1.6: Motion Equations for Constant Acceleration in One Dimension

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Learning Objectives

Calculate displacement of an object that is not accelerating, given initial position and velocity.
Calculate final velocity of an accelerating object, given initial velocity, acceleration, and time.
Calculate displacement and final position of an accelerating object, given initial position, initial velocity, time, and acceleration.

**Figure** \(\PageIndex{1}\): Kinematic equations can help us describe and predict the motion of moving objects such as these kayaks racing in Newbury, England. (credit: Barry Skeates, Flickr)

We might know that the greater the acceleration of, say, a car moving away from a stop sign, the greater the displacement in a given time. But we have not developed a specific equation that relates acceleration and displacement. In this section, we develop some convenient equations for kinematic relationships, starting from the definitions of displacement, velocity, and acceleration already covered.

Notation: t, x, v, a

First, let us make some simplifications in notation. Taking the initial time to be zero, as if time is measured with a stopwatch, is a great simplification. Since elapsed time is \(\Delta t=t_{\mathrm{f}}-t_{0}\), taking \(t_{0}=0\) means that \(\Delta t=t_{\mathrm{f}}\), the final time on the stopwatch. When initial time is taken to be zero, we use the subscript 0 to denote initial values of position and velocity. That is, \(x_{0}\) is the initial position and \(v_{0}\) is the initial velocity. We put no subscripts on the final values. That is, \(t\) is the final time, \(x\) is the final position, and \(v\) is the final velocity. This gives a simpler expression for elapsed time—now, \(\Delta t=t\). It also simplifies the expression for displacement, which is now \(\Delta x=x-x_{0}\). Also, it simplifies the expression for change in velocity, which is now \(\Delta v=v-v_{0}\). To summarize, using the simplified notation, with the initial time taken to be zero,

\[\left.\begin{array}{l}
\Delta t=t \\
\Delta x=x-x_{0} \\
\Delta v=v-v_{0}
\end{array}\right\} \nonumber \]

where the subscript 0 denotes an initial value and the absence of a subscript denotes a final value in whatever motion is under consideration.

We now make the important assumption that acceleration is constant. This assumption allows us to avoid using calculus to find instantaneous acceleration. Since acceleration is constant, the average and instantaneous accelerations are equal. That is,

\[\bar{a}=a=\text { constant } \nonumber \]

so we use the symbol \(a\) for acceleration at all times. Assuming acceleration to be constant does not seriously limit the situations we can study nor degrade the accuracy of our treatment. For one thing, acceleration is constant in a great number of situations. Furthermore, in many other situations we can accurately describe motion by assuming a constant acceleration equal to the average acceleration for that motion. Finally, in motions where acceleration changes drastically, such as a car accelerating to top speed and then braking to a stop, the motion can be considered in separate parts, each of which has its own constant acceleration.

SOLVING FOR DISPLACEMENT (Δx) AND FINAL POSITION (\(x\)) FROM AVERAGE VELOCITY WHEN ACCELERATION (\(a\)) IS CONSTANT

To get our first two new equations, we start with the definition of average velocity:

\[\bar{v}=\frac{\Delta x}{\Delta t}. \nonumber \]

Substituting the simplified notation for Δx and Δt yields

\[\bar{v}=\frac{x-x_{0}}{t}. \nonumber \]

Solving for \(x\) yields

\[x=x_{0}+\bar{v} t, \nonumber \]

where the average velocity is

\[\bar{v}=\frac{v_{0}+v}{2}(\operatorname{constant} a). \nonumber \]

The equation \(\bar{v}=\frac{v_{0}+v}{2}\) reflects the fact that, when acceleration is constant, \(v\) is just the simple average of the initial and final velocities. For example, if you steadily increase your velocity (that is, with constant acceleration) from 30 to 60 km/h, then your average velocity during this steady increase is 45 km/h. Using the equation \(\bar{v}=\frac{v_{0}+v}{2}\) to check this, we see that

\[\bar{v}=\frac{v_{0}+v}{2}=\frac{30 \mathrm{~km} / \mathrm{h}+60 \mathrm{~km} / \mathrm{h}}{2}=45 \mathrm{~km} / \mathrm{h}, \nonumber\]

which seems reasonable.

Example \(\PageIndex{1}\): Calculating Displacement: How Far does the Jogger Run?

A jogger runs down a straight stretch of road with an average velocity of 4.00 m/s for 2.00 min. What is his final position, taking his initial position to be zero?

Strategy

Draw a sketch.

The final position \(x\) is given by the equation

\[x=x_{0}+\bar{v} t. \nonumber\]

To find \(x\), we identify the values of \(x_{0}\), \(\bar{v}\), and \(t\) from the statement of the problem and substitute them into the equation.

Solution

1. Identify the knowns. \(\bar{v}=4.00 \mathrm{~m} / \mathrm{s}, \ \Delta t=2.00 \mathrm{~min}\), and \(x_{0}=0 \mathrm{~m}\).

2. Enter the known values into the equation.

\[x=x_{0}+\bar{v} t=0+(4.00 \mathrm{~m} / \mathrm{s})(120 \mathrm{~s})=480 \mathrm{~m} \nonumber \]

Discussion

Velocity and final displacement are both positive, which means they are in the same direction.

The equation \(x=x_{0}+\bar{v} t\) gives insight into the relationship between displacement, average velocity, and time. It shows, for example, that displacement is a linear function of average velocity. (By linear function, we mean that displacement depends on \(\bar{v}\) rather than on \(\bar{v}\) raised to some other power, such as \(\bar{v}^{2}\). When graphed, linear functions look like straight lines with a constant slope.) On a car trip, for example, we will get twice as far in a given time if we average 90 km/h than if we average 45 km/h.

**Figure** \(\PageIndex{3}\): There is a linear relationship between displacement and average velocity. For a given time \(t\), an object moving twice as fast as another object will move twice as far as the other object.

SOLVING FOR FINAL VELOCITY

We can derive another useful equation by manipulating the definition of acceleration.

\[a=\frac{\Delta v}{\Delta t} \nonumber \]

Substituting the simplified notation for Δv and Δt gives us

\[a=\frac{v-v_{0}}{t}(\text { constant } a). \nonumber \]

Solving for \(v\) yields

\[v=v_{0}+a t(\text { constant } a). \nonumber \]

Example \(\PageIndex{2}\): Calculating Final Velocity: An Airplane Slowing Down after Landing

An airplane lands with an initial velocity of 70.0 m/s and then slows down at \(1.50 \mathrm{~m} / \mathrm{s}^{2}\) for 40.0 s. What is its final velocity?

Strategy

Draw a sketch. We draw the acceleration vector in the direction opposite the velocity vector because the plane is slowing down.

Solution

1. Identify the knowns. \(v_{0}=70.0 \mathrm{~m} / \mathrm{s}, \ a=-1.50 \mathrm{~m} / \mathrm{s}^{2}, \ t=40.0 \mathrm{~s}\).

2. Identify the unknown. In this case, it is final velocity, \(v_{\mathrm{f}}\).

3. Determine which equation to use. We can calculate the final velocity using the equation \(v=v_{0}+a t\).

4. Plug in the known values and solve.

\[v=v_{0}+a t=70.0 \mathrm{~m} / \mathrm{s}+\left(-1.50 \mathrm{~m} / \mathrm{s}^{2}\right)(40.0 \mathrm{~s})=10.0 \mathrm{~m} / \mathrm{s} \nonumber\]

Discussion

The final velocity is much less than the initial velocity, as desired when slowing down, but still positive. With jet engines, reverse thrust could be maintained long enough to stop the plane and start moving it backward. That would be indicated by a negative final velocity, which is not the case here.

**Figure** \(\PageIndex{5}\): The airplane lands with an initial velocity of 70.0 m/s and slows to a final velocity of 10.0 m/s before heading for the terminal. Note that the acceleration is negative because its direction is opposite to its velocity, which is positive.

In addition to being useful in problem solving, the equation \(v=v_{0}+a t\) gives us insight into the relationships among velocity, acceleration, and time. From it we can see, for example, that

final velocity depends on how large the acceleration is and how long it lasts
if the acceleration is zero, then the final velocity equals the initial velocity \(\left(v=v_{0}\right)\), as expected (i.e., velocity is constant)
if \(a\) is negative, then the final velocity is less than the initial velocity

All of these observations fit our intuition, and it is always useful to examine basic equations in light of our intuition and experiences to check that they do indeed describe nature accurately.

MAKING CONNECTIONS: REAL-WORLD CONNECTION

**Figure** \(\PageIndex{6}\): The Space Shuttle *Endeavor* blasts off from the Kennedy Space Center in February 2010. (credit: Matthew Simantov, Flickr)

An intercontinental ballistic missile (ICBM) has a larger average acceleration than the Space Shuttle and achieves a greater velocity in the first minute or two of flight (actual ICBM burn times are classified—short-burn-time missiles are more difficult for an enemy to destroy). But the Space Shuttle obtains a greater final velocity, so that it can orbit the earth rather than come directly back down as an ICBM does. The Space Shuttle does this by accelerating for a longer time.

SOLVING FOR FINAL POSITION WHEN VELOCITY IS NOT CONSTANT (a≠0)

We can combine the equations above to find a third equation that allows us to calculate the final position of an object experiencing constant acceleration. We start with

\[v=v_{0}+a t. \nonumber\]

Adding \(v_{0}\) to each side of this equation and dividing by 2 gives

\[\frac{v_{0}+v}{2}=v_{0}+\frac{1}{2} a t. \nonumber\]

Since \(\frac{v_{0}+v}{2}=\bar{v}\) for constant acceleration, then

\[\bar{v}=v_{0}+\frac{1}{2} a t. \nonumber \]

Now we substitute this expression for \(\bar{v}\) into the equation for displacement, \(x=x_{0}+\bar{v} t\), yielding

\[x=x_{0}+v_{0} t+\frac{1}{2} a t^{2}(\text { constant } a). \nonumber \]

Example \(\PageIndex{3}\): Calculating Displacement of an Accelerating Object: Dragsters

Dragsters can achieve average accelerations of \(26.0 \mathrm{~m} / \mathrm{s}^{2}\). Suppose such a dragster accelerates from rest at this rate for 5.56 s. How far does it travel in this time?

**Figure** \(\PageIndex{7}\): U.S. Army Top Fuel pilot Tony “The Sarge” Schumacher begins a race with a controlled burnout. (credit: Lt. Col. William Thurmond. Photo Courtesy of U.S. Army.)

Strategy

Draw a sketch.

We are asked to find displacement, which is \(x\) if we take \(x_{0}\) to be zero. (Think about it like the starting line of a race. It can be anywhere, but we call it 0 and measure all other positions relative to it.) We can use the equation \(x=x_{0}+v_{0} t+\frac{1}{2} a t^{2}\) once we identify \(v_{0}\), \(a\), and \(t\) from the statement of the problem.

Solution

1. Identify the knowns. Starting from rest means that \(v_{0}=0\), \(a\) is given as \(26.0 \mathrm{~m} / \mathrm{s}^{2}\) and \(t\) is given as 5.56 s.

2. Plug the known values into the equation to solve for the unknown \(x\):

\[x=x_{0}+v_{0} t+\frac{1}{2} a t^{2}. \nonumber\]

Since the initial position and velocity are both zero, this simplifies to

\[x=\frac{1}{2} a t^{2}. \nonumber\]

Substituting the identified values of \(a\) and \(t\) gives

\[x=\frac{1}{2}\left(26.0 \mathrm{~m} / \mathrm{s}^{2}\right)(5.56 \mathrm{~s})^{2}, \nonumber\]

yielding

\[x=402 \mathrm{~m}. \nonumber\]

Discussion

If we convert 402 m to miles, we find that the distance covered is very close to one quarter of a mile, the standard distance for drag racing. So the answer is reasonable. This is an impressive displacement in only 5.56 s, but top-notch dragsters can do a quarter mile in even less time than this.

What else can we learn by examining the equation \(x=x_{0}+v_{0} t+\frac{1}{2} a t^{2}\) We see that:

displacement depends on the square of the elapsed time when acceleration is not zero. In Example \(\PageIndex{3}\), the dragster covers only one fourth of the total distance in the first half of the elapsed time
if acceleration is zero, then the initial velocity equals average velocity \(\left(v_{0}=\bar{v}\right)\) and \(x=x_{0}+v_{0} t+\frac{1}{2} a t^{2}\) becomes \(x=x_{0}+v_{0} t\)

SOLVING FOR FINAL VELOCITY WHEN VELOCITY IS NOT CONSTANT (a≠0)

A fourth useful equation can be obtained from another algebraic manipulation of previous equations.

If we solve \(v=v_{0}+a t\) for \(t\), we get

\[t=\frac{v-v_{0}}{a}. \nonumber \]

Substituting this and \(\bar{v}=\frac{v_{0}+v}{2}\) into \(x=x_{0}+\bar{v} t\), we get

\[v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right)(\text { constant } a). \nonumber \]

Example \(\PageIndex{4}\): Calculating Final Velocity: Dragsters

Calculate the final velocity of the dragster in Example \(\PageIndex{3}\) without using information about time.

Strategy

Draw a sketch.

The equation \(v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right)\) is ideally suited to this task because it relates velocities, acceleration, and displacement, and no time information is required.

Solution

1. Identify the known values. We know that \(v_{0}=0\), since the dragster starts from rest. Then we note that \(x-x_{0}=402 \mathrm{~m}\) (this was the answer in Example \(\PageIndex{3}\)). Finally, the average acceleration was given to be \(a=26.0 \mathrm{~m} / \mathrm{s}^{2}\).

2. Plug the knowns into the equation \(v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right)\) and solve for \(v\).

\[v^{2}=0+2\left(26.0 \mathrm{~m} / \mathrm{s}^{2}\right)(402 \mathrm{~m}). \nonumber\]

Thus

\[v^{2}=2.09 \times 10^{4} \mathrm{~m}^{2} / \mathrm{s}^{2}. \nonumber\]

To get \(v\), we take the square root:

\[v=\sqrt{2.09 \times 10^{4} \mathrm{~m}^{2} / \mathrm{s}^{2}}=145 \mathrm{~m} / \mathrm{s} . \nonumber\]

Discussion

145 m/s is about 522 km/h or about 324 mi/h, but even this breakneck speed is short of the record for the quarter mile. Also, note that a square root has two values; we took the positive value to indicate a velocity in the same direction as the acceleration.

An examination of the equation \(v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right)\) can produce further insights into the general relationships among physical quantities:

The final velocity depends on how large the acceleration is and the distance over which it acts
For a fixed magnitude of acceleration, a car that is going twice as fast doesn’t simply stop in twice the distance—it takes much further to stop. (This is why we have reduced speed zones near schools.)

Putting Equations Together

In the following examples, we further explore one-dimensional motion, but in situations requiring slightly more algebraic manipulation. The examples also give insight into problem-solving techniques. The box below provides easy reference to the equations needed.

SUMMARY OF KINEMATIC EQUATIONS (CONSTANT \(a\))

\[\begin{gathered}
x=x_{0}+\bar{v} t \\
\bar{v}=\frac{v_{0}+v}{2} \\
v=v_{0}+a t \\
x=x_{0}+v_{0} t+\frac{1}{2} a t^{2} \\
v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right)
\end{gathered} \nonumber\]

Example \(\PageIndex{5}\): Calculating Displacement: How Far Does a Car Go When Coming to a Halt?

On dry concrete, suppose a car can slow down at a rate of \(7.00 \mathrm{~m} / \mathrm{s}^{2}\), whereas on wet concrete the maximum magnitude of acceleration is only \(5.00 \mathrm{~m} / \mathrm{s}^{2}\). Find the distances necessary to stop a car moving at 30.0 m/s (about 110 km/h) (a) on dry concrete and (b) on wet concrete. (c) Repeat both calculations, finding the displacement from the point where the driver sees a traffic light turn red, taking into account his reaction time of 0.500 s to get his foot on the brake.

Strategy

Draw a sketch.

In order to determine which equations are best to use, we need to list all of the known values and identify exactly what we need to solve for. We shall do this explicitly in the next several examples, using tables to set them off.

Solution for (a)

1. Identify the knowns and what we want to solve for. We know that \(v_{0}=30.0 \mathrm{~m} / \mathrm{s} ; \ v=0 ; \ a=-7.00 \mathrm{~m} / \mathrm{s}^{2}\) (\(a\) is negative because it is in a direction opposite to velocity). We take \(x_{0}\) to be 0. We are looking for displacement \(\Delta x\), or \(x-x_{0}\).

2. Identify the equation that will help up solve the problem. The best equation to use is

\[v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right). \nonumber\]

This equation is best because it includes only one unknown, \(x\). We know the values of all the other variables in this equation. (There are other equations that would allow us to solve for \(x\), but they require us to know the stopping time, \(t\), which we do not know. We could use them but it would entail additional calculations.)

3. Rearrange the equation to solve for \(x\).

\[x-x_{0}=\frac{v^{2}-v_{0}^{2}}{2 a} \nonumber\]

4. Enter known values.

\[x-0=\frac{0^{2}-(30.0 \mathrm{~m} / \mathrm{s})^{2}}{2\left(-7.00 \mathrm{~m} / \mathrm{s}^{2}\right)} \nonumber\]

Thus,

\[x=64.3 \mathrm{~m} \text { on dry concrete. } \nonumber\]

Solution for (b)

This part can be solved in exactly the same manner as Part A. The only difference is that the acceleration is \(-5.00 \mathrm{~m} / \mathrm{s}^{2}\). The result is

\[x_{\text {wet }}=90.0 \mathrm{~m} \text { on wet concrete. }. \nonumber\]

Solution for (c)

Once the driver reacts, the stopping distance is the same as it is in Parts A and B for dry and wet concrete. So to answer this question, we need to calculate how far the car travels during the reaction time, and then add that to the stopping time. It is reasonable to assume that the velocity remains constant during the driver’s reaction time.

1. Identify the knowns and what we want to solve for. We know that \(\bar{v}=30.0 \mathrm{~m} / \mathrm{s} ; \ t_{\text {reaction }}=0.500 \mathrm{~s} ; \ a_{\text {reaction }}=0\). We take \(x_{0 \text {-reaction }}\) to be 0. We are looking for \(x_{reaction}\).

2. Identify the best equation to use.

\(x=x_{0}+\bar{v} t\) works well because the only unknown value is \(x\), which is what we want to solve for.

3. Plug in the knowns to solve the equation.

\[x=0+(30.0 \mathrm{~m} / \mathrm{s})(0.500 \mathrm{~s})=15.0 \mathrm{~m}. \nonumber\]

This means the car travels 15.0 m while the driver reacts, making the total displacements in the two cases of dry and wet concrete 15.0 m greater than if he reacted instantly.

4. Add the displacement during the reaction time to the displacement when braking.

\[x_{\text {braking }}+x_{\text {reaction }}=x_{\text {total }} \nonumber\]

64.3 m + 15.0 m = 79.3 m when dry
90.0 m + 15.0 m = 105 m when wet

**Figure** \(\PageIndex{11}\): The distance necessary to stop a car varies greatly, depending on road conditions and driver reaction time. Shown here are the braking distances for dry and wet pavement, as calculated in this example, for a car initially traveling at 30.0 m/s. Also shown are the total distances traveled from the point where the driver first sees a light turn red, assuming a 0.500 s reaction time.

Discussion

The displacements found in this example seem reasonable for stopping a fast-moving car. It should take longer to stop a car on wet rather than dry pavement. It is interesting that reaction time adds significantly to the displacements. But more important is the general approach to solving problems. We identify the knowns and the quantities to be determined and then find an appropriate equation. There is often more than one way to solve a problem. The various parts of this example can in fact be solved by other methods, but the solutions presented above are the shortest.

With the basics of kinematics established, we can go on to many other interesting examples and applications. In the process of developing kinematics, we have also glimpsed a general approach to problem solving that produces both correct answers and insights into physical relationships.

MAKING CONNECTIONS: TAKE-HOME EXPERIMENT—BREAKING NEWS

We have been using SI units of meters per second squared to describe some examples of acceleration of cars, runners, and trains. To achieve a better feel for these numbers, one can measure the braking acceleration of a car doing a slow (and safe) stop. Recall that, for average acceleration, \(\bar{a}=\Delta v / \Delta t\). While traveling in a car, slowly apply the brakes as you come up to a stop sign. Have a passenger note the initial speed in miles per hour and the time taken (in seconds) to stop. From this, calculate the acceleration in miles per hour per second. Convert this to meters per second squared and compare with other accelerations mentioned in this chapter. Calculate the distance traveled in braking.

Exercise \(\PageIndex{1}\)

A manned rocket accelerates at a rate of \(20 \mathrm{~m} / \mathrm{s}^{2}\) during launch. How long does it take the rocket reach a velocity of 400 m/s?

Answer

To answer this, choose an equation that allows you to solve for time \(t\), given only \(a\), \(v_{0}\), and \(v\).

\[v=v_{0}+a t \nonumber\]

Rearrange to solve for \(t\).

\[t=\frac{v-v_{0}}{a}=\frac{400 \mathrm{~m} / \mathrm{s}-0 \mathrm{~m} / \mathrm{s}}{20 \mathrm{~m} / \mathrm{s}^{2}}=20 \mathrm{~s} \nonumber\]

Section Summary

To simplify calculations we take acceleration to be constant, so that \(\bar{a}=a\) at all times.
We also take initial time to be zero.
Initial position and velocity are given a subscript 0; final values have no subscript. Thus,
\[\left.\begin{array}{l}
\Delta t=t \\
\Delta x=x-x_{0} \\
\Delta v=v-v_{0}
\end{array}\right\} \nonumber\]
The following kinematic equations for motion with constant \(a\) are useful:
\[\begin{gathered}
x=x_{0}+\bar{v} t \\
\bar{v}=\frac{v_{0}+v}{2} \\
v=v_{0}+a t \\
x=x_{0}+v_{0} t+\frac{1}{2} a t^{2} \\
v^{2}=v_{0}^{2}+2 a\left(x-x_{0}\right)
\end{gathered} \nonumber\]
In vertical motion, \(y\) is substituted for \(x\).