Amplitude of Harmonic Oscillation in Physics

What is the amplitude of the oscillation in the given harmonic oscillator setup?

The amplitude of the oscillation is 41.6 mm.

Calculating Amplitude in Harmonic Oscillation

In a harmonic oscillator system with a frictionless block and an ideal spring, the amplitude of oscillation can be determined by using the formula:

A = (v_max T)/(2π)

Where A is the amplitude of the oscillation, v_max is the maximum speed of the system, T is the period of oscillation, and π is a mathematical constant.

By applying the formula, we can find that the amplitude of the oscillation is 41.6 mm in this specific setup.

For a detailed explanation and calculations, read on below.

Harmonic oscillators are fundamental concepts in physics, representing systems that exhibit repetitive motion around an equilibrium position. In the given scenario, a harmonic oscillator consists of a 0.690 kg frictionless block and an ideal spring with an unknown force constant. Through experimental observation, the oscillator is determined to have a period of 0.149 s and a maximum speed of 2 m/s.

To calculate the amplitude of the oscillation, we utilize the relationship between the maximum speed, period, and amplitude in harmonic motion. The formula A = (v_max T)/(2π) allows us to determine the amplitude of the oscillation, translating into a physical distance measure of 41.6 mm in this case.

Furthermore, understanding the energy conservation principle in harmonic oscillators provides insights into the system's dynamics. The total energy of the system remains constant throughout the oscillation, as there are no external forces acting on the frictionless block and spring system. By considering the total energy equation E_Total = (1/2)kA², where k is the force constant of the spring and A is the amplitude, we can derive the force constant based on the period T of oscillation.

The relationship T = 2π √(m/k) allows us to solve for the force constant k, leading to the calculation k = (4π²m)/(T²). Substituting the given values, we obtain k = 100.14 N/m, providing key information about the spring's stiffness in the system.

By incorporating the formula for amplitude calculation and the revealed force constant, we determine the amplitude of 41.6 mm through rigorous mathematical analysis. It showcases the interconnectedness of physical quantities in harmonic oscillation phenomena and reinforces the significance of energy conservation principles in analyzing such systems.

Exploring these concepts deepens our understanding of harmonic oscillators and their behavior, highlighting the intricate relationship between amplitude, maximum speed, and period in oscillatory motion.