JP3394147B2 - Digital audio broadcast receiver - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital audio broadcasting receiver based on the European telecommunications standard (ETS 300 401) (hereinafter, digital audio broadcasting is also referred to as DAB), and more specifically, transmitter identification information. Identifying DAB receiver.

[0002]

2. Description of the Related Art Digital audio broadcasting is a network composed of broadcasting stations that share the same frequency band and can reduce the influence of multipath, and a single frequency network (SF) that broadcasts the same broadcast program at the same time.
N) is possible, and a NULL symbol is included in the transmission frame prior to the effective symbol. This N
Transmitter identification information (hereinafter also referred to as TII) for identifying a broadcast station (transmitter) is inserted in the ULL symbol.

The TII is defined for each broadcasting station, and the broadcasting station can be identified by the TII and can be used for estimating the receiver position. TII signal, ie STII
(T) is inserted into the NULL symbol in the transmission frame as described above, and its waveform is represented by the following equation (1).

[0004]

[Equation 1]

Here, gTII, k (t) in the equation (1) is expressed by the following equation (2), and Rect in the equation (2) is
(T / Tnull) is expressed by the following equation (3). Rect (t / Tnull) is Rect in equation (3).
It is indicated by (x).

[0006]

[Equation 2]

[0007]

[Equation 3]

Zm, ₀ and k in the equation (1) are represented by the following equation (4). However, in equation (4), Z ₀ , ₀ ,
₀ = 0. Ac and p (k) in the equation (4) are represented by the following equation (5). However, in equation (5),
Ac, p (0) = 0. Δ in the equation (5) is a Kronecker symbol, and δ (i, j) is represented by the following equation (6).

[0009]

[Equation 4]

[0010]

[Equation 5]

[0011]

[Equation 6]

Ab (p) in the equation (5) follows the contents shown in FIG.

The symbols used below, including the symbols in the above equations, will be described. fc represents the center frequency of the received signal. K indicates the number of carriers per symbol, and the transmission mode is determined by the number K of carriers. In SFN, the transmission mode is I, and the number of carriers k in this case is 1536. TF represents a transmission frame length, which is 96 msec in the transmission mode I. TNULL indicates a NULL symbol length, and transmission mode I
Is about 1.297 msec. TU indicates an effective symbol length, which is 1 msec in the transmission mode I.

The TII consists of sub identification information and main identification information. c indicates a comb number as sub-identification information, a value indicating a carrier offset from a predetermined position, and 0 ≦ c ≦ 23.
= I (i = 0 to 23) or ci (i = 0 to 23). p is a pattern number that is main identification information, and is a value that indicates a pattern based on the carrier position of TII, and 0 ≦ p ≦ 69, where p = j (j = 0 to 69), or pj (i = 0 to 69)
Display by. φk represents the phase of the kth carrier.

As described above, the main identification information is 1 TI.
It is expressed by the vertical shape of the carrier in the I pattern, and the sub-identification information is expressed by the deviation of the carrier position from the predetermined position. The carriers in the 1TII pattern stand in pairs. Here, the pattern number p corresponds to a broadcasting station, and 70 broadcasting stations (transmitters) can be identified. That is, as shown in FIG. 6, the pattern number p
The pattern indicated by is an 8-bit pattern, and each pattern number p is expressed by combining 4 bits each of "1" and "0", so there are 0 to 69 types.

As described above, the comb number c is the offset frequency from the predetermined position to the carrier position. As is clear from equation (5), the number of carriers k
(= 1536) is divided into four equal parts, one of which is 1536 /
4 = 384, and the carrier frequency interval is 1 kHz.
z, and there is an 8-bit pattern between them, and the frequency interval per bit is 384 kHz.
/ 8 = 48 kHz, and one set of two carriers with an interval of 1 kHz stands, so the offset frequency is 48/2 = 24.
Depending on the type, the comb number c takes a value of 0 to 23.

Therefore, when the received TII signal is expressed in the frequency domain, in the case of the transmission mode I, the comb number c = 1, and the pattern number p = 2, it becomes as schematically shown in FIG. 5 (a). Since the pattern number p = 2, the bit pattern in each of the four equally divided parts is as shown in FIG.
As is clear from the above, it is 〃00011011〃 and 4
For every 8 kHz, the carrier is not output as shown by the broken line in correspondence with 〃 0 〃, the carrier is output as shown by the solid line in correspondence with 〃 1 〃, and all carriers stand in pairs. , As shown in FIG. 5 (b). In addition,
No carrier is output at the center frequency fc.
Since the comb number c = 1, the offset frequency is 2 (= 2 × 1) kHz.

In the case of transmission mode I, four divisions (fc-768 kHz) to (fc-383 kHz),
(Fc-384 kHz) to (fc-1 kHz), (fc
+1 kHz) to (fc + 384 kHz), (fc + 38
5kHz)-(fc + 768kHz) is exactly the same TII
Pattern.

Hereinafter, (fc-768 kHz) to (fc-
383 kHz) is the first section, (fc-384 kHz)
z) to (fc-1 kHz) is the second section, and (fc +
1 kHz) to (fc + 384 kHz) is the third section, and (fc + 385 kHz) to (fc + 768 kHz).
The section of is also referred to as a fourth section, which corresponds to the above-described four equal parts. The first section, the second section, the third section and the fourth section
Each of the sections is divided into eight 48 kHz sections. Each of these 48 kHz sections is a range determined by the sub-identification information and in which a carrier may exist. Each of these eight 48 kHz sections is referred to as an α small section, a β small section, ..., A small section from the lowest frequency, and each is displayed as an α small section of the first section and an α small section of the second section. To do.

If necessary, the small sections a to h of the first section are also denoted by α ₁ , β ₁ , ..., θ ₁ , and similarly, the small sections of α to θ of the second section are represented. alpha _2, beta _2, ..., to display theta ₂ both, for the third section of the alpha sub-interval ~θ small section, similarly displayed also fourth section of alpha sub-interval ~θ small section.

Next, FIG. 4 shows a TII in the DAB receiver.
FIG. 5 shows a conventional block diagram of a decoder portion for decoding the. A TII signal received by a DAB receiver and frequency-converted into a baseband signal is input to a fast Fourier transform (FFT) circuit 1, converted from a time domain signal to a frequency domain signal, and sent to a block divider 2. To be done. The block divider 2 divides the block into 24 blocks for each offset frequency at which the carrier determined by the comb number c may exist.

The signal for each block is supplied to the power detector 4, the total power for each block is calculated in the power detector 4, and the total power is sent to the maximum value detector 13. The largest block is required, and the com number c corresponding to that block
Signal is output.

On the other hand, the selection signal based on the block having the maximum power obtained by the maximum value detector 13 is sent to the selector 12, and the selector 12 selects the signal of the block having the maximum power.
The signal selected by the selector 12 is input to the pattern detector 14. The pattern detector 14 calculates which pattern number p the input signal is close to, and outputs the closest pattern number p.

[0024]

However, according to the conventional method, the value of TII that can be detected is only one, and when the radio waves broadcast from a plurality of broadcasting stations are received under the SFN environment, There is a problem in that each TII cannot be identified.

According to the present invention, when receiving DAB radio waves broadcast from a plurality of broadcasting stations under the SFN environment, a plurality of T's are received.
It is an object of the present invention to provide a digital audio broadcasting receiver capable of identifying II and determining the arrival time difference of each TII.

[0026]

[Means for Solving the Problems] Claim 1 according to the present invention
DAB receiver described, a power detection means for obtaining a sum of electric power of the carrier for each same sub-identification information in the transmitter identification information in paper which is extracted from the demodulated signal received reception signal,
Pattern detecting means for obtaining a pattern of main identification information in the transmitter identification information based on the power of the carrier of the same sub identification information in each range in which the carrier defined by the sub identification information in the transmitter identification information may exist And the same sub-identification obtained by the power detection means
Below a predetermined threshold in the sum of carrier power for each information
The sub-identification information having the above sum is extracted, and the extracted sub-information
Pattern of main identification information for identification information
From the pattern of the main identification information obtained by the detection means
And sorting means for extracting .

According to the DAB receiver according to claim 1, wherein according to the present invention, the sum of the power carrier for each same sub-identification information in the transmitter identification information is determined by the power detecting means. Further , the pattern of the main identification information in the transmitter identification information is pattern-detected based on the power of the carrier of the same sub identification information in each range in which the carrier defined by the sub identification information in the transmitter identification information may exist. Required by means. At the power detector
During the sum of the calculated carrier power for each same sub-identification information
The sub-identification information having a sum equal to or greater than a predetermined threshold is
Main identification for the extracted sub-identification information
The information pattern is the main obtained by the pattern detection means.
It is extracted by the sorting means from the pattern of identification information.
It Therefore, even if a plurality of transmitter identification information is received by the DAB receiver, if the transmitter identification information is different sub identification information from the output of the sorting means, the main identification information and the sub identification information of each transmitter identification information are obtained. The identification information can be correctly identified.

The DAB receiver according to the present invention to such a second aspect, the power detection for obtaining the sum of electric power of the carrier for each same sub-identification information in the transmitter identification information in paper which is extracted from the demodulated signal received reception signal And a pattern of the main identification information in the transmitter identification information based on the power of the carrier of the same sub identification information in each range in which the carrier defined by the sub identification information in the transmitter identification information may exist a pattern detection means, said path
Main identification information pattern obtained by the turn detection means
Timing detecting means for obtaining a reception timing of the transmitter identification information based on the demodulated signal and the power,
Of the carrier power for each same sub-identification information obtained by the detector
Sub-identification with sum greater than or equal to a predetermined threshold in sum
Main information for extracting information and extracted sub-identification information
The pattern of the identification information is obtained by the pattern detection means.
The main identification information extracted from the pattern of the identification information
Characterized in that a sorting means for outputting the reception timing.

According to the DAB receiver of the second aspect of the present invention, in addition to the DAB receiver of the first aspect , based on the main identification information pattern and the demodulated signal obtained by the pattern detecting means. The reception timing of the transmitter identification information is obtained by the timing detection means. The cache for each identical sub-identification information obtained by the power detector
Has a sum greater than or equal to a predetermined threshold in the sum of rear power
Sub-identification information is extracted, and the extracted sub-identification information is
The pattern of the main identification information for the
Extracted from the pattern of the main identification information obtained from
The reception timing of the main identification information is extracted and output from the sorting means. Therefore, even if a plurality of transmitter identification information is received by the DAB receiver, if the transmitter identification information is different sub identification information from the output of the sorting means, the main identification information and the sub identification information of each transmitter identification information are obtained. The identification information can be correctly identified, and the reception timing of the transmitter identification information can be known.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A DAB receiver according to the present invention will be described below with reference to embodiments.

FIG. 1 shows a DA according to an embodiment of the present invention.
It is a block diagram which shows the structure of the decoder part which decodes TII in a B receiver.

The TII signal received by the DAB receiver and frequency-converted into a baseband signal is input to the FFT circuit 1 and demodulated, converted from a time domain signal into a frequency domain signal, and then transmitted to the block divider 2. Sent out. In the block divider 2, 24 for each frequency in which the carrier determined by the comb number c may exist.
Is divided into blocks. That is, the com number c =
0, com number c = 1, ..., Com number c = 23 are divided into 24 blocks. Therefore, this division means that each of the small sections a to h is divided into 24 blocks based on the comb number c.

Here, the set Pc of frequency points included in the block whose comb number is c is expressed by the following equation (7).

[0034]

[Equation 7]

The elements of the set pc of equation (7) are the following (8)
It is as in the formula. Here, n is a natural number, and the units of the center frequencies fc and pc are kHz.

[0036]

[Equation 8]

The signal for each block divided by the block divider 2 is supplied to the power detector 4 and the pattern detector 3 corresponding to each block. The power detector 4 and the pattern detector 3 are provided corresponding to each block divided by the block divider 2, and there are 24 sheets corresponding to the comb number c.

The signal for each block divided by the block divider 2, that is, the signal corresponding to the comb number ci is input to the corresponding power detector 4, and the level of the signal input in the power detector 4 is set to, for example, 2
The power is calculated by multiplying, and the powers of all the input frequency points are added and output. That is, in the power detector 4, the power of the two frequency points with respect to the comb number c in each small section is from the first section to the first section.
All of the eight sub-sections in the fourth section are added and output.

More specifically, in the power detector 4, small sections α ₁ , β ₁ , ..., θ ₁ , α ₂ , β ₂ , ..., θ ₂ , α.
₃ , β ₃ , ..., θ ₃ , α ₄ , β ₄ , ..., θ _4, the power for the same comb number ci is added, and the sum of the powers of the input signals is the same for all 4 sections. output from the power detector 4 for each ci.
From the output from, the power for each identical comb number ci will be known.

On the other hand, the signal for each block, that is, the signal corresponding to the comb number ci is input to the corresponding pattern detector 3, and from the signal for each block input in the pattern detector 3, the first section to the first section. Electric power is calculated for each of the same small sections of the four sections, and the calculated electric powers are added to obtain 8
Calculate the total power for each small section. That is, in the pattern detector 3, the sum of powers for the same comb number ci in the small sections α ₁ , α ₂ , α ₃ and α ₄ and the small section β ₁ ,
The sum of the powers for the same comb number ci in β ₂ , β ₃ , and β ₄ and the sum of the powers for the same comb number ci in the small sections θ ₁ , θ ₂ , θ ₃ , and θ ₄ are obtained. To be

From the sum of the eight electric powers obtained in this way, the fourth to the smallest in the order from the sum of the powers is set as the small section having the carrier, and the remaining four small sections are the small sections having no carrier. , The pattern number p corresponding to this
The pattern based on is output for each of the same comb numbers ci.

Here, the reason that the upper 4th is set as the small section in which the carrier is present is that there are four bits in the pattern number p as described above,
The rest is set as a small section with no carrier because the bit is not set because there are the remaining four as described above.

Therefore, in each of the pattern detectors 3, the pattern number pi for the same comb number ci is obtained, and 2 for each comb number ci.
Four pattern numbers pi are obtained.

A pattern based on the power value for each block output from the power detector 4, that is, the power value for each comb number ci, and the pattern number p output for each block from the pattern detector 3, that is, a pattern for each comb number ci. The pattern based on the number p is supplied to the sorting circuit 5, and in the sorting circuit 5, a power value for each block supplied from the power detector 4 that is equal to or larger than a predetermined threshold value is selected, and the comb number corresponding to the selected block is selected. The pattern number p corresponding to c is selected, and the selected comb number c and the pattern number p corresponding to the comb number c are rearranged in the descending order of power values and output. This is because the pattern number p for the power value of each block supplied from the power detector 4 that is equal to or larger than the predetermined threshold is a highly reliable pattern.

Therefore, even if a plurality of TIIs are received by the DAB receiver, each TII is output from the output of the sorting circuit 5.
, The pattern number p and the com number c of each TII can be correctly identified.

Next, a DA according to another embodiment of the present invention.
The B receiver will be described. FIG. 2 is a block diagram showing a configuration of a decoder portion for decoding TII in a DAB receiver according to another embodiment of the present invention.

FIG. 2 shows an example including a function of detecting the timing of each TII. In this case,
A timing detector 7 is provided in addition to the configuration of the decoder portion for decoding TII in the DAB receiver according to the embodiment of the present invention shown in FIG.

A TII signal received by the DAB receiver and frequency-converted into a baseband signal is input to the FFT circuit 1 and demodulated, and a signal converted from a time-domain signal into a frequency-domain signal is output. The pattern number p output from the pattern detector 3 is input to the timing detector 7 for each block, and the reception timing for each TII is calculated and output to the sorting circuit 6. In the sorting circuit 6, the power value for each block input from the power detector 4 is input, and a power value that is equal to or greater than a threshold value is selected.
The pattern number p, the comb number c, and the reception timing t corresponding to the selected block are rearranged in the order of power values and output.

The timing detector 7, as shown in FIG.
A cross power calculator 8 that calculates cross power based on the output from the FFT circuit 1 and the output from the pattern generator 11, and a fast inverse Fourier transformer (IFFT) 9 that performs an inverse Fourier transform on the output from the cross power calculator 8. , IF
It is composed of a peak detector 10 and a pattern generator 11 to which the output from the FT circuit 9 is input.

The pattern number detected by the pattern detector 3 and the comb number corresponding to the block are supplied to the pattern generator 11, and the pattern generator 11 supplies the frequency corresponding to the supplied pattern number and the comb number corresponding to the block. Generate a complex conjugate signal of the TII signal in the domain. In the cross power spectrum calculator 8 to which the TII signal and the conjugate complex signal of the TII signal are input, the received TII signal after the FFT and the signal from the pattern generator 11 are complex-multiplied to calculate the cross power spectrum.

In the signal from the pattern generator 11, the carrier amplitude is constant, and the phase of the kth carrier is φk.
If the amplitude is 1, the value at the point where the carrier of the cross power spectrum obtained here represents the transfer characteristic of the transmission line at the frequency of the carrier.
By performing an inverse FFT on the signal in the T circuit 9, an approximate value of the impulse response of the transmission line can be obtained.

By obtaining the temporal position of the maximum value of the output signal from the IFFT circuit 9 by the peak detector 10, the reception timing of the TII signal can be obtained.

The sorting circuit 6 selects one of the inputted powers for each block which is equal to or more than the threshold value, the corresponding comb number, pattern number and reception timing value,
If the power values are in descending order, they are switched and output. As a result, the reception timing of each TII signal is obtained and the arrival time difference is detected.

In the embodiment shown in FIG. 2, the sort circuit 6 may perform the rearrangement in the order of the reception timing. At this stage, the time difference between the reception timings of the respective TII signals may be obtained and output.

[0053]

As described above, the DA according to the present invention
According to the B receiver, when receiving DAB radio waves from a plurality of antennas in an SFN environment, it is possible to identify a plurality of TIIs, and it is also possible to obtain the arrival time difference of each TII.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a decoder unit of a DAB receiver according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a decoder unit of a DAB receiver according to another exemplary embodiment of the present invention.

FIG. 3 is a diagram showing an example of a configuration of a timing detector in the DAB receiver shown in FIG.

FIG. 4 is a block diagram showing a configuration of a decoder unit of a conventional DAB receiver.

FIG. 5 is a waveform diagram showing a TII signal in the frequency domain.

FIG. 6 is an explanatory diagram showing patterns for a pattern number p.

[Explanation of symbols]

1 FFT circuit 2 block divider 3 pattern detector 4 Power detector 5 and 6 sorting circuits 7 Timing detector 8 Cross power calculator 9 IFFT circuit 10 Peak detector 11 pattern generator

Claims (2)

(57) [Claims] 1. A digital audio broadcasting receiver,
A power detection means for obtaining a sum of electric power of the carrier for each same sub-identification information in the transmitter identification <br/> information in paper which is extracted from the demodulated signal of the received reception signal, the sub-identifying information during the transmitter identification information The main identification information in the transmitter identification information is based on the power of the carrier of the same sub identification information in each range where the carrier defined by
And pattern detecting means for determining the pattern, the power test
Of carrier power for each same sub-identification information obtained by the output means
Sub-identification with sum greater than or equal to a predetermined threshold in sum
Main information for extracting information and extracted sub-identification information
The pattern of the identification information is obtained by the pattern detection means.
A digital audio broadcast receiver, comprising: sorting means for extracting from a pattern of in-identification information . 2. A digital audio broadcasting receiver,
A power detection means for obtaining a sum of electric power of the carrier for each same sub-identification information in the transmitter identification <br/> information in paper which is extracted from the demodulated signal of the received reception signal, the sub-identifying information during the transmitter identification information The main identification information in the transmitter identification information is based on the power of the carrier of the same sub identification information in each range where the carrier defined by
Pattern detecting means for obtaining the pattern , and the pattern
The main identification information pattern obtained by the detection means and
Timing detecting means for obtaining a reception timing of the transmitter identification information based on a demodulated signal, and the power detector
During the sum of carrier power for each same sub-identification information obtained in
Sub-identification information having a sum equal to or greater than a predetermined threshold
Main identification information for the extracted sub-identification information
Main knowledge obtained by the pattern detection means of the information pattern
Receiving the main identification information extracted from the pattern of different information
A digital audio broadcast receiver, comprising: sorting means for outputting timing .