JPH0250695A - Two-way remote controller - Google Patents

Abstract

PURPOSE:To prevent malfunction of a remote control unit with a signal sent from a transmission circuit of the remote control unit by avoiding the application of an operating voltage to a reception circuit of the remote control unit in the operation of the transmission circuit of the remote control unit. CONSTITUTION:A transmission signal is generated from a transmission signal generating circuit 11 and a drive transistor(TR) 12 is turned on by an H level of the transmission signal, then a base of the 2nd TR 21 is connected to ground via a diode 19 and a collector emitter junction of the said drive TR 12 and a capacitor 23 is quickly discharged. Then the said 2nd TR 21 is turned off and the 1st TR 18 is turned off, then no power voltage (+VDD) is applied to a reception data extraction circuit 15 and the operation of the reception data extraction circuit 15 is stopped. Thus, malfunction of the remote control unit by a signal sent from the transmission circuit of the remote control unit is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a two-way remote control device that mutually transmits and receives signals between a set main body and a remote control unit. The present invention relates to a two-way remote control device designed to prevent a transmitted signal from being directly received by a receiving circuit of a remote control unit.

(B) Conventional technology Many of the latest consumer electronic devices are equipped with a remote control device, and the signal sent from the transmitting circuit installed in the remote control unit using infrared rays etc. is sent to the main unit of the set. It is configured so that remote control can be performed by receiving the signal with a receiving circuit installed in the device.

By the way, as shown in Japanese Patent Application Laid-Open No. 62-173895, for example, the set main body is provided with a transmitting circuit in addition to the receiving circuit, and the remote control unit is provided with a receiving circuit in addition to the transmitting circuit, and the set main body and the remote control unit are provided with a transmitting circuit in addition to the transmitting circuit. A two-way remote control device that can mutually transmit and receive signals between devices is known.

The two-way remote control device has the advantage that if the remote control unit is provided with a display function, the reception status of the reception circuit of the set body can be confirmed even if the display on the set body cannot be seen because the remote control unit is far away.

(c) Problems to be solved by the invention By the way, since the two-way remote control device has a transmitting circuit and a receiving circuit in the same housing, the transmission signal from the transmitting circuit is received by the receiving circuit in the same housing. This may cause malfunctions. Especially the remote control unit.
Generally, they are small enough to fit in the palm of your hand, and the light emitting section of the transmitting circuit and the light receiving section of the receiving circuit are placed adjacent to each other due to the straightness of infrared rays, so there is a high possibility of malfunctions occurring.

B) Means for Solving the Problems The present invention has been made in view of the above-mentioned points, and is provided with a receiving circuit in addition to a transmitting circuit in a remote control unit for remotely controlling the set main body, and a receiving circuit is provided in the set main body. In a two-way remote control device that includes a transmitting circuit in addition to the circuit and transmits and receives signals between the set main body and the remote control unit, a power supply line for applying an operating voltage to the receiving circuit of the remote control unit is provided. The device includes a switching device that selectively shuts off the device, and a control circuit that controls the switching device depending on the operating state of the transmitting circuit of the remote control unit.

Alternatively, an output transistor that guides the reception signal received by the reception circuit of the remote control unit to a decoder for decoding the reception signal at a subsequent stage, and control that controls the output transistor according to the operating state of the transmission circuit of the remote control unit. It is equipped with a circuit.

Alternatively, the device may have a center frequency that corresponds to a modulation frequency of a transmission signal transmitted from a transmission circuit of the set main body, and a bandpass filter provided in a reception circuit of the remote control unit, and an operating state of the transmission circuit of the remote control unit. and a control circuit that performs control to separate connections between elements that determine the center frequency of the bandpass filter.

(f) Effect The present invention is capable of transmitting a received signal that has been completely received by the receiving circuit of the remote control unit to a subsequent decoder by not applying an operating voltage to the receiving circuit of the remote control unit when the transmitting circuit of the remote control unit is operating. By fixing the output signal from the leading output transistor, or by eliminating the bandpass characteristics of the bandpass filter provided in the receiver circuit of the remote control unit, the remote control unit can malfunction due to the signal sent from the transmitter circuit of the remote control unit. It prevents you from doing so.

(F) Embodiment FIG. 1 is a circuit diagram showing a first embodiment of the present invention, in which (1) is a set body, and (2) is a remote control unit for remotely controlling the set body (1). Said set body (1)
includes a light-receiving element (3) that receives infrared rays, and a light-receiving element (3) that receives infrared rays.
a received data extraction circuit (4) that extracts received data from the received signal obtained from 3);
), a decoder (6) that decodes the received data output from the output transistor (5), and the received data decoded by the decoder (6). A transmission signal generation circuit (7) that creates transmission data according to the transmission data and generates a transmission signal according to the transmission data, and a drive transistor (7) that is controlled according to the transmission signal from the transmission signal generation circuit (7). 8), and a light emitting element (9) that is driven by the drive transistor (8>) and emits infrared light.

On the other hand, the remote control unit (2) has a key switch (10
A transmission signal generation circuit (11) that creates transmission data in response to the operation of > and generates a transmission signal in accordance with the transmission data.
, a drive transistor (12) that can be controlled according to the transmission signal from the transmission signal generation circuit 11), a light emitting element (13) that is driven by the drive transistor (12) and emits infrared light, and a light emitting element (13) that emits infrared light. Light-receiving element that receives light (
14), a received data extraction circuit (15) that extracts received data from the received signal obtained from the light receiving element (14), and an output transistor that amplifies and outputs the received data from the received data extraction circuit (15). (16), a decoder (17) that decodes the received data output from the output transistor (16), and the received data extraction circuit (
15) The first PNP type with the emitter-collector fully inserted into the tlX line for applying t* voltage (+VDD) to
a transistor (18) whose base is connected to the collector of the drive transistor (12) via a diode (9), whose collector is connected to the base of the first transistor (18) and whose emitter is connected via a diode (<20); a grounded NPN type second transistor (21);
'#, the source voltage Vo at the base of the transistor (21)
o) and a capacitor (23) connected to the base of the second transistor (21) and forming a time constant circuit together with the resistor (22).

The light receiving element (3), the received data extraction circuit (4), the output transistor (5), and the decoder in the set body (1) constitute the receiving circuit (41) of the set body (1). The transmission signal generation circuit (7), drive transistor (8), and light emitting element (9> in the main body (1) constitute the transmission circuit (42>) of the set main body (1). ), the key switch (10), the transmission signal generation circuit (11), the drive transistor (12>, and the light emitting element (13)) constitute the transmission circuit (43) of the remote control unit (2). A light receiving element (14), a received data extraction circuit (15), an output transistor (16), and a hitecoder (17) inside constitute a receiving circuit (44) of the remote control unit (2).

By the way, the transmission signal generation circuit (7) of the set body (1)
and a transmission signal generation circuit (11) of the remote control unit (2).
) can be represented by the circuit block diagram shown in FIG. In FIG. 2, an encoder (25) creates encoded transmission data according to an input signal that can be input to an input terminal (26). Note that the input signal input to the input terminal (26) is a signal corresponding to the received data decoded by the decoder <6) in the case of the transmission signal generation circuit (7) of the set body (1), and is a signal corresponding to the received data decoded by the decoder <6). In the case of the transmission signal generation circuit (11) of the unit (2), the signal corresponds to the operation of the key switch (10).

Transmission data output from the encoder (25) is input to the modulation circuit (27). On the other hand, the modulation circuit (27
Since the carrier signal from the carrier signal generation circuit (28) is inputted to the carrier signal, the modulation circuit (27) generates a transmission signal in which the carrier signal is frequency-modulated with the transmission data. Here, as the carrier signal,
Typically 38 to 40 KHz signals are used. Then, the transmission signal output from the modulation circuit (27) is applied to the base of the drive transistor (29).

On the other hand, the received data extraction circuit (4) of the set body (1) and the received data extraction circuit (15) of the remote control unit (2)
) can be represented by the circuit block diagram shown in FIG. In FIG. 3, when the infrared transmission signal is completely received by the light receiving element (30), a current signal that becomes the received signal flows through the light receiving element (30). The received signal is processed by ■/V conversion amplifier circuit (3
1), it is converted into a voltage signal, amplified, and sent to the next stage bandpass filter (B).

P , F ) (32). Then, only the necessary portions of the frequency band of the received signal are passed through the above-mentioned B, P, and F (32). Here, the above B
.

A variable resistor (34) is connected to the terminal (33) of P and F (32) in order to set the center frequency of the frequency band to be passed.
) are connected, and the center frequency of the B, P, F (32) is set by the variable resistor (34) to the modulation frequency of the transmitting signal (38 to 40) from the transmitting circuit shown in FIG.
KHz). Said B, P
, F (32), the received signal passes through the detection circuit (35
) to extract the pulse signal of the received data. The pulse signal of the received data outputted from the detection circuit (35) is waveform-shaped by a waveform shaping circuit (36), and the pulse signal is applied to the base of the output transistor (37).

Next, the operation shown in FIG. 1 will be explained.

When the key switch (10) is operated, the transmission signal generation circuit (11) generates a transmission signal in which a carrier of a predetermined frequency is modulated by transmission data created in response to the operation. Therefore, since the driving transistor (12) can be controlled in accordance with the transmission signal, the light emitting element (13) emits light in accordance with the transmission signal. The light emitting element (13
) emits light, the light emitting element (13) emits an infrared signal corresponding to the transmission signal, and the infrared signal is received by the light receiving element (3) in the set body (1). The infrared signal received by the light receiving element (3) is
It is converted into an electrical signal by the light receiving element (3), demodulated by the received data extraction circuit (4), and received data is extracted from the received data extraction circuit (4>. The received data is transferred to the output transistor (5). ) and input to the decoder (6), the received data can be decoded by the decoder (6).Therefore, the set body (1) is amplified by the key switch (() of the remote control unit (2)).
10) will be controlled according to the operation.

On the other hand, when the received data is decoded by the decoder (6>), the transmission signal generation circuit (7) of the set body (1)
Transmission data is created according to the decoded reception data, and a transmission signal is generated by modulating a carrier of a predetermined frequency with the transmission data. Therefore, the light emitting element (9) is driven by the driving transistor (8) according to the transmission signal, and the light emitting element (9) emits an infrared signal according to the transmission signal.

By the way, the operating state of the reception data extraction circuit (15) in the remote control unit (2) is the same as that of the transmission signal generation circuit (11).
It is controlled in accordance with the generation of transmission signals from. That is, in a state where no transmission signal is generated from the transmission signal generation circuit (11), the output terminal of the transmission signal generation circuit (11) is in a high impedance state, so the drive transistor (12) is turned off. Then, when the drive transistor (12) is in the OFF state, the capacitor (2)
3) is charged.

Therefore, the second transistor (21) is in the on state,
As a result, the first transistor (18) is also turned on. Therefore, in a state where no transmission signal is generated from the transmission signal generation circuit (11), the power supply voltage (+vDD) is applied to the reception data extraction circuit (15), and the reception data extraction circuit (15) is operable. has been made into a state.

On the other hand, when the transmission signal is generated from the transmission signal generation circuit (11) and the drive transistor (12) is turned on due to the rH level of the transmission signal, the second transistor (21)
Since the base of the capacitor (23) is grounded through the diode (19) and the collector-emitter of the drive transistor (12), the capacitor (23) can be quickly discharged. Therefore, the second transistor (21) is turned off, and thereby the first transistor (18) is turned off, so that the power supply voltage (+VDD) is no longer applied to the received data extraction circuit (15), and the received data The operation of the extraction circuit (15) can be stopped.

By the way, when the transmission signal from the transmission signal generation circuit (11) changes to the rL level, the drive transistor (12)
is turned off, and the capacitor (23) is charged via the resistor (22). Therefore, the pre-voltage of the capacitor (23) gradually increases according to the charging time constant determined by the capacitance of the capacitor (23) and the resistance value of the resistor (22). Here, the charging time constant of the capacitor (23) is set according to the generation cycle of the pulse of the transmission signal that can be generated from the transmission signal generation circuit (11).Specifically, the charging time constant of the capacitor (23) The charging time constant is defined as the period from when the collector of the drive transistor (12) becomes "H" level due to the transmission signal from the transmission signal generation circuit (11) until it becomes r L level.
The terminal voltage of 3) is the base of the second transistor (21).
It is set so that it does not exceed a predetermined voltage (2) which is the sum of the rising voltage between the emitters and the rising voltage of the diode (20). Therefore, when the second transistor (21) is depleted, the off state is maintained regardless of the level of the transmission signal until the transmission signal generation circuit (11) finishes generating the transmission signal. Therefore, the transmission signal generation circuit (1
1), the power supply voltage (+VDD) is not applied to the received data extraction circuit (15), and the operation of the received data extraction circuit (15) is completely stopped.

Further, when the transmission signal generation circuit (11) finishes generating the transmission signal and the drive transistor (12) is turned off for a predetermined period of time or more, the capacitor (23) is charged and the terminal voltage of the capacitor (23) reaches a predetermined level. Since the voltage reaches Vth, the second transistor (21) is turned on. Then, the first
Since the transistor (18) is turned on, the reception data extraction circuit (15) becomes operational after a predetermined period of time after the transmission signal generation circuit (11) finishes generating the transmission signal.

Therefore, since the operation of the received data extraction circuit (15) is stopped in response to the generation of the transmission signal from the transmission signal generation circuit (11) in the remote control unit (2), the light emitting element ( The infrared signal emitted from the received data extraction circuit (13) is not received by the received data extraction circuit (15), and after a predetermined period of time after the transmission signal generation circuit (11) finishes generating the transmission signal, the received data extraction circuit ( 15
) becomes operational, the infrared signal emitted from the light emitting element (9> in the set body (1) via the receiving circuit (41) and transmitting circuit (42) of the set body (1) is the received data. It is received by the extraction circuit (15).

On the other hand, the transmission signal generation circuit (7) of the set body (1) is
Since the infrared signal emitted from the light emitting element (13) in the remote control unit (2> is activated once it is received by the receiving circuit (41) in the set body (1), the light emitting element in the set body (1) When the infrared signal is emitted from (9), the transmission signal generation circuit (11) in the remote control unit (2) has already finished generating the transmission signal. When the infrared signal is completely emitted from the light emitting element (9), the infrared signal is received by the light receiving element (14) in the remote control unit (2), demodulated by the received data extraction circuit (15), and sent to the received data extraction circuit (15). 15>, the received data is amplified by the output transistor (16) and input to the decoder (17), so the received data is decoded by the decoder (17). Therefore, the remote control unit (2) is controlled according to the signal completely received by the receiving circuit (41) of the set body (1).For example, if the remote control unit (2) is provided with a display function, the display function is Set body (1)
You can check the operation of.

FIG. 4 is a circuit diagram showing a second embodiment of the present invention.
Only the remote control unit (2) side of the figure is shown. Fourth
In the figure, a single source voltage (+VDD) is always applied to the reception data extraction circuit (15) when it is energized, and a diode (3) is connected to the base of the output transistor (16).
8) to the collector of the drive transistor (12). and the output transistor (16)
A diode (39) is connected to the emitter of.

Therefore, when the power is on, the received data extraction circuit (15)
Since the light-emitting element (13) is always in operation,
The infrared signal emitted from the received data extraction circuit (
15), but by turning on the drive transistor (12), the output transistor (
16> is forcibly turned off, and the output transistor (16)
) is at the rH level.

A capacitor (40) is connected to the base of the output transistor (16), and the transmission signal from the transmission signal generation circuit (11) is at "L" level due to the charging time constant of the capacitor (40). Even when the drive transistor (12) is off, the terminal voltage of the capacitor (40) does not reach the voltage value that turns on the output transistor (16) until the next 1H level of the transmission signal is generated. Therefore, while the transmission signal is being generated from the transmission signal generation circuit (11), the input signal to the decoder (17>) remains unchanged.
The remote control unit (2) will not malfunction.

On the other hand, when the transmission signal generation circuit (11) has finished generating the transmission signal and the drive transistor (12> is off), the output transistor (16) is activated by the reception data extraction circuit (1).
Since the receiving circuit (44) of the remote control unit (2> receives the infrared signal emitted from the set body (1)), the remote control unit (2> is controlled in response to the infrared signal.

By the way, the circuit shown in Fig. 4 can reduce the number of elements compared to the circuit shown in Fig. 1;
As shown in C, the received data extraction circuit (15) and the output transistor (16) are housed in the same package.
It is no exaggeration to say that if a terminal corresponding to the base of the output transistor (16>) is not provided.

In FIG. 4, the same circuits and elements as in FIG. 1 are given the same number.

FIG. 5 is a circuit diagram showing a third embodiment of the present invention.
Only the remote control unit (2) side of the figure is shown. Fifth
In the figure, B and P of the transmission signal generation circuit (11)
, The terminal (33) to which the variable resistor (34) for setting the center frequency of F (32) can be connected is connected to the diode (45).
> to the collector of the drive transistor (12). Further, a capacitor (46) is connected in parallel to the variable resistor (34). Here, since the variable resistor (34) is usually about 100Ω, the drive transistor (12) is turned on and the terminal (33) is connected to the diode (45) and the drive transistor ( 12), the bandpass characteristics of B, P, and F (32) are almost completely eliminated. Therefore, when the drive transistor (12) is turned on, the B, P.

No signal passes through F (32). Then, when the drive transistor (12) is turned off, the capacitor (
46) is discharged via the variable resistor (34) as shown by arrow A. Therefore, the voltage at the terminal (33) gradually increases in accordance with the discharge time constant of the capacitor (46). Here, the discharge time constant of the capacitor (46) is:
It is set according to the timing until the next rH level is generated from the transmission signal generation circuit (11), and the terminal is set while the transmission signal from the transmission signal generation circuit (11) is at "L" level. The voltage of (33) becomes equal to or higher than the predetermined value, and B,
This prevents the bandpass characteristics of P and F(32) from returning. Therefore, the transmission signal generation circuit (11)
In a state where a transmission signal is being generated from the receiving data extraction circuit (15), the output signal from the received data extraction circuit (15) remains unchanged, and the remote control unit (2) will not malfunction.

On the other hand, when the transmission signal generation circuit (11) finishes generating the transmission signal and a predetermined period of time has elapsed, the bandpass characteristics of B, P, and F (32) are restored, so the remote control unit (2
) is controlled according to infrared signals emitted from the set body (1).

By the way, in the circuit shown in Figure 5, the addition of an element is also a diode (
45) and capacitor 46> are sufficient. Further, since the terminal (33) is always provided, there is no case where it cannot be carried out.

In FIG. 5, the same circuits and elements as in FIGS. 1 and 3 are given the same figure numbers.

(G) Effects of the Invention As described above, according to the present invention, no operating voltage is applied to the receiving circuit of the remote control unit during operation of the transmitting circuit of the remote control unit, or the receiving circuit of the remote control unit Since the output signal from the output transistor that guides the received signal to the subsequent decoder is fixed, or the bandpass characteristic of the bandpass filter provided in the remote control unit is eliminated, the transmitter circuit of the remote control unit This prevents the remote control unit from malfunctioning due to signals sent from the remote control unit.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram showing a first embodiment of the present invention, Fig. 2 is a circuit block diagram showing a transmission signal generation circuit of the set main body and remote control unit, and Fig. 3 is a received data extraction circuit of the set main body and remote control unit. FIG. 4 is a circuit diagram showing a second embodiment of the invention, and FIG. 5 is a circuit diagram showing a third embodiment of the invention. Explanation of main drawing numbers (1)... Set body, (2)... Remote control unit, (3) (14)... Light receiving element, (4) (15)
... Received data extraction circuit, (5) (16) ...
Output transistor, (6) (17)...decoder,
(7)<11)...Transmission signal generation circuit, (8)(1
2)...Drive transistor, (9)(13)...
Light emitting element, (18)...first transistor, (2
1)...Second transistor, (19)(38)(4
5>...diode, (23)(40)(46)・
...Capacitor, (32)...B, P, F. Figure 2 Figure 3"o. Figure 4 Figure 5

Claims (3)

[Claims] (1) A remote control unit for remotely controlling the set main body is provided with a receiving circuit in addition to a transmitting circuit, and the set main body is provided with a transmitting circuit in addition to the receiving circuit, and the set main body and the remote control unit are mutually connected. A two-way remote control device that transmits and receives signals to and from the remote control unit includes a switching means for selectively cutting off a power supply line for applying an operating voltage to a receiving circuit of the remote control unit; A two-way remote control device, comprising: a control circuit for controlling the switching means, wherein an operating voltage is not applied to a receiving circuit of the remote control unit when a transmitting circuit of the remote control unit is operating. (2) A remote control unit for remotely controlling the set main body is provided with a receiving circuit in addition to a transmitting circuit, and the set main body is provided with a transmitting circuit in addition to the receiving circuit, and the set main body and the remote control unit are mutually connected. In a two-way remote control device that transmits and receives signals, the operation state of an output transistor that guides a received signal received by a receiving circuit of the remote control unit to a decoder for decoding the received signal at a subsequent stage, and a transmitting circuit of the remote control unit. A two-way remote control device, comprising: a control circuit that controls the output transistor according to the operation of the remote control unit, and an output signal from the output transistor is fixed during operation of a transmitting circuit of the remote control unit. (3) A remote control unit for remotely controlling the set body is provided with a receiving circuit in addition to a transmitting circuit, and the set body is provided with a transmitting circuit in addition to the receiving circuit, and the set body and the remote control unit are mutually connected. In a two-way remote control device that transmits and receives signals, a bandpass filter having a center frequency corresponding to a modulation frequency of a transmission signal transmitted from a transmission circuit of the set main body and provided in a reception circuit of the remote control unit; a control circuit that performs control to separate connections between elements that determine the center frequency of the bandpass filter according to the operating state of the transmitting circuit of the remote control unit, A two-way remote control device characterized by eliminating the bandpass characteristic of a filter.