JP2006054759A - Transmitter, transceiver, and mobile station device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To appropriately cope with the speeding-up of a data rate of a transmission signal in a transmitter applied to a mobile communication system. <P>SOLUTION: The transmitter transmits a DS-CDMA signal generated on the basis of a spread signal including the case that a spreading rate is one. The transmitter is provided with a transmission equalization processor (14) having a frequency equalizer (15) for executing equalization processing in a frequency region to the DS-CDMA signal. Weighting processing based on a prescribed weight generated on the basis of a channel gain of a propagation path, to which the DS-CDMA signal is transmitted, and a control parameter having an arbitrary value is executed in the frequency equalizer (15). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention mainly relates to a transmission apparatus, and more particularly to a transmission apparatus suitable for mobile communication, and a transmission / reception apparatus and a mobile station apparatus including the transmission apparatus.

  In mobile communication, a transmission wave is reflected by a building or the like and is received as a multipath with different path lengths (multipath), that is, multipaths with different delay times. On the other hand, as a transmission method that can overcome multipath, for example, there is a DS-CDMA (Direct Sequence-Code Division Multiple Access) transmission method. In this DS-CDMA transmission method, a spread signal that is spread over a wider frequency band by multiplying a transmission signal by a spread code sequence is transmitted. The receiver performs a correlation operation (despreading process) between the received spread signal and the spread code sequence to separate the paths with different delay times, and performs a combining process that collects the separated signals together. The signal power is increased. This technique is called RAKE combining, and is adopted in the DS-CDMA transmission system of the third generation mobile communication having a transmission speed of about 2 to 10 Mbps.

  By the way, general communication is bidirectional communication, and when the above-described Rake combining is applied to a bidirectional communication system, the receivers of both transmitting and receiving stations need this Rake combining function.

  Under such circumstances, a technique called Pre-Rake transmission in which a transmission side has a Rake combining function has been proposed (for example, Non-Patent Document 1). According to this method, one transmitting / receiving station may have a Pre-Rake transmission function and a Rake combining function, and the other transmitting / receiving station does not need the function, and one or the other transmitting / receiving function is provided. It has the advantage that the station can be made compact.

R. Esmailzadeh and M. Nakagawa, “Pre-rake diversity combination for direct sequence spread spectrum mobile communications systems,” IEICE Trans. Commun. , Vol. E76-B, no. 8, PP. 1008-1015, Aug. 1993.

  By the way, when considering the next generation mobile communication system, it is necessary to deal with the increase in the data rate of the transmission signal flexibly and accurately. For example, in a communication system that includes the Pre-Rake transmission method shown in the above prior art and requires a Rake combining process, the number of paths to be separated increases as the transmission signal data rate increases. Therefore, there is a problem that the apparatus scale increases.

  In RAKE combining, it is necessary to estimate the amplitude and phase of each path and combine the correlator outputs in phase. However, as the number of paths increases, the average signal power of each path decreases, making it impossible to accurately estimate the amplitude and phase of the delay path, and the sign orthogonality collapse due to interference between the delay paths increases. As a result, there has been a problem that the BER characteristics deteriorate.

  The present invention has been made in view of the above, and includes a transmission device that can accurately cope with an increase in the data rate of a transmission signal and can suppress an increase in device scale, and the transmission device. An object of the present invention is to provide a transmission / reception device and a mobile station device.

  In order to solve the above-described problems and achieve the object, a transmission apparatus according to the present invention is a transmission apparatus that transmits a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1. A transmission equalization processing unit including a frequency equalization processing unit that performs equalization processing in a frequency domain on a DS-CDMA signal, and a DS that has been subjected to equalization processing in the frequency domain by the transmission equalization processing unit A transmission antenna that transmits a signal generated based on the CDMA signal as a transmission signal;

  Also, in the transmitter according to the next invention, in the above, the frequency equalization processing unit is based on a channel gain of a channel through which the DS-CDMA signal is transmitted and a control parameter that can take an arbitrary value. A weighting process based on a predetermined weight generated in this way is performed.

  Further, in the transmitter according to the next invention, in the above, the predetermined weight includes a frequency element when the spread signal is subjected to FFT processing, a channel gain of a propagation path through which the DS-CDMA signal is transmitted, Normalization is performed based on the control parameter and the number of antennas of the transmission antenna.

  Further, the transmitter according to the next invention is characterized in that, in the above, the transmission antenna includes a plurality of antennas, and includes a plurality of the transmission equalization processing units respectively connected to the plurality of antennas. To do.

  The transmitter according to the next invention is characterized in that, in the above, the channel gain of the propagation path is transmitted from a receiving means that receives a transmission signal generated based on the DS-CDMA signal.

  In addition, a transmission / reception apparatus according to the next invention receives a transmission apparatus that transmits a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1, and a transmission signal transmitted from another station. And a receiving device that generates and outputs information included in the DS-CDMA signal, and the transmitting device performs equalization processing in the frequency domain on the DS-CDMA signal generated by itself A transmission equalization processing unit including a frequency equalization processing unit, and a signal generated based on the DS-CDMA signal that has been equalized in the frequency domain by the transmission equalization processing unit are transmitted as a transmission signal. And a transmission antenna.

  Also, in the transmitter / receiver according to the next invention, in the above, the receiver is configured to receive a transmission antenna for receiving a transmission signal and a frequency for a DS-CDMA signal generated based on the transmission signal received by the reception antenna. A reception equalization processing unit including a frequency equalization processing unit that performs equalization processing in a region.

  In the transmitter / receiver according to the next invention, in the above, the receiver is provided with a channel estimator that estimates a channel state of a propagation path, and the channel estimator is provided between the communication partner and the own station. The channel state of the propagation path is estimated based on communication, and the estimated channel state of the propagation path is output to the transmission equalization processing unit.

  In the above-described transmission / reception apparatus according to the invention, the function of the frequency equalization processing unit of the transmission apparatus and the function of the frequency equalization processing unit of the reception apparatus are shared.

  Also, in the transmitter / receiver according to the next invention, in the above, the frequency equalization processing unit of the transmitter has a channel gain of a channel through which the DS-CDMA signal is transmitted, a control parameter that can take an arbitrary value, A weighting process based on a predetermined weight generated based on the above is performed.

  In the transmitter / receiver according to the next invention, the predetermined weight includes a frequency element when the spread signal is subjected to FFT processing, a channel gain of a propagation path through which the DS-CDMA signal is transmitted, Normalization is performed based on the control parameter and the number of antennas of the transmission antenna.

  Further, the transmitting / receiving apparatus according to the next invention is characterized in that, in the above, the transmitting antenna includes a plurality of antennas, and includes a plurality of the transmission equalization processing units respectively connected to the plurality of antennas. To do.

  A transmitter according to the next invention is a transmitter that transmits a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1, and for the DS-CDMA signal, A plurality of transmission equalization processing units each having a frequency equalization processing unit for performing equalization processing in the frequency domain; and the plurality of transmission equalization processing units connected in the frequency domain by the plurality of transmission equalization processing units. And a plurality of transmission antennas that transmit signals generated based on the DS-CDMA signal subjected to the equalization processing as transmission signals.

  In the transmitter according to the next invention, in the above, the frequency equalization processing unit generates the channel gain of the propagation path through which the DS-CDMA signal is transmitted and the number of antennas of the transmission antenna. A weighting process based on the determined predetermined weight is performed.

  In the transmitter according to the next invention, the predetermined weight is a maximum ratio combining (MRC) weight in the above.

  In the transmitter according to the next invention, in the above, the predetermined weight is a threshold value for switching between the MRC weight and an equal gain combining (EGC) weight using a predetermined threshold value. It is characterized by a control equalizing and combining (CEC: Control Gain Combining) weight.

  Also, in the transmitter according to the next invention, in the above, the predetermined threshold value is observed on the reception side when frequency domain equalization transmission processing is performed by the plurality of transmission equalization processing units, etc. Channel gain.

  In addition, a transmission / reception apparatus according to the next invention receives a transmission apparatus that transmits a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1, and a transmission signal transmitted from another station. And a receiving device that generates and outputs information included in the DS-CDMA signal, and the transmitting device performs equalization processing in the frequency domain on the DS-CDMA signal generated by itself A plurality of transmission equalization processing units each having a frequency equalization processing unit, and a DS connected to the plurality of transmission equalization processing units and subjected to equalization processing in the frequency domain by the plurality of transmission equalization processing units A plurality of transmission antennas for transmitting a signal generated based on the CDMA signal as a transmission signal;

  Also, in the transmitter / receiver according to the next invention, in the above, the receiver is configured to receive a transmission antenna for receiving a transmission signal and a frequency for a DS-CDMA signal generated based on the transmission signal received by the reception antenna. A reception equalization processing unit including a frequency equalization processing unit that performs equalization processing in a region.

  In the transmitter / receiver according to the next invention, in the above, the receiver is provided with a channel estimator that estimates a channel state of a propagation path, and the channel estimator is provided between the communication partner and the own station. The channel state of the propagation path is estimated based on communication, and the estimated channel state of the propagation path is output to the transmission equalization processing unit.

  Further, the transmitter according to the next invention is characterized in that, in the above, the function of the frequency equalization processing unit of the transmission device and the function of the frequency equalization processing unit of the reception device are shared.

  Moreover, the mobile station apparatus concerning the next invention is provided with the transmission apparatus as described above.

  Moreover, the mobile station apparatus concerning the next invention is provided with the transmission / reception apparatus as described above.

  According to the transmission apparatus of the present invention, the frequency domain is used by using a weight that favorably distributes the power allocated to each subcarrier or a weight that favorably distributes the power allocated to each of the plurality of transmission antennas. Since equalization transmission processing is performed, an effect that the average BER characteristic of a signal received by the reception system can be improved is obtained.

  Moreover, according to the mobile station apparatus concerning this invention, there exists an effect that the collapse of the orthogonality in the channel which arises based on the signal between different users can be compensated.

  Hereinafter, embodiments of a transmission device according to the present invention, and a transmission / reception device and a mobile station device including the transmission device will be described in detail with reference to the drawings. Is not limited. Before describing the embodiments of the present invention, the characteristics of the transmission apparatus according to the present invention, and the transmission / reception apparatus and mobile station apparatus including the transmission apparatus will be described.

(Features of the present invention)
In recent mobile communication, frequency domain equalization reception is attracting attention instead of Rake combining. On the other hand, when frequency domain equalization reception is applied to the bidirectional communication system, the receivers of both transmitting and receiving stations need this frequency domain equalization reception function. Therefore, the present invention discloses a technique in which only one transmission / reception station has frequency domain equalization processing.

  Next, in order to facilitate understanding of the present invention, features of the functions of the present invention will be described using a base station and a mobile station. First, in mobile station → base station communication (uplink), a mobile station performs frequency domain equalization transmission processing in advance and transmits. Therefore, the frequency domain equalization reception function is not required for base station reception. On the other hand, in base station → mobile station communication (downlink), the base station performs transmission without performing equalization processing (as before), while the mobile station performs frequency domain equalization reception processing. In this way, only the mobile station needs to have the functions of frequency domain equalization transmission processing and reception processing. Since these relationships are established even when the relationship between the base station and the mobile station is reversed, a part of the functions of either the base station or the mobile station can be reduced. In addition, since there are many common points in the functions of frequency domain equalization transmission processing and frequency domain equalization reception processing, by sharing both functions, the base station or mobile station where the frequency domain equalization processing is implemented It is also possible to limit the increase in device scale.

  The second feature of the processing of the present invention resides in the weighting processing in the frequency equalization processing unit as described in detail below. The present invention discloses several weights (values) for weighting processing. Among these weights, the power allocated to each subcarrier is preferably distributed. Further, with other weights, the power allocated to each of the plurality of transmission antennas is suitably distributed.

  It should be noted that the present invention is preferably provided in the mobile station apparatus, and details thereof will be described in Embodiment 3. Hereinafter, as the best mode for carrying out the invention, the configuration and operation of the three embodiments according to application to DS-CDMA transmission will be described in detail.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a configuration of a DS-CDMA transmission / reception system according to the present invention. More specifically, FIG. 1 is a block diagram showing a configuration of a DS-CDMA transmission / reception system that performs frequency equalization processing in a transmission system. . The transmission / reception apparatus shown in the figure includes a transmission system for transmitting transmission signals through the transmission antenna 9 (upper part of the figure) and a reception system for receiving reception signals via the reception antenna 10 (lower part of the figure). It consists of.

In FIG. 1, a transmission system includes a data modulation unit 11 that generates modulation data obtained by performing primary modulation such as PSK modulation and QAM modulation on transmission data (d _i ), and a spread that generates a spread signal from the modulation data. 12, a scramble modulation unit 13 that performs modulation using a scramble code on the spread signal generated by the spread unit 12, and an equalization process in the frequency domain for the modulation signal output from the scramble modulation unit 13 A frequency equalization processing unit 15 that performs the above, a guard interval insertion unit (hereinafter referred to as “GI insertion unit”) 16 that adds a redundant signal called a guard interval to the signal output from the frequency equalization processing unit 15; , Is provided. In the above configuration, the frequency equalization processing unit 15 and the GI insertion unit 16 are collectively referred to as a transmission equalization processing unit 14.

  On the other hand, except for frequency equalization processing, the reception system performs processing that is exactly the reverse of the processing performed in the transmission system, and includes processing units corresponding to these processing. That is, the receiving system includes a guard interval removing unit (hereinafter referred to as “GI removing unit”) 21 that removes a guard interval from a received signal received via the receiving antenna 10, and a pseudo signal output from the GI removing unit 21. A descrambling unit 23 for returning a broadband signal of a noise sequence to a spread signal, a despreading unit 24 for generating original modulation data for the spread signal output from the descrambling unit 23, and an output from the despreading unit 24 And a data demodulator 25 for demodulating the modulated data.

  Next, the operation of this transmission / reception apparatus will be described with reference to FIGS. FIG. 2 is a block diagram for explaining processing of a transmission system in multicode DS-CDMA communication, and FIG. 3 is a block diagram for explaining processing of a reception system in multicode DS-CDMA communication.

In FIG. 2, input signal data (d _i , i = 1 to u) (“u” is the number of users, for example) is modulated (primary modulation) by the data modulator 11, and the modulated data is spread by the spreader 12. Is input. The spreading unit 12 multiplies the modulation data by an orthogonal spreading code sequence (C _i , i = 1 to u) such as a WH (Walsh-Hadamard) sequence code to generate a spread signal. The scramble modulation unit 13 multiplies the spread signal by a scramble code (C _scr ) such as an M sequence. This scramble modulation process is performed to convert a signal sequence generated as a spread signal into a pseudo-noise sequence signal. The pseudo-noise sequence signal is converted into parallel data by the serial / parallel converter 41, and after the time domain signal is converted into the frequency domain signal by the FFT processor 42, the frequency equalization processor 15 and the IFFT process are performed. Output to the transmission equalization processing unit 14 including the unit 44, the parallel / serial conversion unit 45, and the GI insertion unit 16.

  In the transmission equalization processing unit 14, the frequency domain signal output from the FFT processing unit 42 is weighted with a predetermined weight value in the frequency equalization processing unit 15, and is converted into a time domain signal in the IFFT processing unit 44. The parallel / serial conversion unit 45 converts the data into serial data. The GI insertion unit 16 adds a guard interval to the serial signal output from the parallel / serial conversion unit 45, that is, the pseudo noise signal subjected to frequency equalization processing. This guard interval insertion processing is performed to prevent intersymbol interference due to multipath. A signal to which the guard interval is added is transmitted from the transmission antenna 9 as a transmission signal.

In FIG. 3, the received signal received via the receiving antenna 10 has the guard interval removed by the GI removal unit 21 and is output to the scramble release unit 23. In the descrambling unit 23, the wideband signal of the pseudo noise sequence is converted into a spread signal using the scramble code (C _scr ) used in the transmission system and the complex conjugate scramble code (C _scr ^* ). Is output. The despreading unit 24 includes correlators 47 _{1 to} 47 _u realized by a sliding correlator or a matched filter. In these correlators 47 _{1 to} 47 _u , modulated data is generated from the spread signal using the orthogonal spreading code sequence (C _i ) used in the transmission system and the complex conjugate orthogonal spreading code sequence (C _i ^* ), The data demodulator 25 demodulates the input data signal.

  FIG. 4 is a diagram illustrating a data frame of a DS-CDMA signal to which the above-described guard interval (GI) is added. The guard interval is inserted in order to prevent interference between data frames caused by a plurality of delay paths having different delay times, and the length thereof is set according to the maximum delay time in the transmission path. If the maximum delay time is within the guard interval, the received signal can be regarded as a periodic waveform within the FFT processing time.

As shown in FIG. 4, on the transmission side, the last Ng chip of the chip sequence of the spread signal spread by the spread code is copied and added as a guard interval (GI) to the head of the data frame. Here, a high-speed data sequence whose band has been expanded by a spreading code is referred to as a chip sequence, and a minimum unit of the data sequence is referred to as one chip. For example, a period of 256 chips means that a 1-bit band is expanded to a 256-fold band by spreading coding. Now, the guard interval length T _g when the chip length (length of one chip) and T _C is represented by _{T g = N g × T C} . Also, to represent the spreading factor SF (Spreading Factor), the data symbol length is spread signal length of 1 bit, the SF × T _C. Assuming that N symbols are transmitted per user within one frame, the transmission symbol length, which is the data length of the modulated data with the guard interval added, is (N _g + N × SF) × T _C. Note that N × SF is the number of processing points Nc for FFT processing and IFFT processing.

FIG. 5A to FIG. 5C are explanatory diagrams for explaining the channel gain in the mobile communication environment. As shown in FIG. 5A, in mobile communication, a signal transmitted from a transmission station (Tx) is received as a different signal passing through a plurality of different propagation paths (delay paths 1 and 2). Now, assuming that the delay times of the received signals received by the receiving station (Rx) through these delay paths 1 and 2 are τ ₁ and τ ₂ , respectively, as shown in FIG. A response h (t) is obtained. On the other hand, a function obtained by Fourier transforming the impulse response h (t) is a transfer function, and the transfer function H (f) in the mobile communication environment varies in level along the frequency axis as shown in FIG. It becomes a function that shows a variable characteristic. This transfer function plays an important role in the analysis of a mobile communication system, and is called channel gain. Further, as shown in the figure, the channel gain at the nth frequency is represented by H (n).

  Next, the weights used in the weighting process performed by the frequency equalization processing unit 15 will be described using mathematical expressions. Now, assuming that the channel gain in the nth channel is H (n) and the number of points of the FFT processing executed by the FFT processing unit 42 is Nc, the weight W (n) for weighting processing (n = 1 to 1). Nc) is expressed as:

Here, λ is called a control parameter, and a suitable value is determined depending on setting values such as the number of delay paths and the spreading factor. In equation (1), when λ = 0, a ZF (Zero Focusing) weight, that is, a weight of W (n) = H ^* (n) / | H (n) | ² is given. On the other hand, when λ = ∞, an MR (Maximum Ratio) weight, that is, a weight of W (n) = H ^* (n) is given.

  In Expression (1), C is a normalization coefficient, and when the control parameter λ takes a predetermined value, the transmission power based on the weight calculated using Expression (1) is always set to a constant value. Has been added. The normalization coefficient C is expressed as the following equation.

  Here, S (n) represents the nth frequency element (component) when the spread signal s (t) is subjected to FFT processing, where s (t) is the spread signal.

  FIGS. 6A and 6B are graphs showing simulation results analyzed using the weights of Expression (1). More specifically, FIGS. 6A and 6B show SF (diffusion rate) = 1, L FIG. 6B is a graph showing the average BER with respect to the SN ratio of the transmission signal when (the number of delay paths) = 16, and FIG. 6B shows the average BER with respect to the SN ratio of the transmission signal when SF = 8 and L = 16. It is a graph. In each simulation, each processing result based on λ = 0 (ZF weight), λ = ∞ (MR weight), and MMSE-FDE reception (frequency domain equalization reception) is shown.

  In the case of SF = 1 (that is, non-diffusion), as shown in FIG. 6-1, much better performance than ZF weight (λ = 0) and MR weight (λ = ∞) is obtained. Has been obtained. In addition, by setting λ to approximately 0.02, a performance value substantially similar to that at the time of frequency domain equalization reception is obtained.

  Further, even when SF = 8, as shown in FIG. 6B, when the S / N ratio of the transmission signal is equal to or smaller than a predetermined value (approximately 13 dB in the example in the figure), λ is set to approximately 0.45. When the S / N ratio of the transmission signal is greater than or equal to the predetermined value, by setting λ to approximately 0.12, a performance value substantially similar to that at the time of frequency domain equalization reception is obtained.

  Thus, in this embodiment, the weight value shown in Equation (1) is used, and the control parameter included in this weight value is set to a predetermined value according to the condition of the transmission signal. A transmission apparatus having performance equivalent to that of a communication apparatus that performs area equalization reception processing can be realized.

  In order to calculate the weight value shown in Equation (1), it is assumed that the channel gain (H (n)) of the propagation path is known in advance on the transmission side. As one method for realizing this, for example, channel gain information obtained on the receiving side may be transmitted to the transmitting side using a control channel or the like. As another method, in the case of a two-way communication system such as a mobile communication system, the reception side on the transmission side is configured to include channel estimation means, and the estimation result of this channel estimation means is transmitted to the transmission system. You may make it use in.

  FIG. 7 is a block diagram showing a system configuration of a bidirectional communication system configured using the transmission apparatus of this embodiment. In the figure, the transmission unit 1 shown on the left side of the lower stage unit corresponds to the transmission system shown in FIG. 2, and the reception unit 2 shown on the right side of the lower stage unit corresponds to the reception system shown in FIG. On the other hand, the transmission unit 2 shown on the right side of the upper stage and the reception unit 1 shown on the left side of the upper stage show the configuration of a transmission / reception system that performs frequency domain equalization reception processing according to the prior art. The receiver 1 is provided with a channel estimator 56 corresponding to the above channel estimator so that channel gain information is transmitted from the channel estimator 56 to the frequency equalization processor 15 of the transmitter 1. It is configured. In FIG. 7, parts having the same or equivalent functions as the constituent parts in FIGS. 2 and 3 are denoted by the same reference numerals.

  As shown in FIG. 7, it is clear that the function of one transmission / reception station can be reduced by applying the transmission apparatus of this embodiment described above to the configuration of a transmission / reception system that performs frequency domain equalization reception processing that has conventionally existed. It is. For example, although one transmission / reception system is configured by the transmission unit 1 and the reception unit 1, the functions of the configuration units denoted by the same reference numerals can be shared, so part of the functions of the transmission / reception system is reduced. Therefore, the configuration of the transmission / reception system that performs the frequency domain equalization processing can be made compact. Conversely, in a transmission / reception system that does not perform frequency domain equalization processing, the function of frequency domain equalization reception processing that was necessary in the prior art can be reduced, so the configuration of the reception system is also compact. It becomes possible.

  As described above, according to the transmission apparatus and the transmission / reception apparatus of this embodiment, the frequency domain equalization process is performed on the DS-CDMA signal because the frequency domain equalization process is performed. A transmission device and a transmission / reception device having performance equivalent to that of a communication device can be realized.

  Further, according to the communication system of this embodiment, one of the transmission / reception stations where bidirectional communication is performed and the other can be configured to have a function of frequency domain equalization (transmission or reception) processing. The function of one of the stations and the other can be reduced, and an increase in the device scale can be suppressed.

Embodiment 2. FIG.
FIG. 8 is a diagram illustrating a configuration of a main part of the transmission apparatus according to the second embodiment of the present invention. The transmission apparatus shown in the figure is connected to two transmission equalization processing units 14 ₁ and 14 ₂ and these transmission equalization processing units 14 ₁ and 14 ₂ in the transmission system of the first embodiment shown in FIG. The transmission antennas 9 ₁ and 9 ₂ are configured to be provided. That is, the transmitting apparatus according to this embodiment is characterized in that it is configured to transmit transmission signals from a plurality of transmitting antennas and to perform transmission equalization processing using a suitable weight for each transmitting antenna. . The weights W ₁ (n) and W ₂ (n) used at this time are respectively expressed by the following equations.

In FIG. 8, the pseudo noise sequence signal output from the scramble modulation unit 13 is input to each of the transmission equalization processing units 14 ₁ and 14 ₂ . In transmission equalization processing units 14 ₁ and 14 ₂ , weighting processing is performed using suitable weights W ₁ (n) and W ₂ (n), respectively, and transmitted from transmission antennas 9 ₁ and 9 ₂ , respectively. On the other hand, since reception processing can be performed using both signals transmitted from the transmission antennas 9 ₁ and 9 ₂ on the reception side, reception is performed compared to the case where transmission is performed using a single transmission antenna. The signal-to-noise ratio of the signal can be increased, and at the same time, the BER can be reduced.

Note that the weights used for the weighting processing performed in each frequency equalization processing unit (not shown) of the transmission equalization processing units 14 ₁ and 14 ₂ are based on the equations (1) and (2), as in the first embodiment. To calculate.

  As described above, according to the transmission apparatus and the transmission / reception apparatus of this embodiment, a transmission signal subjected to frequency equalization processing is transmitted using a plurality of transmission antennas. Compared with the case where it transmits using, the SN ratio of a received signal can be raised and BER can be reduced.

  Although FIG. 8 illustrates a configuration using two transmission antennas, there is no limit to the number of transmission antennas except for space-mounting conditions, and a configuration using three or more transmission antennas is used. Also good.

Embodiment 3 FIG.
FIG. 9 is a diagram illustrating the configuration of the transmission / reception device according to the third embodiment of the present invention. The transmission / reception apparatus shown in the figure is subjected to an FFT process with a plurality of transmission equalization processing units 14 ₁ and 14 ₂ as shown in the second embodiment in the configuration of the transmission unit 1 of the first embodiment shown in FIG. And duplication units 59 _{1 to} 59 _Nc that duplicate and supply the frequency domain signals to the transmission equalization processing units 14 ₁ and 14 ₂ . Further, the configuration of the receiving unit 1 in FIG. 2 includes a plurality of reception equalization processing units 55 ₁ and 55 ₂ and an output combining unit 58 that combines the outputs of the reception equalization processing units 55 ₁ and 55 _2. It is configured as follows.

  Next, the operation of the transmission / reception apparatus shown in FIG. 9 will be described. Note that the description of the operations common to those of the transmission apparatus or the transmission / reception apparatus of Embodiments 1 and 2 is omitted.

In the transmission system (transmission unit 1) shown in FIG. 9, the frequency domain signal (Nc point FFT output) output from the FFT processing unit 42 is output to the duplication units 59 _{1 to} 59 _Nc . In the duplication units 59 _{1 to} 59 _Nc , the same number of outputs as the number of transmission antennas are duplicated and output to the transmission equalization processing units 14 ₁ and 14 ₂ . In the transmission equalization processing units 14 ₁ and 14 ₂ , transmission signals weighted using weights that take into account the power distribution assigned to the transmission / reception antennas 51 ₁ and 51 _{2 in} advance are generated, and the transmission / reception antennas 51 ₁ and 51 ₂ are generated. Respectively sent from. In the above-described processing, the weight considering the power distribution can be calculated based on the outputs of the channel estimation units 56 ₁ and 56 ₂ provided in the reception unit 1. The weight calculation function can be implemented in a control unit (not shown). The weight calculation procedure taking power distribution into account will be described later.

On the other hand, in the reception system (reception unit 1) shown in FIG. 9, the reception signal (guard interval additional signal) received via the transmission / reception antennas 51 ₁ and 51 ₂ is the GI removal unit 21, the serial / parallel conversion unit 41, The data is output to reception equalization processing units 55 ₁ and 55 ₂ each including an FFT processing unit 44 and a frequency equalization processing unit 15. The signal from which the guard interval has been removed by the GI removal unit 21 is converted into parallel data by the serial / parallel conversion unit 41, converted to a frequency domain signal by the FFT processing unit 42, and then the frequency equalization processing unit 15. Is output. In the frequency equalization processing unit 15, the frequency domain signal output from the FFT processing unit 42 is weighted with a predetermined weight value and output to the output synthesis unit 58. In the output combining unit 58, the output signals of Nc points output from the reception equalization processing units 55 ₁ and 55 ₂ are added and output to the IFFT processing unit 44. The subsequent operation is as described in the first embodiment.

In this embodiment, as shown in FIG. 9, each frequency equalization processing unit 15 of the reception equalization processing units 55 ₁ and 55 ₂ performs a predetermined weighting process, but the transmission unit 1 Since the transmission equalization process (frequency equalization process) is performed in advance, the process by the frequency equalization processing unit 15 of the reception unit 1 may be omitted. The system as transmitted as mentioned in the section according to the first embodiment, the channel estimator 56 _1, 56 ₂ performs channel estimation result information and other means (e.g., receiving means of the communication counterpart) With the configuration, the functions of the reception equalization processing units 55 ₁ and 55 ₂ excluding the GI removal unit 21 can be omitted.

  Next, as in the case of the first embodiment, the weights used in the weighting process performed by the frequency equalization processing unit 15 will be described using mathematical expressions. There are two types of weights used in this embodiment. Specifically, the first weight is a maximum ratio combining (MRC) weight, and the second weight is an MRC weight and an equal gain combining (EGC) weight. This is a threshold control equalization combining (CEC) weight that is switched using a threshold value.

  First, the MRC weight that is the first weight is represented by the following equation.

In Equation (4), H _u (m, n) is the channel gain at the user u of the nth channel of the mth antenna, and Nt is the number of transmission / reception antennas. The symbol “ ^* ” indicates a complex conjugate.

  Further, the CEC weight as the second weight is represented by the following equation.

In equation (5), | H _MRC , _u (n) | in parentheses is called equalization channel gain observed on the receiving side when frequency domain equalization transmission is used. Can be represented.

In Equation (6), H _u (n) = [H _u (1, n), H _u (2, n),..., H _u (Nt, n)] is the channel gain vector of the user u. is there. R ₀ is a threshold value for controlling the above CEC weight.

The MRC weight represented by Expression (5) is a weight that maximizes the instantaneous reception SN ratio of each subcarrier. On the other hand, the CEC weight expressed by Equation (6) gives equal transmission power to all antennas when the equivalent channel gain | H _MRC , _u (n) | when using the MRC weight is larger than r _0. When the EGC weight is smaller than r ₀ , the MRC weight is used to make the channel observed on the receiving side closer to frequency non-selectivity. When Nt = 1, the CEC weight is the same as the MRC weight.

  Next, simulation results will be described. However, before describing the effect depending on the weighting weight, the effect depending on the increase in the number of antennas will be described. FIG. 10 is a graph showing a simulation result analyzed using MRC weights. More specifically, FIG. 10 is a graph showing an average BER against the SN ratio of a transmission signal when the number of antennas is different. In the figure, “white circles, black circles” are results when the number of users is 32, and “white triangles, black triangles” are results when the number of users is 16. “White circle, white triangle” is the result when Nt (the number of antennas) = 1, and “black circle, black triangle” is the result when Nt = 4. SF (spreading factor) = 64 and L (delay path number) = 16 are set.

  As shown in FIG. 10, the average BER characteristic is greatly improved by increasing the number of antennas. In addition, even when the number of users increases, it can be understood that the degree of decrease in the average BER characteristic is small.

  On the other hand, FIG. 11 shows a simulation result analyzed using the MRC weight and the CEC weight, and is a graph showing the average BER with respect to the SN ratio of each transmission signal. In the figure, “black circle” is the result when using the MRC weight, and “black square” is the result when using the MRC weight, and the setting parameters are L = 16, SF = 64, Nt = 4. U = 32. For comparison, the “white circle” represents the analysis result when MMSE frequency domain equalization reception using the reception antenna diversity method is performed with the same number of reception antennas as the transmission antennas Nt (ie, Nr = 4). Show.

As shown in the figure, when the MRC weight or the CEC weight is used, the average BER = 10 ⁻⁴ is secured when the S / N ratio of the transmission signal is around 5 to 6 dB when 32 users are used. be able to. On the other hand, in the case of MMSE, for 32 users, no matter how much the S / N ratio of the transmission signal is increased, the average BER = 10 ⁻⁴ as well as the average BER = 10 ^−3. Can't get.

  The reason for this is that when reception diversity is used, it is not possible to compensate for the loss of orthogonality in the channel due to the difference between users as in the frequency domain equalization transmission processing that forms the basis of the present invention. is there. Further, in the frequency domain equalization transmission process that forms the basis of the present invention, frequency domain equalization transmission is performed for each user, so that the phase of each subcarrier component of all users can be in phase. This is because, in the equalization reception process, the phase difference between the subcarrier components of each user remains as it is, and thus the state where the orthogonality between users is lost is maintained. From this, it can be seen that in a multi-user environment, it is more effective to provide a plurality of transmission antennas on the mobile station side than to provide a plurality of antennas on the base station side.

  In addition, when comparing the MRC weight and the CEC weight, it can be seen that the CEC weight gives better BER characteristics than the MRC weight when the number of users is large.

  By the way, in the frequency domain equalization transmission process that forms the basis of the present invention, it is necessary to know the transmission status of the transmission channel. Since the frequency division duplex (FDD) scheme uses different frequencies in transmission and reception, it may be difficult to estimate an accurate channel gain of a transmission channel particularly in high-speed mobile communication. However, the time division duplex (TDD) method using the same frequency for the transmission and reception channels can solve this problem. This is because the channel state estimated using the reception channel can be used as the channel state of the transmission channel. At present, it is considered that TDD can be a next-generation duplex system, and the present invention is suitable as a transmitter of this time division duplex (TDD) system.

  As described above, according to the transmission apparatus and the transmission / reception apparatus of this embodiment, a plurality of transmission antennas are provided, and weighting is performed using weights that appropriately distribute power allocated to the plurality of transmission antennas. Since the processing is performed, an effect of improving the average BER characteristic of the signal received by the receiving system can be obtained.

  Further, according to the transmission apparatus of this embodiment, by applying to a time division duplex (TDD) type mobile station apparatus, it is possible to compensate for the disruption of orthogonality in the channel based on signals between different users. Thus, it is possible to limit the deterioration of reception quality in a communication system in which a large number of users are subscribed.

  In addition, in each weight (MRC weight and CEC weight) disclosed in this embodiment, a suitable power is allocated to each of a plurality of transmission antennas, but a suitable power is allocated to each subcarrier using a control parameter. It is also possible to incorporate the techniques of Embodiments 1 and 2 for assigning. In this case, not only the power assigned to each of the plurality of transmission antennas is suitably distributed, but also the power assigned to each subcarrier is suitably distributed. Therefore, the average BER characteristics shown in FIGS. 10 and 11 can be further improved.

It is a block diagram which shows the structure of the DS-CDMA transmission / reception system concerning this invention. It is a block diagram for demonstrating the process of the transmission system in multicode DS-CDMA communication. It is a block diagram for demonstrating the process of the receiving system in multicode DS-CDMA communication. It is a figure which shows the data frame of the DS-CDMA signal to which the guard interval (GI) was added. It is a figure for demonstrating communication between the transmitting station in a mobile communication environment, and a receiving station. It is a figure for demonstrating the impulse response in a mobile communication environment. It is a figure which shows the channel gain in a mobile communication environment. It is a graph which shows the simulation result (SF = 1, L = 16) analyzed using the weight by a control parameter. It is a graph which shows the simulation result (SF = 8, L = 16) analyzed using the weight by a control parameter. 2 is a block diagram illustrating a system configuration of a bidirectional communication system configured using the transmission apparatus according to Embodiment 1. FIG. It is a figure which shows the structure of the principal part of the transmitter concerning Embodiment 2 of this invention. It is a figure which shows the structure of the transmission / reception apparatus concerning Embodiment 3 of this invention. It is a graph which shows the simulation result in case the number of antennas analyzed using MRC weight differs. It is a graph which shows the simulation result analyzed using the MRC weight and the CEC weight.

Explanation of symbols

9, 9 ₁ , 9 ₂ Transmission antenna 10 Reception antenna 11 Data modulation unit 12 Spreading unit 13 Scramble modulation unit 14, 14 ₁ , 14 ₂ Transmission equalization processing unit 15 Frequency equalization processing unit 16 GI insertion unit 21 GI removal unit 23 Descrambler 24 Despreader 25 Data demodulator 41 Serial / parallel converter 42 FFT processor 44 IFFT processor 45 Parallel / serial converter 47 _{1 to} 47 _u Correlator 51 ₁ , 51 ₂ Transceiver antennas 55 ₁ , 55 ₂ Reception equalization processing unit 56, 56 ₁ , 56 ₂ Channel estimation unit 58 Output synthesis unit 59 ₁ , 59 ₂ Duplicating unit

Claims (23)

In a transmission apparatus that transmits a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1,
A transmission equalization processing unit including a frequency equalization processing unit that performs equalization processing in the frequency domain on the DS-CDMA signal;
A transmission antenna that transmits, as a transmission signal, a signal generated based on the DS-CDMA signal that has been equalized in the frequency domain by the transmission equalization processing unit;
A transmission device comprising:   The frequency equalization processing unit performs a weighting process based on a predetermined weight generated based on a channel gain of a channel through which the DS-CDMA signal is transmitted and a control parameter that can take an arbitrary value. The transmission apparatus according to claim 1, wherein:   The predetermined weight is based on a frequency element when the spread signal is subjected to FFT processing, a channel gain of a propagation path through which the DS-CDMA signal is transmitted, the control parameter, and the number of antennas of the transmission antenna. The transmission apparatus according to claim 2, wherein the transmission apparatus is normalized. The transmitting antenna has a plurality of antennas,
The transmission apparatus according to claim 1, further comprising a plurality of transmission equalization processing units connected to the plurality of antennas.   5. The transmission apparatus according to claim 1, wherein the channel gain of the propagation path is transmitted from a reception unit that has received a transmission signal generated based on the DS-CDMA signal. . A transmitter for transmitting a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1,
A receiving device that receives a transmission signal transmitted from another station and generates and outputs information included in the DS-CDMA signal;
In a transmission / reception device comprising:
The transmitter is
A transmission equalization processing unit including a frequency equalization processing unit that performs equalization processing in a frequency domain on the DS-CDMA signal generated by itself;
A transmission antenna that transmits, as a transmission signal, a signal generated based on the DS-CDMA signal that has been equalized in the frequency domain by the transmission equalization processing unit;
A transmission / reception device comprising: The receiving device is:
A receiving antenna for receiving a transmission signal;
A reception equalization processing unit including a frequency equalization processing unit that performs equalization processing in a frequency domain on a DS-CDMA signal generated based on a transmission signal received by the reception antenna;
The transmission / reception apparatus according to claim 6, further comprising: The receiving device includes a channel estimation unit that estimates a channel state of a propagation path,
The channel estimation unit estimates a channel state of the propagation path based on communication between a communication partner and the own station, and outputs the estimated channel state of the propagation path to the transmission equalization processing unit. The transmission / reception apparatus according to claim 7.   9. The transmission / reception device according to claim 7, wherein a function of a frequency equalization processing unit of the transmission device and a function of a frequency equalization processing unit of the reception device are shared.   In the frequency equalization processing unit of the transmission device, a weighting process based on a predetermined weight generated based on a channel gain of a channel through which the DS-CDMA signal is transmitted and a control parameter that can take an arbitrary value. The transmission / reception apparatus according to any one of claims 6 to 9, wherein:   The predetermined weight is based on a frequency element when the spread signal is subjected to FFT processing, a channel gain of a propagation path through which the DS-CDMA signal is transmitted, the control parameter, and the number of antennas of the transmission antenna. The transmission / reception apparatus according to claim 10, wherein the transmission / reception apparatus is normalized. The transmitting antenna has a plurality of antennas,
The transmission / reception apparatus according to claim 6, further comprising a plurality of transmission equalization processing units connected to the plurality of antennas. In a transmission apparatus that transmits a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1,
A plurality of transmission equalization processing units including a frequency equalization processing unit that performs equalization processing in a frequency domain on the DS-CDMA signal;
A plurality of signals that are connected to the plurality of transmission equalization processing units and that transmit signals generated as transmission signals based on DS-CDMA signals that have been subjected to equalization processing in the frequency domain by the plurality of transmission equalization processing units. Transmit antennas,
A transmission device comprising:   The frequency equalization processing unit performs weighting processing based on a predetermined weight generated based on a channel gain of a propagation path through which the DS-CDMA signal is transmitted and the number of antennas of the transmission antenna. The transmission device according to claim 13, characterized in that:   The transmission apparatus according to claim 14, wherein the predetermined weight is a maximum ratio combining (MRC) weight.   The predetermined weight is a threshold equalization combining (CEC) weight that switches the MRC weight and an equal gain combining (EGC) weight using a predetermined threshold. The transmitter according to claim 14.   The predetermined threshold value is an equalization channel gain observed on a receiving side when frequency domain equalization transmission processing is performed by the plurality of transmission equalization processing units. The transmitting device described. A transmitter for transmitting a DS-CDMA signal generated based on a spread signal including a case where the spreading factor is 1,
A receiving device that receives a transmission signal transmitted from another station and generates and outputs information included in the DS-CDMA signal;
In a transmission / reception device comprising:
The transmitter is
A plurality of transmission equalization processing units including a frequency equalization processing unit that performs equalization processing in a frequency domain on the DS-CDMA signal generated by the device;
A plurality of transmission signals that are connected to the plurality of transmission equalization processing units and that are generated based on the DS-CDMA signal that has been equalized in the frequency domain by the plurality of transmission equalization processing units. Transmit antennas,
A transmission / reception device comprising: The receiving device is:
A receiving antenna for receiving a transmission signal;
A reception equalization processing unit including a frequency equalization processing unit that performs equalization processing in a frequency domain on a DS-CDMA signal generated based on a transmission signal received by the reception antenna;
The transmitting / receiving apparatus according to claim 18, comprising: The receiving device includes a channel estimation unit that estimates a channel state of a propagation path,
The channel estimation unit estimates a channel state of the propagation path based on communication between a communication partner and the own station, and outputs the estimated channel state of the propagation path to the transmission equalization processing unit. The transmission / reception apparatus according to claim 19.   The transmission / reception apparatus according to claim 19 or 20, wherein a function of a frequency equalization processing unit of the transmission apparatus and a function of a frequency equalization processing unit of the reception apparatus are shared.   A mobile station apparatus comprising the transmission apparatus according to any one of claims 1 to 5 or claims 13 to 17.   A mobile station apparatus comprising the transmission / reception apparatus according to any one of claims 6 to 12 or claims 18 to 21.