WO2000060761A1 - Dispositif et procede d'estimation de voie, dispositif et procede de demodulation, et dispositif et procede pour definir la frequence des evanouissements - Google Patents
Dispositif et procede d'estimation de voie, dispositif et procede de demodulation, et dispositif et procede pour definir la frequence des evanouissements Download PDFInfo
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- WO2000060761A1 WO2000060761A1 PCT/JP2000/002105 JP0002105W WO0060761A1 WO 2000060761 A1 WO2000060761 A1 WO 2000060761A1 JP 0002105 W JP0002105 W JP 0002105W WO 0060761 A1 WO0060761 A1 WO 0060761A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/0202—Channel estimation
- H04L25/0224—Channel estimation using sounding signals
- H04L25/0228—Channel estimation using sounding signals with direct estimation from sounding signals
- H04L25/023—Channel estimation using sounding signals with direct estimation from sounding signals with extension to other symbols
- H04L25/0232—Channel estimation using sounding signals with direct estimation from sounding signals with extension to other symbols by interpolation between sounding signals
- H04L25/0234—Channel estimation using sounding signals with direct estimation from sounding signals with extension to other symbols by interpolation between sounding signals by non-linear interpolation
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/69—Spread spectrum techniques
- H04B1/707—Spread spectrum techniques using direct sequence modulation
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
- H04B1/69—Spread spectrum techniques
- H04B1/707—Spread spectrum techniques using direct sequence modulation
- H04B1/7097—Interference-related aspects
- H04B1/711—Interference-related aspects the interference being multi-path interference
- H04B1/7115—Constructive combining of multi-path signals, i.e. RAKE receivers
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/0202—Channel estimation
- H04L25/0224—Channel estimation using sounding signals
- H04L25/0228—Channel estimation using sounding signals with direct estimation from sounding signals
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B2201/00—Indexing scheme relating to details of transmission systems not covered by a single group of H04B3/00 - H04B13/00
- H04B2201/69—Orthogonal indexing scheme relating to spread spectrum techniques in general
- H04B2201/707—Orthogonal indexing scheme relating to spread spectrum techniques in general relating to direct sequence modulation
- H04B2201/70701—Orthogonal indexing scheme relating to spread spectrum techniques in general relating to direct sequence modulation featuring pilot assisted reception
Definitions
- TECHNICAL FIELD A channel estimation device and method, a demodulation device and method, and a fading frequency determination device and method
- the present invention relates to a channel estimation device and method, a demodulation device and method, and a fading frequency determination device and method. More specifically, the present invention relates to a channel estimation device, a demodulation device, and the like applicable to a mobile communication system that performs voice and data transmission in a high-speed fading environment. The present invention also relates to a demodulation apparatus and a demodulation method conforming to the CDMA system, which spread a wideband signal with a high-speed spreading code equal to or higher than an information rate and perform multiple access.
- amplitude and phase fluctuations occur due to Rayleigh fading due to the movement of the relative position between the mobile station and the base station.
- a phase modulation method for transmitting information at a carrier phase a method of identifying and determining information data by differentially encoding the information and placing the information on the relative phase of the preceding and succeeding symbols and performing delay detection on the receiving side is common. It was a target. However, in this differential detection, since the transmission data is differentially encoded as described above, a 1-bit error in the radio section becomes a 2-bit error in the information data.
- the reception error rate is degraded by 3 dB for the same signal power to 1000 * noise power ratio (SNIR) as compared to the synchronous detection.
- SNIR noise power ratio
- the absolute synchronous detection which determines the phase of the received signal by the absolute phase for each symbol, has a highly efficient receiving characteristic, it is difficult to determine the absolute phase of the received signal in a ray-leaf aging environment.
- pilot symbols are inserted between data symbols, and channel estimation of data symbols is performed using the pilot symbols.
- pilot symbol insertion method for example, there is a method (time multiplexing method) of time-multiplexing a data symbol and a pit symbol on one channel (FIG. 16).
- References 1 to 3 below propose channel estimation methods using this time multiplexing method.
- Reference 1 (Transactions of the Institute of Electronics, Information and Communication Engineers, V o 1. J 72 -B-11, No. 1, pp. 7—15, 1989 January, Sanbe "Land mobile communications 16 Q AM fading distortion compensation ”) proposes a method for estimating and compensating for the above problem by estimating fading distortion using pilot symbols with a known phase inserted at regular intervals between data symbols (information symbols). Have been.
- this method one pilot symbol with a known transmission phase is inserted into the communication channel for each symbol of the number of data symbols, and the transmission path is estimated based on the reception phase of the pilot symbol. It measures the amplitude and phase of the received signal of each path of each communicator at the pilot symbol before and after the corresponding data symbol section, and interpolates the measured values to estimate the transmission path fluctuation in the data symbol section. , Compensate.
- Reference 2 (IEICE technical report RCS 97-74, RAKE reception using multislot weighted averaging channel estimation method for pilot symbols in DS-CDMA) uses more pilot symbols.
- a method of performing more accurate channel estimation by performing channel estimation using a pilot symbol inserted between data symbols at a constant period.
- the pilot symbols (estimated complex fading envelope) are averaged (by in-phase addition) in a plurality of slots before and after the slot to which the data symbol for channel estimation belongs. This is performed by obtaining a channel estimation value by averaging the average value with a weighting coefficient. This improves the channel estimation accuracy with respect to thermal noise ⁇ own station multipath interference and other station interference.
- the pilot symbol insertion method includes a parallel time multiplexing method (Fig. 1) and a parallel method (Fig. 22) in which a pilot symbol is time-multiplexed on a control channel multiplexed in parallel with a data channel. .
- the weighting factor is fixedly given.In order to reduce the effect of thermal noise, if the weighting factor of a slot that is temporally separated from the slot is increased, There was a problem that the ability to follow fading fluctuations deteriorated, and as a result, the accuracy of channel estimation deteriorated. Further, although the method of Reference 3 solves the problem of Reference 2, there is a problem that the configuration of the demodulator becomes complicated by using adaptive signal processing.
- amplitude fluctuation and phase fluctuation occur due to Rayleigh fading accompanying movement of a relative position between a mobile station and a base station.
- a synchronous detection processing using a pilot signal is known.
- the transmitting side transmits a known pilot signal
- the receiving side transmits the pilot signal.
- Channel estimation is performed by demodulating the lot signal and averaging it over time. Then, by performing phase correction of the data signal using the estimated channel vector and performing RAKE combining, demodulation that effectively uses the power of the received signal can be realized.
- averaging pilot signals using an appropriate weight sequence improves channel estimation accuracy and enables high-quality communication.
- the weight sequence differs depending on the propagation conditions, mainly the moving speed.
- An object of the present invention is to perform highly accurate channel estimation by calculating the channel estimation value of a data symbol of a data channel by weighting and averaging pilot symbols in a parallel time multiplexing system.
- the data symbols in the slot are divided into a plurality of data symbol sections, By selecting a pilot symbol appropriate for calculating the channel estimation value of the data symbol in the data symbol section, weighting and averaging the pilot symbol, and calculating the channel estimation value of the data symbol in each data symbol section, high accuracy is achieved. It is to perform channel estimation.
- the fading frequency is determined based on the inner product value of the pilot symbol. Another object is to realize an optimal channel estimation for the fading frequency with a simpler configuration.
- an invention according to claim 1 is a channel estimating apparatus for weighting and averaging pilot symbols time-multiplexed on a control channel parallel-multiplexed with a data channel.
- Weighting factor generating means for generating a weighting coefficient
- channel estimation value calculating means for calculating a channel estimation value of the data symbol of the data channel by weighting and averaging the pilot symbols using the weighting coefficient.
- the invention according to claim 2 is the channel estimating device according to claim 1, wherein the weighting coefficient generating unit calculates a weighted average of pilot symbol average values in each of the plurality of slots of the control channel.
- the channel estimation value calculating means calculates the channel estimation value of the data symbol of the data channel by averaging the average value of the pilot symbols using the weighting factor.
- the invention according to claim 3 is the channel estimation device according to claim 1 or 2, wherein the weighting coefficient is determined according to a position of the pilot symbol in a slot of the control channel. It is characterized by.
- the invention according to claim 4 provides the channel estimation device according to any one of claims 1 to 3.
- the weighting coefficient generation means divides a data symbol in a slot of the data channel into a plurality of data symbol sections, and generates a pilot symbol appropriate for calculating a channel estimation value of the data symbol in each data symbol section. Selecting, generating a weighting coefficient for weighting and averaging the pilot symbol, the channel estimation value calculating means weighing and averaging the pilot symbol using the weighting coefficient, and It is characterized by calculating the channel estimation value of.
- the invention according to claim 5 is the channel estimating apparatus according to claim 4, wherein the weighting coefficient generation unit is configured to transmit data symbols between the last data symbol section of the i-th (i: integer) slot. To select the same pilot symbol and calculate the weighted average of the pilot symbols for the calculation of the channel estimation value of, and the calculation of the channel estimation value of the data symbol in the first data symbol section of the (i + 1) th slot. It is characterized by generating a weighting coefficient of.
- the invention according to claim 6 is the channel estimating apparatus according to any one of claims 1 to 5, wherein the fading frequency determining means for determining a fading frequency based on an inner product value of the pilot symbol, and the fading frequency determining means.
- Coefficient changing means for changing a coefficient used for the weighted averaging in accordance with the fading frequency determined by the jing frequency determining means.
- the invention according to claim 7 is the channel estimation device according to any one of claims 1 to 6, wherein a transmission rate of the data channel is different from a transmission rate of the control channel. .
- the invention according to claim 8 is a demodulation device, comprising: a weighting coefficient generation unit configured to generate a weighting coefficient for weighting and averaging a pilot symbol that is time-multiplexed on a control channel that is parallel-multiplexed with a data channel.
- Channel estimation value calculating means for weighting and averaging the pilot symbol using the weighting coefficient, and calculating a channel estimation value of the data symbol of the data channel; and the channel estimation value meter.
- Channel fluctuation compensating means for compensating for the channel fluctuation of the data symbol using the channel estimation value calculated by the calculating means.
- the invention according to claim 9 is a fading frequency determination device, wherein the inner product value calculating means calculates an inner product value of a pilot symbol that is time-multiplexed on a control channel that is multiplexed in parallel with a data channel, and the inner product Determining means for determining the fading frequency based on the inner product value calculated by the value calculating means.
- the invention according to claim 10 is the fading frequency determination device according to claim 9, wherein the inner product value calculating means calculates an average value of pilot symbols in each of two slots of the control channel.
- Normalizing means for normalizing inner product value calculating means for calculating an inner product value of an average value of the two pilot symbols normalized by the normalizing means, and an inner product value calculated by the inner product value calculating means.
- An inner product value averaging means for averaging over a plurality of slots of the control channel, wherein the determining means compares the inner product value averaged by the inner product value averaging means with a threshold to determine a fading frequency. It is characterized by having judgment execution means.
- An invention according to claim 11 is the fading frequency determination device according to claim 10, wherein the inner product value averaged by the inner product value averaging means is larger than a certain value.
- the normalization, the inner product value calculation and the inner product value averaging are performed on the average value of the pilot symbols in each of the two more spaced slots of the control channel, and the averaged inner product value obtained is obtained. And a threshold corresponding to the farther interval is compared to determine the fading frequency.
- the invention according to claim 12 is the fading frequency determination device according to claim 9, wherein the inner product value calculating means is configured to determine, for each of the multipaths used for RAKE combining, Normalizing means for normalizing the average value of pilot symbols in each of the two slots; and calculating, for each of the multipaths, an inner product value of an average value of the two pilot symbols normalized by the normalizing means.
- Inner product value calculation execution means, and the multipath calculated by the inner product value calculation execution means First inner product value averaging means for averaging each inner product value, and second inner product value averaging for averaging the inner product value averaged by the first inner product value averaging means over a plurality of slots of the control channel. Means for determining the fading frequency by comparing the inner product value averaged by the second inner product value averaging means with a threshold value.
- the invention according to claim 13 is the fading frequency determination device according to claim 12, wherein the inner product value averaged by the second inner product value averaging means is larger than a certain value.
- the averaging of the inner product value over the plurality of slots is performed, and a fading frequency is determined by comparing the obtained averaged inner product value with a threshold value corresponding to the farther interval.
- the invention according to claim 14 is the fading frequency determination device according to claim 9, wherein the inner product value calculating means calculates an average value of pilot symbols in each of two slots of the control channel.
- Normalization means for normalizing; inner product value calculation executing means for calculating two or more inner product values of the average value of the two pilot symbols normalized by the normalization means at different inner product measurement intervals; each inner product measurement An inner product value averaging means for averaging the inner product value calculated by the inner product value calculation execution means over a plurality of slots of the control channel, wherein the determination means comprises: It is characterized by having judgment execution means for judging the fading frequency by using the inner product value for each averaged inner product measurement interval.
- the invention according to claim 15 is the fading frequency determination device according to claim 14, wherein the difference between the inner product values for two inner product measurement intervals averaged by the inner product value averaging means is calculated.
- the image processing apparatus further includes a difference calculation unit, wherein the determination execution unit determines the fading frequency using the difference calculated by the difference calculation unit.
- the invention according to claim 16 is the fading frequency determination device according to claim 9, wherein the inner product value calculating means is configured to determine, for each of the multipaths used for RAKE combining, Normalizing means for normalizing the average value of pilot symbols in each of the two slots; and, for each of the multipaths, an inner product value of an average value of the two pilot symbols normalized by the normalizing means.
- Inner product value calculation executing means for calculating two or more at different measurement intervals, and a first inner product value average for averaging the inner product value of each of the multipaths calculated by the inner product value calculating means for each inner product measurement interval Means for averaging the inner product value averaged by the first inner product value averaging means for each inner product measurement interval over a plurality of slots of the control channel.
- Product value averaging means, and the determination means has a determination executing means for determining a fading frequency using an inner product value for each inner product measurement interval averaged by the second inner product value averaging means. It is characterized by the following.
- the invention according to claim 17 is the fading frequency determination device according to claim 16, wherein the difference between the inner product values of the two inner product measurement intervals averaged by the second inner product value averaging means. Is further provided, and the determination executing means determines the fading frequency also using the difference calculated by the difference calculating means.
- the invention according to claim 18 is a channel estimating apparatus that calculates a channel estimation value of the data symbol using a pilot symbol in a channel in which a data symbol and a pilot symbol are time-multiplexed, wherein the slot of the channel is Are divided into a plurality of data symbol sections, a pilot symbol appropriate for calculating a channel estimation value of the data symbol in each data symbol section is selected, and a weighting coefficient for weighting and averaging the pilot symbols is calculated.
- a channel estimation value calculation means for calculating a channel estimation value of a data symbol in each data symbol section by weighting and averaging the pilot symbol using the weighting coefficient. It is characterized by.
- the invention according to claim 19 is the channel estimating apparatus according to claim 18, wherein the weighting coefficient generating means is a data estimator for the last data symbol section of the i-th (i: integer) slot. For calculating the channel estimation value of the symbol and the channel estimation value of the data symbol in the first data symbol section of the (i + 1) th slot, the same pilot symbol is selected and the pilot symbol is weighted and averaged. It is characterized by generating a weighting coefficient for the conversion.
- the invention according to claim 20 is the channel estimating apparatus according to claim 18 or claim 19, wherein the weighting coefficient generation means is configured to calculate an average value of pilot symbol in each of a plurality of slots of the channel.
- a weighting coefficient for weighting and averaging the data symbols, and the channel estimation value calculating means weights and averages an average value of the pilot symbols using the weighting coefficients, and estimates a channel of a data symbol in each data symbol section.
- the method is characterized in that a value is calculated.
- the invention according to claim 21 is the channel estimation device according to any one of claims 18 to 20, wherein the weighting coefficient is determined according to a position of the pilot symbol in a slot of the channel. It is characterized by having been done.
- the invention according to claim 22 is the channel estimation device according to any one of claims 18 to 21, wherein the fading frequency determination unit determines a fading frequency based on an inner product value of the pilot symbols, A coefficient changing means for changing a coefficient used for the weighted averaging according to the fading frequency determined by the fading frequency determining means is further provided.
- the invention according to claim 23 is a demodulation device, which divides a data symbol in a slot of a channel in which data symbols and pilot symbols are time-multiplexed into a plurality of data symbol sections, and Weighting coefficient generating means for selecting a pilot symbol suitable for calculating a channel estimation value of a data symbol in a symbol section and generating a weighting coefficient for weighting and averaging the pilot symbol; and
- the pilot symbols are weighted and averaged using Channel estimation value calculating means for calculating a channel estimation value of a data symbol in a data section, and channel fluctuation compensation means for compensating for channel fluctuation of the data symbol using the channel estimation value calculated by the channel estimation value calculation means. It is characterized by having.
- An invention according to claim 24 is a fusing frequency determination device, wherein an inner product value calculating means for calculating an inner product value of a pilot symbol in a channel in which a data symbol and a pilot symbol are time-multiplexed. And determining means for determining a fading frequency based on the inner product value calculated by the inner product value calculating means.
- An invention according to claim 25 is the fading frequency determination device according to claim 24, wherein the inner product value calculating means calculates an average value of pilot symbol in each of the two slots of the channel.
- Normalizing means for normalizing inner product value calculating means for calculating an inner product value of an average value of the two pilot symbols normalized by the normalizing means, and an inner product value calculated by the inner product value calculating means.
- An inner product value averaging means for averaging over a plurality of slots of the channel, wherein the determining means determines a fading frequency by comparing the inner product value averaged by the inner product value averaging means with a threshold value It is characterized by having a judgment execution means for performing the judgment.
- An invention according to claim 26 is the fading frequency determination device according to claim 25, wherein the inner product value averaged by the inner product value averaging means is larger than a certain value. Performing the normalization, the inner product value calculation and the inner product value averaging on the average value of the pilot symbols in each of the two more spaced apart slots of the control channel, and obtaining the averaged value.
- a fading frequency determining device that determines a fading frequency by comparing an inner product value with a threshold value corresponding to a farther interval.
- An invention according to claim 27 is the fusing frequency determination device according to claim 24, wherein the inner product value calculation means is provided for each of the multipaths used for RAKE combining.
- a normalization means for normalizing an average value of pilot symbols in each of the two slots of the control channel; and an average of two pilot symbols normalized by the normalization means for each of the multipaths.
- Inner product value calculation executing means for calculating the inner product value of the values; first inner product value averaging means for averaging the inner product values of each of the multipaths calculated by the inner product value calculating executing means; and the first inner product value Second inner product value averaging means for averaging the inner product value averaged by the averaging means over a plurality of slots of the channel, wherein the determining means averages the inner product value by the second inner product value averaging means.
- a judgment execution means for judging a fading frequency by comparing the obtained inner product value with a threshold value.
- the invention according to claim 28 is the fading frequency determination device according to claim 27, wherein the inner product value averaged by the second inner product value averaging means is larger than a certain value.
- the normalization, the calculation of the inner product value, the averaging of the inner product value of each of the multipaths, and the average of the pilot symbol in each of two more spaced slots of the control channel are performed.
- the averaging of the inner product value over the slot is performed, and the fading frequency is determined by comparing the obtained averaged inner product value with a threshold value corresponding to the farther interval.
- the invention according to claim 29 is the fusing frequency determination device according to claim 24, wherein the inner product value calculating means is configured to calculate an average value of pilot symbol in each of two slots of the channel.
- Normalization means, and an inner product value calculation executing means for calculating two or more inner product values of the average values of the two pilot symbols normalized by the normalization means at different inner product measurement intervals, and each inner product
- An inner product value averaging means for averaging the inner product value calculated by the inner product value calculation executing means over a plurality of slots of the control channel, for the measurement interval
- the determining means comprises: It is characterized by having judgment execution means for judging the fading frequency by using the inner product value for each inner product measurement interval that is more averaged.
- the invention according to claim 30 provides the fading frequency determination device according to claim 29. And a difference calculating means for calculating a difference between inner product values for two inner product measuring intervals averaged by the inner product value averaging means, wherein the determination executing means is calculated by the difference calculating means. It is characterized in that the fading frequency is determined using the difference.
- the invention according to claim 31 is the fading frequency determination device according to claim 24, wherein the inner product value calculating means is configured to determine, for each of the multipaths used for RAKE combining, Normalizing means for normalizing an average value of pilot symbols in each of the two slots; and for each of the multipaths, an inner product value of an average value of the two pilot symbols normalized by the normalizing means.
- the determining means comprising: a determination executing means for determining a fading frequency using an inner product value for each inner product measurement interval averaged by the second inner product value averaging means. It is characterized by having.
- the invention according to claim 32 is the fading frequency determination device according to claim 31, wherein the difference between the inner product values of the two inner product measurement intervals averaged by the second inner product value averaging means is provided. And a difference calculating unit that calculates the fading frequency by using the difference calculated by the difference calculating unit.
- the invention according to claim 33 is a channel estimation device that calculates a channel estimation value of the data symbol of the data channel using a pilot symbol of the pilot channel multiplexed in parallel to the data channel, wherein The data symbol of the channel is divided into a plurality of data symbol sections, a pilot symbol appropriate for calculating the channel estimation value of the data symbol in each data symbol section is selected, and the pilot symbol is selected.
- Weighting coefficient generation means for generating a weighting coefficient for weighting and averaging of the symbols; andchannel estimation for calculating a channel estimation value of a data symbol in each data symbol section by weighting and averaging the pilot symbols using the weighting coefficient.
- Value calculation means for generating a weighting coefficient for weighting and averaging of the symbols.
- the invention according to claim 34 is the channel estimating device according to claim 33, wherein the weighting coefficient generation means calculates a weighted average of pilot symbol average values in each of a plurality of sections of the pilot channel.
- the channel estimation value calculating means calculates the channel estimation value of the data symbol in each data symbol section by weighting and averaging the average value of the pilot symbols using the weighting coefficient.
- a channel estimation device calculates the channel estimation value of the data symbol in each data symbol section by weighting and averaging the average value of the pilot symbols using the weighting coefficient.
- the invention according to claim 35 is the channel estimation device according to any one of claims 33 or 34, wherein a fading frequency determination unit that determines a fading frequency based on an inner product value of the pilot symbol, And a coefficient changing means for changing a coefficient used for the weighted averaging in accordance with the fading frequency determined by the fading frequency determining means.
- the invention according to claim 36 is the channel estimation device according to any one of claims 33 to 35, wherein a transmission rate of the data channel is different from a transmission rate of the pilot channel.
- the invention according to claim 37 is the demodulation device, wherein the data symbol of the data channel is divided into a plurality of data symbol sections, and the demodulation apparatus is suitable for calculating a channel estimation value of the data symbol of each data symbol section.
- Weighting coefficient generating means for selecting pilot symbols of a pilot channel multiplexed in parallel with the overnight channel and generating weighting coefficients for weighting and averaging the pilot symbols; and
- Channel estimation value calculating means for calculating a channel estimation value of a data symbol in each data symbol section by weighting and averaging, and the data symbol using the channel estimation value calculated by the channel estimation value calculating means.
- channel fluctuation compensating means for compensating for the above channel fluctuation.
- the invention according to claim 38 is a fading frequency determination device, wherein the inner product value calculating means for calculating an inner product value of a pilot symbol of a pilot channel multiplexed in parallel on a data channel, and the inner product value calculating means calculates the inner product value. Determining means for determining the fusing frequency based on the inner product value.
- the invention according to claim 39 is the fading frequency determination device according to claim 38, wherein the inner product value calculating means calculates an average value of pilot symbol in each of two sections of the pilot channel.
- Normalizing means for normalizing inner product value calculating means for calculating an inner product value of an average value of two pilot symbols normalized by the normalizing means, and an inner product value calculating means for calculating the inner product value.
- Inner product value averaging means for averaging the inner product value over a plurality of sections of the channel, wherein the judging means compares the inner product value averaged by the inner product value averaging means with a threshold value to determine a fading frequency. It is characterized by having judgment execution means for judging the number.
- the invention according to claim 40 is the fading frequency determination device according to claim 39, wherein the inner product value averaged by the inner product value averaging means is larger than a certain value.
- the normalization, the inner product value calculation and the inner product value averaging are performed on the average value of the pilot symbols in each of two farther intervals of the pilot channel, and the averaged inner product obtained is obtained.
- the fading frequency is determined by comparing the value with a threshold value corresponding to the farther interval.
- the invention according to claim 41 is the fading frequency determination device according to claim 38, wherein the inner product value calculating means is configured to determine, for each of the multipaths used for RAKE combining, the Normalizing means for normalizing the average value of the pilot symbols in each of the two sections of the multi-channel, and for each of the multipaths, the inner product value of the average values of the two pilot symbols which are normalized by the normalization means.
- Inner product value calculation executing means for calculating; first inner product value averaging means for averaging each inner product value of each of the multipaths calculated by the inner product value calculating executing means; and first inner product value averaging means.
- Second inner product value averaging means for averaging the more averaged inner product value over a plurality of sections of the pilot channel, wherein the determining means comprises the inner product averaged by the second inner product value averaging means. It is characterized by having a judgment execution means for judging a fading frequency by comparing a value with a threshold value.
- the invention according to claim 42 is the fading frequency determination device according to claim 41, wherein the inner product value averaged by the second inner product value averaging means is larger than a certain value. Is the normalization, the inner product calculation, the averaging of the inner product of each of the multipaths, and the average of the pilot symbol in each of the two more spaced intervals of the pilot channel, and The inner product value is averaged, and the fading frequency is determined by comparing the obtained averaged inner product value with a threshold value corresponding to the farther interval.
- the invention according to claim 43 is the fading frequency determination apparatus according to claim 38, wherein the inner product value calculating means calculates an average value of pilot symbols in each of two sections of the pilot channel.
- Normalization means for normalizing; inner product value calculation executing means for calculating two or more inner product values of the average values of the two pilot symbols normalized by the normalization means while changing the inner product measurement interval;
- inner product measurement interval there is an inner product value averaging means for averaging the inner product value calculated by the inner product value calculation executing means over a plurality of sections of the control channel, and the determining means comprises: It is characterized by having judgment execution means for judging the fading frequency by using the inner product value for each of the more averaged inner product measurement intervals.
- the invention according to claim 44 is the fading frequency determination device according to claim 43, wherein a difference between inner product values for two inner product measurement intervals averaged by the inner product value averaging means is calculated.
- the image processing apparatus further includes a difference calculation unit, wherein the determination execution unit determines the fading frequency using the difference calculated by the difference calculation unit.
- the invention according to claim 45 is a fading frequency determination device according to claim 38.
- the inner product value calculating means normalizes an average value of pilot symbols in each of the two sections of the pilot channel for each of the multipaths used for RAKE combining;
- Inner product value calculating means for calculating two or more inner product values of the average values of the two pilot symbols normalized by the normalization means at different inner product measurement intervals for each of the multipaths;
- First inner product value averaging means for averaging the inner product value of each of the multipaths calculated by the inner product value calculating means for the interval; and the first inner product value averaging means for each inner product measurement interval.
- a second inner product value averaging unit for averaging the inner product value averaged over a plurality of sections of the control channel. It is characterized by having judgment execution means for judging the fading frequency using the inner product value for each equalized inner product measurement interval.
- the invention according to claim 46 is the fading frequency determination device according to claim 45, wherein the difference between the inner product values for the two inner product measurement intervals averaged by the second inner product value averaging means. Is further provided, and the determination execution means determines the fading frequency also using the difference calculated by the difference calculation means.
- the invention according to claim 47 is a channel estimation method, wherein a step of generating a weighting coefficient for weighting and averaging pilot symbols time-multiplexed on a control channel parallel-multiplexed with a data channel is performed. And weighting and averaging the pilot symbols using the weighting coefficients, and calculating a channel estimation value of the data symbols of the data channel.
- An invention according to claim 48 is a fading frequency determination method, comprising: calculating an inner product value of a pilot symbol time-multiplexed on a control channel parallel-multiplexed on a data channel; and Determining an aging frequency.
- the data symbol and the pilot symbol are time multiplexed.
- a channel estimation method for calculating a channel estimate of said data symbol by using a pilot symbol in an overlapped channel comprising: dividing a data symbol in a slot of said channel into a plurality of data symbol intervals; A step of selecting a pilot symbol appropriate for obtaining a channel estimation value of the data symbol, and generating a weighting coefficient for weighting and averaging the pilot symbol; and weighting and averaging the pilot symbol using the weighting coefficient. And calculating a channel estimation value of a data symbol in each data symbol section.
- the invention according to claim 50 is a fading frequency determination method, comprising the steps of: calculating an inner product value of a pilot symbol in a channel on which time symbols and pilot symbols are time-multiplexed; and And a step of determining a fading frequency based on the frequency.
- the invention according to claim 51 is a channel estimation method for calculating a channel estimation value of a data symbol of the data channel using pilot symbols of a pilot channel multiplexed in parallel with the data channel. Divides the data symbol of the data channel into a plurality of data symbol sections, selects a pilot symbol appropriate for calculating the channel estimation value of the data symbol in each data symbol section, and weights the pilot symbol. Generating a weighting coefficient for averaging; and weighting and averaging the pilot symbols using the weighting coefficient, and calculating a channel estimation value of a data symbol in each data symbol section. And
- An invention according to claim 52 is a fading frequency determination method, wherein a fading frequency is determined based on an inner product value of pilot symbols of a pilot channel multiplexed in parallel on a data channel. .
- An invention according to claim 53 is a demodulation device, comprising: weighting and averaging a pilot signal temporally using N (N is a natural number of 2 or more) weighted sequences to obtain N channels Channel estimation means for obtaining an estimated value; compensation means for compensating a data sequence using the respective channel estimation values; RAKE combining means for RAKE combining each of the N data sequences after the compensation; and RAKE combining means And a reliability judging means for selecting one data sequence having the highest reliability from the subsequent N data sequences.
- An invention according to claim 54 is a demodulation device, wherein for a data sequence having a predetermined number of frames, a pilot signal is temporally converted using N (N is a natural number of 2 or more) weight sequences.
- the channel estimation means N ′ channel estimation values are obtained by temporally weighting and averaging using the N ′ weight sequences, and the compensating means compensates the data sequence using the N ′ channel estimation values,
- the invention according to claim 55 is the demodulation device according to claim 53 or 54, wherein the data sequence reliability determination unit performs error correction decoding of the data sequence after the RAKE combination.
- CRC bit extraction means for extracting CRC bits added to the data sequence
- CRC decoding means for decoding the data sequence by CRC, and detection of the presence or absence of a frame error from the CRC decoding result.
- Frame error detection means for performing the above-mentioned operation, frame error number counting means for controlling the number of frame errors at a predetermined measurement time, a weight sequence having high reliability based on the frame error count result, and a weight sequence thereof Select the data sequence to be demodulated using Weight sequence to be selected and data selection means.
- the invention according to claim 56 is the demodulation device according to claim 53 or 54, wherein the data sequence reliability determination unit performs error correction decoding of the data sequence after the RAKE combination.
- Error correction decoding means for performing, likelihood information extraction means for extracting likelihood information calculated at the time of error correction decoding of each data sequence, and averaging the extracted likelihood information for a predetermined measurement time.
- Weighting means for selecting a highly reliable weight sequence based on the averaged likelihood information and a data sequence to be demodulated using the weight sequence. It is characterized by the following.
- the invention according to claim 57 is the demodulation device according to claim 53 or 54, wherein the data sequence reliability determination unit calculates the power of each data sequence after the RAKE combination.
- Power calculating means power averaging means for averaging the power calculation result for a predetermined measurement time, and a highly reliable weight sequence based on the averaged power and a weight sequence thereof.
- the invention according to claim 58 is the demodulation device according to claim 53 or 54, wherein the reliability determination unit for the data sequence includes an SN ratio of each data sequence after the RAKE combining ( Signal power-to-noise power ratio), SN ratio averaging means for averaging the SN ratio calculation result for a predetermined measurement time, and reliability based on the averaged SN ratio A weight sequence for selecting a weight sequence having a high degree and a data sequence demodulated using the weight sequence; and a data selection means.
- the invention according to claim 59 is the demodulation device according to claim 53 or 54, wherein the reliability determination unit for the data sequence is configured to correct an error in the data sequence after the RAKE combination.
- Error correction decoding means for decoding CRC bit extraction means for extracting CRC bits added to the data sequence, CRC decoding means for decoding the CRC for the data sequence, and a decoding result of the CRC.
- Frame error detection means for detecting the presence / absence of a frame error, and the number of frame errors at a predetermined measurement time.
- Means for counting the number of frame errors to be counted, means for extracting likelihood information calculated at the time of error correction decoding of each data sequence, and averaging the extracted likelihood information for a predetermined measurement time A likelihood averaging means, a weight sequence having high reliability based on the measured number of frame errors of a plurality of data sequences and the averaged likelihood information, and a data sequence demodulated using the weight sequence.
- Weighting sequence ⁇ data selection means
- the invention according to claim 60 is the demodulation device according to claim 53 or 54, wherein the data sequence reliability determination means performs error correction decoding of the data sequence after the RAKE combining.
- Correction decoding means CRC bit extracting means for extracting CRC bits added to the data sequence, CRC decoding means for decoding the data sequence CRC, frame error based on the CRC decoding result.
- Frame error detection means for detecting the presence / absence of a frame
- frame error number counting means for counting the number of frame errors in a predetermined measurement time, and calculating the power of each data sequence after the RAKE synthesis
- Power calculating means power averaging means for averaging the calculation result of the power over a predetermined measurement time, and reliability of the power based on the number of frame errors and the averaged power.
- a weight sequence for selecting a high weight sequence and a data sequence demodulated using the weight sequence; and data selection means.
- the invention according to claim 61 is the demodulation device according to claim 53 or 54, wherein the data sequence reliability determination means performs error correction decoding of the data sequence after the RAKE combining.
- Error correction decoding means CRC bit extraction means for extracting CRC bits added to the data sequence, CRC decoding means for decoding the data sequence by CRC, and presence or absence of a frame error based on the CRC decoding result.
- Ratio calculating means SN ratio averaging means for averaging the SN ratio calculation result for a predetermined measurement time, the number of frame errors and the averaging And a weight sequence for selecting a data sequence demodulated using the weight sequence with high reliability based on the obtained SN ratio and the weight sequence.
- the invention according to claim 62 is a demodulation device, comprising: a channel estimation means for obtaining a plurality of channel estimation values by weighting and averaging a received pilot signal using a plurality of weight sequences; and A demodulation means for outputting a plurality of demodulated data sequences using the plurality of channel estimation values; and a reliability determination for selecting one demodulated data sequence by determining the reliability of the plurality of demodulated data sequences.
- the invention according to claim 63 is the demodulation device according to claim 62, wherein the reliability determination unit is configured to determine the plurality of weight sequences based on reliability determination results in the plurality of demodulated data sequences.
- selecting means for selecting a predetermined number of weight sequences from among the above, wherein the demodulation means performs demodulation using only the predetermined number of weight sequences when the predetermined number of weight sequences are selected. I do.
- the invention according to claim 64 is the demodulation device according to any one of claims 53 to 63, wherein the pilot signal is a control channel parallel-multiplexed to a data channel including the data sequence. Is time-multiplexed.
- the invention according to claim 65 is the demodulation device according to any one of claims 53 to 63, wherein the pilot signal is time-multiplexed on one channel together with the data sequence.
- the invention according to claim 66 is the demodulation device according to claim 65, wherein the channel estimating means divides a data sequence in a slot of the channel into a plurality of data sequence sections, and A pilot signal suitable for calculating a channel estimation value of data in a sequence section is selected, and the pilot signal is weighted and averaged to calculate a channel estimation value of data in each data series section.
- the invention according to claim 67 is the demodulation device according to any one of claims 53 to 63, wherein the pilot signal is a pilot channel parallel-multiplexed to a data channel including the data sequence. It is characterized by being included in.
- the invention according to claim 68 is the demodulation device according to claim 67, wherein the channel estimating means divides the data sequence into a plurality of data sequence sections, and outputs data between the data sequence sections.
- the method is characterized in that a suitable pilot signal is selected for the calculation of the channel estimation value, and the pilot signal is weighted and averaged to calculate a channel estimation value of data in each data sequence section.
- the invention according to claim 69 is a demodulation method, wherein a pilot signal is temporally weighted and averaged using N (N is a natural number of 2 or more) weight sequences to obtain N channel estimation values. Determining, compensating the data sequence using the respective channel estimation values, RAKE combining each of the N data sequences after the compensation, and N data sequences after the RAKE combining. And a reliability determination step of selecting one data sequence having the highest reliability.
- An invention according to claim 70 is a demodulation method, wherein a pilot signal is temporally converted using N (N is a natural number of 2 or more) weight sequences for a data sequence having a predetermined number of frames. Obtaining N channel estimates by weighting and averaging the data, compensating a data sequence using each of the channel estimates, and RAKE combining each of the compensated N data sequences. And N ′ weight sequences with high reliability ( ⁇ ′: natural number, ⁇ ′ ⁇ ) are selected from the N data sequences after the RAKE synthesis, and the most reliable weight sequence is selected from the ⁇ data sequences.
- N is a natural number of 2 or more
- a reliability determination step of selecting one data sequence having a high degree of reliability the N ′ weight sequences are selected at regular intervals, and the remaining time is determined until the reliability determination is performed next time.
- a channel for estimating the channel Tep obtains N ′ channel estimates by temporally weighting and averaging using the N ′ weight sequences, and the compensating step comprises compensating the data sequence using the N ′ channel estimates.
- the RAKE combining step includes RAKE combining each of the compensated N ′ data sequences, and the reliability determining step includes determining one of the N ′ data sequences having the highest reliability from the N ′ data sequences. It is characterized by selecting a data series.
- the invention according to claim 71 is the demodulation method according to claim 69 or 70,
- the reliability determination step includes a step of performing error correction decoding of the data sequence after the RAKE combination, a step of extracting a CRC bit added to the data sequence, and a process of decoding a CRC of the data sequence. Performing the detection, the step of detecting the presence or absence of a frame error based on the result of decoding of the CRC, the step of counting the number of frame errors in a predetermined measurement time, and the reliability based on the frame error count result. And a step of selecting a data sequence to be demodulated using the weight sequence having a high weight.
- the invention according to claim 72 is the demodulation method according to claim 69 or 70, wherein the reliability determination step performs error correction decoding of the data series after the RAKE combination. Extracting likelihood information calculated at the time of error correction decoding of each data sequence; averaging the extracted likelihood information for a predetermined measurement time; and averaging the likelihood. Selecting a highly reliable weight sequence based on the information and a data sequence to be demodulated using the weight sequence.
- the invention according to claim 73 is the demodulation method according to claim 69 or 70, wherein the reliability determination step includes calculating the power of each data sequence after the RAKE combination. And a step of averaging the power calculation result for a predetermined measurement time, and selecting a highly reliable weight sequence based on the averaged power and a data sequence to be demodulated using the weight sequence. And a step of performing the following.
- the invention according to claim 74 is the demodulation method according to claim 69 or 70, wherein the reliability determination step calculates an SN ratio of each data sequence after the RAKE combining. Averaging the SN ratio calculation result for a predetermined measurement time; and a highly reliable weight sequence based on the averaged SN ratio and data demodulated using the weight sequence. Selecting a sequence.
- the invention according to claim 75 is the demodulation method according to claim 69 or 70, wherein the reliability determination step performs an error correction decoding of the data sequence after the RAKE combining, A step of extracting a CRC bit added to the data sequence; a step of decoding the CRC for the data sequence; and a step of detecting the presence or absence of a frame error from the result of the CRC decoding.
- the invention according to claim 76 is the demodulation method according to claim 69 or 70, wherein the reliability determination step is a step of performing error correction decoding of the data series after the RAKE synthesis. Extracting CRC bits added to the data sequence; performing CRC decoding on the data sequence; and detecting the presence or absence of a frame error from the CRC decoding result. Counting the number of frame errors during a predetermined measurement time; calculating the power of each received data sequence after the RAKE combining; measuring the power calculation result by a predetermined measurement Averaging over time and selecting a highly reliable weight sequence based on the number of frame errors and the averaged power and a data sequence to be demodulated using the weight sequence And having a step.
- the invention according to claim 77 is the demodulation method according to claim 69 or 70, wherein the reliability determination step performs error correction decoding of the data series after the RAKE combination. Extracting CRC bits added to the data sequence; decoding CRC for the data sequence; and detecting the presence or absence of a frame error based on the CRC decoding result. At a predetermined measurement time Counting the number of frame errors in the data sequence, calculating the SN ratio of each data sequence after the RAKE combining, averaging the SN ratio calculation result for a predetermined measurement time, Selecting a highly reliable weight sequence based on the number of errors and the averaged SN ratio and a data sequence to be demodulated using the weight sequence.
- the invention according to claim 78 is a demodulation method, comprising: a step of obtaining a plurality of channel estimation values by weighting and averaging a pilot signal using a plurality of weight sequences; and using the plurality of channel estimation values.
- the invention according to claim 79 is the demodulation method according to claim 78, wherein a predetermined number of the plurality of weighted sequences are selected from the plurality of weighted sequences based on a reliability determination result of the plurality of demodulated data sequences. A weight sequence is selected, and after the selection, demodulation using only the selected weight sequence is performed.
- the invention according to claim 80 is the demodulation method according to any one of claims 69 to 79, wherein the pilot signal is a control channel parallel-multiplexed to a data channel including the data sequence. Is time-multiplexed.
- the invention according to claim 81 is the demodulation method according to any one of claims 69 to 79, wherein the pilot signal is time-multiplexed on one channel together with the data sequence.
- the invention according to claim 82 is the demodulation method according to claim 81, wherein the step of estimating the channel includes dividing a data sequence in a slot of the channel into a plurality of data sequence sections. Selecting a pilot signal suitable for calculating the channel estimation value of the data in each data sequence section, and weighing and averaging the pilot signal to calculate a channel estimation value of the data in each data sequence section. .
- the invention according to claim 83 is a demodulation method according to any one of claims 69 to 79.
- the pilot signal is included in a pilot channel parallel-multiplexed with a data channel including the data sequence.
- the invention according to claim 84 is the demodulation method according to claim 83, wherein the step of estimating the channel comprises: dividing the data sequence into a plurality of data sequence sections; A pilot signal suitable for calculating a data channel estimation value is selected, and the pilot signal is weighted and averaged to calculate a channel estimation value of data in each data sequence section.
- highly accurate channel estimation can be performed by calculating the channel estimation value of the data symbol by weighting and averaging the pilot symbols.
- the data symbols in the slot are divided into a plurality of data symbol sections, pilot symbols suitable for calculating the channel estimation value of the data symbols in each data symbol section are selected, and the pilot symbols are weighted and averaged to obtain each data symbol section.
- the fusing frequency can be determined based on the inner product value of the pilot symbol. Further, it is possible to realize an optimal channel estimation for the fusing frequency with a simpler configuration.
- a weight sequence that is effective when the moving speed is low and is effective to increase the averaging time to some extent is effective when the moving speed is high and the averaging time is somewhat reduced.
- Channel estimation is always performed using multiple weighting factors, and reliability is evaluated using the received data sequence.
- reliability is evaluated using the received data sequence.
- the system load can be reduced by periodically selecting a small number of weighting factors and performing channel estimation using only those weighting factors during a certain period.
- FIG. 1 shows a frame configuration of a signal received by the demodulation device according to the first embodiment of the present invention.
- -It is a figure showing an example.
- FIG. 2 is a diagram for explaining a channel estimation method by the demodulation device according to the first embodiment of the present invention.
- FIG. 3 is a block diagram illustrating a configuration example of the demodulation device according to the first embodiment of the present invention.
- FIG. 4 is a block diagram illustrating a configuration example of the channel estimation unit according to the first embodiment of the present invention.
- FIG. 5 is a block diagram illustrating a configuration example of the fading frequency determination unit according to the first embodiment of the present invention.
- FIG. 6 is a diagram illustrating a calculation example of a channel estimation value.
- FIG. 7 is a diagram showing an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 8 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 9 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 10 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 11A and FIG. 11B are diagrams for explaining the concept of fading frequency determination.
- FIG. 12 is a diagram illustrating a result obtained by a computer simulation of a measurement value with respect to a measurement time using a fading frequency as a parameter.
- FIG. 13 is a diagram showing the relationship between FIG. 13A and FIG. 13B.
- FIGS. 13A and 13B are block diagrams showing another example of the configuration of the fusing frequency determination unit according to the first embodiment of the present invention.
- FIG. 14 is a diagram illustrating an example of determining a fading frequency.
- FIG. 15 is a diagram illustrating an example where the transmission rate of the data channel is different from the transmission rate of the control channel.
- FIG. 16 is a diagram illustrating an example of a frame configuration of a signal received by the demodulation device according to the second embodiment of the present invention.
- FIG. 17 is a block diagram illustrating a configuration example of a demodulation device according to the second embodiment of the present invention.
- FIG. 18 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 19 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 20 is a diagram showing an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 21 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- FIG. 22 is a diagram illustrating an example of a frame configuration of a signal received by the demodulation device according to the third embodiment of the present invention.
- FIG. 23 is a block diagram illustrating a configuration example of the demodulation device according to the third embodiment of the present invention.
- FIG. 24 is a block diagram illustrating a configuration example of a channel estimation unit according to the third embodiment of the present invention.
- FIG. 25 is a diagram illustrating an example of dividing a data symbol of a data channel into a plurality of data symbol sections and calculating a channel estimation value for each data symbol section.
- FIG. 26 is a diagram illustrating an example of dividing a data symbol of a data channel into a plurality of data symbol sections and calculating a channel estimation value for each data symbol section.
- FIG. 27 is a diagram illustrating an example in which a data symbol of a data channel is divided into a plurality of data symbol sections and a channel estimation value is calculated for each data symbol section.
- FIG. 28A and FIG. 28B are diagrams for explaining the concept of fading frequency determination.
- FIG. 29 is an explanatory diagram of an example of a channel estimation method using a pilot signal.
- FIG. 30 is a diagram showing the relationship between FIG. 3OA and FIG. 30B.
- FIG. 3OA and FIG. 30B are configuration block diagrams of a reliability determination unit in the fourth embodiment.
- FIG. 31 is a diagram showing the relationship between FIG. 31A and FIG. 31B.
- FIG. 31A and FIG. 31B are configuration block diagrams of a reliability determination unit according to a modification of the fourth embodiment.
- FIG. 32 is a configuration block diagram of a reliability determination unit according to the fifth embodiment.
- FIG. 33 is a configuration block diagram of a reliability determination unit according to the sixth embodiment.
- FIG. 34 is a configuration block diagram of a reliability determination unit according to the seventh embodiment.
- FIG. 35 is a diagram showing the relationship between FIG. 35A and FIG. 35B.
- FIG. 35A and FIG. 35B are configuration block diagrams of a reliability determination unit in the eighth embodiment.
- FIG. 36 is a diagram showing the relationship between FIG. 36A and FIG. 36B.
- FIG. 36A and FIG. 36B are configuration block diagrams of a reliability determination unit in the ninth embodiment.
- FIG. 37 is a diagram showing the relationship between FIG. 37A and FIG. 37B.
- FIG. 37A and FIG. 378 are configuration block diagrams of the reliability judgment unit in the tenth embodiment.
- FIG. 38 is a diagram illustrating a general concept in the fourth to tenth embodiments. BEST MODE FOR CARRYING OUT THE INVENTION
- FIG. 1 is a diagram illustrating an example of a frame configuration of a signal received by the demodulation device according to the first embodiment of the present invention.
- the demodulation device according to the present embodiment receives and demodulates a data channel and a control channel signal multiplexed in parallel with the data channel. Pilot symbols with a known transmission pattern (for example, with a known phase when the primary modulation is phase modulation) are time-multiplexed on the control channel (parallel time multiplexing). Using the received signal (phase and amplitude) at the pilot symbol portion as a reference signal, the channel fluctuation of the data symbol of the data channel is estimated.
- FIG. 2 is a diagram for explaining a method of channel estimation by the demodulation device according to the present embodiment.
- Channel estimation is performed using pilot symbols. Specifically, the average of pilot symbols (complex fading envelope estimation values) is averaged (in-phase addition) in a plurality of slots, and the average value ⁇ 'is used as a weighting coefficient (coefficient used for weighted averaging) ( ⁇ , This is performed by calculating the channel estimation value ⁇ '' by performing weighted averaging with ai etc.
- the channel estimation value '' ( ⁇ ) of the data symbol of the ⁇ -th slot is calculated as ⁇ '( ⁇ - From (2)
- the channel estimation value of the n + 3rd pilot block '( ⁇ + 3) is calculated as follows.
- FIG. 3 is a block diagram illustrating a configuration example of the demodulation device according to the present embodiment.
- the demodulation device according to the present embodiment includes a matched filter for data channel 102, a delay unit 104, a matched filter for control channel 106, a channel estimation unit 120, a multiplication unit 108, And RAKE (Rake) synthesis unit 110.
- the demodulation device according to the present embodiment conforms to the CD MA (Code Division Multiple Access) system
- the present invention uses another system (for example, the TDMA (Time Division Multiple Access) system, the FD MA (Frequency Division Multiple Access) system). Access) method).
- FIG. 4 is a block diagram illustrating a configuration example of the channel estimation unit according to the present embodiment.
- the channel estimation unit 120 includes a slot synchronization detection unit 122, a pilot symbol averaging unit 124, a delay unit 126, 128, 130, etc., a multiplication unit 132 , 13 It includes a weighting coefficient control unit 1380, an addition unit 140, and a fading frequency determination unit 150, such as 4, 1 and 36.
- the channel estimation unit 120 can be realized as hardware, or can be realized as software using a DSP (Digital Signal Processor) or the like.
- FIG. 5 is a block diagram illustrating a configuration example of the fading frequency determination unit according to the present embodiment.
- the fusing frequency determination unit 150 includes a normalization unit 152, an inner product value calculation unit 154, a first averaging unit 156, a second averaging unit 158, and It is provided with a judgment section 160.
- the received spread signal of the data channel is inversely spread using a spread code replica according to the reception timing of each multipath of each user.
- the received spread signal of the control channel is despread using a spreading code replica according to the reception timing of each multipath of each user.
- the slot (pilot block) of channel estimation section 122 synchronization detection section 122 detects the pilot symbol position in the control channel. From the timing information, the pilot symbol averaging unit 124 averages the reception channels at the pilot symbols in each pilot block to estimate the channel for each pilot block.
- the estimated channel information in each pilot block is input to delay sections 126, 128, 130, etc., and the timings are aligned, and the weighting factor generated by weighting factor control section 138 is used to multiply section.
- the channel estimation value is calculated by performing weighted averaging (weighted addition) using 1 32, 1 34, 1 36, etc., and the adder 140.
- FIG. 6 is a diagram illustrating a calculation example of a channel estimation value.
- the channel estimation value of the data symbol of the nth slot is calculated using the n + 1st pilot block from the n ⁇ 1st pilot block.
- the ratio of the weighting coefficients can be set to, for example, ai-aoo ⁇ -O.4: 1.0: 0.4.
- the value of the weighting factor is preferably set to be larger for a pilot block closer (closer in time) to the data symbol for which the channel estimation value is to be calculated. This is because the propagation path changes every moment, and such a pilot block reflects the state of the propagation path at the time of transmitting the n-th data symbol.
- a pilot block reflects the state of the propagation path at the time of transmitting the n-th data symbol.
- the position of the pilot block (pilot symbol) in the slot is temporally earlier (as can be seen in Fig. 6, it is shifted to the left).
- a highly accurate channel estimation value can be obtained.
- the channel estimation value is calculated using all the pilot symbols in the slot, but the channel estimation value is calculated without using all the pilot symbols in the slot. You may. Also, in FIGS. 2 and 6, weighted averaging is performed after calculating the average value of pilot symbols in the pilot block.Weighting averaging is performed by providing a weighting coefficient for each pilot symbol. You may. If there is only one pilot symbol in the pilot block, there is no need to calculate the average.
- the channel estimation value is common to all data symbols in one slot, but the data symbol in the slot is divided into multiple data symbol sections, and the channel estimation is performed for each data symbol section.
- a pilot symbol suitable for calculating the value is selected, and the pilot symbol is weighted and averaged to obtain each data symbol. It is also possible to calculate the channel estimation value of the data symbol of the section.
- FIG. 7 is a diagram showing an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- the channel estimation value is calculated using the (n-1) th pilot block from the (n-1) th pilot block and the data symbol
- channel estimation values are calculated using the (n + 2) th pilot block from the nth pilot block.
- the calculation of the channel estimation values for the data symbol intervals (1), (2) and (3) can be performed using the same weighting factors or different weighting factors. The same applies to the overnight symbol sections (4), (5) and (6).
- the channel estimation value of the data symbol in the last data symbol section (1) of the n-th slot is calculated, and the data estimation of the first data symbol section (2) in the n-th slot is performed.
- the same pilot symbol is selected, and the pilot symbol is weighted and averaged to calculate the channel estimation value of the data symbol in each data symbol section.
- FIGS. 8 to 10 are also diagrams showing examples in which a data symbol in one slot is divided into a plurality of data symbol sections and a channel estimation value is calculated for each data symbol section.
- two symbols before and two symbols after the slot of the control channel are pilot symbols.
- the average value for pilot symbols with a fixed number of symbols is calculated while sequentially moving the symbol position.
- the pilot symbols are directly weighted and averaged without calculating the average value of the pilot symbols for each pilot block.
- four pilot symbols are used for weighted averaging, and the data symbols in one slot are divided into three sections.
- four pilot symbols are used for weighted averaging. Is divided into five sections.
- the number of pilot symbols used for weighted averaging is eight, and a data symbol in one slot is divided into three sections.
- the weighting coefficients used for weighted averaging are changed according to the fading frequency.
- the fading frequency determination unit 150 determines the fading frequency based on the average value of the pilot symbols, and the weighting factor control unit 1338 changes the weighting factor generated based on the determination result.
- Fading frequency determination section 150 normalizes the average value of pilot symbols in each of the two slots of the control channel, and then calculates an inner product value.
- FIG. 11A and FIG. 11B are diagrams for explaining the concept of fading frequency determination.
- the inner product value becomes large because the correlation of the channel estimation value for each slot is large.
- the fading fluctuation is fast (the fading frequency is large)
- the correlation between the channel estimation values for each slot is small, so that the inner product value is small.
- Fig. 12 is a diagram showing the results obtained by computer simulation for the measured value (vertical axis) with respect to the measurement time (horizontal axis) using the fading frequency (f DT slot) as a parameter.
- the threshold value for the measured value is set to, for example, 0.3, and the value is set below this value. In this case, it can be determined that the fading frequency is 0.3 or more.
- the normalizing unit 1502 of the fading frequency determination unit 150 calculates the average value of pilot symbols in each of the two slots of the control channel, that is, for two pilot blocks, the pilot symbol in the pilot block. Normalize the average.
- the inner product value calculator 154 calculates the inner product value of the average value of the two normalized pilot symbols.
- the demodulation device is a demodulation device that performs RAKE combining, and performs the above-described normalization and inner product value calculation for each of the multipaths used for the RAKE combining.
- the inner product value of each of the multipaths is averaged by the first averaging unit 156. If zero averaging over multiple paths is not performed, the first averaging unit 156 is unnecessary.
- the average value calculated by the first averaging unit 156 is further averaged over a plurality of slots by the second averaging unit 158 (for example, in FIG. 11A, the inner product value (1), ( 2) and (3) are averaged). This reduces the effects of thermal noise. If averaging is not performed over a plurality of slots, the second averaging section 158 is unnecessary.
- the threshold determination unit 160 compares the average value calculated by the second averaging unit 158 with the threshold to determine the fading frequency. Specifically, the threshold is determined in a plurality of steps based on a preset threshold to determine which of the plurality of regions the fading frequency corresponds to. In the present embodiment, the fading frequency is determined based on the threshold value. However, the fading frequency may be determined based on a calculation formula, for example.
- the fusing frequency is determined by taking the inner product of the average values of the pilot symbols of each of the two pilot blocks, but the two pilot blocks that take the inner product are, for example, adjacent slots. Pilot blocks (for example, pilot blocks (1) and (2) in FIG. 11 ⁇ ) or every other slot (for example, pilot blocks (1) and (3) in FIG. 11A) ). Further, the fading frequency may be determined by using an inner product of a certain pilot symbol and another pilot symbol without using a pilot block.
- the inner product value (average value) of the pilot symbol (average value) (for example, If the output of the second averaging unit 158 is larger than a certain value, the normalization and the inner product are performed on the average value of the pilot symbols in each of the two farther-spaced slots of the control channel. Value calculation, averaging the inner product values of each of the multipaths, and averaging the inner product values over the plurality of slots, and calculating the obtained averaged inner product value and a threshold value corresponding to the farther interval.
- the fading frequency can be determined by comparison.
- the difference in the inner product value due to the difference in frequency is relatively large (the resolution is high) at higher fading frequencies, so that the fading frequency can be easily adjusted. It is possible to judge the threshold value, but at lower fading frequencies, the difference in the inner product value is relatively small (the resolution is low), so that the fading frequency judgment tends to be difficult.
- the resolution at lower fading frequencies can be enhanced by increasing the interval (slot of inner product measurement) between slots that include pilot symbols used for calculating the inner product value. Therefore, an inner product value having a low resolution (ie, using a pilot symbol of a short interval) is obtained first, and an inner product value larger than a certain value (ie, a frequency lower than a certain fading frequency) is obtained.
- the inner product value of high resolution that is, using the pilot symbol of a slot with a long interval
- the range from the high fading frequency to the lower fading frequency is further increased. It is possible to make highly accurate judgments over a wide frequency range.
- the inner product value of the two-slot interval is a value corresponding to a lower fading frequency below a certain frequency
- the inner product value of the pilot symbol at the three-slot interval one slot further away is used to perform the fermentation. It is possible to increase the resolution by gradually increasing the inner product measurement interval, such as determining the jing frequency. (The reason for changing the inner product measurement interval from a narrow interval to a wide interval is that given inner product measurement This is because the frequency that can be determined with respect to the interval decreases as the interval increases.)
- the calculation of the inner product value at different inner product measurement intervals can be performed in parallel, and by calculating in parallel, even in the case of performing the above-described stepwise determination, it can be performed in a short time. A determination result can be obtained.
- FIG. 13A and FIG. 13B are block diagrams showing another configuration example of the fading frequency determination unit 150 according to the present embodiment.
- the fading frequency determination unit shown in FIGS. 13A and 13B includes a normalization unit 162, a delay unit 163-1, 163-1, an inner product value calculation unit 164-1, 164-2, and a first averaging unit 166-. 1, 166-2, a second averaging section 168-1, 168-2, a difference calculation section 169, and a determination section 170.
- a normalization unit 162 a delay unit 163-1, 163-1, an inner product value calculation unit 164-1, 164-2, and a first averaging unit 166-. 1, 166-2, a second averaging section 168-1, 168-2, a difference calculation section 169, and a determination section 170.
- the inner product value calculation unit 164-1 calculates the inner product value using the inner product measurement interval as one slot length, and the inner product value calculation unit 164_2 uses the same two slot length as ( (Skipping one slot) The inner product value is calculated.
- the inner product value at each inner product measurement interval is averaged over multiple passes in the first averaging units 166-1, 166-2, and averaged over multiple slots in the second averaging units 168-1, 168-2.
- the difference calculation unit 169 calculates the difference between the inner product values at the two inner product measurement intervals (the difference between the inner product value at one slot interval and the inner product value at two slot intervals).
- determination section 170 determines the fading frequency using the inner product value at one-slot intervals, the inner product value at two-slot intervals, and the difference between these values.
- averaging is performed over a plurality of paths and averaging over a plurality of slots. However, one or both of them may not be performed.
- FIG. 14 is a diagram illustrating an example of determining a fading frequency.
- the points P i the point where the inner product value and the difference (absolute value) at the interval of two slots match first
- the point P 2 the inner product value and the difference at the interval of one slot are the first matching point
- the inner product value at the point P 3 (1 slot interval and is the inner product value in the 2-slot interval first matching
- the point P The fading frequency is determined in four ways, that is, higher than the fading frequency in 3.
- the threshold does not have to be set.
- more detailed judgment is possible than when one inner product value is calculated without changing the inner product measurement interval. By changing the inner product measurement interval and calculating more inner product values, more detailed judgment can be made.
- the fading frequency may be determined using only a plurality of inner product values without calculating the difference. In that case, it will be determined using only the point P 3 in the example of FIG 4.
- the weighting coefficient control section 1338 changes the weighting coefficient.
- the fading frequency when the fading frequency is high, the pilot that is closer (temporally close) to the data symbol for which the channel estimation value is to be calculated is compared to when the fading frequency is low. Increase the weighting coefficient of the block.
- the fading frequency is large, the channel fluctuation of the data symbol for which the channel estimation value is to be calculated is greatly different from the channel fluctuation of the pilot block far (temporally far) from the data symbol. is there.
- the weighting coefficient used for weighted averaging is changed according to the fading frequency, but a fixed weighting coefficient may be used.
- the channel fluctuation (fogging fluctuation) of the data symbol after despreading which is timed by the delay unit 104, is compensated. I do. Specifically, channel fluctuation is compensated by multiplying the despread data symbol by the complex conjugate of the channel estimation value. Then, the compensated signals are combined in phase by the RAKE combining means 110.
- the transmission rate of the data channel and the transmission rate of the control channel are the same, but the two transmission rates may be different.
- FIG. 15 is a diagram illustrating an example where the transmission rate of the data channel is different from the transmission rate of the control channel.
- the transmission rate of the control channel is 1/2 of the transmission rate of the data channel.
- FIG. 16 is a diagram illustrating an example of a frame configuration of a signal received by the demodulation device according to the second embodiment of the present invention.
- the demodulation device according to the present embodiment receives and demodulates a signal of a channel (time multiplexing method) in which data symbols and pilot symbols are time-multiplexed.
- the received signal (phase, amplitude) in the pilot symbol portion is used as a reference signal to estimate the channel variation of the data symbol. Pilot symbols are inserted at regular intervals between data symbols.
- the channel estimation method is the same as the channel estimation method by the demodulation device according to the first embodiment of the present invention.
- FIG. 17 is a block diagram illustrating a configuration example of the demodulation device according to the present embodiment.
- the demodulation device according to the present embodiment includes a matched filter 202, a delay unit 204, a channel estimation unit 220, a multiplication unit 208, and a RAKE (rake) combining unit 210. .
- the demodulation device according to the present embodiment also complies with the CDMA system, but it is also possible to apply the present invention to a demodulation device conforming to another system (for example, TDMA system, FDMA system). You.
- the demodulation device according to the present embodiment performs multiple access transmission by spreading a wideband signal with a spreading code faster than the information rate.
- the configuration example of the channel estimation unit 220 according to the present embodiment is the same as the configuration example of the channel estimation unit 120 according to the first embodiment of the present invention illustrated in FIG.
- the slot synchronization detecting section 122 detects a pilot symbol position in a channel in which the data symbol and the pilot symbol are time-multiplexed.
- the configuration example of the fading frequency determination unit according to the present embodiment is also the same as the configuration example of the fading frequency determination unit 150 according to the first embodiment of the present invention shown in FIG. It can be configured as shown in Fig. 13B).
- the operation of the demodulation device according to the present embodiment is basically the same as the operation of the demodulation device according to the first embodiment of the present invention.
- FIG. 18 is a diagram illustrating an example in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- the channel estimation value is calculated using the n-1st pilot block from the n-1st pilot block, and the data symbol interval (3)
- the channel estimation value is calculated using the n + 2nd pilot block from the nth pilot block.
- the calculation of the channel estimation value for the data symbol interval (1) and (2) can be performed using the same weighting factor, or can be performed using different weighting factors. You can do it too. The same applies to the data symbol sections (3) and (4). Also, in the example of FIG.
- FIGS. 19 to 21 are also diagrams showing examples in which a data symbol in one slot is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- two symbols before and two symbols after the slot of the control channel are pilot symbols.
- the average value for pilot symbols of a fixed number of symbols is calculated while sequentially moving the symbol position.
- the pilot symbols are directly weighted and averaged without calculating the average value of the pilot symbols for each pilot block.
- the number of pilot symbols used for weighted averaging is four, and a data symbol in one slot is divided into three sections.
- the number of pilot symbols used for weighted averaging is four, and the data symbol in one slot is divided into five sections.
- eight pilot symbols are used for weighted averaging, and the data symbols in one slot are divided into three sections.
- the channel estimation value of the data symbol in the last data symbol section of the i-th (i: integer) slot is calculated, and the first data symbol of the i + 1-th slot is calculated.
- the same pilot symbol is selected, the pilot symbol is weighted and averaged, and the channel estimation value of the data symbol in each data symbol section is calculated.
- the weighting coefficient used for the weighted averaging is changed according to the fading frequency.
- fixed weighting factors can also be used. You.
- the channel fluctuation (fading fluctuation) of the data symbol after despreading which is timed by the delay unit 204, is compensated. Specifically, channel fluctuation is compensated by multiplying the despread data symbol by the complex conjugate of the channel estimation value. Then, the compensated signal is subjected to in-phase synthesis by the rake synthesis means 210.
- the transmission rates of data symbols and pilot symbols in a channel are the same, but the transmission rate of data symbols and the transmission rate of pilot symbols in a channel can be different.
- FIG. 22 is a diagram illustrating an example of a frame configuration of a signal received by the demodulation device according to the third embodiment of the present invention.
- the demodulation device according to the present embodiment receives and demodulates a pilot channel signal (parallel method) multiplexed in parallel with a data channel and a data channel.
- the received signal (phase, amplitude) of the pilot symbol of this pilot channel is used as a reference signal to estimate the channel variation of the data channel data symbol.
- the pilot symbol is not transmitted and received using a part of the slot as in the parallel time multiplexing method and the time multiplexing method, but the pilot symbol is transmitted and received continuously, so the concept of the slot is not very important. . Therefore, the slots are not particularly shown in FIG.
- the channel estimation method by the demodulation device according to the present embodiment is basically the same as the channel estimation method by the demodulation device according to the first and second embodiments of the present invention. Is described below.
- FIG. 23 is a block diagram illustrating a configuration example of the demodulation device according to the present embodiment.
- the demodulation device according to the present embodiment includes a matched filter for data channel 302, a delay unit 304, a matched filter for pilot channel 302, a channel estimation unit 320, a multiplication unit 3 08, and RAKE combining unit 310.
- the demodulation device according to the present embodiment is also based on the CDMA system, but the present invention can be applied to a demodulation device based on another system (for example, the TDMA system or the FDMA system).
- FIG. 24 is a block diagram illustrating a configuration example of the channel estimation unit according to the present embodiment.
- the channel estimator 320 according to the present embodiment includes a pilot symbol averager 324, delay units 326, 328, 330, etc., multipliers 332, 334, 336, etc., a weighting factor controller 338, an adder 340, and fading.
- a frequency determination unit 350 is provided.
- the configuration example of the fading frequency determination section (fading frequency determination section 350) according to the present embodiment is the same as the configuration example of the fading frequency determination section 150 according to the first embodiment of the present invention shown in FIG. It is also possible to configure as shown in FIG. 13A and FIG. 13B).
- the operation of the demodulation device according to the present embodiment is basically the same as the operation of the demodulation device according to the first and second embodiments of the present invention.
- FIG. 25 is a diagram illustrating an example in which a data symbol of a data channel is divided into a plurality of data symbol sections, and a channel estimation value is calculated for each data symbol section.
- the data symbol is divided into intervals of 3 symbols, and the channel estimation value is calculated using the pilot symbol interval (three symbol configurations) corresponding temporally and the pilot symbol intervals before and after it. ing. More specifically, the channel estimation value '(0) obtained from the average of three symbols in the temporally corresponding pilot symbol interval, and the channel estimation value obtained from the average in the pilot symbol periods before and after (' 1) and '(1) are weighted and averaged with ⁇ 0 and, respectively, to calculate the channel estimate ⁇ ′′.
- FIGS. 26 and 27 also show examples in which the data symbol of the data channel is divided into a plurality of data symbol sections (intervals of one symbol) and the channel estimation value is calculated for each data symbol section.
- channel estimation an average value for a certain number of pilot symbols is calculated while sequentially moving the symbol position.
- the pilot symbol is directly weighted and averaged, instead of calculating the average value of the pilot symbol and performing weighted averaging as in the example of FIG. 25.
- pilot symbols used for weighted averaging there are four pilot symbols used for weighted averaging, and the pilot symbol used for weighted averaging is changed for each data symbol.
- the number of pilot symbols used for weighted averaging is four, and the pilot symbol used for weighted averaging is changed every two symbols.
- the weighting coefficient used for the weighted averaging is changed according to the fading frequency.
- a fixed weighting factor can be used.
- FIG. 28A and FIG. 28B are diagrams for explaining the concept of fading frequency determination.
- the fading frequency determination method in the present embodiment is basically the same as the fading frequency determination method in the first embodiment and the second embodiment.
- the average value of pilot symbols in each of the two slots is used.
- the average value of pilot symbols in each of the two sections of the pilot channel is used. ing.
- the two sections may be discontinuous or continuous (discontinuous in Figure 28). Further, one section may include one pilot symbol, or two or more pilot symbols.
- the interval of the section including the pilot symbol used for calculating the inner product value is included.
- the inner product value can be calculated.
- two or more inner product values can be calculated by changing the inner product measurement interval, and the fusing frequency can be determined using those inner product values.
- the channel fluctuation of the de-spread symbol after despreading which is timed by the delay ).
- the channel fluctuation is compensated by multiplying the despread data symbol by the complex conjugate of the channel estimation value.
- the compensated signal is subjected to in-phase synthesis by the rake synthesis means 3110.
- the transmission rate of the data channel and the transmission rate of the pilot channel can be different.
- pilot symbol insertion method may be a parallel time multiplexing method (FIG. 1), a time multiplexing method (FIG. 16), or a parallel method (FIG. 22).
- averaging using a weight sequence is performed after performing simple averaging on an arbitrary block of a chip unit or more.
- a pilot signal is weighted and averaged using a plurality of predetermined weight sequences, and channel estimation is performed. Find the value. Then, the received data is demodulated using the obtained channel estimation value, and the reliability of the plurality of demodulated data is determined to select one output data having the highest quality.
- FIG. 3 OA and FIG. 30B are block diagrams showing the fourth embodiment.
- 1 is a despreading unit
- 2 including 2-1 to 2-N
- 3 is a multiplier
- 4 (4-1 to 4 (including N) is the RAKE combiner
- 5 including 5-1 to 5—N
- 6 is the CRC decoder
- 7 (7 — 1 to 7 — N) is the frame error number calculation unit
- 8 A is the reliability comparison unit
- 9 is the reliability determination unit
- 10 is the first switching switch.
- a received spread signal is input to the despreading unit 1, and the input received spread data sequence is despread using a spreading code replica corresponding to the multipath timing.
- the channel estimator 2 prepares N weight sequences (N ⁇ 2) for averaging the pilot signals, and averages the pilot signals in parallel with the respective weight sequences to obtain a channel estimation value.
- the multiplier 3 corrects the phase by multiplying the data sequence of the despread communication channel by the complex conjugate of each channel estimation value.
- the phase-corrected signal is subjected to in-phase combining in all the fingers, and is input to the reliability determining section 9.
- the FEC decoding section 5 decodes the error correction code, and outputs N pieces of decoded data of weighting factors # 1 to #N.
- the CRC decoder 6 decodes the CRC using the CRC bits extracted from the decoded data sequence, determines whether there is a frame error, and inputs the determination result to the frame error number calculator 7. .
- the frame error number calculation unit 7 calculates the number of frame errors existing between the predetermined number of frames, and inputs the count number to the reliability comparison unit 8.
- the reliability comparison / determination unit 8A selects the data sequence of the system with the least number of frame errors from the N frame error information and outputs the data by switching the first switching switch 10 to the desired system. I do.
- channel estimation is always performed using a plurality of weighting factors, and data having high reliability is selected by reliability determination using a received data sequence.
- Weighting factors corresponding to various moving speeds can be used simultaneously, and highly accurate channel estimation is possible.
- CRC decoding result to select a weight sequence with a small number of frame errors, it is possible to make a determination to reduce the frame error rate.
- FIGS. 31A and 31B Modifications of the fourth embodiment are shown in FIGS. 31A and 31B.
- FIG. 31A and FIG. 31B the same parts as those in the fourth embodiment shown in FIG. 30A and FIG. 11 indicates a second switching switch.
- the reliability determination section 9 selects N ′ weight sequences (here, N ′: natural number, 1 ⁇ ⁇ ′ ⁇ ) having a high reliability with the number of frames. After the reliability determination, for the remaining data series until the reliability determination is performed again at the above time interval, only the switch of the selected weight sequence is turned on, and the other weight sequences are turned on. Switches are turned off, and the same operation as in the fourth embodiment is performed in the N ′ system using the selected N ′ weight sequences. Do.
- FIG. 32 is a block diagram illustrating a reliability determination unit according to the fifth embodiment. Functional blocks other than the reliability determination unit conform to the fourth embodiment and are omitted. The same parts as those in the fourth embodiment shown in FIGS. 30A and 30B are denoted by the same reference numerals. 1 2 (1 2—1 to 1 2—N) indicates a likelihood averaging unit.
- the RAKE-combined signal is input to the FEC decoder 5.
- the FEC decoder 5 decodes the error correction code and outputs the decoded data of the weight sequences # 1 to #N, and outputs the likelihood information calculated at the time of error correction to the likelihood averaging unit 1 2 To enter.
- the likelihood averaging unit 12 averages the inputted likelihood with a predetermined number of frames and Y frames (where Y is a natural number, Y ⁇ l) and inputs the same to the reliability comparison unit 8.
- the reliability comparison unit 8 selects a data series having the highest reliability as the information output from the likelihood information of the ⁇ system.
- the determination reflecting the communication quality (such as the bit error rate) is performed by using the likelihood information calculated at the time of error correction decoding for the reliability determination. Becomes possible.
- the modification of the fifth embodiment can be configured by replacing the reliability determination unit of the modification of the fourth embodiment shown in FIGS. 31A and 31B with the fifth embodiment shown in FIG. 32. .
- the reliability determination unit selects N ′ weight sequences (here, N ′: natural number, 1 ⁇ ⁇ ′ ⁇ ) with high reliability in the number of frames.
- the second switching switch 11 is configured such that only the switch of the selected weight sequence is ⁇ ⁇ and the other The switch of the weight sequence is turned OFF, and the same operation as that of the fourth embodiment is performed in the N ′ system using the selected N ′ weight sequences.
- the likelihood averaging unit 12 uses a weighting method other than a simple averaging method using a predetermined number of frames and Y frames (where Y is a natural number, Y ⁇ l). The average, the minimum value, and the maximum value can be selected.
- FIG. 33 is a block diagram illustrating a reliability determination unit according to the sixth embodiment. Functional blocks other than the reliability determination unit conform to the fourth embodiment and are omitted. The same parts as those in the fourth embodiment shown in FIGS. 30A and 30B are denoted by the same reference numerals. 1 3 (including 13-1 to 13-N) indicates the power calculator.
- the RAKE-combined signal is input to the power calculator 13. Power calculation section 13 Then, the powers of the N systems after the RAKE synthesis are calculated and averaged over a predetermined period.
- the averaged power calculation value is input to the reliability comparison unit.
- the reliability comparison / determination unit 8 selects the data sequence having the highest reliability from the power calculation values of the N systems and inputs the data sequence to the FEC decoding unit 5.
- the error correction decoding is performed by the FEC decoding unit 5, and the information is output as an information output.
- the sixth embodiment by using the received power after the RAKE combination for reliability determination, it is possible to make a determination to increase the received power.
- the communication quality (frame error rate, etc.) can be improved, and the reliability can be determined without performing FEC decoding, so that the system load can be reduced.
- the modification of the sixth embodiment is configured by replacing the reliability determination unit of the modification of the fourth embodiment shown in FIGS. 31A and 31B with the sixth embodiment shown in FIG. 33. it can. For each data cycle of a predetermined number of frames at regular intervals, all the second switching switches 11 are turned ON, and the operation of the fourth embodiment is performed by N systems. In addition, the reliability determination unit selects N ′ weight sequences (here, N ′: natural number, 1 ⁇ ⁇ ′ ⁇ ) with high reliability in the number of frames.
- the second switching switch 11 is configured such that only the switch of the selected weight sequence is ⁇ ⁇ and the other The switch of the weight sequence is turned OFF, and the same operation as that of the fourth embodiment is performed in the N ′ system using the selected N ′ weight sequences.
- FIG. 34 is a block diagram showing a reliability judgment unit in the seventh embodiment. Functional blocks other than the reliability determination unit conform to the fourth embodiment and are omitted. The same parts as those in the fourth embodiment shown in FIGS. 30A and 30B are denoted by the same reference numerals. 14 (including 14-1 to 14-N) indicates the SN ratio calculator.
- the RAKE-combined signal is input to the SN ratio calculator 14.
- the SN ratio calculation unit 14 calculates the SN ratio of the N signals after the RAKE synthesis of the N systems, and averages them over a predetermined period.
- the averaged SN ratio calculation value is input to the reliability comparison unit 8.
- the reliability comparison unit 8 selects a data sequence having the highest reliability from the SN ratio calculation values of the N systems and inputs the sequence to the FEC decoding unit 5.
- the error correction decoding is performed by the FEC decoding unit 5, and the information is output as an information output.
- the seventh embodiment by using the S / N ratio after the RAKE combination for reliability determination, it is possible to make a determination to increase the S / N ratio.
- the quality (frame error rate, etc.) can be improved, and the reliability can be determined before performing error correction decoding, so that the load on the system can be reduced.
- the system load can be reduced by modifying as follows.
- the modification of the seventh embodiment is a modification of the fourth embodiment shown in FIGS. 31A and 31B.
- the example can be configured by replacing the reliability determination unit with the seventh embodiment shown in FIG.
- N ′ weight sequences with high reliability in the above-mentioned number of frames (where N ′: natural number, 1 ⁇ ⁇ ′ ⁇ ) are selected.
- the second switching switch 11 is configured such that only the switch of the selected weight sequence is ⁇ and the switches of the other weight sequences are ⁇ . Becomes OFF, and the same operation as in the fourth embodiment is performed in the N ′ system using the selected N ′ weight sequences.
- FIG. 35A and FIG. 35B are block diagrams showing a reliability determination unit in the eighth embodiment.
- the functional blocks other than the reliability determination unit conform to the fourth embodiment and will not be described.
- 30A and FIG. 30B are denoted by the same reference numerals as those in the fourth embodiment.
- the RAKE-combined signal is input to the FEC decoder 5.
- the FEC decoder 5 decodes the error correction code, outputs decoded data with weighting factors # 1 to #N, and averages the likelihood information calculated at the time of error correction. Input to the conversion section 12.
- the likelihood averaging unit 12 averages the inputted likelihood with a predetermined number of frames, Y1 frames (where Y1 is a natural number, Yl ⁇ l), and inputs the averaged likelihood to the reliability comparison determination unit 8.
- the CRC decoder 6 decodes the CRC using the CRC bits extracted from the data sequence decoded by the FEC decoder 5 and determines whether there is a frame error. Then, the judgment result is input to the frame error number calculation unit 7.
- the frame error number calculation unit 7 counts the number of frame errors existing in a predetermined Y 2 frame (here, Y 2 is a natural number, Y 2 ⁇ l), and counts the count number into the reliability comparison unit 8 To enter.
- the reliability comparison unit 8 selects from among the systems having the least number of frame errors than the ⁇ system of frame error information output from the frame error number calculation unit 7 based on the likelihood information input from the likelihood averaging unit 12. The data sequence with the highest reliability is selected as the information output.
- the eighth embodiment by using the likelihood information calculated at the time of error correction decoding together with the number of frame errors counted from the CRC decoding result for reliability determination, mutual By combining judgment factors, strict reliability judgment can be performed.
- the reliability determining unit of the modification of the fourth embodiment shown in FIGS. 31A and 31B is the same as the eighth embodiment shown in FIGS. 35A and 35B. It is composed by replacing the form.
- the second switching switches 11 are all turned on for a data sequence having a predetermined number of frames, and the operation of the fourth embodiment is performed by N systems.
- the reliability determination unit selects N ′ weight sequences (where N ′ is a natural number, 1 ⁇ ⁇ ′ ⁇ ) with the above-mentioned number of frames and high reliability.
- the second switching switch 11 is configured such that only the switch of the selected weight sequence is ⁇ ⁇ and the other The switch of the weight sequence is turned off, and the same operation as in the fourth embodiment is performed in the N ′ system using the selected N ′ weight sequences.
- the likelihood averaging unit 12 calculates the likelihood by a predetermined number of frames, Y1 frame (where Y1 is a natural number, Yl ⁇ l). And a method of selecting the minimum value and a method of selecting the maximum value.
- FIGS. 36A and 36B are block diagrams showing a reliability determination unit in the ninth embodiment.
- the functional blocks other than the reliability determination unit conform to the fourth embodiment and will not be described.
- the same parts as those in the fourth embodiment shown in FIGS. 31A and 31B are denoted by the same reference numerals.
- the RAKE-combined signal is input to the power calculator 13.
- the power calculator 13 calculates the powers of the N systems after the RAKE combination, averages them for a predetermined period, and inputs the calculated value to the reliability comparator 8.
- the FEC decoder 5 decodes the error correction code for the RAKE-combined data sequence from the RAKE combiner 4 and outputs decoded data with weighting factors # 1 to #N.
- the CRC decoding unit 6 performs CRC decoding using the CRC bits extracted from the data sequence decoded by the FEC decoding unit 5, determines whether or not there is a frame error, and determines the determination result as the number of frame errors. Input to calculation unit 7.
- the frame error number calculation unit 7 counts the number of frame errors existing in a predetermined Y frame (where Y is a natural number, Y ⁇ l), and inputs the count number to the reliability comparison unit 8 I do.
- the reliability comparison unit 8 determines, from among the systems with the least number of frame errors than the N frame error information output from the frame error number calculation unit 7, the data sequence with the highest reliability from the power calculation value. Select as output.
- the received power after the RAKE combination is used for reliability determination together with the number of frame errors counted from the CRC decoding result, thereby enabling mutual determination.
- the received power after the RAKE combination is used for reliability determination together with the number of frame errors counted from the CRC decoding result, thereby enabling mutual determination.
- the reliability determining unit of the modification of the fourth embodiment shown in FIGS. 31A and 31B is similar to the ninth embodiment shown in FIGS. 36A and 36B. It can be configured by replacing the form.
- the second switching switches 11 are all set to ⁇ N for a data sequence of a predetermined number of frames, and the operation of the fourth embodiment is performed by N systems.
- the reliability determination unit selects N ′ ( ⁇ ′ ⁇ ) weight sequences with high reliability in the above-mentioned number of frames.
- the second switching switch 11 is configured such that only the switch of the selected weight sequence is ⁇ , and the other weights are The sequence switches are turned off, and the same operation as in the fourth embodiment is performed in the N ′ system using the selected N ′ weight sequences.
- FIG. 37A and FIG. 37B are block diagrams showing the reliability determination unit in the tenth embodiment.
- the functional blocks other than the reliability determining unit conform to the fourth embodiment and are omitted.
- the same parts as those in the fourth embodiment shown in FIGS. 31A and 31B are the same. Is assigned.
- the RAKE-combined signal is input to the SN ratio calculator 14.
- the SN ratio calculator 14 calculates the SN ratio of the N systems after the RAKE combining, averages them for a predetermined period, and inputs the calculated value to the reliability comparator 8.
- the FEC decoding unit 5 decodes the error correction code for the RAKE-combined data sequence from the RAKE combining unit 4, and outputs decoded data of weighting factors # 1 to #N.
- the CRC decoding unit 6 performs CRC decoding using the CRC bits extracted from the data sequence decoded by the FEC decoding unit 5, determines whether or not there is a frame error, and determines the determination result as the number of frame errors. Input to calculation unit 7.
- the frame error number calculation unit 7 counts the number of frame errors existing in a predetermined Y frame (where Y: natural number, Y ⁇ l), and inputs the count number to the reliability comparison unit 8 I do.
- the reliability comparison unit 8 outputs a data sequence having the highest reliability from the SN ratio calculation value from among the systems with the least number of frame errors from the ⁇ system of frame error information output from the frame error number calculation unit 7. Select as output.
- the SN ratio after the RAKE combining is used for reliability determination together with the number of frame errors counted from the CRC decoding result, so that mutual determination factors are combined. This makes it possible to make a strict reliability determination.
- the modified example of the tenth embodiment is a modification of the reliability determining unit of the modified example of the fourth embodiment shown in FIGS. 31A and 31B, and is similar to the third embodiment shown in FIGS. 37A and 37B. It can be configured by replacing the tenth embodiment.
- the second switching switches 11 are set to ON for a data sequence of a predetermined number of frames, and the operation of the fourth embodiment is performed by N systems.
- a weight sequence having high reliability with the number of frames is selected as N ' ⁇ (where N' is a natural number, 1 ⁇ ' ⁇ ).
- N' is a natural number, 1 ⁇ ' ⁇ .
- FIG. 38 is a diagram illustrating a general concept in the fourth to tenth embodiments described above.
- 30 is a despreading unit
- 40 (including 40-1 to 40-N) is a receiving unit
- 50 (including 50-1 to 50-N) is a quality measuring unit.
- Reference numeral 60 denotes a quality comparison / judgment unit
- reference numeral 70 denotes an output switching switch.
- a pilot signal is weighted and averaged using a plurality of predetermined weight sequences to obtain a channel estimation value. Then, the received data is demodulated using the obtained channel estimation value (40), and the reliability of the plurality of demodulated data is determined to select one of the highest quality output data. (50, 60, 70).
- the channel estimation units 120, 220, and 320 in the first to third embodiments can be used as the channel estimation unit 2 in the fourth to tenth embodiments.
- highly accurate channel estimation can be performed by calculating the channel estimation value of the data symbol of the data channel by weighting and averaging the pilot symbol. .
- a data symbol in a slot is divided into a plurality of data symbol sections, a pilot symbol suitable for calculating a channel estimation value of a data symbol in each data symbol section is selected, the pilot symbol is weighted and averaged, and By calculating the channel estimation value of the data symbol in the data symbol section, highly accurate channel estimation can be performed.
- the fading frequency can be determined based on the inner product value of the pilot symbols.
- the absolute synchronous detection can reduce the SNIR required to obtain the required reception quality (reception error rate), and as a result, the transmission power can be reduced. Subscriber capacity can be increased.
- the determination result obtained by the fading frequency determination unit is used to determine not only the weighting factor for channel estimation but also the switching of transmission power control between activation and deactivation and transmission diversity activation and deactivation.
- the transmission characteristics can be further improved by switching the operation of various individual technologies whose parameters (transmission characteristics) are affected by the moving speed of the terminal) or by setting parameters.
- the present invention by directly determining and using a weight sequence effective for a moving speed from reception quality, it is possible not only to improve communication quality but also to reduce transmission power and increase communication capacity. More specifically, the following effects can be obtained.
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Description
Claims
Priority Applications (9)
Application Number | Priority Date | Filing Date | Title |
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KR1020007013628A KR100358034B1 (ko) | 1999-04-02 | 2000-03-31 | 채널 추정 장치 및 방법, 복조 장치 및 방법, 및 페이딩 주파수 판정 장치 및 방법 |
AU34579/00A AU753791B2 (en) | 1999-04-02 | 2000-03-31 | Channel estimation device and method, demodulation device and method, and fading frequency decision device and method |
DE60043377T DE60043377D1 (de) | 1999-04-02 | 2000-03-31 | Kanalschätzungsgerät und -verfahren |
JP2000610142A JP3872647B2 (ja) | 1999-04-02 | 2000-03-31 | チャネル推定装置および方法、復調装置および方法、ならびにフェージング周波数判定装置および方法 |
CA 2333954 CA2333954A1 (en) | 1999-04-02 | 2000-03-31 | Channel estimation device and method, demodulation device and method, and fading frequency decision device and method |
US09/701,705 US7929592B1 (en) | 1999-04-02 | 2000-03-31 | Channel estimation device and method, demodulation device and method, and fading frequency decision device and method |
EP20000913048 EP1089451B1 (en) | 1999-04-02 | 2000-03-31 | Channel estimating device and method |
US11/194,217 US7301991B2 (en) | 1999-04-02 | 2005-08-01 | Fading frequency decision device and method |
US13/033,035 US8295332B2 (en) | 1999-04-02 | 2011-02-23 | Channel estimation device and method, demodulation device and method, and fading frequency decision device and method |
Applications Claiming Priority (6)
Application Number | Priority Date | Filing Date | Title |
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JP11/96804 | 1999-04-02 | ||
JP9680499 | 1999-04-02 | ||
JP34063899 | 1999-11-30 | ||
JP11/340638 | 1999-11-30 | ||
JP2000082929 | 2000-03-23 | ||
JP2000/82929 | 2000-03-23 |
Related Child Applications (3)
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US09/701,705 A-371-Of-International US7929592B1 (en) | 1999-04-02 | 2000-03-31 | Channel estimation device and method, demodulation device and method, and fading frequency decision device and method |
US11/194,217 Division US7301991B2 (en) | 1999-04-02 | 2005-08-01 | Fading frequency decision device and method |
US13/033,035 Continuation US8295332B2 (en) | 1999-04-02 | 2011-02-23 | Channel estimation device and method, demodulation device and method, and fading frequency decision device and method |
Publications (1)
Publication Number | Publication Date |
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WO2000060761A1 true WO2000060761A1 (fr) | 2000-10-12 |
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Family Applications (1)
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PCT/JP2000/002105 WO2000060761A1 (fr) | 1999-04-02 | 2000-03-31 | Dispositif et procede d'estimation de voie, dispositif et procede de demodulation, et dispositif et procede pour definir la frequence des evanouissements |
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US (3) | US7929592B1 (ja) |
EP (9) | EP2146468B1 (ja) |
JP (5) | JP3872647B2 (ja) |
KR (1) | KR100358034B1 (ja) |
CN (1) | CN1270445C (ja) |
AU (1) | AU753791B2 (ja) |
CA (3) | CA2471124C (ja) |
DE (4) | DE60043377D1 (ja) |
MY (2) | MY138261A (ja) |
WO (1) | WO2000060761A1 (ja) |
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ABETA,S ET AL: "The Performance of Channel estimation method using Adaptive Weighted Multi-Symbol Averaging (WMSA) with Pilot Channel in DS-CDMA", TECHNICAL REPORT OF IEICE, vol. 98, no. 21, April 1998 (1998-04-01), KANAGAWA, pages 67 - 74, XP002929086 * |
See also references of EP1089451A4 * |
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US7308020B2 (en) | 2002-02-21 | 2007-12-11 | Ntt Docomo, Inc. | System and method of interference suppression |
US7965796B2 (en) | 2002-02-27 | 2011-06-21 | Freescale Semiconductor, Inc. | Channel estimation in a radio receiver |
US7583739B2 (en) | 2004-05-13 | 2009-09-01 | Ntt Docomo, Inc. | Channel estimation device, channel estimation method, and wireless receiver |
US7548595B2 (en) | 2004-06-17 | 2009-06-16 | Fujitsu Limited | Apparatus and method for fading frequency estimation |
JP2007006105A (ja) * | 2005-06-23 | 2007-01-11 | Nec Corp | 無線基地局及びドップラー周波数推定方法 |
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