JP4400747B2 - Television broadcast receiving apparatus and broadcast form determining apparatus - Google Patents

Description

  The present invention relates to a broadcast form determining apparatus and a television broadcast receiving apparatus, and particularly to a broadcast form determining apparatus and a television broadcast receiving apparatus that can receive broadcast signals corresponding to two different broadcast forms.

  There is provided a television broadcast receiver capable of selectively receiving TV (terrestrial analog or terrestrial digital) broadcast and CATV (cable television) broadcast. In such a television broadcast receiving apparatus, it is necessary to determine whether a TV broadcast or a CATV broadcast is received when performing channel presetting. Conventionally, at the time of channel auto search at the time of channel presetting, discrimination is performed by a method such as judging that a CATV broadcast is received when a plurality of stations are detected within 120 to 300 MHz.

  In Patent Document 1, all frequency bands included in each channel plan of TV broadcasting and CATV broadcasting are substantially continuously searched, and whether or not there is a broadcasting station at the channel frequency assigned to each channel plan. Judgment is made and it is judged whether or not the channel frequency of the station is within a certain frequency range from the center frequency, and if it is within the certain frequency range, there is a station of the channel plan to which the station belongs. The number of channels is counted up, the counted number of TV channels is compared with the number of CATV counts, and if the number of TV counts is greater than or equal to the number of CATV counts, the TV mode is set. If the TV count is smaller than the CATV count, it is determined that the CATV mode is set. There has been disclosed.

In Patent Document 2, if the count number of the channel plan of the TV broadcast is smaller than the count number of the channel plan of the CATV broadcast, whether or not there is a continuous channel among the channels determined to have a station. Only when there is a continuous channel, it is determined that the mode is the CATV channel plan mode. If there is no continuous channel among the channels determined to have a station, the error data channel is further included. It is disclosed that it is determined whether or not there is a continuous channel, and if there is a continuous channel, it is determined that the mode is the CATV channel plan mode.
Noto 3068428 Noto 30687702

  However, there are cases where strong electric field stations exist in some areas, and when a TV broadcast is received in an area where one or more strong electric field stations exist (for example, in the city center), distortion occurs in the tuner section. There was something to do. Then, the broadcast is received on a channel other than the regular channel (spurious reception). Due to the occurrence of such spurious, spurious is generated in the channel that only broadcasts the CATV broadcast although the TV broadcast is received. There was something to do. Since this spurious signal includes a synchronization signal, it is rarely erroneously determined that the CATV broadcast is received even though the TV broadcast is received.

  The present invention has been made in view of the above-described problems, and in broadcast type determination apparatuses and television broadcast receiving apparatuses corresponding to two different broadcast forms such as CATV broadcasts and TV broadcasts, broadcasts can be performed even in areas where spurious signals exist. It is intended to prevent misjudgment of form.

In order to achieve the above object, the broadcast form determination apparatus of the present invention includes a first broadcast form to which a predetermined carrier frequency is assigned and each carrier frequency assigned to the first broadcast form. Corresponding to the second broadcast form in which the carrier frequency is also assigned to a specific frequency band not assigned to one broadcast form, the broadcast form determination device capable of receiving a signal of a desired frequency searches for a receivable frequency. Frequency search means, channel information storage means for storing channel information of the first broadcast form and the second broadcast form, and a spurious frequency which is a frequency that may become spurious. Spurious calculation means for calculating in the specific frequency band based on a search result, and the frequency search means in the spurious frequency If there is no frequency that matches the search result, the broadcast form being received is determined to be the second broadcast form, and there is a frequency that matches the search result of the frequency search means in the spurious frequency and the signal of the frequency When the intensity is equal to or less than a predetermined threshold, the broadcast form being received is determined to be the first broadcast form, and the spurious frequency includes a frequency that matches the search result of the frequency search means, and the signal intensity of the frequency Is greater than a predetermined threshold value, based on the broadcast form determination means for determining the broadcast form being received as the second broadcast form and the channel information corresponding to the broadcast form determined by the broadcast form determination means. And a station setting means for setting channel information.
In this configuration , the frequency search means can receive broadcast signals transmitted in a plurality of broadcast forms, and can detect the presence or absence of receivable frequencies while sequentially tuning to the carrier frequency of each broadcast form. ing. The channel information storage means stores the channel information of the first broadcasting form and the second broadcasting form, and the channel information includes information such as channel number, carrier frequency, RF-AGC voltage, IF-AGC voltage, etc. And their corresponding relationships. The broadcast form judging means judges the broadcast form based on the presence / absence of a receivable frequency in the specific frequency band and the presence / absence of spurious. The spurious includes harmonics, subharmonics, sum signals, difference signals, etc., and is derived from the distortion component of the broadcast signal. Based on the broadcast mode determined by the broadcast mode determination unit, the station setting unit sets the receivable frequencies that match the broadcast mode to the television broadcast receiver as channel information.

Also, the broadcasting style determining means includes spurious calculating means for calculating a spurious frequencies based on a frequency that is a receivable at the frequency search circuit, the spurious frequency and the receivable and frequency and the specific frequency A frequency comparison means for comparing in the band, and a station presence / absence determination means for temporarily receiving the frequency matched by the frequency comparison means to determine the presence / absence of a broadcast signal, and determining which broadcast format it is in It is good also as composition to do .
That is, the spurious calculation means calculates the spurious frequency based on the frequency that can be received by the frequency search means. As a calculation method, among the frequencies that can be received, the harmonics are obtained by multiplying them by an integer based on a frequency lower than the specific frequency band, and for subharmonics, a frequency higher than the specific frequency band is obtained. The sum signal and the difference signal are originally obtained by multiplying by an integer, and the sum signal and difference signal are obtained by combining the frequency, harmonics, and subharmonics that can be received. The frequency comparison means compares the calculated spurious frequency with the receivable frequency, and if there is no match, the broadcast form determination means determines that a broadcast signal exists in a specific frequency region. Is done. On the other hand, if there is a match, the station presence / absence determination means provisionally receives the frequency with the frequency matched by the frequency comparison means and determines whether a broadcast signal exists at the same frequency.

Further, the upper Symbol station existence determining means may be configured to determine the presence or absence of a broadcast signal by the signal strength of a frequency above frequency matching.
The information indicating the signal strength can be obtained from, for example, an AGC voltage generated when performing gain control of an AGC circuit or the like. Of course, signal gain control may be performed by an AGC circuit or the like, and a signal having a signal intensity equal to or less than a predetermined threshold may be determined as spurious.

Further, the upper Symbol spurious calculation means, among the detected receivable and frequency in the frequency search means may be configured to calculate the spurious frequency of the frequency lower than the specific frequency band.
In this configuration , the spurious calculation means calculates a spurious frequency based on a frequency lower than the specific frequency band. That is, since the calculation is performed based on a low frequency, the spurious frequency matching the specific frequency band is mainly a harmonic or a sum signal. That is, spurious frequencies generally tend to be weaker for subharmonics and difference signals than harmonics and sum signals, so subharmonics and difference signals are not calculated, and only harmonics and sum signals are used as spurious frequencies. Is possible to reach. This eliminates the need to calculate subharmonic and difference signal spurious.

Further, the upper Symbol spurious calculation means, among the detected receivable and frequency in the frequency search means may be configured to calculate the spurious frequencies generated by frequency of the video signal.
That is, the broadcast signal includes a video signal and an audio signal, but the audio signal has a weaker signal strength than the video signal, so that only the spurious frequency based on the video signal is set as the spurious frequency. This eliminates the need to calculate spurious frequencies not derived from the video signal.

Further, the upper Symbol spurious calculation means, among the detected receivable and frequency in the frequency search means may be configured to calculate the spurious frequencies generated by the frequency of the frequency and the audio signal of the video signal.
That, film image signal and the audio signal is made clear that to calculate the spurious frequencies comprising a source.

Further, the upper Symbol spurious calculation means, among the detected receivable and frequency in the frequency search means, sum and difference spurious frequencies generated by frequency of the audio signal may be configured not calculated.
That is, sum and difference spurious frequencies generated by voice signals to each other has been clarified that not calculated.

  Based on the above configuration, the invention according to claim 1 of the present invention includes a terrestrial broadcast and a specific frequency that is not assigned to the terrestrial broadcast and includes each carrier frequency assigned to the terrestrial broadcast. An antenna for receiving a broadcast signal of a terrestrial broadcast, and a cable television in a television broadcast receiver capable of receiving and viewing a signal of a desired frequency corresponding to a cable television broadcast in which a carrier frequency is also assigned to a band. A coaxial cable to which a broadcast signal of the broadcast is input, a tuner that tunes a broadcast signal input from any of the antenna and the coaxial cable to a desired carrier frequency and outputs an intermediate frequency signal; and An intermediate frequency amplification circuit that acquires an AGC voltage corresponding to the signal strength of the intermediate frequency signal and amplifies the intermediate frequency signal by an amplification factor based on the AGC voltage. An AGC circuit that outputs the AGC voltage based on the amplified intermediate frequency signal, a semiconductor memory that stores a channel number that can be selected and a carrier frequency in association with each other, and a predetermined signal control process. And a microcomputer in which the AGC voltage is input as a digital signal via an A / D port and the channel plan of the terrestrial broadcast and the cable television broadcast is stored. A channel search for channel tuning is performed for each, and a calculation spurious is calculated from a carrier frequency of a broadcast station in the VHF band among the broadcast stations found by the channel search, and the channel search is performed stably. Among the broadcast stations that can be received, there is a channel with a carrier frequency corresponding to the specified frequency band. If the corresponding channel does not exist, it is determined that the terrestrial broadcast is received, and the channel number and the carrier frequency are stored in the semiconductor memory based on the terrestrial broadcast channel plan. If there is a corresponding channel, it is determined whether or not it matches the calculated spurious, and if it does not match any calculated spurious, it is determined that a cable TV broadcast is received, and the cable TV broadcast channel is determined. Based on the plan, the channel number and carrier frequency are stored in the semiconductor memory, and when the calculated spurious coincides, the strength of the broadcast signal is judged based on the AGC voltage, and if the signal strength is sufficient, the cable Based on the TV broadcast channel plan, the channel number and carrier frequency are stored in the semiconductor memory. If the signal strength is insufficient, the channel number and the carrier frequency are stored in the semiconductor memory based on the channel plan of terrestrial broadcasting.

As described above, according to the present invention, even if a terrestrial broadcast is received in an area where a strong electric field station exists, it is erroneously determined that a cable television broadcast is received due to a spurious generated in a tuner unit or the like. Therefore, it is possible to provide a broadcast form determination apparatus with more accurate received information. Accordingly, since presetting ing so accurately performed, it is unnecessary to make such arrangement of preset channel, the user convenience is improved.
According to the third aspect of the present invention, since the determination is made not only by the spurious but also by the signal strength, it is possible to more appropriately determine the broadcasting form, and it is possible to omit an extra channel selection operation.
Furthermore, according to the inventions according to claims 4 to 7 , the spurious to be calculated is limited, and an effect equivalent to that before the limitation can be obtained. Therefore, the processing required for the spurious calculation and the comparison with the spurious can be reduced. .
Furthermore, it is needless to say that in a more specific configuration as in claim 1, the same effects as those of the inventions of claims 2 to 7 described above are exhibited.

Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of television broadcast receiver:
(2) Broadcast format:
(3) Spurious calculation and determination method:
(4) Microprocessor processing for auto-preset:
(5) Summary:

(1) Configuration of television broadcast receiver:
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram showing a television broadcast receiving apparatus that can receive and view a signal of a desired frequency by applying the broadcast form judging apparatus according to the first embodiment of the present invention. In the channel auto preset, the broadcast type is determined. In the figure, only the video signal processing system is shown for simplification of the figure.
In FIG. 1, a television broadcast receiving apparatus 100 is roughly composed of a tuner 10, an intermediate frequency amplifier circuit 12, a video detection circuit 14, a video signal processing circuit 16, an AGC circuit 18, a semiconductor memory 22, and a microcomputer 20. .

  In the figure, a tuner 10 can be connected to either a U / V antenna 10a that receives a terrestrial broadcast as an input source of a broadcast signal or a cable television (NORMAL) coaxial cable 10b. Correspondingly, the signal is received while being tuned to a signal of a desired frequency, and only a required signal is selected from the received signal, amplified at a high frequency, converted into an intermediate frequency signal and output. The tuner 10 in this embodiment employs a so-called PLL channel selection mechanism, and the reception frequency is controlled by directly controlling the local oscillation frequency based on predetermined frequency data input from the microcomputer 20 described later. It is possible to control and receive a signal of a desired frequency.

  The intermediate frequency signal output from the tuner 10 is input to the intermediate frequency amplifier circuit 12, and is intermediate frequency amplified with an appropriate gain based on an IF-AGC voltage input from an AGC circuit 18 described later. The video detection circuit 14 performs video detection of the intermediate frequency signal output from the intermediate frequency amplifier circuit, and performs predetermined color demodulation processing based on the detection output to output a decoded video signal.

  The signal intensity of the intermediate frequency signal generated by the tuner 10 varies from channel to channel depending on the state of the input television wave. Therefore, the signal intensity is adjusted by any one or combination of the tuner 10 and the intermediate frequency amplifier circuit 12. That is, the amplification factor when the tuner 10 amplifies the intermediate frequency signal is controlled based on the RF-AGC voltage, and the amplification factor when the intermediate frequency amplifier circuit 12 amplifies the intermediate frequency signal is based on the IF-AGC voltage. Be controlled.

  The AGC circuit 18 acquires a composite video signal that is an intermediate frequency signal output from the video detection circuit 14, and generates an RF-AGC voltage and an IF-AGC voltage corresponding to the composite video signal. Specifically, when the signal strength of the composite video signal is strong, the RF-AGC voltage and the IF-AGC voltage are reduced, and when the signal strength of the composite video signal is weak, the RF-AGC voltage and the IF-AGC voltage are reduced. Raise. In this embodiment, the IF-AGC voltage and the RF-AGC voltage are adjusted between 0 and 5V.

  As described above, the signal intensity of the intermediate frequency signal or the composite video signal can be converged to an ideal value by any one or combination of the feedback control for the tuner 10 and the feedback control for the intermediate frequency amplifier circuit 12.

  On the other hand, the composite video signal output from the video detection circuit 14 is input to the video signal processing circuit 16. The composite video signal is a composite wave in which the luminance signal, the carrier color signal, and the synchronization signal are combined, but the video signal processing circuit 16 performs a process of separating the composite video signal into the above signals and outputs the signal to the CRT. Further, the video signal processing circuit 16 is provided with a synchronization separation circuit 16a, and the synchronization separation circuit 16a extracts the vertical synchronization signal and the horizontal synchronization signal and outputs them to the CRT. Note that the synchronization detection signal detected by the synchronization separation circuit 16 a is output to the microcomputer 20.

  The microcomputer 20 includes a CPU 20a, a ROM 20b, and a RAM 20c connected by a bus 20d, and an A / D port 20e is connected to the bus 20d. The CPU 20a reads the control program stored in the ROM 20b, executes processing according to the control program while using the RAM 20c as a work area, and performs signal control processing of each part of the television broadcast receiving apparatus 100. The ROM 20b stores channel data 20b1 for terrestrial broadcasting and channel data 20b2 for cable television broadcasting. Each channel data 20b1 and 20b2 stores a correspondence between a carrier frequency and a channel number. An RF-AGC voltage is input to the A / D port 20e. The RF-AGC voltage is a DC voltage that changes within a predetermined range, and is converted into a digital signal corresponding to the voltage value of the DC voltage via the A / D port 20e.

  FIG. 2 shows the contents stored in the channel data 20b1 and 20b2, where the channel data 20b1 contains the channel number (CHNL IND) and the carrier frequency of the terrestrial broadcast (TV), and the channel data 20b2 contains the channel number. (CHNL IND) and the carrier frequency of cable television broadcasting (CATV) are stored. That is, the correspondence between the carrier frequency of the terrestrial broadcast and the channel number is stored in the channel data 20b1, and the correspondence between the carrier frequency of the cable television broadcast and the channel number is stored in the channel data 20b2. That is, since the channel number and broadcasting station corresponding to the carrier frequency are completely different between terrestrial broadcasting and cable television broadcasting, they are prepared individually. Therefore, the ROM 20b constitutes channel information storage means in which the channel information of the first broadcast form and the second broadcast form is stored.

The semiconductor memory 22 is connected to the outside of the microcomputer 20 and stores a channel data table T1. The channel data table T1 is associated with information indicating the carrier frequency and the channel number. Of course, information such as RF-AGC voltage, IF-AGC voltage, broadcasting station, channel number, etc. may be stored corresponding to each channel.

  When the microcomputer 20 receives a channel selection instruction by operating an operation panel (not shown) or the remote controller 30, the microcomputer 20 acquires information indicating the carrier frequency corresponding to the specified channel from the channel data table T 1, and sends the information to the tuner 10. Outputs the control signal to be set. Thereby, the tuner 10 can receive the TV radio wave of the channel instructed to be selected.

(2) Broadcast format:
FIG. 2 shows channel plans for terrestrial broadcasting and cable television broadcasting, and shows channel numbers (CHNL IND), frequencies, station names and station IDs for each broadcasting form. As shown in the figure, since the channel plan is generally different when the broadcasting form is different, such as terrestrial broadcasting and cable television broadcasting, the microcomputer 20 needs to send the corresponding frequency data according to the broadcasting form to be received. There is. Therefore, in the present embodiment, the frequency corresponding to the channel number is stored in the semiconductor memory 22 in terrestrial broadcasting and cable television broadcasting. Then, the channel plan corresponding to the broadcast form determined by the preset is selected and used for channel selection control.

  On the other hand, regardless of whether it is a terrestrial broadcast or a cable television broadcast, a broadcast signal does not always exist at each carrier frequency. A so-called auto-preset function is provided for storing and selecting a channel based on the stored contents.

  As shown in FIG. 2, in a normal channel plan, if a broadcasting form is different after a certain channel number (for example, after channel 14), the frequency for the same channel number is different, and the corresponding broadcasting stations are generally the same. Absent. Furthermore, there are broadcast frequency bands that do not exist in terrestrial broadcasts in the broadcast frequency bands corresponding to each channel of cable television broadcast. For example, in the figure, broadcast frequency bands 121.25 to 469.25 MHz of cable television broadcast channels 14 to 65 are not assigned to terrestrial broadcasts.

  That is, in this embodiment, the terrestrial broadcast corresponds to the first broadcast form assigned with a predetermined carrier frequency, and the cable television broadcast includes each carrier frequency assigned to the first broadcast form and the same. This corresponds to a second broadcast mode in which a carrier frequency is also assigned to a specific frequency band that is not assigned to one broadcast mode. Further, the specific frequency band corresponds to the broadcast frequency band 121.25 to 469.25 MHz of the cable television broadcast channels 14 to 65. In the present embodiment, among the broadcast frequency bands that do not exist in the terrestrial broadcast, Cable TV broadcasting 13ch to 35ch (about 120 MHz to 300 MHz) is a specific frequency band.

  Further, when performing the above-described auto preset, an auto preset is instructed by depressing an operation button (not shown) of the remote controller 50 or the like. Then, an infrared remote control signal is similarly sent from the remote controller 50, detected by the microcomputer 20, and an auto preset process is executed according to a flowchart described later. Therefore, in the present embodiment, the tuner 10 and the microcomputer 20 constitute frequency search means for searching for receivable frequencies.

(3) Spurious calculation and determination method:
When a terrestrial broadcast is received in an area where a strong electric field station with a high output exists in an urban area or the like in a specific frequency band, a signal at a broadcast signal level may be received. This is because when the tuner 10 receives a broadcast signal of a strong electric field station, distortion occurs in the voltage waveform inside the tuner 10, and spurious such as harmonic components other than the normal frequency band are derived from this distortion. This is because the tuner 10 receives the signal even in the spurious frequency band.

  As such spurious, harmonics, subharmonics, sum signals, difference signals, and the like are conceivable, but generally subharmonics and difference signals are weaker than harmonics and sum signals. Therefore, in this embodiment, only the harmonics and the sum signal are calculated, and the result of the calculation is compared with the frequency of the received broadcast signal to determine whether the signal received in the specific frequency band is spurious. .

  Further, in the frequency band corresponding to each channel, there are a video carrier wave (fp) that carries a video signal and an audio carrier wave (fs) that carries an audio signal. In this embodiment, when calculating the sum signal, since the strength of the audio carrier is lower than that of the video carrier, the sum signal between the video carriers and the sum signal of the video carrier and the audio carrier are calculated. The sum signal between carriers is not calculated. That is, the spurious frequency generated by the frequency of the video signal and the spurious frequency generated by the frequency of the video signal and the frequency of the audio signal are calculated, and the sum-and-difference spurious frequency generated by the frequency of the audio signal is not calculated. This is preferable because the processing of the microcomputer 20 is reduced, but it goes without saying that subharmonics, difference signals, and spurious between audio carriers may be calculated.

  FIG. 3 is a diagram for explaining how to determine spurious. In the figure, search result 1 and search result 2 obtained by searching for a frequency and a calculated spurious value obtained by calculating a spurious based on the search result are schematically shown. As described above, since only the harmonics and the sum signal are calculated as the spurious, the calculation spurious is calculated in the terrestrial broadcast and the cable television broadcast and at a frequency lower than the specific frequency band. A VHF band is used. Therefore, the harmonics and the sum signal are calculated from each search result, and a frequency corresponding to about 120 MHz to 300 MHz is calculated spurious among the calculation results. Further, because the frequencies detected in the VHF band of search result 1 and search result 2 are the same for convenience, the calculated spurious is the same for both search result 1 and search result 2.

  Search result 1 in FIG. 3 is that the A station (fpA, fsA), the B station (fpB, fsB), and the C station (fpC, fsC) are received in the VHF band, and f1 and f2 are received in the specific frequency band. A broadcast signal is received at a frequency of f3. The frequency of station A to station C is a video signal, and the frequency of s is an audio signal. Search result 2 receives stations A to C in the VHF band, as in search result 1, and receives broadcast signals at frequencies f4, f5, and f6 in the specific frequency band. Further, the calculated spurious is calculated from the frequencies of the stations A to C, and the frequencies corresponding to the specific frequency band are f1, f2, and f3. In other words, in the figure, it can be said that search result 1 may have received spurious in the specific frequency band, and search result 2 has not received spurious in the specific frequency band.

  Specifically, in the case where the stations A to C exist in the VHF band, when the spurious is calculated by the above-described calculation method, the harmonics are fpA, 3fpA, 4fpA, 2fpB, 3fpB, 4fpB, 2fpC, 3fpC, 4fpC,. The sum signals are fpA + fpB, fpA + fpC, fpB + fpC, fpA + fsB, fpA + fsC, fpB + fsA, fpB + fsC, fpC + fsA, fpC + fsB,.

  Further, in the case of the search result 1 in which spurious may be received in the specific frequency band, the presence / absence of a broadcast signal is determined based on the signal strength for a signal having a frequency that matches the calculated spurious. That is, the spurious is a distortion component of the fundamental frequency, and the fundamental frequency at which the spurious is generated is derived from the strong electric field station. Therefore, the signal is significantly weaker than the signals of the A to C stations of the fundamental frequency component in this embodiment. Therefore, the spurious and the true broadcast signal are determined by comparing the signal strength.

  Specifically, the RF-AGC voltage or IF-AGC voltage output from the AGC circuit 18 when receiving a broadcast signal in a specific frequency band and the AGC circuit when receiving a VHF band broadcast signal. The RF-AGC voltage or the IF-AGC voltage output from 18 is compared, and if the broadcast signal in the specific frequency band is greatly amplified as compared with the broadcast signal in the VHF band, it can be said that it is spurious.

  The signal strength may be determined by controlling the AGC circuit 18 by the microcomputer 20 and reducing the gain of the AGC. That is, by controlling the AGC circuit 18, the amplification factor in the tuner 10 or the intermediate frequency amplifier circuit 12 is reduced, and if a broadcast signal in a specific frequency band cannot be received while a broadcast signal in the VHF band is received, the spurious It can be said that.

(4) Microprocessor processing for auto-preset:
The auto preset process is executed by the configuration of the television broadcast receiving apparatus 100 described above. With reference to FIG. 4, the process of the microcomputer 20 that performs auto-preset will be described. The microcomputer 20 stores a control program for executing the process, and the CPU 20a executes the process based on the control program. The process is shown in the flowchart in the figure. In the present embodiment, the carrier frequencies of all stations of terrestrial broadcasting and cable television broadcasting are stored in advance in the channel data table T1, and the presence / absence of television waves that can be received at each carrier frequency by performing the following processing. Is verified. Then, a process is performed in which only data on the carrier frequency verified that there is a receivable television wave is left in the channel data table T1.

  When auto-preset is instructed by depressing an operation button (not shown) on the remote controller 50, for example, for each carrier frequency stored in the ROM 20b in step S10, regardless of whether it is terrestrial broadcast or cable television broadcast, A channel search for tuning tuning is performed in ascending order of frequency. Then, the information on the carrier frequency of the broadcasting station that can be stably received and found by the channel search is stored in the work area of the RAM 20 c or the semiconductor memory 22.

  In step S12, it is determined whether or not a channel having a carrier frequency (referred to as fx) corresponding to a specific frequency band exists among the broadcast stations found by the channel search in step S10 that can be stably received. If the corresponding channel exists, the condition is satisfied and the process proceeds to step S14. On the other hand, if the corresponding channel does not exist, the condition is not satisfied and the process proceeds to step S26, where the channel number and the carrier frequency are associated with each other based on the terrestrial broadcast channel data 20b1 and stored in the channel data table T1 to perform auto presetting. Then, the process ends.

When the condition is satisfied in step S12 and the process proceeds to step S14, a calculated spurious (fy) that is a frequency that can be spurious from the carrier frequency of the broadcasting station in the VHF band among the broadcasting stations found by the channel search is calculated. calculated, the process proceeds to step S 20 and stored in the work area of the RAM20c or a semiconductor memory 22.

  In step S20, a carrier frequency that has not been compared with the calculated spurious fy among the carrier frequencies fx corresponding to the specific frequency band is compared with fy. When the compared fx does not match any of fy, it is determined that they do not match, and the process proceeds to step S28, where the channel number and the carrier frequency are associated with each other and stored in the channel data table T1 based on the channel data 20b2 of the cable television broadcast. Auto-preset is performed and the process ends. On the other hand, when the compared fx matches any of fy, the process proceeds to step S22. Information indicating whether fx is compared with fy may be stored in the work area of the RAM 20c or the semiconductor memory 22 with respect to the carrier frequency compared in step S20.

  In step S22, it is determined whether or not the signal strength of fx compared in step S20 is sufficient. That is, the presence / absence of a broadcast signal is determined based on the signal strength of the matched frequency in step S20. As a determination method, the above-mentioned RF-AGC voltage or IF-AGC voltage is compared with the RF-AGC voltage or IF-AGC voltage output from the AGC circuit 18 when receiving a broadcast signal in the VHF band. Or a method of controlling the AGC circuit 18 with the microcomputer 20 and making a determination by reducing the gain of the AGC. When it is determined that the signal strength is sufficient, the condition is satisfied and the process proceeds to step S24, and the channel number and the carrier frequency are associated with each other and stored in the channel data table T1 based on the channel data 20b2 of the cable television broadcast. To end the process. On the other hand, if the signal strength is insufficient, the condition is not satisfied and the process proceeds to step S30.

  In step S30, it is determined whether or not all the carrier frequencies fx corresponding to the specific frequency band have been compared with the calculated spurious fy. When the comparison has not been completed for all fx, that is, when all fx have not been compared in step S20, the processing from step S20 is repeated as the condition is not satisfied. On the other hand, if all fx have been compared with the calculated spurious, that is, if all fx have been compared in step S20, the process proceeds to step S32 as the condition is satisfied, and the channel number and the channel number 20b1 are determined based on the terrestrial broadcast channel data 20b1. Auto-preset is performed by associating it with the carrier frequency and storing it in the channel data table T1, and the process ends.

  As described above, the microcomputer 20 that executes the process of step S14 constitutes the spurious calculation unit that calculates the spurious frequency based on the frequency that can be received by the frequency search unit, and the microcomputer 20 that executes the process of step S20. A frequency comparison unit that compares the spurious frequency and the receivable frequency in the specific frequency band is configured, and the microcomputer 20 that executes the process of step S22 temporarily selects a frequency that matches the frequency in the frequency comparison unit. A station presence / absence determining means for receiving and determining the presence / absence of a broadcast signal is configured.

  Further, the microcomputer 20 that executes the processes of steps S10 to 22, S30, and S32 constitutes a broadcast form determination unit that determines the broadcast form with spurious in the specific frequency band, and executes the processes of steps S24, 26, and 28. The microcomputer 20 constitutes station setting means for setting channel information based on the broadcast form determined by the broadcast form determining means.

(5) Summary:
In other words, a search is made for a receivable frequency, a spurious frequency is calculated based on the frequency that can be received by the search, and the spurious frequency and the receivable frequency are determined in a carrier frequency region that exists only in cable television broadcasting. A comparison is made in a specific frequency band, and a frequency that matches the frequency is provisionally received to determine the presence or absence of a broadcast signal.

As described above, in the broadcasting style determining apparatus that corresponds to the present embodiment includes a first broadcast mode and each carrier frequency assigned to the first broadcast mode in which the predetermined carrier frequency is allocated In addition, in the broadcast form determination device capable of receiving a signal of a desired frequency corresponding to the second broadcast form in which the carrier frequency is also assigned to the specific frequency band not assigned to the first broadcast form, the signal can be received. Frequency search means for searching for frequency, channel information storage means for storing channel information of the first broadcast form and the second broadcast form, and a spurious frequency which is a frequency that may become spurious. Spurious calculation means for calculating in the specific frequency band based on a search result of the search means, and the frequency search in the spurious frequency. If there is no frequency that matches the search result of the stage, the broadcast form being received is determined as the second broadcast form, and there is a frequency that matches the search result of the frequency search means in the spurious frequency and the frequency If the signal strength of the signal is equal to or less than a predetermined threshold, the broadcast form being received is determined to be the first broadcast form, and the spurious frequency includes a frequency that matches the search result of the frequency search means, and If the signal strength is greater than a predetermined threshold, the broadcast form determining means for determining the broadcast form being received as the second broadcast form, and the channel information corresponding to the broadcast form determined by the broadcast form determining means And a station setting means for setting channel information based on it.
In this configuration , the frequency search means can receive broadcast signals transmitted in a plurality of broadcast forms, and can detect the presence or absence of receivable frequencies while sequentially tuning to the carrier frequency of each broadcast form. ing. The channel information storage means stores the channel information of the first broadcasting form and the second broadcasting form, and the channel information includes information such as channel number, carrier frequency, RF-AGC voltage, IF-AGC voltage, etc. And their corresponding relationships. The broadcast form judging means judges the broadcast form based on the presence / absence of a receivable frequency in the specific frequency band and the presence / absence of spurious. The spurious includes harmonics, subharmonics, sum signals, difference signals, etc., and is derived from the distortion component of the broadcast signal. Based on the broadcast mode determined by the broadcast mode determination unit, the station setting unit sets the receivable frequencies that match the broadcast mode to the television broadcast receiver as channel information.
As a result, even if terrestrial broadcasting is received in an area where a strong electric field station exists, it is not erroneously determined that cable television broadcasting is received due to spurious generated in the tuner section, and the received information is more accurate. It is possible to provide a broadcast type determination device. Accordingly, since presetting ing so accurately performed, it is unnecessary to make such arrangement of preset channel, the user convenience is improved.

Also, the broadcasting style determining means includes spurious calculating means for calculating a spurious frequencies based on a frequency that is a receivable at the frequency search circuit, the spurious frequency and the receivable and frequency and the specific frequency A frequency comparison means for comparing in the band, and a station presence / absence determination means for temporarily receiving the frequency matched by the frequency comparison means to determine the presence / absence of a broadcast signal, and determining which broadcast format it is in It is good also as composition to do .
That is, the spurious calculation means calculates the spurious frequency based on the frequency that can be received by the frequency search means. As a calculation method, among the frequencies that can be received, the harmonics are obtained by multiplying them by an integer based on a frequency lower than the specific frequency band, and for subharmonics, a frequency higher than the specific frequency band is obtained. The sum signal and the difference signal are originally obtained by multiplying by an integer, and the sum signal and difference signal are obtained by combining the frequency, harmonics, and subharmonics that can be received. The frequency comparison means compares the calculated spurious frequency with the receivable frequency, and if there is no match, the broadcast form determination means determines that a broadcast signal exists in a specific frequency region. Is done. On the other hand, if there is a match, the station presence / absence determination means provisionally receives the frequency with the frequency matched by the frequency comparison means and determines whether a broadcast signal exists at the same frequency. Thereby, unnecessary channel selection operation can be omitted by more appropriately determining the broadcasting form.

Further , the station presence / absence determining means may be configured to determine the presence / absence of a broadcast signal based on the signal strength of a frequency that matches the frequency.
The information indicating the signal strength can be obtained from, for example, an AGC voltage generated when performing gain control of an AGC circuit or the like. Of course, signal gain control may be performed by an AGC circuit or the like, and a signal having a signal intensity equal to or less than a predetermined threshold may be determined as spurious. Accordingly, since the determination is made not only by the spurious signal but also by the signal strength, it is possible to more appropriately determine the broadcasting form, and it is possible to omit an extra channel selection operation.

Moreover , it is good also as a structure which calculates the spurious frequency of a frequency lower than the said specific frequency band among the frequencies which can be received detected by the said frequency search means.
In this configuration , the spurious calculation means calculates a spurious frequency based on a frequency lower than the specific frequency band. That is, since the calculation is performed based on a low frequency, the spurious frequency matching the specific frequency band is mainly a harmonic or a sum signal. That is, spurious frequencies generally tend to be weaker for subharmonics and difference signals than harmonics and sum signals, so subharmonics and difference signals are not calculated, and only harmonics and sum signals are used as spurious frequencies. Is possible to reach. This eliminates the need to calculate subharmonic and difference signal spurious.

Further , the spurious calculation means may be configured to calculate a spurious frequency generated by the frequency of the video signal among the receivable frequencies detected by the frequency search means.
That is, the broadcast signal includes a video signal and an audio signal, but the audio signal has a weaker signal strength than the video signal, so that only the spurious frequency based on the video signal is set as the spurious frequency. This eliminates the need to calculate spurious frequencies not derived from the video signal.

Further , the spurious calculation means may be configured to calculate a spurious frequency generated by the frequency of the video signal and the frequency of the audio signal among the receivable frequencies detected by the frequency search means.
That, film image signal and the audio signal is made clear that to calculate the spurious frequencies comprising a source.

Further , the spurious calculation means may be configured not to calculate the sum-and-difference spurious frequency generated by the frequency of the audio signal among the receivable frequencies detected by the frequency search means.
That is, sum and difference spurious frequencies generated by voice signals to each other has been clarified that not calculated. As described above, by limiting the spurious to be calculated, the same effect as before the limitation can be obtained, so that the processing required for spurious calculation and comparison with spurious can be reduced.

Based on the above configuration, more specific configuration examples include terrestrial broadcasts and specific frequency bands that are not allocated to the terrestrial broadcasts, including each carrier frequency assigned to the terrestrial broadcasts. In a television broadcast receiver that can receive and view a signal of a desired frequency corresponding to a cable television broadcast to which a carrier frequency is assigned, an antenna to which a terrestrial broadcast signal is input, and a cable television broadcast A coaxial cable to which a signal is input, a tuner that tunes a broadcast signal input from either the antenna or the coaxial cable to a desired carrier frequency and outputs an intermediate frequency signal; and the intermediate frequency signal An intermediate frequency amplification circuit that obtains an AGC voltage corresponding to the signal strength of the signal and amplifies the intermediate frequency signal by an amplification factor based on the AGC voltage; An AGC circuit that outputs the AGC voltage based on the intermediate frequency signal, a semiconductor memory in which channel numbers that can be selected and a carrier frequency are stored in association with each other, and a predetermined signal control process. And a microcomputer for inputting the AGC voltage as a digital signal through an A / D port, and storing a channel plan of the terrestrial broadcast and the cable television broadcast. The microcomputer is provided for each of the carrier frequencies. A channel search that tries to tune in, and calculates a spurious from the carrier frequency of a broadcast station in the VHF band among the broadcast stations discovered by the channel search, and a broadcast that can be stably received discovered by the channel search. Whether there is a carrier frequency channel corresponding to the specific frequency band in the station If the corresponding channel does not exist, it is determined that the terrestrial broadcast is received, the channel number and the carrier frequency are stored in the semiconductor memory based on the channel plan of the terrestrial broadcast, and the corresponding channel Is present, it is determined whether or not it matches the calculated spurious, and if it does not match any calculated spurious, it is determined that a cable TV broadcast is being received, and based on the cable TV broadcast channel plan. The channel number and carrier frequency are stored in the semiconductor memory, and when the calculated spurious coincides, the strength of the broadcast signal is judged based on the AGC voltage. If the signal strength is sufficient, the channel of the cable television broadcast Based on the plan, the channel number and carrier frequency are stored in the semiconductor memory and the signal When the strength is insufficient, the semiconductor memory may be configured to store the channel number and the carrier frequency based on the channel plan of terrestrial broadcasting.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combinations and apply them. It is disclosed as.

1 is a schematic block diagram of a television broadcast receiving apparatus to which a broadcast form determining apparatus according to a first embodiment of the present invention is applied. This is a channel plan for terrestrial broadcasting and cable television broadcasting. It is a figure explaining how a spurious is judged. It is a flowchart explaining the process of the microcomputer which performs an auto preset.

DESCRIPTION OF SYMBOLS 10 ... Tuner 10a ... U / V antenna 10b ... Coaxial cable 12 ... Intermediate frequency amplifier circuit 14 ... Video detection circuit 16 ... Video signal processing circuit 18 ... AGC circuit 20 ... Microcomputer 20a ... CPU
20b ... ROM
20b1, 20b2 ... Channel data 20c ... RAM
20d ... Bus 20e ... A / D port 22 ... Semiconductor memory T1 ... Channel data table 30 ... Remote control 100 ... Television broadcast receiver

Claims (6)

Corresponding to terrestrial broadcasting and cable television broadcasting that includes each carrier frequency assigned to the terrestrial broadcast and also has a carrier frequency assigned to a specific frequency band not assigned to the terrestrial broadcast, In a television broadcast receiver that can receive and view signals,
An antenna to which a terrestrial broadcast signal is input;
A coaxial cable for receiving cable TV broadcast signals;
A tuner that tunes a broadcast signal input from either the antenna or the coaxial cable to a desired carrier frequency and outputs an intermediate frequency signal;
An intermediate frequency amplification circuit that acquires an AGC voltage corresponding to the signal strength of the intermediate frequency signal and amplifies the intermediate frequency signal by an amplification factor based on the AGC voltage;
An AGC circuit that outputs the AGC voltage based on the amplified intermediate frequency signal;
A semiconductor memory in which channel numbers that can be selected and a carrier frequency are stored in association with each other;
A predetermined signal control process is executed, the AGC voltage is input as a digital signal via an A / D port, and a microcomputer for storing the channel plan of the terrestrial broadcast and the cable television broadcast is provided.
The above microcomputer
Perform channel search to try tuning for each of the above carrier frequencies,
Based on the carrier frequency of the broadcast station in the VHF band among the broadcast stations found by the channel search, calculate a calculation spurious that is a frequency that may become a spurious,
It is determined whether there is a channel having a carrier frequency corresponding to the specific frequency band among the broadcast stations found by the channel search that can be stably received. If there is no corresponding channel, terrestrial broadcasting is performed. Based on the channel plan of the terrestrial broadcast, the channel number and the carrier frequency are stored in the semiconductor memory, and if the corresponding channel exists, whether or not it matches the calculated spurious. If it does not match any calculated spurious, it is determined that the cable television broadcast is received, and the channel number and the carrier frequency are stored in the semiconductor memory based on the channel plan of the cable television broadcast. When it matches the calculated spurious, the broadcast signal strength is determined based on the AGC voltage. If the signal strength is sufficient, the channel number and carrier frequency are stored in the semiconductor memory based on the channel plan for cable television broadcasting, and if the signal strength is insufficient, the channel is based on the channel plan for terrestrial broadcasting. A television broadcast receiver characterized in that a number and a carrier frequency are stored in the semiconductor memory. A carrier frequency is also included in a specific frequency band that includes a first broadcast form to which a predetermined carrier frequency is assigned and each carrier frequency assigned to the first broadcast form and is not assigned to the first broadcast form. In the broadcast form determination device capable of receiving a signal of a desired frequency corresponding to the assigned second broadcast form,
A frequency search means for searching for receivable frequencies;
Channel information storage means for storing channel information of the first broadcast form and the second broadcast form;
Spurious calculation means for calculating a spurious frequency, which is a frequency that may become spurious, in the specific frequency band based on a search result of the frequency search means;
If there is no frequency that matches the search result of the frequency search means in the spurious frequency, the broadcast form being received is determined as the second broadcast form, and the search result of the frequency search means is included in the spurious frequency. And the signal intensity of the frequency is equal to or lower than a predetermined threshold value, the broadcast form being received is determined as the first broadcast form, and the spurious frequency includes the search result of the frequency search means. A broadcast form determination means for determining that the broadcast form being received is the second broadcast form when there is a matching frequency and the signal strength of the frequency is greater than a predetermined threshold;
A broadcast form determining apparatus comprising: station setting means for setting channel information based on the channel information corresponding to the broadcast form determined by the broadcast form determining means. The spurious calculation means, among the frequency that is a receivable detected by the frequency search means, billed you characterized and Turkey to calculate the spurious frequencies based on the frequency lower than the specific frequency band Item 3. The broadcast form determination device according to Item 2 . The spurious calculation means, among the detected receivable and frequency in the frequency search means, 請 Motomeko 2 or claim you characterized and Turkey to calculate the spurious frequencies generated by frequency of the video signal 3. The broadcast form determination device according to 3. The spurious calculation means, you characterized among the detected receivable and frequency in the frequency search means, and Turkey to calculate the spurious frequencies generated by the frequency of the frequency and the audio signal of the video signal 請 The broadcast form determination apparatus according to any one of claims 2 to 4 . The spurious calculation means, among the detected receivable and frequency in the frequency search means, 請 Motomeko 2 sum and difference spurious frequencies generated by frequency of the audio signal you characterized and go a calculated The broadcast form judgment apparatus of any one of Claim 5 .

Images