KR830000768B1 - Remote control device - Google Patents

Abstract

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Description

Remote control device

FIG. 1 is a configuration diagram of a receiving side of a remote control apparatus according to an embodiment of the present invention; FIG.

FIG. 2 is a waveform diagram of the first portion of FIG.

FIG. 3 is a connection diagram of a transmitter according to an embodiment of the present invention; FIG.

FIG. 4 is a cross-sectional view of an operation switch used in a transmitter. FIG.

5 is a partial access view of one embodiment of the present invention.

FIG. 6 is an important partial connection view of another embodiment of the present invention. FIG.

7 is a connection diagram of another embodiment of the present invention.

FIG. 8 is a connection diagram for explaining an operation of another embodiment of the present invention; FIG.

The present invention relates to a power supply of a television receiver. And more particularly, to a remote control apparatus used for remote control of remote control from a remote position, in particular, to a remote control apparatus capable of preventing a malfunction due to noise and at the same time being capable of remote operation.

Hereinafter, an embodiment of the present invention will be described with reference to FIG. 5 of the first drawing.

1, the receiving microphone 1 receives a carrier wave of an ultrasonic wave transmitted from a transmitter, and the amplifier 2 amplifies a signal from the receiving microphone 1. In FIG. Carrier wave of ultrasound that is received here is formed of a signal and its continuous signal of frequency f ₂ is the frequency f _1, as shown in the Figure 2a.

The transmitter for transmitting such ultrasonic wave carrier is constructed as shown in FIG. 3 shows a DC power source 11, a transistor 12 constituting an oscillator, a capacitor 13, an oscillation coil 14, an oscillation capacitor 15a (15b), a transmission for converting an electric signal into an ultrasonic wave A microphone 16, and an operation switch 17 provided in the transmitter. The operation switch 17 is structured as shown in detail in FIG.

FIG. 4 shows a case 18 of the operation switch 17, a terminal plate fixed to one side of the case 18, and a sliding body 20 sliding inside the case 18. A handle 22 is provided in front of the operation handle 21 and a spring 23 is provided between the handle 22 and the case 18 It is burnt. Two plate-like fixed contacts parallel to the longitudinal direction in the case 18 are provided from the terminal board 19 and four fixed contacts 24a, 24b, 24c, 24d and 25a ) 25b, 25c, and 25d. The external terminals 26a, 26b, 26c, 26d, 27a, 27b, 27c, 27d connected to these fixed contacts are provided on the terminal plate 19. [ The movable contacts 28 and 29, which are in contact with the two contact points, are provided so as to be integrally slid with the movable contact 20 with respect to the fixed contacts of the respective rows.

The fixed contacts 24a and 24b are connected by the movable contact 28 and the fixed contacts 24a and 24b are fixed by the movable contact 29 while the ordinary handle 22 is not pressed at all. And the contacts 25a and 25b are connected. Next, when the knob 22 is depressed, the fixed contacts 24a and 24c are connected by the movable contact 28 and the fixed contacts 25a and 25c are connected by the movable contact 29 at the same time. The fixed contacts 24a and 24b are connected by the movable contact 28 and the fixed contacts 25a and 25b are connected by the movable contact 29 at the same time when the handle 22 is pressed to a position where the handle 22 is not pressed . Thus, the operation switch 17 has three connection states: the first state in which the knob 22 is not pressed at all, the second state in which the knob 22 is pressed to some extent, and the third state in which the knob 22 is pushed to the final position .

Determines the ultrasonic transmission time of f ₁ as described later according to the time in the second state and accordingly determines the delivery time of the frequency f ₂ ultrasonic wave in accordance with the time in the third state.

3, the fixed contact 24a (25a) of the operating switch 17 is grounded, and when the handle 22 is not pressed, the fixed contact 24a (25a) The fixed contacts 24b and 25b connected to the first and second terminals 25a and 25a are not electrically connected. The fixed contacts 24c and 24d are connected to the negative electrode side of the DC power supply 11 so that the fixed contacts 25c are not electrically fixed and the fixed contacts 25d are connected to the oscillation condensers 15b do.

이 된다. 그 다음 조작스위치(17)의 접점(24a)(24d)과 접점(25a)(25d)가 접속되고, 발진기의 발진동작은 지속되지만, 이때의 발진주파수 f₂는 발진 콘덴사(15a) 및 발진코일(14)이외에도 발진콘덴사(15b)에도 영향을 주고, 이 발진콘덴사(15b)의 값을 C₂로 하는 경우에

이 된다. 이와 같이 하여 제2a도에 도시된 바와같이, 주파수 f₁반송파에 주파수 f₂반송파가 연속신호로 송출된다.In the state in which the handle 22 of the operation switch 17 is not pressed at all (state shown in Fig. 3), the oscillator does not operate and therefore no ultrasonic wave is transmitted from the transmitter micro- Do not. When the handle 22 of the operating switch 17 is pressed, the negative side of the DC power supply 11 is grounded and the oscillation operation is started. The oscillation frequency f _{1 in} this case is determined by the value C ₁ of the oscillation capacitor 15a and the value L of the oscillation coil 14,

. The next operation is the contact (24a), (24d) and the contact (25a), (25d) of the switch 17 are connected, the oscillating operation of the oscillator is continued, but this time the oscillation frequency f ₂ is the oscillation cone densa (15a) and the oscillation When the oscillation condenser 15b is affected in addition to the coil 14 and the value of the oscillation condenser 15b is C ₂

. Thus, as shown in FIG. 2A, the frequency f ₂ carrier is transmitted as a continuous signal to the frequency f ₁ carrier.

을 특별히 강하게 하는 일 없이 손잡이(22)를 가벼운 힘으로 조작할시 가동접점(28) 및 (29)가 고정접점(24c)(25c)에 접촉되어 있는 시간으로 선정한다. 경험적으로 조작스위치(17)의 고정접점(24c)(25c)을 제4도에 도시된 바와같이 충분히 길게 함으로써, 조작을 신속히 할지라도 30ms의 시간을 필요로 한다. 결국 주파수 f₁반송파의 지속시간 t₁은 최소 30ms로 된다. 한편, 주파수 f₂반송파의 지속시간 t₂는 원격조작시에 조작자가 원격조작동작의 완료하는, 즉 텔레비젼 수상기의 전원이 인가되는 것을 확인하고 조작스위치(17)의 손잡이(22)로부터 손을 떼는 시간으로 그 시간이 길다. 결국, 주파수 f₂반송파의 지속시간 t₂는 주파수 f₂반송파가 송출되는 시점으로부터 원격조작으로 인하여 일어나는 동작이 완료되는 지점까지의 시간이다.In the present invention, is longer than the duration t _{2 of the} carrier wave of the frequency f ₂ as compared with the duration t ₁ of the carrier f ₁ . In this case, the duration t ₁ of the carrier wave of the frequency f ₁ is equal to the eccentricity of the spring 23 of the operating switch 17

Is selected as the time when the movable contacts 28 and 29 are in contact with the fixed contacts 24c and 25c when the handle 22 is operated with a light force without particularly strengthening the handle 22. By empirically putting the fixed contacts 24c and 25c of the operation switch 17 sufficiently long as shown in FIG. 4, a time of 30 ms is required even if the operation is quick. As a result, the duration t ₁ of the carrier wave of frequency f ₁ is at least 30 ms. On the other hand, the duration t ₂ of the carrier wave of the frequency f ₂ indicates that the remote control operation is completed by the operator at the time of remote operation, that is, the power supply of the television receiver is applied and the handle 22 of the operation switch 17 is released The time is long. After all, the duration of the frequency f ₂ carrier t ₂ is the time to the point at which the operation takes place due to remote operation from the point at which the carrier frequency f ₂ is transmitted is complete.

The ultrasonic waves transmitted in this manner and received by the receiving microphone 1 are converted into electric signals, amplified again, and then supplied to the band pass filters 3a and 3b. A band-pass filter (3a) the frequency f ₁ carrier is detected by the detection circuit (4a), the detection output shown in the 2b also from the detection circuit (4a) is generated, the same band-pass filter (3b) separated by a the carrier frequency f ₂ are separated by, and detected by the detection circuit (4b), a detection output is shown in the Figure 2f is generated from the detection circuit (4b). These detection outputs are individually supplied to the noise cancellation circuits 5a and 5b.

The noise elimination circuits 5a and 5b are composed of integration circuits 6a and 6b and level determination circuits 7a and 7b, respectively. When the detection output shown in FIG. 2 (b) is supplied to the noise eliminating circuit 5a, the waveform shown in FIG. 2 (c) appears on the output of the integrating circuit 6a, and the waveform level is detected by the level detection circuit 7a V _T , the square wave shown in Fig. 2 (d) is generated, and the flip flop 8 is set in the rising edge of the square wave.

This square wave is generated after the time T ₁ because the detection output is supplied to the noise removing circuit 5a. As a result, even if the detection output, that is, the noise, which does not last more than the time T ₁ is supplied to the noise cancellation circuit 5a, no output is generated from the noise cancellation circuit 5a. The time T ₁ in this sense is defined as the noise removal time and is determined by the detection level V _T and the time constant of the integration circuit 6a. The noise elimination circuit 5b to which the detection output of the detection circuit 4b shown in FIG. 2f is supplied is also generated from the integration circuit 6b as shown in FIG. 2g like the noise elimination circuit 5a, The level of the integration circuit 6b is generated at the output shown in the second h-th diagram at the time when it exceeds the detection level V _T of the level discrimination circuit 7b and the flip flop 8 Is reset.

In the present invention, a time longer than the noise removal time T ₁ of the noise removal circuit 5a for the carrier f _{1 is selected} before the noise removal time T ₂ of the noise removal circuit 5b with respect to the frequency f ₂ carrier to be transmitted later.

Therefore, the output of the noise eliminating circuit 5a is stored in the memory-storing circuit, that is, the flip-flop 8, of the signal shown in Fig. 2d, and the output of the flip- The output is obtained, and the signal shown second h later becomes a logical " 0 " level at the time of arrival. The output of the flip flop 8 and the output of the noise elimination circuit 5b shown at 2h are supplied to the AND gate 9 and thus the output terminal 10 formed by the output terminal of the AND gate 9 The remote control signal shown in the second diagram is displayed and controlled such that the power of the television receiver is applied by the remote control signal.

Thus the present invention the frequency f ₁ carrier duration t, so compared to the _first and hold the duration of the carrier wave of the frequency f ₂ frequency f noise reduction time for a _first carrier T ₁ noise suppression for the frequency f ₂ carrier relative to time t in the ₂ can be lengthened, so that malfunction due to noise can be prevented more reliably.

5 shows concrete connections of the detection circuits 4a and 4b, the noise elimination circuits 5a and 5b, and the flip-flop circuit 8 of the instant embodiment of the present invention. As a result, the detection circuit 4a is constituted by the transistor 30a in which the con- tent 31a is inserted between its collector and ground. The noise eliminating circuit 5a has its emitter grounded and its collector is connected to the resistor 32a And a transistor 34a connected in series with a collector 33a having a relatively large capacity at the collector and grounding time while the flip flop 8 is connected to the power supply terminal + And 36 are connected to each other. The collector of the transistor 30a of the detection circuit 4a is connected to the base of the transistor 34a of the noise elimination circuit 5a and the connection point of the resistor 32a and the condenser 33a of the noise elimination circuit 5a And is connected to the base of the transistor 35 of the flip flop 8. On the other hand, the detection circuit 4b and the noise removal circuit 5b have the same configuration as the detection circuit 4a and the noise removal circuit 5a. The level discrimination circuits 7a and 7b are not particularly provided in the noise elimination circuits 5a and 5b shown in FIG. 5, but in the case of the noise elimination circuit 5b, the transistor 35 of the flip flop 8, A sufficient level for making the diode of the AND gate 9 turn on is the detection level and in the case of the noise canceling circuit 5b the detection level is a sufficient level for making the diode of the end gate 9 off.

In the configuration shown in FIG. 5, the negative detection output from the detection circuit 4a related to the frequency f ₁ carrier is supplied to the base of the transistor 34a of the noise removal circuit 5a. Therefore, the transistor 34a in the on state is turned off, and the potential of these connection points, that is, the base potential of the transistor 35 is raised as a time constant determined by the resistor 32a and the capacitor 33a. (About 0.7 V), the transistor 35 of the flip flop 8 is turned on and the transistor 36 is turned off. On the other hand, the noise elimination circuit 5b operates in the same manner also in the frequency f ₂ carrier.

The individual noise elimination times T ₁ and T ₂ of the noise canceling circuits 5a and 5b are determined by the time constant of the resistor 32a and the capacitor 33a and the time constant of the resistor 32b and the capacitor 33b, Lt; / RTI > At this time, letting the potential level to Vcc, the on level of the next stage to be V ₀ , the values of the resistors 32a and 32b to be R ₁ and R ₂ , and the values of the capacitors 33a and 33b to be C ₁ and C ₂ , the following equation is established.

From the equations (1) and (2), the noise removal times T ₁ and ₂ T are

. (T ₁ < T ₂ ) can be obtained by selecting (R ₁ C ₁ <R ₂ C ₂ ) as apparent from the formulas (3) and (4). If R ₁ C ₁ = R ₂ C ₂ , for example, the charging power may be different. That is, the power source for charging the condenser 33a may be made higher than the power source for charging the condenser 33b.

FIG. 6 shows another example of the present invention.

The embodiment shown in Fig. 6 is different from the embodiment shown in Fig. 6 in that not only the output of the noise elimination circuit 5a but also the output of the noise elimination circuit 5b is stored in the flip flop 8b and the end gate 9a is provided with flip- And the output of the detection circuit 5b are supplied. At the same time, the output of the flip flop 8b and the output of the detection circuit 5a are supplied to the AND gate 9b. In the case where, if the frequency f ₁ carrier carrier and then a frequency f ₂ carrier leading to continuous in the received there, is a remote control signal is obtained from an output terminal (10a) is a carrier wave of frequency f ₂ as opposed to those receiving the first output terminal (10b So that the remote operation signal is obtained.

The sixth road embodiment shown a further example, the original noise-canceling time of the noise suppression circuit (5a) and (5b) is the same as each other and they are selected for removal of the short-side noise time T _1. The diode 39b is inserted between the noise eliminating circuit 5b of the end gate 9a and the integrating circuit composed of the resistor 37b and the condenser 38b and the polarity shown in the drawing. On the other hand, a diode 39a is connected between the AND gate 9b and the noise removing circuit 5a with the polarity shown in the figure, which is an integrating circuit composed of a resistor 37a and a condenser 38a. Wherein the resistor (37a) and a cone the time constant of the integrating circuit to densa (38a) and a resistor (37b) and the cone the time constant of the integrating circuit to densa (38b) are equal to each other, all of which are longer than the noise suppression time to T ₂ .

In a further embodiment of the present invention shown in FIG. 6, for example, when a frequency f ₂ carrier following the frequency f ₁ carrier is received, the detected output of the carrier f ₁ is supplied to the resistor 32a and the condenser 33a Is distinguished from the noise by the determined noise elimination time T ₁ , and is stored in the flip flop 8a. The detected output of the frequency f ₂ carrier is separated from the noise by the noise elimination time T ₂ determined by the resistor 37b and the condenser 38b, and then supplied to the end gate 9a. Since the output (high level) of the flip flop 8a is supplied to the AND gate 9a, the output terminal 10a becomes the logic high level, and the volume of the television receiver is largely controlled by the remote control signal.

At this time, the other output terminal 10b is maintained at the logic low level. When subsequently the frequency f ₁ carrier is received on frequency f ₂ carrier, it is distinguished from the noise by the noise removing time T _1, which is determined by the detection output of the frequency f ₂ carrier resistance (32b) and the cone densa (33b), the flip- And stored in the flop 8b. On the other hand, the detection output of the frequency f ₁ carrier is distinguished from the noise by the noise elimination time T ₂ determined by the resistor 37a and the condenser 38a, and is supplied to the end gate 9b. Since the output (high level) of the flip flop 8b is supplied to the AND gate 9b, the output terminal 10b is brought to the logic high level, and control is performed so that the volume of the television receiver is reduced. At this time, the other output terminal 10a is maintained at the logic low level.

In other words, another embodiment of the present invention shown in FIG. 6 may form two kinds of remote control signals according to the order in which the carriers of different frequencies are received. However, The noise is distinguished from the noise by the time T ₁ , and then the received carrier is distinguished from the noise by the long noise elimination time T ₂ . Accordingly, another embodiment of the present invention can improve the remote operability without fear of malfunction due to noise as in the embodiment of the present invention.

FIG. 7 shows an important part of another embodiment of the present invention. As in FIG. 6, two remote control signals are generated according to the order in which carriers of frequencies f ₁ and f ₂ are received, And parts corresponding to those in the drawings are denoted by the same reference numerals. 7 shows the AND gate 9a to which the output of the flip flop 8a and the output of the noise elimination circuit 5b are supplied and the output of the flip flop 8b and the output of the noise elimination circuit 5a, The end gate 9b is omitted.

7, the jitter points of the resistor 32a and the condenser 33a of the noise canceling circuit 5a are connected to the collector and the resistor of the transistor 35b of the flip flop 8b via the resistor 40a And the connection point of the resistor 32b and the condenser 33b of the noise canceling circuit 5b is connected to the collector of the transistor 35a of the flip flop 8a via the resistor 40b and the resistor 41a.

In the above-mentioned configuration, a case where a frequency f ₂ carrier is continuously received at a frequency f ₁ carrier will be described as an example. First, when a detection output of the frequency f ₁ carrier supplied to the noise reduction circuit (5a), a transistor (35b) of the flip-flop (8b) is turned off, the transistor (36b) is so turned on, the noise suppression circuit (5a) con The charging circuit for the dancer 33a is shown at 8a. Next, when the detection output of the frequency f ₂ carrier supplied to the noise reduction circuit (5b) flip-flop (8a) is already in operation by the frequency f ₁ detected output, the transistor (35a) on accordingly, while the transistor ( 35b are turned off, the charging circuit for the condenser 33b of the noise canceling circuit 5b is shown at 8b. Furthermore, the connection of the resistors shown by the dotted lines in FIGS. 8A and 8B shows a connection constituted by the off-state transistors 36a and 36b of the respective flip flops 8a and 8b.

The charging circuits for the condensers 33a and 33b shown in FIGS. 8A and 8B are compared. If the values of the matching elements match each other, the capacitor 33a is charged and the terminal voltage thereof is next The time until reaching the detection level of the stage becomes shorter than the time until the capacitor 33b is charged and the terminal voltage reaches the same detection level. As a result, the resistance value for determining the charging time constant of the condenser 33a is a resistance composite value in which the resistor 32a and the series resistors 41b and 40a are connected in parallel and the charging time constant of the condenser 33b Since the charging current of the condenser 33b is classified by the resistor 340b, the resistance value of the resistor 32b is larger than the combined resistance value. When the charging circuit shown in FIG. 8A is formed, the noise removal time of the carrier wave received _first is selected as the noise removal time T ₁ of the shorter side, and when the charging circuit shown in FIG. 8B is formed, The noise removal time in the carrier wave is selected as the long noise removal time T ₂ .

It is obvious that another embodiment of the present invention shown in FIG.

The above description is an example of a remote control apparatus using ultrasonic waves, but the present invention can also be applied to an apparatus using radio waves.

Claims (1)

As described in the description of the present invention and as shown in the drawings, different first and second signals are sequentially transmitted, the first and second signals are separately detected at the receiving side, and the first and second Is supplied from the integrating circuit and the level discriminating circuit to the first and second noise removing circuits, the output of the first noise removing circuit is supplied to the storing circuit, and the output of the storing circuit And the output of the second noise cancellation circuit is synthesized to be a remote operation signal, the second signal is transmitted longer than the first signal, and the second noise cancellation circuit Wherein the noise removal time of the second noise removal circuit is made longer than the noise removal time.

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