JP3684605B2 - Transmission method, transmission apparatus and server system - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a transmission method, a transmission apparatus, and a server system, and more particularly to a transmission method, a transmission apparatus, and a server system that can variably set image conditions such as hue, color difference level, and luminance level of an image signal.
[0002]
[Prior art]
Server systems used in television broadcasting stations have different image signal supply sources such as an image signal reproduced by a magnetic tape reproducing device or an image signal transmitted wirelessly and received by an antenna, or the same supply source. Even so, receiving means for receiving image signals having different image conditions such as hue, color difference level, and luminance level depending on the transmission state and the image signal level on the supply source side, and storing the image signals received by the receiving means Storage means, a video decoder (hereinafter referred to as DEC) for converting the image signal stored in the storage means based on a set image condition, and outputting the image signal read from the storage means. And an output unit such as a monitor, and an operation unit for setting the image condition, setting the image output operation of the image output unit, setting the operation of the storage unit, and the like. Control means, an intelligent device controller that performs for setting the image condition in the image output and the DEC from the image output unit comprising comprising (hereinafter, referred to as. IDC) and.
[0003]
The DEC has a first transmission line to which an image signal is supplied from the storage means and a second transmission line to which an image condition is supplied from the IDC.
[0004]
In the server system configured as described above, the operator causes the image signal read out from the storage means by the IDC operation means to be displayed on the output means, and predetermined conditions suitable for on-air are obtained based on the output results. The image condition set in this way is supplied from the IDC to the DEC via the second transmission path, and is supplied from the storage means via the first transmission path based on the image condition by the DEC. Send the image signal at a level suitable for on-air.
[0005]
[Problems to be solved by the invention]
By the way, when constructing a server system provided with a plurality of the DECs, it is necessary to provide the first and second transmission paths in each DEC, and the arrangement of the first and second transmission paths is complicated. In addition, in the IDC, the DEC for setting the image condition is designated by the operation means of the IDC, or the second transmission path is selected by the IDC according to the designated DEC. An operation such as supplying an image condition to the second transmission path is required, which causes a problem that the configuration and operation of the IDC become complicated.
[0006]
In view of the above problems, an object of the present invention is to provide a server system with a simple configuration and operation, and a transmission method and a transmission apparatus suitable for use in the server system.
[0007]
[Means for Solving the Problems]
  The transmission method according to the present invention, which has achieved this object, provides a supplied image signal.A conversion step of converting the information signal into a transmission format information signal conforming to the serial digital data interface (SDDI), and a monitor signal transmission step of decoding the information signal converted by the conversion step and transmitting an outputable information signal , Luminance information, color difference information, and hue information as image conditions of the image signal to be transmitted from the information signal that can be output sent in the monitor signal sending stepImage condition detection process for detecting the image condition and the detection result of the image condition detection processBrightness information, color difference information and hue information as image conditions of the image signal to be transmitted according toA variable image condition setting step;Information signal obtained by converting the attribute information signal including the luminance information, color difference information and hue information set as the image condition of the image signal transmitted in the image condition setting step as video signal control information in the conversion step.A multiplexing step of multiplexing in frame units,The information signal in which the attribute information signal is multiplexed in the frame in the multiplexing step is decoded based on the video signal control information included in the attribute information signal multiplexed on the information signal, and an image signal is output.A decoding step.
[0008]
  A transmission apparatus according to the present invention that achieves the above object is provided.Conversion means for converting an image signal into an information signal in a transmission format compliant with a serial digital data interface (SDDI), and monitor signal transmission for decoding the information signal converted by the conversion means and sending out an outputable information signal Luminance information, color difference information, and hue information as image conditions of the image signal to be transmitted from the information signal that can be output from the means and the monitor signal transmission meansImage condition detection means to detect and detection results of the image condition detection meansBrightness information, color difference information and hue information as image conditions of the image signal to be transmitted according toImage condition setting means for variably setting;An attribute information signal including luminance information, color difference information and hue information set as image conditions of an image signal transmitted by the image condition setting means as video signal control information is converted into an information signal converted by the conversion means in frame units.Multiplexing means for multiplexing;An information signal obtained by multiplexing the attribute information signal in frame units by the multiplexing means is decoded based on video signal control information included in the attribute information signal multiplexed on the information signal, and an image signal is output.Decoding means.
[0009]
  A server system according to the present invention that achieves the above-described object,Conversion means for converting the supplied image signal into an information signal in a transmission format compliant with a serial digital data interface (SDDI), and decoding the information signal converted by the conversion means to send out an information signal that can be output. Luminance information, color difference information, and hue information are output as image conditions of the image signal to be transmitted from the monitor signal transmission means and the information signal that can be output from the monitor signal transmission means.Image condition detection means to detect and detection results of the image condition detection meansBrightness information, color difference information and hue information as image conditions of the image signal to be transmitted according toImage condition setting means for variably setting;An attribute information signal including luminance information, color difference information and hue information set as image conditions of an image signal transmitted by the image condition setting means as video signal control information is converted into an information signal converted by the conversion means in frame units.Multiplexing means for multiplexing;Information signal in which attribute information signal is multiplexed on a frame basis by the multiplexing meansStorage means for storing and stored in the storage meansAn information signal is decoded based on video signal control information included in an attribute information signal multiplexed on the information signal, and an image signal is output.Decoding means.
[0010]
The storage means is characterized in that a detachable recording medium is mounted and an image signal is recorded on the mounted recording medium.
[0011]
The storage means is characterized in that a plurality of detachable recording media are mounted, and an image signal is recorded by selectively selecting the plurality of mounted recording media.
[0012]
[Action]
  According to the transmission method according to the present invention having the above configuration, the multiplexing step in the decoding stepAn information signal in which the attribute information signal is multiplexed in frame units is decoded based on video signal control information included in the attribute information signal multiplexed in the information signal, and an image signal is output.
[0013]
  According to the transmission apparatus of the present invention, the decoding means uses the multiplexing means.An information signal in which the attribute information signal is multiplexed in units of frames is decoded based on video signal control information included in the attribute information signal multiplexed in the information signal, and an image signal is output..
[0014]
  According to the server system of the present invention, the storage meansInformation signal with attribute information signal multiplexed in frame unitsStored in the storage means by the decoding meansAn information signal is decoded based on video signal control information included in an attribute information signal multiplexed on the information signal, and an image signal is output..
[0015]
Further, the storage medium of the storage means is made detachable.
[0016]
Further, a plurality of storage media of the storage means can be attached and detached, and the plurality of recording media are selectively selected and used.
[0017]
【Example】
Hereinafter, a preferred embodiment of a server system according to the present invention will be described with reference to the drawings.
[0018]
As shown in FIG. 1, the server system 10 according to the present invention includes a receiving unit 1 that receives an information signal such as an image signal and an audio signal, an SDI / SDDI converting unit 2 that converts a transmission format of the information signal, Monitor signal sending means 3 for sending the information signal supplied from the SDI / SDDI conversion means 2 so as to be able to output an image, and multiplexing means 4 for multiplexing the condition signal to the information signal supplied from the SDI / SDDI conversion means 2 A storage means 5 for storing the information signal multiplexed with the condition signal by the multiplexing means 4, a decoding means 6 for decoding the information signal supplied from the storage means 5, and the decoding means 6 And an IDC 8 for controlling the SDI / SDDI conversion means 2, the multiplexing means 4, the storage means 5 and the decoding means 6.
[0019]
The receiving means 1 is supplied with an information signal such as an image signal or an audio signal standardized by the NTSC method or the PAL method from an information supply source such as an antenna 71 or a magnetic tape reproducing device 72 that has received a radio signal. An amplifier 11 for amplifying the information signal supplied from 71, a trigger detection circuit 12 for detecting the start and end of the supply of the information signal supplied from the antenna 71 to the amplifier 11, and the amplifier 11 and the magnetic tape reproducing device And a signal processing circuit 13 provided with first and second interfaces 13a and 13b for performing signal processing such as noise removal of the information signal supplied from 72 and transmitting the signal processed information signal.
[0020]
The SDI / SDDI conversion means 2 performs A / D conversion on the information signals supplied from the first and second interfaces 13a and 13b of the signal processing circuit 13 of the reception means 1, and is standardized by a serial digital interface (SDI). SDI decoder circuits 15a and 15b for converting to a format to be converted, and an SDI / SDDI converter 16a for converting an information signal supplied from the SDI decoder circuits 15a and 15b to a format proposed as a serial digital data interface (SDDI) 16b.
[0021]
The SDI is standardized by SMPTE-295M of Society of Motion Picture and Television Engineerings (SMPTE), which issues standards relating to television and video engineering, as a standard for digital audio signals and video signals. This standard is basically a signal standard for D-1 format or D-2 format which is a digital signal standard. FIG. 2 shows a schematic configuration of an SDI format using a D-1 format signal.
[0022]
FIG. 2A shows a frame format consisting of 1716 words in the horizontal direction and 525 lines in the vertical direction. The digital video signal is a first field active video portion AVC having 1440 words in the horizontal direction and 244 lines in the vertical direction.₁And 243 lines of the second field active video part AVC₂Placed on the part. Specifically, the first field active video unit AVC₁Is an odd-field digital video signal, and the second field active video portion AVC₂Is an even field digital video signal. This first field active video part AVC₁And the second field active video part AVC₂Before the vertical blanking part VBK for 9 lines₁, VBK₂And optional blanking section OBK for 10 lines₁, OBK₂Are inserted respectively. In addition, the first field active video unit AVC₁, Second field active video part AVC₂, Vertical blanking part VBK₁, VBK₂, And optional blanking section OBK₁, OBK₂Before and after are inserted a 4-word start synchronization code SAV indicating the start of the active line and a 4-word end synchronization code EAV indicating the end of the active line. Further, an ancillary data portion HANC, which is auxiliary data for horizontal blanking for 268 words, is placed between the start synchronization code SAV and the end synchronization code EAV. FIG. 2B shows the signal in the frame format shown in FIG. 2A in a 10-word width line format. When a signal in the SDI format is transmitted, as shown in FIG. 2C, parallel-serial conversion and transmission path encoding are performed, and the data signal is transmitted as a serial signal having a data rate of 270 Mbps.
[0023]
The SDDI format is based on D-1 format signals. Similar to the SDI format, the first data part DT₁And the second data part DT₂And the first data portion DT₁And the second data part DT₂Before the blank data part BDT₁, BDT₂Are inserted. The data part DT₁, DT₂And blank data part BDT₁, BDT₂Are preceded by a 4-word start synchronization code SAV and an end synchronization code EAV. Further, an ancillary data portion ANC which is auxiliary data is placed between the start synchronization code SAV and the end synchronization code EAV.
[0024]
Thus, the SDDI format is an extension of the SDI format while maintaining compatibility with the SDI format. Specifically, the position and number of lines of the frame format shown in FIG. 3A, that is, the blank data portion BDT in the vertical format can be freely changed by setting the data type and line number described later. is there. Therefore, it is possible to set the same as the SDI format. Therefore, even in a system configuration in which signals are switched in the vertical blanking interval by an existing router, switcher, etc., the SDDI format data is used by previously completing the unit in the vertical blanking interval. be able to. Also, depending on the data setting, it is possible to insert valid data into the entire section of the frame to form the data part DT, so that data in this SDDI format can be constructed with a flexible system. .
[0025]
The line format shown in FIG. 3B, that is, the horizontal format is composed of a 4-word end synchronization code EAV, a 268-word ancillary data portion ANC, a 4-word start synchronization code SAV, and a 1440-word payload portion PAD. Also in the line format of the SDDI format, the start synchronization code SAV and the end synchronization code EAV are inserted as in the SDI format line format. Therefore, compatibility between the signal in the SDDI format and the signal in the SDI format can be maintained.
[0026]
Further, when transmitting a signal in the SDDI format, parallel-serial conversion and transmission path coding are performed in the same manner as in the signal in the SDI format, and the data is transmitted as a serial signal having a data rate of 270 Mbps shown in FIG. 3C. .
[0027]
Next, FIG. 4 shows a specific configuration of the SDDI format.
[0028]
As shown in FIG. 4A, at the head of the ancillary data portion ANC, a line number area LN indicating the number of the line to which this line data corresponds is placed. By setting the line number, a vertical blanking section having a specific line number can be reproduced as in the SDI format. In the ancillary data section ANC, an audio data area AD₁, AD₂, AD_ThreeAnd control data area CD₁As described above, audio data and control data of a plurality of channels can be mixed, and data of one channel can occupy a variable length data area based on the transmission rates of a plurality of media. . Specifically, the audio data area AD or the control data area CD is combined with the flag FG to form one channel data. For example, as shown in FIG. 4A, the flag FG₁Audio data area AD₁, Flag FG₂Audio data area AD₂, Flag FG_ThreeControl data area CD₁, Flag FG_Four... and continue.
[0029]
As shown in FIG. 4B, one data channel includes a type area TP, a byte count area BC, an error correction code ECC, and a data area DT.
. The type area TP indicates the contents of data in the data area DT, the byte count area BC indicates the length of data in the data area DT, and the error correction code ECC is a check of the type area TP and byte count area BC for each medium. It is a thumb or CRC (Cyclic Redundancy Check) code or the like, and error detection and correction of the type area TP and the byte count area BC are performed by this error correction code ECC.
[0030]
Also, video data of a plurality of channels can be mixed in the payload part PAD. The video data of each channel includes a flag FG and a video data area VD. As shown in FIG. 4C, the flag FG₁Video data area VD₁, Flag FG₂Video data area VD₂, Flag FG_ThreeVideo data area VD_Three, Flag FG_FourVideo data area VD_Four, Flag FG_Five... and continue. As shown in FIG. 4D, one data channel includes a type area TP, a byte count area BC, an error correction code BCC, and a data area DT, similarly to the configuration of the data channel in the ancillary data section ANC.
[0031]
The monitor signal sending means 3 includes decoding means 18a and 18b for decoding information signals in the SDDI format supplied from the SDI / SDDI converters 16a and 16b of the SDI / SDDI conversion means 2, and the decoding means 18a, Encoder circuits 19a and 19b that D / A convert the information signal supplied from 18b and output an image signal and an audio signal.
[0032]
The multiplexing means 4 includes server data controllers (hereinafter referred to as SDC) 21 to 28 that multiplex attribute information signals with information signals in the SDDI format supplied from the SDI / SDDI conversion means 2.
[0033]
In the multiplexing means 4, as shown in FIG. 5, two frames of information signals are made into one pack, and attribute information signals are sent to the attribute portions AT1 and AT2 which are part of the areas vacated by the compression processing of the data portions DT1 and DT2. Multiplex.
[0034]
As shown in FIG. 6, the attribute information signal has a separate part SP that can be distinguished from other information signals at the head, and in order from the separate part SP, the attribute information part AT, the attribute control part ATC, and the video information part VC. The video process control unit VPC is arranged, and the terminal unit ED is arranged at the final part. In the attribute information portion AT, type information indicating an attribute command sequence and word count information indicating the number of words of the attribute information signal are set. In the attribute control unit ATC, type information indicating that the data is control information, count information indicating the number of words of the data, and data information are set. In the video information portion VC, type information indicating control information of an image signal and count information indicating the number of words of the control information are set. Luminance information, color difference information, and hue information are set in the video process control unit VPC.
[0035]
As shown in FIG. 7, the identification signal SK that can be identified for each pack is arranged at the head of the information signal of one pack, and the image signal area VD, the audio signal format area EF, and the audio signal are sequentially arranged from the identification section SK. The area AD is arranged, and the terminal part SE is arranged at the final part. In the identification unit SK, separate information indicating the head of one pack, type information indicating the information signal sequence, and word count information indicating the number of words of the information signal sequence are set. In the image signal area VD, an image signal for two frames is formed as one GOP. A frame head indicating the head of each frame, system information indicating the format of the 1 GOP, index information of the image signal, an image signal, and image data are stored. Be placed. The audio signal format area EF includes separate information indicating the head of the audio signal format area EF, type information indicating the format information, count information indicating the number of words of the format information, and a frame of an audio signal of 1 GOP. Channel information indicating the number and mute information indicating normal or mute for each channel of the 1 GOP are set. The audio signal area AD has a capacity of 8 GOP with an audio signal for 2 frames as 1 GOP, and audio format information and audio signals are arranged in GOP units.
[0036]
As described above, the multiplexing unit 4 multiplexes the attribute information set by the IDC 8 in the attribute part.
[0037]
The storage means 5 is a magneto-optical disk drive or the like (hereinafter referred to as MOD) 31 that records and reproduces information signals supplied from the SDCs 21 to 28 of the multiplexing means 4 independently, for example, on a magneto-optical disk. ~ 38.
[0038]
The decoding means 6 decodes the information signals supplied from the MODs 31 to 38 of the storage means 5 and performs SDDI / SDI conversion, and based on the attribute information signals multiplexed on the information signals, the information signals Decoder circuits 41 to 48 that variably set the signal levels independently of each other.
[0039]
The transmission unit 7 outputs the image signal supplied from the decoding circuits 41 to 48 of the decoding unit 6 selected by the IDC 8 via the switcher 30 on a monitor or the like and outputs the audio signal on a speaker or the like. Encoder circuits 51 to 58 that perform the D / A conversion.
[0040]
The IDC 8 includes a control unit 61 and an image condition setting unit 65 which are connected via an internet defined by a local area network (LAN) or the like. The control unit 61 is supplied with a start trigger signal from the trigger detection circuit 12 of the receiving means 1, the magnetic tape reproducing device 72, etc., and based on the start trigger signal, the SDI / SDDI converters 16 a and 16 b of the SDI / SDDI converting means 2. And SDC 21 to 28 of the multiplexer 4 are switched and set, the timing of the multiplexing process of the multiplexer 4 and the attribute information multiplexing operation is controlled, and the information signal in which the attribute information is multiplexed is stored. 5 and the timing for supplying the information signal from the storage means 5 to the decoding means 6 is controlled. The image condition setting means 65 variably sets the signal levels of the level variable circuits 18a and 18b of the monitor signal sending means 3 to a level suitable for on-air while monitoring the information signal supplied from the monitor signal sending means 3. The level control circuits 66a and 66b are used to set the attribute information signal in the SDC selected by the control unit 61 using the set level signal as attribute information.
[0041]
The server system 10 having the above-described configuration is based on the information signal supplied from the SDI decoder circuits 15a and 15b of the SDI / SDDI conversion means 2 while the operator detects the detection result of the monitor signal sending means 3 on the monitor. Attribute information suitable for turning on air is selected by variable setting of the level variable circuits 18a and 18b of the signal transmission means 3, and the SDI / SDDI converter of the SDI / SDDI conversion means 2 is selected as shown in FIGS. The SDCs 21 to 28 of the multiplexing circuit 4 connected to 16a and 16b are controlled by switching the routing switch 20 of the IDC 8, and the attribute information is supplied from the IDC 8 to the selected SDCs 21 to 28. The attribute information is multiplexed with the information signal, and the storage means 5 Ribyuto information records information signals multiplexed in MOD31～38. Information signals recorded in the MODs 31 to 38 of the storage unit 5 are supplied from the MODs 31 to 38 selected by switching of the routing switch 20 under the control of the IDC 8 to the decoding circuits 41 to 48 of the decoding unit 6, The decoding circuit 41 to 48 decodes the information signal based on the attribute information and supplies it to the encoders 51 to 58 of the transmission means 7 for on-air. Thus, the monitor signal sending means 3 and the IDC 8 function as an image condition detecting means and an image condition setting means.
[0042]
The image condition detecting means, the image condition setting means, the multiplexing means 4 and the decoding means 6 constituting the server system 10 function as a transmission device, and the transmission method is implemented by these functions.
[0043]
Therefore, according to the transmission method of the present invention, the image signal in which the image condition is multiplexed in the multiplexing process in the decoding process is decoded based on the image condition, and the operation from the multiplexing process to the decoding process is simplified. It becomes.
[0044]
Further, according to the transmission apparatus of the present invention, the image signal in which the image condition is multiplexed by the multiplexing means 4 in the decoding means 6 is decoded based on the image condition, and the multiplexing means 4 to the decoding means 6 The transmission of the image signal to the camera is performed by one system, and the configuration is simple.
[0045]
Further, according to the server system of the present invention, the image signal in which the image condition is multiplexed is stored in the storage means 5, and the image condition stored in the storage means 5 is multiplexed in the decoding means 6. Is decoded based on the image condition, and the image signal is transmitted from the multiplexing means 4 to the storage means 5 and from the storage means 5 to the decoding means 6 in one system, and the image signal is stored and decoded with a simple configuration. Turn into.
[0046]
The storage medium of the storage means is a detachable magneto-optical disk. Therefore, the magneto-optical disk can be used with compatibility with other server systems and other external devices.
[0047]
Further, the storage means 5 is composed of MODs 31 to 38, a plurality of magneto-optical disks can be attached and detached, the plurality of magneto-optical disks are selectively selected and used, and images supplied from a plurality of image signal supply sources are used. Signals can be stored independently, and filing for each supply source is simplified.
[0048]
【The invention's effect】
  As described above in detail, according to the transmission method of the present invention, in the decoding step, the multiplexing step.An information signal in which the attribute information signal is multiplexed in units of frames is decoded based on video signal control information included in the attribute information signal multiplexed in the information signal, and an image signal is output.To do. For this reason, it is possible to provide a transmission method in which the operation from the multiplexing process to the decoding process is simple.
[0049]
  According to the transmission apparatus of the present invention, the decoding means uses the multiplexing means.An information signal in which the attribute information signal is multiplexed in units of frames is decoded based on video signal control information included in the attribute information signal multiplexed in the information signal, and an image signal is output.. For this reason, it is possible to provide a transmission apparatus having a simple configuration in which transmission of image signals from the multiplexing means to the decoding means is performed in one system.
[0050]
  According to the server system of the present invention, the storage meansInformation signal with attribute information signal multiplexed in frame unitsStored in the storage means by the decoding meansAn information signal is decoded based on video signal control information included in an attribute information signal multiplexed on the information signal, and an image signal is output.. For this reason, the transmission of the image signal from the multiplexing means to the storage means and from the storage means to the decoding means is performed in one system, and it is possible to provide a server system that stores and decodes the image signal with a simple configuration.
[0051]
Further, the storage medium of the storage means is made detachable. Therefore, the recording medium can be used with compatibility with other server systems and other external devices.
[0052]
Further, a plurality of storage media of the storage means can be attached and detached, and the plurality of recording media are selectively selected and used. For this reason, the image signals supplied from a plurality of image signal supply sources can be stored independently, and the usability is improved by simplifying filing for each supply source.
[Brief description of the drawings]
FIG. 1 is a block diagram of a server system according to the present invention.
FIG. 2 is a schematic configuration diagram of an SDI format of the server system.
FIG. 3 is a schematic configuration diagram of an SDDI format of the server system.
FIG. 4 is a specific configuration diagram of a line format of the SDDI format.
FIG. 5 is a configuration diagram of a frame in the line format.
FIG. 6 is a configuration diagram of an attribute information portion of the line format after compression.
FIG. 7 is a configuration diagram of a compressed information signal in the line format.
FIG. 8 is a block diagram of a main part of the server system according to the present invention.
[Explanation of symbols]
3 Monitor signal sending means
4 Multiplexing means
5 Memory means
6 Decryption means
8 Intelligent Device Controller (IDC)
10 Server system

Claims (5)

A conversion step of converting the supplied image signal into an information signal of a transmission format compliant with a serial digital data interface (SDDI);
A monitor signal sending step for decoding the information signal converted by the converting step and sending an information signal that can be output;
An image condition detection step of detecting luminance information, color difference information and hue information as image conditions of the image signal to be transmitted from the information signal that can be output sent in the monitor signal sending step ;
An image condition setting step for variably setting luminance information, color difference information and hue information as image conditions of an image signal to be transmitted according to the detection result of the image condition detection step;
The attribute information signal including luminance information, color difference information, and hue information set as the image condition of the image signal transmitted in the image condition setting step as video signal control information is multiplexed in frame units on the information signal converted in the conversion step. A multiplexing process,
Decoding that outputs an image signal by decoding the information signal in which the attribute information signal is multiplexed in frame in the multiplexing step based on the video signal control information included in the attribute information signal multiplexed in the information signal A transmission method comprising the steps. Conversion means for converting the supplied image signal into an information signal in a transmission format compliant with a serial digital data interface (SDDI);
A monitor signal sending means for decoding the information signal converted by the converting means and sending out an outputable information signal;
Image condition detection means for detecting luminance information, color difference information and hue information as image conditions of the image signal to be transmitted from the information signal which can be output from the monitor signal transmission means ;
Image condition setting means for variably setting luminance information, color difference information and hue information as image conditions of an image signal to be transmitted according to the detection result of the image condition detection means;
An attribute information signal including luminance information, color difference information, and hue information set as image condition of an image signal transmitted by the image condition setting means as video signal control information is multiplexed on an information signal converted by the conversion means on a frame basis. Multiplexing means for
Decoding that decodes the information signal in which the attribute information signal is multiplexed in frame units by the multiplexing means based on the video signal control information included in the attribute information signal multiplexed in the information signal and outputs an image signal And a transmission device. Conversion means for converting the supplied image signal into an information signal in a transmission format compliant with a serial digital data interface (SDDI);
A monitor signal sending means for decoding the information signal converted by the converting means and sending out an outputable information signal;
Image condition detection means for detecting luminance information, color difference information and hue information as image conditions of the image signal to be transmitted from the information signal which can be output from the monitor signal transmission means ;
Image condition setting means for variably setting luminance information, color difference information and hue information as image conditions of an image signal to be transmitted according to the detection result of the image condition detection means;
An attribute information signal including luminance information, color difference information, and hue information set as image condition of an image signal transmitted by the image condition setting means as video signal control information is multiplexed on an information signal converted by the conversion means on a frame basis. Multiplexing means for
Storage means for storing an information signal in which the attribute information signal is multiplexed in frame units by the multiplexing means;
A server system comprising: decoding means for decoding an information signal stored in the storage means based on video signal control information contained in an attribute information signal multiplexed with the information signal and outputting an image signal .   4. The server system according to claim 3, wherein the storage means is mounted with a detachable recording medium and records the image signal on the mounted recording medium.   4. The server system according to claim 3, wherein the storage means is loaded with a plurality of detachable recording media, and selectively selects the plurality of loaded recording media to record an image signal.

Images