RU2446432C1 - Optoelectronic defuzzificator - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: optoelectronic defuzzificator, having a coherent radiation source, an optical n-output splitter, a transparency filter, also includes n optical Y splitters, a second transparency filter, two optical integrators with a definite integral function, a photodiode, a photoresistor, a resistor an inverting operational amplifier.

EFFECT: increase in computational power to 10⁵-10⁶ operations per second, with possibility of performing defuzzification - an operation for calculating the crisp value of the output linguistic variable after the procedure for aggregating all terms of that linguistic variable as a result of a fuzzy logic conclusion.

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Description

The present invention relates to computer technology and can be used in optical information processing devices built on the basis of continuous (fuzzy) logic.

Known optical computing device for multiplying optical signals, containing an optical RS-flip-flop, an optical Y-coupler, three optical bistable elements, optical waveguides with ring branches, optical amplifiers, an optical comparator, a frequency filter, an optical transparency [Pat. RU 2022328 C1 1994, Optical Multiplier / S.V. Sokolov].

The essential features of the analogue common with the claimed device are as follows: optical Y-splitter, optical transparency.

The disadvantages of the above device are the complexity and inability to calculate a clear value of the output linguistic variable (or numbers on a predetermined scale of the output linguistic variable) after the procedure for aggregating all terms of this linguistic variable as a result of fuzzy inference.

Known optical computing device for subtracting optical signals, containing optical amplifiers, an input optical splitter, two groups of optical banners, optical branches, an annular branch, an optical comparator, an optical branch, a pair of coupled optical waveguides and an optical bistable element [Pat. RU 2103721 C1 1998, Device for subtracting optical signals / S.V. Sokolov, A.A. Barannik].

The essential features of an analogue common with the claimed device are as follows: optical transparency, optical splitter.

The disadvantages of the above device are the complexity and inability to calculate a clear value of the output linguistic variable (or numbers on a predetermined scale of the output linguistic variable) after the procedure for aggregating all terms of this linguistic variable as a result of fuzzy inference.

A known optical computing device is a nonlinear power converter adopted as a prototype [Pat. RU 2020550 C1 1994, Optical Functional Converter / SVSokolov], which contains a coherent radiation source, a differentiator, an optical n-output splitter, an optical transparency, an optical n-input combiner, a pair of optically coupled waveguides, an optical modulator.

The essential features of the prototype, common with the claimed device, are as follows: a radiation source, an optical n-output splitter, an optical transparency, an output of a radiation source is connected to an input of an optical n-output splitter, each output of an optical n-output splitter is connected to a corresponding input of an optical transparency.

The disadvantages of the above device are the complexity and inability to calculate a clear value of the output linguistic variable (or numbers on a predetermined scale of the output linguistic variable) after the procedure for aggregating all terms of this linguistic variable as a result of fuzzy inference.

The objective of the invention is the creation of an optoelectronic defuzzifier, which allows to increase computational performance up to 10 ⁵ -10 ⁶ operations per second while simultaneously performing the defuzzification operation - the operation of calculating a clear value of the output linguistic variable (or number on a predetermined scale of the output linguistic variable) after the aggregation of all terms this linguistic variable as a result of fuzzy inference.

The technical result is expressed in expanding the capabilities of the device - creating a device that performs the defuzzification operation - the operation of calculating a clear value of the output linguistic variable (or number on a predetermined scale of the output linguistic variable) after the procedure for aggregating all terms of this linguistic variable as a result of fuzzy inference.

The essence of the invention lies in the fact that in an optoelectronic defuzzifier containing a coherent radiation source, an optical n-output splitter, an optical transparency, the output of the radiation source is connected to an input of an optical n-output splitter, each output of an optical n-output splitter is connected to a corresponding input of an optical transparency , introduced n optical Y-splitters, a second optical transparency, two optical integrators with a specific integration function, photodiode, photoresistor, res a torus inverting the operational amplifier, the output of the coherent radiation source is connected to the input of the optical n-output splitter, each output of which is connected to the corresponding input of the first optical banner, the outputs of the first optical banner are connected to the corresponding inputs of n optical Y-couplers, the first outputs of which are connected to the corresponding the inputs of the second optical banner, and the second outputs are connected to the corresponding inputs of the second optical integrator, the outputs of the second optical transparencies are connected to the corresponding inputs of the first optical integrator, the output of which is connected to the input of the photodiode, the anode of which is connected through the resistor to the inverting input of the inverting operational amplifier, and the cathode is connected to the common bus, the output of the second optical integrator is connected to the input of the photoresistor included in the negative feedback circuit connection of the inverting operational amplifier - between the output and the inverting input of the inverting operational amplifier, the output of which is the output of the device state.

Optoelectronic defuzzifier (ODF) - a device designed to calculate a clear value of the output linguistic variable (or number on a predetermined scale of the output linguistic variable) after the aggregation of all terms of this linguistic variable as a result of fuzzy inference by the center of gravity method described by the formula:

where _OUT is the desired clear value of the output linguistic variable (the center of the area limited by the membership function);

µ _Σ (y) is the resulting membership function of the output linguistic variable y;

Mach - upper boundary - extreme right point of the interval of the carrier of the fuzzy set of the output linguistic variable y;

Min - lower bound - extreme left point of the interval of the carrier of the fuzzy set of the output linguistic variable y.

The functional diagram of the ODF is shown in figure 1.

Optical defuzzifier contains:

- 1 - a source of coherent optical radiation (IKI) with an amplitude of 2n conditional units (units);

- 2 - optical n-output splitter;

- 3 - the first optical transparency (OT) T1 with a transmission function proportional to the membership function µ _Σ (y);

- 4 ₁ , 4 ₂ , ..., 4 _n - a group of optical Y-splitters;

- 5 - the second optical transparency (OT) T2 with a transmission function proportional to the function y;

- 6, 7 - the first and second optical integrators (OI), performing the function of a certain integration, which can be implemented as an optical n-input combiner or focusing lens;

- VD 8 - photodiode operating in the photo-generating mode;

- VR 9 - photoresistor;

- R 10 - resistor;

- DA11 - operational amplifier connected in conjunction with a resistor

R10 in the input circuit and a VR 9 photoresistor in the negative feedback circuit according to the inverting amplifier circuit.

The output of IRI 1 is connected to the input of the optical n-output splitter 2, the outputs 2 ₁ , 2 ₂ , ..., 2 _{n of the} optical n-output splitter 2 are connected to the inputs of the first OT 3. The outputs of the first OT 3 are connected to the corresponding inputs of the optical Y-splitters 4 ₁ , 4 ₂ , ..., 4 _n , the first outputs of which are connected to the inputs of the second OT 5, and the second outputs are connected to the inputs of the second OI 7. The outputs of the second OT 5 are connected to the inputs of the first OI 6, and the output of the first OI 6 is connected to the input of the photodiode VD 8. The anode of the photodiode VD 8 is connected through the resistor R10 to the inverting input I invert the operational amplifier DA 11, and the cathode to the common bus. The output of the second OI 7 is connected to the input of the photoresistor VR 9 included in the negative feedback circuit of the inverting operational amplifier DA11, the output of the inverting operational amplifier DA11 is the output of the device.

. Далее выходной оптический поток второго ОИ 7 поступает на фоторезистор VR9.The operation of the device is as follows. From the output of IKI 1 optical coherent flow with an amplitude of 2n conv. units arrives at the input of the optical n-output splitter 2, at the outputs 2 ₁ , 2 ₂ , ..., 2 _{n of} which a flat optical stream with an amplitude of 2 conv. units along the axis of the OS. This stream enters the inputs of the first OT 3, the outputs of which form an optical stream with an amplitude of 2µ _Σ (y), which arrives at the corresponding inputs of the optical Y-couplers 4 ₁ , 4 ₂ , ..., 4 _n . At the second outputs of the optical Y-couplers 4 ₁ , 4 ₂ , ..., 4 _n , a flat optical stream with an amplitude µ _Σ (y) is formed, which is fed to the inputs of the second OI 7, at the output of which an optical stream with an amplitude proportional to (or with intensity proportional to

. Next, the output optical stream of the second OI 7 is fed to a VR9 photoresistor.

(с интенсивностью, пропорциональной

, поступает на фотодиод VD 8.At the first outputs of the optical Y-couplers 4 ₁ , 4 ₂ , ..., 4 _n , a flat optical stream with an amplitude μ _Σ (у) is also formed, which then flows to the inputs of the second OT 5, at the outputs of which a flat optical stream with an amplitude proportional to μ _Σ (y) This flat optical stream arrives at the inputs of the first OI 6, the output of which is an optical stream with an amplitude proportional to

(with intensity proportional to

arrives at the photodiode VD 8.

[Бодиловский В.Г. Полупроводниковые и электровакуумные приборы в устройсвах автоматики, телемеханики и связи: Учебник для техникумов ж.-д. трансп. - 5-е изд., перераб. и доп. / В.Г.Бодиловский. - М.: Транспорт, 1986. - 440 с.], то на выходе фотодиода VD 8 формируется фотоЭДС Е_VD1, пропорциональная значению

. Так как зависимость сопротивления фоторезистора от интенсивности падающего на него светового потока с требуемой точностью аппроксимируется функцией вида

[Либерман Ф.Я. Электроника на железнодорожном транспорте: Учеб. пособие для вузов ж.-д. трансп. / Ф.Я.Либерман. - М.: Транспорт, 1987. - 288 с.], то сопротивление фоторезистора VR 9 будет обратно пропорционально значению

.Since the dependence of the photoEMF at the output of the photodiode on the intensity of the optical flux arriving at its input is approximated with the required accuracy by a function of the form

[Bodilovsky V.G. Semiconductor and electrovacuum devices in automation, telemechanics and communication devices: Textbook for technical schools. transp. - 5th ed., Revised. and add. / V.G.Bodilovsky. - M .: Transport, 1986. - 440 p.], Then at the output of the photodiode VD 8 the photo-emf E _{VD1 is formed} , proportional to the value

. Since the dependence of the photoresistor resistance on the intensity of the light flux incident on it is approximated with the required accuracy by a function of the form

[Liberman F.Ya. Electronics in railway transport: Textbook. manual for high schools. transp. / F.Ya. Liberman. - M .: Transport, 1987. - 288 p.], Then the resistance of the photoresistor VR 9 will be inversely proportional to the value

.

The voltage at the output of the inverting operational amplifier U _OUT is defined as:

where U _BX is the voltage at the inverting input of the inverting operational amplifier DA11,

K is the gain of the inverting amplifier, which is defined as:

where R _VR9 is the resistance of the VR9 photoresistor;

R _R10 - resistance of the resistor R10.

Considering equations (2) and (3) the voltage at the output of the inverting operational amplifier DA11 U _OUT is defined as:

, a R_VR9 обратно пропорционально

, то с учетом выражения (4) напряжение на выходе инвертирующего операционного усилителя DA11 будет равно:Since U _BX is equal to E _VD1 , which is proportional

, a R _{VR9 is} inversely proportional

, then, taking into account expression (4), the voltage at the output of the inverting operational amplifier DA11 will be equal to:

those. in proportion to the desired absolute values of Y _OUT: Y _OUT ~ | U _OUT |.

The speed of the ODF is determined by the dynamic characteristics of the photodiode, photoresistor, and operational amplifier. Because photodiodes have a cutoff frequency of ~ 10 ⁹ Hz, photoresistors have a delay time of ~ 10 ^-3 ... 10 ^-8 s, operational amplifiers based on FPGAs (PAIS) have a speed of ~ 2.5-3 μs [Scherba A. Programmable analog ICs Anadigm: the use of configurable analog modules as part of AnadigmDesigner2 / A. Scherba // Components and Technologies. - 2007. - No. 12], then for the existing continuous-processing information processing systems, such a speed ensures their operation in almost real time.

Claims (1)

An optoelectronic defuzzifier containing a coherent radiation source, an optical n-output splitter, an optical transparency, an output of a radiation source is connected to an input of an optical n-output splitter, each output of an optical n-output splitter is connected to a corresponding input of an optical transparency, characterized in that n optical Y-couplers, a second optical transparency, two optical integrators with a specific integration function, a photodiode, a photoresistor, a resistor, inverters operating amplifier, the output of the coherent radiation source is connected to the input of the optical n-output splitter, each output of which is connected to the corresponding input of the first optical banner, the outputs of the first optical banner are connected to the corresponding inputs of n optical Y-couplers, the first outputs of which are connected to the corresponding inputs of the second optical transparency, and the second outputs are connected to the corresponding inputs of the second optical integrator, the outputs of the second optical transparency the welts are connected to the corresponding inputs of the first optical integrator, the output of which is connected to the input of the photodiode, the anode of which is connected through the resistor to the inverting input of the inverting operational amplifier, and the cathode is connected to the common bus, the output of the second optical integrator is connected to the input of the photoresistor included in the negative feedback circuit inverting operational amplifier - between the output and the inverting input of the inverting operational amplifier, the output of which is the output of the device.