RU2266618C2 - Central station of system for radio communication with moving objects - Google Patents

Abstract

FIELD: radio communications, can be used for organization of digital communication in automated data exchange systems of air to surface and surface to air types.

SUBSTANCE: central station of system for radio communication with moving objects additionally includes two pulse counters, two pulse generators, delay line, while output of pulse generator is additionally connected to synchronization inputs of counters, outputs of which are connected respectively to shift inputs of shifting register, recording inputs of control block and to reading input of control block, input of third OR circuit through delay line to zero-setting inputs of pulse counters, third output of control block is connected to input of block for storing transfer signals, starting setting of blocks for setting priorities and control, counters of system load is performed by sending flush signal to appropriate inputs.

EFFECT: higher efficiency of system due to increased capacity of device, in particular, concerning transfer of information from moving objects to consumer about all received messages independently from their priority.

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Description

The invention relates to techniques for radio communications and can be used to organize digital communications in automated air-ground data exchange systems.

A known radio communication system comprising a receiver, a demodulator, a transmitter, a modulator, a data recording unit, a data output unit, two And elements, a message decoder, a buffer register of moving objects addresses, a system load counter, an object number counter, clock pulses, a key free access, buffer storage unit, time window shaper, delay line, address polling key, message priority decoder, block of priority message registers, switchboard-distributor with bscheny unit timer counter repeated number, the reset pulse generator in the onboard station - duplexer, a receiver, a demodulator, an address decoder, a modulator, a transmitter, the data recording unit, data output unit [1].

The disadvantages of this system include limited capabilities in terms of the number of serviced moving objects (software) and the lack of adaptation to changing the number of messages in the communication channel.

Closest to the claimed object is the central station of a radio communication system with moving objects, containing a series-connected receiver, demodulator and address decoder unit, as well as a transmitter, a pulse generator, n timers, a system load counter, a priority setting unit, a priority message count counter, connected in series shaper of the transmission enable signal, transmission signal storage unit, data recording unit, data output unit, n AND elements, n pulse counters, n first key her, the control unit, n first, n second pulse shapers, third, fourth pulse shapers, first, second, third, fourth OR elements, and a storage unit, where n is the number of processed messages from moving objects [2]. The disadvantages of the prototype include:

- a limitation on the number of messages processed from the software due to the presence of a threshold in the counter of the number of priority messages and the system load counter, above which less priority messages are not processed and the information is not received by the consumer, which leads to the loss of some data;

- the process of generating response (request) messages to the software is not connected in time with the process of receiving and processing messages with software;

- not used the ability to increase the speed of reading data to the consumer from the storage unit compared to the write speed of the received information from the software in the shift registers;

- after each excess in the system’s load counter of the specified threshold, the dispatcher must enable the “Reset” command to set the priority setting block, system load counter and control unit to “Zero”.

The main task to which the claimed invention is directed is to increase the efficiency of the system by increasing the throughput of the device, namely, transmitting from the mobile objects to the consumer the information of all received messages, regardless of their priority.

The specified technical result is achieved by the fact that in the central station of a radio communication system with moving objects, comprising a receiver, demodulator and a shift register located in a block of address decoders in series, as well as a data recording unit and a first storage unit located in the control unit, in series connected block storage of the transmission signal, the transmission signal generation block, the transmitter, and also a pulse generator, n timers, a system load counter, a reference unit oritet, counter of the number of priority messages, n AND elements, n pulse counters, n first keys, control unit, n first, n second pulse shapers, third, fourth pulse shapers, first, second, third, fourth OR elements, where n is the number processed messages from moving objects, and the signal output of the address decoder block is connected to the inputs of the n first keys, the outputs of which through the fourth OR element are connected to the signal input of the control unit, the outputs of the n elements of the match of the decoder block address and connected to n inputs of the priority setting unit, inputs of n pulse counters and inputs of n first delay lines, the outputs of which are connected through the corresponding timers to the first inputs of the corresponding n AND elements, the outputs of which are connected to the inputs of the corresponding n pulse counters, the outputs of which are through the corresponding second shapers pulses are connected to the inputs of the second OR element, the output of which is connected to the “Reset” input of the counter of the number of moving objects, the recording input of which is connected to the output of the first OR element, whose inputs are connected through the corresponding n first pulse former to the corresponding outputs of the matching elements of the address decoder unit, the output of the pulse generator is connected to the second inputs of n AND elements, the output of the number of moving objects counter is connected through the third OR element to the input of the system’s load counter, the output of which is connected to the control the input of the priority setting unit and the second input of the control unit, the first output of which through the third pulse shaper is connected to the second input of the third electric OR, the third input of which is connected to the output of the fourth pulse shaper, whose input is connected to the output of the transmission signal storage unit, n outputs of the priority setting unit are connected to the control inputs of the n first keys, the (n + 1) th and (n + 2) inputs -th pulse counters, fifth and sixth pulse shapers, (k + n + 1) -th delay line, and the output of the pulse generator is additionally connected to the inputs of the (n + 1) -th and (n + 2) -th pulse counters, output (n + 1) -th pulse counter through the fifth pulse former is connected to the inputs of the "Shift" shear a register located in the address decoder block and the “Records” of the control unit, the output of the (n + 2) -th pulse counter through the sixth pulse shaper is connected to the “Read” input of the control unit, the output of the third element OR through (k + n + 1 ) -th delay line is connected to the inputs “Set to zero” of the (n + 1) -th and (n + 2) -th pulse counters, the third output of the control unit is connected to the input of the transmission signal storage unit, the initial installation of priority setting and control units , the system’s load counter is supplied by the corresponding inputs of the “Reset” signal, in the control unit, the signal input is connected to the inputs of k second delay lines and k decoders of the message type, the outputs of k second delay lines are connected to the information inputs of the corresponding k second keys, the outputs of k decoders of the message through k corresponding fourth pulse generators connected simultaneously to the control inputs of k second keys and to k inputs of a message type analyzer, where k is the number of message types, in addition, the output of the first of k fourth pulse shapers h the counter of the number of priority messages is connected to the input of the element NOT, the third key and the third pulse shaper, and the subtracting input of the counter of the number of priority messages is connected through the seventh pulse shaper to the output of the first storage unit, the outputs of the remaining (k-1) second keys through the fifth element OR are connected to the information input of the second storage unit, the “Record” input of the control unit through the (k + n + 2) -th delay line is connected to the inputs of the first and second storage units, the “Read” input of the control unit through (n + 1) - the th element And is connected to the input of the second storage unit, and through the third key to the input of the first storage unit, the output of the message type analyzer through the eighth pulse shaper and the (k + n + 3) th delay line is connected to the input of the transmission signal storage unit , the output of the system’s load counter is also connected to the input of the data recording unit located in the control unit, the data recording unit and the counter of the number of priority messages are set to zero by sending a “Reset” signal, output One of the first k second keys is connected to the “Read” input of the first storage unit, the outputs of the first and second storage units are connected to the sixth OR element, the output of which is the station output.

Figure 1 shows the structural diagram of the central station of a radio communication system with moving objects, figure 2 is a structural diagram of a control unit.

The central station of a radio communication system with moving objects contains a receiver 1, a demodulator 2, and an address decoder unit 3, a priority setting unit 4, n timers 5, the first n delay lines 6, n AND elements 7, n 8 pulse counters, a 9 pulse generator, n first 10 and n second 11 pulse shapers, first 12 and second 13 element OR, counter 14 for the number of moving objects, third element OR 15, counter 16 for system loading, n first keys 17, fourth element OR 18, third pulse shaper 19, block 20 controls, re Occupancy 21, the unit 22 forming the transmission enable signal, a transmission signal storage unit 23, a fourth pulse generator 24 located in the block address decoder 3, the elements 25 overlap, the address unit 26, the shift register 27.

The control unit 20 contains k second delay lines 28, k second keys 29, fourth formers 30, a counter 31 for the number of priority messages, a third key 32, a first storage unit 33, k decoders 34 message types, (n + 1) th and (n +2) 35th and 36th pulse counters, fifth 37th and 38th sixth pulse shapers, (n + k + 1) 4th delay line 39, message type analyzer 40, element NOT 41, seventh pulse generator 42, fifth element OR 43 , the second storage unit 44, the (n + k + 2) -th delay line 45, the (n + 1) -th element And 46, the eighth pulse shaper 47, the (n + k + 3) -th delay line 48, 49 registration data, the sixth element OR 50.

The central station of a radio communication system with mobile objects operates as follows. The messages generated on the software sequentially in time arrive at the receiver 1 and are processed in the demodulator 2 and are fed to the input of the shift register 27 located in block 3 of the address decoders as a sequence of pulses. Under the influence of pulses from the output of the fifth driver 37 of the pulses supplied to the input of the “Shift”, the digital sequence moves along the shift register 27. The information recorded in the shift register 27 is fed in parallel to the corresponding inputs of n matching elements 25, to the second inputs of which are in parallel information is provided about the message types set for the central station. The pulses from the output of the fifth driver 37 pulses also go to the input of the "Record" of the control unit 20. These pulses are generated using the (n + 1) th counter 35 pulses, where n is the number of processed messages from moving objects. “Zeroing” the counters of 35 and 36 pulses is carried out by pulses from the output of the third element OR 15 supplied to the corresponding inputs and delayed in the (k + n + 1) th line 39 of the delay time t ₁ (t ₁ <t), where t is the delay time in the n first delay lines 6, k is the number of message types. The output of the 9 pulse generator is additionally connected to the inputs of the (n + 1) th and (n + 2) th pulse counters. The output of the (n + 2) -th pulse counter 36 is connected to the input of the sixth pulse shaper 38. Phasing of a group of n counters of 8 pulses is carried out by pulses from the output of the corresponding coincidence element 25 located in block 3 of the address decoders. When the incoming address matches the address stored in the address block 26 of the address block 3 of the address decoders, the corresponding element 25 matches. The signal from its output through one of the n first pulse shapers 10, the first element OR 12, is fed to the “Records” input of the counter 14 of the number of moving objects and increases the previously recorded value by one. At the same time, the signal from the output of the coincidence element 25 resets the corresponding of n counters of 8 pulses and, through one of the n first delay lines 6, starts one of the n timers 5, which is triggered and opens for the time t the corresponding one of n elements And 7, through which one n counters of 8 pulses counting pulses begin to arrive from the generator 9 pulses. If during time t the ith element 25 of the match does not work, i.e. Since the mobile object did not communicate (left the stable radio communication zone), the corresponding pulse counter 8 will fill up and the pulse generated at its output through one of the n second pulse formers 11, the second element OR 13 is fed to the subtracting input of the counter 14 of the number of moving objects. If during time t the i-th element of coincidence 25 again works, then the pulse from the output of this element of coincidence 25 resets the corresponding counter of 8 pulses and, through one of the n first delay lines 6, starts timer 5 again for the time t. If the addresses of the received messages do not match by the dispatcher in the address block 26 or pre-arranged in the address block 26, as well as when superimposing messages from several software at the output of the match elements 25, there are no signals.

At the same time, the signal from the output of the match element 25 is supplied to one of the n inputs of the priority setting unit 4, which has several operating modes and changes the polling modes of the n first keys 17 depending on the signal at the control input of the priority setting unit 4. The system load counter 16 is used to estimate the number of processed messages from the output of the third element OR 15 for a given time interval. The output of the system load counter 16 is connected to the inputs of the priority setting unit 4 and the control unit 20, respectively. Data on the number of received messages is displayed on the data recording unit 49 located in the control unit 20. The “Reset” command to the priority setting block 4, the system load counter 16, the control unit 20, the priority message number counter 31 and the data recording unit 49 is only given at the beginning of operation for setting the registers and counters of the corresponding blocks to “Zero”.

The processing of messages in the control unit 20 is as follows. The message in the form of a sequence of pulses is fed to the signal input of the control unit 20, to k second delay lines 28 and to k message type decoders 34. The type of message carries information about its purpose, for example, for aircraft: alarms, messages of automatic dependent surveillance, data exchange "pilot-dispatcher". In general, there can be k message types that are prioritized. The signals characterizing the signs of message types from the outputs of one of the k fourth pulse formers 30 are fed to the corresponding input of the message type analyzer 40, the output of which through the eighth pulse generator 47 and the (k + n + 3) -th delay line 48 are received at the block input 23 storing the transmission signals, and then, having passed the block 22 of the formation of the transmission enable signal, the transmitter 21, in the form of a radio signal, is radiated into the space for moving objects located there. For messages that do not require a response word, there are no signals at the outputs of the analyzer 40 of the message type. At this time, messages 21 may be generated for the transmitter 21, the packages of which are necessary to indicate the type (number) of the central station of a radio communication system with mobile objects, for example, squatter packages for civilian aircraft. When a message of the highest priority is received, the first of k message type decoders 34 is triggered and, through the corresponding of k pulse shapers 30, the signal is fed to the information input of the first of k second keys 29, through which information is entered into the first storage unit 33. At the control input of the first of k second of keys 29, a signal is output from the output of the first of k fourth pulse shapers. The same signal is fed to the input of the reverse counter 31 of the number of priority messages. In this case, the contents of the reverse counter 31 of the number of priority messages are increased by one. The recording of the highest priority data in the first storage unit 33 is carried out by pulses from the output of the fifth pulse shaper 37, delayed in the (k + n + 2) delay line 45.

Less urgent messages (with a priority of 2 to k) after passing sequentially in time, as they are formed for transmission from moving objects, are processed in the same way as in blocks 28 and 29 discussed above, are combined in the fifth OR 43 element and fed to the information the input of the second storage unit 44. To write information to the second storage unit 44, pulses from the output of the (k + n + 2) -th delay line 45 are used. Reading information from the first and second storage units 33 and 44 is carried out synchronously by the following bursts of pulses from the output of the sixth pulse shaper 38 through the third key 32 and the (n + 1) th element AND 46, respectively, supplied to the “Read” input of the control unit 20, with faster than data writing speed. This allows you to ensure the transfer of information to the consumer of less priority messages, in time intervals free from the transmission of priority messages from the first storage unit 33. Until the priority messages from the first storage unit 33 are transmitted, the output of the counter 31 of the number of priority messages has a high level , which allows 32 pulses to pass through the third key to read data from the first storage unit 33 and is fed to the input of the element NOT 41. In other cases, the inverse signal from The ode of element 41 allows the reading of less priority messages from the second memory unit 44 using pulses transmitted through the (n + 1) th element OR 46. Time-separated messages from memory blocks 33 and 44 after combining in the sixth element OR 50 are received information. After the transmission of each priority message from the seventh pulse shaper 42 to the subtracting input of the counter 31 of the number of priority messages, a pulse is received that returns it to its original state. This ensures that the communication channel is not overloaded due to the constant setting to “Zero” of the counter 31 of the number of priority messages after transmitting data with the highest priority from the first storage unit 33.

Blocks 1-34 in purpose and structure are the same with the prototype. They can be implemented on known serial elements and components. The introduced blocks 35-50 can be implemented on known microcircuits. The functions of blocks 3-20 and 23-50 can be performed programmatically using a computer.

The advantages of the claimed device include:

- the exclusion of restrictions on the number of messages received from the software and, consequently, the loss of information;

- the process of generating response (query) data to the corresponding messages received from the software is synchronized in time and logically combined;

- with an increase in the speed of reading data from storage units, the delivery time of the message from the software to the recipient of information decreases, and in the time interval remaining after the transmission of messages, less priority messages can be transmitted.

Sources of information

1.A / s No. 1411985 M.cl. H 04, 7/26, 1986.

2. A / s No. 2050695 M.cl. H 04 B 7/26, 1995 (prototype).

Claims (1)

The central station of a radio communication system with moving objects, comprising a receiver, demodulator and a shift register in series located in the address decoder unit, as well as a data recording unit and a first memory unit located in the control unit, connected in series with the transmission signal storage unit, an enable signal generating unit transmissions, a transmitter, as well as a pulse generator, n timers, a system load counter, a priority setting unit, a priority message counter, are located in the control unit, n AND elements, n pulse counters, n first key counters, control unit, n first, n second pulse shapers, third, fourth pulse shapers, first, second, third, fourth OR elements, where n is the number of processed messages from moving objects, and the signal output of the address decoder block is connected to the inputs of the n first keys, the outputs of which through the fourth OR element are connected to the signal input of the control unit, the outputs of the n match elements of the address decoder block are connected to the corresponding the corresponding n inputs of the priority setting block, the inputs of the corresponding n pulse counters and the inputs of the corresponding n first delay lines, the outputs of which are connected through the corresponding timers to the first inputs of the corresponding n AND elements, the outputs of which are connected to the inputs of the corresponding n pulse counters, the outputs of which are through the corresponding second formers pulses are connected to the inputs of the second OR element, the output of which is connected to the "Reset" input of the counter of the number of mobile subscribers, the recording input of which is connected connected to the output of the first OR element, the inputs of which through the corresponding n first pulse shapers are connected to the corresponding outputs of the matching elements of the address decoder blocks, the output of the pulse generator is connected to the second inputs of n AND elements, the output of the number of moving objects counter is connected through the third OR element to the input of the load counter system, the output of which is connected to the control input of the priority setting unit and the second input of the control unit, the first output of which through the third pulse shaper with it is single with the second input of the third OR element, the third input of which is connected to the output of the fourth pulse shaper, the input of which is connected to the output of the transmission signal storage unit, n outputs of the priority setting unit are connected to the corresponding control inputs of the n first keys located in the address decoder unit each of the elements matches is connected with both the shift register and the address block, characterized in that the (n + 1) th and (n + 2) th pulse counters, the fifth and sixth pulse shapers, (k + n + 1 ) lth a delay, and the output of the pulse generator is additionally connected to the inputs of the (n + 1) th and (n + 2) th pulse counters, the output of the (n + 1) th pulse counter through the fifth pulse shaper is connected to the inputs of the “Shift” shift the register located in the address decoder block and the “Records” of the control unit, the output of the (n + 2) -th counter through the sixth pulse shaper is connected to the “Read” input of the control unit, the output of the third circuit OR through (k + n + 1) - th delay line is connected to the inputs “Set to zero” of the (n + 1) th and (n + 2) th pulse counters, tr This output of the control unit is connected to the input of the transmission signal storage unit, the initial setting of priority setting and control units, the system load counter is done by applying a “Reset” signal to the corresponding inputs, in the control unit the signal input is connected to the inputs of k second delay lines and k decoders of the type messages, outputs k of the second delay lines are connected to information inputs k of the corresponding second keys, outputs k of decoders of the message type through k of the corresponding fourth pulse formers c are connected simultaneously to the control inputs of the k second keys and to the k inputs of the analyzer of the type of messages, where k is the number of types of messages, in addition, the output of the first of k fourth pulse shapers through the counter of the number of priority messages is connected to the input of the element NOT, the third key and the third shaper pulses, and the subtracting input of the counter of the number of priority messages through the seventh pulse shaper to the output of the first storage unit, the output of the first of k second keys is connected to the “Read” input of the first about the block, the outputs of the remaining (k-1) second keys through the fifth OR element are connected to the information input of the second memory block, the “Records” input of the control block is connected to the inputs of the first and second memory blocks through the (k + n + 2) -th delay line , the “Read” input of the control unit through the (n + 1) th AND element is connected to the input of the second storage unit, and through the third key to the input of the first storage unit, the output of the message type analyzer through the eighth pulse shaper and (k + n +3) th delay line connect It is connected to the input of the transmission signal storage unit, the output of the system’s load counter is also connected to the input of the data recording unit located in the control unit, the data recording unit and the counter of the number of priority messages are set to zero by applying the “Reset” signal, the outputs of the first and second memory units connected to the sixth element OR, the output of which is the output of the station.

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