Standing Wave Summation1970-01-01T00:00:00+00:00Animation showing how the standing wave is formed by the addition of a wave (green) and its reflection (red). The resulting (purple) wave is formed by the sum of these two waves. Notice how at fixed points the standing wave has no amplitude. These poin...PT2Shttps://d3e1m60ptf1oym.cloudfront.net/1a7eaa93-c9d9-40e9-b961-6668c7598739/Standing-wave-summation-perspective-FHD-Russell-Kightley_xlarge.jpghttps://d3e1m60ptf1oym.cloudfront.net/1a7eaa93-c9d9-40e9-b961-6668c7598739/Standing-wave-summation-perspective-FHD-Russell-Kightley_mp4_hd_video.mp4https://www.scientific.pictures/media/1a7eaa93-c9d9-40e9-b961-6668c7598739/pricehttps://www.scientific.pictures/media/1a7eaa93-c9d9-40e9-b961-6668c7598739/price

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Standing Wave Summation

Animation showing how the standing wave is formed by the addition of a wave (green) and its reflection (red). The resulting (purple) wave is formed by the sum of these two waves. Notice how at fixed points the standing wave has no amplitude. These points are called nodes and their positions are shown by fine grey vertical lines. Standing waves like these are set up in musical instruments and there are various harmonic frequencies that can form these standing waves inside a given resonator.

Deakin, Australian Capital Territory, Australia

Animation ID: STANDING-WAVE-Russell-Kightley-FHD

Duration: 0:04

Animation resolution: 1920x1080 pixels @ 30.0 fps, ~27.5 Mbits/s

Animation keywords: addition, amplitude, crest, frequency, harmonic, instrument, interference, light, music, musical, nodal, node, nodes, oscillate, oscillating, oscillation, pattern, phase, physics, point, propagate, propagated, propagation, pulse, pulses, resonance, resonator, ripple, sinuoidal, standing, standing wave, sum, superposition, superpositioning, transverse, travelling, trough, undulate, undulation, vibrating, vibration, wave, waveform, wavelength, waves

Published in: ANIMATIONS, Waves, Physics

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