JP2006340160A - Broadcast receiver and receiving channel display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a broadcast receiver capable of surely displaying whether a broadcast can be received or not while saving power. <P>SOLUTION: While a mobile phone 100 is on standby, a control section 1 drives a terrestrial digital tuner module 80 at search time intervals. An OFDM modulation signal of a channel selected as a search station is then received, and a transport stream (TS) resulting from demodulating the OFDM modulation signal is stored as a search result in accordance with the relevant channel. The control section 1 sequentially receives the OFDM modulation signals of all the channels of the search station. A bit error rate (BER) of a search result for each channel is then measured to determine, from the BER, whether a broadcast can be received or not. A channel determined as being capable of receiving a broadcast is displayed in a pict area 900 as a reception enabled station pict icon. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a broadcast receiving apparatus that receives a broadcast signal and generates and displays video information from the received broadcast signal, and a reception channel display method in the broadcast receiving apparatus.

  2. Description of the Related Art Conventionally, broadcast receiving apparatuses that receive broadcasts such as television (hereinafter referred to as “TV”) broadcasts and radio broadcasts are known. In recent years, broadcast receiving apparatuses have been miniaturized, and for example, portable TVs and mobile phones with built-in receivers such as terrestrial digital TV broadcasts and analog TV broadcasts have become widespread.

  A stationary TV can receive a TV broadcast with stable quality by an antenna installed in an environment favorable for radio wave reception, whereas a portable TV is a stationary TV used at home and the like. You can watch TV on the go. However, since a portable TV is carried by a user, the reception state may change and reception sensitivity may deteriorate.

The following techniques are known as countermeasures against such changes in reception sensitivity due to user movement.
(1) In the mobile TV receiver installed in the car, from the position information measured by the GPS device also installed in the car, the broadcast station area to which the mobile station belongs and the neighboring broadcast station area are determined, There is known a mobile TV receiving apparatus that detects and displays the actual reception sensitivity of each channel including a neighboring broadcast station area by receiving a broadcast of a channel corresponding to each determined broadcast station area. (For example, refer to Patent Document 1).

(2) By detecting a reception state such as radio wave reception sensitivity and reception availability and displaying the reception state in association with the position information measured by the GPS device at the time of detection, a point where the user has moved A receiving apparatus that displays the reception sensitivity in a region is known (for example, see Patent Document 2).

(3) A digital broadcast receiver that judges whether or not a reception state of a broadcast wave of a certain channel (broadcasting station) is good, and displays a channel with a bad reception state on the electronic program table separately from other channels. It is known (see, for example, Patent Document 3).

(4) Based on the reception sensitivity information obtained from the OFDM demodulator, it is determined whether or not the current reception sensitivity satisfies the reference value necessary for receiving the broadcast of the designated channel, and the reference value is satisfied. A digital broadcast receiving apparatus that displays an image when it is present and displays information indicating that reception is impossible and reception sensitivity information when it is not satisfied is known (for example, see Patent Documents 4 and 5).

JP-A-5-83648 JP-A-10-185598 JP 2003-219303 A JP 2004-180271 A JP 2004-228695 A

However, the techniques of Patent Documents 1 to 5 have the following problems.
That is, the techniques of Patent Documents 4 and 5 can know whether or not reception is possible at the place (reception environment) for the first time by starting reception of the broadcast. For this reason, the user can know whether or not the broadcast can be viewed for the first time after giving the broadcast start instruction.

  Moreover, although the technique of patent document 3 can know whether broadcast reception is possible for each channel, the user must take one step of referring to the electronic program guide once before viewing the broadcast, and is easy to use. It got worse.

  In addition, a method of displaying the reception sensitivity by the techniques of Patent Documents 1 and 2 can be considered, but in this case, it is necessary to always drive a receiver for TV broadcasting or radio broadcasting. In the case of TV broadcasting, it is necessary to operate a circuit related to video display by displaying video. For this reason, the problem that the battery consumed for video display increases may arise. This problem is not a problem if it is a device that only receives digital broadcasts. However, when a wireless communication terminal such as a mobile phone is provided with a digital broadcast reception function, it has a considerable impact on the original wireless communication function. .

  The present invention has been made in view of the problems as described above, and an object of the present invention is to realize a broadcast receiving apparatus that can reliably display whether or not broadcast reception is possible while saving power. is there.

In order to solve the above problems, the broadcast receiving device according to claim 1 is:
Broadcast receiving means;
Display means comprising a first display area and a second display area;
Generating means for generating video information from a broadcast signal received by the broadcast receiving means;
First display control means for displaying the video information generated by the generating means in the first display area;
Determining means for driving the broadcast receiving means when the generating means is not driven, and determining for each channel whether broadcast reception is possible;
Second display control means for displaying the result of determination by the determination means in the second display area;
It is characterized by having.

Invention of Claim 2 is invention of Claim 1, Comprising:
The second display control means includes
According to the determination result of the determination means, a receivable station is displayed in the second display area as a channel capable of receiving broadcast.

Invention of Claim 3 is invention of Claim 1 or 2, Comprising:
The second display control means includes
According to the determination result of the determination means, the number of channels capable of receiving broadcasts is displayed in the second display area.

According to a fourth aspect of the present invention, there is provided a reception channel display method in a broadcast receiving apparatus that receives a broadcast signal and generates and displays video information from the received broadcast signal.
A determination step for determining, for each channel, whether or not broadcast reception is possible when the video information is not generated;
A display control step for displaying the determination result in the determination step on the display unit;
Is further provided.

The program according to claim 5 is stored in a computer.
A determination step of determining for each channel whether or not the broadcast reception is possible when video information is not generated by broadcast reception;
A display control step for displaying the determination result in the determination step on the display unit;
It is characterized by executing.

  According to the first, fourth, and fifth aspects of the present invention, when video information is not generated, whether or not broadcast reception is possible for each channel is determined and a determination result is displayed. Thereby, the user can confirm whether or not broadcast reception is possible for each channel even when the video information is not displayed. In addition, since it is not necessary to drive the generation unit, power consumption can be suppressed. Therefore, it is possible to realize a broadcast receiving apparatus that can reliably display whether or not broadcast reception is possible while saving power.

  According to the second aspect of the present invention, the same effect as that of the first aspect of the invention can be obtained. Of course, since the broadcast-receivable channel is displayed, the broadcast channel that can be viewed by the user is displayed. Can be confirmed.

  According to the third aspect of the present invention, it is possible to obtain the same effect as the first or second aspect of the invention. It is possible to check the number of channels for various broadcasts.

[First Embodiment]
A first embodiment in which the broadcast receiving apparatus of the present invention is applied to a mobile phone equipped with a reception function for terrestrial digital TV broadcasting will be described in detail below with reference to FIGS.

  First, FIG. 1 is an example of a front view and a rear view of the mobile phone 100. As shown in the figure, the mobile phone 100 includes an antenna ANT, a reception speaker 70, a transmission microphone 72, a right speaker 78R and a left speaker 78L of a stereo speaker 78, a camera 60, a camera flash 66, a main display 90, and a sub display 91. , A key matrix 40, a detachable rechargeable battery 110, and an earphone jack 75, and are configured to be foldable by a hinge 38.

  The antenna ANT includes a radio antenna ANT2 that transmits and receives radio waves and a TV antenna ANT8 that receives TV broadcasts. The mobile phone 100 is connected to a wireless communication network (including a wireless telephone network) via a wireless antenna ANT2. Then, the reception voice received by performing the wireless call is output as a voice from the reception speaker 70, and the voice input from the transmission microphone 72 is modulated and transmitted.

  The key matrix 40 includes an enter key 41, a cursor key 42, a TV key 43, a menu key 44, a clear key 45, a call start (off hook) key 46, a call end (on hook) key 47, and the like.

  The cursor key 42 is a key for performing screen scrolling and selection operation, and is configured to be able to detect four directions, up, down, left, and right. The user presses the menu key 44 to display the menu list. Then, a function is selected from the menu list and a setting content is changed by pressing the cursor key 42, and further, a function selection and a setting content change are determined and confirmed by pressing the enter key 41, and various settings of the mobile phone 100 are set. I do.

  In addition to the radio wave reception status and the remaining battery capacity of the mobile phone 100, the main display 90 is a picto area 900 that displays a receivable channel number and the number of broadcast stations, and a high resolution such as a TV image. A video display area 901 for displaying video is displayed. When the TV key 43 is pressed, TV video is displayed on the video display area 901 and TV audio is output from the stereo speaker 78. The receivable channel number and the number of broadcast stations may be displayed on the sub display 91.

  The clear key 45 is a key for clearing input contents and returning the display screen to the previous screen. The call start key 46 is a key for connecting to a telephone line at the time of outgoing or incoming calls, and the call end key 47 is a key for disconnecting from the telephone line. The call end key 47 also functions as a power switch of the mobile phone 100. When the call end key 47 is continuously pressed for a predetermined time (for example, 3 seconds), the mobile phone 100 is turned on / off (on / off). Is done.

  Earphone jack 75 is formed so that a plug of earphone microphone 74 can be inserted. The user inserts the earphone microphone 74 into the earphone jack 75 and connects it to the mobile phone 100, so that the voice input of the transmission microphone 72, the voice output of the reception speaker 70, and the voice output of the stereo speaker 78 are output from the earphone microphone 74. Can be switched to voice input / output.

  Further, the main display 90 is configured as shown in FIG. 5A during standby when the wireless call and the TV function are not executed. That is, the mobile phone 100 displays an image set in advance in the mobile phone 100 in the video display area 901 at the time of standby, and the picto area 900 has a reception sensitivity pict icon 902 and a battery remaining pict icon 903. In addition, receivable station pictogram icons 904 and 905 are displayed.

  The reception sensitivity pictogram icon 902 represents the reception sensitivity of a radio signal emitted from the radio base station, the battery remaining amount pictogram icon 903 represents the battery remaining amount of the rechargeable battery 110, and the receivable station pictogram icons 904 and 905 represent broadcasting. Represents a channel of a broadcast station that can be received. These reception sensitivity pictogram icon 902, battery remaining capacity pictogram icon 903, and receivable station pictogram icons 904 and 905 are periodically updated according to the use state and use environment of the mobile phone 100.

  FIG. 2 is a block diagram illustrating an example of a functional configuration of the mobile phone 100. According to the figure, the mobile phone 100 includes a control unit 1, an RF unit 2, a driver unit 3, an input unit 4, a storage unit 5, a camera unit 6, an audio processing unit 7, a TV unit 8, a main display 90, and a sub display. 91 and the power supply unit 10.

  The control unit 1 is a central processing unit that performs processing based on a predetermined program in accordance with an input instruction and transfers instructions and data to each functional unit. For example, a base band IC Consists of. Specifically, the control unit 1 reads a program stored in a program ROM (Read Only Memory) 50 in accordance with an operation signal input from the input unit 4 and executes processing according to the program. Then, the processing result is displayed on the main display 90 and the sub display 91. The control unit 1 includes a crystal oscillator, and performs time measurement using the crystal oscillator.

  Note that the control unit 1 in the first embodiment may include a DSP (Digital Signal Processor) or may function as a DSP in software. The DSP is a processor for digital signal processing, which encodes audio signals and video signals, or decodes digital data to extract audio data and video data.

  The RF unit 2 is connected to a radio base station on a radio communication network (including a radio telephone network) via a radio antenna ANT2 built in the antenna ANT based on an instruction input from the control unit 1 to perform voice Perform wireless communication and data communication for calls. As a modulation / demodulation method of a radio signal transmitted / received between the RF unit 2 and a radio base station, various known methods such as a PDC (Personal Digital Cellular) method, a CDMA (Code Division Multiple Access) method, a GSM (Global System for Mobile communication) method, etc. Any of the techniques may be used.

  The driver unit 3 includes an LED (Light Emitting Diode) driver 30, a motor driver 32, and a USB (Universal Serial Bus) driver 34. The LED driver 30 performs drive control of the key matrix 40, the backlight LED of the LCD 90, the LED for the camera flash 66, and the like.

  The motor driver 32 performs drive control of various motors M. The USB driver 34 detects whether or not a USB cable (not shown) is connected to the IF connector 36, and controls data communication with an external device via the USB cable.

  The input unit 4 is an input device including a key matrix 40 necessary for inputting an instruction for starting execution of a program and inputting various information, and outputs a key pressing signal pressed by the user to the control unit 1.

  The storage unit 5 includes a program ROM 50, a work RAM (Random Access Memory) 52, and a data storage RAM 59. The program ROM 50 is composed of a NOR flash memory, or a NAND flash memory / mask ROM, and is used for programs necessary for the operation of the mobile phone 100 such as various initial settings, hardware inspections and various functions, and the execution of the programs. Store such data.

  The work RAM 52 is composed of a DRAM, and temporarily stores data, application programs, and the like for realizing various functions related to the operation of the mobile phone 100. Data stored in the program ROM 50 and the work RAM 52 will be described later.

  The data storage RAM 59 is composed of a readable and writable nonvolatile memory, and stores various setting information of the mobile phone 100, user personal information such as an address book, image data photographed and generated by the camera unit 6, and the like.

  The camera unit 6 includes an imaging element 62 such as a complementary metal oxide semiconductor (CMOS) sensor or a charge coupled device (CCD) sensor, an optical lens 64, an A / D converter (not shown), and the like. This corresponds to the camera 60. An optical image of a subject input through the optical lens 64 is photoelectrically converted by the imaging device 62, and an electric signal obtained by the photoelectric conversion is A / D converted by an A / D converter, thereby obtaining digital image data. Is generated. The generated image data is output to the control unit 1 and stored in the data storage RAM 59.

  The audio processing unit 7 includes a reception speaker 70, a transmission microphone 72, an earphone microphone 74, a sound source IC 76, and a stereo speaker 78. The reception speaker 70 D / A converts and amplifies the reception voice received by the wireless communication of the RF unit 2 and outputs the voice. The transmission microphone 72 performs A / D conversion on the input transmission voice and transmits it via the RF unit 2. The earphone microphone 74 is configured by integrally forming an earphone and a microphone and having a connector that can be inserted into the earphone jack 75. When the control unit 1 detects that the earphone microphone 74 is connected, the control unit 1 inputs and outputs received voice, transmitted voice, and TV voice via the earphone microphone 74.

  The sound source IC 76 controls sound output to the right speaker 78R and the left speaker 78L of the stereo speaker 78, stores sound sources such as ringtones, and controls output of the sound sources.

  The TV unit 8 is a circuit unit for receiving a terrestrial digital TV broadcast including audio and video. The TV unit 8 includes a terrestrial digital TV tuner module (hereinafter abbreviated as “TV module”) 80, a TV accelerator 82, and a TV antenna ANT8 built in the antenna ANT.

  Terrestrial digital TV broadcasting uses OFDM (Orthogonal Frequency Division Multiplexing), which can multiplex and transmit / receive multiple signals (radio waves), and multiplex multiple signals (radio waves). It is a thing.

  When the control unit 1 detects that the TV key 43 is pressed by the user, the control unit 1 drives the TV unit 8. The TV function received by the TV unit 8 is output to the main display 92 as an image and the stereo speaker 78 as an audio output, thereby realizing the TV function.

  The TV module 80 tunes the TV antenna ANT8, thereby receiving a signal (OFDM modulated signal) having a frequency corresponding to the channel of the broadcast station selected and designated by the user and outputting the signal to the TV accelerator 82. It is.

  The TV module 80 performs A / D conversion on the received OFDM modulation signal, and performs synchronization processing, FFT operation (Fast Fourier Transform), and error correction processing on the digital signal to perform H.264 conversion. A TS (Transport Stream) in which a video signal and an audio signal are compressed according to the H.264 standard is extracted. Since each process until TS is extracted is a known technique, the description thereof is omitted.

  The TV accelerator 82 is a circuit unit with relatively high power consumption that separates the video signal and the audio signal from the TS extracted by the TV module 80 and decodes the video signal and the audio signal, respectively. Specifically, the TV module 80 is controlled via the I2C standard bus 84 to initialize the TV module 80, and then the TS output from the TV module 80 is obtained via the TS interface 86. To do. Then, the video signal and the audio signal are separated from the TS and decoded, and the video data obtained by the decoding is output to the video display area 901 of the main display 90 and the audio data to the sound source IC 76 via the driver 907 described later. By doing so, video output and audio output of the TV broadcast are performed. The TS is encoded by any known technique such as MPEG (Moving Picture Experts Group), and is decoded by a decoding method corresponding to the encoded method.

  As described above, the control unit 1 controls the entire TV unit 8 by detecting that the TV key 43 is pressed, and realizes a TV function for outputting video and audio of terrestrial digital TV broadcast. In contrast, when the TV function is not activated, that is, when the TV unit 8 is not driven, the control unit 1 drives only the TV module 80 via the I2C bus 89 and directly controls it. Then, it is determined whether or not the TV broadcast of all channels of the broadcast station or the channel set in the search station 53 can be received, and the control signal 88 is output to the control unit 1 without using the TV accelerator 82. The control unit 1 drives the driver 907 based on the control signal 88 so that the mobile phone 100 can be received in the picto area 900 of the main display 90 when the mobile phone 100 is in the open state, and the sub display 91 when the mobile phone 100 is in the closed state. Pictograph icons 904 and 905 are displayed.

  The main display 90 has a resolution of QVGA or higher, receives a drive signal from the driver 907, and displays a high-resolution video with a large data capacity in the video display area 901. Display in the pictogram area 900. It is also possible to control to display data with a small capacity such as a pict icon on the sub display 91.

  The power supply unit 10 includes a power supply circuit, a rechargeable battery 110, and the like, and supplies power to each functional unit based on instructions from the control unit 1. In particular, as characteristic control of the present embodiment, switching control of turning on / off the power supply to the TV module 80 and the TV accelerator 82 by the power supply unit 10 is performed.

  Specifically, based on an instruction from the control unit 1, the power supply to the entire TV unit 8 is switched or only the TV module 80 is supplied with power. In FIG. 2, power supply lines to the TV unit 8 and the TV module 80 are indicated by bold lines, and illustration of power supply lines to other functional units is omitted.

  FIG. 3A is a diagram showing an example of the data configuration of the program ROM 50. As shown in FIG. According to FIG. 5A, the program ROM 50 stores a standby screen display program 51 for realizing a standby screen display process (see FIG. 4). The control unit 1 starts the standby screen display process by reading the standby screen display program 51 from the program ROM 50 and developing it when the mobile phone 100 is powered on.

  FIG. 3B is a diagram illustrating an example of the data configuration of the work RAM 52. According to FIG. 5B, a search station 53, a search result table 54, a receivable station 55, and a search time interval 56 are stored.

  The search station 53 is a channel of a broadcast station to be searched for a channel capable of receiving broadcasts, and is selected and set in advance by the user. The control unit 1 stores the channel selected and set by the search station setting operation in the work RAM 52 as the search station 53. The search station setting operation is a series of operations for selecting / determining a desired channel from all broadcast station channels (for example, 1 ch to 60 ch) displayed by selecting “search station setting” from the menu list. is there. When the search station setting operation is not performed, the area for storing the search station 53 is cleared.

  The control unit 1 drives and controls the TV module 80, sequentially designates the channels stored as the search station 53, and receives the OFDM modulated signal corresponding to the channels. Then, the TS obtained by demodulating the received OFDM modulated signal is stored in the search result table 54 in association with the channel as a search result.

  If the search station setting operation is not performed and the search station 53 remains cleared, the channels of all broadcast stations are sequentially designated, and the TS of the OFDM modulation signal corresponding to the channel is searched. To remember.

  The search result table 54 is a data table for storing the search results (TS) obtained by performing broadcast reception of the channels of the search station 53 or the channels of all broadcast stations as described above in association with each channel. .

  The receivable station 55 is a channel of a broadcast station capable of receiving broadcast, and stores a channel searched based on the search result table 54. More specifically, the control unit 1 reads out the search results stored in the search result table 54 for each channel, and determines the error rate (Bit Error Rate; hereinafter referred to as “BER”) of the search results (TS). taking measurement. If the measured BER is lower than a specified value (threshold value), it is determined that the quality of the OFDM modulation signal of the channel is good and broadcast reception is possible, and the channel is set as the receivable station 55. Remember.

  The control unit 1 displays the display unit representing the channel stored as the receivable station 55, that is, the channel capable of receiving the broadcast, as the receivable station pictogram icons 904 and 905 in the pictogram area 900 as shown in FIG. . The receivable station pictogram icons 904 and 905 are display bodies including channel numbers of broadcasting stations. By displaying the receivable station pictogram icons 904 and 905, it is possible to let the user know which channel the broadcast can be viewed.

  The search time interval 56 is a time interval for driving the TV module 80 to search for a channel capable of receiving broadcasts, and is set by the user. The control unit 1 stores the time interval (for example, 1 hour) set by the user in the work RAM 52 as the search time interval 56. Then, the TV module 80 is driven at intervals of the search time interval 56 to search for a channel capable of receiving broadcasts.

  Next, specific processing contents of the standby screen display processing of the mobile phone 100 will be described using the flowchart of FIG. The control unit 1 displays a preset image in the video display area 901 of the main display 90 after turning on the power. On the other hand, the reception sensitivity of the radio signal received via the RF unit 2 and the rechargeable battery 110 The battery capacity is periodically detected, and the display of the reception sensitivity pict icon 902 and the battery remaining amount pict icon 903 is updated. Further, the standby screen display program 51 is read from the program ROM 50, and the standby screen display process is started to update the display of the receivable station pictogram icons 904 and 905.

  First, when the control unit 1 starts the standby screen display process and determines that a search station setting operation has been performed by the user (step S1; Yes), the channel selected according to the operation is set as the search station 53. Store in the work RAM 52 (step S3). On the other hand, when the search station setting operation is not performed (step S1; No), the process proceeds to step S5 as it is.

  Then, the power supply unit 10 is controlled to turn on the TV module 80 (step S5), and the TV module 80 is directly initialized via the I2C bus 89 (step S7). The control unit 1 determines whether or not the channel as the search station 53 is stored in the work RAM 52 (step S9). If the search station 53 is stored (step S9; Yes), the channels in the search station 53 are sequentially designated and the OFDM signal of the channel is received (channel search) (step S11).

  Then, the TS obtained by the channel search is stored for each channel in the search result table 54 (step S13), and it is determined whether or not the channel search of all the channels in the search station 53 has been performed (step S15). If it is determined that the channel search of all the search stations 53 has not been completed (step S15; No), the process proceeds to step S11 to perform channel search by sequentially specifying channels. If it is determined that the channel search of all the search stations 53 has been completed (step S15; Yes), the process proceeds to step S23.

  on the other hand. If it is determined in step S9 that the search station 53 is not stored (step S9; No), the control unit 1 sequentially designates the channels (for example, 1ch to 60ch) of all the broadcast stations, A channel search is performed (step S17).

  Then, the TS obtained by the channel search in step S17 is stored for each channel in the search result table 54 (step S19), and it is determined whether the channel search for the channels of all the broadcasting stations has been performed (step S21).

  If it is determined that the channel search for all channels has not been completed (step S21; No), the process proceeds to step S17 to sequentially specify channels and perform the channel search again. If it is determined that the channel search for all channels has been completed, the BER for each channel is measured from the search results stored in the search result table 54 (step S23), and the measured BER (measured BER) is defined. If it is determined that the value is less than the value (threshold) (step S25; Yes), the channel of the measurement BER is stored in the work RAM 52 as the receivable station 55 (step S27).

  On the other hand, if it is determined that the measurement BER exceeds the specified value (threshold value) (step S25; No), the process proceeds to step S29, and is the BER measurement of all search results stored in the search result table 54 completed? It is determined whether or not (step S29). If it is determined that all the BERs of the search results have not been measured (step S29; No), the process proceeds to step S23, and the BER measurement for each channel is repeated.

  If it is determined in step S29 that all the BERs of the search results have been measured (step S29; Yes), the power of the TV module 80 is turned off (step S31).

  As described above, when the search station 53 is set in advance, only the channel search for the search station 53 is performed, so that the consumption of driving power of the TV module 80 is reduced as compared with the case of performing the channel search for all channels. In addition, the repetition of channel search can be shortened.

  Thereafter, the control unit 1 turns off the power of the TV module 80 in step S31, and then determines whether there is a channel stored as the receivable station 55 (step S33). If the channel as the receivable station 55 is stored (step S33; No), the receivable station pictogram icons 904 and 905 including the channel number of the channel are turned on in the picto area 900 to update the display. (Step S35). If the channel as the receivable station 55 is not stored (step S33; Yes), the receivable station pictogram icons 904 and 905 are not turned on.

  FIG. 5A is an example of a display example of the main display 90. In this picto area 900, a receivable station pict icons 904 and 905 are displayed together with a receiving sensitivity pict icon 902 and a remaining battery level pict icon 903. ing. The receivable station pict icon 904 indicates that the broadcast reception of the 1ch broadcast station is possible, and the receivable station pict icon 905 indicates that the broadcast reception of the 10ch broadcast station is possible. The display of the receivable station pictogram icons 904 and 905 allows the user to know which channel of the broadcast can be viewed without executing the TV function, that is, without activating the TV accelerator 82.

  When the receivable station pictogram icons 904 and 905 are not displayed, it can be known that there is no TV broadcast that can be viewed. For this reason, in spite of the execution of the TV function, it is no longer possible to view the video, and the driving power of the TV unit 8 related to the execution of the TV function can be saved.

  On the other hand, the control unit 1 starts timekeeping (step S37) and waits until the time reaches the search time interval 56 (step S39). If the measured time exceeds the search time interval 56 (step S39; Yes), the process proceeds to step S5, the channel search is performed again, and the display of the receivable station pictogram icons 904 and 905 is updated.

  As described above, according to the first embodiment, the TV module 80 is driven every search time interval 56 to determine whether or not broadcast reception of each channel is possible, and the determination result is used as the receivable station pictographic icons 904 and 905. 900 is displayed. For this reason, even if the TV unit 8 is not always driven, it is possible to notify the user whether broadcast reception is possible or not, and the power consumption of the mobile phone 100 can be suppressed.

  In addition, since the broadcast reception is performed only by driving the TV module 80 in the TV unit 8, power consumption can be suppressed as compared with driving the entire TV unit 8, and further power saving can be achieved. Further, when the search station 53 is set, only the channel search of the search station 53 is performed, so that the power consumption can be reduced as compared with the channel search of all broadcasting stations.

  Further, the user can confirm whether or not the TV broadcast of the channel can be viewed by selecting the desired channel by the search station setting operation, using the receivable station pictogram icons 904 and 905. In addition, since the receivable station pictogram icons 904 and 905 are displayed and updated at any time in the picto area 900, the user can know which channel of the TV broadcast can be viewed before executing the TV function.

  In the first embodiment, the receivable station pictogram icons 904 and 905 are displayed as shown in FIG. 5A as the determination result of whether or not broadcast reception is possible. . That is, the number of channels stored in the receivable stations 55 is counted, and the number of channels is displayed as a receivable station number pictogram icon 906 in the picto area 900. Thus, the user can confirm how many channels are available for viewing TV broadcasts before the TV function is activated. Further, both the receivable station pict icons 904 and 905 and the receivable station number pict icon 906 may be displayed.

[Second Embodiment]
Next, a second embodiment of a mobile phone to which the present invention is applied will be described with reference to FIGS. An overview of the mobile phone 100a in the second embodiment is the same as the mobile phone 100 of the first embodiment shown in FIG. In addition, the same code | symbol is attached | subjected to the component same as the mobile telephone 100 of 1st Embodiment, and the description is abbreviate | omitted.

  FIG. 6 is a block diagram illustrating an example of a functional configuration of the mobile phone 100a. The mobile phone 100a has a configuration in which the positioning unit 11 is added to the mobile phone 100 shown in FIG. 2 and the work RAM 52 in FIG. 3B is replaced with the work RAM 52a in FIG.

  The positioning unit 11 is a functional unit that measures the current position of the mobile phone 100, and includes a GPS (Global Positioning System) antenna ANT11 and a GPS receiver. The control unit 1 drives the positioning unit 11 every search time interval 56 to cause the positioning unit 11 to receive a GPS signal transmitted from a GPS satellite.

  The positioning unit 11 measures the current position (for example, latitude and longitude) based on the GPS signal received via the GPS antenna ANT11 and outputs the current position to the control unit 1. The control unit 1 stores the current position output from the positioning unit 11 in the work RAM 52a.

  FIG. 7 is a diagram illustrating an example of a data configuration of the work RAM 52a. According to the figure, the work RAM 52a stores a search station 53, a search result table 54, a receivable station 55, a search time interval 56, a current position 57, and a previous positioning position 58.

  The current position 57 is a current position measured by the positioning unit 11. When the current position is output from the positioning unit 11, the control unit 1 stores and updates the current position 57 already stored as the previous positioning position 58, and then updates the work RAM 52a with the output current position. The control unit 1 calculates the difference between the current position 57 and the previous positioning position 58 to obtain the movement distance (transition) of the mobile phone 100 at every search time interval 56.

  FIG. 8 is a flowchart for explaining specific processing contents of the standby screen display processing in the second embodiment. Note that the same step numbers are assigned to the same processing steps as the standby screen display processing in the first embodiment shown in FIG. 4, and description thereof is omitted.

  According to FIG. 8, when the standby screen display process is started, the control unit 1 turns on the TV module 80 after turning on the power of the TV module 80 and, for each channel of the search station 53 or every channel, as in the first embodiment. Channel search is performed to obtain a search result. Then, the BER for each channel is measured from the search result. If the BER is equal to or less than the specified value, the channel is stored in the work RAM 52a as the receivable station 55 (steps S1 to S39).

  Then, after waiting for the search time interval 56 (step S39; Yes), the control unit 1 drives the positioning unit 11 to measure the current position, and stores the current position 57 in the work RAM 52a (step S39). ). Next, a difference between the current position 57 and the previous positioning position 58 is calculated, and it is determined whether or not the difference is equal to or greater than a specified distance (for example, 100 m) (step S41).

  When it is determined that the difference is equal to or greater than the specified distance (step S41; Yes), the control unit 1 determines that the mobile phone 100a has moved more than the specified distance, shifts the process to step S5, and starts the channel search again. . On the other hand, if the calculated difference is less than the specified distance, the process proceeds to step S37, and the current position is measured again after the search time interval 56 has elapsed.

  As described above, according to the second embodiment, if the current position is measured and it is determined that the mobile phone 100a has moved from the current position by a predetermined distance or more, the TV module 80 is driven to determine whether or not each channel can be received. And update the display of the receivable station pictogram icon. For this reason, for example, when the moving distance of the user such as sleeping or at work is small, that is, when the reception environment does not change, the channel search is not performed, and thus the mobile phone 100a with further power saving design can be realized. it can.

  In the second embodiment, the positioning method by the positioning unit 11 has been described by applying the positioning based on the reception of the GPS signal. However, the present invention is not limited to this and can be appropriately changed. For example, the acceleration of the movement of the mobile phone may be detected by an acceleration sensor, and the channel search may be started when the detected acceleration exceeds a predetermined value. Further, the channel search may be started when the communication area is switched across the communication area managed by each radio base station.

  In addition, the mobile phone of the present embodiment has been described as receiving terrestrial digital TV broadcast, but for example, receiving terrestrial analog TV broadcast to display TV video and output TV audio. Alternatively, FM radio broadcast or AM radio broadcast may be received and the radio broadcast may be output as sound. However, when receiving radio broadcasts, video display output is not performed.

  In this case, whether broadcast reception is possible is determined based on the amount of power of the received signal. For example, in the case of a terrestrial analog TV broadcast, if the amplitude (power amount) of the TV broadcast received by the TV antenna ANT8 is equal to or higher than a predetermined level, that is, if the reception sensitivity is good, the TV broadcast Receivable station pictogram icons 904 and 905 are displayed on the assumption that the broadcast reception of the channel is possible. If the level is lower than the level, that is, if the reception sensitivity is poor and the TV broadcast is weak, the receivable station pictogram icon The display of 904 and 905 is not performed. The application method in the case of radio broadcasting is the same as that for terrestrial analog TV broadcasting. In this case, since it is possible to determine whether broadcast reception is possible without demodulating the OFDM modulated signal and extracting the TS, further reduction in power consumption can be expected.

  The broadcast receiving apparatus of the present invention has been described as being applied to a mobile phone. For example, a wireless communication device that performs voice communication with a TV broadcast or radio broadcast receiver, a built-in PDA (Personal Digital Assistant), PHS, etc. It can be applied to other electronic devices.

1 is an example of an overview of a mobile phone to which the present invention is applied. The block diagram which shows an example of a function structure of the mobile telephone in 1st Embodiment. (A) in 1st Embodiment is a figure which shows an example of a data structure of program ROM, (b) is a work RAM. The flowchart for demonstrating a standby screen display process. The figure which shows an example of the standby screen of a mobile telephone. The block diagram which shows an example of a function structure of the mobile telephone in 2nd Embodiment. The figure which shows an example of the data structure of the work RAM in 2nd Embodiment. The flowchart for demonstrating the standby screen display process in 2nd Embodiment.

Explanation of symbols

100 Mobile phone (broadcast receiver)
1 control unit (determination means, first display control means, second display control means)
2 RF unit 4 input unit 5 storage unit 50 program ROM
51 Standby screen display program 52 Work RAM
53 Search station 54 Search station table 55 Receivable station 56 Search time interval 57 Current position 58 Previous positioning position 7 Audio processing section 8 Television section (broadcast receiving means)
80 TV module (broadcast receiving means)
82 TV accelerator (generation means)
90 Main display (display means)
900 pictogram area (second display area)
901 Video display area (first display area)
10 Power supply part 11 Positioning part

Claims (5)

Broadcast receiving means;
Display means comprising a first display area and a second display area;
Generating means for generating video information from a broadcast signal received by the broadcast receiving means;
First display control means for displaying the video information generated by the generating means in the first display area;
Determining means for driving the broadcast receiving means when the generating means is not driven, and determining for each channel whether broadcast reception is possible;
Second display control means for displaying the result of determination by the determination means in the second display area;
A broadcast receiving apparatus comprising: The second display control means includes
2. The broadcast receiving apparatus according to claim 1, wherein a receivable station is displayed in the second display area as a broadcast-receivable channel according to a determination result of the determination unit. The second display control means includes
3. The broadcast receiving apparatus according to claim 1, wherein the number of channels capable of broadcast reception is displayed in the second display area in accordance with a determination result of the determination unit. In a reception channel display method in a broadcast receiving apparatus that receives a broadcast signal and generates and displays video information from the received broadcast signal.
A determination step for determining, for each channel, whether or not broadcast reception is possible when the video information is not generated;
A display control step for displaying the determination result in the determination step on the display unit;
A receiving channel display method, further comprising: On the computer,
A determination step of determining for each channel whether or not the broadcast reception is possible when video information is not generated by broadcast reception;
A display control step for displaying the determination result in the determination step on the display unit;
A program for running

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