JP2003115816A - Method and device for ofdm demodulation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve performance in wide band synchronizing processing in an OFDM demodulation method suitable for applying to a receiver for ground wave digital television broadcasting or the like. SOLUTION: Slot management is made into two systems of slot management (figure 1A) for wide band synchronizing processing and slot management (figure 1B) for detection processing, and after the slot management for wide band synchronizing processing is completed, the slot management for detection processing is started.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is suitable for OFDM applied to a receiver for terrestrial digital television broadcasting.
(Orthogonal Frequency Division Multiplex) Demodulation method and apparatus.

[0002]

2. Description of the Related Art ISDB-T (Integrated Services Digital Broadcascas) using OFDM technology is used as a transmission method for terrestrial digital television broadcasting, which is a next-generation broadcasting method.
ting for Terrestrial) is ARIB (Association of R)
adio Industries and Business: Association of Radio Industries and Businesses)
It is standardized by.

The OFDM modulation system is a kind of multi-carrier modulation system, and coded data (information symbols) serial-parallel converted into a large number of carriers which are orthogonal to each other between adjacent ones.
And the Inverse Fast Fourier Transform (Invert Fast Fourie
After it is collectively modulated into a signal in the time domain by r Transform (IFFT), an OFDM signal is generated and transmitted by quadrature modulation.

Since the OFDM modulation method is a multi-carrier modulation method, it is possible to set the modulation method for each carrier. In ISDB-T, DQPSK, QPSK, 16QAM, 6 are used depending on the bit rate to be transmitted.
It is possible to allocate 4QAM.

The ISDB-T employs a system (segment structure) in which the 6M frequency band of the UHF band is divided into bands called 13 segments, and a modulation system can be set for each segment. It has a feature that hierarchical modulation of up to 3 hierarchical layers can be performed.

FIG. 5 shows an ISDB-T model receiver (OFD).
FIG. 3 is a circuit diagram showing a part of the configuration of the M demodulation device). This ISDB-T model receiver includes a differential demodulation / synchronization demodulation unit (differential detection / synchronization detection unit) 1 and an FEC (Forward Er).
ror correction) units 2 and 3.

The differential demodulation / synchronization demodulation unit 1 performs orthogonal demodulation and FFT (Fast Fourier Transforforation) on a baseband signal obtained by frequency-converting and digital-converting a received signal.
m), differential demodulation, synchronous demodulation, etc.
FFT circuit 6, detection circuit 7, OFDM frame decoding circuit 8 and TMCC (Transmission and Multiplexin)
g Configuration Control) signal circuit 9.

The FEC sections 2 and 3 are circuit sections for performing error correction, and the FEC section 2 is a frequency deinterleave circuit 10.
Time deinterleave circuit 11, modulation division circuit 12, QP
An SK demapping circuit 13, a 16QAM demapping circuit 14, a 64QAM demapping circuit 15 and a modulation synthesizing circuit 16 are provided.

The FEC section 3 includes a layer dividing circuit 17, bit deinterleaving circuits 18 to 20, depuncturing circuits 21 to 23, a layer combining circuit 24, a Viterbi decoding circuit 25,
Hierarchical division circuit 26 and byte deinterleave circuits 27-2
9, energy diffusion circuits 30 to 32, a null packet circuit 33, a TS reproduction circuit 34, and an outer code circuit 35.

The frequency / clock synchronizing circuit 5 detects a narrow band frequency error within the carrier interval (hereinafter referred to simply as "frequency error") and a wide band frequency error per carrier interval unit (hereinafter referred to as "wide band synchronization error"). 6A shows an example in which wideband synchronization is established, and FIG. 6B shows an example in which wideband synchronization is not established (when center frequency f ₀ is two carriers lower).

FIG. 7 is a circuit diagram showing a conventional configuration example of the frequency / clock synchronization circuit 5. In this configuration example, the frequency / clock synchronization circuit 5 includes a complex multiplier 36 and a delay circuit 3.
7, 38, correlation circuits 39, 40, frequency error detection circuit 4
1, a wideband synchronization error detection circuit 42 and an addition circuit 43.

In the frequency / clock synchronization circuit 5 thus constructed, the delay circuit 37 delays the I signal output from the complex multiplier 36 by one symbol length,
The correlation circuit 39 obtains the correlation between the I signal output from the complex multiplier 36 and the delayed I signal output from the delay circuit 37 (see FIG. 8).

The delay circuit 38 delays the Q signal output from the complex multiplier 36 by one symbol length, and the correlation circuit 40 outputs the Q signal output from the complex multiplier 36.
The correlation between the signal and the delayed Q signal output from the delay circuit 38 is obtained.

The frequency error detection circuit 41 detects the frequency error from the correlation information of the I / Q signals output from the correlation circuits 39 and 40, and the wide band synchronization error detection circuit 42 outputs the output of the FFT circuit 6. The wideband synchronization error is detected from the output, the frequency error and the wideband synchronization error are added by the adder 43, and the added value is supplied to the complex multiplier 36.
The frequency error and the wide band synchronization error of the I / Q signal output from are removed.

The FFT circuit 6 is a circuit for extracting an effective symbol period signal from the I / Q signal output from the complex multiplier 36 and subjecting it to fast Fourier transform to demodulate I / Q symbol data. The detection circuit 7 is a DQPSK. This is a circuit that performs differential detection on the modulated signal and synchronous detection on the QPSK modulated signal, 16QAM modulated signal, and 64QAM modulated signal.

FIG. 9 is a circuit diagram showing a part of a conventional configuration example of the FFT circuit 6 and the detection circuit 7. FFT circuit 6
4, 44 and 45 are FFTs for alternately storing I / Q symbol data output from a butterfly operation circuit (not shown) included in the FFT circuit 6 for each symbol.
It is an output buffer.

In the detection circuit 7, 46 and 47 are selectors, 48 is a complex division circuit, 49 is a DQPSK demapping circuit, 50 is a differential demodulation memory for storing the output of the DQPSK demapping circuit 49, and 51 is a slot management circuit.

In the detection circuit 7, in the differential detection, in the complex division circuit 48, the current symbol data output from the FFT circuit 6 is complexed with the previous symbol data stored in one of the FFT output buffers 44 and 45. It is done by dividing. Further, the synchronous detection is performed from the symbol data accumulated in the FFT output buffers 44 and 45 to the SP.
(Scattered Pilot) After extracting carriers, the SP carriers are interpolated to create virtual SP carriers for all data, and then the symbol data is read from the FFT output buffers 44 and 45 and divided by the virtual SP carrier. .

The slot management circuit 51 divides one symbol period into eight slots and manages wideband synchronization processing and detection processing in slot units. FIG. 10 is a diagram showing a conventional slot management system. In this example, slot 1 is assigned FFT output processing and differential demodulation processing,
Wideband synchronization processing and SP interpolation processing are assigned to slot 2, and synchronous detection processing is assigned to slot 3.
Detection output processing is assigned to slots 4 to 8.

Therefore, in slot 1, symbol data is output from the FFT circuit 6 and differential demodulation is performed,
The differential demodulated data is demapped by the DQPSK demapping circuit 49 and written in the differential demodulation memory 50, and the slot 2
Then, wideband synchronization error detection and SP extraction / interpolation are performed,
In slot 3, synchronous detection is performed using the SP signal,
In slots 4 to 8, each circuit is controlled so that the detection output to the FEC unit 2 is processed.

[0021]

In the conventional OFDM demodulation device, since the wide band synchronization processing is restricted within slot 2, the carrier capture range is ± 25 carriers, and in the case of mode 3, it is up to ± 25 kHz. Therefore, there is a problem that performance is not sufficient.

By the way, even for terrestrial digital audio broadcasting,
Similar to terrestrial digital television broadcasting, OFDM is adopted as a transmission technology, and it is a standard (ISDB- _TSB ) compatible with terrestrial digital television broadcasting. But,
As shown in FIG. 11, 13 segments are used for terrestrial digital television broadcasting, while 1 segment or 3 segments are used for terrestrial digital audio broadcasting. Therefore, the AC / TM which is a pilot signal necessary for wideband synchronization error detection.
There is a problem that the number of CC signals is small and a wideband synchronization error may not be detected.

In view of the above points, the present invention has an object to provide an OFDM demodulation method and apparatus capable of improving the performance of wideband synchronization processing.

[0024]

Means for Solving the Problems The present invention includes first, second, and
The third OFDM demodulation method and the first and second OFDM demodulation devices are included.

The first OFDM demodulation method of the present invention is 1
An OFDM demodulation method in which a symbol period is divided into a plurality of slots to perform wideband synchronization processing and detection processing by slot management, and two systems of slot management are provided: slot management for wideband synchronization processing and slot management for detection processing. Then, after the slot management for the wideband synchronization processing is completed, the processing shifts to the slot management for the detection processing.

According to the first OFDM demodulation method of the present invention, it is possible to allocate a plurality of slots to wideband synchronization processing during wideband synchronization processing, and to extend the carrier capture range in wideband synchronization error detection.

The second OFDM demodulation method of the present invention is to perform wideband synchronization error detection at the time of receiving a digital audio broadcast using differential demodulation data.

According to the second OFDM demodulation method of the present invention, wideband synchronization error detection at the time of receiving a digital audio broadcast can be performed using differential demodulation data having a larger number of bits than the data after demapping.

According to the third OFDM demodulation method of the present invention, when a digital audio broadcast is received, the wideband synchronization error detection as if the segments are synchronously modulated and the wideband synchronization error as if the segments are differentially modulated is performed. If the detection results are the same, the wideband synchronization error detection result as being differentially modulated is given priority, and if the detection results are different, the wideband synchronization error detection result as being synchronously modulated is given. It has priority.

According to the third OFDM demodulation method of the present invention, it is possible to efficiently detect a wide band synchronization error when receiving a digital audio broadcast.

The first OFDM demodulator of the present invention is
An OFDM demodulator including a slot management circuit that divides a symbol period into a plurality of slots and controls wideband synchronization processing and detection processing by slot management, wherein the slot management circuit includes slot management for wideband synchronization processing. There are two systems of slot management for detection processing, and slot management is performed so as to shift to slot management for detection processing after completion of slot management for broadband synchronization processing.

According to the first OFDM demodulator of the present invention, a plurality of slots can be assigned to the wide band synchronization process during the wide band synchronization process, and the carrier capture range in wide band synchronization error detection can be expanded.

The second OFDM demodulation device of the present invention is an OFDM demodulation device provided with a memory for storing data obtained by demapping differential demodulation data, and does not demap the differential demodulation data when receiving digital audio broadcasting. It is stored in the memory.

According to the second OFDM demodulation device of the present invention, the wide band synchronization error can be detected when the digital audio broadcast is received by using the differential demodulation data before demapping stored in the memory.

[0035]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a first OFDM of the present invention.
It is a figure for explaining one embodiment of a demodulation method. According to one embodiment of the first OFDM demodulation method of the present invention, one symbol period is divided into 8 slots, and slot management is performed for wideband synchronization processing (FIG. 1A) and detection processing (FIG. 1A). 1B), and after the slot management for wideband synchronization processing is completed, the process shifts to slot management for detection processing.

In this example, during wideband synchronization processing, FFT output processing and differential demodulation processing are assigned to slot 1, and wideband synchronization processing is assigned to slots 2 to 5. At the time of detection processing, slot 1 is assigned FFT output processing and differential demodulation processing, slot 2 is assigned SP interpolation processing, and slot 3 is assigned synchronous detection processing.
Detection output processing is assigned to slots 4 to 8. “NOP” is an abbreviation for “no operation”.

As described above, the first OFDM of the present invention
According to one embodiment of the demodulation method, the slot management is divided into two systems, that is, slot management for wideband synchronization processing and slot management for detection processing, and after the slot management for wideband synchronization processing is completed, For example, four slots from slot 2 to slot 5 are assigned to the wideband synchronization processing during the wideband synchronization processing. Therefore, the carrier capture range in the wideband synchronization processing is, for example, ± 100.
Can be extended to carriers. Therefore, the performance of wideband synchronization processing can be improved.

FIG. 2 is a circuit diagram showing a part of one embodiment of the second OFDM demodulation device of the present invention. One embodiment of the second OFDM demodulation device of the present invention is a conventional OFD.
A detection circuit 52 having a circuit configuration different from that of the detection circuit 7 shown in FIG. 9 included in the M demodulation device is provided, and the others are configured similarly to the conventional OFDM demodulation device.

The detection circuit 52 outputs to the differential demodulation memory 50 the output of the DQPSK demapping circuit 49 (3 bits of differential data per carrier) or the complex division circuit 48.
Output (12 bits of differential data per carrier) can be stored, and instead of the slot management circuit 51 shown in FIG. 9, an embodiment of the first OFDM demodulation method of the present invention is implemented. A slot management circuit 53 capable of performing slot management is provided, and the others are configured similarly to the detection circuit 7 shown in FIG. OFDM equipped with such a slot management circuit 53
The demodulation device is an embodiment of the first OFDM demodulation device of the present invention.

In one embodiment of the second OFDM demodulation device of the present invention, when receiving a digital television broadcast,
The output of the DQPSK demapping circuit 49 is stored in the differential demodulation memory 50 as in the conventional case, and the output of the complex division circuit 49 is stored in the differential demodulation memory 50 when receiving a digital audio broadcast.

FIG. 3 is a diagram for explaining the management method of the differential demodulation memory 50, in which the 3-bit differential data output from the DQPSK demapping circuit 49 is converted to the differential demodulation memory 5.
In the case of storing it in 0, each 3-bit differential data is written in one address, and in the case of storing the 12-bit differential data output from the complex division circuit 48 in the differential demodulation memory 50, Each 12-bit differential data is written in 4 addresses.

Therefore, in one embodiment of the second OFDM demodulation device of the present invention, the wideband synchronization error detection is performed by the output data (1 carrier) of the demapping circuit stored in the differential demodulation memory 50 at the time of receiving the digital television broadcast. 3 bits per differential data), and when the digital audio broadcast is received, the output of the complex division circuit 48 (12 bits differential data per carrier) stored in the differential demodulation memory 50 is used. Be seen. This is a main part of one embodiment of the second OFDM demodulation method of the present invention.

As described above, the second OFDM of the present invention
According to the demodulator, when the digital audio broadcast is received, the wideband synchronization error is detected by using the output data of the complex division circuit 48 stored in the differential demodulation memory 50.
Although there are only 1 segment or 3 segments as effective carriers, it is possible to improve the accuracy of wideband synchronization error detection at the time of receiving digital audio broadcasting and improve the performance of wideband synchronization processing at the time of receiving digital audio broadcasting.

Note that the size of the data stored in the differential demodulation memory 50 at the time of receiving digital audio broadcasting is four times that at the time of receiving digital television broadcasting, but the number of carriers is 1/13 to 3 / 13 does not exceed the capacity of the differential demodulation memory 50, and in this case, a memory for storing the output of the complex division circuit 48 is provided separately from the differential demodulation memory 50. There is also an advantage that it is not necessary to provide it.

FIG. 4 is a diagram for explaining one embodiment of the third OFDM demodulation method of the present invention. According to one embodiment of the third OFDM demodulation method of the present invention, at the time of receiving one segment of a digital audio broadcast, first, an AC / TMCC signal is detected as if the segment is synchronously modulated, and then the segment is When the AC / TMCC signal is detected as being differentially modulated, and when the AC / TMCC signal detection results are the same, the AC / TMCC signal detected as the differentially modulated segment is detected as the wideband synchronization error detection result. When the TMCC signal is prioritized and the AC / TMCC signal detection result is different, the AC / TMCC signal detected as the differentially modulated segment is prioritized as the wideband synchronization error detection result.

One embodiment of the third OFDM demodulation method of the present invention takes advantage of the feature that the carrier arrangement of AC / TMCC signals in the case of synchronous modulation is a subset in the case of differential modulation. According to the third embodiment of the OFDM demodulation method of the present invention, it is possible to efficiently perform wideband synchronization error detection at the time of receiving a digital audio broadcast and improve the performance of the wideband synchronization processing at the time of receiving the digital audio broadcast.

[0047]

INDUSTRIAL APPLICABILITY As described above, the first OFD of the present invention
According to the M demodulation method, a plurality of slots can be assigned to the wide band synchronization process during the wide band synchronization process, and the carrier capture range in wide band synchronization error detection can be expanded, so that the performance of the wide band synchronization process is improved. You can

According to the second OFDM demodulation method of the present invention, wide band synchronization error detection at the time of receiving a digital audio broadcast can be performed using differential demodulation data having a larger number of bits than the data after demapping. It is possible to improve the accuracy of wideband synchronization error detection at the time of receiving digital audio broadcasting and improve the performance of wideband synchronization processing at the time of receiving digital audio broadcasting.

According to the third OFDM demodulation method of the present invention, it is possible to efficiently detect the wideband synchronization error when receiving the digital audio broadcast and improve the performance of the wideband synchronization processing when receiving the digital audio broadcast.

According to the first OFDM demodulator of the present invention, a plurality of slots can be allocated to the wide band synchronization process during the wide band synchronization process, and the carrier capture range in wide band synchronization error detection can be expanded. It is possible to improve the performance of wideband synchronization processing.

According to the second OFDM demodulator of the present invention, since the differential demodulation data before demapping stored in the memory can be used to perform wideband synchronization error detection at the time of receiving a digital voice broadcast, It is possible to improve the accuracy of wideband synchronization error detection during broadcast reception and improve the performance of wideband synchronization processing during digital audio broadcast reception.

[Brief description of drawings]

FIG. 1 is a diagram for explaining an embodiment of a first OFDM demodulation method of the present invention.

FIG. 2 is a circuit diagram showing a part of a second OFDM demodulation device of the present invention.

FIG. 3 is a diagram for explaining a management method of a differential demodulation memory included in the detection circuit shown in FIG.

FIG. 4 is a diagram for explaining an embodiment of a third OFDM demodulation method of the present invention.

FIG. 5 is a circuit diagram showing a part of the configuration of an ISDB-T model receiver.

FIG. 6 is a diagram used to describe wideband synchronization processing.

FIG. 7 is a circuit diagram showing a conventional configuration example of a frequency / clock synchronization circuit included in an ISDB-T model receiver.

8 is a diagram for explaining operations of a delay circuit and a correlation circuit included in the frequency / clock synchronization circuit shown in FIG.

FIG. 9 is a circuit diagram showing a part of a conventional configuration example of an FFT circuit and a detection circuit included in the ISDB-T model receiver.

FIG. 10 is a diagram showing a conventional slot management system.

FIG. 11 is a diagram showing a segment structure of a digital television broadcast and a segment structure of a digital audio broadcast.

[Explanation of symbols]

1 ... Differential demodulation / synchronization demodulation unit (differential detection / synchronization detection unit) 2, 3 ... FEC section

Claims (5)

[Claims] 1. An OFDM demodulation method in which one symbol period is divided into a plurality of slots to perform wideband synchronization processing and detection processing by slot management, wherein slot management is for slot management and detection processing for wideband synchronization processing. The OFDM demodulation method is characterized in that there are two systems of slot management, and after the slot management for wideband synchronization processing is completed, the slot management for detection processing is performed. 2. An OFDM demodulation method characterized in that wide band synchronization error detection at the time of receiving a digital audio broadcast is performed using differential demodulation data. 3. When receiving a digital audio broadcast, wide-band synchronization error detection as if the segment is synchronously modulated and wide-band synchronization error detection as if the segment is differentially modulated are performed, and if the detection results are the same, , OFDM demodulation characterized by giving priority to the wideband synchronization error detection result as being differentially modulated, and giving priority to the wideband synchronization error detection result as being synchronously modulated if the detection results are different Method. 4. An OFDM demodulator provided with a slot management circuit that divides one symbol period into a plurality of slots to control wideband synchronization processing and detection processing by slot management, wherein the slot management circuit has wideband slot management. There are two systems: slot management for synchronization processing and slot management for detection processing, and slot management is performed so as to shift to slot management for detection processing after completion of slot management for wideband synchronization processing. An OFDM demodulator characterized by: 5. An OFDM demodulator provided with a memory for storing data obtained by demapping differential demodulation data, wherein the differential demodulation data is stored in the memory without being demapped when a digital audio broadcast is received. OF of
DM demodulator.