JP4488566B2 - Broadcast receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a broadcast receiving apparatus such as a television and a radio, and more specifically, a frequency expected to be satisfactorily received by each region and a broadcast station name corresponding to the frequency are registered in advance as a database. Both auto-preset function that can search and register channels and frequencies that are expected to be received in the area by selecting from database, and auto-tuning function that automatically detects frequencies that can receive good video and audio etc. The present invention relates to a broadcast receiving apparatus having a function.
[0002]
[Prior art]
For example, many television receivers have been provided with an “auto-tuning function” or an “auto-preset function” in order to easily select a reception frequency, and an example is disclosed in Japanese Patent Laid-Open No. 8-23263. (Note that in the following explanation of auto-tuning, “auto-tuning function” in the present invention is referred to as “auto-preset function” in JP-A-8-23263).
[0003]
A television receiver with an “auto tuning function” will be described.
FIG. 21 is a block diagram showing a configuration of a conventional television with an auto tuning function.
The detection / demodulation unit 51 detects and demodulates the received television radio wave, and detects and demodulates the antenna 511 that receives the radio wave, the tuner unit 512 that selects and receives the broadcast wave of a specific frequency, and the broadcast wave received by the tuner unit 512. And a detection demodulator 513.
An auto tuning switch 521, a channel switch 522, a channel memory 523, and a channel up / down switch 524 are connected to the microcomputer 52. The channel switch 522 and the channel up / down switch 524 have the appearance as shown in FIG. 22, and when the user operates the channel switch 522 or the channel up / down switch 524, the frequency of the broadcast radio wave stored in the corresponding channel memory 523 is called up. Then, the microcomputer 52 sends a reception frequency instruction signal indicating the reception frequency to the detection demodulation unit 51.
Receiving the reception frequency instruction signal, the detection demodulator 51 receives the broadcast radio wave of the instructed frequency. The received broadcast radio wave is separated into a video signal and an audio signal by a detection demodulator 513.
The video signal is amplified by the video amplifier 531 of the display unit 53 and displayed on the display 532 such as a liquid crystal. The audio signal is amplified by the audio amplifier 541 of the audio unit 54 and output through the speaker 542.
[0004]
Next, a method for storing the frequency of the broadcast radio wave in the channel memory 523 will be described.
In the auto-tuning method, when the auto-tuning switch 521 is operated, the reception frequency is sequentially scanned based on the instruction of the microcomputer 52, the detection of each reception frequency, the demodulated reception signal level and the reference signal preset in the microcomputer 52. The level (set to the minimum electric field strength necessary for obtaining a good image) is compared, and if the received signal level is higher, the received frequency is registered in the channel memory 523. If the received signal level is lower, a good video cannot be obtained, and the received frequency is not stored in the channel memory 523. In this way, the reception signal level and the reference signal level are sequentially compared for the broadcast waves of all reception frequencies, and only the frequency of the broadcast wave having a reception signal level higher than the reference signal level is automatically stored in the channel memory 523.
[0005]
A television receiver with an auto preset function will be described.
FIG. 23 is a block diagram showing a configuration of a conventional television receiver with an auto preset function.
The detection / demodulation unit 61 detects and demodulates the received TV radio wave, and detects and demodulates the antenna 611 that receives the radio wave, the tuner unit 612 that selects and receives the broadcast wave of a specific frequency, and the broadcast radio wave received by the tuner unit. It comprises a detection demodulator 613.
An area number input means 621, a channel switch 622, a channel memory 623, a channel up / down switch 624, and a preset database 625 are connected to the microcomputer 62. The channel switch 622 and the channel up / down switch 624 have the same appearance as the conventional example shown in FIG. 22, and when the user operates the channel switch 622 or the channel up / down switch 624, the broadcast stored in the corresponding channel memory 623 is stored. The frequency of the radio wave is called, and a reception frequency instruction signal for instructing the reception frequency is sent from the microcomputer 62 to the detection demodulation unit 61.
Receiving the reception frequency instruction signal, the detection demodulator 61 receives the broadcast radio wave of the instructed frequency. The received broadcast radio wave is separated into a video signal and an audio signal by the detection demodulator 613.
The video signal is amplified by the video amplifier 631 of the display unit 63 and displayed on the display 632 such as a liquid crystal. The audio signal is amplified by the audio amplifier 641 of the audio unit 64 and output through the speaker 642.
[0006]
Next, a method for storing the frequency of the broadcast radio wave in the channel memory 623 will be described.
In the auto preset function, the user operates the area number input means 621 to input a number for specifying an area such as a postal code. In the preset database 625, a channel database (consisting of a reception frequency, a channel number, and a broadcasting station name with a region number as a main key) that can be received well in a certain region is registered for all regions. .
When the user inputs an area number using the area number input means 621, the preset database 625 is referred to and all the channels that can be successfully received in that area are stored in the channel memory 623. For example, when the user inputs the area number of Nara using the area number input means 621, the preset database 625 is referenced to find the registered channel, the frequency for that channel, and the name of the broadcasting station. All are stored in the channel memory 623. FIG. 24A shows a state where all channels that can be received in the Nara region are registered in the channel memory 623. The numbers on the left side of FIG. 24A are channel numbers, which correspond to the channel switch 522 numbers in FIG.
[0007]
When the above-described “auto tuning function” or “auto preset function” is performed and the reception frequency that can be satisfactorily received is registered in the channel memory 523 (or 623), the channel switch 522 (or 622) or the channel up / down When the switch 524 (or 624) is selected, the frequency of the broadcast radio wave stored in the channel memory 523 (or 623) is called, and the tuner 512 (or 612) receives the radio wave and displays the video on the display 532 (or 632). Is displayed.
[0008]
[Problems to be solved by the invention]
However, the above-described “auto-preset function” of the prior art has the following problems.
That is, by referring to the preset database 625 based on the area number input by the user and storing the channels that can be received in that area in the channel memory 623, all the channels stored in the channel memory 623 are good images. It is not always possible to receive in the state. This is because the reception state of a television changes depending on the local radio wave condition and geographical conditions. For example, it may be impossible to receive radio waves in a frequency band where radio waves are blocked by large mountains or buildings.
This will be described with reference to FIG. 24A. Even if the person lives in Nara, the radio wave condition is bad and Nara TV may not be received as a good video. In such a case, even if the 11th button of the channel switch 522 in FIG. 22 is selected, Nara TV is not displayed.
[0009]
Therefore, as a method for solving this problem, a user manually sets a channel after performing “auto-preset”.
This will be described below.
This is because, after using the “auto-preset function” to register channels that are expected to be received in the area where the user lives in the channel memory 623, the user has a poor radio wave condition for each registered channel. The channel determined to be unreceivable is deleted from the registration in the channel memory 623 under the manual operation of the user.
For example, it is assumed that a user living in Nara Prefecture has registered in the channel memory 623 using the auto preset function as shown in FIG. It is assumed that the area where the user lives is poor in radio reception of Nara TV, and Nara TV cannot receive well. Then, the user can delete Nara TV from the registration of the channel memory 623 using a screen as shown in FIG. Specifically, if the item “skip” is changed to “Yes” on the screen shown in FIG. 24B, the registration of the channel memory 523 is deleted, and the channel memory 623 is deleted as shown in FIG. Is updated. (In FIG. 24B, compared with FIG. 24A, Nara TV is deleted from the position of channel number 11.)
[0010]
However, it is very troublesome for the user to manually change the contents registered in the channel memory 623. Up to now, the maximum number of channels was about 10, so it was possible for users to change the contents manually. However, in today's digital broadcasting era, there are hundreds of channels. On the other hand, it is difficult to manually change the registration contents one by one.
In the case of analog broadcasting, even if auto-tuning is performed by comparing the reference signal level (minimum electric field strength necessary for obtaining good images) with the actual received signal level, the reference signal level is actually ambiguous. (It is not certain how much the reference signal level is set to satisfy the user.) As described in the above example, the user can confirm the deletion while manually deleting from the channel memory. It was necessary.
In today's era of digital broadcasting, data transmitted as digital data includes a checksum (a code indicating whether or not the data has been transmitted correctly without error. It is not included in analog data). ing. By auto-tuning using this checksum, it could not be realized in the case of analog broadcasting originally (in the analog era, the user had to manually set the channel after all) It is feasible to set the channel to “ Because in the case of digital broadcasting,
1) Check whether there is any error in the data using the checksum.
2) Compare the reference signal level with the actual received signal level as has been done in analog broadcasting.
This is because auto-tuning can be performed by the two processing methods, and channel setting can be performed more reliably.
The present invention automatically changes the registered contents of the channel memory without manual operation by the user, that is, automatically deletes channels having poor radio wave reception status from the channels registered in the channel memory. It is an object of the present invention to provide a device that can be used.
[0011]
  Therefore, an object of the present invention is to register an effective (good) channel for multi-station by digital broadcasting in the channel memory.In view of the fact that if auto-tuning (effective channel extraction processing by sensitivity check) is completely performed in a mobile device, it will be a sequential process. If the reception sensitivity is above the reference value even if it exceeds the limit, the stored contents of the channel are maintained and auto-tuning is performed.The channel memory allocation should not change frequently.
[0018]
[Means for Solving the Problems]
  The present invention has been made to achieve the above-described object, and the first technical means includes a preset database in which a plurality of broadcast frequency information is associated with a plurality of areas, an area specifying means, Program designation means for designating a viewing broadcast program, channel memory for storing broadcast frequency information corresponding to the area designated by the area designation means, and each of the plurality of broadcast frequency information stored in the channel memory Auto-tuning means for judging whether the received content is good or not without user confirmation, and the received content judged by the auto-tuning means at the time of initial registration of the broadcast frequency information in the channel memory is good Means for registering only broadcast frequency information in the channel memory, and location information acquisition for obtaining current location information. It means, and a table for converting the position information obtained by the position information acquisition means, the area information of the preset data base, the current positionWhenRegional range calculated immediately beforeDistance calculating means for calculating whether or not the distance to the boundary is within a specified value,At least one of the stored contents of the channel memory for the area range calculated immediately beforeOneThe auto-tuning process.When the calculation result of the distance calculation means is within the specified value, the reception sensitivity check is performed on the auto-tuning result of the area range calculated immediately before, and the stored contents of the channel whose reception sensitivity is the reference value or more are maintained. Equipped with a means for auto-tuningIt is characterized by that.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
  Less thanThe figure1 to 11FIG. 2 is a diagram for explaining an example of a broadcast receiving apparatus used for implementing the present invention;12 to 20FIG. 3 is a diagram for explaining an embodiment of the present invention..
  1 to 11Provides the following devices today in the digital broadcasting eraIs a thing. First, register the channels that may be received in the area where the TV is set with the "Auto Preset Function" in the channel memory, then use the "Auto Tuning Function" to improve the channel registered in the channel memory. Or search for channels that are not receiving correctly. Channels that are good or not received correctly are automatically deleted from the channel memory registration.
[0026]
Here, a method of searching for a channel that is not successfully or correctly received by auto-tuning will be roughly divided into the following two processes.
(1) The detection and demodulated reception signal level of each reception frequency is compared with the reference signal level preset in the microcomputer (set to the minimum electric field strength necessary for obtaining a good image). If the received signal level is higher, the channel corresponding to that frequency remains registered in the channel memory. If the received signal level is lower, a good video cannot be obtained, and the received frequency is automatically deleted from the channel memory registration.
[0027]
(2) After performing the processing of (1), the digital data is in error using the checksum in the transmitted digital data (a code that can confirm whether the data has been sent correctly without error). Make sure that it is sent properly. If it has been transmitted correctly without error, the channel corresponding to that frequency remains registered in the channel memory. If there is an error and the message has not been sent correctly, it is automatically deleted from the channel memory registration.
[0028]
Although a data check method using a checksum is described as a method for determining whether or not the data has been transmitted without error, the data check method is not limited to the checksum method, and a data check using a CRC code is also possible. Any appropriate method can be applied.
[0029]
  FIG.Broadcast receiving apparatus as described aboveFIG. 2 is a block diagram showing the configuration of the above, taking a car navigation system with a TV as an example.
  FIG. 2 shows the appearance of a car navigation system with a TV. As appearance components, an antenna 111 for receiving TV broadcast radio waves, a channel switch 121, a channel up / down switch 122, a car navigation related input means 123, a power switch 124, A display unit 13 and a speaker 142 are provided. In this embodiment, the various switches and input means 121 to 124 are arranged on the car navigation system with a TV. However, these switches are provided on a remote controller separated from the car navigation system with a TV. Alternatively, it may be provided in the display unit 13 whose display part is a touch panel type.
[0030]
The functions of the above switches are as follows. The power switch 124 is a switch for controlling ON / OFF of the power.
The channel up / down switch 122 is a switch for sending a forward or reverse channel command, and can send a command to display only the registered channels when it is reflected well. The channel switch 121 has the same appearance as that shown in FIG. 22 which is a conventional example, and is a switch for sending a number command from 1 to 12.
The car navigation-related input means 123 is a switch for sending a command related to only the car navigation system (for example, setting of the shortest route to the destination) in the car navigation system with a TV.
[0031]
Each component forming the car navigation system with TV shown in FIG. 1 will be described.
The detection / demodulation unit 11 is a processing unit that detects and demodulates the received television broadcast radio wave. The detection / demodulation unit 11 includes an antenna 111 that receives a television broadcast radio wave transmitted as digital information, a tuner unit 112 that receives the broadcast radio wave, and a tuner unit 112. It comprises a detection demodulator 113 for detecting and demodulating the broadcast radio wave received at.
The microcomputer 16 is connected to an input means 12, a car navigation processing section 15, a channel memory 17, a preset database 18, an area number calculation means 19, an auto tuning processing section 20, and a program information database 21.
Since the input unit 12 has been described with reference to FIG. 22, the input unit 12 includes a channel switch 121, a channel up / down switch 122, a car navigation-related input unit 123, and a power switch 124.
[0032]
The car navigation processing unit 15 is a part that performs everything related to the car navigation processing.
The channel memory 17 is a part in which information relating to channel setting as shown in FIG. 24A again, the channel number is composed of 1 to 12, and this number coincides with the channel switch 121 number. The frequency indicates the frequency that the tuner unit 112 should receive in order to display the video of the channels corresponding to the channel numbers 1 to 12. The name of the broadcasting station indicates the name of the broadcasting station that is broadcasting the television image that is displayed when the corresponding frequency is received.
[0033]
In the preset database 18, channel numbers, frequencies, and broadcast station names of all channels that can be received well in a certain area are registered. In these, information on all regions is stored in a database with the region number as a primary key. FIG. 3 shows a state of the preset database 18 in which channel numbers, frequencies, and broadcast station names that can be viewed for each area number are stored. In the case of FIG. 3, the postal code is taken as an example of the area code, but the area code may be a telephone area code or the like.
[0034]
The area number arithmetic means 19 is a means for calculating an area number (for example, a zip code or a telephone area code) of an area where the car navigation system with a TV is installed. The process for calculating the area number will be described in detail below.
The auto-tuning processing unit 20 sequentially scans the frequency based on an instruction from the microcomputer 16, detects each received frequency, demodulates the received signal level, and a reference signal level preset in the microcomputer 16 (good video is displayed. (Minimum electric field strength necessary to obtain), and in addition to that, the checksum can be extracted from the TV broadcast signal of a certain channel sent as digital information, and the TV broadcast signal can be received without error. It is a means for judging whether or not. This process is also described in detail below.
[0035]
The program information database 21 stores electronic program information included in the vertical blanking period (VBI) in the television broadcast radio wave received by the antenna 111 and is stored as a database. Note that the electronic program information is not necessarily transmitted by being inserted into the VBI in the television broadcast radio wave, and there are regions where the electronic program information is not inserted and cannot be received depending on the region. Therefore, the electronic program information is recorded in the program information database 21 only when the electronic program information is inserted and transmitted in the VBI.
[0036]
In addition, a display unit 13 and an audio unit 14 are connected to the detection demodulation unit 11. The display unit 13 is formed of a display 132 and a video amplifier 131, and the audio unit 14 is formed of a speaker 142 and an audio amplifier 141.
[0037]
Here, the operation of each component when the user views the TV will be described.
When the user operates the channel switch 121 or the channel up / down switch 122, the corresponding broadcast radio wave frequency stored in the channel memory 17 is called, and the microcomputer 16 receives the reception frequency instruction signal for instructing the reception demodulation frequency to the detection demodulation unit 11. Will be sent.
Receiving the reception frequency instruction signal, the detection demodulator 11 receives the broadcast wave of the instructed frequency. The received broadcast radio wave is separated into a video signal and an audio signal by the detection demodulator 113. The video signal is amplified by the video amplifier 131 and the video is output from the display 132. The audio signal is amplified by the audio amplifier 141 and output through the speaker 142.
[0038]
Next, a process flow when the power is turned on, that is, an auto preset process will be described with reference to FIG.
(Step 1) It is monitored whether or not the power switch 124 has been selected by the user and a power ON command has been issued. Monitoring is continued in step 2 when a power-on command is issued, and in step 1 when a power-on command is not issued.
(Step 2) The car navigation processing unit 15 is activated.
(Step 3) The position information of the position where the car navigation system with TV is installed is calculated by the car navigation processing unit 15. Note that the calculation method at this time is not directly related to the gist of the present invention, and since it is well known in the past, it will be described briefly, but it communicates with the satellite for car navigation around the earth, The position where the car navigation system with TV is installed is calculated. At this time, the position information is calculated as information represented by latitude and longitude, for example.
[0039]
(Step 4) The area number calculating means 19 is activated.
(Step 5) The area number calculation means 19 activated in step 4 calculates the area number using the position information represented by the latitude and longitude calculated by the car navigation processing unit 15 in step 3. An example of processing at this time will be described. For example, as shown in FIG. 5, in the area number calculation means 19, area numbers corresponding to respective longitudes and latitudes (in this case, zip codes as examples of area numbers) are stored. It is databased.
In step 3, if the car navigation processing unit 15 calculates that the position information of the position where the car navigation system with TV is currently installed is “35.0 degrees north latitude, 135.0 degrees east longitude”, the area number calculation is performed. The means 19 calculates how many area numbers correspond to “35.0 degrees north latitude and 135.0 degrees east longitude” by referring to the database. In this case, the calculated area number is “734-5520”.
[0040]
(Step 6) Based on the area number calculated in Step 5, the microcomputer 16 searches the preset database 18 for channel setting information that matches the area number, and registers it by storing it in the channel memory 17. This process will be described in detail. For example, it is assumed that the area number at the position where the car navigation system with a TV is currently installed is calculated as “734-5520” (postal code) by the area number calculating means in step 5. Then, the microcomputer 16 refers to the preset database 18 and searches for a registered channel and a frequency and a broadcasting station name corresponding to the channel when the postal code is “734-5520”. Register in the memory 17. Here, the state registered in the channel memory 17 is shown in FIG.
[0041]
Next, after the processing of FIG. 7, that is, the auto-preset processing, is finished, processing for automatically deleting channels that are not well received or correctly received from the channels registered in the channel memory 17 by auto-tuning. Will be described with reference to FIG.
(Step 11) The auto tuning processing unit 20 is activated. Note that the start timing may be immediately after the completion of the auto-preset process described with reference to FIG. Alternatively, an operation button for outputting an auto-tuning start command may be prepared and the user may select that button.
(Step 12) 1 is substituted into the variable M.
(Step 13) The auto-tuning processing unit 20 refers to the channel setting information in the channel memory 17 and checks whether data is input to the channel with the channel number M. Here, the determination method of whether or not data has been input will be described. In FIG. 4, “the data with the channel number 1 is not input, and the data with the channel number 2 is input. Defined. That is, it is defined that data is input when there is data. If data has been input, the process proceeds to step 14, and if data has not been input, the process proceeds to step 18.
(Step 14) When the auto-tuning processing unit 20 instructs the tuner unit 112 to set the channel number in the channel memory 17 to a frequency corresponding to M through the microcomputer 16, the microcomputer 16 instructs the detection demodulation unit 11 to receive frequency. A reception frequency indicating signal is transmitted. Receiving the reception frequency instruction signal, the detection demodulator 71 receives the broadcast wave of the instructed frequency. Then, the received signal level of the radio wave of the instructed frequency and the digital information transmitted as the radio wave are sent to the microcomputer 16.
[0042]
An example of digital information transmitted as radio waves will be described.
FIG. 6 is a diagram showing digital information of television broadcast radio waves. As shown in FIG. 6, the digital information includes a header 22, data 23 indicated by 0 and 1, and a checksum 24.
Here, the checksum 24 will be described. For example, the checksum 24 used in the simplest parity check method will be described. If the data 23 indicated by 0 and 1 contains an even number of 1s, “0” is inserted into the checksum 24. If 1 is an odd number, a checksum “1” is inserted.
[0043]
(Step 15) The auto-tuning processing unit 20 sets the reception signal level received in Step 14 and the reference signal level preset in the microcomputer 16 (set to the minimum electric field intensity necessary for obtaining a good image). Compare). And
Received signal level ≥ reference signal level
If so, go to Step 17. Also,
Received signal level <reference signal level
If so, go to Step 16.
[0044]
(Step 16) Since the television image has not been received properly and correctly, the auto-tuning processing unit 20 deletes the frequency of the data corresponding to the channel number M and the broadcast station name from the channel memory 17 and proceeds to Step 18. .
(Step 17) The auto-tuning processing unit 20 checks whether there is any data error in the digital information as shown in FIG. 6 transmitted as the radio wave received in Step 14.
Here, a method for checking whether or not an error is included in the data will be specifically described. For example, even if 1 is included in the data 23 indicated by 0 and 1, the checksum 24 is displayed. If 1 is inserted, it means that an error has occurred during transmission of the data 23 indicated by 0 and 1.
If there is an error in the data, the process proceeds to step 16, and if there is no error, the process proceeds to step 18.
[0045]
The sensitivity check by the sum check will be described. Broadcast communication is unidirectional communication, that is, the receiving side only has to check whether the data transmitted (broadcasted) by the transmitting side (broadcasting station) is correct. Therefore, it is checked whether the data transmitted in the specified format is received on the receiving side according to the specified format. In order to determine whether one transmission packet is correct, The sum of packet data is added. Although this data is referred to as sum check data, just because a check sum of a certain packet is invalid does not mean that it cannot be received.
Sensitivity check by packet checksum means whether the frequency of checksum errors occurring within a unit time (within a certain number of packets) is greater than the specified value. This is an effective method compared to the sensitivity check by electric field strength.
[0046]
(Step 18) Substitute M + 1 for the variable M.
(Step 19) If the variable M is larger than 12, all the channels registered in the channel memory 17 have been auto-tuned, and the process is terminated. In other cases, the process returns to step 13 to compare the received signal level with the reference signal level, and perform data error detection processing using a checksum. As apparent from FIG. 24A, since there are only 12 channel numbers for registering channels in the channel memory 16, the variables M and 12 are compared in step 19.
[0047]
As described above, by performing the auto-preset process shown in FIG. 7 and the auto-tuning process shown in FIG. 8, the channel memory 17 can receive channels correctly and properly in the area where the car navigation system with a TV is installed. Only registered.
[0048]
Next, based on FIG. 9, when the TV image is displayed on the display unit 13 after the processing of FIGS. 7 and 8, the user operates the channel up / down switch 122 to change the TV reception channel. The operation to be performed will be described.
(Step 21) It is monitored whether or not a channel forward or fast forward command has been issued by the user operating the channel up / down switch 122. If a forward or fast-forward command is issued, the process proceeds to step 22; Next, the description will proceed to step 22. In this case, it is assumed that the user has selected the switch indicated by the down arrow of the channel up / down switch 122.
(Step 22) The microcomputer 16 holds the channel number corresponding to the currently displayed television image in the variable K.
(Step 23) Substitute K + 1 for the variable K.
(Step 24) Compare whether K is equal to 13. If they are equal, the process proceeds to Step 25, and if they are not equal, the process proceeds to Step 26. The reason why the variables K and 13 are compared here is that, since there are only 12 channel numbers for registering channels in the channel memory 16 from FIG. 24A, the variables K and 13 are compared. If K is 13, the process of changing K to 1 in step 25 is performed.
(Step 25) If the variable K is equal to 13, then 1 is substituted into the variable K and the process proceeds to Step 26.
[0049]
(Step 26) The microcomputer 16 refers to the setting information in the channel memory 17 and checks whether data is input to the channel with the channel number K. If data has been input, the process proceeds to step 27, and if data has not been input, the process proceeds to step 23.
(Step 27) The microcomputer 16 instructs the detection demodulator 11 to receive a frequency whose channel number in the channel memory corresponds to K. Receiving this command, the detection / demodulation unit 11 receives the broadcast radio wave of the instructed frequency, and outputs the TV video and audio to the display unit 13 and the audio unit 14.
[0050]
When the user selects the down arrow switch of the channel up / down switch 122 by performing the processing described with reference to FIG. 9, the channel number of the TV image currently being viewed by the user from among the channels registered in the channel memory 17. Next, the channels registered in the channel memory 17 are displayed from among the channels with the larger channel numbers as being displayed well.
In the above description, the operation is described on the assumption that the user selects the down arrow switch of the channel up / down switch 122. However, the operation when the user selects the up arrow switch of the channel up / down switch 122 is illustrated in FIG. Step 9 in Step 9 may be changed to “K ← K−1”, and the comparison processing in Step 24 may be changed to “K = 0?”. When such processing is performed, when the user selects the upward arrow of the channel up / down switch 122, the channel registered in the channel memory 17 with a channel number smaller than the channel number of the currently viewed television image is displayed. The video of the number will be displayed.
[0051]
  The above is an example of a car navigation system with a TV.TheoryAs described above, the present invention is not limited to such a configuration. For example, it can be implemented with a simple television that does not include a car navigation system. In this case, since it is a mere television receiver, the area number where the television receiver is currently installed cannot be automatically detected.
  Therefore, the area number is manually input by the user using, for example, a separately provided area number setting means (a means for generating an area number setting command), for example, a zip code or a telephone area code. At this time, the processing flow when the power is turned on shown in FIG. 7 may be replaced with the processing flow shown in FIG.
(Step 31) It is monitored whether a power ON command is issued.
(Step 32) The user inputs an area number using the area number setting means.
(Step 33) The microcomputer 16 searches the preset database 18 for channel setting information that matches the area number input by the area number setting means, and registers it in the channel memory 17.
[0052]
  Also, electronic program information embedded in the vertical blanking period (VBI) of the current program radio wave (this information includes the program start / end time, channel, broadcast station name, genre, contents, etc. ) Is displayed on the TV screen., TeBy displaying only the electronic program information corresponding to the channel registered in the channel memory 17 after channel setting in the revision receiving apparatus, it is possible to display an electronic program guide that is easier to use for the user. This is because it is possible to display only the electronic program guide of the channel that is determined to be well reflected by using this technique. That is, the program guide for channels that do not appear well is not displayed. In digital broadcasting, the number of channels exists on the order of several hundreds. By not displaying all the programs of these hundreds of channels, but only by displaying the program guide of the channel that looks good, the time until the user finds the channel that the user wants to watch is shortened.
  A processing flow for realizing this technique will be described with reference to FIG.
  This process can be performed only when electronic program information is inserted and transmitted in the VBI of a television broadcast radio wave.
[0053]
(Step 41) 1 is substituted into the variable A. As an example of the timing for substituting 1 for the variable A, it is conceivable that the user selects a program guide display button and issues a program guide display command.
(Step 42) The microcomputer 16 refers to the setting information in the channel memory 17 and obtains the broadcasting station name of the channel whose channel number is A.
(Step 43) The microcomputer 16 refers to the program information database 21 and displays on the display 132 the program information broadcast by the broadcast station name acquired in Step 42.
(Step 44) The variable A is incremented by one.
(Step 5) It is checked whether or not the variable A is equal to 13. If they are equal, the process ends. If not, the process proceeds to Step 42.
By performing the above processing, it is possible to display on the display 132 a program guide for only the registered channels if the channel memory 17 can be received satisfactorily.
[0054]
Figure12 isFor explaining an embodiment of the present inventionIt is a block diagram and shows a car navigation system with a TV as an example. The basic configuration is shown in Fig. 1.ExampleHowever, in order to facilitate the explanation of the point part of the invention, the block names and block numbers are different.
  FIG. 13 is a diagram showing a schematic external shape of a car navigation system with a TV.
[0055]
TThe car navigation system with V has two functions, which are roughly divided into a TV function and a car navigation function.
  In the product image shown in FIG. 13, a TV / car navigation display switching button 41 is a button for switching between these two functions.
  However, since the detailed configuration of the car navigation function block is not directly related to the present invention, only the “position detection device” that is a necessary component among the components of the car navigation system is shown.
  Therefore, actually, the block configuration of FIG. 12 includes a block for controlling the TV function to the car navigation function when the TV / car navigation display switching button 41 and the TV / car navigation display switching button 41 are pressed. To do.
[0056]
  The position detection device 37 is, TGPS (Global Positioning System) is a typical device that detects and outputs location information (generally output in latitude / longitude) where a vehicle equipped with a car navigation system with V is present. However, if the accuracy of the location information is ignored, a location acquisition service such as PHS can be used.
  In short, any means can be used as long as it can obtain location information of the current device and output it to the channel memory control unit 31 described later.
[0057]
Next, the channel button 38 is a switch for switching a reception channel as a television receiver, and six switches are provided in the product image shown in FIG. 13, but the number is a necessary number without any limitation. be able to. When one of the channel buttons 38 is pressed, a television broadcast having a reception frequency stored in a channel memory (CHMemory) 33 as shown in FIG. The device 35 receives the information and outputs the received content (video) to the display device 39.
In short, this system is a television broadcast receiver capable of switching channels for six channels.
[0058]
In addition to the configuration described above, the area structure (AreaTbl) 32 having the data structure shown in FIG. 15 and the sensitivity definition values (Basel, Base2) for determining whether to register in the channel memory 33, and other variables shown in FIG. / Variable memory 34 in which constants are stored, and further, a reception sensitivity detector 36 that checks whether or not the reception sensitivity for a certain channel (reception frequency) is equal to or higher than a specified value, and outputs the result, and a channel memory The channel memory control unit 31 performs control of registration in the channel memory control unit 33. These components and their control will be described in detail based on the processing flow of the channel memory control unit 31 below.
In FIG. 12, the broadcast receiving device 35 and the reception sensitivity detection unit 36 detect the reception sensitivity while receiving the contents (video) of a certain reception frequency under the control of the channel memory control unit 31. This means that two or more tuners (broadcast receiving apparatuses) are required when detecting reception sensitivity based on an error rate of broadcast reception contents (video data) using a checksum or the like. However, for example, a receiving device that can receive a program while receiving electronic program information (EPG), in other words, in the case of different receiving frequency bands (in the case of digital broadcasting, two or more contents may be transmitted in the same receiving frequency band). In this case, there are some broadcast receivers that can process a multiplicity of data), so that two or more tuners are not necessarily required.
[0059]
  17 to 19 show a processing flow of the channel memory control unit 31.
HThe channel memory registration process is described below.
  1) Basically, high-sensitivity broadcasts are sequentially registered in the channel memory for all channel memories, and assigned to individual channel buttons 38.
  2) Always check the current position, and re-register the channel memory 33 according to the contents of the area database (AreaTbl) 32 in rectangular units as shown in FIG.
  3) However, processing in the vicinity of the boundary between the rectangular unit and the rectangular unit (range of processing rectangle to processing rectangle + constant d) (see FIG. 20) is a special processing (“ Channel button assignment does not change "or" sensitivity check is loosened "), and the channel button assignment is changed as much as possible.
However, it is expected that the channel button assignment will still change frequently and it will be difficult to use only with the processes 1) to 3).
[0060]
Therefore, the following consideration must be made to make the best use of the channels (frequency) set in the channel memory other than the selected (reception) channel.
1) Prepare two types of buttons (channel memory and control are necessary), which are channel buttons to be auto-tuned and channel buttons not to be processed.
2) Give priority (weight) to effective broadcasting stations (Broadcast []) in the regional database, and change the channel memory registration priority according to the priority. (For example, NHK is always set to channel button 1 regardless of reception sensitivity.)
3) Creating a database of affiliated stations and similar broadcasting stations (for example, people who live in Osaka feel that Nara Broadcasting, Kyoto Broadcasting, and Wakayama Broadcasting basically broadcast the same program) Search for alternative broadcast stations even at different broadcast stations, such as by checking the same program by electronic program information (EPG) (for example, high school baseball is good for people who are watching in private or NHK / NHK education) Assign.
[0061]
Returning to the description of the processing flow of the channel memory control unit 31 shown in FIGS. 17 to 19, the channel memory control unit 31 has two types of entries (entrances), and the processing flow of FIG. In the other entry, the processing flow of FIG. 18 operates.
The processing flow of FIG.
1) When the first TV function is activated after product shipment (pressing the first TV / car navigation display switching button or first power-on process)
2) When pressing the reset button
This is done when the reset button is pressed when the channel memory is not registered at all, or when it is desired to initialize the registration of the current channel memory.
(Step 51) Current position information is acquired from the position detection device 31.
(Step 52) From the area database (AreaTbl) 32, it is checked on which map number the current position corresponds, and the corresponding map number is stored in the variable Mo.
(Step 53) Of the effective broadcast station list (Broadcast []) with the map number Mo, channels (reception frequencies) having higher sensitivity than the specified value BASE1 (higher reference value) are sequentially registered in the channel memory 33 in the order of higher sensitivity.
[0062]
Next, the processing flow shown in FIG. 18 by the other entry is the TV function operation (switching from the car navigation display mode to the TV function or the TV function mode when registration is already made in the channel memory 33). ) Is always controlled by checking whether the channel button 38 is pressed and where the vehicle equipped with the car navigation system with TV is present,
(Step 61) First, it is checked whether or not the channel button 38 is pressed.
(Step 62) When pressed, the channel (reception frequency) corresponding to the pressed channel button is stored in the variable SelCh.
(Step 63) By outputting the channel (reception frequency) to the broadcast receiving device 35, the designated channel is received (displayed).
In this process, error processing for a case where the channel (reception frequency) is not assigned to the pressed channel button 38 that is generated when the number of channels with good sensitivity is less than 6, or a variable immediately after resetting, etc. The processing when (SelCh) is not initially set is actually necessary, but is omitted for the sake of simplicity.
[0063]
(Step 64) If the channel button 38 is not pressed in step 61, the current position information is acquired from the position detection device 37.
(Step 65) The map number for the current position is obtained from the area database (AreaTbl) 32 and stored in the variable Mn.
(Step 66) By comparing the variable Mn value with the Mo value, it is checked whether or not a map change (exactly, it is not a simple map change, as can be seen from the following control contents), and there is no change. If not, the channel memory 38 is not updated, the channel button 38 is checked, and the process returns to step 61. If it is determined that a map change has occurred, the process proceeds to the channel memory update process shown in FIG.
[0064]
FIG. 19 is a processing flow showing channel memory update processing.
(Step 71) It is checked whether or not the currently selected channel (reception frequency) indicated by the variable SelCh exists in the effective broadcast station list of the map number Mn corresponding to the current position.
(Step 72) If it exists, the variable Mo value already set in the channel memory 33 is updated with Mn. This relates to step 66 described in FIG. 18, and after this process (re-update of channel memory 33), this process (re-update of channel memory) is not performed unless a map change occurs again. Means. That is, when there is a currently selected channel indicated by the variable SelCh in the effective broadcast station list of the map number Mn, the channel button (channel memory) to which the SelCh is assigned should not be changed as much as possible. However, the process means that the map change is determined only once at the first occurrence, and thereafter, unless there is a further map change.
[0065]
(Step 75) Next, the reception sensitivity is checked at a low specified value (Base2).
(Step 76) If the reception sensitivity check is OK, the channel buttons (channel memory) are reassigned (reset) to other effective broadcast stations so that the channel button (channel memory) assignment of the variable SelCh does not change. ).
[0066]
(Step 73) If the currently selected channel (reception frequency) does not exist in the effective broadcast station list at the current position Mn in Step 71, the current position Mn exists in the area adjacent area of Mo. Check whether or not.
Whether or not it is within the Mo area adjacent area means whether or not the Mo rectangular area exists in an area that is widened by a constant d.
(Step 75, Step 74) If it is determined that the current position Mn is within the Mo area adjacent area, a reception sensitivity check is performed with a low specified value (Base2), and if it is determined that it is out of the area, a high specified value (Base1) Then, check the reception sensitivity.
(Step 76) If the sensitivity is OK in Step 75 and Step 74, the channel buttons (channel memory) are reassigned (reset) to other effective broadcast stations so that the channel button (channel memory) assignment of the variable SelCh does not change. ).
(Step 77) If the sensitivity is NG in step 74, the variable Mo value is updated with Mn.
(Step 78) Next, the assignment of the channel button (channel memory) of the variable SelCh is completely ignored, and the re-update control of the channel memory is performed simply by the effective broadcast station list (Broadcast []) of the variable Mn.
It should be noted that in this processing, the point to be noted is that, even if it does not exist in the effective broadcasting station list, the setting of the channel button (channel memory) is tried to be utilized as much as possible by the sensitivity check. The point is not.
[0067]
  FIG., TFIG. 20A is a diagram for explaining the operation of the car navigation system with V, and FIG. 20A shows a display screen including an area around the area where the vehicle equipped with the car navigation system with a TV is present. FIG. 20 (B) showsThe figureIt is a figure which expands and shows only the area where vehicles exist among displays of 20 (A).
  For example, as shown in FIG. 20 (A), from point A on map M5 to point B (on the way, map M5 via map B2 (corresponding to the area adjacent area on map M2 and map M5)).ThroughTherefore, consider the case of moving to (move to map M4).
  Further, as shown in FIG. 15, the broadcasting station B1 is an effective broadcasting station in M5, but is not an effective broadcasting station in M2.
[0068]
Assume that the broadcasting station B5 is being received at the point A. When arriving near the point B (transition from the map M5 to the map M2), if the broadcasting station B5 cannot receive at all, the channel memory allocation is updated when the map M2 is entered. However, in most cases, the broadcast by the broadcasting station B5 can be received even if the sensitivity is slightly worse. That is, when the vehicle transitions from the map M5 to the map M2, the variable Mo value is frequently updated if the auto-tuning process is immediately activated for the map M2. Further, if the processing flow is maintained, the variable Mo value is not always updated and Mo = M5 is maintained. However, since the variable Mn value changes to M5 at point A and to M2 at point B, it is an incorrect value when returning to the map M5 point except for the allocation of the currently selected channel memory (channel button). (The value that the system does not want) may have been set.
[0069]
  However, in the present invention, when the vehicle crosses the boundary of the region, it is calculated immediately beforeFor example, in FIG.Regional scopeM5Stored in the channel memory(B _1, B _2, B _3, B _4, B _5, B _6, B ₇ …)At least one of(B ₅ )The auto-tuning process is performed while the allocation of the current area and the distance between the current position and the boundary of the area range calculated immediately before is within a specified value. By performing a reception sensitivity check on the result and performing auto-tuning processing while maintaining the stored contents of the channel whose reception sensitivity is equal to or higher than the reference value, usability at the boundary of the region can be improved.
[0070]
【The invention's effect】
  BookAccording to the invention, since the auto-tuning process is performed in addition to the auto-preset process, only the channels that can be received at a good level are automatically registered in the channel memory, and it is possible to save time and effort set by the user.
Since the allocation of at least one channel memory is maintained at the boundary of the area range, the allocation of the channel memory does not change for each movement destination of the mobile device and is easy to use.
[0075]
  AlsoEven if the mobile device exceeds the specified value at the boundary of the regional range, if the reception sensitivity is equal to or higher than the reference value, channel memory allocation is performed because the stored contents of the channel are maintained and auto tuning processing is performed. Easy to use without changing frequently.
[0076]
  FurthermoreSince the sensitivity reference value at the time of performing the auto-tuning process can be set low at the boundary of the region range, it is possible to prevent channel memory changes that are not intended for the user.
[Brief description of the drawings]
FIG. 1 of the present inventionUsed for implementationIt is a block diagram which shows a car navigation system with TV.
FIG. 2 is a diagram showing an external shape of a car navigation system with a TV.
FIG. 3 is a diagram showing registered contents of a preset database.
FIG. 4 is a diagram illustrating a state in which a receivable channel is registered in a channel memory.
FIG. 5 is a diagram showing registered contents of a database in a region number calculating means.
FIG. 6 is a diagram showing digital information of television broadcast radio waves.
FIG. 7 is a flowchart showing processing when power is turned on (auto-preset processing).
FIG. 8 is a flowchart showing an auto-tuning process.
FIG. 9 is a flowchart showing processing when the reception channel of the television is changed.
FIG. 10 is a flowchart showing processing at the time of power-on of a simple television receiver that does not include a car navigation system.
FIG. 11 is a flowchart showing processing when an electronic program guide displaying only channels registered in the channel memory is displayed.
FIG. 12 shows the present invention.One example to explainIt is a block diagram which shows a car navigation system with TV.
FIG. 13 is a diagram showing an external shape of a car navigation system with a TV.
FIG. 14 is a diagram showing registered contents of a channel memory.
FIG. 15 is a diagram showing registered contents in a regional database.
FIG. 16 is a diagram showing registered contents of a constant / variable memory.
FIG. 17 is a flowchart showing processing when the first TV function is activated or when a reset button is pressed.
FIG. 18 is a flowchart showing processing when switching to the TV function from the car navigation display mode or when the power is turned on in the TV function mode when registration in the channel memory is performed.
FIG. 19 is a flowchart showing channel memory update processing;
FIG. 20 is a diagram for explaining the operation of a car navigation system with a TV mounted on a mobile device.
FIG. 21 is a block diagram illustrating a configuration of a conventional television with an auto-tuning function.
FIG. 22 is a diagram showing the external shape of a channel switch and a channel up / down switch.
FIG. 23 is a block diagram illustrating a configuration of a conventional television with an auto preset function.
FIG. 24 is a diagram illustrating a state in which a receivable channel is registered in a channel memory.
FIG. 25 is a diagram showing a display screen when channel setting is manually performed.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 ... Detection demodulation part, 12 ... Input means, 121 ... Channel switch, 122 ... Channel up / down switch, 123 ... Car navigation related input means, 124 ... Power switch, 13 ... Display part, 14 ... Audio part, 15 ... Car navigation processing part , 16 ... microcomputer, 17 ... channel memory, 18 ... preset database, 19 ... area number calculating means, 20 ... auto-tuning processing unit, 21 ... program information database, 22 ... header, 23 ... data indicated by 0 and 1, 24 …Checksum.

Claims (1)

A preset database in which multiple broadcast frequency information is associated with multiple regions;
Region designation means;
A program designating means for designating a viewing broadcast program;
A channel memory for storing broadcast frequency information corresponding to the area designated by the area designation means;
Auto-tuning means for judging whether or not the received content is good for each of the plurality of broadcast frequency information stored in the channel memory, without user confirmation;
Means for registering in the channel memory only the broadcast frequency information whose reception content determined by the auto-tuning means is good at the initial registration of the broadcast frequency information in the channel memory;
Position information acquisition means for obtaining current position information;
A table for converting the position information obtained by the position information acquisition means into area information of the preset database;
Distance calculating means for calculating whether the distance between the current position and the boundary of the area range calculated immediately before is within a specified value;
Maintains at least one assignment of the contents of the channel memory to local range calculated in the immediately preceding, the have line auto-tuning process, when the calculated result of the distance calculation means is within a said specified value, Broadcast reception comprising: means for performing a reception sensitivity check on an auto-tuning result of the area range calculated immediately before, and performing an auto-tuning process while maintaining a stored content of a channel having a reception sensitivity equal to or higher than a reference value apparatus.

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