JP2679038B2 - Command signal transmission method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The description will be made in the following order. A Industrial Field B Outline of the Invention C Conventional Technology D Problems to be Solved by the Invention E Means for Solving Problems (FIG. 1) F Action G Example (FIGS. 1 to 5) ) H Effect of the invention A Industrial field of application The present invention relates to a method of transmitting a command signal. B Outline of the Invention The present invention is directed to the case where the command signal CMD is bidirectionally transmitted between the transmitting device (100) side and the terminal device (200) side, the transmitting device (100) side to the terminal device (200) side. Command signal transmitted in the downlink channel direction to the terminal device, this command signal transmitted in the uplink channel direction from the terminal device (200) side to the transmission device (100) side, and this command used in the channels in both directions. The signal is composed of a combination of high-order bits and low-order bits, and a command signal transmitted in the down channel direction, a command signal transmitted in the up channel direction, and channels in both directions. By grouping them so that the relationship between these upper bits and lower bits is different from that of the command signal used in The issue destination of the command signal is obtained so as to be easily discriminated. C. Prior Art An audio / video system is provided in an international airliner or the like, and a device is devised so that a passenger is not bored as much as possible even on a long flight. In addition, a service system such as a reading light and a stewardess calling light is also provided so that the passengers' individual requirements can be met. D In the system as described above, the transmission device (center device) is provided in the passenger compartment and the terminal device is provided for each seat of the passengers, and the transmission device and the terminal are provided. A common transmission line may be connected to the device. However, in such a system, when supplying an information signal such as a video signal or an audio signal to the terminal device, it is necessary to access various command signals related to the information signal between the transmitting device and the terminal device. is there. The present invention makes it possible to easily determine the issue destination of such a command signal, and to facilitate transmission control or maintenance / inspection. E Means for Solving the Problems For this reason, in the present invention, the command signal CMD is bidirectionally transmitted between the transmission device (100) side and the terminal device (200) side.
In the case of transmitting a command signal transmitted in the downlink channel direction from the transmitting device (100) side to the terminal device (200) side, and the transmitting device (100) from the terminal device (200) side.
The command signal transmitted in the upward channel direction to the side and the command signal used in the channels in both directions are configured by a combination of the high-order bit and the low-order bit. Between the command signal transmitted in the direction, the command signal transmitted in the upstream channel direction, and the command signal used in the channels in both directions, such that the relationship between the upper bits and the lower bits is different. It was designed to be transformed. The load on the hardware and software for the F-action command signal is reduced, and the issue destination of the command CMD can be easily determined, so that the system can be debugged, maintained or inspected, or adjusted easily. G Embodiment In FIG. 1, (100) indicates a transmission device provided in a passenger compartment, etc., and (200) indicates a terminal device provided for each seat in a passenger cabin. In this example, a transmission device (100)
This is a case where seven downlink channels and one uplink channel are prepared by the frequency division method between the terminal and the terminal device (200). Then, in the transmitting device (100), (110) to (11)
3) shows the VTR, which is composed of 8 mm video, and the VTR (110) is set for overriding, and a tape cassette that records how to wear a life jacket etc. is set, and the VTR (111) ~ (113) is for general use, and a tape cassette on which a movie or the like is recorded is set.
Thus, the video signals V, the stereo audio signals L and R in the first language, and the monaural audio signal A in the second language are extracted from the VTRs (110) to (113). Reference numeral (114) denotes a television tuner, and (115) denotes a still image reproducing device, for example, a CD-ROM player. In this player (115), a CD on which an airfield guide map and various procedures are recorded is set. ing. And the device (11
From 4) and (115), the video signal V and the audio signal L,
R and A are taken out. Reference numerals (121) to (129) denote CD players, from which stereo audio signals L and R such as music are extracted. (131) is the microphone for in-flight Anaus, (1)
32) is the AV control unit, (132A) is the Anaus switch, (132B) is the override switch, (132C)
To (132E) are pause switches of the VTRs (111) to (113). Reference numerals (141) to (148) denote memory cartridges, and cartridges (141) to (147) denote ROM cartridges used in, for example, a personal computer of the MSX standard, into which programs such as games are written. ing. The cartridge (148) has a built-in RAM in which programs and data such as an in-flight service menu are stored. The programs or data of the cartridges (141) to (148) are stored in the multiplexer (149) as described later.
Time-division multiplexed into a serial signal. (151) and (152) indicate encoders. These encoders (151), (152) are called CADA encoders, and the details of the signal format will be described later, but one encoder has 16 channels of monaural audio signal (8 channels of audio signal if stereo). ) Is converted into a PCM signal, time-division multiplexed, and a command signal for controlling the terminal device (200) is added to this multiplexed signal. The output signal has a bandwidth almost equal to that of a general video signal. It will be. Further, (161) to (167) are modulation circuits, (169) is a duplexer that divides a downlink channel signal and an uplink channel signal, and (105) controls the above circuits and the terminal device (200). A controller, which is composed of a microcomputer. Then, the controller (105) is supplied with commands and data from each terminal device (200) through the duplexer (169) and the decoder (106). Further, (101) represents a master control unit composed of a microcomputer, and this unit (101) centrally manages and controls the entire transmission device (100) and terminal device (200). For this purpose, the unit (101) is connected to the controller (105), a keyboard (102) is connected as input means for data, a CRT display (103) is connected for monitoring, and an FDD / HDD (104) is connected. In a normal state, the video signal V from the VTR (111) is
And the audio signal A is switched circuit (116), (117)
Are supplied to the modulation circuit (161) through the video signal V and the audio signal A from the devices (112) to (115) and are supplied to the modulation circuits (162) to (165) to modulate the modulation circuits (161) to (165). Signals 165) are modulated by signals V and A in the same manner as broadcast wave signals in general television broadcasting, and modulated signals having different channels are taken out, and these signals are supplied to an adding circuit (168). Further, the audio signals L to A from the VTR (111) are supplied to the encoder (151) through the switch circuit (116) and the devices (112) to (115), (121) to (129).
Audio signals L to A and multiplexer (14)
The output signal of 9) is supplied to the encoders (151) and (152) to be two time division multiplexed signals, and these signals are supplied to the modulation circuits (166) and (167) to be modulated signals of empty channels, respectively. And these signals are added circuit (168)
Supplied to Therefore, the modulation circuit (161) is output from the addition circuit (168).
To 167 are frequency-multiplexed and extracted. Then, the multiplexed signal is supplied to a duplexer (16
Through 9), it is sent out to the leaky cable (171) as a downstream channel signal. This cable (171) is formed by notching the coaxial cable spirally.
The signal passing through this leaks to the outside. Therefore, normally, the video signal V and the audio signal reproduced by the devices (111) to (115) are frequency-multiplexed and sent to the cable (171), and at the same time, the devices (111) to (115) and (121). ~ (129) reproduced audio signals LA and the cartridge (14
The programs or data of 1) to (148) are time-division-multiplexed, frequency-multiplexed, and sent to the cable (171). When the aircraft is in Anaus, the Anaus switch (132
When (A) is turned on, the devices (111) to (115) and (121) to (129) are put in a pause state by the control signal from the unit (132), and the reproduction signal system thereof is muted. , The switch circuit (117) is connected in a state opposite to that shown in the figure, and the Anus audio signal from the microphone (131) is transferred from the unit (132) to the switch circuit (1).
The signal is supplied to the modulation circuit (161) through 17) to be an FM signal similar to the broadcast wave signal of audio in general television broadcasting, and this signal is supplied to the addition circuit (168). Further, at this time, the audio signal A from the microphone (131) is transmitted from the unit (132) to the encoder (15
The controller (105) supplies the encoder (151), (152) with a command signal indicating the Anaus mode based on the signal indicating the state of the unit (132). Therefore, at the time of Anaus on board, the modulation circuit (161)
Also, the encoder (151) sends out the audio signal A of the Anaus and the command signal indicating that it is in the Anaus mode. When the Anaus switch (132A) is turned off, the mode returns to the normal mode. Further, when the override switch (132B) is turned on during overriding, the devices (111) to (115) and (121) to (12) are controlled by the control signal from the unit (132).
9) is set to the pause state, the VTR (110) is set to the reproduction state, and the switch circuit (116) is switched to the state opposite to that shown in the figure, and the reproduction signals V and L to A of the VTR (110) are modulated. It is supplied to the circuit (161) and the encoder (151). At this time, the controller (105) sends an encoder (15) based on a signal indicating the state of the unit (132).
A command signal indicating the override mode is supplied to (1) and (152). Therefore, at the time of override,
The playback signals V, L to A of the VTR (110) are sent out in place of the playback signals V, L to A of the VTR (111), and a command signal indicating that this override mode is in effect is sent out. At the time of over-ride, the ANAUS switch (13
2A) is turned on, the switch circuit (117) and the encoder (15) are set so that the audio signal A from the microphone (131) has priority only for the audio signal A.
1) and (152) are controlled. On the other hand, since the terminal device (200) is provided for each passenger seat, the cable (171) is wired along the seat. Then, in the terminal device (200), (201) indicates a transmitting / receiving antenna (coupler), which is provided in proximity to the cable (171) so as to be inductively coupled with the cable (171), and is transmitted by the transmitting device (100). To access signals between the terminal device (200) and the terminal device (200). Also, (203) and (204) indicate tuners, and in the tuner (203), the modulation circuits (161) to
The modulated signal from (165) is selected, the original video signal V (and audio signal A) is demodulated from the selected modulated signal, and the tuner (204) modulates the modulation circuit (166), The modulated signal from (167) is selected and time-division multiplexed with that from the selected modulated signal, ie encoder (151) or (1
The time division multiplexed signal from 52) is taken out. Further, (205) indicates a decoder, which performs processing reverse to that of the encoders (151) and (152). Also, (20
Reference numeral 6) denotes a display selection unit, which has a color picture tube (61) and various operation switches, and can be connected to a headphone (207) and a joystick (208) as described later. Further, (209) indicates, for example, a microcomputer of MSK standard, which mainly performs display processing in the picture tube (61). Furthermore, (211) is a PSU, (212)
Is the reading light, (213) is the stewardess calling light, (21
9) is a transmission circuit for the up channel, (214) is a sensor for detecting the state of the passenger in each seat, for example, whether the passenger is seated or the seat belt is correctly set, etc., and (220) is the terminal This is a microcomputer that controls the entire device. FIG. 2 shows an example of the display selection unit (206). The color picture tube (61) is, for example, an index beam type flat color picture tube. (62) is a reading light switch, (63) is a stewardess call switch,
(64) is a connector to which the joystick (208) is connected. Further, (65) is a television switch for selecting a reproduction signal V (and L to A) of the devices (111) to (115),
(66) is a music switch for selecting the playback signals L and R of the players (121) to (129), and (67) is a channel (65) selected from the modes selected by the switches (65) and (66). (68) is a display means for digitally displaying the channel number of the selected channel. Further, (71) is a menu switch for displaying a menu on the picture tube (61), (72) is a cursor key (switch) for moving the cursor displayed on the picture tube (61) up and down, (73 ) Is an enter key (74) for validating the item designated by the cursor, and a slide knob for adjusting the volume of the headphones (207). The display selection unit (206) is provided on the back of the seat in front of the seat on which the user sits, as shown in FIG. 3, for example. Then, normally, the frequency-multiplexed signal sent to the cable (171) is picked up by the antenna (201), and this signal is supplied to the tuners (203) and (204) through the duplexer (202). Then, when the switch (65) is pressed, the television mode is set by this, and when the switch (67) is further pressed, the modulation circuits (161) to (16) to (16) in the tuner (203).
The output signal of 5) is selected, and the signals V and A of the channel designated by the switch (67) among the reproduction signals V and A from the devices (111) to (115) are taken out and the signals V are received by the picture tube ( 61)
Supplied to At this time, the tuner (204) selects the output signals of the modulation circuits (166) and (167) and supplies the output signal of the encoder (151) or (152) to the decoder (205). ) Switch (6
7) The audio signals LA of the designated channel are decoded, and this signal is supplied to the headphones (207) through the unit (206). Therefore, by operating the switches (65) and (67), any one of the signals reproduced by the devices (111) to (115) can be viewed. When the switch (66) is pressed, the music mode is set, and when the switch (67) is pressed, the music mode is set.
In the tuner (204), the output signals of the modulation circuits (166) and (167) are selected, and the encoder (151) or (152)
Is supplied to a decoder (205). In this decoder (205), the audio signals L and R of the channel specified by the switch (67), that is, the players (121) to
The reproduction signals L and R specified by the switch (67) of the reproduction signals from (129) are decoded, and the signals L and R are supplied to the headphones (207) through the unit (206). Further, when the menu switch (71) is pressed,
The program and data of the menu of the cartridge (148) are taken out from the decoder (205), and the microcomputer (20)
9) is loaded and executed. As a result, the picture tube (6
The menu screen is displayed in 1), and the cursor key (7
2) Move the cursor to and press the enter key (73) to display the game menu. Furthermore, move the cursor to the desired game name in the game menu and press the enter key (73). The game program designated by the cursor, that is, the programs prepared for the cartridges (141) to (147) are loaded from the decoder (205) to the microcomputer (209), and thereafter, using the joystick (208). You will be able to play the game. Thus, normally, the devices (111) to (115), (12)
1)-(129) and (141)-(147) can be used freely. At this time, data indicating the software usage status of each seat is output from the microcomputer (220),
This data is supplied to the transmission circuit (219) and is converted into an upstream channel signal. This signal is transmitted from the transmission circuit (219) → duplexer (202) → antenna (201) → cable (171).
→ Duplexer (169) → Original data supplied to the decoder (106) through the line of the decoder (106) is taken out, and this data is supplied to the unit (101) through the controller (105), and the software in each seat is Is used and managed. Further, at the time of anus, a command signal indicating that this is in the aus mode is sent to the downlink channel. This is taken out from the decoder (205), and the decoder (205) causes the microphone (1
The channel of the audio signal A of Anaus sent from the unit 31) through the encoder (151) is forcibly controlled, and the audio signal A is supplied to the headphones (207). At this time, the volume of the headphones (207) is set to a constant value regardless of the position of the volume knob (74). If the game is in progress, the game is set to the pause mode. At this time, if necessary, the player (115)
The video signal V of the image corresponding to that Anus is extracted from the image signal, is forcibly selected by the tuner (203) and is supplied to the picture tube (61), and the still image corresponding to that Anus is displayed. Then, after the end of Anaus, the terminal device (200) is returned to the state before Anaus by a command signal indicating this. Also, at the time of override, the signal V, L, and R from the VTR (110) is forcibly selected by the command signal indicating this in the same manner as at the time of Anaus, and this is supplied to the picture tube (61) and at the same time as the headphones. (207). When trouble occurs in the encoders (151), (152) or the decoder (205), the audio signal A from the modulation circuits (161) to (165) is forcibly selected. Further, when the reading light switch (62) is pressed, a seat number and a command signal indicating that the switch (62) is pressed are sent to the controller (105) through the up channel in the same manner as described above. Then, in the controller (105), a command signal (which also has a seat number) for lighting the reading light (213) is formed based on this command signal, and this command signal pushes the switch (62) through the downlink channel. The reading light (212) is turned on by being taken out from the decoder (205) of the seat and supplied to the PUS (211). At this time, data indicating that the reading light switch (62) has been pressed and data of the seat number are supplied from the controller (105) to the unit (101), and the reading light (212) in the unit (101) is supplied. The on / off state of is controlled. The reading light (212) is turned off by pressing the switch (62) again, and this is processed in the same manner as when the reading light is turned on. Further, when a predetermined key input is performed on the keyboard (102), a command for turning on / off the reading light (212) and a command signal having the seat number thereof are supplied to the controller (105), and the command signal is transmitted through the downstream channel. The reading device (200) is turned on and off. That is, in this case, the reading light (212) of each seat can be controlled from the master control unit (101). Also, when the stewardess calling switch (63) is pressed, the calling light (213) is turned on in the same manner as when the reading light (212) is turned on, and the calling light (213) is turned on.
01) and is displayed on the display (103). Further, the seat state detected by the sensor (214) is also sent to the controller (105) together with the seat number and managed by the unit (101). Then, in order to realize the above-described processing or operation, the command signal has the following format. FIG. 4 shows the signal format of the time division multiplexed signal output from the encoders (151) and (152). The signal format is Japanese Patent Application No. 58-210356 and Japanese Patent Application No. 59-17.
This is an improvement on the signal format proposed by No. 0925 or the like. That is, the multiplexed signal is a serial binary signal St composed of a number of superframes, as shown in FIG.
One frame is composed of 168 bits and has a period of 1 / 32k as shown in FIG.
Hz. Each frame includes an 8-bit synchronization code SYNC, a 4-bit service bit SB, and a 32-bit ×
It has 4 data blocks BLKA to BLKD and 7 bits × 4 error correction bits ECC in order. In this case, the synchronization code SYNC is, as shown in FIG.
In the first frame F1 of the super frame, the super frame sync SS is set, and in the subsequent 255 frames F2 to F256, the frame sync is set to the FS, and the super frame sync SS is set.
The bit pattern is different from the frame sync SS. As will be described later in detail, the service bit SB has data of commands, seat numbers, etc., with 77 frames as one unit. Furthermore, each of the data blocks BLKA to BLKD is 32
In addition to being composed of bits, four blocks BLKA to BLKD are formed independently of each other. And
The blocks BLKA to BLKD are divided into _four channels M _{1 to} M ₄ each having 8 bits as shown in FIG. 7C, and each of the channels M _{1 to} M ₄ frequency-converts the signal L, R or A. The PCM signal is sampled at 32 kHz. Therefore, four blocks BLKA are included in one frame.
~ With BLKD, each block has 4 channels
Since it has M _{1 to} M ₄ , one signal St makes 16
The audio signals of the channels can be transmitted simultaneously in a time-division manner. Since each channel has a sampling frequency of 32 kHz and a quantization bit number of 8 bits, it has almost the same standard as PCM audio in 8 mm video. Further, the programs or data from the memory cartridges (141) to (148) are made into a bit-sequential time division signal in the multiplexer (149), and this signal is directly used as one of 16-channel signals. When each program or data is sent to the last bit, it is sent again from the first bit. Since one channel is 8 bits and the number of cartridges (141) to (148) is 8, the first bit of the channel for transmitting the program or data of the cartridges (141) to (148) is The eighth to eighth bits correspond to the programs or data of the cartridges (141) to (148), and the transmission speed of each program or data is 32 kbps. Further, the error correction code ECC is such that 7 bits each perform error correction for each of the blocks BLKA to BLKD. Then, since the signal St has the above format, the transmission bit rate is 168 bits × 32 kHz 5.4 Mbps, and 1/2 of the transmission bit rate is the Nyquist frequency. It can be transmitted. Therefore, as described above, the encoders (151), (15
In 2), each 16-channel audio signal can be time-division multiplexed, and the time-division multiplexed signal can be frequency-multiplexed with other video signals. The service bit SB is used, for example, in the format shown in FIG. That is, the service bits SB are 4 bits per frame and the 4-bit and sequentially bit B ₁ .about.B _4. Then, as schematically shown in FIG. A, a set of 77 consecutive frames, and the 77 frames are arranged vertically in frame units, the service bits are:
The size is 77 bits high x 4 bits wide. Therefore, as shown in FIG. 9B, if the service bit SB is taken out in the vertical direction and 77 bits are taken as one packet, 77 of the bits B ₁ form the first packet PKTA, and similarly, the bit B ₂ second to fourth packet PKTC~PKTD is formed by the 77 amino .about.B _4. Then, as shown in FIG. 9B, each of the packets PKTA to PKTD has seven words WADA to WADG in order of 11 bits each.
And each word, as shown in FIG.
The first 1 bit is the "0" level start bit STRT, the following 8 bits are the data bit DTBT, the next 1 bit is the parity bit PRTY, and the last 1 bit is the "1" level stop. Bit is STOP. And, regarding the data bit DTBT, the packet PKTA ~
In each PKTD, there is one data bit DTBT per word and seven words per 77 frames, so there are seven data bits DTBT (77 bytes) per 77 frames, therefore the data bits as a whole. DTBT has 8 bytes x 4 packets. The second packet of this data bit DTBT
The data bit DTBT of PKTB is the first bit as shown in FIG.
The byte is a header HDER of a predetermined bit pattern (hexadecimal value "AA"), the second byte is a command CMD, and the third and fourth bytes are seat numbers (terminal device (20
The address ADRS indicating the (0) number), and the 5th and 6th
The byte is status information STTS indicating the data or parameter associated with the command CMD, and the final byte is the checksum CS. In the uplink channel, only the service bits SB described above are transmitted in the format described with reference to FIGS. 5B to 5D and in a PSK signal state at a bit rate of 32 kbps equal to that of the downlink channel. In this case, since the command CMD has a size of 1 byte, a maximum of 256 types of commands can be set by the value 00 to FF (hexadecimal value), but only commands used in the downlink channel and only the uplink channel The command CMD values are grouped by the command used in and the command used in both channels. For example, I. Command for downlink channel The upper 4 bits of the command CMD are made larger than the lower 4 bits. That is, F0 to FE, E0 to ED, ..., 20, 21, 21 II. Command for upstream channel The upper 4 bits of the command CMD are made smaller than the lower 4 bits. That is, 01 to 0F, 12 to 1F, ..., DE, DF, EF III. Command used in both channels The upper 4 bits and lower 4 bits of the command CMD are made equal. That is, 00,11,22, ..., EE, FF. This command CMD is also used between the master unit (101) and controller (105), and the unit (1
The command from 01) to the controller (105) is the downlink channel command. That is, as viewed from the command, the unit (101) is the highest, the controller (105) is the middle, and the terminal device (200) is the lowest. The transmission of commands or data between the unit (101) and the controller (105) is carried out, for example, in the RS-422 format. Furthermore, the following commands are prepared as commands transmitted by the command CMD (partially shown). i. Command for downlink channel AVCNT: Anus, Overwrite, VTR (110) ~ (113)
For control of. These distinctions are made by the status information STTS. For example, at the time of Anaus, the least significant bit of the first byte of the information STTS is set to "1". CCHCK: For checking the line between the unit (101) and the controller (105). Upon receiving this command, the controller (105) returns a predetermined command. RESET: For system reset. MSG: The unit (101) controls the controller (105). The control content is indicated by the information STTS. KBI: For controlling the prohibition / permission of key input (switch input) in the unit (206). ii. Command REQ for uplink channel: For requesting service from the terminal device (200). The service content is indicated by the information STTS. For example, if the most significant bit of the first byte of the information STTS is "1", the reading light (212) is turned on. MIS: Indicates that the information STTS has the menu content selected by the terminal device (200). DWN: If the unit (101) commands the controller (105) to poll the terminal (200) (this is done by the command MSG), the terminal (20
When there is no response from 0), it is issued from the controller (105) to the unit (101). iii. Commands used on both channels POL: For polling the terminal equipment (200). This command POL is sent from the unit (101) to the controller (10
When issued to 5), the controller (105) returns a confirmation command. Next, the controller (105) issues a command POL to the terminal device (200), and when the command POL is confirmed by the terminal device (200), the same command POL is returned. The controller (105) is the terminal device (200).
When the command (200) is received from the unit, a predetermined command is sent to the unit (105). ACK: Command Command that shows confirmation for CCHK, POL, etc. NACK: Similar to command ACK, but a command that indicates when there is a parity error or checksum error in the received command. The above is the format and contents relating to the command CMD. Also, the address ADRS is a command CM in the downlink channel.
The destination seat number (terminal device number) such as D is shown, and the issuer seat number such as the command CMD is shown in the upstream channel. Since this address ADRS is 2 bytes in size, it has a maximum of about 650,000 seats or terminal devices (20
0) can be specified, the first byte of the address ADRS is used for grouping seats, and the second byte is used for the seat number within that group. Further, the status information STTS is an operand of the command CMD and indicates parameters or data attached to the command CMD. The checksum CS is used for error checking, and is exclusive OR for each byte of all data bits STRT, CMD, ADRS, STTS. Therefore, the data bit DTBT of the packet PKTB allows the transmission device (100) to identify the terminal device (200) and to perform a predetermined operation, for example, control of turning on / off the reading light (212). You can Further, since the data bit DTBT of the first packet PKTA has only one upstream channel, it is used as a flag of the usage state of this upstream channel, and the flag is set when the upstream channel is used. Therefore, the terminal device (200) receives this packet PKT.
Whether or not the uplink channel can be used can be determined by the data bit DTBT of A, and when the channel is in use, it waits for the command (and data) to be issued to the transmission device (100) until it becomes free. Note that the third and fourth packets PKTC and PKTD are undefined. Further, in the above description, the passenger plane is taken as an example, but in the case of providing service to a large number of opponents, trains,
It can also be applied to vehicles such as buses, theaters and stadiums. H Effect of the Invention According to the present invention, since the transmission data has a configuration suitable for the scale of the data to be handled, the transmission control is facilitated and the load on the hardware and software can be reduced. That is, since the data packet has a fixed length of 7 bytes, transmission / reception can be performed more easily. Also, 256 types of command CMD can be set, which is a sufficient type for the function of the in-flight system, and various services can be realized. Further, since the address ADRS for specifying the seat or the terminal device (200) is 2 bytes, 650,000 or more seats can be specified, or groups can be made, and various services can be effectively realized. In addition, taking advantage of the fact that data transmission can be performed relatively well onboard, data error checking is performed using an 8-bit checksum CS, so the software or hardware for this error checking should be simple. can do. Furthermore, system adjustment, debugging, and maintenance are usually performed while observing the signal waveform. At this time, the command CMD is divided into groups for upstream channels, downstream channels, and both directions. Since this command CMD is used, the issue destination of that command CMD or the data following this command CMD can be determined, and therefore adjustment, debugging, and maintenance inspection can be easily performed. Moreover, since it can be integrated with an audio / video system, the entire system can be simplified and the expandability can be enhanced. In addition, since the status and demands of the passengers can be centrally managed or monitored, various services such as software for providing services to the passengers from the transmission device (100) or types of meals can be realized in detail.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a system diagram of an example of the present invention, and FIGS. 2 to 5 are diagrams for explaining the same. (100) is a transmitting device, (101) is a master control unit, (110) to (115) and (121) to (129) are video signal or audio signal sources, (151) and (152) are encoders, (161) to (167) are modulation circuits, (200) is a terminal device, (205) is a decoder, and (206) is a selection display unit.

Claims (1)

(57) [Claims] In a transmission method for bidirectionally transmitting a command signal between a transmission side and a terminal device side, a command signal transmitted in the downlink channel direction from the transmission side to the terminal device side and the transmission from the terminal device side to the transmission The command signal transmitted in the upward channel direction to the side and the command signal used in the channels in both directions are configured by a combination of the upper bit and the lower bit, and in the downlink channel direction. The command signals to be transmitted, the command signals to be transmitted in the upward channel direction, and the command signals to be used in the channels in both directions are grouped so that the relationship between the upper bits and the lower bits is different. A method of transmitting a command signal, characterized in that