JP3637584B2 - Display control apparatus and display control method - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a display control device and a display control method. In particular, the present invention relates to a display control apparatus and a display control method that make it possible to easily find a desired program from among programs of a plurality of broadcast channels.
[0002]
[Prior art]
In recent years, high-efficiency coding technology such as MPEG (Moving Picture Experts Group) has been applied in the United States, and cable television (CATV) and digital direct satellite broadcasting (DSS) are trademarks of Hughes Communications. )), Etc., multi-channel broadcasting is progressing.
[0003]
[Problems to be solved by the invention]
As the number of channels increases, for example, the number of broadcast channels becomes 150 to 200, and it is not easy to find a desired program from these channels. That is, if one broadcast channel is selected, the program is actually confirmed, and if it is not what is desired, another broadcast channel is selected. When there are a large number of channels like this, the viewer will feel annoyed.
[0004]
Therefore, the applicant of the present application, for example, as Japanese Patent Application No. 6-279618, allows viewers to easily recognize the contents of programs on many channels currently being broadcast, and further, from among them, a desired one can be obtained. An apparatus that can easily and quickly select a program has been proposed.
[0005]
That is, in this apparatus, the sub-screens of the programs of the respective channels are displayed sequentially, and the viewer can attach a bookmark as a predetermined mark to the desired program while viewing the sub-screens. It has been made possible. A program with a bookmark is displayed on the main screen when a predetermined switch is operated.
[0006]
By the way, in this apparatus, when bookmarks are attached to a plurality of programs, the bookmarked programs are sequentially displayed every time a predetermined switch is operated. Therefore, if bookmarks are attached in advance to a large number of programs that are desired to be viewed, and a program to be viewed later is to be selected, if the number of programs with bookmarks increases, In order to confirm the contents of the program, a predetermined switch has to be operated, and there is a problem that makes the viewer feel bothersome.
[0007]
The present invention has been made in view of such a situation, and makes it possible to more easily confirm the contents of a program and select the program.
[0008]
[Means for Solving the Problems]
The display control apparatus of the present invention includes a receiving unit that receives a signal including programs of a plurality of broadcast channels, an output unit that outputs and displays the program received by the receiving unit, and the receiving unit receives the program. Storage means for storing a virtual array image in which reduced screens obtained by reducing each of the screens of a plurality of programs are arranged in a predetermined number of matrices from the signal, and stored in the storage means Arranged in a predetermined number of matrices From a virtual array image, Less than a certain number Multiple reduced screens for a given selection area Select Reading means for reading and displaying on the display means a multi-screen composed of the plurality of reduced screens; , Further comprising cursor display control means for displaying a cursor for instructing a reduced screen on the display means, and cursor moving means operated when the cursor is moved to the next reduced screen. When the direction operation by the cursor moving means is performed in a state where it is moved to the left and right ends, the reading means moves the selection area according to the direction operation, and is newly selected from the virtual array image. A plurality of reduced images in the selected area are read, and a multi-screen composed of the plurality of reduced images is displayed on the display means. It is characterized by that.
[0009]
According to the display control method of the present invention, a signal including programs of a plurality of broadcast channels is received, the received program is output and displayed on a display means, and the screens of the plurality of programs are reduced from the received signal. Virtual array image with reduced screens arranged in a predetermined number of matrices The Stored in storage means and stored in storage means Arranged in a predetermined number of matrices From a virtual array image, Less than a certain number Multiple reduced screens for a given selection area Select Read out and display a multi-screen consisting of multiple reduced screens on the display means When a cursor is operated to move the cursor while the cursor is moved to the top, bottom, left and right edges of the multi-screen, the cursor for instructing the reduced screen is displayed on the display means. Move according to the operation, read out a plurality of reduced images of the newly selected selection area from the virtual array image, and display the multi-screen consisting of the plurality of reduced images on the display means It is characterized by that.
[0010]
[Action]
In the display control apparatus of the present invention, the receiving means receives a signal including programs of a plurality of broadcast channels, and the output means outputs the program received by the receiving means to the display means for display. Yes. The storage means stores a virtual array image in which reduced screens obtained by reducing the screens of a plurality of programs are arranged in a predetermined number of matrices from the signal received by the receiving means. And the reading means is stored in the storage means Arranged in a predetermined number of matrices From a virtual array image, Less than a certain number Multiple reduced screens for a given selection area Select Read out and display a multi-screen consisting of multiple reduced screens on the display means When the cursor for instructing the reduced screen is displayed on the display means, the cursor moving means is operated when moving the cursor to the next reduced screen, and the cursor is moved to the top, bottom, left and right edges of the multi-screen, When the direction operation by the cursor moving means is performed, the selection area is moved in accordance with the direction operation, and a plurality of reduced images of the newly selected selection area are read out from the virtual array image, Display a multi-screen consisting of reduced images on the display means It is made like that.
[0011]
According to the display control method of the present invention, a virtual array image in which reduced screens obtained by reducing the screens of a plurality of programs are arranged in a predetermined number of matrices is stored in a storage unit, and stored in the storage unit. Arranged in a predetermined number of matrices From a virtual array image, Less than a certain number Multiple reduced screens for a given selection area Select Read out and display a multi-screen consisting of multiple reduced screens on the display means. When a cursor is operated to move the cursor while the cursor is moved to the top, bottom, left and right edges of the multi-screen, the cursor for instructing the reduced screen is displayed on the display means. Move according to the operation, read out a plurality of reduced images of the newly selected selection area from the virtual array image, and display the multi-screen consisting of the plurality of reduced images on the display means It is made like that.
[0012]
【Example】
Examples of the present invention will be described below, but before that, in order to clarify the correspondence between each means of the invention described in the claims and the following examples, parentheses after each means are shown. The features of the present invention are described as follows by adding the corresponding embodiment (however, an example).
[0013]
That is, the display control apparatus according to claim 1 is a display control apparatus that controls display of a program of a plurality of broadcast channels on display means for displaying information (for example, the monitor apparatus 4 shown in FIG. 3). Receiving means (for example, the front end 20 shown in FIG. 10) that receives a signal including programs of a plurality of broadcast channels, and output means (for example, FIG. 10) that outputs and displays the program received by the receiving means on the display means. CPU 29 shown in FIG. 10) and storage means (for example, a virtual array image in which reduced screens obtained by reducing the screens of a plurality of programs are arranged in a predetermined number of matrixes from the signals received by the receiving means (for example, Virtual frame memory 49 shown in FIG. 10) and the storage means Arranged in a predetermined number of matrices From a virtual array image, Less than a certain number Multiple reduced screens for a given selection area Select Reading means (for example, the CPU 29 shown in FIG. 10) for reading and displaying on the display means a multi-screen composed of the plurality of reduced screens. Cursor display control means (for example, processing step S51 of the program shown in FIG. 39) for displaying a cursor for instructing a reduced screen on the display means, and is operated when moving the cursor to the next reduced screen. A cursor moving means (for example, a joystick 410 shown in FIG. 12), and when a direction operation is performed by the cursor moving means in a state where the cursor is moved to the top, bottom, left and right edges of the multi-screen, The selection area is moved in accordance with the direction operation, a plurality of reduced images of the newly selected selection area are read from the virtual array image, and a multi-screen including the plurality of reduced images is displayed on the display means. It is characterized by that.
[0015]
Claim 3 The display control device described in 1) is a program designating unit operated when designating a predetermined program indicated by the cursor from the multi-screen while the multi-screen is displayed on the display unit (for example, FIG. And the cursor is moved while instructing each of a plurality of reduced screens constituting the multi-screen displayed on the display unit by a predetermined time unit under the control of the cursor display control unit. The storage means further stores EPG (Electrical Program Guide) data corresponding to the reduced screen indicated by the cursor when the program specifying means is operated.
[0016]
Claim 6 The display control apparatus described in 1) further includes reception specifying means (for example, a joystick 410 shown in FIG. 12) operated when the receiving means receives a program.
[0017]
Of course, this description does not mean that the respective means are limited to those described above.
[0018]
FIG. 1 is a diagram for explaining terms used in the present invention. FIG. 1A shows a normal screen (program screen), and an original image displayed in full motion with a full size (for example, 720 × 480 pixels) and a frame rate of 30 frames / second (30 fps). Means the screen to be displayed.
[0019]
FIG. 1B shows a multi-screen (program selection screen or reduced screen arrangement), and a reduced screen having a 1/9 size (240 × 160 pixels) frame size of a normal screen (FIG. 1A). The images are arranged in a 3 × 3 matrix, and each reduced screen is an image displayed in full motion (30 fps).
[0020]
FIG. 1C shows a virtual screen. 1 to No. 6 is a virtual array image in which 6 multi-screens are arrayed in a 2 × 3 matrix, and are sequentially written into the virtual frame memory at a timing that satisfies a frame rate of 30 fps. Each reduced screen has a frame size of 1/9 (240 × 160 pixels) and is written so as to be displayed in full motion (30 fps).
[0021]
FIG. 1D shows a selection area (reading area), which is an area for selecting a multi-screen to be read out according to the cursor movement operation from the virtual screen written in the virtual frame memory. It moves up, down, left and right as it moves When each reduced screen is displayed in units of program categories or the like, the arrangement of the reduced screens constituting the virtual screen is rearranged in such program category units.
[0022]
When the image selected in the selection area is displayed on the monitor device, a multi preview screen (program selection screen) is displayed. This multi-preview screen displays a multi-screen read in response to the cursor movement operation on the monitor device from the virtual screens written in the virtual frame memory. Each reduced screen has a frame size. It is 1/9 size (240 × 160 pixels) and is displayed in full motion (30 fps).
[0023]
Next, the archiving process described in this specification will be described with reference to FIG.
[0024]
In other words, in the present invention, the screens of a plurality of programs (9 in this embodiment) are reduced (compressed) by thinning, for example, so that the number of pixels is 1/3 in the vertical direction and the horizontal direction, respectively. As a result, a reduced screen having an area reduced to 1/9 is generated. The nine reduced screens are arranged at each position of the multi-screen obtained by dividing one screen into 3 × 3, thereby corresponding to one screen (corresponding to one broadcast channel). . 1 to No. 6 multi-screens are generated. In addition, these six Nos. 1 to No. As shown in FIG. 2, the multi-screen 6 is compressed by, for example, the MPEG method, and multiplexed by the multiplexer (MPX) 211 so that it can be transmitted by one transmission channel. In the present specification, the compression multiplexing process is described as an archiving process.
[0025]
The data multiplexed as data of one transmission channel by the multiplexer 211 is transmitted to the reception side through a transmission path composed of satellites, cables, and the like.
[0026]
On the receiving side, the data of one transmission channel transmitted through the transmission path by the demultiplexer (DMPX) 24 is separated, and the data for the original six broadcast channels (No. 1 having nine reduced screens). To No. 6 multi-screen data).
[0027]
And the separated No. 1 to No. 6 multi-screen data (program selection screen data) is expanded (decoded) by the MPEG method and stored in the virtual frame memory 49 so as to form a large virtual screen.
[0028]
Then, an arbitrary 3 × 3 reduced screen area of the virtual screen is appropriately selected, output, and displayed.
[0029]
FIG. 3 shows a configuration of an embodiment of a broadcasting system to which the present invention is applied. In broadcasting stations, for example, program broadcasting by DSS is performed. That is, at the broadcasting station, a program (analog signal image and sound) of one or a plurality of broadcast channels is produced and supplied to the digitizing unit 51. The digitizing unit 51 is also supplied with programs from other broadcasting stations. In the digitizing unit 51, the images and sounds constituting the program are digitized and output to the archiving unit 52.
[0030]
The archiving unit 52 is supplied with a program from the digitizing unit 51, and also supplied with a digitized program (digitalized image and sound) of one or a plurality of broadcast channels from other broadcasting stations. It is made to be done. In the archiving unit 52, data for selecting a program for each channel (data for a program selection screen) representing the contents of each of the programs of a plurality of channels input thereto is generated. That is, in the archiving unit 52, for example, a screen (image) of a program of a plurality of channels input thereto is reduced, and a multi-screen image is formed by nine reduced screens. For example, a program of nine broadcast channels is set as a multi-screen of one broadcast channel.
[0031]
In this way, the program selection data (reduced screen) is created using the program that is normally broadcast as it is, so the program selection program is created separately (independently) from the program that is normally broadcast. This saves you time and effort.
[0032]
Here, in the archiving unit 52, the vertical and horizontal screens of the programs of each channel are reduced to, for example, 1/3 (therefore, considering the area, 1 / of the screen of the program of each broadcast channel). 9) is generated. Accordingly, in this case, on the viewer side, a reduced screen of programs of nine broadcast channels can be simultaneously displayed on one screen.
[0033]
In the archiving unit 52, the audio of the program corresponding to each reduced screen constituting the multi-screen (program supplied from the digitizing unit 51 and other broadcasting stations) is transmitted together with the reduced screen.
[0034]
The archiving unit 52 further compresses these data by the MPEG method.
[0035]
In the archiving unit 52, a plurality of (for example, six) such multi-screens (program selection screens) are generated (that is, a reduced screen of a total of 54 (= 6 × 9) programs is generated). Then, the six multi-screen data are collected (combined (archived)) as data of one transmission channel. Here, the data of a plurality of program selection screens, which are output from the archiving unit 52 and are compiled from a plurality of broadcast channel programs into one transmission channel data, are hereinafter referred to as archive data (“archive” as appropriate) This is a so-called computer terminology, meaning that a plurality of data are combined into one).
[0036]
The video server 53 is supplied with archive data from the archiving unit 52, and is also supplied with a plurality of broadcast channel programs digitized and compressed by the MPEG system from the digitizing unit 51 (note that Details will be described later with reference to FIG.
[0037]
In the video server 53, the data input thereto is temporarily stored and supplied to the transmission unit 54.
[0038]
In the transmission unit 54, error correction processing, modulation (for example, QPSK modulation) processing, and other necessary processing (for example, encryption processing, multiplexing processing, up-conversion, etc.) are performed on the data from the video server 53. Is given. Then, a signal obtained as a result of the processing is transmitted to the satellite (BS (broadcast satellite) or CS (communication satellite)) 61 via the parabolic antenna 55, and transmitted from the satellite 61 to the viewer side. That is, in the transmission unit 54, the archive data of the program selection screen is transmitted to the viewer side through the satellite 61 together with the programs of a plurality of broadcast channels. Accordingly, when the screen of each program is considered as a full-size screen, the full-size screen and a reduced screen obtained by reducing the screen are simultaneously transmitted from the broadcasting station.
[0039]
Note that programs and archive data of a plurality of broadcast channels are transmitted from the video server 53 by a wired transmission path such as a cable, terrestrial waves, or other distribution methods in addition to being transmitted to the viewer side via the satellite 61. It is possible to transmit to the viewer side. Furthermore, a plurality of channels of programs and archive data are transmitted to the viewer through a plurality of types of transmission channels rather than a single type of transmission channel (for example, programs of a plurality of broadcast channels are transmitted via the satellite 61). The archive data can also be transmitted via a cable, etc.).
[0040]
In addition, the programs of the plurality of broadcast channels (ordinary program data) are transmitted as digitized by the digitizing unit 51. In addition, the programs of the plurality of broadcast channels are in analog signal states (as they are). An analog program) can be supplied to the transmission unit 54 and transmitted together with archive data from the video server 53.
[0041]
On the viewer side, data (programs and archive data of a plurality of broadcast channels) transmitted from the broadcasting station via the satellite 61 are received by the parabolic antenna 3 and supplied to the receiver (set top box) 2.
[0042]
In the receiver 2, necessary processing is performed on the data from the parabolic antenna 3, and the image is supplied to and displayed on a monitor device 4 such as a television receiver, and the sound is sent to a speaker (not shown). Supplied and output. That is, when a specific broadcast channel is selected in the receiver 2, the program of the broadcast channel is displayed on the monitor device 4. When archive data is selected in the receiver 2, the monitor device 4 has a predetermined number of broadcast channels (as described above, 9 channels in the present embodiment) out of a plurality of reduced screens. ) Are displayed at the same time. Therefore, in this case, the viewer can recognize the contents of each of the programs of a plurality of broadcast channels currently being broadcast by looking at the program selection screen (details will be described later). Here, the program selection screen is hereinafter referred to as a preview or a preview screen as appropriate.
[0043]
When data is transmitted from a broadcasting station via a cable or the like, the data is directly received by the receiver 2. Further, when data is transmitted from a broadcasting station by terrestrial waves, the data is received by a terrestrial antenna (not shown) and supplied to the receiver 2. Also, in FIG. 3, two receivers 2 are shown, but at least one receiver 2 transmits data transmitted via the satellite 61 and other cables or terrestrial waves. Data Both Can be received.
[0044]
FIG. 4 shows how archive data is generated in the archive unit 52. As shown in the figure, the archiving unit 52 reduces the screens (images) of nine broadcast channel programs to generate one multi-screen. This multi-screen data can be handled as data of one broadcast channel or independent data for program selection on the viewer side. Then, the archiving unit 52 generates, for example, six such multi-screens, and collects (combines) them as data (archive data) 52 of one transmission channel.
[0045]
As described above, the program data shown in FIG. 4 includes the audio of the program of each broadcast channel in addition to the reduced screen data.
[0046]
In addition, the archiving unit 52 converts the reduced screens of programs of a plurality of broadcast channels into archive data as they are and outputs them to the video server 53, for example, arranging them separately for each category (genre) of programs. After being arranged in a predetermined arrangement state, it can be converted into archive data and output to the video server 53.
[0047]
That is, for example, as shown in FIG. 5, reduced screens having different program categories can be arranged (arranged) in the vertical direction, and reduced screens having the same program category can be arranged in the horizontal direction. . Specifically, for example, a reduced screen of a news program is arranged on the first line, a reduced screen of a movie program is arranged on the second line, and a reduced screen of a music program is arranged on the third line. Like that. In this case, the reduced screens of programs of the same category are arranged in the horizontal direction, for example, in ascending order of the broadcast channels of the programs or in alphabetical order of the program titles.
[0048]
When there are four or more categories and when there are four or more programs of a predetermined category, they are arranged on another program selection screen. A plurality of (six) program selection screens constitute one virtual frame (this will be described later).
[0049]
By displaying the multi preview screen in which the reduced screen is arranged as described above on the viewer side, the viewer views the row of the category of the desired program in the horizontal direction on the multi preview screen. Thus, a desired program can be easily found.
[0050]
Further, in this case, the cursor is displayed on a predetermined one on the reduced screen constituting the multi preview screen as shown in FIG. 5, and the viewer moves the cursor so that the viewer can select a desired program. You can easily find and select that channel.
[0051]
Next, generation of a program selection screen will be described in more detail with reference to FIG. The digitizing unit 51 performs A / D conversion on the input analog video signal and audio signal by the A / D converter 231, and then outputs the analog video signal and audio signal to the MPEG video / audio encoder / multiplexer system 232 for program transmission. The digital video signals for 54 channels are supplied to the multi-screen generation circuits 201-1 to 201-6 of the archiving unit 52. When the video signal and the audio signal are supplied as digital signals, the digital signals are supplied as they are to the MPEG video / audio encoder / multiplexer system 232 for program transmission and the multi-screen generation circuits 201-1 to 201-6. The
[0052]
The multi-screen generation circuit 201-1 has nine RAMs 202-1-1 to 201-1-9, and the screen data of nine input programs is stored here. Then, the data of the nine screens are reduced to 1/3 in the vertical direction and the horizontal direction, thereby generating nine reduced screens. The nine reduced screens are arranged on a multi-screen obtained by dividing one screen into nine 3 × 3 screens.
[0053]
For example, when one screen (one frame) is composed of 720 × 480 pixels, this number is reduced to 1/3 in the horizontal direction and the vertical direction, that is, pixels are thinned out to 240 × 160 pixels. The image is reduced. Then, by arranging 3 × 3 images of these reduced screens in the horizontal direction and the vertical direction, one multi-screen having nine reduced screens is generated. In this multi-screen, one frame is composed of 720 × 480 pixels.
[0054]
Similar processing is performed in the other five multi-screen generation circuits 201-2 to 201-6. As a result, six multi-screens (program selection screens) each having nine reduced screens are generated.
[0055]
In this way, the six multi-screen data generated by the multi-screen generation circuits 201-1 to 201-6 are supplied to the corresponding MPEG video encoders 203-1 to 203-6, and compressed by the MPEG method. Is done. As a result, 6 pieces of archive data (for 6 broadcast channels) are obtained.
[0056]
Also, the EPG (Electrical Program Guide) data generation device 204 of the archiving unit 52 includes 54 broadcast channels supplied from the MPEG video / audio encoder / multiplexer system 232 for program transmission to the multi-screen generation circuits 201-1 to 201-6. Electronic program guide data (such as broadcast start time, minute channel number (channel ID), category, program name (program ID), position on multi-screen, number of pixels on reduced screen (eg 240 × 160)) EPG data) is generated.
[0057]
The video server 53 stores the video data supplied from the MPEG video encoders 203-1 to 203-6 of the archiving unit 52 and the EPG data supplied from the EPG data generation device 204 in a built-in memory as necessary. After that, the data is read out, and each data is packetized and multiplexed (archived) by the multiplexer 211 so that it can be transmitted through one transmission channel (channel corresponding to one transponder). At this time, the archived 54 program audio data is also input from the MPEG video / audio encoder / multiplexer system 232 for program transmission to the video server 53, and these audio data are also packetized and transmitted in the same manner. Multiplexed for transmission on the channel.
[0058]
In this way, archive data including six multi-screens each having nine reduced screens (the six multi-screens constitute one virtual frame) is transmitted as a signal of one transmission channel. Is supplied to the transmission path encoding device 221-1 of the unit 54.
[0059]
The error correction encoding circuit 222-1 of the transmission path encoding device 221-1 performs error correction encoding processing on the data input from the multiplexer 211, and then outputs the data to the QPSK modulation circuit 223-1. The QPSK modulation circuit 223-1 performs QPSK modulation on the input data and outputs it to the up-converter 224-1. The up-converter 224-1 converts the input data into a signal of a predetermined frequency band (a signal corresponding to one transponder of the satellite) and outputs the signal to the mixer 225.
[0060]
Thus, the transmission channel of the program selection screen is a dedicated transmission channel.
[0061]
On the other hand, video data and audio data of at least 54 programs (programs as full-size screens) are compressed by the MPEG system in the MPEG video / audio encoder / multiplexer system 232 for program transmission, respectively. The broadcast channel programs are packetized and multiplexed so as to be transmitted through one transmission channel. However, the number of multiplexed broadcast programs (broadcast channels) varies depending on the complexity of the image.
[0062]
Then, data of one transmission channel is input to the transmission path encoding device 221-2, and error correction encoding processing and QPSK modulation processing are performed as in the transmission path encoding device 221-1. The data output from the transmission path encoding device 221-2 is converted into a signal of a predetermined frequency band corresponding to another transponder of the satellite by the up-converter 224-2, and then input to the mixer 225. .
[0063]
Hereinafter, the data subjected to the same processing is mixed by the other transmission path encoding device 221-3, up-converter 224-3 (not shown) or transmission path encoding device 221-n and up-converter 224-n. Input to the device 225.
[0064]
The mixer 225 mixes the data input from the up converters 224-1 to 224-n and transmits the mixed data to the satellite 61 via the parabolic antenna 55.
[0065]
By the way, on the viewer side, the broadcast channel number is displayed together with a plurality of reduced screens as a multi-preview screen, and the broadcast channel of the desired program is displayed to the viewer. of It is also possible to select by entering a number. However, in that case, for example, it is conceivable that the viewer mistakes the broadcast channel or erroneously inputs a number corresponding to the broadcast channel. Therefore, from the state in which the preview as shown in FIG. 5 is displayed, it is preferable to display the screen of the program by directly selecting the reduced screen corresponding to the desired program.
[0066]
Therefore, the archiving unit 52 establishes a link between the reduced screen and the program corresponding to the reduced screen. Specifically, for example, a broadcast channel number of a program corresponding to the reduced screen is added to the reduced screen data, and this is transmitted as EPG data. In this way, for example, as shown in FIG. 7, by selecting a reduced screen constituting the preview, it is possible to cope with a program linked with the reduced screen, that is, the selected reduced screen. A full size screen (program) can be displayed. In FIG. 7, of the nine reduced screens constituting the preview, the one arranged at the center of the screen is selected, whereby the program PROG2 corresponding to the reduced screen is displayed instead of the preview. It shows the state.
[0067]
Next, FIG. 8 shows a schematic configuration example of the receiver 2 on the viewer side. The receiver 2 includes a receiving unit 2a, a processing device 2b, and a storage device 2c. In the receiving unit 2a, for example, a signal supplied from the parabolic antenna 3 (FIG. 3) is received, subjected to demodulation processing, error correction processing, and other necessary processing, and output to the processing device 2b. The processing device 2b is composed of a CPU or the like, and controls the receiving unit 2a so as to output a predetermined channel signal. After the processor 2b decodes the signal supplied from the receiving unit 2a, if the signal is normal program data, the processor 2b supplies the signal to the monitor device 4 for display (note that the sound is And output from a speaker (not shown).
[0068]
In addition, when the signal supplied from the receiving unit 2a is archive data, the processing device 2b decodes the archive data, and converts the reduced screen data obtained as a result into, for example, a RAM, a magnetic disk, or a magneto-optical device. The data is stored in the virtual frame memory of the storage device 2c formed of a disk or the like.
[0069]
If the archive data includes sound, the sound is also supplied to and stored in the storage device 2c.
[0070]
When the remote commander 5 is operated to instruct to display a reduced screen, the processing device 2b displays one screen of the monitor device 4 among the reduced screens stored in the virtual frame memory. The number of reduced screens that can be displayed (in this embodiment, nine reduced screens as described above) is read and supplied to the monitor device 4 for display.
[0071]
The reduced screen that is read from the virtual frame memory and displayed on the monitor device 4 can be changed by operating the remote commander 5, and therefore, the number that cannot be displayed on the screen at one time. Even if the reduced screen is transmitted, the viewer can view all the reduced screens by operating the remote commander 5. Further, the received reduced screens are sequentially updated and stored in the virtual frame memory. For example, by holding the reduced screens stored in the virtual frame memory for a predetermined period, it is possible to store previously received programs. A reduced screen can be viewed.
[0072]
The reduced screen displayed on the monitor device 4 can be selected by operating the remote commander 5 and moving and confirming the cursor, and the reduced screen corresponding to the program desired by the viewer is selected. Then, the processing device 2b instructs the receiver 2a to output a program corresponding to the reduced screen (a program linked to the reduced screen), and normal program data obtained as a result Is supplied to the monitor device 4 for display.
[0073]
FIG. 9 shows the connection relationship of devices on the viewer side. As will be described later with reference to FIG. 10, the receiver 2 includes a modem unit 631, to which a telephone (base unit) 600 is connected, and also has a function as a cordless telephone (slave unit). For example, a signal can be exchanged with the terminal 5 via an RF signal.
[0074]
FIG. 10 shows an example of the internal configuration of the receiver 2 for receiving the above-described DSS. The front end 20, the demultiplexer 24, the multi-channel real-time decoder 25, or the virtual frame memory 49 in FIG. 10 correspond to the receiving unit 2a or the storage device 2c shown in FIG. 8, respectively. Further, the other blocks in FIG. 10 correspond to the processing apparatus 2b shown in FIG.
[0075]
The parabolic antenna 3 has an LNB (Low Noise Block downconverter) 3a, receives a signal from the satellite 61, and converts it into an intermediate frequency signal (IF signal). The IF 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 supplied to the QPSK demodulating circuit 22 and QPSK demodulated. The output of the QPSK demodulator circuit 22 is supplied to an error correction circuit 23, where an error is detected and corrected.
[0076]
For example, a CAM (Conditional Access Module) 33 configured by an IC card including a CPU, a ROM, a RAM, and the like stores a key necessary for decrypting a cipher together with a decryption program. When a broadcast station transmits data after performing encryption processing, a key and decryption processing are required to decrypt the encryption. Therefore, this key is read from the CAM 33 via the card reader interface 32 and supplied to the demultiplexer 24. The demultiplexer 24 uses this key to decrypt the encrypted signal.
[0077]
The CAM 33 stores accounting information as well as keys and decryption programs necessary for decryption.
[0078]
The demultiplexer 24 receives the signal output from the error correction circuit 23 of the front end 20 and temporarily stores it in a data buffer memory (SRAM: Static Random Access Memory) 35. This is read out as appropriate and decrypted as described above. Then, the demultiplexer 24 supplies the image data or audio data obtained as a result of the decoding to the multi-channel real time decoder 25 or the MPEG audio decoder 26, respectively.
[0079]
As will be described later with reference to FIG. 23, the multi-channel real-time decoder 25 can decode MPEG video decoders 25-1 to 25-6 and DRAMs 25a-1 to 25a so as to be able to decode screen data of programs for six broadcast channels. -6 is incorporated, and the input image data (digital image data) is appropriately stored in the DRAM 25a, and the decoding process of the video signal compressed by the MPEG system is executed. The video data obtained as a result of decoding is supplied to the NTSC encoder 27 when it is from a normal program, and is converted into an NTSC luminance signal (Y), chroma signal (C), and composite signal (V). Converted. The luminance signal and the chroma signal are respectively output as S video signals via the buffer amplifiers 28Y and 28C. The composite signal is output via the buffer amplifier 28V.
[0080]
The data of the program selection screen is supplied to and stored in the virtual frame memory 49. Then, predetermined nine reduced screens are read out as necessary and supplied to the NTSC encoder 27.
[0081]
As the MPEG video decoder 25-i in FIG. 23, an MPEG2 decoding LSI (STi3500) manufactured by SGS-Thomson Microelectronics can be used. The outline is introduced by Martin Bolton on pages 101 to 110 of Nikkei PB "Nikkei Electronics" 1994.14 (no. 603), pages 101 to 110, for example.
[0082]
The MPEG2-Transport stream is described in pages 231 to 253 of “Latest MPEG Textbook” issued on August 1, 1994 by ASCII Corporation.
[0083]
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 method. The decoded audio signal is D / A converted by the D / A converter 30, the left channel audio signal is output via the buffer amplifier 31L, and the right channel audio signal is output via the buffer amplifier 31R. Is done.
[0084]
The RF modulator 41 converts the composite signal output from the NTSC encoder 27 and the audio signal output from the D / A converter 30 into an RF signal and outputs the RF signal. The RF modulator 41 passes through an NTSC RF signal input from an AV device (not shown) such as a cable box when a TV mode for receiving a terrestrial television broadcast signal is set. , Output to the VCR (VTR) and other AV devices (both not shown) as they are.
[0085]
In this embodiment, these video signals and audio signals are supplied to the monitor device 4.
[0086]
A CPU (Central Processor Unit) 29 executes various processes in accordance with programs stored in the ROM 37. For example, the tuner 21, the QPSK demodulation circuit 22, the error correction circuit 23, and the like are controlled. Further, the AV device control signal transmitting / receiving unit 2A is controlled to output 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. Receive control signal from.
[0087]
A predetermined command can be directly input to the CPU 29 by operating an operation button / switch (not shown) provided on the front panel 40 of the receiver 2, and the remote controller 5 is operated. Also, a predetermined command can be input.
[0088]
That is, when the remote controller 5 is operated, an RF signal is emitted from a built-in antenna 681 (not shown), and this RF signal is received by the base unit (phone base phone) 600. The output of the base unit 600 is supplied to the modem unit 631 via the modular jacks 601 and 636.
[0089]
The modem unit 631 connected to the CPU 29 has a modem 632 incorporating a DTMF decoder 633. The modem 632 is connected to a telephone line via a modular jack 635 and is connected to the modular jack 636 via a circumscribed telephone off-hook detection circuit 634.
[0090]
Further, when the signal supplied from the front end 20 is EPG data, the demultiplexer 24 supplies the EPG data to the data buffer memory 35 and temporarily stores it. The EPG data stored in the data buffer memory 35 is transferred to and stored in the SRAM 36 at an arbitrary timing (for example, free time of the CPU 29).
[0091]
In an EEPROM (Electrically Erasable Programmable Read Only Memory) 38, data to be retained after the power is turned off (for example, reception history of the tuner 21 for four weeks, channel number received immediately before the power is turned off (last channel) )) Etc. are stored as appropriate. For example, when the power is turned on, the same channel as the last channel is received again. When the last channel is not stored, the channel stored in advance in ROM 37 as a default is received. Further, when the sleep mode is set, the CPU 29 operates a minimum circuit such as the front end 20, the demultiplexer 24, the data buffer memory 35, etc. even when the power is off, and is included in the received signal. Control is also performed such as counting the current time from the time information and causing each circuit to perform a predetermined operation (so-called timer recording or the like) at a predetermined time. For example, scheduled timer automatic recording is executed in conjunction with an external VCR.
[0092]
Further, the CPU 29 controls the MPEG video decoder 25-i when it is desired to generate predetermined OSD (On-Screen Display) data. In response to this control, the MPEG video decoder 25-i generates predetermined OSD data, writes it in the OSD area of the DRAM 25a-i, reads it out, and outputs it. As a result, predetermined characters, graphics, etc. (for example, a cursor, a broadcast channel of a program currently output from the receiver 2, a bar whose length changes according to the volume, etc.) are output to the monitor device 4 as appropriate. Can be displayed.
[0093]
FIG. 11 illustrates a configuration example of the base unit 600. The modular jack 601 is connected to a line interface (I / F) 651. A DTMF encoder 652 is also connected to the line interface 651, and the DTMF encoder 652 encodes the input command into a DTMF signal and outputs it.
[0094]
The line interface 651 outputs a signal to be transmitted to the remote controller 5 that also functions as a slave unit to the transmission circuit (TX) 653. The transmission circuit 653 digitizes and modulates the transmission signal and outputs it from the antenna 655 as an RF signal. The receiving circuit (RX) 654 receives and demodulates the RF signal transmitted from the remote controller 5 via the antenna 655, outputs a voice signal to the line interface 651, and outputs a command to the microcomputer 656.
[0095]
A microcomputer 656 incorporating a CPU, ROM, RAM and the like controls the transmission circuit 653 and the reception circuit 654 in response to an input from the key 657. In addition, predetermined characters, symbols, and the like are displayed on the display unit 658.
[0096]
In FIG. 11, for convenience of explanation, illustration of a microphone and a speaker included in the base unit (master unit) 600 is omitted.
[0097]
Next, the remote controller 5 will be described. 12 is a front view of the remote controller 5, and FIG. 13 is an XY cross-sectional view of the remote controller 5 shown in FIG. The remote controller 5 is shaped like a penguin, and basically includes a main body 405 and a microphone portion 703A (described later) that is rotatably attached to the main body 405.
[0098]
The main body 405 is formed on the top thereof, and a display device 401 that performs predetermined display (a key group 701 is displayed in the figure) such as a speaker 702 that outputs the voice of the other party and a channel key and a telephone number. A call button 402 that is operated when calling a telephone number displayed on the display device 401, a memory button 403 that is operated when information such as a telephone number is stored, and an operation mode will be described later. It has a preview button 404 that is operated when the preview mode is set, and a joystick 410 that is operated when a cursor displayed on the monitor device 4 is moved. In addition, the remote controller 5 includes an antenna 681 (FIG. 22) therein, and exchanges radio waves with the base unit 600 (receiver 2).
[0099]
When the remote controller 5 is placed on a desk or the like, a leg portion 405A that supports the main body 405 together with the microphone portion 703A is formed at the lower back of the main body 405, and the microphone portion 703A is counterclockwise in FIG. A stopper portion 441 that restricts rotation is formed in the lower front portion of the main body 405. Furthermore, a cylindrical shaft portion 441A as a rotation shaft of the microphone portion 703A is formed at the tip of the stopper portion 441. Further, a contact portion 452 (described later) as a power switch of the remote controller 5 is disposed on the lower surface of the stopper portion 441.
[0100]
14 shows a configuration of the microphone unit 703A shown in FIGS. 12 and 13, FIG. 14A is a plan view of the microphone unit 703A, and FIG. 14B shows an A- of the microphone unit 703A. FIG. 14C is a rear view of the microphone unit 703A. A microphone 703 that collects the user's voice is formed at the center of the tip (left end in the figure) of the microphone part 703A, and the center of the opposite end face (right end face in the figure) is formed in a cylindrical shape. A shaft portion 441A that is penetrated and formed in the main body 405 is fitted into the bored portion. Therefore, the microphone part 703A can be rotated around the shaft part 441A.
[0101]
Further, corner portions 460 and 461 are formed so as to limit the clockwise and counterclockwise rotation of the microphone portion 703A in FIG. 13, and the corner portion 460 or 461 is a stopper portion formed on the main body 405. The rotation of the microphone unit 703A is restricted by contacting the lower surface or the upper surface of 441, respectively. Further, since the spring 440 shown in FIG. 13 urges the microphone portion 703A counterclockwise in FIG. 13, when the remote controller 5 is not placed on the stand (when the remote controller 5 is lifted), the microphone The part 703A is arranged at a position indicated by a dotted line in FIG.
[0102]
A contact portion 451 as a power switch of the remote controller 5 is a predetermined position on the corner portion 460 (a position corresponding to the contact portion 452 disposed on the stopper portion 441) (as shown in FIG. 14C). In this case, when the microphone unit 703A is disposed at the position indicated by the dotted line in FIG. 13 (that is, when the remote controller 5 is lifted), the microphone unit 703A is disposed below the stopper unit 441 described above. The power supply of the remote controller 5 is turned on in contact with the arranged contact portion 452. On the other hand, when arranged at the position indicated by the solid line in FIG. 13 (that is, when the remote controller 5 is placed on the table), the contact between the contact portion 451 and the contact portion 452 is released and the remote controller 5 is turned off. Is done.
[0103]
FIG. 15 is a perspective view when the remote controller 5 is placed on a table (that is, when not in use). In this case, the microphone portion 703A rotates counterclockwise in the drawing around the shaft portion 441A against the biasing force of the spring 440, and the corner portion 461 is in contact with the upper surface of the stopper portion 441. . Therefore, the remote controller 5 is supported by the microphone part 703A and the leg part 405A and is independent. At this time, the contact portion 452 disposed on the lower surface of the stopper portion 441 and the contact portion 451 disposed on the corner portion 460 are not in contact with each other, so that the power source of the remote controller 5 is turned off.
[0104]
FIG. 16 is a perspective view when the remote controller 5 is lifted by the user (that is, in use). In this case, since the remote controller 5 is not placed on the stand, the microphone portion 703A is biased by the spring 440 and rotates clockwise in the drawing, and the corner portion 460 contacts the lower surface of the stopper portion 441. At this time, the contact portion 452 disposed on the lower surface of the stopper portion 441 contacts the contact portion 451 disposed on the corner portion 460, so that the power source of the remote controller 5 is turned on.
[0105]
As illustrated in FIG. 13, the display device 401 includes a display unit 430 that includes an LCD (Liquid Cristal Display) that displays information, and a transparent tablet 431 that covers the top of the display unit 430. Furthermore, when the key group 701 shown in FIG. 12 is displayed on the display unit 430, a portion corresponding to the display position of each key of the tablet 431 is formed to protrude so that the user can easily press each key. .
[0106]
In the embodiment of FIG. 12, the key group 701 is composed of keys displaying numbers 0 to 9, keys displaying * and # marks, and keys displaying TEL characters. Yes.
[0107]
The number 2 key is the letter ABC, the number 3 key is the letter DEF, the number 4 key is the letter GHI, the number 5 key is the letter JKL, and the number 6 key is the letter MN. However, the character PRS is displayed on the key of the number 7, the character TUV is displayed on the key of the number 8, the character WXY is displayed on the key of the number 9, and the character QZ is displayed on the key of the number 0.
[0108]
In addition, the number 4 key has a rewind symbol that symbolizes rewinding the playback point, the number 5 key has a symbol that pauses playback, and the number 6 key plays a symbol. Each fast-forward symbol that symbolizes fast-forwarding of points is displayed.
[0109]
In addition, the number 0 key is displayed with a symbol obtained by symbolizing a predetermined function.
[0110]
Furthermore, as a symbol that symbolizes the movement of the cursor, an arrow pointing upward in the vicinity of the numeric key 2, a downward arrow in the vicinity of the numeric key 8, and a left arrow in the vicinity of the numeric key 4 However, a right arrow is displayed in the vicinity of the numeric key 6. In addition, the characters “YES” or “NO” are displayed in the vicinity of the numeric key 5 or 0 as symbols that symbolize the meaning of affirmation or negation.
[0111]
FIG. 17 is a top rear view of the main body 405, and only the vicinity of the joystick 410 is shown in cross section. The joystick 410 is disposed on the right side when the main body 405 is viewed from the back (on the left side when the main body 405 is viewed from the front) and in the vicinity of the lower end of the speaker 702. The concave portion 411 is formed so that the user can move the joystick 410 in multiple directions (in this embodiment, eight directions as will be described later). Although not shown, the recess 411 is covered so that dust and the like do not enter.
[0112]
FIG. 18 is a perspective view illustrating a configuration example of the joystick 410. The joystick 410 has a structure in which a lever 162 protrudes from a main body 161 and a hemispherical operation ball 473 operated by a user's finger is attached to the tip of the lever 162. When the operation ball 473 is operated in eight directions in the horizontal plane, the lever 162 rotates corresponding to the operation direction, and when the operation ball 473 is selected (perpendicular operation), the lever 162 is pushed down in the vertical direction.
[0113]
FIG. 19 shows eight operating directions of the lever 162 in the horizontal plane. As shown in the figure, the lever 162 can be operated in directions in eight horizontal planes indicated by A to H.
[0114]
In this embodiment, since the joystick 410 is disposed near the lower end of the speaker 702 on the side surface of the main body 405 (the left side when the main body 405 is viewed from the front), the user can The joystick 410 can be easily operated with a predetermined finger of the hand having the main body 405, and remote control of the receiver 2 and the like can be performed.
[0115]
For example, as shown in FIG. 20, when a call is made with the remote controller 5 held in the left hand (that is, when the sound output from the speaker 702 is listened to with the left ear), the user can easily hold the joystick 410 with the left thumb 480. Remote control can be performed.
[0116]
On the other hand, as shown in FIG. 21, when a call is made with the remote controller 5 held in the right hand (that is, when the sound output from the speaker 702 is listened to with the right ear), the user can easily hold the joystick 410 with the right hand index finger 490. Remote control can be performed.
[0117]
Further, for example, when the telephone number list is displayed on the display device 401, the telephone number list displayed on the display device 401 can be scrolled by operating the joystick 410.
[0118]
FIG. 22 shows an example of the internal configuration of the remote controller 5. The audio signal input from the microphone 703 is input to the transmission circuit 682, digitized, modulated, and transmitted to the base unit 600 as an RF signal via the antenna 681.
[0119]
The receiving circuit 683 demodulates the RF signal received via the antenna 681, outputs an audio signal of the demodulated signal to the speaker 702, and outputs a command to the microcomputer 684.
[0120]
The microcomputer 684 also includes a CPU, a ROM, and a RAM. The operation signal of the key group 701 displayed on the display unit 430 or the signal corresponding to the operation of the call button 402, the memory button 403, and the preview button 404 is output from the tablet 431. Various operation controls are performed according to the above. Further, the microcomputer 684 causes the display unit 430 to perform a predetermined display as necessary.
[0121]
The microcomputer 684 also monitors the operation state of the joystick 410 (main body 161). That is, the contacts A to H inside the main body 161 correspond to the eight directions A to H shown in FIG. 19, respectively. When the lever 162 is operated in the directions A to D, any of the terminals A to D is selected. The terminal C1 is made conductive. Further, when the lever 162 is rotated in any one of the directions E to H, any one of these terminals E to H is electrically connected to the terminal C2. Further, between H and A and between D and E, the terminals C1 and C2 are both conducted. Further, when the lever 162 is operated in the vertical direction, the terminals 1 and 2 are made to be the normal band.
[0122]
The conduction state of these terminals of the main body 161 is monitored by the microcomputer 684, whereby the direction operation and the selection operation of the joystick 410 are detected.
[0123]
Next, the operation of the receiver 2 when the operation mode is the preview mode for displaying a preview on the monitor device 4 will be described with reference to FIGS. 10 and 23. FIG. For example, when the preview button 404 of the remote controller 5 is operated continuously for a predetermined time, the operation mode of the receiver 2 is set to the preview mode.
[0124]
That is, when the preview button 404 is operated, an operation signal corresponding to the operation is input to the CPU 29 via the base unit 600 and the modem unit 631, and the CPU 29 outputs an operation signal corresponding to the operation of the preview button 404. When the data is continuously received for a predetermined time, the front end 20 is instructed to receive the archive data transmission channel, and the archive data is supplied from the front end 20 to the demultiplexer 24.
[0125]
As a result, the tuner 21 receives and demodulates the signal from the transmission channel dedicated to the program selection screen. The output of the tuner 21 is further QPSK demodulated by the QPSK demodulating circuit 22, subjected to error correction processing by the error correcting circuit 23, and input to the demultiplexer 24. The data input to the demultiplexer 24 includes the six multi-screen video data packets described above.
[0126]
Assuming that data IDs (packet IDs) of numbers 1 to 6 are added to these packets, data having data IDs of numbers 1 to 6 are decomposed (separated), respectively. Then, it is decoded by the corresponding MPEG video decoders 25-1 to 25-6 of the multi-channel real-time decoder 25, supplied to the DRAMs 25a-1 to 25a-6, and stored. That is, the multi-screen of the packet ID1 is stored in the DRAM 25a-1, and similarly, the multi-screens of the data ID2 to 6 are stored in the DRAMs 25a-2 to 25a-6.
[0127]
Then, the six multi-screens stored in the DRAMs 25a-1 to 25a-6 are read out from the DRAMs, and are expanded and stored in the virtual frame memory 49 so as to form one virtual screen. In the example of FIG. 1 is arranged at the upper left of the virtual screen, and the data ID 2 No. 2 is arranged on the right side, and the data ID 3 No. 3 is arranged on the lower side of the multi-screen of data ID1, and No. 3 of data ID4. 4 is arranged on the right side of the multi-screen of data ID3. 5 is arranged on the lower side of the multi-screen of data ID3. The multi-screen shown by 6 is arranged on the right side of the multi-screen of data ID5.
[0128]
As mentioned above, No. 1 to No. Six pieces of multi-screen data indicated by 6 are transmitted by one transmission channel (one carrier wave from one transponder). Therefore, as shown in FIG. 23, if one front end 20 including the tuner 21 is provided with six MPEG video decoders 25-1 to 25-6, six multi-screens can be received simultaneously, It can be stored in the virtual frame memory 49.
[0129]
When one or more of the multi-screens constituting the program selection screen are transmitted via a transmission channel corresponding to another transponder, the reception frequency of the tuner 21 is received in order to receive the multi-screen of the transmission channel. As a result, it becomes impossible to receive all the multi-screens at the same time. (Of course, if a plurality of tuners 21 are provided, this is possible. However, this makes the configuration complicated. And the cost is high). Therefore, it is preferable that the transmission channel for transmitting the program selection screen is one transmission channel (common transmission channel).
[0130]
The process of receiving a plurality of program selection screens from one transmission channel (archive data) and storing them in the virtual frame memory 49 is schematically shown in FIGS.
[0131]
That is, when receiving the archive data in which the six program selection screens are collected, the demultiplexer 24 separates them into individual program selection screens as shown in FIG. Then, as shown in FIG. 25, the six multi-screens obtained as a result are stored in the virtual frame memory 49 arranged in a matrix. Therefore, the virtual frame memory 49 stores a virtual screen (a virtual screen larger than one multi-screen) (virtual screen) in which 6 × 9 reduced screens of programs of a plurality of broadcast channels transmitted from a broadcasting station are arranged. Is done. Since the reduced screen is a reduced screen of a normal program, it is a full motion image (complete moving image) with a frame rate of 30 fps. Therefore, if a virtual screen is displayed, a broadcast station The contents (reduced screen) of the programs of 54 broadcast channels transmitted from can be viewed in full motion.
[0132]
Here, when the reduced screen is stored in the virtual frame memory 49, the six multi-screens are not arranged at 2 × 3 predetermined positions in the virtual frame memory 49 as they are, but each reduced screen is stored in the CPU 29. By managing independently (managing the pixel data of the virtual screen in units of 240 × 160 pixels), it is managed so that it can be arranged at an arbitrary position of the 6 × 9 child screens of the virtual frame memory 49 You can also
[0133]
In this case, for example, each reduced screen is sequentially arranged in a predetermined number from the left end of the uppermost row of the virtual frame memory 49 in the right direction, and further, a predetermined number is arranged in the right direction from the left end of the next row. They can be arranged in the same manner, or can be arranged separately for each program category as in the case described with reference to FIG. When the reduced screens are arranged separately for each program category, the broadcast station side adds the program category corresponding to the reduced screen to the reduced screen as EPG data. The program category added to the screen may be read from the EPG data, and each reduced screen may be arranged in the virtual frame memory 49 separately for each program category.
[0134]
In the virtual frame memory 49, the reduced screens can be arranged by an arrangement method desired by the viewer. That is, when the broadcast station side adds a program category to the reduced screen as described above, the setting order is set by operating the remote commander 5 and setting the order of the program category. Thus, the reduced screens can be sequentially arranged from the top row of the virtual frame memory 49. Furthermore, for example, it is possible to count the frequency with which the viewer views the program of each channel, and arrange the reduced screens in the order of the frequency.
[0135]
For example, when the broadcast station side adds broadcast channels of programs corresponding to each reduced screen to the reduced screen, the remote commander 5 is operated to set the order of the broadcast channels of the programs. Accordingly, the reduced data can be sequentially arranged from the top row of the virtual frame memory 49 in the setting order.
[0136]
Further, the reduced screen stored in the virtual frame memory 49 is displayed on the monitor device 4, and by operating the remote commander 5 while viewing this display, the reduced data stored in the virtual frame memory 49 is displayed. It is also possible to change the arrangement position.
[0137]
Therefore, in this case, it is possible to arrange the reduced screens according to the viewer's preference. That is, the arrangement of the reduced screen can be customized.
[0138]
Further, as described with reference to FIG. 5, when the reduced screens are arranged and transmitted for each program category on the broadcasting station side, the reduced screens are displayed in the arrangement state in the virtual frame memory 49. Can be memorized. However, even if the reduced screens are arranged and transmitted for each program category, as described above, the reduced screens can be arranged by the arrangement method desired by the viewer. .
[0139]
The arrangement method (arrangement order) is set according to a predetermined menu screen displayed on the monitor device 4 by continuously operating the call button 402 of the remote commander 5 for a predetermined period of time, according to the remote commander 5 (joystick 410). It can be done by operating. The set arrangement method is stored in, for example, the EEPROM 38. When the arrangement method is set in the EEPROM 38, the CPU 29 determines the arrangement order when the reduced screen is stored in the virtual frame memory 49 with respect to the demultiplexer 24. specify. Then, the demultiplexer 24 stores the reduced screen in the virtual frame memory 49 according to the arrangement order designated by the CPU 29.
[0140]
When the reduced screen is stored in the virtual frame memory 49, the CPU 29 commands a reduced screen in a range (selection area) that can be displayed on one screen of the monitor device 4 at the same time. That is, in the present embodiment, as described above, one reduced screen is obtained by reducing the vertical and horizontal lengths of a normal program screen to 1/3. For example, as shown in FIG. In this figure, 3 × 3 reduced screens surrounded by bold lines are read out. The 3 × 3 reduced screens are supplied from the receiver 2 to the monitor device 4 and displayed. That is, a preview is displayed.
[0141]
Here, as described above, when a predetermined 3 × 3 range of the reduced screens stored in the virtual frame memory 49 is displayed, the screen of the monitor device 4 is reduced on the virtual frame memory 49. It can be said that it is used as a metaphor for peeking partially at the screen.
[0142]
In this case, in the monitor device 4, together with the 3 × 3 reduced screens that are previews, for example, as shown in FIG. 27, a frame-like cursor 201 that surrounds one reduced screen is also displayed on the screen. Impose and OSD display. Note that the cursor 201 is not limited to the frame shape as described above, and may be any graphic that makes an image of selection of an arrow or other mark.
[0143]
When the cursor 201 is positioned at the center of the 3 × 3 reduced screen, for example, the joystick 410 of the remote commander 5 moves upward (for example, in the direction of A in FIG. 19) and downward (for example, FIG. 19), the cursor 201 is moved in accordance with the operation direction when the direction is operated to the right, left, right diagonally upward, right diagonally downward, left diagonally upward, or diagonally downward left. , Upward, downward, rightward, leftward, diagonally upward right, diagonally downward right, diagonally upward left, or diagonally down to the left. The movement of the cursor 201 in the up / down / left / right directions can also be performed by operating the numeric keys 2, 8, 4 or 6 of the key group 701, respectively.
[0144]
Here, if the direction of the joystick 410 is further operated while the cursor 201 is moved to the top, bottom, left, and right ends of the screen of the monitor device 4, the display content of the monitor device 4, that is, the preview scrolls. . For example, when the cursor 201 is positioned on the bottom line of the preview and the joystick 410 is operated downward, the preview scrolls upward by one line.
[0145]
In this scroll, for example, instead of the 3 × 3 reduced screen surrounded by the thick line in FIG. 26, the 3 × 3 reduced screen surrounded by the dotted line in FIG. 4 is performed. Since the cursor 201 remains stopped at the bottom line, as a result, the cursor 201 has moved down by one line in the virtual frame memory 49 shown in FIG.
[0146]
Further, for example, as shown in FIG. 28, 3 × 3 reduced screens (3 × 3 surrounded by bold lines in the figure) including reduced screens arranged (arranged) in the lowermost row of the virtual frame 35 are displayed on the monitor device 4. When the cursor 201 is moved to the lower end of the screen of the monitor device 4 and the joystick 410 is further operated in the downward direction. However, the screen of the monitor device 4 is scrolled, so that the monitor device 4 has the 3 × 2 reduced screens in the lowermost row in the range surrounded by the dotted line in FIG. 3 × 1 reduced screens are displayed.
[0147]
Accordingly, in the state in which the monitor device 4 displays the 3 × 3 reduced screen surrounded by the thick line in FIG. 28 and the cursor 201 is moved to the lower end of the screen of the monitor device 4, Further, when the downward direction operation of the joystick 410 is performed three times in succession, the monitor device 4 includes 3 × 3 pieces including the reduced screen on the uppermost line shown by hatching in FIG. A reduced screen will be displayed.
[0148]
Scrolling is performed in the same manner for the upper, left, right, diagonally upward right, diagonally downward right, diagonally upward left, and diagonally downward left directions.
[0149]
In this scroll, a signal (operation signal) corresponding to the direction operation of the joystick 410 is received by the CPU 29 of the receiver 2, and the read address of the virtual frame memory 49 corresponds to the received operation signal in the CPU 29. This is done by being controlled. That is, the CPU 29 recognizes a reduced screen range to be displayed on the monitor device 4, that is, a selection area, based on the received operation signal. Then, the CPU 29 instructs the virtual frame memory 49 to read the selected area. As a result, the selected area (a part of the virtual screen) is read from the virtual frame memory 49 and output to the monitor device 4, and as a result, the screen scrolls.
[0150]
Therefore, the operation of the joystick 410 in this case can be said to be an operation for designating a selection area to be read from the virtual frame memory 49.
[0151]
As described above, since the preview scrolls, previews of all programs are provided to the viewer even if the number of programs is larger than the number of the reduced screens that can be simultaneously displayed on the monitor device 4. Can do.
[0152]
The viewer operates the joystick 410 while viewing the full motion reduced screen displayed on the monitor device 4 as shown in FIG. 27 to move the cursor 201 to the desired reduced screen. When the joystick 410 is vertically operated (select operation) (enter operation) to confirm the selection of the program (program) with the cursor 201 positioned on the desired reduced screen, the CPU 29 A command is sent to the front end 20 to receive a program of a channel that is linked to the reduced screen. This command is also sent by operating the numeric key 5 of the key group 701.
[0153]
As a result, the tuner 21 of the front end 20 adjusts the tuning frequency to the transmission channel of the commanded program, and outputs packet data of a plurality of programs included in the transmission channel to the multiplexer 24. The demultiplexer 24 separates a predetermined program packet from a plurality of program packets in response to a command from the CPU 29 and outputs the packet to the MPEG video decoder 25-1. The decoded data is processed by the NTSC encoder 27 and output to the monitor device 4 via the subsequent block. The monitor device 4 displays the data (program) output from the receiver 2 instead of the preview. Is done.
[0154]
That is, the viewer can view a desired program by operating the joystick 410 to move the cursor 201 to a desired reduced screen and vertically operating the joystick 410 at that position.
[0155]
Note that audio is attached to the program selection screen, and the multiplexer 24 separates the audio packet corresponding to the reduced screen on which the cursor 201 is located (the audio of the program corresponding to the reduced screen) to MPEG audio. The data is supplied to the decoder 26 and decoded. This allows the viewer to locate the cursor 201. Ru In addition to being able to see a full-motion reduced screen, it is also possible to listen to the audio accompanying the reduced screen simultaneously in real time.
[0156]
As described above, the eight-way operation of the joystick 410 for moving the cursor 201 and the vertical operation of the joystick 410 for confirming the selection of the program corresponding to the reduced screen on which the cursor 201 is subsequently performed are performed. As described with reference to FIG. 20 or FIG. 21, a series of operations (select operation) can be performed with only the thumb or index finger and without changing the remote commander 5, thereby improving operability. Is planned.
[0157]
The operation for selecting a desired program from the program selection screen has been described above. The general usage of the remote controller 5 is summarized as shown in the flowchart of FIG. In the embodiment of FIG. 29, the direction operation of the cursor 201 and the selection operation are performed using the key group 701 instead of the joystick 410.
[0158]
That is, first in step S1, the user determines whether to use the remote controller 5 as a telephone or as a remote commander for remotely controlling the receiver 2 (monitor device 4) as an electronic device. In the case of using as a remote commander, the process proceeds to step S2, and the preview button 404 is operated. At this time, in response to the signal from the remote controller 5, a DTMF signal corresponding to the preview button 404 is generated from the base unit 600 and transmitted to the modem 632. The modem 632 decodes this DTMF signal and outputs a predetermined code to the CPU 29. Then, the CPU 29 interprets the function assigned to this code, controls the tuner 21 in accordance with the interpretation, and receives and displays the program selection screen.
[0159]
Next, in step S3, the user operates one of the direction keys constituted by the numeric keys 2, 8, 4 or 6. Even when this operation is performed, a DTMF signal corresponding to the operated key is transmitted to the modem unit 631, and a code corresponding to the number 2, 8, 4 or 6 is input from the modem 632 to the CPU 29. The CPU 29 interprets the function corresponding to this code, and moves the cursor in the direction corresponding to the operated key according to the interpretation (cursor movement).
[0160]
After moving the cursor 201 onto the desired program (reduced screen), the user operates the YES key (number key 5) in step S4. Also at this time, a DTMF signal corresponding to the number 5 is transmitted to the modem unit 631, and a code corresponding to the number 5 is input from the modem 632 to the CPU 29. The CPU 29 interprets the function corresponding to this number 5 as the confirmation of the program. In accordance with this interpretation, the CPU 29 controls the tuner 21 to receive and display the designated program. Thereby, the program designated on the program selection screen is displayed on the monitor device 4 in full size.
[0161]
On the other hand, when using the remote controller 5 as a telephone, the user proceeds to step S10 when the determination is made in step S1, and first presses the TEL key. When the DTMF signal corresponding to the TEL key is input through the same processing as described above, the circumscribed telephone off-hook detection circuit 634 detects off-hook. At this time, the modem 632 sets the telephone mode, and thereafter processes numbers and symbols input as DTMF signals as input for telephone operation. Therefore, in this case, the modem 632 does not decode the input DTMF signal.
[0162]
Therefore, the user proceeds to step S11 and presses the numeric key to input a telephone number. The microcomputer 684 of the remote controller 5 controls the transmission circuit 682 to cause the base unit 600 to transmit a signal corresponding to the operated key.
[0163]
When receiving the input of this signal via the receiving circuit 654, the microcomputer 656 of the base unit 600 controls the DTMF encoder 652 to generate a DTMF signal corresponding to the operated numeric key. When a DTMF signal is input in the telephone mode, the modem 632 transmits the DTMF signal to the telephone line via the modular jack 635. That is, a line control operation is performed.
[0164]
The modem 632 closes the telephone line when the other party detects that the caller has responded to the call operation from the reversal of the polarity of the telephone line.
[0165]
As a result, the received voice transmitted from the other party via the telephone line is input to the base unit 600 via the external telephone off-hook detection circuit 634. The line interface 651 supplies the received voice to the transmission circuit 653 and transmits it to the remote controller 5 via the antenna 655.
[0166]
In the remote controller 5, the received voice is received by the receiving circuit 683 via the antenna 681 and output from the speaker 702.
[0167]
In addition, the transmitted voice input from the microphone 703 is transmitted from the transmission circuit 682 to the base unit 600 via the antenna 681.
[0168]
In the base unit 600, this transmission voice is received by the reception circuit 654 via the antenna 655 and output via the line interface 651. This transmitted voice is transmitted to the telephone line via the external telephone off-hook detection circuit 634. In this way, the call process in step S12 is executed.
[0169]
When a call signal is input from the other party via the telephone line, this call signal is input to the base unit 600. When this calling signal is input via the line interface 651, the receiving circuit 654 detects this and outputs a detection signal to the microcomputer 656.
[0170]
At this time, the microcomputer 656 controls the transmission circuit 653 to generate a ringer sound signal and output it from a speaker (not shown). This ringer sound signal is also transmitted from the transmission circuit 653 to the remote controller 5 via the antenna 655. In the remote controller 5, the ringer sound signal is received by the receiving circuit 683 and output from the speaker 702. Thereby, the user can know that there was an incoming call.
[0171]
Note that it is possible to prevent the ringer sound from being output from the remote controller 5 by performing a predetermined setting.
[0172]
When the user answers the incoming call, he operates the TEL key. At this time, the microcomputer 684 controls the transmission circuit 682 to generate a response signal.
[0173]
When receiving the response signal detection signal from the reception circuit 654, the microcomputer 656 of the base unit 600 controls the reception circuit 654 to generate an off-hook signal. This off-hook signal is detected by the external telephone off-hook detection circuit 634 of the modem unit 631 via the line interface 651. The modem 632 closes the telephone line when off-hook is detected. This enables a call.
[0174]
FIG. 30 shows the structure of the DTMF signal. As shown in the figure, a DTMF (Dual Tone Muliti Frequency) signal is assigned a mixed signal of two frequencies, a low group frequency and a high group frequency, corresponding to each key. As shown in FIG. 30, the low group frequency is either 697 Hz, 770 Hz, 852 Hz, or 941 Hz, and the high group frequency is either 1209 Hz, 1336 Hz, 1477 Hz, or 1633 Hz. These frequencies are assigned.
[0175]
For example, the numeric key 1 is assigned a low group frequency of 697 Hz and a high group frequency of 1209 Hz. The numeric key 2 is assigned a low group frequency of 697 Hz and a high group frequency of 1336 Hz.
[0176]
In FIG. 30, for example, a low group frequency of 697 Hz and a high group frequency of 1633 Hz are assigned to the TEL key shown in FIG. Further, for example, the frequency at the position indicated by the letters B, C, or D in FIG. 30 is assigned to the call button 402, the memory button 403, or the preview button 404 in FIG.
[0177]
Therefore, for example, when the numeric key 1 is operated, the DTMF encoder 652 outputs a signal obtained by mixing signals of two frequencies of 697 Hz and 1209 Hz as a DTMF signal. When the numeric key 2 is operated, a mixed signal of a signal having a frequency of 697 Hz and a signal having a frequency of 1336 Hz is generated as a DTMF signal.
[0178]
When the DTMF decoder 633 receives this DTMF signal, it generates a code corresponding to the corresponding numeral or symbol. For example, when a DTMF signal having a frequency of 697 Hz and 1336 Hz is detected, a code of number 2 is output.
[0179]
A signal other than the DTMF signal can be used to notify the receiver 2 of the key operation signal from the telephone set (base unit) 600. However, if it does so, it will be necessary to provide the detection circuit for exclusive use for it in the receiver 2, and it will become expensive. The modem 632 originally has a built-in DTMF decoder for interfacing with the telephone line, so that the configuration can be simplified and the cost can be reduced by using this as it is as in this embodiment. Can be reduced.
[0180]
FIG. 31 is a front view showing the configuration of another embodiment of the remote controller 5. The configuration of the remote controller 5 is basically the same as that described above, but in this embodiment, the lid 100 can be opened and closed with respect to the main body 405. 2 Is provided. When the lid 1002 is opened, the full keyboard 1001 of the main body 405 is exposed. Further, on the back side of the lid 1002, an LCD panel 1003 on which a transparent tablet (not shown) is overlaid and a card reader 1004 for reading information recorded on a credit card or the like are attached. The user can input information from a transparent tablet (not shown) superimposed on the LCD panel 1003 using a pen or the like.
[0181]
Also in this case, since the joystick 410 is disposed at the same position as in the case shown in FIG. 12, it is possible to easily perform remote control by operating the joystick 410 even in a call state.
[0182]
In the above, the DTMF signal generated by the base unit 600 is used. However, when the remote controller 5 includes a DTMF encoder, it is also possible to use the DTMF signal generated by the remote controller 5. .
[0183]
In addition, when the receiver 2 receives a signal from the video server 53 via a cable network (not shown) and can receive provision of a so-called video on demand service, By operating the remote controller 5, the screen can be rewound. That is, for example, when a video-on-demand program (full-size screen) is currently displayed on the monitor device 4, a rewind key (number key 4) and a fast-forward key (number key 6) Alternatively, by operating the pause key (numeric key 5), the screen of the currently received program can be returned in the reverse direction, advanced, or paused.
[0184]
That is, when these keys are operated, a corresponding DTMF signal is generated, a DTMF signal corresponding to the number 4, 6 or 5 is transmitted to the modem unit 631, and the modem 632 corresponds to the number 4, 6 or 5. A code is input to the CPU 29.
[0185]
The CPU 29 interprets these codes and supplies a signal requesting rewind, fast forward or pause corresponding to the operation of these keys to the video server 53 via the cable network. When the video server 53 receives this signal, the video server 53 changes the program transmitted to the receiver 2 via the cable network to a screen that goes back in time or to a screen that advances in time. Or change to a still image screen. In other words, when the VCR is being reproduced, the same screen as when the magnetic tape is rewound, fast-forwarded or paused is transmitted. As a result, such a screen is displayed on the monitor device 4.
[0186]
Next, the operation of the receiver 2 when the operation mode is the browse mode will be described. When, for example, the joystick 410 of the remote controller 5 is continuously selected for a predetermined time (for example, 3 seconds) (when it is in a vertically operated state), the operation mode of the receiver 2 is the browse mode (automatic browsing). Mode), and the CPU 29 performs processing according to the flowchart shown in FIG.
[0187]
That is, when the joystick 410 is pushed (select operation is performed), an operation signal corresponding to the operation is input to the CPU 29 via the base unit 600 and the modem unit 631, and the CPU 29 performs the select operation of the joystick 410. When the corresponding operation signal is continuously received for a predetermined time, in step S21, the operation mode is set to the browse mode, and initial setting processing is performed.
[0188]
Here, for example, when the operation mode is the preview mode, when the joystick 410 is selected, a program is selected as described above. This is because the CPU 29 selects the joystick 410 from the remote controller 5. This is performed when the operation signal corresponding to the selection operation can be received only for a predetermined short time (for example, 1 second or less). Accordingly, as described above, when the joystick 410 is continuously selected for a certain long time (vertical operation), program selection and other processing are not performed.
[0189]
The browse mode can be activated by selecting the joystick 410 as described above continuously for a predetermined time, or by a software trigger caused by other specific operations. For example, a button or the like) may be provided on the remote controller 5 and operated by the operation.
[0190]
In the initial setting process of step S21, the CPU 29 instructs the front end 20 to receive the archive data transmission channel, thereby causing the front end 20 to supply the demultiplexer 24 with the archive data. Thereafter, the virtual screen is stored in the virtual frame memory 49 in the same manner as in the preview mode.
[0191]
Further, in step S21, the CPU 29 selects, for example, 3 × 3 reduced screens in the upper left part of the virtual screen shown by hatching in FIG. 33, for example, which is output to the monitor device 4 and displayed. Is done. That is, a preview is displayed (in this way, the preview displayed first when the operation mode is set to the browse mode is hereinafter referred to as an initial preview as appropriate). At this time, as described above, the CPU 29 also displays the cursor 201 at the position of the upper left reduced screen in the initial preview, for example.
[0192]
Thereafter, in step S22, the audio of the program corresponding to the reduced screen on which the cursor is positioned is reproduced as described above, and the process proceeds to step S23, where it is determined whether or not the joystick 410 has been selected. If it is determined in step S23 that the joystick 410 has not been selected, the process proceeds to step S24, where it is determined whether or not the joystick 410 has been operated (direction operation) in any of the eight directions described above. . If it is determined in step S24 that the direction of the joystick 410 has been operated, the process proceeds to step S28, the browse mode is canceled, and the process ends. That is, the operation mode of the receiver 2 is set to the operation mode before the browse mode is set. Therefore, when the user wants to exit the browse mode, the user can end the browse mode by operating the joystick 410 in the direction.
[0193]
If it is determined in step S24 that the joystick 410 has not been operated, the process proceeds to step S25 to determine whether or not the memory button 403 has been operated. If it is determined in step S25 that the memory button 403 has not been operated, the process proceeds to step S26, and the display of the cursor 201 is started on the reduced screen on which the cursor 201 is now positioned, and then a predetermined time T1. It is determined whether or not (for example, 10 seconds) has elapsed. If it is determined in step S26 that the predetermined time has not elapsed, the process returns to step S22.
[0194]
If it is determined in step S26 that the predetermined time has elapsed, the cursor 201 is moved to another reduced screen position, and the process returns to step S22. Therefore, in this case, in step S22, the audio of the program corresponding to the reduced screen to which the cursor 201 is moved is started.
[0195]
Therefore, if the remote controller 5 is not operated, the processes in steps S22 to S27 are repeatedly performed, whereby the cursor 201 moves while instructing the reduced screen displayed on the monitor device 4 in units of a predetermined time T1. It will be.
[0196]
Here, the cursor 201 can move the reduced screens constituting the virtual screen so as to point in an arbitrary order. That is, for example, as shown in FIG. 33, the cursor 201 can move the reduced screens constituting the virtual screen in order from left to right and from top to bottom.
[0197]
Furthermore, the cursor 201 can be moved as shown in FIG. 34, for example. That is, the cursor 201 is moved so that the 3 × 3 reduced screen constituting the initial preview displayed first after the transition to the browse mode is instructed in order from left to right and from top to bottom. Next, the 3 × 3 reduced screen located below the screen is displayed as a preview, and the cursor 201 is similarly moved. Hereinafter, a 3 × 3 reduced screen arranged at the lower left of the virtual screen, a 3 × 3 reduced screen arranged at the upper right, a 3 × 3 reduced screen arranged below the 3 × 3 reduced screen, and a 3 arranged below the 3 × 3 reduced screen. The cursor 201 is moved in the same manner for the × 3 reduced screen.
[0198]
The cursor 201 can also be moved on the virtual screen so as to perform a so-called zigzag scan.
[0199]
Returning to FIG. 32, if it is determined in step S23 that the joystick 410 has been selected, the process proceeds to step S29, where the full-motion screen linked with the reduced screen on which the cursor 201 is located is displayed as described above. Displayed in the same way as Thereafter, when a predetermined time T2 (however, the time T2 is sufficiently shorter than the above-described time T1 (for example, 1, 2 seconds, etc.) has passed, the process proceeds to step S30, the cursor 201 is moved on the virtual screen, The preview screen is displayed, and the process returns to step S22.
[0200]
Therefore, when the display of the monitor device 4 is in a state as shown in FIG. 35A, for example, when the joystick 410 is selected, full motion corresponding to the reduced screen on which the cursor 201 is positioned at that time. This screen (normal screen) is displayed on the entire monitor device 4 as shown in FIG. When the predetermined time T2 has elapsed, as shown in FIG. 35C, a preview screen with the cursor 201 moved is displayed on the next reduced screen, and audio corresponding to the reduced screen is output.
[0201]
As described above, the cursor 201 automatically moves to the next reduced screen every time the predetermined time T1 elapses. If it is troublesome to wait for the predetermined time T1, The user can immediately move the cursor 201 to the next reduced screen by selecting the joystick 410.
[0202]
In the embodiment shown in FIG. 35, the cursor 201 is moved in the order shown in FIG.
[0203]
In the above, when the joystick 410 is selected, a full motion screen corresponding to the reduced screen on which the cursor 201 is positioned is displayed, and then the cursor 201 is moved to the next reduced screen. However, the cursor 201 can be moved without displaying a full motion screen. However, when the joystick 410 is selected, it is preferable to move the cursor after displaying a full-motion screen or outputting other beep sounds, rather than only moving the cursor 201. 2, the user can better recognize that the joystick 410 has been selected.
[0204]
As described above, while the cursor 201 moves while the preview is displayed, the user can select a program he / she desires (for example, one to be set as one of program candidates to be watched later, When the cursor 201 is positioned on the reduced screen corresponding to a program to be displayed as an initial preview, the memory button 402 is operated. In this case, it is determined in step S25 in FIG. 32 that the memory button 402 has been operated, the process proceeds to step S31, and the memory processing shown in FIG. 36 is performed.
[0205]
That is, in step S41, the writing of data to the virtual screen is prohibited, whereby the preview is a still image. Here, the preview is set as a still image in this manner so that the user can recognize that the reduced screen on which the cursor 201 is located is stored when the memory button 402 is operated. This is for interface feedback, and the preview does not necessarily have to be a still image.
[0206]
Thereafter, the process proceeds to step S42, in which the reduced screen in which the cursor 201 is located in the preview made as a still image is an area secured in the virtual frame memory 49 separately from the area for storing the virtual screen (hereinafter, referred to as the “still image”). If necessary, it is copied to a mark frame). That is, a still image (still image) of a reduced screen on which the cursor 201 is positioned when the memory button 402 is operated is stored in the mark frame.
[0207]
Here, as shown in FIG. 37A, the mark frame is divided into, for example, a 3 × 3 matrix with an area that can store an image of 240 × 160 pixels similar to the reduced screen as one unit. Has been. When the memory button 402 is operated, the still image of the reduced screen on which the cursor 201 is positioned at that time is stored in the mark frame, for example, at the upper left, and each time the memory button 402 is operated, Sometimes the still image of the reduced screen on which the cursor 201 is located is stored sequentially from left to right and from top to bottom of the mark frame. That is, the mark frame stores a plurality of reduced screens arranged in a matrix.
[0208]
After the still image of the reduced screen is stored in the mark frame, the prohibition of writing data to the virtual screen is released, and the process proceeds to step S43, and the program ID, channel ID, and the like of the program corresponding to the reduced screen are required. The EPG data is read from the SRAM 36 and copied (registered) to a further area (hereinafter referred to as a mark list as appropriate) of the virtual frame memory 49 as shown in FIG. 37B, for example. Here, in FIG. 37B, the mark list is illustrated as a matrix area in the same manner as the mark frame so that the correspondence relationship with the mark frame can be easily understood. There is no need. However, it is necessary that the CPU 29 can recognize where the EPG data corresponding to the reduced screen stored in the mark frame is stored in the mark list.
[0209]
After registration of the mark list, the process proceeds to step S44, where the number of still images on the reduced screen stored in the mark frame (the number of EPG data stored in the mark list), that is, the number of programs is a predetermined reference number (this embodiment). In the example, for example, it is determined whether or not the number of still images that can be stored in the mark frame is 9 (= 3 × 3). If it is determined in step S44 that the number of still images (hereinafter referred to as still images) of the reduced screen stored in the mark frame is not a predetermined reference number, the memory processing is terminated, and step S22 ( Returning to FIG.
[0210]
On the other hand, if it is determined in step S44 that the number of still screens stored in the mark frame has reached the predetermined reference number, that is, in this embodiment, as shown in FIG. When nine still screens are stored, the process proceeds to step S45, where the mark frame data is read out and displayed on the monitor device 4 instead of the preview. That is, in this case, only a still screen of a program desired by the user is displayed in a 3 × 3 matrix (in this way, what is stored in the mark frame is referred to as a favorite as appropriate below. Called preview).
[0211]
As described above, after a favorite preview is displayed, when a predetermined time (for example, an arbitrary time that can be set by the user such as several seconds) has elapsed, the process proceeds to step S46, and the selection process shown in FIG. 39 is performed. . That is, first, in step S51, the cursor 201 is displayed at the position of, for example, the upper left still screen in the favorite preview in which the still screens are arranged in 3 × 3, and the process proceeds to step S52. The still screen on which 201 is located is made a corresponding reduced screen (moving image). That is, in this case, as shown in FIG. 40, the cursor 201 is positioned on the still picture on the upper right of the favorite preview, but the reduced screen corresponding to the still picture is transferred from the virtual screen.
[0212]
In step S52, the audio of the program corresponding to the reduced screen is also output.
[0213]
Thereafter, the process proceeds to step S53, where it is determined whether or not the joystick 410 has been selected. If it is determined that the joystick 410 has not been operated, the process proceeds to step S54, where it is determined whether or not the joystick 410 has been operated. If it is determined in step S54 that the joystick 410 has not been operated, the process returns to step S53. If it is determined in step S54 that the direction of the joystick 410 has been operated, the process proceeds to step S55, and the cursor 201 is moved to the still screen displayed in the direction in which the direction has been operated. Then, the process proceeds to step S56, and in the same manner as in step S52, the still screen on which the cursor 201 is positioned is changed to a reduced screen (moving image) corresponding thereto, and the audio of the program corresponding to the reduced screen is further reproduced. Then, the process returns to step S53.
[0214]
If the screen on which the cursor 201 has moved is not a still screen but has already been reduced (moving image) in step S52 or S56, the process in step S56 is skipped.
[0215]
Accordingly, when the cursor 201 is moved so as to indicate all the 3 × 3 screens constituting the favorite preview, the favorite preview becomes all moving images.
[0216]
The user operates the joystick 410 in a direction to move the cursor 201 to a screen (reduction screen) that the user really wants to view and selects the joystick 410 at that position. In this case, it is determined in step S53 that the joystick 53 has been selected, and the process proceeds to step S57, where the full motion screen corresponding to the reduced screen on which the cursor 201 was positioned when the joystick 410 was selected is marked. By referring to the EPG data registered in the list, it is displayed as described above, and the process is terminated.
[0217]
When we read magazines, books, etc., we first take a rough look, put a bookmark or sticky note on a page with interesting descriptions, and later read the details of the page. I often take it. The method of selecting a program as described above uses such behavior as a metaphor. That is, the user selects several programs that he / she wants to watch as if he / she bookmarks them (channel marking), and later, he / she can easily and easily select a program that he / she really wants to watch. You can choose quickly.
[0218]
Furthermore, some conventional apparatuses sequentially receive and display all broadcast channels for a predetermined time (hereinafter, referred to as appropriate). In such apparatuses, the scan order is, for example, broadcast. It was supposed to be ascending order of channel or ascending order of carrier frequency. In the apparatus described in the present embodiment, the arrangement of the reduced screens constituting the virtual screen can be classified for each category as described above, or in the order of frequency of viewing. Alternatively, the cursor 201 can be moved in ascending order of the carrier frequency, the cursor 201 can be moved by category, or can be moved in the order of viewing frequency.
[0219]
Further, in this embodiment, in both the preview mode and the browse mode, the program can be selected by the same operation of moving the cursor 201 to the desired program position by the direction operation of the joystick 410 and then performing the select operation. In other words, since the user interface (operation of the joystick 410) when selecting a program is unified, a seamless operation environment can be provided.
[0220]
In this embodiment, 3 × 3 reduced screens are simultaneously displayed on the monitor device 4 for program selection. However, the number of reduced screens simultaneously displayed on the monitor device 4 is not limited to this. It is not limited. That is, the monitor device 4 can simultaneously display, for example, 4 × 4 reduced screens or 3 × 2 reduced screens corresponding to the resolution and the like (however, one reduced screen) Must be at least large enough to allow viewers to see and understand the content of the program).
[0221]
Furthermore, in the present embodiment, the receiver 2 and the monitor device 4 are independent devices, but the receiver 2 and the monitor device 4 can be configured integrally.
[0222]
In the present embodiment, as the data for selecting a program, a reduced screen that is a moving image, which is a reduced screen of a normal program, is transmitted. Still image or text data representing can be used.
[0223]
In this embodiment, the program selection data is transmitted. However, the program selection data can be generated on the viewer side, for example. That is, on the viewer side, it is possible to generate a reduced screen or data representing the contents of another program from the received normal program and use this as data for selecting a program.
[0224]
Furthermore, in this embodiment, it is possible to view all program selection data by scrolling the screen. However, in addition to this, all programs can be switched by switching the screen, for example, turning pages. It is also possible to view the data for selection.
[0225]
In this embodiment, the still image (still screen) of the reduced screen is stored in the mark frame. However, the reduced screen itself is stored in the mark frame by always transferring the reduced screen from the virtual screen. It is also possible to do so. However, in this case, since the reduced screen is a moving image, the screen when the user operates the joystick 410 is different from the screen when the favorite preview is displayed.
[0226]
Furthermore, in the present embodiment, a plurality of reduced screens are displayed at a time in the browse mode, but in addition, a full motion screen is displayed, for example, in the order of the channel or the frequency of the carrier. Is also possible.
[0227]
However, in Japan, for example, the VHF band and UHF band broadcast channels, and even the cable television broadcast channels, are about 10 channels at present. Even if the screens are sequentially displayed, it does not take much time to finish displaying all of them, but if the multi-channel broadcasting is progressed in the future, it will be much more difficult to display the full motion screens sequentially. It will take a long time.
[0228]
Therefore, as described in the embodiment, it is preferable to display a plurality of reduced screens at a time in the browse mode. Furthermore, in this case, the user can comprehensively check what programs are being broadcast on other channels.
[0229]
In this embodiment, a favorite preview is displayed when a predetermined number of still screens are stored in the mark frame. However, the favorite preview is displayed at any other timing (for example, a predetermined number of remote controllers 5). It is also possible to display a favorite preview when the operation is performed.
[0230]
Further, the EPG data stored in the mark list can be held until the mark list is initialized. In this case, when the power is turned on again, by referring to the mark list and transferring the reduced screen from the virtual screen to the mark frame, for example, displaying this as an initial preview, the user can In addition, it is possible to immediately select a desired program without selecting a program in the browse mode and registering it in a mark frame.
[0231]
Further, in this embodiment, the mark frame (same for the mark list) is configured so that a 3 × 3 still screen can be arranged, but the mark frame has other n × m configurations. It is also possible.
[0232]
Furthermore, in this embodiment, all the still screens stored in the mark frame are displayed at one time. However, for example, when many still screens are arranged in the mark frame, the same as in the preview mode. In addition, a part of the mark frame can be read and displayed.
[0233]
【The invention's effect】
As described above, according to the display control device and the display control method of the present invention, the storage means A virtual array image in which reduced screens obtained by reducing the screens of a plurality of programs are arranged in a predetermined number of matrixes is stored, and a plurality of reduced screens in a predetermined selection area are stored from the virtual array images stored in the storage means. A multi-screen consisting of multiple reduced screen Since it is displayed, even if the number of programs is large, it becomes possible to easily confirm and select the contents of the desired program.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating terms used in the present invention.
FIG. 2 is a diagram for explaining archive processing;
FIG. 3 is a diagram showing a configuration of an embodiment of a broadcasting system to which the present invention is applied.
FIG. 4 is a diagram showing how archive data is generated.
FIG. 5 is a diagram for explaining a method of arranging a reduced screen.
6 is a diagram showing a more detailed configuration of a part of the embodiment of FIG. 3; FIG.
FIG. 7 is a diagram for explaining a link established between normal program data and a reduced screen thereof.
8 is a block diagram illustrating a configuration example of an apparatus on the viewer side in FIG. 3;
FIG. 9 is a diagram for explaining a connection relationship of devices on the viewer side.
10 is a block diagram illustrating a detailed configuration example of the receiver 2 in FIG. 3;
11 is a block diagram illustrating a configuration example of a base unit 600. FIG.
FIG. 12 is a front view showing the configuration of the remote commander 5;
FIG. 13 is a side sectional view showing the configuration of the remote commander 5;
14 is a diagram showing a configuration of a microphone unit 703A shown in FIGS. 12 and 13. FIG.
FIG. 15 is a perspective view showing a state when the remote commander 5 is not used.
FIG. 16 is a perspective view showing a state when the remote commander 5 is in use.
17 is a diagram showing a state where the joystick 410 is attached to the main body 405. FIG.
18 is a perspective view showing a configuration example of a joystick 410. FIG.
FIG. 19 is a diagram illustrating an operation direction of the lever 162 in the horizontal plane.
FIG. 20 is a perspective view for explaining the operation of the joystick 410 when the remote commander 5 is held with the left hand.
FIG. 21 is a perspective view for explaining the operation of the joystick 410 when the remote commander 5 is held with the right hand.
22 is a block diagram showing an example of the internal configuration of the remote commander 5. FIG.
FIG. 23 is a diagram for explaining a part of the operation of the embodiment of FIG. 10;
FIG. 24 is a diagram illustrating a state where archive data is separated.
FIG. 25 is a diagram showing a state in which reduced screens are arranged and stored in a matrix in the virtual frame memory 49;
FIG. 26 is a diagram showing a range of a reduced screen displayed on the monitor device 4;
FIG. 27 is a diagram showing a state in which a reduced screen is displayed on the monitor device 4;
FIG. 28 is a diagram for explaining a reduced screen displayed on the monitor device 4 when the remote commander 5 is scrolled.
FIG. 29 is a flowchart for explaining the operation of the remote commander 5;
FIG. 30 is a diagram illustrating a DTMF signal.
31 is a diagram showing another configuration example of the remote commander 5. FIG.
FIG. 32 is a flowchart for explaining the operation of the receiver 2 when the operation mode is the browse mode.
FIG. 33 is a diagram for describing a direction in which a cursor 201 is moved in a browse mode.
FIG. 34 is a diagram for describing a direction in which a cursor 201 is moved in the browse mode.
35 is a diagram for describing a change in display on the monitor device 4 when it is determined in step S23 in FIG. 32 that the joystick 410 has been selected. FIG.
FIG. 36 is a flowchart for explaining details of the memory processing in step S31 of FIG. 32;
FIG. 37 is a diagram illustrating a mark frame and a mark list.
FIG. 38 is a diagram illustrating a state in which nine still screens are stored in a mark frame.
FIG. 39 is a flowchart for explaining details of the selection process in step S46 of FIG. 36;
FIG. 40 is a diagram for explaining the process of step S52 of FIG. 39;
[Explanation of symbols]
2 receivers
2a Receiver
2b Processing device
2c storage device
3 Parabolic antenna
4 Monitor device
5 Remote Commander
20 Front end
21 tuner
22 QPSK demodulation circuit
23 Error correction circuit
24 Demultiplexer
25 Multi-channel real-time decoder
26 MPEG audio decoder
27 NTSC encoder
29 CPU
35 Data buffer memory
36 SRAM
37 ROM
38 EEPROM
49 Virtual frame memory
51 Digitization section
52 Archive Department
53 Video server
54 Transmitter
201 cursor
402 Call button
403 Memory button
404 Clear button
410 Joystick

Claims (7)

A display control device for controlling display of programs of a plurality of broadcast channels in a display means for displaying information,
Receiving means for receiving a signal including programs of the plurality of broadcast channels;
Output means for outputting and displaying the program received by the receiving means on the display means;
Storage means for storing virtual array images in which reduced screens obtained by reducing the screens of the plurality of programs are arrayed in a predetermined number of matrices from the signal received by the receiving means;
From the virtual array images arranged in a matrix of the predetermined number stored in the storage means, a plurality of reduced screens of a predetermined selection area having a number smaller than the predetermined number are selected and read out, and the plurality of reduced screens Reading means for causing the display means to display a multi-screen comprising :
Cursor display control means for causing the display means to display a cursor for instructing the reduced screen;
Cursor moving means operated when moving the cursor to the next reduced screen;
Further comprising
When the cursor is moved to the top, bottom, left and right edges of the multi-screen, and the direction operation by the cursor moving means is performed,
The reading means moves the selection area according to the direction operation, reads a plurality of reduced images of the selection area newly selected from the virtual array image, and reads the plurality of reduced images from the reduced images. To display on the display means
A display control device characterized by that . The display control apparatus according to claim 1, further comprising the display unit. In the state where the multi-screen is displayed on the display unit, the display unit further includes a program designating unit operated when designating a predetermined program designated by the cursor from the multi-screen,
The cursor moves while instructing each of a plurality of reduced screens constituting the multi-screen displayed on the display unit by a predetermined time unit under the control of the cursor display control unit,
The storage means further stores EPG (Electrical Program Guide) data of a program corresponding to the reduced screen indicated by the cursor when the program specifying means is operated. the display control device according to 1. The display control apparatus according to claim 3 , wherein the cursor moving unit is operated when the cursor is moved to the next reduced screen before the predetermined time elapses. The display control apparatus according to claim 3 , wherein the storage unit further stores a still image of the reduced screen specified by operating the program specifying unit. The display control apparatus according to claim 1, further comprising: a reception designation unit that is operated when causing the reception unit to receive a program. In a display control method for controlling display of a program of a plurality of broadcast channels in a display means for displaying information,
Receiving a signal including programs of the plurality of broadcast channels;
Outputting and displaying the received program on the display means;
From the received signal, a virtual array image in which a reduced screen obtained by reducing each of the screens of the plurality of programs is arranged in a predetermined number of matrix shapes is stored in the storage means,
From the virtual array images arranged in a matrix of the predetermined number stored in the storage means, a plurality of reduced screens of a predetermined selection area smaller than the predetermined number are selected and read out, and the reduced screens the multi-screen consisting of is displayed on the display means,
A cursor for indicating the reduced screen is displayed on the display means;
When a direction operation for moving the cursor is performed in a state where the cursor is moved to the top, bottom, left and right edges of the multi-screen,
The selected area is moved according to the direction operation, and a plurality of reduced images of the newly selected selection area are read from the virtual array image, and a multi-screen including the plurality of reduced images is displayed. A display control method characterized by displaying on a display means .

Images