KR820000871B1 - Control ciruit - Google Patents

Abstract

The control circuit comprises a variable oscillator (25) from which generated oscillating frequency f1-f15 are supplied to the frequency discriminating circuit (5) through the mixer (26) by manual control signal. The oscillator and the frequency discriminating circuit are made of IC. and the variable time-constant circuit is attached externally. The circuit can be miniaturized through reducing the number of terminals and cut down cost.

Description

Control circuit

1 is a system diagram showing an example of a receiving circuit of a remote control device used in the description of the present invention.

2 and 3 are waveform diagrams for explaining the operation thereof.

4 is a schematic diagram illustrating an example of an important part of the present invention.

5 and 6 are one schematic diagram of a transmitting circuit.

When integrating a circuit having a large number of input terminals, such as a receiving circuit of a remote control device of a television receiver having an electronic tuning tuner, it is necessary to reduce the terminal on the input side to a small size and low cost. There is.

2)개인 경우, 입력측의 단자수는 N개 필요로 하지만 이 IC회로의 입력단을 매트릭스 구성으로 하면 단자수를 감소할 수가 있다. 예를들면 =8일 때 매트릭스 구성으로 하면 단자수를 두 개 삭감할 수 있다.Input information is N (N

2) In the case of individuals, the number of terminals on the input side is N, but the number of terminals can be reduced by making the input terminal of this IC circuit into a matrix configuration. For example, when the matrix configuration is set to = 8, two terminals can be reduced.

If the input information is encrypted, the above example becomes = 3, so that the number of terminals can be drastically reduced, while the encoder must be installed, but the cost is increased.

The present invention relates to a lower cost and a smaller number of terminals than encryption. First of all, the prior art is specifically illustrated to facilitate understanding of the present invention.

1 is a conventional example in the case of ICizing a part of a receiving circuit of a remote control device which takes a frequency separation scheme. (1) is a receiver of a remote control signal, (2) is an amplifying circuit, and (4) is a control circuit having a plurality of IC input terminals.

The control circuit 4 is composed of a frequency discriminating circuit 5 to which an amplified remote control signal is supplied and a tuning pulse generating circuit 6 to which a part of its output is supplied. The discriminating circuit 5 is a digital filter for frequency separation. It has a group and a plurality of detectors (not shown) to detect the filter output.

The remote control signal is a second degree that the contents to be remotely controlled as described showing an example that the frequency is different from each other in the example of the figure the frequency f ₁ of the whole power. In the off-control circuit, and the frequency f ₃ (f ₃ < f ₂ ), on the contrary, are allocated for the control for reducing the volume.

This example is allocated for control due to channel switching from different frequencies f ₄ to f ₁₅ (for 12 channels).

The frequency used in this example is up to 20-200 MHz.

The remote control signal SP (referring to the detection output) having a frequency f ₁ is supplied to the flip-flop circuit 7 so that the relay 8 is controlled. SWM is a power switch controlled by the relay 8, 9 is an AC source, and 10 is a power supply circuit of the receiver. ⑪ is a volume control circuit, and the remote control signals S _U , S _D for raising or lowering the volume are supplied to one of the AND circuits 12 _U and 12 _D , and the clock from the pulse generating circuit 13 therebetween. The pulse is supplied to the counter 14.

The parallel cryptographic signal, which is the output of the counter 14, is supplied to the PWM modulator 15 to obtain a modulated output such that the pulse width is widened by one remote control signal S _U and reduced by the remote control signal S _D on the other. . This PWM modulation output is again supplied to the integrating circuit 16 and converted into a DC output corresponding to the PWM modulation output, which is supplied as its control signal to a gain control circuit 17 to which an audio signal is supplied.

Although the tuning circuit is explained in the following, this example is an embodiment in which the desired channel can be tuned directly. In the tuning pulse generator 6, a reset pulse P _R and a predetermined number of trigger pulses P _T are formed in response to the channel control remote control signals S ₁ to S ₁₂ supplied thereto.

For example, when the first channel is currently being received and switching to the third channel is not possible, when the remote control signal S ₃ for the third channel is supplied to the tuning pulse generator 6, the reset pulse P of FIG. _R is obtained and later than this, the trigger pulse P _T of the same drawing B is obtained. The pulses P _R and P _T are supplied to the corresponding input terminals of the tuning station counter 20, and at the same time as the tuning station counter 20 is reset, a counter output relating to the pulse P _T is obtained. This counter output is supplied to the control channel for tuning the channel selection voltage of the third channel installed in the tuning tuner 21, which is known in the electronic tuning tuner 21, whereby the third channel is directly tuned. Will be.

With a manual switch, in order to realize the same tuning operation, a manual control signal such as remote control signals S ₁ to S ₁₂ may be supplied to the input of the tuning pulse generator 6, and therefore, the tuning of the tuning pulse generator 6 may be performed. On the input side, manual switches SW ₁ to SW ₁₂ are provided.

However, in the case where a part of the control circuit 4 is shared to realize remote and manual tuning operations, if the control circuit 4 is IC, this example requires a total of 19 terminals including a power supply terminal. Among them, the number of terminals required on the input side occupies 70% or more of the whole.

As described in the opening paragraph of the present invention, the number of terminals required on the input side is greatly reduced, so that the control circuit can be miniaturized and can be configured at low cost.

Although the present invention will be described in detail with reference to FIG. 4, the embodiment shown below is a case where the remote control apparatus is applied to the control circuit as described above.

In the present invention, the variable oscillator 25 is provided, and the frequency obtained therefrom is supplied to the frequency discrimination circuit 5 through the synthesizer 26 as a manual control signal with a frequency f ₁ to f ₁₅ oscillation output. As the oscillator 25, for example, a CR type can be used, and the time constant circuit 30 for determining the oscillation frequency is externally mounted so as to be variable.

The variable correction circuit 30 is composed of a series circuit of CR, and the resistor R is a manual switch between the connection points l ₁ to l ₁₅ of the respective resistors R ₁ to R ₁₅ respectively divided and divided into a plurality as shown in the drawing. SW _P to SW ₁₂ are connected.

Switch SW _P is for power supply, switch SW _U is for volume up, and switch SW _D is for volume down. One end of the capacitor C is connected to the DC power supply of the oscillator 25 and the other end of the capacitor C is connected to the input terminal of the oscillator 25.

When the switch SW _P is turned on, the time constants of C and R ₁ are determined so that the oscillation frequency fosc becomes f ₁ . When the respective switches SW _U to SW ₁₂ are turned on as described below, the synthetic resistance values of the resistors R ₂ to R ₁₅ are determined so as to obtain corresponding oscillation frequencies f ₂ to f ₁₅ , respectively. When the receiving circuit of the remote control device is configured in this manner, the transmitting circuit may be configured as shown in FIG. In the figure, reference numeral 35 denotes a transmitter for a remote control signal, reference numeral 36 denotes an amplifier, and reference numeral 37 denotes a remote control signal transmitter. Numeral 40 denotes a time constant circuit for varying the oscillation frequency for obtaining a predetermined remote control signal, and is configured in the same manner as that of the receiving circuit. SW _PR through SW _12R indicate the remote control switch.

As described above, according to the configuration of the present invention, it is possible to drastically reduce the number of terminals when ICizing the control circuit 4 by simply adding the oscillator 25 and the variable correction circuit 30. In other words, in the example of FIG. 4, the oscillator 25 is added, and the oscillator 25 is controlled to include channel switching. In this example, only two terminals are required to achieve 15 kinds of control states. Therefore, since the number of terminals can be reduced significantly, the control circuit 4 can be made compact and inexpensive.

In addition, when the tuning voltage for switching channels is configured to be obtained by the tuning pulse generator 6 and the counter 20 as shown in the drawing, only the number of output terminals of the channels that can be tuned by the tuning pulse generator 6 are selected. Since it is not necessary to derive, the IC of the control circuit 4 becomes easier.

In the above-described embodiment, the unmodulated remote control signal is used. However, the present invention can also be applied to modulated ones.

6 shows an example of a transmission circuit when a remote control device of the modulation method is used. Reference numeral 41 denotes a modulation circuit, 42 denotes a carrier generation circuit, and a carrier frequency is selected to be about 40 KHz. One example of the modulated remote control signal is shown in FIGS. 2C and 2D.

Although the above-described examples have all described examples in which the present invention is applied to the IC as part of the receiving circuit of the control device, the present invention can be used when the IC of the multi-input control circuit is IC.

Claims (1)

As described in the text and illustrated in the drawings, the oscillator has a frequency discrimination circuit, and the oscillator has a oscillation output configured as a variable time constant circuit so that a plurality of oscillation frequencies can be obtained, and the frequency discrimination circuit having different frequencies. And an oscillator and a frequency discrimination circuit are integrated into an IC, and the variable time constant circuit is mounted externally.

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