KR19980040407A - Input switching control device to television - Google Patents

Abstract

The present invention provides an input switching control circuit that automatically performs input switching between television receiver related equipment by having the advantage of full duplex bidirectional communication or unidirectional communication provided in a telephone circuit.

Communication means for performing full duplex bidirectional communication or unidirectional communication, detection means for detecting operation information provided from at least one external device via the communication means, and between the internal input and the external input in response to the detection result of the detection means. It is an object of the present invention to provide an input switching control device having control means that affects the switching control of the controller.

Description

Input switching control device to television

1 is a schematic circuit diagram showing an arrangement of a conventional communication circuit for full duplex bidirectional communication.

2 is a diagram showing a voltage change on a control line of a communication circuit.

3 shows a change in reference voltage for a voltage comparator in a communication circuit.

4 is a circuit diagram showing an arrangement of a communication circuit according to the present invention.

5 is a circuit diagram showing first and second arithmetic means of a communication circuit.

* Description of the symbols for the main parts of the drawings *

100: receiving side 110: first arithmetic means

120: second arithmetic means 130: comparator means

140: variable means 200: transmission side

[Purpose of invention]

The present invention relates to an input switching control circuit which automatically performs input switching between television receiver related equipment by having the advantage of full duplex bidirectional communication or unidirectional communication provided in the telephone circuit, in particular full duplex communication or unidirectional communication mentioned above. It relates to a communication circuit for performing the.

TECHNICAL FIELD OF THE INVENTION

The television receiver abbreviated herein as a television receiver has a plurality of external terminals. A video tape recorder can be connected to this external terminal for viewing on a reproduced video television receiver screen.

That is, the video tape recorder is connected to the television receiver so as to view the image reproduced by the video tape recorder on the screen of the television receiver, and the user first decides which of the external input terminals of the television receiver is connected to the video tape recorder. Initial setup is performed.

Next, the user sets the television receiver to an input mode associated with the remaining external input terminals to which the video tape recorder is connected by a remote controller dedicated to the television receiver or by a mode setting switch provided to the television receiver. This switches the input mode of the television receiver from the video tape recorder to the input.

The user presses the playback button provided on the main body of the remote control or video tape recorder by selecting the operation. This starts the operation of the video tape recorder to be sent to the television receiver of the image signals. Thus, the television receiver displays an image corresponding to the image signal provided from the external input terminal before switching beforehand on the screen.

To switch external input terminals as described above, television receivers and video tape recorders are generally provided in half-duplex bidirectional circuits, and control signals are transmitted by half-duplex bidirectional circuits in accordance with half-duplex communication systems.

Even if data is transferred from one of the communicators to another with a half duplex communication system, one-way communication is possible. Therefore, when the above-mentioned control signal for specifying the operation state of the video tape recorder is always transmitted, it is impossible to transmit any control signal.

On the other hand, while the initialization operation is complicated for any of the control terminals to which the connected equipment is connected, the user needs to perform the initialization operation at each time the connection state is modified.

In addition, the initialization operation is extremely complicated because three jumper wires are required for the interconnection of the equipment.

If a full duplex bidirectional circuit in which two people can communicate simultaneously with the other party is used in the above-described half duplex bidirectional circuit, the ratio of the output impedance between the transmit and receive circuits is larger, and the transmitted signal cannot be detected accurately. As in the conventional full-duplex bidirectional circuit, a circuit is known which adds or subtracts the reference voltage Vref of the voltage comparator IC1 according to a specialized signal for detecting the transmitted signal OUT1. In general, the signal driving impedance Dr1 of the transmitting or receiving side of the full-duplex bidirectional circuit is determined by the resistor R1.

The voltage of the control line CL (common line) is zero when the transmitted signal OUT1 and the signal OUT2 to be transmitted are low L, while the voltage of the common line is as shown in FIG. Similarly, it becomes 1/2 of the height level H, and is high level H when one of the signals is H or two of the signals are H.

At the same time, the reference voltage Vref of the voltage controller IC1 becomes 1/4 and 3/4 of the source voltage level, depending on the level of the signal OUT1 transmitted as shown in FIG. The transmission level of the other party can be detected by comparing the voltage on the control line CL by the reference voltage Vref and the voltage comparator IC1.

However, when the H level of the signal to which the signal OUT1 is to be transmitted is generated from the reference voltage source of the voltage comparator IC1, any voltage difference reduces the margin of the voltage provided by the comparison by the voltage comparator IC1.

For example, when the maximum voltage of the H level of the signal OUT2 to be transmitted is 4V, the maximum voltage of the H level of the signal OUT1 to be transmitted is 3V, the power of the reference voltage Vref is 5V, and the control line The voltage of (CL) has four voltage values of 0 V, 1.5 V, 2 V and 3.5 V, while the voltage values of 1.2 V and 3.75 V of the reference voltage Vref, and as a result, the margins are 1.5 V and 3.5 V It becomes smaller than the control line voltage of. As a result, the signal level OUT1 to be transmitted accurately detects a malfunction.

On the other hand, if the circuit is modified or an operation step is added to control the operation between other equipment such as a television receiver and a video tape recorder, the transmission system for control signals is different from the conventional system, and as a result, the existing equipment is changed in circuit. Or an operation step could not be connected to other equipment to be added as described above.

[Technical problem to be achieved]

It is an object of the present invention to provide an input switching device that can be connected to existing equipment and can be easily interconnected with other equipment.

Another object of the present invention is to provide a communication device capable of accurately detecting the level of a transmitted signal without damaging the ability to interchange existing communication circuits.

[Configuration and Action of the Invention]

According to the configuration of the present invention to achieve this object, communication means for performing full-duplex bidirectional communication or unidirectional communication, detection means for detecting operation information provided from at least one external device via the communication means, and detection thereof It is to provide an input switching control apparatus having control means for influencing switching control between an internal input and an external input in response to a detection result of the means. The control means manages the control so that when the motion information is detected by the detection means, the input is switched to an input from one of the external devices associated with the detected motion information to execute an action corresponding to the motion information. Since switching can be realized automatically in response to operation information from equipment connected to other equipment between the internal input and the external input, the connection of existing equipment is possible, and the connection can be made easily.

The present invention also provides a communication circuit for detecting a transmission level on the transmission side for performing unidirectional communication including first arithmetic means for performing full duplex bidirectional communication or an arithmetic operation.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the embodiments of the present invention.

In Fig. 4, the communication circuit for performing the full duplex bidirectional communication is configured to apply a voltage equal to the voltage V2 for the transmission signal of the transmission side 200 which detects the transmission level of the first arithmetic means 110. The second arithmetic means 120 is doubled as a result (4V) of the operation by the first arithmetic means. In addition, this communication circuit compares the result of comparison by the comparison means 130 and the comparison means 130 for comparing the voltage V3 of the transmission signal transmitted to the receiving side 100 with the comparison reference voltages V5, V6. And variable means 140 for varying the transmission impedance R1 at the receiving side in response.

The first arithmetic means comprises an additional device 111 for performing the following arithmetic operations. V1 is the transmission signal voltage of the receiving side 100, R1 is the transmission impedance of the receiving side 200, V2 is the transmission signal voltage of the transmitting side, R2 is the transmission impedance of the receiving side 100, V3 is the transmission The voltage of the transmission signal transmitted to the receiving side 100 via the control line CL interconnecting the side 200 and the receiving side 100. That is, the voltage V3 of the transmission signal transmitted to the receiving side on the control line CL is as follows.

In order to know the transmission signal voltage V2 of the transmission side 200, the transmission signal voltage V1 of the reception side 100 multiplied by (−K × R1) is added by the additional device 111 as the voltage V3. do. If K = R1 (R1 + R2) and R1 = R2, K can be quite close to 1/2.

Therefore, the voltage V4 obtained by the first arithmetic means 110 is used as follows.

The second arithmetic means executes an arithmetic operation V5 = 2 x V4 using the result V4 of the first arithmetic means 110. That is, the transmission signal voltage V2 of the transmission side 200 can be accurately known by doubling the voltage V4 (= V2 / 2) obtained by the first arithmetic means 110.

In Fig. 5, the first arithmetic means 110 and the second arithmetic means 120 are composed of operational amplifiers IC2 and IC3 as shown.

In the first arithmetic means 110, the voltage V1 of the signal to be transmitted is a partial voltage input to the subtraction terminal CI2 (-) of the operational amplifier IC2 by the impedance ratio of the impedances R4 and R5. Divided. The transmission signal voltage V3 transmitted to the receiving side 100 via the control line CL is input to the additional terminal IC + of the operational amplifier IC2.

The operation amplifier IC2 subtracts a voltage that is 1/2 of the input voltage to the subtraction terminal IC2 (−) by the voltage V3 from the control line CL, thereby adding the terminal IC3 + of the operation amplifier IC3. Transfers the voltage V4 (= V3-1 / 2V1).

The operational amplifier IC3 doubles the voltage V4 from the operational amplifier IC2 and outputs a resultant voltage equal to the voltage V5. The signal voltages V3 transmitted through the control line CL are 0V, 1.5V, 2V and 3.5V, and the voltages to be transmitted to V1 are 1V and 4V.

If voltage V1 is 0V, voltage V3 is 0V and 1.5V. As a result of the arithmetic operation in the operational amplifier IC2, the voltage V4 is equal to the voltage V3, while the voltage V5 output from the operational amplifier IC3 is the voltage of the signal transmitted from the transmission side.

On the other hand, when the voltage V1 is 4V, the voltages V3 are 2V and 3.5V. As a result of the arithmetic operation in the operational amplifier IC2, the voltage V4 becomes equal to 0 V and 1.5 V, while the output voltage V5 from the operational amplifier IC3 is the voltage of the signal transmitted from the transmission shaft. .

Since the voltage of the signal transmitted via the control line CL is divided into partial voltages by the transmission impedance R1, the transmission signal level from the transmission side is 1/2 voltage V1 of the signal to be transmitted from the voltage V3. Can be accurately detected by subtracting a voltage such as

When the ratio between the transmission impedance R1 of the receiving side 100 and the transmission impedance R2 of the transmitting side 200 is large as shown in FIG. 4, the transmission signal voltage V2 of the transmitting side 200 is large. Changes the value.

Thus, as in the above case, the comparator means 130 receives the voltage V3 and the transmission signal to be transmitted to the receiving side 100 via the control line CL, the two voltages 5V and V6 for comparison. It occurs from the H level value of the transmission signal voltage V1 on the side 100. When the transmission signal voltage V1 of the receiving side 100 is at the H level and the transmission signal voltage V2 of the transmission side 200 is at the L level, the voltage V3 is compared with the reference voltages V5 and V6. And the result of the comparison is applied to the variable means 140.

When the result of the comparison is V5V3 and V6V3, since the transmission impedance R1 of the receiving means 100 is larger than the transmission impedance R2 of the transmitting side R2 (R1R2), the variable means 140 manages the control. As a result, the transmission impedance R1 of the receiving side R1 becomes smaller. Conversely, when the result of the comparison is V5V3 and V6V3, the transmission impedance R1 of the reception means 100 is smaller than the transmission impedance of the transmission side 200 (R1R2), whereby the variable means manages the control to The transmission impedance becomes larger.

In the case of V5V3 and V6V3, the variable means has a transmission impedance R1 of the receiving side 100 that is approximately equal to the transmission impedance R2 of the transmitting side 200 (R1 = R2), and the transmission impedance of the receiving side 100 ( It is determined that the variable control of R1) is not executed. Therefore, when the output impedance of the communication circuit is not matched, the matching of the impedance can be made by applying the communication circuit shown in FIG. 4 to one side to accurately detect the transmission voltage V2 of the transmission side 200. . That is, the signal level to be transmitted can be detected accurately without compromising the interchangeability with respect to conventional communication circuits.

Hereinafter, the operation of the communication circuit will be described.

The transmission side 200 transmits the transmission signal of the voltage V2 to the reception side 100 via the transmission impedance R2 and the control line CL.

At this time, the transmission signal of the voltage V transmitted by the transmission side 200 is transmitted to the reception side 100 together with the voltage transmission signal of V3 = (R2 × V1 + R1 × V2) / (R1 + R2). .

The transmission signal of the voltage V3 is provided to the first arithmetic means 110 and the comparator means 130, while the signal of the voltage to which V1 is to be transmitted is provided to the first arithmetic means 110 and the comparator means 130. .

As a result, the first arithmetic means 110 performs the following arithmetic operation to transfer the voltage V4 to the second arithmetic means 120.

K = R1 / (R1 + R2)

V4 = V3-K × V1

The second arithmetic means sets the voltage V5 obtained when doubling the voltage V4 from the first arithmetic means 110, so as to be the transmission signal voltage V2 of the transmission side 200, and to the transmission side. A transmission level of 200 is detected.

At this time, the second arithmetic means 100 transmits to the comparator means 130 a voltage V5 obtained by the above-described operation, which is the voltage V2 detected for the transmission signal of the transmission side 200.

The comparator means 130 generates H levels for the comparison reference voltages V5 and V6 from the transmission signal voltage V3 provided from the transmission side 200 and the voltage V1 of the transmission signal. When the voltage V1 of the transmission signal is at the H level and the voltage V5 obtained by the second arithmetic means 120 which is the voltage V2 of the transmission signal is at the L level, the comparator makes a comparison with the voltage V3. The two reference voltages V5 and V6 generated for comparison are compared, and the result of the comparison is transmitted to the variable means 140. The variable means 140 responds to the comparison result from the comparing means 130, so as to match the impedance between the transmission impedance R2 from the transmission side 200 and the transmission impedance R1, the transmission impedance R1. To vary.

Therefore, the transmission signal of the transmitted voltage V3 transmitted to the receiving side via the control line CL is provided to the first arithmetic means 110 via the transmission impedance R1 varied by the variable means 140. .

The first arithmetic means 110 and the second arithmetic means 120 perform the arithmetic operation described above to detect the transmission level on the transmission side 200.

[Effects of the Invention]

The above-described communication circuit according to the present invention can detect the level of the signal transmitted from the communication side, and can also be used for the transmission of the analog voltage.

In addition, a feature of the present invention includes communication means for performing full-duplex bidirectional communication or unidirectional communication, detection means for detecting operation information provided from at least one external device via the communication means, and detection results of the detection means. In response, there is provided an input switching control device having control means for influencing switching control between an internal input and an external input. The control means manages the control so that when the operation information is detected by the detection means, the input is switched to an input from one of the external devices associated with the detection operation information to execute an operation corresponding to the detection operation information. Since switching can be realized automatically in response to operation information from equipment connected to other equipment between the internal input and the external input, the connection of existing equipment is possible, and the connection can be made easily.

Claims (2)

Communication means for executing full duplex bidirectional communication or unidirectional communication; Detection means for detecting operation information provided from at least one external device via the communication means; Control means for executing switching control between an internal input and an external input in response to a detection result of the detection means, The control means switches to an input provided from one of the external devices associated with the detected motion information so that when the motion information is detected by the detection means, an input corresponds to the detected motion information. An input switching control device for television, characterized in that the control is managed as possible. 2. An input switching to television as set forth in claim 1, comprising a communication circuit for detecting a transmission level on a transmission side for performing unidirectional communication, including first arithmetic means for performing full duplex bidirectional communication or an arithmetic operation. controller.