RU2280330C1 - Device for controlling transmission of control data via a radio channel - Google Patents

Abstract

FIELD: computer science, possible use in systems for remote control of telecommunication networks during transmission of control data along broadcasting multi-point radio channel.

SUBSTANCE: device for controlling transmission of control data via a radio channel consists of: random numbers generator, synchronizer, first AND element, counter, RS-trigger, second AND element, comparison block, signal selection block, clock pulse generator, address analysis block, commutation block, block for measuring parameters, record counter of text portion of packet, packet reading counter, multi-input OR element, random-access memory device. Due to new set of substantial signs due to insertion of communication block, parameters measuring block, record counter of text portion of packet, packet reading counter, multi-input OR element and random-access memory device and appropriate new connections, automatic calibration is possible for parameter measuring block and also measuring of such a parameter of optical route, as fading coefficient of cable equipment reflection, and also it is possible to generate a packet of control data and to transfer it via radio channel to superior node of network.

EFFECT: generation of status control data for remote element of telecommunication network due to measurement of one of parameters of its optical route and transferring these data along radio-channel to superior network node.

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Description

The invention relates to computer technology and can be used in remote control systems of telecommunication networks when transmitting control data via a broadcast multi-point radio channel.

A device is known for controlling data transmission over a radio channel (AS USSR No. 1162058, IPC 5 H 04 L 7/00, 1985), comprising a synchronizer, first and second AND elements, a delay element, an OR element, a counter, a cycle trigger transmission, random number generator, comparison unit, transmission permission trigger, pulse shaper.

There is also known a device for controlling data transmission over a radio channel (AS USSR No. 1319298, IPC 5 H 04 L 7/00, 1990), containing a random number generator and a synchronizer, the first, second, third and fourth elements of And, a counter , comparison unit, transmission cycle trigger, transmission enable trigger, two pulse shapers, OR element, two delay elements.

These devices do not have a sufficient transmission rate over the radio channel, the devices lack tools to implement the function of generating control data of remote network elements.

The closest in technical essence and the functions performed to the claimed one is a radio data transmission control device (RF patent No. 2144267, IPC 7 H 04 L 7/00, published January 10, 2000), containing a random number generator, synchronizer, counter, the first element And , the first input of which is the control input of the device, the RS-trigger, the second element And, the comparison unit, the third element And, the block selection of the sign of the navigation packet, the clock, the address allocation block, the block determining the interval of receipt of the packet and a timer block, the synchronizer output being connected to the counter input and the first input of the second AND element, the group output of the counter is connected to the counting input of the comparison unit, the random number input of which is connected to the group output of the random number generator, the output of the first element And is connected to the input of the random number generator and the reset input of the RS-trigger, the installation input of which is connected to the output of the comparison unit and the first input of the third element And, the output of the second element And is connected to the second input of the first element And, the output of the RS-trigger a - with the second input of the second AND element, the information input of the feature block for allocating the navigation package is connected to the information input of the address allocation unit and is the information input of the device, the output of the third AND element is the control output of the device, the signal output of the feature block for allocating the feature of the navigation package is connected to the first signal input the unit for determining the interval of receipt of the packet and the control input of the unit for allocating the address, the first output of the signal "Reset" of the unit for determining the interval is received I of the packet is connected to the input of the “Reset” signal of the allocation block of the sign of the navigation packet, the output of the address allocation block is connected to the second signal input of the block for determining the interval of packet arrival, the second output of the “Reset” signal is connected to the input of the “Reset” signal of the address allocation block, the generator output clock pulses connected to the clock inputs of a block for selecting a sign of a navigation packet, a block for allocating an address, a block for determining an interval of packet arrival and a block for timers, a group output of a block for determining an interval a packet arrival timers connected to the input unit, the output of which is connected to the inverted input of the third element I.

However, the prototype device has a drawback: the device does not include the means to implement the function of generating control data of remote network elements.

The aim of the invention is the development of a control device for transmitting control data over a radio channel, providing the formation of state monitoring data of a remote element of a telecommunication network by measuring one of the parameters of its optical path and transmitting this data over the air to a senior network node.

This goal is achieved by the fact that in the known device for transmitting data via a radio channel containing a random number generator, a synchronizer, a counter, a first AND element, an RS trigger, a second AND element, a comparison unit, a signal extraction unit, a clock pulse generator, an address analysis unit moreover, the output of the synchronizer is connected to the input of the counter and the first input of the second element And, the group output of the counter is connected to the counting input of the comparison unit, the input of random numbers of which is connected to the group output of the generator yth numbers, the output of the first element And is connected to the input of the random number generator and the input R of the RS-trigger, the output of which is connected to the second input of the second element And, the output of which is connected to the second input of the first element And, the output of the comparison unit is connected to the input S of the RS-trigger , the information inputs of the signal extraction unit and the address analysis unit are combined and are the information input of the device, the signal output of the signal extraction unit is connected to the signal input of the address analysis unit, the output of the clock generator is connected to acts input block selection signal and a block address analysis additionally introduced switching unit, a parameter measurement, the counter recording the text portion of the packet, packet counter reading, multi-input OR gate and a random access memory. In this case, the output of the address analysis unit is connected to the control input of the switching unit and the recording input of random access memory. The signal output of the switching unit is connected to the first input of the first element I. The first, second, third and fourth control outputs of the switching unit are connected to the first, second, third and fourth control inputs of the parameter measuring unit, respectively. The clock output of the switching unit is connected to the input of the recording counter of the text part of the packet. The output of the comparison unit is connected to the signal input of the switching unit, the input of the packet read counter and the read input of random access memory. The outputs of the counters for recording the text part of the packet and reading the packet through a multi-input OR element are connected to the address input of random access memory, the information input of which is connected to the information output of the parameter measurement unit. The input of the parameter measurement unit is the input of the optical path of the device, the output of the optical path of the parameter measurement unit is the output of the optical path of the device, the output of the random access memory is the information output of the device.

Thanks to a new set of essential features due to the introduction of a switching unit, a parameter measuring unit, a text part recording counter, a packet reading counter, an OR multi-input element and random access memory and corresponding new connections, automatic calibration of the parameters measuring unit means and measurement of such an optical path parameter are possible, as the attenuation coefficient of reflection of cable equipment.

The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features identical to all the features of the claimed technical solution are absent, which indicates the compliance of the claimed device with the patentability condition of "novelty".

Search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the claimed object from the prototype showed that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the impact provided by the essential features of the claimed invention, the transformations on the achievement of the specified technical result. Therefore, the claimed invention meets the condition of patentability "inventive step".

The inventive device is illustrated by drawings:

- figure 1 is a functional diagram of a control device for transmitting control data over a radio channel;

- figure 2 is a diagram of a random number generator;

- figure 3 is a block diagram of the signal extraction;

- figure 4 is a block diagram of the address analysis;

- figure 5 - circuit block switching;

- 6 is a diagram of a unit for measuring parameters;

- Fig.7 is a diagram of an electronic switch.

The inventive control device for transmitting control data over a radio channel, shown in Fig. 1, consists of a random number generator 1, a synchronizer 2, a first element And 3, a counter 4, an RS trigger 5, a second element And 6, a comparison unit 7, a signal extraction unit 8, a clock generator 9, an address analysis unit 10, a switching unit 11, a parameter measuring unit 12, a text counter for writing a text part of a packet 13, a read counter for a packet 14, a multi-input element OR 15, a random access memory 16. In this case, the output of the hell analysis block Resa 10 is connected to the control input of the switching unit 11 and the recording input of random access memory 16. The signal output of the switching unit 11 is connected to the first input of the first element And 3. The first, second, third and fourth control outputs of the switching unit 11 are connected to the first, second, third and the fourth control inputs of the parameter measurement unit 12, respectively. The clock output of the switching unit 11 is connected to the input of the recording counter of the text part of the package 13. The output of the comparing unit 7 is connected to the signal input of the switching unit 11, the input of the reading counter of the package 14 and the reading input of the random access memory 16. The outputs of the counters of recording the text part of the package 13 and the reading of the package 14 through a multi-input element OR 15 are connected to the address input of random access memory 16, the information input of which is connected to the information output of the parameter measurement unit 12. In this case the input of the parameter measuring unit 12 is the input of the optical path of the device, the output of the optical path of the parameter measuring unit 12 is the output of the optical path of the device, the output of the random access memory 16 is the information output of the device.

The elements included in the general functional diagram have the following purpose.

The random number generator 1 is designed to provide a random code combination for the control signal. Can be implemented according to the scheme shown in figure 2. It consists of p D-flip-flops 1.1 ₁ -1.1 _p and p noise generators 1.2 ₁ -1.2 _p , where p is the bit depth of random code combinations (for example, p = 8). Clock inputs From all D-flip-flops are interconnected and are the control input of the random number generator 1. Information inputs of D D-flip-flops are connected to the outputs of the corresponding p noise generators 1.2 ₁ -1.2 _p . The outputs of the D-flip-flops 1.1 ₁ -1.1 _p form the output bus of the random number generator 1.

The synchronizer 2, as well as the clock generator 9 and the pulse generator 11.4 are intended for the formation of clock pulses and are clock generators. The circuit of such a generator is known and described, for example, in the book: Microcircuits and their application: Reference, manual. / 1984, - p. 213, Fig. 7.6. It can be implemented on integrated circuits (ICs) of the 511, 176 series.

Counter 4 is designed to count the number of clock pulses, counter 13 is designed to count the required number of clock pulses when writing the text part of the generated packet to RAM 16, counter 14 is designed to count the required number of clock pulses when reading the generated packet into the radio channel. These counters, as well as counters 8.2.3 (10.1.3), 8.2.9 (10.1.9), which are part of the electronic switches 8.2 and 10.1, and the counter 11.3 from the switching unit 11 can be implemented according to the scheme described - Pulse basics and digital technology. / Under the general ed. A.M. Sidorova, - SPVVIUS, 1995, Fig. 5.38, p. 169-172.

Comparison unit 7, as well as comparison schemes 8.4, 10.3, are intended to compare code combinations, are known and described, for example, in the book: Lebedev I.O., Sidorov A.M. Pulse digital devices. - L .: YOU, 1980, - p. 51-53, Fig. 2.33, 2.34. They can be implemented on the IC series 133, 564.

The signal extraction unit 8 is intended for extracting a measurement signal from the header of a received packet. Can be implemented in the form shown in figure 3. It includes a pulse shaper 8.1, an electronic switch 8.2, a shift register 8.3, a comparison circuit 8.4, and an OR element 8.5. The combined input of the pulse shaper 8.1 and the information input of the electronic switch 8.2 are the information input of the signal isolation unit 8. The output of the pulse shaper 8.1 is connected to the first and second control inputs of the electronic switch 8.2, the clock input of which is the clock input of the signal selection block 8. In this case, the information output of the electronic switch 8.2 is connected to input D of shift register 8.3, and the clock output of electronic switch 8.2 is connected to input C of shift register 8.3. The output of the shift register 8.3 is connected to the input B of the comparison circuit 8.4, the input A of which is the input of the code combination of the measurement signal. The outputs A = B and A # B of the comparison circuit 8.4 through an OR element 8.5 are connected to the input R of the shift register 8.3. Moreover, the output A = B of the comparison circuit 8.4 is the signal output of the signal isolation unit 8.

Block analysis of the address 10 is intended to highlight from the header of the received packet and analysis of the recipient address. Can be implemented in the form shown in figure 4. It includes an electronic switch 10.1, a shift register 10.2, a comparison circuit 10.3, and an OR element 10.4. The information input of the electronic switch 10.1 is the information input of the address analysis unit 10. The combined first and second control inputs of the electronic switch 10.1 are the signal input of the address analysis unit 10, the clock input of the electronic switch 10.1 is the clock input of the address analysis unit 10. In this case, the information output of the electronic switch 10.1 connected to the input D of the shift register 10.2, and the clock output of the electronic switch 10.1 is connected to the input C of the shift register 10.2. The output of the shift register 10.2 is connected to the input B of the comparison circuit 10.3, the input A of which is the input of the address code combination. The outputs A = B and A # B of the comparison circuit 10.3 through the element OR 10.4 are connected to the input R of the shift register 10.2. In this case, the output A = B of the comparison circuit 10.3 is the output of the address analysis block 10.

The switching unit 11 is designed to generate control signals for optical switches in the unit for measuring parameters 12 during the calibration and measurement of the attenuation coefficient of reflection of the cable equipment of the optical path, can be implemented in the form shown in Fig.5. It includes an RS-trigger 11.1, an element And 11.2, a counter 11.3, a pulse generator 11.4, read-only memory (ROM) 11.5-11.8 and a decoder 11.9. The input of the installation S of the RS-trigger 11.1 is the control input of the switching unit 11, and the reset input R of this trigger is the signal input of the switching unit 11. The output of the RS-trigger 11.1 is connected to the first input of the And 11.2 element, to the second input of which the pulse generator 11.4 is connected . The output of the element And 11.2 is connected to the input of the counter 11.3 and at the same time is the clock output of the switching unit 11. The output of the counter 11.3 is connected to the address inputs of the ROM 11.5-11.8, the outputs of which are the first, second, third and fourth control outputs of the switching unit 11, respectively. The signal output of the switching unit 11 is the output of the decoder 11.9, the input of which is connected to the output of the ROM 11.7.

The unit for measuring parameters 12 is intended for automatic calibration of the measuring instruments included in it, measuring the required characteristics of the optical path and issuing the results of the measurement data in RAM 16 to form a control data packet. The unit for measuring parameters 12 can be implemented in the form shown in Fig.6 (dashed line shows the connection of the optical cable). It includes an optical signal source 12.1, first 12.2, second 12.3 optical switches, an optical power meter 12.4, an optical load with zero reflection 12.5, a third 12.7 and a fourth 12.6 optical switches, an optical splitter 12.8. In this case, the output of the optical signal source is connected to the information input of the first optical switch 12.1, the first output of which is connected to the first information input of the second optical switch 12.3, the second output to the first information input of the third optical switch 12.7, and the third output to the first input-output of the optical splitter 12.8. The second information input of the second optical switch 12.3 is connected to the second input-output of the optical splitter 12.8, and the third information input is connected to the second information input of the third optical switch 12.7. The third information input of the third optical switch 12.7 is connected to the optical load with zero reflection 12.5, and the fourth information input is connected to the first output of the fourth optical switch 12.6. The output of the third optical switch 12.7 is connected to the third input-output of the optical splitter 12.8. In this case, the control inputs of the first 12.2, second 12.3, third 12.7 and fourth 12.6 optical switches are the first, second, third and fourth control inputs of the unit for measuring parameters 12, respectively. The output of the second optical switch 12.3 is connected to the input of the optical power meter 12.4, the output of which is the information output of the parameter measurement unit 12. The information input of the fourth optical switch 12.6 is the input of the optical path of the parameter measurement unit 12, and its second output is the output of the optical path of the parameter measurement unit 12 .

Random access memory (RAM) 16 is designed to accumulate the results of intermediate measurements when calibrating the means of the parameter measurement unit and directly measuring the parameters of the optical path and reading the generated control data packet into the radio channel. They can be implemented according to the scheme described: Shilo V.L. Popular chip TTL. - M .: "Argus", 1993, p. 53-54, on the IMS series 155, 531.

The pulse shaper 8.1, which is part of the signal extraction unit 8, is designed to generate a short pulse from the logical level, it is known and described, for example, in the book: L. Maltseva et al. Fundamentals of digital technology. - M .: Radio and communications, 1986, - fig. 21, p.30.

Electronic switch 8.2 (10.1) is designed to count the number of characters preceding the symbols of the measurement signal (address) and the actual symbols of the measurement signal (address) and the formation of the control signal. Can be implemented in the form shown in Fig.7. It consists of RS-triggers 8.2.1 (10.1.1), 8.2.5 (10.1.5), 8.2.7 (10.1.7), 8.2.11 (10.1.11), elements AND 8.2.2 (10.1. 2), 8.2.4 (10.1.4), 8.2.6 (10.1.6), 8.2.8 (10.1.8), 8.2.10 (10.1.10), 8.2.12 (10.1.12), counters 8.2 .3 (10.1.3), 8.2.9 (10.1.9). Moreover, the first control input of the electronic switch is the installation input S of the RS-flip-flop 8.2.1 (10.1.1), the reset input R of which is connected to the reset input R of the counter 8.2.3 (10.1.3) and the installation inputs of the S RS-flip-flops 8.2.5 (10.1.5) and 8.2.11 (10.1.11). The output of the RS-trigger 8.2.1 (10.1.1) is the first input of the AND 8.2.2 (10.1.2) element, the second input of which is combined with the second inputs of the And 8.2.8 (10.1.8) and 8.2.12 (10.1. 12) and is the clock input of the electronic switch. The output of AND 8.2.2 (10.1.2) is connected to the clock input C of the counter 8.2.3 (10.1.3), the outputs of which are connected to the inputs of And 8.2.4 (10.1.4). The reset input R of the RS-flip-flop 8.2.5 (10.1.5) is connected to the output of the element And 8.2.10 (10.1.10), the reset inputs of the R RS-flip-flops 8.2.7 (10.1.7), 8.2.11 (10.1.11 ) and counter 8.2.9 (10.1.9). The output of trigger 8.2.5 (10.1.5) is connected to the first input of AND 8.2.6 (10.1.6), the second input of which is the information input of the electronic switch, and the output is the information output of the electronic switch. The installation input S of the RS-flip-flop 8.2.7 (10.1.7) is the second control input of the electronic switch, and its output is connected to the first input of AND 8.2.8 (10.1.8), the output of which is connected to the clock input of the counter 8.2.9 ( 10.1.9). The outputs of this counter are connected to the inputs of the element And 8.2.10 (10.1.10). The output of the RS-trigger 8.2.11 (10.1.11) is connected to the first input of AND 8.2.12 (10.1.12), the output of which is the clock output of the electronic switch.

Permanent storage devices (ROM) 11.5-11.8 are designed for sequential issuing of code combinations for controlling the optical switches included in the unit for measuring parameters. The circuit of such a ROM is known and described, for example, in the book: Fundamentals of pulsed and digital technology / Ed. A.M.Sidorova. - SPb .: SPVVIUS, 1995, - Fig. 6.10, p .97-199.

Shift registers 8.3, 10.2 are intended for short-term storage of information and can be implemented according to the scheme described - Fundamentals of pulse and digital technology / Ed. A.M. Sidorova, - SPVVIUS, 1995, Fig. 5.28, p. 158-159.

Optical switches 12.2, 12.3, 12.6, 12.7 are known and described: Shurygina V. Long-awaited MEMS: small form technology /http://cs.mipt.ru/docs/comp/rus/internet/admin/fddi/main.pdf.

An optical signal source 12.1, an optical power meter 12.4, an optical load with zero reflection 12.5, an optical splitter 12.8 are known, their implementation and application are described: OST 45.131-98, clause 7.2.3.1.

D-flip-flops 1.1 ₁ -1.1 _p included in the random number generator 1 are known and described - Fundamentals of pulsed and digital technology / Ed. A.M. Sidorova, - SPVVIUS, 1995, p. 90-91.

Noise generators 1.2 ₁ -1.2 _r , included in the random number generator 1, are designed to generate output voltages randomly changing over time. The schemes of noise generators are known and described in the book - Elements of electronic devices. / B.I. Korotkov, - M.: Radio and Communications, 1988, Fig. 7.24, p. 107.

The decoder 11.9, which is part of the switching unit 11, is designed to generate a signal for initiating the process of transmitting a control data packet, described in the book: L. Maltseva, E. Fromromberg The basics of digital technology - M .: Radio and communications, 1986. - S. 60-61.

RS-triggers included in the blocks of the described device are known and described, for example, in the book: Batushev V.A., Veniaminov V.N., Kovalev V.G. and other Microcircuits and their application: Reference, manual. - M.: Radio and Communications, 1984, p. 122, Fig. 4.16. They can be implemented on the IC series 133, 564.

The logical elements And included in the blocks of the described device are identical, known and described, for example, in the book: Maltseva L.A., Fromberg E.M. The basics of digital technology - M .: Radio and communications, 1986. - p.30-31. They can be implemented on the IC series 133 and 564.

The logical elements OR included in the blocks of the described device are identical, known and described, for example, in the book: Fundamentals of pulse and digital technology / Ed. A.M.Sidorova. - SPVVIUS, 1995, Fig. 2.4, p. 39-41.

The functional diagram of a device that implements the described functions of the formation and transmission of control data over the air is shown in figure 1.

The inventive device operates as follows.

When you turn on the power (power scheme is not shown), trigger 5 is set to the storage mode of the logical unit. Synchronizer 2 generates pulses with a time interval equal to the duration of the packet transmission interval, while pulses are transmitted through the open second element And 6 to the second input of the first element And 3 and to the input of the counter 4, causing a sequential change of code combinations at the output of the counter 4 (the number of code combinations equal to the number of "windows" in the transmission cycle).

All packets transmitted over the air are sent to the information input of the device. When the allocation unit signal 8 from the header of the received packet of the code combination of the measurement signal (which is a command to conduct automatic - without operator intervention - calibrate the device’s measuring instruments and measure the required characteristics to control the reflection attenuation coefficient of the optical cable cable equipment) is a signal with a logical unit level of signal the output of block 8 is fed to the signal input of the address analysis block 10. In this block, upon receipt of this signal from the header, it is accepted on the package selected and analyzed codeword recipient address. If the address coincides with the own address of this device, the output from the analysis unit of address 10 receives a signal with the level of a logical unit at the control input of the switching unit 11, initiating the calibration and measurement process. In this case, the switching unit 11, at certain time intervals, provides code combinations for controlling the optical switches (included in the parameter measuring unit 12) to the control inputs of the parameter measuring unit 12. From the clock output of the switching unit 11, clock pulses are received at the input of the recording counter of the text part of the packet 13, which provide the recording of the measurement results from the parameter measurement block 12 to the text part of the packet formed in RAM 16. At the end of the measurements, at the moment of the arrival of the next pulse from synchronizer 2, the signal with the level of the logical unit from the signal output of the switching unit 11 through the first element And 3 is fed to the input R of trigger 5, translating it into a zero state, as well as to the control input of the random number generator 1, to which generates in a parallel code to the input of random numbers of the comparison unit 7 a code pattern corresponding to the window number in the transmission cycle selected for transmission of the packet. In this case, trigger 5 closes the second element And 6.

At the moment of matching code combinations at both inputs of the comparison unit 7, the signal with the level of the logical unit from its output goes to the read input of RAM 16 and to the input of the read counter of packet 14 (thereby reading from the RAM 16 into the radio channel of the generated control data packet). In addition, this signal is fed to the signal input of the switching unit 11, translating the latter into its initial state, and also puts trigger 5 in single mode. Thus, the device is ready for the next cycle of work.

The random number generator 1, the functional diagram of which is shown in figure 2, works as follows. Ha D inputs of each of the D-flip-flops 1.1 ₁ -1.1 _{p there} are randomly varying in time output voltages of independent noise generators 1.2 ₁ -1.2 _p . If at the moment of the appearance of the pulse from the output of the first element And 3 at the C input of the i-th trigger 8.1, the output voltage of the i-th noise generator 8.2 is lower than the trigger threshold, then the output of the trigger will have a logic zero level (otherwise, a logical unit level ) A random code combination from the outputs of the triggers 1.1 ₁ -1.1 _{p is} fed to the input of the comparison unit 7.

The block selection signal 8, the functional diagram of which is shown in figure 3, operates as follows. When passing through a radio channel of information, the contents of the packet from the information input of the device goes to the information input of the electronic switch 8.2 and the input of the pulse shaper 8.1. The pulse from the output of the latter goes to the first and second control inputs of the electronic switch 8.2. As a result of the operation of the switch, the code combination located in the header of the received packet in place of the measurement signal is recorded in the shift register 8.3. This combination in parallel code from the output of the shift register 8.3 is fed to the second input B of the comparison circuit 8.4 (while the first A input of the comparison circuit 8.4 is constantly supplied with the code combination of the measurement signal). If the code combinations at inputs A and B coincide (that is, as part of the received packet, a signal was sent to conduct a measurement session of the optical path parameters), then the signal with the level of the logical unit from the output A = B of the comparison circuit 8.4 comes from the signal output of the signal isolation unit 8 to the signal input of the address analysis block 10. In this case, this signal through the OR element 8.5 also goes to the input R of the shift register 8.3 and restores it to its original state (if the combinations at the inputs of the comparison circuit do not match, the shift register translates I'm in the zero state signal output from the A # The comparator circuit 8.4).

Block analysis of address 10, the functional diagram of which is shown in figure 4, operates as follows. In the event that the unit 8 extracts a measurement signal from the packet transmitted in the radio channel, the signal with the level of a logical unit from the output of unit 8 is fed to the first and second control inputs of the electronic switch 10.1. As a result of the operation of the electronic switch 10.1, a code combination of the address of the receiver of the measurement signal is recorded in the shift register 10.2, then it is fed to the input B of the comparison circuit 10.3. If the measurement signal is addressed to this device, then the signal that initiates the process of measuring the optical path parameters from the output of the analysis unit of address 10 is fed to the input of the switching unit 11 (shift register 10.2 is initialized by supplying a signal with a logic level from the output of the OR element 10.4) .

The switching unit 11, the functional diagram of which is shown in figure 5, works as follows. Upon receipt of a signal address 10 from the analysis unit with a logic level of one at the control input of the switching unit 11, the RS trigger 11.1 opens the AND element 11.2. In this case, a pulse sequence is supplied to the input of the counter 11.3 from the pulse generator through the open element And 11.2. The intervals between pulses have the duration necessary for performing calibration and measurements performed in the parameter measuring unit 12. In accordance with OST 45.131-98 (clause 7.2.3.1), the calibration process includes four steps (without including measuring instruments in the controlled optical path) . The fifth step is measurement with inclusion in the optical path. The code combinations coming from the output of counter 11.3 to the address inputs of ROM 11.5-11.8 provide reading out at each stage the corresponding combinations of optical switch controls in the parameter measuring unit 12. The set of control combinations is shown in Table 1 (here, the unit means closing the input of the optical switch to the output with number, corresponding to the discharge number in which the unit is located).

Table 1 Measurement step Optical switch one 2 3 four one one hundred one hundred 0000 10 2 010 010 1000 10 3 001 001 0100 10 four 001 010 0010 10 5 001 010 0001 01

Decoder 11.9, configured for code combination 0001, when it appears, outputs a signal with a logic level to the signal output of switching unit 11 (this means that the calibration and measurement process is completed and the process of reading the control data packet to the radio channel begins).

The unit for measuring parameters 12, the functional diagram of which is shown in Fig.6, calibrates the measuring instruments and directly measures the required characteristics of the optical path in accordance with OST 45.131-98 (clause 7.2.3.1) in five stages.

The first stage: the optical power meter 12.4 measures the power level Rpd at the output of the optical signal source 12.1.

The second stage: the optical signal source 12.1 is connected to the input-output 3 of the optical splitter 12.8, the power level P32 is measured at the input-output 2 of the optical splitter 12.8.

Third stage: the output of the optical signal source 12.1 is connected to the input-output 1 of the optical splitter 12.8, the power level P13 is measured at the input-output 3 of the optical splitter 12.8.

The fourth stage: an optical connector (load) with a zero reflection of 12.5 is connected to the input-output 3 of the optical splitter 12.8, the power level Po at the input-output 2 of the optical splitter 12.8 is measured.

Fifth stage: to the input-output 3 of the optical splitter 12.8 connects the point PD (S) of the optical path and measures the power Ppr at the input-output 2 of the optical splitter 12.8.

At each stage, the measurement results are recorded in the corresponding memory areas of RAM 16 (that is, in the text part of the generated control data packet).

The electronic switch 8.2 (10.1), the functional diagram of which is shown in Fig.7, operates as follows. The control signal arriving at the first and second control inputs of the electronic switch puts the RS-flip-flops 8.2.1 (10.1.1) and 8.2.7 (10.1.7) into the logical unit storage mode, as a result of which the sequence of clock pulses through the open AND elements 8.2.2 (10.1.2), 8.2.8 (10.1.8) is supplied to the counting inputs of the counters 8.2.3 (10.1.3), 8.2.9 (10.1.9). Counter 8.2.3 (10.1.3) counts the number of packet header symbols preceding the symbols of the measurement signal (address), after which the signal with the level of a logical unit transfers trigger 8.2.1 (10.1.1) to the zero state (receipt of clock pulses at the counter input 8.2.3 (10.1.3) stops), and the triggers 8.2.5 (10.1.5), 8.2.11 (10.1.11) are transferred to the single state. The information output of the electronic switch receives a sequence of characters in the packet header, starting with the first of the symbols of the measurement signal (address). The counter 8.2.3 (10.1.3) itself also goes into a zero state. Counter 8.2.9 (10.1.9), having completed the counting of the number of characters preceding the symbols of the measurement signal (address), and the number of characters of the actual measurement signal (address), gives a signal with a logic level to the inputs of R triggers 8.2.7 (10.1.7 ), 8.2.5 (10.1.5), 8.2.11 (10.1.11) and puts them in the zero state. In this case, the flow of information and clock pulses to the outputs of the electronic switch is terminated.

Claims (2)

1. A control device for transmitting control data over a radio channel, comprising a random number generator, a synchronizer, a counter, a first I element, an RS trigger, a second I element, a comparison unit, a signal extraction unit, a clock pulse generator, an address analysis unit, the synchronizer output being connected with the counter input and the first input of the second AND element, the group output of the counter is connected to the counting input of the comparison unit, the random number input of which is connected to the group output of the random number generator, the output of the first element And so is dined with the input of the random number generator and the input R of the RS-trigger, the output of which is connected to the second input of the second element And, the output of which is connected to the second input of the first element And, the output of the comparison unit is connected to the input S of the RS-trigger, the information inputs of the signal extraction unit and the address analysis unit is combined and is the information input of the device, the signal output of the signal extraction unit is connected to the signal input of the address analysis unit, the output of the clock generator is connected to the clock inputs of the signal allocation unit as well as an address analysis unit, characterized in that a switching unit, a parameter measurement unit, a packet text recording counter, a packet reading counter, a multi-input OR element and random access memory are additionally introduced, the output of the address analysis unit being connected to a control input of the switching unit and an input write RAM, the signal output of the switching unit is connected to the first input of the first element And, and the first, second, third and fourth control outputs of the switching unit are connected are coupled with the first, second, third and fourth control inputs of the parameter measuring unit, respectively, the clock output of the switching unit is connected to the input of the recording counter of the text part of the packet, the output of the comparison unit is connected to the signal input of the switching unit, the input of the packet reading counter and the read-in memory input, the outputs of the counters of recording the text part of the packet and reading the packet through a multi-input element OR are connected to the address input of random access memory, information the first input of which is connected to the data output parameter measurement unit, wherein the input parameter measuring unit is the input device of the optical path, the optical path output parameter measurement block is the output path of the optical device, the output device is a random access memory data output device. 2. The device according to claim 1, characterized in that the parameter measurement unit consists of an optical signal source, a first, second third and fourth optical switch, an optical power meter, an optical load with zero reflection, an optical splitter, wherein the output of the optical signal source is connected with the information input of the first optical switch, the first output of which is connected to the first information input of the second optical switch, the second output with the first information input t optical switch, and the third output with the first input-output of the optical splitter, the second information input of the second optical switch is connected to the second input-output of the optical splitter, and the third information input is with the second information input of the third optical switch, the third information input of the third optical switch connected to the optical load with zero reflection, and the fourth information input with the first output of the fourth optical switch, the output of the third the optical switch is connected to the third input-output of the optical splitter, while the control inputs of the first, second, third and fourth optical switches are the first, second, third and fourth control inputs of the parameter measurement unit, respectively, the output of the second optical switch is connected to the input of the optical power meter, the output of which is the information output of the parameter measurement unit, the information input of the fourth optical switch is an optical input the path of the parameter measuring unit, and its second output is the output of the optical path of the parameter measuring unit.

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