JP2004159077A - Data reception device and data reception method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data reception device capable of following fluctuation of a transmission path characteristic in a slot and improving reception performance. <P>SOLUTION: A TSC transmission path estimation part 108, a tip TB transmission path estimation part 110 and a rear end TB transmission path estimation part 112 estimate the transmission path characteristics in a TSC zone A, a tip TB zone B and a rear end TB zone C. Estimation parts for number of taps 114, 116 and 118 estimate the number of taps in the respective zones based on the respective estimated transmission path characteristics. A first half data demodulation control part 120 and a latter data demodulation control part 122 generate control signals for controlling a demodulation processing in a demodulation part 124 based on the number of the estimated taps. The demodulation part 124 demodulates a reception signal obtained from a reception signal memory 106 in accordance with the respective generated control signals. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a data receiving device and a data receiving method.
[0002]
[Prior art]
Generally, a data receiving apparatus (for example, a mobile station) used in a mobile communication system stores in advance known signals included in a plurality of slots constituting a received signal, and determines a correlation between the received signal and the known signal. The channel characteristics are estimated by the calculation, and the number of taps and the tap coefficient used in the demodulation unit that performs the demodulation process (for example, the adaptive equalization process) are estimated based on the estimated channel characteristics.
[0003]
A conventional data receiving apparatus first obtains a correlation value between a received signal and a known signal, compares the magnitude of the obtained correlation value with a predetermined threshold value, and determines whether or not positions indicating correlation values equal to or higher than the threshold value are concentrated. Is determined, the number of taps and tap coefficients are estimated based on the determination result, and the received signal is demodulated (for example, see Patent Document 1).
[0004]
[Patent Document 1]
JP-A-8-56186 (pages 5-7)
[0005]
[Problems to be solved by the invention]
However, the conventional data receiving apparatus estimates the number of taps used in the demodulation unit for each slot. In other words, once the number of taps and the tap coefficient are estimated, the number of taps and the tap coefficient are not re-estimated within the slot, so that as will be described in detail later, if the propagation path characteristics fluctuate within the period of one slot, On the other hand, the conventional data receiving apparatus cannot follow the fluctuation of the propagation path characteristic during the demodulation process. Therefore, there is a certain limit in improving the reception performance.
[0006]
The present invention has been made in view of the above points, and provides a data receiving apparatus and a data receiving method that can follow a variation in propagation path characteristics in each slot and improve reception performance. The purpose is to:
[0007]
[Means for Solving the Problems]
The data receiving apparatus according to the present invention includes: a demodulation unit configured to demodulate a received signal including a plurality of slots each including a plurality of known signals; and a propagation path at a plurality of points in the slot using the plurality of known signals included in each slot. A configuration including a channel characteristic estimating unit for estimating characteristics and a control unit for controlling demodulation processing in the demodulating unit based on the estimated channel characteristics is adopted.
[0008]
According to this configuration, using the plurality of known signals included in the plurality of slots, the channel characteristics at a plurality of points in the slot are estimated using the plurality of known signals, and the channel characteristics at the plurality of points are estimated. In order to estimate the propagation path characteristics used for controlling the demodulation processing a plurality of times within one slot, it follows the fluctuation of the propagation path characteristics in the slot during the demodulation processing. And the reception performance can be improved.
[0009]
The data receiving apparatus of the present invention, in the above configuration, wherein the control means has a tap number estimating means for estimating the number of taps at each corresponding point based on the estimated propagation path characteristics. The demodulation process is controlled based on the number.
[0010]
According to this configuration, the number of taps at each corresponding point is estimated based on each estimated propagation path characteristic, and demodulation processing is controlled based on the estimated number of taps. Since the number of taps to be used is estimated a plurality of times within the period of one slot, it is possible to follow the fluctuation of the propagation path characteristics in the slot during the demodulation processing and improve the reception performance.
[0011]
The data receiving device of the present invention, in the above-described configuration, wherein the control unit further includes a monitoring unit that monitors a variation in the estimated number of taps, and the tap number estimation unit is configured to perform a monitoring based on a monitoring result of the monitoring unit. A configuration for estimating the number of taps is employed.
[0012]
According to this configuration, the fluctuation of the estimated number of taps is monitored by, for example, a statistical method, and the number of taps is estimated based on the monitoring result. When there is no change in the propagation path characteristics, the estimation range of the number of taps can be limited to estimate the number of taps, and the amount of calculation when estimating the number of taps can be reduced.
[0013]
In the data receiving apparatus of the present invention, in the above configuration, the control unit measures a main wave detection unit that detects a main wave of the received signal based on the estimated propagation path characteristics, and measures a level of the detected main wave. It has a level measuring means and a monitoring means for monitoring the fluctuation of the measured level, and adopts a configuration for controlling demodulation processing based on the monitoring result of the monitoring means.
[0014]
According to this configuration, the main wave of the received signal is detected based on the propagation path characteristics, the level of the detected main wave is measured, and the fluctuation of the measured level is monitored, for example, by a statistical method. Since the demodulation process is controlled based on the monitoring result, the demodulation process can be controlled according to the fluctuation of the main wave level, and the demodulation process follows the fluctuation of the propagation path characteristic in the slot. And the reception performance can be improved.
[0015]
In the data receiving apparatus of the present invention, in the above configuration, the control unit measures a main wave detection unit that detects a main wave of the received signal based on the estimated propagation path characteristics, and measures a phase of the detected main wave. It has a phase measuring means and a monitoring means for monitoring the fluctuation of the measured phase, and adopts a configuration for controlling demodulation processing based on the monitoring result of the monitoring means.
[0016]
According to this configuration, the main wave of the received signal is detected based on the propagation path characteristics, the phase of the detected main wave is measured, and the fluctuation of the measured phase is monitored by, for example, a statistical method. Since the demodulation process is controlled based on the monitoring result, the demodulation process can be controlled according to the fluctuation of the main wave level, and the demodulation process follows the fluctuation of the propagation path characteristic in the slot. And the reception performance can be improved.
[0017]
In the data receiving device of the present invention, in the above configuration, the control unit may include a tap number estimating unit configured to estimate a tap number at each corresponding point based on the estimated channel characteristics, Tap number fluctuation monitoring means for monitoring, main wave detection means for detecting the main wave of the received signal based on the estimated propagation path characteristics, level measurement means for measuring the level of the detected main wave, Phase measuring means for measuring the phase of the main wave, level fluctuation monitoring means for monitoring the fluctuation of the measured level, and phase fluctuation monitoring means for monitoring the fluctuation of the measured phase, the tap number estimation Means for estimating the number of taps based on the monitoring result of the tap number variation monitoring means, and the control means includes the estimated number of taps, the monitoring result of the level variation monitoring means, and the phase variation. A configuration for controlling the demodulation process on the basis of the monitoring result of the viewing means.
[0018]
According to this configuration, the variation in the number of taps estimated based on the channel characteristics is monitored, for example, by a statistical method, the number of taps is estimated based on the monitoring result, and the tap number is estimated based on the channel characteristics. Detect the main wave of the received signal, measure the level and phase of the detected main wave, monitor the fluctuation of the measured level and phase, for example, in a statistical manner, respectively, and estimate the number of taps and level. Since the demodulation process is controlled based on the fluctuation monitoring result and the phase fluctuation monitoring result, the estimation range of the number of taps is limited, for example, when the fluctuation of the channel characteristics is small or when there is no fluctuation of the channel characteristics. In this way, the number of taps can be estimated, and the amount of arithmetic processing when estimating the number of taps can be reduced. In addition, demodulation processing can be controlled in accordance with fluctuations in the level and phase of the main wave, and during demodulation processing, it is possible to follow fluctuations in propagation path characteristics within a slot, thereby improving reception performance. can do.
[0019]
The data receiving method according to the present invention includes a demodulating step of demodulating a received signal composed of a plurality of slots each including a plurality of known signals, and a method of propagating at a plurality of points in the slot using the plurality of known signals included in each slot. A channel characteristic estimating step of estimating channel characteristics and a control step of controlling demodulation processing in the demodulation step based on the channel characteristics estimated in the channel characteristic estimating step are provided.
[0020]
According to this method, a plurality of known signals included in a plurality of slots are used, and channel characteristics at a plurality of points in the slot are estimated using the plurality of known signals. In order to estimate the propagation path characteristics used for controlling the demodulation processing a plurality of times within one slot, it follows the fluctuation of the propagation path characteristics in the slot during the demodulation processing. And the reception performance can be improved.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
The gist of the present invention is to estimate propagation path characteristics at a plurality of points in a slot using a plurality of known signals respectively included in a plurality of slots constituting a received signal, so that demodulation processing can be performed within a slot. It is to improve the receiving performance by following the fluctuation of the propagation path characteristics.
[0022]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Here, a data receiving apparatus (for example, a mobile station) applied to a mobile communication system of the GSM (Global Systems for Mobile communications) system will be described.
[0023]
(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of the data receiving apparatus according to Embodiment 1 of the present invention.
[0024]
The data receiving apparatus 100 shown in FIG. 1 includes an antenna 102, a radio processing unit 104, a received signal memory 106, a TSC channel estimating unit 108, a leading TB channel estimating unit 110, a trailing TB channel estimating unit 112, and a tap number estimating unit. Units 114, 116 and 118, a first half data demodulation control unit 120, a second half data demodulation control unit 122 and a demodulation unit 124.
[0025]
The antenna 102 receives a signal transmitted from a base station (not shown), and the wireless processing unit 104 down-converts the received signal from an RF (Radio Frequency) signal to a baseband signal. The down-converted received signal is output to received signal memory 106.
[0026]
Here, a frame configuration of a signal received by the antenna 102 will be described. FIG. 2 is a diagram for explaining a signal frame structure used in a GSM mobile communication system.
[0027]
The signal illustrated in FIG. 2 is configured by a sequence of a TDMA (Time Division Multiple Access) frame having a predetermined time length. One TDMA frame is composed of a predetermined number (for example, eight) of slots having the same time length and configuration. One slot is constituted by a training sequence code (TSC: Training Sequence Code) 150, tail bits (TB: Tail Bit) 152, 154, data 156, 158, and a guard interval 160.
[0028]
The TSC 150 is a known signal having a predetermined code length (for example, 26 bits), and a section A (hereinafter, referred to as a “TSC section”) A of the TSC 150 is located at the center of the slot. Each of the TBs 152 and 154 is a known signal having a predetermined code length (for example, 3 bits), and a section of the TB 152 (hereinafter, referred to as a “leading TB section”) is located at the leading end of the slot, C (hereinafter referred to as a “rear end TB section”) is located at the rear end of the slot. The data 156 is data demodulated by the demodulation unit 124, and a section D of the data 156 (hereinafter, referred to as “first half data section”) is located between the leading TB section B and the TSC section A. The data 158 is data demodulated by the demodulation unit 124, and a section E of the data 158 (hereinafter, referred to as a “second half data section”) is located between the TSC section A and the rear end TB section C. The guard interval 160 indicates a boundary with the subsequent slot, and a section F of the guard interval 160 is inserted between the rear end TB section C and the subsequent slot.
[0029]
TSC propagation path estimating section 108 stores in advance the same signal as TSC 150 (hereinafter referred to as “stored TSC”), and obtains a correlation between stored TSC and a received signal stored in received signal memory 106, TSC (hereinafter, referred to as “received TSC”) 150 in the received signal is detected, and a tap coefficient is estimated as a propagation path characteristic in TSC section A. Specifically, the estimated tap coefficients are, for example, tap coefficients when assuming that 6 taps are used in demodulation section 124, tap coefficients when assuming that 5 taps are used, and 4 taps when assuming that 5 taps are used. Tap coefficients when it is assumed that three taps are used, and tap coefficients when it is assumed that three taps are used and when two taps are used. Then, the estimated tap coefficient is output to tap number estimation section 114. Further, TSC channel estimating section 108 outputs synchronization information obtained by detection of reception TSC 150 to reception signal memory 106.
[0030]
The reception signal memory 106 temporarily stores the reception signal down-converted by the wireless processing unit 104. Further, received signal memory 106 acquires the synchronization information output from TSC channel estimating section 108, adds this synchronization information to the received signal, and outputs it to demodulation section 124.
[0031]
The leading end TB propagation path estimating section 110 stores in advance the same signal as the TB 152 (hereinafter referred to as “stored leading end TB”), and determines the correlation between the stored leading end TB and the received signal stored in the received signal memory 106. By taking this, TB (hereinafter referred to as “receiving end TB”) 152 in the received signal is detected, and tap coefficients are estimated as propagation path characteristics in end TB section B. Specific examples of the estimated tap coefficients are the same as the tap coefficients estimated by the TSC channel estimating unit 108. Then, the estimated tap coefficient is output to tap number estimating section 116.
[0032]
The rear end TB propagation path estimating section 112 previously stores the same signal as the TB 154 (hereinafter referred to as “storage rear end TB”), and stores the same signal as the storage rear end TB and the reception signal stored in the reception signal memory 106. , A TB (hereinafter referred to as “reception rear end TB”) 154 in the received signal is detected, and a tap coefficient is estimated as a propagation path characteristic in the rear end TB section C. Specific examples of the estimated tap coefficients are the same as the tap coefficients estimated by the TSC channel estimation unit 108 and the leading TB channel estimation unit 110, respectively. Then, the estimated tap coefficient is output to tap number estimation section 118.
[0033]
Here, as a basis of the effect of the present invention, a description will be given of a change in propagation path characteristics. FIG. 3 is a diagram for explaining fade duration in a GSM mobile communication system. However, the transmission frequency of the signal is 960 MHz, and the moving speed of the mobile station is 250 km / h. The fade duration is known as one of the indices representing the propagation path characteristics, and indicates an average value of a time when a signal level (for example, a power level) of a certain path continues to fall by a predetermined value or more from an average level of a received signal. It is.
[0034]
As shown in FIG. 3, the fade duration when the signal level of a certain path is lower than the average level by 20 dB or more (level difference: -20 dB) is 139 μs. In general, since a signal slot used in a GSM mobile communication system has a time length of 400 μs or more, it can be understood that the propagation path characteristics can fluctuate in a period shorter than one slot period. Therefore, while the conventional data receiving apparatus that estimates the propagation path characteristics and estimates the number of taps only once within the period of one slot cannot follow the fluctuation of the propagation path characteristics within the slot, the present embodiment does not. In the data receiving apparatus according to the embodiment, by estimating the propagation path characteristic a plurality of times within one slot period, it is possible to follow the fluctuation of the propagation path characteristic within the slot and to improve the reception performance.
[0035]
Tap number estimating section 114 estimates the number of taps based on the tap coefficient of TSC section A estimated by TSC channel estimating section 108. Then, tap number estimation section 114 outputs the estimated number of taps corresponding to TSC section A to first half data demodulation control section 120 and second half data demodulation control section 122.
[0036]
Here, a specific operation of estimating the number of taps based on the estimated tap coefficients will be described. First, tap number estimating section 114 generates a first replica of the received signal using storage TSC and tap coefficients estimated assuming that the number of taps used in demodulating section 124 is six. . Similarly, the tap number estimating unit 114 estimates the tap coefficient estimated on the assumption that the number of taps used in the demodulation unit 124 is 5, and the case where the number of taps used in the demodulation unit 124 is 4. And the tap coefficient estimated by assuming that the number of taps used by the demodulation unit 124 is three and the tap number estimated by assuming that the number of taps used by the demodulation unit 124 is two , And the second to fifth replicas of the received signal are generated using each of the estimated tap coefficients and the stored TSC. Then, using each of the generated first to fifth replicas and the received signal, an error corresponding to each of the two to six tap numbers is calculated. Then, of the two to six tap numbers, the one with the smallest corresponding error is determined as the tap number corresponding to TSC section A.
[0037]
Tap number estimation section 116 estimates the number of taps based on the tap coefficient of tip TB section B estimated by tip TB propagation path estimation section 110. The specific operation of estimating the number of taps is the same as that of the tap number estimating unit 114 described above. Then, the number of taps corresponding to the leading end TB section B estimated in this way is output to first half data demodulation control section 120.
[0038]
Tap number estimation section 118 estimates the number of taps based on the tap coefficient of rear end TB section C estimated by rear end TB propagation path estimation section 112. The specific operation of estimating the number of taps is the same as that of the above-described tap number estimation units 114 and 116. Then, the number of taps corresponding to rear end TB section C thus estimated is output to second half data demodulation control section 122.
[0039]
Note that the range of the number of taps estimated by the tap number estimating units 114, 116, and 118 (hereinafter referred to as “estimation range”) is determined in advance from two to six. This is why the TSC channel estimating unit 108, the leading TB channel estimating unit 110, and the trailing TB channel estimating unit 112 estimate tap coefficients assuming the number of taps from 2 to 6.
[0040]
However, the estimation range is not limited to the above two to six. For example, the tap number estimating units 114, 116, and 118 may estimate the number of taps in an estimation range of two to seven. In this case, the TSC channel estimating unit 108, the leading TB channel estimating unit 110, and the trailing TB channel estimating unit 112 estimate tap coefficients assuming the number of taps from two to seven.
[0041]
First-half data demodulation control section 120 demodulates using the number of taps corresponding to TSC section A estimated by tap number estimation section 114 and the number of taps corresponding to leading TB section B estimated by tap number estimation section 116. A control signal for controlling the demodulation processing in section 124 is generated, and the generated control signal is output to demodulation section 124.
[0042]
Specifically, the number of taps corresponding to the TSC section A and the number of taps corresponding to the leading TB section B are compared, and the demodulation unit 124 controls the demodulation process to use the larger number of taps. A control signal is generated and output to demodulation section 124. For example, if the number of taps corresponding to the leading TB section B is 3 and the number of taps corresponding to the TSC section A is 5, a demodulation process in the demodulation section 124 generates a control signal for using 5 taps and demodulates. Output to the unit 124.
[0043]
Further, the first half data demodulation control section 120 adjusts the step size of the adaptive algorithm in the demodulation processing in demodulation section 124 in accordance with the change in the number of taps corresponding to TSC section A and the number of taps corresponding to head TB section B. A control signal for changing a tap coefficient in the demodulation unit (correction width) is generated. Specifically, for example, when the number of taps corresponding to the leading TB section B is three and the number of taps corresponding to the TSC section A is five, an increase in the number of taps to improve the reception state sooner. Only increase the step size. If the number of taps corresponding to the leading TB section B is 5 and the number of taps corresponding to the TSC section A is 3, the step size is reduced by the reduced number of taps to more reliably improve the reception state. Make it smaller. Then, a control signal for changing the step size is generated and output to the demodulation section 124 as described above.
[0044]
The second half data demodulation control unit 122 uses the number of taps corresponding to the TSC section A estimated by the tap number estimation unit 114 and the number of taps corresponding to the rear end TB section C estimated by the tap number estimation unit 118. A control signal for controlling the demodulation processing in demodulation section 124 is generated, and the generated control signal is output to demodulation section 124. The specific method of generating the control signal is the same as that of the first half data demodulation control section 120.
[0045]
Demodulation section 124 demodulates the reception signal obtained from reception signal memory 106 according to the control signals obtained from first half data demodulation control section 120 and second half data demodulation control section 122. More specifically, the data 156 included in the first half data section D is demodulated according to the control signal obtained from the first half data demodulation control section 120, and the second half is demodulated according to the control signal obtained from the second half data demodulation control section 122. The data 158 included in the data section E is demodulated. Then, demodulation section 124 outputs the demodulated data thus obtained.
[0046]
Next, the operation of the data receiving apparatus 100 having the above configuration will be described.
[0047]
First, the radio processing unit 104 down-converts a signal received by the antenna 102 from an RF signal to a baseband signal.
[0048]
Then, the reception signal memory 106 temporarily stores the reception signal down-converted by the wireless processing unit 104.
[0049]
The TSC channel estimating unit 108 detects the received TSC 150 in the received signal by correlating the stored TSC with the received signal stored in the received signal memory 106, and determines the tap coefficient as the channel characteristic in the TSC section A. Is estimated. Then, the estimated tap coefficient is output to tap number estimation section 114. Further, TSC channel estimating section 108 outputs synchronization information obtained by detection of reception TSC 150 to reception signal memory 106.
[0050]
In addition, similarly to the TSC channel estimation unit 108, the tip TB channel estimation unit 110 uses the stored tip TB and the reception signal stored in the reception signal memory 106 to generate tap coefficients as the channel characteristics of the tip TB section B. Is estimated. Then, the estimated tap coefficient is output to tap number estimating section 116.
[0051]
Further, similarly to the TSC channel estimating section 108 and the leading TB channel estimating section 110, the rear end TB channel estimating section 112 uses the stored rear end TB and the received signal stored in the received signal memory 106 to perform A tap coefficient is estimated as a propagation path characteristic of the end TB section C. Then, the estimated tap coefficient is output to tap number estimation section 118.
[0052]
Then, the received signal memory 106 adds the synchronization information obtained from the TSC channel estimating section 108 to the received signal and outputs it to the demodulation section 124.
[0053]
Then, tap number estimating section 114 estimates the number of taps based on the tap coefficient of TSC section A estimated by TSC channel estimating section 108. Then, it outputs the estimated number of taps corresponding to TSC section A to first data demodulation control section 120 and second data demodulation control section 122.
[0054]
Further, tap number estimating section 116 estimates the number of taps based on the tap coefficient of tip TB section B estimated by tip TB propagation path estimating section 110. Then, it outputs the estimated number of taps corresponding to tip TB section B to first-half data demodulation control section 120.
[0055]
Further, tap number estimating section 118 estimates the number of taps based on the tap coefficient of rear end TB section C estimated by rear end TB propagation path estimating section 112. Then, the estimated number of taps corresponding to rear end TB section C is output to second half data demodulation control section 122.
[0056]
Then, the first half data demodulation control section 120 uses the number of taps corresponding to the TSC section A estimated by the tap number estimation section 114 and the number of taps corresponding to the leading TB section B estimated by the tap number estimation section 116, A control signal for controlling demodulation processing in demodulation section 124 is generated and output to demodulation section 124.
[0057]
Also, the second half data demodulation control section 122 uses the number of taps corresponding to the TSC section A estimated by the tap number estimation section 114 and the number of taps corresponding to the rear end TB section C estimated by the tap number estimation section 118. , And generates a control signal for controlling the demodulation processing in the demodulation unit 124 and outputs the control signal to the demodulation unit 124.
[0058]
Then, demodulation section 124 demodulates the reception signal obtained from reception signal memory 106 according to the control signal obtained from first half data demodulation control section 120 and the control signal obtained from second half data demodulation control section 122.
[0059]
As described above, according to the present embodiment, a plurality of points in a slot using storage TSC, storage leading end TB, and storage trailing end TB (ie, TSC section A, leading end TB section B, and trailing end TB section C). , And controls the demodulation processing in demodulation section 124 based on the propagation path characteristics at the plurality of points, that is, estimates the propagation path characteristics used for controlling the demodulation processing a plurality of times within one slot period. Therefore, it is possible to follow the fluctuation of the propagation path characteristics in the slot during the demodulation processing, and to improve the reception performance. Further, the number of taps at each corresponding point is estimated based on the estimated propagation path characteristics, and the demodulation unit 124 controls the demodulation process based on the estimated number of taps. Since the estimated channel characteristics are estimated a plurality of times within the period of one slot, it is possible to follow the fluctuation of the channel characteristics in the slot during the demodulation process, and to improve the reception performance.
[0060]
Although the data receiving apparatus 100 according to Embodiment 1 has a configuration applied to a GSM mobile communication system and has been described to receive a signal having a frame configuration shown in FIG. It is not limited to application only. The data receiving apparatus can be applied to any type of mobile communication system as long as the mobile communication system has a frame configuration in which a plurality of known signals are included in one slot.
[0061]
(Embodiment 2)
FIG. 4 is a block diagram showing a configuration of the data receiving apparatus according to Embodiment 2 of the present invention. The data receiving device 200 shown in FIG. 4 has the same basic configuration as the data receiving device 100 shown in FIG. 1, and the same components are denoted by the same reference characters and description thereof will be omitted. I do.
[0062]
A feature of the second embodiment is that channel characteristics at a plurality of points within one slot period are estimated, and a change in the number of taps estimated based on each channel characteristic is monitored. For this purpose, the data receiving apparatus 200 shown in FIG. 2 has tap number estimating sections 114a, 116a, 118a instead of the tap number estimating sections 114, 116, 118 in the data receiving apparatus 100, and the tap number variation monitoring section 202, 204 and 206.
[0063]
Tap number estimation section 114a estimates the number of taps based on the tap coefficient of TSC section A estimated by TSC channel estimation section 108 and the instruction signal obtained from tap number variation monitoring section 202. A specific method for estimating the number of taps will be described later. Then, it outputs the estimated number of taps to tap number variation monitoring section 202, first half data demodulation control section 120, and second half data demodulation control section 122.
[0064]
The tap number estimating section 116a estimates the tap number based on the tap coefficient of the distal end TB section B estimated by the distal end TB propagation path estimating section 110 and the instruction signal obtained from the tap number variation monitoring section 204. The specific method of estimating the number of taps is the same as that of tap number estimating section 114a. Then, it outputs the estimated number of taps to tap number variation monitoring section 204 and first half data demodulation control section 120.
[0065]
Tap number estimation section 118a estimates the number of taps based on the tap coefficient of rear end TB section C estimated by rear end TB propagation path estimation section 112 and the instruction signal obtained from tap number fluctuation monitoring section 204. The specific method of estimating the number of taps is the same as that of the tap number estimating units 114a and 116a. Then, it outputs the estimated number of taps to tap number variation monitoring section 206 and second half data demodulation control section 122.
[0066]
The tap number variation monitoring unit 202 monitors the variation in the number of taps estimated by the tap number estimation unit 114a over a plurality of slots in a statistical manner. Then, an instruction signal as a monitoring result is generated and output to tap number estimating section 114a.
[0067]
Specifically, the number of taps is estimated in a reference estimation range (for example, 2 to 6 estimation ranges), and a specific number of taps (for example, 3 If the estimated ratio of taps is less than a predetermined value (for example, 90%), the tap number fluctuation monitoring unit 202 determines that the fluctuation of the propagation path characteristic is large, and continues estimating the number of taps in the reference estimation range. An instruction signal to be output is output to tap number estimation section 114a.
[0068]
In addition, the number of taps is estimated in a reference estimation range (for example, two to six estimation ranges), and a specific number of taps (for example, three taps) in the reference estimation range is determined in a plurality of slots. When the estimated ratio is equal to or greater than a predetermined value (for example, 90%), tap number variation monitoring section 202 determines that the variation in the propagation path characteristic is small, and sets a restricted estimation range (for example, a range that is more limited than the reference estimation range) (The estimation range from two to four) and outputs an instruction signal for estimating the number of taps to the tap number estimating unit 114a.
[0069]
Further, the number of taps is estimated in the limited estimation range (for example, two to four estimation ranges), and the center tap number (for example, three taps) of the limited estimation range is estimated in a plurality of slots. If the calculated ratio is equal to or greater than a predetermined value (for example, 90%), the tap number variation monitoring unit 202 determines that there is no variation in the propagation path characteristics, and taps an instruction signal to continue estimating the number of taps in the limited estimation range. Output to number estimating section 114a.
[0070]
Further, the number of taps is estimated in the limited estimation range (for example, two to four estimation ranges), and the center tap number (for example, three taps) of the limited estimation range is estimated in a plurality of slots. If the ratio is less than a predetermined value (for example, 90%), the tap number variation monitoring unit 202 determines that there is a variation in the propagation path characteristic, and returns from the limited estimation range to the reference estimation range to estimate the number of taps. An instruction signal to be output is output to tap number estimation section 114a.
[0071]
The unit of the period for monitoring the change in the number of taps is not limited to a plurality of slots, and monitoring may be performed over a plurality of frames.
[0072]
Further, the tap number variation monitoring unit 204 monitors the variation in the number of taps estimated by the tap number estimation unit 116a over a plurality of slots in a statistical manner. Then, an instruction signal as a monitoring result is generated and output to tap number estimating section 116a. A specific monitoring method is the same as that of the tap number fluctuation monitoring unit 202.
[0073]
Further, the tap number variation monitoring unit 206 monitors the variation in the number of taps estimated by the tap number estimation unit 118a over a plurality of slots in a statistical manner. Then, an instruction signal as a monitoring result is generated and output to tap number estimating section 118a. The specific monitoring method is the same as that of the tap number fluctuation monitoring units 202 and 204.
[0074]
Next, the operation of monitoring the change in the number of taps in data receiving apparatus 200 having the above configuration will be described.
[0075]
The tap number estimation unit 114a estimates the number of taps in the normal estimation range or the limited estimation range based on the tap coefficient of the TSC section A estimated by the TSC channel estimation unit 108. Then, it outputs the estimated number of taps to tap number variation monitoring section 202, first half data demodulation control section 120, and second half data demodulation control section 122.
[0076]
Then, the tap number variation monitoring unit 202 monitors the variation in the number of taps corresponding to the TSC section A estimated by the tap number estimation unit 114a over a plurality of slots, and issues an instruction signal for estimating the number of taps within the normal estimation range. An instruction signal for estimating the number of taps in the limited estimation range is generated as a monitoring result and output to the tap number estimating unit 114a.
[0077]
The operations in tap number estimating section 116a and tap number fluctuation monitoring section 204 and the operations in tap number estimating section 118a and tap number fluctuation monitoring section 206 are the same as the operations in tap number estimating section 114a and tap number fluctuation monitoring section 202. Corresponding to the leading end TB section B and the trailing end TB section C, respectively.
[0078]
As described above, according to the present embodiment, the change in the number of taps is monitored by a statistical method, and the number of taps is estimated based on the monitoring result of the tap number change monitoring units 202, 204, and 206. When the fluctuation of the channel characteristics is small or when there is no fluctuation of the propagation path characteristics, the estimation range of the number of taps can be limited and the number of taps can be estimated, and the amount of computation when estimating the number of taps is reduced. can do.
[0079]
In the present embodiment, tap number variation monitoring sections 202, 204, and 206 output instruction signals to tap number estimating sections 114a, 116a, and 118a, respectively. A configuration may be adopted in which the signals are output to the channel estimating unit 108, the leading TB channel estimating unit 110, and the trailing TB channel estimating unit 112, respectively. In this case, the tap number variation monitoring units 202, 204, and 206 not only generate the above-described instruction signal for estimating the number of taps, but also generate an instruction signal for estimating the tap coefficient.
[0080]
Specifically, the TSC channel estimation unit 108 estimates tap coefficients in a reference estimation range (for example, two to six estimation ranges), and the tap number estimation unit 114a performs estimation in a plurality of slots. If the rate of estimating the specific number of taps (for example, 3 taps) within the reference estimation range is less than a predetermined value (for example, 90%), the tap number variation monitoring unit 202 determines that the variation in the channel characteristics is large. Then, an instruction signal for continuing estimation of tap coefficients in the reference estimation range is generated and output to TSC channel estimating section 108.
[0081]
In this case, the TSC channel estimation unit 108 continues estimating the tap coefficients in the reference estimation range according to the instruction signal obtained from the tap number variation monitoring unit 202. For example, TSC channel estimating section 108 determines that tap coefficients when demodulating section 124 uses 6 taps are used, tap coefficients when 5 taps are used, and 4 taps are used. Then, a tap coefficient when three taps are assumed to be used and a tap coefficient when two taps are assumed to be used are estimated.
[0082]
Further, the tap coefficients are estimated in the reference estimation range (for example, two to six estimation ranges) by the TSC channel estimation unit 108, and the reference estimation range in a plurality of slots is determined by the tap number estimation unit 114a. If the ratio of the estimated number of taps (for example, 3 taps) is equal to or greater than a predetermined value (for example, 90%), the tap number variation monitoring unit 202 determines that the variation in the propagation path characteristics is small, An instruction signal for estimating tap coefficients is generated by changing to a limited estimation range (for example, two to four estimation ranges) whose range is more limited than the reference estimation range, and is output to the TSC channel estimation unit 108. .
[0083]
In this case, the TSC channel estimation unit 108 estimates tap coefficients in the limited estimation range according to the instruction signal obtained from the tap number variation monitoring unit 202. For example, TSC propagation path estimating section 108 assumes that tap coefficients in demodulation section 124 when four taps are used are used, tap coefficients in the case where three taps are used and two taps are used. Then, the tap coefficient is estimated.
[0084]
Furthermore, the TSC channel estimation unit 108 estimates tap coefficients in a limited estimation range (for example, two to four estimation ranges), and the tap estimation unit 114a estimates the tap estimation range in a plurality of slots. If the ratio of the estimated number of center taps (for example, three taps) is equal to or greater than a predetermined value (for example, 90%), the tap number variation monitoring unit 202 determines that there is no variation in the propagation path characteristics, and Is generated and output to TSC channel estimating section 108.
[0085]
In this case, the TSC channel estimation unit 108 continues to estimate tap coefficients in the limited estimation range according to the instruction signal obtained from the tap number variation monitoring unit 202. For example, TSC propagation path estimating section 108 assumes that tap coefficients in demodulation section 124 when four taps are used are used, tap coefficients in the case where three taps are used and two taps are used. Then, the tap coefficient is estimated.
[0086]
Furthermore, the TSC channel estimation unit 108 estimates tap coefficients in a limited estimation range (for example, two to four estimation ranges), and the tap estimation unit 114a estimates the tap estimation range in a plurality of slots. If the ratio of the estimated number of center taps (for example, 3 taps) is less than a predetermined value (for example, 90%), the tap number change monitoring unit 202 determines that there is a change in the propagation path characteristic, and determines the limit estimation range. And returns to the reference estimation range to generate an instruction signal for estimating the tap coefficient, and outputs the instruction signal to the TSC channel estimation unit 108.
[0087]
In this case, the TSC channel estimation unit 108 estimates tap coefficients in the reference estimation range according to the instruction signal obtained from the tap number variation monitoring unit 202. For example, TSC channel estimating section 108 determines that tap coefficients when demodulating section 124 uses 6 taps are used, tap coefficients when 5 taps are used, and 4 taps are used. Then, a tap coefficient when three taps are assumed to be used and a tap coefficient when two taps are assumed to be used are estimated.
[0088]
The instruction signal generating operation of the tap number fluctuation monitoring units 204 and 206 is the same as that of the tap number fluctuation monitoring unit 202. The tap coefficient estimation operations of the leading TB propagation path estimating section 110 and the trailing TB propagation path estimating section 112 are the same as those of the TSC propagation path estimating section 108.
[0089]
As described above, by adopting a configuration in which tap number variation monitoring sections 202, 204, and 206 output instruction signals to TSC channel estimation section 108, leading TB channel estimation section 110, and trailing TB channel estimation section 112, respectively. In the case where the fluctuation of the propagation path characteristic is small or the fluctuation of the propagation path characteristic does not occur, the estimation range of the tap coefficient can be limited and the estimation of the tap coefficient can be performed, thereby reducing the amount of calculation processing when estimating the tap coefficient. can do.
[0090]
Further, the configuration of the data receiving apparatus according to Embodiment 2 is as shown in FIG. 4, but it may have a configuration as shown in FIG. 5 as a modification. The data receiving apparatus 200 shown in FIG. 4 monitors the change in the number of taps based on the propagation path characteristics at a plurality of points in one slot (that is, the TSC section A, the leading TB section B, and the trailing TB section C). Data receiving apparatus 250 shown in FIG. 5 has a configuration for monitoring a change in the number of taps based on the propagation path characteristic at one point in one slot (for example, TSC section A), A demodulation control unit 252 is provided instead of the demodulation control unit 120 and the second half data demodulation control unit 122, and a demodulation unit 254 is provided instead of the demodulation unit 124.
[0091]
Demodulation control section 252 reduces the number of taps corresponding to TSC section A estimated by tap number estimation section 114a by a method similar to first half data demodulation control section 120 and second half data demodulation control section 122 in data receiving apparatus 200. Based on the control signal obtained from demodulation control section 252, a control signal for controlling demodulation processing in demodulation section 254 is output based on the same method as demodulation section 124 in data receiving apparatus 200. The received signal obtained from the received signal memory 106 is demodulated.
[0092]
As described above, even in the data receiving apparatus 250 illustrated in FIG. 5, the estimation of the number of taps can be performed by limiting the estimation range of the number of taps when the variation in the channel characteristics is small or when there is no variation in the channel characteristics. It is possible to reduce the amount of arithmetic processing when estimating the number of taps and tap coefficients.
[0093]
Also, the data receiving apparatus 200 according to Embodiment 2 has a configuration applied to a GSM mobile communication system and has been described to receive a signal having the GSM frame configuration shown in FIG. It is not limited only to the application to the method. The data receiving apparatus can be applied to any type of mobile communication system as long as the mobile communication system has a frame configuration in which a plurality of known signals are included in one slot.
[0094]
(Embodiment 3)
FIG. 6 is a block diagram showing a configuration of a data receiving device according to Embodiment 3 of the present invention. The data receiving apparatus 300 shown in FIG. 6 has the same basic configuration as that of the data receiving apparatus 100 shown in FIG. 1, and the same components are denoted by the same reference numerals and description thereof will be omitted. I do.
[0095]
A feature of the third embodiment is that channel characteristics at a plurality of points within one slot period are estimated, and fluctuation of the main wave level is monitored based on each channel characteristic. For this purpose, data receiving apparatus 300 shown in FIG. 6 includes leading end TB propagation path estimating section 110, trailing end TB propagation path estimating section 112, first half data demodulation control section 120, and second half data demodulation control section 122 in data receiving apparatus 100. , A leading TB propagation path estimating section 110a, a trailing TB propagation path estimating section 112a, a first half data demodulation control section 120a and a second half data demodulation control section 122a, respectively, and a main wave detection section 302, a main wave level It has measuring units 304 and 306 and main wave level fluctuation monitoring units 308, 310 and 312.
[0096]
The main wave detection unit 302 measures the maximum level (for example, the power level) of the received signal using the tap coefficient estimated by the TSC channel estimation unit 108, and determines the phase of the path having the measured maximum level. , The main wave of the received signal is detected. Then, the measured main wave level is output to main wave level fluctuation monitoring section 308. Further, main wave detection section 302 outputs the detected phase of the main wave to leading end TB propagation path estimating section 110a and trailing end TB propagation path estimating section 112a.
[0097]
Tip TB propagation path estimating section 110 a synchronizes reception tip TB 152 using the phase of the main wave obtained from main wave detecting section 302, and, like tip TB propagation path estimating section 110 in the first embodiment, receives the same signal. The tap coefficient of TB section B is estimated. Then, tip TB propagation path estimation section 110a outputs the estimated tap coefficients to tap number estimation section 116 and main wave level measurement section 304.
[0098]
The rear end TB channel estimation unit 112a synchronizes the reception rear end TB 154 using the phase of the main wave obtained from the main wave detection unit 302, and performs the same operation as the front end TB channel estimation unit 112 in the first embodiment. , A tap coefficient of the rear end TB section C is estimated. Then, rear end TB propagation path estimation section 112a outputs the estimated tap coefficient to tap number estimation section 118 and main wave level measurement section 306.
[0099]
The main wave level measuring section 304 measures the main wave level using the tap coefficient of the distal end TB section B estimated by the distal end TB propagation path estimating section 110a. Then, the measured level is output to main wave level fluctuation monitoring section 310.
[0100]
The main wave level measuring section 306 measures the main wave level using the tap coefficient of the rear end TB section C estimated by the rear end TB propagation path estimating section 112a. Then, the measured level is output to main wave level fluctuation monitoring section 312.
[0101]
The main wave level fluctuation monitoring unit 308 monitors fluctuations in the main wave level measured by the main wave detection unit 302 over a plurality of slots in a statistical manner. Then, the monitoring result of the level change is output to the first half data demodulation control section 120a and the second half data demodulation control section 122a.
[0102]
Specifically, statistics of a plurality of levels measured in a plurality of slots are taken, and if the ratio of the measured level within a predetermined range is equal to or more than a predetermined value, the fluctuation of the main wave level is small. to decide. On the other hand, when the ratio of the measured level within the predetermined range is not more than the predetermined value, it is determined that the fluctuation of the main wave level is large.
[0103]
In addition, the monitoring method in the main wave level fluctuation monitoring unit 308 is not limited to the above method. For example, among the measured levels, the difference between the largest value and the smallest value may be obtained, and this difference may be compared with a predetermined threshold. In this case, if the difference is equal to or larger than the threshold, it is determined that the fluctuation of the main wave level is large, and if the difference is smaller than the threshold, it is determined that the fluctuation of the main wave level is small.
[0104]
The unit of the period for monitoring the level change is not limited to a plurality of slots, and the monitoring may be performed over a plurality of frames.
[0105]
The main wave level fluctuation monitoring section 310 monitors the fluctuation of the main wave level measured by the main wave level measuring section 304 over a plurality of slots in a statistical manner. Then, the monitoring result of the level change is output to the first half data demodulation control section 120a.
[0106]
The main wave level fluctuation monitoring unit 312 monitors the fluctuation of the main wave level measured by the main wave level measuring unit 306 over a plurality of slots in a statistical manner. Then, the monitoring result of the level change is output to the second half data demodulation control unit 122a.
[0107]
The specific monitoring method in the main wave level fluctuation monitoring units 310 and 312 is the same as that of the main wave level fluctuation monitoring unit 308.
[0108]
First-half data demodulation control section 120a, like the first-half data demodulation control section 120 in Embodiment 1, estimates the number of taps corresponding to TSC section A estimated by tap number estimation section 114 and estimation by tap number estimation section 116. A control signal for controlling the demodulation processing in demodulation section 124 is generated using the number of taps corresponding to the leading end TB section B, and the generated control signal is output to demodulation section 124.
[0109]
Further, the first half data demodulation control section 120a monitors the main wave level fluctuation in the TSC section A by the main wave level fluctuation monitoring section 308 and the main wave level fluctuation in the leading TB section B by the main wave level fluctuation monitoring section 310. A control signal for controlling the demodulation processing in the demodulation unit 124 is generated using the monitoring result of the above and the generated control signal is output to the demodulation unit 124.
[0110]
More specifically, the first half data demodulation control unit 120a performs the main wave level fluctuation when the main wave level fluctuation monitoring unit 308 determines that the fluctuation of the main wave level is large and the main wave level fluctuation monitoring unit 310. Is determined to be high, it is determined that the moving speed of the data receiving apparatus 300 is high, and a control signal for executing the adaptive algorithm in the demodulation processing in the demodulation unit 124 is generated. On the other hand, when the main wave level fluctuation monitoring section 308 and the main wave level fluctuation monitoring section 310 determine that the fluctuation of the level of the main wave is small, it is determined that the moving speed of the data receiving apparatus 300 is low, and the demodulation section 124. In the demodulation process, a control signal that does not execute the adaptive algorithm is generated.
[0111]
The control method based on the monitoring result of the level variation is not limited to the above. Instead of controlling the execution of the adaptive algorithm, a control signal for changing a parameter such as a step size of the adaptive algorithm in the demodulation processing in the demodulation unit 124 is transmitted. It may be generated.
[0112]
The second-half data demodulation control unit 122a uses the same method as the first-half data demodulation control unit 120a to calculate the number of taps corresponding to the TSC section A estimated by the tap estimation unit 114 and the rear end estimated by the tap number estimation unit 118. Number of taps corresponding to TB section C, monitoring result of main wave level fluctuation in TSC section A by main wave level fluctuation monitoring section 308, and main wave level fluctuation in rear end TB section C by main wave level fluctuation monitoring section 312 And a control signal for controlling the demodulation processing in the demodulation section 124 using the monitoring result of the above, and outputs the generated control signal to the demodulation section 124.
[0113]
Next, the operation of monitoring the main wave level fluctuation in the data receiving apparatus 300 having the above configuration will be described.
[0114]
The main wave detection unit 302 measures the maximum level (for example, the power level) of the received signal using the tap coefficient estimated by the TSC channel estimation unit 108, and determines the phase of the path having the measured maximum level. By measuring, the main wave of the received signal is detected. Then, the measured main wave level is output to main wave level fluctuation monitoring section 308. Further, main wave detection section 302 outputs the detected phase of the main wave to leading end TB propagation path estimating section 110a and trailing end TB propagation path estimating section 112a.
[0115]
Then, the leading end TB propagation path estimating section 110a synchronizes the receiving leading end TB 152 using the phase of the main wave obtained from the main wave detecting section 302, and estimates the tap coefficient of the leading end TB section B. Then, the estimated tap coefficients are output to tap number estimation section 116 and main wave level measurement section 304.
[0116]
Further, rear end TB propagation path estimation section 112a synchronizes reception rear end TB 154 using the phase of the main wave obtained from main wave detection section 302, and estimates the tap coefficient of rear end TB section C. Then, the estimated tap coefficient is output to tap number estimating section 118 and main wave level measuring section 306.
[0117]
Then, the main wave level measuring section 304 measures the main wave level using the tap coefficient of the front end TB section B estimated by the front end TB propagation path estimating section 110a. Then, the measured level is output to main wave level fluctuation monitoring section 310.
[0118]
The main wave level measuring section 306 measures the main wave level using the tap coefficient of the rear end TB section C estimated by the rear end TB channel estimating section 112a. Then, the measured level is output to main wave level fluctuation monitoring section 312.
[0119]
Then, the main wave level fluctuation monitoring unit 308 monitors the fluctuation of the main wave level measured by the main wave detection unit 302 over a plurality of slots by a statistical method. Then, the monitoring result of the level change is output to the first half data demodulation control section 120a and the second half data demodulation control section 122a.
[0120]
Further, the main wave level fluctuation monitoring section 310 monitors the fluctuation of the main wave level measured by the main wave level measuring section 304 over a plurality of slots by a statistical method. Then, the monitoring result of the level change is output to the first half data demodulation control section 120a.
[0121]
Also, the main wave level fluctuation monitoring unit 312 monitors the fluctuation of the main wave level measured by the main wave level measuring unit 306 over a plurality of slots in a statistical manner. Then, the monitoring result of the level change is output to the second half data demodulation control unit 122a.
[0122]
Then, the first half data demodulation control section 120a determines the number of taps corresponding to the TSC section A estimated by the tap number estimation section 114, the number of taps corresponding to the leading TB section B estimated by the tap number estimation section 116, and the main wave level. The demodulation unit 124 demodulates using the monitoring result of the main wave level fluctuation in the TSC section A by the fluctuation monitoring unit 308 and the monitoring result of the main wave level fluctuation in the leading TB section B by the main wave level fluctuation monitoring unit 310. A control signal for controlling the processing is generated, and the generated control signal is output to the demodulation unit 124.
[0123]
Also, in the latter half data demodulation control section 122a, the number of taps corresponding to the TSC section A estimated by the tap estimating section 114, the number of taps corresponding to the rear end TB section C estimated by the tap number estimating section 118, and the main signal level The demodulation unit 124 uses the monitoring result of the main wave level fluctuation in the TSC section A by the fluctuation monitoring unit 308 and the monitoring result of the main wave level fluctuation in the rear end TB section C by the main wave level fluctuation monitoring unit 312. A control signal for controlling the demodulation processing is generated, and the generated control signal is output to the demodulation unit 124.
[0124]
As described above, according to the present embodiment, the main wave of the received signal is detected based on the propagation path characteristics, the level of the detected main wave is measured, and the fluctuation of the measured level is measured by a statistical method. Since the monitoring and control of the demodulation processing in the demodulation section 124 are performed based on the monitoring results of the main wave level fluctuation monitoring sections 308, 310, and 312, the demodulation processing can be controlled according to the fluctuation of the main wave level. In the demodulation process, it is possible to follow the fluctuation of the propagation path characteristic in the slot, and it is possible to improve the reception performance.
[0125]
The configuration of the data receiving apparatus according to the third embodiment is as shown in FIG. 6, but may have a configuration as shown in FIG. 7 as a modified example. The data receiving apparatus 300 shown in FIG. 6 changes the level of the main wave based on the propagation path characteristics at a plurality of points in one slot (that is, the TSC section A, the leading TB section B, and the trailing TB section C). The data receiving apparatus 350 shown in FIG. 7 has a configuration for monitoring the fluctuation of the main wave level based only on the propagation path characteristics at one point in one slot (for example, TSC section A). The data receiving apparatus 300 includes a demodulation control section 352 instead of the first half data demodulation control section 120a and the second half data demodulation control section 122a, and a demodulation section 354 instead of the demodulation section 124.
[0126]
Demodulation control section 352 calculates the number of taps corresponding to TSC section A estimated by tap number estimation section 114 by a method similar to first half data demodulation control section 120a and second half data demodulation control section 122a in data receiving apparatus 300. And a control signal for controlling the demodulation processing in the demodulation unit 354 based on the result of monitoring the fluctuation of the main wave level by the main wave level fluctuation monitoring unit 308, and the demodulation unit 354 The demodulation section 124 demodulates the received signal obtained from the received signal memory 106 according to the control signal obtained from the demodulation control section 352 by the same method as the demodulation section 124.
[0127]
As described above, also in the data receiving apparatus 350 shown in FIG. 7, the fluctuation of the main wave level is monitored based on the propagation path characteristics, and the demodulation processing in the demodulation section 354 is performed based on the monitoring result of the main wave level fluctuation monitoring section 308. , The demodulation process can be controlled according to the fluctuation of the main wave level, and the reception performance can be improved.
[0128]
Also, the data receiving apparatus according to Embodiment 3 has a configuration applied to a GSM mobile communication system and has been described to receive a signal having a GSM frame configuration shown in FIG. It is not limited only to the application. The data receiving apparatus can be applied to any type of mobile communication system as long as the mobile communication system has a frame configuration in which a plurality of known signals are included in one slot.
[0129]
(Embodiment 4)
FIG. 8 is a block diagram showing a configuration of a data receiving device according to Embodiment 4 of the present invention. The data receiving device 400 shown in FIG. 8 has the same basic configuration as the data receiving device 100 shown in FIG. 1, and the same components are denoted by the same reference characters and description thereof will be omitted. I do.
[0130]
A feature of the fourth embodiment is that channel characteristics at a plurality of points within one slot period are estimated, and fluctuation of the main wave phase is monitored based on each channel characteristic. For this purpose, data receiving apparatus 400 shown in FIG. 8 includes a leading end TB propagation path estimating section 110, a trailing end TB propagation path estimating section 112, first half data demodulation control section 120, and second half data demodulation control section 122 in data receiving apparatus 100. Instead of the above, the leading end TB propagation path estimating section 120a and the trailing end TB propagation path estimating section 112a, the first half data demodulation control section 120b and the second half data demodulation control section 122b similar to the data receiving apparatus 300 according to Embodiment 3 And a main wave detection unit 402, main wave phase measurement units 404 and 406, and main wave phase fluctuation monitoring units 408, 410 and 412.
[0131]
Main wave detecting section 402 detects the main wave of the received signal by the same method as main wave detecting section 302 in the third embodiment. Then, it outputs the detected phase of the main wave to main wave phase fluctuation monitoring section 408, leading end TB propagation path estimating section 110a, and trailing end TB propagation path estimating section 112a.
[0132]
The main wave phase measuring section 404 measures the phase of the main wave using the tap coefficient of the distal end TB section B estimated by the distal end TB propagation path estimating section 110a. Then, the measured phase is output to main wave phase fluctuation monitoring section 410.
[0133]
The main wave phase measuring section 406 measures the phase of the main wave using the tap coefficient of the rear end TB section C estimated by the rear end TB propagation path estimating section 112a. Then, the measured phase is output to main wave phase fluctuation monitoring section 412.
[0134]
The main wave phase fluctuation monitoring section 408 monitors the fluctuation of the phase of the main wave detected by the main wave detecting section 402 over a plurality of slots in a statistical manner. Then, the monitoring result of the phase change is output to first data demodulation control section 120b and second data demodulation control section 122b.
[0135]
Specifically, statistics of a plurality of phases measured in a plurality of slots are taken, and when the ratio of the measured phase within a predetermined range is equal to or more than a predetermined value, the fluctuation of the main wave phase is small. to decide. On the other hand, when the ratio of the measured phase within the predetermined range is not more than the predetermined value, it is determined that the fluctuation of the phase of the main wave is large.
[0136]
In addition, the monitoring method in the main wave phase fluctuation monitoring unit 408 is not limited to the above method. For example, among the measured phases, the difference between the largest value and the smallest value may be obtained, and this difference may be compared with a predetermined threshold value. In this case, if the difference is equal to or larger than the threshold, it is determined that the fluctuation of the phase of the main wave is large, and if the difference is smaller than the threshold, it is determined that the fluctuation of the phase of the main wave is small.
[0137]
The unit of the period for monitoring the phase change is not limited to a plurality of slots, and monitoring may be performed over a plurality of frames.
[0138]
The main wave phase fluctuation monitoring section 410 monitors the fluctuation of the main wave phase measured by the main wave phase measuring section 404 over a plurality of slots in a statistical manner. Then, the monitoring result of the phase change is output to the first half data demodulation control section 120b.
[0139]
The main wave phase fluctuation monitoring unit 412 monitors the fluctuation of the main wave phase measured by the main wave phase measuring unit 406 over a plurality of slots in a statistical manner. Then, the monitoring result of the phase change is output to the second half data demodulation control unit 122b.
[0140]
The specific monitoring method in the main wave phase fluctuation monitoring unit 410 and the main wave phase fluctuation monitoring unit 412 is the same as that of the main wave phase fluctuation monitoring unit 408.
[0141]
First-half data demodulation control section 120b, like the first-half data demodulation control section 120 in Embodiment 1, estimates the number of taps corresponding to TSC section A estimated by tap number estimation section 114 and estimation by tap number estimation section 116. A control signal for controlling the demodulation processing in demodulation section 124 is generated using the number of taps corresponding to the leading end TB section B, and the generated control signal is output to demodulation section 124.
[0142]
Further, the first-half data demodulation control section 120b calculates the main wave phase fluctuation monitoring result in the TSC section A by the main wave phase fluctuation monitoring section 408 and the main wave phase fluctuation in the leading TB section B by the main wave phase fluctuation monitoring section 410. A control signal for controlling the demodulation processing in the demodulation unit 124 is generated using the monitoring result of the above and the generated control signal is output to the demodulation unit 124.
[0143]
More specifically, the first half data demodulation control unit 120b performs the main wave phase fluctuation when the main wave phase fluctuation monitoring unit 408 determines that the fluctuation of the main wave level is large and the main wave phase fluctuation monitoring unit 410. Is determined to be high, it is determined that the moving speed of the data receiving apparatus 400 is high, and a control signal for executing the adaptive algorithm in the demodulation processing in the demodulation unit 124 is generated. On the other hand, when the main wave phase fluctuation monitoring unit 408 and the main wave phase fluctuation monitoring unit 410 determine that the fluctuation of the phase of the main wave is small, it is determined that the moving speed of the data receiving device 400 is low, and the demodulation unit 124 In the demodulation process, a control signal that does not execute the adaptive algorithm is generated.
[0144]
The control method based on the monitoring result of the phase variation is not limited to the above. Instead of controlling the execution of the adaptive algorithm, a control signal for changing a parameter such as a step size of the adaptive algorithm in the demodulation processing in the demodulation unit 124 is transmitted. May be generated.
[0145]
The second-half data demodulation control unit 122b uses the same method as the first-half data demodulation control unit 120b to calculate the number of taps corresponding to the TSC section A estimated by the tap estimation unit 114 and the rear end estimated by the tap number estimation unit 118. The number of taps corresponding to TB section C, the result of monitoring the main wave phase fluctuation in TSC section A by main wave phase fluctuation monitoring section 408, and the main wave phase fluctuation in rear end TB section C by main wave phase fluctuation monitoring section 412. And a control signal for controlling the demodulation processing in the demodulation section 124 using the monitoring result of the above, and outputs the generated control signal to the demodulation section 124.
[0146]
Next, the operation of the main wave phase fluctuation monitoring in the data receiving apparatus 400 having the above configuration will be described.
[0147]
The main wave detection unit 402 measures the maximum level (for example, power level) of the received signal using the tap coefficient estimated by the TSC channel estimation unit 108, and determines the phase of the path having the measured maximum level. By measuring, the main wave of the received signal is detected. Then, it outputs the measured phase of the main wave to main wave level fluctuation monitoring section 408, leading end TB propagation path estimating section 110a, and trailing end TB propagation path estimating section 112a.
[0148]
Then, the main wave phase measuring section 404 measures the phase of the main wave using the tap coefficient of the distal end TB section B estimated by the distal end TB propagation path estimating section 110a. Then, the measured phase is output to main wave phase fluctuation monitoring section 410.
[0149]
In addition, main wave phase measurement section 406 measures the phase of the main wave using the tap coefficient of rear end TB section C estimated by rear end TB propagation path estimation section 112a. Then, the measured phase is output to main wave phase fluctuation monitoring section 412.
[0150]
Then, the main wave phase fluctuation monitoring section 408 monitors the fluctuation of the main wave phase detected by the main wave detecting section 402 over a plurality of slots in a statistical manner. Then, the monitoring result of the phase change is output to first data demodulation control section 120b and second data demodulation control section 122b.
[0151]
Further, the main wave phase fluctuation monitoring unit 410 monitors the fluctuation of the main wave phase detected by the main wave phase measuring unit 404 over a plurality of slots by a statistical method. Then, the monitoring result of the phase change is output to the first half data demodulation control section 120b.
[0152]
Further, the main wave phase fluctuation monitoring unit 412 monitors the fluctuation of the main wave phase detected by the main wave phase measuring unit 406 over a plurality of slots by a statistical method. Then, the monitoring result of the phase change is output to the second half data demodulation control unit 122b.
[0153]
Then, the first half data demodulation control section 120b calculates the number of taps corresponding to the TSC section A estimated by the tap number estimation section 114, the number of taps corresponding to the leading TB section B estimated by the tap number estimation section 116, and the main wave phase. The demodulation unit 124 demodulates using the monitoring result of the main wave phase fluctuation in the TSC section A by the fluctuation monitoring unit 408 and the monitoring result of the main wave phase fluctuation in the leading TB section B by the main wave phase fluctuation monitoring unit 410. A control signal for controlling the processing is generated, and the generated control signal is output to the demodulation unit 124.
[0154]
Further, the second half data demodulation control section 122b calculates the number of taps corresponding to the TSC section A estimated by the tap estimating section 114, the number of taps corresponding to the rear end TB section C estimated by the tap number estimating section 118, and the main wave phase. The demodulation unit 124 uses the monitoring result of the main wave phase fluctuation in the TSC section A by the fluctuation monitoring unit 408 and the monitoring result of the main wave phase fluctuation in the trailing end TB section C by the main wave phase fluctuation monitoring unit 412. A control signal for controlling the demodulation process is generated, and the generated control signal is output to the demodulation unit 124.
[0155]
As described above, according to the present embodiment, the main wave of the received signal is detected based on the propagation path characteristics, the phase of the detected main wave is measured, and the fluctuation of the measured phase is determined by a statistical method. Since the demodulation unit 124 monitors and controls the demodulation processing in the demodulation unit 124 based on the monitoring result of the main wave phase fluctuation monitoring units 408, 410, and 412, the demodulation processing can be controlled according to the fluctuation of the main wave level. In the demodulation process, it is possible to follow the fluctuation of the propagation path characteristic in the slot, and it is possible to improve the reception performance.
[0156]
Note that the configuration of the data receiving apparatus according to Embodiment 4 is as shown in FIG. 8, but as a modified example, it may have a configuration as shown in FIG. The data receiving apparatus 400 shown in FIG. 8 performs the fluctuation of the phase of the main wave based on the propagation path characteristics at a plurality of points in one slot (that is, the TSC section A, the leading TB section B, and the trailing TB section C). The data receiving apparatus 450 shown in FIG. 9 has a configuration for monitoring the fluctuation of the phase of the main wave based only on the propagation path characteristics at one point in one slot (for example, TSC section A). Data receiving apparatus 400 has demodulation control section 452 instead of first half data demodulation control section 120b and second half data demodulation control section 122b, and has demodulation section 454 instead of demodulation section 124.
[0157]
Demodulation control section 452 determines the number of taps corresponding to TSC section A estimated by tap number estimation section 114 in the same manner as first half data demodulation control section 120b and second half data demodulation control section 122b in data receiving apparatus 400. And a control signal for controlling the demodulation processing in the demodulation section 454 based on the result of monitoring the fluctuation of the phase of the main wave by the main wave phase fluctuation monitoring section 408, respectively. The demodulation section 124 demodulates the reception signal obtained from the reception signal memory 106 in accordance with the control signal obtained from the demodulation control section 452 by the same method as the demodulation section 124.
[0158]
Thus, also in data receiving apparatus 450 shown in FIG. 9, the fluctuation of the main wave phase is monitored based on the propagation path characteristics, and the demodulation processing in demodulation section 454 is performed based on the monitoring result of main wave phase fluctuation monitoring section 408. , The demodulation process can be controlled according to the fluctuation of the main wave level, and the reception performance can be improved.
[0159]
Further, the data receiving apparatus according to Embodiment 4 has a configuration applied to a GSM mobile communication system and has been described to receive a signal having a GSM frame configuration shown in FIG. It is not limited only to the application. The data receiving apparatus can be applied to any type of mobile communication system as long as the mobile communication system has a frame configuration in which a plurality of known signals are included in one slot.
[0160]
(Embodiment 5)
FIG. 10 is a block diagram showing a configuration of a data receiving device according to Embodiment 5 of the present invention. The data receiving device 500 shown in FIG. 10 has the same basic configuration as the data receiving device 100 shown in FIG. 1, and the same components are denoted by the same reference characters and description thereof will be omitted. I do.
[0161]
The features of the fifth embodiment are that propagation paths at a plurality of points within one slot period are estimated, the number of taps is estimated based on each propagation path characteristic, fluctuation of the main wave level is monitored, and fluctuation of the main wave phase is changed. This is to monitor. For this purpose, data receiving apparatus 500 shown in FIG. 10 includes leading end TB propagation path estimating section 110, trailing end TB propagation path estimating section 112, tap number estimating sections 114, 116, 118, and demodulation control for the first half data in data receiving apparatus 100. Instead of section 120 and second-half data demodulation control section 122, front-end TB propagation path estimating section 120a and rear-end TB propagation path estimating section 112a similar to those of data receiving apparatus 300 according to Embodiment 3, and Embodiment 2 It has the same tap number estimation units 114a, 116a, 118a, the first half data demodulation control unit 120c and the second half data demodulation control unit 122c as the data reception device 200, and has the same taps as the data reception device 200 according to the second embodiment. Number fluctuation monitoring units 202, 204, 206, main wave detection unit 502, main wave level / phase measurement units 504, 506, actual Main wave level fluctuation monitoring sections 308, 310, and 312 similar to data receiving apparatus 300 according to Embodiment 3 and main wave phase fluctuation monitoring sections 408, 410, and 412 similar to data receiving apparatus 400 according to Embodiment 4 are provided. .
[0162]
Main wave detecting section 502 detects the main wave of the received signal by the same method as main wave detecting section 302 in the third embodiment. Then, the measured main wave level is output to main wave level fluctuation monitoring section 308, and the measured main wave phase is measured for main wave phase fluctuation monitoring section 408, leading TB propagation path estimating section 110a, and trailing TB propagation path. Output to the estimation unit 112a.
[0163]
The main wave level / phase measuring section 504 uses the tap coefficient of the distal end TB section B estimated by the distal end TB propagation path estimating section 110a in the same manner as the main wave level measuring section 304 in the third embodiment, and , And outputs the measured level to the main wave level fluctuation monitoring unit 310. Further, main wave level / phase measuring section 504 uses the tap coefficient of tip TB section B estimated by tip TB propagation path estimating section 110a by the same method as that of main wave phase measuring section 404 in the fourth embodiment. The phase of the main wave is measured, and the measured phase is output to main wave phase fluctuation monitoring section 410.
[0164]
Main wave level / phase measuring section 506 uses the tap coefficient of rear end TB section C estimated by rear end TB propagation path estimating section 112a by the same method as main wave level measuring section 306 in the third embodiment. The main wave level is measured, and the measured level is output to main wave level fluctuation monitoring section 312. Further, main wave level / phase measuring section 506 calculates the tap coefficient of rear end TB section C estimated by rear end TB propagation path estimating section 112a by the same method as main wave phase measuring section 406 in the fourth embodiment. To measure the phase of the main wave, and outputs the measured phase to the main wave phase fluctuation monitoring unit 412.
[0165]
First-half data demodulation control section 120c, like the first-half data demodulation control section 120 in Embodiment 1, estimates the number of taps corresponding to TSC section A estimated by tap number estimation section 114a and estimation by tap number estimation section 116a. A control signal for controlling the demodulation processing in demodulation section 124 is generated using the number of taps corresponding to the leading end TB section B, and the generated control signal is output to demodulation section 124.
[0166]
Also, similarly to the first half data demodulation control section 120a in the third embodiment, the first half data demodulation control section 120c monitors the main wave phase fluctuation monitoring result of the main wave level fluctuation monitoring section 308 and the main wave phase fluctuation in the TSC section A. The control signal for controlling the demodulation processing in the demodulation unit 124 is generated using the monitoring result of the phase fluctuation of the main wave in the tip TB section B by the level fluctuation monitoring unit 310, and the generated control signal is demodulated. Output to the unit 124.
[0167]
Further, similarly to demodulation control section 120b for the first half data in the first embodiment, demodulation control section 120c for the first half data monitors the phase fluctuation monitoring result of the main wave in TSC section A by main wave phase fluctuation monitoring section 408 and the main wave. The control signal for controlling the demodulation processing in the demodulation unit 124 is generated using the monitoring result of the phase fluctuation of the main wave in the leading end TB section B by the phase fluctuation monitoring unit 410, and the generated control signal is demodulated. Output to the unit 124.
[0168]
The second-half data demodulation control unit 122c uses the same method as the first-half data demodulation control unit 120c to calculate the number of taps corresponding to the TSC section A estimated by the tap estimation unit 114a and the rear end estimated by the tap number estimation unit 118a. Number of taps corresponding to TB section C, monitoring result of main wave level fluctuation in TSC section A by main wave level fluctuation monitoring section 308, and main wave level fluctuation in rear end TB section C by main wave level fluctuation monitoring section 312 And the monitoring result of the main wave phase fluctuation in the TSC section A by the main wave phase fluctuation monitoring unit 408 and the monitoring result of the main wave phase fluctuation in the trailing end TB section C by the main wave phase fluctuation monitoring unit 412. And a control signal for controlling the demodulation processing in the demodulation unit 124 is generated. And outputs it to the 24.
[0169]
Next, the operation of demodulation control in data receiving apparatus 500 having the above configuration will be described.
[0170]
Main wave detecting section 502 detects the main wave of the received signal by the same method as main wave detecting section 302 in the third embodiment, and outputs the measured level of the main wave to main wave level fluctuation monitoring section 308, The measured main wave phase is output to main wave phase fluctuation monitoring section 408, leading end TB propagation path estimating section 110a, and trailing end TB propagation path estimating section 112a.
[0171]
Then, the main wave level / phase measuring unit 504 measures the main wave level in the same manner as the operation of the main wave level measuring unit 304 in the third embodiment, and sends the measured level to the main wave level fluctuation monitoring unit 310. Output. Further, main wave level / phase measuring section 504 measures the phase of the main wave similarly to the operation of main wave phase measuring section 404 in the fourth embodiment, and transmits the measured phase to main wave phase fluctuation monitoring section 410. Output.
[0172]
The main wave level / phase measuring unit 506 measures the main wave level in the same manner as the operation of the main wave level measuring unit 306 in the third embodiment, and sends the measured level to the main wave level fluctuation monitoring unit 312. Output. Further, main wave level / phase measuring section 506 measures the main wave phase in the same manner as the operation of main wave phase measuring section 406 in the fourth embodiment, and transmits the measured phase to main wave phase fluctuation monitoring section 412. Output.
[0173]
Then, similarly to the operation of first-half data demodulation control section 120 in the first embodiment, first-half data demodulation control section 120c generates a control signal for controlling demodulation processing in demodulation section 124 and generates the control signal. The resulting control signal is output to demodulation section 124. Further, similarly to the operation of first-half data demodulation control section 120a in the third embodiment, a control signal for controlling demodulation processing in demodulation section 124 is generated, and the generated control signal is transmitted to demodulation section 124. Output. Further, similarly to the operation in the first half data demodulation control section 120b in the fourth embodiment, a control signal for controlling the demodulation processing in demodulation section 124 is generated, and the generated control signal is transmitted to demodulation section 124. Output.
[0174]
Further, the second-half data demodulation control unit 122c generates control signals for controlling the demodulation processing in the demodulation unit 124, similarly to the operation of the first-half data demodulation control unit 120c, and generates the generated control signal. Is output to the demodulation unit 124.
[0175]
As described above, according to the present embodiment, the variation in the number of taps estimated based on the propagation path characteristics is monitored by a statistical method, and based on the monitoring results of tap number variation monitoring units 202, 204, and 206. Estimates the number of taps, detects the main wave of the received signal based on the propagation path characteristics, measures the level and phase of the detected main wave, and measures the fluctuations in the measured level and phase in a statistical manner. Based on the monitored and estimated number of taps, the monitoring results of the main wave level fluctuation monitoring units 308, 310, and 312 and the monitoring results of the main wave phase fluctuation monitoring units 408, 410, and 412, control of the demodulation processing in the demodulation unit 124 is performed. Therefore, when the fluctuation of the propagation path characteristics is small or when there is no fluctuation of the propagation path characteristics, it is possible to estimate the number of taps by limiting the estimation range of the number of taps. It is possible to reduce the amount of arithmetic processing. In addition, demodulation processing can be controlled in accordance with fluctuations in the level and phase of the main wave, and during demodulation processing, it is possible to follow fluctuations in propagation path characteristics within a slot, thereby improving reception performance. can do.
[0176]
In the present embodiment, tap number variation monitoring sections 202, 204, and 206 output instruction signals to tap number estimating sections 114a, 116a, and 118a, respectively. Similarly to the above, a configuration may be adopted in which the instruction signal is output to the TSC channel estimation unit 108, the leading TB channel estimation unit 110a, and the trailing TB channel estimation unit 112a. By adopting such a configuration, it is possible to estimate the tap coefficient by limiting the estimation range of the tap coefficient when the fluctuation of the propagation path characteristic is small or when there is no fluctuation of the propagation path characteristic. In this case, it is possible to reduce the amount of calculation processing.
[0177]
The configuration of the data receiving apparatus according to the fifth embodiment is as shown in FIG. 10, but may have a configuration as shown in FIG. 11 as a modification. Data receiving apparatus 500 shown in FIG. 10 estimates the number of taps based on each of the propagation path characteristics at a plurality of points in one slot (ie, TSC section A, leading TB section B, and trailing TB section C), While monitoring the fluctuation of the level and phase of the main wave, the data receiving apparatus 550 shown in FIG. 11 estimates the number of taps based only on the propagation path characteristics at one point in one slot (for example, TSC section A), It has a configuration for monitoring fluctuations in the level and phase of the main wave, has a demodulation control unit 552 instead of the first half data demodulation control unit 120c and the second half data demodulation control unit 122c in the data receiving device 500, and has a demodulation unit 124 Has a demodulation unit 554 instead of.
[0178]
Demodulation control section 552 uses the same method as first half data demodulation control section 120c and second half data demodulation control section 122c in data receiving apparatus 500 to determine the number of taps corresponding to TSC section A estimated by tap number estimation section 114a. The demodulation unit 554 controls the demodulation process based on the result of monitoring the fluctuation of the main wave level by the main wave level fluctuation monitoring unit 308 and the result of monitoring the fluctuation of the main wave phase by the main wave phase fluctuation monitoring unit 408. The demodulation section 554 outputs the received signal obtained from the received signal memory 106 according to the control signal obtained from the demodulation control section 552 in the same manner as the demodulation section 124 in the data receiving apparatus 500. Is demodulated.
[0179]
As described above, also in data receiving apparatus 550 shown in FIG. 11, when the fluctuation of the propagation path characteristic is small or when there is no fluctuation of the propagation path characteristic, estimation range of the number of taps is limited and estimation of the number of taps is performed. This makes it possible to reduce the amount of calculation processing when estimating the number of taps and tap coefficients. In addition, demodulation processing can be controlled in accordance with fluctuations in the level and phase of the main wave, and the reception performance can be improved.
[0180]
Also, the data receiving apparatus according to Embodiment 5 has a configuration applied to a GSM mobile communication system and has been described to receive a signal having a GSM frame configuration shown in FIG. It is not limited only to the application. The data receiving apparatus can be applied to any type of mobile communication system as long as the mobile communication system has a frame configuration in which a plurality of known signals are included in one slot.
[0181]
【The invention's effect】
As described above, according to the present invention, it is possible to follow the fluctuation of the propagation path characteristics in each slot and improve the reception performance.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a data receiving apparatus according to Embodiment 1 of the present invention.
FIG. 2 is a diagram showing a frame configuration of a signal used in a GSM mobile communication system;
FIG. 3 is a diagram for explaining fade duration in a GSM mobile communication system;
FIG. 4 is a block diagram showing a configuration of a data receiving apparatus according to Embodiment 2 of the present invention.
FIG. 5 is a block diagram showing a modified example of the configuration of the data receiving apparatus according to Embodiment 2 of the present invention.
FIG. 6 is a block diagram showing a configuration of a data receiving apparatus according to Embodiment 3 of the present invention.
FIG. 7 is a block diagram showing a modification of the configuration of the data receiving apparatus according to Embodiment 3 of the present invention.
FIG. 8 is a block diagram showing a configuration of a data receiving apparatus according to Embodiment 4 of the present invention.
FIG. 9 is a block diagram showing a modification of the configuration of the data receiving apparatus according to Embodiment 4 of the present invention.
FIG. 10 is a block diagram showing a configuration of a data receiving apparatus according to Embodiment 5 of the present invention.
FIG. 11 is a block diagram showing a modified example of the configuration of the data receiving apparatus according to Embodiment 5 of the present invention.
[Explanation of symbols]
100, 200, 250, 300, 350, 400, 450, 500, 550 data receiving devices
102 antenna
104 wireless processing unit
106 Received signal memory
108 TSC channel estimation unit
110, 110a Advanced TB channel estimator
112, 112a Trailing end TB channel estimation unit
114, 114a, 116, 116a, 118, 118a Tap number estimation unit
120, 120a, 120b, 120c Demodulation control unit for first half data
122, 122a, 122b, 122c Demodulation control unit for second half data
124, 254, 354, 454, 554 demodulation unit
150 training sequence code
152, 154 tail bit
156, 158 data
160 guard interval
202, 204, 206 Tap number fluctuation monitoring unit
252, 352, 452, 552 demodulation control unit
302, 402, 502 main wave detector
304, 306 Main wave level measurement unit
308, 310, 312 Main wave level fluctuation monitoring unit
404, 406 main wave phase measurement unit
408, 410, 412 main wave phase fluctuation monitoring unit
504, 506 main wave level / phase measuring unit

Claims (7)

Demodulation means for demodulating a received signal consisting of a plurality of slots each containing a plurality of known signals,
Channel characteristic estimating means for estimating channel characteristics at a plurality of points in each slot using a plurality of known signals included in each slot,
Control means for controlling demodulation processing in the demodulation means based on the estimated propagation path characteristics,
A data receiving device comprising: The control means includes:
Tap number estimating means for estimating the number of taps at each corresponding point based on each estimated channel characteristic,
2. The data receiving apparatus according to claim 1, wherein demodulation processing is controlled based on the estimated number of taps. The control means includes:
Further comprising monitoring means for monitoring a change in the estimated number of taps,
The tap number estimating means includes:
3. The data receiving device according to claim 2, wherein the number of taps is estimated based on a monitoring result of the monitoring unit. The control means includes:
Main wave detection means for detecting the main wave of the received signal based on the estimated propagation path characteristics,
Level measuring means for measuring the level of the detected main wave;
Monitoring means for monitoring the fluctuation of the measured level,
2. The data receiving apparatus according to claim 1, wherein control of demodulation processing is performed based on a monitoring result of said monitoring means. The control means includes:
Main wave detection means for detecting the main wave of the received signal based on the estimated propagation path characteristics,
Phase measuring means for measuring the phase of the detected main wave,
Monitoring means for monitoring the variation of the measured phase,
2. The data receiving apparatus according to claim 1, wherein control of demodulation processing is performed based on a monitoring result of said monitoring means. The control means includes:
Tap number estimating means for estimating the number of taps at each corresponding point based on each estimated channel characteristic,
Tap number fluctuation monitoring means for monitoring the fluctuation of the estimated number of taps,
Main wave detection means for detecting the main wave of the received signal based on the estimated propagation path characteristics,
Level measuring means for measuring the level of the detected main wave;
Phase measuring means for measuring the phase of the detected main wave,
Level fluctuation monitoring means for monitoring the fluctuation of the measured level;
Having phase variation monitoring means for monitoring the variation of the measured phase,
The tap number estimating means includes:
Estimating the number of taps based on the monitoring result of the tap number variation monitoring means,
The control means includes:
2. The data receiving apparatus according to claim 1, wherein demodulation processing is controlled based on the estimated number of taps, a monitoring result of the level variation monitoring unit, and a monitoring result of the phase variation monitoring unit. Demodulating a received signal consisting of a plurality of slots each including a plurality of known signals,
A channel characteristic estimation step of estimating channel characteristics at a plurality of points in the slot using a plurality of known signals included in each slot,
A control step of controlling demodulation processing in the demodulation step based on the propagation path characteristics estimated in the propagation path characteristic estimation step,
A data receiving method comprising:

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