Calculate the theoretical acceleration of the lightest spherical object using Newton's second law. Then compare this to the averages when the distance relative to the ramp was 10, 20, and 30 cm using percent error calculations. (Include a free body diagram of the set-up in your solution) RICAL OBECT 1 MASS (kg)0.00271RICAL OBECT 2 MASS (kg)0.00898RICAL OBECT 3 MASS (kg)0.058GHTEST MASS AT DIFFERENT LENGTHS WITH CATCHERS 1 AND 2)Time from top to end of ramp and correspondingaccelerationsTrials for 10 cmCatcher 1 Knock-Trials for 20 cmCatcher 1 Knock-Trials for 30 cm rampCatcher 1 Knock-Time 1Time 2Time 3Ave.ramp distanceback Distanceramp distanceback Distance (cm)distanceback Distance (cm)0.290.310.420.3411.51.722.37812.08111.13371.8643122220.40.410.50.4366673131.832.42.52.37951.62.159833Ave.1.166666667Ave.1.833333333Ave.2.1333333330.50.50.50.520.5066672.42.42.21892.339633Catcher 2 Knock-Trials for 10 cmback DistanceTrials for 20 cmCatcher 2 Knock-Trials for 30 cm rampCatcher 2 Knock-ramp distance(cm)ramp distanceback Distance (cm)distanceback Distance (cm)mp distand0.005052253110.511.6mp distane0.00585314721.521.7mp distand0.006340405330.832Ave.Ave.0.933333333Ave.1.766666667HER SPHERICAL OBJECTS WITH CATCHER 1 AT 10 CM)SHPERICALSHPERICAL OBJECT23|ОBJECT NO.NO.Catcher 1 Knock-Trials for 10 cmback DistanceTrials for 10 cmCatcher 1 Knock-ramp distance(cm)ramp distanceback Distance (cm)3323.823.23434.3Ave.3.6Ave.3.5

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Description: Calculate the theoretical acceleration of the lightest spherical object using Newton's second law. Then compare this to the averages when the distance relative to the ramp was 10, 20, and 30 cm using percent error calculations. (Include a free body d

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Calculate the theoretical acceleration of the lightest spherical object using Newton's second law. Then compare this to the averages when the distance relative to the ramp was 10, 20, and 30 cm using percent error calculations. (Include a free body diagram of the set-up in your solution)

Calculate the theoretical acceleration of the lightest spherical object using Newton's second law. Then compare this to the averages when the distance relative to the ramp was 10, 20, and 30 cm using percent error calculations. (Include a free body diagram of the set-up in your solution)

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter28: Special Relativity

Section: Chapter Questions

Problem 37PE: (a) Find the momentum of a 1.00109 kg asteroid heading towards the Earth at 30.0 km/s. (b) Find the...

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