JP2016063303A - Communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a specific receiver to receive transmission data transmitted from a transmitter, without mounting a microcomputer on the transmitter.SOLUTION: A transmitter 10 transmits a transmission signal whose signal length is ruled so as to vary depending on a transmission address and transmission data. A receiver 20 comprising a clock generation unit 23 for generating a clock signal having a given frequency and a counter 24 for counting, on the basis of the clock signal generated by the clock generation unit 23, a signal length of a transmission signal transmitted from a transmission circuit identifies a transmission address and transmission data on the basis of a count value of the counter.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a communication system including a transmission device and a reception device.

  Conventionally, in a communication system including a transmission device and a reception device, each of the transmission device and the reception device is equipped with a microcomputer having a communication function, and data is transmitted from the transmission device to a specific reception device according to the communication software processing of each microcomputer. There is something like that (see, for example, Patent Document 1).

JP 2012-49885 A

  However, a system such as that described in Patent Document 1 is installed in a transmission device even when the amount of data transmitted from the transmission device is small, such as when an on / off signal of one switch is transmitted from the transmission device. Since the data is transmitted by the communication software processing of the microcomputer, there is a problem that the component cost is increased. Moreover, the expense for developing software is also required.

  The present invention has been made in view of the above problems, and an object of the present invention is to enable a specific receiving device to receive transmission data transmitted from a transmitting device without mounting a microcomputer on the transmitting device.

  In order to achieve the above object, an invention according to claim 1 is a communication system including a transmission device (10) and a reception device (20), wherein the transmission device has a signal length according to a transmission address and transmission data. Including a transmission circuit (11 to 16) for transmitting transmission signals defined so as to differ from each other, and the reception device includes a clock generation unit (23) that generates a clock signal having a constant frequency, and a clock generated by the clock generation unit A counter (24) for counting the signal length of the transmission signal transmitted from the transmission circuit based on the signal; and a specifying means (25 to 27) for identifying the transmission address and transmission data based on the count value of the counter. It is characterized by that.

  According to such a configuration, the transmission device transmits a transmission signal defined so that the signal length differs according to the transmission address and transmission data, and the reception device generates a clock signal having a constant frequency. (23), a counter (24) for counting the signal length of the transmission signal transmitted from the transmission circuit based on the clock signal generated by the clock generation unit, and a transmission address and transmission data based on the count value of the counter Thus, the transmission data transmitted from the transmission device can be received by the specific reception device without mounting a microcomputer in the transmission device.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is a figure which shows the structure of the communication system which concerns on one Embodiment of this invention. It is a figure for demonstrating the carrier wave signal and transmission signal which are transmitted from the transmitter. It is a figure for demonstrating the carrier wave signal and detection signal which were superimposed on the power line. It is the figure which showed the relationship between the signal length of the transmission signal sent from a transmitter, and the count value of the counter of a receiver. It is a figure for demonstrating the timing of a transmission signal and a reply signal.

  A configuration of a communication system according to an embodiment of the present invention is shown in FIG. The communication system includes a transmission device 10 and a reception device 20 that are mounted on a vehicle and perform power line communication using the power line 30 as a communication medium. The communication system in the present embodiment is configured to include # 1 to # 3 transmitters 10 and # 1 to # 3 receivers 20. The # 1 transmitting apparatus 10 communicates with the # 1 receiving apparatus 20. The # 2 transmitting apparatus 10 communicates with the # 2 receiving apparatus 20, and the # 3 transmitting apparatus 10 communicates with the # 3 receiving apparatus 20.

  First, the configuration of the transmission device 10 will be described. The transmission device 10 includes a switch group 11, a pulse generator 12, a switching unit 13, a power supply switching unit 14, an oscillator 15, a transmitter 16, a reception detection unit 17, a carrier wave monitor 18, and a retransmission control unit 19. The switch group 11, the pulse generator 12, the switching unit 13, the power supply switching unit 14, the oscillator 15, and the transmitter 16 correspond to the transmission circuit in the claims. The carrier monitor 18 corresponds to carrier signal detection means. In addition, each circuit which comprises the transmitter 10 is comprised without using a microcomputer.

  The switch group 11 includes switches 11a to 11d that are turned on or off according to a user operation. When the user operates the switch 11a, a low level signal is input from the switch 11a to the pulse generator 12. When the switch 11b is operated by the user, a low level signal is input from the switch 11b to the pulse generator 12, and when the user operates the switch 11c, the low level signal is input from the switch 11c to the pulse generator 12. When the switch 11d is operated by the user, a low level signal is input to the pulse generator 12 from the switch 11d. Note that the switches 11a to 11d in the present embodiment output low-level signals to the pulse generator 12 in accordance with instructions from the retransmission control unit 19, respectively.

  When the signals input from the switches 11a to 11d change from the high level to the low level, the pulse generator 12 generates a pulse signal having a predetermined pulse width by using the falling as a trigger. The pulse width of the pulse signal generated by the pulse generator 12 varies depending on the switches 11a to 11d. Further, the pulse width of the pulse signal generated by the pulse generator 12 varies depending on the # 1 to # 3 transmitters 10. The pulse width of this pulse signal will be described later in detail.

  The switching unit 13 switches whether to input the pulse signal generated by the pulse generator 12 to the power supply switching unit 14. When the transmittable flag is stored in a memory (not shown) by a carrier wave monitor 18 described later, the switching unit 13 inputs the pulse signal generated by the pulse generator 12 to the power supply switching unit 14 and transmits the transmittable flag. Is deleted from the memory, the switching is performed so that the pulse signal generated by the pulse generator 12 is not input to the power supply switching unit 14.

  The power supply switching unit 14 switches power supply to the oscillator 15. The circuits other than the oscillator 15 are supplied with power regardless of the switching of the power switch 14. When the pulse signal generated by the pulse generator 12 is input via the switching unit 13, the power supply switching unit 14 supplies power to the oscillator 15 for the period during which the pulse signal is input. That is, the oscillator 15 is turned on only during a period in which the pulse signal generated by the pulse generator 12 is input to the power supply switching unit 14.

  The oscillator 15 generates a carrier wave signal having a constant frequency. The oscillator 15 can be configured using a crystal oscillator or a ring oscillator. The oscillator 15 outputs a carrier wave signal having a constant frequency during a period in which the power source switching unit 14 is powered on, that is, during the same period as the pulse width T1 of the pulse signal generated by the pulse generator 12.

  The transmitter 16 superimposes the carrier wave signal output from the oscillator 15 on the power line 30. As shown in FIG. 2, the transmitter 16 in the present embodiment transmits a carrier wave signal output from the oscillator 15 as a transmission signal.

  The reception detector 17 detects the carrier wave signal superimposed on the power line 30. When detecting the carrier signal superimposed on the power line 30, the reception detector 17 outputs a pulsed detection signal as shown in FIG. That is, the reception detection unit 17 outputs a pulsed detection signal that rises at the start of reception of the transmission signal and falls at the completion of reception of the transmission signal.

  Based on the carrier signal output from the transmitter 16 and the detection signal output from the reception detector 17, the carrier monitor 18 detects whether another transmission device 10 is transmitting the carrier signal to the power line 30. To do. When it is detected that the other transmitting device 10 and the receiving device 20 are not continuously transmitting a carrier signal for a second period T2 or later, the carrier wave monitor 18 stores a transmission enable flag in a memory (not shown). When it is detected that the other transmitting apparatus 10 and receiving apparatus 20 are transmitting carrier waves, the transmittable flag is erased from the memory.

  The carrier wave monitor 18 measures a signal length of a transmission signal transmitted from the transmitter 16 and a signal length of a reply signal (ACK) transmitted from the receiving device 20 in response to the transmission signal. And a third counter that measures the time after the transmission signal is transmitted from the transmitter 16.

  The carrier wave monitor 18 measures the signal length of the transmission signal transmitted from the transmitter 16 using the first counter, and measures the signal length of the return signal (ACK) using the second counter. If the count value does not match the count value of the second counter, a retransmission flag is stored in a memory (not shown). In addition, the carrier wave monitor 18 does not receive a reply signal (ACK) even when the specified time elapses after the transmission signal is transmitted from the transmitter 16 and the count value of the third counter becomes the specified value. If the 2 counter is not counting up, a retransmission flag is stored in a memory (not shown). Also, the carrier wave monitor 18 deletes the retransmission flag from the memory when the count value of the first counter matches the count value of the second counter.

  The retransmission control unit 19 retransmits the transmission signal when the signal length of the reply signal (ACK) transmitted from the receiving device 20 in response to the transmission signal is different from the transmission signal. The retransmission control unit 19 stores the switch that was last operated among the switches 11a to 11d. When the retransmission flag is stored in the memory by the carrier wave monitor 18, the retransmission control unit 19 finally transmits the same transmission signal. The operated switch is turned on to generate a pulse signal having a predetermined pulse width from the pulse generator 12.

  Next, the configuration of the receiving device 20 will be described. The reception device 20 includes a reception detection unit 21, a power supply switching unit 22, a clock generation unit (denoted as CLK in the figure) 23, a counter 24, a decoder 25, a register 26, a data processing unit 27, a pulse generation unit 28a, and a delay circuit. 28b, a power supply switching unit 28c, an oscillator 28d, and a transmitter 28e. The decoder 25, the register 26, and the data processing unit 27 correspond to the specifying means in the claims. The pulse generator 28a, the delay circuit 28b, the power switch 28c, the oscillator 28d, and the transmitter 28e correspond to a reply signal transmitter.

  The reception detector 21 detects the carrier wave signal superimposed on the power line 30. When detecting the carrier signal superimposed on the power line 30, the reception detector 21 outputs a pulsed detection signal as shown in FIG.

  The power supply switching unit 22 switches the power supply to the clock generation unit 23 and the counter 24. The circuits other than the clock generator 23 and the counter 24 are supplied with power regardless of the switching of the power switch 22.

  When the detection signal is output from the reception detection unit 21, the power supply switching unit 22 supplies power to the clock generation unit 23 and the counter 24, and when the detection signal is not output from the reception detection unit 21, The supply of power to the counter 24 is stopped.

  When the power is supplied from the power supply switching unit 22, the clock generation unit 23 outputs a clock signal having a constant frequency to the counter 24. Further, the clock generation unit 23 stops its operation and does not output a signal when power is not supplied from the power supply switching unit 22.

  The counter 24 is configured as a four-stage binary counter that counts up at the rising edge of the clock signal generated by the clock generator 23. When the power is supplied from the power supply switching unit 22 and the clock signal generated by the clock generation unit 23 is input, the counter 24 counts up according to the rising edge of the clock signal. In addition, when power is not supplied from the power supply switching unit 22, the counter 24 does not operate.

  The counter 24 is a period from the start of reception to the end of reception of a carrier wave signal transmitted as a transmission signal from the transmission device 10, that is, a period from the rise to the fall of the detection signal output from the reception detection unit 21, Power is supplied from 22 and the number of rising edges of the clock signal is counted.

  The counter 24 has 4-bit output terminals Q0 to Q3, and the count value of the counter 24 is output from these output terminals Q0 to Q3. The output terminal Q0 is LSB and the output terminal Q3 is MSB.

  In this communication system, the receiving device 20 specifies transmission data and a transmission address of the transmission signal based on the count value of the counter 24. The output terminal Q0 of the counter 24 corresponds to D0 (LSB) of transmission data, and the output terminal Q1 of the counter 24 corresponds to D1 (MSB) of transmission data. The output terminal Q2 of the counter 24 corresponds to the transmission address AD0 (LSB), and the output terminal Q3 of the counter 24 corresponds to the transmission address AD1 (MSB).

  The decoder 25 sets the register 26 when the address value specified by the output terminal Q2 (AD0) and the output terminal Q3 (AD1) of the counter 24 becomes the assigned self address, and is output from the counter 24. The register 26 is reset when the address value becomes the assigned self address + 1. Note that different self-addresses are assigned to the receiving apparatuses 20 of # 1 to # 3. Therefore, the configuration of the decoder 25 differs depending on each receiving device 20.

  The register 26 outputs a stored state (set or reset) according to the falling edge of the detection signal output from the reception detection unit 21. In the present embodiment, a high level signal is output from the register 26 when the set state is stored, and a low level signal is output from the register 26 when the reset state is stored. It has become.

  When a high level signal indicating a set is input from the register 26, the data processing unit 27 takes in the transmission data D0 (LSB) and D1 (MSB) output from the output terminals Q0 and Q1 of the counter 24 into the internal memory. When a low level signal indicating reset is input from the register 26, the transmission data D0 (LSB) and D1 (MSB) output from the output terminals Q0 and Q1 of the counter 24 are inhibited.

  The receiving device 20 in this communication system is configured to send a reply signal (ACK) having the same signal length as the received transmission signal when a certain period T0 has elapsed after receiving the transmission signal from the transmitting device 10. The pulse generation unit 28a, the delay circuit 28b, the power supply switching unit 28c, the oscillator 28d, and the transmitter 28e are circuits for sending a reply signal (ACK).

  The pulse generation unit 28 a includes a counter and a decoder (both not shown), generates a pulse signal having the same pulse width as the detection signal output from the reception detection unit 21, and outputs a high level signal output from the register 26. When the signal is input, the generated pulse signal is output to the delay circuit 28b. The pulse generator 28a does not output a pulse signal to the delay circuit 28b when a low level signal is input from the register 26.

  When the pulse signal generated by the pulse generation unit 28a is input to the delay circuit 28b, the delay circuit 28b delays the signal for the first period T0 and outputs the delayed signal to the power supply switching unit 28c.

  The power switching unit 28c switches power supply to the oscillator 28d. When a pulse signal is input from the delay circuit 28b, the power supply switching unit 28c supplies power to the oscillator 28d only during the period in which the pulse signal is input.

  The oscillator 28d generates a carrier wave signal having a constant frequency. The oscillator 28d outputs a carrier signal having a constant frequency as a reply signal (ACK) during the period when the power is switched on to the power switching unit 28c, that is, during the same period as the pulse width of the pulse signal generated by the pulse generation unit 28a. To do.

  The transmitter 28e superimposes the carrier wave signal output from the oscillator 28d on the power line 30. The transmitter 28e in the present embodiment transmits the carrier signal output from the oscillator 28d as a return signal (ACK).

  As shown in FIG. 4, the transmission apparatus 10 in the communication system transmits a transmission signal defined so that the signal length differs according to transmission data and a transmission address. In addition, the reception detection unit 21 of the reception device 20 detects the transmission signal transmitted from the transmission device 10. The power supply switching unit 22 supplies power to the clock generation unit 23 and the counter 24 in response to the rising of the detection signal output from the reception detection unit 21. The clock generator 23 and the counter 24 each start to operate when power is supplied from the power switch 22. The counter 24 counts the period from the rising edge of the detection signal to the falling edge of the detection signal, that is, the signal length of the transmission signal, and the transmission data and the transmission address are specified based on the count value of the counter 24. .

  In this embodiment, when the switch 11a of the # 1 transmitter 10 is turned on in response to a user operation, a pulse signal having a pulse width corresponding to the switch 11a is output from the pulse generator 12, and the signal shown in FIG. A long transmission signal is transmitted from the # 1 transmission apparatus 10.

  That is, a transmission signal having a signal length corresponding to 3 clocks + α generated by the clock generation unit 23 of the reception device 20 is output from the # 1 transmission device 10. Here, α is less than one clock. This transmission signal is a decimal number and has a signal length of transmission address = 1 and transmission data = 0.

  When the switch 11b of the # 1 transmitter 10 is turned on in response to a user operation, a pulse signal having a pulse width corresponding to the switch 11b is output from the pulse generator 12, and the signal length shown in FIG. 4B is transmitted. The signal is transmitted from the # 1 transmission device 10.

  That is, a transmission signal having a signal length corresponding to 4 clocks + α generated by the clock generation unit 23 of the reception device 20 is output from the # 1 transmission device 10. This transmission signal is a decimal number and has a signal length of transmission address = 1 and transmission data = 1.

  When the switch 11c of the # 1 transmitter 10 is turned on in response to a user operation, a pulse signal having a pulse width corresponding to the switch 11c is output from the pulse generator 12, and the transmission of the signal length shown in FIG. The signal is transmitted from the # 1 transmission device 10.

  That is, a transmission signal having a signal length corresponding to 5 clocks + α generated by the clock generation unit 23 of the reception device 20 is output from the # 1 transmission device 10. This transmission signal is a decimal number and has a signal length of transmission address = 1 and transmission data = 2.

  When the switch 11d of the # 1 transmitter 10 is turned on in response to a user operation, a pulse signal having a pulse width corresponding to the switch 11d is output from the pulse generator 12, and the signal length shown in FIG. The signal is transmitted from the # 1 transmission device 10.

  That is, a transmission signal having a signal length corresponding to 6 clocks + α generated by the clock generation unit 23 of the reception device 20 is output from the # 1 transmission device 10. This transmission signal is a decimal number and has a signal length of transmission address = 1 and transmission data = 3.

  Also, for example, when the switch 11c of the # 2 transmitter 10 is turned on in response to a user operation, a pulse signal having a pulse width corresponding to the switch 11c is output from the pulse generator 12, and the signal length shown in FIG. Are transmitted from the transmitter 10 of # 2.

  That is, a transmission signal having a signal length corresponding to 9 clocks + α generated by the clock generation unit 23 of the reception device 20 is output from the # 1 transmission device 10. This transmission signal is a decimal number and has a signal length of transmission address = 2 and transmission data = 2.

  For example, when the switch 11c of the # 3 transmitter 10 is turned on in response to a user operation, a pulse signal having a pulse width corresponding to the switch 11c is output from the pulse generator 12, and the signal length shown in FIG. Are transmitted from the transmitter 10 of # 3.

  That is, a transmission signal having a signal length corresponding to 13 clocks + α generated by the clock generation unit 23 of the reception device 20 is output from the # 1 transmission device 10. This transmission signal is a decimal number and has a signal length of transmission address = 3 and transmission data = 2.

  When a transmission signal having a signal length as shown in FIG. 4A is transmitted from the transmission device 10, the counter 24 of the reception device 20 counts the period from the start of reception of the transmission signal to the end of reception, and the count value is When “0100” is reached, the count is stopped. At this time, the transmission address AD1 = 0, the transmission address AD0 = 1, the transmission data D1 = 0, and the transmission data D0 = 0.

  When a transmission signal having a signal length as shown in FIG. 4B is transmitted from the transmission device 10, the counter 24 of the reception device 20 counts the period from the start of reception of the transmission signal to the end of reception. When the value reaches “0101”, the count is stopped. That is, the transmission address AD1 = 0, the transmission address AD0 = 1, the transmission data D1 = 0, and the transmission data D0 = 1.

  When a transmission signal having a signal length as shown in FIG. 4C is transmitted from the transmission device 10, the counter 24 of the reception device 20 counts the period from the start of reception of the transmission signal to the end of reception. When the value reaches “0110”, the count is stopped. That is, the transmission address AD1 = 0, the transmission address AD0 = 1, the transmission data D1 = 1, and the transmission data D0 = 0.

  When a transmission signal having a signal length as shown in FIG. 4D is transmitted from the transmission device 10, the counter 24 of the reception device 20 counts the period from the start of reception of the transmission signal to the end of reception. When the value becomes “0111”, the count is stopped. That is, the transmission address AD1 = 0, the transmission address AD0 = 1, the transmission data D1 = 1, and the transmission data D0 = 1.

  For example, when a transmission signal having a signal length as shown in FIG. 4E is transmitted from the transmission device 10, the counter 24 of the reception device 20 counts a period from the start of reception of the transmission signal to the end of reception. When the count value reaches “1010”, the count is stopped. That is, transmission address AD1 = 1, transmission address AD0 = 0, transmission data D1 = 1, and transmission data D0 = 0.

  When a transmission signal having a signal length as shown in FIG. 4F is transmitted from the transmission device 10, the counter 24 of the reception device 20 counts the period from the start of reception of the transmission signal to the end of reception. When the value becomes “1110”, the count is stopped. That is, the transmission address AD1 = 1, the transmission address AD0 = 1, the transmission data D1 = 1, and the transmission data D0 = 0.

  As described above, the count value of the counter 24 of the reception device 20 differs depending on the signal length of the transmission signal transmitted from the transmission device 10, and the transmission addresses AD1, AD0 are based on the count value of the counter 24. And transmission data D1 and D0 are specified.

  The decoder 25 sets the register 26 when the address value specified by the output terminal Q2 (AD0) and the output terminal Q3 (AD1) of the counter 24 becomes a self address, and the address output from the counter 24. The register 26 is reset when the value becomes the assigned self address +1.

  In this embodiment, the # 1 receiving device 20 is assigned a decimal number 1 to the self address, and the # 2 receiving device 20 is assigned a decimal number 2 to the self address. The receiver 3 of # 3 is assigned a decimal number of 3 as its own address.

  Therefore, the decoder 25 of the # 1 receiving device 20 sets the register 26 when the address value output from the counter 24 becomes a decimal number 1, and resets the register 26 when the address value output from the counter 24 becomes 2. To do. At this time, the decoder 25 of the # 2 to # 3 receiving devices 20 remains reset in the register 26.

  Also, the decoder 25 of the receiver 20 of # 2 sets the register 26 when the address value output from the counter 24 becomes a decimal number 2, and resets the register 26 when the address value output from the counter 24 becomes 3. To do.

  However, the decoder 25 of the receiver 3 of # 3 sets the register 26 when the address value output from the counter 24 becomes a decimal number 3, and resets the register 26 when the address value output from the counter 24 becomes 0. To do.

  The register 26 outputs the stored state (set or reset) in response to the completion of transmission of the transmission signal, that is, in response to the fall of the detection signal output from the reception detection unit 21.

  In addition, when a high level signal indicating a set state is input from the register 26, the data processing unit 27 internally transmits transmission data D0 (LSB) and D1 (MSB) output from the output terminals Q0 and Q1 of the counter 24. Capture to memory.

  In this way, the transmission data transmitted from the # 1 transmitting apparatus 10 is taken into the data processing unit 27 of the # 1 receiving apparatus 20. Also, the transmission data transmitted from the # 2 transmitting apparatus 10 is taken into the data processing unit 27 of the # 2 receiving apparatus 20. Also, the transmission data transmitted from the # 3 transmitting apparatus 10 is taken into the data processing unit 27 of the # 3 receiving apparatus 20.

  The receivers 20 of # 1 to # 3 have different configurations of the decoders 25, and therefore, for example, the data processing unit 27 of the receiver 20 of # 1 receives transmission data transmitted from the transmitter 10 of # 1. Are not captured by the data processing unit 27 of the receiving devices 20 # 2 to # 3.

  In addition, as illustrated in FIG. 5, the reply signal transmission unit of the reception device 20 according to the present embodiment transmits a reply signal (ACK) after the first period T0 has elapsed after the reception of the transmission signal is completed. It is supposed to be.

  By the way, if another transmitting apparatus 10 starts transmitting a transmission signal before a certain receiving apparatus 20 transmits a reply signal (ACK) in response to reception of the transmission signal, this transmission signal and the reply signal ( ACK) may collide. In order to avoid such a collision, the transmission apparatus 10 of the communication system transmits a transmission signal when it is detected that the carrier signal is not superimposed in the second period T2 longer than the first period T0. It is supposed to be.

  Further, the retransmission control unit 19 of the transmission device 10 transmits a transmission signal from the transmission device 10 to the reception device 20 when a reply signal having the same signal length as the transmission signal is not received within a specified time. 11-16), the transmission signal is retransmitted.

  According to the configuration described above, the transmission device 10 transmits a transmission signal that is defined so that the signal length differs according to the transmission address and transmission data, and the reception device 20 generates a clock signal having a constant frequency. 23, a counter 24 that counts the signal length of the transmission signal transmitted from the transmission circuit based on the clock signal generated by the clock generation unit 23, and a transmission address and transmission data are identified based on the count value of the counter 24 Therefore, transmission data transmitted from the transmission device can be received by a specific reception device without mounting a microcomputer in the transmission device.

  In addition, since the receiving device 20 includes a reception signal transmitting unit (28b to 28e) that, when receiving the transmission signal transmitted from the transmitting device 10, transmits a reply signal having the same signal length as the transmission signal to the transmitting device, The transmission device 10 can recognize that the transmission signal transmitted based on this reply signal has been normally received by the reception device 20.

  In addition, when the signal length of the reply signal (ACK) is different from that of the transmission signal, the transmission device 10 includes the retransmission control unit 19 that causes the transmission circuit to retransmit the transmission signal, so that the reliability can be improved.

  The transmission apparatus 10 includes a carrier wave monitor 18 that detects whether or not a carrier wave signal is superimposed on the power line 30, and the transmission circuit detects that the carrier wave signal is not superimposed on the power line 30 by the carrier wave monitor 18. In this case, since the transmission signal is transmitted, it is possible to prevent the transmission signal from being transmitted even though another transmission signal or a reply signal is superimposed on the power line 30.

  In addition, the reception device 20 transmits a return signal having the same signal length as the transmission signal to the transmission device after the first period T0 has elapsed after the reception of the transmission signal is completed (28b to 28e). Therefore, a reply signal having the same signal length as that of the transmission signal can be transmitted to the transmission device after the first period T0 has elapsed after the reception of the transmission signal is completed.

  In addition, the transmission circuit transmits a transmission signal when the carrier wave monitor 18 detects that the carrier wave signal is not superimposed on the power line in the second period T2 longer than the first period T0. When the receiving device 20 tries to transmit a reply signal (ACK) in response to receiving the transmission signal, another transmitting device 10 transmits the transmission signal, and the reply signal (ACK) and the transmission signal collide with each other. Can be prevented.

  As shown in the above embodiment, in this communication system, the transmission device 10 is configured to transmit a transmission signal defined so that the signal length differs according to transmission data and a transmission address. Even if noise is superimposed on the carrier wave signal during transmission, the signal length of the transmission signal is not affected. Therefore, a system with high noise resistance can be constructed.

  Also, for example, in HDLC (High Level Data Link procedure), which is one of data transmission control procedures, a flag sequence for frame synchronization between transmission / reception devices and an FCS for error control are used for frames between transmission / reception devices. Although the communication time for including (Frame Check Sequence) is increased, the communication system according to the present embodiment does not require a flag sequence or FCS, so the communication time can be shortened.

  In addition, this invention is not limited to the said embodiment, Based on the meaning of this invention, it can implement with a various form.

  For example, in the above embodiment, the transmission device 10 and the reception device 20 are connected via a power line in the above embodiment, but may be configured to be connected via a communication line. In this case, the transmission signal can be configured to be transmitted as a carrier signal, and the transmission signal can be configured to be transmitted as a digital signal.

  Moreover, in the said embodiment, although the example which mounted this communication system on the vehicle was shown, it is not limited to what was mounted in the vehicle.

  In the above-described embodiment, the counter 24 of the receiving device 20 is configured by a four-stage counter, but may be configured by a counter having five or more stages. That is, the size of the counter 24 of the receiving device 20 can be appropriately changed according to the value of the transmission address and the value of the transmission data.

DESCRIPTION OF SYMBOLS 10 Transmission apparatus 11 Switch group 12 Pulse generator 13 Switching part 14 Power supply switching part 15 Oscillator 16 Transmitter 17 Reception detection part 18 Reception detection part 19 Carrier monitor 20 Retransmission control part 21 Reception detection part 22 Power supply switching part 23 Clock generation part 23 24 counter 25 decoder 26 register 27 data processing unit 28a pulse generation unit 28b delay circuit 28c power supply switching unit 28c oscillator 28e transmitter 30 power line 31 battery

Claims (7)

A communication system comprising a transmitting device (10) and a receiving device (20),
The transmitter is
A transmission circuit (11-16) for transmitting a transmission signal defined so that the signal length differs according to a transmission address and transmission data;
The receiving device is:
A clock generator (23) for generating a clock signal having a constant frequency;
A counter (24) for counting a signal length of the transmission signal transmitted from the transmission circuit based on the clock signal generated by the clock generation unit;
A communication system comprising: specifying means (25-27) for specifying the transmission address and the transmission data based on a count value of the counter.   The reception device includes a return signal transmission circuit (28b to 28e) that, when receiving the transmission signal transmitted from the transmission device, transmits a return signal having the same signal length as the transmission signal to the transmission device. The communication system according to claim 1.   3. The transmission device according to claim 2, wherein the transmission device includes a retransmission control unit (19) that causes the transmission circuit to retransmit the transmission signal when the signal length of the reply signal is different from the transmission signal. 4. Communication system. The transmitter (10) and the receiver (20) are connected via a power line,
The communication system according to claim 1, wherein the transmission circuit superimposes a carrier wave signal on the power line as the transmission signal. The transmission device includes carrier signal detection means (19) for detecting whether a carrier signal is superimposed on the power line,
5. The communication system according to claim 4, wherein the transmission circuit transmits the transmission signal when the carrier signal detection unit detects that a carrier signal is not superimposed on the power line. 6.   The reception apparatus transmits a reply signal having the same signal length as the transmission signal to the transmission apparatus after a first period (T0) has elapsed since reception of the transmission signal is completed. The communication system according to claim 4, comprising: .about.28 e).   In the second period (T2) longer than the first period (T0), the transmission circuit detects that the carrier signal is not superimposed on the power line by the carrier signal detection means. The communication system according to claim 6, wherein:

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