JP4149328B2 - OFDM signal carrier data equalizer and OFDM signal receiving apparatus - Google Patents

Description

  The present invention relates to a carrier data equalizer for an OFDM signal suitable for use in the receiving apparatus when the state of the received signal fluctuates at a high speed in mobile reception of the OFDM signal, and an OFDM signal receiving apparatus .

In the ISDB-T transmission system, which is a transmission system for terrestrial digital television, there are several thousand OFDM signal carriers in one symbol, and once every 3 carriers in the carrier direction to indicate the QAM reference phase and reference level. In the symbol direction, a scattered pilot (SP) signal is inserted at a rate of once every four symbols (see FIGS. 3 and 4). The OFDM signal receiving apparatus extracts the past four symbols of the SP signal and calculates a frequency response H (i, k) (where i is a symbol number, k is a carrier number, and so on) from this. Thus, equalization (phase and level) of carrier data of the OFDM signal is performed.
JP 2002-344411 A JP 2002-344410 A Japanese Patent Laid-Open No. 2002-026865 JP 2002-026861 A JP 2001-316628 A JP 2001-313627 A JP 2001-292122 A

  In the above conventional method, the SP signal used to calculate the frequency response H (i, k) of the transmission path is received up to 3 symbols before the current OFDM signal carrier data. It has become. However, in a high-speed mobile reception environment, the received signal varies greatly in time due to the influence of Doppler shift, so the signal level may be significantly different between the SP signal three symbols before and the SP signal of the latest symbol. There was a limit to the accuracy of equalization. This becomes a problem particularly in the case of multipath with a short delay time.

  In order to solve this problem, if the carrier data is equalized by using only the SP signal of the latest symbol (the one inserted in symbol number n in FIG. 4), the time variation of the received signal is reduced. On the other hand, it is possible to perform equalization with higher accuracy. However, in this case, since the SP signal exists only once per 12 carriers, it is not possible to detect a multipath with a long delay time, and therefore equalization with respect to a multipath with a long delay time. Will not be able to.

  It is an object of the present invention to perform equalization of a received signal for both a short delay time multipath and a long delay time multipath, and is particularly accurate for a short delay time multipath. It is an object of the present invention to provide an OFDM signal carrier data equalizer and an OFDM signal receiver capable of performing high equalization.

In order to achieve the above object, a carrier data equalizer of an OFDM signal according to the present invention estimates a frequency response of a transmission line using a scattered pilot signal extracted from the carrier data of the OFDM signal, and the estimated transmission line An OFDM signal carrier data equalizer configured to output OFDM signal carrier data equalized by dividing the OFDM signal carrier data by a frequency response of:
Estimate the frequency response of the transmission line up to the upper limit of the time zone in which the multipath delay time can be detected using the latest scattered pilot signal for one symbol, and the multipath delay time in the detectable time zone. When the upper limit is exceeded, there is provided means for estimating the frequency response of the transmission path by using a scattered pilot signal for a plurality of past symbols including the latest one symbol.

The carrier signal equalizer of the OFDM signal according to the present invention is a means for extracting a scattered pilot signal from the carrier data of the OFDM signal, and an IFFT for calculating an impulse response of the transmission line using the extracted scattered pilot signal. Circuit, an FFT circuit for estimating a frequency response of the transmission path from the calculated impulse response of the transmission path, and an OFDM signal carrier equalized by dividing the carrier data of the OFDM signal by the estimated frequency response of the transmission path In a carrier data equalizer for OFDM signals comprising a divider circuit for outputting data, the equalizer comprises:
The extracting means extracts first and second extracted pilot signals for the past four symbols including the latest one symbol, and scattered pilot signals for only the latest one symbol, respectively. The IFFT circuit calculates first and second impulse responses using the scattered pilot signals extracted from the first and second extracting means, respectively. And the second impulse response is used on the input side of the FFT circuit in a time zone in which a multipath delay time can be detected by the scattered pilot signal of only the latest one symbol. Then, the scattered pilot signal for the past four symbols including the latest one symbol from the upper limit of the time zone is used as a marker. Up to the limit of the detectable hours delay time is-path is characterized in that it comprises a combining circuit that uses the first impulse response.

The OFDM signal receiving apparatus of the present invention also includes means for extracting a scattered pilot signal from carrier data of the OFDM signal, an IFFT circuit for calculating an impulse response of the transmission line using the extracted scattered pilot signal, and the calculation An FFT circuit that estimates the frequency response of the transmission path from the impulse response of the transmission path, and outputs the carrier signal of the OFDM signal equalized by dividing the carrier data of the OFDM signal by the frequency response of the estimated transmission path In an OFDM signal carrier data equalizer comprising a division circuit, the extracting means includes a scattered pilot signal for the past four symbols including the latest one symbol and a scatter for only the latest one symbol. Comprising first and second means for extracting the tard pilot signal, respectively. From the first and second IFFT circuits, the IFFT circuits calculate first and second impulse responses, respectively, using the scattered pilot signals extracted from the first and second extracting means, respectively. And the second impulse response is used on the input side of the FFT circuit in a time zone in which a multipath delay time can be detected by the scattered pilot signal of only the latest one symbol, and the time A synthesis circuit that uses the first impulse response from the upper limit of the band up to the upper limit of the time period in which the multipath delay time can be detected by the scattered pilot signals for the past four symbols including the latest one symbol Which has
A demapping circuit for decoding data is provided in the subsequent stage of the carrier data equalizer of the OFDM signal.

  According to the present invention, in mobile reception of an OFDM signal, particularly in the case of multipath with a short delay time, high-precision equalization can be performed even if the received signal fluctuates greatly in time, For multipath with a long delay time, the same equalization as before can be performed.

  As described above, the present invention is based on the SP signal for the past 4 symbols including the latest one symbol for the long delay time multipath, and the latest for the short delay time multipath. The frequency response of the transmission path is calculated from the SP signal for only one symbol, and based on the calculation result, particularly in the case of multipath with a short delay time, high-precision equalization is performed for time fluctuations at high speed. And an OFDM signal receiving apparatus.

Further, the present invention is generally constructed by making good use of the property that a multipath with a short delay time fluctuates quickly in time and a multipath with a long delay time has a relatively gentle fluctuation.
Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of an embodiment of a carrier data equalizer for OFDM signals according to the present invention.
In FIG. 1, 1 is an FFT unit, 2 is a transmission frequency response estimation (Quadrature mirrorfilter: QMF) unit, 3 is a division circuit, 4 is an SP signal extraction circuit, 5-1, 5-2 are IFFT circuits, 6-1 , 6-2 are low-pass filters (LPF), 7 is a synthesis circuit, and 8 is an FFT circuit.

The operation will be described.
In FIG. 1, an FFT unit 1 performs fast Fourier transform (FFT) on a digital complex baseband signal that is an input signal for each symbol, outputs carrier data Y (i, k) of an OFDM signal, and transmits it with a divider circuit 3. The signal is supplied to the SP signal extraction circuit 4 of the road frequency response estimation (QMF) unit 2.

  As shown in FIG. 3, the SP signal extraction circuit 4 uses the symbol number n to the symbol number n of the carrier data Y (i, k) of the OFDM signal (where i is a symbol number, k is a carrier number, and so on). -3 including the latest one symbol up to -3, the scattered pilot signals SP (n, 0), SP (n-1, 0), SP (n-2, 0), SP (n -3, 0), SP (n, 1),..., SP (n-3, 2) are extracted (the extracted pilot signals are indicated by white circles) and supplied to the IFFT circuit 5-1. Further, as shown in FIG. 4, the same SP signal extraction circuit 4 performs the scattered pilot signal SP (n, n, which is only the latest one symbol indicated by the symbol number n from the carrier data Y (i, k) of the OFDM signal. 0), SP (n, 1), SP (n, 2) are extracted (the extracted pilot signal is indicated by a white circle) and supplied to the IFFT circuit 5-2.

In the IFFT circuit 5-1, the scattered pilot signals for the past four symbols including the latest one symbol are subjected to inverse fast Fourier transform (IFFT), and the impulse response h ₁ (i, t) of the transmission path (here) I is a symbol number, t is a delay time, and so on. The IFFT circuit 5-2 calculates the impulse response h ₂ (i, t) of the transmission line by performing inverse fast Fourier transform (IFFT) on the latest scattered pilot signal for one symbol. The calculated impulse responses h ₁ (i, t) and h ₂ (i, t) of the transmission line are supplied to low-pass filters (LPF) 6-1 and 6-2, respectively.

The LPFs 6-1 and 6-2 are impulse responses h ′ ₁ obtained by removing high frequency components of a predetermined frequency or more from the calculated impulse responses h ₁ (i, t), h ₂ (i, t) of the transmission line. (i, t), h ' 2 (i, t) to generate respective synthesized and supplies to the synthesizing circuit 7. In the synthesis, as shown in FIG. 2, the impulse response h ′ ₂ (i, t) is used in the time zone in which the multipath delay time can be detected by the latest scattered pilot signal for one symbol. From the upper limit of the time zone (indicated by T ′) to the upper limit of the time zone in which the multipath delay time can be detected by the scattered pilot signals for the past 4 symbols including the latest one symbol (indicated by T) Is switched and synthesized in the time domain so as to use the synthesized impulse response h ′ ₁ (i, t).

That is, 0 'in the time period of the impulse response h' T from ₂ (i, t) is also, 'T from (However, T' T <T) impulse response h _'1 (i in time zone, The synthesis is performed so that t) is output from the synthesis circuit 7. Therefore, if the impulse response of the output of the synthesis circuit 7 is h ₃ (i, t), h ₃ (i, t) is expressed by the following equation (1).
h ₃ (i, t) = h ′ ₂ (i, t) (0 ≦ t ≦ T ′)
= H ' ₁ (i, t) (T ′ <t ≦ T) (1)

The impulse response h ₃ (i, t) of the transmission path, which is the output of the synthesis circuit 7, is supplied to the FFT circuit 8 and fast Fourier transformed (FFT) to estimate the frequency response H (i, k) of the transmission path. The estimated frequency response H (i, k) of the transmission path is supplied to the dividing circuit 3 and is next to the carrier data Y (i, k) of the OFDM signal directly supplied from the FFT circuit 1 to the dividing circuit 3. (2) is divided and the equalized carrier signal Y ′ (i, k) of the OFDM signal is output.
Y ′ (i, k) = Y (i, k) / H (i, k) (2)

Other examples

  The present invention is not limited to the embodiment described above, and the SP signal output from the SP signal extraction circuit 4 and supplied to the IFFT circuit 5-1 includes the latest one symbol and the past four symbols. The SP signal is not limited to the SP signal, and may be the SP signal for the past X (X is an even number of 4 or less) symbols including the latest one symbol. Further, in the first embodiment shown in FIG. 1, the SP signal extraction circuit 4 outputs the SP signals for the past four symbols and the latest one symbol including the latest one symbol to the IFFT circuits 5-1 and 5-2. In addition, in order to obtain the frequency response of the transmission line in three time zones according to the multipath delay time, another system comprising an IFFT circuit and a low-pass filter is added. In addition, SP signals for the past two symbols including the latest one symbol may be supplied.

  Note that the present invention includes not only the equalizer according to the present invention described above but also an OFDM signal receiving apparatus, and the OFDM signal receiving apparatus is connected to the downstream of the equalizer according to the present invention in accordance with the QAM scheme. A well-known demapping circuit (not shown) for mapping and decoding data is provided.

  The present invention may be widely used when multipath interference becomes a problem in mobile reception of various OFDM signals, including ISDB-T mobile reception.

It is a block diagram of one Example of the carrier data equalizer of this invention OFDM signal. The impulse response _{h '1 (i, t)} , h' is a diagram showing how the synthesis of ₂ (i, t). It is a figure which shows extraction of the scattered pilot signal for the past 4 symbols from the carrier data Y (i, k) of the OFDM signal. It is a figure which shows extraction of the scattered pilot signal for the newest 1 symbol from the carrier data Y (i, k) of the OFDM signal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 FFT part 2 Transmission line frequency response estimation (QMF) part 3 Division circuit 4 SP signal extraction circuit 5-1 and 5-2 IFFT circuit 6-1 and 6-2 Low-pass filter (LPF)
7 Synthesis circuit 8 FFT circuit

Claims (3)

OFDM equalized by estimating the frequency response of the transmission path using the scattered pilot signal extracted from the carrier data of the OFDM signal and dividing the carrier data of the OFDM signal by the estimated frequency response of the transmission path In an OFDM signal carrier data equalizer configured to output signal carrier data,
Estimate the frequency response of the transmission line up to the upper limit of the time zone in which the multipath delay time can be detected using the latest scattered pilot signal for one symbol, and the multipath delay time in the detectable time zone. OFDM signal carrier data or the like comprising means for estimating the frequency response of the transmission path using a scattered pilot signal for a plurality of past symbols including the latest one symbol when the upper limit is exceeded Generator. Means for extracting a scattered pilot signal from carrier data of an OFDM signal;
An IFFT circuit for calculating an impulse response of a transmission line using the extracted scattered pilot signal;
An FFT circuit that estimates a frequency response of the transmission path from the calculated impulse response of the transmission path, and a carrier data of the OFDM signal that is equalized by dividing the carrier data of the OFDM signal by the frequency response of the estimated transmission path In an OFDM signal carrier data equalizer comprising a divider circuit to output, the equalizer comprises:
The extracting means extracts first and second extracted pilot signals for the past four symbols including the latest one symbol, and scattered pilot signals for only the latest one symbol, respectively. Consisting of means,
From the first and second IFFT circuits, the IFFT circuits calculate first and second impulse responses, respectively, using the scattered pilot signals extracted from the first and second extracting means, respectively. And at the input side of the FFT circuit, the second impulse response is used in a time zone in which a multipath delay time can be detected by the scattered pilot signal of only the latest one symbol, and the time A synthesis circuit that uses the first impulse response from the upper limit of the band up to the upper limit of the time period in which the multipath delay time can be detected by the scattered pilot signals for the past four symbols including the latest one symbol An OFDM signal carrier data equalizer characterized by comprising: Means for extracting a scattered pilot signal from carrier data of an OFDM signal;
An IFFT circuit for calculating an impulse response of a transmission line using the extracted scattered pilot signal;
An FFT circuit that estimates a frequency response of the transmission path from the calculated impulse response of the transmission path, and a carrier data of the OFDM signal that is equalized by dividing the carrier data of the OFDM signal by the frequency response of the estimated transmission path In an OFDM signal carrier data equalizer having a divider circuit for output,
The extracting means extracts first and second extracted pilot signals for the past four symbols including the latest one symbol, and scattered pilot signals for only the latest one symbol, respectively. Consisting of means,
From the first and second IFFT circuits, the IFFT circuits calculate first and second impulse responses, respectively, using the scattered pilot signals extracted from the first and second extracting means, respectively. And at the input side of the FFT circuit, the second impulse response is used in a time zone in which a multipath delay time can be detected by the scattered pilot signal of only the latest one symbol, and the time A synthesis circuit that uses the first impulse response from the upper limit of the band up to the upper limit of the time period in which the multipath delay time can be detected by the scattered pilot signals for the past four symbols including the latest one symbol And after the carrier data equalizer of the OFDM signal,
An OFDM signal receiving apparatus comprising a demapping circuit for decoding data.

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