JP3819388B2 - Cable extension device - Google Patents

Description

    The present invention relates to a cable extension device capable of transmitting a video signal and an audio signal from a video input source to a video output device arranged at a remote location via a transmission cable, and in particular, a configuration of the cable extension device. The present invention relates to a cable extension device capable of transmitting a relatively fast signal such as an RS232C signal together with an audio signal without complicating the operation and with a simple operation.

    Conventionally, as this type of cable extension device, there is a cable extension device that can transmit RGB signals and audio signals from a video input source to a video output device located at a remote location via a LAN cable. Are known.

    By the way, if an RS232C (Recommended Standard-232-C) signal of EIA (American Electronics Industry Association) can be transmitted in addition to the RGB signal and the audio signal, for example, an image that can be remotely operated based on the RS232C signal Since a cable extension device can be used for an output device (for example, a plasma display), a cable extension device that can transmit an RS232C signal together with an RGB signal and an audio signal while using a LAN cable is desired. It was.

    However, since a relatively fast signal such as the RS232C signal changes to a sound level with respect to time, it can be added to a vacant portion of the sound signal like a signal with little time change (for example, a contact signal). There was an inconvenience that could not be easily done. Also, if the RS232C signal is transmitted in a processed form as a command, it is necessary to provide a CPU to the cable extension device, so that not only the configuration of the cable extension device is complicated, but also communication parameter setting work must be performed. The operation of the cable extension device is complicated.

    Accordingly, an object of the present invention is to provide a cable extension device that can transmit a relatively fast signal such as an RS232C signal together with an audio signal without complicating the configuration of the cable extension device and with a simple operation.

The invention of claim 1 is a cable extension device (1) configured to transmit a digital signal from a signal transmitter (2) to a signal receiver (3) via a transmission cable (5) .
It said signal transmitter (2) is
Analog voice signals that have been input (LSA, RSA) and digital audio signal by sampling at a first sampling frequency (SSF) (LSD, RSD) audio signal conversion output means for converting (41),
N times (e.g. eight times) the second sampling frequency (CSF) second sampling frequency calculation setting means for calculating (42) of said first sampling frequency (SSF),
A digital signal conversion output means you output (42) as a digital signal which is input to (CS1) by sampling at the second sampling frequency (CSF) digital conversion signal (CS2),
The audio signal conversion output means (41) by converted digital audio signal (LSD, RSD) after the digital signal conversion output unit digital converted signal output from the (42) to (CS2) N bits (e.g., 8 bits ) and sequence to serial transmission signal (serial transmission signal generation and transmission means that sends the serial transmission signal to generate a TS) to (TS) in said transmission cable (5) (43),
Provided,
The signal receiver (3),
Wherein the transmission cable (5) to separate the active serial transmission signal received (TS) or al the digital conversion signal (CS2) via a digital conversion signal separating means (51),
The digital conversion signal (CS2) digital signal recovery output means you outputting said restored digital signal (CS1) at the second sampling frequency (53), and the provided,
It is configured as a feature.

In the invention of claim 2, the digital signal (CS1) has a data structure corresponding to the start-stop synchronization method (for example, a data structure composed of STA, CH, and STO shown in FIG. 3).
The signal receiver (3) converts the digital signal (CS1) output from the digital signal restoration output means (53) of the signal receiver (3) into a start bit sampling frequency (SBF) based on the start-stop synchronization method. ) And can be connected to a digital signal receiving device (for example, 10B),
Second sampling frequency calculation setting means (42) of the signal transmitter (2) sets the second sampling frequency (CSF) to be equal to or higher than the start bit sampling frequency (SBF).
It is configured as a feature.

In the invention of claim 3, the start-stop synchronization method is a data transmission method standardized by RS232C.
It is configured as a feature.

According to the invention of claim 1, the digital signal (CS1) is transmitted to the signal receiver (3) together with the digital audio signal (LSD, RSD) while being finely sampled at the second sampling frequency (CSF). Therefore, without increasing the number of signal lines of the transmission cable (5), even if the digital signal (CS1) is a relatively fast signal (for example, a signal that changes to a voice level), the digital signal (CS1) The signal can be output from the signal receiver (3) in a well-restored form.

    According to the second aspect of the present invention, the digital signal (CS1) is sampled by the digital signal conversion output means (42) at a sampling frequency equal to or higher than the start bit sampling frequency (SBF). 53) can restore the digital signal (CS1) in a finer form than the start bit sampling frequency (SBF) without affecting the reception processing of the digital signal (CS1) by the start-stop synchronization method. (CS1) can be output to a digital signal receiving apparatus (for example, 10B).

    Since the digital signal (CS1) is sampled as a waveform even if the start-stop synchronization method is a data transmission method standardized by RS232C, the command is transmitted to the cable extension device (1). It is possible not to provide a CPU for interpretation. As a result, it is possible to prevent the configuration of the cable extension device (1) from becoming complicated, and it is not necessary to set communication parameters, so only the transmission cable (5) is connected to the cable extension device (1). Thus, the digital signal receiving device (for example, 10B) can be remotely operated.

    The numbers in parentheses indicate the corresponding elements in the drawings for the sake of convenience in order to help understanding of the present invention. Therefore, the present description is not limited to the description on the drawings, and the present invention should not be construed by the description of the reference numerals.

    FIG. 1 is an external view showing an example of a cable extension device to which the present invention is applied, FIG. 2 is a block diagram showing an example of the configuration of a signal transmitter and a signal receiver, and FIG. 3 is an RS232C signal conversion process. FIGS. 4A and 4B are explanatory diagrams of the generation processing of the twisted pair transmission signal, where FIG. 4A is a left digital audio signal, FIG. 4B is a right digital audio signal, FIG. 4C is an RS232C converted signal, and FIG. FIG. 5 is an explanatory diagram of the reception processing of the RS232C signal by the plasma display.

[I / O terminal of cable extension device]
FIG. 1 shows an example of a cable extension device 1. As shown in FIG. 1, the cable extension device 1 includes a signal transmitter 2 and a signal receiver 3.

    As shown on the left side in FIG. 1, the signal transmitter 2 has a housing 20, and the housing 20 is provided with a terminal board 20 a. The terminal board 20a is provided with a BNC cable input terminal 21, an audio input terminal 22, and an RS232C cable input terminal 23 as input terminals, and a LAN cable output terminal 25 as output terminals.

The BNC cable input terminal 21 has 5 BNCs (Bayonet
A BNC cable 6A having a Neill Concelman) connector (not shown) at both ends is configured to be connectable, and RGB signals can be input. The RGB signal is composed of an R (red) signal R, a G (green) signal G, a B (blue) signal B, a horizontal synchronization signal HD, and a vertical synchronization signal VD. In the following description, the R signal When it is not necessary to distinguish the R, G signal G, and B signal B, they are simply expressed as color signals R, G, B, and when it is not necessary to distinguish the horizontal synchronization signal HD and the vertical synchronization signal VD, They are simply expressed as synchronization signals HD and VD.

    The audio input terminal 22 is configured such that an RCA cable 7A having RCA pin plugs (not shown) at both ends of the cable is connectable, and stereo analog signals (hereinafter referred to as “analog audio signals LSA, RSA”). Can be input freely. The RS232C cable input terminal 23 is configured to be connectable to an RS232C cable 9A conforming to RS232C (Recommended Standard-232-C) of EIA (Electronic Industry Association), and can input an RS232C signal. The LAN cable output terminal 25 is configured to be freely connectable with a category 5 or category 6 LAN cable 5 conforming to the 568 standard of EIA / TIA (American Electronics Industry Association / American Telecommunications Industry Association).

    Next, as shown in the right side of FIG. 1, the signal receiver 3 has a housing 30 as in the signal transmitter 2 described above, and the housing 30 is provided with a terminal board 30 a. Yes. The terminal board 30a is provided with a BNC cable output terminal 31, an audio output terminal 32 and an RS232C cable output terminal 33 as output terminals, and a LAN cable input terminal 35 as an input terminal.

    Similarly to the BNC cable input terminal 21 described above, the BNC cable output terminal 31 is configured such that the BNC cable 6B can be freely connected. Similarly to the audio input terminal 22 described above, the audio output terminal 32 is configured to be connectable to the RCA cable 7B. Similarly to the RS232C cable input terminal 23 described above, the RS232C cable output terminal 33 is configured to be connectable to the RS232C cable 9B. Similar to the LAN cable output terminal 25 described above, the LAN cable input terminal 35 is configured to be connectable to the LAN cable 5.

[Configuration of cable extension device]
FIG. 2 shows an example of the configuration of the signal transmitter 2 and the signal receiver 3. A signal transmitter (broken line) 2 shown on the left side in FIG. 2 includes a synchronization signal adding unit 40, an AD conversion unit 41, an RS232C signal conversion unit 42, a data processing unit 43, and the like.

    The synchronization signal adding unit 40 is connected to the BNC cable input terminal 21, the AD conversion unit 41 is connected to the audio input terminal 22, and the RS232C signal conversion unit 42 is connected to the RS232C cable input terminal 23. Yes. The AD conversion unit 41 and the RS232C signal conversion unit 42 are connected to the data processing unit 43, and the data processing unit 43 and the synchronization signal adding unit 40 are connected to the LAN cable output terminal 25.

    Next, the signal receiver (one-dot chain line) 3 shown on the right side in FIG. 2 includes a synchronization signal separation unit 50, a data separation unit 51, a DA conversion unit 52, an RS232C signal restoration unit 53 and the like.

    The synchronization signal separation unit 50 and the data separation unit 51 are connected to the LAN cable input terminal 35. The data separation unit 51 is connected to the DA conversion unit 52 and the RS232C signal restoration unit 53. The synchronization signal separation unit 50 is connected to the BNC cable output terminal 31, the DA conversion unit 52 is connected to the audio output terminal 32, and the RS232C signal restoration unit 53 is connected to the RS232C cable output terminal 33. Has been.

[Transmission cable connection]
Since the cable extension device 1 has the above-described configuration, the video input source and the video output device are arranged at separate locations, and the RGB signal and audio signal from the video input source are output to the video output device. In order to remotely operate the video output device based on the RS232C signal from the video input source, an operator first performs setup work such as connection of a transmission cable.

    Here, it is assumed that the personal computer 10A shown in FIG. 1 is used as the video input source and the plasma display (plasma television) 10B shown in FIG. 1 is used as the video output device. It shall be arranged at the predetermined position.

    When the operator arranges the personal computer 10A and the plasma display 10B at predetermined positions, as shown on the left side of FIG. 2, the BNC cable 6A from the personal computer 10A is connected to the color signals R, G, B, the synchronization signals HD, VD. Are connected to the BNC cable input terminal 21 of the signal transmitter 2 so as to correspond to the input / output. Similarly, the RCA cable 7A from the personal computer 10A is connected to the audio input terminal 22 so that the input / output of the analog audio signals LSA and RSA corresponds, and the RS232C cable 9A from the personal computer 10A is connected to the RS232C input terminal 23. To do.

    When the personal computer 10A and the signal transmitter 2 are connected, the operator connects the LAN cable output terminal 25 of the signal transmitter 2 to the twisted pair wires 5A, 5B, 5C, 5D constituting the LAN cable 5, as shown in the center of FIG. To the LAN cable input terminal 35 of the signal receiver 3.

    When the signal transmitter 2 and the signal receiver 3 are connected, the operator connects the BNC cable 6B from the plasma display 10B to the signal receiver 3 in the same manner as the BNC cable 6A described above, as shown on the right side in FIG. To the BNC cable output terminal 31. Further, the RCA cable 7B from the plasma display 10B is connected to the audio output terminal 32 in the same manner as the RCA cable 7A described above, and the RS232C cable 9B from the plasma display 10B is connected to the RS232C cable output terminal 33.

[Communication parameter setting work]
Thus, when the transmission cable is connected, the operator sets communication parameters relating to data transmission of the RS232C signal in the personal computer 10A and the plasma display 10B. The communication parameters include a communication speed (baud rate), a bit length of a data string CH (described later), a bit length of a stop bit STO (described later), and the presence / absence of parity.

    The operator first activates the personal computer 10A, the signal transmitter 2, the signal receiver 3, and the plasma display 10B, and sets the communication speed via the input means (not shown) of the personal computer 10A and the plasma display 10B. . Usually, the communication speed can be freely selected from a plurality of values of 19.2 kbps, 9.6 kbps, 4.8 kbps,... As an example for explaining the features of the present invention. Since an embodiment with a high communication speed is appropriate, it is assumed that the operator has set the communication speed of the RS232C signal CS1 to 19.2 kbps via the input means.

    The operator sets other communication parameters as well as the communication speed. These communication parameters do not need to be limited to any one, but here, it is assumed that the operator sets the bit length of the data string CH to 8 bits, the bit length of the stop bit STO to 1 bit, and the parity to be unchecked. .

[Signal output from PC]
Thus, when the setup work is completed, it is assumed that the operator inputs an output command of RGB signals, audio signals, and RS232C signals through the input means of the personal computer 10A. Then, the color signals R, G, B and the synchronization signals HD, VD are output from the personal computer 10A to the signal transmitter 2 via the BNC cable 6A. Similarly, the analog audio signals LSA and RSA are output to the signal transmitter 2 via the RCA cable 7A, and the RS232C signal CS1 is output via the RS232C cable 9A.

    The output R signal R, G signal G, B signal B, horizontal synchronization signal HD, and vertical synchronization signal VD are transmitted through the BNC cable input terminal 21 as shown in the left side of FIG. Is input. Similarly, the left analog audio signal LSA and the right analog audio signal RSA are input to the AD conversion unit 41 via the audio input terminal 22, and the RS232C signal CS1 is input to the RS232C signal conversion unit via the RS232C cable input terminal 23. 42.

[Signal processing in signal transmitter]
The synchronization signal adding unit 40 adds the input synchronization signals HD and VD to the color signals R, G, and B (for example, the B signal B), and outputs these color signals R, G, and B to the LAN cable output terminal 25. .

    Next, the AD conversion unit 41 samples the voltage levels of the input analog audio signals LSA and RSA at an audio sampling frequency SSF (for example, 44 kHz). Here, it is assumed that the number of quantization bits is set to a length of 16 bits, for example. Therefore, the AD conversion unit 41 converts the voltage levels of the sampled analog audio signals LSA and RSA into audio data SDL and SDR each having a 16-bit length for each audio sampling period TSSF corresponding to the audio sampling frequency SSF. And output to the data processing unit 43 as digital audio signals LSD and RSD.

    The RS232C signal conversion unit 42 performs a conversion process on the input RS232C signal CS1. Here, the conversion process will be described with reference to FIG. FIG. 3 shows an example of the data structure of the RS232C signal CS1.

    The RS232C signal CS1 constitutes a serial signal and has a data structure corresponding to the start-stop synchronization method. Specifically, as shown in FIG. 3, the RS232C signal CS1 has a frame FL, and the frame FL includes a start bit STA, a data string CH, and a stop bit STO.

    The start bit STA indicates the start of transmission of transmission data, and 1 bit is arranged at the head of the frame FL. A data string CH indicates transmission data and is arranged following the start bit STA. Since the data length is set to 8 bits as described above, the data string CH shown in FIG. 3 has an 8-bit length (partially omitted). The stop bit STO is arranged following the data string CH, and its data length is set to 1 bit. Therefore, the stop bit STO shown in FIG.

    When the transmission data continues, as shown in FIG. 3, the next frame FL is transmitted following the stop bit STO. When the transmission data does not continue, the next frame FL is transmitted via an idle state (low voltage level) for a predetermined time.

    In the RS232C standard, the voltage levels of High and Low correspond to logic “0” and “1”, respectively. However, in order to easily explain the invention, the RS232C signal CS1 shown in FIG. The voltage levels are shown to correspond to logic “1” and “0”, respectively.

    In addition, the RS232C signal converter 42 samples the voltage level of the input RS232C signal CS1 in the same manner as the sampling of the analog audio signals LSA and RSA described above. At that time, the sampling frequency corresponding to the RS232C signal CS1 (hereinafter referred to as “RS232C sampling frequency CSF”) is set to be N times the above-described audio sampling frequency SSF (for example, 44 kHz). It is assumed that the sampling frequency is set to 8 times the SSF. That is, the RS232C signal conversion unit 42 samples the RS232C signal CS1 at 352 kHz (= 44 kHz × 8).

    Therefore, as shown in FIG. 3, the RS232C signal conversion unit 42 receives the sampling clock SCCSF at the RS232C sampling cycle TCSF obtained by dividing the audio sampling cycle TSSF corresponding to the audio sampling frequency SSF into eight equal parts. The RS232C signal conversion unit 42 changes the voltage level of the RS232C signal CS1 according to the sampling clock SCCSF (for each RS232C sampling cycle TCSF) to “1” with respect to the RS232C data CD having a 1-bit length (high voltage level). The low voltage level is converted to “0”) and is output to the data processing unit 43 as the RS232C conversion signal CS2.

    Next, the data processing unit 43 performs a generation process of the twisted pair transmission signal TS in which the input digital audio signals LSD and RSD and the RS232C converted signal CS2 are sequentially arranged. Here, the process of generating the twisted pair transmission signal TS will be described with reference to FIG. 4A and 4B are explanatory diagrams of the generation processing of the twisted pair transmission signal TS, where FIG. 4A is a left digital audio signal LSD, FIG. 4B is a right digital audio signal RSD, FIG. 4C is an RS232C converted signal CS2, and FIG. Indicates a twisted pair transmission signal TS.

    First, as shown in FIG. 4D, the data processing unit 43 arranges the position specifying data LD composed of combinations of predetermined data (for example, continuous “0” having a predetermined data length). The position specifying data LD functions as a mark for specifying the position of the data on the signal receiver 3 side described later.

    When the position specifying data LD is arranged, the data processing unit 43 increases the communication speed of the left digital audio signal LSD shown in FIG. 4A and the left audio data SDL as shown in FIG. 4D. In a compressed form, it is arranged following the position specifying data LD.

    When the left audio data SDL is arranged, the data processing unit 43 increases the communication speed of the right digital audio signal RSD shown in FIG. 4B and converts the right audio data SDR to the same as the left digital audio signal LSD. In the compressed form as shown in FIG. 4 (d), the audio data is arranged following the left audio data SDL.

    When the right audio data SDR is arranged, the data processing unit 43 increases the communication speed of the RS232C conversion signal CS2 shown in FIG. 4 (c) and converts the RS232C data CD to the RS232C data CD shown in FIG. As shown in (d), N bits are arranged following the right audio data SDR in a compressed form. This “N” means a multiple N of the audio sampling frequency SSF in which the RS232C sampling frequency CSF is set, and the multiple N is set to “8” as described above. As shown in 4 (d), RS232C data CD is arranged in 8 bits.

    The data processing unit 43 performs the above-described data arrangement process for each audio sampling period TSSF, and from the position specifying data LD, the audio data SDL, SDR, and the 8-bit RS232C data CD as shown in FIG. The twisted pair transmission signal TS is generated by sequentially arranging the twisted pair transmission data TSD.

    The RS232C sampling frequency (352 kHz) is a frequency different from the audio sampling frequency SSF (44 kHz). However, as described above, the data processing unit 43 performs audio data SDL, SDR and 8-bit data for each audio sampling period TSSF. Since the RS232C data CD is combined as twisted pair transmission data TSD, the sampling frequency corresponding to the 8-bit RS232C data CD is 44 kHz (= 352 kHz / 8 bits), which is the same as the audio sampling frequency SSF.

    That is, in the twisted pair transmission signal TS, the audio data SDL, SDR and the 8-bit RS232C data CD have the same communication speed. Therefore, as described above, the digital audio signals LSD, RSD, the RS232C conversion signal CS2, Can be sequentially arranged as a twisted pair transmission signal TS.

    Note that the data structure of the twisted pair transmission signal TS shown in FIG. 4 (d) shows only the data necessary for the description. The data structure is not particularly required, and other data (for example, a control signal for RS232C) ) Can be added as appropriate. Further, the arrangement order of the audio data SDL, SDR, and RS232C data CD shown in FIG. 4D is an example, and the arrangement order is arbitrary.

    When the twisted pair transmission signal TS is generated, the data processing unit 43 outputs the generated twisted pair transmission signal TS to the LAN cable output terminal 25. Thus, the R signal R, G signal G, and B signal B output from the synchronization signal adding unit 40 are transmitted through the twisted pair lines 5A, 5B, and 5C via the LAN cable output terminal 25, respectively. The twisted pair transmission signal TS output from the data processing unit 43 is transmitted via the LAN cable output terminal 25 via the twisted pair line 5D.

[Signal processing in signal receivers]
The R signal R, the G signal G, and the B signal B are input to the synchronization signal separation unit 50 of the signal receiver 3 via the LAN cable input terminal 35 when transmitted through the twisted pair wires 5A, 5B, and 5C, respectively. Further, when the twisted pair transmission signal TS is transmitted through the twisted pair line 5D, the twisted pair transmission signal TS is input to the data separation unit 51 of the signal receiver 3 via the LAN cable input terminal 35.

    When the color signals R, G, and B are input, the synchronization signal separation unit 50 separates the synchronization signals HD and VD added to the B signal B, and the color signals R, G, and B and the synchronization signals HD and VD are separated. Is output to the BNC cable output terminal 31.

    When the twisted pair transmission signal TS is input, the data separation unit 51 detects the position specifying data LD from the twisted pair transmission data TSD (see FIG. 4D) constituting the twisted pair transmission signal TS. When the position specifying data LD is detected, the position of each data (the number of bits from the position specifying data LD) can be specified. Therefore, the data separation unit 51 uses the detected position specifying data LD as a reference for the left and right voices. The data SDL, SDR, and RS232C data CD are separated from the twisted pair transmission signal TS.

    The data separation unit 51 performs the above-described separation process for each audio sampling period TSSF, and outputs the separated left and right audio data SDL and SDR to the DA conversion unit 52 as digital audio signals LSD and RSD.

    Further, since the bit length of the separated RS232C data CD is 8 bits as described above (see FIG. 4D), the above-described separation processing is performed on the RS232C sampling period TCSF with respect to the RS232C data CD per bit. (= TSSF / 8), and the data separation unit 51 outputs the separated RS232C data CD for each original RS232C sampling period TCSF, as an RS232C conversion signal CS2, and an RS232C signal restoration unit. To 53.

    Next, when the digital audio signals LSD and RSD are input from the data separator 51, the DA converter 52 converts the digital audio signals LSD and RSD into analog audio signals LSA and RSA based on the audio sampling frequency SSF. When converted into the analog audio signals LSA and RSA, the DA converter 52 outputs the analog audio signals LSA and RSA to the audio output terminal 32.

    On the other hand, when the RS232C conversion signal CS2 is input from the data separation unit 51, the RS232C signal restoration unit 53 restores the RS232C conversion signal CS2 to the RS232C signal CS1 based on the RS232C sampling frequency CSF. That is, for each RS232C sampling period TCSF, a voltage corresponding to High or Low is output in association with the RS232C data CD (“1” or “0”). Then, when the RS232C signal CS1 is restored, the RS232C signal restoration unit 53 outputs the restored RS232C signal CS1 to the RS232C cable output terminal 33.

[Reception processing in plasma display]
Thus, the color signals R, G, B and the synchronization signals HD, VD output from the synchronization signal separation unit 50 are input to the plasma display 10B via the BNC cable output terminal 31 and the BNC cable 6B. The analog audio signals LSA and RSA output from the DA converter 52 are input to the plasma display 10B via the audio output terminal 32 and the RCA cable 7B. The RS232C signal CS1 output from the RS232C signal restoration unit 53 is input to the plasma display 10B via the RS232C cable output terminal 33 and the RS232C cable 9B.

    The plasma display 10B incorporates a CPU (not shown) for interpreting RS232C commands, and includes color signals R, G, B, synchronization signals HD, VD, analog audio signals LSA, RSA, and RS232C signal CS1. Is input to the plasma display 10B, the CPU of the plasma display 10B performs a reception process of the RS232C signal CS1.

    In the plasma display 10B, reception processing by an asynchronous process is performed on the RS232C signal CS1. Specifically, the CPU of the plasma display 10B has a start bit STA arranged at the head of the frame FL at a relatively fine sampling frequency (hereinafter referred to as “start bit sampling frequency SBF”) with respect to the set communication speed. (See FIG. 3), and when the start bit STA is detected, the subsequent data string CH is synchronized and the RS232C signal CS1 is received.

    The start bit sampling frequency SBF described above is normally set to a frequency corresponding to 16 times the communication speed, and in the present embodiment, it is also assumed to be set to a frequency corresponding to 16 times the communication speed. Since the communication speed is set to 19.2 kbps as described above, the set start bit sampling frequency SBF is 307 kHz (≈19.2 kbps × 16).

    Therefore, the sampling clock SCSBF is inputted to the CPU of the plasma display 10B at the sampling period TSBF corresponding to the start bit sampling frequency SBF, and the CPU of the plasma display 10B is connected to the RS232C cable according to the sampling clock SCSBF. When the voltage level of the output terminal 33 is detected and a high voltage level is detected, it is determined that the start bit STA has been detected.

    Specifically, referring to FIG. 5, in the idle state before time t0, the CPU of the plasma display 10B detects the low voltage level according to the sampling clock SCSBF, and therefore detects the start bit STA. It is determined that it is not, and the reception process is not started. When the RS232C signal CS1 is input to the plasma display 10B at the time t0, the voltage level becomes High. When the CPU of the plasma display 10B detects the voltage level at the time t1, the High voltage level is detected, and the start bit It is determined that an STA has been detected.

    As already described, the RS232C sampling frequency CSF (352 kHz) is set to 8 times the audio sampling frequency SSF (44 kHz), and thus exceeds the start bit sampling frequency SBF (307 kHz) (that is, TCSF < TSBF relationship). Therefore, since the RS232C signal C1 is restored in a finer form than the start bit sampling frequency SBF on the signal receiver 3 side, the CPU of the plasma display 10B extends the cable between the personal computer 10A and the plasma display 10B. Even if the device 1 is present, the start bit STA can be detected with high accuracy.

    Note that the multiple N of the audio sampling frequency SSF is not necessarily “8” if the RS232C sampling frequency CSF is equal to or higher than the start bit sampling frequency SBF, for example, other than “8” (eg, “16”). It is also possible to set.

    That is, the case where the communication speed of the RS232C signal CS1, the audio sampling frequency SSF, and the start bit sampling frequency SBF are 19.2 kbps, 44 kHz, and 307 kHz (16 times the communication speed), respectively, has been explained. Also, the multiple N may be set so that the RS232C sampling frequency CSF (N times the audio sampling frequency SSF) is equal to or higher than the start bit sampling frequency SBF.

    Thus, when the start bit STA is detected, the CPU of the plasma display 10B switches the sampling frequency from the start bit sampling frequency SBF and starts the reception process of the RS232C signal CS1. That is, as shown in FIG. 5, the CPU of the plasma display 10B synchronizes the start bit STA at time t2 when half cycle T0 / 2 has elapsed from time t1, and thereafter, every time period T0 from time t2. Then, each bit data in the data string CH is accepted.

    Thus, the CPU of the plasma display 10B outputs the video corresponding to the color signals R, G, B and the synchronization signals HD, VD, and the audio corresponding to the analog audio signals LSA, RSA, and the received RS232C signal CS1. Control based on the instruction indicated by the transmission data is executed.

    When the instruction indicated by the transmission data is a change in volume, the sound corresponding to the analog audio signals LSA and RSA is changed and set to a volume corresponding to the instruction. Thereafter, when the operator inputs a command for predetermined control (for example, power-off) through the input means of the personal computer 10A, the corresponding RS232C signal CS1 is transmitted from the personal computer 10A through the cable extension device 1 in the same manner as described above. The data is transmitted to the plasma display 10B, and the CPU of the plasma display 10B executes the predetermined control.

As described above, the cable extension device 1 according to the present invention transmits the RS232C signal to the signal receiver 3 together with the digital audio signals LSD and RSD while finely sampling the RS232C signal at the RS232C sampling frequency CSF. However, the RS232C signal can be output from the signal receiver 3 in a form accurately restored even if it is a relatively fast signal such as an RS232C signal (for example, a signal that changes to an audio level). Remote control can be performed based on the RS232C signal.

    In addition, the cable extension device 1 according to the present invention converts the RS232C signal CS1 into a digital signal (RS232C signal CS2) corresponding to the voltage level High / Low without processing it as a command (that is, sampling as a waveform). Therefore, unlike the plasma display 10B described above, it is not necessary to provide a CPU for interpreting commands in the cable extension device 1, and the configuration of the cable extension device 1 can be simplified. In addition, since communication parameter setting work is not required, the video output device can be remotely operated simply by connecting a transmission cable to the cable extension device 1.

    In the embodiment described above, RS232C has been described as an asynchronous data transmission method. However, the present invention is not limited to this, and may be, for example, an EIA RS422 serial interface standard. Further, the data transmission method does not necessarily need to be an asynchronous method, and may be a synchronous method. In this case, the multiple N need not be set in accordance with the start bit sampling frequency SBF, and may be set to such a degree that the video output apparatus can synchronize the signal to be transmitted. Furthermore, as an example of a signal that changes to the audio level, a signal for controlling a video output device such as an RS232C signal is shown. However, the present invention is not limited to this, and for example, other than the analog audio signals LSA and RSA, It is also possible to transmit an audio signal.

  As an application example of the present invention, the video output apparatus can be applied not only to a plasma display but also to a personal computer, a projector, an OHP (Overhead Projector), and the like.

FIG. 1 is an external view showing an example of a cable extension device to which the present invention is applied. FIG. 2 is a block diagram illustrating an example of the configuration of the signal transmitter and the signal receiver. FIG. 3 is an explanatory diagram of the conversion process of the RS232C signal. 4A and 4B are explanatory diagrams of the generation processing of the twisted pair transmission signal, where (a) is the left digital audio signal, (b) is the right digital audio signal, (c) is the RS232C converted signal, and (d) is the twisted pair transmission signal. FIG. FIG. 5 is an explanatory diagram of the reception process of the RS232C signal by the plasma display.

Explanation of symbols

1 …… Cable extension device 2 …… Signal transmitter 3 …… Signal receiver 5 …… Transmission cable (LAN cable)
10B: Digital signal receiver (plasma display)
41 …… Audio signal conversion output means (AD converter)
42 ...... Second sampling frequency calculation setting means, digital signal conversion output means (RS232C signal conversion unit)
43 ... Serial transmission signal generation and transmission means (data processing section)
51 …… Digital conversion signal separation means (data separation unit)
53 ...... Digital signal restoration output means (RS232C signal restoration unit)
CD: Digital signal data (RS232C data)
CS1 …… Digital signal (RS232C signal)
CS2: Digital conversion signal (RS232C conversion signal)
CSF: Second sampling frequency (RS232C sampling frequency)
LSA, RSA ... Analog audio signal LSD, RSD ... Digital audio signal SDL, SDR ... Digital audio data (left audio data, right audio data)
TCSF: Period corresponding to the second sampling frequency (RS232C sampling period)
TS …… Serial transmission signal (twisted pair transmission signal)
TSSF: Period corresponding to the first sampling frequency (audio sampling period)
SBF …… Start bit sampling frequency SSF …… First sampling frequency (voice sampling frequency)

Claims (3)

In a cable extension device configured to transmit a digital signal from a signal transmitter to a signal receiver via a transmission cable ,
Wherein the signal transmitter,
A voice signal conversion output means for converting the digital audio signal an analog audio signal by sampling at a first sampling frequency which has been input,
A second sampling frequency calculation setting means for calculating a second sampling frequency of N times said first sampling frequency,
A digital signal conversion output means you output as a digital conversion signal of the digital signal that has been input by sampling at the second sampling frequency,
After the digital audio signal converted by the audio signal conversion output means , N bits of the digital conversion signal output from the digital signal conversion output means are arranged to generate a serial transmission signal, and the serial transmission signal is converted into the transmission cable. a serial transmission signal generation and transmission unit that sends at,
Provided,
Wherein the signal receiver,
A digital conversion signal separating means to separate the active serial transmission signal or al the digital conversion signal received through the transmission cable,
And digital signal recovery output means you output the digital signal to said digital converted signal restored by said second sampling frequency,
Provided,
A cable extension device. The digital signal has a data structure corresponding to an asynchronous process,
The signal receiver is freely connectable to a digital signal receiving apparatus that detects and receives a digital signal output from the digital signal restoration output means of the signal receiver at a start bit sampling frequency based on the start-stop synchronization method. Because
The second sampling frequency calculation setting means of the signal transmitter calculates and sets the second sampling frequency to be equal to or higher than the start bit sampling frequency.
The cable extension device according to claim 1, which is configured as described above. The start-stop synchronization method is a data transmission method standardized by RS232C.
The cable extension device according to claim 2, wherein the cable extension device is configured as described above.

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