Oscillation


 * ''For other uses, see oscillator (disambiguation)

Oscillation is the repetitive variation, typically in time, of some measure about a central value (often a point of equilibrium) or between two or more different states. Familiar examples include a swinging pendulum and AC power. The term vibration is sometimes used more narrowly to mean a mechanical oscillation but sometimes is used to be synonymous with "oscillation." Oscillations occur not only in physical systems but also in biological systems and in human society.

Simplicity
The simplest mechanical oscillating system is a mass attached to a linear spring, subject to no other forces; except for the point of equilibrium, this system is equivalent to the same one subject to a constant force such as gravity. Such a system may be approximated on an air table or ice surface. The system is in an equilibrium state when the spring is unstretched. If the system is displaced from the equilibrium, there is a net restoring force on the mass, tending to bring it back to equilibrium. However, in moving the mass back to the equilibrium position, it has acquired momentum which keeps it moving beyond that position, establishing a new restoring force in the opposite sense. The time taken for an oscillation to occur is often referred to as the oscillatory period.

The specific dynamics of this spring-mass system are described mathematically by the simple harmonic oscillator and the regular periodic motion is known as simple harmonic motion. In the spring-mass system, oscillations occur because, at the static equilibrium displacement, the mass has kinetic energy which is converted into potential energy stored in the spring at the extremes of its path. The spring-mass system illustrates some common features of oscillation, namely the existence of an equilibrium and the presence of a restoring force which grows stronger the further the system deviates from equilibrium.

The harmonic oscillator offers a model of many more complicated types of oscillation and can be extended by the use of Fourier analysis.

Damped, driven and self-induced oscillations
In real-world systems, the second law of thermodynamics dictates that there is some continual and inevitable conversion of energy into the thermal energy of the environment. Thus, damped oscillations tend to decay with time unless there is some net source of energy in the system. The simplest description of this decay process can be illustrated by the harmonic oscillator. In addition, an oscillating system may be subject to some external force (often sinusoidal), as when an AC circuit is connected to an outside power source. In this case the oscillation is said to be driven.

Some systems can be excited by energy transfer from the environment. This transfer typically occurs where systems are embedded in some fluid flow. For example, the phenomenon of flutter in aerodynamics occurs when an arbitrarily small displacement of an aircraft wing (from its equilibrium) results in an increase in the angle of attack of the wing on the air flow and a consequential increase in lift coefficient, leading to a still greater displacement. At sufficiently large displacements, the stiffness of the wing dominates to provide the restoring force that enables an oscillation.

Coupled oscillations
The harmonic oscillators and the systems it models have a single degree of freedom. More complicated systems have more degrees of freedom, for example two masses and three springs (each mass being attached to fixed points and to each other). In such cases, the behavior of each variable influences that of the others. This leads to a coupling of the oscillations of the individual degrees of freedom. For example, two pendulum clocks mounted on a common wall will tend to synchronise. The apparent motions of the individual oscillations typically appears very complicated but a more economic, computationally simpler and conceptually deeper description is given by resolving the motion into normal modes.

Continuous systems - waves
As the number of degrees of freedom becomes arbitrarily large, a system approaches continuity; examples include a string or the surface of a body of water. Such systems have (in the classical limit) an infinite number of normal modes and their oscillations occur in the form of waves that can characteristically propagate.

Examples
See also: list of wave topics

Mechanical

 * Double pendulum
 * Foucault pendulum
 * Helmholtz resonator
 * Playground swing
 * String instruments
 * Tuning fork
 * Vibrating string
 * Oscillations in the Sun (helioseismology) and stars (asteroseismology)

Electrical

 * Alternating current
 * Armstrong oscillator
 * Astable multivibrator
 * Blocking oscillator
 * Clapp oscillator
 * Colpitts oscillator
 * Electronic oscillator
 * Hartley oscillator
 * Oscillistor
 * Pierce oscillator
 * Relaxation oscillator
 * RLC circuit
 * Royer oscillator
 * Vačkář oscillator
 * Wien bridge oscillator
 * Oscillators and Multivibrators
 * Virtual Cathode Oscillator

Electro-mechanical

 * Crystal oscillator
 * Loudspeaker
 * Microphone

Optical

 * Laser (oscillation of electromagnetic field with frequency of order $$10^{15}$$Hz)
 * Oscillator Toda or self-pulsation (pulsation of output power of laser at frequencies $$10^{4}$$Hz -- $$10^{6}$$Hz in the transient regime)
 * Quantum oscillator may refer to an optical local oscillator, as well as to a usual model in quantum optics.

Biological

 * Circadian rhythm
 * Prey-predator systems
 * Neural oscillations

Human

 * Brain waves
 * Pilot-induced oscillation
 * Voice production
 * Insulin release oscillations

Economic and social

 * Business cycle
 * Generation gap
 * Malthusian economics
 * News cycle

Climate and geophysics

 * Chandler wobble
 * El Niño-Southern Oscillation
 * Quasi-biennial oscillation
 * Tides in the Earth's oceans

Chemical

 * Belousov-Zhabotinsky reaction
 * Mercury beating heart