RU69359U1 - FIBER OPTICAL LOCAL NETWORK - Google Patents

Abstract

The utility model relates to optical fiber networks, in particular to fiber optic local area networks, which provide the transmission of television signals, control and monitoring signals. The technical result of the claimed utility model is to improve the quality of the conversion of television signals to digital form by automatically adjusting the sampling frequency of the ADC to the frequency of the input signal. To do this, in the first transmitting and receiving unit, the analog-to-digital conversion module contains a converter of logical voltage levels to TIA / EIA-232 standard levels, a low-pass filter, an offset driver designed to set the black level offset in a television signal, an ADC and a comparator, and the module the signal transceiver comprises a digital video signal processing device, a pulse frequency modulation signal decoder, a receiving optical module, a front highlighter, a delay element, a protocol monitoring device , comparison circuit, storage register, encoder, parallel-to-serial code converter, optical module, clock, first and second dividers with a division ratio of 6 and a pre-divider with a division coefficient of 3. In the second transceiver block, the DAC module contains a converter of logical voltage levels in TIA / EIA-232 standard levels, a DAC and a low-pass filter, and the second receive-transmit module contains a transmitting optical module, a pulse-frequency modulator, a receiving optical module, and a converter serial code divider into parallel code, decoder, protocol control device, interpolator, phase detector, voltage controlled oscillator, first and second dividers with division factors by 6, third divider with division coefficient by 3, comparison circuit and frequency multiplier by 2. 1 s.p. f-ly, 2 ill.

Description

The utility model relates to optical fiber networks, in particular to fiber optic local area networks, which provide the transmission of television signals, control and monitoring signals.

Currently, fiber optic networks are widely used.

From patent RU 2239286, published October 27, 2004, a fiber-optic information transmission network is already known, which consists of a receiving unit and a transmitting unit interconnected.

However, this network does not allow the transmission of television signals.

A local network is also known, as described in US Pat. No. 6,112,323, published August 29, 2000. This network is also designed to transmit television signals and contains a central station (block 12) (first transceiver block) connected through a fiber optic line to subscriber terminals (second transceiver blocks). The central station contains transceivers, terminal equipment, a network management system, and communication interface units. The subscriber terminal contains an ADC, DAC, scrambler, descrambler, encoder, decoder, receiving interface, transmitting interface, RS-232 interface, RS-485 interface, processor, modulator, demodulator, frequency signal level control unit, frequency setting unit, modem, distributor .

However, this network has low noise immunity. And besides, this network is very difficult to implement, because It requires a lot of structural elements.

Also known is a fiber optic network described in the application US 2005/0169316, published 04.04.2005. The known network comprises an optical channel terminal (first transceiver block) connected via a fiber optic line to an optical network terminal (second transceiver block). Known network allows you to transmit television signals. The optical channel terminal includes electro-optical converters (ADCs) and an optical multiplexer. The optical network unit contains optoelectronic converters (DACs) and an optical demultiplexer.

However, this system has a drawback - it has a low quality conversion of television signals into digital form, because in this network there is no automatic adjustment of the sampling frequency of the ADC to the frequency of the input signal, i.e. the network does not carry out phase correction to automatically adjust the phase of the ADC synchronization signal to the beginning of the line of the television signal.

Also known is a fiber optic local area network for transmitting television signals, described in the application US 2005/0053376, published March 10, 2005. The known network comprises an optical channel terminal (first transceiver unit), which is connected via an optical fiber line to an optical network unit (second transceiver unit), which is also connected to optical terminals of subscribers via a fiber optic line. A television signal via a fiber-optic line is sequentially supplied through an optical channel terminal to an optical network unit, from which it then goes to the optical terminals of subscribers. The optical channel terminal comprises an Ethernet switch, an optical transceiver consisting of an optical transmitter and an optical receiver, an optical transmitter, a wave separation multiplexer, means

time synchronized multiplexing. The optical network unit comprises a time division multiplexed demultiplexer, time synchronized demultiplexer, a multicast flow switch, N time division multiplexers, an Ethernet switch, N transceivers.

However, this network is very difficult to implement, as It requires a lot of structural elements. And in addition, this network has a low quality conversion of television signals into digital form, because in this network there is no automatic adjustment of the sampling frequency of the ADC to the frequency of the input signal, i.e. the network does not carry out phase correction to automatically adjust the phase of the ADC synchronization signal to the beginning of the line of the television signal.

Thus, the technical result of the claimed utility model is to improve the quality of converting television signals into digital form by automatically adjusting the sampling frequency of the ADC to the frequency of the input signal.

This result is achieved due to the fact that the Fiber-optic local area network for transmitting television signals (TV), control and monitoring signals, comprising a first transceiver unit and a second transceiver unit, which is connected through the fiber optic cable to the first transceiver unit, while the first and second transceiver units are designed for electron-optical conversion and temporary multiplexing and demultiplexing of TV signals and control signals and control I, while the first transceiver block is designed to transmit TV signals and control and control signals via a fiber-optic cable to the second transceiver block, as well as to receive control and control signals via a fiber-optic cable from the second transceiver block and the second transceiver unit is designed to transmit control and monitoring signals via fiber optic

cable to the first transceiver unit, while the first transceiver unit contains an analog-to-digital converter (ADC) module and a first signal transceiver module, an analog television signal arriving through the radio frequency cable is supplied to the first input of the ADC module, and to the second control and monitoring signals are input to the ADC module, control and monitoring signals are issued from the first output of the ADC module, the second output of the ADC module is connected to the input of the aforementioned first signal transceiver module, the second transceiver the lock contains a digital-to-analog converter (DAC) module and a second signal reception and transmission module, while control and monitoring signals are received at the first input of the DAC module, a TV signal is output from the first output of the DAC module, control and control signals are output from the second output of the DAC module, this second input of the DAC module is connected to the first output of the said second module of the reception and transmission of signals, characterized in that the ADC module contains a converter of logical voltage levels into levels corresponding to the selected standard serial code transmission, low-pass filter, bias generator used to set the black level offset in the television signal, the ADC and the comparator, the low-pass filter input is the first input of the ADC module, and the ADC output is the second output of the ADC module, low-pass filter output connected to the first information input of the bias driver, to the second input of which a bias signal is applied, the output of the bias driver is connected to the first information input of the ADC and the first th input of the comparator, the second input of which is supplied with the voltage comparator providing actuation when the horizontal and vertical sync pulses of the television signal, said first module receiving and transmitting signals comprises a device for digitally processing a video signal, a decoder pulse frequency modulation signal, receiving

optical module, front isolator, delay element, protocol control device, comparison circuit, storage register, encoder, parallel-to-serial code converter, transmitting optical module, clock generator, first and second dividers and a clock splitter, while a digital video signal processing device It is intended for digital filtering and analysis of the correspondence of a television line to a given television line, as well as for the issuance of a work permit signal for the bias driver, the information input of the digital video processing device and the first information input of the protocol monitoring device are the mentioned input of the first transceiver module, the second control input of the digital video processing device and the second synchronizing input of the ADC of the ADC module are connected to the output of the second divider, the output of the digital video processing device connected to the control input of the aforementioned shifter of the ADC module, the first information input of the second divider, the first the control input of the comparison circuit and the information input of the first divider are connected to the output of the pre-selector, the input of which is connected to the output of the clock generator and to the control input of the parallel code to serial converter, the information input of which is connected to the output of the encoder, the information input of which is connected to the protocol control device, the first the control input of which is connected to the output of the delay element, the input of which is connected to the output of the front highlighter and the control input of the register, information the first output of which is coupled to a second data input of the protocol control device and the first information input of the comparison circuit, a second information input connected to a second output of the first divider and the input information register, a first output of the first divider coupled to a second control input of the control device and the first protocol

the control input of the encoder, the second control input of which is connected to the second output of the converter of logical voltage levels into levels corresponding to the selected standard for transmitting the serial code, the ADC module, while the second information input of the said converter of logical voltage levels to levels corresponding to the selected standard for transmitting the serial code, the ADC module is connected with the output of the decoder, the input of which is connected to the output of the receiving optical module, the input of which is intended for communication and with said fiber-optic cable and for receiving control and monitoring signals from said fiber-optic cable, the output of the parallel-to-serial code converter is connected to the input of the transmitting optical module, the output of which is intended for communication with said fiber-optic cable and for transmitting TV signals and control and monitoring signals to the aforementioned fiber optic cable, the second output of the protocol monitoring device is connected to the reset input of the comparison circuit, the selector input is front and connected to the output of the aforementioned comparator of the ADC module, the first output of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, the ADC module intended for issuing control and monitoring signals, the first input of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code , the ADC module is designed to receive control and monitoring signals, while the said DAC module of the second transceiver The first block contains a converter of logical voltage levels into levels corresponding to the selected serial code transmission standard, a DAC and a low-pass filter, the output of which is the first output of the DAC module, the low-pass filter input is connected to the DAC output, the first information input of which is the second input of the DAC module , the first input of the logical voltage level converter

into the levels corresponding to the selected transmission standard of the serial code, designed to receive control and monitoring signals, the second output of the logical voltage level converter to the levels corresponding to the selected transmission standard of the serial code, is used to issue control and control signals, while the second signal reception and transmission module contains a transmitter optical module, pulse frequency modulator, receiving optical module, serial code to parallel code converter, decoder, protocol control device, interpolator, phase detector, voltage-controlled generator, first and second dividers, third divider, comparison circuit and frequency multiplier, the first output of which is connected to the control input of the DAC of the DAC module, the second output of the frequency multiplier is connected to the first control input an interpolator, the second control input of which and the input of the frequency multiplier are connected to the output of the second divider, the first input of which is connected to the output of the comparison circuit, the first input of which is connected to the first output designed to issue a permission signal, a protocol control device, the information output of which is connected to the information input of the interpolator, the information output of which is the first output of the second transceiver module, the second synchronizing input of the second divider, the second synchronizing input of the comparison circuit and the input of the first divider are connected to the output of the third a divider, the input of which is connected to the output of a voltage-controlled generator, with the first input of the phase detector and the first input eobrazovatelya serial to parallel code whose output is connected to a first data input of the decoder, the first output of which is connected to the first protocol control information input device, and the control input of which a control input of the decoder coupled to the first output of the first divider, a second data output which is connected to

the first input of the comparison circuit, the second input of which is connected to the information output of the protocol control device, the second output of the decoder is connected to the second input of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, the DAC module, the first output of the converter of logical voltage levels into levels corresponding to the selected standard transmission serial code, the DAC module connected to the input of the frequency-pulse modulator, the output of which is connected to one of the transmitting optical module, the output of which is intended for communication with the aforementioned fiber optic cable and for issuing control and monitoring signals to said fiber-optic cable, the input of the transmitting optical module is intended for communication with the aforementioned fiber optic cable and for receiving TV signals from fiber optical cable, the output of the receiving optical module is connected to the second information input of the serial code to parallel code converter and to the information input of the phase detector ctor, the output of which is connected to the input of the generator, controlled by voltage.

The proposed utility model is illustrated by the following drawings:

Figure 1 - which shows a generalized block diagram of an example implementation of a fiber optic local area network;

Figure 2 - which shows a structural block diagram of an example implementation of a first transceiver block;

Figure 3 - which shows a structural block diagram of an example implementation of a second transceiver block.

As can be seen from the drawing of FIG. 1, the claimed fiber optic local area network comprises a first transceiver unit 1 (hereinafter referred to as PPU-1) and a second transceiver unit 5 (hereinafter referred to as PPU-2), interconnected by a fiber optic cable 3. Connection carried out using appropriate connectors (2, 4).

Data is transmitted via fiber-optic cable 3, containing 2 optical fibers, in two directions: from PPU-1 to PPU-2, the digitized TV signal and signals of the TIA / EIA-232 standard are transmitted, in the direction from PPU-2 to PPU-1 TIA / EIA-232 signals are transmitted.

The first transceiver unit 1 contains an analog-to-digital converter (ADC) module 6 and the first transceiver module 7 associated with the ADC module 6. The ADC module 7 converts an analog television (TV) signal received via radio frequency (RF) cable, digitally. The ADC 7 module includes a power supply device that converts 27V voltage to 5V voltage, which is necessary for powering FOCL equipment.

The first transceiver module 7 is intended for electron-optical conversion and temporary multiplexing and demultiplexing of TIA / EIA-232 standard signals and a TV signal over a fiber optic cable (FOC).

The second transceiver unit 5 comprises a digital-to-analog converter (DAC) module 8 and a second transceiver module 9, which is connected to the DAC module 8.

The DAC module converts a digital signal into analog form and provides a television signal for display on a monitor. The DAC module also includes a power supply device that converts 27V voltage to 5V voltage, which is necessary to power the fiber-optic network equipment.

The transmit-receive module 7 as part of PPU-2 (5) is designed to convert a serial data stream in the form of an optical signal coming through a fiber-optic local area network into an electric signal, which is converted into a data word stream with a bit capacity of 18 bits. The transmit-receive module 7 provides input without noticeable loss

useful information in synchronism with the transmission node and restore synchronization in the event of a failure in the exchange.

The module is also designed to transmit a TIA / EIA-232 standard signal subjected to pulse-frequency modulation to a fiber-optic local area network.

As can be seen from the drawing of figure 2, the ADC module 6, which is part of PPU-1 (1), contains a converter 10 of the logical voltage levels into TIA / EIA-232 standard levels, a low-pass filter 11, an offset driver 12, designed to set the level offset black in the television signal, the ADC 13 and the comparator 14.

The output of the ADC 13 is the second output of the ADC module 6, the output of the low-pass filter 11 is connected to the first information input of the bias generator 12, the second input of which is supplied with a bias signal, the output of the bias driver 12 is connected to the first input of the ADC 13 and the first input of the comparator 14, the second input of which is supplied with voltage, which ensures that the comparator is triggered at the time of the horizontal and frame sync pulses of the television signal.

The control and monitoring signals are supplied to the first input of the converter 10, and the control and monitoring signals are output from the first output of this converter 10. The input of the low-pass filter 11 receives TV signals.

The first transceiver module 7, which is part of PPU-1, contains a digital video signal processing device 15, a pulse-frequency modulation signal decoder 16, a receiving optical module 17, a front highlighter 18, a delay element 19, a protocol monitoring device 20, a comparison circuit 21 , storage register 22, encoder 23, the parallel-to-serial code converter 24, the transmitting optical module 25, the clock 26, the first and second dividers 27, 28 with a division ratio of 6 and a divider 29 with a division ratio of 3.

The information input of the digital video processing device 15 and the first information input of the protocol monitoring device 20 are the second input of the first transceiver module 7, the second control input of the digital video processing device 15 and the second clock input of the ADC 13 are connected to the output of the second divider 28 with a division ratio of 6, the output of the digital video signal processing device 15 is connected to the control input of the aforementioned displacement driver 12, the first information input of the second divider 28 with a coefficient d 6, the first control input of the comparison circuit 21 and the information input of the first divider 27 with a coefficient of 6 are connected to the output of the pre-divider 29 with a coefficient of 3, the input of which is connected to the output of the clock generator 26 and to the control input of the parallel code converter to serial code 24, the information input of which connected to the output of the encoder 23, the information input of which is connected to the protocol monitoring device 20, the first control input of which is connected to the output of the delay element 19, the input of which is connected to the output a front isolator 18 and a control input of the register 22, the information output of which is connected to the second information input of the protocol control device 20 and the first input of the comparison circuit 21, the second input of which is connected to the second output of the first divider 27 with a coefficient of 6 and the information input of register 22, the output of the first divider 27 with a coefficient of 6 is connected to the second control input of the protocol monitoring device 20 and the first control input of the encoder 23, the second control input of which is connected to the second output of the log converter 10 voltage levels to the levels of the standard TIA / EIA-232 of the ADC module 6, the second information input of the said converter 10 of the logical voltage levels to the levels of the standard TIA / EIA-232 of the ADC module 6 is connected to the output of the decoder 16, the input of which is connected to the output of the receiving optical module 17 which is intended for reception

control and control signals transmitted via a fiber optic cable, the output of the parallel code to serial code converter 24 is connected to the input of the transmitting optical module 25, which is designed to transmit TV signals and control and control signals via a fiber optic cable, the second output of the protocol monitoring device 20 is connected to the reset input of the comparison circuit 21, the input of the front isolator 18 is connected to the output of the comparator 14.

As can be seen from the drawing of figure 3, the DAC module 8 of the second transceiver unit (PPU-2) 5 contains a converter 30 of the logical voltage levels to the levels of the standard TIA / EIA-232, DAC 32 and a low-pass filter 31.

The output of the lowpass filter 31 is the first output of the DAC module 8, the input of the lowpass filter 31 is connected to the output of the DAC 32, the first information input of which is the second input of the DAC module 8, the first input of the TIA / EIA-232 30 logic level converter is designed for receiving control and monitoring signals, the second output of the converter of logical voltage levels into levels of the TIA / EIA-232 30 standard is intended for issuing control and monitoring signals.

The second transceiver module 9 comprises a transmitting optical module 33, a pulse frequency modulator (PFM encoder) 34, a receiving optical module 35, a serial to parallel code converter 36, a decoder 37, a protocol monitoring device 38, an interpolator 39, a phase detector 40, a voltage controlled oscillator 41, first and second dividers 42, 43 with division factors by 6, a third divider 44 with a division ratio of 3, a comparison circuit 45 and a frequency multiplier 46 by 2.

The first output of the multiplier 46 is connected to the control input of the DAC 32 of the DAC module 8, the second output of the frequency multiplier 46 by 2 is connected to the first control input of the interpolator 39, the second control input

which and the input of the frequency multiplier 46 by 2 are connected to the output of the second divider 43 with a division factor of 6, the first input of which is connected to the output of the comparison circuit 45, the first input of which is connected to the first output intended to issue a permission signal, protocol monitoring device 38, information the output of which is connected to the information input of the interpolator 39, the information output of which is the first output of the second transceiver module 9, the second clock input of the second divider 43 with the division coefficient n 6, the second synchronizing input of the comparison circuit 45 and the input of the first divider 42 with a division ratio of 6 are connected to the output of the third divider 44 with a division ratio of 3, the input of which is connected to the output of the voltage-controlled generator 41, with the first input of the phase detector 40 and the first input the serial code to parallel code converter 36, the output of which is connected to the first information input of the decoder 37, the first output of which is connected to the first information input of the protocol control device 38, the control input to and the control input of the decoder 37 is connected to the first output of the first divider 42 with a division factor of 6, the second information output of which is connected to the first input of the comparison circuit 45, the second input of which is connected to the information output of the protocol control device 38, the second output of the decoder 37 is connected to the second the input of the converter 30 of the logical voltage levels to the levels of the standard TIA / EIA-232 of the DAC module 8, the first output of the converter 30 of the logical voltage levels to the levels of the standard TIA / EIA-232 of the DAC module 8 is connected to the input part a pulsed modulator 34, the output of which is connected to the input of the transmitting optical module 33, the output of which is intended for issuing control and monitoring signals to the fiber optic cable 3, the input of the transmitting optical module 33 is designed to receive TV signals from the fiber optic cable 3, output the receiving optical module 35 is connected to the second

information input of the serial code converter into parallel code 36 and with the information input of the phase detector 40, the output of which is connected to the input of the voltage controlled generator 41.

Next, the operation of PPU-1 (1) will be described.

The ADC 6 module converts an analog television signal supplied via an RF cable with a wave impedance of 75 Ohms into a parallel digital code. Module 6 operates in conjunction with the TV signal reception and transmission module 7, based on the PPM-100 module, which was developed by VOSPI Center CJSC and has been tested for compliance with group 1.3. The purpose of the module 7 for receiving and transmitting a TV signal as part of PPU-1 is to receive and pre-digitally process a digitized TV signal, convert a 10-bit parallel code and TIA / EIA-232 signals into a balanced serial line code, and transfer it to a local fiber-optic network. The transfer rate is 288 Mbps.

A standard analog television signal is input to the “TV Input” of the ADC 6 module. Module 6 filters the signal and limits the channel bandwidth to 6 MHz using an active analog low-pass filter 11.

The Offset Shaper 12 is designed to set the black level offset in the television signal supplied to the analog-to-digital converter. The offset is specified by the voltage Ucm. The resolution of the displacement driver comes from the digital processing circuitry for the television signal 15, which performs digital filtering to exclude color signals and analyzes for compliance of the television line with the standard and, if the signal is correct, generates an operation resolution signal from 6 to 8 μs from the beginning to the offset driver 12 strings.

The signal is converted into digital form by an analog-to-digital converter (ADC) 13. The sampling frequency of the ADC is 13-16 MHz, the resolution is 10 bits. The ADC module 13 uses an ADC chip with a pipelined architecture with a performance of 20 MSPS, specialized for converting a television signal, AD9200 from Analog Devices, USA.

For high-quality conversion of television signals into digital form, as a rule, automatic adjustment of the sampling frequency of the ADC 13 to the frequency of the input signal (PLL) is used. To implement a transmission system over a fiber-optic local area network, such a solution cannot be used, since several different types of input signal sources can be used in the system. For example, a Fast Ethernet signal or a second television signal. At the same time, it is impossible to adjust the frequency of one clock generator for various non-multiple frequencies of several input signals.

To solve this problem, a new one is the use of a phase correction system to automatically adjust the phase of the ADC 13 synchronization signal to the beginning of the TV signal line. A comparator 14 is installed in the ADC module 13, which is configured to give a pulse at the moment of the appearance of horizontal and frame sync pulses of the television signal. As a comparator 14 used chip AD8061 company Analog Devices, USA. Response time no more than 7 ns.

The synchronization reference source for transmission is a 288 MHz clock 26 with a divider 29 with a division ratio of 3 and a divider 27 with a division ratio of 6, which can store the value of its counter in the storage register (REG) 22. The value of the divider 27 is stored when a rising edge appears signal from comparator 14.

The digitized data from the ADC 13 is supplied to the Protocol Monitoring Device 20, which operates according to the following algorithm:

- in the absence of a signal from the comparator 14, which passed the delay element 19, UKP 20 receives the digitized data and passes to the output for transmission to the fiber-optic local area network (main mode).

- when a signal appears from the comparator 14 that has passed the delay element 19, the input data is replaced with a value of 0, which at the reception is a command to carry out the correction. The value 0 cannot be obtained in native mode.

- In the next clock step, the input data is replaced by the value of the counter of the divider 27, stored in the REG 22 register at the time of the rising edge of the signal from the comparator 14. UKP 20 generates a signal enabling the operation of the comparison circuit (CC) 21.

- In the next cycle, the enable signal of the operation of the comparison circuit (CC) 21 is removed and UKP 20 switches to the main mode.

If there is a enable signal for the operation of the comparison circuit (CC) 21, it generates a reset signal for the divider 28, which is the source of the clock signal for the ADC 13. A reset signal is generated when the value stored in the REG 22 register and the counter value of the divider 27. In this case, the ADC 13 clock signal appears with the same delay relative to the start of each television line. The accuracy of the correction is determined by the phase jitter of the signal of the comparator 14, and the period of the synchronization signal of the nodes of the circuit 96 MHz. In practice, the accuracy of the adjustment is no worse than 14 ns.

The signal of the comparator 14 must be applied to the UKP 20 with a delay of 1-2 μs so that the phase correction is not carried out at the moment when the falling edge of the clock continues. Correction is carried out only inside the clock signal of the television signal, when the values of the ADC 13 are not used to build a television image.

Thus, information about the current offset of the synchronization pulses of the ADC 13 relative to the phase of the reference generator is transmitted

to the receiving side in the form of a special command, which replaces the original video image data inside the horizontal or frame sync pulse. The command is decoded and the synchronization phase of the DAC 32 is shifted. Thus, the television output signal is synchronous with the television input signal without using a separate phase-locked loop (PLL). Studies show that the applied system with phase correction allows you to get rid of visible distortion of the color image in the form of moire on blue and red fields. The absence of a separate PLL node makes it possible to encode two television signals with a bit width of 8 bits for transmission over FOCL without loss of quality.

Data is received at the input of Encoder 23, which collects all the information to be transmitted to the fiber optic local area network and performs linear coding.

The parallel-to-serial-to-serial converter 10 temporarily compresses 18 digital information signals into one at a speed of 288 Mbit / s. After loading a parallel code with a capacity of 18 bits into the output, bits of the output code with a frequency of 288 MHz are output. The indicated number of information channels includes 10 bits of the digitized television image, 1 bit of TIA / EIA-232 signals. The remaining 6 bits remain redundant and can be used to increase the capabilities of the system. For example, signaling other types of serial low-speed interfaces.

The described digital nodes are complex high-speed logic devices and are implemented on a four-layer printed circuit board in PC104 construct using a user-programmable logic integrated circuit (FPGA) of the Xilinx company (USA) of the Virtex XCV50-4TQ144i series with the integration of 50,000 system valves.

The bitstream arrives at the input of the transmitting optical module (POM) 25. A domestic laser produced by f. NOLATEH POM14-2k operating at a wavelength of λ = 1.31 microns. The radiation power is 1 dBm. To control the laser, the driver microcircuit MAX 3264 is used from Maxim, USA.

The receive-transmit module 7 of the PPM-100 TV signal has a receiving optical module (PROM) 17 designed to receive TIA / EIA-232 signals encoded by the pulse frequency modulation method for transmission to a fiber-optic local area network. To obtain a balanced linear code, the logical units of the original signal are encoded by alternating sequences “00” and “11”, and logical zeros are encoded by alternating “0” and “1”. This method is simple to implement and provides, with a narrow passband, an acceptable phase jitter of the edges of the TIA / EIA-232 standard output signal. The decoding procedure is performed by the PFM Decoder 16.

To convert logical voltage levels to TIA / EIA-232 standard levels, use the TIA / EIA-232 Converter (10).

Now the operation of PPU-2 (5) will be described.

The conversion of the optical signal into electrical form and its amplification is carried out by the domestic receiving optical module (PrOM) 35 manufactured by f. NOLATEH FDU-1. Sensitivity is - 35 dBm. The energy potential of the transmission line is 35 dB. This is enough to transmit information over a single-mode fiber up to a distance of 50 km or 2 km over a multimode fiber in harsh operating conditions.

The synchronization system of the TV signal receiving module is based on the PLL loop, consisting of a voltage-controlled oscillator (VCO) 41, a phase detector (PD) 40. The PLL system reference signal is a signal from a fiber-optic local area network.

The code used for linear coding has a sufficient number of transitions for stable frequency capture by the PLL.

VCO 41, together with a divider 44 with a division ratio of 3 and a divider 43 with a division ratio of 6, is a source of synchronization of the nodes of the device.

Information pulses are fed to the input of the converter 36, which descrambles the data stream and searches for the boundaries of the blocks of the serial code and converts the serial code into parallel. The received data blocks with a dimension of 18 bits contain 17 information bits and 1 service. Decoder 37 allocates a 10-bit video sampling word in the 10 low-order bits of a block, and a TIA / EIA-232 channel bit in 11 bits. The 6 remaining bits are reserved for a possible build-up of the transmission system.

The phase synchronization between the synchronization signal of the DAC 32 and the phase of the reference generator is restored at the moment of receipt of the command generated by the TV signal transmission module. This operation is carried out by the protocol control device (UKP) 38 and the comparison circuit (SS) 45. UKP 38 gives a signal allowing the SS 45 to work. If the values of the reference divider 42 and the values received in the UKP 38 from the transmission unit 9 match, the comparison circuit 45 gives a reset signal to a divider 43, which is the clock source for the DAC 32.

In order to improve the shape of the TV output signal, the DAC 32 synchronization frequency is doubled and amounts to 32 MHz. The transition to a new frequency is carried out by means of an interpolator 39 and a frequency multiplier 46 by 2.

The transceiver module 9 of the TV signal, like the transceiver module 7, contains an FPGA for implementing digital nodes.

Digital readings are converted to analog form for further viewing on a monitor screen or processing in a computer. This operation is performed using a digital-to-analog converter.

(DAC) 32 on the ADV7127KR50 chip manufactured by Analog Devices, USA. An active low-pass filter 31 at the output of the circuit is necessary to suppress the high-frequency components of the analog TV signal that occurs after digital-to-analog conversion.

In the transmit-receive module 9 of the PPM-100 TV signal, there is a transmitting optical module (POM) 33 for transmitting TIA / EIA-232 signals encoded by the pulse frequency modulation method for transmission to a fiber-optic local area network. To obtain a balanced linear code, the logical units of the original signal are encoded by alternating sequences “00” and “11”, and logical zeros are encoded by alternating “0” and “1”. This method is simple to implement and provides, with a narrow passband, an acceptable phase jitter of the edges of the TIA / EIA-232 standard output signal. The encoding procedure is performed by the PFM Encoder 34.

To convert logical voltage levels to TIA / EIA-232 standard levels, use the TIA / EIA-232 30 Converter.

Ways of building and upgrading PPU.

The redundancy and architecture features of these transmitting and receiving devices make it possible to adapt the system for various applications. Possible ways of modernization are:

- additional transmission of up to 6 channels of independent serial interfaces together with a television signal without loss of quality of the latter with a transmission speed of up to 3 Mbit / s.

- transmission of parallel codes with a capacity of 8 bits at a speed of 16 MB / s while reducing the bit depth of a television signal to 8 bits.

- simultaneous transmission of two television signals in one direction.

- transmission of an uncompressed television signal with a resolution of 8 bits in conjunction with signals of the Fast Ethernet standard 100 Mbit / s.

multiplexing a television signal and signals of low-speed interfaces by using the redundancy of an analog television signal (use of horizontal sync pulses to transmit sections).

Claims (1)

A fiber optic local area network for transmitting television signals (TV), control and monitoring signals, comprising a first transceiver unit and a second transceiver unit, which is connected via a fiber optic cable to a first transceiver unit, the first and the second transceiver blocks are designed for electron-optical conversion and temporary multiplexing and demultiplexing of TV signals and control and monitoring signals, while the first transceiver block pre It is designed to transmit TV signals and control and control signals via a fiber-optic cable to the second transceiver unit, as well as to receive control and control signals via a fiber-optic cable from the second transceiver unit, and the second transceiver unit is intended for transmitting control and monitoring signals via a fiber optic cable to a first transceiver unit, wherein the first transceiver unit contains an analog-to-digital converter (ADC) module and a first signal transceiver module fishing, the analogue television signal arriving through the RF cable is supplied to the first input of the ADC module, and control and monitoring signals are received to the second input of the ADC module, control and monitoring signals are issued from the first output of the ADC module, the second output of the ADC module is connected to the input of the said first module signal transceiver, the second transceiver block contains a digital-to-analog converter (DAC) module and a second signal transceiver module, while control and control signals are received at the first input of the DAC module Olya, a TV signal is output from the first output of the DAC module, control and monitoring signals are output from the second output of the DAC module, while the second input of the DAC module is connected to the first output of the second signal reception and transmission module, characterized in that the ADC module contains a logic level converter voltage levels corresponding to the selected serial code transmission standard, low-pass filter, bias generator, designed to set the black level bias in a television signal, ADC and compar OP, the low-pass filter input is the first input of the ADC module, and the ADC output is the second output of the ADC module, the low-pass filter output is connected to the first information input of the bias driver, the second input of which supplies the bias reference signal, the output of the bias driver is connected to the first information input of the ADC and with the first input of the comparator, the second input of which is supplied with voltage, which ensures the comparator is triggered at the moment of horizontal and frame sync pulses of the television system of the signal, said first signal reception and transmission module comprises a digital video signal processing device, a pulse frequency modulation signal decoder, a receiving optical module, a front highlighter, a delay element, a protocol monitoring device, a comparison circuit, a storage register, an encoder, a parallel code to serial code converter transmitting an optical module, a clock generator, first and second dividers and a clock frequency divider, while the digital video signal processing device is designed to Digital filtering and analysis of the correspondence of a television line to a given television line, as well as for issuing a work permit signal to a displacement driver, the information input of a digital video signal processing device and the first information input of a protocol control device are the mentioned input of the first transceiver module, the second control input digital video processing devices and the second synchronizing input of the ADC module of the ADC are connected to the output of the second divider, the output is For digital video processing, it is connected to the control input of the above-mentioned ADC module displacement driver, the first information input of the second divider, the first control input of the comparison circuit and the information input of the first divider are connected to the output of the pre-divider, the input of which is connected to the output of the clock generator and to the control input of the parallel code converter to serial code, the information input of which is connected to the output of the encoder, the information input of which is connected to the control device , the first control input of which is connected to the output of the delay element, the input of which is connected to the output of the front highlighter and the control input of the register, the information output of which is connected to the second information input of the protocol control device and the first information input of the comparison circuit, the second information input of which is connected to the second output of the first the divider and the information input of the register, the first output of the first divider is connected to the second control input of the protocol control device and the first control input an encoder house, the second control input of which is connected to the second output of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, the ADC module, while the second information input of the said converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, the ADC module connected to the output of the decoder, the input of which is connected to the output of the receiving optical module, the input of which is designed to communicate with the mentioned fiber-optic cable and for receiving control and monitoring signals from said fiber-optic cable, the output of the parallel code to serial code converter is connected to the input of the transmitting optical module, the output of which is intended for communication with the fiber-optic cable and for transmitting TV signals and signals control and monitoring of said fiber-optic cable, the second output of the protocol monitoring device is connected to the reset input of the comparison circuit, the front isolator input is connected to the course of the aforementioned comparator of the ADC module, wherein the first output of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, the ADC module intended for issuing control and monitoring signals, the first input of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, the ADC module is designed to receive control and monitoring signals, while the said DAC module of the second transceiver block It implements a converter of logical voltage levels into levels corresponding to the selected serial code transmission standard, a DAC and a low-pass filter, the output of which is the first output of the DAC module, the low-pass filter input is connected to the DAC output, the first information input of which is the second input of the DAC module, the first input of the converter of logical voltage levels into levels corresponding to the selected serial code transmission standard is intended for receiving control signals and control, the second output of the converter of logical voltage levels into levels corresponding to the selected transmission standard of the serial code, is intended for the issuance of control and monitoring signals, while the second signal reception and transmission module contains a transmitting optical module, a pulse-frequency modulator, a receiving optical module, a converter serial code to parallel code, decoder, protocol control device, interpolator, phase detector, voltage-controlled generator, first and second dividers, a third divider, a comparison circuit and a frequency multiplier, the first output of which is connected to the control input of the DAC of the DAC module, the second output of the frequency multiplier is connected to the first control input of the interpolator, the second control input of which and the input of the frequency multiplier are connected to the output of the second divider, the first input of which connected to the output of the comparison circuit, the first input of which is connected to the first output intended for issuing a permission signal, a protocol monitoring device, the information output of which is connected to the input input of the interpolator, the information output of which is the first output of the second transceiver module, the second synchronizing input of the second divider, the second synchronizing input of the comparison circuit and the input of the first divider are connected to the output of the third divider, the input of which is connected to the output of the voltage-controlled generator, with the first the input of the phase detector and the first input of the serial code to parallel code converter, the output of which is connected to the first information input of the decoder, the first output of which is connected to the first information input of the protocol control device, the control input of which and the control input of the decoder are connected to the first output of the first divider, the second information output of which is connected to the first input of the comparison circuit, the second input of which is connected to the information output of the protocol control device, the second output the decoder is connected to the second input of the converter of the logical voltage levels into levels corresponding to the selected serial code transmission standard, mode I DAC, the first output of the converter of logical voltage levels into levels corresponding to the selected standard for transmitting a serial code, a DAC module connected to the input of a pulse-frequency modulator, the output of which is connected to the input of a transmitting optical module, the output of which is designed to communicate with the aforementioned fiber-optic cable and for issuing control and monitoring signals to said optical fiber cable, the input of the transmitting optical module is designed to communicate with said optical fiber with a cable and for receiving TV signals from a fiber optic cable, the output of the receiving optical module is connected to the second information input of the serial code to parallel converter and to the information input of the phase detector, the output of which is connected to the generator input, controlled by voltage.