Textbook Question
A certain simple pendulum has a period on the earth of 1.60 s. What is its period on the surface of Mars, where g = 3.71 m/s2?
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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 51c
A simple pendulum 2.00 m long swings through a maximum angle of 30.0° with the vertical. Calculate its period (a) assuming a small amplitude, and (b) using the first three terms of Eq. (14.35). (c) Which of the answers in parts (a) and (b) is more accurate? What is the percentage error of the less accurate answer compared with the more accurate one?
Verified step by step guidance1
Step 1: Understand the problem. We need to calculate the period of a simple pendulum with a length of 2.00 m and a maximum angle of 30.0° with the vertical. We will do this in two ways: (a) assuming a small amplitude, and (b) using the first three terms of a given equation (Eq. 14.35). Finally, we will compare the accuracy of both methods.
Step 2: For part (a), use the formula for the period of a simple pendulum assuming small amplitude: , where is the length of the pendulum and is the acceleration due to gravity (approximately 9.81 m/s²). Substitute the given values into this formula.
Step 3: For part (b), use the first three terms of Eq. (14.35) to calculate the period. This equation accounts for larger amplitudes and is typically expressed as: , where is the maximum angle in radians. Convert 30.0° to radians and substitute into the equation.
Step 4: Compare the results from parts (a) and (b). The method in part (b) is more accurate because it accounts for the larger amplitude of the pendulum swing. Calculate the percentage error of the less accurate answer (from part (a)) compared to the more accurate answer (from part (b)) using the formula: , where and are the periods calculated in parts (a) and (b), respectively.
Step 5: Reflect on the importance of considering amplitude in pendulum calculations. For small angles, the simple formula is sufficient, but for larger angles, corrections are necessary to ensure accuracy. This highlights the importance of understanding the limitations of approximations in physics.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Simple Harmonic Motion
Simple harmonic motion (SHM) describes the motion of oscillating systems like pendulums, where the restoring force is directly proportional to the displacement. For small angles, a simple pendulum exhibits SHM, allowing us to use the formula T = 2π√(L/g) to calculate its period, where L is the length and g is the acceleration due to gravity.
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Simple Harmonic Motion of Pendulums
Pendulum Period Formula
The period of a simple pendulum for small angles is given by T = 2π√(L/g). This formula assumes that the angle of swing is small enough for the approximation sin(θ) ≈ θ to hold true, which simplifies the motion to SHM. This approximation is valid for angles typically less than about 15°.
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Nonlinear Pendulum Motion
For larger angles, the simple pendulum does not follow SHM precisely, and corrections are needed. The period can be calculated using a series expansion, such as Eq. (14.35), which includes higher-order terms to account for the nonlinearity. This provides a more accurate period for larger amplitudes, reducing the error from the small-angle approximation.
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Related Practice
Textbook Question
A building in San Francisco has light fixtures consisting of small 2.35-kg bulbs with shades hanging from the ceiling at the end of light, thin cords 1.50 m long. If a minor earthquake occurs, how many swings per second will these fixtures make?
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Textbook Question
A simple pendulum 2.00 m long swings through a maximum angle of 30.0° with the vertical. Calculate its period (a) assuming a small amplitude, and (b) using the first three terms of Eq. (14.35).
1
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