PhysicsLAB: LabPro: Uniformly Accelerated Motion

PhysicsLAB

Lab
LabPro: Uniformly Accelerated Motion

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Purpose

This lab is going to investigate and collect data from rolling carts up and down inclined planes using combinations of these modes of linear acceleration:

Speeding up away from the detector
Slowing down away from the detector
Slowing down towards the detector
Speeding up towards the detector

Materials

LabPro Interface
Motion Detector w/ C-clamp
USB Cable
DIG/Sonic Cable
Wooden Ramp
Wooden Cart

Under the Start Menu, Follow:

Start > Programs > Vernier Software > Logger Pro 3.1

Logger Pro 3.1 should automatically set up graphs according to the connected sensors. With the Motion Detector properly connected, the program should display graphs of position versus time and velocity versus time.

Elevate one side of the wooden ramp with a stool and fasten the Motion Detector to the end of the ramp with a C-clamp.

When you are ready to obtain data, hit the "Collect" button on the top right-hand side of the program window.

Note: Do not allow the cart to roll within roughly 0.4 meters of the sensor during collection. This will cause faulty returns and skew the data.

Target Graphs

Your purpose is to learn how to tilt the boards and roll your cart so as to recreate each of the following position-time graphs. Once obtained, sketch each accompanying velocity-time graphs on the "green axes" provided.

Conclusions

Refer to the following information for the next three questions.

1. What is the generic shape during accelerated motion for each of the following. Choose one of the following three terms: horizontal line, oblique line, parabola

(a) position-time graph?

horizontal lineoblique lineparabola

(b) velocity-time graph?

horizontal lineoblique lineparabola

(c) acceleration-time graph?

horizontal lineoblique lineparabola

Refer to the following information for the next two questions.

2. Choose the two (2) types of activity which resulted in your position-time graph

(a) moving to a higher final vertical position

speeding up while going away from the detector
slowing down while going away from the detector
speeding up while coming towards the detector
slowing down while coming towards the detector

(b) moving to a lower final vertical position

speeding up while going away from the detector
slowing down while going away from the detector
speeding up while coming towards the detector
slowing down while coming towards the detector

Refer to the following information for the next two questions.

3. Choose the two (2) types of activity which resulted in your velocity-time graph being drawn

(a) in quadrant I

speeding up while going away from the detector
slowing down while going away from the detector
speeding up while coming towards the detector
slowing down while coming towards the detector

(b) in quadrant IV

speeding up while going away from the detector
slowing down while going away from the detector
speeding up while coming towards the detector
slowing down while coming towards the detector

Refer to the following information for the next two questions.

4. Describe the two (2) types of activity which resulted in your velocity-time graph

having a positive slope - - that is a > 0.

speeding up while going away from the detector
slowing down while going away from the detector
speeding up while coming towards the detector
slowing down while coming towards the detector

In which quadrant I or IV would an accompanying acceleration vs time graph for these activities be drawn?

IIV

Refer to the following information for the next two questions.

5. Describe the two (2) types of activity which resulted in your velocity-time graph

having a negative slope - - that is a < 0.

speeding up while going away from the detector
slowing down while going away from the detector
speeding up while coming towards the detector
slowing down while coming towards the detector

In which quadrant I or IV would an accompanying acceleration vs time graph for these activities be drawn?

IIV

Refer to the following information for the next eleven questions.

6. These graphs represent a related "set." Show how you either obtained or verified the requested information from the diagram which accompanies each question. Neatly, show your calculations for each answer.

According to these graphs, for how many seconds did the experiment last?

What was the cart's initial position?

In which direction was the cart moving?

towards the detectoraway from the detector

What was the cart's initial speed?

What was the cart's final speed?

Was the cart speeding up or slowing down?

speeding upslowing down

According to the velocity-time provided, what total distance did the cart travel along the ramp?

What is the numerical value of P on the position-time graph provided?

According to the velocity-time graph provided, what was the numerical value of the cart's acceleration?

What is the numerical value of A on the acceleration-time?

According to the acceleration-time graph, what was the change in the cart's velocity?

Refer to the following information for the next question.

7. On the position-time graph provided, sketch the following "story."

A turtle starts from a state of rest 1 meter from the side of a busy road. After waiting for 5 seconds and watching for on-coming traffic, the turtle decides that it is safe to cross the 6 meter-wide road. He takes 3 seconds to accelerate as he moves up to the edge of the road. Keeping his final speed constant, the turtle hurries across the road in 9 seconds. As soon as he successfully reaches the other side of the road, he takes 2 more seconds to quickly slow to a stop 1 meter off the road in the deep, cool grass.

What was the turtle's average speed during his journey?

Related Documents

Lab:	Labs - A Photoelectric Effect Analogy Labs - Acceleration Down an Inclined Plane Labs - Ballistic Pendulum: Muzzle Velocity Labs - Coefficient of Friction Labs - Coefficient of Kinetic Friction (pulley, incline, block) Labs - Collision Pendulum: Muzzle Velocity Labs - Conservation of Momentum Labs - Cookie Sale Problem Labs - Flow Rates Labs - Freefall Mini-Lab: Reaction Times Labs - Freefall: Timing a Bouncing Ball Labs - Galileo Ramps Labs - Gravitational Field Strength Labs - Home to School Labs - InterState Map Labs - LAB: Ramps - Accelerated Motion Labs - LabPro: Newton's 2nd Law Labs - Mass of a Rolling Cart Labs - Moment of Inertia of a Bicycle Wheel Labs - Monkey and the Hunter Animation Labs - Monkey and the Hunter Screen Captures Labs - Projectiles Released at an Angle Labs - Ramps: Sliding vs Rolling Labs - Range of a Projectile Labs - Roller Coaster, Projectile Motion, and Energy Labs - Rube Goldberg Challenge Labs - Target Lab: Ball Bearing Rolling Down an Inclined Plane Labs - Terminal Velocity Labs - Video LAB: A Gravitron Labs - Video Lab: Ball Bouncing Across a Stage Labs - Video LAB: Ball Re-Bounding From a Wall Labs - Video Lab: Cart Push #2 and #3 Labs - Video Lab: Falling Coffee Filters Labs - Video Lab: Two-Dimensional Projectile Motion
Resource Lesson:	RL - Accelerated Motion: A Data Analysis Approach RL - Accelerated Motion: Velocity-Time Graphs RL - Analyzing SVA Graph Combinations RL - Average Velocity - A Calculus Approach RL - Chase Problems RL - Chase Problems: Projectiles RL - Comparing Constant Velocity Graphs of Position-Time & Velocity-Time RL - Constant Velocity: Position-Time Graphs RL - Constant Velocity: Velocity-Time Graphs RL - Derivation of the Kinematics Equations for Uniformly Accelerated Motion RL - Derivatives: Instantaneous vs Average Velocities RL - Directions: Flash Cards RL - Freefall: Horizontally Released Projectiles (2D-Motion) RL - Freefall: Projectiles in 1-Dimension RL - Freefall: Projectiles Released at an Angle (2D-Motion) RL - Monkey and the Hunter RL - Summary: Graph Shapes for Constant Velocity RL - Summary: Graph Shapes for Uniformly Accelerated Motion RL - SVA: Slopes and Area Relationships RL - Vector Resultants: Average Velocity
Review:	REV - Test #1: APC Review Sheet
Worksheet:	APP - Hackensack APP - The Baseball Game APP - The Big Mac APP - The Cemetary APP - The Golf Game APP - The Spring Phling CP - 2D Projectiles CP - Dropped From Rest CP - Freefall CP - Non-Accelerated and Accelerated Motion CP - Tossed Ball CP - Up and Down NT - Average Speed NT - Back-and-Forth NT - Crosswinds NT - Headwinds NT - Monkey Shooter NT - Pendulum NT - Projectile WS - Accelerated Motion: Analyzing Velocity-Time Graphs WS - Accelerated Motion: Graph Shape Patterns WS - Accelerated Motion: Practice with Data Analysis WS - Advanced Properties of Freely Falling Bodies #1 WS - Advanced Properties of Freely Falling Bodies #2 WS - Advanced Properties of Freely Falling Bodies #3 WS - Average Speed and Average Velocity WS - Average Speed Drill WS - Charged Projectiles in Uniform Electric Fields WS - Chase Problems #1 WS - Chase Problems #2 WS - Chase Problems: Projectiles WS - Combining Kinematics and Dynamics WS - Constant Velocity: Converting Position and Velocity Graphs WS - Constant Velocity: Position-Time Graphs #1 WS - Constant Velocity: Position-Time Graphs #2 WS - Constant Velocity: Position-Time Graphs #3 WS - Constant Velocity: Velocity-Time Graphs #1 WS - Constant Velocity: Velocity-Time Graphs #2 WS - Constant Velocity: Velocity-Time Graphs #3 WS - Converting s-t and v-t Graphs WS - Energy Methods: More Practice with Projectiles WS - Energy Methods: Projectiles WS - Force vs Displacement Graphs WS - Freefall #1 WS - Freefall #2 WS - Freefall #3 WS - Freefall #3 (Honors) WS - Horizontally Released Projectiles #1 WS - Horizontally Released Projectiles #2 WS - Kinematics Along With Work/Energy WS - Kinematics Equations #1 WS - Kinematics Equations #2 WS - Kinematics Equations #3: A Stop Light Story WS - Lab Discussion: Gravitational Field Strength and the Acceleration Due to Gravity WS - Position-Time Graph "Story" Combinations WS - Projectiles Released at an Angle WS - Rotational Kinetic Energy WS - SVA Relationships #1 WS - SVA Relationships #2 WS - SVA Relationships #3 WS - SVA Relationships #4 WS - SVA Relationships #5 WS - Work and Energy Practice: An Assortment of Situations TB - 2A: Introduction to Motion TB - 2B: Average Speed and Average Velocity TB - Antiderivatives and Kinematics Functions TB - Honors: Average Speed/Velocity TB - Kinematics Derivatives TB - Projectile Summary TB - Projectile Summary TB - Projectiles Mixed (Vertical and Horizontal Release) TB - Projectiles Released at an Angle TB - Set 3A: Projectiles

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