JP4032255B2 - Television receiving system, tuner, and television receiving method - Google Patents

Description

  The present invention relates to a television receiving system, a tuner, and a television receiving method.

2. Description of the Related Art Conventionally, as this type of television receiving system, a system that sequentially performs channel search for digital broadcasting and channel search for analog broadcasting is known (for example, see Patent Document 1).
According to such a television receiving system, it is possible to create a channel map that defines both digital broadcasting and analog broadcasting, and to select a channel for both.
JP 2003-219289 A

However, unless the channel search for digital broadcasting and the channel search for analog broadcasting are completed, there is a problem that the user cannot confirm the search results.
In other words, the user usually performs channel search and determines the position where the most receivable channels are the largest as the installation position of the smart antenna, and each time channel search is performed for digital broadcasting and analog broadcasting. The problem was that it took too long.

  On the other hand, since broadcast waves are generally transmitted from a broadcasting station at the same point in both digital broadcasting and analog broadcasting, an antenna is installed at an optimal position for either digital broadcasting or analog broadcasting. Then, it can be considered that there is a high possibility that the antenna is installed at the optimum position for the other side. In other words, the optimum position of the smart antenna may be determined for either digital broadcasting or analog broadcasting, and channel search is performed for both digital broadcasting and analog broadcasting to determine the optimal position of the smart antenna. However, it was a wasteful work.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a television receiving system, a tuner, and a television receiving method capable of quickly optimizing the installation position of a smart antenna.

In order to achieve the above object, according to the first aspect of the present invention, a smart antenna having a plurality of variable directivity directions, an antenna control unit for switching the same directivity direction in the smart antenna, and a frequency signal received by the smart antenna are used. A tuner unit that extracts a desired frequency component, a digital playback unit that generates a video signal from the digital signal extracted by the tuner unit, and an analog playback that generates a video signal from the analog signal extracted by the tuner unit In a television receiving system comprising a tuner comprising a unit,
The tuner shifts the frequency band extracted by the tuner unit, scans a digital signal included in the extracted frequency component, and receives a channel suitable for receiving the channel. Digital channel detection means for detecting, a channel that can be received by scanning an analog signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and suitable for receiving the channel Detected by the analog channel detection means for detecting the directivity direction, first detection execution means for executing one of the digital channel detection means and the analog channel detection means, and the first detection execution means A means of transmitting the number of channels to the user When the input of whether or not the number of channels is satisfied is received and satisfied, the digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed, and is not satisfied The second is to prompt the user to move the smart antenna, and when the user confirms that the smart antenna has been moved, the second detection is performed again by the first detection execution means. The tuner unit selects the correspondence between the channel detected by the first detection execution means, the first search execution means, and the second search execution means, the frequency, and the directivity suitable for reception of the channel. And a channel selection data storage means for storing channel selection data to be read and used at the time.

  In the invention according to claim 1 configured as described above, the smart antenna is provided with a plurality of variable directivity directions. The antenna control unit switches one of the plurality of directivity directions to be set for the smart antenna. The tuner unit extracts a desired frequency component from the frequency signal received by the smart antenna, and the digital reproduction unit generates a video signal from the digital signal extracted by the tuner unit. On the other hand, the analog reproduction unit generates a video signal from the analog signal extracted by the tuner unit. That is, it is possible to reproduce video from both digital / analog broadcast radio waves.

  The digital channel detection means shifts the frequency band extracted by the tuner unit. Then, a receivable channel is detected by scanning a digital signal included in the frequency component extracted at that time, and the directivity direction suitable for reception of the channel is detected. On the other hand, the analog channel detection means similarly shifts the frequency band extracted by the tuner section, scans the analog signal included in the frequency component extracted at that time, and receives the channel. The pointing direction suitable for the above is detected. The first detection execution means executes one of the digital channel detection means and the analog channel detection means. At this time, the user may be allowed to input which detection means is to be executed, or one of them may be forcibly executed regardless of the user's intention.

  The transmission means transmits the number of channels detected by the first detection execution means to the user. That is, the number of analog broadcast channels or the number of digital broadcast channels detected by either the digital channel detection means or the analog channel detection means is transmitted to the user. The second detection execution means receives an input as to whether or not the number of the same channel is satisfied by the user. If the input is satisfied, the digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed. On the other hand, if an input indicating that the user is not satisfied is made, the user is prompted to move the smart antenna. Further, when an input for confirming that the smart antenna is moved is made by the user, the detection by the first detection execution means is performed again. That is, the channel detection means executed by the first detection execution means is executed again.

  The channel selection data storage means stores, as channel selection data, the correspondence between the channel, the frequency detected by the first search execution means and the second search execution means, and the directivity direction suitable for reception of the channel. To do. This tuning data is read and used by the tuner unit when tuning. That is, when the number of channels is obtained for either digital or analog, the number of channels can be transmitted to the user, and unnecessary channel detection means need not be continued.

  Here, the components of the television receiving system of the present invention may be provided in a single device or may be provided in another device. For example, a set top box such as a television receiving system box may be provided with the components of the present invention alone, or a television or video may be provided with the components of the present invention in combination.

The invention according to claim 2 is a smart antenna having a plurality of variable directivity directions;
An antenna control unit that switches the same directivity direction in the smart antenna, a tuner unit that extracts a desired frequency component from a frequency signal received by the smart antenna, and a video signal generated from the digital signal extracted by the tuner unit In a television reception system comprising a digital playback unit that performs a tuner and a analog playback unit that generates a video signal from the analog signal extracted by the tuner unit,
The tuner shifts the frequency band extracted by the tuner unit, scans a digital signal included in the extracted frequency component, and receives a channel suitable for receiving the channel. Digital channel detection means for detecting, a channel that can be received by scanning an analog signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and suitable for receiving the channel Detected by the analog channel detection means for detecting the directivity direction, first detection execution means for executing one of the digital channel detection means and the analog channel detection means, and the first detection execution means and transmission means for transmitting the number of channels to the user, the by the user When the input of whether or not the number of channels is satisfied is received and satisfied, the digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed, and is not satisfied Includes a second detection execution unit that prompts the user to move the smart antenna .

  In the invention of claim 2 configured as described above, the smart antenna is provided with a plurality of variable directivity directions. The antenna control unit switches one of the plurality of directivity directions to be set for the smart antenna. The tuner unit extracts a desired frequency component from the frequency signal received by the smart antenna, and the digital reproduction unit generates a video signal from the digital signal extracted by the tuner unit. On the other hand, the analog reproduction unit generates a video signal from the analog signal extracted by the tuner unit. That is, it is possible to reproduce video from both digital / analog broadcast radio waves.

The digital channel detecting means shifts the frequency band extracted by the tuner unit while scanning a digital signal included in the extracted frequency component, and the directivity suitable for receiving the channel. Detect direction. On the other hand, the analog channel detection means similarly shifts the frequency band extracted by the tuner unit and scans an analog signal included in the extracted frequency component, and receives the channel. A suitable pointing direction is detected. The first detection execution means executes one of the digital channel detection means and the analog channel detection means.

The transmission means transmits the detection result detected by the first detection execution means to the user. That is, the detection result of the analog broadcast or digital broadcast detected by either the digital channel detection means or the analog channel detection means is transmitted to the user. The second detection execution means receives an input as to whether or not the number of the same channel is satisfied by the user. If satisfied, the digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed. In other words, the detection result can be transmitted to the user at the time when the detection result is obtained for either one of digital and analog, and it is not necessary to continue useless channel detection means. On the other hand, if not satisfied, the user is prompted to move the smart antenna. If the user is not satisfied with the number of channels detected by the first detection execution means, the user can be prompted to move the smart antenna at that time.

Further, in the invention according to claim 3, when the second detection execution means prompts the user to move the smart antenna, the second detection execution means moves the smart antenna by the user. When the input for confirming is received and the input for confirming is received, the detection by the first detection execution unit is performed again.
In the invention of claim 3 configured as described above, when the user is not satisfied with the number of channels detected by the first detection execution unit and prompts the user to move the smart antenna, The second detection execution means accepts an input confirming that the user has moved the smart antenna. And when the input which confirms having moved is received, the detection by said 1st detection execution means is performed again. That is, the channel search can be performed again by changing the position of the smart antenna.

According to a fourth aspect of the present invention, the digital channel detection means or the analog channel detection means that requires a short time for scanning is configured to be executed.
In the invention of claim 4 configured as described above, the first search execution unit selects the digital channel detection unit or the analog channel detection unit that requires a short time for scanning. That is, it is possible to execute the case where a long time is required for scanning the channel only when the user is satisfied, and the useless time can be saved.

According to a fifth aspect of the invention, the tuner section reads out and uses the correspondence between the channel and frequency detected by the first search execution means and the second search execution means. A tuning data storage means for storing the tuning data is provided.
According to the invention of claim 5 configured as described above, the channel selection data storage means indicates the correspondence between the channel and the frequency detected by the first search execution means and the second search execution means. Remember as. This tuning data is read and used by the tuner unit when tuning.

According to a sixth aspect of the present invention, the channel selection data storage means has the channel and frequency detected by the first search execution means and the second search execution means, and the directivity suitable for receiving the channel. The correspondence relationship with the direction is stored as the channel selection data.

According to the sixth aspect of the present invention configured as described above, the channel selection data storage means is suitable for receiving the channel and frequency detected by the first search execution means and the second search execution means and the channel. The correspondence with the pointing direction is stored as channel selection data. This tuning data is read and used by the tuner unit when tuning. As a result, it is possible to receive the broadcast radio wave of the channel by setting the optimum directivity direction.

The method of receiving broadcast radio waves using the smart antenna as described above is not necessarily limited to a substantial apparatus, and is effective as a method invention as in the invention described in claim 8 . In addition, the above-described television receiving system may exist alone, or may be used in a state where it is incorporated in a certain device. The idea of the invention includes various aspects. For example, the present invention can be realized as a tuner as in the seventh aspect . Further, it can be changed as appropriate, such as software or hardware.

As described above, according to the first, second, seventh, and eighth aspects of the present invention, it is not necessary to perform channel search for both digital and analog, and therefore smart in a short time. The antenna installation position can be optimized. Furthermore, it is possible to prompt the change of the installation position of the smart antenna and install the smart antenna at a position where the number of channels is satisfactory.
According to the invention of claim 3 , channel search can be performed again by changing the position of the smart antenna.

According to the fourth aspect of the present invention, it is possible to prevent analog channel detection that takes time to scan as much as possible.
According to the invention concerning Claim 5 , it can perform smoothly for subsequent channel selection.
According to the sixth aspect of the present invention, the directivity of the smart antenna can be matched for each selected channel.

Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of television receiving system:
(2) Smart antenna installation work:
(3) Modification:
(4) Summary:

  FIG. 1 shows a schematic configuration of a television receiving system according to the present invention. In the figure, a television 30 is provided, and a control unit 20 having a substantially rectangular box shape connected to the television 30 with a cable (not shown) is provided. The control unit 20 is a so-called set top box, and can be installed at an arbitrary position as long as it can be connected to the television 30. An antenna cable 16 is connected to the control unit 20, and the control unit 20 and the smart antenna unit 10 are connected via the antenna cable 16.

  The smart antenna unit 10 has a leg portion 17 for stably installing on the floor surface, and a substantially columnar column portion 18 is erected substantially vertically from the leg portion. A substantially disk-shaped antenna holding portion 19 is held at the upper end of the column portion 18. The antenna holding part 19 is substantially horizontal, and four rod-shaped directional antennas 11, 11, 11, 11 protrude radially outward from the side surfaces. Since the angles formed by the adjacent directional antennas 11 are 90 degrees, the directional antennas 11, 11, 11, 11 are evenly arranged in the circumferential direction of the side surface of the antenna holding unit 19. It will be. Further, the directional antennas 11, 11, 11, and 11 can be extended, respectively, and can be pulled out and used by the user as appropriate.

  The directional antennas 11, 11, 11, 11 can each independently receive broadcast radio waves, and each has high reception sensitivity in the direction outside the axial direction. That is, the four directional antennas 11, 11, 11, 11 having high reception sensitivity with respect to the direction outside the axial direction are arranged evenly in the circumferential direction of the antenna holding unit 19, thereby receiving in all directions An antenna with good sensitivity can be configured. With this configuration, even if terrestrial television broadcast waves are transmitted from any direction of the smart antenna unit 10, broadcast waves can be received by any of the directional antennas 11, 11, 11, 11. . That is, since the directivity in the direction of the broadcast radio waves that can be received by the smart antenna unit 10 can be eliminated, it is possible to receive television broadcast radio waves transmitted from more broadcast stations and enjoy more channels. It becomes possible.

  However, if broadcast radio waves can be received from all directions at all times, noise radio waves transmitted from directions other than the broadcast radio waves transmitted from the desired broadcast station will also be received. Control is performed so as to limit the directivity direction in which reception is possible. Further, the directional antennas 11, 11, 11, 11 are respectively controlled and combined to control the amount of phase, thereby switching the directional direction. Hereinafter, the internal configuration of the smart antenna unit 10 will be described.

  FIG. 2 conceptually shows the internal configuration of the smart antenna unit 10. In the figure, four directional antennas 11, 11, 11, and 11 are connected to phase shifters 12, 12, 12, and 12, respectively. The phase shifters 12, 12, 12, and 12 are circuits that can control the phase amounts of signals input from the directional antennas 11, 11, 11, and 11, respectively, and correspond to the bias voltage output from the control unit 20. It is possible to delay the phase. The signals whose phase amounts are controlled by the phase shifters 12, 12, 12, 12 are input to the combiner 14 and are combined by the combiner 14. The signal synthesized by the synthesizer 14 is input to the booster circuit 13 and amplified.

  As described above, the four directional antennas 11, 11, 11, 11 can be combined only in the axial direction by combining the signals input from the four directional antennas 11, 11, 11, 11 while varying them. It can be made to have directivity in any direction. That is, by setting the phase amount of each phase shifter 12, 12, 12, 12 to an appropriate value, the direction of the main beam formed by the smart antenna unit 10 can be set to an arbitrary direction.

  FIG. 3 conceptually shows the internal configuration of the control unit 20. In the figure, a control unit 20 includes an antenna control unit 21 that controls the phase amount of each phase shifter 12, 12, 12, 12 in the smart antenna unit 10, and a tuner unit 22 that receives a frequency signal from the smart antenna unit 10. It has. The control unit 20 generates a signal for switching the directivity direction set in the smart antenna unit 10 in accordance with a command from the CPU 28a. Specifically, the directivity direction in the smart antenna unit 10 is varied by varying the bias voltage output to each of the phase shifters 12, 12, 12, 12. The control unit 20 includes a ROM (not shown) for storing combinations of bias voltages output to the phase shifters 12, 12, 12, 12. Sixteen combinations of bias voltages are stored, and the control unit 20 outputs one of the patterns to each of the phase shifters 12, 12, 12, and 12 in accordance with a command from the CPU 28a.

  That is, with the above configuration, the smart antenna unit 10 can realize 16 directivity directions. FIG. 4 shows the directivity direction of the 16 patterns. In the figure, it is possible to set a uniform directional direction of 16 azimuths radially about the antenna holding portion 19. That is, the angle difference between adjacent directing directions is equal to 360/16 = 22.5 degrees. In this way, by setting the directivity direction equally around the antenna holding unit 19, it is possible to follow broadcast radio waves incident from any direction. Note that the directivity direction above the plane of the paper is defined as a pattern D1, which is identified as patterns D2, D3, D4.

  The tuner unit 22 shown in FIG. 3 is configured as a so-called synthesizer-type television reception system, and PLL data as a channel selection control signal, that is, data of the frequency division ratio of the variable frequency dividing circuit in the PLL loop is supplied to the tuner unit 22. Given. The tuner unit 22 receives PLL data as a channel selection control signal from the CPU 28a, and extracts a frequency signal in a desired frequency band from the input frequency signal, so that one channel is selected from a plurality of channels. Select. The CPU 28a detects a frequency shift in the tuner unit 22 and supplies an AFT voltage to the tuner unit 22 based on the detection result. The tuner unit 22 corrects the frequency band to be extracted in accordance with the AFT voltage, so that optimum tuning is performed.

  The output of the tuner unit 22 is supplied to either the digital playback unit 23 or the analog playback unit 24. That is, the control unit 20 according to the present embodiment can reproduce both digital broadcasting and analog broadcasting. The digital playback unit 23 includes a digital I / F 23a, a demodulation circuit 23b, a descrambling unit 23c, a demultiplexing unit 23d, and an MPEG decoder 23g. The digital I / F 23a to which the frequency signal is input from the tuner unit 22 is provided with an A / D converter. The demodulating unit that receives the signal supplied from the digital I / F 23a includes a channel equalizer, an error correction decoding unit, and the like. Is also provided.

  That is, the digital I / F 23a and the demodulation circuit 23b convert the frequency signal input from the tuner unit 22 into a digital signal, and perform so-called ghost cancellation on the digitally demodulated signal based on the control information from the CPU 28a. Further, the digital I / F 23a and the demodulation circuit 23b correct a bit error generated on the transmission path to obtain a transport stream (TS) output. In the above processing, the demodulation circuit 23b detects the ratio of the bit error with respect to the entire data as an error rate.

  The transport stream obtained by performing demodulation and error correction processing in the demodulation circuit 23b is supplied to the descrambling unit 23c. Since the transport stream is usually scrambled, video / audio cannot be properly reproduced as it is. Therefore, the descrambling unit 23c performs descrambling processing on the transport stream, thereby restoring the transport stream to a reproducible data array. The transport stream subjected to the descrambling process has a format in which video signals, audio signals, character information, and the like are multiplexed, and is supplied to the demultiplexing unit 23d. The demultiplexing unit 23d performs demultiplexing processing on the input data. That is, multiplexing is released here. The descrambling unit 23c and the demultiplexing unit 23d can use the DRAM 23e as a work area when performing the respective processes.

  When demultiplexing is canceled by the demultiplexing process, the video signal and the audio signal are separated into MPEG data compressed by a predetermined method and data other than the video signal and the audio signal such as character information about the program, The latter data is supplied to the CPU 28a. Further, when MPEG data of a plurality of channels are multiplexed and conveyed in a predetermined frequency band, the multiplexing is also released for these. The former MPEG data is supplied to the MPEG decoder 23g, and the MPEG decoder 23g performs compression / decompression processing, that is, MPEG decoding processing. By performing MPEG decoding on the MPEG data, a digital video signal and a digital audio signal are generated, and the generated digital video signal is further converted into an analog video signal.

  The MPEG decoder 23g includes an OSD processing unit 23h, and can perform processing such as displaying a predetermined still image superimposed on a video or displaying a predetermined still image by replacing it. The OSD processing unit 23h can receive the received data such as character information from the CPU 28a, and can generate a still image or the like based on the data such as the character information.

  The MPEG decoder 23g can use the DRAM 23f as a work area when performing MPEG decoding processing and OSD processing. As described above, the MPEG decoder 23g can execute compression / decompression processing, and the OSD processing unit 23h can execute graphics processing. The compressed / decompressed / analog converted video signal is supplied to the video output unit 26, and the video output unit 26 outputs the video signal to the television 30. As a method for outputting an analog video signal to the television 30, various methods such as composite output and S-Video output can be employed.

  On the other hand, the audio signal generated by the MPEG decoding process is input to the D / A converter 25 and converted into an analog audio signal by the D / A converter 25. The analog audio signal is input to the audio output unit 27 and output from the audio output unit 27 to the television 30. However, if the television 30 includes an optical input terminal or the like and can receive a digital audio signal, the digital audio signal may be output to the television 30 as it is without going through the D / A conversion unit 25.

  On the other hand, the analog reproduction unit 24 includes an analog I / F 24a, a demodulation circuit 24b, an NTSC decoder 24d, and an audio decoder 24e. The analog I / F 24a and the demodulation circuit 24b include an AGC circuit 24b1 that amplifies the intermediate frequency signal input from the tuner unit 22. The amplification factor of the intermediate frequency signal in the AGC circuit 24b1 is defined by the AGC voltage, and the AGC voltage varies according to the amplitude level of the intermediate frequency signal amplified by the AGC circuit 24b1. That is, the AGC circuit 24b1 amplifies the intermediate frequency signal using the AGC voltage as a feedback signal.

  Specifically, when the amplified intermediate frequency signal is strong, the AGC voltage is reduced to reduce the amplification factor, and when the amplified intermediate frequency signal is weak, the AGC voltage is increased to increase the amplification factor. That is, in the present embodiment, it can be said that the higher the AGC voltage, the weaker the intermediate frequency signal input from the tuner unit 22. As a result, the amplitude level of the amplified intermediate frequency signal can be made substantially constant, so that there is no difference in the color reproduced between the channels. Further, since the AGC voltage is generated by comparing the amplified intermediate frequency signal with a predetermined reference voltage, the amplitude level of the amplified intermediate frequency signal can maintain an ideal value. The AGC voltage is output to the CPU 28a, and the CPU 28a executes various controls based on the output AGC voltage.

  The demodulating circuit 24b separates the demodulated intermediate frequency signal to generate an NTSC format analog video signal and analog audio signal. The generated analog video signal is input to the NTSC decoder 24d and converted into a CCIR656 format digital video signal by the NTSC decoder 24d. The NTSC format is a standard format for analog television signals, and includes a color reproduction signal, a 15.75 kHz horizontal synchronizing signal, a 60 Hz vertical synchronizing signal, and the like. The demodulation circuit 24b is provided with a synchronization separation circuit 24b2 for extracting a horizontal synchronization signal and a vertical synchronization signal. Based on the horizontal synchronization signal and the vertical synchronization signal extracted by the synchronization separation circuit 24b2, the NTSC decoder 24d It is possible to generate a synchronized digital video signal. The CCIR656 format is a digital video signal format in which each element of YUV is expressed in digital gradation. On the other hand, the analog audio signal separated by the demodulation circuit 24b is supplied to the audio decoder 24e, and is separated into the left and right independent stereo audio signals by the audio decoder 24e.

  The digital video signal generated by the NTSC decoder 24d is input to the MPEG decoder 23g and subjected to OSD processing and analog conversion in the same manner as described above. The analog-converted video signal is supplied to the video output unit 26, and is output from the video output unit 26 to the television 30. On the other hand, an audio signal is input to the audio output unit 27, and is output from the audio output unit 27 to the television 30.

  The CPU 28a described above is connected to the bus 29, and executes control processing for realizing various functions of the control unit 20 while using the RAM 28b connected to the bus 29 as a work area. A program for executing this control process is stored in advance in the ROM 28c, and the CPU 28a executes the control process while appropriately reading a predetermined program from the ROM 28c into the RAM 28b. The bus 29 is provided with a rewritable EEPROM 28d, and the CPU 28a executes control processing using various data stored in the EEPROM 28d.

  As an example of data stored in the EEPROM 28d, channel selection data 28d1 is stored. FIG. 5 shows an example of the channel selection data 28d1. The channel selection data 28d1 is a table in which channel numbers that can be specified by the remote control transmitter 40, the frequency band that is extracted by the tuner unit 22, and the directivity directions D1 to D16 that are suitable for reception are associated with each other. The CPU 28a can specify the frequency band corresponding to the designated channel number and the directivity directions D1 to D16 used for reception by referring to the table. In the present embodiment, the tuner unit 22 employs a synthesizer method, and therefore the correspondence between the channel number and the data of the frequency division ratio is stored as the channel selection data 28d1.

  By storing an optimum combination in advance as such channel selection data 28d1, each channel can be received under optimum conditions. It is conceivable that the broadcast radio wave transmitting station differs for each channel number, and the broadcast radio wave enters the smart antenna unit 10 from different directions for each channel number. Therefore, it is important to previously set the directivity directions D1 to D16 having the same directivity according to the channel number in order to ensure good reception quality. Information for specifying the optimum directivity directions D1 to D16 is supplied to the antenna control unit 21 through the CPU 28a, and a bias voltage is output to each of the phase shifters 12, 12, 12, and 12 based on the information. Here, the optimum directivity directions D1 to D16 are the directivity directions D1 to D16 that coincide with the direction in which the broadcast station of the broadcast radio wave corresponding to the channel number to be received exists in principle. That is, by setting the directivity directions D1 to D16 in the direction that coincides with the direction in which the broadcast station exists, it is possible to receive strong broadcast radio waves and make it less susceptible to noise radio waves from other directions. it can.

  The EEPROM 28d stores OSD data 28d2 for generating an OSD image by the OSD processing unit 23h. The CPU 28a appropriately reads out the OSD data 28d2 according to the command from the remote control transmitter 40, the operation status of each circuit, etc., and supplies the OSD data 28d2 to the OSD processing unit 23h. For example, when the CPU 28a determines that a warning is necessary for the user, the OSD data 28d2 that can generate a warning screen is read, and the OSD processing unit 23h is instructed to incorporate the warning screen into the video. The EEPROM 28d stores address data in which address information for specifying the installation position of the smart antenna unit 10 is stored. Such data is input via the remote control I / F 28e, the bus I / F 28f, the IC card I / F 28g, and the LAN I / F 28h and stored in the EEPROM 28d.

  A remote control transmitter I / F 28e is connected to the bus 29, and an infrared blink signal output from a remote control transmitter 40 as an external device can be input. This infrared blinking signal is sent to the CPU 28a via the bus 29, and the CPU 28a executes a corresponding control process. In addition, the bus 29 communicates with a bus I / F 28f for connecting to an external device via a cable, an IC card I / F 28g for exchanging data with the IC card, and an external device compliant with the LAN standard. LAN I / F 28h is connected. Information read from the bus I / F 28f and the IC card I / F 28g is sent to the CPU 28a via the bus 29, and predetermined processing is performed in the CPU 28a.

(2) Smart antenna installation work:
FIG. 6 shows a flow of smart antenna installation work. In the figure, when the smart antenna installation work is started, first, in step S100, the control unit 20 outputs predetermined image data to the television 30 and causes the television 30 to display an image. In this image, a message indicating which of the digital channel (Ch) or the analog channel (Ch) is to be scanned is displayed. Specifically, the OSD data 28d2 for displaying this image is stored in the EEPROM 28d in advance, and the OSD processing unit 23h incorporates the OSD data 28d2 into the image data, so that the image is output. The OSD data 28d2 may be stored in the ROM 28c. The CPU 28a receives an instruction to start the smart antenna installation work by the user via the remote control I / F 28e, and outputs a command for displaying the image to each unit.

  In step S100, the image is output and the user's selection is accepted. When the user selects the digital Ch using the remote control transmitter 40, the smart antenna unit 10 and the control unit 20 cause the digital Ch to be scanned. On the other hand, when the analog Ch is selected, the smart antenna unit 10 and the control unit 20 execute scanning for the analog Ch (first detection execution step). When scanning digital Ch and analog Ch, the frequency of the frequency signal extracted by the tuner unit 22 is shifted over the entire area. The frequency may be shifted over the entire area, the frequency may be gradually increased or decreased, or the frequency may be shifted randomly.

  In addition, by sequentially switching the directivity directions D1 to D16 set in the smart antenna unit 10 at each frequency, the reception state of each frequency with respect to each directivity direction D1 to D16 is detected. If no signal satisfying a predetermined condition is detected in any of the directivity directions D1 to D16 at each frequency, it is determined that there is no receivable channel at that frequency. On the other hand, when a signal satisfying a predetermined condition is detected when setting in any of the directivity directions D1 to D16 at each frequency, it is determined that there is a channel that can be received at that frequency. By making such a determination in the entire frequency domain, a receivable channel in the entire frequency domain is determined (digital / analog channel detecting step).

  Note that various conditions can be adopted as the predetermined condition for determining that there is a receivable channel at each frequency. For example, in the analog Ch scan, signal strength, AGC voltage, presence / absence of a synchronization signal, and the like can be adopted as the predetermined condition. On the other hand, in the analog Ch scan, signal intensity, AGC voltage, error rate, and the like can be adopted as the predetermined conditions. For example, when the signal intensity is set to the predetermined condition, the signal intensity received at the time of setting the directivity directions D1 to D16 at each frequency is compared. Then, the directivity directions D1 to D16 having the most ideal signal intensity are specified as the most suitable directivity directions D1 to D16 for receiving the channel of the frequency.

  Data indicating the detected channel, the frequency corresponding to the channel, and the directivity directions D1 to D16 most suitable for reception of the channel are temporarily stored in the RAM 28b or the EEPROM 28d. Therefore, the CPU 28a can specify the number of channels detected for either digital Ch / analog Ch by referring to the temporary data.

  Next, in step S130, the control unit 20 outputs predetermined image data to the television 30, and causes the television 30 to display an image representing the number of channels detected in step S110 or step S120 (transmission step). Also in the display of this image, the OSD data 28d2 and the OSD processing unit 23h are provided in the same manner as described above. In addition, a message asking whether the user is satisfied with the same number of channels is displayed in this image. The message and the number of channels are not necessarily transmitted by video, but may be transmitted by voice.

  In step S140, a user response to the message is accepted. Again, it is assumed that a response is accepted via the remote control I / F 28e. If the user inputs that the number of channels is satisfied, a scan of digital Ch / analog Ch that was not executed last time is executed in step S150. For example, if a digital Ch scan was executed in the previous step S110, an analog Ch scan is executed in this step S150. On the other hand, if the analog Ch scan was executed in the previous step S120, the digital Ch scan is executed in the current step S150. Note that the digital Ch / analog Ch scan in step S150 is the same as that described above, and a description thereof will be omitted.

  By executing step S150, it is possible to obtain channels detected for both digital Ch / analog Ch, frequencies corresponding to the channels, and directivity directions D1 to D16 most suitable for reception of the channels. . In step S160, correspondence data indicating the detection channel acquired in step S150 and step S110 or step S120, the frequency corresponding to the channel, and the directivity directions D1 to D16 that are most suitable for reception of the channel is digital Ch. / Analog Ch is stored in the channel selection data 28d1 (channel selection data storage step). Thereby, the tuning data 28d1 as shown in FIG. 5 can be formed. Accordingly, since the tuner section 22 can refer to the channel selection data 28d1 for both digital Ch / analog Ch after that, it is possible to perform channel selection smoothly.

  On the other hand, if the user inputs that the number of channels is satisfied in step S140, an image for prompting the position change of the smart antenna unit 10 is output based on the OSD data 28d2 in step S170. Accordingly, the user recognizes that the desired number of channels cannot be received unless the installation position of the smart antenna unit 10 is changed, and changes the installation position of the smart antenna unit 10. In step S180, an input for confirming whether the user has changed the installation position of the smart antenna unit 10 is accepted. That is, when the user changes the installation position of the smart antenna unit 10, the remote control receiver 40 is guided to perform a predetermined operation and waits until the operation is accepted.

  Normally, the user changes the installation position of the smart antenna unit 10 and performs the confirmation operation. However, if the operation is accepted within a predetermined time, the smart antenna unit 10 is suspended. May be. On the other hand, when the confirmation operation for changing the installation position of the smart antenna unit 10 is accepted, in step S190, scanning of the digital Ch / analog Ch selected in step S100 is executed. That is, the same scan as in step S110 or step S120 is performed again. When step S190 is executed, step S130 and subsequent steps are executed in the same manner as described above.

  In this way, the user can determine whether the installation position of the smart antenna unit 10 is appropriate based on the scan result for only one of the digital Ch / analog Ch. That is, the user does not have to wait for the scan result for both the digital Ch / analog Ch, and the waiting time can be shortened. If the number of channels that can be received by the digital Ch / analog Ch is greatly different under the condition that the smart antenna unit 10 is installed at the same position, the digital Ch / analog Ch should be scanned individually. Is desirable. However, it is common that the broadcasting stations for broadcasting radio waves of digital Ch / analog Ch are at the same point. Therefore, if a satisfactory number of channels can be received for one of digital Ch / analog Ch, it can be estimated that a satisfactory number of channels can be received for the other. Also, when scanning digital Ch / analog Ch individually, the user must memorize the number of receivable channels for both, or check again by another operation, which is cumbersome. Become.

(3) Modification:
In the above description, it is possible to select which scan of digital Ch / analog Ch is to be executed first in Step S100, but it is also possible to forcibly execute a scan for one of them. FIG. 7 shows the flow of smart antenna installation work in that case. In the figure, when the smart antenna installation work is started, the digital Ch is scanned as it is in step S210. Since the extraction method in the tuner unit 22 and the demodulation method in the demodulation units 23a and 24a are different from those of the digital Ch / analog Ch, it is considered that the time required for scanning differs greatly.

  Therefore, the shorter scan time is forcibly scanned in step S210, and the longer scan time is executed only when an answer to the satisfaction is obtained in step S240. It becomes possible. Accordingly, when the installation position of the smart antenna unit 10 is changed many times, the time required for the smart antenna installation work can be greatly reduced. In the present embodiment, the time required for scanning digital Ch is assumed to be short, but the magnitude relationship of the required time may be reversed depending on the scanning method. In that case, it is only necessary to forcibly scan the analog Ch in step S210.

  In the above-described embodiment, the control unit 20 that realizes the tuner function of the present invention and the television 30 are separate devices. However, the television 30 directly controls the smart antenna unit 10. It is also possible. FIG. 8 shows a configuration for that purpose. In the figure, various circuits provided in the control unit 20 are provided in the television 130, and a video signal and an audio signal are output to a monitor and a speaker provided in the television 130, respectively. When a digital display element such as a liquid crystal panel or a plasma panel is applied as a monitor, it can be output to the monitor as a digital video signal.

(4) Summary:
As described above, in the present invention, the user can determine whether the installation position of the smart antenna unit 10 is appropriate based on the scan result for only one of the digital Ch / analog Ch. That is, the user does not have to wait for the scan result for both the digital Ch / analog Ch, and the waiting time can be shortened.

It is an external appearance perspective view of a television receiving system. It is a circuit block diagram of a smart antenna unit. It is a circuit block diagram of a control unit. It is a schematic diagram which shows a directivity direction. It is a table | surface which shows channel selection data. It is a flowchart of a smart antenna installation work. It is a flowchart of the smart antenna installation work concerning a modification. It is a circuit block diagram of the television receiving system concerning a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Smart antenna unit 11 ... Directional antenna 12 ... Phaser 13 ... Booster circuit 14 ... Synthesizer 16 ... Antenna cable 17 ... Leg part 18 ... Column part 19 ... Antenna holding part 20 ... Control unit 21 ... Antenna control part 22 ... Tuner unit 23 ... digital reproduction unit 23b ... demodulation circuit 23c ... descramble unit 23d ... demultiplexing unit 23e, 23f ... DRAM
23g ... MPEG decoder 23h ... OSD processing unit 24 ... analog playback unit 24b ... demodulation circuit 24b1 ... AGC circuit 24b2 ... sync separation circuit 24d ... NTSC decoder 24e ... audio decoder 26 ... video output unit 27 ... audio output unit 28a ... CPU
28b ... RAM
28c ... ROM
28d ... EEPROM
28d1 ... tuning data 29 ... bus 30 ... television 40 ... remote control transmitter

Claims (8)

A smart antenna having a plurality of variable directivity directions;
An antenna control unit that switches the same directivity direction in the smart antenna, a tuner unit that extracts a desired frequency component from a frequency signal received by the smart antenna, and a video signal generated from the digital signal extracted by the tuner unit In a television reception system comprising a digital playback unit that performs a tuner and a analog playback unit that generates a video signal from the analog signal extracted by the tuner unit,
The above tuner is
A channel that can be received by scanning a digital signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and a digital channel that detects the directivity direction suitable for reception of the channel Detection means;
A channel that can be received by scanning the analog signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and an analog channel that detects the directivity direction suitable for reception of the channel Detection means;
First detection execution means for executing one of the digital channel detection means and the analog channel detection means;
A transmission means for transmitting the number of channels detected by the first detection execution means to the user;
Accepts whether the user is satisfied with the number of channels,
If you are satisfied,
The digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed,
If you are not satisfied,
Second detection execution that prompts the user to move the smart antenna and causes the first detection execution means to perform detection again when an input is received confirming that the user has moved the smart antenna. Means,
The tuner section reads out and uses the correspondence relationship between the channel detected by the first search execution means and the second search execution means, the frequency, and the directivity direction suitable for reception of the channel. A television receiving system, comprising: channel selection data storage means for storing as channel selection data. A smart antenna having a plurality of variable directivity directions;
An antenna control unit that switches the same directivity direction in the smart antenna, a tuner unit that extracts a desired frequency component from a frequency signal received by the smart antenna, and a video signal generated from the digital signal extracted by the tuner unit In a television reception system comprising a digital playback unit that performs a tuner and a analog playback unit that generates a video signal from the analog signal extracted by the tuner unit,
The above tuner is
A channel that can be received by scanning a digital signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and a digital channel that detects the directivity direction suitable for reception of the channel Detection means;
A channel that can be received by scanning the analog signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and an analog channel that detects the directivity direction suitable for reception of the channel Detection means;

First detection execution means for executing one of the digital channel detection means and the analog channel detection means;
A transmission means for transmitting the number of channels detected by the first detection execution means to the user;
Accepts whether the user is satisfied with the number of channels,
If you are satisfied,
The digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed,
If you are not satisfied,
A television receiving system, comprising: second detection execution means for urging a user to move the smart antenna . When the second detection execution means prompts the user to move the smart antenna, the second detection execution means accepts an input confirming that the user has moved the smart antenna and confirms the same. The television receiving system according to claim 2 , wherein when the input to be received is accepted, the detection by the first detection execution unit is performed again. 4. The television reception according to claim 2, wherein the first search execution unit executes the digital channel detection unit or the analog channel detection unit that requires a short time for scanning. 5. system. Tuning data storage for storing the correspondence between the channel and the frequency detected by the first search execution means and the second search execution means as channel selection data to be read and used by the tuner during channel selection The television receiving system according to any one of claims 2 to 4 , further comprising: means. The channel selection data storage means indicates the correspondence between the channel detected by the first search execution means and the second search execution means, the frequency, and the directivity direction suitable for reception of the channel. The television receiving system according to claim 5 , wherein the television receiving system is stored as An antenna control unit that switches the same directivity direction of a smart antenna having a plurality of variable directivity directions, a tuner unit that extracts a desired frequency component from a frequency signal received by the smart antenna, and a digital that is extracted by the tuner unit In a tuner comprising a digital playback unit that generates a video signal from a signal and an analog playback unit that generates a video signal from an analog signal extracted by the tuner unit,
A channel that can be received by scanning a digital signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and a digital channel that detects the directivity direction suitable for reception of the channel Detection means;
A channel that can be received by scanning the analog signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and an analog channel that detects the directivity direction suitable for reception of the channel Detection means;
First detection execution means for executing one of the digital channel detection means and the analog channel detection means;
A transmission means for transmitting the number of channels detected by the first detection execution means to the user;
Accepts whether the user is satisfied with the number of channels,
If you are satisfied,
The digital channel detection means or the analog channel detection means not executed by the first detection execution means is executed,
If you are not satisfied,

A tuner comprising second detection execution means for urging a user to move the smart antenna . An antenna control unit that switches the same directivity direction of a smart antenna having a plurality of variable directivity directions, a tuner unit that extracts a desired frequency component from a frequency signal received by the smart antenna, and a digital that is extracted by the tuner unit In a television reception method performed using a digital playback unit that generates a video signal from a signal and an analog playback unit that generates a video signal from an analog signal extracted by the tuner unit,
A channel that can be received by scanning a digital signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and a digital channel that detects the directivity direction suitable for reception of the channel A detection process;
A channel that can be received by scanning the analog signal included in the extracted frequency component while shifting the frequency band extracted by the tuner unit, and an analog channel that detects the directivity direction suitable for reception of the channel A detection process;
A first detection execution step for executing one of the digital channel detection step and the analog channel detection step;
A transmission step of transmitting the number of channels detected in the first detection execution step to the user;
Accepts whether the user is satisfied with the number of channels,
If you are satisfied,
The digital channel detection step or the analog channel detection step that was not executed in the first detection execution step is executed,
If you are not satisfied,
And a second detection execution step for urging the user to move the smart antenna .

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