vela said:What forces are on the block?
vela said:Can you say anything about the forces on the block when it's right on the verge of losing contact with the piston?
You're right. The normal force can only push up on the block. It can get as big as necessary to accelerate the block upward, but the smallest it can get is zero. So what's the maximum downward acceleration the block can have? And how does this tell you when the block and piston separate?LeakyFrog said:The only thing I can really think of is that the normal force might be zero and the only force acting on the block would be Mg. Although I think that would only be if it were in the air already so I'm probably wrong about this.
vela said:So what's the maximum downward acceleration the block can have? And how does this tell you when the block and piston separate?
The formula for Simple Harmonic Motion is x = A sin(ωt + φ), where x represents the displacement from equilibrium, A is the amplitude of the motion, ω is the angular frequency, and φ is the phase angle.
The period of Simple Harmonic Motion can be calculated using the formula T = 2π/ω, where T represents the time it takes for one complete oscillation and ω is the angular frequency.
The amplitude in Simple Harmonic Motion represents the maximum displacement from equilibrium. It is a measure of the strength or intensity of the oscillation.
Simple Harmonic Motion can be observed in many real-life phenomena, such as the motion of a pendulum, the vibrations of a guitar string, and the back-and-forth motion of a spring. It is a fundamental principle in understanding the behavior of oscillating systems.
The phase angle in Simple Harmonic Motion determines the starting point of the oscillation. It represents the initial displacement from equilibrium at t = 0, and it is responsible for the different shapes and patterns of the motion.