cm (0.1 m) beyond equilibrium is \[ W = \int_{0}^{0.1} 400x\, dx = 200x^2 \Big|_0^{0.1} = 2 \textrm{J} \]
2. If the spring is at position \(x=-3\) cm, then the work \(W\) required to compress it further to \(x=-5\) cm is \[ W = \int_{-0.03}^{-0.05} 400x\, dx = 200x^2 \Big|_{-0.03}^{-0.05} = 0.5 - 0.18 = 0.32 \textrm{J} \] Observe that we integrate from the starting point \(x=-0.03\) to the ending point \(x= -0.05\) (even though the lower limit of the integral is larger than the upper limit in this case).

On the earth's surface, work against gravity is equal to the force \(mg\) times the vertical distance through which the object is lifted. No work against gravity is done when an object is moved sideways.

EXAMPLE 6 Building a Cement Column

Compute the work (against gravity) required to build a cement column of height 5 m and square base of side 2 m. Assume that cement has density \(1500 \mathrm{kg\text{/}m}^{3}\).

Solution Think of the column as a stack of \(n\) thin layers of width \(\Delta y = 5/n\). The work consists of lifting up these layers and placing them on the stack (Figure 6.49), but the work performed on a given layer depends on how high we lift it.

Figure 6.49: Total work is the sum of the work performed on each layer of the column.

First, let us compute the gravitational force on a thin layer of width \(\Delta y\): \[ \begin{eqnarray} &\textrm{Volume of layer}& &=\textrm{area \(\times\) width} & &= 4\Delta y \textrm{m}^3\notag\\ &\textrm{Mass of layer}& &=\textrm{density \(\times\) volume} & &= 1500\cdot 4\Delta y \textrm{kg}\notag\\ &\textrm{Force on layer}& &= g \times \mathrm{mass} & &= 9.8\cdot 1500\cdot 4\Delta y=58{,}800\,\Delta y \textrm{N}\notag \end{eqnarray} \] The work performed in lifting this layer to height \(y\) is equal to the force times the distance \(y\), which is \((58{,}800\Delta y)y\). Setting \(L(y) = 58{,}800y\), we have \[ \boxed{\bbox[#FAF8ED,5pt]{ \textrm{Work lifting layer to height \(y\)} \approx (58{,}800\Delta y)y = L(y)\Delta y}} \]

This is only an approximation (although a very good one if \(\Delta y\) is small) because the layer has nonzero width and the cement particles at the top have been lifted a little bit higher than those at the bottom. The \(i\)th layer is lifted to height \(y_i\), so the total work performed is \[ W \approx \sum_{i=1}^n L(y_i)\,\Delta y \] This sum is a right-endpoint approximation to \(\int_0^5 L(y)\, dy\). Letting \(n\to\infty\), we obtain \[ W=\int_0^5 L(y)\, dy=\int_0^5 58{,}800 y\, dy = 58{,}800\frac{y^2}{2}\bigg|_0^5 = 735{,}000 \textrm{J} \]

In Examples 6 and 7, the work performed on a thin layer is written \[ L(y)\Delta y \] When we take the sum and let \(\Delta y\) approach zero, we obtain the integral of \(L(y)\). Symbolically, the \(\Delta y\) “becomes” the \(dy\) of the integral. Note that \[ \begin{align*} L(y) = g \;\times&\; density \times A(y)\\ &\times (vertical~distance~lifted) \end{align*} \] where \(A(y)\) is the area of the cross section.

EXAMPLE 7 Pumping Water out of a Tank

A spherical tank of radius \(R\) meters is filled with water. Calculate the work \(W\) performed (against gravity) in pumping out the water through a small hole at the top. The density of water is \(1000 \mathrm{kg\text{/}m}^3\).

Solution The first step, as in the previous example, is to compute the work against gravity performed on a thin layer of water of width \(\Delta y\). We place the origin of our coordinate system at the center of the sphere because this leads to a simple formula for the radius \(r\) of the cross section at height \(y\) (Figure 6.50).

Figure 6.50: The sphere is divided into \(N\) thin layers.

Step 1. Compute work performed on a layer.

Figure 6.50 shows that the cross section at height \(y\) is a circle of radius \(r = \sqrt{R^2-y^2}\) and area \(A(y) = \pi r^2 = \pi(R^2 - y^2)\). A thin layer has volume \(A(y)\Delta y\), and to lift it, we must exert a force against gravity equal to \[ \begin{alignat*}{2} \textrm{Force on layer}& = g \times \overbrace{\textrm{density}\times A(y)\Delta y}^{\textrm{mass}}&&\approx (9.8) 1000\pi(R^2 - y^2) \Delta y \end{alignat*} \] The layer has to be lifted a vertical distance \(R-y\), so \[ \begin{align*} \boxed{\bbox[#FAF8ED,5pt]{ \textrm{Work on layer} \approx \overbrace{9800\pi(R^2 - y^2)\Delta y}^{\textrm{Force against gravity}}\,\,\, \times \overbrace{(R-y)}^{\textrm{Vertical distance lifted}} = L(y)\Delta y}} \end{align*} \] where \(L(y)=9800\pi(R^3-R^2y -Ry^2+y^3)\).

Step 2. Compute total work.

Now divide the sphere into \(N\) layers and let \(y_i\) be the height of the \(i\)th layer. The work performed on \(i\)th layer is approximately \(L(y_i)\,\Delta y\), and therefore \[ W \approx \sum_{i=1}^N L(y_i),\Delta y \]

This sum approaches the integral of \(L(y)\) as \(N\to \infty\) (that is, \(\Delta y \to 0\)), so \[ \begin{align} W &= \int_{-R}^RL(y)\,dy =9800\pi\int_{-R}^R(R^3-R^2y -Ry^2+y^3)\,dy\notag\\ & = 9800\pi \left(R^3y-\frac12R^2y^2-\frac13Ry^3+\frac14y^4 \right)\bigg|_{-R}^R = \frac{39{,}200\pi}3\,R^4 \textrm{J}\notag \end{align} \] Note that the integral extends from \(-R\) to \(R\) because the \(y\)-coordinate along the sphere varies from \(-R\) to \(R\).