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Since the steepness remains the same and the steepness represents acceleration, we can also say that the acceleration of that cheetah is a constant. Meaning, the cheetah is gaining velocity. Its velocity is changing, but it's acceleration does not change with time.
Understanding Distance-Time Graphs Directions: Use your knowledge of distance-time graphs to answer the questions that follow. Part 1 1. What can be calculated using the distance-time graph above? Explain your reasoning. 2. What does the Tortoise’s line tell you about its speed? 3. What does the Hare’s line tell you about its speed?
What is the cheetah’s speed for the first four seconds? Show your work! 3. What can you infer about the event(s) that took place once the cheetah reached 120 meters? 3. Generate and organize your own data in a table, and use the data to create a line graph.
17 lip 2017 · Cheetahs hold the title of the world’s fastest land animal and can reach a top speed of 70 miles per hour. The Galápagos tortoise is roughly the same size as a cheetah, yet the fastest it...
If the cheetah spots a gazelle and runs twice its original speed to catch it, then there would be a change in both the position-time graph, velocity-time graph and also the motion map. The position-time graph would have a slope of 13.44 in/sec therefore the slope would be steeper.
Our expert guide to these big cats reveals how fast Cheetahs can run, how to identify, what they eat and where they live.
This classroom-tested graphing activity explores similarities and differences between Position vs. Time and Velocity vs. Time graphs. It accepts user inputs in creating prediction graphs, then generates an accurate comparison graph for the process being analyzed.
