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Phase

 
Sci-Tech Encyclopedia: Phase
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The fractional part of a period through which the time variable of a periodic quantity (alternating electric current, vibration) has moved, as measured at any point in time from an arbitrary time origin. In the case of a sinusoidally varying quantity, the time origin is usually assumed to be the last point at which the quantity passed through a zero position from a negative to a positive direction.

In comparing the phase relationships at a given instant between two time-varying quantities, the phase of one is usually assumed to be zero, and the phase of the other is described, with respect to the first, as the fractional part of a period through which the second quantity must vary to achieve a zero of its own (see illustration). In this case, the fractional part of the period is usually expressed in terms of angular measure, with one period being equal to 360° or 2π radians. See also Phase-angle measurement; Sine wave.

An illustration of the meaning of phase for a sinusoidal wave. The difference in phase between waves 1 and 2 is φ and is called the phase angle. For each wave, <i>A</i> is the <ailnk tname=amplitude and T is the period.">
An illustration of the meaning of phase for a sinusoidal wave. The difference in phase between waves 1 and 2 is φ and is called the phase angle. For each wave, A is the amplitude and T is the period.

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Britannica Concise Encyclopedia: phase
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In wave motion, the fraction of the time required to complete a full cycle that a point completes after last passing through the reference position. Two periodic motions are said to be in phase when corresponding points of each reach maximum or minimum displacements at the same time. If the crests of two waves pass the same point at the same time, they are in phase for that position. If the crest of one and the trough of the other pass the same point at the same time, the phase angles differ by 180° and the waves are said to be of opposite phase. Phase differences are important in alternating electric current technology (see alternating current).

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Electronics Dictionary: phase
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Angular relationship between two waves.


Wikipedia: Phase (waves)
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Simple harmonic motion; A is the amplitude and T is the period

The phase of an oscillation or wave is the fraction of a complete cycle corresponding to an offset in the displacement from a specified reference point at time t = 0. Phase is a frequency domain or Fourier transform domain concept, and as such, can be readily understood in terms of simple harmonic motion. The same concept applies to wave motion, viewed either at a point in space over an interval of time or across an interval of space at a moment in time. Simple harmonic motion is a displacement that varies cyclically, as depicted to the right.

It is described by the formula:

x(t) = A\cdot \sin( 2 \pi f t + \theta ),\,

where A is the amplitude of oscillation, f is the frequency, t is the elapsed time, and θ is the phase of the oscillation. The phase determines or is determined by the initial displacement at time t = 0. A motion with frequency f has period T=\frac{1}{f}.  

Two potential ambiguities can be noted:

  • One is that the initial displacement of  \cos( 2 \pi f t + \theta )\,  is different from the sine function, yet they appear to have the same "phase".
  • The time-variant angle  2 \pi f t + \theta,\,  or its modulo value, is also commonly referred to as "phase". Then it is not an initial condition, but rather a continuously-changing condition.

The term instantaneous phase is used to distinguish the time-variant angle from the initial condition. It also has a formal definition that is applicable to more general functions and unambiguously defines a function's initial phase at t=0.  I.e., sine and cosine inherently have different initial phases. When not explicitly stated otherwise, cosine should generally be inferred. (also see phasor)

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Phase shift

Illustration of phase shift. The horizontal axis represents an angle (phase) that is increasing with time.

θ is sometimes referred to as a phase-shift, because it represents a "shift" from zero phase. But a change in θ is also referred to as a phase-shift.

For infinitely long sinusoids, a change in θ is the same as a shift in time, such as a time-delay. If x(t)\, is delayed (time-shifted) by \begin{matrix} \frac{1}{4} \end{matrix}\, of its cycle, it becomes:

x(t - \begin{matrix} \frac{1}{4} \end{matrix}T) \, = A\cdot \sin(2 \pi f (t - \begin{matrix} \frac{1}{4} \end{matrix}T) + \theta) \,
= A\cdot \sin(2 \pi f t - \begin{matrix}\frac{\pi }{2} \end{matrix} + \theta ),\,

whose "phase" is now \theta - \begin{matrix}\frac{\pi }{2} \end{matrix}.   It has been shifted by \begin{matrix}\frac{\pi }{2} \end{matrix}.

Phase difference

In-phase waves
Out-of-phase waves
Left: the real part of a plane wave moving from top to bottom. Right: the same wave after a central section underwent a phase shift, for example, by passing through a glass of different thickness than the other parts. (The illustration on the right ignores the effect of diffraction whose effect increases over large distances).

Two oscillators that have the same frequency and different phases have a phase difference, and the oscillators are said to be out of phase with each other. The amount by which such oscillators are out of step with each other can be expressed in degrees from 0° to 360°, or in radians from 0 to 2π. If the phase difference is 180 degrees (π radians), then the two oscillators are said to be in antiphase. If two interacting waves meet at a point where they are in antiphase, then destructive interference will occur. It is common for waves of electromagnetic (light, RF), acoustic (sound) or other energy to become superposed in their transmission medium. When that happens, the phase difference determines whether they reinforce or weaken each other. Complete cancellation is possible for waves with equal amplitudes.

Time is sometimes used (instead of angle) to express position within the cycle of an oscillation.

  • A phase difference is analogous to two athletes running around a race track at the same speed and direction but starting at different positions on the track. They pass a point at different instants in time. But the time difference (phase difference) between them is a constant - same for every pass since they are at the same speed and in the same direction. If they were at different speeds (different frequencies), the phase difference is undefined and would only reflect different starting positions. Technically, phase difference between two entities at various frequencies is undefined and does not exist.
  • We measure the rotation of the earth in hours, instead of radians. And therefore time zones are an example of phase differences.

In-phase and quadrature (I&Q) components

The term in-phase is also found in the context of communication signals:

A(t)\cdot \sin[2\pi ft + \phi(t)] = I(t)\cdot \sin(2\pi ft) + Q(t)\cdot \underbrace{\cos(2\pi ft)}_{\sin\left(2\pi ft + \frac{\pi}{2} \right)}

and:

A(t)\cdot \cos[2\pi ft + \phi(t)] = I(t)\cdot \cos(2\pi ft) \underbrace{{}- Q(t)\cdot \sin(2\pi ft)}_{{} + Q(t)\cdot \cos\left(2\pi ft + \frac{\pi}{2}\right)},

where \ f\, represents a carrier frequency, and

I(t)\ \stackrel{\text{def}}{=}\ A(t)\cdot \cos\left(\phi(t)\right), \,
Q(t)\ \stackrel{\text{def}}{=}\ A(t)\cdot \sin\left(\phi(t)\right).\,

A(t)\, and \phi(t)\, represent possible modulation of a pure carrier wave, e.g.:  \sin(2\pi ft).\,  The modulation alters the original \sin\, component of the carrier, and creates a (new) \cos\, component, as shown above. The component that is in phase with the original carrier is referred to as the in-phase component. The other component, which is always 90° (\begin{matrix} \frac{\pi}{2} \end{matrix} radians) "out of phase", is referred to as the quadrature component.

Phase coherence

Coherence is the quality of a wave to display well defined phase relationship in different regions of its domain of definition.

In physics, quantum mechanics ascribes waves to physical objects. The wave function is complex and since its square modulus is associated with the probability of observing the object, the complex character of the wave function is associated to the phase. Since the complex algebra is responsible for the striking interference effect of quantum mechanics, phase of particles is therefore ultimately related to their quantum behavior.

See also

External links


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Sci-Tech Encyclopedia. McGraw-Hill Encyclopedia of Science and Technology. Copyright © 2005 by The McGraw-Hill Companies, Inc. All rights reserved.  Read more
Britannica Concise Encyclopedia. Britannica Concise Encyclopedia. © 2006 Encyclopædia Britannica, Inc. All rights reserved.  Read more
Electronics Dictionary. Copyright 2001 by Twysted Pair. All rights reserved.  Read more
Wikipedia. This article is licensed under the Creative Commons Attribution/Share-Alike License. It uses material from the Wikipedia article "Phase (waves)" Read more