wave

American Heritage Dictionary:

wave

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(wāv)

v., waved, wav·ing, waves.

v.intr.

To move freely back and forth or up and down in the air, as branches in the wind.
To make a signal with an up-and-down or back-and-forth movement of the hand or an object held in the hand: waved as she drove by.
To have an undulating or wavy form; curve or curl: Her hair waves naturally.

v.tr.

To cause to move back and forth or up and down, either once or repeatedly: She waved a fan before her face.
1. To move or swing as in giving a signal: He waved his hand. See synonyms at flourish.
2. To signal or express by waving the hand or an object held in the hand: We waved goodbye.
3. To signal (a person) to move in a specified direction: The police officer waved the motorist into the right lane.
To arrange into curves, curls, or undulations: wave one's hair.

1. A ridge or swell moving through or along the surface of a large body of water.
2. A small ridge or swell moving across the interface of two fluids and dependent on surface tension.
The sea. Often used in the plural: vanished beneath the waves.
Something that suggests the form and motion of a wave in the sea, especially:
1. A moving curve or succession of curves in or on a surface; an undulation: waves of wheat in the wind.
2. A curve or succession of curves, as in the hair.
3. A curved shape, outline, or pattern.
A movement up and down or back and forth: a wave of the hand.
1. A surge or rush, as of sensation: a wave of nausea; a wave of indignation.
2. A sudden great rise, as in activity or intensity: a wave of panic selling on the stock market.
3. A rising trend that involves large numbers of individuals: a wave of conservatism.
4. One of a succession of mass movements: the first wave of settlers.
5. A maneuver in which fans at a sports event simulate an ocean wave by rising quickly in sequence with arms upraised and then quickly sitting down again in a continuous rolling motion.
A widespread, persistent meteorological condition, especially of temperature: a heat wave.
Physics.
1. A disturbance traveling through a medium by which energy is transferred from one particle of the medium to another without causing any permanent displacement of the medium itself.
2. A graphic representation of the variation of such a disturbance with time.
3. A single cycle of such a disturbance.

phrasal verb:

wave off

To dismiss or refuse by waving the hand or arm: waved off his invitation to join the group.
Sports. To cancel or nullify by waving the arms, usually from a crossed position: waved off the goal because time had run out.

[Middle English waven, from Old English wafian.]

waver wav'er n.

wave

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Home > Library > Miscellaneous > Britannica Concise Encyclopedia

Physics

Propagation of disturbances from place to place in a regular and organized way. Most familiar are surface waves that travel on water, but sound, light, and the motion of subatomic particles all exhibit wavelike properties. In the simplest waves, the disturbance oscillates periodically ( periodic motion) with a fixed frequency and wavelength. Mechanical waves, such as sound, require a medium through which to travel, while electromagnetic waves ( electromagnetic radiation) do not require a medium and can be propagated through a vacuum. Propagation of a wave through a medium depends on the medium's properties. seismic wave.

Geology

In oceanography, a ridge or swell on the surface of a body of water, normally having a forward motion distinct from the motions of the particles that compose it. Ocean waves are fairly regular, with an identifiable wavelength between adjacent crests and with a definite frequency of oscillation. Waves result when a generating force (usually the wind) displaces surface water and a restoring force returns it to its undisturbed position. Surface tension alone is the restoring force for small waves. For large waves, gravity is more important.

For more information on wave, visit Britannica.com.

McGraw-Hill Science & Technology Encyclopedia:

Wave

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The general term applied to the description of a disturbance which propagates from one point in a medium to other points without giving the medium as a whole any permanent displacement.

Waves are generally described in terms of their amplitude, and how the amplitude varies with both space and time. The actual description of the wave amplitude involves a solution of the wave equation and the particular boundary conditions for the case being studied. See also Wave equation; Wave motion.

Acoustic waves, or sound waves, are a particular kind of the general class of elastic waves. Elastic waves are propagated in media having two properties, inertia and elasticity. Electromagnetic waves (for example, light waves and radio waves) are not elastic waves and therefore can travel through a vacuum. The velocity of the wave depends on the medium through which the wave travels. See also Electromagnetic wave.

Computer Desktop Encyclopedia:

wave

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A ripple or undulation. All electromagnetic radiation, including radio signals, light rays, x-rays, and cosmic rays, as well as sound, behave like rippling waves in the ocean. To visualize a wave, take a piece of paper and keep drawing a line up and down while pulling the paper perpendicular to the line. Modulate the line by making it different lengths as you draw it with the paper moving, and notice the resulting pattern. See wave-particle duality and wavelength.

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Roget's Thesaurus:

wave

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verb

To move to and fro vigorously and usually repeatedly: switch, wag¹, waggle. See repetition.
To move or cause to move about while being fixed at one edge: flap, flutter, fly. See repetition.
To move (one's arms or wings, for example) up and down: beat, flap, flitter, flop, flutter, waggle. See repetition.
To wield boldly and dramatically: brandish, flourish, sweep. See express.
To have or cause to have a curved or sinuous form or surface: curl, curve, undulate. See straight/bent.

Columbia Encyclopedia:

wave

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in the earth sciences
in physics

wave, in oceanography, an oscillating movement up and down, of a body of water caused by the frictional drag of the wind, or on a larger scale, by submarine earthquakes, volcanoes, and landslides. In seismology, waves moving though the earth are caused by the propagation of a disturbance generated by an earthquake or explosion. In atmospheric science, waves are periodic disturbances in the air flow.

Oceanographic Waves

In a body of water, waves consist of a series of crests and troughs, where wavelength is the distance between two successive crests (or successive troughs). As waves are generated, the water particles are set in motion, following vertical circular orbits. Water particles momentarily move forward as the wave crest passes and backward as the trough passes. Thus, except for a slight forward drag, the water particles remain in essentially the same place as successive waves pass. The orbital motion of the water particles decreases in size at depths below the surface, so that at a depth equal to about one half of the wave's length, the water particles are barely oscillating back and forth. Thus, for even the largest waves, their effect is negligible below a depth of 980 ft (300 m).

The height and period of water waves in the deep ocean are determined by wind velocity, the duration of the wind, and the fetch (the distance the wind has blown across the water). In stormy areas, the waves are not uniform but form a confusing pattern of many waves of different periods and heights. Storms also produce white caps at wind speeds c.8 mi per hr (13 km per hr). Major storm waves can be over a half mile long and travel close to c.25 mi per hr (40 km per hour). A wave in the Gulf of Mexico associated with Hurricane Ivan (2004) measured 91 ft (27.7 m) high, and scientists believe that other waves produced by Ivan may have reached as much as 132 ft (40 m) high. Waves of similar heights, sometimes called rogue waves, most commonly occur in regions of strong ocean currents, which can amplify wind-driven waves when they flow in opposing directions; sandbanks may also act to focus wave energy and give rise to rogue waves.

When waves approach a shore, the orbital motion of the water particles becomes influenced by the bottom of the body of water and the wavelength decreases as the wave slows. As the water becomes shallower the wave steepens further until it "breaks" in a breaker, or surf, carrying the water forward and onto the beach in a turbulent fashion. Because waves usually approach the shore at an angle, a longshore (littoral) current is generated parallel to the shoreline. These currents can be effective in eroding and transporting sediment along the shore (see coast protection; beach).

In many enclosed or partly enclosed bodies of water such as lakes or bays, a wave form called a standing wave, or seiche, commonly develops as a result of storms or rapid changes in air pressure. These waves do not move forward, but the water surface moves up and down at antinodal points, while it remains stationary at nodal points.

Internal waves can form within waters that are density stratified and are similar to wind-driven waves. They usually cannot be seen on the surface, although oil slicks, plankton, and sediment tend to collect on the surface above troughs of internal waves. Any condition that causes waters of different density to come into contact with one another can lead to internal waves. They tend to have lower velocities but greater heights than surface waves. Very little is known about internal waves, which may move sediment on deeper parts of continental shelves.

Just as a rock dropped into water produces waves, sudden displacements such as landslides and earthquakes can produce high energy waves of short duration that can devastate coastal regions (see tsunami). Hurricanes traveling over shallow coastal waters can generate storm surges that in turn can cause devastating coastal flooding (see under storm).

Seismic and Atmospheric Waves

Seismic waves are generated in the earth by the movements of earthquakes or explosions. Depending on the material traveled through, surface and internal waves move at variable velocities. Layers of the earth, including the core, mantle, and crust, have been discerned using seismic wave profiles. Seismic waves from explosions have been used to understand the subsurface structure of the crust and upper mantle and in the exploration for oil and gas deposits. Atmospheric waves are caused by differences in temperature, the Coriolis effect, and the influence of highlands.

wave, in physics, the transfer of energy by the regular vibration, or oscillatory motion, either of some material medium or by the variation in magnitude of the field vectors of an electromagnetic field (see electromagnetic radiation). Many familiar phenomena are associated with energy transfer in the form of waves. Sound is a longitudinal wave that travels through material media by alternatively forcing the molecules of the medium closer together, then spreading them apart. Light and other forms of electromagnetic radiation travel through space as transverse waves; the displacements at right angles to the direction of the waves are the field intensity vectors rather than motions of the material particles of some medium. With the development of the quantum theory, it was found that particles in motion also have certain wave properties, including an associated wavelength and frequency related to their momentum and energy. Thus, the study of waves and wave motion has applications throughout the entire range of physical phenomena.

Classification of Waves

Waves may be classified according to the direction of vibration relative to that of the energy transfer. In longitudinal, or compressional, waves the vibration is in the same direction as the transfer of energy; in transverse waves the vibration is at right angles to the transfer of energy; in torsional waves the vibration consists of a twisting motion as the medium rotates back and forth around the direction of energy transfer. The three types of waves are illustrated by an example in which a coil spring is held stretched out by two persons. If the person holding one end pulls a few coils toward himself and releases them, a longitudinal wave will travel along the spring, with coils alternately being pressed closer together, then stretched apart, as the wave passes. If the first person then shakes his end up and down or from side to side, a transverse wave will travel along the spring. Finally, if he grabs several coils and twists them around the axis of the spring, a torsional wave will travel along the spring.

A wave may be a combination of types. Water waves in deep water are mainly transverse. However, as they approach a shore they interact with the bottom and acquire a longitudinal component. When the longitudinal component becomes very large compared to the transverse component, the wave breaks.

Parameters of Waves

The maximum displacement of the medium in either direction is the amplitude of the wave. The distance between successive crests or successive troughs (corresponding to maximum displacements in the same direction) is the wavelength of the wave. The frequency of the wave is equal to the number of crests (or troughs) that pass a given fixed point per unit of time. Closely related to the frequency is the period of the wave, which is the time lapse between the passage of successive crests (or troughs). The frequency of a wave is the inverse of the period.

One full wavelength of a wave represents one complete cycle, that is, one complete vibration in each direction. The various parts of a cycle are described by the phase of the wave; all waves are referenced to an imaginary synchronous motion in a circle; thus the phase is measured in angular degrees, one complete cycle being 360°. Two waves whose corresponding parts occur at the same time are said to be in phase. If the two waves are at different parts of their cycles, they are out of phase. Waves out of phase by 180° are in phase opposition. The various phase relationships between combining waves determines the type of interference that takes place.

The speed of a wave is determined by its wavelength λ and its frequency ν, according to the equation v=λν, where v is the speed, or velocity. Since frequency is inversely related to the period T, this equation also takes the form v=λ/T. The speed of a wave tells how quickly the energy it carries is being transferred. It is important to note that the speed is that of the wave itself and not of the medium through which it is traveling. The medium itself does not move except to oscillate as the wave passes.

Wave Fronts and Rays

In the graphic representation and analysis of wave behavior, two concepts are widely used-wave fronts and rays. A wave front is a line representing all parts of a wave that are in phase and an equal number of wavelengths from the source of the wave. The shape of the wave front depends upon the nature of the source; a point source will emit waves having circular or spherical wave fronts, while a large, extended source will emit waves whose wave fronts are effectively flat, or plane. A ray is a line extending outward from the source and representing the direction of propagation of the wave at any point along it. Rays are perpendicular to wave fronts.

Investopedia Financial Dictionary:

Wave

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A metaphor for daily market activity that goes against the weekly market tide.

Investopedia Says:
An investor trading daily would measure the market waves, or the daily market trends, with various oscillators from the triple screen trading system.

The ocean metaphors for market trends were coined by one of the markets first technical analysts, Robert Rhea.

Related Links:
Acquaint yourself with the principle built on the discovery that stock markets did not behave in a chaotic manner. Elliott Wave Theory
Discover new developments that help you apply this difficult theory to trading and how computer power can help reduce the guess-work. Elliott Wave In The 21st Century
With an appropriate filter, you can ride the waters to rising profits. Surf's Up With Filtered Waves
Trade what you see: Follow the charts, buy breakouts and honor stops. Finding Success Where Indicators Fail
By following the strategies of the pros, even a beginner can learn to invest like an expert. Invest Like A Pro

Electronics Dictionary:

wave

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Electric, electromagnetic, acoustic, mechanical or other form whose physical activity rises and falls or advances and retreats periodically as it travels through some medium.

US Defense Department Military Dictionary:

wave

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(DOD, NATO) 1. A formation of forces, landing ships, craft, amphibious vehicles or aircraft, required to beach or land about the same time. Can be classified as to type, function or order as shown: a. assault wave; b. boat wave; c. helicopter wave; d. numbered wave; e. on-call wave; f. scheduled wave. 2. (DOD only) An undulation of water caused by the progressive movement of energy from point to point along the surface of the water.

Word Tutor:

waving

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IN BRIEF: n. - The act of signaling by a movement of the hand adj. - Streaming or flapping or spreading wide as if in a current of air.

LearnThatWord.com is a free vocabulary and spelling program where you only pay for results!

Sign Language Videos:

waves

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as in: waves in the water
sign description: Both flat hands make a waving motion away from the body.

Dictionary of Cultural Literacy: Science:

wave

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In physics, any regularly recurring event, such as surf coming in toward a beach, that can be thought of as a disturbance moving through a medium. Waves are characterized by wavelength, frequency, and the speed at which they move. Waves are found in many forms.

The motion of a wave and the motion of the medium on which the wave moves are not the same: ocean waves, for example, move toward the beach, but the water itself merely moves up and down. Sound waves are spread by alternating compression and expansion of air.

Random House Word Menu:

categories related to 'wave'

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Random House Word Menu by Stephen Glazier

For a list of words related to wave, see:

Hair Styles - wave: hair formed into loose curls
Forecasting and Meteorology - wave: period of intense, unseasonable heat or cold
Principles of Mechanics, Waves, and Measurement - wave: traveling disturbance in a medium that does not create any permanent displacement in that medium
Electricity and Electronics - wave: progressive disturbance or variation that propagates energy from point to point in a medium; undulating or jagged representation of this action
Directions - wave: waver

Wikipedia on Answers.com:

Wave

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This article is about waves in the scientific sense. For other uses of wave or waves, see Wave (disambiguation).

Surface waves in water

In physics, a wave is a disturbance or oscillation that travels through spacetime, accompanied by a transfer of energy. Wave motion transfers energy from one point to another, often with no permanent displacement of the particles of the medium—that is, with little or no associated mass transport. They consist, instead, of oscillations or vibrations around almost fixed locations. Waves are described by a wave equation which sets out how the disturbance proceeds over time. The mathematical form of this equation varies depending on the type of wave.

There are two main types of waves. Mechanical waves propagate through a medium, and the substance of this medium is deformed. The deformation reverses itself owing to restoring forces resulting from its deformation. For example, sound waves propagate via air molecules colliding with their neighbors. When air molecules collide, they also bounce away from each other (a restoring force). This keeps the molecules from continuing to travel in the direction of the wave.

The second type of wave, electromagnetic waves, do not require a medium. Instead, they consist of periodic oscillations in electrical and magnetic fields generated by charged particles, and can therefore travel through a vacuum. These types of waves vary in wavelength, and include radio waves, infrared radiation, visible light, ultraviolet radiation, X-rays, and gamma rays.

A wave can be transverse or longitudinal depending on the direction of its oscillation. Transverse waves occur when a disturbance creates oscillations perpendicular (at right angles) to the propagation (the direction of energy transfer). Longitudinal waves occur when the oscillations are parallel to the direction of propagation. While mechanical waves can be both transverse and longitudinal, all electromagnetic waves are transverse.

General features

A single, all-encompassing definition for the term wave is not straightforward. A vibration can be defined as a back-and-forth motion around a reference value. However, a vibration is not necessarily a wave. An attempt to define the necessary and sufficient characteristics that qualify a phenomenon to be called a wave results in a fuzzy border line.

The term wave is often intuitively understood as referring to a transport of spatial disturbances that are generally not accompanied by a motion of the medium occupying this space as a whole. In a wave, the energy of a vibration is moving away from the source in the form of a disturbance within the surrounding medium (Hall 1980, p. 8). However, this notion is problematic for a standing wave (for example, a wave on a string), where energy is moving in both directions equally, or for electromagnetic (e.g., light) waves in a vacuum, where the concept of medium does not apply and interaction with a target is the key to wave detection and practical applications. There are water waves on the ocean surface; gamma waves and light waves emitted by the Sun; microwaves used in microwave ovens and in radar equipment; radio waves broadcast by radio stations; and sound waves generated by radio receivers, telephone handsets and living creatures (as voices), to mention only a few wave phenomena.

It may appear that the description of waves is closely related to their physical origin for each specific instance of a wave process. For example, acoustics is distinguished from optics in that sound waves are related to a mechanical rather than an electromagnetic wave transfer caused by vibration. Concepts such as mass, momentum, inertia, or elasticity, become therefore crucial in describing acoustic (as distinct from optic) wave processes. This difference in origin introduces certain wave characteristics particular to the properties of the medium involved. For example, in the case of air: vortices, radiation pressure, shock waves etc.; in the case of solids: Rayleigh waves, dispersion; and so on.

Other properties, however, although usually described in terms of origin, may be generalized to all waves. For such reasons, wave theory represents a particular branch of physics that is concerned with the properties of wave processes independently of their physical origin.^[1] For example, based on the mechanical origin of acoustic waves, a moving disturbance in space–time can exist if and only if the medium involved is neither infinitely stiff nor infinitely pliable. If all the parts making up a medium were rigidly bound, then they would all vibrate as one, with no delay in the transmission of the vibration and therefore no wave motion. This is impossible because it would violate general relativity. On the other hand, if all the parts were independent, then there would not be any transmission of the vibration and again, no wave motion. Although the above statements are meaningless in the case of waves that do not require a medium, they reveal a characteristic that is relevant to all waves regardless of origin: within a wave, the phase of a vibration (that is, its position within the vibration cycle) is different for adjacent points in space because the vibration reaches these points at different times.

Similarly, wave processes revealed from the study of waves other than sound waves can be significant to the understanding of sound phenomena. A relevant example is Thomas Young's principle of interference (Young, 1802, in Hunt 1992, p. 132). This principle was first introduced in Young's study of light and, within some specific contexts (for example, scattering of sound by sound), is still a researched area in the study of sound.

Mathematical description of one-dimensional waves

Wave equation

Main articles: Wave equation and D'Alembert's formula

Consider a traveling transverse wave (which may be a pulse) on a string (the medium). Consider the string to have a single spatial dimension. Consider this wave as traveling

Wavelength λ, can be measured between any two corresponding points on a waveform

in the $x$ direction in space. E.g., let the positive $x$ direction be to the right, and the negative $x$ direction be to the left.
with constant amplitude $u$
with constant velocity , where is
- independent of wavelength (no dispersion)
- independent of amplitude (linear media, not nonlinear).^[2]
with constant waveform, or shape

This wave can then be described by the two-dimensional functions

$u(x, \ t) = F(x - v \ t)$ (waveform $F$ traveling to the right)

$u(x, \ t) = G(x + v \ t)$ (waveform $G$ traveling to the left)

or, more generally, by d'Alembert's formula:^[3]

$u(x,t)=F(x-vt)+G(x+vt). \,$

representing two component waveforms $F$ and $G$ traveling through the medium in opposite directions. This wave can also be represented by the partial differential equation

$\frac{1}{v^2}\frac{\partial^2 u}{\partial t^2}=\frac{\partial^2 u}{\partial x^2}. \,$

General solutions are based upon Duhamel's principle.^[4]

Wave forms

Sine, square, triangle and sawtooth waveforms.

The form or shape of F in d'Alembert's formula involves the argument x − vt. Constant values of this argument correspond to constant values of F, and these constant values occur if x increases at the same rate that vt increases. That is, the wave shaped like the function F will move in the positive x-direction at velocity v (and G will propagate at the same speed in the negative x-direction).^[5]

In the case of a periodic function F with period λ, that is, F(x + λ − vt) = F(x − vt), the periodicity of F in space means that a snapshot of the wave at a given time t finds the wave varying periodically in space with period λ (the wavelength of the wave). In a similar fashion, this periodicity of F implies a periodicity in time as well: F(x − v(t + T)) = F(x − vt) provided vT = λ, so an observation of the wave at a fixed location x finds the wave undulating periodically in time with period T = λ/v.^[6]

Amplitude and modulation

Illustration of the envelope (the slowly varying red curve) of an amplitude-modulated wave. The fast varying blue curve is the carrier wave, which is being modulated.

Main article: Amplitude modulation

See also: Frequency modulation and Phase modulation

The amplitude of a wave may be constant (in which case the wave is a c.w. or continuous wave), or may be modulated so as to vary with time and/or position. The outline of the variation in amplitude is called the envelope of the wave. Mathematically, the modulated wave can be written in the form:^[7]^[8]^[9]

$u(x, \ t) = A(x, \ t)\sin (kx - \omega t + \phi) \ ,$

where $A(x,\ t)$ is the amplitude envelope of the wave, $k$ is the wavenumber and $\phi$ is the phase. If the group velocity $v_g$ (see below) is wavelength-independent, this equation can be simplified as:^[10]

$u(x, \ t) = A(x - v_g \ t)\sin (kx - \omega t + \phi) \ ,$

showing that the envelope moves with the group velocity and retains its shape. Otherwise, in cases where the group velocity varies with wavelength, the pulse shape changes in a manner often described using an envelope equation.^[10]^[11]

Phase velocity and group velocity

Frequency dispersion in groups of gravity waves on the surface of deep water. The red dot moves with the phase velocity, and the green dots propagate with the group velocity.

Main articles: Phase velocity and Group velocity

There are two velocities that are associated with waves, the phase velocity and the group velocity. To understand them, one must consider several types of waveform. For simplification, examination is restricted to one dimension.

This shows a wave with the Group velocity and Phase velocity going in different directions.

The most basic wave (a form of plane wave) may be expressed in the form:

$\psi (x, \ t) = A e^{i \left( kx - \omega t \right)} \ ,$

which can be related to the usual sine and cosine forms using Euler's formula. Rewriting the argument, $kx-\omega t = \left(\frac{2\pi}{\lambda}\right)(x - vt)$ , makes clear that this expression describes a vibration of wavelength $\lambda = \frac{2\pi}{k}$ traveling in the x-direction with a constant phase velocity $v_p = \frac{\omega}{k}\,$ .^[12]

The other type of wave to be considered is one with localized structure described by an envelope, which may be expressed mathematically as, for example:

$\psi (x, \ t) = \int_{-\infty} ^{\infty}\ dk_1 \ A(k_1)\ e^{i\left(k_1x - \omega t \right)} \ ,$

where now A(k₁) (the integral is the inverse fourier transform of A(k1)) is a function exhibiting a sharp peak in a region of wave vectors Δk surrounding the point k₁ = k. In exponential form:

$A = A_o (k_1) e^ {i \alpha (k_1)} \ ,$

with A_o the magnitude of A. For example, a common choice for A_o is a Gaussian wave packet:^[13]

$A_o (k_1) = N\ e^{-\sigma^2 (k_1-k)^2 / 2} \ ,$

where σ determines the spread of k₁-values about k, and N is the amplitude of the wave.

The exponential function inside the integral for ψ oscillates rapidly with its argument, say φ(k₁), and where it varies rapidly, the exponentials cancel each other out, interfere destructively, contributing little to ψ.^[12] However, an exception occurs at the location where the argument φ of the exponential varies slowly. (This observation is the basis for the method of stationary phase for evaluation of such integrals.^[14]) The condition for φ to vary slowly is that its rate of change with k₁ be small; this rate of variation is:^[12]

$\left . \frac{d \varphi }{d k_1} \right | _{k_1 = k } = x - t \left . \frac{d \omega}{dk_1}\right | _{k_1 = k } +\left . \frac{d \alpha}{d k_1}\right | _{k_1 = k } \ ,$

where the evaluation is made at k₁ = k because A(k₁) is centered there. This result shows that the position x where the phase changes slowly, the position where ψ is appreciable, moves with time at a speed called the group velocity:

$v_g = \frac{d \omega}{dk} \ .$

The group velocity therefore depends upon the dispersion relation connecting ω and k. For example, in quantum mechanics the energy of a particle represented as a wave packet is E = ħω = (ħk)²/(2m). Consequently, for that wave situation, the group velocity is

$v_g = \frac {\hbar k}{m} \ ,$

showing that the velocity of a localized particle in quantum mechanics is its group velocity.^[12] Because the group velocity varies with k, the shape of the wave packet broadens with time, and the particle becomes less localized.^[15] In other words, the velocity of the constituent waves of the wave packet travel at a rate that varies with their wavelength, so some move faster than others, and they cannot maintain the same interference pattern as the wave propagates.

Sinusoidal waves

Sinusoidal waves correspond to simple harmonic motion.

Mathematically, the most basic wave is the (spatially) one-dimensional sine wave (or harmonic wave or sinusoid) with an amplitude $u$ described by the equation:

$u(x, \ t)= A \sin (kx - \omega t + \phi) \ ,$

where

$A$ is the maximum amplitude of the wave, maximum distance from the highest point of the disturbance in the medium (the crest) to the equilibrium point during one wave cycle. In the illustration to the right, this is the maximum vertical distance between the baseline and the wave.
$x$ is the space coordinate
$t$ is the time coordinate
$k$ is the wavenumber
$\omega$ is the angular frequency
$\phi$ is the phase.

The units of the amplitude depend on the type of wave. Transverse mechanical waves (e.g., a wave on a string) have an amplitude expressed as a distance (e.g., meters), longitudinal mechanical waves (e.g., sound waves) use units of pressure (e.g., pascals), and electromagnetic waves (a form of transverse vacuum wave) express the amplitude in terms of its electric field (e.g., volts/meter).

The wavelength $\lambda$ is the distance between two sequential crests or troughs (or other equivalent points), generally is measured in meters. A wavenumber $k$ , the spatial frequency of the wave in radians per unit distance (typically per meter), can be associated with the wavelength by the relation

$k = \frac{2 \pi}{\lambda}. \,$

The period $T$ is the time for one complete cycle of an oscillation of a wave. The frequency $f$ is the number of periods per unit time (per second) and is typically measured in hertz. These are related by:

$f=\frac{1}{T}. \,$

In other words, the frequency and period of a wave are reciprocals.

The angular frequency $\omega$ represents the frequency in radians per second. It is related to the frequency or period by

$\omega = 2 \pi f = \frac{2 \pi}{T}. \,$

The wavelength $\lambda$ of a sinusoidal waveform traveling at constant speed $v$ is given by:^[16]

$\lambda = \frac{v}{f},$

where $v$ is called the phase speed (magnitude of the phase velocity) of the wave and $f$ is the wave's frequency.

Wavelength can be a useful concept even if the wave is not periodic in space. For example, in an ocean wave approaching shore, the incoming wave undulates with a varying local wavelength that depends in part on the depth of the sea floor compared to the wave height. The analysis of the wave can be based upon comparison of the local wavelength with the local water depth.^[17]

Although arbitrary wave shapes will propagate unchanged in lossless linear time-invariant systems, in the presence of dispersion the sine wave is the unique shape that will propagate unchanged but for phase and amplitude, making it easy to analyze.^[18] Due to the Kramers–Kronig relations, a linear medium with dispersion also exhibits loss, so the sine wave propagating in a dispersive medium is attenuated in certain frequency ranges that depend upon the medium.^[19] The sine function is periodic, so the sine wave or sinusoid has a wavelength in space and a period in time.^[20]^[21]

The sinusoid is defined for all times and distances, whereas in physical situations we usually deal with waves that exist for a limited span in space and duration in time. Fortunately, an arbitrary wave shape can be decomposed into an infinite set of sinusoidal waves by the use of Fourier analysis. As a result, the simple case of a single sinusoidal wave can be applied to more general cases.^[22]^[23] In particular, many media are linear, or nearly so, so the calculation of arbitrary wave behavior can be found by adding up responses to individual sinusoidal waves using the superposition principle to find the solution for a general waveform.^[24] When a medium is nonlinear, the response to complex waves cannot be determined from a sine-wave decomposition.

Plane waves

Main article: Plane wave

Standing waves

Main articles: Standing wave, Acoustic resonance, Helmholtz resonator, and Organ pipe

Standing wave in stationary medium. The red dots represent the wave nodes

A standing wave, also known as a stationary wave, is a wave that remains in a constant position. This phenomenon can occur because the medium is moving in the opposite direction to the wave, or it can arise in a stationary medium as a result of interference between two waves traveling in opposite directions.

The sum of two counter-propagating waves (of equal amplitude and frequency) creates a standing wave. Standing waves commonly arise when a boundary blocks further propagation of the wave, thus causing wave reflection, and therefore introducing a counter-propagating wave. For example when a violin string is displaced, transverse waves propagate out to where the string is held in place at the bridge and the nut, where the waves are reflected back. At the bridge and nut, the two opposed waves are in antiphase and cancel each other, producing a node. Halfway between two nodes there is an antinode, where the two counter-propagating waves enhance each other maximally. There is no net propagation of energy over time.

One-dimensional standing waves; the fundamental mode and the first 6 overtones.
A two-dimensional standing wave on a disk; this is the fundamental mode.
A standing wave on a disk with two nodal lines crossing at the center; this is an overtone.

Physical properties

Light beam exhibiting reflection, refraction, transmission and dispersion when encountering a prism

Waves exhibit common behaviors under a number of standard situations, e.g.,

Transmission and media

Main articles: Rectilinear propagation, Transmittance, and Transmission medium

Waves normally move in a straight line (i.e. rectilinearly) through a transmission medium. Such media can be classified into one or more of the following categories:

A bounded medium if it is finite in extent, otherwise an unbounded medium
A linear medium if the amplitudes of different waves at any particular point in the medium can be added
A uniform medium or homogeneous medium if its physical properties are unchanged at different locations in space
An anisotropic medium if one or more of its physical properties differ in one or more directions
An isotropic medium if its physical properties are the same in all directions

Absorption

Main articles: Absorption (acoustics) and Absorption (electromagnetic radiation)

Reflection

Main article: Reflection (physics)

When a wave strikes a reflective surface, it changes direction, such that the angle made by the incident wave and line normal to the surface equals the angle made by the reflected wave and the same normal line.

Interference

Main article: Interference (wave propagation)

Waves that encounter each other combine through superposition to create a new wave called an interference pattern. Important interference patterns occur for waves that are in phase.

Refraction

Main article: Refraction

Sinusoidal traveling plane wave entering a region of lower wave velocity at an angle, illustrating the decrease in wavelength and change of direction (refraction) that results.

Refraction is the phenomenon of a wave changing its speed. Mathematically, this means that the size of the phase velocity changes. Typically, refraction occurs when a wave passes from one medium into another. The amount by which a wave is refracted by a material is given by the refractive index of the material. The directions of incidence and refraction are related to the refractive indices of the two materials by Snell's law.

Diffraction

Main article: Diffraction

A wave exhibits diffraction when it encounters an obstacle that bends the wave or when it spreads after emerging from an opening. Diffraction effects are more pronounced when the size of the obstacle or opening is comparable to the wavelength of the wave.

Polarization

Main article: Polarization (waves)

A wave is polarized if it oscillates in one direction or plane. A wave can be polarized by the use of a polarizing filter. The polarization of a transverse wave describes the direction of oscillation in the plane perpendicular to the direction of travel.

Longitudinal waves such as sound waves do not exhibit polarization. For these waves the direction of oscillation is along the direction of travel.

Dispersion

Schematic of light being dispersed by a prism. Click to see animation.

Main articles: Dispersion (optics) and Dispersion (water waves)

A wave undergoes dispersion when either the phase velocity or the group velocity depends on the wave frequency. Dispersion is most easily seen by letting white light pass through a prism, the result of which is to produce the spectrum of colours of the rainbow. Isaac Newton performed experiments with light and prisms, presenting his findings in the Opticks (1704) that white light consists of several colours and that these colours cannot be decomposed any further.^[25]

Mechanical waves

Main article: Mechanical wave

Waves on strings

Main article: Vibrating string

The speed of a wave traveling along a vibrating string ( v ) is directly proportional to the square root of the tension of the string ( T ) over the linear mass density ( μ ):

$v=\sqrt{\frac{T}{\mu}}, \,$

where the linear density μ is the mass per unit length of the string.

Acoustic waves

Acoustic or sound waves travel at speed given by

$v=\sqrt{\frac{B}{\rho_0}}, \,$

or the square root of the adiabatic bulk modulus divided by the ambient fluid density (see speed of sound).

Water waves

Main article: Water waves

Ripples on the surface of a pond are actually a combination of transverse and longitudinal waves; therefore, the points on the surface follow orbital paths.
Sound—a mechanical wave that propagates through gases, liquids, solids and plasmas;
Inertial waves, which occur in rotating fluids and are restored by the Coriolis effect;
Ocean surface waves, which are perturbations that propagate through water.

Seismic waves

Main article: Seismic waves

Shock waves

Main article: Shock wave

See also: Sonic boom and Cherenkov radiation

Other

Waves of traffic, that is, propagation of different densities of motor vehicles, and so forth, which can be modeled as kinematic waves^[26]

Metachronal wave refers to the appearance of a traveling wave produced by coordinated sequential actions.

Electromagnetic waves

Main articles: Electromagnetic radiation and Electromagnetic spectrum

(radio, micro, infrared, visible, uv)

An electromagnetic wave consists of two waves that are oscillations of the electric and magnetic fields. An electromagnetic wave travels in a direction that is at right angles to the oscillation direction of both fields. In the 19th century, James Clerk Maxwell showed that, in vacuum, the electric and magnetic fields satisfy the wave equation both with speed equal to that of the speed of light. From this emerged the idea that light is an electromagnetic wave. Electromagnetic waves can have different frequencies (and thus wavelengths), giving rise to various types of radiation such as radio waves, microwaves, infrared, visible light, ultraviolet and X-rays.

Quantum mechanical waves

Main article: Schrödinger equation

de Broglie waves

Main articles: Wave packet and Matter wave

Louis de Broglie postulated that all particles with momentum have a wavelength

$\lambda = \frac{h}{p},$

where h is Planck's constant, and p is the magnitude of the momentum of the particle. This hypothesis was at the basis of quantum mechanics. Nowadays, this wavelength is called the de Broglie wavelength. For example, the electrons in a CRT display have a de Broglie wavelength of about 10⁻¹³ m.

A wave representing such a particle traveling in the k-direction is expressed by the wave function:

$\psi (\mathbf{r}, \ t=0) =A\ e^{i\mathbf{k \cdot r}} \ ,$

where the wavelength is determined by the wave vector k as:

$\lambda = \frac {2 \pi}{k} \ ,$

and the momentum by:

$\mathbf p = \hbar \mathbf{k} \ .$

However, a wave like this with definite wavelength is not localized in space, and so cannot represent a particle localized in space. To localize a particle, de Broglie proposed a superposition of different wavelengths ranging around a central value in a wave packet,^[28] a waveform often used in quantum mechanics to describe the wave function of a particle. In a wave packet, the wavelength of the particle is not precise, and the local wavelength deviates on either side of the main wavelength value.

In representing the wave function of a localized particle, the wave packet is often taken to have a Gaussian shape and is called a Gaussian wave packet.^[29] Gaussian wave packets also are used to analyze water waves.^[30]

For example, a Gaussian wavefunction ψ might take the form:^[31]

$\psi(x,\ t=0) = A\ \exp \left( -\frac{x^2}{2\sigma^2} + i k_0 x \right) \ ,$

at some initial time t = 0, where the central wavelength is related to the central wave vector k₀ as λ₀ = 2π / k₀. It is well known from the theory of Fourier analysis,^[32] or from the Heisenberg uncertainty principle (in the case of quantum mechanics) that a narrow range of wavelengths is necessary to produce a localized wave packet, and the more localized the envelope, the larger the spread in required wavelengths. The Fourier transform of a Gaussian is itself a Gaussian.^[33] Given the Gaussian:

$f(x) = e^{-x^2 / (2\sigma^2)} \ ,$

the Fourier transform is:

$\tilde{ f} (k) = \sigma e^{-\sigma^2 k^2 / 2} \ .$

The Gaussian in space therefore is made up of waves:

$f(x) = \frac{1}{\sqrt{2 \pi}} \int_{-\infty}^{\infty} \ \tilde{f} (k) e^{ikx} \ dk \ ;$

that is, a number of waves of wavelengths λ such that kλ = 2 π.

The parameter σ decides the spatial spread of the Gaussian along the x-axis, while the Fourier transform shows a spread in wave vector k determined by 1/σ. That is, the smaller the extent in space, the larger the extent in k, and hence in λ = 2π/k.

Animation showing the effect of a cross-polarized gravitational wave on a ring of test particles

Gravitational waves

Main article: Gravitational wave

Researchers believe that gravitational waves also travel through space, although gravitational waves have never been directly detected. Not to be confused with gravity waves, gravitational waves are disturbances in the curvature of spacetime, predicted by Einstein's theory of general relativity.

WKB method

Main article: WKB method

In a nonuniform medium, in which the wavenumber k can depend on the location as well as the frequency, the phase term kx is typically replaced by the integral of k(x)dx, according to the WKB method. Such nonuniform traveling waves are common in many physical problems, including the mechanics of the cochlea and waves on hanging ropes.

References

^ Lev A. Ostrovsky & Alexander I. Potapov (2002). Modulated waves: theory and application. Johns Hopkins University Press. ISBN 0-8018-7325-8. http://www.amazon.com/gp/product/0801873258.
^ Michael A. Slawinski (2003). "Wave equations". Seismic waves and rays in elastic media. Elsevier. pp. 131 ff. ISBN 0-08-043930-6. http://books.google.com/?id=s7bp6ezoRhcC&pg=PA134.
^ Karl F Graaf (1991). Wave motion in elastic solids (Reprint of Oxford 1975 ed.). Dover. pp. 13–14. ISBN 978-0-486-66745-4. http://books.google.com/?id=5cZFRwLuhdQC&printsec=frontcover.
^ Jalal M. Ihsan Shatah, Michael Struwe (2000). "The linear wave equation". Geometric wave equations. American Mathematical Society Bookstore. pp. 37 ff. ISBN 0-8218-2749-9. http://books.google.com/?id=zsasG2axbSoC&pg=PA37.
^ Louis Lyons (1998). All you wanted to know about mathematics but were afraid to ask. Cambridge University Press. pp. 128 ff. ISBN 0-521-43601-X. http://books.google.com/?id=WdPGzHG3DN0C&pg=PA128.
^ Alexander McPherson (2009). "Waves and their properties". Introduction to Macromolecular Crystallography (2 ed.). Wiley. p. 77. ISBN 0-470-18590-2. http://books.google.com/?id=o7sXm2GSr9IC&pg=PA77.
^ Christian Jirauschek (2005). FEW-cycle Laser Dynamics and Carrier-envelope Phase Detection. Cuvillier Verlag. p. 9. ISBN 3-86537-419-0. http://books.google.com/?id=6kOoT_AX2CwC&pg=PA9.
^ Fritz Kurt Kneubühl (1997). Oscillations and waves. Springer. p. 365. ISBN 3-540-62001-X. http://books.google.com/?id=geYKPFoLgoMC&pg=PA365.
^ Mark Lundstrom (2000). Fundamentals of carrier transport. Cambridge University Press. p. 33. ISBN 0-521-63134-3. http://books.google.com/?id=FTdDMtpkSkIC&pg=PA33.
^ ^a ^b Chin-Lin Chen (2006). "§13.7.3 Pulse envelope in nondispersive media". Foundations for guided-wave optics. Wiley. p. 363. ISBN 0-471-75687-3. http://books.google.com/?id=LxzWPskhns0C&pg=PA363.
^ Stefano Longhi, Davide Janner (2008). "Localization and Wannier wave packets in photonic crystals". In Hugo E. Hernández-Figueroa, Michel Zamboni-Rached, Erasmo Recami. Localized Waves. Wiley-Interscience. p. 329. ISBN 0-470-10885-1. http://books.google.com/?id=xxbXgL967PwC&pg=PA329.
^ ^a ^b ^c ^d Albert Messiah (1999). Quantum Mechanics (Reprint of two-volume Wiley 1958 ed.). Courier Dover. pp. 50–52. ISBN 978-0-486-40924-5. http://books.google.com/?id=mwssSDXzkNcC&pg=PA52&dq=intitle:quantum+inauthor:messiah+%22group+velocity%22+%22center+of+the+wave+packet%22.
^ See, for example, Eq. 2(a) in Walter Greiner, D. Allan Bromley (2007). Quantum Mechanics: An introduction (2nd ed.). Springer. pp. 60–61. ISBN 3-540-67458-6. http://books.google.com/?id=7qCMUfwoQcAC&pg=PA61.
^ John W. Negele, Henri Orland (1998). Quantum many-particle systems (Reprint in Advanced Book Classics ed.). Westview Press. p. 121. ISBN 0-7382-0052-2. http://books.google.com/?id=mx5CfeeEkm0C&pg=PA121.
^ Donald D. Fitts (1999). Principles of quantum mechanics: as applied to chemistry and chemical physics. Cambridge University Press. pp. 15 ff. ISBN 0-521-65841-1. http://books.google.com/?id=8t4DiXKIvRgC&pg=PA15.
^ David C. Cassidy, Gerald James Holton, Floyd James Rutherford (2002). Understanding physics. Birkhäuser. pp. 339 ff. ISBN 0-387-98756-8. http://books.google.com/?id=rpQo7f9F1xUC&pg=PA340.
^ Paul R Pinet (2009). op. cit.. p. 242. ISBN 0-7637-5993-7. http://books.google.com/?id=6TCm8Xy-sLUC&pg=PA242.
^ Mischa Schwartz, William R. Bennett, and Seymour Stein (1995). Communication Systems and Techniques. John Wiley and Sons. p. 208. ISBN 978-0-7803-4715-1. http://books.google.com/?id=oRSHWmaiZwUC&pg=PA208&dq=sine+wave+medium++linear+time-invariant.
^ See Eq. 5.10 and discussion in A. G. G. M. Tielens (2005). The physics and chemistry of the interstellar medium. Cambridge University Press. pp. 119 ff. ISBN 0-521-82634-9. http://books.google.com/?id=wMnvg681JXMC&pg=PA119. ; Eq. 6.36 and associated discussion in Otfried Madelung (1996). Introduction to solid-state theory (3rd ed.). Springer. pp. 261 ff. ISBN 3-540-60443-X. http://books.google.com/?id=yK_J-3_p8_oC&pg=PA261. ; and Eq. 3.5 in F Mainardi (1996). "Transient waves in linear viscoelastic media". In Ardéshir Guran, A. Bostrom, Herbert Überall, O. Leroy. Acoustic Interactions with Submerged Elastic Structures: Nondestructive testing, acoustic wave propagation and scattering. World Scientific. p. 134. ISBN 981-02-4271-9. http://books.google.com/?id=UfSk45nCVKMC&pg=PA134.
^ Aleksandr Tikhonovich Filippov (2000). The versatile soliton. Springer. p. 106. ISBN 0-8176-3635-8. http://books.google.com/?id=TC4MCYBSJJcC&pg=PA106.
^ Seth Stein, Michael E. Wysession (2003). An introduction to seismology, earthquakes, and earth structure. Wiley-Blackwell. p. 31. ISBN 0-86542-078-5. http://books.google.com/?id=Kf8fyvRd280C&pg=PA31.
^ Seth Stein, Michael E. Wysession (2003). op. cit.. p. 32. ISBN 0-86542-078-5. http://books.google.com/?id=Kf8fyvRd280C&pg=PA32.
^ Kimball A. Milton, Julian Seymour Schwinger (2006). Electromagnetic Radiation: Variational Methods, Waveguides and Accelerators. Springer. p. 16. ISBN 3-540-29304-3. http://books.google.com/?id=x_h2rai2pYwC&pg=PA16. "Thus, an arbitrary function f(r, t) can be synthesized by a proper superposition of the functions exp[i (k·r−ωt)]..."
^ Raymond A. Serway and John W. Jewett (2005). "§14.1 The Principle of Superposition". Principles of physics (4th ed.). Cengage Learning. p. 433. ISBN 0-534-49143-X. http://books.google.com/?id=1DZz341Pp50C&pg=PA433.
^ Newton, Isaac (1704). "Prop VII Theor V". Opticks: Or, A treatise of the Reflections, Refractions, Inflexions and Colours of Light. Also Two treatises of the Species and Magnitude of Curvilinear Figures. 1. London. p. 118. http://gallica.bnf.fr/ark:/12148/bpt6k3362k.image.f128.pagination. "All the Colours in the Universe which are made by Light... are either the Colours of homogeneal Lights, or compounded of these..."
^ M. J. Lighthill; G. B. Whitham (1955). "On kinematic waves. II. A theory of traffic flow on long crowded roads". Proceedings of the Royal Society of London. Series A 229: 281–345. Bibcode 1955RSPSA.229..281L. doi:10.1098/rspa.1955.0088. And: P. I. Richards (1956). "Shockwaves on the highway". Operations Research 4 (1): 42–51. doi:10.1287/opre.4.1.42.
^ A. T. Fromhold (1991). "Wave packet solutions". Quantum Mechanics for Applied Physics and Engineering (Reprint of Academic Press 1981 ed.). Courier Dover Publications. pp. 59 ff. ISBN 0-486-66741-3. http://books.google.com/?id=3SOwc6npkIwC&pg=PA59. "(p. 61) ...the individual waves move more slowly than the packet and therefore pass back through the packet as it advances"
^ Ming Chiang Li (1980). "Electron Interference". In L. Marton & Claire Marton. Advances in Electronics and Electron Physics. 53. Academic Press. p. 271. ISBN 0-12-014653-3. http://books.google.com/?id=g5q6tZRwUu4C&pg=PA271.
^ See for example Walter Greiner, D. Allan Bromley (2007). Quantum Mechanics (2 ed.). Springer. p. 60. ISBN 3-540-67458-6. http://books.google.com/?id=7qCMUfwoQcAC&pg=PA60. and John Joseph Gilman (2003). Electronic basis of the strength of materials. Cambridge University Press. p. 57. ISBN 0-521-62005-8. http://books.google.com/?id=YWd7zHU0U7UC&pg=PA57. ,Donald D. Fitts (1999). Principles of quantum mechanics. Cambridge University Press. p. 17. ISBN 0-521-65841-1. http://books.google.com/?id=8t4DiXKIvRgC&pg=PA17. .
^ Chiang C. Mei (1989). The applied dynamics of ocean surface waves (2nd ed.). World Scientific. p. 47. ISBN 9971-5-0789-7. http://books.google.com/?id=WHMNEL-9lqkC&pg=PA47.
^ Walter Greiner, D. Allan Bromley (2007). Quantum Mechanics (2nd ed.). Springer. p. 60. ISBN 3-540-67458-6. http://books.google.com/?id=7qCMUfwoQcAC&pg=PA60.
^ Siegmund Brandt, Hans Dieter Dahmen (2001). The picture book of quantum mechanics (3rd ed.). Springer. p. 23. ISBN 0-387-95141-5. http://books.google.com/?id=VM4GFlzHg34C&pg=PA23.
^ Cyrus D. Cantrell (2000). Modern mathematical methods for physicists and engineers. Cambridge University Press. p. 677. ISBN 0-521-59827-3. http://books.google.com/?id=QKsiFdOvcwsC&pg=PA677.

Sources

Campbell, M. and Greated, C. (1987). The Musician’s Guide to Acoustics. New York: Schirmer Books.
French, A.P. (1971). Vibrations and Waves (M.I.T. Introductory physics series). Nelson Thornes. ISBN 0-393-09936-9. OCLC 163810889.
Hall, D. E. (1980). Musical Acoustics: An Introduction. Belmont, California: Wadsworth Publishing Company. ISBN 0-534-00758-9. .
Hunt, F. V. (1992) (^{[dead link]}). Origins in Acoustics. New York: Acoustical Society of America Press. http://asa.aip.org/publications.html#pub17. .
Ostrovsky, L. A.; Potapov, A. S. (1999). Modulated Waves, Theory and Applications. Baltimore: The Johns Hopkins University Press. ISBN 0-8018-5870-4. .
Vassilakis, P.N. (2001). Perceptual and Physical Properties of Amplitude Fluctuation and their Musical Significance. Doctoral Dissertation. University of California, Los Angeles.

External links

Wikimedia Commons has media related to: Wave

Look up wave in Wiktionary, the free dictionary.

Interactive Visual Representation of Waves
Science Aid: Wave properties—Concise guide aimed at teens
Simulation of diffraction of water wave passing through a gap
Simulation of interference of water waves
Simulation of longitudinal traveling wave
Simulation of stationary wave on a string
Simulation of transverse traveling wave
Sounds Amazing—AS and A-Level learning resource for sound and waves
chapter from an online textbook
Simulation of waves on a string
of longitudinal and transverse mechanical wave
MIT OpenCourseWare 8.03: Vibrations and Waves Free, independent study course with video lectures, assignments, lecture notes and exams.

Velocities of waves
Phase velocity • Group velocity • Front velocity • Signal velocity

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Translations:

Wave

Top

Home > Library > Literature & Language > Translations

Dansk (Danish)
v. intr. - vinke, vifte, ondulere, bølge, veje
v. tr. - vinke, bølge, vifte, veje, ondulere
n. - bølge, sø, vink, vinken, svingen

idioms:

make waves skabe uro, gøre sig bemærket
wave band bølgeområde
wave down vinke ned
wave goodbye vinke farvel
wave power bølgekraft
wave train bølgetog

Nederlands (Dutch)
golven, zwaaien, wuiven, waaien, watergolven, gewuif, golf, watergolf

Français (French)
v. intr. - saluer qn de la main, faire signe à qn de faire, gesticuler, onduler (des branches), ondoyer, flotter au vent (un drapeau)
v. tr. - agiter, brandir, faire un signe de la main, faire au revoir de la main à, (fig) dire adieu à, faire signe d'avancer/de s'éloigner/de passer
n. - signe (de la main), vague, (fig) vague (de), cran (cheveu), (Phys) onde, ondulation

idioms:

make waves faire des vagues (vent), (fig) faire du bruit, créer des histoires
wave aside repousser (qch) d'un geste (une suggestion), écarter qn
wave band (Phys, Radio) longueur d'ondes, bande de fréquences
wave down se calmer, redescendre, faire signe de s'arrêter
wave goodbye (lit) faire au revoir de la main à, (fig) dire adieu à
wave power énergie des vagues
wave train train d'ondes

Deutsch (German)
v. - winken, schwenken, (sich) wellen, wehen
n. - Welle, Woge

idioms:

make waves Wellen schlagen, für Aufregung sorgen
wave aside eine Idee verwerfen
wave band Frequenzband, Wellenband, Wellenband, Wellenbereich
wave down (durch Winken) anhalten
wave goodbye zum Abschied zuwinken
wave power Wellenkraft
wave train Wellenzug

Ελληνική (Greek)
v. - κυματίζω, ανεμίζω, κατσαρώνω, χαιρετώ με κίνηση του χεριού, χειρονομώ
n. - κύμα, κατσάρωμα, οντουλάρισμα (μαλλιών), χαιρετιστήρια χειρονομία, γνέψιμο, κούνημα του χεριού
abbr. - των κυμάτων

idioms:

make waves δημιουργώ δυσκολίες ή προβλήματα
wave band (τεχνολ.) ζώνη συχνοτήτων
wave down κάνω σήμα σε (κινούμενο) όχημα να σταματήσει
wave goodbye αποχαιρετώ
wave power κυματική ενέργεια
wave train σειρά κυμάτων με την ίδια κατεύθυνση

Italiano (Italian)
far cenni di mano, arricciare, sventolare, ondulare, flutto, ondata, onda

idioms:

make waves sollevare obbiezioni, creare problemi, far rumore
wave band banda di frequenza
wave down fermare
wave power potenza d'onda
wave train serie d'onde

Português (Portuguese)
v. - acenar, flutuar
n. - onda (f), aceno (m), explosão (f)
abbr. - membro da reserva americana

idioms:

make waves fazer ondas
wave band faixa de ondas (f)
wave down acenar com a mão para fazer um veículo (taxi, ônibus, etc.) para parar
wave power energia de ondas
wave train várias ondas uma atrás da outra

Русский (Russian)
волна, подъем чего-л., демографический взрыв, волнистость, волновой импульс, колебание, атакующая цепь, развеваться, качаться, волноваться (о ниве и т.п.), виться (о волосах), завивать (волосы), подавать знак рукой

idioms:

make waves вызывать неприятности, волновать (общество), производить впечатление
wave band диапазон волн
wave down остановить (автомобиль), махая рукой
wave power использование энергии морских волн
wave train волны, перемежающиеся регулярными интервалами

Español (Spanish)
v. intr. - ondular, flamear, señalar con un ademán, hacer señales, ondulación
v. tr. - agitar la mano, saludar con la mano, ondular, blandir, agitarse, hacer señas con, hacer ademán de
n. - ola, onda, oleada, racha, ondulación, piélago, movimiento de la mano, ademán

idioms:

make waves hacer olas, levantar polvareda
wave aside echar a un lado, desechar, apartar (con un ademán)
wave band banda de ondas
wave down hacer señales para que pare
wave goodbye despedirse de alguien, hacer adiós con la mano
wave power energía mareomotriz
wave train tren de ondas

Svenska (Swedish)
v. - vinka, bölja, vaja
n. - våg, vågformig, vinkning
n. pl., - abbr.

中文（简体）(Chinese (Simplified))
示意, 波动, 致意, 使波动, 挥舞, 使飘扬, 波, 波浪

idioms:

make waves 捣蛋
wave band 波带, 电视波段
wave down 挥手示意停下
wave goodbye 挥手告别, 打招呼
wave power 水波动力
wave train 波列

中文（繁體）(Chinese (Traditional))
v. intr. - 示意, 波動, 致意
v. tr. - 使波動, 揮舞, 使飄揚
n. - 波, 波動, 波浪

idioms:

make waves 搗蛋
wave band 波帶, 電視波段
wave down 揮手示意停下
wave goodbye 揮手告別, 打招呼
wave power 水波動力
wave train 波列

한국어 (Korean)
v. intr. - 파도 치다, 흔들리다, 손을 흔들다
v. tr. - 흔들다, 흔들어 신호하다, 물결 모양으로 하다
n. - 물결, 흔들림, 웨이브, 고조

idioms:

make waves 풍파를 일으키다
wave down 손을 흔들어 (차를) 세우다

日本語 (Japanese)
n. - 波, 波のような動き, うねり, 波動, 振ること, 高まり, 変動, 起伏
v. - 揺れる, 振る, ウエーブさせる, 合図する, 波の形をしている

idioms:

make waves 平穏を乱す
tidal wave 津波, 激しい動き
wave band 周波帯
wave down 手を振って止める
wave power 波力
wave train 波列

العربيه (Arabic)
‏(فعل) يموج, يتموج, يلوح, يشير من بعيد (الاسم) موجه, تموج, تلويح (الجمع) (اختصار) متجندة في البحريه الأمريكيه‏

עברית (Hebrew)
v. intr. - ‮התנועע, התנופף, הסתלסל‬
v. tr. - ‮נענע, נופף, נפנף, סלסל‬
n. - ‮גל, נחשול, נפנוף יד, סלסול, סלסול שיער‬

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Columbia Encyclopedia The Columbia Electronic Encyclopedia, Sixth Edition Copyright © 2012, Columbia University Press. Licensed from Columbia University Press. All rights reserved. www.cc.columbia.edu/cu/cup/. Read

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Answer these

How do S-waves compare to P-Waves and Rayleigh Waves?

What waves property is not different about radio waves and ultraviolet waves?

Why electromagnetic wave is atransverse wave and not a compressional wave?

The wave crest of light waves are what to the direction the wave travels?

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