JP2005354632A - Television receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a television receiver employing a smart antenna capable of detecting directivities in optimum directions in a short time. <P>SOLUTION: Since the television receiver detects a state of signals only of directivities wherein horizontal synchronizing signals in full directivities are detected, the television receiver can particularize some of optimum directivities among the full directivities D1 to D16 without the need for detecting AGC voltages of the full directivities D1 to D16. Thus, the entire processing time can be reduced. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a television receiver using a smart antenna.

Conventionally, as a television receiver of this type, in Japanese Patent Laid-Open No. 11-284918, a diversity receiver detects a vertical synchronization signal, selects a plurality of antennas in a good reception state, and sequentially switches the antennas. There is a technical disclosure.
Japanese Patent Application Laid-Open No. 06-165059 discloses a technique of selecting one antenna having a good reception state from a plurality of antennas mounted on a car or combining a plurality of antennas.
As described above, according to the above technique, it is possible to realize a good reception state regardless of the direction in which broadcast radio waves are transmitted.
JP-A-11-284918 Japanese Patent Laid-Open No. 06-165059

The conventional techniques described above have the following problems.
A technique that detects the reception state by detecting the synchronization signal and sequentially switches the antenna according to the state is effective for a moving body whose reception state constantly changes, but noise is present in the video signal due to weak input. There is a risk of overlapping. For this reason, there is a problem that the conventional technique described above is not effective in an antenna that is fixedly installed indoors and outdoors where the electric field strength of the received signal is important and has little change in the reception state.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a television receiver capable of quickly specifying an optimal antenna direction and adjusting the direction to obtain a good reception state.

In order to achieve the above object, according to a second aspect of the present invention, there is provided a smart antenna capable of statically changing directivity, an antenna control unit for switching a directivity direction of the smart antenna by an electric signal, and reception by the smart antenna. In a television receiver including a tuner unit that extracts a desired frequency component from the frequency signal that has been performed, and a playback unit that generates a video signal and an audio signal from the frequency signal extracted by the tuner unit,
Channel selection means by auto scan that scans all frequencies in the predetermined frequency band in the tuner section and automatically extracts receivable frequencies and stores them in a predetermined storage section;
The antenna control unit electrically switches the search direction for each of the plurality of directivity directions of the smart antenna,
Signal detection means for detecting the synchronization signal for each of a plurality of directivity directions of the smart antenna for a frequency including a predetermined synchronization signal in the television signal extracted by the channel selection means in the reproduction unit;
Signal state detection means for detecting a signal state by detecting an AGC voltage that defines an amplification factor of the frequency signal for each of the directivity directions in which the synchronization signal is detected by the detection means;
The signal state detecting means includes a directivity direction specifying means that specifies a directivity direction in which the AGC voltage is an extreme value and the signal state is good, and is capable of electrically switching the directivity direction.

The invention according to claim 2 configured as described above is such that the smart antenna does not move and the directivity direction is variable, and the antenna control unit determines the directivity direction to be set for the smart antenna among the directivity directions. Selectively switch. The tuner unit extracts a desired frequency component from the frequency signal received by the smart antenna, and the reproduction unit generates a video signal and an audio signal from the frequency signal extracted by the tuner unit.
The signal detection means detects a presence or absence of the predetermined synchronization signal by extracting a predetermined synchronization signal at the reproduction unit for the frequency extracted by the tuner unit.
The signal state detection means detects the signal state by detecting the AGC voltage from the signal state of the predetermined synchronization signal. The signal detection means and the signal state detection means are performed in all directional directions in the smart antenna.
Here, the AGC voltage is related to the reception state of the signal received by the tuner unit and reflects the strength of the received electric field strength of the frequency signal. By detecting this AGC voltage, it is determined whether the frequency signal is strong or weak. Can be recognized.

Therefore, the signal detection means detects the directivity direction having a predetermined synchronization signal, and the signal intensity detected by the signal state detection means for the synchronization signal is the most appropriate among the directivity directions determined to be appropriate. A direction in which the electric field strength is high is specified in one direction.
The channel selection means automatically stores a frequency that can be received within a predetermined frequency band and an optimum directivity direction of the smart antenna specified by the directivity direction detection means at the frequency in a predetermined storage unit, Extraction of the next frequency is started within a predetermined frequency band.

  Here, the components other than the smart antenna in the television receiver 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 tuner box may be provided with the components of the present invention alone, or the components of the present invention may be incorporated into a television, video, personal computer, or the like. Of course, the smart antenna itself may include components other than the smart antenna of the present invention.

  Further, the invention according to claim 3 is configured such that the predetermined synchronizing signal according to claim 2 is a horizontal synchronizing signal in a television signal.

  In the invention of claim 3 configured as described above, the predetermined synchronizing signal is a horizontal synchronizing signal.

Here, the first aspect of the present invention provides a smart antenna having a radially uniform variable directivity direction, an antenna control unit that switches the directivity direction of the smart antenna with an electric signal, and a desired frequency from a frequency signal received by the smart antenna. In a television receiver comprising a tuner unit for extracting a component and a playback unit for generating a video signal and an audio signal from the frequency signal extracted by the tuner unit,
Channel selection means by auto scan that scans all frequencies in the predetermined frequency band in the tuner section and automatically extracts receivable frequencies and stores them in a predetermined storage section;
The antenna control unit electrically switches the search direction for each of the plurality of directivity directions of the smart antenna,
Signal detection means for detecting the horizontal synchronization signal for each of a plurality of directivity directions of the smart antenna for a frequency including a horizontal synchronization signal in the television signal extracted by the channel selection means in the reproduction unit;
Signal state detection means for detecting a signal state by detecting an AGC voltage that defines an amplification factor of the frequency signal for each of the directivity directions in which the horizontal synchronization signal is detected by the detection means;
The signal state detecting means comprises a pointing direction specifying means capable of specifying a directivity direction in which the AGC voltage is an extreme value and the signal state is good, and electrically switching the directivity direction. Can be said to be a combination of the means and actions of claims 2 to 3.

  The method of receiving broadcast waves using the smart antenna as described above is not necessarily limited to a substantial apparatus, and is effective as a method invention. Further, the idea of the invention includes various aspects such as the above-described television receiver using a smart antenna may exist alone or may be used in a state of being incorporated in a certain device. Further, it can be changed as appropriate, such as software or hardware.

  As described above, according to the first to third aspects of the present invention, since it is not necessary to detect the signal state in all the directional directions, it is possible to reduce the time required for specifying the optimal directional direction. The broadcast radio wave can be received in a good reception state.

Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of television receiver:
(2) Direction direction specifying process using horizontal synchronization signal and AGC voltage:
(3) Summary:

(1) Configuration of television receiver:
FIG. 1 shows a schematic configuration of a television receiver using a smart antenna 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 any 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 disc-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 project 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 input, thereby finely switching the directivity 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. In other words, directivity can be given 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 inputs 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 the bias voltages are stored, and the control unit 20 outputs one of the patterns to each of the phase shifters 12, 12, 12, 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. It is defined that the directing direction above the paper surface is a pattern D1, and is identified as patterns D2, D3, D4.

  The tuner unit 22 shown in FIG. 3 has a so-called synthesizer-type tuner configuration, and PLL data, that is, data on the frequency division ratio of the variable frequency dividing circuit in the PLL loop is given to the tuner unit 22 as a channel selection control signal. 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 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 converter 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 the ROM 28c in advance, 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 optimal combination in advance as such channel selection data 28d1, each channel can be received under optimal 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 to be 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. In addition, the EEPROM 28d includes address data 28d4 in which address information for specifying the installation position of the smart antenna unit 10 is stored, broadcast station data 28d3 in which information on the broadcast station that is the source of the broadcast radio wave is stored, and the like. It is remembered. 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 an external device conforming to the LAN standard with a bus I / F 28f for connecting to an external device via a cable, an IC card I / F 28g for transferring data to and from the IC card. 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) Direction direction specifying process using horizontal synchronization signal and AGC voltage:
By storing an optimal combination in advance as the channel selection data 28d1, each channel can be received under optimal conditions. As described above, it is important to set the directivity directions D1 to D16 having the same directivity according to the channel number in order to ensure good reception quality.
Here, the horizontal synchronization signal of the broadcast radio wave received in the directivity direction of the 16 patterns of the smart antenna is detected, and the time required for identification is shortened by detecting the signal state of the detected horizontal synchronization signal using the AGC voltage. However, a description will be given of a process for specifying the optimum directivity direction to ensure good reception quality.
This processing may be performed for frequencies that can be received within a predetermined frequency band, and an optimum directivity direction may be specified and set for each corresponding channel number.

FIG. 6 shows a flowchart of the pointing direction specifying process using the horizontal synchronizing signal and the AGC voltage at the frequency according to the present invention.
First, in step S100 shown in FIG. 6, with respect to the directivity direction Dn (n is a natural number from 1 to 16) of the directivity antenna 11 shown in FIG. 4, the control unit 20 applies the bias voltage in the directivity direction Dn according to the command of the CPU 28a. A pattern is output to each phase shifter 12 to select a directivity direction Dn. Here, n = 1 is set as an initial value of the directivity direction Dn when the acquisition of the AGC voltage is started for the directivity direction Dn, and signal detection by the horizontal synchronization signal is started in order from the directivity direction D1.

In step S110, when the horizontal synchronization signal separated from the television signal is detected by the synchronization separation circuit 24b2 of the demodulation circuit 24b, it is determined that there is a reception signal and the process proceeds to step S120. If the horizontal synchronizing signal is not detected, it is determined that there is no received signal, and the process proceeds to step S140 described later. (Signal detection means)
The detection result of the horizontal sync signal is stored as detection data in the RAM 28b via the CPU 28a and the bus 20, and is temporarily stored until the pointing direction specifying process at the frequency is completed. Here, the storage location of the detection data is the RAM 28b. However, it is sufficient if the detection data can be temporarily stored, and it may be a storage area such as the EEPROM 28d. An example of the detection data is shown in FIG.
In step S120, the AGC voltage is detected from the AGC circuit 24b1 of the analog reproducing unit 24 only as the direction detection of the detected signal only in the directivity direction Dn (n is a natural number from 1 to 16) in which the horizontal synchronizing signal is detected. (Signal state detection means)
The detected AGC voltage is stored in the detection data of the RAM 28b from the AGC circuit 24b1 via the CPU 28a and the bus 29 in step S130.

In step S140, it is determined whether or not the current directivity direction Dn is the directivity direction D16 (ie, n = 16) that is finally searched for the frequency.
Here, the horizontal synchronizing signal is detected in order from the directivity direction D1 to the final directivity direction D16 in the clockwise direction in FIG.
If not n = 16, the directivity direction Dn is varied by setting n = n + 1 in step S145. At this time, 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 phase shifter 12.
In this way, the process proceeds to detection of a horizontal synchronizing signal in the directing direction D2 that is adjacent to the right of the directing direction D1 and is searched next.
As described above, by changing the directivity direction and repeating until the final n = 16, detection of the horizontal synchronization signal and detection of the AGC voltage in all directivity directions are sequentially performed.

On the other hand, if n = 16 in step S140, that is, the final directivity direction D16, it is determined that the search for all directivity directions is completed, and the process proceeds to step S150.
In step S150, the AGC voltage in the directivity direction stored in the detection data of the RAM 28b in step S130 is compared, and the optimum directivity direction for obtaining a good reception state is specified. Here, the directivity direction with the lowest AGC voltage is specified.
Here, the AGC voltage varies according to the amplitude level of the intermediate frequency signal amplified by the AGC circuit 24b1. As described above, it can be said that the higher the AGC voltage, the weaker the intermediate frequency signal input from the tuner unit 22. In addition, the AGC voltage becomes maximum at a frequency where there is no receivable signal, that is, there is no broadcasting station.
Accordingly, the directivity direction Dn having the lowest acquired AGC voltage is a strong direction of the intermediate frequency signal, and if the directivity direction Dn is specified at the frequency, a good reception state can be obtained.
In this manner, the identification of the optimum directivity direction Dn that provides a good reception state at the frequency ends.

According to the above-described directivity direction specifying process, the above process is executed to detect the presence or absence of horizontal synchronization signals in the directivity directions D1 to D16, and an AGC voltage is acquired for the directivity direction in which the horizontal synchronization signal is detected and stored in the RAM 28b. To do. And the directivity direction from which the AGC voltage became an extreme value is specified from the directivity direction. The specified directivity direction is associated with a channel number that can be specified by the remote control transmitter 40 or the like, a frequency band that is extracted by the tuner unit 22, and directivity directions D1 to D16 that are suitable for reception.
Here, the above processing is executed for the broadcast radio wave from the broadcasting station corresponding to the channel number, and the channel number, its frequency, and the directing direction Dn are associated with each other as channel selection data 28d1 as shown in FIG. Stored in the EEPROM 28d.

The above pointing direction specifying process is sequentially performed for frequencies selected within a predetermined frequency band by auto-scanning. (Channel selection means)
As described above, by setting the directivity directions D1 to D16 having the same directivity according to each channel number in the channel selection data 28d1, it is possible to always ensure good reception quality.

Here, FIG. 7 schematically shows the state of the smart antenna unit 10 and the broadcasting station. In the figure, the directivity directions D1 to D16 (direction of the main beam when set to the directivity directions D1 to D16) in the smart antenna unit 10 are virtually shown. A broadcasting station A and a broadcasting station B exist around the smart antenna unit 10, and the broadcasting station A is located on an extension of the directivity direction D2. On the other hand, the broadcasting station B is located on the extension of the directivity direction D5. Broadcast station A and broadcast station B transmit television broadcast radio waves having different carrier radio frequencies.
Here, in a certain area where a broadcasting station exists as shown in FIG. 7, the specific procedure of the pointing direction specifying process when broadcasting station A corresponds to channel number 1 and broadcasting station B corresponds to channel number 2 explain.

When the above-described directivity direction specifying process is started for the channel number 1, first, the initial value of the directivity direction is set to n = 1 for the directivity direction Dn of the antenna 11, and the antenna 11 is electrically switched to the directivity direction D1 ( S100).
Next, it is determined whether or not the broadcast radio wave of channel number 1 is received in the set directivity direction D1, and the horizontal synchronization signal separated from the television signal and extracted by the synchronization separation circuit 24b2 can be detected (S110). . Since the horizontal synchronizing signal is detected in the directivity direction D1, the AGC voltage is detected to acquire the AGC voltage AG1 (S120), and is temporarily stored in the detection data of the RAM 28b shown in FIG. 8 (S130).
Here, since the detection of the horizontal synchronizing signal is not performed for all the directivity directions Dn (S140), n = 1 in the already obtained directivity direction D1 is set to n = n + 1, and the pattern in the directivity direction is increased by one. = 2, that is, the setting is changed to the directivity direction D2 (S145). Then, the antenna 11 is switched to the directivity direction D2 (S100), and the horizontal synchronization signal in the next directivity direction D2 is detected (S110).

Similarly, the directivity pattern is incremented by one until the directivity direction Dn is increased to n = 16 (S145), and the presence / absence of a horizontal synchronizing signal is detected in each of all directivity directions D1 to D16. When a signal is detected as a result of the detection of the horizontal synchronizing signal, an AGC voltage is acquired and stored in the detection data each time as a signal state detection, and detection of the next pointing direction is started. On the other hand, when no signal is detected, the process proceeds to signal detection in the next directivity direction.
In channel number 1, the horizontal synchronization signal is detected in the directivity directions D1, D2, D3, D14, D15, and D16, and an AGC voltage is acquired every time a signal is detected in each directivity direction (S120). Then, the presence / absence of the horizontal synchronizing signal and the AGC voltage are associated with the omnidirectional direction Dn, and are stored in the RAM 28b as detection data as shown in FIG. 8 (S130).
The detection data is data temporarily stored in the RAM 28b, and after the optimum pointing direction for the channel number is determined and stored in the EEPROM 28d as the channel selection data 28d1, the address in the RAM 28b is cleared, or the next Are overwritten and erased by the same detection data in the process for the channel number.

As described above, the signal state detection by the AGC voltage is not performed for the directivity direction in which the horizontal synchronization signal is not detected. In this embodiment, the AGC voltage is detected only six times in the directivity directions D1, D2, D3, D14, D15, and D16, and the detection time when the AGC voltage is detected in all the directivity directions D1 to D16 is detected. Of 6/16.
As described above, the detection time can be shortened by narrowing down the detection of the AGC voltage, which takes time to acquire, based on the presence or absence of the horizontal synchronization signal and minimizing the number of directivity directions for acquiring the AGC voltage. .

After detection of the horizontal synchronization signal in all directional directions and signal state detection for the detected directional direction is completed, the detection data is called and the lowest of the acquired AGC voltages AG1, AG2, AG3, AG14, AG15, AG16 Specify the pointing direction. (S150)
FIG. 9 shows the relationship between the directivity direction and the AGC voltage in which the horizontal synchronization signal is detected in channel number 1.
In the figure, the vertical axis indicates the AGC voltage, and the horizontal axis indicates the directivity direction Dn. The AGC voltage varies according to the amplitude level of the intermediate frequency signal amplified by the AGC circuit 24b1. As described above, it can be said that the higher the AGC voltage, the weaker the intermediate frequency signal input from the tuner unit 22. Therefore, in the figure, the directivity direction D2 having the lowest acquired AGC voltage is the strong direction of the intermediate frequency signal, and if the directivity direction D2 is specified at the frequency, a good reception state can be obtained.
The identified directivity direction D2 is associated with channel number 1 and its frequency, and is stored as an optimum combination in the channel selection data 28d1 as shown in FIG.
This completes the identification of the optimum directivity direction in which the channel number 1 is in a good reception state, and the above directivity direction identification processing is repeated within a predetermined frequency band in this region by the channel selection means by auto scan.

Similarly, for the channel number 2 of the next frequency band, the optimum directivity direction specifying process is started by the auto scan.
As a result of detecting the presence or absence of a horizontal synchronizing signal in each of all the directional directions D1 to D16 by increasing the directional direction Dn to n = 16 one by one and detecting the presence or absence of the horizontal synchronization signal, the directional directions D1, D3, D4, D5, and D6 are detected. , D7, and D16, signals are detected, and an AGC voltage is acquired as signal state detection each time (S120). And it is memorize | stored in the said RAM28b as detection data as shown in FIG. 10 (S130).
At this time, the detection data acquired with channel number 1 is overwritten and erased by writing the data acquired with channel number 2.

The detection data in channel number 2 shown in FIG. 10 is called, and the lowest directivity direction is specified among the acquired AGC voltages.
FIG. 11 shows the relationship between the AGC voltages AG1, AG3, AG4, AG5, AG6, AG7, and AG16 acquired in the directivity directions D1, D3, D4, D5, D6, D7, and D16, respectively, in which the horizontal synchronization signal is detected. Show.
In the figure, the directional direction D5 having the lowest acquired AGC voltage is the strong direction of the intermediate frequency signal, and the channel number 2 specifies the directional direction D5 as the optimal directional direction. (S150)
Channel number 2 and its frequency are associated with the pointing direction D5 specified as described above, and stored as the optimum combination in the channel selection data 28d1 as shown in FIG.

In this way, in the above-mentioned directivity direction specifying process, the presence of a horizontal synchronization signal in all directivity directions is detected by changing the directivity direction of the antenna with respect to the broadcast radio wave from the broadcast station corresponding to the channel number, and the signal state Can be identified by the AGC voltage to specify the best directivity direction.
Further, the above directivity direction specifying process is repeated within the frequency band by the automatic scanning channel selection means, and the directivity directions D1 to D16 having the same directivity according to the channel number are set in advance as described above. Then, the channel numbers are associated with the frequency and the directivity direction Dn and stored in the EEPROM 28d as channel selection data 28d1 as shown in FIG.
As described above, in the channel selection data 28d1, the directivity directions D1 to D16 having the same directivity according to each channel number can be set in advance, and good reception quality can always be ensured.

  In the above-described embodiment, the control unit 20 and the television 30 are separate devices. However, the television 30 can directly control the smart antenna unit 10. In that case, various circuits provided in the control unit 20 are provided in the television 30, and the video signal and the audio signal are output to a monitor and a speaker provided in the television 30, respectively.

(3) Summary:
As described above, in the present invention, since the horizontal synchronization signal is detected in all directional directions and the signal state is detected only in the directional direction in which the horizontal synchronization signal is detected, the AGC voltage is applied to the omnidirectional directions D1 to D16. The optimal directivity directions D1 to D16 can be specified without detection. Therefore, the entire processing time can be shortened.

It is an external appearance perspective view of the television receiver by a smart antenna. 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 an orientation direction specific process. It is a schematic diagram which shows the relationship between a smart antenna unit and a broadcasting station. 3 is a table showing detection data in channel 1. FIG. 5 is an AGC voltage characteristic diagram in a directivity direction in which a signal is detected in channel 1; 3 is a table showing detection data in channel 2. FIG. 5 is an AGC voltage characteristic diagram in a directivity direction in which a signal is detected in channel 2;

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 ... synchronization separation circuit 24d ... decoder 24e ... audio decoder 26 ... video output unit 27 ... audio output unit 28a ... CPU
28b ... RAM
28c ... ROM
28d ... EEPROM
28d1 ... tuning data 28d2 ... OSD data 28d3 ... broadcast station information 28d4 ... address information 29 ... bus 30 ... television 40 ... remote control transmitter

Claims (3)

A smart antenna having a radially variable directivity direction, an antenna control unit that switches the directivity direction of the smart antenna with an electric signal, a tuner unit that extracts a desired frequency component from the frequency signal received by the smart antenna, and In a television receiver comprising a reproduction unit that generates a video signal and an audio signal from the frequency signal extracted by the tuner unit,
Channel selection means by auto scan that scans all frequencies in the predetermined frequency band in the tuner section and automatically extracts receivable frequencies and stores them in a predetermined storage section;
The antenna control unit electrically switches the search direction for each of the plurality of directivity directions of the smart antenna,
Signal detection means for detecting the horizontal synchronization signal for each of a plurality of directivity directions of the smart antenna for the frequency including the horizontal synchronization signal in the television signal extracted by the channel selection means in the reproduction unit;
Signal state detection means for detecting a signal state by detecting an AGC voltage defining an amplification factor of the frequency signal for each of the directivity directions in which the horizontal synchronization signal is detected by the detection means;
The television comprises: a pointing direction specifying means capable of specifying a directivity direction in which the AGC voltage is an extreme value in the signal state detection means and the signal state is good and electrically switching the directivity direction. Receiver device. A smart antenna that can statically change directivity, an antenna control unit that switches a directivity direction in the smart antenna by an electric signal, a tuner unit that extracts a desired frequency component from a frequency signal received by the smart antenna, In a television receiver comprising a reproduction unit that generates a video signal and an audio signal from the frequency signal extracted by the tuner unit,
Channel selection means by auto scan that scans all frequencies in the predetermined frequency band in the tuner section and automatically extracts receivable frequencies and stores them in a predetermined storage section;
The antenna control unit electrically switches the search direction for each of the plurality of directivity directions of the smart antenna,
Signal detection means for detecting the synchronization signal for each of a plurality of directivity directions of the smart antenna for a frequency including a predetermined synchronization signal in the television signal extracted by the channel selection means in the reproduction unit;
Signal state detection means for detecting a signal state by detecting an AGC voltage that defines an amplification factor of the frequency signal for each of the directivity directions in which the synchronization signal is detected by the detection means;
The television comprises: a pointing direction specifying means capable of specifying a directivity direction in which the AGC voltage is an extreme value in the signal state detection means and the signal state is good and electrically switching the directivity direction. Receiver device.   The television receiver according to claim 2, wherein the predetermined synchronization signal is a horizontal synchronization signal in a television signal.

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