JP3791606B2 - Broadcast receiving apparatus and broadcast receiving method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a broadcast receiving apparatus and a broadcast receiving method that enable a receiver to watch a program that is frequently viewed without being overlooked in a television receiver or a radio receiver, for example.
[0002]
[Prior art]
When viewing a broadcast program with a television receiver or radio receiver, the user tends to view the same program every week for a specific time. In particular, in the case of a continuous program or a favorite program, at the same time on the same day, in many cases, the same program-compatible channel is always selected to view the program.
[0003]
Here, in this specification, a program-compatible channel indicates a channel number assigned to a broadcasting station, and is distinguished from a transmission channel assigned a number for each frequency band obtained by dividing a transmission band of a broadcast wave. . Incidentally, in the current terrestrial television broadcasting in Japan, the number of the transmission channel and the number of the channel corresponding to the program are often the same.
[0004]
By the way, when a user is watching a broadcast program on a television receiver or radio receiver, he / she watches it weekly, for example, forgetting the passage of time or continuing to select a channel corresponding to another program. There are cases where a broadcast program (hereinafter, a broadcast program that is frequently viewed is referred to as a high-frequency viewing program, and a program-compatible channel of the high-frequency viewing program is referred to as a high-frequency viewing channel) may be overlooked.
[0005]
In view of this point, the present applicant has provided channel selection information storage means for sequentially storing program-corresponding channels selected by the tuner at the day of the week and time, using the day of the week and time as parameters, and the storage of this storage means. The frequency of each program-compatible channel selected by the tuner is accumulated from the contents to determine whether or not it is a high-frequency viewing channel, and the high-frequency viewing channel at the same day of the week as the current time When there is a discrepancy with the program-compatible channel that you are currently watching, that is, when you are not watching a broadcast program that you are often watching at that time, the advice information is output by screen or sound, A receiving apparatus has been proposed first to alert the viewer.
[0006]
In the previous proposal, the above-mentioned alert is issued by voice output so that the user can obtain this advice information even when the power switch of the television receiver is off.
[0007]
[Problems to be solved by the invention]
However, as described above, even if the advice information is provided from the television receiver or the radio receiver to the user, the user may miss or hear the advice information. In this case, when the user sees the advice information again, the program that he / she has already watched has already started, for example, he missed the first part of the reasoning drama, and the story line is not understood. There is a problem of being fooled.
[0008]
Further, when the user is absent, even if there is the advice information as described above, this does not mean anything, and the user must give up watching the program that he / she is always watching.
[0009]
Therefore, it is conceivable to use a recording / playback apparatus such as a VTR to perform scheduled recording of the program of the high-frequency viewing channel. However, in general, many users recognize that the scheduled recording operation is complicated and operation mistakes, etc. In consideration of this, it is impossible to expect a situation in which the user always uses the reserved recording function.
[0010]
In view of the above points, the present invention includes a case where a frequently watched program preferred by the user is present and a program corresponding channel of the program is not currently viewed (including a case where the power switch is turned off). In addition, the present invention intends to provide a broadcast receiving apparatus that allows the user to surely view the frequently viewed program.
[0011]
[Means for Solving the Problems]
In order to solve the above problems, a broadcast receiving apparatus according to the present invention provides:
Channel selection means for selecting a desired program signal from the broadcast wave according to the channel selection control signal;
Channel selection control signal generating means for generating the channel selection control signal in response to a user channel selection operation;
It stores information about program viewing frequency , Sequentially update to the new information of the viewing frequency Storage means;
A determination unit that examines the storage content of the storage unit and determines whether or not a high-frequency viewing program exists;
A disc-shaped recording medium;
When the presence of the high frequency viewing program is detected by the determination unit, the channel selection control signal is generated so that the channel selection unit selects a signal of the high frequency viewing program, and the high frequency viewing is generated. The program signal is controlled so as to be recorded on the disc-shaped recording medium, and when the free area of the disc-shaped recording medium is not sufficient, the storage content of the storage means is examined and the viewing frequency of the program to be recorded And the viewing frequency of the recorded program on the disc-shaped recording medium, and according to the comparison result, the signal of the program to be recorded is overwritten and recorded on the signal of the recorded program Control means for controlling whether or not,
It is characterized by providing.
[0012]
According to this invention comprised as mentioned above, the presence or absence of the program which a user likes is determined from the content of the memory | storage information of a memory | storage means. When it is determined that there is a program that the user likes, the program is controlled so as to be received and automatically recorded on the disk-shaped recording medium. Therefore, the user can surely view the recorded program by playing it at a later time.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a broadcast receiving apparatus according to the present invention will be described below with reference to the drawings, taking as an example a television receiver for receiving analog television broadcast waves using terrestrial waves.
[0014]
FIG. 1 is a block diagram of the television receiver of this embodiment. The television receiver of this example has a so-called picture-in-picture (PinP) function capable of displaying a small screen in a partial small area of the display screen, and has a built-in recording / playback device unit, A so-called back program can be recorded. For this reason, the television receiver of this example has a so-called double tuner configuration having two tuners. However, one of the tuners is used to display an image on a PinP sub-screen and as a recording source. Therefore, it does not have a PinP parent / child screen switching function.
[0015]
In the following description, PinP and the signal system for recording will be described as sub, and the others will be described as main signal systems.
[0016]
In FIG. 1, 1M is a main tuner, and 1S is a sub-tuner. Broadcast radio waves received by the antenna are distributed and supplied to the main tuners 1M and 1S. In these tuners 1M and 1S, a channel corresponding to a predetermined program is selected by a channel selection control signal from a control circuit 100 constituted by a microcomputer to be described later. In this case, the channel selection control signal is generated by the control circuit 100 in response to a selection operation through the user's remote commander or the like, in the case of automatic recording of a high-frequency reception program described later, or PinP of the high-frequency reception program. In some cases, the control circuit 100 itself generates the data regardless of the user's selection operation, such as for displaying a small screen of the user.
[0017]
These tuners 1M and 1S convert the selected broadcast wave signals into video intermediate frequency signals and supply them to video intermediate frequency and detection circuits 2M and 2S, respectively. In these circuits 2M and 2S, the intermediate frequency signal is amplified and the video signal and the audio signal are demodulated.
[0018]
The demodulated video signal from the video intermediate frequency and detection circuit 2M is supplied to one input terminal TV of the switch circuit SW1, and the demodulated audio signal is supplied to one input terminal TV of the switch circuit SW3. .
[0019]
The demodulated video signal from the video intermediate frequency and detection circuit 2S is supplied as a recording source to the recording / reproducing apparatus unit 10 and also supplied to one input terminal S of the switch circuit SW2. The demodulated audio signal from the video intermediate frequency and detection circuit 2S is supplied only to the recording / playback apparatus unit 10. This is because the sound of the sub-screen displayed as PinP is generally not reproduced.
[0020]
Then, the playback video signal from the recording / playback apparatus unit 10 is supplied to the other input terminal VT of the switch circuit SW1 and the other input terminal VT of the switch circuit SW2. Further, the playback audio signal from the recording / playback apparatus unit 10 is supplied to the other input terminal VT of the switch circuit SW3.
[0021]
The switch circuits SW1, SW2, and SW3 are switched by a switching signal from the control circuit 100. The switch circuit SW1 and the switch circuit SW3 are switching circuits for selecting a signal from the main tuner 1M or a playback signal from the recording / playback apparatus unit 10, and switching signals for these circuits SW1 and SW3 are common. is there.
[0022]
That is, when the user wants to watch a broadcast program selected by the main tuner 1M and performs a selection operation using a remote controller to be described later, the switch circuits SW1 and SW3 are switched to one input terminal TV side, and the recording / playback apparatus When the user performs a selection operation to view the reproduced video signal and audio signal with the unit 10 in the reproduction mode, the switch circuits SW1 and SW3 are switched to the other input terminal VT side.
[0023]
The switch circuit SW2 is a switching circuit for selecting a video signal of a program selected by the sub-tuner 1S as a PinP child screen, or selecting a playback video signal of the recording / playback apparatus unit 10. Is switched to one input terminal S side when selecting a sub-tuned PinP sub-screen, and switched to the other input terminal VT side when viewing the playback video screen of the recording / playback apparatus unit 10. It is done.
[0024]
The video signal obtained from the switch circuit SW1 is supplied to the PinP synthesis circuit 4 through the video signal processing circuit 3M. The video signal obtained from the switch circuit SW2 is supplied to the PinP synthesis circuit 4 through the video signal processing circuit 3S. The video signal processing circuit 3S performs a process of compressing the image size of the input video signal so that it is displayed as a PinP child screen.
[0025]
When the PinP display is performed from the control circuit 100, the control signal is supplied to the PinP synthesis circuit 4 and the video signal from the video signal processing circuit 3S is synthesized so as to be superimposed as a child screen. . When the PinP display is not performed, the PinP synthesis circuit 4 outputs the video signal from the video signal processing circuit 3M as it is.
[0026]
The video signal from the PinP synthesis circuit 4 is supplied to the superimposed display processing circuit 5. The superimposed display processing circuit 5 is supplied with signals such as characters and graphics, which will be described later, and the superimposed display processing circuit 5 performs processing such that the superimposed display processing circuit 5 superimposes and displays warning symbols. This is appropriately performed according to a control signal supplied from the control circuit 100. The signal to be superimposed is generated in accordance with the control of the control circuit 100 as will be described later. In this example, the video signal from the superimposing display processing circuit 5 is supplied to the CRT display 6, and the image of the broadcast program received by the tuners 1 </ b> M and 1 </ b> S on the screen and the image based on the playback signal of the recording / playback device unit 10. Is displayed in color.
[0027]
Also, the audio signal obtained from the switch circuit SW3 is supplied to the audio amplifier 8 via the audio processing circuit 7 and reproduced by the speaker 9. In this example, in response to a control signal from the control circuit 100, the amplifier 8 performs volume control and sound quality control of reproduced sound.
[0028]
In this example, the recording / reproducing apparatus unit 10 is realized by a configuration equivalent to a video tape recorder using a magnetic tape such as 8 mm video as a recording medium, and the configuration thereof is well known and will be omitted.
[0029]
Next, the control circuit 100 will be described. When the so-called main power switch is turned on while the TV receiver of this example is connected to an AC outlet, the remote commander can turn the power on and off, and the main power switch is turned on. In the state, the control circuit 100 is always in an operating state.
[0030]
As described above, the control circuit 100 includes a microcomputer, and the CPU 101, the ROM 103, the DRAM 104, and the SRAM 105 are connected to the system bus 102. In addition, I / O ports 111 to 117 are connected to the system bus 102 so that various signals are input and output.
[0031]
For example, a tuning control signal is supplied to the main tuner 1M and the sub tuner 1S via the I / O port 111. In addition, the control circuit 100 supplies the recording / playback device unit 10 with recording start, playback start, stop, and other control commands via the I / O port 112, or from the recording / playback device unit 10 A mode state signal is taken into the control circuit 100 via the I / O port 112. Switching control signals to the switch circuits SW1, SW2, and SW3 are supplied from the I / O port 113.
[0032]
Reference numeral 11 denotes a clock circuit. The clock circuit 11 records the current time. In this example, the clock circuit 11 serves as a timer for generating an interrupt timing signal when the ROM 303 program is activated by an interrupt, as will be described later. It is what. The clock circuit 11 is supplied with a power supply voltage even when the power switch of the television receiver is off. In this example, although not shown, the clock circuit 11 is supplied with a power supply voltage from another power source such as a battery or a rechargeable battery. Time information and timer information from the clock circuit 11 are taken into the system bus 102 via the I / O port 114.
[0033]
Further, the time of the clock circuit 11 is corrected by the execution of the program by the CPU 101. The clock circuit 11 has not only the hour, minute, and second but also the year, month, day, and day of the week as information. However, in the case of this embodiment, as long as there is information on the day of the week and the time, it is sufficient as a time parameter to be associated with channel history information described later.
[0034]
In this specification, the channel history information is information on the selection status of a program-compatible channel of the tuner 1M stored in a memory (SRAM 105 to be described later) in association with the day of the week and the time (that is, for example, past data). Information on how many channels were selected by the tuner 1M at a certain time on a certain day of the week), and in this example, information for a plurality of weeks.
[0035]
A control signal is supplied to the PinP synthesis circuit 4 and the amplifier 8 via the I / O port 115.
[0036]
Further, a work signal indicating whether or not to perform superimposed display is supplied to the superimposed display processing unit 5 via the I / O port 116. Examples of this overlay display include a channel number indicating how many channels have been switched when switching channels, a display of the current reception channel, and a bar display indicating how much the volume has increased. A message display as described later can be given.
[0037]
For this superimposed display, a video RAM 12 is connected to the system bus 102. The video RAM 12 temporarily stores character information, symbol information, and the like formed by the control circuit 100 using the character information recorded in the ROM 103, and the program control of the CPU 101 for superimposing display on the screen. Accordingly, the image is supplied to the superimposed display processing device 5 via the display controller 13.
[0038]
In this case, the font data and image data of characters and symbols necessary for superimposed display are stored in the ROM 103, and the font data and image data of necessary characters and symbols are read out by the CPU 101 according to the program. The image data in the video RAM is combined with the video signal by being transferred to an arbitrary address in the RAM 12 and supplied to the superimposed display processing unit via the display controller 13, and is displayed on the screen of the CRT display 6 over an appropriate time. Will be displayed.
[0039]
As the superimposed display, an overlay process such as so-called superimpose is performed and displayed on the CRT display 6.
[0040]
In the television receiver of this example, various controls are performed by the remote commander 14 in a so-called wireless manner. When a remote control signal by, for example, infrared rays is generated from the remote commander 14, this is transmitted to the television receiver side. The remote control signal receiving / decoding unit 15 receives the received light, decodes the received remote control signal, and supplies the decoded signal to the system bus 102 via the I / O port 117.
[0041]
The CPU 101 interprets the remote control signal taken in via the I / O port 117, selects a channel corresponding to the program, volume control, PinP composition control, superimposition display control, switch SW1 to SW3 switching control, recording / playback apparatus The mode control of the unit 10 is performed.
[0042]
The DRAM 104 is mainly used as a work area for operations and the like. The SRAM 105 is used as a last memory function for channel and volume when the power switch is turned on and off, and as a recording area for holding channel history information described later. In this example, the SRAM 105 has a non-volatile memory configuration that is a so-called battery power backup. Therefore, even when the television receiver is turned off, the contents of the SRAM 105 are backed up and will not disappear.
[0043]
[First Embodiment of Channel History Information Creation Processing]
In this example, the channel history information samples the channel selection state of the main tuner IM at regular intervals, and the channel corresponding to the channel selection program at that time is written and stored in the SRAM 105.
[0044]
In the case of this embodiment, processing for searching the channel selection state of the program-compatible channel is performed on the main tuner 1M as interrupt processing at regular intervals based on the timer information from the clock circuit 11, and the tuner 1M at that time is searched. The channel selection state of the program corresponding channel is stored in the SRAM 105.
[0045]
In the channel history information creation method of this example, since the CPU 101 is interrupted at regular intervals, if only the starting time is known as absolute time information, the time at each sampling point can be known as the time elapsed thereafter. Therefore, it is not necessary to store the time information at each sampling time in the SRAM 105 as it is.
[0046]
FIG. 2 and FIG. 3 show an image diagram of the channel history information management method in this case. The memory area of the channel history information in the SRAM 105 is imaged. 2A, 2B and 3, the position indicated by the arrow is the position of the pointer P. This pointer P indicates the memory area at which the current point in time. As shown in FIG. 3, the memory area of the SRAM 105 is managed as a channel history data as a ring history as shown in FIG. Is.
[0047]
In this example, channel history information for n weeks (n is an integer of 2 or more) weeks before the current time is always stored in the SRAM 105, and new information is sequentially added while discarding information older than n weeks ago. Channel history information is sequentially accumulated.
[0048]
In other words, in this example, for example, the tuner 1M is scanned every 10 minutes to acquire the channel history, and the obtained channel history information is continuous at 10-minute intervals as shown in FIG. Managed by the address space. Then, when the storage area of the ring structure as shown in FIG. 3 is full, as shown in FIG. 2B, the oldest channel history data is discarded and the newly acquired current channel history data is stored in the memory. Take a memory method like you do.
[0049]
In this case, the channel history data stored in the SRAM 105 is stored for at least a plurality of weeks as described above. The CPU 101 can manage the channel history data of the SRAM 105 for each day of the week. This is because if it is an interval of 10 minutes, 144 times that is for one day and 7 times that for one week, it can be managed simply by counting the number of channel history data. is there.
[0050]
In this case, the acquisition of the channel history data by the interrupt processing described above is the time when the program actually started, such as XX hour 01 minute, XX hour 11 minute, XX hour 21 minute, XX hour 31 minute, etc. Will be launched.
[0051]
Prior to storing the channel history data in the channel history data storage area of the SRAM 105, this area is initialized. In other words, it is cleared. At the same time, the pointer position for history storage is also initialized. The past history information is cleared by this initialization, and this initialization setting is performed by, for example, allocating remote control data and program broadcast channels and registering the current time in the clock circuit 11 in a television receiver. It is performed at the opportunity.
[0052]
Here, the assignment of the remote control button and the program broadcast channel is, for example, an operation in which the user assigns a specific channel of the remote control button to one of the program-compatible channels (broadcast stations). Generally, this channel setting or the like is performed at the time of purchase of the television receiver, but may be performed by the user as appropriate.
[0053]
In this example, the remote commander 14 is provided with a channel history reset button. By pressing this reset button, the contents of the channel history area of the SRAM 105 can be initialized as described above. . In general, for example, in the case of Japanese television broadcasting, the program content has been changed by being reset by the user at the time of program change, taking into account that the content of the program changes significantly between spring and autumn. Nevertheless, it is intended to prevent the user from being erroneously selected as a high-frequency viewing channel by the user based on past history.
[0054]
Next, the channel history recording operation in this example will be described with reference to the flowchart of FIG.
That is, in the case of this example, when an interruption occurs every 10 minutes that is considered to be actually broadcast as described above (step S0), this channel history data capturing process routine is started.
[0055]
In the next step S1, the pointer is updated in the channel history memory space of the SRAM 105. This update of the pointer secures a new data area, and in this step S1, a process of null-clearing (setting 0) the newly secured data area is simultaneously performed. In the case of this example, the channel history memory area of the SRAM 105 is managed in a ring shape as described above. Therefore, after the ring-shaped channel history data area is full, pointer update processing is performed. Will involve discarding the oldest channel history data.
[0056]
In this case, if the address of the new data area by updating the pointer exceeds the final address of the ring-shaped memory area, the pointer is reset to the head address.
[0057]
In this case, while the main power switch of the television receiver is on, the activation is performed every 10 minutes through the step S0 in this example, while the main power switch of the television receiver is off. The interrupt processing to the processing routine of FIG. 4 is not activated. Therefore, in this example, since the clock circuit 11 operates with a separate power supply, the time information is used to turn off the main power supply at the first interrupt timing after the next main power supply turn-on. An update process of the channel history area, which should be performed for a while, is performed.
[0058]
In other words, in this example, the SRAM 105 holds the time of the interrupt timing performed immediately before the main power switch is turned off. After that, when the main power switch of the television receiver is turned on and the interrupt timing is reached, the interrupt timing time performed immediately before the main power switch of the SRAM 105 is turned off is referred to during that time. The number of interrupts to be performed is detected, the pointer is updated for the number of interrupts, and all the data areas for the number of updated data are null-cleared. Then, the data area corresponding to the current interrupt timing is updated.
[0059]
When the pointer is updated and a new data area is secured in this way, the process proceeds to step S2 to check whether or not the broadcast is currently being viewed. That is, when the recording / reproducing apparatus unit 10 is in the reproduction mode and is being viewed, the television is not viewed here.
[0060]
If a broadcast wave is being viewed, the process proceeds from step S2 to step S3, and information on the program-corresponding channel selected by the tuner 1M at that time is stored in a newly secured data area. The information content of the program-corresponding channel to be stored may be a channel number or channel selection control data supplied to the tuner 1M.
[0061]
On the other hand, if it is determined in step S2 that the broadcast wave is not being viewed, the process proceeds to step S4, where “0” is set in the newly secured data area. In this example, even when the main power is not turned on by the processing during the main power-off of the television receiver in the above-described step S1, the data area of the channel history is similarly set to “ “0” is held, and this state is also a state in which the television broadcast is not viewed.
[0062]
After finishing the process of step S3 or step S4, this routine is complete | finished from step S5.
[0063]
Thus, in this example, in the channel history area for a plurality of weeks of the SRAM 105, the information on the program-corresponding channel of the broadcast wave being viewed at that time is left as a new history every 10 minutes. As described above, when the channel history area for a plurality of weeks is full, new channel history information is sequentially written while discarding the old history.
[0064]
FIG. 5 shows an example of channel history information for one day, and FIG. 6 shows an example of channel history information for three weeks in the form of a table. Each channel history data area Dch includes: In this example, program-corresponding channel number information is stored. Note that the time shown on the left side of the data area Dch is the fetch time of each channel history data. In this example, these times need to be stored in the data area Dch as described above. Absent.
[0065]
In this example, when referring to the channel history information to determine the presence or absence of a high-frequency viewing channel, which will be described later, it is determined that the probability of watching the channel is high before and after the time when the channel history information is captured. I have to. The interval before and after the channel history data capture time is, for example, ± 5 minutes if the channel history data is captured at the aforementioned 10 minute intervals.
[0066]
In this embodiment, since the channel history is updated every 10 minutes, 6 × 24 = 144 history data are stored in one day. Therefore, 144 × 7 = 1008 history data is recorded in one week. In this case, if one channel history data is 1 byte long, it becomes 1008 bytes per week. As described above, since it is necessary to collect history for a plurality of weeks, a memory area for an integer multiple of 1008 bytes is set as a channel history area in the SRAM 105.
[0067]
As described above, in this example, the channel history data table is as shown in FIGS. 5 and 6, and the number of history data per day and week is fixed. If a data area having a relative time relationship such as one week ago and two weeks ago is known, channel history data at the same time in the past can be easily obtained. Therefore, the channel history information stored in the SRAM 105 does not need information on the absolute time of the fetch time of each history data as described above. However, the clock circuit 11 needs to have an absolute time set. This is because when checking whether or not there is a high frequency viewing channel, the channel history information table is referenced with reference to the time indicated by the clock circuit 11 in the channel history.
[0068]
Therefore, when the current time of the clock circuit 11 is set again, the interrupt timer information is obtained from the clock circuit 11, and the channel history memory (channel history table) and its pointer are described above. Is initialized.
[0069]
In the above example, since the pointer is updated by a certain amount as time passes, as described above, while the main power of the television receiver is off, the pointer is updated and the data area is null-cleared. Will be repeated. Therefore, when the main power switch of the television receiver is turned off, the number of interrupts that should be performed during the main power off at the next main power on is detected, and the data recorded in the channel history memory area is the number of times It is also possible to save a memory area by recording a code representing the continuation of minute null data, for example, [FF **] (** represents the number of null data) in hexadecimal display.
[0070]
In the above example, the channel history information is fetched at intervals of 10 minutes, but may be every 15 minutes or every 30 minutes, and when the memory area of the channel history information is sufficiently large, It may be every 1 minute or every 5 minutes. However, since the broadcast time of the program is in units of 30 minutes or 60 minutes, when the channel history information is periodically fetched as in this example, a unit deviation such as every 8 minutes or every 9 minutes occurs. It is better not to have such timing.
[0071]
In addition, channel history information is not always captured at regular time intervals. In general, channel history information is captured in a fine period during the time period called prime time, which has a high audience rating, and other periods are coarse. You may make it take in.
[0072]
[Processing of High Frequency Viewing Channel in the First Embodiment]
Next, processing relating to a high frequency viewing program using channel history information in the case of the first embodiment will be described.
[0073]
In this case, the past channel history is checked at a timing different from the above-described channel history data capturing process timing, and it is checked whether or not there is a program-compatible channel that is frequently viewed. Here, the different timing means that the above-described channel history data import processing timing is preferably started at the time when the program actually starts, whereas the past history is examined and appropriate processing is performed. When it is performed, it is because it is better to start the program at the time when it actually starts or just before that.
[0074]
That is, the above-described channel history data capture is started at the time when the program actually starts, such as XX hour 01 minute, XX hour 11 minute, XX hour 21 minute, XX hour 31 minute, and the like. . On the other hand, the following processing using the past history is as follows: XX hour 00 minutes, XX hour 10 minutes, XX hour 20 minutes, XX hour 30 minutes, XX hour 29 minutes, XX hour 59 The program is started at the timing when the program starts or the timing immediately before or after the preferred recording starts.
[0075]
In addition, in this example, even if there is a program-compatible channel that has been viewed frequently in the past, when recording by reserved recording is performed, or when waiting for a reserved time by recording reservation is in progress Gives priority to the reserved program. Therefore, in this example, since the recording / reproducing apparatus unit 10 is a VTR unit using a magnetic tape as a recording medium, the processing described below is not started when a recording reservation is made. After the scheduled recording content is completed, the user restarts, and the content recorded by the scheduled recording is automatically recorded as described later (when there is a high frequency viewing channel, it is automatically recorded). It is considered so that it will not disappear due to overwriting by the same).
[0076]
Further, this process is not started even when there is no free space that can be recorded on the recording medium set in the recording / reproducing apparatus unit 10.
[0077]
Next, a process of counting past histories using channel history data and performing automatic recording will be described with reference to the flowchart of FIG.
[0078]
First, as described above, when an interrupt with a certain period is applied at a timing different from the channel history capturing timing (step S10), this processing routine is started.
[0079]
In step S11, the past channel history of the current time, the same day of the week, and the same time is checked with reference to the channel history data table of the SRAM 105. Then, information on whether there is a program-corresponding channel (high frequency viewing channel) that is always viewed at that time and how many channels are corresponding to the program is extracted.
[0080]
In this case, whether or not there is a high frequency viewing channel is determined based on whether or not a threshold value having a preset frequency is exceeded. In other words, the high frequency viewing channel means a channel that is watched over a predetermined percentage including the state where the TV receiver is turned on and the state where it is not turned on. We try to eliminate the effects as much as possible. That is, in the case of this example, if the TV power is off at that time and the user has not watched the broadcast, it is set to 0, but this is also the data for calculating the number of viewing frequencies.
[0081]
For example, if you want to save your channel history for the past three weeks, if there is a channel that has been viewed for two consecutive weeks, it will be judged as a high-frequency viewing channel, and you will not normally watch TV However, even if there is a history of selecting a channel even once, it is not always the channel that you are watching.
[0082]
In this way, in determining the high frequency viewing channel from the past history, the size of the memory area of the channel history information set in the SRAM 105 is set so as not to exceed the program change period of the broadcasting station. Is more convenient. For example, since a Japanese broadcasting station divides a year into four courses and organizes the program every time, it is better to capture a history of up to three months into the SRAM 105 as past information.
[0083]
Next, the process proceeds from step S11 to step S12, and it is checked whether or not automatic recording has already been performed in the recording / playback apparatus unit 10 of the television receiver. As described above, the automatic recording referred to here is to record the usual high-frequency channel, and not to scheduled recording for recording a program at a time set by the user.
[0084]
If automatic recording is not in progress, the process jumps to step S15. If it is determined in step S12 that automatic recording is in progress, the process proceeds to step S13, and referring to the survey result of the channel history data in step S11, it is time when there is no high frequency viewing channel, or Even if there is a high frequency viewing channel, it is checked whether the high frequency viewing channel is different from the channel that is currently automatically recorded.
[0085]
If it is neither, the high frequency viewing channel during automatic recording indicates that it has been a high frequency viewing channel in the past even at the interruption timing, so automatic recording is continued and the flow jumps to step S15.
[0086]
In addition, when it is a time that is not a high frequency viewing channel in step S13, and even if a high frequency viewing channel is detected from the history table, it is a channel different from that during automatic recording. In step S14, automatic recording in the recording / playback apparatus unit 10 is stopped. Then, the process proceeds to step S15.
[0087]
In step S15, it is determined whether or not there is a high frequency viewing channel that is always viewed at the same time with reference to the survey result of the channel history data in the SRAM 105 in step S11. If not, the process routine is exited from step S23. finish.
[0088]
In this step S15, the case where the high frequency viewing channel is determined from the past history will be described with reference to the channel history table of FIG. As described above, this example shows that there is a history for three weeks, and the past viewing history of the same day of the week and the same time as the interrupt processing timing when the flowchart of FIG. 7 is activated is referred to. The Then, if there is a program-corresponding channel having a viewing frequency of a certain percentage or more on the same day of the week and the same time, it is determined as a high-frequency viewing channel.
[0089]
Therefore, in the example of FIG. 6, in the case of 00:21, there are two weeks of “0” indicating that the broadcast program is not watched, and since the 10 channels were watched last week, this is the most watched. Although it is a channel, since the viewing frequency is 1/3, it is not a channel that is always viewed, that is, a high frequency channel.
[0090]
On the other hand, in the case where the current time is 19:01, 12 channels are selected for all three weeks, so this is determined as a high frequency viewing channel. Thus, instead of setting a channel viewed every week, that is, at a rate of 100%, as a high frequency viewing channel, for example, two thirds (66%) or more are determined as a high frequency viewing channel. May be.
[0091]
If it is determined in step S15 that there is a high-frequency viewing channel, the process proceeds to step S16 to check whether the TV receiver is turned on and the program is being viewed. If the broadcast wave is being viewed, the process proceeds to step S17, and it is checked whether the program-corresponding channel currently being viewed is the high frequency viewing channel detected in step S15.
[0092]
If it is the same channel, this routine is exited from step S23 and the process is terminated. If it is a different channel, the process proceeds to step S18, and a message for calling attention to the user, for example, “I always watch the A channel” or other high frequency viewing channels are displayed. A picture symbol such as an icon is displayed on the display.
[0093]
At the same time, the control circuit 100 supplies a tuning control signal for selecting a high frequency viewing channel to the sub-tuner 1S, and receives it on the high frequency viewing channel as a PinP child screen on the display. The displayed video content is displayed for a certain period of time. That is, the video of the high frequency viewing channel that is always viewed is displayed for PinP for a certain period of time.
[0094]
The user can know from the display message and pictorial symbol that there is a program that is always seen in the so-called back program, and can know the content of the program on the PinP child screen.
[0095]
Then, the process proceeds to step S19, and it is detected whether or not a certain period of time has elapsed without the user performing a channel selection operation for selecting a high frequency viewing channel. If the user changes the channel that is currently viewed by the main tuner 1M to the high frequency viewing channel, the process routine is exited from step S23. The display of PinP is appropriately deleted by the user.
[0096]
On the other hand, if the user does not switch the channel even after a predetermined time has elapsed, the small-screen display in PinP is deleted, and the process proceeds to step S21. Also, if it is determined in step S16 that the TV broadcast wave is not being watched even though there is a high frequency viewing channel, the process proceeds to step S21.
[0097]
In step S21, it is determined whether or not the recording / playback apparatus unit 10 is recording. That is, it is detected whether automatic recording of the high-frequency viewing channel has started, recording of a program reserved by the recording / playback apparatus unit 10 has been performed, or whether the recording state has been set by a user's forced operation. To do.
[0098]
If the recording / reproducing apparatus unit 10 is in the recording state, the recording state is prioritized, the process jumps from step S21 to step S23, and the routine is exited (step S22). When it is determined in step S21 that recording is not in progress, the recording / playback apparatus unit 10 starts recording the high-frequency viewing channel determined in step S15. The recording source in this case is the sub tuner 1S as described above. For this reason, if the television receiver is not turned on, power is not supplied to the display portion, but power is supplied to the sub-tuner 1S, the video intermediate frequency amplification and detection unit 2S, and the recording / playback device unit 10. Is input and recording processing is performed.
[0099]
FIG. 8 is a display example of the message performed in step S18. In this example, when the user is viewing 10 channels, 4 channels are normally viewed as high frequency viewing channels at the same time. We are alerting you. FIG. 9 shows an example of the message displayed in step S18 and the sub-screen display by PinP. The program contents of the four channels, which are the high-frequency viewing channels in the case of FIG. 8, are displayed on the PinP sub-screen. .
[0100]
When the automatic recording is performed as described above, the CPU 101 stores the history of the automatic recording in the SRAM 105 and reads it out as needed to record the recording history contents as shown in FIG. Is displayed.
[0101]
That is, the CPU 101 sequentially stores the timing at which automatic recording is started, the end time of the recording, and channel information in the SRAM 105. Then, for example, when the user operates the recording history call button of the remote commander, the screen of FIG. 10 is called. Then, on the screen of FIG. 10, the recorded content selected by the up / down cursor key of the remote commander can be reproduced to enjoy the program.
[0102]
In the above example, the channel selected once is set to frequency 1 as it is. However, frequency data may be weighted for a program that is particularly desired to be viewed according to the user's preference. For this weighting, the remote commander may be provided with a weighting button for the user to weight the viewing channel.
[0103]
Further, in the case of digital television broadcasting, which will be described later, the viewing frequency may be weighted according to the user's program selection trend when selecting a menu. For example, if a user often selects news and dramas, the channel history for the news and dramas is selected once, so that the frequency is doubled and the same as selecting twice. It is advisable to weight the information.
[0104]
In the above-described example, the VTR is used for the recording / reproducing apparatus unit 10. However, by providing an A / D converter on the input side of the recording / reproducing apparatus unit 10 and a D / A converter on the output side, You may make it record on a magneto-optical disc as digital data. In this way, if the video signal and audio signal are recorded on the disc and played back, the recorded content is not stored sequentially, so only the portion recorded by the recording reservation is prohibited from being overwritten. Automatic recording can also be continued.
[0105]
Therefore, there is no need to perform a process not to perform automatic recording when a recording reservation has been made, as in the case where the VTR described above is used as the recording / playback apparatus unit 10, and the user waits for the end of recording. There is no need to reboot.
[0106]
When a disc is used as a recording medium, when there is no free space on the disc, as described above, there is a method of not recording, and overwriting (recording over the previous recording portion) is performed. Two specifications are possible. However, in the former case, after the recording medium has run out of capacity, even if the program that was most desired to be recorded thereafter is broadcast, it cannot be recorded. Even in the latter case, if the program that was most desired to be recorded is recorded and then automatic recording is performed thereafter, the contents may be erased.
[0107]
Therefore, in this embodiment, when automatic recording is performed, the viewing frequency of the previously automatically recorded program is compared with the viewing frequency of the program to be recorded, and a program with a higher viewing frequency is left. It is determined whether to overwrite or not. This configuration is very convenient because it enables recording according to the viewer's request.
[0108]
Also, depending on the capacity of the recording medium, if the capacity is small, the time range for automatic recording can be set, for example, only at night or only during the day, or automatically by button operation. By turning on / off the recording capacity, the recording capacity can be saved.
[0109]
In the above-described embodiment, the recording / reproducing apparatus is built in the television receiver. However, the television receiver is provided with a VTR connector jack having a control signal terminal, and is connected to the VTR connected thereto. If the recording command and the channel selection control signal for selecting the high frequency viewing channel are sent from the control circuit 100 of the television receiver, the recording / reproducing apparatus unit may be external.
[0110]
[Second Embodiment of Channel History Information Creation Processing]
In the first embodiment described above, the channel selection state of the tuner 1M is scanned and the channel history data is created at a constant time period. In the second embodiment, however, when the user performs a channel selection operation. In addition, the channel selection data is loaded into the memory as channel history data, and past history data is referenced at the channel selection operation timing to determine whether there is a high frequency viewing channel, and automatic recording is performed as described above. Or, it is configured to display a message.
[0111]
That is, the channel history table of the SRAM 105 shows the channel number selected at the time of the channel selection operation by the user's remote commander or the press of the channel selection button provided in the television receiver, and the time information at that time. Record as. In this case, since the channel selection operation is performed at an arbitrary timing, the information of the selected channel number corresponding to the program (or the channel selection control signal data) and the time information thereof are stored in the channel history table. To be recorded.
[0112]
Then, when this remote control signal is received or when a button is pressed, the past channel history table is examined, and whether there is a program-compatible channel that is being viewed at a certain frequency or more on the same day of the week and at the same time as above. If so, it is determined as a high frequency viewing channel. In the same manner as described above, message display and PinP sub-screen display are performed, and automatic recording is appropriately performed.
[0113]
[Other Embodiments of Broadcast Receiving Apparatus]
The above example is a case of a terrestrial broadcast wave receiving apparatus, but the example described below is a case where the present invention is applied to a digital satellite broadcast started broadcasting in the United States. In the above-described analog terrestrial broadcasting, in Japan, for example, a frequency band is divided every 6 MHz, and each divided frequency band is used as a broadcast transmission channel, and one broadcast station, that is, a program-compatible channel is paired with one broadcast transmission channel. Therefore, by selecting one broadcast transmission channel, it is possible to selectively receive a program of a specific broadcast station (program-corresponding channel).
[0114]
On the other hand, in the digital satellite broadcasting of this example, the transmission channel and the program-compatible channel (corresponding to the broadcasting station in this example, the same applies hereinafter) do not match, and the channel indicates a specific frequency band. Don't be. This is to effectively use the broadcast frequency band.
[0115]
That is, in digital satellite broadcasting, video and audio are data-compressed and broadcast by a method such as MPEG1 or MPEG2, and if the program has little screen movement, the amount of information to be broadcast may be small. In the case of a fast moving video such as a sports program, a large amount of information is necessary to broadcast the video without reducing the image quality. Therefore, when a certain program is broadcast, the broadcast frequency band is effectively used by changing the broadcast frequency or frequency group used according to the amount of information to be broadcast. That is, when the amount of information is small, it is possible to broadcast a plurality of programs at one frequency or one frequency group, and when the amount of information is large, even a single program has a plurality of frequencies. Alternatively, it may be necessary to broadcast using a plurality of frequency groups.
[0116]
In digital satellite broadcasting, the use of broadcast waves is not fixed with respect to program-compatible channels in this way. Therefore, other broadcast wave frequencies or frequency groups are used as program-specific channels as broadcast signals of a specific frequency group. Information on how it is used is broadcast. In this specification, this is called an index channel.
[0117]
This index channel information includes broadcast program schedule information including program titles. For this reason, in digital satellite broadcasting, if the program-compatible channel and time are known, the title of the broadcast program can be obtained from the index channel. Therefore, if this program title information is stored together with the high-frequency channel history information, the program title as well as the program-compatible channel can be notified to the receiver as information on the high-frequency viewing program. . That is, the program title can be included in a message indicating that the high frequency viewing channel exists in the back program.
[0118]
In the case of digital television broadcasting, it is not necessary to provide two tuners, and this can be replaced with one program selector and two decoders. Since the broadcast wave transmission channel does not match the program-corresponding channel representing the program, in this case, the program-corresponding channel is stored as channel history information.
[0119]
FIG. 11 shows a block configuration example of the receiving apparatus of this example. Reference numeral 21 denotes a satellite broadcast antenna. A digital broadcast wave received by the antenna 21 is supplied to the program selector 22. As will be described later, the program selector 22 receives a control signal from the system control unit 300, selects a so-called program-corresponding channel, extracts index data from the broadcast signal, and selects the program-corresponding channel designated by the user. Video data packets and audio data packets are extracted.
[0120]
The program selector 22 can extract not only a single program-compatible channel but also a plurality of program-compatible channels of video data packets and audio data packets. In the apparatus of this example, two program-corresponding channels are extracted, and in the following description, one is called a main channel data packet and the other is called a sub-channel data packet.
[0121]
The video data compressed by the MPEG1 or MPEG2 system of the main channel extracted by the program selector 22 is supplied to the video data decoding unit 23M, and the compressed video data of the subchannel is supplied to the video data decoding unit 23S. Decoding, data expansion processing, and interpolation processing are performed respectively.
[0122]
The video data decoding unit 23M outputs the output video data to the video display processing unit 25, and the video data decoding unit 23S outputs the output video data to the sub-screen processing unit 26 in the form of a frame image.
[0123]
The video display processing unit 25 writes a frame image into a frame memory built in the video display processing unit 25 at a predetermined cycle, performs D / A conversion, and displays it via the PinP processing unit 27, which is a CRT in this example. The data is output to the display 28. Thus, the video of the main program selected and designated by the user is reproduced and displayed on the screen of the CRT display 28.
[0124]
Further, the sub-screen processing unit 26 compresses the frame image data, generates data for displaying the image on a part of the screen of the display 28, writes the data in the memory at a predetermined cycle, A-converted and supplied to the PinP processing unit 27.
[0125]
When there is a PinP request from the system control unit 300, the PinP processing unit 27 receives a screen position designated in advance or a screen position designated by a position designation signal included in the PinP request from the child screen processing unit 26. It superimposes on the video signal from the video display processing unit 25 so as to display an image based on the video signal. Therefore, when a PinP request is received from the system control unit 300, the sub-channel program image is displayed as a partial sub-screen of the main channel program image at the designated screen position.
[0126]
Also, the audio data compressed in the MPEG / audio format of the main channel and sub-channel extracted by the program selector 22 is supplied to the audio data decoding units 24M and 24S, respectively, decoded, data decompression processing, etc. Output in the form of a signal.
[0127]
The audio data from the audio data decoding unit 24M is supplied to the speaker 31 via the amplifier 30 via the audio processing unit 29, and the main program audio is reproduced. The audio processing unit 29 receives the control signal from the system control unit 300 according to the D / A conversion of the digital audio data and the user's volume adjustment operation and sound quality adjustment operation through the remote commander 50 to adjust the volume and sound quality. Etc. are performed.
[0128]
The audio data from the sub-channel audio data decoding unit 24S is the audio of the program displayed on the PinP sub-screen, and is not directly reproduced by the speaker 31 as described above. However, in this example, as will be described later, this is a storage target in the recording / reproducing apparatus unit 200.
[0129]
The system control unit 300 is configured as a microcomputer, and stores fixed data such as image data and character font data for displaying a program to be executed, a program guide, and the like with respect to the system bus 301. ROM 303, RAM 304 as a volatile memory used for a work area, SRAM 305 as a nonvolatile memory for data that needs to be retained, video RAM 306, and timer (via I / O port 302) Clock circuit) 308 is connected.
[0130]
When the user performs an operation on the remote commander 50, the remote commander 50 transmits a remote control signal corresponding to the user's operation to the remote control reception / decoding unit 43 as, for example, infrared rays. The remote control receiving / decoding unit 43 decodes the received remote control signal and inputs it to the system control unit 300 via an I / O port (not shown). The system control unit 300 interprets the input digital remote control signal and executes the program in the ROM 303 so as to perform control according to the user's remote control operation.
[0131]
When the remote commander 50 performs a program-compatible channel selection operation (program selection operation), the video data packet, audio data packet, and the like of that channel are extracted.
[0132]
In extracting this data packet, the system control unit 300 receives the index data of the index channel from the program selector 22 as described above, refers to the channel assignment information of the channel assignment information packet 22, and uses the remote commander 50 to make the user a user. It recognizes to which frequency or frequency group the program-corresponding channel selected by is assigned.
[0133]
Then, the system control unit 300 sends a selection control signal corresponding to the recognition result to the program selector 22, and the program selector 22 performs control so as to select the video data packet, the audio data packet, etc. of the channel designated by the user. To do. At this time, the system control unit 300 can store the program title of the selected program-compatible channel in the RAM 304.
[0134]
As described above, the frequency or frequency group allocation information for the channel, which is sequentially changed according to the broadcast wave by the index channel, is broadcast as the channel allocation information packet 22 at a constant period. In this example, the system control unit 300 requests the program selector 22 to request a data packet of index data at a constant cycle. Upon receiving a request from the system control unit 300, the program selector 22 returns an index channel data packet to the system control unit 300. Thereby, the system control unit 300 can always monitor the allocation of the frequency or the frequency group to the channel.
[0135]
Similarly, the system control unit 300 requests the program selector 22 to transfer the index channel current time information, program schedule information packet, etc., for example, at regular intervals, and in response to this request, the program selector 22 The received data packet is transferred to the system control unit 300.
[0136]
It should be noted that when the data packet acquisition request for the index data is not issued from the system control unit 300 to the program selector 22 at a fixed period, but the program selector 22 finds the data packet of the index channel in advance, Is set to notify (transfer) to the system control unit 300, or the specified data packet found so far from the program selector 22 at regular intervals regardless of the request of the system control unit 300 May be notified to the system control unit 300.
[0137]
The receiving apparatus of this example includes a recording / reproducing apparatus unit 200 as shown in FIG. In this example, the recording / reproducing apparatus unit 200 is configured as a so-called mini-disc recording / reproducing apparatus unit, which is a magneto-optical disk capable of recording and reproducing as described above.
[0138]
The system control unit 300 sends the video data from the video data decoding unit 23S to the video encoding / decoding unit 41 when a recording request operation is performed on the recording / reproducing device unit 200 through the remote commander 50. The audio data from the audio data decoding unit 24S is sent to the audio encoding / decoding unit 42.
[0139]
The video encoding / decoding unit 41 encodes the video data from the video data decoding unit 23S into a format to be recorded in the recording / playback device unit 200. In this example, in order to record on the magneto-optical disk, encoding is performed in, for example, the MPEG1 data format.
[0140]
In addition, the audio encoding / decoding unit 42 encodes the audio data from the audio data decoding unit 24S into data in a format to be recorded on the minidisc. In other words, the audio data is divided into a plurality of bands so that the bandwidth becomes wider as the frequency is higher, and a block composed of a plurality of samples for each divided band (the number of samples should be the same in each band). A method is used in which orthogonal transformation is performed for each block in each band, coefficient data is obtained, and bit allocation is performed for each block based on this coefficient data. In this case, the data compression method takes into consideration human auditory sensation characteristics with respect to sound and can perform data compression with high efficiency (see Japanese Patent Application No. 1-278207). For example, audio data is compressed to about 1/5.
[0141]
The video encoding / decoding unit 41 and the audio encoding / decoding unit 42 receive and decode the reproduction video data and the reproduction audio data from the recording / reproduction device unit 200, respectively, when the recording / reproduction device unit 200 is set to the reproduction mode. The decoded reproduced video data is displayed on the CRT display 28 via the video display processing unit 25, and the decoded reproduced audio data is reproduced by the speaker 31 via the audio processing unit 29.
[0142]
A specific configuration example of the recording / reproducing apparatus unit 200 is shown in FIG.
In FIG. 12, reference numeral 201 denotes a magneto-optical disk (mini disk). The mini disc 201 in this example is configured by storing a disc 201B having a diameter of 64 mm in a cartridge 201A in order to prevent dust and scratches. A pre-groove for light spot control (for tracking control) is formed in advance on the disc 201B. In particular, in this example, an absolute address is superimposed on the wobbling signal for tracking on this pre-groove. Data is recorded.
[0143]
The disk 201B is rotated by the spindle motor 202. The rotation of the spindle motor 202 is controlled by the servo control circuit 205 so that the disk 201B rotates at a constant linear velocity. The disk cartridge 201A is provided with a shutter. When the disk cartridge 201A is placed on the disk mounting tray and loaded in the apparatus, the shutter is opened. A recording magnetic head 203 is disposed above the shutter opening of the disk 201B, and an optical pickup 204 is disposed below the shutter opening of the disk 201B.
[0144]
The optical pickup 204 is controlled to move in the radial direction of the disk 201B by a feed motor 206. Further, the servo control circuit 205 performs focus and tracking control of the optical pickup 204.
[0145]
The system controller 210 built in the recording / reproducing apparatus unit 200 is configured by mounting a microcomputer, and communicates control data and UTOC data to be described later with the system controller unit 300 via the communication interface 211. The operation of the entire apparatus 200 is managed.
[0146]
The configuration of the signal system of the recording / reproducing apparatus unit 200 of the embodiment of FIG. 12 is devised so that the configuration can be simplified as much as possible by making an IC. Note that, during recording and during playback, each unit is switched in mode by a mode switching signal from the system controller.
[0147]
The video encoder / decoder 41 and the audio encoder / decoder 42 and the signal system of the recording / reproducing apparatus 200 are connected via an interface 220 to exchange recording / reproducing signals.
[0148]
The recording data input via the interface 220 is once stored in the buffer memory 222 controlled by the memory controller 221 via the memory controller 221. In this example, the buffer memory 222 is a DRAM having a data capacity of 1M to 4M bits.
[0149]
The memory controller 221 sequentially reads and reads the compressed data from the buffer memory 222 at a transfer speed of about 5 times the writing speed if there is no track jump that causes the recording position on the disk 201B to jump due to vibration or the like during recording. The data is transferred to a data encoding / decoding circuit 223 having a sector structure.
[0150]
When it is detected that a track jump has occurred during recording, the memory controller 221 stops data transfer to the data encoding / decoding circuit 223 and stores the compressed data from the interface 220 in the buffer memory 222. Then, when the recording position is corrected, control is performed so that the data transfer from the buffer memory 222 to the data encoding / decoding circuit 223 is resumed.
[0151]
Whether or not a track jump has occurred can be detected by, for example, providing a vibration meter in the apparatus and detecting whether or not the magnitude of vibration is such that a track jump occurs. Further, as described above, since the absolute address data is recorded in the pregroove on the disc 201B of this example, the absolute address data can be read at the time of recording, and the track jump can be detected from the decoded output. Further, the track jump may be detected by taking the OR of the vibration meter and the absolute address data. When a track jump occurs, the power of the laser beam for magneto-optical recording is lowered or the power is made zero.
[0152]
The recording position can be corrected when the track jump occurs using the absolute address data. Further, as can be understood from the above, the data capacity of the buffer memory 222 in this case is a capacity capable of storing compressed data corresponding to the time from when the track jump occurs until the recording position is correctly corrected. Is a minimum requirement. In this example, the capacity of the buffer memory 222 has 1M to 4M bits as described above, and this capacity is selected to have a margin so as to sufficiently satisfy the above conditions.
[0153]
In this case, the memory controller 221 controls the memory so that the data stored in the buffer memory 222 is reduced as much as possible during the normal operation during the recording. That is, when the amount of data in the buffer memory 222 exceeds a predetermined amount, only a predetermined amount of data, for example, 32 sectors (one sector is one CD-ROM sector (about 2 Kbytes)) from the buffer memory 222. Memory control is performed so as to always ensure a writing space of a predetermined data amount or more after reading.
[0154]
The data encoding / decoding circuit 223 encodes the compressed data transferred from the buffer memory 222 into data having a sector structure of CD-ROM. The 36-sector data including the data for 32 sectors is hereinafter referred to as a cluster. As will be described later, recording / reproduction is performed in units of clusters.
[0155]
The output data of the data encoding / decoding circuit 223 is supplied to the EFM and CIRC encoding / decoding circuit 224. In this circuit 224, encoding processing for error detection and correction is performed on the data, and modulation processing suitable for recording, in this example, EFM (8-14 modulation) processing is performed. In this example, the error detection / correction code is ACIRC (Add-on Interleave + CIRC) in which interleaving is changed with respect to the CIRC (Cross Interleave Reed-Solomon Code) of the CD.
[0156]
The recording data is intermittent data, and a total of four sectors (hereinafter referred to as linking sectors) for cluster connection are added before and after the data of 32 sectors to form one cluster of recording data consisting of 36 sectors. .
Note that the circuit 223 and the circuit 224 can be formed as one IC.
[0157]
The recording data thus formed is supplied to the recording magnetic head 203 via the head driving circuit 225. As a result, a magnetic field modulated by the recording data is applied to the disk 201B (magneto-optical disk). Further, the laser beam from the optical pickup 204 is irradiated onto the disk 201B.
[0158]
The optical pickup 204 includes, for example, a laser light source such as a laser diode, an optical component such as a collimator lens, an objective lens, a polarization beam splitter, and a cylindrical lens, and a photodetector. Larger constant power laser light is irradiated. Data is recorded on the disk 201B by thermomagnetic recording by this light irradiation and the modulation magnetic field by the magnetic head 203. The magnetic head 203 and the optical pickup 204 are both configured to move along the radial direction of the disk 201 in synchronization.
[0159]
At the time of recording, the output of the optical pickup 204 is supplied to the address decoder 227 via the RF amplifier 226, and the absolute address data recorded in the wobble in the pregroove provided along the track of the disk 201B is extracted. And decoded. The detected absolute address data is supplied to the EFM and CIRC encoding / decoding circuit 224, inserted into the recording data, and recorded on the disc. The absolute address data is supplied to the system control circuit 210 and used for recording position recognition and position control.
[0160]
Further, a signal from the RF amplifier 226 is supplied to the servo control circuit 205, and a control signal for a constant linear velocity servo of the spindle motor 202 is formed from the signal from the pregroove of the disk 201B, and the spindle motor 202 is speed controlled. The
[0161]
Next, playback will be described. At the time of this reproduction, in the same way as at the time of recording, the servo control circuit 205 controls the spindle motor 202 by the signal from the pregroove to control the rotation speed at the same linear velocity as that at the time of recording of the disc 201B.
[0162]
At the time of reproduction, the optical pickup 204 detects a focus error by, for example, an astigmatism method by detecting reflected light of a laser beam irradiated to a target track, and also detects a tracking error by, for example, a push-pull method, A reproduction RF signal is output by detecting the difference in the polarization angle (Kerr rotation angle) of the reflected light from the target track.
[0163]
The output of the optical pickup 204 is supplied to the RF amplifier 226. The RF amplifier 226 extracts a focus error signal and a tracking error signal from the output of the optical pickup 204 and supplies them to the servo control circuit 205, and also binarizes the reproduction signal and supplies it to the EFM and CIRC encode / decode circuit 224.
[0164]
The servo control circuit 205 performs focus control of the optical system of the optical pickup 204 so that the focus error signal becomes zero, and performs tracking control of the optical system of the optical pickup 204 so that the tracking error signal becomes zero. Do.
[0165]
The output of the RF amplifier 226 is supplied to an address decoder 227, where the absolute address data from the pregroove is extracted and decoded. The absolute address data from the decoder 227 is supplied to the system control circuit 210 via the EFM and CIRC encode / decode circuit 224, and is used for controlling the reproduction position of the optical pickup 204 in the disk radial direction by the servo control circuit 205. Is done. The system control circuit 210 can also use address information in units of sectors extracted from the reproduction data to manage the position on the recording track scanned by the optical pickup 204.
[0166]
During this reproduction, as will be described later, the compressed data read from the disk 201B is written to the buffer memory 222 and read and decompressed. However, due to the difference between the transmission rates of the two data, the optical pickup from the disk 201B is used. Data reading by 204 is performed intermittently, for example, so that the data stored in the buffer memory 222 does not fall below a predetermined amount.
[0167]
In the EFM and CIRC encoding / decoding circuit 224, the signal supplied via the RF amplifier 226 is EFM demodulated and subjected to error correction processing. The output of the EFM and CIRC encode / decode circuit 224 is supplied to the sector structure data encode / decode circuit 223, which uncovers the sector structure of the CD-ROM and decodes the data into compressed original data.
[0168]
The output of the data encode / decode circuit 223 is temporarily stored in the buffer memory 222 via the memory controller 221. Then, the memory controller 221 sequentially transfers the compressed data from the circuit 223 at a transfer rate of about 1/5 times the writing rate if there is no track jump that causes the playback position to jump during playback. The read data is transferred to the video encoding / decoding unit 41 and / or the audio encoding / decoding unit 42 via the interface 220.
[0169]
In this case, during normal operation, the memory controller 221 performs memory control so that predetermined data greater than the necessary minimum is stored in the buffer memory 222 as much as possible. For example, when the data amount in the buffer memory 222 is equal to or less than a predetermined amount, the data is intermittently taken in from the disk 201B by the optical pickup 204, and the data is written from the data encoding / decoding circuit 223. The memory control is performed so as to always secure a read space of a predetermined data amount or more.
[0170]
As described above, the video data reproduced by the recording / playback apparatus unit 200 and supplied to the video encoding / decoding unit 41 is decoded, expanded, and interpolated by the video encoding / decoding unit 41 according to the MPEG1 system. Is supplied to the CRT display 28 via the video display processing unit 25, and an image is reproduced on the screen.
[0171]
The audio data reproduced by the recording / reproducing apparatus unit 200 is decoded and data decompressed by the audio encoding / decoding unit 42, supplied to the speaker 31 via the audio processing unit 29, and output as audio.
[0172]
Also in the case of this digital broadcast receiving apparatus, in the same way as in the case of the analog television broadcast described above, in the first embodiment of the method for creating channel history information, the main decoding unit in the program selector 22 at a constant cycle. The selection status of the channel corresponding to the program to be decoded by 23M and 24M is scanned to create channel history information and store it in the SRAM 305. The timing for scanning in the selected state at a fixed period is obtained from the timer 308. In this example, the timer 308 is powered separately from the receiving device.
[0173]
Then, it is determined whether or not there is a high frequency viewing channel at the same day of the week as the present time and at the same time at a timing different from the above-described channel history information capturing timing. If it is not currently viewed, a message similar to the above example is displayed and PinP display is performed. Then, if necessary, the recording / reproducing apparatus unit 200 performs digital recording on the disc.
[0174]
Also in the broadcast receiving apparatus of the example of FIG. 11, in the second embodiment of the method for creating channel history information, the channel history is fetched at the time of selecting the program-corresponding channel, and this is stored in the SRAM 305 at that time. Store with information. Time information is obtained from the timer 308. In selecting the program-corresponding channel, the user refers to the program information included in the index information of the index channel, so that the title of the selected program can also be obtained from this index information. Therefore, in this example, the program history is stored together with the channel history data.
[0175]
This program title is displayed on the display screen in a message for informing the presence of the high-frequency viewing channel when the high-frequency viewing channel is determined at the time of selecting the program-compatible channel. .
[0176]
If there is a program of a high frequency viewing channel and it is not viewed, the video data and audio data of that channel are compressed and automatically recorded on the disc in the same manner as in the above example. . Then, the record history is recorded in UTOC (user TOC (TABLE OF CONTENTS)).
[0177]
In this example, video data and audio data are compressed and recorded, so that a larger amount of data can be recorded.
[0178]
Although the case of television broadcasting has been described above, the present invention can also be applied to the case of radio broadcasting. In that case, a disk medium such as an MD can be used as a recording / reproducing apparatus. In the case of MD, since the recording history is automatically recorded in the UTOC area, the contents of the UTOC are read out. Thus, the automatically recorded radio broadcast program can be easily known.
[0179]
【The invention's effect】
As described above, according to the present invention, a program preferred by the user is determined from, for example, past history, and automatically recorded when the user does not view the determined program preferred by the user. Since the recording is performed on the medium, the user can always view the program without overlooking the program he / she likes only by playing it on the recording / playback apparatus.
[0180]
Further, according to the present invention, since the program preferred by the user is automatically recorded unless the user is watching the broadcast, the automatic recording can be performed even if the user is absent and the power is turned off. is there. And since it is automatic recording, the troublesome setting operation like reservation recording is also unnecessary.
[Brief description of the drawings]
FIG. 1 is a block diagram of an embodiment of a broadcast receiving apparatus according to the present invention.
FIG. 2 is a diagram for explaining a channel history data management method used in an embodiment of a broadcast receiving apparatus according to the present invention;
FIG. 3 is a diagram for explaining a channel history data management method used in an embodiment of a broadcast receiving apparatus according to the present invention;
FIG. 4 is a flowchart showing a procedure for storing channel history data used in an embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 5 is a diagram for explaining one day of channel history data used in an embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 6 is a diagram for explaining three weeks of the same day of channel history data used in an embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 7 is a flowchart for explaining an automatic recording operation of a high frequency viewing channel in an embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 8 is a diagram showing an example of a message displayed on a display in one embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 9 is a diagram showing an example of a screen displayed on the display in one embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 10 is a diagram showing an example of display display of contents automatically recorded in an embodiment of the broadcast receiving apparatus according to the present invention.
FIG. 11 is a block diagram of another embodiment of a broadcast receiving apparatus according to the present invention.
12 is a block diagram of a portion of the embodiment of FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1M ... Main tuner, 1S ... Sub tuner, 10 ... Recording and reproducing apparatus part, 11 ... Clock circuit, 14 ... Remote commander, 100 ... Control circuit, 101 ... CPU, 103 ... ROM, 105 ... SRAM for channel history information storage, 22 ... Program selector, 23M, 23S ... Video data decoding unit, 24M, 24S ... Audio data decoding unit, 50 ... Remote commander, 200 ... Recording / playback device unit, 300 ... System control unit

Claims (10)

Channel selection means for selecting a desired program signal from the broadcast wave according to the channel selection control signal;
Channel selection control signal generating means for generating the channel selection control signal in response to a user channel selection operation;
Storage means for storing viewing frequency information of a program, and sequentially updating the information to the new viewing frequency information ;
A determination unit that examines the storage content of the storage unit and determines whether or not a high-frequency viewing program exists;
A disc-shaped recording medium;
When the presence of the high frequency viewing program is detected by the determination unit, the channel selection control signal is generated so that the channel selection unit selects a signal of the high frequency viewing program, and the high frequency viewing is generated. The program signal is controlled so as to be recorded on the disc-shaped recording medium, and when the free area of the disc-shaped recording medium is not sufficient, the storage content of the storage means is examined and the viewing frequency of the program to be recorded And the viewing frequency of the recorded program on the disc-shaped recording medium, and according to the comparison result, the signal of the program to be recorded is overwritten and recorded on the signal of the recorded program Control means for controlling whether or not,
A broadcast receiving apparatus comprising: The broadcast receiving device according to claim 1,
The control means is only when the presence of the frequently watched program is detected by the judgment by the judging means and when the channel selecting means has not selected the signal of the frequently watched program. The broadcast receiving apparatus, wherein the channel selection control signal is generated so that a signal of a high frequency viewing program is recorded on the disk-shaped recording medium. The broadcast receiving device according to claim 1,
Compression means for compressing the signal of the program selected by the channel selection means;
The broadcast receiving apparatus, wherein the control means controls to record the signal of the frequently watched program compressed by the compression means on the disk-shaped recording medium. Storing the program viewing frequency information in the storage means, and sequentially updating the information to the new viewing frequency information;
A determination step of examining the information of the viewing frequency stored in the storage means and determining the presence or absence of a high frequency viewing program;
In the channel selection means for selecting a signal of a desired program from a broadcast wave according to a channel selection control signal when the presence of the high frequency program is detected by the determination in the determination step, the signal of the frequently viewed program The selection control signal is selected to control the high frequency viewing program signal to be recorded on a disc-shaped recording medium, and when the free space of the disc-shaped recording medium is not sufficient, The stored contents of the storage means are examined, the viewing frequency of the program to be recorded is compared with the viewing frequency of the recorded signal program on the disc-shaped recording medium, and the program to be recorded is determined according to the comparison result. A control step for controlling whether or not the signal of the recorded program is overwritten on the recorded program signal;
A broadcast receiving method comprising: The broadcast receiving method according to claim 4,
In the control step, only when the presence of the high frequency viewing program is detected by the determination in the determination step and the channel selection unit has not selected a signal of the high frequency viewing program, The broadcast receiving method, wherein the channel selection control signal is generated so that the signal of the high frequency viewing program is recorded on the disc-shaped recording medium. The broadcast receiving method according to claim 4,
A compression step of compressing the signal of the program selected by the channel selection means;
In the control step, control is performed so as to record the signal of the frequently watched program compressed in the compression step on the disc-shaped recording medium. The broadcast receiving device according to claim 1,
The broadcast receiving apparatus is characterized in that the storage means fetches viewing history information at a period that is finer than other time periods and updates the viewing frequency information during a time period when the audience rating is high. The broadcast receiving device according to claim 1,
Receiving a program recording reservation by the user, the recording reservation recording means for recording the signal of the reserved program to the disk-shaped recording medium when the reservation time comes,
When the recording of the reserved program signal is being executed by the recording reservation recording unit, the control unit may detect the presence of the frequently watched program by the determination by the determination unit. A broadcast receiving apparatus, wherein control is performed so that a signal of a viewing program is not recorded on the disk-shaped recording medium. The broadcast receiving device according to claim 1,
The presence of the frequently viewed program is detected by the determination by the determining unit, and when the signal of the frequently viewed program is recorded on the disc-shaped recording medium by the control unit, a history of the recording is recorded. A broadcast receiving apparatus comprising: means for storing. The broadcast receiving device according to claim 1,
The storage means stores information on the program title of the high frequency viewing program together with information on the viewing frequency of the program,
The control means detects the program title of the frequently watched program before generating the channel selection control signal for the frequently watched program when the presence of the frequently watched program is detected by the judgment by the judging means. A broadcast receiving apparatus characterized in that display accompanied by display is performed on a display screen of a program being viewed.

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