a) The oscillations of two points x₁ and x₂ at x = 0 and x = 1 m respectively are modelled as: y₁ = 0.3 sin(4πt) and y₂ = 0.3 sin(4πt + π/8). Calculate the wavelength and speed of the associated wave.

Introduction

In this problem, we are given the oscillations at two different points on a wave. By analyzing the phase difference and distance between these points, we can determine the wavelength and speed of the wave. This is a typical problem related to wave propagation and phase relationships.

Given

• y₁ = 0.3 sin(4πt) at x = 0
• y₂ = 0.3 sin(4πt + π/8) at x = 1 m

This means the wave at point x = 1 m is ahead in phase by π/8 radians compared to the point at x = 0. The two points are 1 meter apart.

Step 1: Use Phase Difference to Find Wavelength

The general form of a traveling wave is:

y(x, t) = A sin(ωt ± kx)

Here, the phase difference Δϕ between two points a distance Δx apart is:

Δϕ = kΔx = (2π/λ) × Δx

We are told:

• Δϕ = π/8
• Δx = 1 m

Substitute into formula:

π/8 = (2π/λ) × 1

λ = 16 m

Step 2: Calculate Frequency from Angular Frequency

From the wave equation, ω = 4π

f = ω / (2π) = 4π / (2π) = 2 Hz

Step 3: Calculate Speed

Wave speed v is given by:

v = f × λ = 2 × 16 = 32 m/s

Final Answers

• Wavelength (λ): 16 meters
• Speed (v): 32 m/s

Conclusion

Using the phase difference between two known points on a wave, we determined the wavelength and wave speed. This kind of analysis is important for understanding how wave parameters can be derived from observations of oscillatory motion at different spatial points.