oscillator

(′äs·ə′lād·ər)

(electronics) An electronic circuit that converts energy from a direct-current source to a periodically varying electric output. The stage of a superheterodyne receiver that generates a radio-frequency signal of the correct frequency to mix with the incoming signal and produce the intermediate-frequency value of the receiver. The stage of a transmitter that generates the carrier frequency of the station or some fraction of the carrier frequency.
(physics) Any device (mechanical or electrical) which, in the absence of external forces, can have a periodic back- and-forth motion, the frequency determined by the properties of the oscillator.

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For more information on oscillator, visit Britannica.com.

An electronic circuit that generates a periodic output, often a sinusoid or a square wave. Oscillators have a wide range of applications in electronic circuits: they are used, for example, to produce the so-called clock signals that synchronize the internal operations of all computers; they produce and decode radio signals; they produce the scanning signals for television tubes; they keep time in electronic wristwatches; and they can be used to convert signals from transducers into a readily transmitted form.

Oscillators may be constructed in many ways, but they always contain certain types of elements. They need a power supply, a frequency-determining element or circuit, a positive-feedback circuit or device (to prevent a zero output), and a nonlinearity (to define the output-signal amplitude). Different choices for these elements give different oscillator circuits with different properties and applications.

Oscillators are broadly divided into relaxation and quasilinear classes. Relaxation oscillators use strong nonlinearities, such as switching elements, and their internal signals tend to have sharp edges and sudden changes in slope; often these signals are square waves, trapezoids, or triangle waves. The quasilinear oscillators, on the other hand, tend to contain smooth sinusoidal signals because they regulate amplitude with weak nonlinearities. The type of signal appearing internally does not always determine the application, since it is possible to convert between sine and square waves. Relaxation oscillators are often simpler to design and more flexible, while the nearly linear types dominate when precise control of frequency is important.

Relaxation oscillators

Illustration a shows a simple operational-amplifier based relaxation oscillator. This circuit can be understood in a number of ways (for example, as a negative-resistance circuit), but its operation can be followed by studying the signals at its nodes (illus. b). The two resistors, labeled r, provide a positive-feedback path that forces the amplifier output to saturate at the largest possible (either positive or negative) output voltage. If v₊, for example, is initially slightly greater than v₋, then the amplifier action increases v_o, which in turn further increases v₊ through the two resistors labelled r. This loop continues to operate, increasing v_o until the operational amplifier saturates at some value V_max. [An operational amplifier ideally follows Eq. (1),
1.
where A_v is very large, but is restricted to output levels |v_o| ≤ V_max.] For the purposes of analyzing the circuit, the waveforms in the illustration have been drawn with the assumption that this mechanism has already operated at time 0 and that the initial charge on the capacitor is zero. See also Amplifier; Operational amplifier.

Simple operational-amplifier relaxation oscillator. (a) Circuit diagram. (b) Waveforms.

Capacitor C will now slowly change from v_o through resistor R, toward V_max, according to Eq. (2).
2.
Up until time t₁, this process continues without any change in the amplifier's output because v₊ > v₋, and so v_o = V_max. At t₁, however, v₊ = v₋ and v_o will start to decrease. This causes v₊ to drop, and the positive-feedback action now drives the amplifier output negative until v_o = −V_max. Capacitor C now discharges exponentially toward the new output voltage until once again, at time t₂, v₊ = v₋, and the process starts again. The period of oscillation for this circuit is 2RC ln 3.

The basic elements of an oscillator that were mentioned above are all clearly visible in this circuit. Two direct-current power supplies are implicit in the diagram (the operational amplifier will not work without them), the RC circuit sets frequency, there is a resistive positive-feedback path that makes the mathematical possibility v_o(t) = 0 unstable, and the saturation behavior of the amplifier sets the amplitude of oscillation at the output to ±V_max.

Relaxation oscillators that have a low duty cycle—that is, produce output pulses whose durations are a small fraction of the overall period—are sometimes called blocking oscillators because their operation is characterized by an “on” transient that “blocks” itself, followed by a recovery period.

Inverters (digital circuits that invert a logic signal, so that a 0 at the input produces a 1 at the output, and vice versa) are essentially voltage amplifiers and can be used to make relaxation oscillators in a number of ways. A circuit related to that of the illustration uses a loop of two inverters and a capacitor C to provide positive feedback, with a resistor R in parallel with one of the inverters to provide an RC charging time to set frequency. This circuit is commonly given as a simple example, but there are a number of problems with using it, such as that the input voltage to the first gate sometimes exceeds the specified limits for practical gates. A more practical digital relaxation oscillator, called a ring oscillator, consists simply of a ring containing an odd number N (greater than 1) of inverters. See also Logic circuits.

Sine-wave oscillators

Oscillators in the second major class have their oscillation frequency set by a linear circuit, and their amplitudes set by a weak nonlinearity.

A simple example of a suitable linear circuit is a two-component loop consisting of an ideal inductor [whose voltage is given by Eq. (3),
3.
where i is its current] and a capacitor [whose current is given by Eq. (4)],
4.
connected in parallel. These are said to be linear elements because, in a sense, output is directly proportional to input, for example, doubling the voltage v across a capacitor also doubles dv/dt and therefore doubles i. The overall differential equation for a capacitor-inductor loop can be written as Eq. (5).
5.
Mathematically this has solutions of the form of Eq. (6),
6.
where ω = 1/LC [which means that the circuit oscillates at a frequency 1/(2πLC)] and A and φ are undefined. They are undefined precisely because the elements in the circuit are linear and do not vary with time: any solution (possible behavior) to the equation can be scaled arbitrarily or time-shifted arbitrarily to give another. Practically, A and φ are determined by weak nonlinearities in a circuit. See also Differential equation; Linearity.

Equation (5) is a good first approximation to the equation describing a pendulum, and so has a long history as an accurate timekeeper. Its value as an oscillator comes from Galileo's original observation that the frequency of oscillation (ω/2π) is independent of the amplitude A. This contrasts sharply with the case of the relaxation oscillator, where any drift in the amplitude (resulting from a threshold shift in a comparator, for instance) can translate directly into a change of frequency. Equation (5) also fundamentally describes the operation of the quartz crystal that has replaced the pendulum as a timekeeper; the physical resonance of the crystal occurs at a time constant defined by its spring constant and its mass. See also Harmonic motion; Harmonic oscillator; Pendulum.

Frequency locking

If an external signal is injected into an oscillator, the natural frequency of oscillation may be affected. If the external signal is periodic, oscillation may lock to the external frequency, a multiple of it, or a submultiple of it, or exhibit an irregular behavior known as chaos. See also Chaos.

This locking behavior occurs in all oscillators, sometimes corrupting intended behavior (as when an oscillator locks unintentionally to a harmonic of the power-line frequency) and sometimes by design. An important example of an oscillator that exploits this locking principle is the human heart. Small portions of heart muscle act as relaxation oscillators. They contract, incidentally producing an output voltage that is coupled to their neighbors. For a short time the muscle then recovers from the contraction. As it recovers, it begins to become sensitive to externally applied voltages that can trigger it to contract again (although it will eventually contract anyway). Each small section of heart muscle is thus an independent oscillator, electrically coupled to its neighbors, but the whole heart is synchronized by the frequency-locking mechanism.

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An electronic circuit used to generate high-frequency pulses. See crystal oscillator, VCO and clock.

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A technical analysis tool that is banded between two extreme values and built with the results from a trend indicator for discovering short-term overbought or oversold conditions. As the value of the oscillator approaches the upper extreme value the asset is deemed to be overbought, and as it approaches the lower extreme it is deemed to be oversold.

Investopedia Says:
Oscillators are most advantageous when a clear trend cannot be easily seen in a company's stock such as when it trades horizontally or sideways. The most common oscillators are: the Stochastic oscillator, RSI, ROC and MFI.

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Learn how to build a price rate of change indicator and incorporate it in your strategy. Measure Momentum Change With ROC
Don't be confused about whether a long-term trend will continue, stall or reverse. Finding The Trend With Aroon
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An electronic circuit that produces a continuous output waveform with only DC applied.

Dansk (Danish)
n. - oscillator, svingningsgenerator

Nederlands (Dutch)
oscillator, trillingsaggregaat

Français (French)
n. - oscillateur

Deutsch (German)
n. - Oszillator

Ελληνική (Greek)
n. - ταλαντωτής

Italiano (Italian)
oscillatore

Português (Portuguese)
n. - oscilador (m)

Русский (Russian)
осциллятор

Español (Spanish)
n. - oscilador

Svenska (Swedish)
n. - oscillator

中文（简体）(Chinese (Simplified))
摆动物, 振荡器, 动摇者, 振动器

中文（繁體）(Chinese (Traditional))
n. - 擺動物, 振蕩器, 動搖者, 振動器

한국어 (Korean)
n. - 발진기, 진동자

日本語 (Japanese)
n. - 揺れ動くもの, 発振器, 振動子, 動揺する人

العربيه (Arabic)
‏(الاسم) المتذبذب, جهاز التذبذب السريع‏

עברית (Hebrew)
n. - ‮מכשיר ליצירת זרמי חשמל משתנים, מתנד‬

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multi wave oscillator