JP2011103539A - Controller, portable terminal, control method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To switch full-segment broadcasting to one-segment broadcasting at the right timing while suppressing power consumption. <P>SOLUTION: A control part determines whether a count value i corresponding to the time when one segment CNR exceeds a threshold CNR_cnt exceeds the threshold Cnt_th, based on reception quality of one-segment broadcasting (step S804). The control part activates a full segment tuner (step S805) when the determination is affirmed (step S804; Yes). The control part determines whether reception quality of full segment data output from the full segment tuner 160 is better than the predetermined reference (steps S806, 807). When the determination is negated (step S807; No), the control part stops the full segment tuner (step S809), and increases the threshold Cnt_th by 1 (step S810). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a control device that controls a television device that receives and demodulates a digital broadcast (for example, terrestrial digital broadcast) broadcast signal, a portable terminal that includes the control device, and a digital broadcast broadcast signal. The present invention relates to a control method for controlling a television device to be demodulated and a program for causing a computer to function as the control device.

  A broadcast receiving apparatus that receives a broadcast signal of terrestrial digital broadcasting includes a tuner that demodulates the broadcast signal into a transport stream (TS). After various packets are separated from the TS demodulated by the tuner, the decoder decodes the packets to output video and audio.

  In terrestrial digital broadcasting, a frequency band assigned to one broadcasting station is divided into 13 segments. Each broadcasting station transmits one-segment broadcasting using one of the segments, and transmits broadcasting for fixed television using the remaining twelve segments.

  In broadcasting for fixed television, there are a case where only one program is transmitted using all 12 segments, and a case where a standard broadcast of SD quality is transmitted by a plurality of programs. In broadcasting for fixed television, some data included in a segment used for one-segment broadcasting may be used.

  One-segment broadcasting is standardized for mobile terminals. One-segment broadcasting has a feature that broadcast signals can be normally received even when reception sensitivity is low compared to broadcasting for fixed television.

  Therefore, if the reception condition deteriorates during reception of a high-definition broadcast signal, switching to one-segment broadcasting is continued and reception is continued.If the radio wave condition of the high-definition broadcast is recovered during reception of one-segment broadcasting, a selection means for switching to high-definition broadcasting is provided. An in-vehicle digital broadcast receiving apparatus is disclosed (for example, see Patent Document 1).

  Furthermore, in order to reduce power consumption, a tuner that constantly receives high-definition broadcasts is not started and the reception status is monitored, but a CNR (Carrior to Noise Ratio, carrier power to noise) output from a tuner that receives one-seg broadcasts. It has also been proposed to predict the reception status of high-definition broadcasts using radio wave conditions such as (power ratio), and start up as necessary. In this case, while watching the 1Seg broadcast, the CNR output by the tuner for the 1Seg broadcast is monitored, and if it is determined that the radio wave condition is good, the tuner for the HDTV broadcast is activated, and then the tuner for the HDTV broadcast outputs. Processing to monitor radio wave conditions and switch to high-definition broadcasting is performed.

JP 2005-277873 A

  However, the CNR value output from the one-segment broadcasting tuner may be less correlated with the radio wave status of high-definition broadcasting due to the influence of multipath fading or the like. Therefore, even if the CNR value of the one-segment broadcasting is monitored and the tuner for high-definition broadcasting is activated, the situation where the radio wave condition is not good enough to switch to the high-definition broadcasting can occur. In such a situation, even if the high-definition broadcast tuner is activated, it cannot be switched to the high-definition broadcast after all, and power is wasted.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a control device, a control method, a portable terminal, and a program that can perform tuner switching at an appropriate timing while suppressing power consumption. To do.

In order to achieve the above object, a control device according to the first aspect of the present invention provides:
A first tuner for receiving and demodulating the first broadcast;
A second tuner for receiving and demodulating a second broadcast of higher quality than the first broadcast;
Playback means for playing back either the first broadcast or the second broadcast;
A control device for controlling a television device comprising:
First determination means for determining, at a predetermined timing, whether or not an activation condition for activating the second tuner is satisfied based on the reception quality of the first broadcast;
Starting means for starting the second tuner when the determination in the first determination means is affirmed;
Second determination means for determining at a predetermined timing whether or not the reception quality of the second broadcast output from the activated second tuner is better than a predetermined reference;
An adjustment unit for adjusting the activation condition in the first determination unit when the determination by the second determination unit is denied;
A control device comprising:

In this case, when the determination by the second determination unit is denied, the apparatus further includes a stop unit that stops the second tuner.
It is good as well.

The adjusting means includes
If the determination by the second determination unit is denied after the activation unit has activated the second tuner, the activation condition is adjusted in a direction in which the determination by the first determination unit is less likely to be affirmed. ,
It is good as well.

The adjusting means includes
When the reception quality of the first broadcast does not satisfy the activation condition, but satisfies another condition that is milder according to the activation condition,
Adjusting the activation condition in a direction in which the determination in the first determination means is less likely to be affirmed;
It is good as well.

In addition, the start condition includes
At least one of an upper limit and a lower limit is provided,
It is good as well.

Further, the reproducing means includes
A first television priority mode for preferentially reproducing the first broadcast;
A second television priority mode for preferentially reproducing the second broadcast, as an operation mode;
The adjusting means includes
When the first television priority mode is set, the activation condition is adjusted in a direction in which the determination in the first determination unit is difficult to be affirmed,
When the second television priority mode is set, the activation condition is adjusted in a direction in which the determination in the first determination unit is easily affirmed;
It is good as well.

Further, the first discriminating means includes
It is determined that the reception quality of the first broadcast is better than the threshold value continuously for a specific period as the activation condition,
The adjusting means includes
When adjusting in a direction in which the determination in the first determination means is less likely to be affirmed, the specific period is lengthened,
When adjusting in a direction in which the determination in the first determination unit is likely to be affirmed, the specific period is shortened.
It is good as well.

Further, the first discriminating means includes
It is determined that the reception quality of the first broadcast is better than the threshold value continuously for a specific period as the activation condition,
The adjusting means includes
When adjusting in a direction in which the determination in the first determination unit is difficult to be affirmed, the threshold is increased,
When adjusting in a direction in which the determination in the first determination unit is easily affirmed, the threshold value is lowered.
It is good as well.

The reception quality of the first broadcast is
It is at least one of the ratio of noise power to carrier power included in the data, bit error rate, and electric field strength of the broadcast signal.
It is good as well.

A portable terminal according to the second aspect of the present invention is
The control apparatus of the present invention is provided.

A control method according to the third aspect of the present invention is as follows.
A first tuner for receiving and demodulating the first broadcast;
A second tuner for receiving and demodulating a second broadcast of higher quality than the first broadcast;
Playback means for playing back either the first broadcast or the second broadcast;
A control method for controlling a television device comprising:
A first determination step of determining at a predetermined timing whether or not an activation condition for activating the second tuner is satisfied based on the reception quality of the first broadcast;
An activation step of activating the second tuner when the determination in the first determination step is affirmed;
A second determination step of determining at a predetermined timing whether or not the reception quality of the second broadcast output from the activated second tuner is better than a predetermined reference;
If the determination in the second determination step is negative, an adjustment step for adjusting the activation condition in the first determination step;
including.

A program according to the fourth aspect of the present invention is:
A first tuner for receiving and demodulating the first broadcast;
A second tuner for receiving and demodulating a second broadcast of higher quality than the first broadcast;
Playback means for playing back either the first broadcast or the second broadcast;
A computer for controlling a television device comprising:
First determination means for determining, at a predetermined timing, whether or not an activation condition for activating the second tuner is satisfied based on the reception quality of the first broadcast;
Starting means for starting the second tuner when the determination in the first determination means is affirmed;
Second determination means for determining at a predetermined timing whether or not the reception quality of the second broadcast output from the activated second tuner is better than a predetermined reference;
An adjustment unit for adjusting the activation condition in the first determination unit when the determination by the second determination unit is denied;
And make it work.

  According to the present invention, when the activation condition for activating the second tuner is satisfied during viewing of the first broadcast, the second tuner is activated. If the radio wave condition of the second broadcast is not better than a predetermined reference even after the second tuner is activated, the adjusting means adjusts the activation condition for activating the second tuner. As a result, the activation condition of the second tuner can be adjusted to match the reception status of the second broadcast. Therefore, it is possible to switch the tuner at an appropriate timing while suppressing power consumption.

It is an external view when it sees from the front in the state which opened the portable terminal provided with the control apparatus which concerns on Embodiment 1 of this invention. It is a block diagram which shows the circuit structure of the portable terminal of FIG. FIG. 3A is a block diagram illustrating a configuration of a one-segment demodulation / decoding unit included in the mobile terminal of FIG. FIG. 3B is a block diagram illustrating a configuration of a full-segment demodulation / decoding unit included in the mobile terminal of FIG. It is a schematic diagram for demonstrating an example of the area which can receive each 1-segment and full-segment broadcast signal. FIG. 5A and FIG. 5B are examples of a time change of the full segment BER or the one segment CNR. It is a flowchart of the full segment video output process in the portable terminal of FIG. It is a figure for demonstrating the segment of digital broadcasting. It is a flowchart of the one segment → full segment switching process in the portable terminal of FIG. It is a flowchart of the 1 seg-> full seg switching process in the portable terminal concerning Embodiment 2 of the present invention. It is a flowchart of the 1 seg-> full seg switching process in the portable terminal concerning Embodiment 3 of the present invention. It is a block diagram which shows the circuit structure of the portable terminal which concerns on Embodiment 4 of this invention. 5 is a diagram showing the contents of a threshold range table 1100. FIG. It is a flowchart of the 1seg-> full seg switching judgment processing in the portable terminal concerning Embodiment 4 of the present invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following embodiment, it is assumed that the first broadcast is a one-segment broadcast, and the high-quality second broadcast having a larger amount of data than the first broadcast is a high-definition broadcast (or full-segment broadcast).

  In the present embodiment, standard broadcasting is handled in the same manner as high-definition broadcasting. In the present embodiment, the second broadcast, that is, a broadcast using 12 segments is collectively referred to as a high-vision broadcast. In high-definition broadcasting, data included in the one-segment broadcasting segment may be used.

(Embodiment 1)
First, Embodiment 1 of the present invention will be described.

  The mobile terminal 1 including the control device according to the present embodiment includes a content reception function and a content reproduction function. For example, the portable terminal 1 may be a foldable type as shown in FIG. The portable terminal 1 can receive arbitrary content. In the present embodiment, the configuration and operation of the mobile terminal 1 when receiving contents (programs) of one-segment broadcasting and high-vision broadcasting will be described.

  As shown in FIG. 1, the mobile terminal 1 includes a keyboard 2, a display panel 5, a call microphone 6, a call speaker 7, a speaker 8, and the like.

  The keyboard 2 is operated by the user. The keyboard 2 is used for inputting various data and instructions. The keyboard 2 includes a cursor key 3, a switching button 4, and various other buttons.

  The cursor key 3 and various other buttons are used, for example, for inputting instructions such as channel selection. The switching button 4 is used, for example, for input of switching of a broadcast to be reproduced.

  The display panel 5 is, for example, a dot matrix type LCD (liquid crystal display) panel or the like. The display panel 5 displays arbitrary information (for example, video of a broadcast program, subtitles, data broadcast, etc.).

  The call microphone 6 inputs a call voice. When making a call, the user brings his mouth close to the call microphone 6.

  The call speaker 7 outputs a received voice. When making a call, the user brings his ear close to the call speaker 7.

  The speaker 8 outputs audio or the like during content playback (when playing 1Seg or high-definition broadcasts).

  Next, the circuit configuration of the mobile terminal 1 will be described. As shown in FIG. 2, the mobile terminal 1 includes a control unit 11, a storage unit 12, an operation unit 13, a display unit 14, a one-segment demodulation / decoding unit 15, a full-segment demodulation / decoding unit 16, an audio output unit 17, and an audio input unit. 18, a communication unit 19, a bus 20, a timer 24, and an antenna 31.

  The control unit 11 includes a microprocessor unit and the like. The control unit 11 controls the overall operation of the mobile terminal 1 (the operation of each unit).

  For example, the control unit 11 controls the reproduction of data broadcast based on the demodulated broadcast signal. The data based on the broadcast signal is video data or the like, and may be broadcast data itself. Broadcast data is, for example, a TS (Transport Stream) in the case of terrestrial digital broadcasting. Broadcast playback includes playback using data processed by decoding TS output from each tuner unit. Further, the control unit 11 controls channel change.

  The control unit 11 displays various data (video, caption text, data broadcast, etc.) on the display unit 14 (display panel 5). Further, the control unit 11 supplies power (power on / off) to the one seg tuner unit 150 constituting the one seg demodulation / decoding unit 15 and the full seg tuner unit 160 constituting the full seg demodulation / decoding unit 16, for example. And the operation of the one-segment tuner unit 150 and the operation of the full-segment tuner unit 160 are controlled. The one segment tuner unit 150 and the full segment tuner unit 160 will be described later.

  The storage unit 12 includes a storage device such as a RAM or an auxiliary storage device. The storage unit 12 may include a memory built in the mobile terminal 1, a removable external memory, or both. In addition, the storage unit 12 may realize a part of its functions with a memory accessible from the control unit 11 provided outside the mobile terminal 1. The storage unit 12 stores various data and various programs. The storage unit 12 also has a work area for the control unit 11.

  The operation unit 13 includes the keyboard 2 (cursor key 3, switching button 4, etc.) described above. The operation unit 13 outputs an operation signal corresponding to the operation from the user to the control unit 11.

  The display unit 14 includes the display panel 5 and its driver circuit (not shown). In the display unit 14, an image is displayed on the display panel 5 by driving the driver circuit under the control of the control unit 11.

  As shown in FIG. 3A, the one-segment demodulation / decoding unit 15 includes a one-segment tuner unit 150 as a first tuner and a one-segment decoding unit 159. The one-seg tuner unit 150 demodulates the one-seg broadcast TS from the broadcast signal received via the antenna 31 and outputs the demodulated signal TS to the one-seg decode unit 159. The one-segment decoding unit 159 separates and decodes the TS of the demodulated signal, and outputs video data, audio data, caption data, and the like.

  Specifically, the one-segment tuner unit 150 includes, for example, a receiver 151, a CNR measurement unit 152, a demodulator 153, and a BER (Bit Error Rate) measurement unit 154, as shown in FIG. The one-segment tuner unit 150 is connected to a CNR output line 155, a BER output line 156, a TS output line 157, and the like.

  The receiver 151 extracts a signal designated by the control unit 11 from the broadcast signal input from the antenna 31 as an RF (Radio Frequency) signal. The receiver 151 outputs the extracted RF signal to the demodulator 153 via the CNR measuring device 152. For example, a signal having a predetermined frequency band corresponding to one-segment broadcasting of a channel designated by the user is extracted as the RF signal.

  The CNR measuring device 152 obtains a CNR value using the RF signal, and outputs the obtained CNR value to the control unit 11 via the CNR output line 155 or stores it in the storage unit 12. As a result, the CNR value stored in the storage unit 12 is read by the control unit 11. Therefore, in this embodiment, the case of “outputting to the control unit 11” includes the case of outputting to the control unit 11 via the storage unit 12. Hereinafter, the CNR value output from the CNR measuring device 152 may be referred to as a “one-segment CNR”.

  The RF signal output from the receiver 151 is input to the demodulator 153 via the CNR measuring device 152. The demodulator 153 demodulates the input RF signal into a TS, and outputs the one-segment broadcasting TS to the BER measuring device 154.

  The BER measuring device 154 measures the BER value based on the input TS of the one-segment broadcasting, and then outputs the TS to the TS output line 157. The measured BER value is output to the control unit 11 via the BER output line 156. Hereinafter, the BER value output from the BER measuring device 154 may be referred to as “one-segment BER”.

  As shown in FIG. 3B, the full segment demodulation / decoding unit 16 includes a full segment tuner unit 160 as a second tuner, a descrambling unit 168, and a full segment decoding unit 169.

  Full-segment tuner unit 160 demodulates the full-segment broadcasting TS using radio waves received via antenna 31 and outputs the demodulated TS to descrambling unit 168.

  The descrambling unit 168 decrypts the encrypted scrambled TS output from the full segment tuner unit 160, plains the data, and outputs the data as clear text data (plain text TS) to the full segment decoding unit 169.

  The full segment decoding unit 169 separates and decodes the plain text TS output from the descrambling unit 168, and outputs video data, audio data, subtitle data, and the like.

  As shown in FIG. 3B, the full segment tuner unit 160 includes a receiver 161, a CNR measurement unit 162, a demodulator 163, and a BER measurement unit 164. The full segment tuner unit 160 is connected to a CNR output line 165, a BER output line 166, a TS output line 167, and the like.

  The receiver 161 extracts a signal designated by the control unit 11 from the broadcast signal input from the antenna 31 as an RF signal. What is extracted as the RF signal is a signal in a frequency band of a predetermined width corresponding to, for example, full-segment broadcasting of a channel specified by the user.

  The full segment tuner unit 160 has the same configuration as the one segment tuner unit 150. Hereinafter, the CNR value output from the CNR measuring device 162 may be referred to as “full segment CNR”, and the BER value output from the BER measuring device 164 may be referred to as “full segment BER”.

  Note that the one-segment tuner unit 150 and the full-segment tuner unit 160 may be configured by a single LSI (Large Scale Integration), or may be configured by separate tuners. When the one-segment tuner unit 150 and the full-segment tuner unit 160 are configured by one LSI, this tuner is divided into a one-segment mode for demodulating and outputting a one-segment broadcasting TS and a full-segment mode for demodulating and outputting a high-definition broadcasting TS. There are two modes of operation.

  The one seg mode is an operation mode when the one seg tuner unit 150 operates, and is an operation mode for preferentially reproducing the one seg broadcast. The full segment mode is an operation mode when the full segment tuner unit 160 operates, and is an operation mode in which full segment broadcasting is preferentially reproduced. The switching of the operation mode is controlled by the control unit 11. For example, the control unit 11 switches the operation mode by rewriting a register value indicating the operation mode.

  The display unit 14 (see FIG. 2) is a reproduction unit that reproduces the one-segment broadcast received by the one-segment tuner unit 150 or the full-segment broadcast received by the full-segment tuner unit 160. The control unit 11 (see FIG. 2) switches between the one-segment tuner unit 150 and the full-segment tuner unit 160 so as to reproduce the one-segment broadcast or the high-definition broadcast based on either the one-segment broadcast TS or the high-definition broadcast TS. The display unit 14 is controlled.

  Returning to FIG. 2, the audio output unit 17 includes the above-described telephone speaker 7 and speaker 8, a DAC (Digital Analog Converter) not shown. For example, the audio output unit 17 performs DA conversion on the audio signal of the content reproduced under the control of the control unit 11, and outputs the audio converted into an analog signal through the speaker 8.

  The voice input unit 18 collects voice signals and supplies them to the communication unit 19 during a call or the like.

  The communication unit 19 transmits / receives call voice, various data, and the like via the base station.

  The bus 20 transmits data between the units.

  The timer 24 is a mechanism attached to a microprocessor unit or the like constituting the control unit 11. The timer 24 generates interrupts at regular time intervals. By adjusting the timer 24, the time interval at which the control unit 11 generates an interrupt can be set.

  The antenna 31 is an antenna capable of receiving a digital broadcast signal. The antenna 31 has a shape necessary for receiving, for example, UHF band radio waves or VHF band radio waves.

  Next, the operation of the mobile terminal 1 according to this embodiment will be described.

(Overview of switching process contents)
For example, as shown in FIG. 4, the sending station 41 is a base station that transmits a broadcast signal. An area 42 close to the sending station 41 is an area where the electric field strength of the broadcast signal sent from the sending station 41 is strong, and is an area where the reception status of the high-definition broadcast is good. A wide area 43 centering on the transmitting station 41 is an area where the electric field intensity of the broadcast signal transmitted from the transmitting station 41 is weak, and is an area where the reception status of the one-segment broadcasting is good. Of course, the area 43 includes the area 42.

  In the area 42, the mobile terminal 1 can receive both full-segment broadcasting and one-segment broadcasting in a good state. On the other hand, in the area 43, the mobile terminal 1 can receive and display the one-segment broadcasting in a good state.

  First, consider a case where the mobile terminal 1 moves from within the area 42 to outside the area 42 and into the area 43. In this case, if the reception status of the high-definition broadcast deteriorates while the user is receiving and watching the high-definition broadcast, block noise occurs in the video, and the viewing cannot be continued further. For this reason, the portable terminal 1 switches and displays the one-seg broadcasting of the same channel. Thereby, since the user can view the program without interruption, usability is improved.

  In order to perform such switching control, the control unit 11 acquires, for example, a full segment CNR or electric field strength measured by the CNR measuring unit 162 during reception of a high-definition broadcast, and the acquired value is a predetermined threshold value. It is determined whether or not the number is exceeded. In order to acquire the electric field strength, it is necessary to provide an electric field strength measuring device in the full-segment demodulation / decoding unit 16 or the like. The electric field strength measuring device is provided, for example, at the position of the CNR measuring device 152 and the CNR measuring device 162 shown in FIG.

  If the full segment CNR or the electric field strength is less than a predetermined threshold, the control unit 11 switches from full segment broadcasting to one segment broadcasting. The threshold is different between the case where the full segment CNR is used and the case where the electric field strength is used.

  The control unit 11 may acquire the full segment BER output from the full segment tuner unit 160 and determine whether the full segment BER is less than a predetermined threshold. When the full segment BER is equal to or greater than the threshold, the control unit 11 switches from full segment broadcasting to one segment broadcasting.

  Furthermore, when the mobile terminal 1 enters the area 42 while watching 1Seg, the mobile terminal 1 can receive high-definition broadcasts well. Therefore, if the broadcast to be viewed is switched from the 1Seg broadcast to the high-definition broadcast, You can watch quality broadcasts.

  Of the above processing, the processing content using the full segment BER will be briefly described with reference to FIG.

  As shown in FIG. 5A, the threshold value 140 is a threshold value for switching from high-vision broadcasting to one-segment broadcasting when the full-segment BER is higher than this. For example, at time t1 (or t3), the acquired full-segment BER exceeds the threshold value 140, and at this point, the control unit 11 switches from full-segment broadcasting to one-segment broadcasting. In addition, by using the full segment BER for switching between the one segment tuner unit 150 and the full segment tuner unit 160, the reception status of each broadcast can be grasped more accurately.

(Overview of Full Seg → One Seg switching process)
A switching process from full segment broadcasting to one segment broadcasting will be described.

  In this switching process, for example, the control unit 11 activates the one seg tuner unit 150 by turning on the power of the one seg tuner unit 150 and starting it. The one-segment tuner unit 150 demodulates and outputs the one-segment broadcasting TS from the broadcast signal received by the antenna 31. The output TS is input to the one-segment decoding unit 159. The input TS is decoded by the one-segment decoding unit 159 and converted into YUV data or the like.

  Subsequently, the control unit 11 stops the display of the YUV data image output from the full segment decoding unit 169 on the display unit 14 and displays the YUV data image output from the one segment decoding unit 159 on the display unit 14. Let Thereafter, the control unit 11 turns off the power of the full segment tuner unit 160 and stops the operation of the full segment tuner unit 160.

  In this way, the control unit 11 acquires the reception quality of the high-definition broadcast output from the full-segment tuner unit 160 when the full-segment tuner unit 160 is operating, and the received reception quality of the full-segment broadcast satisfies a predetermined standard. If not, the one-segment tuner unit 150 is operated and the full-segment tuner unit 160 is stopped.

  Subsequently, the control unit 11 reproduces the one-segment broadcasting based on the one-segment broadcasting TS. Here, the reception quality of the high-definition broadcast output from the full segment tuner unit 160 is the full segment BER, but may be a full segment CNR or electrolytic strength.

  Note that the switching process using the full segment CNR or the electric field strength is the same process as the switching process described above. However, in the case of full-segment BER, the control unit 11 switches from full-segment broadcasting to one-segment broadcasting when the value falls below a certain threshold value, not when the certain threshold value is exceeded.

(Overview of 1Seg → Full Seg switching process)
For example, as shown in FIG. 5A, when the full-segment BER falls below the threshold value 140 at time t2 (or t4), the control unit 11 recovers the reception status of the high-definition broadcast while viewing the one-segment broadcast. Then, it is determined that switching to high-definition broadcasting is possible. In this case, the control unit 11 turns on and activates the full-segment tuner unit 160, operates the full-segment tuner unit 160, and switches to high-definition broadcasting.

  Full segment tuner section 160 demodulates and outputs TS from the broadcast signal received via antenna 31. The output TS is input to the descrambling unit 168, the cipher of the scrambled TS is decrypted, and the data is converted into plain text and output to the full segment decoding unit 169. The output TS is input to the full segment decoding unit 169. The input TS is decoded by the full segment decoding unit 169 and converted into YUV data or the like.

  Then, the control unit 11 causes the display unit 14 to stop displaying the YUV data image decoded by the one-segment decoding unit 159 and displays the YUV data image output from the full-segment decoding unit 169 on the display unit 14. Let

  In this manner, the control unit 11 reproduces the high-definition broadcast based on the high-definition broadcast TS. Thereafter, the control unit 11 turns off the power of the one seg tuner unit 150 and stops the operation of the one seg tuner unit 150.

(Full segment video output processing)
Here, full-segment video output processing for outputting high-definition broadcast video will be described in detail with reference to the flowchart of FIG.

  When a broadcast signal is input to the full segment tuner unit 160 via the antenna 31, under the control of the control unit 11, the full segment tuner unit 160 performs demodulation processing and outputs a high-definition broadcast TS (step S701).

  Subsequently, since the TS is scrambled for content protection, the descrambling unit 168 performs a decryption process and outputs a plaintext TS (step S702).

  Subsequently, the full segment decoding unit 169 decodes the plaintext TS (step S703). In this decoding process, first, the TS is separated into data such as video, audio, subtitles, data broadcast, and PSI / SI information, and then each elementary stream (ES) is decoded from the separated data. Thereby, for example, the video ES is converted into YUV data (video data), and the audio ES is converted into PCM (Pulse Code Modulation) data (audio data).

  Subsequently, the control unit 11 performs display on the display unit 14, output from the speaker 8, and the like using each converted ES, and reproduces the high-definition broadcast (step S704).

  In this way, the control unit 11 controls playback of the high-definition broadcast based on the high-definition broadcast TS output from the full segment tuner unit 160.

(Low power consumption operation)
As described above, in the present embodiment, the full-segment BER can be used to automatically switch from the high-definition broadcast to the one-segment broadcast while watching the high-definition broadcast. High-definition broadcast receivability determination processing can be performed.

  Here, when the switching determination process is performed using the full segment BER or the full segment CNR, if the full segment tuner unit 160 is always turned on and the full segment tuner unit 160 is operated, the power consumption increases.

  In general, the full segment tuner unit 160 consumes more power than the one segment tuner unit 150. This is because, as shown in FIG. 7, high-definition broadcasting uses a frequency band about 12 times that of one-segment broadcasting, and the TS bit rate is high and the data processing amount is large.

  As shown in FIG. 7, the full-segment broadcasting segment and the one-segment broadcasting segment are generally different, but the full-segment broadcasting uses a part of the data included in the segment used for the one-segment broadcasting. Sometimes it is done.

  In the mobile terminal 1 according to the present embodiment, when the one seg tuner unit 150 is operated, the operation of the full seg tuner unit 160 is stopped, so that the power consumption of the entire mobile terminal 1 can be reduced.

  In the present embodiment, the control unit 11 also controls the one-seg tuner unit 150 to operate only when displaying one-seg broadcasting without always starting (operating). The one-segment tuner unit 150 does not require as much power consumption as the full-segment tuner unit 160. However, in the present embodiment, the operation of the one-segment tuner unit 150 is stopped as much as possible so that the consumption of the entire mobile terminal 1 is reduced. Electric power can be reduced.

(Full segment tuner activation judgment)
A more detailed flow of switching processing when switching from one-segment broadcasting to full-segment broadcasting will be described.

  The switching process is roughly divided into a start determination process of the full segment tuner unit 160 using the one segment CNR while watching the one segment broadcast, and a switching determination process to the full segment broadcast viewing using the full segment BER output by the full segment tuner unit 160 thereafter. Two processes are executed.

  Here, the value of the one-segment CNR may not have a linear correlation with the full-segment CNR or the full-segment BER due to the influence of fading due to multipath or the like. In this case, even if it is determined that the radio wave state is good in the one-segment CNR, it may be determined that the radio wave state is not good enough to be switched to full-segment broadcasting in the full-segment BER.

  In such a situation, even if the full segment tuner unit 160 is activated, it cannot be switched to full segment broadcasting, and wasteful power consumption is used. Therefore, in the present embodiment, if the full segment broadcasting is not switched to the full segment broadcasting even when the full segment tuner unit 160 is activated, the activation condition for activating the full segment tuner unit 160 is adjusted.

  Note that the activation criterion of the full segment tuner unit 160 can be adjusted to an optimal value by performing a test in advance. However, the location of use of the mobile terminal 1 changes as the user moves, so that the optimal determination criterion. The value may change. On the other hand, if this switching process is performed, the starting conditions of the full segment tuner unit 160 can be kept optimal at all times.

  Processing contents of the switching process of the control unit 11 when the radio wave status changes as shown in FIG. 5B will be described. In the graph shown in FIG. 5B, a black circle indicates a value of one-segment CNR, and a white circle indicates a value of full-segment BER.

  During the viewing of the one-segment broadcasting, the one-segment CNR exceeds the threshold 601 from time t5 to time t6 and satisfies a predetermined time interval (for example, three times the sampling interval). The full segment tuner unit 160 is activated.

  Then, the full segment BER is acquired at time t7, but since it is not below the threshold value 140, switching to full segment broadcasting does not occur, and the full segment tuner unit 160 is stopped. Here, in order to suppress unnecessary activation of the full segment tuner unit 160, the activation condition of the full segment tuner unit 160 is adjusted to a stricter one.

  That is, the predetermined time interval in which the one-segment CNR must continuously satisfy the threshold value 601 is increased (for example, four times the sampling interval). When the one-segment CNR exceeds the threshold 601 from time t8 to time t9, the control unit 11 activates the full-segment tuner unit 160 again. And since full seg BER is less than threshold 140 at time t10, control part 11 switches to full seg broadcasting.

  Hereinafter, the activation determination of the full segment tuner unit 160 and the determination of switching to full segment broadcasting (one segment to full segment switching processing) will be mainly described with reference to the flowchart of FIG.

  First, the control unit 11 acquires the one-segment CNR output from the one-seg tuner unit 150 (step S801). Subsequently, the control unit 11 determines whether or not the acquired one-segment CNR exceeds the threshold value CNR_th (step S802). When the one-segment CNR is equal to or less than the threshold CNR_th (step S802; No), the control unit 11 resets the counter value i (step S811) and acquires the one-segment CNR again (step S801). In other words, as long as the one-segment CNR is equal to or less than the threshold CNR_th (step S802; No), steps S801 → S802 → S811 are repeated.

  When the one-segment CNR exceeds the threshold CNR_th (step S802; Yes), the control unit 11 increments the counter value i (step S803). Here, the counter value i is a value of a counter provided in the control unit 11 for controlling the execution of the program. The counter value i is a value indicating the number of times (duration) that the one-segment CNR has continuously exceeded the threshold value CNR_th.

  Subsequently, the control unit 11 determines whether or not the counter value i exceeds the threshold value Cnt_th (step S804). When the one-segment CNR is equal to or less than the threshold Cnt_th (step S804; No), the control unit 11 acquires the one-segment CNR again (step S801). The state where the one-segment CNR is larger than the threshold CNR_th is continued (step S802; Yes), and as long as the one-segment CNR is equal to or less than the threshold Cnt_th (step S804; No), steps S801 → S802 → S803 → S804 are repeated.

  If the one-segment CNR becomes equal to or less than the threshold CNR_th during this repetition (step S802; No), the control unit 11 resets the counter value i (step S811) and acquires the one-segment CNR again (step S801). On the other hand, while the one-segment CNR continues to exceed the threshold value Cnt_th, the counter value i is incremented (step S803) and increases.

  When the counter value i exceeds the threshold value Cnt_th (step S804; Yes), the control unit 11 activates the full segment tuner unit 160 (step S805).

  After starting the full segment tuner unit 160, the control unit 11 performs a full segment broadcast switching determination process (step S806). If it is determined in this process that switching to full-segment broadcasting is possible (step S807; Yes), the control unit 11 switches to full-segment broadcasting (step S808).

  On the other hand, when it is determined that switching to full-segment broadcasting is not possible (step S807; No), the control unit 11 stops the operation of the full-segment tuner unit 160 (step S809), and increases the value of the threshold Cnt_th by 1 (step S810). ).

  As described above in detail, according to the present embodiment, the full segment tuner unit 160 is activated when the activation condition for activating the full segment tuner unit 160 is satisfied during viewing of the one-segment broadcast. If the radio wave quality of the full segment broadcasting is not better than a predetermined standard even when the full segment tuner unit 160 is activated, the control unit 11 adjusts an activation condition (threshold) for activating the full segment tuner unit 160 (step). S810). Thereby, the starting conditions of the full segment tuner unit 160 can be adjusted according to the reception status of the broadcast signal of the full segment broadcast. For this reason, the tuner can be switched at an appropriate timing while suppressing the power consumption of the portable terminal.

  More specifically, in the present embodiment, after the full segment tuner unit 160 is activated, when the reception quality of the full segment broadcasting does not satisfy a predetermined standard, the threshold Cnt_th is increased by 1, and the full segment tuner unit 160 is activated. Adjust the startup conditions for those who are difficult. As a result, it is possible to reduce the frequency at which the full segment tuner unit 160 is activated in a state where the reception quality of the full segment broadcast is low.

  Thereby, only when the one-segment CNR exceeds the threshold CNR_th continuously for a longer time, the full-segment tuner unit 160 is activated and switched to full-segment broadcasting. As a result, when the full-segment broadcasting is not available for viewing, it is possible to reduce the frequency at which the full-segment tuner unit 160 is unnecessarily activated and to reduce power consumption.

(Embodiment 2)
Next, Embodiment 2 of the present invention will be described.

  In the first embodiment, when the full segment tuner unit 160 is activated and the switching to the full segment broadcasting cannot be performed, that is, when the full segment tuner unit 160 is unnecessarily activated, the control unit 11 performs the full segment tuner unit 160. Strict conditions for starting.

  However, depending on the radio wave condition, even if the full segment tuner unit 160 is activated, switching to full segment broadcasting cannot be performed, and the threshold value Cnt_th may become too large. In this case, the frequency at which the counter value i indicating the number of times the one-segment CNR has continuously exceeded the threshold CNR_th reaches the threshold Cnt_th is reduced. As a result, the full segment tuner unit 160 becomes difficult to start, and there is a possibility that the timing for switching to the full segment is delayed.

  Therefore, in the mobile terminal 1 according to the present embodiment, when the time during which the one-segment CNR continuously exceeds the threshold CNR_th becomes longer than the threshold Cnt_th2, the control unit 11 decreases the threshold Cnt_th by one. The threshold value Cnt_th2 is smaller than the threshold value Cnt_th, but is a threshold value close to the threshold value Cnt_th.

  A switching process from one segment to full segment in the mobile terminal 1 according to the present embodiment will be described with reference to the flowchart of FIG. As illustrated in FIG. 9, in the one-segment to full-segment switching process in the mobile terminal 1 according to the present embodiment, when it is determined that the one-segment CNR does not exceed the threshold value CNR_th (step S802; No), before the execution of step S811 Moreover, the point which performs the process shown below differs from the said Embodiment 1. FIG.

  As shown in FIG. 9, first, the control unit 11 obtains a one-segment CNR (step S801). When the one-segment CNR is equal to or less than the threshold CNR_th (step S802; No), the control unit 11 determines whether or not the counter value i exceeds the threshold Cnt_th2 (step S901).

  Only when the counter value i is larger than the threshold value Cnt_th2 (step S901; Yes), the control unit 11 decreases the threshold value Cnt_th by 1 (step S902).

  After executing step S901 or step S902, the control unit 11 resets the counter value i (step S811).

  As described above in detail, according to the present embodiment, when the one-segment CNR is equal to or smaller than the threshold value CNR_th and the counter value i is larger than the threshold value Cnt_th2, the threshold value Cnt_th is decreased by 1, so that the threshold value Cnt_th becomes too large. Thus, it is difficult for the full-segment tuner unit 160 to start up, and it is possible to prevent the switching timing to full-segment broadcasting from being delayed.

(Embodiment 3)
Next, a third embodiment of the present invention will be described.

  In the mobile terminal 1 according to each of the above embodiments, the setting range of the threshold value Cnt_th is not particularly limited, and may continue to increase or decrease depending on radio wave conditions. On the other hand, in the mobile terminal 1 according to the third embodiment, the upper limit value Cnt_th_max and the lower limit value Cnt_th_min of the threshold Cnt_th are defined. The upper limit value Cnt_th_max and the lower limit value Cnt_th_min are stored in the storage unit 12.

  The one-segment to full-segment switching process according to the mobile terminal 1 according to the present embodiment will be described with reference to the flowchart of FIG.

  As illustrated in FIG. 10, the control unit 11 acquires the one-segment CNR (step S801) and performs a comparison determination (step S802) between the one-segment CNR and the threshold CNR_th, as in the second embodiment.

  If the one-segment CNR does not exceed the threshold CNR_th (step S802; No) and the counter value i exceeds the threshold Cnt_th2 (step S901; Yes), the control unit 11 compares the threshold Cnt_th with the lower limit Cnt_th_min (step S1001). ).

  When the threshold value Cnt_th is larger than the lower limit value Cnt_th_min (step S1001; Yes), the control unit 11 decreases the threshold value Cnt_th by 1 (step S902). Thereafter, the control unit 11 resets the counter value i (step S811).

  On the other hand, when the threshold value Cnt_th is equal to or lower than the lower limit value Cnt_th_min (step S1001; No), the control unit 11 resets the counter value i (step S811). Thereby, the threshold value Cnt_th remains the lower limit value Cnt_th_min.

  In addition, after starting the full segment tuner unit 160 (step S805), a full segment broadcast switching determination process is performed (step S806), and when it is determined not to switch to the full segment broadcast (step S807; No), the control unit 11 The tuner unit 160 is stopped (step S809).

  Subsequently, the control unit 11 determines whether or not the threshold value Cnt_th is smaller than the upper limit value Cnt_th_max (step S1002). When the threshold value Cnt_th is smaller than the upper limit value Cnt_th_max (step S1002; Yes), the control unit 11 increases the threshold value Cnt_th by 1 (step S810). Thereafter, the control unit 11 ends the process.

  On the other hand, if the threshold value Cnt_th is greater than or equal to the upper limit value Cnt_th_max (step S1002; No), the control unit 11 ends the process. Thus, the threshold value Cnt_th remains the upper limit value Cnt_th_max.

  As described above in detail, according to the present embodiment, by providing the lower limit value Cnt_th_min and the upper limit value Cnt_th_max for a specific time, the threshold value Cnt_th of the counter value i continues to increase or decrease to any extent. Can be prevented.

(Embodiment 4)
Next, a fourth embodiment of the present invention will be described.

  In the mobile terminal 1 according to the third embodiment, the upper limit value Cnt_th_max and the lower limit value Cnt_th_min are fixed. However, depending on the radio wave condition, the threshold Cnt_th may not be changed, and the full segment tuner unit 160 may be activated unnecessarily, and switching to full segment broadcasting may be delayed.

  In addition, there is a user demand that some users want to view full-seg broadcasting with priority even when power consumption increases, or conversely, one-seg broadcasting is acceptable at the expense of image quality.

  Therefore, in order to respond to such user demands, the operation mode is set in the mobile terminal 1 of the fourth embodiment. There are two types of operation modes, for example, full segment priority mode and one segment priority mode.

  In the full segment priority mode, the threshold value Cnt_th is set to be small in order to quickly switch to full segment broadcasting. In the one-segment priority mode, the threshold value Cnt_th is set to be large so that the full-segment tuner unit 160 is not frequently activated in order to suppress power consumption as much as possible.

  In the mobile terminal 1 according to the fourth embodiment, as illustrated in FIG. 11, a threshold range table 1100 is stored in the storage unit 12. In the threshold range table 1100, as shown in FIG. 12, the lower limit value Cnt_th_min and the upper limit value Cnt_th_max in the one-segment priority mode and the full-segment priority mode are set. As shown in FIG. 12, in the full segment priority mode, the upper limit value Cnt_th_max is 5 and the lower limit value Cnt_th_min is 1. In the one-segment priority mode, the upper limit value Cnt_th_max is 15 and the lower limit value Cnt_th_min is 10.

  The switching determination process of the mobile terminal 1 according to the present embodiment will be described with reference to the flowchart of FIG.

  As shown in FIG. 13, in the present embodiment, the process of obtaining the lower limit value Cnt_th_min (step S1201) is performed prior to the comparison (step S1001) between the threshold value Cnt_th and the lower limit value Cnt_th_min. (See FIG. 10).

  In the acquisition process of the lower limit value Cnt_th_min, the control unit 11 first acquires the operation mode. The operation mode is a program variable held in the storage unit 12. For example, if the operation mode is 1, the full segment priority mode can be set, and if the operation mode is 0, the one segment priority mode can be set. The control unit 11 acquires this operation mode from the storage unit 12. When the operation mode is acquired, the control unit 11 acquires the lower limit value Cnt_th_min of the operation mode in the threshold range table 1100.

  Further, the process of obtaining the upper limit value Cnt_th_max (step S1202) is performed prior to the comparison between the threshold value Cnt_th and the upper limit value Cnt_th_max (step S1002), which is different from the flowchart of the third embodiment (see FIG. 10). As for the upper limit value Cnt_th_max, the upper limit value of the current operation mode set in the threshold range table 1100 is acquired in the same manner as the lower limit value Cnt_th_min.

  As described above in detail, according to the present embodiment, by providing an operation mode, even if the threshold value Cnt_th fluctuates depending on the radio wave condition, priority is given to viewing full-seg broadcasting or viewing for a long time with reduced power consumption. It is possible to implement priority switching determination processing that suits the user's preference.

  In each of the above embodiments, in order to suppress unnecessary activation of the full segment tuner unit 160, as a method of tightening the activation condition of the full segment tuner 160, the time when the reception quality continuously exceeds a predetermined standard is adjusted. This is because high-accuracy switching can be performed without being influenced by local fluctuations in reception quality.

  However, the present invention is not limited to this. As a method for tightening the reference, the threshold CNR_th of the one-segment CNR may be adjusted. As a result, since the time required for determination is constant, the time from when the radio wave condition improves until switching occurs is constant, which improves usability for the user.

  In each of the above embodiments, the tuner is switched using CNR, BER, and electric field strength. Since these are indicators of the reception quality of the broadcast signal, the tuner can be switched at an appropriate timing.

  It should be noted that the timing for displaying the same scene is shifted from about 1 second to about 2 seconds due to a difference in processing amount from reception of radio waves to display in one-segment broadcasting and high-definition broadcasting. Therefore, when the broadcast to be viewed is switched, both the screen and the sound are interrupted, and some users feel annoyed.

  In each of the above-described embodiments, in order to correct such a deviation, image data of a broadcast (usually a high-definition broadcast) that can be displayed after decoding is completed is stored in a memory, and decoding is completed later. Then, a method of reproducing in synchronization with the scene of the broadcast (usually one-segment broadcasting) that can be displayed may be used. However, when this method is used, a large-capacity memory is required and costs are increased. Therefore, it is desirable to provide a memory considering cost effectiveness.

  In each of the above embodiments, a mobile phone has been described as an example of the mobile terminal 1, but is not limited thereto. The mobile terminal 1 according to the present embodiment may be a mobile video display terminal, a portable television receiver, or the like.

  In each of the above embodiments, the program executed by the control unit 11 is a computer such as a flexible disk, CD-ROM (Compact Disk Read-Only Memory), DVD (Digital Versatile Disk), or MO (Magneto-Optical Disk). A system that executes the above-described processing may be configured by storing and distributing the program in a readable recording medium and installing the program.

  Further, the program may be stored in a disk device or the like of a predetermined server device on a communication network such as the Internet, and may be downloaded, for example, superimposed on a carrier wave.

  In addition, when the above functions are realized by sharing an OS (Operating System), or when the functions are realized by cooperation between the OS and an application, only the part other than the OS may be stored in a medium and distributed. You may also download it.

  In addition, this invention is not limited by the said embodiment and drawing. It goes without saying that the embodiments and the drawings can be modified without changing the gist of the present invention.

  The present invention is suitable for a portable terminal that receives a broadcast signal.

  DESCRIPTION OF SYMBOLS 1 ... Portable terminal, 2 ... Keyboard, 3 ... Cursor key, 4 ... Switching button, 5 ... Display panel, 6 ... Calling microphone, 7 ... Calling speaker, 8 ... Speaker, 11 ... Control part, 12 ... Memory | storage part, DESCRIPTION OF SYMBOLS 13 ... Operation part, 14 ... Display part, 15 ... One segment demodulation and decoding part, 16 ... Full segment demodulation and decoding part, 17 ... Audio | voice output part, 18 ... Audio | voice input part, 19 ... Communication part, 20 ... Bus, 24 ... Timer , 31 ... antenna, 41 ... transmitting station, 42, 43 ... area, 51, 52 ... segment, 150 ... one-segment tuner unit, 151 ... receiver, 152 ... CNR measuring device, 153 ... demodulator, 154 ... BER measuring device, 155... CNR output line, 156... BER output line, 157... TS output line, 159... One-segment decoding unit, 160 .. full segment tuner unit, 161... Receiver, 162. 63 ... demodulator, 164 ... BER meter, 165 ... CNR output lines, 166 ... BER output lines, 167 ... TS output line 168 ... descramble section, 169 ... Full Seg decoding unit, 1100 ... threshold range table

Claims (12)

A first tuner for receiving and demodulating the first broadcast;
A second tuner for receiving and demodulating a second broadcast of higher quality than the first broadcast;
Playback means for playing back either the first broadcast or the second broadcast;
A control device for controlling a television device comprising:
First determination means for determining, at a predetermined timing, whether or not an activation condition for activating the second tuner is satisfied based on the reception quality of the first broadcast;
Starting means for starting the second tuner when the determination in the first determination means is affirmed;
Second determination means for determining at a predetermined timing whether or not the reception quality of the second broadcast output from the activated second tuner is better than a predetermined reference;
An adjustment unit for adjusting the activation condition in the first determination unit when the determination by the second determination unit is denied;
A control device comprising: A stop means for stopping the second tuner when the determination by the second determination means is denied;
The control device according to claim 1. The adjusting means includes
If the determination by the second determination unit is denied after the activation unit has activated the second tuner, the activation condition is adjusted in a direction in which the determination by the first determination unit is less likely to be affirmed. ,
The control device according to claim 1 or 2, wherein The adjusting means includes
When the reception quality of the first broadcast does not satisfy the activation condition, but satisfies another condition that is milder according to the activation condition,
Adjusting the activation condition in a direction in which the determination in the first determination means is less likely to be affirmed;
The control apparatus according to claim 1, wherein the control apparatus is a control apparatus. The start condition includes
At least one of an upper limit and a lower limit is provided,
The control device according to any one of claims 1 to 4, wherein The reproducing means includes
A first television priority mode for preferentially reproducing the first broadcast;
A second television priority mode for preferentially reproducing the second broadcast, as an operation mode;
The adjusting means includes
When the first television priority mode is set, the activation condition is adjusted in a direction in which the determination in the first determination unit is difficult to be affirmed,
When the second television priority mode is set, the activation condition is adjusted in a direction in which the determination in the first determination unit is easily affirmed;
The control device according to any one of claims 1 to 5, wherein The first discrimination means includes
It is determined that the reception quality of the first broadcast is better than the threshold value continuously for a specific period as the activation condition,
The adjusting means includes
When adjusting in a direction in which the determination in the first determination means is less likely to be affirmed, the specific period is lengthened,
When adjusting in a direction in which the determination in the first determination unit is likely to be affirmed, the specific period is shortened.
The control device according to claim 1, wherein the control device is a control device. The first discrimination means includes
It is determined that the reception quality of the first broadcast is better than the threshold value continuously for a specific period as the activation condition,
The adjusting means includes
When adjusting in a direction in which the determination in the first determination unit is difficult to be affirmed, the threshold is increased,
When adjusting in a direction in which the determination in the first determination unit is easily affirmed, the threshold value is lowered.
The control device according to claim 1, wherein the control device is a control device. The reception quality of the first broadcast is
It is at least one of the ratio of noise power to carrier power included in the data, bit error rate, and electric field strength of the broadcast signal.
The control device according to claim 1, wherein the control device is a control device.   A portable terminal provided with the control apparatus as described in any one of Claims 1 thru | or 9. A first tuner for receiving and demodulating the first broadcast;
A second tuner for receiving and demodulating a second broadcast of higher quality than the first broadcast;
Playback means for playing back either the first broadcast or the second broadcast;
A control method for controlling a television device comprising:
A first determination step of determining at a predetermined timing whether or not an activation condition for activating the second tuner is satisfied based on the reception quality of the first broadcast;
An activation step of activating the second tuner when the determination in the first determination step is affirmed;
A second determination step of determining at a predetermined timing whether or not the reception quality of the second broadcast output from the activated second tuner is better than a predetermined reference;
If the determination in the second determination step is negative, an adjustment step for adjusting the activation condition in the first determination step;
Control method. A first tuner for receiving and demodulating the first broadcast;
A second tuner for receiving and demodulating a second broadcast of higher quality than the first broadcast;
Playback means for playing back either the first broadcast or the second broadcast;
A computer for controlling a television device comprising:
First determination means for determining, at a predetermined timing, whether or not an activation condition for activating the second tuner is satisfied based on the reception quality of the first broadcast;
Starting means for starting the second tuner when the determination in the first determination means is affirmed;
Second determination means for determining at a predetermined timing whether or not the reception quality of the second broadcast output from the activated second tuner is better than a predetermined reference;
An adjustment unit for adjusting the activation condition in the first determination unit when the determination by the second determination unit is denied;
Program to make it work.

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