WAVES – MCQ SET (25 Questions)

WAVES – DETAILED SOLUTIONS

Q1. Wave speed

Equation: $y = 0.02 \sin(50t – 2x)$y=0.02sin(50t−2x)

Wave equation form: $y = A \sin(\omega t – kx)$y=Asin(ωt−kx)$$v = \frac{\omega}{k} = \frac{50}{2} = 25 \text{ m/s}$$v=kω​=250​=25 m/s

Answer: A

Q2. Distance between nodes (standing wave)

$$\text{Distance between nodes} = \frac{\lambda}{2}$$Distance between nodes=2λ​

Answer: B

Q3. Tension increases 4×

$$v = \sqrt{\frac{T}{\mu}}$$v=μT​​ $$v’ = \sqrt{\frac{4T}{\mu}} = 2v$$v′=μ4T​​=2v

Answer: B

Q4. Wave enters new medium (air → water)

Frequency remains constant across media.

Answer: B

Q5. Maximum particle velocity

$$v_{particle,max} = \omega A$$vparticle,max​=ωA

Proportional to $A\omega$Aω

Answer: C

Q6. Pipe closed at one end

Harmonics: odd multiples$$f_1 = 200\,\text{Hz}, \quad f_3 = 3f_1 = 600\,\text{Hz}$$f1​=200Hz,f3​=3f1​=600Hz

Answer: B

Q7. Doppler effect, both moving toward each other

Observed frequency increases

Answer: C

Q8. Energy transmitted in wave

$$E \propto A^2$$E∝A2

Answer: B

Q9. Two waves interfere with phase π

Destructive interference → amplitude zero

Answer: C

Q10. Wave speed on string

$$v = \sqrt{\frac{T}{\mu}}$$v=μT​​

Depends on tension and linear density

Answer: C

Q11. Wavelength

$$v = f \lambda \implies \lambda = \frac{v}{f} = \frac{300}{500} = 0.6\,\text{m}$$v=fλ⟹λ=fv​=500300​=0.6m

Answer: A

Q12. Nodes in standing wave

Nodes = points of zero displacement

Answer: B

Q13. Frequency doubles, wavelength (Tension constant)

$$v = f \lambda \implies \lambda = \frac{v}{f} \implies \lambda’ = \frac{\lambda}{2}$$v=fλ⟹λ=fv​⟹λ′=2λ​

Answer: B

Q14. Sound speed ratio & temperature

$$v \propto \sqrt{T} \implies \frac{v_1}{v_2} = \sqrt{\frac{T_1}{T_2}}$$v∝T​⟹v2​v1​​=T2​T1​​​

Given $v_1/v_2 = \sqrt{2}$v1​/v2​=2​, so $T_1/T_2 = 2$T1​/T2​=2

Answer: A

Q15. Wave equation $y = A \sin(\omega t + kx)$y=Asin(ωt+kx)

Form $\sin(\omega t + kx)$sin(ωt+kx) → wave travels along –x

Answer: B

Q16. Beats produced

Beats occur when two waves of slightly different frequency interfere

Answer: B

Q17. Intensity increases by 9×

$$I \propto A^2 \implies A’ = \sqrt{9} A = 3A$$I∝A2⟹A′=9​A=3A

Answer: B

Q18. Closed pipe fundamental frequency

$$f_1 = \frac{v}{4L} = \frac{340}{4 \times 0.85} = 100\,\text{Hz}$$f1​=4Lv​=4×0.85340​=100Hz

Answer: C

Q19. Energy transport in stationary wave

In standing wave, net energy transport = 0

Answer: C

Q20. Phase difference over λ/4

$$\Delta \phi = \frac{2\pi}{\lambda} \cdot \frac{\lambda}{4} = \frac{\pi}{2}$$Δϕ=λ2π​⋅4λ​=2π​

Answer: B

Q21. Group velocity = phase velocity

Occurs in non-dispersive medium

Answer: B

Q22. Sound intensity increase 20 dB

$$\beta = 10 \log_{10} \frac{I}{I_0} \implies 20\,\text{dB} \to I/I_0 = 10^{20/10} = 100$$β=10log10​I0​I​⟹20dB→I/I0​=1020/10=100

Answer: C

Q23. Linear density doubles

$$v = \sqrt{\frac{T}{\mu}} \implies v’ = \sqrt{\frac{T}{2\mu}} = \frac{v}{\sqrt{2}}$$v=μT​​⟹v′=2μT​​=2​v​

Answer: C

Q24. Two identical waves in phase

$$A_{res} = 2A \implies I_{res} \propto (2A)^2 = 4I$$Ares​=2A⟹Ires​∝(2A)2=4I

Answer: C

Q25. Source moves away, observer stationary

Observed frequency decreases

Answer: B