Describing Mo tion. Speed and Velocity. What is speed?

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CHAPTER 1 LESSON 2 Describing Mo tion Speed and Velocity Key Concepts What is speed? How can you use a dis tance-time graph to calculate average speed? What are ways velocity can change? What do you think? Read the two statements below and decide whether you agree or disagree with them. Place an A in the Before column if you agree with the statement or a D if you disagree. After you ve read this lesson, reread the statements to see if you have changed your mind. Before Statement After 3. Constant speed is the same thing as average speed. 4. Velocity is another name for speed. Discuss What You Read Work with a partner. Read a paragraph to yourselves. Then discuss what you learned in the paragraph. Continue until you and your partner understand the main ideas of the lesson. Key Concept Check 1. Define What is speed? What is speed? How fast do you walk when you are hungry and you smell good food in the kitchen? How fast do you move when you have a difficult chore to do? Sometimes you move quickly. Other times you might move slowly. One way you can describe how fast you move is to determine your speed. Speed is the measure of the distance an object travels per unit of time. Units of Speed To calculate speed, divide the distance traveled by the time it takes to travel that distance. The units of speed are units of distance divided by units of time. The SI unit for speed is meters per second (m/s). There are other units of speed. Different units of distance and time can be used to express the speed an object is moving. The speed of an airplane might be expressed in kilometers per hour (km/h). The speed of a car on a highway might be expressed in miles per hour (mph). The typical speed of an airplane can be expressed as 245 m/s, or 882 km/h, or 548 mph. Similarly, the typical speed of a person walking can be expressed as 1.3 m/s, or 4.7 km/h, or 2.9 mph. 6 Describing Motion Reading Essentials

Constant speed s 2 s 4 s 6 s 4 2 m 1 m 2 m 3 m 4 m 5 m 6 m 7 m 8 m Changing speed s 2 s 4 s 6 s m 1 m 2 m 3 m 4 m 5 m 6 m 7 m 8 m Constant Speed What happens to a car s speed as the driver moves from one place to another? If the car is traveling on a highway, it might move at a steady speed. As a car moves away from a stop sign, the car s speed increases. The driver slows the car down to pull into a parking space. Think specifically about a time when a car s speed does not change. For example, the car in the top figure is moving at the same speed. In 1 s, the car moves 11 m. In 2 s, it moves 22 m. Each second, the car moves 11 m. Because the car moves the same distance each second, its speed is not changing. The speed of the car is constant. Constant speed is the rate of change of position in which the same distance is traveled each second. The car is moving at a co nstant speed of 11 m/s. Changing Speed The bottom half of the figure shows a car moving away from a stop sign with increasing speed. Between s and 2 s, the car at the bottom travels about 1 m. However, between 4 s and 6 s, the car travels more than 3 m. The car travels a different distance each second. Its speed is changing. If an object s speed is not constant, you might want to know its speed at a certain moment. Instantaneous speed is speed at a specific instant in time. You can see a car s instantaneous speed on its speedometer. 2. Identify Look at the speedometer of the bottom car. What is its instantaneous speed at 6 s? Reading Check 3. Calculate How would the distance the car travels each second change if it were slowing down? Reading Essentials Describing Motion 7

Math Skills Melissa shot a model rocket 36 m into the air. It took the rocket 4 s to fly that far. What was its average speed? distance: d = 36 m time: t = 4 s a. Find: average speed: v v = d t b. Substitute: v = 36 4 = 9 c. Determine the units: units of d units of v = units of t = m s = m/s The rocket s average speed = 9 m/s 4. Solve It takes Ahmed 5 s to bike to his friend s house 25 m away. What is his average speed? 5. Apply How far did Horse A travel in 8 s? Reading Check 6. State How is constant speed shown on a distancetime graph? Average Speed Describing an object s speed is easy if the speed is constant. But how can you describe the speed of an object when it is speeding up or slowing down? One way is to calculate the object s average speed. Average speed is the total distance traveled divided by the total time taken to travel that distance. The SI unit for speed, meters per second (m/s), is used in the equation below. You can use the equation to calculate average speed. You could use other units of distance and time, such as kilometers and hours, in the average speed equation. Average Speed Equation total distance (in m) average speed (in m/s) = total time (in s) v = d t Distance-Time Graphs During the Kentucky Derby, horses run a distance of 2 km. The speed of the horses changes many times during the race. You can create a graph that charts these changes in speed. But sometimes it is helpful to graph an object s motion if its speed does not change. The graph below describes what the motion of horse A and horse B might be if their speeds did not change. Notice that distance measurements are made every 2 seconds. Follow the height of the line from the left side of the graph to the right side. You can see how the distance that each horse ran changed over time. Distance (km) 1..5 Horse Race 2. Horse A Horse B 1.5 4 8 12 Time (s) Graphs like the one on the left show how one measurement compares to another. In the study of motion, the two measurements that are compared are time and distance. Graphs that show comparisons between time and distance are called distance-time graphs. Notice that the change in the distance the horses ran around the track is the same each second on the graph. This means the horses were moving at a constant speed. Constant speed is shown as a straight line on distance-time graphs. 8 Describing Motion Reading Essentials

Comparing Speeds on a Distance-Time Graph You can use distance-time graphs to compare the motion of two objects. The distance-time graph on the previous page compares the motion of two horses that ran the Kentucky Derby. The motion of horse A is shown by the solid line. The motion of horse B is shown by the dashed line. When horse A reached the finish line at 2 km from the starting point, horse B was 1.5 km from the starting point of the race. Recall that average speed is distance traveled divided by time. Horse A traveled a greater distance than horse B in the same amount of time. This means that horse A had greater average speed. Compare how steep the lines are on the graph. The measure of steepness is the slope. The line for horse A is steeper than the line for horse B. Steeper lines on distancetime graphs indicate faster speeds. Using a Distance-Time Graph to Calculate Speed You can use distance-time graphs to calculate the average speed of an obj ect. The graph below represents the motion of a trail horse traveling at a constant speed. The steps on the graph explain how to calculate average speed from a distance-time graph. Key Concept Check 7. Explain How can you use a distance-time graph to calculate average speed? 8. Compare How does the horse s average speed from 6 s to 12 s compare to its average speed from 12 s to 18 s? Distance (m) 1 8 6 4 2 Complete steps 1 4. Then divide the difference in distance by the difference in time: 3 m/6 s = 5 m/s. This value is the average speed of the horse from 6 s to 12 s. 2 Choose another point on the line. The point chosen here is (6, 3). 1 Choose one point on the line. The point chosen here is (12, 6). 3 Find the time difference of the points: 12-6 = 6. 2 4 6 8 1 12 14 16 18 2 Time (s) 5 Divide the difference in distance by the difference in time, 3 m = 5 m/s. 6 s 4 Find the distance difference of the points: 6-3 = 3. Reading Essentials Describing Motion 9

Make a three-tab book to summarize how changes in speed are represented on a distance-time graph. Slowing Down Stopping Speeding Up Distance-Time Graph and Changing Speed A straight line on a distance-time graph means that the object moved at a constant speed. The graph for the motion of a train is shown below. The graph is different because the speed of the train is not constant. The train speeded up, slowed down, and stopped. When the changes in speed are graphed, the train s motion is shown as a curved line. Slowing Down Notice the shape of the solid line on the graph. The line rises steeply at first. Then it levels off between 2 and 3 minutes. This means that the train is slowing down. Stopping Between 3 and 5 minutes, the graph line is horizontal. The train s distance from the starting point remains at 4 km. This horizontal line means that there is no motion. The train stopped between minutes 3 and 5. Speeding Up Between about 5 minutes and 1 minutes, the slope of the line increases. The upward curve means that the train was speeding up. Train s Distance v. Time 1 9. Identify Highlight the area on the graph where the train is stopped. Distance (km) 8 6 4 2 Starting point 5 Time (min) Ending point Average Speed Even when an object s speed is not constant, you can calculate its average speed from a distance-time graph. To calculate the average speed between any two points on the graph, follow these steps: Choose a starting point and ending point. Figure the change in distance between the two points. Figure the change in time between the two points. Substitute these values into the average speed equation. The slope of the dashed line shown above represents the train s average speed between minutes and 1 minutes. 1 1 Describing Motion Reading Essentials

Velocity Describing the speed of a moving object does not completely describe its motion. Motion is more than just speed. It also includes direction. Velocity is the speed and the direction of a moving object. Representing Velocity In Lesson 1, an arrow represented the displacement of an object from a reference point. An arrow can also be used to represent the velocity of an object. The length of the arrow indicates the speed. A greater speed is shown by a longer arrow. The arrow points in the direction of the object s motion. Imagine two people walking in the same direction at the same speed. They would have equal velocities. Arrows representing the people would point in the same direction and be the same length. But if the people were walking in opposite directions at the same speed, they would have different velocities. Arrows representing them would be the same length but be pointing in opposite directions. Changes in Velocity Look at the bouncing ball in the figure below. The arrows show the velocity of the ball. From one position to the next, the arrows change direction and length. This means that the velocity is changing. Velocity changes when the speed changes, the direction changes, or both the speed and the direction change. The velocity of the ball changes continually because both the speed and the direction of the ball change as the ball bounces. Velocity Key Concept Check 1. Explain How can velocity change? 11. Identify Are there any positions of the bouncing ball in which the velocity is the same? Explain. Reading Essentials Describing Motion 11

Mini Glossary average speed: the total distance traveled divided by the total time taken to travel that distance constant speed: the rate of change of position in which the same distance is traveled each second speed: the measure of the distance an object travels per unit of time velocity: the speed and the direction of a moving object instantaneous speed: the speed at a specific instant in time 1. Review the terms and their definitions in the Mini Glossary. Write a one-sentence example of two objects traveling at the same speed but with different velocities. 2. On the graph below, find point (2, 2). Label it A. Next find point (4, 4). Label it B. Draw a dotted line from point A along the 2 km line to the 4 s line. Next, draw a dotted line from point B along the 4 s line to the 2 km line. Use this graph to solve for average speed. 5 a. Difference in distance between points A and B: Distance (km) 4 3 2 1 2 4 6 Time (s) 3. Which idea that you and your partner discussed was hardest to understand? Write a question and the answer on the lines below to show that you understand the idea. What do you think Reread the statements at the beginning of the lesson. Fill in the After column with an A if you agree with the statement or a D if you disagree. Did you change your mind? b. Difference in time between points A and B: c. Average speed = d. Average speed = km/s ConnectED Log on to ConnectED.mcgraw-hill.com and access your textbook to find this lesson s resources. END OF LESSON 12 Describing Motion Reading Essentials

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