JP2000049747A5 - - Google Patents

Description

[Claims]
[Claim 1] An OFDM demodulator that receives an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
A phase error detecting means for detecting a phase difference between the plurality of pilot carriers and a known pilot carrier, and
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase difference,
A phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change is provided.OFDM demodulator.
2. The OFDM demodulator
A subcarrier separating means for separating the plurality of OFDM symbols into the plurality of subcarriers, respectively.
Further provided with a pilot carrier position detecting means for detecting the positions of the plurality of pilot carriers from the plurality of subcarriers.The OFDM demodulator according to claim 1.
3. The subcarrier separating means is a Fourier transform means for Fourier transforming the OFDM symbol.The OFDM demodulator according to claim 2.
4. The phase change amount calculation means calculates the phase change amount of data carriers between adjacent sets of pilot carriers.The OFDM demodulator according to claim 1.
5. The OFDM demodulator
Claim 1 further provided with a data demodulation means for demodulating the phase-corrected data carrier.The OFDM demodulator described.
6. Claim 1 in which the OFDM signal is input in a burst form.The OFDM demodulator described.
7. An OFDM demodulation method that demodulates an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
The step of detecting the phase difference between the plurality of pilot carriers and the known pilot carriers, and
A step of calculating the amount of phase change of the plurality of data carriers based on the phase difference, and
A step of correcting the phases of the plurality of data carriers based on the amount of phase change, and
An OFDM demodulation method comprising a step of demodulating a plurality of phase-corrected data carriers.
8. An OFDM transmission system that transmits and receives OFDM signals containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
It is equipped with an OFDM transmitter and an OFDM receiver.
The OFDM transmitter is
A modulation means that assigns a known pilot carrier to a plurality of predetermined subcarriers among the plurality of subcarriers and modulates the plurality of data carriers with transmission data.
An OFDM signal generation means for generating an OFDM symbol from the plurality of subcarriers,
The OFDM receiver is
A phase error detecting means for detecting a phase difference between the plurality of pilot carriers and a known pilot carrier, and
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase difference,
An OFDM transmission system including a phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change.
9. An OFDM demodulator that receives an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
A phase detection means for detecting the phase of each of the plurality of pilot carriers,
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase of the pilot carrier, and
A phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change is provided.OFDM demodulator.
10. The OFDM demodulator
A subcarrier separating means for separating the plurality of OFDM symbols into the plurality of subcarriers, respectively.
9. Claim 9 further comprising a pilot carrier position detecting means for detecting the positions of the plurality of pilot carriers from the plurality of subcarriers.The OFDM demodulator described.
11. 10. The subcarrier separating means is a Fourier transform means for Fourier transforming the OFDM symbol.The OFDM demodulator described.
12. 9. The phase change amount calculation means calculates the phase change amount of data carriers between adjacent sets of pilot carriers.The OFDM demodulator described.
13. The OFDM demodulator
9. Claim 9 further provided with a data demodulation means for demodulating the phase-corrected data carrier.The OFDM demodulator described.
14. 9. The OFDM signal is input in a burst form.The OFDM demodulator described.
15. An OFDM demodulation method that demodulates an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
A step of detecting the phase of each of the plurality of pilot carriers, and
A step of calculating the amount of phase change of the plurality of data carriers based on the phase of the pilot carrier, and
A step of correcting the phases of the plurality of data carriers based on the amount of phase change, and
An OFDM demodulation method including a step of differentially demodulating a plurality of phase-corrected data carriers.
16. An OFDM transmission system that transmits and receives OFDM signals containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
It is equipped with an OFDM transmitter and an OFDM receiver.
The OFDM transmitter is
A modulation means that assigns a known pilot carrier to a plurality of predetermined subcarriers among the plurality of subcarriers and differentially modulates the plurality of data carriers based on the transmission data with respect to the pilot carrier.
An OFDM signal generation means for generating an OFDM symbol from the plurality of subcarriers,
The OFDM receiver is
A phase detection means for detecting the phase of each of the plurality of pilot carriers,
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase of the pilot carrier, and
An OFDM transmission system including a phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change.
17. An OFDM demodulator that receives an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of pilot carriers and a plurality of data carriers.
A subcarrier separating means for separating the plurality of OFDM symbols into the plurality of subcarriers, respectively.
With respect to the plurality of separated subcarriers, a phase correction means for correcting the phase of the plurality of data carriers based on the phase of the pilot carrier, and
A demodulation means for demodulating the data carrier after the phase correction is provided.OFDM demodulator.
18. A known complex number is assigned to each of the plurality of pilot carriers.
Claim 17 that the phase correction means corrects the phase of the plurality of data carriers with a value obtained by linearly interpolating the phase difference between the plurality of pilot carriers and a known complex number in the frequency direction.The OFDM demodulator described.
19. The plurality of pilot carriers are assigned the same phase.
The plurality of data carriers are differentially modulated by transmission data with reference to the pilot carrier.
The phase correction means corrects the phases of the plurality of data carriers with a value obtained by linearly interpolating the phase difference between the plurality of pilot carriers in the frequency direction.
17. The demodulation means differentially demodulates the phase-corrected data carrier.The OFDM demodulator described.
20. An OFDM demodulation method that demodulates an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of pilot carriers and a plurality of data carriers.
A subcarrier separation step that separates the plurality of OFDM symbols into the plurality of subcarriers, respectively.
A phase correction step of correcting the phases of the plurality of data carriers based on the phases of the pilot carriers with respect to the plurality of separated subcarriers.
An OFDM demodulation method including a demodulation step for demodulating the data carrier after the phase correction.

The OFDM demodulation is performed by performing a Fourier transform process on the OFDM signal down-converted to the baseband band by the orthogonal detector using a fast Fourier transform (hereinafter referred to as “FFT”) circuit. At this time, in the orthogonal detector , it is necessary to establish accurate frequency synchronization between transmission and reception, and in FFT, one symbol section from the received OFDM signal is accurately captured by a specified clock and Fourier transformed to perform each subcarrier. It is necessary to obtain the phase and amplitude information of.

Conventional OFDM demodulator DMC is the OFDM signal Sb which is down-converted to baseband by the quadrature detector 103 performs a Fourier transform operation using fast Fourier transform (FFT) unit 105. In this case, it is necessary to correct frequency synchronization establishment between transmission and reception in the quadrature detector 103, also a one symbol period from the received OFDM signal in FFT accurately capture a defined clock, each subcarrier by Fourier transform Obtain the phase and amplitude information of.

The first invention is an OFDM demodulator that receives an OFDM signal including a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
A phase error detecting means for detecting a phase difference between the plurality of pilot carriers and a known pilot carrier, and
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase difference,
It is provided with a phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change.

According to the first invention as described above, the phase difference between transmission and reception of the pilot carrier is detected, the amount of change in the amount of phase rotation between transmission and reception with respect to the carrier frequency is calculated based on this phase difference, and based on this amount of change. Since the phase correction amount of each subcarrier is calculated, this phase correction amount corresponds to the absolute phase error (phase error between transmission and reception) of each subcarrier. Therefore, even for an OFDM signal in which absolute phase modulation such as QPSK or QAM modulation is performed on the subcarriers, the phase error of each subcarrier can be corrected and demodulated correctly.

The second invention is the first invention.
The OFDM demodulator
A subcarrier separating means for separating the plurality of OFDM symbols into the plurality of subcarriers, respectively.
Further, the pilot carrier position detecting means for detecting the positions of the plurality of pilot carriers from the plurality of subcarriers is provided.

The third invention is the second invention.
The subcarrier separating means is a Fourier transform means for Fourier transforming the OFDM symbol.

The fourth invention is the first invention.
The phase change amount calculation means calculates the phase change amount of data carriers between adjacent sets of pilot carriers.

The fifth invention is the first invention.
The OFDM demodulator
Further, a data demodulation means for demodulating the data carrier after the phase correction is provided.

The sixth invention is the first invention.
The OFDM signal is input in a burst form.

The seventh invention is
An OFDM demodulation method that demodulates an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
The step of detecting the phase difference between the plurality of pilot carriers and the known pilot carriers, and
A step of calculating the amount of phase change of the plurality of data carriers based on the phase difference, and
A step of correcting the phases of the plurality of data carriers based on the amount of phase change, and
It includes a step of demodulating a plurality of phase-corrected data carriers.

The eighth invention is
An OFDM transmission system that transmits and receives OFDM signals containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
It is equipped with an OFDM transmitter and an OFDM receiver.
The OFDM transmitter is
A modulation means that assigns a known pilot carrier to a plurality of predetermined subcarriers among the plurality of subcarriers and modulates the plurality of data carriers with transmission data.
An OFDM signal generation means for generating an OFDM symbol from the plurality of subcarriers,
The OFDM receiver is
A phase error detecting means for detecting a phase difference between the plurality of pilot carriers and a known pilot carrier, and
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase difference,
It is provided with a phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change.

The ninth invention is
An OFDM demodulator that receives an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
A phase detection means for detecting the phase of each of the plurality of pilot carriers,
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase of the pilot carrier, and
It is provided with a phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change.

According to the ninth invention as described above, the phase correction amount between the subcarriers is obtained based on the phase of the received pilot carrier, and the phase difference between the transmission and reception of the pilot carrier is not obtained. Therefore, for an OFDM signal in which differential modulation is performed in the frequency direction with respect to the subcarriers, the error of the phase difference between the subcarriers can be corrected and demodulated correctly with a simple configuration.

The tenth invention is the ninth invention.
The OFDM demodulator
A subcarrier separating means for separating the plurality of OFDM symbols into the plurality of subcarriers, respectively.
Further, the pilot carrier position detecting means for detecting the positions of the plurality of pilot carriers from the plurality of subcarriers is provided.

The eleventh invention is the tenth invention.
The subcarrier separating means is a Fourier transform means for Fourier transforming the OFDM symbol.

The twelfth invention is the ninth invention.
The phase change amount calculation means calculates the phase change amount of data carriers between adjacent sets of pilot carriers.

The thirteenth invention is the ninth invention.
The OFDM demodulator
Further, a data demodulation means for demodulating the data carrier after the phase correction is provided.

The fourteenth invention is the ninth invention.
The OFDM signal is input in a burst form.

The fifteenth invention is
An OFDM demodulation method that demodulates an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
A step of detecting the phase of each of the plurality of pilot carriers, and
A step of calculating the amount of phase change of the plurality of data carriers based on the phase of the pilot carrier, and
A step of correcting the phases of the plurality of data carriers based on the amount of phase change, and
It includes a step of differentially demodulating a plurality of phase-corrected data carriers.

The sixteenth invention is
An OFDM transmission system that transmits and receives OFDM signals containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of data carriers and a plurality of pilot carriers.
It is equipped with an OFDM transmitter and an OFDM receiver.
The OFDM transmitter is
A modulation means that assigns a known pilot carrier to a plurality of predetermined subcarriers among the plurality of subcarriers and differentially modulates the plurality of data carriers based on the transmission data with respect to the pilot carrier.
An OFDM signal generation means for generating an OFDM symbol from the plurality of subcarriers,
The OFDM receiver is
A phase detection means for detecting the phase of each of the plurality of pilot carriers,
A phase change amount calculating means for calculating the phase change amount of the plurality of data carriers based on the phase of the pilot carrier, and
It is provided with a phase correction means for correcting the phases of the plurality of data carriers based on the amount of phase change.

According to the 16th invention as described above, the phase correction amount of the subcarrier of the Fourier-transformed OFDM signal is obtained based on the pilot carrier having the reference phase assigned to the predetermined subcarrier, and the phase correction thereof. Since the phase error due to the synchronization shift is quickly corrected based on the quantity, even when a plurality of OFDM symbols are transmitted in a burst, each OFDM symbol can be demodulated correctly.

The seventeenth invention is
An OFDM demodulator that receives an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of pilot carriers and a plurality of data carriers.
A subcarrier separating means for separating the plurality of OFDM symbols into the plurality of subcarriers, respectively.
With respect to the plurality of separated subcarriers, a phase correction means for correcting the phase of the plurality of data carriers based on the phase of the pilot carrier, and
It is provided with a demodulation means for demodulating the data carrier after the phase correction.

The eighteenth invention is the seventeenth invention.
A known complex number is assigned to each of the plurality of pilot carriers.
The phase correction means corrects the phases of the plurality of data carriers with a value obtained by linearly interpolating the phase difference between the plurality of pilot carriers and known complex numbers in the frequency direction.

The nineteenth invention is the seventeenth invention.
The plurality of pilot carriers are assigned the same phase.
The plurality of data carriers are differentially modulated by transmission data with reference to the pilot carrier.
The phase correction means corrects the phases of the plurality of data carriers with a value obtained by linearly interpolating the phase difference between the plurality of pilot carriers in the frequency direction.
The demodulation means differentially demodulates the phase-corrected data carrier.

The twentieth invention is
An OFDM demodulation method that demodulates an OFDM signal containing a plurality of OFDM symbols generated from a plurality of subcarriers including a plurality of pilot carriers and a plurality of data carriers.
A subcarrier separation step that separates the plurality of OFDM symbols into the plurality of subcarriers, respectively.
A phase correction step of correcting the phases of the plurality of data carriers based on the phases of the pilot carriers with respect to the plurality of separated subcarriers.
The demodulation step of demodulating the data carrier after the phase correction is included.

The pilot carrier position detector 8a detects the position of the pilot carrier PC in the subcarrier Sc'and generates a pilot carrier position signal Lpc based on the order assigned on the transmitting side to generate the pilot carrier position signal Lpc, and the pilot carrier extractor 8b and the pilot. Output to the carrier memory 8c. However, the method of detecting the position of the pilot carrier based on the order assigned to the subcarriers on the transmitting side is the data in the subcarrier SC which is the output of the FFT circuit 5 when the frequency offset of the OFDM signal becomes equal to or larger than the carrier interval. Since the position of the carrier shifts, the position of the pilot carrier PC cannot be detected correctly. In such a case, the pilot carrier PC and the data carrier DC may be modulated at different power levels on the transmitting side, and the position of the pilot carrier PC may be detected based on the modulated power level.

The phase difference calculator 8d is a transmission held in the reception pilot carrier PC (R) extracted by the pilot carrier extraction circuit 8b and the pilot carrier memory 8c based on the reception pilot carrier signal Rpc and the transmission pilot carrier signal Spc. The pilot carrier PCs (S) are compared, and the phase difference PD is obtained. The phase difference PD takes the complex number A assigned to the receiving pilot carrier and the complex number B assigned to the transmitting pilot carrier as inputs, multiplies the complex number A and the conjugate complex number of the complex number B, and obtains the complex number C = (i). , Q) can be calculated by calculating the inverse tangent arctan (q / i).