RU2550518C2 - Data transmission method - Google Patents

Abstract

FIELD: physics, communications.

SUBSTANCE: invention relates to communication engineering and specifically to methods of transmitting information from physical quantity detectors using a current loop interface. A method of transmitting data using a current loop interface includes consecutively transmitting on the same transmission lines multiple analogue and digital parameters, wherein digital data are transmitted after transmitting analogue data with association to a second clock-pulse generated by a microcontroller sensor, digital data are transmitted byte-wise while breaking down the current range into 256 subranges, and transmission of control commands from the receiver, which includes a programmable microcontroller, to the sensor is carried out by changing the time of turning on power for, or measurement with testing and outputting of measurement results, or measurement with testing and turning colour display. In the method of transmitting data using a current loop interface, the current in the line ranges from 4 mA to 20 mA.

EFFECT: high noise-immunity of data transmission and powering the sensor directly from the transmission line.

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Description

The invention relates to communication technology, and in particular to methods of transmitting information from sensors of physical quantities using the current loop interface. Mostly it can be used in fire alarm systems to collect information from fire detectors. Moreover, this method can be used to obtain information from various devices that issue data in digital or analog form.

Various methods for transmitting data using the digital current loop interface are known. For example, there is a known method of transmitting data using the digital current loop interface, which was initially used in teletype devices, and then for radial connection of various devices with serial transmission of information (IRPS) (see p. 4, GOST 27696-88. Industrial robots. Interfaces Technical requirements, as well as GOST 28854-90 Serial interface of radial type for automated control systems for dispersed objects. General technical requirements). In the known method of transmitting data using a digital current loop interface that outputs data in digital form, a low current level of 0 to 3 mA is used as a logic zero value. However, this method also uses a high current level of 15 to 25 mA as a value of a logical unit. Data is transmitted using the start-stop method, the send format is the same as RS-232, for example, 8-N-1: 8 bits, without parity, 1 stop bit. In the known method, IRPS provide data transmission at a speed of up to 19.2 kbit / s over a distance of up to 500 m. This method of data transmission using the digital current loop interface has been widely used in computers, mainly produced in the USSR and CMEA countries until the 90s twentieth century. The same method of data transfer in a slightly modified form was used abroad. It is described in IEC 62056-21 (see p. 19 IEC 62056-21 International Standard. Electricity metering - Data exchange for metering reading, tariff and load control - Part 21: Direct local data exchange. An advantage of the known method of data transmission using the interface of the digital current loop is a high noise immunity, which in turn allows signals to be transmitted over long distances, up to several kilometers, but the known method has a major drawback consisting in the low data transfer rate.

This drawback of the method of transmitting data using the digital current loop interface is not inherent in the known method of transmitting data using an analog current loop (see p. 3 GOST 27696-88. Industrial robots. Interfaces. Technical requirements, as well as with. 2 GST 26.011-80 Means of measurement and automation.Signals of current and voltage, electrical, continuous input and output). This method of data transfer is the closest solution to the claimed (prototype). In the prototype method, an analog current loop is used to transmit an analog signal over a pair of wires in laboratory equipment, control systems, etc. Moreover, in the described prototype method, an offset range of 4 to 20 mA is used, that is, the smallest signal value corresponds to a current of 4 mA, and the largest - 20 mA. Thus, the entire allowable range is 16 mA. A zero value of the current in the circuit means an open circuit and makes it easy to diagnose this situation. The described method of data transmission using the analog current loop interface is used to obtain data from a variety of sensors, for example, pressure sensors, temperature sensors, etc. Also, this method is used to control recording and executive devices: recorders, shutters, etc. Its advantage is also the accuracy of data transmission, which does not depend on the length and resistance of the transmission line, since the controlled current source will automatically maintain the required current in the line. In addition, when using this method, you can "power" the sensor directly from the transmission line. But it should be noted that in this method, only one stream of information, for example, the current temperature value, can be transmitted over the communication line. This is its major drawback.

The task set by the developer of a new data transmission method was to create a method that would allow data to be transmitted with a high degree of accuracy and noise immunity, with no sensitivity to line length, and also to transmit data at high speed and over long distances.

The technical result of the proposed method was a large noise immunity of data transmission, as well as the ability to power the sensor directly from the transmission line.

The essence of the invention lies in the fact that in the method of transmitting data using the current loop interface, several analog as well as digital parameters are sequentially transmitted over the same communication lines, and the digital data is transmitted after transmitting the analog data with reference to the second clock pulse generated by the sensor microcontroller , digital data is transmitted byte-by-bit with the current range being divided into 256 sub-bands, and the transmission of control commands from the receiver, including the programmable microcontroller, to the fected by changing the time of inclusion on the power line, while according to the received control command sensor perform different actions.

However, the essence of the invention lies in the fact that in the method of transmitting data using the current loop interface, the range of current in the line is taken in the range from 4 to 20 mA.

The inventive method can be implemented, for example, in the implementation of interaction and control of a multifunctional fire sensor, as well as receiving from him the necessary information from the information collection device.

The invention is illustrated graphically, where in FIG. 1 shows a diagram of a device for implementing a data transmission method using a current loop interface between a fire detector and a receiving device.

A device for implementing the method of transmitting data using the current loop interface consists of a receiving device 1, which includes a microcontroller 2. The control input of the electronic key 3 is connected to the output of the microcontroller 2. The DC power supply 4 is connected to the fire sensor 5 via an electronic key 3 via a communication line 6. An analog-to-digital converter (ADC) 7 is connected to the input of the microcontroller 2, and a measuring resistor 8 is connected to its input. The measuring resistor 8 is connected in series to the communication line 6, which It allows to measure the current in the loop. Microcontroller 2 via data bus 9 is connected to an external control device - the central monitoring panel of the fire alarm system 10. And the fire detector 5 consists of a microcontroller 11 connected to a temperature sensor 12 and a smoke chamber 13. The input of the microcontroller 11 is connected to a secondary power source 14, and its output is with a controlled current generator 15. One of the outputs of the controller 11 is connected to the light indication device "Fire" 16.

A new method of transmitting data using the current loop interface is as follows. Using the microcontroller 2 of the receiving device 1 with a given frequency and duration through the electronic key 3, the voltage is switched from the DC power source 4 to the fire sensor 5. The voltage is switched through the communication line 6. And using the fire sensor 5, depending on the duration of the supply voltage different actions. The values of the time intervals are divided into the first, second and third. They correspond to three control commands: “measurement”, “measurement with testing and delivery of its results” and “measurement with testing and inclusion of light indication”.

The operation of the fire sensor 5 in the measurement mode is as follows. Using the receiving device 1, power is supplied to the fire detector 5 for a time equal to the first interval. This operation is performed using a microprocessor 2 by supplying a control signal of a given duration to the control input of the electronic key 3. In this case, using the electronic key 3, the voltage of the power supply 4 is switched to the communication line 6. And the direct data transfer is carried out as follows. Using the microcontroller 11 of the fire sensor 5, the supply voltage and the duration of the time interval from the communication line 6 are obtained via the secondary power supply 14. The temperature values are obtained from the temperature sensor 12. The smoke level in the smoke chamber 13 is also obtained using the microcontroller 11. Next, using the microcontroller 11, as well as a controlled current generator 15, form a response short synchronizing pulse of a given amplitude in the current loop. After that, for two short periods of time, the analog temperature values from the temperature sensor 12 and the smoke level in the smoke chamber 13 are transmitted sequentially using the microcontroller 11. The analog values of the temperature and smoke level are transmitted by direct current values in the range from 4 to 20 mA and with reference to time to the clock pulse. And receiving data is as follows. Using the microcontroller 2 of the receiving device 1 through the ADC 7 with a certain pace read the current values in the communication line 6. This is done by measuring the voltage drop across the measuring resistor 8 and enter these measurements into the RAM of the microcontroller 2. After the first time interval that corresponds to the control to the “measurement” command, using the microcontroller 2 of the receiving device 1, the power is removed from the fire sensor 5. Then, using the microcontroller 2, programmatically, they are isolated from the fixed current samples the time of arrival of the synchronizing pulse. The ADC 7 readings are recorded at the moments corresponding to the transmission of temperature and smoke level data by the fire sensor 5. These time moments are determined during each information current pulse by the end of transient processes of establishing current in the circuit. After that, using the microcontroller 2 programmatically convert these current values into the corresponding physical quantities of temperature and optical density of the medium. Then, using the microcontroller 2, these converted values are output for further processing through the data bus 9 to the central monitoring console of the fire alarm system 10.

The operation of the fire sensor 5 in test mode is as follows. Using the receiving device 1 turn on the power to the fire sensor 5 for a time equal to the second interval. This interval corresponds to the second control command - “measurement with testing and delivery of test results”, which is longer than the first interval in duration. This operation is carried out using a microcontroller 2 by supplying a control signal of a given duration to the control input of the electronic key 3. In this case, the electronic key 3 commutes the voltage of the power supply 4 to the communication line 6 in the same way as when the first control command is generated. During the first time interval using the fire sensor 5 perform the actions as described above. But if, using the microcontroller 11 of the fire sensor 5, the presence of the supply voltage is detected after the end of the first time interval, then in this case, the operation of the test mode operation is started. Further, after completion of the testing operations, a second synchronizing pulse, similar to the first, is formed using the microcontroller 11 of the fire sensor 5 and the current generator 15. At the end of this impulse, the test result is transmitted. The test result is an analogue value of the intrinsic temperature of the temperature sensor 12 in the test mode in the form of a direct current pulse in the range from 4 to 20 mA, tied to the specified synchronizing pulse. After that, digital data is transmitted, including the serial number of the fire sensor, information about the manufacturer, the type of device and the date of its release in digital form for the presentation of information. Data transmission is carried out by the method of transmitting current pulses in a loop, byte-by-by-line, by dividing the 4-20 mA current range into 256 current sub-bands (by the number of codes in a byte) and transmitting each byte for short periods of time with reference to the second clock pulse. The transmitted digital data contains a synchronization field, data and a cyclic checksum to protect against errors. Using the microcontroller 2 of the receiving device 1 through the ADC 7 read samples of the current value. This is carried out at a certain pace in the communication line 6. Moreover, they do this by measuring the voltage drop across the measuring resistor 8. Next, these digital data are stored in the RAM of the microcontroller 2. After the second time interval, the power from the fire sensor is turned off using the microcontroller 2 of the receiving device 1 5. Then, the program determines the time of arrival of the second synchronizing pulse from the recorded current samples, and also records the ADC 7 at time points corresponding to the transmission yes GOVERNMENTAL with the result of the test, and digital data with information about the manufacturer, the type of instrument and the date of issue at time points. After that, using the microcontroller 2 programmatically convert the indicated current values into the corresponding data and give them to the central monitoring console of the fire alarm system 10 for further processing. The inclusion of the light indication device "Fire" of the fire sensor is as follows. At the time of the third time interval corresponding to the third control command - “measurement with testing and turning on the light indication”, the power is switched to the fire sensor 5. This is done using microcontroller 2 of the receiving device 1. During the second time interval, data is transmitted from the fire sensor 5, as described above. But if, with the help of the fire sensor 5, the presence of the supply voltage is detected after the end of the second time interval, then in this case, the operation to enable the light indication mode is performed. This is done using the microcontroller 11 of the fire sensor 5 by applying a control voltage to the light indication device "Fire" 16. The light indication device "Fire" 16 works until the power supply is disconnected by the receiving device 1 on the fire sensor 5.

The use of the inventive method of transmitting data between the receiving device and the fire sensor using the current loop has reduced the data exchange time, including a combination of several parameters between the sensor and the receiving device. In addition, the application of the proposed method allowed us to maintain high noise immunity of the communication channel under the influence of industrial interference, to maintain high accuracy in the transmission of analog values, to save a significant amount of electricity mainly when working in measurement mode and, therefore, to improve the energy consumption of the fire alarm system in operation from backup battery, as well as increase the life of the fire sensors.

Claims (2)

1. A method of transmitting data using the current loop interface, characterized in that in the method several analogue and also digital parameters are sequentially transmitted over the same communication lines, the digital data being transmitted after transmitting the analogue data with reference to a second clock pulse generated by the microcontroller the sensor, digital data is transmitted byte-by-bit with the current range being divided into 256 sub-bands, and control commands are transmitted from the receiver, including the programmable microcontroller, to the sensor m by changing the power-on time to the line, while depending on the received control command sensor measurement is performed, or the measurement with the testing and issuing of the results, or the measurement with the testing and switching the display color. 2. The method of transmitting data using the current loop interface according to claim 1, characterized in that the range of current in the line is taken in the range from 4 to 20 mA.