JP2007214694A - Remote control signal receiving circuit, and remote control signal receiving system used for the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote control signal receiving circuit for receiving a remote control signal, to the head of which a start signal is attached that can make an AGC circuit normally function, even if the circuit is provided with an AGC circuit and reduce battery consumption of a remote control transmitter. <P>SOLUTION: In the remote control signal receiving system wherein the remote control signal is amplified according to the AGC, a stopped clock is oscillated by a restart pulse included in the remote control signal to restart a control means and the control means extracts a control code from the remote control signal, the remote control signal is configured with the restart pulse comprising an ON part t2 and an OFF part t3 succeeding thereto; and remote control code pulses succeeding to the OFF part t3, wherein relations of the ON part time t2<the charge delay time t5, and the OFF part time t3> the discharge delay time t5' are satisfied, and the OFF part time t3 is selected longer than the ON part time t2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a remote control receiving circuit using infrared rays and the like and a remote control signal receiving method used therefor, and more particularly to timing for starting a control microcomputer in a stopped state in a power saving mode.

Conventionally, the remote control signal receiving circuit is provided in the power saving apparatus shown in the block diagram of FIG.
In FIG. 3, reference numeral 11 denotes a remote control light receiving circuit (hereinafter referred to as a remote control light receiving circuit) which is a remote control function receiving means using infrared rays, and is based on infrared rays transmitted from a remote control function transmitting means (not shown). The key code signal is received and amplified and detected, and after waveform shaping, it is output as a remote control pulse code.

  The output of the remote control light receiving circuit 11 is supplied to a control microcomputer (hereinafter referred to as a control microcomputer) 12 for controlling various circuits and operation functions constituting the electronic device. The control microcomputer 12 includes a system microcomputer unit 12a for controlling a signal processing circuit constituting an electronic device and a circuit for controlling an operation function in accordance with a remote control pulse code supplied from the remote control light receiving circuit 11, a clock function and an electronic And a timer / microcomputer unit 12b for controlling the operation display of the device.

  The timer / microcomputer unit 12b operates with an independent reference clock signal of several tens of kilohertz, which is different from the reference clock signal of the system / microcomputer unit 12a, and even if the commercial power supply is cut off, the backup battery is used. Operates and maintains the clock function.

  On the other hand, the control signal from the system microcomputer 12a of the control microcomputer 12 is output to the signal processing / operation circuit 13 including various signal processing circuits constituting the electronic device and circuits for controlling the operation functions. The time and operation display generated by the timer microcomputer 12b is output to display means (not shown).

  The signal processing / operation circuit 13 is connected to a main power supply circuit 14 for supplying operation power. The main power supply circuit 14 supplies operation power to the signal processing / operation circuit 13 in accordance with an instruction from the control microcomputer 12. Turn on and off. A clock generation circuit 15 that supplies a reference clock signal is connected to the control microcomputer 12.

  A standby power supply circuit 16 for supplying operating power is connected to the remote control light receiving circuit 11, the control microcomputer 12, and the clock generation circuit 15. The main power supply circuit 14 and the standby power supply circuit 16 are connected to a commercial power supply via a main power switch 17.

  The restart signal generation circuit 18 operates with the operating power supplied from the standby power supply circuit 16, generates a start signal according to a specific remote control pulse code from the remote control light receiving circuit 11, and restarts the control microcomputer 12. It is like that.

  Next, the operation of the power saving apparatus will be described. First, the main power switch 17 is turned on, and commercial power is supplied to the main power circuit 14 and the standby power circuit 16. At this time, the main power circuit 14 The power supply mode generated by the control microcomputer 12 is turned off by the remote control pulse code for power operation supplied from the remote control light receiving circuit 11, and the operation power is supplied from the main power supply circuit 14 to the signal processing / operation circuit 13. In addition, operating power is supplied from the standby power supply circuit 16 to the remote control light receiving circuit 11, the control microcomputer 12, the clock generation circuit 15, and the restart signal generation circuit 18. Hereinafter, this state is referred to as a standby state of the electronic device.

  In the standby state of the electronic device, since the operating power is supplied to the remote control light receiving circuit 11, the control microcomputer 12, the clock generation circuit 15, and the restart signal circuit generation circuit 18, the remote control light reception circuit 11 and the restart signal generation circuit are supplied. 18, power of several mW is consumed, and a current of several tens mA or more flows between the control microcomputer 12 and the clock generation circuit 15, and power of at least 100 mW is consumed.

  In the power supply mode in which the main power supply circuit 14 is turned off, supply of the reference clock signal from the clock generation circuit 15 to the control microcomputer 12 is stopped, and only power for memory backup of the control microcomputer 12 is supplied from the standby power supply circuit 16. In the power saving mode, the power supply current of the control microcomputer 12 is 1 μA or less, and the power consumption is about several μW. As described above, when the main power supply circuit 14 is turned off, the reference clock signal from the clock generation circuit 15 supplied to the control microcomputer 12 is stopped, and further, the power supply from the standby power supply circuit 16 to the clock generation circuit 15 is stopped. By stopping the operation, the control microcomputer 12 enters the power saving mode.

  The control microcomputer 12 can cancel the power saving mode at the edge of the rising signal input to the dedicated terminal provided for this, and after the transition to the power saving mode, the control microcomputer 12 starts from the restart signal generation circuit 18. The restart signal is supplied to the 12 dedicated terminals to cancel the power saving mode and shift to the standby mode.

  The operation of the restart signal generation circuit 18 will be described in detail with reference to the signal waveform diagram of FIG. FIG. 4A is an operation waveform showing a remote control pulse code received by the remote control light receiving circuit 11 and output to the control microcomputer 12 by a key operation of a remote control transmission means (not shown). In the period of time t0 to t3 in the figure, the output of the remote control light receiving circuit 11 indicates a non-output state. Time t3 indicates the output start position from the remote control light receiving circuit 11.

  The 9 ms (millisecond) period from time t3 to t4 is the leader part of the remote control pulse code, and the 54ms period from time t5 to t6 is the pulse string period of the remote control pulse code, which is expressed by a 32-bit remote control pulse code string. The The period from time t4 to t5 is a period for clarifying the division between the leader portion and the pulse train.

  That is, the main power supply circuit 14 is turned on / off based on the leader portion output from the remote control light receiving circuit 11 at time t3 to t4 and the contents of the pulse train for the period from time t5 to t6 4.5 ms after time t4. The operation of the signal processing / operation circuit 13 including the above is controlled.

  When the power key of the remote control transmission means is pressed, such a remote control pulse code is output and the main power supply circuit 14 is turned off. Then, the power supply from the main power supply circuit 14 to the signal processing / operation circuit 13 is stopped and enters a standby state, and when the supply of the reference clock signal from the clock generation circuit 15 to the control microcomputer 12 is stopped, the control microcomputer 12 is saved. Power mode is entered.

  Next, the timing at which the main power supply circuit 14 is turned off and the control microcomputer 12 restarts the standby mode from the power saving mode will be described with reference to FIG.

  In order to restart the control microcomputer 12 from the power saving mode to the standby mode, during the period of time t0 to t3 before the start of the leader portion of the time t3 of the remote control pulse code waveform of the normal operation shown in FIG. A remote control pulse code format with a restart pulse of about 200 ms is used.

  When the remote control pulse code to which the restart pulse is added is transmitted from the remote control transmission means, the remote control light receiving circuit 11 receives this and the received signal is supplied to the control microcomputer 12 and the restart signal generating circuit 18. . On the other hand, the control microcomputer 12 cannot decode the remote control pulse code with the restart pulse because of the power saving mode state.

  The restart signal generation circuit 18 detects a restart pulse in the period of time t0 to t3 in the supplied remote control pulse code with a restart pulse, and generates a rising pulse based on the detected restart pulse, The power is supplied to the control microcomputer 12 to cancel the power saving mode. The restart signal generation circuit 18 is constituted by an integration circuit, a monostable multivibrator and the like, and the time constant T of the integration circuit is set to about 100 ms.

  A trigger signal is generated when a restart pulse is present within the 100 ms period, and a rising pulse is generated from the trigger signal by a monostable multivibrator. The state of occurrence of this rising pulse is shown in FIG. By the restart pulse in the period from time t0 to t2 shown in FIG. 4B, a rising pulse is generated at time t1 from time t0 to 100 ms of time constant T.

  The rising pulse generated by the restart signal generation circuit 18 is supplied to the control microcomputer 12 as a restart signal. As shown in FIG. 4 (d), the control microcomputer 12 to which the rising pulse has been input cancels the power saving mode at the timing of time t1, supplies the reference clock signal from the clock generation circuit 15, and sets the oscillation clock frequency. The standby mode is started again at the timing of time t2 after the warming-up is stabilized. Then, the control microcomputer 12 reads the remote control pulse code from the timing of time t3.

  At this time, when a pulse code for turning on the power supply of the main power supply circuit 14 is output from the remote control light receiving circuit 11, the control microcomputer 12 outputs a signal for turning on the main power supply circuit 12, and the signal processing / operation circuit 13 is supplied with the operation power supply. Supply is started, and the electronic device starts normal operation (see, for example, Patent Document 1).

  By the way, as a drawback of a remote control using infrared rays, there are cases where it is affected by infrared rays from the natural world such as sunlight and other adjacent devices such as fluorescent lamps. These occur because they contain light having a wavelength close to the infrared wavelength used for the remote control. In addition, there is a strong infrared due to sunlight during the day, but it decreases at night. In addition, there is a problem that the level of such a noise signal constantly fluctuates, such as the intensity of infrared rays from the fluorescent lamp varies greatly depending on whether the fluorescent lamp is turned on or off.

  Therefore, if the reception sensitivity of the remote control receiver is lowered in advance in order to cope with this problem, the level of the actual remote control signal is also lowered, resulting in a short reach and a difficult remote control. Conversely, if the reception sensitivity of the remote control receiver is increased in advance, the above-described unnecessary infrared light is also amplified and received, and as a result, the unnecessary infrared signal and the remote control signal cannot be distinguished.

  For this reason, remote control receivers equipped with an AGC (Aouto Gain Control) circuit have recently become widespread, and the reception sensitivity of the remote control receiver is automatically changed according to the brightness of the surrounding infrared light. The optimum reception sensitivity is maintained.

  However, generally, the operation of the AGC circuit does not react excessively, but operates after a certain delay time after the reception level changes. That is, even if the ambient brightness changes, the reception sensitivity corresponding to the changed brightness is maintained for a certain time (delay time). For this reason, when a long restart pulse (on time of 130 mS) as described above is received, the surroundings are erroneously recognized as bright, and the reception sensitivity remains lowered for a certain period of time (charging delay time). Then, when a certain time (discharge delay time) elapses after the restart pulse disappears, the sensitivity shifts to the reception sensitivity corresponding to the level of the infrared ray received at that time.

  Therefore, if the AGC charging delay time elapses while a long restart pulse is received, the reception sensitivity changes according to the reception level of the restart pulse. Since this restart pulse is a signal having a relatively high reception level, the AGC circuit shifts in the direction of lowering the reception sensitivity, and maintains this low reception sensitivity for a certain time (discharge delay time).

  If the original remote control signal following the restart pulse is received in this state, the reception sensitivity may remain low, or the transition of the reception sensitivity transition due to AGC may occur. In some cases, normal remote control pulse codes cannot be received.

  For this reason, there is a problem that the reach of the remote control signal is shortened as a result. Furthermore, the transmission of the long restart pulse as described above means that the infrared light emitting element of the remote control transmitter is driven during this time, and the battery consumption of the remote control transmitter is accelerated. there were.

Japanese Patent Laid-Open No. 11-272371 (page 4-5, FIG. 2)

  The present invention solves the above-described problems, receives a remote control signal with a start signal added at the head, and allows a remote control receiver circuit equipped with an AGC circuit to function normally with the AGC function, An object is to reduce battery consumption of a remote control transmitter.

In order to solve the above-described problems, the present invention converts a received infrared ray to output an electrical signal, an amplification circuit that amplifies the electrical signal, extracts a remote control signal from the amplified electrical signal, and outputs the remote control signal. An automatic gain control (AGC) circuit that automatically adjusts the sensitivity of the amplifier circuit after a predetermined delay time (charge delay time or discharge delay time) after the level of the electrical signal changes, and the input remote control signal again. A pulse detection circuit for extracting only a start pulse and outputting it as a start signal; and a control means for extracting a remote control code from the input remote control signal, comprising a clock signal oscillation circuit for oscillating a clock stopped by the start signal. Remote control signal receiving circuit,
The remote control signal is composed of an on portion where the signal is turned on, a restart pulse composed of the following off portion, and a pulse representing the remote control code following the restart pulse,
The ON portion time <the charging delay time and the OFF portion time> the discharge delay time.

Alternatively, the remote control signal received using infrared is amplified according to auto gain control (AGC) that automatically adjusts the sensitivity of the received infrared after a predetermined delay time (charge delay time or discharge delay time) after the reception level changes. Is a remote control signal receiving system that oscillates the clock stopped by the restart pulse included in the remote control signal and restarts the control means, and the control means extracts the remote control code from the remote control signal,
The remote control signal is composed of an on portion where the signal is turned on, a restart pulse composed of the following off portion, and a pulse representing the remote control code following the restart pulse,
The ON portion time <the charging delay time and the OFF portion time> the discharge delay time.

  Further, the off-part time is made longer than the on-part time.

By using the above means, according to the remote control signal receiving circuit according to the present invention and the remote control signal receiving system used therefor, the invention according to claim 1 and claim 3,
Without being affected by a predetermined delay time (charge delay time or discharge delay time) of the AGC circuit, the remote control code following the restart pulse can be received correctly and without lowering the sensitivity.

  In the inventions according to claim 2 and claim 4, by setting the off part time longer than the on part time, the duty ratio of the on part time of the restart pulse is reduced, and the remote control transmitter The driving time of the infrared light emitting element can be reduced, and the battery consumption of the remote control transmitter can be reduced compared to the timing described in the background art.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail as examples based on the attached drawings. The feature of the present invention is that the timing of the restart pulse added to the head of the normal remote control signal is determined in consideration of the delay time of the AGC circuit.

FIG. 1 is a schematic block diagram of an infrared remote control receiving circuit according to the present invention.
This remote control receiving circuit includes a photoamplifier 1 that receives an infrared remote control signal transmitted from a remote control transmitter (not shown), and a microcomputer 2 that is connected to an input port of a remote control signal output from the photoamplifier 1 and that comprises control means. And a pulse detection circuit 6 for inputting a remote control signal output from the photoamplifier 1 and connecting the output signal to an interrupt terminal (INT) of the microcomputer 2 to pass only pulses having a predetermined width or more.

  The photoamplifier 1 converts a received infrared ray to output an electric signal, an amplifying circuit 1c for amplifying the electric signal, extracting a remote control signal from the amplified electric signal, and outputting it, and a level of the electric signal And an auto gain control (AGC) circuit 1b that automatically adjusts the sensitivity of the amplifier circuit 1c after a predetermined delay time (charging delay time or discharging delay time) since the change of.

  Note that a power circuit (not shown) is connected to all these circuits, and power is always supplied. However, when the microcomputer 2 is in the power saving mode in which the clock is stopped, the power consumption is hardly consumed. Further, the microcomputer 2 outputs a control signal to a signal processing / operation circuit (not shown) and a main power supply circuit. Since these operations have been described in the background art, a detailed description thereof will be omitted.

  The pulse detection circuit 6 includes an inverter 3 to which an input signal is connected, a resistor 4 having one end connected to the output of the inverter 3, and a capacitor having one end connected to the other end of the resistor 4 and the other end grounded. 5 and an inverter 7 whose input is connected to the other end of the resistor 4 and whose output is connected to the interrupt terminal (INT) of the microcomputer 2.

  The photoamplifier 1 includes an AGC circuit that automatically adjusts the reception sensitivity, and maintains an optimum reception sensitivity corresponding to the surrounding brightness. The AGC circuit is designed to change with a certain delay time with respect to fluctuations in the input infrared signal level so that it does not react with instantaneous noise (infrared rays).

This delay time is generally set to about several tens of milliseconds (milliseconds) in consideration of various factors. This delay time is classified into a charge delay time when a signal is input and a discharge delay time when there is no signal.
In this embodiment, the delay time of the AGC circuit will be described as an example of the photoamplifier 1 in which charge delay time = discharge delay time = 50 mS.

  The resistor 4 and the capacitor 5 in the pulse detection circuit 6 constitute a time constant circuit of about 20 mS, and only the restart pulse described in the background art is extracted from the infrared signal received by the integration operation, and 20 mS. The following noise is cut.

  The microcomputer 2 has a power saving mode, and is configured such that almost no power is consumed when it is stopped by stopping the built-in clock signal oscillation circuit 2a. Further, once the clock signal oscillation circuit 2a is stopped by an instruction of the microcomputer 2 itself, the microcomputer 2 itself cannot restart the clock signal oscillation circuit 2a. Therefore, in order to start the clock signal oscillation circuit 2a and return the microcomputer 2 to the normal operation, a start signal from the outside is necessary.

  The INT terminal of the microcomputer 2 is an acceptance terminal for the activation signal. When a falling signal is input to this terminal in the power saving mode, the internal clock signal oscillation circuit 2a is activated. Note that clock oscillation starts when a falling signal is input to the INT terminal, but the signal level and frequency are not stable until a certain time has passed. This time is generally about 20 to 30 mS. Therefore, the microcomputer 2 actually starts processing after a warm-up period of about 30 mS has elapsed after the falling signal is input to the INT terminal. It becomes.

  As described above, when the internal clock signal oscillation circuit 2a is activated and the microcomputer 2 starts normal operation, the remote control signal input from the input port of the microcomputer 2 can be decoded. Or a connected device such as an air conditioner motor or a display device is driven. The microcomputer 2, the photoamplifier 1, the inverters 3, 7 and the like are always supplied with power by a power circuit (not shown). Since these operations have been described in the background art, a detailed description thereof will be omitted.

  Next, the timing of the remote control receiving circuit described above will be described with reference to the time chart of FIG. FIG. 2A shows an infrared remote control signal output from the photoamplifier 1 and is represented by active low. FIG. 2B shows the sensitivity of the amplifier circuit 1c controlled by the AGC circuit 1b. The upper direction indicates high sensitivity and the lower direction indicates low sensitivity. 2C shows the voltage of the time constant circuit of the pulse detection circuit 6, and FIG. 2D shows the signal at the INT terminal of the microcomputer 2. 2E shows a clock oscillation waveform of the clock signal oscillation circuit 2a, and FIG. 2F shows a transition state of each mode of the microcomputer 2.

  FIG. 2A shows a state in which a restart pulse of 140 mS is added to the head of a remote control code (a plurality of pulse trains following the reader signal) that is a remote control signal that the microcomputer 2 receives during normal operation. The restart pulse is composed of an ON portion (t2 = 40 mS) in which the signal is at a low level, that is, an ON state, and an OFF portion (t3 = 100 mS) in which the signal is at a high level, that is, an OFF state. .

  As described above, the restart pulse is a pulse used only to cancel the microcomputer 2 when the microcomputer 2 is in the power saving mode. When the microcomputer 2 is in a normal operation, only the remote control code portion is not shown. Sent from Therefore, in general, the pulse is transmitted only when the power button of the remote control transmitter is pressed to turn on the main power of the target device.

  2B shows the AGC sensitivity by the AGC circuit 1b when the remote control signal of FIG. 2A is output from the photoamplifier 1. FIG. When the level of the infrared signal input to the photoamplifier 1 is large and the signal is continuous, the sensitivity is lowered, and when there is no infrared signal, the sensitivity is increased. As described above, the AGC circuit 1b has a delay time of charging delay time t5 = 50 mS that works when the sensitivity is lowered and a discharge delay time t5 ′ = 50 mS that works when the sensitivity is raised. The change in sensitivity level will appear after the delay time has elapsed.

  FIG. 2C shows a change in the integrated voltage of the pulse detection circuit 6 when the remote control signal by infrared rays in FIG. 2A is input to the photoamplifier 1. This integration circuit is set to a time constant of 20 mS depending on the values of the resistor 4 and the capacitor 5. This is to remove 50 Hz noise of the fluorescent lamp in which the peak of the commercial power supply voltage is repeated every 10 mS. Naturally, in the case of 60 Hz, since the peak of the commercial power supply voltage is every 8 mS, noise can be similarly removed.

  Since the voltage of this integrating circuit is input to the inverter 7, it is switched on and off at the threshold value consisting of the threshold voltage of the inverter 7, and the waveform shown in FIG. 2D is obtained. As described above, since ON and OFF are switched at the threshold, the noise integrated by the pulse detection circuit 6 does not reach this threshold and is therefore completely removed.

  The same applies to the remote control signal of the remote control code output from the remote control transmitter. In general, even the longest leader signal in the remote control code is around 9 mS, and even the entire remote control code including this leader signal does not reach the threshold value as a result of integration by the integration circuit. Is not output from.

  FIG. 2E shows a clock oscillation waveform in the clock signal oscillation circuit 2 a built in the microcomputer 2. In response to the fall of the restart pulse signal in FIG. 2D, an oscillation start signal is output from the INT terminal of the microcomputer 2 to the clock signal oscillation circuit 2a of the microcomputer 2, and the clock starts to oscillate correspondingly. However, as described above, the clock is not stable unless the clock oscillation warm-up time (t4 = 30 mS) elapses.

  FIG. 2 (F) shows the state of the microcomputer. From the power saving mode in which the clock oscillation is stopped, the clock oscillation is started by inputting the restart pulse, the normal operation is performed after the warm-up period, and the remote control code is waited for. The state leading to the uptake is shown.

  In FIG. 2, the restart pulse ON portion (t2 = 40 mS) passes through the pulse detection circuit 6, is delayed by the time constant (t1 = 20 mS) of the pulse detection circuit 6, and is set as the start pulse (t2 ′ = 40 mS). 2 is input to the INT terminal. The clock of the microcomputer 2 starts oscillating at the fall of the start pulse, and the microcomputer 2 starts normal operation after a warm-up period (t4 = 30 mS).

  When the microcomputer 2 starts normal operation, it waits for the remote control code following the restart pulse by monitoring the input port. At this time, since only 50 mS (t1 + t4) has passed since the fall of the restart pulse of the remote control signal, there is a margin of 90 mS (t2 + t3-t1-t4) until the fall of the leader signal, which can be handled sufficiently.

  On the other hand, the AGC sensitivity is temporarily reduced by the on-time of the restart pulse, but after 100 mS (t5 + t5 ′), it has returned to the original sensitivity, and the remote control code following the 140 mS restart pulse (t2 + t3) There is no impact.

The timing described above is expressed as a relational expression as follows. T1: Time constant of the pulse detection circuit, t2: ON part of the restart pulse, t3: OFF part of the restart pulse, t4: Warming up period, t5: Charge delay time of the AGC circuit, t5 ′: Discharge of the AGC circuit Defined as delay time.

Reactivation pulse = t2 + t3

Further, in order to restore the original sensitivity by turning on / off the restart pulse, the relationship between the charge delay time and the discharge delay time of the AGC circuit 1b needs to be as follows.

t2 <t5 and t3> t5 ′... Formula 2

In other words, the meaning of Equation 2 is

ON section time <charge delay time and OFF section time> discharge delay time Formula 3

It becomes. Also,

t2> t1 ..... formula 4

Need to be satisfied at the same time. That means

ON time of restart pulse> Time constant time of pulse detection circuit ・ ・ ・ ・ Formula 5

It becomes.

Further, the charging delay time t5 in the AGC circuit 1b requires a longer time than the on-time t2 of the restart pulse. If it is short, the AGC sensitivity decreases during reception of the ON portion of the restart pulse, and in the worst case, the latter half of the ON portion of the restart pulse may not be received. Therefore, the following relationship must be maintained.

t5> t2 or at worst t5 = t2

On the other hand, generally, the delay time of the AGC circuit 1b of the photoamplifier 1 is mostly generated using an analog integration circuit. As a characteristic of the analog integration circuit, the discharge time tends to be longer than the charge time. Therefore,

The relationship is t5 <t5 ′. Here, if the discharge time can be set to the shortest,
t5 = t5 '(7)

Here, considering Equation 6 and Equation 7, t5 = t5 ′ = t2... Equation 8

On the other hand, the restart pulse needs to be larger than the sum of the charge delay time and the discharge delay time. Therefore,

Reactivation pulse> t5 + t5 '... Equation 9

Further, when Expression 1 is substituted into Expression 9, t2 + t3> t5 + t5 ′... Expression 10

Therefore, when Equation 10 is transformed,

t3> t5 + t5'-t2 (11)

It becomes. Here, when Expression 8 is substituted into Expression 11, t3> t2 + t2-t2 is obtained, and finally, as follows.

t3> t2... Equation 12

This means the following conditions.

OFF time of restart pulse> ON time of restart pulse: Equation 13

  Thus, if the restart pulse satisfies Expression 3, it is not affected by the delay time of the AGC circuit 1b of the photoamplifier 1, and the remote control code following the restart pulse is correct and the sensitivity is not lowered. Can be received. Further, from the relationship of Equation 13, since the duty ratio of the on-time of the restart pulse is reduced, the driving time of the infrared light emitting element of the remote control transmitter can be reduced, and the remote control transmitter can be compared with the conventional timing. Battery consumption can be reduced.

  In this embodiment, the remote controller signal receiver of the air conditioner is described. However, the present invention is not limited to this, and any remote controller using infrared rays can be widely applied to general home appliances having a power saving mode. Can do.

  In the present embodiment, the AGC circuit 1b is built in the photoamplifier 1. However, the present invention is not limited to this. Even if the AGC circuit 1b is provided outside the photoamplifier 1, the same effect can be obtained. it can.

It is a block diagram explaining the remote control signal receiving circuit by this invention. It is a time chart which shows the timing of the remote control signal of the remote control signal receiving circuit by this invention. It is a block diagram of the power saving apparatus using the conventional remote control signal receiving circuit. It is a time chart which shows the timing of the conventional remote control signal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Photo amplifier 1a Light receiving element 1b Amplifying circuit 1c AGC circuit 2 Microcomputer (control means)
2a Clock signal oscillation circuit 3 Inverter 4 Resistor 5 Capacitor 6 Pulse detection circuit 7 Inverter

Claims (4)

A light receiving element that converts input infrared light and outputs an electrical signal, an amplification circuit that amplifies the electrical signal, extracts a remote control signal from the amplified electrical signal, and outputs the remote control signal; and after the level of the electrical signal changes An auto gain control (AGC) circuit that automatically adjusts the sensitivity of the amplifier circuit after a predetermined delay time (charge delay time or discharge delay time), and only a restart pulse is extracted from the input remote control signal and output as a start signal A remote control signal receiving circuit comprising a pulse detection circuit and a clock signal oscillation circuit for oscillating a clock stopped by the start signal, and a control means for extracting a remote control code from the input remote control signal;
The remote control signal is composed of an on portion where the signal is turned on, a restart pulse composed of the following off portion, and a pulse representing the remote control code following the restart pulse,
A remote control signal receiving circuit, wherein the ON part time <the charge delay time and the OFF part time> the discharge delay time.   The remote control signal receiving circuit according to claim 1, wherein the off portion time is longer than the on portion time. The remote control signal received using infrared is amplified according to auto gain control (AGC) that automatically adjusts the sensitivity of the received infrared after a predetermined delay time (charge delay time or discharge delay time) after the reception level changes, The control means is restarted by oscillating a clock that has been stopped by a restart pulse included in the remote control signal, and the control means is a remote control signal receiving system that takes out a remote control code from the remote control signal,
The remote control signal is composed of an on portion where the signal is turned on, a restart pulse composed of the following off portion, and a pulse representing the remote control code following the restart pulse,
A remote control signal receiving system characterized by the relationship of the ON part time <the charge delay time and the OFF part time> the discharge delay time.   4. The remote control signal receiving system according to claim 3, wherein the off part time is longer than the on part time.

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