RU2293341C2 - Multi-channel fiber-optic device for transferring and registration of one-time impulse electric signals - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: in accordance to invention, mounted onto each optical channel of registration device is an optical multiplexer, and registration device itself (oscillograph) is provided with additional demultiplexing function.

EFFECT: increased number of registration channels for one-time impulse electric signals without increasing number of channels for registration of optical signals registration device.

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Description

The invention relates to information-measuring equipment and is intended for transmission and digital recording of single pulsed electrical analog signals. It can be used in scientific research in nuclear physics.

A device [1] is known, which allows the transmission of electrical signals through an optical fiber. It includes an optical transmitter that converts the input electrical signal into an optical analogue, an optical fiber as the transmission line through which this analogue is transmitted, and a photodetector that performs the inverse conversion of the optical signal to the original electrical signal, which can be detected using an analog-to-digital recorder. However, this device is single channel.

Known multi-channel device for transmitting information [2], consisting of four optical transmitters included in the transmitting unit, four optical fibers and four photodetectors included in the receiving unit. The analog outputs of the photodetectors are each connected to its own analog-to-digital recorder. Also, this device includes control blocks and circuits that enable / disable optical transmitters and calibrate information transmission channels: optical transmitter - optical fiber - photodetector. This device allows you to simultaneously transmit four electrical signals that can be registered using four analog-to-digital recorders connected to the outputs of photodetectors.

The disadvantage of this device is the need to use four high-speed analog-to-digital recorders.

The closest technical solution to the proposed one is a multi-channel device [3], which implements a high-speed optoelectronic method for recording analog data consisting of N electrical pulse signals. This device consists of N optical transmitters that convert the input electrical signals to optical. The optical output of each of the transmitters is connected to the optical fiber. Optical fibers are arranged in a row and connected through an entrance slit to a high-speed multi-channel optical signal recorder, consisting of a picosecond electron-optical camera and a computer. In this device, signals from optical transmitters are transmitted via optical fibers to a high-speed multi-channel optical signal recorder. In the recorder, they are temporarily scanned on the screen of an electron-optical camera in the form of parallel lines, the number of which corresponds to the number of input optical fibers N, and the brightness of the points along these lines is proportional to the magnitude of the optical signals. The recorded image on the screen of the electron-optical camera is digitized and transmitted to a computer, where, according to a special program, the recorded electrical signals are restored. This multi-channel device allows the transmission and recording of electrical impulse signals using a single multi-channel high-speed recorder.

The disadvantage of the prototype is the limited number of recording channels of a multi-channel recorder, due to the spatial resolution of the electron-optical camera.

The technical result provided by the claimed invention is to increase the number of transmission channels and registration of single pulsed electrical signals without increasing the number of registration channels of a multi-channel optical signal recorder.

The technical result is achieved by the fact that a multi-channel fiber-optic device for transmitting and recording single pulsed electrical signals, containing N optical transmitters by the number of transmitted electrical signals, N optical fibers, the input of each of which is connected to the output of the corresponding optical transmitter, a multi-channel optical signal recorder with To the inputs, additionally contains K identical fiber optic splitters, each of which has M inputs and one output, where M = N / K, the outputs of the optical transmitters through the corresponding optical fibers are connected to the corresponding inputs of the corresponding optical splitters, the outputs of which are connected to the corresponding inputs of the multi-channel recorder, the optical fibers connected to the inputs of the same splitter are made of different lengths determined from conditions:

L _n = L ₀ + (nM · (k-1) -1) · ν _g t _reg , n = M · (k-1) +1, ..., M · k; k = 1, ... K,

where L _n is the length of the optical fiber; L ₀ is the distance from the optical transmitters to the splitters along the optical fiber; ν _g is the propagation speed of the optical signal in the optical fiber; t _reg is the time of registration of the electric signal,

multi-channel optical signal recorder, configured to implement on each channel its functions:

where U _n (t) is the electrical signal supplied to the input of the nth optical transmitter, S _n is the conversion coefficient of the device on the nth channel; P _k (t) is the optical signal recorded at the kth input of the optical signal recorder.

The essence of the invention consists in optical time multiplexing of signals from different optical transmitters due to different transit times of optical signals through optical fibers of different lengths, followed by software and hardware demultiplexing carried out in the recorder according to a special program, due to which it is possible to increase the number of registration channels without increasing the number of inputs of a multi-channel optical signal recorder.

Functional diagram of the proposed device is shown in the drawing.

A fiber-optic multi-channel device for transmitting and recording pulsed electrical signals contains 1 ₁ , ..., 1 _N optical transmitters, the number of which is equal to the number N of transmitted electrical signals, which are connected through an equal number of optical fibers 2 ₁ , ..., 2 _N to the inputs of the corresponding identical fiber optic splitters 3 ₁ , ..., 3 _K , the outputs of which are connected to the corresponding inputs of the multi-channel optical signal recorder 4.

The number M of inputs of a fiber optic splitter is determined by the condition:

where t _un. - the duration of the time sweep of the multi-channel recorder of optical signals 4; t _reg. - the duration of the recorded input pulsed electrical signals, the same for all N input signals, which must satisfy the condition:

t _reg. ≥t _d

where t _d is the expected maximum duration of the input electrical signals.

The number K of fiber optic splitters 3 ₁ , ..., 3 _K and, respectively, the inputs of the multi-channel optical signal recorder 4 is determined by the condition:

The lengths of the optical fibers 2 _{M · (k-1) +1} , ..., 2 _{M · k} connected to the inputs of the same k-th fiber optic splitter 3 _k are selected from the condition:

where L _n is the length of the optical fiber 2 _n connected to the (n-M (k-1)) - th input of the k-th fiber optic splitter; L ₀ is the distance from the optical transmitters to the splitters along the optical fiber; ν _g is the propagation velocity of the optical signal in the optical fiber.

The multi-channel optical signal recorder 4 is configured to perform calculations for each of its channels K according to the following formula:

where U _n (t) is the electrical signal supplied to the input of one of the optical transmitters 1 _{1 ... N} connected through one of the optical fibers 2 _1..N to the (nM (k-1)) - input of the splitter 3 _k corresponding to this transmitter; S _n - transmission coefficient of the device on the n-th channel; P _k (t) is the optical signal recorded at the k-th input of the optical signal recorder 4, to which this splitter 3 _k is connected.

поступают на входы оптических передатчиков 1₁, ..., 1_N, где преобразуются в аналогичные им сигналы оптической мощности

по формуле:The device operates as follows. Pulse electrical signals

arrive at the inputs of the optical transmitters 1 ₁ , ..., 1 _N , where they are converted to similar optical power signals

according to the formula:

P ' _n (t) = a · U _n (t),

where a is the coefficient of conversion of the electrical signal into an optical signal in the corresponding transmitter. These signals are transmitted through optical fibers 2 ₁ , ..., 2 _N to the inputs of fiber optic splitters 3 ₁ , ..., 3 _K.

Since the optical fibers corresponding to the same fiber optic splitter 3 _k have different lengths defined by formula (1), these signals P '' _n (t) will arrive at the inputs of the fiber optic splitter 3 _k at different times shifted relative to the arrival of the nth input electrical pulse by the time L _n / ν _g :

where α is the extinction coefficient of the optical fiber.

At the output of the fiber optic splitter 3 _k , a signal P _k (t) is generated, which is the sum of the signals at the inputs of the splitter 3 _k :

where b is the loss factor in the splitter 3 _k .

The signal P _k (t) from the output of the splitter 3 _k goes to the k-th input of the optical signal recorder 4, where it is recorded for further processing.

Thus, the recorder of optical signals 4 at the kth input will record the following signal:

where S _n is the conversion coefficient of the device at the nth input, equal to the product:

In the recorder 4, the signal P _k (t) is digitized and, using a special program, the initial pulsed electrical signals U _n (t) are calculated by the formula:

The implementation of demultiplexing according to the formula (4) is possible when the duration of the input pulses U _n (t) will be less than the registration time t _reg . Otherwise, the signal will be distorted due to superposition of pulses on each other.

Indeed, if the input pulsed electrical signals U _n (t) are representable in the form:

where t _dn is the duration of the input electric pulse arriving at the nth transmitter; U _Pn (t) is a function that describes the shape of the pulse, and the time t is counted here from the beginning of the registration of signals common to all optical transmitters, then U _n (t) can be written in the form:

where t _reg. - signal recording time, which must satisfy the condition:

t _reg. ≥max {t _dn } ^N _{n = 1} ;

H (t) is the Heaviside function.

We substitute expression (5) into (3):

тогдаmake a change of variables

then

Based on the properties of the Heaviside function, this expression is rewritten in the form:

P _k (t '+ L _n / ν _g ) = S _n U _n (t'),

whence formula (4) immediately follows.

The above analysis showed that in the proposed device through one input channel of a multi-channel optical signal recorder 4, it is possible to register M input optical signals. Accordingly, with K input channels of the recorder, it is possible to register CM signals.

Thus, the proposed device in comparison with the prototype allows you to register M times more electrical signals when using the same recorder as in the prototype, having K channels of registration.

Information sources

1. J. Gower. "Optical communication systems." M .: "Radio and communications", 1989, p.16.

2. Demyanovich M.V., Evreev A.I., Sorokin V.B. "Multichannel device for transmitting information." - Technical progress in the nuclear industry, No. 10-11, 1990, p. 34.

3. Chang and others. "High-speed optoelectronic method for recording analog data." - Devices for scientific research, No. 10, 1985, p.3.

Claims (1)

A multichannel fiber-optic device for transmitting and recording single pulsed electrical signals, containing N optical transmitters according to the number of transmitted electrical signals, N optical fibers, the input of each of which is connected to the output of the corresponding optical transmitter, a multi-channel optical signal recorder with K inputs, characterized in that it additionally contains K identical fiber optic splitters, each of which has M inputs and one output, where M = N / K, optical outputs transmitters through their corresponding optical fibers are connected to the corresponding inputs of the corresponding optical splitters, the outputs of which are connected to the corresponding inputs of the multi-channel recorder, the optical fibers connected to the inputs of the same fiber-optic splitter are of different lengths, determined from the condition: L _n = L ₀ + (nM · (k-1) -1) · v _g t _reg. , n = M · (k-1) +1, ..., M · k; k = 1, ..., K; where L _n is the length of the optical fiber; L ₀ is the distance from the optical transmitters to the splitters along the optical fiber; v _g is the propagation speed of the optical signal in the optical fiber; t _reg is the time of registration of the electric signal, k is the index of the fiber optic splitter, the multichannel recorder of optical signals is made with the possibility of implementing the functions for each channel: U _n (t) = (1 / S _n ) · P _k (t + L _n / v _g ), t∈ [0, t _reg ], where U _n (t) is the electrical signal supplied to the input of the nth optical transmitter; S _n is the conversion coefficient of the device on the n-th channel; P _k (t) is the optical signal recorded at the k-th input of the optical signal recorder.