Textbook Question
A 0.500-kg glider, attached to the end of an ideal spring with force constant k = 450 N/m, undergoes SHM with an amplitude of 0.040 m. Compute the speed of the glider when it is at x = -0.015 m.
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Ch 14: Periodic Motion
Young & Freedman Calc14th EditionUniversity PhysicsISBN: 9780321973610
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Table of contents
- Ch 01: Units, Physical Quantities & Vectors41
- Ch 02: Motion Along a Straight Line67
- Ch 03: Motion in Two or Three Dimensions47
- Ch 04: Newton's Laws of Motion23
- Ch 05: Applying Newton's Laws59
- Ch 06: Work & Kinetic Energy14
- Ch 07: Potential Energy & Conservation8
- Ch 08: Momentum, Impulse, and Collisions18
- Ch 09: Rotation of Rigid Bodies42
- Ch 10: Dynamics of Rotational Motion48
- Ch 11: Equilibrium & Elasticity27
- Ch 12: Fluid Mechanics31
- Ch 13: Gravitation35
- Ch 14: Periodic Motion32
- Ch 15: Mechanical Waves25
- Ch 16: Sound & Hearing32
- Ch 17: Temperature and Heat36
- Ch 18: Thermal Properties of Matter38
- Ch 19: The First Law of Thermodynamics33
- Ch 20: The Second Law of Thermodynamics22
- Ch 21: Electric Charge and Electric Field36
- Ch 22: Gauss' Law24
- Ch 23: Electric Potential31
- Ch 24: Capacitance and Dielectrics18
- Ch 25: Current, Resistance, and EMF26
- Ch 26: Direct-Current Circuits30
- Ch 27: Magnetic Field and Magnetic Forces18
- Ch 28: Sources of Magnetic Field10
- Ch 29: Electromagnetic Induction28
- Ch 30: Inductance17
- Ch 31: Alternating Current21
- Ch 32: Electromagnetic Waves1
- Ch 33: The Nature and Propagation of Light20
- Ch 34: Geometric Optics34
- Ch 35: Interference19
- Ch 36: Diffraction25
- Ch 37: Special Relativity20
- Ch 38: Photons: Light Waves Behaving as Particles15
- Ch 39: Particles Behaving as Waves26
- Ch 40: Quantum Mechanics I: Wave Functions21
- Ch 41: Quantum Mechanics II: Atomic Structure25
- Ch 42: Molecules and Condensed Matter18
- Ch 43: Nuclear Physics16
- Ch 44: Particle Physics and Cosmology23
Young & Freedman Calc14th EditionUniversity PhysicsISBN: 9780321973610Not the one you use?Change textbook
Chapter 14, Problem 24b
For the oscillating object in Fig. E14.4, what is its maximum acceleration?
Verified step by step guidance1
Identify the amplitude of the oscillation from the graph. The amplitude is the maximum displacement from the equilibrium position, which is 10 cm in this case.
Determine the angular frequency \( \omega \) of the oscillation. The period \( T \) can be found from the graph as the time it takes to complete one full cycle. From the graph, the period \( T \) is 10 seconds. Use the formula \( \omega = \frac{2\pi}{T} \) to calculate the angular frequency.
Recall the formula for maximum acceleration in simple harmonic motion: \( a_{max} = \omega^2 A \), where \( A \) is the amplitude and \( \omega \) is the angular frequency.
Substitute the values of \( \omega \) and \( A \) into the formula for maximum acceleration to find \( a_{max} \).
Ensure the units are consistent. Since the amplitude is given in cm, convert it to meters by dividing by 100 if necessary, to ensure the acceleration is in \( \text{m/s}^2 \).
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Simple Harmonic Motion (SHM)
Simple Harmonic Motion is a type of periodic motion where an object oscillates around an equilibrium position. The motion is characterized by a restoring force proportional to the displacement from the equilibrium, leading to sinusoidal position, velocity, and acceleration graphs. In SHM, the maximum displacement from the equilibrium is known as the amplitude.
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07:52
Simple Harmonic Motion of Pendulums
Acceleration in SHM
In Simple Harmonic Motion, the acceleration of the oscillating object is directly related to its displacement from the equilibrium position. The maximum acceleration occurs at the maximum displacement (amplitude) and is given by the formula a_max = ω²A, where ω is the angular frequency and A is the amplitude. This relationship highlights how acceleration varies throughout the oscillation.
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05:47Intro to Acceleration
Graph Interpretation
The graph provided depicts the position of the oscillating object over time, illustrating its periodic nature. By analyzing the graph, one can determine key parameters such as amplitude, period, and phase. The maximum displacement from the horizontal axis indicates the amplitude, while the steepest slopes correspond to maximum velocity, and the points of zero slope indicate maximum acceleration.
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07:32Graphing Position, Velocity, and Acceleration Graphs
Related Practice
Textbook Question
For the oscillating object in Fig. E14.4, what is its maximum speed?
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Textbook Question
A mass on a spring has velocity as a function of time given by . What are the period and the force constant of the spring?
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Textbook Question
A small block is attached to an ideal spring and is moving in SHM on a horizontal frictionless surface. The amplitude of the motion is 0.165 m. The maximum speed of the block is 3.90 m/s. What is the maximum magnitude of the acceleration of the block?
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Textbook Question
A mass on a spring has velocity as a function of time given by . What are the amplitude and the maximum acceleration of the mass?
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Textbook Question
A small block is attached to an ideal spring and is moving in SHM on a horizontal, frictionless surface. The amplitude of the motion is 0.250 m and the period is 3.20 s. What are the speed and acceleration of the block when x = 0.160 m?
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