JP3568186B2 - Digital broadcast receiver - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a digital broadcast receiver, and in particular, when a seek is instructed, the digital broadcast receiver is tuned to a plurality of digital broadcast frequencies in order and stops seeking when a receivable digital broadcast is found. It relates to a broadcast receiver.
[0002]
[Prior art]
In Europe, digital audio broadcasting called DAB (Digital Audio Broadcasting) has been put to practical use. In this DAB, a modulation scheme called OFDM (Orthogonal Frequency Division Multiplex), which is a kind of multi-carrier modulation scheme, is used. A transmission symbol is composed of a guard interval and an effective symbol, so that multipath modulation is performed. It enables strong reception. Each carrier of the DAB is DQPSK modulated.
[0003]
DAB uses three bands: band II (87 to 108 MHz band), band III (175 to 250 MHz band), and L band (1.452 to 1.492 GHz band). In bands II and III, the transmission frame period is used. Transmission mode 1 (strong in multipath, SFN; suitable for single frequency networks) with 96 ms and 1 kHz carrier spacing is used (transmission mode 1 is limited to use in bands II and III). In the L band, a transmission mode 2 with a frame period of 24 ms and a carrier interval of 4 kHz (resistant to movement), a transmission mode 3 with a frame period of 24 ms and a carrier interval of 8 kHz (such as satellite broadcasting), and a transmission mode 4 with a frame period of 48 ms and a carrier interval of 2 kHz are used. Is done.
[0004]
The format of the transmission frame signal in the DAB transmission mode 1 is shown in the upper part of FIG. First, there is a synchronization signal composed of a NULL symbol of 1.297 ms and a phase reference symbol (PRS) of 1.246 ms, and subsequently, 75 OFDM symbols of 1.246 ms are included. The symbols other than the NULL symbol are transmission symbols, where 0.246 ms is a guard interval and the remaining 1 ms is a valid symbol.
[0005]
The S = 1st transmission symbol is a PRS used for performing AFC (Automatic Frequency Adjustment) or the like, and a predetermined specific code (CAZAC code; called Constant Amplitude Zero Auto Correlation code) is a difference between adjacent carriers. Dynamically modulated. S = 2 to 4th transmission symbols are FIC (Fast Information Channel) for transmitting information necessary for the receiver to select a desired program and auxiliary information for the program, S = 5 to 76 The third transmission symbol is an MSC (Main Service Channel) that multiplexes and transmits voice and data sub-channels (Sub Channel). Normally, one sub-channel corresponds to one program, and the FIC includes structural information indicating how the sub-channels are multiplexed in the MSC. Channels can be extracted.
In transmission mode 2, each symbol period in FIG. 5 is reduced to 1/4. In transmission mode 3, each symbol period in FIG. 5 is reduced to 1/8 and the number of OFDM symbols is increased. In transmission mode 4, each symbol period in FIG. 5 is halved.
[0006]
FIG. 6 is a configuration diagram of a DAB receiver with a seek function.
For example, a received signal of a DAB broadcast signal (also referred to as an ensemble) of the band II captured by the antenna 1 is sent to the front end 2, and is subjected to high-frequency amplification by an RF amplifier circuit 3 whose gain can be changed by an AGC voltage, and then mixed. First local oscillation signal L input from PLL circuit 5 by₁  And the center frequency is f_IF1  To the first intermediate frequency signal. The PLL circuit 5 has a frequency f of the reference oscillation signal input from the reference oscillator 6.₁  For f₁  ・ (N₁  / M₁  ) Times frequency L₁  Is output. m₁  Is a fixed value but n₁  Is variably set by a system controller having a microcomputer configuration, which will be described later, so that the tuning frequency can be changed in, for example, 16 kHz steps. The reference oscillator 6 is a VCXO, and varies the oscillation frequency according to a control voltage for automatic frequency adjustment. The first intermediate frequency signal is band-limited by a SAW filter (surface acoustic wave filter) 7 to a pass band width of 1.536 MHz.
[0007]
The output of the SAW filter 7 passes through the AGC amplifier 8 and the second local oscillation signal L input from the PLL circuit 10 by the mixer 9.₂  And the center frequency is f_IF2  (<F_IF1  ) Is converted into a second intermediate frequency signal. The PLL circuit 10 outputs the frequency f of the reference oscillation signal input from the reference oscillator 6.₁  For f₁  ・ (N₂  / M₂  ) Times frequency L₂  Is output. n₂  , M₂  Are both fixed values. The band of the second intermediate frequency signal is limited by the anti-aliasing filter 11.
[0008]
The second intermediate frequency signal output from the anti-aliasing filter 11 is subjected to envelope detection by the envelope detection circuit 12 and output to the RF amplifier circuit 3 and the AGC amplifier 8 as an AGC voltage (see FIG. 5A). The RF amplifier circuit 3 and the AGC amplifier 8 decrease or increase the gain in accordance with the increase or decrease of the AGC voltage so that the second intermediate frequency signal having a substantially constant level can be obtained regardless of the level of the antenna input level. . The output of the envelope detection circuit 12 is input to a NULL detection circuit 13 for detecting a NULL symbol. The NULL detection circuit 13 measures the fall time length Td after the NULL symbol portion is waveform-shaped (see FIG. 5B), and when the NULL time matches the NULL symbol length of any of the transmission modes specified by DAB. A NULL symbol detection signal ND (see FIG. 5C) is output to the timing synchronization circuit 14, the system controller, and the like at the timing of the rising edge. Also, a transmission mode detection signal TM is output (see d in FIG. 5. In FIG. 5 d, Td = 1.297 ms, so that the transmission mode 1 is output as the transmission mode detection signal TM. ).
[0009]
The timing synchronization circuit 14 receives a component for each carrier of a PRS portion (effective symbol period) normally input from an FFT circuit described later, calculates power for each carrier, and detects frame synchronization from a cepstrum obtained by performing IFFT processing. Then, a synchronization detection signal is output to a timing signal generation circuit (not shown) to generate various timing signals. However, immediately after starting reception of a certain ensemble, frame synchronization is detected using the NULL symbol detection signal ND input from the NULL detection circuit 13, and a synchronization detection signal is output.
[0010]
After the output of the anti-aliasing filter 11 is A / D converted by the A / D converter 30, the I / Q component is demodulated by the I / Q demodulation circuit 31, and the transmission frame signal shown in FIG. 5 is restored. . Then, FFT processing is performed on the demodulated I / Q components by the FFT circuit 32 configured by a dedicated processor, and the number of OFDM modulated waves constituting the OFDM modulated wave is n in units of symbols (in the case of the transmission mode 1, n = 1536, In the case of the transmission mode 2, n = 384 lines, in the case of the transmission mode 3, n = 192 lines, and in the case of the transmission mode 4, n = 768 lines. Carrier-specific components (carrier-specific complex data) are extracted. You. The FFT circuit 32 outputs the component for each carrier in the effective symbol period of the PRS portion to the frequency error detection circuit 33 according to a predetermined timing signal. In the frequency error detection circuit 33, after the carrier-specific components of the PRS portion are differentially demodulated between the carriers and decoded (the PRS portion is a transmission side in which a predetermined fixed code is inter-carrier differentially modulated), and then a predetermined reference code is output. Is calculated (see FIG. 9 for a graph of the correlation function). Then, a frequency error between the tuning frequency and the frequency of the DAB broadcast signal is detected from the correlation function by calculation. The frequency error detection circuit 33 outputs frequency error data to the integration circuit 34 while the AFC is turned on by the system controller (outputs data indicating that the frequency error is zero while the AFC is off). ). The integrated data in the integrating circuit 34 is D / A converted by the D / A converter 35 and then output to the reference oscillator 6 as a control voltage for automatic frequency adjustment. The reference oscillator 6 varies the oscillation frequency according to the control voltage, and sets the frequency f of the reference oscillation signal to f.₁  Is varied in a direction to cancel the frequency error.
[0011]
The FFT circuit 32 outputs a carrier-specific component (complex-specific data for each carrier) after FFT for each transmission symbol (effective symbol period) of S = 2 to 76 in FIG. In the channel decoder 36, DQPSK symbol demapping and FIC / MSC separation are performed. After three effective symbols of the FIC are divided into four equal parts, error detection / correction (Viterbi decoding) and descrambling are performed. Twelve FIBs (Fast Information Blocks) are output to the system controller in the form of data called FIGs (Fast Information Groups).
On the other hand, the effective symbol of the MSC is divided into 18 symbols and reconstructed into four CIFs (Common Interleaved Frames). Each CIF includes a plurality of sub-channels (Sub Channel), and one sub-channel usually corresponds to one program.
[0012]
When the user performs a desired program selection operation using the program selection key on the operation panel 37, the system controller 38 performs a predetermined program selection control and outputs the sub-channel designation information corresponding to the desired program with reference to the FIC information. The channel decoder 36 separates the sub-channel designated by the system controller 38 from the four CIFs, and then performs time deinterleaving, error detection / correction (Viterbi decoding), and descrambling to decode DAB audio frame data. , And outputs the decoded DAB audio frame data to the MPEG decoder 39.
The MPEG decoder 39 decodes DAB audio frame data and outputs audio data for two channels. This audio data is D / A converted by the D / A converter 40 and output as an analog audio signal.
[0013]
The operation panel 37 is also provided with a seek key. The memory 41 stores a plurality of ensemble broadcast frequency data. When a seek key is pressed on the operation panel 37 to give a seek command, the system controller 38 performs ensemble seek control. Hereinafter, the seek control processing will be described with reference to the flowchart shown in FIG.
When a seek command is given, the system controller 38 gives an AFC-off command to the frequency error detection circuit 33 to output data indicating zero frequency error and fix the oscillation frequency of the reference oscillator 6 (step S1 in FIG. 7). ).
[0014]
Then, the broadcast frequency data of the first ensemble is read out with reference to the memory 41, and the corresponding n₁  Is set in the PLL circuit 5 to tune to the first ensemble (step S2). Next, it is checked whether a NULL symbol detection signal has been input from the NULL detection circuit 13 (step S3). When the ensemble is caught at the current reception frequency, the output of the envelope detection circuit 12 drops at the NULL symbol portion. The NULL detection circuit 13 shapes the waveform of the output of the envelope detection circuit 12, and outputs a NULL symbol detection signal ND at the rising edge. When the NULL symbol detection signal ND is input, the system controller 38 determines YES in step S3 and gives an AFC ON command to the frequency error detection circuit 33 assuming that there is a DAB broadcast signal at the current reception frequency, and performs seek control processing. It ends (step S4).
[0015]
The output of the front end 2 is subjected to I / Q demodulation by an I / Q demodulation circuit 31, and then subjected to FFT processing by an FFT circuit 32. The carrier-specific component of the PRS portion is subjected to inter-carrier differential demodulation and decoded by the frequency error detection circuit 33, and then a correlation function between the decoded code and a predetermined reference code is calculated. An example of a graph of the correlation function is shown in FIG. 9 (the horizontal axis in FIG. 9 is frequency, and the vertical axis is correlation value). From this correlation function, a frequency error between the tuning frequency and the frequency of the DAB broadcast signal is detected by calculation.
[0016]
Now, as shown by the solid line A in FIG. 8, the center of the spectrum distribution of the received ensemble viewed from the first intermediate frequency signal has the normal center frequency f._IF1  If the frequency is shifted to a higher frequency (the dashed line B in FIG. 8 is the attenuation characteristic of the SAW filter 7), the graph of the correlation function becomes as shown in FIG. When the AFC ON command is given, the frequency error detection circuit 33 outputs frequency error data indicating a frequency error detected by calculation from the correlation function. The frequency error data is integrated by the integration circuit 34, D / A converted by the D / A converter 35, and output to the reference oscillator 6.
[0017]
The reference oscillator 6 varies the oscillation frequency according to the control voltage, and outputs the first local oscillation signal L₁  And the second local oscillation signal L₂  Is varied in a direction to cancel the frequency error. As a result, the spectrum distribution of the received ensemble seen in the first intermediate frequency signal shifts to a lower frequency (see arrow C in FIG. 8), and finally, as shown by the symbol A ′ in FIG. Within the passband of. As a result, the channel decoder 36 can restore the information of the FIC and the MSC without error. When the user selects a desired program on the operation panel 37, the system controller 38 instructs the channel decoder 36 to output DAB audio frame data of the desired program to the MPEG decoder 39. Thereby, a desired program can be heard.
[0018]
If NO in step S3, since there is no ensemble that can be received at the current tuning frequency, the system controller 38 refers to the memory 41 and checks whether broadcast frequency data of the next ensemble exists (step S3). S5) If not present, end seek control processing; if present, seek control corresponding to n₁  Is set in the PLL circuit 5 and tuned to a new ensemble, and the same processing as described above is repeated (step S6).
[0019]
[Problems to be solved by the invention]
However, in the above-described conventional DAB receiver with a seek function, the amount of attenuation in the cutoff band of the SAW filter 7 is not so large, so that when another ensemble exists at a frequency adjacent to the tuning frequency, the seek ends. There was a problem.
That is, each ensemble of DAB has a square frequency spectrum due to the nature of the OFDM modulated wave, and each ensemble is arranged at a narrow interval on the frequency axis. For this reason, a SAW filter 7 having a steep attenuation characteristic is used as a band limiting filter for the first intermediate frequency signal of the DAB receiver. However, if a large amount of attenuation is to be obtained, the area of the SAW filter 7 is increased. Must be installed, requiring installation space and increasing costs. Therefore, normally, an attenuation of about −40 dB is used.
[0020]
On the other hand, the reception sensitivity required for a DAB receiver is that it can receive even an antenna input of -90 dBm, and in order to realize this, a strong AGC (automatic gain adjustment) by a plurality of stages of AGC amplification is applied. ing.
Then, when the front end 2 tunes to a certain reception frequency during the seek, as shown in FIG. 11, the ensemble D adjacent to the upper side of the pass band when viewed from the input side of the SAW filter 7 is used.₀  (The dashed line B in FIG. 11 indicates the attenuation characteristic of the SAW filter 7), only -40 dB is attenuated by the SAW filter 7, and leaks to the output side of the SAW filter 7 (D in FIG. 12).₁  reference). Ensemble D₀  Is converted into a second intermediate frequency signal and then further attenuated by the anti-aliasing filter 11. However, since there is no signal component in the pass band, the envelope detection circuit 12, the RF amplification circuit 3, and the AGC The level is greatly increased by the automatic gain adjustment function applied in the system of the amplifier 8, and D in FIG.₂  It looks like
[0021]
At this time, the NULL detection circuit 13 can detect NULL symbols, and the system controller 38 ends the seek. But Ensemble D₀  Center frequency and f_IF1  , There is a deviation of several hundred kHz or more, which exceeds the automatic frequency adjustment capability using the PRS.₀  Cannot be received normally.
An object of the present invention is to provide a digital broadcast receiver capable of correctly performing a seek operation of digital broadcast in view of the above-described problems of the related art.
[0022]
[Means for Solving the Problems]
In the digital broadcast receiver according to the first aspect of the present invention, the frequency conversion of the received signal of the digital broadcast signal composed of the OFDM modulated wave is converted to a predetermined intermediate frequency, and the band is limited to the intermediate frequency signal bandwidth and output. Receiving means (2A) including means (4, 7), automatic gain adjusting means (8, 12) provided on the output side of the frequency converting means for performing automatic gain adjustment, and a user-desired output from the receiving means. Program information demodulation means (31, 32, 36, 39) for demodulating the program information of the above, storage means (41) for storing a plurality of digital broadcast frequency information, and NULL symbols for detecting the presence or absence of NULL symbols from the received signal When a seek is instructed with the detecting means (16, 17, 13A), the receiving means is sequentially tuned to the frequency of each digital broadcast stored in the storage means, and Stopping a seek when the NULL symbol is detected by the NULL symbol detecting means in signal frequency, if the NULL symbol is not detected a seek control means for continuing the seek (38A), in the digital broadcasting receiver with,Narrow band pass means (15) having a pass band narrower than the signal bandwidth of the intermediate frequency signal for inputting the intermediate frequency signal before automatic gain adjustment outputted from the frequency conversion means (4, 7) is provided. The detection means (16, 17, 13A) detects the presence or absence of a NULL symbol from the intermediate frequency signal when the level of the intermediate frequency signal output from the narrow band pass means exceeds a predetermined reference level. It is characterized by having.
[0023]
According to the first aspect of the present invention, when tuning to a certain reception frequency during a seek, the NULL symbol detection means detects when the level of the intermediate frequency signal output from the frequency conversion means exceeds a predetermined reference level. The presence or absence of a NULL symbol is detected from the intermediate frequency signal.
If a digital broadcast signal to be sought is received at a certain reception frequency during the seek, the level of the intermediate frequency signal output from the frequency conversion means at the preceding stage of the automatic gain adjustment means increases, but the level of the intermediate frequency signal adjacent to the seek target is increased. Of frequencyStrong or medium field strengthIf the digital broadcast signal is received only, it is output from the frequency conversion means at the preceding stage of the automatic gain adjustment means.Passed through the narrow band pass meansThe level of the intermediate frequency signal does not increase. Therefore, when the level of the intermediate frequency signal output from the frequency conversion means at the preceding stage of the automatic gain adjustment means exceeds a predetermined reference level, the presence or absence of a NULL symbol is detected from the intermediate frequency signal and the NULL symbol is detected. By stopping the seek when it is detected, a digital broadcast that is a seek target and can be received can be correctly captured.
When tuning to a certain reception frequency during seek, even if a digital broadcast signal of a strong electric field adjacent to the broadcast frequency to be sought is received, the interference component is blocked by the narrow band pass means, so that NULL symbol detection is performed. The means can more accurately detect a NULL symbol and correctly receive a digital broadcast to be sought.
[0024]
Claims of the invention2In the digital broadcast receiver described above, frequency conversion means (4, 7) for frequency-converting a received signal of a digital broadcast signal composed of an OFDM modulated wave to a predetermined intermediate frequency, limiting the intermediate frequency signal bandwidth, and outputting the intermediate frequency signal. Receiving means (2A) including automatic gain adjusting means (8, 12) provided on the output side of the frequency converting means for performing automatic gain adjustment; and demodulating program information desired by the user from the output of the receiving means. Program information demodulating means (31, 32, 36, 39) and automatic frequency adjusting means (33A, 34, 35, 6, 5, 10) for detecting a frequency error and adjusting the frequency so as to cancel the frequency error; Storage means (41) for storing frequency information of a plurality of digital broadcasts; NULL symbol detection means (16, 17, 13A) for detecting the presence or absence of a NULL symbol from a received signal; When the search is instructed, the receiving means is sequentially tuned to the frequency of each digital broadcast stored in the storage means, and when a NULL symbol is detected by the NULL symbol detection means at a certain reception frequency, the seek is stopped, and And a seek control means (38A) for continuing the seek if no NULL symbol is detected by the frequency adjustment means, and the NULL symbol detection means (16, 17, 13A) comprises: When the level of the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means exceeds a predetermined reference level, the presence or absence of a NULL symbol is detected from the intermediate frequency signal, and the seek control means (38A ) Indicates that, when a seek is instructed, the receiving means is sequentially set to the frequency of each digital broadcast stored in the storage means. It will be tuned, when the NULL symbol is detected by the NULL symbol detection means at a certain receiving frequency, further to perform the frequency adjustment in automatic frequency adjusting means,Within a certain timeIf the frequency error converges below a certain level, stop seeking,Within a certain timeIf the frequency error does not converge below a certain value, the seek is continued.
[0025]
Claim2According to the invention, when the level of the intermediate frequency signal output from the frequency conversion means exceeds a predetermined reference level, the NULL symbol detecting means detects the presence or absence of a NULL symbol from the intermediate frequency signal. The seek control means, when a seek is instructed, sequentially tunes the receiving means to the frequency of each digital broadcast stored in the storage means, and when a NULL symbol is detected by the NULL symbol detection means at a certain reception frequency. Further, if the frequency error converges to a certain value or less within a certain time, the seek is stopped,Within a certain timeIf the frequency error does not converge below a certain value, the seek is continued.
[0026]
When tuned to a certain reception frequency during seek, a digital broadcast signal of a strong electric field adjacent on the frequency axis is received, or a TV broadcast signal other than the digital broadcast signal is displayed on the time axis due to fading phenomenon during mobile reception. For example, if the level of the intermediate frequency signal output from the frequency conversion means happens to exceed a predetermined reference level during the seek due to the occurrence of a dip, and a NULL symbol is detected from the intermediate frequency signal, the automatic frequency adjustment means The frequency cannot be adjusted. Therefore, even if the frequency is adjusted by the automatic frequency adjusting means, if the frequency error does not converge to a certain value or less within a certain time, the seek is continued, so that it is possible to prevent a stop at a tuning frequency at which digital broadcasting cannot be received.
[0027]
Claims of the invention3In the described digital broadcast receiver,Request2The narrow band pass means (15) having a pass band narrower than the signal bandwidth of the intermediate frequency signal to which the intermediate frequency signal before the automatic gain adjustment output from the frequency conversion means (4, 7) is input. When the level of the intermediate frequency signal output from the narrow band pass means exceeds a predetermined reference level, the NULL symbol detecting means (16, 17, 13A) detects the NULL symbol from the intermediate frequency signal. It is characterized in that the presence or absence is detected.
Thereby, when tuning to a certain reception frequency during a seek, even if a digital broadcast signal of a strong electric field adjacent to the broadcast frequency to be sought is received, the interference component is blocked by the narrow band pass means, The NULL symbol detection means can more accurately detect NULL symbols, and can correctly receive digital broadcasts to be sought.
[0028]
Claims of the invention4In the digital broadcast receiver described above, discriminating means (16, 17) for discriminating whether or not the level of the intermediate frequency signal before automatic gain adjustment outputted from the frequency converting means (4, 7) exceeds a reference level is provided.Narrow band pass means (15) having a pass band narrower than the signal bandwidth of the intermediate frequency signal for inputting the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means (4, 7) is provided. (16, 17) determines whether the level of the intermediate frequency signal output from the narrow band pass means exceeds a predetermined reference level,The NULL symbol detection means (16, 13A)Output from the narrow band pass meansThe presence / absence of a NULL symbol is detected from the intermediate frequency signal, and the seek control means (38A) sets the receiving means (2A) to the frequency of each digital broadcast stored in the storage means (41) when the seek is instructed. The tuning is performed in order, and at a certain reception frequency, the level of the intermediate frequency signal output from the frequency conversion means before the automatic gain adjustment is determined to exceed the reference level by the determination means, and the NULL symbol detection means determines NULL. The seek is stopped when the symbol is detected, and the discriminating means determines that the level of the intermediate frequency signal before the automatic gain adjustment output from the frequency conversion means does not exceed the reference level, or the NULL symbol detecting means determines that the signal is NULL. The seek operation is continued when no symbol is detected.
[0029]
Claim4According to the invention, when tuning to a certain reception frequency during the seek, the level of the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means is determined by the determination means to exceed the reference level, and When the NULL symbol is detected by the NULL symbol detection means, the seek is stopped, and the determination means determines that the level of the intermediate frequency signal before the automatic gain adjustment output from the frequency conversion means does not exceed the reference level, or When the NULL symbol is not detected by the NULL symbol detecting means, the seek is continued.
[0030]
If a digital broadcast signal to be sought is received at a certain reception frequency during the seek, the level of the intermediate frequency signal output from the frequency conversion means at the preceding stage of the automatic gain adjustment means increases, but the level of the intermediate frequency signal adjacent to the seek target is increased. Of frequencyStrong or medium field strengthThe level of the intermediate frequency signal output from the frequency converter at the preceding stage of the automatic gain adjuster does not increase just by receiving the digital broadcast signal. Therefore, the output from the frequency conversion means at the preceding stage of the automatic gain adjustment means is output.Passed through the narrow band pass meansBy stopping the seek when the level of the intermediate frequency signal exceeds a predetermined reference level and detecting the presence or absence of a NULL symbol from the intermediate frequency signal, a digital broadcast that can be received by the seek target can be correctly captured.
Also, when tuning to a certain reception frequency during a seek, even if a digital broadcast signal of a strong electric field adjacent on the frequency axis is received, the interference component is reliably blocked by the narrow band pass means, so The means eliminates the possibility of erroneously determining that the level of the intermediate frequency signal exceeds a predetermined reference level even when receiving strong adjacent interference. There is no danger of detecting a NULL symbol of an adjacent digital broadcast from the intermediate frequency signal by mistake. Therefore, when there is a digital broadcast signal of a strong electric field adjacent to the broadcast frequency to be sought during the seek, there is no possibility that the seek is stopped by mistake.
[0031]
Claims of the invention5In the digital broadcast receiver described above, discriminating means (16, 17) for discriminating whether or not the level of the intermediate frequency signal before automatic gain adjustment outputted from the frequency converting means (4, 7) exceeds a reference level is provided. The NULL symbol detection means (16, 13A) detects the presence or absence of a NULL symbol from the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means, and the seek control means (38A) instructs a seek operation. At this time, the receiving means (2A) is sequentially tuned to the frequency of each digital broadcast stored in the storage means (41), and at a certain receiving frequency, the discriminating means determines whether or not there is an automatic gain adjustment output from the frequency converting means. When it is determined that the level of the intermediate frequency signal exceeds the reference level and a NULL symbol is detected by the NULL symbol detection means. Further, the automatic frequency adjusting means performs frequency adjustment, and stops seeking if the frequency error converges to a certain value or less within a certain time, and continues seeking if the frequency error does not converge to a certain value or less within a certain time. It is characterized by having done.
[0032]
Claim5According to the invention, when tuning to a certain reception frequency during the seek, it is determined that the level of the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means exceeds the reference level by the determination means, and When a NULL symbol is detected from the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means by the NULL symbol detection means, the automatic frequency adjustment means further performs frequency adjustment;Within a certain timeIf the frequency error converges below a certain level, stop seeking,Within a certain timeIf the frequency error does not converge below a certain value, the seek is continued.
[0033]
When tuned to a certain reception frequency during seek, a digital broadcast signal of a strong electric field adjacent on the frequency axis is received, or a TV broadcast signal other than the digital broadcast signal is displayed on the time axis due to fading phenomenon at the time of mobile reception. For example, if the level of the intermediate frequency signal output from the frequency conversion means happens to exceed a predetermined reference level during the seek due to the occurrence of a dip, and a NULL symbol is detected from the intermediate frequency signal, the automatic frequency adjustment means The frequency cannot be adjusted. Therefore, even if the frequency is adjusted by the automatic frequency adjustment means, if the frequency error does not converge to a certain value or less within a certain time, the seek operation is continued, thereby preventing a stop at a tuning frequency at which there is no receivable digital broadcast. it can.
[0034]
Claims of the invention6In the described digital broadcast receiver,Request5The narrow band pass means (15) having a pass band narrower than the signal bandwidth of the intermediate frequency signal to which the intermediate frequency signal before the automatic gain adjustment output from the frequency conversion means (4, 7) is input. The determination means (16, 17) determines whether the level of the intermediate frequency signal output from the narrow band pass means exceeds a predetermined reference level, and the NULL symbol detection means (16, 13A) It is characterized in that the presence or absence of a NULL symbol is detected from the intermediate frequency signal output from the band pass means.
[0035]
Thereby, when tuning to a certain reception frequency during a seek, even if a digital broadcast signal of a strong electric field adjacent on the frequency axis is received, the disturbing component is reliably blocked by the narrow band pass means, The discriminating means is free from the possibility of erroneously discriminating that the level of the intermediate frequency signal exceeds a predetermined reference level even if it receives strong adjacent interference, and the NULL symbol detecting means receives no strong adjacent interference. Also, there is no possibility that the NULL symbol of the adjacent digital broadcast is erroneously detected from the intermediate frequency signal. Therefore, when there is a digital broadcast signal of a strong electric field adjacent to the broadcast frequency to be sought during the seek, there is no possibility that the seek is stopped by mistake.
[0036]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, an embodiment of the present invention will be described with reference to FIG.
FIG. 1 is a block diagram of a DAB receiver with a seek function according to the present invention, and the same components as those in FIG. 6 are denoted by the same reference numerals.
On the output side of the SAW filter 7 of the front end 2A, the center of the pass bandwidth is f_IF1  A peaking filter 15 is connected as a narrow band pass filter whose pass band width is smaller than 1.536 MHz, and when the front end 2A tunes to an ensemble of a certain DAB broadcast, another DAB adjacent on the frequency axis. When the broadcast ensemble is received, the first intermediate frequency signal from which the interference component due to the adjacent ensemble has been removed is extracted. FIG. 2 shows the attenuation characteristics of the peaking filter 15.
[0037]
An envelope detection circuit 16 is connected to the output side of the peaking filter 15, and the first intermediate frequency signal narrowed by the peaking filter 15 is subjected to envelope detection (see FIG. 4A). The output of the envelope detection circuit 16 is connected to a NULL detection circuit 13A for detecting the presence or absence of a NULL symbol, and a determination circuit 17 for determining whether the level of the first intermediate frequency signal exceeds a predetermined reference level. . The discriminating circuit 17 averages the output of the envelope detection circuit 16 to detect an average voltage AV indicating the level of the first intermediate frequency signal, and converts the average voltage AV to a reference voltage E corresponding to a predetermined reference level._C  AV> E_C  At this time, a NULL detection permission signal NOK is output to the NULL detection circuit 13A.
[0038]
When the NULL detection permission signal NOK is not input from the discrimination circuit 17, the NULL detection circuit 13A does not perform the operation of detecting the presence or absence of the NULL symbol, keeps the output at the low level, and outputs the NULL detection permission signal from the discrimination circuit 17. Only while NOK is being input, the operation of detecting the presence or absence of a NULL symbol is performed in the same manner as the NULL detection circuit 13 of the conventional example in FIG. That is, after the output of the envelope detection circuit 16 is shaped (see b in FIG. 4 and b in FIG. 6), the fall time length Td is measured, and the NULL symbol length in any of the transmission modes specified by DAB is determined. , A NULL symbol detection signal ND (see FIGS. 4 and 6c) is output to the timing synchronization circuit 14, the system controller, and the like at the timing of the rising edge. The transmission mode detection signal TM is also output to each unit.
[0039]
When a seek key is pressed on the operation panel 37 and a seek instruction is given, a system controller 38A of a microcomputer executes a predetermined seek control process. When a program selection operation is performed with a program selection key, a predetermined program selection control is performed. I do. Among these, in the seek control processing, as a seek stop condition, in addition to the detection of a NULL symbol, the frequency error detection circuit 33A, the integration circuit 34, the D / A converter 35, the reference oscillator 6, and the PLL circuits 5, 10 When the frequency adjustment is performed by the automatic frequency adjustment system, the condition is that the frequency error falls within a certain value within a certain time.
The frequency error detection circuit 33A outputs the frequency error data Δf to the system controller 38A.
The other components are configured exactly the same as in FIG.
[0040]
Next, the seek operation in the above-described embodiment will be described with reference to FIGS. FIG. 3 is a flowchart showing the seek control processing of the system controller 38A, and FIG. 4 is a time chart showing the operation of the discrimination circuit and the NULL detection circuit.
Here, for convenience of explanation, it is assumed that the DAB receiver with a seek function shown in FIG. 1 can receive an ensemble of DAB broadcasts of band II and band III. It is assumed that broadcast frequency data of ten ensembles in band II and band III is stored in memory 41 in advance in memory channels CH1 to CH10.
[0041]
When the user presses a seek key on the operation panel 37 to instruct a seek, the system controller 38A gives an AFC off command to the frequency error detection circuit 33A to output data indicating zero frequency error, and the oscillation frequency of the reference oscillator 6 is changed. It is fixed (step S10 in FIG. 3).
Then, the broadcast frequency data of the first ensemble stored in the memory channel CH1 is read out with reference to the memory 41, and n corresponding to the broadcast frequency data is read out.₁  Is set in the PLL circuit 5 to tune to the first ensemble (step S11). Next, it is checked whether a NULL symbol detection signal ND has been input from the NULL detection circuit 13A (step S12).
[0042]
Here, when the ensemble to be sought is not received, and only the ensemble of the weak electric field or the medium electric field strength adjacent on the frequency axis is received, the ensemble is viewed with the first intermediate frequency signal extracted from the preceding stage of the AGC amplifier 8. In this case, the reception level of the adjacent ensemble is low, and when only the ensemble of the strong electric field strength adjacent on the frequency axis is received, the first ensemble extracted from the preceding stage of the AGC amplifier 8 via the peaking filter 15 is further extracted. The reception level of the adjacent ensemble when viewed from the intermediate frequency signal is low.
[0043]
The output of the peaking filter 15 is subjected to envelope detection by an envelope detection circuit 16 and input to a discrimination circuit 17 and a NULL detection circuit 13A (see a in FIG. 4A). Is equal to the reference voltage E._C  (See (1) of FIG. 4), the NULL detection permission signal NOK is not output to the NULL detection circuit 13A. Therefore, the NULL detection circuit 13A does not perform the NULL symbol detection operation and holds the NULL symbol detection signal ND low.
[0044]
At this time, the system controller 38A determines NO in step S12, can correctly determine that the ensemble is not received at the current reception frequency, and does not need to stop seeking at the wrong reception frequency. That is, when the determination in step S12 is NO, the broadcast frequency data of the ensemble stored in the next memory channel CH2 is read out because it is not the last memory channel with reference to the memory 41, and the corresponding n₁  Is set in the PLL circuit 5 and tuned to the second ensemble (steps S13 and S14).
[0045]
Here, assuming that the ensemble to be sought is received, the signal level of the first intermediate frequency signal extracted from the preceding stage of the AGC amplifier 8 via the peaking filter 15 is somewhat higher. The output of the peaking filter 15 is envelope-detected by the envelope detection circuit 15 and input to the discrimination circuit 17 and the NULL detection circuit 13A (see a in FIG. 4B). Is equal to the reference voltage E._C  (See FIG. 4B), and outputs a NULL detection permission signal NOK to the NULL detection circuit 13A.
[0046]
The NULL detection circuit 13A, which has received the NULL detection permission signal NOK, shapes the waveform of the output of the envelope detection circuit 16 (see b in FIG. 4 (2)), measures the fall time length Td, and outputs DAB If the value matches the NULL symbol length of any of the transmission modes specified in (1), a NULL symbol detection signal ND (see FIG. 4 (2)) is output to the timing synchronization circuit 14, the system controller 38A, and the like at the timing of the rising edge. Further, a transmission mode detection signal is also output to each unit. Using the NULL symbol detection signal ND, the timing synchronization circuit 14 detects frame synchronization and outputs a synchronization detection signal, and a timing signal generation circuit (not shown) generates and outputs various timing signals.
[0047]
When NULL symbol detection signal ND is input, system controller 38A determines YES in step S12. However, the detection of the NULL symbol this time happens to cause a digital broadcast signal with a strong electric field adjacent to it on the frequency axis to be received, or a dip on the time axis to a TV broadcast signal other than the digital broadcast signal due to a fading phenomenon during mobile reception. Occurs, the level of the first intermediate frequency signal output from the peaking filter 15 happens to be higher than a predetermined reference level during a seek, and there is no possibility that a NULL symbol is detected from the intermediate frequency signal. I can not say. Therefore, the seek stop condition is not satisfied only by detecting the NULL symbol.
[0048]
That is, when YES is determined in the step S12, an AFC ON command is given to the frequency error detection circuit 33A, and a timer for measuring a fixed time is started (steps S15 and S16).
The second intermediate frequency signal output from the front end 2A is subjected to A / D conversion and then subjected to I / Q demodulation by the I / Q demodulation circuit 31 to restore the transmission frame signal shown in FIG. From the output of the I / Q demodulation circuit 31, the FFT circuit 32 constitutes n OFDM modulated waves in symbol units (n = 1536 in transmission mode 1, n = 384 in transmission mode 2, In the case of the transmission mode 3, n = 192 lines, and in the case of the transmission mode 4, n = 768 lines). The FFT circuit 32 outputs the carrier-specific component of the PRS portion to the frequency error detection circuit 33A, and the frequency error detection circuit 33A performs differential demodulation and decoding between the carriers, and then performs correlation with a predetermined known reference code. The function is calculated. Then, a frequency error is detected from the obtained correlation function by calculation, and the detected frequency error data is output to the integration circuit 34. The frequency error data is integrated by an integration circuit 34, D / A converted by a D / A converter 35, and output to the reference oscillator 6 as a control voltage for automatic frequency adjustment. The reference oscillator 6 has an oscillation frequency f according to the control voltage.₁  And the first local oscillation signal L₁  And the second local oscillation signal L₂  Is varied in a direction to cancel the frequency error.
[0049]
If the detection of the NULL symbol this time is not based on the ensemble, but happens to cause only a dip on the time axis in TV broadcast signals other than DAB broadcast signals due to fading phenomenon during mobile reception, etc. The frequency error does not become small even after elapse.
[0050]
The system controller 38A inputs the frequency error data Δf at that time from the frequency error detection circuit 33A when the timer has finished measuring the predetermined time and the time is up, and checks whether the frequency error data has converged below a certain value (steps S17 and S18). . If NO, it is determined that a NULL symbol has been detected by mistake for some reason despite the fact that frequency pull-in is originally impossible, and an AFC off command is given to the frequency error detection circuit 33A, and an integration circuit is given. After outputting the data of zero frequency error to 34 (step S19), the process proceeds to step S13 to tune to the ensemble stored in the next memory channel CH3 (steps S14 and S11). Perform processing.
This eliminates the needless continuation of the frequency pull-in operation for a nonexistent DAB broadcast, and enables a high-speed and accurate seek.
[0051]
On the contrary, there is originally an ensemble of the DAB broadcast to be sought this time, and when viewed from the first intermediate frequency signal, the center frequency of the received ensemble is the center frequency f of the SAW filter 7._IF1  If the frequency pull-in by the AFC is possible, the AFC operates normally and the frequency error converges to zero as time elapses. In this case, YES is determined in the step S18, and since the ensemble program can be normally heard, the seek is finished.
The channel decoder 36 restores FIC and MSC information from the carrier-specific components of each symbol input from the FFT circuit 32. When the user selects a desired program on the operation panel 37, the system controller 38A instructs the channel decoder 36 to output DAB audio frame data of the desired program to the MPEG decoder 39. Thereby, a desired program can be heard.
[0052]
According to the above-described embodiment, when tuning to a certain reception frequency during a seek, the level of the first intermediate frequency signal extracted from the preceding stage of the AGC amplifier 8 is determined by the envelope detection circuit 16 and the discrimination circuit 17 to the predetermined reference level. It is determined whether the level exceeds the predetermined reference level. When the level exceeds a predetermined reference level, the presence of the NULL symbol is detected from the first intermediate frequency signal by the envelope detection circuit 16 and the NULL detection circuit 13A, and the NULL symbol is detected. By stopping the seek when the ensemble is sought, an ensemble that is a seek target and can be received can be correctly captured.
[0053]
Further, since the first intermediate frequency signal is extracted from the preceding stage of the AGC amplifier 18 through the peaking filter 15 having a pass band narrower than the reception signal bandwidth of the DAB broadcast, even if the adjacent ensemble is a strong electric field, the discrimination circuit 17 However, there is no danger of erroneously determining that the level of the first intermediate frequency signal exceeds a predetermined reference level.
Further, when a NULL symbol is detected, it is further determined by the AFC whether or not the frequency error has converged to a predetermined value or less within a predetermined time. If the frequency error does not converge, the TV broadcast signal other than the ensemble due to a fading phenomenon during mobile reception or the like. It is determined that the dip on the time axis that has occurred, etc., is only detected as a NULL symbol by mistake, and the seek of another ensemble is continued without ending the seek, so that an ensemble that can listen to the program is received quickly and accurately. it can.
[0054]
The NULL detection circuit 13A always detects the presence or absence of a NULL symbol from the output of the envelope detection circuit 16 as in the conventional NULL detection circuit 13, and outputs a NULL symbol detection signal ND when a NULL symbol is detected. The determination circuit 17 outputs a NULL detection permission signal NOK to the system controller 38A, and the system controller 38A outputs a NULL detection signal from the determination circuit 17 between steps S11 and S12 in FIG. It may be checked whether the permission signal NOK has been input, and if YES, the process of step S12 may be performed, and if NO, the process may proceed to step S13.
Alternatively, the peaking filter 15 may be omitted, and the output of the SAW filter 7 may be directly input to the envelope detection circuit 16.
[0055]
In each of the above-described embodiments and modified examples, DAB broadcasting performed in Europe has been described. However, the present invention is not limited to this, and OFDM modulated signals having NULL symbols exist. Digital broadcasting using waves can be similarly applied to broadcasting, communication, and the like for other uses such as digital terrestrial TV broadcasting and digital satellite broadcasting.
[0056]
【The invention's effect】
According to the present invention, when the level of the intermediate frequency signal output from the frequency conversion means at the preceding stage of the automatic gain adjustment means exceeds a predetermined reference level, the presence or absence of a NULL symbol is detected from the intermediate frequency signal. , When a NULL symbol is detected, a digital broadcast that is a seek target and can be received can be correctly captured.
[Brief description of the drawings]
FIG. 1 is a block diagram of a DAB receiver with a seek function according to one embodiment of the present invention.
FIG. 2 is a diagram showing an attenuation characteristic of a peaking filter in FIG. 1;
FIG. 3 is a flowchart showing a seek control process by the system controller of FIG. 1;
FIG. 4 is a time chart for explaining a NULL symbol detection operation in FIG. 1;
FIG. 5 is an explanatory diagram illustrating a configuration of a DAB transmission frame signal and an operation of detecting a NULL symbol.
FIG. 6 is a block diagram of a conventional DAB receiver with a seek function.
FIG. 7 is a flowchart showing a seek control process by the system controller of FIG. 6;
FIG. 8 is a diagram illustrating a frequency spectrum of an ensemble viewed from a first intermediate frequency signal.
FIG. 9 is a diagram showing an operation of the frequency error detection circuit.
FIG. 10 is a diagram illustrating a frequency spectrum of an ensemble viewed from a first intermediate frequency signal.
FIG. 11 is a diagram showing a frequency spectrum of an ensemble viewed from a first intermediate frequency signal on the input side of a SAW filter.
FIG. 12 is a diagram showing a frequency spectrum of an ensemble viewed from a first intermediate frequency signal on the output side of a SAW filter.
FIG. 13 is a diagram showing a frequency spectrum of an ensemble viewed from a first intermediate frequency signal on the output side of the AGC amplifier.
[Explanation of symbols]
1 Antenna 2A Front end
3 RF amplifier circuit 4, 9 mixer
5, 10 PLL circuit 6 Reference oscillator
7 SAW filter 8 AGC amplifier
11 Anti-aliasing filter 12, 16 Envelope detection circuit
13A NULL detection circuit 15 Peaking filter
17 discrimination circuit 31 I / Q demodulation circuit
32 FFT circuit 33A Frequency error detection circuit
34 integration circuit 35 D / A converter
36 channel decoder 37 operation panel
38A system controller 39 MPEG decoder
41 memory

Claims (6)

Frequency conversion means for converting a received signal of a digital broadcast signal composed of an OFDM modulated wave into a predetermined intermediate frequency, limiting the output to the intermediate frequency signal bandwidth, and outputting the converted signal; Receiving means including automatic gain adjusting means for performing gain adjustment; program information demodulating means for demodulating program information desired by a user from an output of the receiving means; storage means for storing frequency information of a plurality of digital broadcasts; A NULL symbol detecting means for detecting the presence or absence of a NULL symbol from a signal; and, when a seek is instructed, the receiving means is sequentially tuned to the frequency of each digital broadcast stored in the storage means. When the detecting means detects a NULL symbol, the seek is stopped, and when the NULL symbol is not detected, the seek is continued. And over click control means, in the digital broadcasting receiver with,
Providing a narrow band pass means having a narrower pass band than the signal bandwidth of the intermediate frequency signal to input the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means,
The NULL symbol detection means, when the level of the intermediate frequency signal output from the narrow band pass means exceeds a predetermined reference level, detects the presence or absence of a NULL symbol from the intermediate frequency signal;
A digital broadcast receiver characterized by the following. Frequency conversion means for converting a received signal of a digital broadcast signal composed of an OFDM modulated wave into a predetermined intermediate frequency, limiting the output to the intermediate frequency signal bandwidth, and outputting the converted signal; Automatic gain adjusting means for performing gain adjustment; receiving means including: a program information demodulating means for demodulating user-desired program information from an output of the receiving means; detecting a frequency error and performing frequency adjustment so as to cancel the frequency error. Automatic frequency adjusting means for performing, a storage means for storing a plurality of frequency information of digital broadcasting, a NULL symbol detecting means for detecting the presence or absence of a NULL symbol from a received signal, and a receiving means for storing when a seek is instructed. The tuning is sequentially tuned to the stored frequency of each digital broadcast, and a NULL symbol is detected by a NULL symbol detecting means at a certain reception frequency. There stop seek when detected, to perform the frequency adjustment in the automatic frequency adjusting means, in the digital broadcasting receiver having a seek control means for continuing the seek, the if the NULL symbol is not detected,
The NULL symbol detection means detects the presence or absence of a NULL symbol from the intermediate frequency signal when the level of the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means exceeds a predetermined reference level,
The seek control means, when a seek is instructed, sequentially tunes the receiving means to the frequency of each digital broadcast stored in the storage means, and when a NULL symbol is detected by the NULL symbol detection means at a certain reception frequency. Furthermore, the automatic frequency adjusting means performs frequency adjustment, and seek stops if the frequency error converges to a certain value or less within a certain time, and continues seek if the frequency error does not converge to a certain value or less within a certain time. What you did,
A digital broadcast receiver characterized by the following. Providing a narrow band pass means having a narrower pass band than the signal bandwidth of the intermediate frequency signal to input the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means,
The NULL symbol detection means, when the level of the intermediate frequency signal output from the narrow band pass means exceeds a predetermined reference level, detects the presence or absence of a NULL symbol from the intermediate frequency signal;
The digital broadcast receiver according to claim 2, wherein: Frequency conversion means for converting a received signal of a digital broadcast signal composed of an OFDM modulated wave into a predetermined intermediate frequency, limiting the output to the intermediate frequency signal bandwidth, and outputting the converted signal; Receiving means including automatic gain adjusting means for performing gain adjustment; program information demodulating means for demodulating program information desired by a user from an output of the receiving means; storage means for storing frequency information of a plurality of digital broadcasts; A NULL symbol detecting means for detecting the presence or absence of a NULL symbol from a signal; and, when a seek is instructed, the receiving means is sequentially tuned to the frequency of each digital broadcast stored in the storage means. When the detecting means detects a NULL symbol, the seek is stopped, and when the NULL symbol is not detected, the seek is continued. And over click control means, in the digital broadcasting receiver with,
Along with providing determination means for determining whether the level of the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means exceeds the reference level,
Providing a narrow band pass means having a pass band narrower than the signal bandwidth of the intermediate frequency signal to input the intermediate frequency signal output from the frequency conversion means,
The determining means determines whether or not the level of the intermediate frequency signal output from the narrow band pass means exceeds the reference level,
NULL symbol detecting means detects the presence or absence of a NULL symbol from the intermediate frequency signal before automatic gain adjustment output from the narrow band pass means,
A digital broadcast receiver characterized by the following. Frequency conversion means for converting a received signal of a digital broadcast signal composed of an OFDM modulated wave into a predetermined intermediate frequency, limiting the output to the intermediate frequency signal bandwidth, and outputting the converted signal; Automatic gain adjusting means for performing gain adjustment; receiving means including: a program information demodulating means for demodulating user-desired program information from an output of the receiving means; detecting a frequency error and performing frequency adjustment so as to cancel the frequency error. Automatic frequency adjusting means for performing, a storage means for storing a plurality of frequency information of digital broadcasting, a NULL symbol detecting means for detecting the presence or absence of a NULL symbol from a received signal, and a receiving means for storing when a seek is instructed. The tuning is sequentially tuned to the stored frequency of each digital broadcast, and a NULL symbol is detected by a NULL symbol detecting means at a certain reception frequency. There stop seek when detected, to perform the frequency adjustment in the automatic frequency adjusting means, in the digital broadcasting receiver having a seek control means for continuing the seek, the if the NULL symbol is not detected,
Along with providing determination means for determining whether the level of the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means exceeds the reference level,
The NULL symbol detection means detects the presence or absence of a NULL symbol from the intermediate frequency signal before automatic gain adjustment output from the frequency conversion means,
The seek control means, when a seek is instructed, sequentially tunes the receiving means to the frequency of each digital broadcast stored in the storage means, and at a certain reception frequency, the automatic gain output from the frequency conversion means by the discriminating means. When it is determined that the level of the intermediate frequency signal before the adjustment exceeds the reference level, and the NULL symbol detection unit detects a NULL symbol, the automatic frequency adjustment unit further performs frequency adjustment, and within a certain period of time. If the frequency error converges below a certain value, the seek is stopped, and if the frequency error does not converge below a certain value within a certain time, the seek is continued.
A digital broadcast receiver characterized by the following. Providing a narrow band pass means having a pass band narrower than the signal bandwidth of the intermediate frequency signal to input the intermediate frequency signal output from the frequency conversion means,
The determining means determines whether or not the level of the intermediate frequency signal output from the narrow band pass means exceeds the reference level,
NULL symbol detecting means detects the presence or absence of a NULL symbol from the intermediate frequency signal before automatic gain adjustment output from the narrow band pass means,
The digital broadcast receiver according to claim 5, wherein:

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