HomeworkLib
Question

A 5.40 kg block hangs from a spring with spring constant 2020 N/m . The block...

A 5.40 kg block hangs from a spring with spring constant 2020 N/m . The block is pulled down 6.10 cm from the equilibrium position and given an initial velocity of 1.20 m/s back toward equilibrium.

a. What is the frequency of the motion?

b. What is the amplitude?

c. What is the total mechanical energy of the motion?

science   physics   
0 0
Add a comment Improve this question Transcribed image text
Next > < Previous
Sort answers by oldest

Homework Answers

Answer #1

0 0
Add a comment
Know the answer?
Add Answer to:
A 5.40 kg block hangs from a spring with spring constant 2020 N/m . The block...
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Log In

Sign Up

Not the answer you're looking for? Ask your own homework help question. Our experts will answer your question WITHIN MINUTES for Free.
Similar Homework Help Questions

  • A 5.10 kg block hangs from a spring with spring constant 1760 N/m . The block...

    A 5.10 kg block hangs from a spring with spring constant 1760 N/m . The block is pulled down 6.80 cm from the equilibrium position and given an initial velocity of 1.20 m/s back toward equilibrium. A) What is the frequency of the motion? B) What is the amplitude? C)What is the total mechanical energy of the motion?

  • Review PartA A 4.70 kg block hangs from a spring with spring constant 2180 N/m. The...

    Review PartA A 4.70 kg block hangs from a spring with spring constant 2180 N/m. The block is pulled down 4.30 cm from the equilibrium position and given an initial velocity of 1.00 m/s back toward equilibrium. What is the frequency of the motion? Express your answer with the appropriate units. Value Units Submit Reguest Answer - Part B What is the amplitude? Express your answer with the appropriate units. Value Units Submit ▼ Part C What is the total...

  • A 1.10 kg mass hangs from a spring of force constant 400 N/m . The mass...

    A 1.10 kg mass hangs from a spring of force constant 400 N/m . The mass is then pulled down 13.0 cm from the equilibrium position and released. At the end of five complete cycles of vibration, the mass reaches only 10.0 cm from the equilibrium position. Part A: How much mechanical energy is lost during these five cycles? Part B: What percentage of the mechanical energy is lost during the five cycles?

  • A spring with spring constant 14.5 N/m hangs from the ceiling. A 510 g ball is...

    A spring with spring constant 14.5 N/m hangs from the ceiling. A 510 g ball is attached to the spring and allowed to come to rest. It is then pulled down 6.10 cm and released. What is the time constant if the ball's amplitude has decreased to 3.90 cm after 48.0 oscillations?

  • A 5 kg block hangs from a spring with spring constant 5 N/m. At t=0s the...

    A 5 kg block hangs from a spring with spring constant 5 N/m. At t=0s the block is 3 m below the equilibrium point and moving upward with a speed of 6 m/s. What is the amplitude of the oscillations?

  • A spring with spring constant 13.0 N/m hangs from the ceiling. A 420 g ball is...

    A spring with spring constant 13.0 N/m hangs from the ceiling. A 420 g ball is attached to the spring and allowed to come to rest. It is then pulled down 6.10 cm and released. Part A What is the time constant if the ball's amplitude has decreased to 4.00 cm after 43.0 oscillations? Express your answer with the appropriate units.

  • The force of constant of a spring of spring pendulum is 50N/m. A block of mass...

    The force of constant of a spring of spring pendulum is 50N/m. A block of mass 0.5 kg, attached to it is pulled through a distance of 0.01 m before being released. Calculate the following expressions: a) the time period and frequency b) velocity amplitude and acceleration amplitude; c) the time required by the block to move half-way towards the center from its initial position d) total energy of the system.

  • A block–spring system consists of a spring with constant k=425 N/m attached to a 2.00-kg block...

    A block–spring system consists of a spring with constant k=425 N/m attached to a 2.00-kg block on a frictionless surface. The block is pulled 8.00 cm from equilibrium and released from rest. For the resulting oscillation, find the (a) ampli- tude, (b) angular frequency, (c) frequency, and (d) period. What is the maximum value of the block’s (e) velocity and (f ) acceleration?

  • A classic spring/block system is moving back and forth on an air track (no friction). The...

    A classic spring/block system is moving back and forth on an air track (no friction). The mass of the block is 0.5 kg and the spring constant is 200 N/m. The mass is pulled back from equilibrium and then quickly pushed into motion such that it has an initial speed at the release point (60 cm from the equilibrium position) of 5.0 m/s. Determine the frequency of this oscillator.

  • A mass of 0.601 kg hangs on a vertical spring of spring constant 19.2 N/m. If...

    A mass of 0.601 kg hangs on a vertical spring of spring constant 19.2 N/m. If you displace the mass by 1.69 cm from its equilibrium position and let it go from rest, what will be the maximum velocity?

ADVERTISEMENT
Free Homework Help App
Download From Google Play
Scan Your Homework
to Get Instant Free Answers
Need Online Homework Help?
Ask a Question
Get Answers For Free
Most questions answered within 3 hours.
ADVERTISEMENT
ADVERTISEMENT