Solve a and b We now focus on the take-off stage b to c in Figure 1.Squat stagelowest pointof squatA. mgB. 2.25 mgGRF, in terms of mgC.3 mgD. 0.5 mgStandstill-0.6aB. √0.5gdC. √1.25gdD. √2.5gd-0.4Step onforce plate-0.2Time (s)bpush offstageс0 Aa. What is the force at the lowest point of the squat (point b) if the person's mass m= 65 kg?Enter to 2 significant figuresNb. What is the peak force during the push-off if the person's mass m= 65 kg? Round to the upper gridmark on the graph.Enter to 2 significant figuresNIn airFor questions d-f, use the answers from the previous questions to solve for the current question.c. The take-off stage in the force-time graph occurs between the points b to c.From the plot, what is the approximate average GRF, (in terms of mg) during take-off (between b andc)?A rough estimate is fine.0.4 0.6d. Calculate the average acceleration during take-off in terms of the acceleration due to gravity g.A. 0B. 0.5 gC. 1.25 gD. 2 ge. Calculate the take-off velocity v in terms of the acceleration due to gravity g and the squat depth d.Pick from the following choices.A. 0f. Calculate the height during the jump in terms of the squat depth d.A. 0.5 dB. 1.0 dC. 1.25 dD. 2.5 d

Name: Solve a and b We now focus on the take-off stage b to c in Figure 1.Sq
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Description: Solve a and b We now focus on the take-off stage b to c in Figure 1.Squat stagelowest pointof squatA. mgB. 2.25 mgGRF, in terms of mgC.3 mgD. 0.5 mgStandstill-0.6aB. √0.5gdC. √1.25gdD. √2.5gd-0.4Step onforce plate-0.2Time (s)bpush offstageс0 Aa. What

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We now focus on the take-off stage b to c in Figure 1. Squat stage lowest point of squat GRF, in terms of mg 0 Stand -still -0.6 a -0.4 -0.2 Time (s) Step on force plate b push off stage 0 0.4 0.6 In air a. What is the force at the lowest point of the squat (point b) if the person's mass m= 65 kg? Enter to 2 significant figures N b. What is the peak force during the push-off if the person's mass m= 65 kg? Round to the upper grid mark on the graph. Enter to 2 significant figures N

We now focus on the take-off stage b to c in Figure 1. Squat stage lowest point of squat GRF, in terms of mg 0 Stand -still -0.6 a -0.4 -0.2 Time (s) Step on force plate b push off stage 0 0.4 0.6 In air a. What is the force at the lowest point of the squat (point b) if the person's mass m= 65 kg? Enter to 2 significant figures N b. What is the peak force during the push-off if the person's mass m= 65 kg? Round to the upper grid mark on the graph. Enter to 2 significant figures N

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter8: Conservation Of Energy

Section: Chapter Questions

Problem 8.1CQ: One person drops a ball from the top of a building while another person at the bottom observes its...

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