JPH0662474A - Remote-controlled system - Google Patents

Abstract

PURPOSE: To extend an arrival distance in spite of spatial limitation by receiving an infrared signal, generating a control signal corresponding to that infrared signal, and converting the result transmitting/receiving relevant data through a power line to an infrared signal. CONSTITUTION: The infrared signal sent from a remote controller is received by a reception part 12 and corresponding to the infrared signal received by the reception part 12, the control signal is generated from a control part. According to the control signal from the control part 13, a MODEM part 14 is switched to transmission mode and reception mode. At the time of transmission mode, the received infrared signal is sent out to the power line and at the time of reception mode, the data received from the MODEM part 14 are converted to infrared signals and sent out by an infrared transmission part 16.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automated system, and more particularly to a remote control system capable of controlling facilities by infrared signals. Recently, with the development of an automated system for home use, a user can conveniently remotely control home electric appliances and various facilities installed in homes and collective living facilities.

Normally, when controlling an apparatus using an infrared signal from a remote controller, the distance from the control space is restricted. FIG. 1 is a block diagram for explaining a conventional infrared signal transmission method, which is a device (1) controlled by a remote controller (2).
Is a preamplifier (PRE-AM) for receiving infrared signals.
P: 1A), a microcomputer (1B) that generates a control signal according to the received infrared signal, and a main device (1C) that operates according to the control signal of the microcomputer (1B).

The remote controller (2) corresponds to a battery (2A) for supplying operating power, a key input section (2B) made up of various function selection keys, and a key input signal from the keypad (2B). It is composed of an infrared transmitter (2C) for transmitting an infrared signal. When the user presses a key on the remote controller (2), an infrared signal corresponding to the key input signal is sent to the device (1) through the space (atmosphere). The signal sent out is input to the preamplifier (1A) of the device (1) to be waveform-shaped. The shaped signal is input to the microcomputer (1B) of the device (1), and the microcomputer (1B) generates a control signal by analyzing the input signal, and the main device (1C) is operated according to the control signal. It is.

However, in such a conventional system, as shown in FIG. 1, control of equipment is performed in a space (Y) other than the used space (X) to which the remote controller (2) belongs, for example, between two spaces closed by a wall. However, there is a problem that the remote controller cannot operate even if the reception angle and the communication distance are out of the control range even in the same space. There is a method of increasing the power consumption of the remote controller when trying to increase the communication distance, but there is still a problem that the battery consumption of the remote controller is increased.

[0005]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a remote control system capable of sending out an infrared signal regardless of spatial restrictions. Another object of the present invention is to provide a remote control system capable of extending the reach of infrared signals.

Yet another object of the present invention is to provide a remote control system in which the range of infrared signal reception angles is widened. Another object of the present invention is to provide a remote control system capable of minimizing battery consumption of the remote controller. Such purposes include a receiving unit for receiving an infrared signal sent from a remote controller, a control unit connected to the receiving unit for generating a control signal according to the infrared signal, and an infrared ray according to the control signal. A remote control system comprising a modem unit for transmitting and receiving data corresponding to a signal to and from a power line and an infrared transmission unit for converting data received from the power line into an infrared signal and transmitting the infrared signal. It

[0007]

Embodiments of the present invention will now be described in detail with reference to the attached FIGS. 2 and 5. FIG. 2 is a block diagram of a remote control system according to an embodiment of the present invention, which includes a receiving unit (12) for receiving an infrared signal transmitted from a remote controller (not shown),
A control unit (13) that generates a control signal according to the infrared signal received from the reception unit (12), and a transmission mode and a reception mode are set by the control signal of the control unit (13). 13) The infrared signal received through the power line is sent to the power line, and the data sent to the power switching line in the reception mode is received by the modem unit (14) and the data received from the modem unit (14). And an infrared transmitting section (16) for converting and transmitting the infrared signal. An unexplained reference numeral 11 is a power supply unit for supplying power to each unit, and 15 is a display unit for indicating whether or not an infrared signal of the remote controller is received.

FIG. 3 is a detailed circuit diagram of FIG. 2, in which the power supply section (11) rectifies the AC power supply (AC) under reduced pressure to supply the operating power supply (Vcc) to each part of the circuit.
1), bridge diode (BD), regulator (1
1A), capacitors (C1, C2, C3), coils (L
1). The infrared receiver (12) is a preamplifier (12) that receives an infrared signal sent from a remote controller.
A), a resistor (R1), and a capacitor (C4). The control unit (13) delays the received signal for a predetermined time and generates a control signal for controlling the transmission / reception mode switching depending on whether the infrared signal is received or not.
R3, R4), transistor (TR1), capacitor (C5), multivibrator (13A), and delay element (13B). The display unit (15) includes resistors (R7) (R8), a transistor (TR2), and a light emitting diode (LED) so as to notify that the infrared signal is received by the control signal of the control unit (13). The power line modem unit (14) switches between a transmission mode and a reception mode in response to a control signal from the control unit (13) and transmits an infrared signal input through the transmission mode control unit (13) to the power line to receive the reception mode power line. An interface transformer (T2), capacitors (C6, C7), so as to transmit the received signal to the infrared transmitter (16),
It consists of resistors (R5, R6) and modem (14A),
The transmission unit (6) is composed of a plurality of infrared transmitters (IRT1-IRTn) which convert data transmitted from the power line modem unit (14) into infrared signals and transmit the infrared signals.

When the AC power source (AC) is input to the transformer (T1), the voltage of the power source (AC) is reduced by the transformer (T1), rectified through the bridge diode (BD), and then by the capacitor (C1). It is converted into a DC power source and input to the regulator (11A). The predetermined constant voltage output from the regulator (11A) is passed through the ripple removing capacitor (C2), the noise removing coil (L1) and the capacitor (C3) to the modem unit (1).
4).

A preamplifier (1) in the infrared receiver (12)
When the infrared signal sent from the remote controller to 2A) is not received, the transistor (TR1) is turned off, so that the two input terminals (A, B) of the multivibrator (13A) are shown in FIG. Such a low potential signal is applied to the clear terminal (C) at this time.
A high potential signal such as f of A is input.

Therefore, a low potential signal such as b in FIG. 4A is output through the output terminal (Q) of the multivibrator (13A), and this signal causes the transistor (TR
Since 2) is turned off, it means that the light emitting diode (LED) is turned off and the infrared signal is not input. Transmission / reception selection terminal (R / T) of modem (14A)
Since a low potential signal is input to the modem, the modem (14A) enters the reception mode.

When the modem (14A) is operated in the reception mode, the data input through the data input terminal (D / I) is ignored, and the signal input through the terminal (I / O) is output as the data output terminal. It is sent to (D / O). When a signal transmitted from a modem of another remote control system is placed on the power line, this signal passes through a high-pass filter consisting of the capacitor (C6) and the primary coil of the transformer (T2), and the AC power supply ( 60HZ) signal is removed, resonance occurs due to the secondary coil of the transformer (T2) and the capacitor (C7), and a signal as shown in c of FIG. 4A is applied to the terminal (I / O) of the modem (14A). Is entered.

This signal is sent to the modem (14A) as shown in FIG.
After converting to a pulse signal like
O) to the infrared transmitters (IRT1-IRTn), and the pulse signals output to the transistors (Q1-Q).
n) is turned on / off to turn on / off the infrared lamp diodes (DA1-DAn) (DB1-DBn).
The signal turned off and placed on the power line is converted into an infrared signal and transmitted.

On the other hand, when the infrared signal sent from the remote controller is received by the preamplifier (12A), the transistor (TR1) is repeatedly turned on and off, so that the input terminal of the multivibrator (13A) ( A pulse signal as shown in a of FIG. 4B is input to B) and the delay element (13B). Therefore, a high potential signal such as b in FIG. 4B is output through the output terminal (Q) of the multivibrator (13A), and this signal causes the transistor (TR
Since 2) is turned on, the light emitting diode (LED) is turned on to indicate that the infrared signal is being input, and the high potential signal is being input to the transmission / reception selection terminal (R / T) of the modem (14A). , The modem (14A) is in transmission mode (T
X).

At this time, the data input terminal (D / I) of the modem (14A) receives a remote controller signal such as d shown in FIG. 4B, which is delayed by the delay element (13B) for a predetermined time. In the modem (14A), the pulse signal is converted into a signal such as c in FIG.
/ O). After passing through the interface transformer (T2), this signal is transmitted to the modem of another remote control system through the power line.

FIG. 5 shows a space (A) as an example of a substantial remote control space to which the remote control system of the present invention is applied.
(B) is a club room, space (C) is a bathroom, and space (D) is a kitchen. Here, each remote control signal is transmitted to the other space in the home through the power line (indicated by a dotted line) connecting the household electric appliances (3A-3C) and the electric lights (4A-4D) already used here. A remote control device (5A-5C) is provided at an appropriate position in the space. After receiving the remote controller signal transmitted from the remote control device (5A-5C) through the power line, the infrared signal is transmitted to the device through the infrared transmitter of itself.

As described above, according to the present invention, since the remote controller signal is transmitted to the other space through the power line, it is possible to control the household appliances and the like from the other space, and the communication distance of the infrared signal transmitted to the equipment can be controlled. The control range can be expanded by lengthening the transmission angle.

[Brief description of drawings]

FIG. 1 is a block diagram for explaining a conventional infrared signal transmission system.

FIG. 2 is a block diagram of a remote control system according to an exemplary embodiment of the present invention.

FIG. 3 is a detailed circuit diagram of FIG.

FIG. 4 is an input / output waveform diagram of each part of FIG.

FIG. 5 is a drawing showing an example of a substantial remote control space to which the remote control system of the present invention is applied.

[Explanation of symbols]

 11 ... Power supply section 12 ... Receiving section 13 ... Control section 14 ... Modem section 15 ... Display section 16 ... Infrared transmitting section

Claims (4)

[Claims] 1. A means for receiving an infrared signal sent from a remote controller, a means connected to the receiving means for generating a control signal in response to the infrared signal, and an infrared ray in response to the control signal. A remote control system comprising means for transmitting and receiving data corresponding to a signal through a power line, and means for converting data received from the power line into an infrared signal corresponding to the data and sending the infrared signal. 2. The remote control system according to claim 1, further comprising means for displaying a reception state of an infrared signal from a remote controller, the means being connected to the control signal generating means. 3. The remote control system according to claim 1, wherein the control signal generating means has means for delaying the signal received from the receiving means for a predetermined time. 4. The data transmission / reception means switches between a transmission mode and a reception mode according to the control signal, transmits an infrared signal from the remote controller to a power line in the transmission mode, and transmits the infrared signal from the power line in the reception mode. 2. The remote control system according to claim 1, wherein the remote control system comprises a modem for receiving data from the device and an interface circuit for connecting the modem and a power line to process a transmission / reception mode.