JPH09181655A - Data transmitter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate circuit integration in a digital circuit with simplified circuit configuration and proper data and power transmission so as to reduce power consumption at a slave section. SOLUTION: A changeover circuit 32 is switched to a position of a continuous OSC with a '0' level of a signal RSm and the wave OSC is fed to a slave section 40 via a coil drive circuit 33 and coils 34, 41. The wave OSC sent to the slave section 40 is rectified by a rectifier circuit 42 and a power supply voltage VDDS is fed to each circuit in the slave section 40. Then the signal RS is set to '1' and the circuit 32 is thrown to the position of transmission data SDm . The data SDm are fed to the coil 34 via the circuit 33 and a coil pulse current flows to the coil 41. A power detection circuit 43 detects it and a signal detection circuit 44 is operated by the result of detection to detect the coil current flowing to the coil 41 and reception data RDs are demodulated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to transmission and reception of data in a non-contact state between, for example, a master unit equipped with a power supply and a microcomputer and a slave unit equipped with a microcomputer without a power supply. The present invention relates to a data transmission device for performing.

[0002]

2. Description of the Related Art FIG. 2 is a block diagram showing an example of the configuration of a conventional data transmission device. This data transmission device includes a master unit 10 equipped with a microcomputer having a central processing unit (hereinafter referred to as “CPU”) and a slave unit 20 equipped with a microcomputer having a CPU. It is a device that transmits and receives data and power between the slave unit 10 and the slave unit 20. The master unit 10 has a power supply from a battery 11, and the modulation circuit 12, the drive circuit 13, the coil 14, and the amplitude detection circuit 15 which are program-controlled by a CPU (not shown) by this power supply voltage VDD operate. There is. The modulation circuit 12 receives a clock signal CK, a transmission control signal RS _m , and transmission data SD _m from the CPU side (not shown),
Based on the clock signal CK and the transmission control signal RS _m ,
This is a circuit that performs modulation suitable for power transmission on the transmission data SD _{m and} outputs the modulation output signal S12 to the drive circuit 13. As a modulation method suitable for power transmission, for example, frequency shift keying (Frequency Shift Keyin)
g, FSK) modulation method, pulse width modulation method, phase modulation method and the like. The amplitude detection circuit 15 is a circuit that detects the amplitude of the transmission data SD _s sent from the slave unit 20 side through the coil 14 and outputs the reception data RD _m to give to the CPU side.

The slave unit 20 is a circuit which does not have a battery and which receives power from the master unit 10 to operate.
The coil 21, the rectifier circuit 22, the demodulation circuit 23, and the drive circuit 24 are included. The coil 14 on the side of the master unit 10 and the coil 21 on the side of the slave unit 20 are adapted to transmit data and electric power by electromagnetic coupling. The rectifier circuit 22 is a circuit that rectifies a signal sent from the master unit 10 through the coil 21 to generate the power supply voltage VDD. The demodulation circuit 23 is connected to the coil 2 from the master unit 10.
The data sent through 1 is demodulated and the received data R
This is a circuit that outputs D _s and supplies it to the CPU side (not shown). The drive circuit 24 turns on and off the switching transistor according to the polarity of the transmission data SD _s given from the CPU side, thereby changing the resistance load on the coil 21 and utilizing this load fluctuation to perform the transmission. It is a circuit that amplitude-modulates the data SD _s and sends the modulated signal (load fluctuation) to the amplitude detection circuit 15 via the coil 14. The amplitude modulation method by such load fluctuation is
Since it consumes less power and has a simple circuit configuration, it is suitable for portable electronic devices.

FIG. 3 is an operation waveform diagram of FIG. 2. The operation of FIG. 2 will be described with reference to this figure. When transmitting data and power source power from the master unit 10 to the slave unit 20,
Transmission data SD _m is given to the modulation circuit 12 from the CPU side in the master unit 10. The modulation circuit 12 modulates the transmission data SD _m and the power supply power in a superimposed manner by a modulation method suitable for power transmission (for example, FSK modulation method), and the modulation output signal S12 is driven by the drive circuit 13. . The output signal of the drive circuit 13 is output to the coils 14 and 21.
Is transmitted to the slave unit 20 by electromagnetic coupling of. In the slave unit 20, the reception signal of the coil 21 is rectified by the rectifier circuit 22, and the power supply voltage VDD is output to the slave unit 2
The inside of 0 operates. The received signal of the coil 21 is the demodulation circuit 2
The received data RD _s is demodulated at 3 and is output to the CPU side. When data is transmitted from the slave unit 20 to the master unit 10, the transmission data SD _s given from the CPU side in the slave unit 20 is amplitude-modulated by the drive circuit 24 by load fluctuation, and the modulated signal is It is transmitted to the master unit 10 via the coils 21 and 14.
In the master unit 10, the reception signal of the coil 14 is detected by the amplitude detection circuit 15, the reception data RD _m is output, and CP
It is sent to the U side.

[0005]

However, the conventional data transmission device has the following problems and it is difficult to solve them. In the data transmission device of FIG. 2, when data is transmitted from the slave unit 20 to the master unit 10, due to the simple circuit configuration and low power consumption, the driving circuit 24 causes a load variation with respect to the transmission data SD _s . Amplitude modulation is performed and it is transmitted to the master unit 10. In the master unit 10, the load detection is detected (demodulated) by the amplitude detection circuit 15 to obtain the reception data RD _m . When detecting (demodulating) such a load change, it is necessary to detect a slight level change. That is, with a large load change, the probability that an error will occur in the transmission from the master unit 10 to the slave unit 20 increases, and the change in the rectified power supply voltage VDD in the slave unit 20 also increases. Load fluctuation detection (demodulation) must be performed. However, if the level change from the slave unit 20 to the master unit 10 is small, not only the probability of error due to noise or the like increases but also a highly accurate analog circuit is required to detect the small level change.
Further, by using such an analog circuit, integration becomes difficult and power consumption increases. The present invention solves the problems of the prior art, has a simple circuit configuration, can accurately transmit data and power, consumes less power on the slave side, and can be integrated in a digital circuit. An easy data transmission device is provided.

[0006]

In order to solve the above-mentioned problems, a first invention is a master unit having a first coil for transmission / reception, and a first unit for transmission / reception electromagnetically coupled to the first coil. A slave unit having two coils,
And a data transmission device for performing data transmission between the master unit and the slave unit in a non-contact state via the second coil, wherein the master unit and the slave unit are configured as follows. The master unit includes a power supply that supplies power, and a switching unit that switches and outputs one of the first transmission data and a pulsed continuous wave having a shorter cycle than the first transmission data by a control signal. A first drive unit that generates a first drive signal from the output signal of the switching unit, and outputs the first drive signal when the output side is turned on or opened by the selection signal And transmitting the first drive signal to the second coil,
The first drive signal is received from the second coil in the form of a pulsed second coil current.
Of the coil and the output side of the first driving means are in an open state, the positive pulse and the negative pulse of the second coil current received by the first coil are detected, and a logic corresponding to the detection result is detected. A first signal detecting means for outputting the second received data of the level.

The slave unit receives the first drive signal sent from the first coil in the form of a pulsed first coil current, and receives the second drive signal from the first coil current. The second coil for transmitting to another coil, and the second coil
Power receiving means for rectifying the first coil current received by the coil and outputting power source power for driving the slave unit, and counting the pulse cycle of the first coil current received by the second coil. Based on the count value, the power reception detection unit that detects the continuous wave or the first transmission data from the master unit, and the power reception detection unit detects the first transmission data, based on the detection result, The second
Second signal detecting means for detecting the positive pulse and the negative pulse of the first coil current received by the coil and outputting the first received data of the logical level according to the detection result, and the second transmission The second drive signal is generated from the data, and the output side is turned on or opened at a timing according to the detection result of the power reception detection means or the output data of the second signal detection means, And a second drive means for outputting the second drive signal to the second coil.

A second aspect of the invention comprises a master section having a first transmitting / receiving means for transmission and a slave section having a second transmitting / receiving means for transmission / reception, via the first and second transmitting means. It is a data transmission device that performs data transmission between the master unit and the slave unit in a non-contact state, and the master unit and the slave unit are configured as follows.
The master unit includes a power supply that supplies power, and a switching unit that switches and outputs one of the first transmission data and a pulsed continuous wave having a shorter cycle than the first transmission data by a control signal. When the switching means outputs the continuous wave, a pulsed drive signal is generated and output from the continuous wave, and when the switching means outputs the first transmission data, the first transmission data is output. A pulsed drive signal is generated from the first transmission data according to the activation level of the first selection pulse synchronized with the first transmission data, and is output;
And, when the first selection pulse is at the deactivation level, the first driving means whose output side is in an open state, and the pulsed signal output from the first driving means is transmitted to the second transmission means. And the first transmission means for receiving a pulsed signal sent from the second transmission means,
While the output side of the first drive means is in the open state,
A first signal detecting means for detecting a positive pulse and a negative pulse of the pulsed signal received by the first transmitting means, and outputting second received data of a logical level according to the detection result. ing.

The slave unit outputs the second selection pulse according to the activation level of the second selection pulse synchronized with the second transmission data.
From the transmission data, and outputs the pulse-shaped drive signal, and when the second selection pulse is at the deactivation level, the output side is in the open state, and the first transmission means. The second transmission means for receiving the pulsed signal transmitted and transmitting the pulsed signal output from the second drive means to the first transmission means; and the second transmission A power receiving unit that rectifies the signal received by the unit and outputs power source power for driving the slave unit; and a pulse period of the pulsed signal received by the second transmitting unit, and counts the pulse period based on the count value. When the power reception detection unit that detects the continuous wave or the first transmission data from the master unit and the power reception detection unit detects the first transmission data, based on the detection result, the second transmission unit Received pal Of the positive pulse and the logic level corresponding on the detected wave results by detecting the negative pulse shaped for signal first
Second signal detecting means for outputting the reception data of. Then, the second selection signal is set to an activation level or a deactivation level at a timing according to the detection result of the power reception detection means or the output data of the signal detection means. A third aspect of the present invention is the data transmission device according to the second aspect, wherein the pulse width during data transmission from the master unit to the slave unit is larger than the pulse width during data transmission from the slave unit to the master unit. It is configured to A fourth invention is the data transmission device according to the second or third invention, wherein the first and second transmission means are composed of first and second coils that are electromagnetically coupled.

According to the first aspect of the invention, since the data transmission device is configured as described above, when transmitting the first transmission data and the power source power from the master unit to the slave unit, first, the switching that operates by the control signal is performed. The continuous wave is switched and output by the means. In the first drive means, the output side is turned on by the selection signal, so the first drive signal is generated from the output signal of the switching means and sent to the first coil. The second coil on the slave unit side receives the first drive signal sent from the first coil in the form of a pulse-shaped first coil current. The power receiving unit rectifies the first coil current, outputs power source power, and supplies the power source power to each circuit in the slave unit.

Next, the switching means switches the first transmission data and sends it to the first driving means. At this time, since the output side of the first drive means is turned on by the selection signal, the first drive means generates the first drive signal from the output signal of the switching means and sends it to the first coil. To be In the second coil on the slave side, the first drive signal sent from the first coil is pulsed to the first coil.
Receive in the form of coil current. The power receiving unit rectifies the first coil current, outputs power source power, and supplies the power source power to each circuit in the slave unit. In the power reception detecting means, the fact that the cycle of the continuous wave is shorter than that of the first transmission data is used, and the pulse cycle of the first coil current received by the second coil is counted and based on the count value, Either the continuous wave sent from the master unit or the first transmission data is detected.
When the detection result of the power reception detecting unit is the first transmission data, the second signal detecting unit operates based on the detection result, and the positive pulse and the negative pulse of the first coil current are detected, and the second pulse is detected. The first reception data is output from the signal detection means. At this time, the output side of the second drive unit is in the open state at a timing according to the detection result of the power reception detection unit or the output data of the second signal detection unit.
When the second transmission data is transmitted from the slave unit to the master unit, if the power reception detection unit detects a continuous wave break from the master unit, the power reception detection unit responds to the detection result of the power reception detection unit or output data of the second signal detection unit. At the timing, the output side of the second drive means is turned on. The second transmission data on the slave side is driven by the second driving means and sent to the second coil. Then, the pulse-shaped second coil signal flows through the first coil on the master unit side, and the second coil current is detected by the first signal detecting means, and the second signal from the first signal detecting means to the second coil current is detected. Received data is output.

According to the second and fourth aspects of the invention, the first drive means on the master section side is synchronized with the first transmission data when the first transmission data is output from the switching means. A pulsed drive signal is generated from the first transmission data according to the activation level of the selection pulse of 1, and is sent to the first transmission means. Then, the second transmission means receives the first transmission data, and the same processing as in the first invention is performed.
When the first selection pulse is at the deactivation level, the first selection pulse
The output side of the driving means is opened. On the slave side, when detecting that the continuous wave is cut off from the master section, the second transmission data is converted into a pulsed drive signal by the second drive means, and this drive signal is transmitted by the second transmission means. Is transmitted to the first transmission means on the master side, and the reception data is output by the first signal detection means as in the first invention. According to the third invention, in the data transmission device of the second invention, when data is transmitted from the master unit to the slave unit, the pulse width is larger than the pulse width when transmitting data from the slave unit to the master unit. The pulse is transmitted.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION First Embodiment FIG. 1 is a block diagram of a data transmission apparatus showing a first embodiment of the present invention. This data transmission device has a power supply voltage VD
A master unit 30 having a battery 31 for supplying D and a slave unit 40 receiving power supply from the master unit 30 are provided, and data and power are transmitted and received between the master unit 30 and the slave unit 40. Is a device for performing. The master unit 30 includes a microcomputer having a CPU (not shown) that operates with a power supply voltage VDD supplied from a battery 31, and a transmission / reception circuit that is program-controlled by the CPU. In addition to the battery 31, the transceiver circuit
A switching unit (for example, a switching circuit) 32, a first driving unit (for example, a coil driving circuit) 33, a first coil 34 for transmission and reception, and a first signal detection unit (for example, a signal detection circuit) 35 are provided. doing. The switching circuit 32 is a continuous wave OS composed of first transmission data SD _m given from the CPU side and a clock signal having a shorter cycle than the transmission data SD _m.
It is a circuit for switching and outputting either one of C and C according to the transmission control signal RS _m , and the coil drive circuit 33 is connected to this output side. The switching circuit 32 is, for example, a circuit that outputs the transmission data SD _m when the transmission control signal RS _m is “1” and outputs the continuous wave OSC when the transmission control signal RS _m is “0”.

The coil drive circuit 33 is composed of, for example, a tri-state buffer, and when the transmission mode selection signal SEL _m given from the CPU side is "1", the output side is turned on and the output signal of the switching circuit 32 is kept as it is. The signal is output in the form of a first drive signal, and the transmission mode selection signal SEL _m
Is a circuit in which the output side is open when is 0, and the first coil 34 for transmission and reception is connected to this output side. The first coil 34 is electromagnetically coupled to the second coil 41 for transmission / reception provided on the slave section 40 side. The drive signal output from the coil drive circuit 33 is
It is converted into a coil current having a differential waveform by electromagnetic coupling by the coil and transmitted to the slave unit 40. A signal detection circuit 35 is connected between the coil drive circuit 33 and the coil 34. The signal detection circuit 35 is provided in the slave unit 40 while the output side of the coil drive circuit 33 is in the open state.
The coil current S34, in which the data sent from the coil 34 is received by the coil 34, is input, the positive pulse and the negative pulse of the coil current S34 are detected, and the second pulse of "1" or "0" is detected according to the detection result. It is a circuit that outputs the reception data RD _m .

The slave unit 40 includes a microcomputer having a CPU (not shown) and a transmission / reception circuit program-controlled by the CPU. The transmission / reception circuit includes a second coil 41 for transmission / reception that is electromagnetically coupled to the first coil 34 on the master unit 30 side, and a power receiving unit that receives power transmitted from the master unit 30 through the coil 41 (for example, rectification). Circuit 42, power reception detection means for detecting the continuous wave OSC sent from the master unit 30 (for example,
Power detection circuit) 43, a second signal detection means (for example, a signal detection circuit) 44 for detecting the data sent from the master unit 30, and second transmission data SD _s given from the CPU side. It has a second drive means (for example, a coil drive circuit) 45. The rectifier circuit 42 is connected to the coil 41, and the master unit 3 received by the coil 41 is received.
It is a circuit that rectifies the coil current S41 from 0 and outputs the power supply voltage VDDS for driving the slave unit, and is configured by, for example, a diode and a capacitor. The power detection circuit 43 is connected to the coil 41, and the coil 4
The counter is reset by the differential pulse of the conversion point of the continuous wave OSC received in 1, the continuous wave OSC is detected from the value of this counter, and the power reception detection signal CD _s (this is " 1 ", transmission data SD _m
Is output when it is sent to the CPU)
Give to the side.

The signal detection circuit 44 is connected to the coil 41, receives the coil current S41 from the master section 30 received by the coil 41, detects the positive pulse and the negative pulse, and responds to the detection result. It is a circuit for outputting the first reception data RD _s of "1" and "0" and giving it to the CPU side. The signal detection circuit 44 receives the power reception detection signal CD _s.
When is switched from "1" to "0", it is activated by the control of the CPU side. Coil drive circuit 45
Is connected to the coil 41 on the output side and is constituted by, for example, a tri-state buffer. This coil drive circuit 4
When the transmission mode selection signal SEL _s is “1”, the output side is turned on and the transmission data SD _s given from the CPU side is used as it is in the form of the second drive signal for the coil 41.
To the output side when the transmission mode selection signal SEL _s is “0”. The transmission mode selection signal SEL _s becomes “1” or “0” under the control of the CPU based on the power reception detection signal CD _s or the reception data RD _s .

FIG. 4 is a circuit diagram showing a configuration example of the signal detection circuit 44 in FIG. The signal detection circuit 35 on the master unit 30 side and the signal detection circuit 44 on the slave unit 40 side have the same circuit configuration. Signal detection circuit 44 on the slave unit 40 side
Is a positive-side level slicer 51 that detects a positive pulse of the coil current S41 received by the coil 41 and outputs a detection signal rds ⁺ , and a negative-level pulse that detects a negative pulse and detects a detection signal rds.
^- a negative electrode side level slicer 52 for outputting, connected set-reset flip-flop circuit on the output side of these levels slicer 51 (hereinafter, "RS-FF"
53). The positive-side level slicer 51 is composed of a comparator 51a or the like that slices the positive-electrode pulse at a constant level. Similarly, the negative-side level slicer 52 is also composed of a comparator 52a for slicing the negative-electrode pulse at a constant level. RS
The -FF 53 is set by the positive side detection signal rds ⁺ input to the set input terminal S, reset by the negative side detection signal rds ⁻ input to the reset input terminal R, and output from the output terminal Q to "1", "0". It is a circuit that outputs the reception data RD _{s of} "".

FIG. 5 is an operation waveform diagram of FIGS. 1 and 4, and FIG. 6 is a power detection operation waveform diagram of FIG. 1. The operation of FIGS. 1 and 4 will be described with reference to these diagrams. . When transmitting the transmission data SD _m and the power from the master unit 30 to the slave unit 40, first, in the initial state, the transmission control signal RS _m
Is switched to the continuous wave OSC side, the continuous wave OSC is output from the switch circuit 32. At this time, the transmission mode selection signal SEL _m is “1”,
Since the coil drive circuit 33 is in the ON state, the continuous wave OSC output from the switching circuit 32 is supplied to the coil 34 through the coil drive circuit 33 and the slave unit 4
A coil current S41 flows through the 0-side coil 41. The coil current S41 is rectified by the rectifier circuit 42, the power supply voltage VDDS is output from the rectifier circuit 42, and the slave unit 4
Each circuit within 0 is activated.

Next, when the transmission control signal RS _m becomes "1" and the switching circuit 32 is switched to the transmission data SD _m side, the transmission data SD _m is output from the switching circuit 32. The transmission data SD _m output from the switching circuit 32 is
It is sent to the coil 34 through the coil drive circuit 33 in the ON state. Since direct current cannot be transmitted by the electromagnetic coupling of the coils 34 and 41, when the output drive signal of the coil drive circuit 33 flows to the coil 34, the coil 41 on the slave unit 40 side will be transmitted.
A coil current S41 having a differential waveform flows through the. The coil current S41 is rectified by the rectifier circuit 42, and the power supply voltage VDDS is output from the rectifier circuit 42, so that the slave unit 40
Is supplied to each circuit inside. In the power detection circuit 43, as shown in FIG.
, The change in the cycle T1, T2, T3, ... Of the coil current S41 flowing in the coil 41 is determined by the count value by resetting at each conversion point, and the power reception detection signal is received while the continuous wave OSC is being received. When CD _s = “1” is output and the transmission data SD _m having a longer cycle than the continuous wave OSC is received, the power reception detection signal CD _s = “0” is output. That is, in the power detection circuit 43, the counter is reset by the differential pulse of the conversion point of the continuous wave OSC, and when the count value is equal to or less than the fixed value, the power reception detection signal CD _s = “1”.
Is output. After that, when the reception signal at the coil 41 changes from the continuous wave OSC to the data signal of the differential waveform having a longer cycle than the continuous wave OSC, the reset cycle of the counter becomes longer and the count value exceeds a certain value. The power reception detection signal CD _s = “0” is output.

When the power reception detection signal CD _s changes from "1" to "0" by the power detection operation of the power detection circuit 43, this is sent to the CPU side (not shown), and the signal detection circuit 44 is activated by the control signal on the CPU side. To be done. In the signal detection circuit 44 shown in FIG. 4, the positive pulse of the coil current S41 received by the coil 41 is detected by the comparator 51a in the positive side level slicer 51, and the detection signal rds ⁺ is output from the comparator 51a. Coil current S4
The negative pulse of 1 is detected by the comparator 52a in the negative level slicer 52, and the detection signal rds ^- is output from the comparator 52a. Positive detection signal rds ⁺
The RS-FF 53 is set by and the RS-FF 53 is reset by the detection signal rds ⁻ on the negative side. When the transmission data SD _m to be transmitted from the master unit 30 to the slave unit 40 is transmitted in the positive logic, the reception data RD _s of “1” is output from the output terminal Q of the RS-FF 53 by the positive pulse detection of the comparator 51a. , RS-F is detected by the negative pulse detection by the comparator 52a.
The reception data RD _s of “0” is output from the output terminal Q of F53. On the other hand, the master unit 30 to the slave unit 40
When transmitting the transmission data SD _m to be transmitted to the negative logic, the reception data R of “0” is output from the output terminal Q of the RS-FF 53 by the positive pulse detection by the comparator 51a.
D _s is output, and the reception data RD _s of “1” is output from the output terminal Q of the RS-FF 53 by the negative pulse detection by the comparator 52a.

CP (not shown) in the slave unit 40 of FIG.
On the U side, the number of times of the power reception detection signal CD _s = “0” or the control signal included in the reception data RD _s is decoded, and the data transmission time point (transmission mode selection signal S
EL _m = “0”) is detected and the transmission mode selection signal SEL
_{s is set} to "1" to turn on the coil drive circuit 45. When the transmission mode selection signal SEL _s is "0", the output side of the coil drive circuit 45 is in an open state and is in a receivable state. When the coil drive circuit 45 is turned on, the transmission data SD _s on the slave unit 40 side is driven by the coil drive circuit 45, and the drive signal output from the coil drive circuit 45 is sent to the coil 41. Then
The coil current S of the differential waveform is applied to the coil 34 on the master unit 30 side.
34 flows. At this time, since the transmission mode selection signal SEL _m becomes “0” and the output side of the coil drive circuit 33 is in the open state, the coil current S34 is input to the signal detection circuit 35. In the signal detection circuit 35, as in the signal detection circuit 44 on the slave unit 40 side, the coil current S3
The positive pulse and the negative pulse of No. 4 are detected, and the reception data RD _m of the logic level according to the detection result is output and given to the CPU side (not shown).

As described above, in the first embodiment,
There are the following advantages. Master unit 30 to slave unit 4
0 to the continuous wave OSC to supply power to the continuous wave OSC.
From the switching circuit 32 until the power supply voltage VDDS on the slave unit 40 side reaches the minimum value of the circuit operating voltage,
The coils 34 and 41 are directly driven by a digital data signal, and the rising and falling differential pulses of the data signal are received through the electromagnetic coupling by the coils 34 and 41. The reception data RD _s of 1 ”and“ 0 ”are demodulated. Therefore, the circuit has a simple structure, a highly accurate analog circuit for detecting a minute level change, which is conventionally required, is not required, and integration in a digital circuit is facilitated.

Second Embodiment FIG. 7 is an operation waveform diagram showing a second embodiment of the present invention. In the second embodiment, the coil drive circuit 3 of FIG.
3, 45 has the following functions. That is, when the continuous wave OSC is output from the switching circuit 32, the coil drive circuit 33 on the master unit 30 side is provided with the continuous wave OSC.
Pulsed generates and outputs a drive signal from該切when replacement transmitted from the circuit 32 data SD _m is outputted, the first selection of the transmission mode selection signal SEL _m in synchronization with the polarity of the transmission data SD _m Pulse activation level (eg,
"1") generates and outputs a pulsed drive signal from the first transmission data SD _m , and the deactivation level (for example, "0") of the first selection pulse causes the output side to It has the function of opening. The coil drive circuit 45 on the slave unit 40 side also includes the coil drive circuit 33.
It has the same function as. In this second embodiment,
For example, when transmitting the transmission data SD _m from the master unit 30 to the slave unit 40, the transmission mode selection signal SEL
a first selection pulse _m in synchronization with the polarity of the transmission data SD _m, and only the output mode time width corresponding to the differentiated pulse width of the first embodiment. As a result, the coil drive circuit 33 generates a pulsed drive signal from the input transmission data SD _m and supplies it to the coil 34.

Coil drive circuit 33 of the first embodiment
Then, the signals of "1" and "0" of the transmission data SD _m are input as they are, and this conversion point is differentiated according to the transmission characteristic due to the electromagnetic coupling between the coils 34 and 41, and the slave unit 40
Is transmitted to the side as positive and negative differential pulses. On the other hand, in the second embodiment, the coil drive circuit 33 previously generates a differential pulse according to the polarity of the transmission data SD _m , and sends the differential pulse to the coil 34. At this time, the positive and negative polarities of the differential pulse are obtained by reversing the coil drive current. Slave unit 40 to master unit 3
Even when transmitting the transmission data SD _s to 0, the master unit 30
Like the coil drive circuit 33 on the side, the slave unit 40
The side coil drive circuit 45 operates.

As described above, in the second embodiment,
In addition to the advantages substantially similar to those of the first embodiment, there are the following advantages. (A) For example, when transmitting the transmission data SD _m from the master unit 30 to the slave unit 40, the coil driving circuit 33 is operated by the selection pulse of the transmission mode selection signal SEL _m synchronized with the transmission data SD _m , and the pulse shape is generated. Drive signal is supplied to the coil 34. Therefore, the transmission data SD
_{Even if} the polarity of _m is "1" or "0", one pulse is always sent from the master unit 30 to the slave unit 40 in the data cycle.
Is transmitted to the slave unit 40, it is possible to reduce the voltage drop of the power supply voltage VDDS output from the rectifier circuit 42 on the slave unit 40 side. (B) The coil drive circuit 45 on the slave unit 40 side operates similarly to the coil drive circuit 33 on the master unit 30 side. Therefore, when the transmission data SD _s is transmitted from the slave unit 40 to the master unit 30, the transmission mode selection signal SE
When the second selection pulse of L _s is “1”, the coil drive circuit 45
Is turned on, the output side of the coil drive circuit 45 is opened with "0", and a pulsed drive signal is applied to the coil 4
By supplying 1 to 1, the transmission data SD _s is transmitted to the master unit 30. Here, the transmission mode selection signal SE
When the second selection signal of L _s is “0”, the coil drive circuit 4
Since the output side of 5 is in the open state and the coil 41 is not driven, the power consumption on the slave unit 40 side can be reduced. (C) Since the pulse drive signals are output from the coil drive circuits 33 and 45 to transmit the transmission data SD _m or SD _s , the differential pulse forming coils 34, as a transmission medium,
It is also possible to use other transmission means such as an optical transmission medium such as a photocoupler or an ultrasonic transmission medium without necessarily using 41.

Third Embodiment In the third embodiment of the present invention, in the second embodiment shown in FIG. 7, it is generated by the coil drive circuit 33 at the time of data transmission from the master unit 30 to the slave unit 40. The pulse width of the drive signal is set to be larger than the pulse width of the drive signal generated by the coil drive circuit 45 at the time of data transmission from the slave unit 40 to the master unit 30 so that data is transmitted and received. With this configuration, when data is transmitted from the master unit 30 to the slave unit 40, the slave unit 4
Power supply voltage VDDS output from the rectifier circuit 42 on the 0 side
Can be prevented.

The present invention is not limited to the above embodiment, and various modifications can be made. For example, there are the following modifications. (I) The switching circuit 32 may be configured by other switching means such as a gate circuit instead of being configured by the switching circuit as shown in FIG. The signal detection circuits 35 and 44 may be composed of signal detection means having a configuration other than that shown in FIG. Further, the power detection circuit 43 may be configured by power reception detection means using circuit elements other than the timer. (Ii) The master unit 30 and the slave unit 40 in FIG. 1 are controlled by the respective microcomputers, but other control circuits may control the transmission device in FIG. 1 instead of these microcomputers.

[0028]

As described in detail above, according to the first aspect of the invention, the master section supplies the power source with a continuous wave to the slave section, and the continuous wave is switched to the first transmission data by the switching means. In response to the first transmission data, the first coil is driven via the first driving means, and the second coil on the slave side receives the pulse-shaped first coil current. Since the first reception data is demodulated according to the polarity of the coil current of 1, the circuit has a simple configuration.
Therefore, a highly accurate analog circuit for detecting minute level fluctuations, which is conventionally required, is not required, and integration in a digital circuit is facilitated. According to the second aspect of the invention, the transmission means is driven by the pulsed drive signal generated by the drive means in accordance with the polarity of the transmission data, so that the polarity of the transmission data is continuous "1" or "0". Also, one pulse is always transmitted in the cycle of the transmission data. Therefore, it is possible to reduce the level reduction of the power source power output from the power receiving unit on the slave unit side. Moreover, at the time of data transmission from the slave unit to the master unit, the output side of the second driving unit is opened when the second selection pulse is at the inactivation level, and therefore the second transmission unit is not driven at this time. The power consumption on the slave side can be reduced. According to the third aspect of the invention, the pulse width during data transmission from the master unit to the slave unit is made larger than the pulse width during data transmission from the slave unit to the master unit. It is possible to prevent the level of the power source power output from the power receiving means on the slave side at the time of data transmission to the slave section from decreasing.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a data transmission device showing a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a conventional data transmission device.

FIG. 3 is an operation waveform diagram of FIG. 2;

4 is a circuit diagram of a signal detection circuit in FIG.

5 is an operation waveform diagram of FIGS. 1 and 4. FIG.

FIG. 6 is a power detection operation waveform diagram in FIG. 1.

FIG. 7 is an operation waveform diagram showing a second embodiment of the present invention.

[Explanation of symbols]

 30 master part 31 battery 32 switching circuit 33, 45 coil drive circuit 34, 41 coil 35, 44 signal detection circuit 42 rectification circuit 43 power detection circuit

Claims (4)

[Claims] 1. A master unit having a first coil for transmission and reception, and a slave unit having a second coil for transmission and reception electromagnetically coupled to the first coil, and the first and second units. A data transmission device that performs data transmission between the master unit and the slave unit in a non-contact state via a coil, wherein the master unit includes a power supply for supplying power source power, first transmission data, and Switching means for switching and outputting either one of a pulsed continuous wave having a shorter cycle than the first transmission data by a control signal, and generating a first drive signal from the output signal of the switching means,
And the output side is turned on or opened by the selection signal, and the first driving means for outputting the first driving signal when in the on state; and transmitting the first driving signal to the second coil And the first coil that receives the second drive signal sent from the second coil in the form of a pulsed second coil current, and the output side of the first drive means is in an open state. During the period
A first signal detecting means for detecting a positive pulse and a negative pulse of the second coil current received by the first coil and outputting second received data of a logical level according to the detection result. The slave unit receives the first drive signal sent from the first coil in the form of a pulse-shaped first coil current, and receives the second drive signal from the first coil. Second to send to
Coil, a power receiving unit that rectifies the first coil current received by the second coil and outputs power source power for driving a slave unit, and the first coil current received by the second coil And a power reception detecting unit that detects the continuous wave or the first transmission data from the master unit based on the count value, and the power reception detection unit detects the first transmission data. A second pulse that detects a positive pulse and a negative pulse of the first coil current received by the second coil based on the detection result, and outputs first received data of a logical level according to the detection result. And a signal detecting means for generating the second drive signal from the second transmission data, and at the timing according to the detection result of the power reception detecting means or the output data of the second signal detecting means. Is turned on or in an open state, and second driving means for outputting the second drive signal to the second coil when in the on state is provided. 2. A master unit having a first transmission / reception means for transmission and a slave unit having a second transmission / reception means for transmission, and a non-contact state via the first and second transmission means. In the data transmission device for performing data transmission between the master unit and the slave unit, the master unit includes a power supply for supplying power source power, first transmission data, and a cycle based on the first transmission data. A switching means for switching and outputting either one of a short pulsed continuous wave of the control signal, and when the continuous wave is being output from the switching means,
A pulsed drive signal is generated from the continuous wave and output, and when the first transmission data is output from the switching means, activation of a first selection pulse synchronized with the first transmission data. A first drive means for generating and outputting a pulsed drive signal from the first transmission data according to a level, and having an output side in an open state when the first selection pulse is at a deactivation level; The first transmission means for transmitting the pulsed signal output from the first drive means to the second transmission means, and receiving the pulsed signal transmitted from the second transmission means; While the output side of the first drive means is in the open state,
A first signal detecting means for detecting a positive pulse and a negative pulse of the pulsed signal received by the first transmitting means, and outputting second received data of a logical level according to the detection result, The slave unit generates and outputs a pulsed drive signal from the second transmission data according to the activation level of the second selection pulse synchronized with the second transmission data, and the second selection pulse is generated. Second drive means whose output side is in an open state at the deactivation level, and a pulse which receives the pulse-like signal sent from the first transmission means and is output from the second drive means The second transmission means for transmitting a signal in the form of a line to the first transmission means, a power receiving means for rectifying the signal received by the second transmission means and outputting power source power for driving the slave unit, Second transmission means A power reception detection unit that counts the pulse period of the received pulse-shaped signal and detects the continuous wave or the first transmission data from the master unit based on the count value, and the power reception detection unit includes the first power reception detection unit. Detection of the transmission data of the first transmission data of the logic level corresponding to the detection result by detecting the positive pulse and the negative pulse of the pulsed signal received by the second transmission means based on the detection result. And a second signal detection means for outputting the second selection signal, wherein the second selection signal has an activation level or an inactivation timing according to a detection result of the power reception detection means or output data of the second signal detection means. A data transmission device characterized in that it has a configuration level. 3. The pulse width when transmitting data from the master unit to the slave unit is made larger than the pulse width when transmitting data from the slave unit to the master unit. 2. The data transmission device according to 2. 4. The data transmission device according to claim 2, wherein the first and second transmission means are composed of first and second coils that are electromagnetically coupled.