JP5395762B2 - Signal transmission / reception means - Google Patents

Description

  The present invention relates to a signal transmission / reception means used in a transmission / reception system for transmitting / receiving a rectangular wave signal.

  In a transmission / reception system that transmits and receives a rectangular wave signal, it has been proposed to use a delay circuit to compensate for the transmission delay of the rectangular wave signal (see, for example, Patent Document 1).

JP-A-60-59814

  In the conventional transmission / reception system, the delay time can be variably set in order to cope with the magnitude (delay time) of transmission delay of a rectangular wave signal that changes fluidly. Specifically, it is variably set by a switching circuit connected in parallel to the delay element. For this reason, there has been a trouble that a delay element must be set by a switching element for each transmission / reception system.

  Accordingly, an object of the present invention is to provide a signal transmission / reception means used in a transmission / reception system that can compensate for a transmission delay of a rectangular wave signal without complicated settings.

The present invention transmits a first rectangular wave signal and a second rectangular wave signal from a transmission device, transmits a transmission path, and receives them by a reception device. In the transmission device and the reception device, the first rectangular wave signal In the signal transmission / reception means used in the transmission / reception system in which the rise timing of the second rectangular wave signal and the fall timing of the second rectangular wave signal are synchronized,
For the first rectangular wave signal or the second rectangular wave signal on the transmission device side from the transmission path, perform inversion between the rising edge and the falling edge,
Performing the inversion on the first rectangular wave signal or the second rectangular wave signal on the receiving device side from the transmission path,
In the transmission line, the rising timings of both the first rectangular wave signal and the second rectangular wave signal are synchronized, or the falling timings of both the first rectangular wave signal and the second rectangular wave signal are synchronized. It is characterized by.

  In the transmission / reception system, a plurality of rectangular wave signals, that is, a first rectangular wave signal and a second rectangular wave signal are transmitted from a transmitting device, transmitted through a transmission path, and received by a receiving device. In the transmission device, the rising timing of the first rectangular wave signal and the falling timing of the second rectangular wave signal are synchronized, and no transmission delay occurs. According to the signal transmission / reception means of the present invention, even in the receiving apparatus, the rising timing of the first rectangular wave signal and the falling timing of the second rectangular wave signal are synchronized so that no transmission delay occurs. Can do. As described above, the transmission delay is not directly related to the so-called absolute value of the rising timing (time) of the first rectangular wave signal and the falling timing (time) of the second rectangular wave signal. The target is the relative difference (time) between the timing (time) and the fall timing (time). That is, even if a transmission delay occurs in the second rectangular wave signal with respect to the first rectangular wave signal, the transmission delay can be eliminated by delaying the first rectangular wave signal with a delay element as in the prior art. it can. However, conventionally, a delay element has to be set according to the magnitude of the transmission delay.

  In the present invention, while the rising edge of the first rectangular wave signal and the falling edge of the second rectangular wave signal are transmitted through the transmission line, the rising timing of the first rectangular wave signal and the rising edge of the second rectangular wave signal are detected. Based on the fact that the timing falls and the transmission delay occurs, the transmission timing of the first rectangular wave signal and the second rectangular wave signal is matched (synchronized) with each other during transmission. We decided to match (synchronize) the falling timing. The rises of the first rectangular wave signal and the second rectangular wave signal are similarly delayed in any transmission path, and no transmission delay, which is a difference in timing between them, occurs. Similarly, the trailing edges of the first rectangular wave signal and the second rectangular wave signal are similarly delayed in any transmission path, and there is no transmission delay that is a difference in timing between them. Then, in order to align the timing of the rising of the first rectangular wave signal and the second rectangular wave signal, the rising and rising of the first rectangular wave signal or the second rectangular wave signal on the transmission device side from the transmission path. The reversal of the descending is performed. Further, in order to restore the original relationship so that the inverted first rectangular wave signal or the second rectangular wave signal is inverted again and returned to the original state, the first rectangular wave is received from the transmission line on the receiving device side. The inversion between the rising edge and the falling edge of the signal or the second rectangular wave signal is performed again.

Further, in the present invention, the inversion is performed on one of the first rectangular wave signal and the second rectangular wave signal on the transmission device side from the transmission path,
It is preferable that the inversion is performed again on the inverted first rectangular wave signal or the second rectangular wave signal on the receiving device side from the transmission path and on the transmitting device side from the transmission path.

  According to this, the first rectangular wave signal and the second rectangular wave signal can be aligned with each other on the transmission device side from the transmission line, and the first and second rectangular wave signals can be aligned with each other. The one rectangular wave signal or the second rectangular wave signal can be inverted again and restored.

Further, in the present invention, when the inversion is performed for both the first rectangular wave signal and the second rectangular wave signal in one of the transmitting device and the receiving device,
Performing the inversion on either the first rectangular wave signal or the second rectangular wave signal on the transmission device side from the transmission path,
It is preferable that the inversion is performed on the first rectangular wave signal or the second rectangular wave signal that is not inverted on the receiving device side from the transmission path and on the transmitting device side from the transmission path.

  This also allows the first rectangular wave signal and the second rectangular wave signal to have the same timing such as the rising of the first rectangular wave signal and the second rectangular wave signal from the transmission path, and the first inverted from the transmission path on the receiving apparatus side. The rectangular wave signal or the second rectangular wave signal can be inverted again and restored.

  In the present invention, it is preferable to use at least a bipolar IC.

  Bipolar ICs are promising because they are less prone to malfunction due to environmental disturbances such as static electricity, but transmission delays between the rising edge of the first rectangular wave signal and the falling edge of the second rectangular wave signal can be reduced to C-MOS-IC or It was easy to become larger than BI-CMOS-IC. However, according to the first aspect of the present invention, the transmission delay between the rising edge of the first rectangular wave signal and the falling edge of the second rectangular wave signal can be eliminated. Thus, it is possible to provide a transmission / reception system in which occurrence of transmission delay is suppressed.

In the present invention, the transmission device is used in a control device that controls a motor,
The receiving device is preferably used for a driving device that drives the motor based on the first rectangular wave signal and the second rectangular wave signal.

  According to this, the motor and the drive device (reception device) are integrally formed, and the control device (transmission device) is arranged away from them, and the drive device (reception device) and the control device (transmission device) are arranged. Since the transmission delay of the rectangular wave signal can be compensated no matter how the transmission path is arranged between the arbitrary paths, the first rectangular wave signal and the second rectangular wave signal in which the transmission delay is eliminated Based on this, the motor can be driven. According to the first rectangular wave signal and the second rectangular wave signal from which the transmission delay has been eliminated, torque ripple of the motor output can be suppressed, and generation of vibration and sound can be suppressed.

  In the present invention, it is preferable that the transmission / reception system is used in an electric power steering apparatus that drives the motor and generates a steering assist torque based on a steering torque generated in a steering shaft.

  According to this, it is possible to provide an electric power steering device in which torque ripple of the motor output is suppressed and generation of vibration and sound is also suppressed.

  According to these aspects of the present invention, it is possible to provide a signal transmission / reception means capable of compensating for a transmission delay of a rectangular wave signal without complicated settings.

It is a lineblock diagram of an electric power steering device carrying a transmission / reception system using a signal transmission / reception means concerning a 1st embodiment of the present invention. 1 is a connection diagram of a motor control system having a transmission / reception system in which a signal transmission / reception unit according to a first embodiment of the present invention is used. It is a timing chart of the transmission / reception system using the signal transmission / reception means which concerns on the 1st Embodiment of this invention. It is a conceptual circuit diagram of the U_H system (V_H system, W_H system) of the transmission / reception system using the signal transmission / reception means according to the first embodiment of the present invention. It is a conceptual circuit diagram of the U_L system (V_L system, W_L system) of the transmission / reception system using the signal transmission / reception means according to the first embodiment of the present invention. It is a wave form chart of the potential of a capacitor at the time of a rise of the 1st rectangular wave signal and the 2nd rectangular wave signal. It is a wave form chart of the potential of a capacitor at the time of the fall of the 1st rectangular wave signal and the 2nd rectangular wave signal. It is a connection diagram of a motor control system having a transmission / reception system in which a signal transmission / reception unit according to a second embodiment of the present invention is used. It is a timing chart of the transmission / reception system using the signal transmission / reception means which concerns on the 2nd Embodiment of this invention.

  Next, embodiments of the present invention will be described in detail with reference to the drawings as appropriate. In each figure, common portions are denoted by the same reference numerals, and redundant description is omitted.

(First embodiment)
FIG. 1 shows a configuration diagram of an electric power steering apparatus 1 equipped with a transmission / reception system 3 using a signal transmission / reception means 9 according to the first embodiment of the present invention. The electric power steering apparatus 1 includes a steering wheel (steering handle) 11, a steered wheel 10, and a connecting member that couples the steering wheel 11 and the steered wheel 10. The connecting member transmits the steering torque applied to the steering wheel 11 to the steered wheels 10 to steer the steered wheels 10. The connecting member includes a steering shaft 12, a universal joint 13, a pinion shaft 14, a speed reduction mechanism 15, a pinion gear 16, a rack gear 17, a rack shaft 18, and a tie rod 19.

  The steering shaft 12 is provided integrally with the steering wheel 11 and is connected to the pinion shaft 14 via a universal joint 13. A rack gear 17 is provided on the rack shaft 18 so as to mesh with a pinion gear 16 provided at the tip of the pinion shaft 14. By the engagement of the pinion gear 16 and the rack gear 17, the rotational motion of the pinion shaft 14, the steering shaft 12, and the steering wheel 11 is converted into a reciprocating motion in the longitudinal direction (vehicle width direction) of the rack shaft 18. The steered wheels 10 are connected to both ends of the rack shaft 18 via tie rods 19.

  The electric power steering apparatus 1 has a motor 7 (M). The motor 7 transmits the generated assist torque (assist force) to the speed reduction mechanism 15 in the forward direction or the reverse direction with respect to the steering direction of the steering wheel 11. The motor 7 causes the generated assist torque to act on the pinion shaft 14 via the speed reduction mechanism 15. Thus, the electric power steering apparatus 1 transmits the steering torque applied by the driver to the steering wheel 11 to the pinion shaft 14 and transmits the assist torque generated by the motor 7 to the pinion shaft 14. The steered wheel 10 is steered by a rack and pinion mechanism having a rack gear 17. As the motor 7, a three-phase brushless motor can be used.

  The speed reduction mechanism 15 is a torque transmission means for transmitting the assist torque generated by the motor 7 to the pinion shaft 14. For example, a worm gear mechanism can be used. The worm gear mechanism can be composed of a worm shaft connected to the motor shaft of the motor 7, a worm gear formed on the worm shaft, and a worm wheel meshing with the worm gear and connected to the pinion shaft 14.

  The electric power steering apparatus 1 includes a torque sensor 8 that detects a steering torque and transmits the steering torque (signal) to a CPU (control apparatus, transmission apparatus) 4.

  The CPU 4 functions as a control device, and transmits a control signal to the FET driver (driving device, receiving device) 5 based on the steering torque (signal) received from the torque sensor 8. If the motor 7 is a three-phase brushless motor, a first rectangular wave signal (U_H system, V_H system, W_H system) is used as a pair of control signals for each of the three phases (U phase, V phase, W phase). ) And the second rectangular wave signal (U_L system, V_L system, W_L system), a total of 6 control signals are sent from the CPU (control device, transmission device) 4 to the FET driver (drive device, reception device) 5. Are transmitted through the signal transmission / reception means 9 and the transmission path 6. From the viewpoint of this transmission, when looking at the CPU (control device, transmission device) 4 and the FET driver (drive device, reception device) 5, the CPU 4 functions as a transmission device, and the FET driver 5 functions as a reception device. The CPU 4, the FET driver 5, the signal transmission / reception means 9 that connects them, and the transmission path 6 can be considered to constitute the transmission / reception system 3.

  The FET driver 5 supplies a drive current I (U) corresponding to the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system) to the motor (M) 7. Further, the FET driver 5 supplies a driving current I (V) corresponding to the first rectangular wave signal (V_H system) and the second rectangular wave signal (V_L system) to the motor (M) 7. The FET driver 5 supplies a drive current I (W) corresponding to the first rectangular wave signal (W_H system) and the second rectangular wave signal (W_L system) to the motor (M) 7. The motor 7 is rotated by the supplied drive currents I (U), I (V), and I (W) to generate the assist torque (assist force). From the viewpoint of motor drive (motor control), when looking at the CPU (control device, transmission device) 4, FET driver (drive device, reception device) 5, and motor 7, the CPU 4 is FET drive (drive). (Device, receiving device) 5 and further functions as a control device for controlling the motor 7, and the FET driver 5 functions as a drive device for driving the motor 7 based on the control by the CPU 4, and the CPU 4, the FET driver 5 and the motor 7 It can be considered that the motor control system 2 is configured.

  FIG. 2 shows a connection diagram of the motor control system 2 having the transmission / reception system 3 in which the signal transmission / reception means 9 according to the first embodiment of the present invention is used. The motor control system 2 has a transmission / reception system 3. In the transmission / reception system 3, a first rectangular wave signal (U_H system, V_H system, W_H system) and a second rectangular wave signal (U_L system, V_L system, W_L system) are transmitted from a CPU (transmission device) 4, and the transmission source The transmission path 6 is transmitted via the I / F (interface) 21 and received by the FET driver (reception device) 5 via the reception-side I / F 23. A transmission source I / F 21 is provided on the CPU (transmission device) 4 side from the transmission path 6. A reception-side I / F 23 is provided on the FET driver (reception device) 5 side from the transmission line 6. A signal transmission / reception means 9 is composed of a transmission source I / F (interface) 21 and a reception side I / F 23.

  FIG. 3 shows, as an example, a timing chart of the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system) in the transmission / reception system 3.

  FIG. 3A shows a time change of the voltage VH1 of the first rectangular wave signal (U_H system) output from the U_H system of the CPU 4. FIG. 3B shows a time change of the voltage VL1 of the second rectangular wave signal (U_L system) output from the U_L system of the CPU 4. The rising timing of the voltage VH1 of the first rectangular wave signal (U_H system) from the L level to the H level, and the falling timing of the voltage VL1 of the second rectangular wave signal (U_L system) from the H level to the L level. Are transmitted from the CPU 4 so as to be substantially synchronized. Similarly, the falling timing of the voltage VH1 of the first rectangular wave signal (U_H system) from the H level to the L level and the rising of the voltage VL1 of the second rectangular wave signal (U_L system) from the L level to the H level. Is transmitted from the CPU 4 so as to be substantially synchronized with the timing.

As shown in FIG. 2, the transmission source I / F 21 has a bipolar IC (buffer) 22 and inverters INV1, INV2, and INV3. The bipolar IC (buffer) 22 is connected to the reference potential for each of the first rectangular wave signal (U_H system, V_H system, W_H system) and the second rectangular wave signal (U_L system, V_L system, W_L system). When the signal level is H (high) or L (low), a comparison (determination) is performed. If the signal level is H, an L level signal is output, and if the signal level is L, an H level signal is output. This makes it possible to reduce the impedance of the signal level, which is difficult to change due to environmental disturbances such as static electricity.
The inverters INV1, INV2, and INV3 are connected to the second rectangular wave signals (U_L system, V_L system, and W_L system), respectively.

  FIG. 3C shows a time change of the voltage VL2 (output voltage (U_L system) of the transmission source I / F 21) of the second rectangular wave signal (U_L system) inverted by the inverter INV1. Since inverting, VL2 in FIG. 3C falls at the rise timing of VL1 and rises at the fall timing of VL1 as compared to VL1 in FIG. 3B. On the other hand, the output voltage (U_H system) VH2 of the transmission source I / F 21 matches (synchronizes) with the output voltage (U_H system) VH1 of the CPU 4.

  Then, due to the inversion, the rising timing of the voltage VH2 (VH1) of the first rectangular wave signal (U_H system) in FIG. 3A and the voltage of the second rectangular wave signal (U_L system) in FIG. The signal is transmitted from the transmission source I / F 21 to the reception-side I / F 23 via the transmission path 6 so that the rising timing of VL2 is synchronized. Similarly, the falling timing of the voltage VH2 (VH1) of the first rectangular wave signal (U_H system) in FIG. 3A and the voltage VL2 of the second rectangular wave signal (U_L system) in FIG. The signal is transmitted from the transmission source I / F 21 to the reception side I / F 23 via the transmission path 6 so that the falling timing is synchronized.

  FIG. 3D shows a time change of the voltage VH3 (the input voltage (U_H system) of the receiving side I / F 23) of the first rectangular wave signal (U_H system) after being transmitted through the transmission path 6. Since VH3 is transmitted, VH3 in FIG. 3D rises by a delay time tdH1 from the rise timing of VH1, and delays by a delay time tdL1 from the fall timing of VH1, compared to VH1 in FIG. And then fall down. The delay time tdH1 is not equal to the delay time tdL1, and is longer. The delay time tdH1 and the delay time tdL1 will be described in detail later with reference to FIGS.

  FIG. 3E shows a time change of the voltage VL3 (the input voltage (U_L system) of the receiving side I / F 23) of the second rectangular wave signal (U_L system) after being transmitted through the transmission path 6. Since VL3 in FIG. 3C is transmitted, VL3 in FIG. 3E rises with a delay time tdH1 from the rise timing of VL2, and delays tdL1 with a delay time tdL1 from the fall timing of VL2. It's falling. The rising delay time tdH1 is equal between the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system). The falling delay time tdL1 is also equal between the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system). This is because the delay time tdH1 and the delay time tdL1 are constant in the transmission lines 6 routed in the same shape with the same length.

  Due to the coincidence of the respective delay times, the rising timing of the voltage VH3 of the first rectangular wave signal (U_H system) in FIG. 3D and the voltage VL3 of the second rectangular wave signal (U_L system) in FIG. Is received by the receiving-side I / F 23 so as to be synchronized with the rising timing of. Similarly, the falling timing of the voltage VH3 of the first rectangular wave signal (U_H system) in FIG. 3D and the falling of the voltage VL3 of the second rectangular wave signal (U_L system) in FIG. It is received by the receiving side I / F 23 so as to be synchronized with the timing.

  As illustrated in FIG. 2, the reception-side I / F 23 includes a filter 24 and inverters INV4, INV5, and INV6. The filter 24 performs filtering for the purpose of noise removal from the first rectangular wave signal (U_H system, V_H system, W_H system) and the second rectangular wave signal (U_L system, V_L system, W_L system), and is used by the FET driver 5 The voltage is boosted (recovered / amplified) to a possible potential. Specifically, the filter 24 is activated for each system of the first rectangular wave signal (U_H system, V_H system, W_H system) and the second rectangular wave signal (U_L system, V_L system, W_L system). When the signal level is H (high) or L (low), a comparison (determination) is performed with respect to the threshold value VH. Further, at the time of falling, the signal level is compared (determined) with respect to the threshold value VL between H (high) and L (low). An L level signal is output. As a result, the signal level is unlikely to fluctuate due to environmental disturbances such as static electricity, and high-accuracy transmission is possible.

  The inverters INV1, INV2, and INV3 are connected to the second rectangular wave signals (U_L system, V_L system, and W_L system), respectively.

  The inverters INV4, INV5, and INV6 are connected to the second rectangular wave signals (U_L system, V_L system, and W_L system), respectively. When the inverters INV1, INV2, and INV3 are connected to the first rectangular wave signals (U_H system, V_H system, and W_H system), the inverters INV4, INV5, and INV6 are also connected to the first rectangular wave signal (U_H system). System, V_H system, W_H system).

  FIG. 3F shows a time change of the voltage VL4 (output voltage (U_L system) of the receiving side I / F 23) of the second rectangular wave signal (U_L system) inverted by the inverter INV4. As a result of the inversion, VL4 in FIG. 3F falls at the rise timing of VL3 and rises at the fall timing of VL3 as compared to VL3 in FIG. On the other hand, the output voltage (U_H system) VH4 of the receiving side I / F 23 matches (synchronizes) with the input voltage (U_H system) VH3 of the receiving side I / F 23.

  Then, by the inversion, the rising timing of the voltage VH4 (VH3) of the first rectangular wave signal (U_H system) in FIG. 3D and the voltage VL4 of the second rectangular wave signal (U_L system) in FIG. Is transmitted from the receiving-side I / F 23 to the FET driver 5 so as to be synchronized with the falling timing of. Similarly, the falling timing of the voltage VH4 (VH3) of the first rectangular wave signal (U_H system) in FIG. 3D and the voltage VL4 of the second rectangular wave signal (U_L system) in FIG. The signal is transmitted from the reception-side I / F 23 to the FET driver 5 so that the rising timing is synchronized. These synchronization phenomena indicate that the transmission delay of the rectangular wave signal could be compensated.

  As shown in FIG. 2, the FET driver 5 supplies three systems of drive currents I (U), I (V), and I (W) to the motor (M) 7. In the FET driver 5, the drive currents I (U), I (V), and I (W) are the first rectangular wave signal (U_H system, V_H system, W_H system) of the corresponding system, and the second rectangular wave signal (U_L). The direction of the current is changed between the forward direction and the reverse direction so as to correspond to the H level and L level of the system, V_L system, and W_L system). That is, in the FET driver 5, the drive currents I (U), I (V), I (W) are the first rectangular wave signal (U_H system, V_H system, W_H system) of the corresponding system and the second rectangular wave signal. Corresponding to the rising timing and falling timing of (U_L system, V_L system, W_L system), the direction of the current is changed depending on the direction of the signal output by the forward / reverse torque sensor 8.

  Next, the reason why the rising delay time tdH1 and the falling delay time tdL1 shown in FIG. 3D are different from each other and the delay time tdH1 is larger than the delay time tdL1 will be described.

  FIG. 4 shows a conceptual circuit diagram of the U_H system (V_H system, W_H system) of the transmission / reception system 3, and FIG. 5 shows a conceptual circuit diagram of the U_L system (V_L system, W_L system) of the transmission / reception system 3. Show. The difference between the U_H system (V_H system, W_H system) and the U_L system (V_L system, W_L system) of the transmission / reception system 3 is that the inverters INV1 and INV4 are connected to the U_L system (V_L system, W_L system). Is a point. On the other hand, the bipolar IC 22 is common in that it has a PNP type Tr (transistor) and an NPN type Tr. The filter 24 is common in that it includes a capacitor C and a buffer BUF that are grounded at one end. In the bipolar IC 22, the base of the PNP type Tr and the base of the NPN type Tr are connected to each other and connected to the CPU 4. The collector of the PNP type Tr and the collector of the NPN type Tr are connected to each other and connected to the transmission line 6.

  When the first rectangular wave signal (second rectangular wave signal) falls from the H level to the L level, the PNP type Tr is turned on and the NPN type Tr is turned off. Then, the current Iout flows from the high potential Va to the transmission line 6 and the capacitor C through the PNP type Tr, and increases the potential Vb on the side of the capacitor C that is not grounded.

  FIG. 6 shows a waveform diagram of the potential Vb of the capacitor C when the first rectangular wave signal (second rectangular wave signal) rises. For this potential Vb, the filter 24 compares (determines) whether the signal level is H (high) or L (low) with respect to the threshold value VH (bipolar). If it is H, the filter 24 outputs an H level signal. If L, an L level signal is output. The threshold value VH (bipolar) is a threshold value when a bipolar IC is used for the buffer BUF of the receiving side I / F 23, and is a delay time tdH1 from ON to H (high) determination. In the waveform of the potential Vb at the time of rising, the slope becomes smaller as the potential Vb approaches the level H. This is because the PNP type Tr has a smaller driving capability than the NPN type Tr, and it is difficult for current to flow when the potential difference between the emitter and the collector becomes small. For this reason, the delay time tdH1 is increased. Note that the threshold value VH (bipolar) is set higher for toughness against environmental disturbances such as static electricity. When a C-MOS or BI-CMOS IC is used for the buffer (bipolar IC) 22 of the transmission source I / F 21, it is difficult to obtain toughness against environmental disturbances such as static electricity, so the threshold value VH (C-MOS, BI-CMOS) Is made smaller than the threshold value VH (bipolar). For this reason, the delay time tdH2 can be made smaller than the delay time tdH1.

  FIG. 7 shows a waveform diagram of the potential Vb of the capacitor C when the first rectangular wave signal (second rectangular wave signal) falls. When the first rectangular wave signal (second rectangular wave signal) rises from the L level to the H level, the PNP type Tr is turned off and the NPN type Tr is turned on. The capacitor C is grounded (connected to a low potential) via the transmission line 6 and the NPN type Tr, and the current Iin flows out of the capacitor C, and drops the potential Vb on the ungrounded side of the capacitor C.

  For this potential Vb, the filter 24 compares (determines) whether the signal level is H (high) or L (low) with respect to the threshold VL (bipolar), and if it is H, it outputs an H level signal. If L, an L level signal is output. The threshold value VL (bipolar) is a threshold value when a bipolar IC is used for the buffer (bipolar IC) 22 of the transmission source I / F 21, and is a delay time tdL1 from OFF to L (low) determination. In the waveform of the potential Vb at the time of falling, even if the potential Vb approaches the level L, the slope does not change. This is because the NPN-type Tr has a higher driving capability than the PNP-type Tr, and a current can easily flow even if the potential difference between the emitter and the collector is reduced. For this reason, the delay time tdL1 is smaller than the delay time tdH1. Note that the threshold value VL (bipolar) is set low for toughness against environmental disturbances such as static electricity. When a C-MOS or BI-CMOS IC is used for the buffer (bipolar IC) 22 of the transmission source I / F 21, it is difficult to obtain toughness against environmental disturbances such as static electricity, so the threshold value VL (C-MOS, BI-CMOS) Is made larger than the threshold value VL (bipolar). For this reason, the delay time tdL2 can be made smaller than the delay time tdL1.

(Second Embodiment)
FIG. 8 shows a connection diagram of the motor control system 2 according to the second embodiment of the present invention. The motor control system 2 of the second embodiment is different from the motor control system 2 of the first embodiment in that the CPU 4 has a system (U_H system, U_L system, V_H system, V_L system, W_H system, W_L For each system), the U_H system, the V_H system, and the W_H are replaced with the U_L system, the V_L system, and the W_L system at the point where the inverters INV7 to INV12 are connected and the transmission source I / F 21 on the CPU 4 side from the transmission path 6. This is that inverters INV13 to INV15 are connected to the system. In other words, the transmission I / F 21 on the CPU 4 side from the transmission path 6 and the reception I / F 23 on the FET driver 5 side from the transmission path 6 differ in the systems to which the inverter INV4 and the like are connected.

  FIG. 9 shows a timing chart of the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system) in the transmission / reception system 3. The timing chart of the first rectangular wave signal (V_H system, W_H system) and the second rectangular wave signal (V_L system, W_L system) is also the same for the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system). The timing chart and the rising and falling timings of the first rectangular wave signal and the second rectangular wave signal are the same.

  FIG. 9A shows the time change of the voltage VH10 of the first rectangular wave signal (U_H system) before the inverter INV7 of the CPU 4. FIG. FIG. 9B shows a time change of the voltage VL10 of the second rectangular wave signal (U_L system) before the inverter INV8 of the CPU 4. The rising timing of the voltage VH10 of the first rectangular wave signal (U_H system) from the L level to the H level, and the falling timing of the voltage VL10 of the second rectangular wave signal (U_L system) from the H level to the L level. Are synchronized. Similarly, the falling timing of the voltage VH10 of the first rectangular wave signal (U_H system) from the H level to the L level and the rising of the voltage VL10 of the second rectangular wave signal (U_L system) from the L level to the H level. The timing is synchronized.

  FIG. 9C shows a time change of the voltage VH11 of the first rectangular wave signal (U_H system) inverted by the inverter INV7 of the CPU 4. Since it is inverted, VH11 in FIG. 9C falls at the rise timing of VH10 and rises at the fall timing of VH10, compared to VH10 in FIG. 9A.

  FIG. 9D shows a time change of the voltage VL11 of the second rectangular wave signal (U_L system) inverted by the inverter INV8 of the CPU 4. Since it is inverted, VL11 in FIG. 9D falls at the rise timing of VL10 and rises at the fall timing of VL10 as compared to VL10 in FIG. 9B.

  FIG. 9E shows a time change of the voltage VH12 (the output voltage (U_H system) of the transmission source I / F 21) of the first rectangular wave signal (U_H system) inverted by the inverter INV13. Since it is inverted, VH12 in FIG. 9 (e) falls at the rise timing of VH11 and rises at the fall timing of VH11, compared to VH11 in FIG. 9 (c). On the other hand, the output voltage (U_L system) VL12 of the transmission source I / F 21 matches (synchronizes) with the output voltage (U_L system) VL10 of the CPU 4.

  Then, due to the inversion, the rising timing of the voltage VH12 of the first rectangular wave signal (U_H system) in FIG. 9E and the rising of the voltage VL12 of the second rectangular wave signal (U_L system) in FIG. Is transmitted from the transmission source I / F 21 to the reception-side I / F 23 via the transmission path 6 so as to be synchronized with each other. Similarly, the falling timing of the voltage VH12 of the first rectangular wave signal (U_H system) in FIG. 9E and the falling of the voltage VL12 of the second rectangular wave signal (U_L system) in FIG. It is transmitted from the transmission source I / F 21 to the reception side I / F 23 via the transmission path 6 so that the timing is synchronized.

  FIG. 9F shows the time change of the voltage VH13 (input voltage (U_H system) of the receiving side I / F 23) of the first rectangular wave signal (U_H system) after transmission through the transmission path 6. Since the signal has been transmitted, the voltage VH13 after transmission in FIG. 9 (f) rises with a delay time tdH1 from the rise timing of VH12 and rises and falls as compared with the voltage VH12 before transmission in FIG. 9 (e). Is delayed by a delay time tdL1 from the above timing. The delay time tdH1 is not equal to the delay time tdL1, and is longer.

  FIG. 9G shows a time change of the voltage VL13 (input voltage (U_L system) of the receiving side I / F 23) of the second rectangular wave signal (U_L system) after transmission through the transmission path 6. Since VL13 (VL11) in FIG. 9 (d) is transmitted, VL13 in FIG. 9 (g) rises with a delay time tdH1 from the rising timing of VL12 and rises with a delay time tdL1 from the falling timing of VL12. Falling down with a delay. The rising delay time tdH1 is equal between the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system). The falling delay time tdL1 is also equal between the first rectangular wave signal (U_H system) and the second rectangular wave signal (U_L system). This is because the delay time tdH1 and the delay time tdL1 are constant in the transmission lines 6 routed in the same shape with the same length.

  Due to the coincidence of the respective delay times, the rising timing of the voltage VH13 of the first rectangular wave signal (U_H system) in FIG. 9F and the voltage VL13 of the second rectangular wave signal (U_L system) in FIG. Is received by the receiving-side I / F 23 so as to be synchronized with the rising timing of. Similarly, the fall timing of the voltage VH13 of the first rectangular wave signal (U_H system) in FIG. 9F and the fall of the voltage VL13 of the second rectangular wave signal (U_L system) in FIG. It is received by the receiving side I / F 23 so as to be synchronized with the timing.

  FIG. 9 (h) shows the time change of the voltage VL14 (output voltage (U_L system) of the receiving side I / F 23) of the second rectangular wave signal (U_L system) inverted by the inverter INV4. Since it is inverted, VL14 in FIG. 9H falls at the rise timing of VL13 and rises at the fall timing of VL13 as compared with VL13 in FIG. 9G. On the other hand, the output voltage (U_H system) VH14 of the reception-side I / F 23 matches (synchronizes) with the input voltage (U_H system) VH13 of the reception-side I / F 23.

  Then, by the inversion, the rising timing of the voltage VH14 (VH13) of the first rectangular wave signal (U_H system) in FIG. 9F and the voltage VL14 of the second rectangular wave signal (U_L system) in FIG. Is transmitted from the receiving-side I / F 23 to the FET driver 5 so as to be synchronized with the falling timing of. Similarly, the falling timing of the voltage VH14 (VH13) of the first rectangular wave signal (U_H system) in FIG. 9F and the voltage VL14 of the second rectangular wave signal (U_L system) in FIG. The signal is transmitted from the reception-side I / F 23 to the FET driver 5 so that the rising timing is synchronized. These synchronization phenomena indicate that the transmission delay of the rectangular wave signal could be compensated.

  In the second embodiment, in the CPU 4, the inverters INV7 to INV12 are connected for each system (U_H system, U_L system, V_H system, V_L system, W_H system, W_L system). However, the present invention is not limited to this. In the driver 5, the inverters INV7 to INV12 may be connected to each system (U_H system, U_L system, V_H system, V_L system, W_H system, W_L system).

DESCRIPTION OF SYMBOLS 1 Electric power steering apparatus 2 Motor control system 3 Transmission / reception system 4 CPU (control apparatus, transmission apparatus)
5 FET driver (driving device, receiving device)
6 Transmission path 7 Motor 9 Signal transmission / reception means 12 Steering shaft 21 Source I / F
22 Bipolar IC (Buffer)
23 Receiver I / F
24 filter INV1 to INV18 inverter

Claims (6)

The first rectangular wave signal and the second rectangular wave signal are transmitted from the transmission device, transmitted through the transmission path, and received by the reception device. In the transmission device and the reception device, the rising timing of the first rectangular wave signal And a signal transmission / reception means used in a transmission / reception system in which the falling timing of the second rectangular wave signal is synchronized,
For the first rectangular wave signal or the second rectangular wave signal on the transmission device side from the transmission path, perform inversion between the rising edge and the falling edge,
Performing the inversion on the first rectangular wave signal or the second rectangular wave signal on the receiving device side from the transmission path,
In the transmission line, the rising timings of both the first rectangular wave signal and the second rectangular wave signal are synchronized, or the falling timings of both the first rectangular wave signal and the second rectangular wave signal are synchronized. Signal transmitting / receiving means characterized by the above. Performing the inversion on either the first rectangular wave signal or the second rectangular wave signal on the transmission device side from the transmission path,
The inversion is performed again on the inverted first rectangular wave signal or the second rectangular wave signal on the receiving device side from the transmission path and on the transmitting device side from the transmission path. The signal transmitting / receiving means according to 1. When performing the inversion for both the first rectangular wave signal and the second rectangular wave signal in one of the transmitting device and the receiving device,
Performing the inversion on either the first rectangular wave signal or the second rectangular wave signal on the transmission device side from the transmission path,
The inversion is performed on the first rectangular wave signal or the second rectangular wave signal that is not inverted on the receiving device side from the transmission path and on the transmitting device side from the transmission path. The signal transmitting / receiving means according to 1.   4. The signal transmission / reception means according to claim 1, wherein the signal transmission / reception means is configured using at least a bipolar IC. The transmission device is used in a control device that controls a motor,
The said receiving apparatus is used for the drive device which drives the said motor based on the said 1st rectangular wave signal and the said 2nd rectangular wave signal, The any one of Claim 1 thru | or 4 characterized by the above-mentioned. Signal transmission / reception means.   6. The signal transmission / reception means according to claim 5, wherein the transmission / reception system is used in an electric power steering apparatus that drives the motor and generates a steering assist torque based on a steering torque generated in a steering shaft.

Images