(a) The when the object is at equilibrium

Question

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Answer 1

Question

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

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1. vector projection. Assume, ER1001 and you know the following: ||||=4, 7=-0.5.7. For each of the following, explicitly compute the value. འབ (a) (b) (c) (d) answer. Explicitly compute ||y7||. Explain your answer. Explicitly compute the cosine similarity of and y. Explain your Explicitly compute (x, y). Explain your answer. Find the projection of onto y and the projection of onto .

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Answer 2

Question

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

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Answer 3

Question

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

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Answer 4

Question

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

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Answer 5

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

Answer 6

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

Answer 7

Chapter 12, Problem 74QAP

To determine

(a)

The when the object is at equilibrium

Answer 8

Expert Solution

Answer to Problem 74QAP

At t2= 0.0816 sec the object is at equilibrium

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given:

Mass of the object m=0.10kg

Spring constant K=15N/m

Displacement x1=0.15m

Body is released from rest v1=0 m/s

Formula used:

Conservation of energy
12Kx12+12mv12=12Kx22+12mv22

Calculation:

12Kx12+12mv12=12Kx22+12mv22

12Kx12=12mv22

v22=Kx12m

v2= K x 1 2 m = (15) (0.15) 2 0.1 = 1.837 m/s

Speed at equilibrium point is v2= 1.837 m/s

Time taken to reach the equilibrium position
t2−t1=Δt=ΔxΔv =0.151.837 =8.165×10−2 = 0.0816 sec

t2−t1=0.0816sec(t1=0)t2= 0.0816 sec

Conclusion:

At t2= 0.0816 sec the object is at equilibrium

Answer 13

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

Answer 14

To determine

(b)

When the object is 10.0cm to the left of equilibrium

Answer 15

Expert Solution

Answer to Problem 74QAP

At t3=0.204s(t1=0) the object is at equilibrium

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Given:

x3=−10cm=−0.1m

Calculation:

12Kx32=12mv32

v32=Kx32m

v3= K x 3 2 m = (15) (0.1) 2 0.1 = 1.224 m/s

Speed at equilibrium point is v3= 1.224 m/s

Time taken to reach the equilibrium position
t3−t1=Δt=ΔxΔv =−0.15−0.11.224 =0.204s

t3=0.204s(t1=0)

Conclusion:

At t3=0.204s(t1=0) the object is at equilibrium

Answer 20

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

Answer 21

To determine

(c)

When the object is 5.0cm to the left of equilibrium

Answer 22

Expert Solution

Answer to Problem 74QAP

At t4=0.163s(t1=0) the object is at equilibrium

Answer 23

Expert Solution

Answer 24

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Given:

x3=−5cm=−0.05m

Calculation:

12Kx42=12mv42

v42=Kx42m

v4= K x 4 2 m = (15) (0.05) 2 0.1 = 0.612 m/s

Speed at equilibrium point is v4= 1.167 m/s

Time taken to reach the equilibrium position
t4−t1=Δt=ΔxΔv =0.10.612 =0.163s

t4=0.163s(t1=0)

Conclusion:

At t4=0.163s(t1=0) the object is at equilibrium

Answer 27

Ch. 12 - Prob. 1QAP Ch. 12 - Prob. 2QAP Ch. 12 - Prob. 3QAP Ch. 12 - Prob. 4QAP Ch. 12 - Prob. 5QAP Ch. 12 - Prob. 6QAP Ch. 12 - Prob. 7QAP Ch. 12 - Prob. 8QAP Ch. 12 - Prob. 9QAP Ch. 12 - Prob. 10QAP

(a) The when the object is at equilibrium

Concept explainers

Videos

(a)

The when the object is at equilibrium

Answer to Problem 74QAP

Explanation of Solution

(b)

When the object is 10.0cm to the left of equilibrium

Answer to Problem 74QAP

Explanation of Solution

(c)

When the object is 5.0cm to the left of equilibrium

Answer to Problem 74QAP

Explanation of Solution

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Chapter 12 Solutions

(a) The when the object is at equilibrium

Concept explainers

Videos

(a) The when the object is at equilibrium

Answer to Problem 74QAP

Explanation of Solution

(b) When the object is 10.0cm to the left of equilibrium

Answer to Problem 74QAP

Explanation of Solution

(c) When the object is 5.0cm to the left of equilibrium

Answer to Problem 74QAP

Explanation of Solution

Want to see more full solutions like this?

Chapter 12 Solutions

(a)

The when the object is at equilibrium

(b)

When the object is 10.0cm to the left of equilibrium

(c)

When the object is 5.0cm to the left of equilibrium