RU2130642C1 - Device for information exchange - Google Patents

Abstract

FIELD: automation and computer engineering, in particular, peripheral devices for information input and output, information exchange with other remote peripheral devices of computer. SUBSTANCE: device has information exchange unit, central control unit, seven information delay gates, two AND gates and four OR gates, flip-flop, two code converters, three univibrators, alarming unit, frequency divider, three pulse generators, two control pulse detection units, transmitter and receiver. Device provides controlled information data gathering from information-providing locations through communication channels, remote data receiving by selected receivers. EFFECT: increased fidelity of information input due to possibility to control device operations by commands which enter from peripheral device which serves as information gathering center. 3 dwg

Description

 The invention relates to the field of automation and computer technology, in particular to peripheral devices, and can be used for input-output of information, exchange with a remote peripheral device of a computer.

 A device for recording information (A. S. N 1314328, G 06 F 3/02, B. I. N 20, 1987), which includes a transceiver unit, keyboard, switch, synchronization unit, control unit, indicators, unit address generation and call generation unit.

 The disadvantage of this device is the low reliability of the transmitted information, which is generated in the receiving device.

 As a prototype, you can choose a well-known device for the exchange of information (A. S. 1497619, G 06 F 13/10, N 28, 1989), comprising a transceiver unit, an information source unit, an indication unit, a synchronization unit, a central control unit, five decoders , a signaling unit, wherein the gate inputs of the first, second, third and fourth decoders are connected respectively to the first, second, third and fourth outputs of the command of the control unit, the group of outputs of the first decoder is connected to the group of sample inputs of the inform source block a group, the information output group of which is connected via the data bus to the information inputs of the first and second registers, display units and the information input-output of the transceiver unit, the information input and output of which are the corresponding input and output of the device for connecting to the information output and the computer input, the first and the second clock inputs, the strobe input of the status byte and the reset of the control unit are connected respectively to the first, second, third and fourth outputs of the synchronization unit, the reset input to It is connected to the output of the initial installation of the block of information sources, and the fifth output is to the clock input of the transceiver block, the outputs of the first and second registers are connected to the corresponding information inputs of the receiver block, the group of outputs of the second decoder is connected to the group of operational inputs of the signaling block, the first, second outputs of the third the decoder is connected respectively to the gate inputs of the first register and the display unit, the reset input of which is connected to the reset input of the second register and the sync block It is connected to the fifth output of the command of the control unit, the sixth output of the command of which is connected to the synchronizing input of the synchronization unit, and the device also contains a memory unit, an interrupt unit, an operation mode setting unit, and the address inputs of the transceiver unit, memory unit, second register, and information inputs of the first to fifth decoders via the address bus are connected to the address output of the control unit, the data input-output of which is connected via the data bus to the information output of the operating mode selection unit, inform with interrupt block inputs, memory block, the interrupt block request input group is connected to the corresponding data tracking output of the operation mode setting block, the interrupt request block of the information sources block, the transceiver block and the interrupt request block of the receiver block, clock and gate inputs and permission input interrupt units are connected respectively to the fifth output of the synchronization unit and the seventh and eighth outputs of the command of the control unit, the first and ninth outputs of the command which they are connected respectively to the read and write inputs of the memory unit, and the interrupt request input is connected to the output of the interrupt unit, the output of the fourth decoder is connected to the gate input of the operation mode setting unit, the first and second outputs of the fifth decoder are connected to the gate inputs of the transceiver unit and the second register, which controls the input of which is connected to the third output of the command of the control unit and the recording input of the transceiver unit, the sampling, reading and reset inputs of which are connected respectively to the third output of the fifth decoder fourth and fifth output command the control unit, sampling interrupt block input coupled to a third output of a third decoder, the tenth command output control unit is connected to the input of the sampling unit receivers.

 The disadvantage of this device is also the low reliability of the information generated in the receiving device. This low reliability of information transmitted remotely to the receiving device from the transmitting device is determined by the presence of interference of a different nature in the transmitting medium.

 The solved problem of the invention is to increase the reliability of information transfer by organizing the operating mode of the receiving device according to the commands received from the peripheral transmitting device, which is the center for collecting information of high value. The increased value of the transmitted information requires the transmission of increased reliability.

 The solution to this problem is achieved by the fact that in an information exchange device comprising a central control unit and a transceiver unit, the latter comprising a first memory unit, a receiver and a transmitter, an alarm unit, four additional OR elements, three pulse shapers, a comparison element, seven elements are additionally introduced pulse delays, two code converters, a receiver and a transmitter, three one-shots, a trigger, two AND elements, two control pulse isolation devices, a second memory unit and a frequency divider, the output of which is connected to the input of the alarm unit, and the installation inputs of this frequency divider are connected to the inputs of the number of checks of the reliability of the transmitted information by the device, the output of the comparison element is connected to the first pulse shaper, the output of which 2 is directly connected to the "Reset" input of the first memory block and through the second the pulse delay element is connected to the first input of the trigger, through a series-connected first one-shot and the first input of the first element OR with the second driver x, through the second element of the pulse delay with the input "Reset" of the frequency divider, and through the first input of the second element OR with the input "Reset" of the second memory block, the information outputs of the first and second memory block are connected to the corresponding inputs of the comparison element, the synchronization input of which is connected to the output of the third pulse delay element and through the fourth pulse delay element with a counting input of the frequency divider and with the first input of the first element And, the second input of which is connected to the first output of the trigger and the input of the second one-vibrator, the output of the first AND element is connected to the second input of the second OR element, and through the first input of the third OR element to the control input of the first code converter and the first input of the fourth OR element, the output of the second one-vibrator is connected to the input of the third pulse delay element, and through the fifth pulse delay element with the “Record” input of the second memory block, the second trigger output is connected to the first input of the second AND element, the second input of which is connected to the output of the receiver and the input of the third driver pulses, the output of which is connected through the first control pulse extraction device to the control input of the second code converter and directly to its information input, the outputs of the second code converter are connected to the information inputs of the second memory block, the outputs of which are also connected to the information inputs of the central control unit, the information outputs of which connected to the information inputs of the first memory unit, the control output of the Central control unit is connected to the input "Record" ne of the first memory block and through the sixth pulse delay element with the second input of the third OR element, the information inputs of the first code converter are connected to the outputs of the first memory block, the first output of the first code converter is connected to the second input of the first OR element, and the second output of the first code converter is connected through the seventh pulse delay element with a second trigger input and directly to the second input of the fourth OR element, the output of which is connected through the third one-shot to the third input of the first OR element, the output of the second element is connected to the fourth input of the first OR element and through the second control pulse extraction device with the "Record" input of the central control unit, the output of the second pulse shaper is connected to the transmitter input.

The block diagram of the proposed device is shown in FIG. 1. In the device for exchanging information, the output of the comparison element ES 1 is connected to the first pulse shaper FI ₁ 2. The output of the first pulse shaper FI ₁ 2 is directly connected to the “Reset” input of the first memory unit BP ₁ 3 and through the second pulse delay element τ ₁ 4 connected to the first input of the trigger Tr 5, through a series-connected first one-shot OB ₁ 6 and the first input of the first element OR ₁ 7 with the second pulse shaper FI ₂ 8, through the second pulse delay element τ ₂ 9 with the input "Reset" of the frequency divider 10 PM, and through vy input of second OR input ₂ 11 "Reset" of the second memory unit 12. Information PD ₂ outputs a first power supply ₁ 3 and the second power supply unit ₂ memory 12 are connected to respective inputs of the comparison element ES 1. Input synchronization ES comparison element 1 connected to the output the third pulse delay element τ ₃ 13 and through the fourth pulse delay element τ ₄ 14 with the counting input of the frequency divider DC 10 and with the first input of the first element And ₁ 15. The second input of the first element And ₁ 15 is connected to the first output of the trigger Tr 5 and the input of the second one-shot OB ₂ 1 6. The output of the first element And ₁ 15 is connected to the second input of the second element OR ₂ 11, and through the first input of the third element OR ₃ 17 with the control input of the first code converter PrK ₁ 18 and with the first input of the fourth element OR ₄ 19. The output of the second one-shot OB ₂ 16 is connected to the input of the third pulse delay element τ ₃ 13, and through the fifth pulse delay element τ ₅ 20 with the “Record” input of the second memory unit BP ₂ 12. The second trigger output Tr 5 is connected to the first input of the second element And ₂ 21, the second the input of which is connected to the output of the receiver Pr 22 and I House third pulse shaper FI ₃ 23. The output of the third pulse generator 23 is connected FI ₃ through the control pulses, the first device isolation UVIU _{Jan. 24} to the control input of the second inverter PrK code ₂ 25 and directly to its data input. The outputs of the second code converter PrK ₂ 25 are connected to the information inputs of the second memory unit BP ₂ 12. The outputs of the second memory block BP ₂ 12 are also connected to the information inputs of the central control unit BTsU 26, the information outputs of which are connected to the information inputs of the first memory unit BP ₁ 3. central control unit BCU control output 26 is connected to the input of "Recording" of the first memory block BP _{January 3} and via the sixth delay element pulses τ _{June 27} to a second input of the third OR gate 17. The _three inputs of the first Information n eobrazovatelya PrK codes ₁ 18 are connected to the outputs of the first power supply storage unit ₁ 3. A first output of the first inverter PrK codes ₁ 18 is connected to second input of first OR 7 ₁ and the second output of the first inverter PrK codes _{January 18} connected through a seventh delay element pulse τ ₇ 28 with the second input of trigger Tr 5 and directly to the second input of the fourth element OR ₄ 19, the output of which through the third one-shot OB ₃ 29 is connected to the third input of the first element OR ₁ 7. The output of the second element And ₂ 21 is connected to the fourth input of the first element OR ₁ 7 and through a second device for selecting control pulses UVU ₂ 30 with the “Record” input of the central control unit BTSU 26. The output of the second pulse shaper FI ₂ 8 is connected to the input of the transmitter PRD 31. The output of the frequency divider DC 10 is connected to the input of the signaling unit BS 32 and the installation inputs of the frequency divider DC 10 are connected to the inputs of the job number of checks of the reliability of the transmitted information by the device. All blocks except the central control unit BTSU 26 constitute the transceiver block 33.

 Comparison element 1 can be implemented, for example, in the form of a digital comparator type K561IP2 with its cascade connection to provide the required number of comparison inputs.

 An example of the implementation of the first (leading) code converter PrK 18, which converts a parallel code into a serial one, is shown in FIG. 2. In this device, the S-input of trigger Tr 34 is connected to the control input of the code converter PrK 18, and the output of trigger Tr 34 is connected to the control input of the pulse generator ГИ 35, the output of which is connected to the clock input of the memory register РП 36, with the counting input of the frequency divider DF 37. The setup input to the initial state of the frequency divider DF 37 is connected to the S-input of the trigger Tr 34, the R-input of which is connected to the output of the frequency divider DF 37 and the control output of the code converter PrK 18. Information inputs of the memory register RP 36 are connected to the inputs setting codes of the code converter PrK 18, and the information inputs of the frequency divider DC 37 are connected to the inputs of setting the number of bits of the transmitted information. The output of the memory register RP 36 is connected to the output of the code converter PrK 18, and the recording input of the memory register RP 36 is connected to the "Record" input of the code converter PrK 18.

An example implementation of the second (slave) code converter 25 is shown in FIG. 3. This device, which converts serial code into parallel, can be implemented, for example, in the following form. The control input of the code converter PrK 19 is connected to the input of the And 38 element and through the first signal delay element τ ₁ 39 with the information input of the Prohibition 40 element, the output of which is connected to the S-input of the trigger Tr 41, whose R input is connected to the output of the And element 38. The trigger output Tr 41 is connected to the control input of the pulse generator ГИ 42 and to the second input of the And 38 element, and through the second pulse delay element τ ₂ 43 with the inhibit input of the "Prohibition" element 40. The output of the pulse generator ГИ 42 is connected to the clock input of the register memory RP 44, inform the output of which is connected to the information outputs of the code converter PrK 19, and the information input of which is connected to the information input of the memory register RP 44. Moreover, the frequencies of the generators of the first and second code converters 35, 42 must be equal.

 In the initial state, the RAM of the central control unit 26 contains information that must be transferred. The ROM contains a program that ensures the operation of the device for the accumulation and storage of information in the device, which will subsequently be transferred to the central device. The central control unit 26 can be implemented, for example, on a microprocessor (for example, K580IK80), a PIC controller (for example, PIC16C5X) or a microcomputer (for example, СОР800) with the corresponding binding for their functioning.

In the initial state, trigger Tr 5 is set to a state in which the second element And ₂ 21 is open for the signal from the output of the receiver 22 to the input of the first element OR ₁ 7. The memory blocks BP ₁ 3, VP ₂ 12 are set to zero at the corresponding inputs of the installation in the initial state. Triggers 34, 41 of code converters PrK ₁ 18, PrK ₁ 25 are set to their initial state at the corresponding inputs of their installation to their initial state (not shown in the diagram), which provides braking of the generation of generators GI ₁ 35, GI ₂ 42, respectively. The first code converter PrK ₁ 18 contains a division coefficient equal to the number of bits in the packet of transmitted information. In the frequency divider DC 10 at the inputs of the installation, a division coefficient is entered, equal to the permissible number of transmission cycles of this information packet.

A device for exchanging information works as follows. In the initial state, in the RAM of the central control unit BTsU 26 of the transmitting device, the amount of information necessary for transmission is generated, and the receiving device is set to the initial state, which ensures reception of the transmitted information. When establishing a communication channel between two devices of this type, one of which is located in the information collection center, and the second in the reception center, on the device located in the information transmission center (from which information transmission begins), the operator presses the "Exchange" button of the central control unit BCU 26, and the first device is launched to transmit information to the second device. At the same time, through the output port of the central control unit BTsU 26, the information accumulated in the central control unit BTsU 26 is fed to the information inputs of the first memory unit BP ₁ 3. The signal "Record" from the central control unit BTsU 26 this information is recorded in the first memory block BP ₁ 3 and, having passed to its outputs, it goes to the inputs of the first code converter PRK ₁ 18, which prepares it for transmission over the communication channel, i.e. converts it, for example, from parallel to serial form. The "Write" signal of the first memory unit BP ₁ 3, delayed by the sixth element of the pulse delay τ ₆ 27, through the third element OR ₃ 17 is turned on by the control input to the conversion of the first code converter PrK ₁ 18. Moreover, in the memory register RP 36 of the first code converter PrK ₁ 18 the transmitted information is entered from the output of the first memory unit BP ₁ 3. The control signal from the output of the third element OR ₃ 17 turns on the trigger Tr 34 of the first code converter PrK ₁ 18 and starts the pulse generator ГИ 35, the output pulses of which are clocked for the memory register RP 36 and at its output, bits of transmitted information appear sequentially. Clock pulses are counted by the frequency divider DCH 37 and if the code stored in it coincides with the code set on the installation inputs (equal to the number of bits of transmitted information), the frequency divider DCH 37 is activated and sets the trigger Tr 34 to its original state, turning off the pulse generator GI 35. In this case, the information recorded in the memory register RP 34 of the first converter of PrK ₁ 18 codes will appear bitwise at its output, and the control pulse that starts the first converter of PrK ₁ 18 codes for conversion will enter through the fourth element OR ₄ 9 to the input of the third one-shot OB ₃ 29, which forms the pulse of the beginning of the transmitted information packet. This pulse differs in parameters from information pulses, the transmission of which will follow. At the end of the transmission of information, the pulse from the output of the frequency divider Дч 37, passing through the fourth element OR ₄ 19, also goes to the third one-shot OB ₃ 29. At the same time, an end pulse of the transmitted information packet is formed, which differs from the transmitted information signals. Information from the output of the first converter of codes PrK ₁ 18 together with the pulses of the beginning and end of the transmitted burst through the first element OR ₁ 7 and the second pulse shaper FI ₁ 8 is fed to the input of the transmitter PRD 31. Further, the transmitted information from the transmitting part of one transceiver block, passing through the channel communication, enters the receiving part of another transceiver unit, the structure of which coincides.

At the same time, the output control pulse of the first pulse converter PrK ₁ 18 enters through the seventh pulse delay element τ ₇ 28 and cocks the trigger Tr 5. In this case, the second element B ₂ 21 is closed in the transmitting device for the passage of pulses and the first element And ₁ 15 is opened for the passage of pulses. The element delay time τ ₇ 28 should be slightly less than the signal transit time between the transmitting and receiving parts of the transceiver blocks for exchanging information.

The information received at the receiver PR 22 of the receiving part passes through the third pulse shaper FI ₃ 23 to the information input of the second code converter PrK ₂ 25, to the clocking input of which 24 pulses of the beginning and end of the transmitted information packet allocated on the first control pulse allocation device UVI ₁ are received . In this case, information pulses from the transmitted information packet are recorded in the memory register RP 44 of the second code converter PrK ₂ 25 by its information input under the influence of clock pulses from its pulse generator GI 41.

The transmitted information is recorded in the memory register RP 44 of the second code converter PrK ₂ 25 and appears on the information outputs of the second code converter PrK ₂ 25.

In parallel, the information arriving at the input of the receiving device also comes through the second element And ₂ 21, which is open in the initial state, and to the fourth input of the first element OR ₁ 7 of the receiving device and then to its transmitter PR 31. Information is received through the second communication channel between the devices from the receiving side to the receiver PR 22 of the transmitting part and passes through the third pulse shaper FI ₃ 23 to the information input of the second code converter PrK ₂ 25, to the clock input of which the highlighted at the first device for the allocation of control pulses UVIU ₁ 24 pulses of the beginning and end of the transmitted information packet. At the same time, information pulses from the transmitted information packet are recorded in the memory register RP 44 of the second code converter PrK ₂ 25 by its information input under the influence of clock pulses from the pulse generator GI 42.

When the trigger Tr 5 is triggered in the transmitting part, the leading edge of the pulse from its output, highlighted by the second one-shot OB ₂ 16 and delayed by the fifth pulse delay element τ ₅ 20, goes to the “Record” input of the second memory unit BP ₂ 12. In this case, to the second block BP ₂ 12 memory records information previously converted in the second code converter PrK ₂ 25. After a time determined by the second pulse delay element τ ₂ 13, the pulse from the output of the second one-shot OB ₂ 16 is fed to the input of the Synchro of the ES 1 comparison element. codes at its inputs, which coincide with the codes accumulated in the first and second memory blocks of the power supply units _1,2 3, 12, at the output of the comparison element 1, a coincidence pulse is generated, which is fed through the first pulse shaper FI ₁ 2 to the “Reset” input of the first memory block BP ₁ 3, to the input of the first one-shot OB ₁ 6, and also through the second element OR ₂ 11 to the input "Reset" of the second memory block BP ₂ 12. With this pulse, the information recorded in the second memory block BP ₂ 12 is erased. The same pulse from the output of the first pulse shaper FI ₁ 2 sets the trigger Tr 5 through the time specified by the first delay element τ ₁ 4, closing the first element And ₁ 15 and including the second element And ₂ 21, and after the time specified by the second element delay pulses τ ₂ 9, the frequency divider Дч 10 is also set in the initial state, in which pulses from the Synchro input of the ES 1 comparison element delayed by the fourth pulse delay element τ ₄ 14 are accumulated before that.

The pulse from the output of the first pulse shaper FI ₁ 2, arriving at the first one-shot OB ₁ 6, generates a signal that through the first element OR ₁ 7, the second pulse shaper FI ₂ 8 and the transmitter PRD 31 is transmitted to the output of the transmitting device and transmitted through the communication channel with transmitting part to the input of the receiving. The first one-shot OB ₁ 6 generates a pulse confirming the coincidence of the transmitted and received information, and the characteristics of this pulse differ in parameters from information pulses. For example, this impulse may differ from the information in duration or amplitude, which allows it to be detected by the second UVI ₂ 30 control pulse isolation device in the receiving part. This pulse arriving through the receiver PR 22 of the receiving part and passing through the open second element And ₂ 21 of the receiving part, is fed to the input of the second control pulse allocation device UVIU ₂ 30, where it is detected and confirms the correctness of the information received in the receiving part. In this case, the second device for allocating control pulses of the UVIU ₂ 30 generates a pulse for recording the received information from the second memory unit BP ₂ 5 into the main storage device of the central control unit BCU 1 of the receiving part of the information transmission.

If during the exchange of information a failure occurred during the transmission of information, then the comparison element ES 1 of the transmitting part does not form a pulse of coincidence. In this case, the trigger Tr 5 does not turn on. In this regard, the signal from the output of the fourth pulse delay element τ ₄ 14 passes through the first element And ₁ 15 and the second element OR ₂ 11 and resets the second memory unit BP ₂ 12 to its original state. In this case, the pulse from the output of the third pulse delay element τ ₃ 13 enters through the fourth pulse delay element τ ₄ 14 to the counting input of the frequency divider DC 10. The same pulse passes through the open first element And ₁ 15 and from its output through the third element OR ₃ 17 the cycle starts the entire device for exchanging information a second time, repeating the algorithm described above. When this algorithm is worked out more than a specified number of times, which is set in the initial state by the installation inputs of the frequency divider Дч 10 from the inputs of the task of the number of checks of the reliability of the transmitted information of the device, an alarm signal is generated at the output of the frequency divider Дч 10, which leads to information loss signaling unit BS 32. The signal at the output of the signaling unit BS 32 is the basis for the analysis of the device as a whole for the reliability of its operation.

 Thus, using these devices, a centralized remote data collection from the places of information generation, data transmission and remote data reception to selected receivers are provided, and the information received at the receivers coincides with the information located on the transmitting side.

Claims (1)

A device for exchanging information comprising a central control unit and a transceiver unit, the latter comprising a first memory unit, a receiver, a transmitter and an alarm unit, characterized in that four OR elements, three pulse shapers, a comparison element, seven pulse delay elements are introduced into the transceiver unit , two code converters, a receiver and a transmitter, three one-shots, a trigger, two AND elements, two control pulse isolation devices, a second memory unit and a frequency divider, the output of which is connected is connected to the input of the alarm unit, and the installation inputs are with the inputs for setting the number of checks of the reliability of the transmitted information by the device, the output of the comparison element is connected to the first pulse shaper, the output of which is directly connected to the "Reset" input of the first memory block and is connected to the first through the fourth pulse delay element trigger input, through the first one-shot connected to the first input of the first OR element associated with the second pulse shaper, the output of the first shaper through the second element The pulse generator is connected to the “Reset” input of the frequency divider and to the first input of the second OR element, connected to the “Reset” input of the second unit
memory, information outputs of the first and second memory blocks are connected to the corresponding inputs of the comparison element, the synchronization input of which is connected to the output of the third pulse delay element and through the fourth pulse delay element with the counting input of the frequency divider and with the first input of the first element And, the second input of which is connected to the first trigger output and the input of the second one-shot, the output of the first AND element is connected to the second input of the second OR element and to the first input of the third OR element connected to the input control of the first code converter and with the first input of the fourth OR element, the output of the second one-shot is connected to the input of the third pulse delay element, and through the fifth pulse delay element with the "Record" input of the second memory unit, the second trigger output is connected to the first input of the second And element, the second the input of which is connected to the output of the receiver and the input of the third pulse shaper, the output of which is connected through the first device for selecting control pulses with the control input of the second code converter in and directly with its information input, the outputs of the second code converter are connected to the information inputs of the second memory unit, the outputs of which are connected to the information inputs of the central control unit, the information outputs of which are connected to the information inputs of the first memory unit, the control output of the central control unit is connected to the input Record of the first memory block and through the sixth pulse delay element with the second input of the third OR element, the information inputs of the first converter codes are connected to the outputs of the first memory block, the first output of the first code converter is connected to the second input of the first OR element, and the second output of the first code converter is connected through the seventh pulse delay element to the second input of the trigger and directly to the second input of the fourth OR element, the output of which is through the third a single vibrator is connected to the third input of the first OR element, the output of the second AND element is connected to the fourth input of the first OR element and through the second control pulse output device to the input m "Record" central control unit, the output of the second pulse shaper is connected to the input of the transmitter.

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