A resonant circuit in which either the inductance or capacitance is made to vary periodically at one-half the driving frequency; used as a digital computer element, in which the oscillation represents a binary digit. Also known as parametric phase-locked oscillator; phase-locked oscillator; phase-locked subharmonic oscillator.



an element in automation and computer technology based on the parametric excitation and amplification of electromagnetic oscillations. The simplest parametron is an oscillatory circuit tuned to a frequency f0. When one of the energy-storing parameters is varied periodically by a pump signal at a frequency fp approximately equal to 2/o, an oscillation is generated at a frequency fg = fp/2 ≈ f0; the generated oscillation is coherent with respect to the exciting oscillation. The phase of the oscillations excited in a parametron can assume one of two values; these values differ by 180° and are conventionally designated as 0 and π. The phase can remain in this state as long as desired. The parametron’s capability to select one of two stable phases is known as the phase-quantization feature. The parametron was invented by the Japanese scientist E. Goto, who patented it as a logic element or cell in a memory unit in 1954. Parametrons have been used in constructing counters, registers, adders, memory units, and computer control systems.

Parametrons are classified according to the type of nonlinear element as inductive (using ferrite cores and magnetic films), capacitive (using parametric semiconductor diodes and ferroelectric capacitors), or resistive (using tunnel and other semiconductor diodes with a volt-ampere characteristic that has a decreasing portion). The switching rate—clock frequency fc—of a parametron is proportional to the pump frequency, which is 20 to 50 times greater than fc. The most reliable and inexpensive parametrons are the single-circuit inductive types that use ferrite cores, have a power requirement of 15 to 50 milliwatts, and have fc ≤ 100 kilohertz. Capacitive parametrons using capacitors are more economical (3 to 6 milliwatts) and have a faster speed (fc ≈ 5 megahertz). Resistive parametrons are even faster because the time needed to establish oscillations is comparable to the period of the natural oscillations in the circuit. Inductive parametrons using thin magnetic films and capacitive parametrons using semiconductor diodes have a clock frequency of up to 150 megahertz. The development of parametric light amplifiers and generators has made it possible, in principle, to work with frequencies in the optical band. Such a development should bring a substantial improvement in parametron speed.


Parametrony, books 1–2. Moscow, 1961–62. (Collection of articles translated from Japanese)
Parametrony v tsifrovykh ustroistvakh. Moscow, 1968.
Vishnevetskii, A. I., and G. M. Nemetskii. Parametrony i ikh primenenie v ustroistvakh sviazi. Moscow, 1968.


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In addition to endeavoring to realize a quantum annealing machine through superconducting parametron device development, three-dimensional integration technology, and signal reading/control as well as theoretical studies and simulations supporting them, the four participating organizations will work in close coordination with those charged with the task of developing software infrastructure for application and software layers in this project commissioned by NEDO (i.e., Research and Development of Common Software Platform for Ising Machines; representative entity: Waseda University) to achieve mutual optimization and bring to fruition the strong unification of both sides.
A thoughtful (and simultaneously comical) discussion of these issues appears in Clarence Barlow's "Bus Journey to Parametron (All About Coglutobusisletmesi)," Die Feedback Papers 21--23 (December 1980): 33--41.