JP2006140846A - Television broadcasting receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To quickly display a selected television broadcasting video when television broadcastings different in system are subjected to a channel selection operation many times for a short period of time while saving power consumption and reducing radiant noise in a television broadcasting receiver capable of receiving television broadcast signals of two different systems. <P>SOLUTION: This television broadcasting receiver 1 comprises: an NTSC amplification circuit 31, an NTSC demodulation circuit 32 and a video decoder 33 for processing a broadcast signal of an NTSC system; and an ATSC amplification circuit 41, an ATSC demodulation circuit 42 and an MPEG decoder 43 for processing a broadcast signal of an ATSC system. A CPU 11 disconnects power supply of the NTSC amplification circuit 31 with a short rise time, the NTSC demodulation circuit 32 and the video decoder 33 in this order when switching reception from the NTSC system to the ATSC system, and disconnects power supply of the ATSC amplification circuit 41 with a short rise time, the ATSC demodulation circuit 42 and the MPEG decoder 43 in this order. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a television broadcast receiver for receiving a television broadcast signal distributed from a broadcasting station and displaying an image based on the television broadcast signal on a display.

  2. Description of the Related Art Conventionally, there are television broadcast receiving apparatuses that can receive television broadcast signals of two different systems, NTSC system and ATSC system. Such a television broadcast receiving apparatus generates NTSC signal processing means for processing an NTSC television broadcast signal to generate a video signal, and an ATSC television broadcast signal to generate a video signal. Signal processing means for NTSC.

  The NTSC signal processing means includes an NTSC amplifier circuit that amplifies an NTSC television broadcast signal, an NTSC demodulator circuit that demodulates the signal amplified by the amplifier circuit, and a signal demodulated by the demodulator circuit. A decoding circuit for NTSC that decodes and generates a signal related to video. The ATSC signal processing means includes an NTSC amplifier circuit that amplifies an ATSC television broadcast signal, an ATSC demodulator circuit that demodulates the signal amplified by the amplifier circuit, and a demodulator circuit that demodulates the signal. And an ATSC decoding circuit that decodes the signal to generate a video signal.

  Further, in a television broadcast receiving apparatus capable of receiving MUSE and NTSC television broadcast signals, when receiving a MUSE broadcast, the power supply to the MUSE signal processing circuit and the power supply to the NTSC signal processing circuit are cut off. When receiving NTSC broadcasts, power is supplied to the signal processing circuit for NTSC and power supply to the signal processing circuit for MUSE is cut off, thereby preventing mutual interference between the signal processing circuit for MUSE and the signal processing circuit for NTSC. What was made to do is known (for example, refer patent document 1).

Also, in a television broadcast receiver capable of receiving high-definition television and NTSC television broadcast signals, when receiving high-definition television broadcasts, power is supplied to the signal processing circuit and audio decoder for high-definition television and video for NTSC. The power supply to the output circuit, the signal processing circuit, and the audio decoder is cut off, and the NTSC video output circuit, the signal processing circuit, the audio decoder are supplied with power when receiving the NTSC broadcast, and the signal processing circuit for the high-definition television broadcast is provided. A device that saves power consumption by cutting off the power supply to the audio decoder is known (see, for example, Patent Document 2).
JP-A-8-223499 JP-A-2-154585

  By the way, in the conventional television broadcast receiving apparatus described above, if power is supplied to both the NTSC signal processing means and the ATSC signal processing means when receiving the NTSC television broadcast, the power is supplied to the ATSC signal processing means. Power is wasted, and radiation noise from each circuit of the signal processing means for ATSC adversely affects each circuit of the signal processing means for NTSC. A similar problem occurs when power is supplied to both the ATSC signal processing means and the NTSC signal processing means when receiving an ATSC television broadcast.

  Therefore, as described in Patent Document 1 and Patent Document 2, it is conceivable to cut off power supply to a circuit for television broadcasting of the other system when receiving the television broadcasting of one system. In the television broadcast receivers described in Patent Literature 1 and Patent Literature 2, power supply to all circuits for television broadcasting of the other system is cut off during reception of the television broadcasting of the other system. Therefore, in the above-described conventional television broadcast receiving apparatus, when receiving the NTSC television broadcast, power is supplied to the NTSC signal processing means and power supply to all circuits of the ATSC signal processing means is cut off. It is conceivable to cut off the power supply to all the circuits of the signal processing means for NTSC while supplying power to the signal processing means for ATSC at the time of receiving the TV broadcast.

  However, when such a configuration is adopted, for example, when a channel selection operation for receiving an ATSC television broadcast is performed during reception of an NTSC television broadcast, the channel selection operation is performed and then the signal processing means for ATSC is used. When power is supplied, each circuit of the signal processing means for ATSC starts up in a state where signal processing is possible. As a result, it takes time for each circuit of the ATSC signal processing means to start up after the channel selection operation until the image is displayed. I can't. Similarly, when a channel selection operation for receiving an NTSC television broadcast is performed while an ATSC television broadcast is being received, the television broadcast video cannot be viewed immediately even if the channel selection operation is performed. This is a big problem when searching for a program to be viewed by selecting various TV broadcast channels and watching the video displayed on the display.

  The present invention has been made in order to solve the above-described problems. When a television broadcast of a different system is selected many times in a short period of time while saving power consumption and reducing radiation noise, the present invention is selected. An object of the present invention is to provide a television broadcast receiving apparatus capable of quickly displaying a television broadcast image.

  In order to achieve the above object, the invention of claim 1 is directed to receiving means for receiving a television broadcast signal modulated and distributed from a broadcasting station to a carrier wave of a predetermined frequency, and among the television broadcast signals received by the receiving means, NTSC NTSC signal processing means for processing a television broadcast signal of a system to generate a signal related to video, and an ATSC signal for processing a television broadcast signal of the ATSC system among the television broadcast signals received by the receiving means to generate a signal related to video Processing means, analog video processing means for processing a signal related to the video generated by the NTSC signal processing means or ATSC signal processing means into a signal in a format capable of displaying video on an analog display connected to the apparatus, and NTSC signal Signals related to video generated by the processing means or ATSC signal processing means are connected to this device. Digital video processing means for processing signals in a format that can display video on a digital display, and power for controlling power supply to NTSC signal processing means, ATSC signal processing means, analog video processing means, and digital video processing means A power supply control means, and when the power supply control means receives an NTSC television broadcast signal, it supplies power to the NTSC signal processing means and cuts off the power supply to the ATSC signal processing means, thereby providing an ATSC television. When a broadcast signal is received, the NTSC signal processing means cuts off the power supply to the NTSC signal processing means and supplies power to the ATSC signal processing means. The NTSC signal processing means receives the NTSC television broadcast received by the receiving means. Increased by NTSC amplifier and NTSC amplifier to amplify signals An NTSC demodulating circuit for demodulating the received signal, and an NTSC decoding circuit for decoding the signal demodulated by the NTSC demodulating circuit to generate a signal related to video, and the ATSC signal processing means is an ATSC system received by the receiving means. An ATSC amplifier circuit that amplifies a television broadcast signal, an ATSC demodulator circuit that demodulates the signal amplified by the ATSC amplifier circuit, and an ATSC decoder circuit that decodes the signal demodulated by the ATSC demodulator circuit and generates a signal related to video The NTSC amplifier circuit, the NTSC demodulator circuit, and the ATSC amplifier circuit are each separately made into an analog IC, and the NTSC decoder circuit, the ATSC demodulator circuit, and the ATSC decoder circuit are each separately made into a digital IC, NTSC amplification circuit, NTSC demodulation circuit, NTSC decoding circuit, ATSC amplification circuit In order to individually turn on and off the power supply to the circuit, the ATSC demodulation circuit, the ATSC decoding circuit, the analog video processing means, and the digital video processing means, a plurality of switches individually provided corresponding thereto are further provided. The power supply control means individually turns on and off each switch, thereby providing an NTSC amplification circuit, NTSC demodulation circuit, NTSC decoding circuit, ATSC amplification circuit, ATSC demodulation circuit, ATSC decoding circuit, analog video processing means, and When individually controlling the power supply to the digital video processing means and switching from the reception of the NTSC television broadcast signal to the reception of the ATSC television broadcast signal, the ATSC amplification circuit, the ATSC demodulation circuit, and the ATSC decoding circuit After starting the power supply, first cut off the power supply to the NTSC amplifier circuit, then the NTS When the power supply to the demodulation circuit is cut off, and finally the power supply to the NTSC decoding circuit is cut off to switch from the reception of the ATSC television broadcast signal to the reception of the NTSC television broadcast signal, the NTSC amplification circuit and the NTSC demodulation circuit , And after starting the power supply to the NTSC decoding circuit, first the power supply to the ATSC amplifier circuit is cut off, then the power supply to the ATSC demodulation circuit is cut off, and finally the power supply to the ATSC decoding circuit is cut off. When displaying an image on an analog display, supply power to the analog video processing means and cut off the power supply to the digital video processing means. When displaying an image on the digital display, the digital video processing means And the power supply to the analog video processing means is cut off.

  The invention of claim 2 is a receiving means for receiving a television broadcast signal that is modulated and distributed from a broadcasting station to a carrier wave of a predetermined frequency, and a television broadcast signal of the first method among the television broadcast signals received by the receiving means. A first signal processing means for generating a signal relating to video by processing a second television broadcasting signal among the television broadcast signals received by the receiving means to generate a signal relating to the video Signal processing means and power supply control means for controlling power supply to the first and second signal processing means, and the power supply control means receives the first type of television broadcast signal when When power is supplied to the first signal processing means and the power supply to the second signal processing means is cut off, and when a second type television broadcast signal is received, the power supply to the first signal processing means is cut off. With the second In the television broadcast receiving apparatus that supplies power to the signal processing means, the first signal processing means includes a first amplification circuit that amplifies the first-type television broadcast signal received by the reception means, and a first amplification circuit. A first demodulating circuit for demodulating the signal amplified by the first demodulating circuit, and a first decoding circuit for decoding the signal demodulated by the first demodulating circuit to generate a signal related to video, and second signal processing means The second amplifying circuit for amplifying the second type television broadcast signal received by the receiving means, the second demodulating circuit for demodulating the signal amplified by the second amplifying circuit, and the second demodulating circuit And a second decoding circuit that decodes the signal demodulated in accordance with the above and generates a signal related to video, and the power supply control means includes a first amplifier circuit, a first demodulation circuit, a first decoding circuit, and a second decoding circuit. Amplifier circuit, second demodulator circuit, The power supply of the beauty to the second decoding circuit is for controlling individually.

  According to a third aspect of the present invention, in the television broadcast receiving apparatus according to the second aspect, the first decoding circuit and the second decoding circuit are each made into a digital IC, and the power supply control means is the first system. When the power supply to the first signal processing means is cut off when switching from the reception of the television broadcast signal to the reception of the television broadcast signal of the second system, first, the first amplification circuit and the first demodulation circuit are connected. When the power supply is cut off and then the power supply to the first decoding circuit is cut off to switch from the reception of the second system television broadcast signal to the reception of the first system television broadcast signal, the second signal processing means When the power supply to is cut off, the power supply to the second amplification circuit and the second demodulation circuit is first cut off, and then the power supply to the second decoding circuit is cut off.

  According to the first aspect of the present invention, when the NTSC television broadcast signal is received, the power supply to the ATSC signal processing means is cut off. When the ATSC television broadcast signal is received, the NTSC signal processing means is supplied. Since the power supply is cut off, wasteful power consumption can be suppressed and radiation noise can be suppressed. Moreover, when switching from the reception of the NTSC television broadcast signal to the reception of the ATSC television broadcast signal, the power supply is cut in the order of the short circuit rise time in the order of the NTSC amplifier circuit, the NTSC demodulation circuit, and the NTSC decoding circuit. When switching from reception of an ATSC television broadcast signal to reception of an NTSC television broadcast signal, power supply is cut in the order of short circuit rise time in the order of an ATSC amplifier circuit, an ATSC demodulation circuit, and an ATSC decoding circuit. . As a result, after switching from receiving an NTSC television broadcast signal to receiving an ATSC television broadcast signal, immediately switching back to receiving an NTSC television broadcast signal, power supply to a circuit with a long rise time is cut off. Reception of the NTSC television broadcast signal is started in a state where it is not leaned, and the video of the NTSC television broadcast signal can be quickly displayed as long as the circuit having a long rise time has already been started up. Similarly, when switching from receiving an ATSC television broadcast signal to receiving an NTSC television broadcast signal and immediately switching back to receiving an ATSC television broadcast signal, the video of the ATSC television broadcast signal is also displayed. It can be displayed quickly. Therefore, while saving power consumption and reducing radiation noise, for example, when selecting a variety of TV broadcast channels and looking for a program that you want to watch by watching the video displayed on the display, it is often in a short time. When a different type of television broadcast is selected, the selected television broadcast image can be quickly displayed. Also, when displaying TV broadcast video on an analog display, power supply to the digital video processing means is cut off, and when displaying on a digital display, power supply to the analog video processing means is cut off. Further, power consumption can be saved.

  According to the second aspect of the present invention, when receiving a television broadcast signal of the first system, the power supply to the second signal processing means is cut off, and when receiving a television broadcast signal of the second system. Since the power supply to the first signal processing means is cut off, wasteful power consumption can be suppressed and radiation noise can be suppressed. In addition, the first amplifier circuit of the first signal processing means, the first demodulation circuit, the power supply to the first decoding circuit, and the second amplification circuit and second demodulation circuit of the second signal processing means Since the power supply to the second decoding circuit is individually controlled, for example, in the first signal processing means, the first amplification circuit, the first demodulation circuit, and the first decoding circuit are controlled. In the second signal processing means, the power supply to the second amplifier circuit, the second demodulation circuit, and the second decoding circuit is performed in the order of short rise time. It is possible to cut off. In this way, after switching from reception of the first system television broadcast signal to reception of the second system television broadcast signal, immediately switching back to reception of the first system television broadcast signal, the rise time is increased. In the state where the power supply to the long circuit is not cut off, the reception of the first system television broadcast signal is started, and the circuit of the first system television broadcast signal has already been started since the circuit with the long rise time has already been started. Can be displayed quickly. Similarly, when switching from the reception of the television broadcast signal of the second system to the reception of the television broadcast signal of the first system and immediately switching to the reception of the television broadcast signal of the second system again, The video of the TV broadcast signal can be displayed quickly. Therefore, while saving power consumption and reducing radiation noise, for example, when selecting a variety of TV broadcast channels and looking for a program that you want to watch by watching the video displayed on the display, it is often in a short time. When a different type of television broadcast is selected, the selected television broadcast image can be quickly displayed.

  According to the invention of claim 3, since the rise time of the digital IC is long and the power supply to the first decoding circuit and the second decoding circuit converted into the digital IC is cut off at the end, it is repeated several times in a short time. The operation of quickly displaying an image when a different type of television broadcast is selected can be performed more effectively.

  Hereinafter, a television broadcast receiver according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic configuration of a television broadcast receiving apparatus. The television broadcast receiving apparatus 1 receives a television broadcast signal that is modulated by a carrier wave of a predetermined frequency and distributed from a broadcasting station via an antenna 2 connected to the apparatus, and a display (not shown) connected to the apparatus. It is an apparatus for displaying a video by a television broadcast signal. The television broadcast receiving apparatus 1 can receive an NTSC television broadcast signal and an ATSC television broadcast signal as a television broadcast signal, and a display such as a CRT display can display a video. Both analog displays and digital displays such as liquid crystal displays can be used.

  The TV broadcast receiving apparatus 1 includes a CPU (power supply control means) 11 for controlling the TV broadcast receiving apparatus 1, a broadcast signal receiving circuit 12 that receives a TV broadcast signal, and an NTSC that processes an NTSC television broadcast signal. A signal processing block 13, an ATSC signal processing block 14 for processing an ATSC television broadcast signal, a video encoder (analog video processing means) 15 for generating a signal for displaying an image on an analog display, and a digital display A DVI (digital video processing means) 16 for generating a signal for displaying video, an OSD processing circuit 17, a memory 18, a remote controller 19, and a remote control receiver 20.

  The television broadcast receiver 1 also includes a received signal switching switch 51 for switching to which of the NTSC signal processing block 13 and the ATSC signal processing block 14 the television broadcast signal received by the broadcast signal receiving circuit 12 is supplied. 52, and an output signal switching switch 53 for switching to which of the video encoder 15 and the DVI 16 the signal output from the NTSC signal processing block 13 or the ATSC signal processing block 14 is supplied.

  Furthermore, the television broadcast receiver 1 supplies power to the NTSC power supply first to third switches 61 to 63 for supplying and shutting off power to the NTSC signal processing block 13 and the ATSC signal processing block 14. First to third switches 71 to 73 for supplying ATSC power for cutting off, a switch 81 for supplying video encoder power for supplying and blocking power to the video encoder 15, and supplying and cutting power to the DVI 16 And a switch 82 for supplying DVI power.

  The broadcast signal receiving circuit 12 receives the television broadcast signal via the antenna 2 by tuning the reception frequency to the frequency of the television broadcast signal distributed from the broadcast station under the control of the CPU 11. The television broadcast signal received by the broadcast signal receiving circuit 12 is supplied to either the NTSC signal processing block 13 or the ATSC signal processing block 14 when the received signal switching switches 51 and 52 are switched.

  The NTSC signal processing block 13 processes an NTSC television broadcast signal among the television broadcast signals received by the broadcast signal receiving circuit 12 to generate and output a signal such as a luminance signal, a color signal, and a synchronization signal related to video. . The NTSC signal processing block 13 includes an NTSC amplification circuit 31, an NTSC demodulation circuit 32, and a video decoder (NTSC decoding circuit) 33.

  The NTSC amplifier circuit 31 amplifies the NTSC television broadcast signal received by the broadcast signal receiving circuit 12 under the control of the CPU 11. The NTSC amplifier circuit 31 is an analog IC, and power is supplied and cut off when the first switch 61 for NTSC power supply is turned on and off. The first switch 61 for supplying NTSC power is a switch for supplying and cutting off power to the NTSC amplifier circuit 31.

  The NTSC demodulation circuit 32 demodulates the signal amplified by the NTSC amplification circuit 31 under the control of the CPU 11 and generates a color video signal in which signals such as a luminance signal, a color signal, and a synchronization signal related to the video are combined. . The NTSC demodulation circuit 32 is an analog IC, and power is supplied and cut off when the second switch 62 for supplying NTSC power is turned on and off. The second switch 62 for supplying NTSC power is a switch for supplying and blocking power to the NTSC demodulation circuit 32. Since the NTSC demodulating circuit 32 has a more complicated circuit configuration than the NTSC amplifying circuit 31, the rise time until the NTSC demodulating circuit 32 rises to a state capable of signal processing when power is supplied is longer than that of the NTSC amplifying circuit 31.

  The video decoder 33 decodes the color video signal demodulated and generated by the NTSC demodulation circuit 32 under the control of the CPU 11 to generate signals such as a luminance signal, a color signal, and a synchronization signal related to the video. The video decoder 33 is a digital IC, and power is supplied and cut off when the third switch 63 for supplying NTSC power is turned on and off. The third switch 63 for supplying NTSC power is a switch for supplying and cutting off power to the video decoder 33. Since the video decoder 33 is a digital IC, the rise time is longer than that of the NTSC demodulation circuit 32.

  The ATSC signal processing block 14 processes an ATSC system television broadcast signal among the television broadcast signals received by the broadcast signal receiving circuit 12, and generates and outputs a signal such as a luminance signal, a color signal, and a synchronization signal related to video. . The ATSC signal processing block 14 includes an ATSC amplification circuit 41, an ATSC demodulation circuit 42, and an MPEG decoder (ATSC decoding circuit) 43.

  The ATSC amplifier circuit 41 amplifies the ATSC television broadcast signal received by the broadcast signal receiving circuit 12 under the control of the CPU 11. The ATSC amplifier circuit 41 is an analog IC, and power is supplied and cut off when the first switch 71 for supplying ATSC power is turned on and off. The first switch 71 for supplying ATSC power is a switch for supplying and blocking power to the ATSC amplifier circuit 41.

  The ATSC demodulation circuit 42 demodulates the signal amplified by the ATSC amplification circuit 41 under the control of the CPU 11, and a signal such as a luminance signal, a color signal, and a synchronization signal related to video is digitally compressed and encoded in MPEG format. A converted TS (Transport Stream) signal is generated. The ATSC demodulation circuit 42 is a digital IC, and power is supplied and cut off when the second switch 72 for supplying ATSC power is turned on and off. The second switch 72 for supplying ATSC power is a switch for supplying and cutting off power to the ATSC demodulation circuit 42. Since the ATSC demodulator circuit 42 is a digital IC, the rise time is longer than that of the ATSC amplifier circuit 41.

  The MPEG decoder 43 decodes the TS signal demodulated and generated by the ATSC demodulation circuit 42 under the control of the CPU 11 to generate signals such as a luminance signal, a color signal, and a synchronization signal related to the video. The MPEG decoder 43 is a digital IC, and power is supplied and cut off when the third switch 73 for supplying ATSC power is turned on and off. The ATSC power supply third switch 73 is a switch for supplying and blocking power to the MPEG decoder 43. Since the MPEG decoder 43 has a more complicated circuit configuration than the ATSC demodulation circuit 42, the rise time is longer than that of the ATSC demodulation circuit 42.

  Signals such as luminance signals, color signals, and synchronization signals relating to the video generated by the NTSC signal processing block 13 or the ATSC signal processing block 14 are passed through the OSD processing circuit 17 by switching the output signal switching switch 53. , And supplied to either the video encoder 15 or the DVI 16.

  Under the control of the CPU 11, the video encoder 15 is connected to the analog output terminal 15a for signals such as a luminance signal, a color signal, and a synchronization signal relating to the video generated by the NTSC signal processing block 13 and the ATSC signal processing block 14. It is processed into an analog video signal in a format that can display video on an analog display (not shown), and is output from the analog output terminal 15a. The video encoder 15 is powered on and off when the video encoder power supply switch 81 is turned on and off.

  The DVI 16 is a digital display connected to the digital output terminal 16a for signals such as luminance signals, color signals, and synchronization signals related to the video generated by the NTSC signal processing block 13 and the ATSC signal processing block 14 under the control of the CPU 11. The digital video signal is processed into a format capable of displaying video (not shown) and output from the digital output terminal 16a. The DVI 16 is powered on and off when the DVI power supply switch 82 is turned on and off.

  The OSD processing circuit 17 displays an operation content of the remote controller 19 or an image such as a menu screen on a display on a signal related to video output from the NTSC signal processing block 13 and the ATSC signal processing block 14 under the control of the CPU 11. Various on-screen display signals are superimposed. The memory 18 stores the reception frequency of the television broadcast signal in association with the channel number of the television broadcast signal.

  The remote controller 19 is operated by the user in order to instruct various operations such as power on / off, channel selection of a television broadcast signal reception channel, and other various operations of the television broadcast receiver 1. Are provided with various operation keys (all not shown) operated by the user. When the various operation keys are operated, the remote controller 19 sends out an infrared code signal associated with the operation. The remote control receiver 20 receives the infrared code signal transmitted from the remote controller 19 and converts it into an electrical signal, and outputs a signal corresponding to the operation of the remote controller 19 to the CPU 11.

  Switches 51 and 52 for switching received signals, switches 53 for switching output signals, first to third switches 61 to 63 for supplying NTSC power, first to third switches 71 to 73 for supplying ATSC power, The video encoder power supply switch 81 and the DVI power supply switch 82 are individually turned on and off under the control of the CPU 11.

  The CPU 11 controls the reception operation of the television broadcast signal by controlling the reception frequency of the broadcast signal reception circuit 12 according to the operation of the remote controller 19, and switches the switches 51, 52, 53 to receive the broadcast signal reception circuit 12. The TV broadcast signal supply path is controlled, and the switches 61 to 63, 71 to 73, and 81 are turned on and off to control power supply to the respective units. Further, the CPU 11 controls various other operations of the television broadcast receiving apparatus 1.

  With such a configuration, the television broadcast receiver 1 receives an NTSC or ATSC television broadcast signal via the antenna 2, and displays an image based on the television broadcast signal on an analog display ( (Not shown) or a digital display (not shown) connected to the digital output terminal 16a.

  FIG. 2 is a flowchart showing the operation of the television broadcast receiver 1 when switching the reception from the NTSC television broadcast signal to the ATSC television broadcast signal. When an ATSC television broadcast channel is selected by the remote controller 19 during reception of an NTSC television broadcast signal (YES in # 1), the CPU 11 selects the reception frequency of the broadcast signal receiving circuit 12 as a channel selection channel. The reception of the ATSC broadcast signal of that channel is started (# 2).

  At the same time, the CPU 11 switches the received signal switching switches 51 and 52 from the NTSC signal processing block 13 side to the ATSC signal processing block 14 side, and receives the ATSC television broadcast signal received by the broadcast signal receiving circuit 12. To the ATSC signal processing block 14 (# 3), and further, the first to third switches 71 to 73 for supplying ATSC power are turned on, and the ATSC amplifier circuit 41, ATSC demodulator circuit 42, and MPEG decoder 43 are turned on. The power supply to is started (# 4).

  As a result, the reception of the NTSC television broadcast signal is switched to the reception of the ATSC television broadcast signal. When the ATSC amplification circuit 41, the ATSC demodulation circuit 42, and the MPEG decoder 43 are ready to perform signal processing, the ATSC receiving signal is received. The video based on the system television broadcast signal is displayed on an analog display connected to the analog output terminal 15a or a digital display connected to the digital output terminal 16a.

  Thereafter, the CPU 11 first turns off the first switch 61 for NTSC power supply to cut off the power supply to the NTSC amplifier circuit 31 (# 5). At this time, the timing for turning off the switch 61 is, for example, one second after the channel selection operation at # 1. Following this, the CPU 11 turns off the second switch 62 for NTSC power supply and cuts off the power supply to the NTSC demodulation circuit 32 (# 6). At this time, the timing to turn off the switch 62 is, for example, 3 seconds after the switch 61 is turned off in # 5. Finally, the CPU 11 turns off the third switch 63 for NTSC power supply and cuts off the power supply to the video decoder 33 (# 7). At this time, the timing for turning off the switch 63 is, for example, 5 seconds after the switch 62 is turned off in # 6.

  FIG. 3 shows an operation flowchart when the television broadcast receiving apparatus 1 switches the reception from the ATSC television broadcast signal to the NTSC television broadcast signal. If a remote control 19 is used to select a channel for an NTSC television broadcast while receiving an ATSC television broadcast signal (YES in # 11), the CPU 11 selects the reception frequency of the broadcast signal receiving circuit 12 as a channel selection channel. The reception of the NTSC broadcast signal of that channel is started (# 12).

  At the same time, the CPU 11 switches the received signal switching switches 51 and 52 from the ATSC signal processing block 14 side to the NTSC signal processing block 13 side, and receives the NTSC television broadcast signal received by the broadcast signal receiving circuit 12. Is supplied to the NTSC signal processing block 13 (# 13), and the first to third switches 61 to 63 for supplying NTSC power are turned on, and the NTSC amplifier circuit 31, the NTSC demodulator circuit 32, and the video decoder 33 are turned on. The power supply to is started (# 14). Thereby, the reception is switched from the reception of the ATSC television broadcast signal to the reception of the NTSC television broadcast signal.

  As a result, the reception of the ATSC television broadcast signal is switched to the reception of the NTSC television broadcast signal, and when the NTSC amplifier circuit 31, the NTSC demodulation circuit 32, and the video decoder 33 are ready for signal processing, the receiving NTSC is received. The video based on the system television broadcast signal is displayed on an analog display connected to the analog output terminal 15a or a digital display connected to the digital output terminal 16a.

  Thereafter, the CPU 11 first turns off the first switch 71 for supplying ATSC power and cuts off the power supply to the ATSC amplifier circuit 41 (# 15). At this time, the timing for turning off the switch 71 is, for example, one second after the channel selection operation at # 11. Following this, the CPU 11 turns off the second switch 72 for supplying ATSC power and cuts off the power supply to the ATSC demodulation circuit 42 (# 16). At this time, the timing for turning off the switch 72 is, for example, 3 seconds after the switch 71 is turned off in # 15. Finally, the CPU 11 turns off the third switch 73 for supplying ATSC power and cuts off the power supply to the MPEG decoder 43 (# 17). At this time, the timing at which the switch 73 is turned off is, for example, 5 seconds after the switch 72 is turned off at # 16.

  When displaying an image of a television broadcast on an analog display, the CPU 11 sets the output signal switching switch 53 to the video encoder 15 side and outputs a signal output from the NTSC signal processing block 13 or the ATSC signal processing block 14. Is supplied to the video encoder 15, the video encoder power supply switch 81 is turned on to supply power to the video encoder 15, and the DVI power supply switch 82 is turned off to cut off the power supply to the DVI 16.

  When displaying a television broadcast video on the digital display, the CPU 11 sets the output signal switching switch 53 to the DVI 16 side, and outputs the signal output from the NTSC signal processing block 13 or the ATSC signal processing block 14 to the DVI 16. , The DVI power supply switch 82 is turned on to supply power to the DVI 16, the video encoder power supply switch 81 is turned off, and the power supply to the video encoder 15 is cut off.

  According to the television broadcast receiver 1 having such a configuration, when receiving an NTSC television broadcast signal, the power supply to the ATSC signal processing block 14 is cut off and when receiving an ATSC television broadcast signal. Since the power supply to the NTSC signal processing block 13 is cut off, wasteful power consumption can be suppressed and radiation noise can be suppressed.

  In addition, when switching reception from the NTSC system to the ATSC system television broadcast signal, the power supply is cut in the order of short circuit rise time in the order of the NTSC amplifier circuit 31, the NTSC demodulator circuit 32, and the video decoder 33. When switching reception to an NTSC television broadcast signal, the power supply is cut in the order of short circuit rise time in the order of the ATSC amplifier circuit 41, the ATSC demodulator circuit 42, and the MPEG decoder 43. As a result, if the reception is switched again from the NTSC system to the ATSC system broadcast signal and then immediately switched to the NTSC system broadcast signal, the power supply to the circuit having a long rise time is not cut off. Since the reception of the television broadcast signal of the system is started and the circuit having a long rise time has already been started, the video of the NTSC television broadcast signal can be quickly displayed. Similarly, when the reception is switched from the ATSC system to the NTSC system television broadcast signal and then the reception is switched again to the ATSC system television broadcast signal, the image of the ATSC system television broadcast signal can be displayed quickly.

  Therefore, according to the television broadcast receiving apparatus 1 having the above-described configuration, for example, various channels of a television broadcast signal can be selected and a video displayed on the display can be viewed while saving power consumption and reducing radiation noise. For example, when searching for a television program that the user wants to watch, when a television broadcast signal of a different system is selected many times in a short time, an image of the selected television broadcast signal can be quickly displayed. Further, when displaying an image of a TV broadcast signal on an analog display, the power supply to the DVI 16 is cut off, and when displaying on a digital display, the power supply to the video encoder 15 is cut off. , Can save power consumption.

  In addition, this invention is not restricted to the structure of the said embodiment, A various deformation | transformation is possible. For example, the timing of turning off the first to third switches 61 to 63 for supplying NTSC power at the time of switching the reception from the NTSC system to the ATSC system television broadcast signal is not limited to the timing described in the above embodiment. Considering the rise time of the amplifier circuit 31, the NTSC demodulator circuit 32, and the video decoder 33, the timing may be appropriate. Also, the timing of turning off the first to third switches 71 to 73 for supplying ATSC power at the time of switching the reception from the ATSC system to the NTSC system television broadcast signal is not limited to the timing described in the above embodiment, but the ATSC Considering the rise time of the amplifier circuit 41, the ATSC demodulation circuit 42, and the MPEG decoder 43, the timing may be appropriate.

  Further, since the digital IC has a microcomputer, the ATSC demodulation circuit 42 can be provided with a reception frequency control function when receiving an ATSC television broadcast signal by using the microcomputer. In this case, when the reception is switched from the ATSC system to the NTSC system television broadcast signal, the first to third switches 71 to 73 for supplying ATSC power are replaced with the first switch 71, the third switch 73, and the second switch. The power supply may be cut off in the order of the ATSC amplification circuit 41, the MPEG decoder 43, and the ATSC demodulation circuit 42 in the order of the switch 72.

The electric block block diagram which shows schematic structure of the television broadcast receiver by one Embodiment of this invention. The flowchart which shows the operation | movement at the time of the reception switching of the television broadcast signal of the NTSC system of the television broadcast receiver to the television broadcast signal of the ATSC system. The flowchart which shows the operation | movement at the time of the reception switching from the television broadcast signal of ATSC system of the television broadcast receiver to the television broadcast signal of NTSC system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Television broadcast receiver 2 Antenna 11 CPU (power supply control means)
12 broadcast signal receiving circuit 13 NTSC signal processing block 14 ATSC signal processing block 15 video encoder (analog video processing means)
15a Analog output terminal 16 DVI (digital video processing means)
16a Digital output terminal 31 NTSC amplifier circuit 32 NTSC demodulation circuit 33 Video decoder (NTSC decoding circuit)
41 ATSC amplification circuit 42 ATSC demodulation circuit 43 MPEG decoder (ATSC decoding circuit)
51, 52 Switch for receiving signal switching 53 Switch for switching output signal 61 First switch for NTSC power supply 62 Second switch for NTSC power supply 63 Third switch for NTSC power supply 71 ATSC power supply First switch for 72 72 Second switch for ATSC power supply 73 Third switch for ATSC power supply 81 Switch for video encoder power supply 82 Switch for DVI power supply

Claims (3)

A receiving means for receiving a television broadcast signal that is modulated by a carrier wave of a predetermined frequency and distributed from a broadcasting station, and a signal related to video by processing an NTSC television broadcast signal among the television broadcast signals received by the receiving means. NTSC signal processing means for generating; ATSC signal processing means for processing a television broadcast signal of the ATSC system among the television broadcast signals received by the receiving means to generate a signal relating to video; and the NTSC signal processing means or the ATSC An analog video processing means for processing a signal related to the video generated by the signal processing means into a signal in a format capable of displaying the video on an analog display connected to the apparatus, and the NTSC signal processing means or the ATSC signal processing means. The signal related to the generated video is sent to the digital device connected to this device. Digital video processing means for processing a signal in a format capable of displaying video by spraying, and power supply control for controlling power supply to the NTSC signal processing means, ATSC signal processing means, analog video processing means, and digital video processing means And the power supply control means supplies power to the NTSC signal processing means and cuts off power supply to the ATSC signal processing means when receiving an NTSC television broadcast signal. When receiving a television broadcast signal, in the television broadcast receiving apparatus that cuts off the power supply to the NTSC signal processing means and supplies power to the ATSC signal processing means,
The NTSC signal processing means includes an NTSC amplification circuit for amplifying the NTSC television broadcast signal received by the reception means, an NTSC demodulation circuit for demodulating the signal amplified by the NTSC amplification circuit, and a demodulation by the NTSC demodulation circuit. An NTSC decoding circuit for decoding the generated signal and generating a signal related to video,
The ATSC signal processing means includes an ATSC amplification circuit for amplifying the ATSC television broadcast signal received by the reception means, an ATSC demodulation circuit for demodulating the signal amplified by the ATSC amplification circuit, and a demodulation by the ATSC demodulation circuit. An ATSC decoding circuit that decodes the generated signal and generates a signal related to video,
The NTSC amplifier circuit, the NTSC demodulator circuit, and the ATSC amplifier circuit are each separately made into an analog IC,
The NTSC decoding circuit, the ATSC demodulating circuit, and the ATSC decoding circuit are each separately made into a digital IC,
In order to individually turn on / off the power supply to the NTSC amplification circuit, NTSC demodulation circuit, NTSC decoding circuit, ATSC amplification circuit, ATSC demodulation circuit, ATSC decoding circuit, analog video processing means, and digital video processing means, these It further includes a plurality of switches individually provided corresponding to
The power supply control means includes
By individually turning on and off each of the switches, the NTSC amplifier circuit, NTSC demodulator circuit, NTSC decoder circuit, ATSC amplifier circuit, ATSC demodulator circuit, ATSC decoder circuit, analog video processing means, and digital video processing means Individual power supply control,
When switching from receiving an NTSC television broadcast signal to receiving an ATSC television broadcast signal, power supply to the ATSC amplifier circuit, ATSC demodulator circuit, and ATSC decoder circuit is started, and then to the NTSC amplifier circuit. And then the power supply to the NTSC demodulating circuit, and finally the power supply to the NTSC decoding circuit,
When switching from reception of an ATSC television broadcast signal to reception of an NTSC television broadcast signal, power supply to the NTSC amplification circuit, NTSC demodulation circuit, and NTSC decoding circuit is started, and then to the ATSC amplification circuit. And then cut off the power supply to the ATSC demodulation circuit, and finally cut off the power supply to the ATSC decoding circuit,
Further, when displaying an image on the analog display, when supplying power to the analog video processing means and cutting off power supply to the digital video processing means, and displaying an image on the digital display A television broadcast receiver characterized in that it supplies power to the digital video processing means and cuts off power supply to the analog video processing means. Receiving means for receiving a television broadcast signal that is modulated by a carrier wave of a predetermined frequency and distributed from a broadcasting station, and the television broadcasting signal of the first method among the television broadcast signals received by the receiving means, First signal processing means for generating a signal; second signal processing means for processing a second type of television broadcast signal among the television broadcast signals received by the receiving means to generate a signal relating to video; Power supply control means for controlling power supply to the first and second signal processing means, and the power supply control means receives the first type television broadcast signal when the first system broadcast signal is received. When power is supplied to the signal processing means and the power supply to the second signal processing means is cut off, and when a second type television broadcast signal is received, the power supply to the first signal processing means is cut off. In both television broadcast receiving apparatus for supplying electric power to said second signal processing means,
The first signal processing means amplifies a first type television broadcast signal received by the receiving means, and demodulates a signal amplified by the first amplification circuit. A demodulation circuit; and a first decoding circuit that decodes the signal demodulated by the first demodulation circuit to generate a signal related to video,
The second signal processing means a second amplification circuit for amplifying a second type television broadcast signal received by the reception means, and a second amplification circuit for demodulating the signal amplified by the second amplification circuit. A demodulation circuit; and a second decoding circuit that decodes the signal demodulated by the second demodulation circuit to generate a signal related to video,
The power supply control means individually supplies power to the first amplifier circuit, the first demodulator circuit, the first decoder circuit, the second amplifier circuit, the second demodulator circuit, and the second decoder circuit. A television broadcast receiver characterized in that the control is performed. Each of the first decoding circuit and the second decoding circuit is made into a digital IC,
The power supply control means includes
When switching off the power supply to the first signal processing means when switching from the reception of the television broadcast signal of the first system to the reception of the television broadcast signal of the second system, first, the first amplification circuit and the first amplification circuit The power supply to the first demodulation circuit is cut off, and then the power supply to the first decoding circuit is cut off,
When switching off the power supply to the second signal processing means when switching from the reception of the television broadcast signal of the second system to the reception of the television broadcast signal of the first system, first, the second amplification circuit and the second amplification circuit The television broadcast receiver according to claim 2, wherein power supply to the second demodulation circuit is cut off and then power supply to the second decoding circuit is cut off.

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