standing wave

n. A wave that oscillates in place and creates stable nodes of maximum and zero oscillation, produced whenever a wave is confined within boundaries, as in the vibrating string of a musical instrument. Also called stationary wave.

standing wave

n (General Physics) physics the periodic disturbance in a medium resulting from the combination of two waves of equal frequency and intensity travelling in opposite directions. There are generally two kinds of displacement, and the maximum value of the amplitude of one of these occurs at the same points as the minimum value of the amplitude of the other. Thus in the case of electromagnetic radiation the amplitude of the oscillations of the electric field has its greatest value at the points at which the magnetic oscillation is zero, and vice versa. Also called: stationary wave Compare node, antinode

stand′ing wave′

n.
Physics. a wave in which each point on the wave has a constant amplitude, ranging from zero at the nodes to a maximum, equal to the amplitude of the wave, at the antinodes.

stand·ing wave

(stăn′dĭng) A wave that does not appear to move. Standing waves occur when two similar waves travel in opposite directions between two fixed points, called nodes, at which there is no movement. Standing waves can be transverse waves, like ocean waves, or longitudinal waves, like sound waves. Also called stationary wave.

Thesaurus

Noun

standing wave - a wave (as a sound wave in a chamber or an electromagnetic wave in a transmission line) in which the ratio of its instantaneous amplitude at one point to that at any other point does not vary with timestationary waveundulation, wave - (physics) a movement up and down or back and forth

Translations

standing wave

[′stand·iŋ ′wāv] (physics) A wave in which the ratio of an instantaneous value at one point to that at any other point does not vary with time. Also known as stationary wave.

Standing Wave

(or stationary wave), a wave arising as a result of the interference of two waves propagating in opposite directions. In practice, a standing wave is formed, owing to the superposition of the incident wave and the reflected wave, when a wave is reflected from an obstacle or inhomogeneity. Different parts of a standing wave oscillate in the same phase but with different amplitudes (see Figure 1). In contrast to a traveling wave, there is no net energy flow in a standing wave.

Figure 1. Pressure and velocity distribution in a standing wave in a tube with a closed end and a tube with an open end

Standing waves can arise in, for example, an elastic system, such as a bar or a column of air located inside a tube that is closed at one end and in which traveling waves are produced by the oscillation of a piston in the tube. The traveling waves are reflected from the boundaries of the system, and standing waves are formed in the system as a result of the superposition of the incident and reflected waves. In this case, displacement (velocity) nodes and antinodes are formed along the length of the column. The displacement nodes are planes perpendicular to the axis of the column; in these planes, there are no displacements of air particles but the pressure amplitudes are at a maximum. The antinodes are planes in which the displacements are at a maximum and the pressures are equal to zero. The displacement nodes and antinodes are located in the tube at quarter-wavelength distances. Moreover, a displacement node and a pressure antinode are always formed at the solid wall at the end of the tube. A similar situation is observed if this solid wall is removed, but the velocity antinode and pressure node are then located approximately in the plane of the opening. Standing waves can be formed in any volume with definite boundaries and a sound source, but in this case the standing waves have a more complicated structure.

Any wave process associated with the propagation of disturbances can be accompanied by the formation of standing waves. Standing waves can arise not only in gaseous, liquid, and solid media but also in a vacuum where electromagnetic disturbances are propagated and reflected. Such waves may arise, for example, in electric transmission lines. The antenna of a radio transmitter is often made in the form of a linear dipole or system of di-poles, along which a standing wave is formed. Specific types of standing waves are established in sections of wave guides and in closed, variously shaped volumes used as resonators in microwave equipment. The electric and magnetic fields in electromagnetic standing waves are separated in much the same way as the displacement and pressure in elastic standing waves.

Strictly speaking, pure standing waves can be established only in the absence of damping in the medium and only when there is total reflection of waves from the boundary. Traveling waves, which feed energy to points of energy absorption or emission, are usually present in addition to standing waves.

In optics, standing waves with visible maxima and minima of the electric field may also be formed. If the light is nonmonochro-matic, then the electric field antinodes of different wavelengths are located at different points in the standing waves, and separation of colors is often observed.

REFERENCE

Gorelik, G. S. Kolebaniia i volny. Moscow-Leningrad, 1950.

standing wave

i. A wave in the atmosphere that remains stationary in a moving fluid. Mountain waves and lee waves are two standing waves normally encountered in flight. See mountain wave.
ii. A stationary wave or wave pattern formed in a vibrating body (e.g., in a turbine disc by reflection).
iii. Stationary voltage existing on an antenna that is caused by two waves traveling in opposite directions along the conductor but which are identical in amplitude and frequency.

standing wave

standing wave

standing wave

stand′ing wave′

stand·ing wave

standing wave

standing wave

Standing Wave

REFERENCE

standing wave

standing wave

Synonyms for standing wave

noun a wave (as a sound wave in a chamber or an electromagnetic wave in a transmission line) in which the ratio of its instantaneous amplitude at one point to that at any other point does not vary with time

Synonyms

Related Words