JP2009118073A - Broadcast receiving terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve receiving conditions in channel scan. <P>SOLUTION: During the channel scan, transfer of data for display to a display is stopped, and display of a display picture 4c is simultaneously turned off. Thus, the channel scan is executed without being affected by noise resulting from an operation of the display. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a broadcast receiving terminal that receives a television broadcast, and more particularly to a channel scan technique.

A mobile phone with a TV function, which is a broadcast receiving terminal, has a function of executing a channel scan (see, for example, Patent Document 1).
In the channel scan, channels are sequentially selected, whether or not a plurality of channels can be received is checked, and channels that are determined to be received are registered in the channel list. The mobile phone displays this channel list as a menu and accepts channel selection from the user.
Japanese Unexamined Patent Publication No. 2006-13945

By the way, according to the analysis of the present inventor, it has been found that noise affecting reception of broadcast waves occurs due to the operation of the mobile phone itself.
Due to the influence of this noise, there is a risk that the number of channels determined to be receivable during channel scanning may be reduced.
It is also possible that channel scanning takes time.

That is, when the current position is near the boundary of the reception area of a predetermined channel, the broadcast wave is weak, so that it is severely affected by noise and it is determined that the predetermined channel cannot be received.
Further, when the desired reception level of the channel cannot be obtained, it takes more time to scan the channel than when a level at which the reception level is obtained is received.

  The present invention has been made in view of the above-described problems, and in a broadcast receiving terminal that receives a television broadcast such as a mobile phone, noise caused by the operation of the mobile phone itself is avoided or suppressed. The purpose is to perform a channel scan without being affected.

According to the analysis of the present inventor, in a broadcast receiving terminal having a display display function, display data is transferred to the display through a transfer cable or the like, and it has been found that radiation noise is emitted from the transfer cable or the like. ing.
Furthermore, it has been found that the noise is also generated from a back end unit such as an audio circuit, a CPU, and a memory, and a power source unit that supplies power to them.

As the amount of radiated noise tends to increase with the increase in data transfer speed due to the increase in screen size and resolution, the suppression of such noise is urgent.
Therefore, the broadcast receiving terminal according to the present invention is a broadcast receiving terminal having a television function, and includes a display, transfer means for transferring display data to the display, channel scan means for channel scanning, and channel scan means. And a transfer suppression unit that suppresses transfer of the display data by the transfer unit during scanning.

  According to the configuration described in the means for solving the problem, noise caused by the transfer of display data can be avoided during scanning, and channel scanning can be performed without being affected by noise.

Hereinafter, embodiments will be described by taking a mobile phone with a TV function as a broadcast receiving terminal as an example.
(Embodiment)
<Configuration>
FIG. 1 is a diagram showing an appearance of the mobile phone 2.

The cellular phone 2 is a folding type, and FIG. 1A shows the unfolded state and FIG. 1B shows the folded state.
The mobile phone 2 includes a display 4 for performing various displays, a speaker 6, an LED 8 capable of emitting a plurality of colors, and a key group 10 for receiving operations.
FIG. 2 is a functional block diagram of the mobile phone 2.

The mobile phone 2 includes a communication unit 12, a tuner unit 18, and a BE (back end) unit 20.
The communication unit 12 is a functional block that is connected to an antenna 12a, a speaker 14, and a microphone 16 and implements a call function of the mobile phone 2. The communication unit 12 includes a BB (baseband) unit and an RF (high frequency) unit. .

The tuner unit (front end unit) 18 receives a digital broadcast wave input from the TV antenna 18 a and outputs a TS (Transport Stream) to the BE unit 20.
The BE unit 20 includes a CPU 22, a memory 24, a transfer unit 26, a TS processing unit 28, a display control unit 30, an audio control unit 32, an LED control unit 36, and an operation unit 38.
The memory 24 includes a ROM and a RAM, stores various control programs and various application programs, and secures a program work area.

The CPU 22 executes a program stored in the memory 24. The CPU 22 has a known function for switching the frequency of the operation clock.
The transfer unit 26 includes, for example, a bus, and transfers data such as display data from the display control unit 30 to the display 4 and audio data from the audio output control unit 32 to the speaker 6.

The CPU 22 controls the transfer of data read from the main memory (memory 24) to the register by the data transfer command, and also stops and suppresses the data transfer.
The TS processing unit 28 decomposes the TS into video ES (Elementary Stream), audio ES, program information PSI / SI (Program Specific Information / Service Information), and the like, and decodes the video ES and audio ES.

The display control unit 30 performs display control of the display 4 based on the decoded video data.
The audio output control unit 32 controls the audio output to the speaker 6 based on the decoded audio data.
The LED control unit 36 controls on / off of light emission of the LED 8. Further, the LED 8 blinks in a predetermined pattern, or the emission color is switched.

The operation unit 38 includes various keys such as a key group 10 and receives operation inputs such as a channel scan start instruction and channel selection.
<Operation>
As described in the section for solving the problem, when the display 4 operates, high-frequency radiation noise is generated from a transfer cable or the like for transferring display data, and this is generated by the TV antenna 18a and the tuner unit. It has been clarified that the input sensitivity is reduced as noise on the 18 input circuit portions.

Although some noise countermeasures can be taken for each part of the noise generation source by a magnetic shield, a noise absorber, or the like, it is actually difficult to completely remove the noise.
For this reason, in the present embodiment, functions unnecessary for channel scanning are temporarily suppressed, and channel scanning is executed in a state where the influence of noise is reduced.
FIG. 3 is a flowchart related to the overall processing of the channel scan.

FIG. 4 is a flowchart illustrating channel scan preprocessing.
FIG. 5 is a flowchart showing channel scan processing.
FIG. 6 is a flowchart related to channel scan recovery processing.
FIG. 7 is a diagram illustrating transition of the screens 4a to 4e of the display 4 before and after channel scanning.

The processing related to the channel scan is basically realized by the CPU 22 executing the control program in the memory 24.
First, when the reception status of the channel being viewed deteriorates [S11: Yes, FIG. 7 (a) (b)], a menu for inquiring whether or not to start channel scanning is displayed. (S12: Yes, S13). The detection of the deterioration of the reception state is a known method, and for example, the case where the tuner cannot be locked due to frame synchronization with the broadcast wave is detected as deterioration.

In the preparation process, first, the LED 8 starts blinking (S21). Then, the data transfer to the display 4 is stopped (S22), and the operation clock of the CPU 22 is lowered (S23).
Also, during channel scanning, unlike normal viewing, the encoded video data and audio data are not decoded, so even if the operation clock of the CPU 22 is significantly reduced, there is no problem in operation.

For example, when the operation clock of the CPU 22 is 300 MHz, it is possible to suppress noise caused by the BE unit due to the high clock operation of the CPU 22 by reducing the operation clock to 3 MHz.
When the preparation process (S13) is completed, the process proceeds to a channel scan process (S14).
In the channel scan, as shown in FIG. 5, the CPU 22 sets the channel of the tuner unit 18 to C = 13 (S31), and waits until the tuner unit 18 completes the tuning (S32).

If it can be received (S33: Yes), the program information is acquired and registered in the channel list (S34). If reception is not possible (S33: No), it is registered in the channel list that reception is not possible (S35).
Steps S31 to S35 are repeated by increasing the channel by 1 until C = 62. The period from the start when C = 13 is set to when the tuning of C = 62 is completed is, for example, several minutes.

Since the transfer of display data is stopped during the channel scan, as shown in FIG. 7C, the screen 4c of the display 4 is in a state where nothing is displayed and only the LED 8 is blinking. Become.
As described above, since the transfer of the display data is stopped (FIG. 4: S22), the channel scan can be executed without being affected by the noise caused by the transfer. It should be noted that noise caused by this transfer can be avoided by stopping the transfer of the audio data in addition to the display data.

When the channel scan process (S14) is completed, the process proceeds to a return process (S15).
The return process is a process corresponding to the preparation, stops the blinking of the LED (S41), restarts the display data transfer to the display (S42), and restores the CPU operation clock (S43).
Subsequently, as shown in FIG. 7D, a channel list is displayed on the screen 4d of the display 4 (S16), channel selection is accepted from the list (S17), and the accepted channel is selected [FIG. 7E]. ].

Although the embodiments have been described above, examples of functions to be suppressed during channel scanning include the following examples. Hereinafter, it demonstrates as a modification which concerns on embodiment.
(Modification 1)
In the embodiment, in the preparation process, the transfer of display data to the display is stopped (FIG. 4: S22). However, noise can be suppressed by reducing the transfer speed without stopping.

As an operation of the first modification, a transfer speed, which is a transfer data amount per unit time, is reduced during scanning.
Methods for reducing the transfer speed include (1) reducing the 60 Hz frame rate to 30 Hz, (2) reducing the resolution, and (3) reducing color information (for example, reducing from 32 bits to 1 bit). Can be mentioned.

If the transfer speed is high, noise is likely to occur. Therefore, by reducing the transfer speed, channel scanning can be performed in a state where the influence of noise is reduced.
Further, during the channel scan, as shown in FIG. 8, it is possible to easily notify the user that the scan is in progress by displaying a message as shown in the screen 5.
(Modification 2)
In this modification, power supply and charging to functions that are not necessary for channel scanning are temporarily stopped.

FIG. 9 is a block diagram illustrating the flow of power of the mobile phone.
The cellular phone 40 includes a tuner unit 18, a BE unit 20, a display 4, a speaker 6, an LED 8, and a battery control circuit 42 that controls power supply from the battery 44 to each unit.
FIG. 10 is a diagram illustrating a preparation process according to the present modification.
First, the battery control circuit 42 stops the power supply by stopping the power supply to the communication unit 12, the display 4, and the speaker 6 (S51 to S53).

Data transfer is also stopped at the part where the power is turned off, and the display 4 and the speaker 6 also avoid noise caused by operation.
By turning off the power, data transfer can be stopped and noise caused by the operation of the display 4 and the speaker 6 can be avoided. In addition, since noise from the communication unit 12 during communication with the base station of the mobile phone may be generated, the noise can be avoided by turning off the power.

If charging is in progress (S54: Yes), charging is stopped (S55). This charging check is performed, for example, by comparing the terminal voltage of the battery with a threshold value, and the charging is stopped, for example, by switching that stops power supply to the booster circuit.
Even when the battery 42 is charged, noise that affects reception of broadcast waves may occur. Therefore, the noise can be avoided by stopping charging.

It should be noted that the power-off and the charging stop in steps S51 to S55 are resumed immediately after the channel scan is completed.
(Modification 3)
In the second modification, the power of the communication unit 12 is continuously turned off during the channel scan. However, in this modification, the operation is switched to the operation of the communication unit 12 during the channel scan (intermittent interruption). By doing so, it is possible to execute a channel scan in a good reception state while securing a communication call function as a mobile phone.

FIG. 11A is a flowchart according to the third modification.
During the channel scan (S61), the channel scan is temporarily stopped (S62), the communication unit power is turned on (S63), the communication with the base station (S64), and when the communication is completed, the communication unit is turned off (S65), Restart channel scanning.
FIG. 11B shows a timeline between the scanning operation and the communication operation.

As shown in this timeline, since the communication operation is switched even during the channel scan operation, the communication call function of the mobile phone can be maintained by the communication operation. Further, since the channel scan is temporarily stopped during the communication operation, the scan operation can be executed without being affected by noise caused by the communication operation.
For example, in the case of CDMA, the communication operation is executed once every about 5 seconds, and the time required for one communication is about 20 milliseconds.
<Supplement>
Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described content, and can be implemented in any form for achieving the object of the present invention and the related or incidental object. It may be the following.

(1) In the embodiment, as shown in FIG. 3, it has been described that the preparation (S13) is performed at a stage earlier than the channel scan (S14). It may be at the same time as the start or slightly overlap with the scan period.
(2) In the embodiment, a digital broadcast receiving terminal is taken as an example, but an analog broadcast receiving terminal may be used, or a receiving terminal having both may be used. However, since the reception of digital broadcasts has a greater influence on the availability of reception of broadcast waves compared to analog broadcasts, the present invention can be suitably applied.

(3) In the embodiments, a mobile phone has been described as an example of a broadcast receiving terminal. However, the present invention is not limited to this, and the present invention is also applicable to broadcast receiving terminals such as portable game machines with a TV function, car navigation, and PDAs. Is possible.
(4) In the embodiment, the LED has been described as an example of the light emitter. However, the light source is not limited to this as long as it is a blinking light source. For example, a krypton bean bulb may be used.

(5) In the embodiment, reception condition deterioration (FIG. 3: S11) is triggered by channel scan execution. However, the present invention is not limited to this, and it may be when the area movement is detected using the GPS function of the mobile phone 2. Alternatively, the execution timing specified by the user may be used.
(6) The embodiment and each modification can be combined.
(7-1) A broadcast receiving terminal according to an embodiment is a broadcast receiving terminal having a television function, a display, transfer means for transferring display data to the display, channel scan means for channel scanning, Transfer suppression means for suppressing transfer of the display data by the transfer means during scanning by the channel scanning means.

(7-2) Here, the transfer suppression by the transfer suppression unit may be a transfer stop or a transfer rate decrease.
According to this configuration, it is possible to reliably avoid noise caused by the transfer by stopping the transfer of the display data. Further, by reducing the transfer speed, it is possible to cause the display to display to some extent while suppressing noise caused by the transfer.

(7-3) In addition, the tuner includes a tuner that receives a digital broadcast wave, and a back-end unit that includes a processor and decodes encoded data included in the received digital broadcast wave. During the scanning by the channel scanning means, the operation clock of the processor of the back end unit may be lowered.
According to this configuration, it is possible to reduce noise generated from the back-end unit by lowering the operation clock of the processor of the back-end unit compared to before the channel scan is executed.

The back end unit is not required to be operated during the channel scan, and the channel scan can be executed without any trouble even if the operation clock is lowered.
(7-4) Furthermore, a light emitter and light emitter control means for making the light emission state of the light emitter different from that before scanning during the scan may be provided.
According to this configuration, it is possible to easily notify the user of the broadcast receiving terminal that scanning is in progress.

(7-5) The battery control unit further includes a battery that supplies power to the display, and a battery control unit that controls the battery. During the scan by the channel scanning unit, the battery control unit controls the power to the display. The supply may be stopped.
(7-6) Further, a rechargeable battery, charging means for charging the battery, and charging suppression means for suppressing charging by the charging means during scanning by the channel scanning means may be provided. Absent.

Noise that affects reception sensitivity may occur while the battery is being charged. According to this configuration, noise due to charging can be avoided.
(7-7) Further, communication means for wirelessly communicating with the base station of the mobile phone at predetermined intervals, and channel scan control means for stopping channel scanning by the channel scanning means during communication by the communication means And may be provided.

There are interference caused by radio waves used during communication with a mobile phone base station and noise accompanying the communication operation. According to this configuration, it is possible to avoid interference and noise caused by the communication.
(7-8) Furthermore, a speaker is further provided, the transfer means transfers audio data to the speaker, and the transfer suppression means is configured to transfer the audio data by the transfer means during scanning by the channel scan means. The transfer may be suppressed.

  According to this configuration, channel scanning can be performed without being affected by noise caused by the transfer of audio data or noise generated in the audio reproduction circuit (audio amplifier).

  The broadcast receiving terminal according to the present invention has improved reception status at the time of channel scanning, so that it can detect many channels and contribute to the realization of a comfortable TV viewing environment.

2 is a diagram showing an external appearance of a mobile phone 2. FIG. 3 is a functional block diagram of the mobile phone 2. FIG. It is a figure which shows the flowchart regarding the whole process of a channel scan. It is a figure which shows the flowchart regarding the pre-process of a channel scan. It is a figure which shows the flowchart regarding the pre-process of a channel scan. It is a figure which shows the flowchart regarding the return process of a channel scan. It is a figure which shows the transition of the screens 4a-4e of the display 4 before and behind a channel scan. It is a figure which shows the screen 5 of the mobile telephone which concerns on the modification 1. FIG. FIG. 10 is a block diagram for explaining the flow of power of a mobile phone according to Modification 2. It is a figure which shows the preparatory process which concerns on the modification 2. (A) is a flowchart according to the third modification. (B) is a diagram showing a timeline of a scanning operation and a communication operation.

Explanation of symbols

2 Mobile phone 4 Display 6 Speaker 8 LED
12 Communication unit 18 Tuner unit 22 CPU
24 memory 26 transfer unit 28 TS processing unit 30 display control unit

Claims (8)

A broadcast receiving terminal having a TV function,
Display,
Transfer means for transferring display data to the display;
Channel scanning means for channel scanning;
A transfer suppression unit that suppresses transfer of the display data by the transfer unit during scanning by the channel scan unit;
A broadcast receiving terminal comprising: 2. The broadcast receiving terminal according to claim 1, wherein the transfer suppression by the transfer suppression means is a transfer stop or a transfer speed decrease. A tuner for receiving digital broadcast waves;
A back end unit that includes a processor and decodes encoded data included in the received digital broadcast wave;
The broadcast receiving terminal according to claim 1, wherein the transfer suppression unit further reduces an operation clock of a processor of the back-end unit during scanning by the channel scanning unit. And a light emitter,
During the scan, light emitter control means for making the light emission state of the light emitter different from that before the scan,
The broadcast receiving terminal according to any one of claims 1 to 3, further comprising: A battery for supplying power to the display;
Battery control means for controlling the battery,
The broadcast receiving terminal according to claim 1, wherein the battery control unit stops power supply to the display during scanning by the channel scanning unit. And a rechargeable battery
Charging means for charging the battery;
Charging suppression means for suppressing charging by the charging means during scanning by the channel scanning means;
The broadcast receiving terminal according to claim 1, further comprising: Further, a communication means for wirelessly communicating with the base station of the mobile phone at predetermined intervals;
Channel scanning control means for stopping channel scanning by the channel scanning means during communication by the communication means;
The broadcast receiving terminal according to claim 1, further comprising: In addition, with a speaker,
The transfer means causes audio data to be transferred to the speaker,
2. The broadcast receiving terminal according to claim 1, wherein the transfer suppression unit suppresses transfer of the audio data by the transfer unit during scanning by the channel scanning unit.