Progressive vs Standing Waves
When the Sydney Opera House Concert Hall opened in 1973, acoustic engineers measured a resonance peak at 70 Hz (B₂) caused by the hall's 2,679-seat volume interacting with the timber reflector panels above the stage. Jørn Utzon's panel geometry set the distance between reflecting surfaces at ≈ 2.43 m — one half-wavelength at 70 Hz — turning the hall into a standing-wave resonator for that frequency while progressive waves (direct sound) reached the audience seats.
List as many differences as you can between a wave on the ocean (progressive) and a vibrating guitar string (standing). Write your predictions.
Warm-up — which wave type transports energy from one place to another?
Know
- Five key differences between progressive and standing waves
- Energy transport: progressive yes, standing no
- Amplitude and phase relationships in each type
Understand
- Why nodes are permanent in standing waves but not in progressive waves
- Why all particles in a standing wave loop are in phase with each other
- Why standing waves require fixed boundaries or resonance conditions
Can Do
- Complete a comparison table of the two wave types
- Classify a described wave as progressive or standing
- Apply the distinction to exam questions (ACSPH072)
Core Content
Sit in the Sydney Opera House Concert Hall during a rehearsal: the cello section directly in front of you sends sound outward as a progressive wave — you feel the energy arriving at your seat. But inside the reflector panel cavity above the stage, the 70 Hz sound reflects back and forth between surfaces 2.43 m apart, building a standing wave that reinforces the bass warmth the hall is famous for. Same physics, two very different behaviours depending on whether the wave is travelling or trapped.
We just saw standing waves with fixed nodes, antinodes, and no net energy transport. That raises a question: how do standing waves systematically differ from the progressive waves (direct sound, ocean swell) we use in everyday life? This card answers it → five key properties distinguish the two types.
This table covers the five properties most commonly examined at HSC (ACSPH072). Learn all five rows.
| Property | Progressive wave | Standing wave |
|---|---|---|
| Energy transport | Energy carried in direction of propagation | No net energy transport |
| Pattern | Waveform moves through medium | Pattern of fixed nodes and antinodes |
| Amplitude | Same for all particles (in undamped case) | Varies from 0 (node) to maximum (antinode) |
| Phase | Phase changes continuously along the wave | All particles in a loop are in phase; particles in adjacent loops are anti-phase |
| Formation | A single source radiates into the medium | Two identical waves travel in opposite directions |
Progressive waves transport energy with uniform amplitude and continuously varying phase along the medium. Standing waves have no net energy transport, amplitude varying from zero (node) to maximum (antinode), and particles within each loop are in phase while adjacent loops are anti-phase.
Pause — copy the highlighted five-property comparison into your book before moving on.
In a progressive wave, all particles (in an undamped medium) have the same amplitude.
In a standing wave, particles in adjacent loops vibrate in phase with each other.
In a standing wave, particles within the same loop (between adjacent nodes) are:
Activities
For each description below, state whether it is a progressive or standing wave and give one reason:
- Ocean swell arriving at a beach
- A vibrating violin string
- Sound from a speaker travelling down a corridor
- The resonant vibration in a microwave oven cavity
Explain why the phase relationship in a standing wave differs from a progressive wave. Use the terms "in phase" and "anti-phase" in your answer.
Explain why a standing wave does not transport net energy, even though the particles in the wave are oscillating.
Which of these is a property of progressive waves but NOT standing waves?
A progressive wave and a standing wave both have the same frequency and wavelength. The main difference is that the standing wave has:
In a standing wave, two particles on opposite sides of a node are:
UnderstandBand 3(4 marks) 1. Distinguish between progressive and standing waves under four headings: energy transport, amplitude, phase, and formation.
ApplyBand 3(2 marks) 2. Identify whether a microwave standing wave in a cavity or a water wave rippling outward from a dropped stone is a progressive or standing wave. Justify each.
AnalyseBand 5(4 marks) 3. Explain why particles within the same loop of a standing wave are in phase with each other but anti-phase with particles in the adjacent loop. Use the idea of superposition in your answer.
Show all answers
Short Answer — Model Answers
Q1 (4 marks): Energy transport: progressive carries energy in direction of travel; standing has no net energy transport. Amplitude: progressive gives same amplitude to all particles; standing varies from zero at nodes to maximum at antinodes. Phase: progressive — phase varies continuously along wave; standing — all particles within a loop are in phase, adjacent loops are anti-phase. Formation: progressive from single source; standing from two identical waves in opposite directions.
Q2 (2 marks): Microwave in cavity — standing wave; the cavity walls act as fixed boundaries, creating nodes and antinodes with no net energy transport. Water wave — progressive; energy radiates outward from the disturbance.
Q3 (4 marks): A standing wave is the superposition of two sinusoidal waves moving in opposite directions. Within one loop, both waves reinforce in the same direction at every moment — particles move together and are in phase. Across a node, the superposition changes sign: when one wave's crest arrives the other's trough does; the net displacement is opposite in direction. Adjacent loop particles are therefore anti-phase (180° out of phase) with those in the first loop.
The Sydney Opera House Concert Hall (1973, Jørn Utzon) demonstrates both wave types simultaneously: the direct sound from the orchestra reaches the audience as a progressive wave — energy transported outward — while the timber reflector panels spaced ≈ 2.43 m above the stage trap a standing wave at 70 Hz (B₂) with a pressure antinode at each panel surface.
Your Think First predictions about ocean swell vs guitar string were on the right track. The formal five-property comparison (energy transport, pattern, amplitude profile, phase, formation) is what ACSPH072 requires you to articulate precisely in the exam.