JP2008182521A - Digital broadcast receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital broadcast receiver enabling a user to switch television receiving performance (frontend performance). <P>SOLUTION: The digital broadcast receiver includes a frontend part for receiving and demodulating a digital broadcast wave, a storing part stored with a plurality of receiving modes of the frontend part, a vide image displaying part for displaying a receiving mode selection picture stored in the storing part on the screen, and a control part for controlling setting of the frontend part by the receiving mode of the frontend part stored in the storing part. The user checks the presence/absence of a block noise by the image, can select the optimum receiving mode of the frontend part and can switch performance modes of the frontend by a key input operation of a remote controller. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a digital broadcast receiver in which the reception performance (front end performance) of a digital television can be switched by a user.

  In a conventional digital broadcast receiver, the front end, which includes a tuner and a demodulation LSI and affects the reception performance of a television, uniquely determines a register setting value without performing adaptive control. Alternatively, two or more register setting values of the demodulation LSI are prepared in advance, and the register setting values are switched by an adaptive control algorithm.

  Here, a description will be given with the configuration of a conventional digital broadcast receiver. FIG. 10 is a block diagram of a conventional digital broadcast receiver.

  In FIG. 10, a digital broadcast receiver 900 is connected to an antenna 200 for receiving broadcast waves. The digital broadcast receiver 900 can be remotely operated by the remote controller 300 so that the user can remotely operate the digital broadcast receiver 900.

  The digital broadcast receiver 900 includes an input terminal 910, a front end unit 920, a control unit 950, a remote control receiving unit 960, an OSD (On Screen Display) unit 970, and a video display unit 980.

  The input terminal 910 is an interface that inputs a broadcast wave received by the antenna 200 to the digital broadcast receiver 900.

  The front end unit 920 includes a tuner unit 921 that receives a broadcast wave input from the input terminal 910 and tunes the channel selected by the user, and a demodulation unit 922 that demodulates the tuned received signal into a video signal. . The demodulator 922 demodulates the received signal with the register setting value uniquely determined. Alternatively, a reference value for selecting an optimum register value from the received signal is calculated, and an adaptive algorithm for setting the optimum register value based on the reference value is operated and demodulated.

  The control unit 950 causes the OSD unit 970 to display an OSD diagram when the user inputs an instruction such as an operation guide display from the remote controller 300. In addition, the channel tuning instruction input by the user using the remote controller 300 is output to the tuner unit 921 of the front end unit 920.

  The remote control receiving unit 960 converts an instruction input by the user with the remote control 300 from a remote control signal to an electrical signal, and transmits the electrical signal to the control unit 950.

  The OSD unit 970 creates an OSD screen other than the received video, such as creating an operation guide diagram according to an instruction from the control unit 950.

The video display unit 980 displays the video signal demodulated by the demodulation unit 922 of the front end unit 920, or displays the video signal created by the OSD unit 970 on the video signal. The video display unit 980 includes a plasma display, a liquid crystal panel, a cathode ray tube, and the like.
JP 2002-374430 A

  However, there are a wide variety of signals that are actually received by the antenna, and when a situation occurs in which a signal greatly deviating from the assumption of the adaptive control algorithm is received, the adaptive control algorithm does not operate correctly in the conventional configuration. There is a problem in that block noise may occur as a reception result without being a register set value suitable for the reception signal. In addition, when receiving a non-standard signal as a transmission side or when receiving in a difficult viewing area, there is a problem that the adaptive control algorithm does not operate correctly and block noise occurs.

  SUMMARY OF THE INVENTION The present invention solves the above-described conventional problems, and an object thereof is to provide a digital broadcast receiver that allows a user to switch television reception performance (float end performance).

  In order to solve the conventional problems, a digital broadcast receiver according to the present invention includes a front end unit that receives and demodulates a digital broadcast wave, a storage unit that stores a plurality of reception modes of the front end unit, and a storage unit. A video display unit that displays the stored reception mode selection screen on the screen and a control unit that controls the setting of the front end unit according to the reception mode of the front end unit stored in the storage unit are provided.

  Further, the digital broadcast receiver of the present invention displays a front end unit that receives and demodulates digital broadcast waves, a storage unit that stores a plurality of reception modes of the front end unit, and a reception mode selection screen that is stored in the storage unit. A video display unit to display, a control unit that controls the setting of the front end unit according to the reception mode of the front end unit stored in the storage unit, and a block noise detection unit that detects the block noise amount of the video demodulated by the front end unit The control unit causes the video display unit to display the block noise amount detected by the block noise detection unit on the screen.

  Further, the digital broadcast receiver of the present invention displays a front end unit that receives and demodulates digital broadcast waves, a storage unit that stores a plurality of reception modes of the front end unit, and a reception mode selection screen that is stored in the storage unit. A video display unit to be displayed, a control unit for controlling the setting of the front end unit according to the reception mode of the front end unit stored in the storage unit, and a bit error rate calculation for calculating a bit error rate of a signal demodulated by the front end unit The control unit causes the video display unit to display the bit error rate amount calculated by the bit error rate calculation unit on the screen.

  With this configuration, the user can confirm the optimum reception mode of the front end, and the front end performance mode can be switched by a key input operation of the remote controller.

  According to the digital broadcast receiver of the present invention, when a variety of signals received by an antenna receive a signal greatly deviating from the assumption of the adaptive control algorithm, or when a signal outside the standard as a transmission side is difficult. When receiving in a viewing area, it is possible to provide an image that does not generate block noise.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

(Embodiment 1)
First, the configuration of the digital broadcast receiver of the present invention will be described. FIG. 1 is a block diagram of a digital broadcast receiver according to Embodiment 1 of the present invention.

  In FIG. 1, a digital broadcast receiver 100 is connected to an antenna 200 for receiving broadcast waves. The digital broadcast receiver 100 can be remotely operated by a remote controller 300 so that the user can remotely operate the digital broadcast receiver 100.

  The digital broadcast receiver 100 includes an input terminal 110, a front end unit 120, a storage unit 140, a control unit 150, a remote control receiving unit 160, an OSD (On Screen Display) unit 170, and a video display unit 180. It is configured.

  The input terminal 110 is an interface for inputting a broadcast wave received by the antenna 200 to the digital broadcast receiver 100.

  The front end unit 120 includes a tuner unit 121 that receives a broadcast wave input from the input terminal 110 and tunes the channel selected by the user, and a demodulation unit 122 that demodulates the tuned received signal into a video signal. . The demodulator 122 demodulates the received signal in the front-end reception mode instructed by the user via the controller 150.

  The storage unit 140 stores a plurality of reception modes of the demodulation unit 122 of the front end unit 120. The plurality of modes are a normal reception mode and a mode that strengthens important performance of the front end performance, and two or more types are prepared. Then, it is assumed that the front end reinforcement mode A and the front end reinforcement mode B are used. Then, the register values of the normal reception mode, front end enhancement mode A, and front end enhancement mode B are prepared in the storage unit 140.

  The normal reception mode is a mode in which two or more types of register setting values of the demodulator 122 are prepared in advance and the register setting values are switched by an adaptive control algorithm. The front end enhancement modes A and B are not adaptively controlled, but one type of register value is prepared for each, and the performance of enhancement is different between A and B. For example, in the front end enhancement mode A, a register value for enhancing the anti-phase noise performance is prepared. In the front-end enhancement mode B, a register value that enhances the ghost performance is prepared. Note that the front end enhancement mode may be prepared not only in the phase noise performance and ghost performance but also in all the components constituting the demodulator 122 such as noise performance and AGC tracking performance, so that the number of reception modes can be increased. Can be extended.

  When the user inputs an instruction to select the front-end reception mode with the remote controller 300, the control unit 150 causes the OSD unit 170 to display the reception mode selection diagram of FIG. Then, the reception mode selected by the user using the remote controller 300 is selected from the plurality of modes stored in the storage unit 140, and is output to the demodulation unit 122 of the front end unit 120, and the front end unit is selected. 120 controls the received signal to be decoded in the optimum reception mode.

  The remote control receiving unit 160 converts an instruction input by the user using the remote control 300 from a remote control signal to an electrical signal and transmits the electrical signal to the control unit 150.

  The OSD unit 170 creates a reception mode selection diagram in FIG. 2 or creates an OSD screen in accordance with an instruction from the control unit 150.

  The video display unit 180 displays the video signal demodulated by the demodulation unit 122 of the front end unit 120, or displays the video signal created by the OSD unit 170 on the video signal. The video display unit 180 includes a plasma display, a liquid crystal panel, a cathode ray tube, and the like.

  Next, the flow of the digital broadcast receiver of the present invention will be described. FIG. 3 is a flowchart of reception mode selection of the digital broadcast receiver in Embodiment 1 of the present invention.

  When selecting the reception mode of the front-end of the terrestrial digital broadcasting channel to be tuned by the user other than the normal reception mode, first, the control unit 150 inputs a remote control signal via the remote control reception unit 160 and displays the reception mode selection screen. Confirm that it is an instruction to enter. Then, the control unit 150 instructs the OSD unit 170 to create a reception mode selection diagram of the digital broadcast receiver of FIG. 2, and causes the video display unit 180 to display a reception mode selection screen (step S410).

  The reception mode is set to 1 (normal reception mode) at the time of shipment. On the reception mode selection screen, the user can select either setting 2 (front end enhancement mode A) or setting 3 (front end enhancement mode) with the remote controller 300. It becomes possible to select. The control unit 150 confirms whether the user has selected a reception mode other than setting 1 (normal reception mode) (step S420). When a setting other than setting 1 (normal reception mode) is selected in step S420, for example, when the user selects setting 2 (front end enhancement mode A) on the remote control 300, the control unit 150 inputs the remote control input via the remote control reception unit 160. It is determined that the reception mode of the channel currently being tuned from the signal is changed to setting 2 (front end enhancement mode A). Then, the control unit 150 calls the setting register value of setting 2 (front end enhancement mode A) stored in the storage unit 140 (step S430), and outputs the setting register value to the demodulation unit 122 of the front end unit 120. Control is performed so that re-demodulation is performed with the setting register value of setting 2 (front end enhancement mode A) (step S440).

  If setting 1 (normal reception mode) is selected in step S420, the reception mode selection is terminated.

  The user determines whether the reception result is good by looking at the video reception screen (step S470). If it is determined in step S470 that the reception result is good, the remote controller 300 issues an instruction to complete the reception mode selection so that the reception mode selection in that channel is completed and the reception mode is fixed. The control unit 150 inputs a reception mode selection completion instruction from the user via the remote control reception unit 160, and stores the reception mode re-demodulated last in the storage unit 140 as the optimum reception mode of the channel (step S480).

  Alternatively, when it is not determined that the reception result in step S470 is good, the process returns to step S420 again, and re-demodulation from step S430 to step S440 is performed in another reception mode. Then, the user looks at the video screen to determine whether the reception result is good (step S470), and selects an optimal reception mode. The control unit 150 stores the reception mode selected by the user in the storage unit 140 as the optimum reception mode for the channel (step S480). With these flows, selection of the reception mode of the digital broadcast receiver of the present invention is completed.

  According to such a configuration, a mode that emphasizes performance important for front-end performance is provided, and it is possible to select an optimal reception mode by performing mode setting by a user key input operation, and there is little block noise. A good image can be output.

(Embodiment 2)
First, the configuration of the digital broadcast receiver of the present invention will be described. FIG. 4 is a block diagram of a digital broadcast receiver according to Embodiment 2 of the present invention.

  In FIG. 4, an antenna 200 is connected to a digital broadcast receiver 500 in order to receive broadcast waves. The digital broadcast receiver 500 can be remotely operated by the remote controller 300 so that the user can remotely operate the digital broadcast receiver 500.

  The digital broadcast receiver 500 includes an input terminal 510, a front end unit 520, a block noise detection unit 530, a storage unit 540, a control unit 550, a remote control receiving unit 560, an OSD (On Screen Display) unit 570, and the like. , And a video display unit 580.

  The input terminal 510 is an interface for inputting a broadcast wave received by the antenna 200 to the digital broadcast receiver 500.

  The front end unit 520 includes a tuner unit 521 that receives a broadcast wave input from the input terminal 510 and tunes the channel selected by the user, and a demodulation unit 522 that demodulates the tuned received signal into a video signal. . The demodulator 522 demodulates the received signal in the front-end reception mode instructed by the user via the controller 550.

  The block noise detection unit 530 quantitatively detects block noise included in the video signal demodulated by the demodulation unit 522. The detection result is calculated as data of two elements of block noise magnitude and quantity. Then, the detection result of the block noise is output to the control unit 550.

  The storage unit 540 stores a plurality of reception modes of the demodulation unit 522 of the front end unit 520. The plurality of modes are a normal reception mode and a mode that strengthens important performance of the front end performance, and two or more types are prepared. Then, it is assumed that the front end reinforcement mode A and the front end reinforcement mode B are used. Then, the register values of the normal reception mode, the front end enhancement mode A, and the front end enhancement mode B are prepared in the storage unit 540.

  The normal reception mode is a mode in which two or more register setting values of the demodulator 522 are prepared in advance and the register setting values are switched by an adaptive control algorithm. The front end enhancement modes A and B are not adaptively controlled, but one type of register value is prepared for each, and the performance of enhancement is different between A and B. For example, in the front end enhancement mode A, a register value for enhancing the anti-phase noise performance is prepared. In the front-end enhancement mode B, a register value that enhances the ghost performance is prepared. The front end enhancement mode may be prepared not only in the phase noise performance and ghost performance, but also in all the components constituting the demodulator 522 such as noise performance and AGC tracking performance, and the number of reception modes can be increased. Can be extended.

  The control unit 550 causes the OSD unit 570 to display the reception mode selection diagram of FIG. 5 when the user inputs an instruction to select the reception mode of the front end using the remote controller 300. Then, the reception mode selected by the user using the remote controller 300 is selected from the plurality of modes stored in the storage unit 540, and is output to the demodulation unit 522 of the front end unit 520, and the front end unit is selected. 520 controls the received signal to be decoded in the optimum reception mode. After the demodulation unit 522 demodulates, the control unit 550 receives the block noise detection result of the video signal detected by the block noise detection unit 530 and outputs the block noise detection result to the OSD unit 570 for each reception mode. Further, the block noise detection result for each channel reception mode is stored in the storage unit 540, and the reception mode set for each channel by the user is also stored in the storage unit 540. Also, the channel tuning instruction input by the user using the remote controller 300 is output to the tuner unit 521 of the front end unit 520.

  The remote control receiving unit 560 converts an instruction input by the user with the remote control 300 from a remote control signal to an electrical signal and transmits the electrical signal to the control unit 550.

  The OSD unit 570 creates a reception mode selection diagram of FIG. 5 according to an instruction from the control unit 550, creates a diagram that displays a block noise detection result for each reception mode, and creates an OSD screen.

  The video display unit 580 displays the video signal demodulated by the demodulation unit 522 of the front end unit 520 or displays the video signal generated by the OSD unit 570 on the video signal. The video display unit 580 includes a plasma display, a liquid crystal panel, a cathode ray tube, and the like.

  Next, the flow of the digital broadcast receiver of the present invention will be described. FIG. 6 is a flowchart of reception mode selection of the digital broadcast receiver in Embodiment 2 of the present invention.

  When the reception mode of the front-end digital terrestrial broadcasting channel to be tuned by the user is selected other than the normal reception mode, the control unit 550 first inputs a remote control signal via the remote control reception unit 560 and displays the reception mode selection screen. Confirm that it is an instruction to enter. Then, the control unit 550 instructs the OSD unit 570 to create a reception mode selection diagram of the digital broadcast receiver of FIG. 5, and causes the video display unit 580 to display a reception mode selection screen (step S410).

  The reception mode is set to 1 (normal reception mode) at the time of shipment. On the reception mode selection screen, the user can select either setting 2 (front end enhancement mode A) or setting 3 (front end enhancement mode) with the remote controller 300. It becomes possible to select. Control unit 550 confirms whether the user has selected a reception mode other than setting 1 (normal reception mode) (step S420). When a setting other than setting 1 (normal reception mode) is selected in step S420, for example, when the user selects setting 2 (front end enhancement mode A) on the remote control 300, the control unit 550 inputs the remote control input via the remote control reception unit 560. It is determined that the reception mode of the channel currently being tuned from the signal is changed to setting 2 (front end enhancement mode A). Then, the control unit 550 calls the setting register value of setting 2 (front end enhancement mode A) stored in the storage unit 540 (step S430), and outputs the setting register value to the demodulation unit 522 of the front end unit 520. The demodulation unit 522 Control is performed so that re-demodulation is performed with the setting register value of setting 2 (front end enhancement mode A) (step S440).

  If setting 1 (normal reception mode) is selected in step S420, the reception mode selection is terminated.

  When demodulation of the reception signal tuned by the demodulation unit 522 is completed, the demodulation unit 522 outputs the video signal to the block noise detection unit 530. Then, the block noise detection unit 530 quantitatively calculates and detects block noise included in the video signal as data of two elements of block noise magnitude and quantity. The block noise detection unit 530 outputs the detection result to the control unit 550 (step S450).

  The control unit 550 receives the block noise detection result from the block noise detection unit 530 and sets the OSD unit 570 to display the block noise detection result on the screen as the channel selection state in the re-demodulated setting 2 (front end enhancement mode A). Is instructed to create an OSD screen. Then, the OSD screen on which the block noise detection result created by the OSD unit 570 is displayed is displayed on the video display unit 580 (step S460).

  The user determines whether the reception result is good by looking at the block noise detection result (step S470). If it is determined in step S470 that the reception result is good, the remote controller 300 issues an instruction to complete the reception mode selection so that the reception mode selection in that channel is completed and the reception mode is fixed. The control unit 550 inputs a reception mode selection completion instruction from the user via the remote control reception unit 560, and stores the reception mode re-demodulated last in the storage unit 540 as the optimum reception mode of the channel (step S480).

  Alternatively, if it is not determined that the reception result in step S470 is good, the process returns to step S420 again, and re-demodulates from step S430 to step S450 in another reception mode. Then, the control unit 550 instructs the OSD display unit 570 to display the block noise detection results re-selected in a plurality of modes on the screen, and OSD displays the plurality of block noise detection results on the video display unit 580 (step S460). ). Then, the user determines whether the reception result is good by looking at the plurality of block noise detection results displayed on the video display unit 580 (step S470), and selects an optimal reception mode. The control unit 550 stores the reception mode selected by the user in the storage unit 540 as the optimum reception mode for the channel (step S480). With these flows, selection of the reception mode of the digital broadcast receiver of the present invention is completed.

  According to this configuration, it is possible to select an optimal reception mode by setting a mode that is important for the front-end performance and setting the mode based on the user's key input operation and block noise detection result. Thus, a good image with less block noise can be output.

  In the present embodiment, the optimum reception mode is stored in the storage unit 540 by the user's remote controller 300, but the control unit 550 may automatically store the optimum reception mode in the recording unit 540 based on the block noise detection result. In this case, when the user instructs reception mode selection on a specific channel from the remote controller 300, the control unit 550 calls each reception mode from the storage unit 540 in accordance with the instruction input via the remote control reception unit 560. Then, the demodulation unit 522 of the front end unit 520 performs re-demodulation for each received reception mode, and outputs an image to the block noise detection unit 530. Then, the block noise detection unit 530 outputs the detection result of the block noise included in the video to the control unit 550. The control unit 550 instructs the demodulation unit 522 to re-demodulate all the reception modes stored in the storage unit 540, and inputs the block noise detection result in all the reception modes from the block noise detection unit 530, and then the optimum Select the reception mode. Then, the control unit 550 instructs the OSD unit 560 to create an OSD screen that displays the block noise detection results of all reception modes, and causes the video display unit 580 to display the block noise detection results of all reception modes. Furthermore, the control unit 550 causes the storage unit 540 to store the optimum reception mode for that channel.

  In this embodiment, the optimum reception mode for one selected channel is selected. However, the optimum reception mode for all reception channels may be selected. In this case, for example, when the tuning setting is performed from the low channel to the high channel at the initial channel tuning setting, the above reception mode selection algorithm is applied to each channel.

(Embodiment 3)
First, the configuration of the digital broadcast receiver of the present invention will be described. FIG. 7 is a block diagram of a digital broadcast receiver according to Embodiment 3 of the present invention.

  In FIG. 7, an antenna 200 is connected to a digital broadcast receiver 700 in order to receive broadcast waves. The digital broadcast receiver 700 can be remotely operated by the remote controller 300 so that the user can remotely operate the digital broadcast receiver 700.

  The digital broadcast receiver 700 includes an input terminal 710, a front end unit 720, a bit error rate calculation unit 730, a storage unit 740, a control unit 750, a remote control reception unit 760, and an OSD (On Screen Display) unit 770. And a video display unit 780.

  The input terminal 710 is an interface that inputs a broadcast wave received by the antenna 200 to the digital broadcast receiver 700.

  The front end unit 720 includes a tuner unit 721 that receives a broadcast wave input from the input terminal 710 and tunes the channel selected by the user, and a demodulation unit 722 that demodulates the tuned received signal into a video signal. . The demodulator 722 demodulates the received signal in the front-end reception mode instructed by the user via the controller 750.

  The bit error rate calculation unit 730 calculates the error rate per bit calculated by the error correction unit of the demodulation unit 722. The calculation result is represented by a number of 1 or less. For example, when there is a 1-bit error for 100 bits, it is calculated as a quantity of 1 × 10 −2, and if it is zero, it can be determined that there is no error. . Then, the calculation result of the bit error rate is output to the control unit 750.

  The storage unit 740 stores a plurality of reception modes of the demodulation unit 722 of the front end unit 720. The plurality of modes are a normal reception mode and a mode that strengthens important performance of the front end performance, and two or more types are prepared. Then, it is assumed that the front end reinforcement mode A and the front end reinforcement mode B are used. Then, the register values of the normal reception mode, front end enhancement mode A, and front end enhancement mode B are prepared in the storage unit 740.

  The normal reception mode is a mode in which two or more register setting values of the demodulator 722 are prepared in advance and the register setting values are switched by an adaptive control algorithm. The front end enhancement modes A and B are not adaptively controlled, but one type of register value is prepared for each, and the performance of enhancement is different between A and B. For example, in the front end enhancement mode A, a register value for enhancing the anti-phase noise performance is prepared. In the front-end enhancement mode B, a register value that enhances the ghost performance is prepared. Note that the front end enhancement mode may be prepared not only in the phase noise performance and ghost performance but also in all the components constituting the demodulator 722 such as noise performance and AGC tracking performance, so that the number of reception modes can be increased. Can be extended.

  The control unit 750 causes the OSD unit 770 to display the reception mode selection diagram of FIG. 8 when the user inputs an instruction to select the reception mode of the front end using the remote controller 300. Then, the reception mode selected by the user using the remote controller 300 is selected from the plurality of modes stored in the storage unit 740, and is output to the demodulation unit 722 of the front end unit 720, and the front end unit is selected. 720 controls to decode the received signal in the optimum receiving mode. After the demodulation unit 722 demodulates, the control unit 750 receives the bit error rate detection result calculated by the bit error rate calculation unit 730 and outputs the bit error rate calculation result to the OSD unit 770 for each reception mode. Furthermore, the calculation result of the bit error rate for each reception mode of each channel is stored in the storage unit 740, and the reception mode set for each channel by the user is also stored in the storage unit 740. In addition, a channel tuning instruction input by the user using the remote controller 300 is output to the tuner unit 721 of the front end unit 720.

  The remote control receiving unit 760 converts an instruction input by the user with the remote control 300 from a remote control signal to an electrical signal and transmits the electrical signal to the control unit 750.

  The OSD unit 770 creates a diagram for selecting the reception mode in FIG. 8 according to an instruction from the control unit 750, creates a diagram for displaying the detection result of the block noise for each reception mode, and creates an OSD screen.

  The video display unit 780 displays the video signal demodulated by the demodulation unit 722 of the front end unit 720, or displays the video signal created by the OSD unit 770 on the video signal. The video display unit 780 includes a plasma display, a liquid crystal panel, a cathode ray tube, and the like.

  Next, the flow of the digital broadcast receiver of the present invention will be described. FIG. 9 is a flowchart of reception mode selection of the digital broadcast receiver in Embodiment 1 of the present invention.

  When selecting the reception mode of the front-end of the terrestrial digital broadcasting channel to be tuned by the user other than the normal reception mode, the control unit 750 first inputs a remote control signal via the remote control receiving unit 760, and displays the reception mode selection screen. Confirm that it is an instruction to enter. Then, the control unit 750 instructs the OSD unit 770 to create the reception mode selection diagram of the digital broadcast receiver of FIG. 5, and causes the video display unit 780 to display a reception mode selection screen (step S410).

  The reception mode is set to 1 (normal reception mode) at the time of shipment. On the reception mode selection screen, the user can select either setting 2 (front end enhancement mode A) or setting 3 (front end enhancement mode) with the remote controller 300. It becomes possible to select. The control unit 750 confirms whether the user has selected a reception mode other than setting 1 (normal reception mode) (step S420). When a setting other than setting 1 (normal reception mode) is selected in step S420, for example, when the user selects setting 2 (front end enhancement mode A) on the remote control 300, the control unit 750 inputs the remote control input via the remote control reception unit 760. It is determined that the reception mode of the channel currently being tuned from the signal is changed to setting 2 (front end enhancement mode A). Then, the control unit 750 calls the setting register value of setting 2 (front end enhancement mode A) stored in the storage unit 740 (step S430), and outputs the setting register value to the demodulation unit 722 of the front end unit 720. The demodulation unit 722 Control is performed so that re-demodulation is performed with the setting register value of setting 2 (front end enhancement mode A) (step S440).

  If setting 1 (normal reception mode) is selected in step S420, the reception mode selection is terminated.

  When the demodulation of the reception signal tuned by the demodulator 722 is completed, the demodulator 722 outputs the bit error rate calculator 730. Then, the bit error rate calculation unit 730 outputs the calculation result of the bit error rate in the video signal to the control unit 750 (step S455).

  The control unit 750 receives the bit error rate calculation result from the bit error rate calculation unit 730, and displays the bit error rate calculation result on the screen as the channel selection state in the re-demodulated setting 2 (front end enhancement mode A). The OSD unit 770 is instructed to create an OSD screen. Then, the OSD screen on which the bit error rate calculation result created by the OSD unit 770 is displayed is displayed on the video display unit 780 (step S465).

  The user determines whether the reception result is good by looking at the bit error rate calculation result (step S470). If it is determined in step S470 that the reception result is good, the remote controller 300 issues an instruction to complete the reception mode selection so that the reception mode selection in that channel is completed and the reception mode is fixed. The control unit 750 inputs a reception mode selection completion instruction from the user via the remote control reception unit 760, and stores the reception mode re-demodulated last in the storage unit 740 as the optimal reception mode of the channel (step S480).

  Alternatively, if it is not determined that the reception result in step S470 is good, the process returns to step S420 again, and re-demodulates from step S430 to step S450 in another reception mode. Then, the control unit 750 instructs the OSD display unit 770 to display the bit error rate calculation results re-selected in a plurality of modes on the screen, and OSD displays the plurality of bit error rate calculation results on the video display unit 780 ( Step S460). Then, the user determines whether the reception result is good by looking at a plurality of bit error rate calculation results displayed on the video display unit 780 (step S470), and selects an optimal reception mode. The control unit 750 stores the reception mode selected by the user in the storage unit 740 as the optimum reception mode for the channel (step S480). With these flows, selection of the reception mode of the digital broadcast receiver of the present invention is completed.

  According to such a configuration, a mode that emphasizes performance important for front-end performance is provided, and an optimum reception mode is selected by setting a mode by a user key input operation and a bit error rate calculation result. Therefore, it is possible to output a good image with less block noise.

  In the present embodiment, the optimum reception mode is stored in the storage unit 740 by the user's remote controller 300. However, the control unit 750 may automatically store the optimum reception mode in the recording unit 740 based on the bit error rate calculation result. In that case, when the user instructs reception mode selection on the specific channel from the remote controller 300, the control unit 750 calls each reception mode from the storage unit 740 in accordance with the instruction input via the remote control reception unit 760. Then, the demodulation unit 722 of the front end unit 720 performs re-demodulation for each received reception mode, and outputs a video to the bit error rate calculation unit 730. Then, the bit error rate calculation unit 730 outputs the bit error rate calculation result to the control unit 750. When the control unit 750 instructs the demodulation unit 122 to re-demodulate all the reception modes stored in the storage unit 740 and inputs the bit error rate calculation results in all the reception modes from the block noise detection unit 730, Select the optimal reception mode. The control unit 750 instructs the OSD unit 760 to create an OSD screen displaying the bit error rate calculation results for all reception modes, and causes the video display unit 780 to display the bit error rate calculation results for all reception modes. Further, the control unit 750 causes the storage unit 740 to store the optimum reception mode for that channel.

  In this embodiment, the optimum reception mode for one selected channel is selected. However, the optimum reception mode for all reception channels may be selected. In this case, for example, when the tuning setting is performed from the low channel to the high channel at the initial channel tuning setting, the above reception mode selection algorithm is applied to each channel.

  Since the digital broadcast receiver according to the present invention can provide a video that does not generate block noise for various signals received by an antenna, the user can switch the reception performance (front-end performance) of the television. It is useful as a digital broadcast receiver that has been made possible.

1 is a block diagram of a digital broadcast receiver according to Embodiment 1 of the present invention. The figure of reception mode selection of the digital broadcast receiver in Embodiment 1 of this invention Flowchart of reception mode selection of digital broadcast receiver in Embodiment 1 of the present invention Block diagram of a digital broadcast receiver in Embodiment 2 of the present invention FIG. 10 is a diagram of reception mode selection of the digital broadcast receiver in Embodiment 2 of the present invention. Flowchart of reception mode selection of digital broadcast receiver in embodiment 2 of the present invention Block diagram of a digital broadcast receiver in Embodiment 3 of the present invention The figure of the reception mode selection of the digital broadcast receiver in Embodiment 3 of this invention Flowchart of selection of reception mode of digital broadcast receiver in Embodiment 3 of the present invention Block diagram of a conventional digital broadcast receiver

Explanation of symbols

100, 500, 700 Digital broadcast receiver 110, 510, 710 Input terminal 120, 520, 720 Front end 121, 521, 721 Tuner 122, 522, 722 Demodulator 140, 540, 740 Storage 150, 550, 750 Control unit 160, 560, 760 Remote control reception unit 170, 570, 770 OSD unit 180, 580, 780 Video display unit 200 Antenna 300 Remote control 530 Block noise detection unit 730 Bit error rate calculation unit

Claims (7)

A front end for receiving and demodulating digital broadcast waves;
A storage unit storing a plurality of reception modes of the front end unit;
A video display unit for displaying the reception mode selection screen stored in the storage unit;
A control unit for controlling the setting of the front end unit according to the reception mode of the front end unit stored in the storage unit;
The digital broadcast receiver characterized in that the control unit switches the reception mode of the front end unit. A front end for receiving and demodulating digital broadcast waves;
A storage unit storing a plurality of reception modes of the front end unit;
A video display unit for displaying the reception mode selection screen stored in the storage unit;
A control unit for controlling the setting of the front end unit according to the reception mode of the front end unit stored in the storage unit;
A block noise detection unit for detecting a block noise amount of the video demodulated by the front end unit;
The digital broadcast receiver, wherein the control unit causes the video display unit to display the block noise amount detected by the block noise detection unit on the screen. The digital broadcast receiver according to claim 2, wherein the control unit stores the block noise amount detected by the block noise detection unit for each of a plurality of reception modes. The digital broadcast receiver according to claim 3, wherein the control unit selects an optimum reception mode from the block noise amounts of the plurality of reception modes, and stores the selected reception mode in the storage unit. A front end for receiving and demodulating digital broadcast waves;
A storage unit storing a plurality of reception modes of the front end unit;
A video display unit for displaying the reception mode selection screen stored in the storage unit;
A control unit for controlling the setting of the front end unit according to the reception mode of the front end unit stored in the storage unit;
A bit error rate calculation unit that calculates a bit error rate of the signal demodulated by the front end unit,
The digital broadcast receiver, wherein the control unit causes the video display unit to display the bit error rate amount calculated by the bit error rate calculation unit on the screen. The digital broadcast receiver according to claim 5, wherein the control unit stores the bit error rate amount calculated by the bit error rate calculation unit for each of a plurality of reception modes. The digital broadcast receiver according to claim 6, wherein the control unit selects an optimum reception mode from the bit error rate amounts of the plurality of reception modes and stores the selected reception mode in the storage unit.

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