This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.10 kg mass on a spring with k=40 N/m is released from rest at maximum displacement, reaching equilibrium after one quarter period. Choice B is correct because ω=√(k/m)=√(40/0.10)=20 rad/s, giving period T=2π/ω=π/10≈0.314 s, so t=T/4≈0.079 s. Choice C is incorrect due to a common error where students might calculate T/2 instead of T/4, thinking the mass needs half a period to reach equilibrium from the extreme position. To help students: Emphasize that SHM motion from extreme position to equilibrium takes exactly one quarter period. Practice problems should include finding times to reach various positions to reinforce the periodic nature of the motion.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a mass passes through equilibrium (x=0) at t=0 with positive velocity, requiring us to find the phase constant φ from initial conditions x(0)=0 and v(0)>0. Choice C is correct because x(0)=A cos(φ)=0 means cos(φ)=0, so φ=±π/2, and v(0)=-Aω sin(φ)>0 requires sin(φ)<0, which is satisfied by φ=-π/2. Choice A is incorrect because φ=π/2 would give sin(φ)=1, making v(0)=-Aω<0, contradicting the positive initial velocity. To help students: Emphasize the importance of checking both position and velocity conditions when determining phase. Practice problems should include various initial conditions to build intuition about how phase affects the starting point of oscillation.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.40 kg block on a spring with k=160 N/m has initial position x₀=0.050 m and initial velocity v₀=-0.40 m/s, requiring us to find the amplitude using A²=x₀²+(v₀/ω)². Choice B is correct because ω=√(k/m)=√(160/0.40)=20 rad/s, giving A²=(0.050)²+(0.40/20)²=0.0025+0.0004=0.0029, so A≈0.064 m. Choice C is incorrect due to a common error where students might forget to square the terms in the amplitude formula, calculating A=x₀+v₀/ω instead. To help students: Emphasize that amplitude represents the maximum displacement and can be found from initial conditions using energy conservation or the Pythagorean-like formula. Practice problems should include various combinations of initial position and velocity to reinforce this concept.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a simple pendulum with length L=0.80 m undergoes small-angle oscillations where the angular frequency is ω=√(g/L)=√(9.8/0.80)=3.5 rad/s. Choice B is correct because the period T=2π/ω=2π/3.5≈1.8 s, noting that the mass of the bob does not affect the period for small angles. Choice A is incorrect due to a common error where students might calculate T=π/ω instead of 2π/ω, getting half the correct period. To help students: Emphasize that pendulum period depends only on length and gravity for small angles, not on mass. Practice problems should include comparing pendulums of different masses but same length to reinforce this counterintuitive concept.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.60 kg cart on a spring with k=240 N/m oscillates with amplitude A=0.070 m, and we need the maximum acceleration amax=ω²A. Choice A is correct because ω=√(k/m)=√(240/0.60)=20 rad/s, giving amax=(20)²×0.070=400×0.070=28 m/s². Choice B is incorrect due to a common error where students might calculate amax=ωA instead of ω²A, getting 20×0.070=1.4 m/s² (though this doesn't match choice B exactly). To help students: Emphasize that acceleration in SHM is proportional to displacement with factor -ω², making maximum acceleration occur at maximum displacement. Practice problems should include finding acceleration at various positions to reinforce the a=-ω²x relationship.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.20 kg mass on a spring with k=50 N/m is released from rest at amplitude A=0.060 m, and we need to find the maximum speed. Choice A is correct because vmax=Aω where ω=√(k/m)=√(50/0.20)=15.81 rad/s, giving vmax=0.060×15.81≈0.95 m/s. Choice D is incorrect due to a common error where students might divide by 10 instead of multiplying, possibly confusing units or misapplying the formula. To help students: Emphasize that maximum speed occurs at equilibrium where all energy is kinetic, and vmax=Aω is a fundamental SHM relationship. Practice problems should include energy conservation checks to verify that ½mvmax²=½kA².

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a pendulum with length L=1.2 m undergoes small-angle oscillations with angular frequency ω=√(g/L)=√(9.8/1.2)=2.86 rad/s. Choice A is correct because the frequency f=ω/(2π)=2.86/(2π)≈0.455 Hz, which rounds to 0.45 Hz. Choice D is incorrect due to a common error where students might calculate f=1/T but use an incorrect period, possibly forgetting the 2π factor or misapplying the pendulum formula. To help students: Emphasize that pendulum frequency depends on √(g/L) and is independent of mass and amplitude for small angles. Practice problems should include comparing pendulums of different lengths to build intuition about the inverse square root relationship.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.50 kg mass on a spring with k=80 N/m oscillates with amplitude A=0.10 m, and we need to find the total mechanical energy E=½kA². Choice A is correct because E=½×80×(0.10)²=½×80×0.01=0.40 J. Choice C is incorrect due to a common error where students might forget the factor of ½ in the energy formula, calculating E=kA²/10 or making a decimal place error. To help students: Emphasize that total energy in SHM equals maximum potential energy (at amplitude) or maximum kinetic energy (at equilibrium). Practice problems should include energy calculations at various positions to reinforce conservation of mechanical energy.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.25 kg mass on a spring with k=100 N/m oscillates with angular frequency ω=√(k/m)=√(100/0.25)=20 rad/s. Choice B is correct because the frequency f=ω/(2π)=20/(2π)≈3.18 Hz, which rounds to 3.2 Hz. Choice C is incorrect due to a common error where students might calculate f=1/(2π) without including the angular frequency, or confuse period with frequency. To help students: Emphasize the distinction between angular frequency ω (in rad/s) and frequency f (in Hz), connected by f=ω/(2π). Practice problems should include converting between period, frequency, and angular frequency to build fluency with these related quantities.

This question tests the ability to represent and analyze simple harmonic motion (SHM) in the context of AP Physics C: Mechanics. SHM is characterized by periodic motion where the restoring force is proportional to displacement, commonly modeled by mass-spring systems or pendulums. In this scenario, a 0.50 kg block attached to a spring with k=200 N/m undergoes SHM with angular frequency ω=√(k/m)=√(200/0.50)=20 rad/s. Choice B is correct because the period T=2π/ω=2π/20≈0.314 s, which rounds to 0.31 s. Choice D is incorrect due to a common error where students might calculate T=2π√(m/k) but forget the 2π factor, getting approximately 0.16 s instead. To help students: Emphasize the importance of remembering the complete period formula T=2π/ω and the relationship between angular frequency and spring-mass parameters. Practice problems should include variations in mass and spring constant to reinforce the inverse relationship between period and angular frequency.