JPH0937167A - Device and method for controlling electronic program guide display - Google Patents

Abstract

PROBLEM TO BE SOLVED: To more efficiently select a desired program by controlling the display state of an electronic program guide corresponding to the setting of the use of a display. SOLUTION: When a user operates a remote commander, a CPU 29 controls an MPEG video decoder 25 and a system menu is displayed on a monitoring device. When the user selects an installation menu in the system menu, the CPU 29 makes it be displayed on the monitoring device. When the user selects aspect ratio setting from the displayed menu, the CPU 29 makes an aspect ratio setting screen be displayed on the monitoring device. In this case, the user opedates the remote commander, selects whether the aspect ratio of the monitoring device possessed by himself/herself is the standard one of 4:3 or the wide aspect ratio of 16:9 and performs setting. The setted result is stored in an EEPROM 38. Thereafter, when the program chart switch of the remote commander is operated, the CPU 29 reads the setting of the ROM 38 and controls the display state.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic program guide display control device and method, and more particularly, to an electronic program guide display control device and method capable of displaying an electronic program guide more efficiently.

[0002]

2. Description of the Related Art Recently, a system in which a television signal is digitized and transmitted via a satellite such as a broadcasting satellite or a communication satellite and is received in each home is becoming popular. In this system, for example, nearly 80 channels can be secured, so that an extremely large number of programs can be broadcast.

Thus, when the number of channels increases,
It becomes difficult to quickly and surely select a desired program from many programs. Therefore, an electronic program guide (EPG: Elec) is provided so that a desired program can be selected.
It has been proposed to transmit a Trial Program Guide), display it on the display of the receiving side, and select a desired program from this electronic program guide.

[0004]

By the way, recently, a display having an aspect ratio of 16: 9 is becoming widespread instead of the display having the aspect ratio of 4: 3 of the NTSC system which has been widespread until then.

In the conventional EPG system, since the same EPG is always displayed regardless of the aspect ratio of such a display, there is a problem that it is difficult to efficiently select a program. .

The present invention has been made in view of such a situation, and it is possible to select a desired program more efficiently.

[0007]

An electronic program guide display control device according to claim 1, wherein the electronic program guide display control device includes setting means for setting information regarding specifications of a display for displaying an electronic program guide.
And a control means for controlling the display state of the electronic program guide on the display corresponding to the setting of the setting means.

According to a fourth aspect of the present invention, there is provided an electronic program guide display control method, wherein information regarding specifications of a display for displaying the electronic program guide is set, and the display state of the electronic program guide on the display is controlled according to the setting. Is characterized by.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an example of the configuration of a transmitting device to which the present invention is applied. This transmitting device is provided with a switcher 301, and in this switcher 301, for example, in the United States, CNN, GAORA, Asahi, STAR, TR.
Broadcasting stations such as Y, MTV, Super, Sports, BBC, CSNI, Green (trademark or service mark),
In Japan, video data and audio data supplied from broadcasting stations such as NHK, NTV, TBS TV, Fuji TV, TV Asahi, TV Tokyo, and WOWOW (trademark or service mark) are input as digital data.

Alternatively, the switcher 301 has a digital video tape recorder (DVT) (not shown).
The digital video signal and the audio signal reproduced by R) are input.

The switcher 301 is a program transmission control device 3
Controlled by 08, a plurality of predetermined broadcast channels (however, in this case, the video signal and the audio signal are counted as one broadcast channel) are selected from the input video signal and audio signal, and a promotion channel is generated. Output to the device 302.

Further, the switcher 301 selects five predetermined broadcast channels from the input signal, and the MPE
Output to the G video / audio encoder block 303-1. Similarly, the MPEG video / audio encoder blocks 303-2 to 303-7 have a predetermined number of 5
Select and output signals for broadcast channels.

Further, the predetermined video signal output from the switcher 301 is supplied to the JPEG encoder block 310 incorporated in the EPG data generator 309.

Promotion channel generation device 302
Processes the signals of two predetermined channels among the input signals of the plurality of broadcast channels independently.

Further, the promotion channel generation device 302 has bit map data (such as icons, station logos, category logos, etc. to be transmitted generated by the EPG data generation device 309 under the control of the program transmission control device 308. , Which can be stored in advance on the IRD2 side of FIG. 20 to be described later). The promotion channel generation device 302 superimposes the bitmap data on the video signal input from the switcher 301.

Promotion channel generation device 302
Processes the processed data into a multiplexer (MUX) 30.
Output to 4-1. The details of the promotion channel generation device 302 will be described later with reference to FIG.

The MPEG video / audio encoder blocks 303-1 to 303-7 are connected to the switcher 301.
In order to be able to encode the video and audio signals for each of the 5 broadcast channels input from the
It incorporates (five) MPEG video / audio encoders for five channels. The MPEG video / audio encoders 303-1 to 303-7 encode the input video data and audio data and output them to the corresponding multiplexers 304-2 to 304-8.

The JPEG video encoder block 310 built in the EPG data generation device 309 displays a predetermined representative screen from the video signal input from the switcher 301 in response to a command from the program transmission control device 308. The representative screen is selected, and the representative screen is reduced to a small screen. Further, the data of the reduced screen is compressed to be the first EPG data (EPG1), and the multiplexer 30
It outputs to 4-1 to 304-8.

Further, the multiplexers 304-2 to 30-30
Other EPG data (EPG2) generated by the EPG data generation device 309 is supplied to 4-8.
This EPG2 includes EPG data centered on a text of a relatively short period. The multiplexer 3
04-1 includes the EPG data of EPG2 and the third EPG data (E
PG3) is supplied.

Multiplexers 304-2 to 304-8
And the multiplexer 304-1 transmits these EPG1 to EPG3 or EPG1 and EPG2 to the MPEG video / audio encoder blocks 303-1 to 30.
3-7, or promotion channel generation device 3
Video data and audio data input from H.02, and digital modulation circuits 305-2 to 305
-8 or output to the digital modulation circuit 305-1. The digital modulation circuits 305-1 to 305-8 use input digital data in a predetermined method (for example, QPSK method).
Digitally modulate with. These digital modulation circuits 305
Outputs -1 to 305-8 are assigned to the transponders of the satellite (transponders 1 to 8 in FIG. 12, which will be described later), respectively.

The synthesis circuit 306 is a digital modulation circuit 30.
The outputs of 5-1 to 305-8 are combined to form an antenna 307.
To the satellite via.

FIG. 2 shows a configuration example of the promotion channel generation device 302. The data of one broadcast channel output from the switcher 301 is processed as a single screen by the single screen generation device 332-1. The output is then the Super Imposer 333-
The data input to 1 and supplied from the EPG data generation device 309 is superimposed. The output of the super-imposer 333-1 is output to the MPEG video / audio encoder block 334-1.

Similarly, the data for the remaining one broadcast channel output from the switcher 301 is independently processed by the single screen generation device 332-2 and then input to the super-imposer 333-2, and the EPG data is transmitted. The data input from the generation device 309 is superimposed. The data output from the super imposer 333-2 is input to the MPEG video / audio encoder block 334-2 and encoded.

The individual screen generation devices 332-1 and 33-3
The audio data for each channel captured in 2-2 is recorded by the MPEG video / audio encoder 33.
4-1 and 334-2 are encoded respectively.

The data output from the MPEG video / audio encoder blocks 334-1 and 334-2 are multiplexed by the multiplexer 335 and output to the multiplexer 304-1.

In this way, the European standard of digital video broadcasting carried out toward the receiving device (IRD2 in FIG. 20) arranged in each home via the satellite is mainly based on European broadcasters and manufacturers. About 150 companies participate in the DVB (Digital Video Broadcast) project
However, on the receiving side, the EP transmitted in this way is in accordance with this standard.
An electronic program guide screen can be generated from the G data and displayed on the monitor device.

Next, the operation of the embodiment shown in FIGS. 1 and 2 will be described. The switcher 301 is controlled by the program transmission control device 308, selects signals for two channels to be broadcast for promotion, and outputs them to the promotion channel generation device 302.

The data of one channel output from the switcher 301 is subjected to predetermined processing in the single screen generation device 332-1, and then the superimposer 3
33-1 is input. This single-screen program introduces a part of the program in order to advertise a predetermined program, for example. FIG. 3 shows a display example of this promotion program.

The superimposer 333-1 superimposes the data input from the EPG data generator 309 on this video data. In the display example of FIG. 3, the characters “promotion channel 1 NHK” as the item name displayed at the upper left, the characters “program introduction” as the item contents, and the broadcast that actually broadcasts this program The logo of the station (station) (“NHK” in this embodiment) is superimposed (however, if the station logo is stored on the IRD 2 side, it is not superimposed).

The output of the super-imposer 333-1 is input to the MPEG video / audio encoder block 334-1 and encoded by the MPEG2 system.

The single screen generation device 332-2, the superimposer 333-2, and the MPEG video / audio encoder block 334 are also applied to the signal of the remaining one channel selected by the switcher 301.
-2, the same processing is performed. Therefore, in this embodiment, two promotion channels for introducing a program on a single screen are generated.

The multiplexer 335 is an MPEG video / audio encoder block 334-1, 334-.
The data of the promotion channel consisting of the two independent screens output from 2 is multiplexed and the multiplexer 30
Output to 4-1.

The multiplexer 304-1 receives the EPG data input from the promotion channel generation device 302 and the EPG data input from the EPG data generation device 309.
The data EPG1 to EPG3 are multiplexed, packetized, and output. The digital modulation circuit 305-1 digitally modulates the data input from the multiplexer 304-1. The data output from the digital modulation circuit 305-1 is assigned to the guide transponder (transponder 1 in FIG. 12) of the satellite.

On the other hand, the MPEG video / audio encoder block 303-1 encodes the video data and audio data for 5 broadcast channels input from the switcher 301 and outputs them to the multiplexer 304-2. The multiplexer 304-2 packetizes these five broadcast data and the EPG data EPG1 and EPG2 supplied from the EPG data generation device 309, multiplexes them, and outputs them to the digital modulation circuit 305-2. The digital modulation circuit 305-2 includes the multiplexer 3
The data input from 04-2 is digitally modulated. The data digitally modulated by the digital modulation circuit 305-2 is assigned to the first transponder (transponder 2 in FIG. 12) of the normal transponders.

Thereafter, in the same manner, the multiplexer 304
-3 to 304-8 are packetized and multiplexed with the data of the other five broadcast channels encoded by the MPEG video / audio encoder blocks 303-2 to 303-7 and the EPG data EPG1 and EPG2, Corresponding digital modulation circuits 305-3 to 3
Enter it in 05-8. The digital modulation circuits 305-3 to 305-8 digitally modulate the input data.
The data signal modulated by these digital modulation circuits 305-3 to 305-8 is assigned to each of the remaining six normal transponders (transponders 3 to 8 in FIG. 12).

The synthesis circuit 306 is a digital modulation circuit 30.
The data output from 5-1 to 305-8 are combined,
Output to the satellite via the antenna 307. The satellite processes this data with eight transponders and transmits it to each receiving device (IRD2).

Here, EPG data EPG1 to EPG
3 will be described. In this embodiment, as will be described later, the program guide button switch 1 of the remote commander 5
44 (FIG. 24) is operated, the monitor device 4 (FIG. 20)
In this case, as shown in FIG. 4, the screen of the data stream is superimposed and displayed on the normal screen. This data stream is composed of a title bar and a program window, as shown in FIGS. 5 and 6, respectively.

On the title bar, as shown in FIG. 5, a genre icon symbolically representing the genre of the program is displayed on the leftmost side. Next to the genre icon, a station logo as a symbol of the broadcasting station broadcasting the program is displayed. Then, next to the station logo, the title of the program is displayed.

As shown in FIG. 6, the program window is composed of still images obtained by reducing the representative screens of the five broadcast channels in this embodiment. On each reduced screen, a genre icon that symbolizes the genre to which the program belongs is displayed.

When the info button switch 145 (FIG. 24) of the remote commander 5 is operated, as shown in FIG. 7, an info screen for explaining the program in more detail is displayed. At the top of this info screen, a title bar is displayed as in the case of the data stream shown in FIG.

On the lower left of the title bar, a reduced screen of the still image of the representative screen is displayed, and on the upper and lower sides of the right side, the broadcast date and time of this program and the name of the performer (person) of this program are
Displayed respectively. And further below that,
A content description explaining the content of this program is displayed.

Of these, EPG1 is still image data that constitutes the program window shown in FIG.
PG3 is data such as a program title, broadcast date and time, performers, content explanations, etc., EPG2 is related to programs from the present to the near future, and EPG3 is E
It relates to a program broadcast in the far future than the program represented by PG2. These EPG 1 to E
PG3 is displayed as OSD.

8 to 10 show OSD as
A receiving device that mainly processes characters (characters) and that can be displayed (cannot process still images) (I in FIG. 29).
The display example of the electronic program guide displayed in RD2) is shown.

FIG. 8 shows an electronic program guide (overall program guide) for all channels, in which the vertical axis represents the broadcasting station name and the horizontal axis represents the time, and the positions defined by the two axes. The title of the program to be broadcast at that time is displayed on the.

FIG. 9 shows a display example of the electronic program guide (channel program guide) of one broadcasting station. In this example, the title and the broadcast start time of the program being broadcast on that broadcast channel are displayed from the top to the bottom.

The overall program table shown in FIG. 8 and the channel program table shown in FIG. 9 are the minimum information (program outline description) required to select a desired program. In contrast, FIG.
As shown in, information (detailed description of a program) that describes the content of a predetermined program (or a predetermined broadcasting station (broadcast channel)) is information that is not necessarily required to select a program. It will be helpful in selecting. Therefore, this detailed program description is also transmitted as EPG data.

If both the program guide (schematic description of the program) and the program content (detailed description of the program) are transmitted from each transponder for a long time, the corresponding amount of video data and audio data to be transmitted should be transmitted. The transmission rate will deteriorate. Therefore, each transponder (multiplexer 304-2 to 304-8) of the transmission channel for transmitting the data of the normal program is set as the EPG 2 by the EPG data generation device 309 as shown in FIG.
As shown in Fig. 7, if the maximum number of broadcast channels is 80 (10 channels per transponder, and 8 satellites are assigned to one satellite,
It will be 0 broadcast channel. However, in the case of the embodiment of FIG.
37 (= 5 × 7 + 2) broadcast channels)
24 hours of program guide data and the current (at that time) of 80 broadcast channels (37 broadcast channels)
The program content data relating to the program being broadcast and the next program is transmitted.

As a result, in each transponder,
It is possible to prevent the transmission rate of the video signal and the audio data which should be transmitted originally from being deteriorated.

On the other hand, the transmission channel of the promotion channel generation device 302 (digital modulation circuit 305-1
Is a transmission channel corresponding to (1), a program that is broadcast on another transmission channel (transmission channel corresponding to the digital modulation circuits 305-2 to 305-8), a program that encourages reception of the broadcast, and a program provider It is used as a channel mainly (priority) for transmitting promotional programs such as advertisements. Unlike other normal transponders, the transponders (guide transponders) that transmit information on this promotion channel transmit a large amount of program guide data and program content data because the number of normal programs that are transmitted is small. It is possible.

Therefore, in this promotion channel, the EPG data generating device 309 transmits the EPG 3 for a longer time as shown in FIG. 11B, that is, program guide data and program content data. In this embodiment, the program table data is 150 hours worth of data, and the program content data is 70 hours worth of data.

Therefore, as shown in FIG. 12, in the guide transponder (transponder 1), program guide data for 150 hours of each broadcast channel of 80 broadcast channels and program content data for 70 hours of 80 broadcast channels are provided. Is transmitted.

On the other hand, in a normal transponder (transponders 2 to 8), 8
Program guide data for 24 hours of 0 broadcast channel and program content data for 80 broadcast channels up to the current program and the next program are transmitted.

As shown in FIG. 11, the still image data (data stream) is indispensable for program selection, and therefore, in a normal transponder, as in the program table (schematic description), Hours and minutes (EPG1-2)
Is transmitted, and in the guide transponder, 150
Time minutes (EPG1-2 and EPG1-3) are transmitted.

Next, the details of the EPG data will be further described. The EPG data, together with other accompanying data, is a service information SI (Service Information).
data is transmitted in the DVB system as a type of on), and the data necessary to create the electronic program guide from this EPG data is the data shown in FIG.

The service supplier that specifies the supplier who supplies the service (broadcast channel), the service name that represents the name of the service, and the service type (service type) that represents the type of service are SDT (S) in the EPG data.
service Description Table)
It is described in. For this service type, for example,
A description indicating whether it is a single screen (promotion_service) or not is described.

The title representing the program name is EIT (Eve
Short of nt Information Tabl)
Event Descipator's event_na
Specified as me. Subtitle (type) is EIT
Component Descriptor of.

The current date and time is TDT (Time and
Date Table) is defined as UTC_time.

The program start time is start_t of EIT.
It is described as "ime". Program length is du in EIT
It is described as a relation.

Further, for example, in the case where only a person of a predetermined age or more is allowed to watch, a parental rate (Parent) for defining the age is provided.
alRate) is the EIT's ParentalRat
It is described in ing Descriptor.

The video mode is EIT's Component
t Descriptor, provided language is P
ISO's ISO 639 Language Descri
It is described in ptor. Also, the provided voice mode is EI
It is described in the component descriptor of T.

The category is Content D of EIT.
It is described in the descriptor.

Further, for example, a brief description of programs such as the performers shown in FIG. 7, the entire program guide, and the channel program guide shown in FIGS. 8 and 9 can be found in the Short Event D of EIT.
It is described in the escriptor, and the contents explanation of FIG. 7 and
Detailed description of programs such as the detailed description of programs in FIG. 10 can be found in Extended Event Descriptor of EIT
Is described in

Further, the promotion information such as the item name (promotion channel 1 NHK), item content (program introduction), and station logo (NHK) (when transmitting) described with reference to FIG.
It is described in the motion descriptor.

FIG. 14 shows the structure of the SDT. The SDT contains data that describes a service within the system, such as service name, service provider, and so on.
In the figure, the numbers in parentheses represent the number of bytes.

The first 10 bytes are used as a header,
Common structure 1 (3), transport stream ID (t
transport_stream_id (2)), common structure 2 (3), and original network ID (o
It is composed of the original_network_id (2)). Transport stream ID is SD
It provides a label to distinguish the transport stream to which T provides information from other transport streams that are multiplexed within the same delivery system.

The original network ID is a label for identifying the network ID that is the origin of the delivery system.

Next to the header, the service descriptor loop (service descriptors lo)
op) [0] to service description
rsloop [N] is arranged, and finally CRC_32 (4) for error correction is arranged.

Each service descriptor loop contains se
rvice_id (2), EIT_schedule_
flag, EIT_pre / fol_flag, run
"ning_status" and "free_CA_mode" are arranged.

Service_id provides a label for identifying the service from other services in the same transport stream. service_id is
Corresponding program map section (program
This is the same as the program number (program_number) in _map_section).

EIT_schedule_flag is
EIT_sche in its own transport stream
Indicates whether or not there is a Dule information.

EIT_present / followi
ng_flag is an EIT_present / following in in its transport stream.
Indicates the presence or absence of formation.

Whether running_status does not start the service yet, or starts a few minutes later (VC
R to prepare for recording), has already started, has already started, or is currently suspended, etc.

The free_CA_mode indicates whether the service can be accessed free of charge or is controlled by the conditional access system.

Next, the descriptor_lo
op_length is arranged. This follows d
Indicates the total byte length.

Next service_descript
r [i] supplies the service_provider (service provider) name and the service name in text format together with service_type.

Next country_availability
ity_descriptor [i] represents a permitted country list and a prohibited country list, and can be inserted up to twice.

Next, the descriptors are arranged, and the above-mentioned promotion descriptors are arranged here.
ptor and the like are included.

FIG. 15 shows the structure of the EIT. The first 10-byte header contains the common structure 1 (3), se
rvice_id (2), common structure 2 (3), and t
The transport_stream_id (2) is arranged.

Next, original_netw
ork_id (2) is arranged, and next, last_ta
ble_id (1) is arranged. This last_
table_id (1) is the final (= maximum) table
Identify _id. If only one table is used, the table_id of that table is set. When table_id takes continuous values, the information is also kept in chronological order. Below, event decr
iptors loop [0] to eventdesc
riptors loop [N] is placed, and finally,
CRC_32 (4) is arranged.

In each event descriptor, an event that provides an identification number of the event to be described
_Id (2) is placed, and then start_time that displays the start time of the event as UTC and MJD.
(5) is arranged. This field gives the 16 LSBs of the MJD in 16 bits, followed by 4-
It represents 6 digits by BCD of BIT. For example, 93/1
0/12 12:45:00 is 0XC0781245
It is encoded as 00.

The next duration (3) represents the duration of the event (program) in hours, minutes and seconds.

Next, running_status is arranged, and further free_CA_mode is arranged.

Further next, the descriptor
_Loop_length (1.5) is arranged, and then Short_event_descripto
r [i] (7 + α) is arranged. It provides the event name and a short description (program guide) of the event in text format.

Next Extended_event_de
script [i] (11 + α) is the above Sh.
A more detailed event description (program content) than that provided by the ort event descriptor
I will provide a.

In addition, audio_component
_Descriptor [i] (6), video_c
component_descriptor [i]
(3), subtitle_component_de
script [i] (6) is described.

Next CA_identifier_des
The descriptor [i] (4) describes whether or not the data is scrambled, whether or not conditional access such as billing is conditioned.

Further below that, the other description
tors is described. This descriptor
In s, event_still_image for recording the data (still image data) of the program window shown in FIG.
e_descriptor [i] is arranged.

FIG. 16 shows this event_still_
This indicates the format of image_descriptor [i] (the format of a still image). As shown in the figure, at the beginning thereof, an 8-bit descriptor_tag indicating that the type of information is still image data
Is placed, followed by an 8-bit descriptor_l indicating the total length represented in this format.
The length is arranged.

Next to descriptor_length, 8-bit descriptor_number
Is placed, and next, 8-bit last_
descriptor_number is placed. These are the number of this descriptor and
The number of the last (maximum) descriptor is shown.

Finally, an image_structure as substantial image data of a still image is arranged. This image_structure is composed of an 8-bit format_identifier, a 32-bit image_size and an image_data.

Format_identifier is
represents the ID of image_data, and
When the denifier is 0x10, the image_d
ata is black and white binary image data. form
If at_identifier is 0x11, the ima
The ge_data is image data of 256 gradations in black and white. When it is 0x12, it is RGB, 8-bit image data, and when it is 0x20, it is JPEG-compressed image data. Therefore, in the case of the embodiment shown in FIG. 1, since the reduced screen forming the program window is an image compressed by the JPEG method, the format_id
The entity is set to 0x20.

When image_data is binary black and white image data, the value may not be divisible by 8 bits. In this case, the dummy data is stuffed.

The image_size is the image_d.
It represents the size of ata.

FIG. 17 shows the structure of the TDT. As shown in the figure, the TDT has a common structure 1 (3) and a UT.
It is composed of C_time (5).

In addition to the above table, SI has the following structure shown in FIG.
8 PAT (Program Association)
Table) and PMT (Program) shown in FIG.
MMap Table) is included.

As shown in FIG. 18, the PAT has a common structure 1 (3), transport_stream_id.
(2), common structure 2 (3), program_ma
p_id_loop [0] (4) to program_
composed of map_id_loop [N] (4),
Finally, CRC_32 (4) is arranged.

Each program_map_id_loo
p [i] (4) is program_number
[I] (2) and program_map_PID
[I] (2) (or network_PID).

Program_number represents a program for which the corresponding program_map_PID is valid. When this is set to 0x0000, the PID to be referred to next is network_
It becomes PID. In all other cases, the value of this field is user-defined. This field does not take the same value more than once in one version of PAT.
For example, program_number is used as a broadcast channel designation.

Network_PID is NIT (Ne
PI of the transport stream packet including the "work Information Table"
Define D. The value of network_PID is user-defined (0x0010 in DVP), but it cannot be a value reserved for other purposes. net
Presence or absence of work_PID is optional.

Program_map_PID is pr
transport st containing a PMT valid for the program specified by ogram_number
Specifies the PID of the ream packet. 1 or more pros
gram_map_program_with PID assignment
There is no number. program_map_PID
The value of is defined by the user but cannot be a value reserved for other purposes.

As shown in FIG. 19, in the PMT, a 10-byte header composed of a common structure 1 (3), a program_number (2), a common structure 2 (3), and a PCR_PID (1.375) is arranged at the head. ing. PCR
_PID includes a PCR field that is valid for the program specified by program_number.
The PID of the transport stream packet is shown. If there is no PCR associated with the program definition for the privatestream, this field takes the value 0x1FFF.

Next, program_info_le
ngth (1.5) is arranged. This defines the number of bytes in the descriptor that immediately follows this field.

The next program info de
scripts is CA_descriptor,
Copyright_descriptor, Max_
bitrate_descriptor and the like are described.

Next, stream type l
loop [0] (5 + α) to stream type
loop [N] (5 + α) and CRC_32 (4) are arranged.

Each stream type loop is
stream_type (1), elementary
_PID (2). stream_type
Is an elemental carried in a packet with a PID that takes the value specified by elementary_PID.
Specifies y stream, or payload type.
The value of stream_type is defined by MPEG2.

Elementary_stream-P
ID is the related elementary stream
, Or the PID of a transport stream packet that carries data.

Next, ES_info_lengh
t (1.5) is located, this is a 12-bit field, the first 2 bits are 00, and the associated elementary stream immediately following this field.
Specifies the number of bytes in the descriptor.

Then, ES info description
ptors [N] is defined. Here, CA_de
The descriptor and other descriptors are described.

FIG. 20 shows an AV (Aud) to which the present invention is applied.
2 shows an example of the configuration of the io Video) system. In the case of this embodiment, the AV system 1 demodulates a radio wave transmitted from the transmitter of FIG. 1 into a signal received by the parabolic antenna 3 via a satellite (broadcast satellite or communication satellite) not shown in the figure, and an IRD (Integrated). Receive
er / Decoder) 2 and a monitor device 4. Monitor device 4 and IRD 2 are AV line 1
1 and a control line 12 are connected to each other.

For IRD2, remote commander 5
Thus, a command can be input by an infrared (IR) signal. That is,
When a predetermined one of the button switches of the remote commander 5 is operated, an infrared signal corresponding to the button is transmitted to the IR transmitter 51.
And is incident on the IR receiver 39 (FIG. 23) of the IRD 2.

FIG. 21 shows an electrical connection state of the AV system 1 of FIG. The parabolic antenna 3 is LNB
(Low Noise Block downconv
er) 3a, converts a signal from a satellite into a signal of a predetermined frequency, and supplies the signal to the IRD 2. IRD2
Outputs its output to, for example, a composite video signal line,
It is supplied to the monitor device 4 via an AV line 11 composed of three lines, an audio L signal line and an audio R signal line.

Further, the IRD 2 has an AV device control signal transmission / reception unit 2A, and the monitor device 4 has an AV device control signal transmission / reception unit 4A. These are wired S
IRCS (Wired Sony Infrared)
They are connected to each other by a control line 12 composed of a Remote Control System.

FIG. 22 shows an example of the front structure of the IRD 2. On the left side of IRD2 is the power button switch 11
1 is provided. This power button switch 111
Is operated when the power is turned on or off. The LED 112 is turned on when the power is turned on. The LED 113 on the right side of the LED 112 is a TV / D
By the operation of the SS switch button switch 123, it is turned on when the DSS mode is set and turned off when the TV mode is set. Here, DSS (Digital State)
The lite system) mode is a mode for receiving the radio waves transmitted via the satellite in the above-described system, and the TV mode is a mode for receiving normal terrestrial television broadcasting.

The LED 114 sends this IR signal via the satellite.
The light is turned on when a predetermined message is transmitted to D2. When the user outputs and displays this message on the monitor device 4 and confirms it, the LED 114 is turned off.

The menu button switch 121 is operated when displaying a menu on the monitor device 4. The exit button switch 122 is operated to erase the OSD display.

An up button switch 117, a down button switch 118, a left button switch 119 and a right button switch 120 are arranged on the upper, lower, left and right sides of the select button switch 116, respectively. These up button switch 117, down button switch 118, left button switch 119, and right button switch 120 are operated when the cursor is moved in the up, down, left, and right directions. Select button switch 1
16 is operated when the selection is confirmed (when the selection is made).

FIG. 23 shows an example of the internal structure of the IRD 2 for performing reception in the above-mentioned DSS mode. The RF signal output from the LNB 3a of the parabolic antenna 3 is supplied to the tuner 21 of the front end 20 and demodulated. The output of the tuner 21 is the QPSK demodulation circuit 2
2 and is QPSK demodulated. The output of the QPSK demodulation circuit 22 is supplied to an error correction circuit 23, where an error is detected and corrected, and corrected if necessary.

I consisting of CPU, ROM, RAM, etc.
CAM (Conditi) composed of C card
The key required for deciphering the cipher is stored in the onal access module 33 together with the deciphering program. If the signal transmitted via the satellite is encrypted, a key and a decryption process are required to decrypt the code. Therefore, this key is read from the CAM 33 via the card reader interface 32,
It is supplied to the demultiplexer 24. The demultiplexer 24 uses this key to decrypt the encrypted signal.

The CAM 33 stores a key necessary for decryption, a decryption program, and billing information.

The demultiplexer 24 receives the signal output from the error correction circuit 23 of the front end 20 and outputs it to the data buffer memory (DRAM (Dyna).
micRandom Access Memory) or SRAM (StaticRandom Acces)
s Memory)) 35. And
This is read out as appropriate, the decoded video signal is supplied to the MPEG video decoder 25, and the decoded audio signal is supplied to the MPEG audio decoder 26.

The MPEG video decoder 25 stores the input digital video signal in the DRAM 25a as appropriate, and executes the decoding process of the video signal compressed by the MPEG system. The decoded video signal is
The signal is supplied to the NTSC encoder 27 and is converted into a luminance signal (Y), a chroma signal (C), and a composite signal (V) of the NTSC system. The luminance signal and the chroma signal are output as S-video signals via buffer amplifiers 28Y and 28C, respectively. The composite signal is
It is output via the buffer amplifier 28V.

As the MPEG video decoder 25, the SGS-Thomson Microselect is used.
Ronics' MPEG2 decoding LSI (STi35
00) can be used. The outline is, for example, “Nikkei Electronics” 1994. 3.14, Nikkei BP.
(No. 603) Pages 101 to 110 include Mart
Introduced by Mr. Bolton.

In addition, MPEG2-Transports
As for stream, ASCII Corporation August 1994
231 to 2 "Latest MPEG Textbooks" published on January 1
An explanation is given on page 53.

The MPEG audio decoder 26 appropriately stores the digital audio signal supplied from the demultiplexer 24 in the DRAM 26a and executes the decoding process of the audio signal compressed by the MPEG system. The decoded audio signal is D / A converted in the D / A converter 30, the left channel audio signal is output through the buffer amplifier 31L, and the right channel audio signal is output in the buffer amplifier 31R.
Is output via.

The RF modulator 41 converts the composite signal output by the NTSC encoder 27 and the audio signal output by the D / A converter 30 into an RF signal and outputs the RF signal. When the TV mode is set, the RF modulator 41 passes an NTSC system RF signal input from an AV device such as a cable box,
The data is directly output to a VCR or other AV equipment (neither is shown).

In the case of this embodiment, these video signal and audio signal are supplied to the monitor device 4.

CPU (Central Process)
The ing unit) 29 executes various processes according to the programs stored in the ROM 37. For example,
It controls a tuner 21, a QPSK demodulation circuit 22, an error correction circuit 23, and the like. Further, it controls the AV device control signal transmission / reception unit 2A, outputs a predetermined control signal to another AV device (in this embodiment, the monitor device 4) via the control line 12, and the other AV device. Receives the control signal from.

A predetermined command can be directly input to the CPU 29 by operating the operation button switch (FIG. 22) on the front panel 40. When the remote commander 5 (Fig. 24) is operated, the IR transmitter 5
An infrared signal is emitted from 1, the infrared signal is received by the IR receiving section 39, and the light reception result is supplied to the CPU 29. Therefore, by operating the remote commander 5, it is possible to input a predetermined command to the CPU 29.

Further, the demultiplexer 24 takes in EPG data and the like in addition to the MPEG video data and audio data supplied from the front end 20, and supplies them to the EPG area 35A of the data buffer memory 35,
Remember. EPG information is 24 hours after the current time (E
PG2 and EPG1-2) or after 150 hours (EPG2, EPG3, EPG1-2, EPG1-3)
Information about programs on each broadcast channel (for example, still image of program, channel, broadcast time,
Title, category, etc.). Since this EPG information is frequently transmitted, the latest EPG can always be held in the EPG area 35A.

EEPROM (Electrically)
Erasable Programmable Rea
In the d Only Memory) 38, the data (for example, the reception history of the tuner 21 for four weeks, the channel number (last channel) received immediately before the power-off) which is desired to be retained after the power-off is appropriately stored in the d Only Memory 38. To be done.
Then, for example, when the power is turned on, the same channel as the last channel is received again. ROM 37 when the last channel is not stored
The channel stored as the default is received.

Further, when the sleep mode is set, the CPU 29 activates the minimum circuits such as the front end 20, the demultiplexer 24, the data buffer memory 35, etc., even when the power is off, and receives the received signal. It also measures the current time from the time information included in, and controls each circuit to perform a predetermined operation at a predetermined time. For example, timer automatic recording is executed in conjunction with an external VCR.

Further, the CPU 29 causes the predetermined OSD (O
When it is desired to generate n-Screen Display data, the MPEG video decoder 25 is controlled. MP
The EG video decoder 25 generates predetermined OSD data in response to this control, writes the OSD data in the OSD area 25aA (FIG. 28) of the DRAM 25a, and further reads it.
Output. As a result, predetermined characters, figures, images, etc. (for example, in FIGS. 3 to 10, characters superimposed on a normal screen, station logo, genre icon,
A still image of the program window) or the like can be appropriately output to the monitor device 4 and displayed.

The SRAM 36 is used as a work memory for the CPU 29. The modem 34 exchanges data via a telephone line under the control of the CPU 29.

FIG. 24 shows a configuration example of the button switch of the remote commander 5. The select button (decision key) switch 131 can be pressed (select operation) in the vertical direction with respect to the upper surface of the remote commander 5. Up button switch (up key) 135, down button switch (down key) 136,
The left button switch (left key) 137 and the right button switch (right key) 138 are operated when moving a cursor or the like up, down, left and right (when operating a direction). The menu button switch 134 is operated when the monitor device 4 displays a menu screen.

Channel up / down button switch 1
Reference numeral 33 is operated when the number of a broadcast channel to be received is increased or decreased. The volume button switch 132 is operated when raising or lowering the volume.

The number button (ten-key) switch 138 displaying the numbers 0 to 9 is operated when the displayed number is input. Tuning button switch 158
When the operation of the number button switch 138 is completed,
It is operated subsequently to the end of input of a numeral and the meaning that the input numeral represents a channel. The promo channel button switch 157 is operated when selecting a promotion channel. The program guide button switch 144 is operated when displaying a data stream as shown in FIG. 4, and the info button switch 145 is operated when displaying an info screen as shown in FIG. 7.

The input selector button switch 154 is an IRD.
It is operated when switching the input to 2. When the mute button switch 151 is operated, the sound is muted, and when it is operated again, the mute is released. The TV power button switch 152 and the power button switch 153 are operated when the power of the monitor device (television receiver) 4 or the IRD 2 is turned on or off.

FIG. 25 shows another example of arrangement of button switches. In this embodiment, the select button switch 131 is arranged at the lower right of the up button switch 135 to the light button switch 138.

FIG. 26 shows an example of the internal structure of the remote commander 5. The CPU 72, which constitutes the microcomputer 71, constantly scans the button switch matrix 82 to display the remote commander 5 shown in FIG.
Detects the operation of various button switches.

The CPU 72 executes various kinds of processing according to the programs stored in the ROM 73 and causes the RAM 74 to store necessary data as needed.

When outputting the infrared signal, the CPU 72 drives the LED 76 through the LED driver 75 to output the infrared signal.

FIG. 27 schematically shows how video data, audio data and SI data (including EPG data) are packetized, transmitted, and then demodulated by IRD2. In the encoder on the transmission side, as shown in FIG. 27, SI data, video data, and audio data are packetized and mounted on the satellite 1
It transmits to the high power transponder for the BSS band of 2.25 GHz to 12.75 GHz. In this case, the signal of the predetermined frequency assigned to each transponder,
Packets of a plurality of channels (up to 10) are multiplexed and transmitted. That is, each transponder transmits signals of a plurality of broadcast channels on one carrier wave (transmission channel). Therefore, for example, if the number of transponders is 23, data of 230 (= 10 × 23) broadcast channels at maximum can be transmitted.

In the IRD2, the front end 20
At, a carrier wave of one frequency corresponding to one predetermined transponder is received and demodulated. This gives a maximum of 1
Packet data of 0 broadcast channels (5 broadcast channels in the embodiment) is obtained. Then, the demultiplexer 24 temporarily stores each packet obtained from this demodulated output in the data buffer memory 35 and reads it. Regarding the SI packet including the EPG data, the data portion excluding the header is stored in the EPG area 35A. The video packet is stored in the DRAM 25a and stored in M
The decoding process is performed in the PEG video decoder 25. The audio packet is stored in the DRAM 26a and decoded by the MPEG audio decoder 26.

In each transponder, scheduling is performed so that the transfer rates are the same. The transmission rate per one carrier assigned to each transponder is 30 Mbits / sec.

In the case of a picture with a lot of motion such as a sports program, the MPEG video data occupies many packets. Therefore, as the number of such programs increases, the number of programs that can be transmitted by one transponder decreases.

On the other hand, MPEG video data of an image with little movement such as an announcement scene of a news program can be transmitted with a small number of packets.
Therefore, when there are many such programs, the number of programs that can be transmitted by one transponder becomes large.

FIG. 28 schematically shows the processing of data until the screen of the program guide is displayed on the monitor device 4.

The CPU 29 presets the transfer destination of the data input from the front end 20 in the register 24a incorporated in the demultiplexer 24. Then, the data supplied from the front end 20 is once stored in the data buffer memory 35, read by the demultiplexer 24, and transferred to the transfer destination set in the register 24a.

As described above, the header is added to each packet, and the demultiplexer 24 refers to this header to supply MPEG video data to the MPEG video decoder 25 and MPEG audio data to MPEG.
Transfer to the audio decoder 26. Further, the PID (Packet ID) included in the header is SDT, E
In the case of IT, these EPG data (S
I data) is the EPG set in the register 24a.
It is stored at a predetermined address in the area 35A.

The header becomes unnecessary when this transfer is completed, and is discarded.

In this way, for example, when radio waves from a normal transponder (transponder other than the guide transponder for the promotion channel) are being received, 2 from the current time of 80 (37) broadcast channels.
The reduced still image data up to four hours later, the program outline description data (program guide), and the program detailed description (program content) of the current program and the next program are taken into the EPG area 35A. It is possible to receive from any normal transponder. That is, the same EPG data is transmitted from any ordinary transponder.

On the other hand, when the radio wave from the guide transponder is being received (when the promotion channel is being received), the reduced still image data for 80 (37) channels from the current time to 150 hours later, Program outline explanation data and program detail explanation data up to 70 hours later are fetched.

The CPU 29 uses the entire EPG table 24.
Time from 0 to a predetermined display area 250 broadcast channel (for example, 5 broadcast channels in the example of FIG. 4, 15 broadcast channels in the example of FIG. 8) within a predetermined range (in the example of FIG. 4, Is the current time, in the example of FIG. 8, the program data at the time of about 4 hours after the current time) is read from the EPG area 35A, and the DRAM 25
The OSD area 25aA of a is written as bitmap data. Then, the MPEG video decoder 25
Reads out the bitmap data of the OSD area 25aA and outputs it to the monitor device 4, so that the monitor device 4
E, such as reduced still images (Fig. 4) and the entire program guide (Fig. 8)
The PG can be displayed.

The MPEG video decoder 25 is a JPEG
Image data compressed by the method can also be decoded. However, the size of the screen is processed as a normal size. Therefore, the CPU 29 takes in the decoded still image data, converts it into the size of the reduced screen, outputs the data again to the MPEG video decoder 25, and displays it as the reduced screen by using the OSD function.

When a character or the like is displayed as OSD data, the character data stored in the EPG area 35A is compressed, and therefore the dictionary is used to restore the character data. For this reason, the compression code conversion dictionary is stored in the ROM 37.

The ROM 37 also stores a correspondence table (address conversion table) between character codes and storage positions of font bitmap data. By referring to this conversion table, the bitmap data corresponding to the predetermined character code can be read and written in the OSD area 25aA. Of course, this bit map data itself is also stored in the ROM 37 at a predetermined address.

Further, when the Logo (logo) data is not transmitted, the ROM 37 stores the Logo data (various logo data including the category logo and the station logo) for displaying the Logo (logo), and the Logo data is also stored. A conversion table of an ID and an address for calling Logo data (bitmap data) corresponding to the ID is stored. When the Logo ID is known, the Logo data stored in the address corresponding to the ID is read out and written in the OSD area 25aA, thereby indicating the category of each program.
And the like can be displayed on the monitor device 4. That is, when the logo data is transmitted, the super imposers 333-1 to 333 of FIG.
4 is superimposed and transmitted from the transmitting side, but if it is not transmitted, the I
D is transmitted, and the bitmap data corresponding to ID is transferred to R
Read from OM37.

As described above, when the program guide button switch 144 of the remote commander 5 is operated while a normal program is being received and displayed on the monitor device 4, the display screen of the monitor device 4 is displayed as shown in FIG. As shown, a data stream consisting of five reduced screens is displayed. A cursor is displayed on a predetermined reduced screen in this data stream. By operating the left button switch 137 or the right button switch 138, this cursor can be moved left and right. On the reduced screen where the cursor is moved, the genre icon is erased in order to make the entire screen easier to see. Then, in the title bar, the genre icon of the program where the cursor is located, the station logo, and the title are displayed.

When the user further operates the select button switch 131, the CPU 29 controls the tuner 21 so as to receive the program at which the cursor is located. As a result, the image of the program selected and designated is displayed in large size (normal size) on the monitor device 4.

On the other hand, as shown in FIG. 4, while the data stream is being displayed, the remote commander 5
When the info button switch 145 is operated, more detailed information (info screen) of the program where the cursor is located at that time is displayed as shown in FIG. 7. That is, the genre icon, the station logo, and the title are displayed on the title bar, and the still image is displayed larger than in the case of FIG. Furthermore, the broadcast date and time of this program, the performers, a description of the content, etc. are displayed. The user can grasp the outline of the content of the program by looking at this display.

When the user operates the select button switch 131 while the info screen as shown in FIG. 7 is displayed, the program is received and displayed.

The above is the operation when the IRD 2 has a function of processing a still image. For example, when the IRD 2 is configured as shown in FIG. 29 (when the IRD 2 has a function of processing a still image, Without a function for mainly processing only characters), the remote commander 5
When the program guide button switch 144 is operated, the entire program guide as shown in FIG. 8 is displayed in characters on the monitor device 4. When the up button switch 135 to the light button switch 138 are operated to move the cursor to a predetermined broadcast channel in the entire program guide displayed in FIG. 8 and the select button switch 131 is operated, the monitor device 4 displays As shown in FIG. 9, the program guide of the broadcast channel is displayed.

When the cursor is moved to a predetermined current program and the select button switch 131 is operated in the state where the entire program table as shown in FIG. 8 is displayed,
The CPU 29 controls the tuner 21 to receive the program.

In the description of the above embodiment, the various logos shown are for convenience of description,
It is not used in actual broadcasting.

In the present invention, the monitor device 4 (display) is further followed according to the flowchart shown in FIG.
The aspect ratio can be set.

In other words, first in step S1,
When the user operates the menu button switch 134 of the remote commander 5, the CPU 29 controls the MPEG video decoder 25 in step S2 to generate OSD data of the main menu, and causes the monitor device 4 to display the OSD data as shown in FIG. Display the main menu. The user selects the system menu from this main menu in step S3. This selection is performed by moving the cursor (the portion shaded in FIG. 31) to the up button switch 135 to the light button switch 138.
Is operated to move it to a predetermined position, and further, the select button switch 131 is operated (hereinafter the same). At this time, the CPU 29 controls the MPEG video decoder 25 in step S4 to generate OSD data of the system menu and causes the monitor device 4 to display the system menu as shown in FIG.

The user moves the cursor in step S5 to select the installation menu in the system menu. At this time, the CPU 29 controls the MPEG video decoder 25 in step S6,
An installation menu as shown in FIG. 33 is displayed on the monitor device 4.

In step S7, the user moves the cursor and selects the aspect ratio setting (SET ASPECT RATI) from this installation menu.
Select O). At this time, the CPU 29 executes step S8.
In controlling the MPEG video decoder 25, the monitor device 4 is caused to display an aspect ratio setting screen as shown in FIG.

Then, in step S9 (setting means), the user operates the up button switch 135 to the light button switch 138 of the remote commander 5,
By moving the cursor and operating the select button switch 131 at a predetermined position, does the monitor device 4 owned by itself have a standard aspect ratio of 4: 3? It is selected and set whether it has a wide aspect ratio of 16: 9. When this setting process is performed, the setting result is EE
It is stored in the PROM 38.

Thereafter, when the program guide button switch 144 of the remote commander 5 is operated, the CPU 29 causes the E
The setting of the EPROM 38 is read, and the display state of the data stream is controlled according to the setting.

That is, when the monitor device 4 is set so as to have an aspect ratio of 4: 3, the CPU 29 (control means) controls the MPEG video decoder 25, as shown in FIG. The data stream is displayed on the monitor device 4. That is, in this embodiment, the data stream has a configuration in which five reduced screens having an aspect ratio of 4: 3 are arranged.

On the other hand, when the aspect ratio of the monitor device 4 is set to the aspect ratio of 16: 9, the CPU 29 controls the MPEG video decoder 25 so that the monitor device 4 is displayed as shown in FIG. Display the data stream as shown in. That is, in this embodiment, there are six reduced screens having an aspect ratio of 4: 3.
Individually arranged. Since the standard aspect ratio of the NTSC system is 4: 3, the reduced screen is also set to have an aspect ratio of 4: 3. However, when the monitor device 4 has an aspect ratio of 16: 9, the screen is a horizontally long screen. Becomes Therefore, since it is possible to display more reduced screens of 4: 3, a larger number of reduced screens are displayed than in the case of a monitor device having an aspect ratio of 4: 3.

As a result, the user can more efficiently view the reduced screen.

In the above embodiment, the data stream is changed according to the aspect ratio. However, in addition to this, for example, the monitor device 4 (display).
It is also possible to control the size of the reduced screen in accordance with the resolution of the specifications. in this case,
For example, when the resolution is high, it is possible to display a finer image. Therefore, the size of the reduced screen is made smaller than that when the resolution is low. As a result, it is possible to display a larger number of reduced screens when the resolution is higher.

The case where the present invention is applied to the IRD 2 has been described above as an example, but the IRD can be substantially incorporated in the monitor device 4 (television receiver).

[0175]

As described above, according to the electronic program guide display control device of the first aspect and the electronic program guide display control method of the fourth aspect, the electronic program guide corresponding to the setting of the use of the display. Since the display state is controlled, the desired program can be selected from a large number of programs more efficiently, quickly and surely.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration example of a transmission device to which the present invention is applied.

2 is a promotion channel generation device 30 of FIG.
It is a block diagram which shows the structural example of 2.

FIG. 3 is a diagram showing a display example of a promotion channel.

FIG. 4 is a diagram showing a display example of a data stream.

FIG. 5 is a diagram showing a structure of a title bar.

FIG. 6 is a diagram showing a configuration of a program window.

FIG. 7 is a diagram showing a display example of an info screen.

FIG. 8 is a diagram showing a display example of an entire program guide.

FIG. 9 is a diagram showing a display example of a channel program guide.

FIG. 10 is a diagram showing a display example of detailed program description (program content).

FIG. 11 is a diagram illustrating a program guide and a range of program contents.

FIG. 12 is a diagram illustrating transmission of EPG information in a transponder.

FIG. 13 is a diagram illustrating EGP data.

FIG. 14 is a diagram illustrating the configuration of SDT.

FIG. 15 is a diagram illustrating a configuration of EIT.

FIG. 16 is a diagram showing a format of a still image.

FIG. 17 is a diagram illustrating the configuration of TDT.

FIG. 18 is a diagram illustrating the configuration of a PAT.

FIG. 19 is a diagram illustrating a configuration of a PMT.

FIG. 20 is a perspective view showing a configuration example of an AV system to which the present invention has been applied.

21 is a block diagram showing an electrical connection state of the AV system of FIG.

22 is a front view showing a configuration example of the front of the IRD 2 of FIG. 20. FIG.

23 is a block diagram showing an internal configuration example of the IRD 2 of FIG.

24 is a plan view showing a configuration example of the upper surface of the remote commander 5 of FIG.

FIG. 25 is a diagram showing another arrangement state of the button switches of the remote commander 5.

FIG. 26 is a block diagram showing an internal configuration example of the remote commander 5 of FIG. 24.

[Fig. 27] Fig. 27 is a diagram for describing the outline of the processing in the encoder on the transmission side and the processing of the IRD 2 that receives the output.

FIG. 28 is an E stored in the EPG area 35A of FIG.
It is a figure explaining PG data.

FIG. 29 is a block diagram showing another configuration example of IRD2.

FIG. 30 is a flowchart showing processing for setting an aspect ratio.

FIG. 31 is a diagram showing a display example of a main menu.

FIG. 32 is a diagram showing a display example of a system menu.

FIG. 33 is a diagram showing a display example of an installation menu.

FIG. 34 is a diagram showing a display screen for setting an aspect ratio.

FIG. 35 is a diagram showing a display example of EPG on a monitor device with an aspect ratio of 4: 3.

FIG. 36 is a diagram showing a display example of an EPG on a monitor device having an aspect ratio of 16: 9.

[Explanation of symbols]

 1 AV System 2 IRD 3 Parabolic Antenna 4 Monitor Device 5 Remote Commander 21 Tuner 23 Error Correction Circuit 24 Demultiplexer 25 MPEG Video Decoder 25a DRAM 26 MPEG Audio Decoder 26a DRAM 29 CPU 35 Data Buffer Memory 35A EPG Area 36 SRAM 37 ROM 38 EEPROM 39 IR receiver 131 Select button switch 144 Program guide button switch 145 Info button switch

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location H04N 7/081 H04N 7/08 Z H04Q 9/00 301

Claims (4)

[Claims] 1. An electronic program guide display control device for displaying an electronic program guide on a display and selecting a desired program from the electronic program guide, wherein information relating to specifications of the display for displaying the electronic program guide is set. An electronic program guide display control device comprising: setting means; and control means for controlling the display state of the electronic program guide on the display in correspondence with the setting of the setting means. 2. The electronic program guide display control device according to claim 1, wherein the specification is an aspect ratio or resolution of the display. 3. The electronic program guide is a reduced screen obtained by reducing a representative screen of a program, and the control means controls the number of the reduced screens displayed on one screen in accordance with the setting of the setting means. The electronic program guide display control device according to claim 1, wherein: 4. An electronic program guide display control method for displaying an electronic program guide on a display and selecting a desired program from the electronic program guide, wherein information relating to specifications of the display for displaying the electronic program guide is set. An electronic program guide display control method comprising controlling the display state of the electronic program guide on the display according to the setting.