Abstract:
The invention relates to radio engineering, more specifically to a method and a device for receiving multipath signals in a radio communications system with a code division multiple access (CDMA) and can be used for the receiving equipment of a base station. Said invention makes it possible to compensate a reciprocal signal interference of all user beams of information and pilot channels in a shaped complex cross-correlation response of all user beams of the information and pilot channels. The number of information channels and the data transmission rate in the information channels can vary from user to user. A serial compensation of the reciprocal signals interference of all user beams of the information and pilot channels during measurement of user signal parameters and complex waveform envelopes of all user beams is carried out in several iterations.

Description:
BACKGROUND OF THE INVENTION  
         [0001]    I Field of Invention  
           [0002]    The present invention relates to radio engineering, particularly, to methods and devices of multipath signal receiving in CDMA systems and can be used in BTS receiving equipment.  
           [0003]    II Description of the Related Art  
           [0004]    Today cellular communication systems are being developed at an amazing speed. Reduction of service cost and fast growth of the number of users are forced by the increasing demand for system capacity, capacity defined as a number of simultaneously served users per cell. In addition, new data exchange networks like Internet impose new requirements to data transmission rate and propagation channel reliability.  
           [0005]    These requirements have accelerated development of signal processing methods and led to the emergence of new radio communication systems. Among latest achievements in this field is CDMA systems. There are CDMA based cellular systems currently operating according to IS-95 Mobile Station—Base Station Compatibility Standard for Dual—Mode Wideband Spread Spectrum Cellular System (to be published as IS-95).—Qualcomm Inc., 3 Volumes, March 1993.—2123 p. and there are third generation standards under development for future wireless networks: UMTS [The ETSI UMTS Terrestrial Radio Access (UTRA) ITU-R RTT Candidate Submission. (UMTS Standard)] and cdma2000 [The ETSI UMTS Terrestrial Radio Access (UTRA) ITU-R RTT Candidate Submission. (UMTS Standard)]. They are supposed to add new service functions, such as high rate channels, access to Internet, location, etc.  
           [0006]    CDMA systems are asynchronous address systems, where signals from different users share a common frequency bandwidth and users are separated based on the signal type—a unique function, scrambling function, is assigned to each user. Since signals of different users arrive at the receiving end with random delays, it is not possible to provide full mutual orthogonality of signals from different users. Therefore, it is very critical to jointly differentiate and estimate signal parameters of all the users simultaneously processed at the receiving end. This task is referred to as “multi-user detection” [4] S. Verdu “Optimum Multiuser Asymptotic Efficiency”, IEEE Transactions on Communications, vol. COM-34, 9, September 1986, pp. 890-897.  
           [0007]    Despite the huge interest in multi-user detection: Z. XIE, R. T. Short, and G. K. Rushforth “A Family of Suboptimum Detectors for Coherent Multiuser Communication”, IEEE Journal on selected areas in communications, vol. 8, no.  4 , May 1990, pp. 683-690, B. Wu, Wang, “New Sub-Optimal Multiuser Detectors for Synchronous CDMA Systems”, Proceedings Pacific Rim Conference on Communications, Victoria, BC, Canada, IEEE, May, 1995, Z. Zvonar, M. Stojanivic, “Performance of Multiuser Diversity Reception in Nonselective Rayleigh Fading CDMA Channels”, IEEE Personal Communications, 1994, pp. 171-175. etc. there are still a lot of unsolved issues. For example, there is a problem to develop simple and effective methods and devices of simultaneous receiving of signals of multiple users under the conditions of a priori unknown complex envelope of receiving multipath signals with several info channels per user.  
           [0008]    At present there are different methods and devices of multipath signals in CDMA systems.  
           [0009]    There is a method of signal receiving and CDMA communication system developed by Qualcomm according to the IS-95 standard “An Overview of Application of Code Division Multiple Access (CDMA) to Digital Cellular Systems and Personal Cellular Networks”, USA, Qualcomm, May, 1992, Document Number EX60- 10010 , where base (central) station, BS, comprises N receivers that receive signals from mobile stations. The level of structural interference at BS in this system is reduced because of the use of adaptive power control of mobile station signals.  
           [0010]    However, the above method of signal receiving and communication system do not provide high interference immunity, power losses during signal receiving are possible because of the presence of multi-user interference.  
           [0011]    There are methods and algorithms of multi-user detection in synchronous coherent system of CDMA communication system described by Peter Kempf in the paper “On Multi-User Detection Schemes for Synchronous Coherent CDMA Systems”, IEEE Vehicular Technology Conference, pp. 479-483, 1995.  
           [0012]    In this paper several methods of multi-user detection are addressed. Let us consider one of them.  
           [0013]    It is assumed that N users are served in a communication system. Data transmission rates of different users, the length of info symbols are the same. Each user has a single information, info, channel. The complex envelopes of signals from different users are assumed to be known and methods of their estimation are not considered. Signal propagation channel is one path. Analysis of the suggested algorithm is carried out without fading.  
           [0014]    Unknown info parameters of users are estimated through L stages by sequential compensation of interfering effect of user signals on each other. At each of these stages the correlation responses of user signals, on which the final decision has been made at the previous stages, are formed. Out of them N/L maximum by module correlation responses are selected, on which the final decision about info parameters is made. The estimates of interfering effect of signals of these users are obtained and the output signal of this stage is generated by subtracting the obtained estimates from the output signal of the previous stage.  
           [0015]    In the described method of multi-user detection forming of the estimate of interfering impact of user signals and subtraction of this estimate are carried out at high intermediate frequency, which makes it a difficult task to implement this method.  
           [0016]    The use of the described method supposes the knowledge of complex envelopes of user signals and does not have the mechanism of their effective estimation. This renders it impossible to use this method in fading and invariable channel conditions.  
           [0017]    The presence of only info signal per user does not correspond to the structure of user signals in today&#39;s radio systems, where several info channels and pilot channel are available.  
           [0018]    Propagation channel is assumed to be one path  
           [0019]    There is a method multi-user description in a CDMA communication system described by Andrew L. C. Hui and Khaled Ben Letaief “Successive Interference Cancellation for Multiuser Asynchronous DS/CDMA Detectors in Multipath Fading Links”, IEEE, vol. 46, 3, march, 1998, pp. 384-391.  
           [0020]    In is assumed that N users are served in a communication system. Data transmission rates of different users, the lengths of info symbols, are the same. Each user has a single info channel. The complex envelopes of signals from different users are assumed to be known and their estimation methods are not considered. Propagation channel is multipath. Analysis of the algorithms is carried out under fading conditions.  
           [0021]    It is assumed that the receiving equipment of base station recovers complex envelopes and user delays highly accurately; the method of how this is done is not specified.  
           [0022]    The method is implemented in the following manner. The input signal is demodulated thus forming the correlation responses of all the paths of all the users at the output. The info parameters are estimated through sequential compensation of the interfering impact of user signals on one another through L stages. At each of L stages:  
           [0023]    the correlation responses of all the paths of each user are combined forming soft decisions on info parameters of users;  
           [0024]    the user with maximum by modulo soft decision and the final decision about his info parameter is made;  
           [0025]    considering the matrices of cross-correlation the estimate of interfering effect of a given user on the correlation responses of user signals paths by which final decision has not been made at the previous stages is formed;  
           [0026]    the correlation responses of this stage are formed by subtracting the obtained estimates of interfering effect from the correlation responses of the previous stage.  
           [0027]    The use of this method supposes the presence of accurate estimates of complex envelopes of user signals that cannot be obtained in practice because the processes of obtaining complex envelope estimates and information parameters are interrelated.  
           [0028]    A single info channel per user does not meet the user signal structure in today&#39;s radio systems, where a number of info channels is assumed. The algorithm supposes similar data transmission rates of all the users that does not correspond to real conditions.  
           [0029]    At each stage the final decision is made by one user, so at the final stage the final decision by N-L users has to be made, which, in case N is much greater than L (N&gt;&gt;L), reduces interference stability of an estimate. When the number of stages L is a bit lower than the number of users N, the algorithm becomes more complex due to multiple stages.  
           [0030]    Finally there is a multi-user detection method in the CDMA IS-95 system described by A. Duel-Hallen, J. Holtzman, Z. Zvonar in “Multiuser Detection for CDMA Systems”, IEEE Personal Communications, April 1995, pp. 46-57.  
           [0031]    In this system N users are served. The length of info symbols of different users in this system is the same. A user is supposed to have a single info channel. The estimates of complex envelopes of signals from different users are derived by non-coherent estimation of info symbols of each user with subsequent accumulation of complex correlation responses of symbols correlated in accordance with the estimates obtained. User propagation channel is assumed to be multipath. Analysis of the considered algorithm is carried out in fading conditions.  
           [0032]    The mentioned method is implemented in the following manner. The input signal is demodulated thus forming the correlation responses of signals of all the paths of all the users at the output. The info parameters are estimated by serial compensation of the interfering effect of users on each other through N stages. Within each of N stages:  
           [0033]    the correlation responses of signals of all the paths of each user are combined thus forming soft decisions about info parameters of user signals;  
           [0034]    the user of max by modulo soft decision is chosen and final decision about its info parameter is made;  
           [0035]    considering the cross-correlation matrices the estimate of interfering effect of a signal from a given user on the correlation responses of signals of user paths by which the final decision at the previous stages has not been made is formed;  
           [0036]    the correlation responses of this stage are formed by subtracting the obtained estimates of interfering effect from the correlation responses of the previous stage.  
           [0037]    The method of estimation of complex envelopes of user signals used in the described algorithm is, first, limited by the IS-95 standard frames, second, is not so efficient for it does not consider the mutual effect of user signals on each other.  
           [0038]    A single info channel per user does not correspond to the 3G user signal structure (IS-2000, UMTS, 3GPP), where a number of info channels are supposed to be available.  
           [0039]    The method supposes the same length of info symbols of different users in this system, which does not correspond to the requirements of mobile 3G standards.  
           [0040]    With a great number of users N owing to multiple stages implementation of the method becomes a complex tasks.  
         SUMMARY OF THE INVENTION  
         [0041]    The main goal of the present invention is to create the method and reliable device of multipath signal receiving in a CDMA communications system providing improved interference stability, throughput, and capacity and the reliable device for implementation of the same.  
           [0042]    This goal is attained through the following. In the method of multipath signal receiving in a CDMA mobile communications systems, where the input signal of base station, BS, is an additive mixture of user signals and noise, where a signal of every user being a collection of independently fading path signals comprises the pilot component and info components received via the corresponding pilot and info channels, the amounts of info channels per user and data transmission rates varying in user info channels, further comprising:  
           [0043]    making soft decisions about the info parameters of signals of all the info channels of all the users by compensating the interfering effect of signals of all the paths of pilot and info channels of all the users on each other, for which the input signal is searched for by isolating the paths of maximum power signals from the detected signals of paths;  
           [0044]    the complex correlation responses of signals of all the isolated paths of info channels of all the users are formed;  
           [0045]    the complex correlation responses of signals of all the isolated paths of pilot channels of all the users are formed;  
           [0046]    the complex correlation responses of signals of each path of pilot channel of each user are accumulated within the corresponding accumulation time thus generating averaged complex correlation responses of signals of all the paths of pilot channels of all the users;  
           [0047]    the generated complex correlation responses of signals of all the paths of info channels of all the users and all the generated complex correlation responses of signals of all the paths of pilot and info channels of all the users are delayed so that while compensating their interfering effect on each other the estimates of this interfering effect be formed, the soft decisions about the info parameters of signals of all the info channels of all the users are formed successively in L iterations, where L—the integer greater than or equal to 1, where at each iteration the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on each other are formed and this interfering effect is compensated in the averaged complex correlation responses of signals of all the paths of pilot channels of all the users thus forming more accurate complex correlation responses of signals of all the paths of pilot channels of all the users;  
           [0048]    the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users are made and this interfering effect is compensated in complex correlation responses of signals of all the paths of info channels of all the users thus forming more accurate complex correlation responses of signals of all the paths of info channels of all the users;  
           [0049]    the estimates of the interfering effect of signals of all the paths of info channels of all the users on signals of all the paths of pilot channels of all the users are made and this interfering effect is compensated in more accurate complex correlation responses of signals of all the paths of pilot channels of all the users thus forming the estimates of complex envelopes of signals of all the paths of all the users;  
           [0050]    the soft decisions about the info parameters of signals of all the info channels of all the users are formed successively through P l  stages compensating the interfering effect of signals of all the paths of info channels of all the users on each other, l takes the integer values of 1 to L, l—iteration number, where at the p-th stage p takes the values of 1 to P l ,  
           [0051]    more accurate complex correlation responses of signals of all the paths of each info channel of each user, p being equal to one, or the complex correlation responses of signals of all the paths of info channel of the (p−1)-th stage users, p being greater than one, are combined using the estimates of complex envelopes of signals of all the user paths thus forming soft decisions about the info parameters of signals of info channels of the p-th stage users;  
           [0052]    out of the generated soft decisions K p  maximum by modulo ones are selected and considered to be the final soft decisions about the info parameters of signals of info channels of the current iteration users;  
           [0053]    the estimates are made of the interfering effect of signals of all the paths of user info channel, corresponding to the selected soft decisions about the info parameters of user info channels, on the remaining signals of all the paths of user info channels on which the final decision has not yet been made by this stage;  
           [0054]    this interfering effect is compensated in the remaining more accurate complex correlation responses of signals of all the paths of info channels of users, p being equal to one, or in the remaining complex correlation responses of signals of all the paths of info channel of the (p−1)-th stage users, p being greater than one, thus forming complex correlation responses of signals of all the paths of info channels of the p-th stage users;  
           [0055]    at the last P l -th stage the complex correlation responses of signals of all the paths of info channels of the P l -th stage users, on which the final decision has not yet been made, are combined using the estimates of complex envelopes of signals of all the paths of users thus forming the soft decisions about the info parameters of signals of info channels of the P l -th stage users, which along with the final soft decisions about the info parameters of signals of user info channels of the previous stages are the final soft decisions about the info parameters of this iteration;  
           [0056]    the obtained soft decisions about the info parameters of signals of all the info channels of all the users and the estimates of complex envelopes of signals of all the paths of all the users of the current iteration, except the last one, that are delayed by the time of iteration, are used to generate the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on each other, the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users and the estimates of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users of the subsequent iteration;  
           [0057]    at the first iteration in order to generate the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on each other the averaged complex correlation responses of signals of all the paths of pilot channels of all the users are used, in order to generate the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users more accurate complex correlation responses of signals of the all the paths of pilot channels of all the users are used, in order to generate the estimates of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users more accurate complex correlation responses of signals of all the paths of pilot and info channels of all the users are used;  
           [0058]    the soft decisions about the info parameters of signals of all the info channels of all the users of the last iterations are the output signals for decision making.  
           [0059]    In order to put the listed features of the filed method into practice, the preferable examples of how the following operations of the methods should be executed are presented below.  
           [0060]    The accumulation interval of complex correlation responses of signals of each path of pilot channel of each user is selected to be equal to the interval of communication channel invariability but not longer than double time of tolerable signal processing delay.  
           [0061]    While forming the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on each other, the elements of cross-correlation matrix of the pseudo-random sequences of the pilot components of signals of all the paths of all the users to each other are generated. The pseudo-random sequence will be referred to in this document as PN-sequence.  
           [0062]    While forming the estimates of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the elements of cross-correlation matrix of PN sequence of the pilot components of signals of all the paths of all the users to PN sequence of the info components of signals of all the paths of all the users are generated.  
           [0063]    While forming the estimates of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users, the elements of cross-correlation matrix of PN sequence of the info components of signals of all the paths of all the users to PN sequence of the pilot components of signals of all the paths of all the users are generated.  
           [0064]    While forming the estimates of the interfering effect of signals of all the paths of info channels of all the users on each other, the elements of cross-correlation matrix of PN sequences of the info components of signals of all the paths of all the users to each other are generated.  
           [0065]    The estimates of the interfering effect of signals of all the paths of pilot channels of all the users on each other for the first iteration are formed by weight combining of the averaged complex correlation responses of signals of all the paths of pilot channels of all the users with the weights defined by the elements of cross-correlation matrix of PN sequences of the pilot components of signals of all the paths of all the users to each other, and for the subsequent iterations by weight combining of the estimates of complex envelopes of signals of all the paths of all the users of the previous iteration with the weights defined by the elements of cross-correlation matrix of PN sequence of the pilot components of signals of all the paths of all the users to each other.  
           [0066]    The interfering effect of signals of all the paths of pilot channels of all the users on each other is compensated by subtracting the generated estimates of the interfering effect of signals of all the paths of pilot channels of all the users on each other from the averaged complex correlation responses of signals of all the paths of pilot channels of all the users.  
           [0067]    The estimates of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users for the first iteration are made by weight combining of more accurate complex correlation responses of signals of all the paths of pilot channels of all the users with the weights defined by the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users, and for the subsequent iterations by weight combining of the estimates of complex envelopes of signals of all the paths of all the users of the previous iteration with the weights defined by the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users.  
           [0068]    The interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users is compensated by subtracting the generated estimates of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users from the complex correlation responses of signals of all the paths of info channels of all the users.  
           [0069]    The estimates of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users for the first iteration are made by combining more accurate complex correlation responses of signals of all the paths of each info channel of each user using more accurate complex correlation responses of signals of all the paths of pilot channel of each user thus making the interim soft decisions about the info parameters of signals of each info channel of each user, forming the estimates of the info parameters of signals of all the info channels of all the users by comparing the interim soft decisions about the info parameters of signals of each info channel of each user with preset thresholds and weight combining of the products of more accurate complex correlation responses of signals of all the paths of pilot channels of all the users and the estimates of the info parameters of signals of all the info channels of all the users with the weights defined by the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users, and for subsequent iterations by generating the estimates of the info parameters of signals of all the info channels of all the users by comparing the soft decisions about the info parameters of signals of all the info channels of all the users of the previous iteration to the preset thresholds and weight combining of the products of the estimates of complex envelopes of signals of all the paths of pilot channels of all the users of the previous iteration and the estimates of the info parameters of signals of all the info channels of all the info channels of all the users with the weights defined by the elements of cross-correlation matrix of PN sequences of the info components of signals of all the paths of all the users to the PN sequence of the pilot components of signals of all the paths of all the users.  
           [0070]    The interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users is compensated by subtracting the estimates of the interfering effect of signals from all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users from more accurate complex correlation responses of signals of all the paths of pilot channels of all the users.  
           [0071]    The interfering effect of signals of all the paths of info channels of the users corresponding to the selected soft decisions about the info parameters of signals of user info channel on the remaining info components of signals of all the user paths, on which the final decision has not yet been made by this stage, is compensated by subtracting the obtained estimates of this interfering effect from the remaining more accurate complex correlation responses of signals of all the paths of each info channel of each user, p being equal to one, or from the remaining complex correlation responses of signals of all the paths of info channels of the (p−1)-th stage users, p being greater than 1, thus forming complex correlation responses of signals of all the paths of info channels of the p-th stage users.  
           [0072]    While executing current l-th iteration, where l is greater than 1, the generated elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to each other, the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users, the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users and the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to each other are delayed by the time of previous iterations.  
           [0073]    The set goal is further attained by the device of multipath signal reception in a CDMA mobile communications system further comprising, according to the present invention, demodulation unit that generates at the first outputs delayed complex correlation responses of signals of all the paths of info channels of all the users; at the second outputs—delayed complex correlation responses of signals of all the paths of pilot channels of all the users; at the third outputs—control signals; at the fourth outputs—the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to each other, the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users, the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users and the elements of cross-correlation matrix of the PN sequences of the info components of the signals of all the paths of all the users to each other; accumulator of complex correlation responses of signals of each path of pilot channel of each user generating at the outputs averaged complex correlation responses of signals of all the paths of pilot channels of all the users; L−1 first delay units, L−1 second delay units, and L signal processing units, each generating soft decisions about the info parameters of signals of all the info channels of all the users at the first outputs; the estimates of complex envelopes of signals of all the paths of all the users at the second outputs of each of them but last L-th signal processing unit, wherein first signal processing unit implements first method iteration, subsequent signal processing units along with corresponding first and second delay units implement subsequent method iterations, the input of demodulation unit being a signal input of the device; the first outputs of demodulation unit are linked to the first inputs of L signal processing units, to first signal processing unit directly and to the rest of signal processing units via corresponding first delay units and all the previous first delay units; the second outputs of demodulation unit are connected to the inputs of accumulator whose outputs are joined with the second inputs of L signal processing units, to the first signal processing unit directly and to the rest of signal processing units via corresponding first delay units and all the previous first delay units; the first and second outputs of previous first delay unit are linked to the first and second inputs of subsequent first delay unit, the third outputs of demodulation unit are connected to the third inputs of L signal processing units; the fourth outputs of demodulation unit are connected to the fourth inputs of L signal processing units, to first signal processing unit directly and to the rest of signal processing units via corresponding second delay units and all the previous second delay units; the first outputs of previous second delay unit are connected to the fourth inputs of corresponding signal processing unit and to the first inputs of subsequent second delay unit; the first and second outputs of previous signal processing units are connected to the fifth and sixth inputs of subsequent signal processing unit via second delay unit corresponding to this subsequent signal processing unit; the second and third inputs of second delay unit are linked to the first and second outputs of previous signal processing unit and the second and third outputs of second delay unit are linked to the fifth and sixth inputs of corresponding signal processing unit; the outputs of the last L-th signal processing unit, the soft decisions about the info parameters of signals of all the info channels of all the users, are outputs of the device; each signal processing unit comprises sub-unit for compensation of the interfering effect of signals of all paths of pilot channels of all the users on each other; sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users, and sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, producing soft decisions about the info parameters of signals of all the info channels of all the users through p l  stages, where l—signal processing unit number taking the integer values of 1 to L; in first signal processing unit the first inputs are formed by the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the second inputs are formed by the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other; the third inputs are formed by the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other, the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users, and the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other; the fourth inputs are formed by the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other, the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users of the signals of all the paths of pilot channels of all the users, and the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other, generating at these outputs more accurate complex correlation responses of signals of all the paths of pilot channels of all the users, are linked to the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users and the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users, the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, generating at these outputs more accurate complex correlation responses of signals of all the paths of info channels of all the users, are connected to the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users and to the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users, generating at these outputs the estimates of complex envelopes of signals of all the paths of all the users, are joined with the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other and are second outputs of first signal processing unit, the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, generating at these outputs soft decisions about the info parameters of signals of all the info channels all the users, are the first outputs of first signal processing unit, in each subsequent l-th signal processing unit,  1  taking the integer values of 2 to L; the first inputs are formed by the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users; the second inputs are formed by the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other; the third inputs are formed by the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other, the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users and first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other; the fourth inputs are formed by the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other, the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users and second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other; the fifth inputs are formed by the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users; the sixth inputs are formed by the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other and fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users; the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other, generating at these outputs more accurate complex correlation responses of signals of all the paths of pilot channels of all the users, are linked to the fifth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users; the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on the signals of all the paths of info channels of all the users, generating at these outputs more accurate complex correlation responses of signals of all the paths of info channels of all the users, are linked to the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other; the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on the signals of all the paths of pilot channels of all the users, generating at these outputs the estimates of complex envelopes of signals of all the paths of all the users, are connected to the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other and for each signal processing unit except the last, L-th, one are the second outputs; the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, generating at these outputs soft decisions about the info parameters of signals of all the info channels of all the users, are the first outputs of signal processing unit; the outputs of the last L-th signal processing unit are the outputs of the device.  
           [0074]    It is desirable that demodulation unit and sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, which comprises signal processing unit, be accomplished in the following manner.  
           [0075]    Demodulation unit further comprises searcher, correlators for signal of each path of each user, sub-unit for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users, controller, and cross-correlation matrix element former, wherein the first inputs of correlators and searcher are combined thus forming signal input of demodulation unit, the second inputs of correlators and searchers are connected to the first and second control outputs of controller, respectively; the first outputs of each correlator and searcher are connected to the first and second inputs of controller, respectively; the second outputs of correlators are joined with the first inputs of sub-unit for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users; the second inputs of sub-unit for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users are connected to the third control outputs of controller; the first outputs of sub-unit for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users, generating at these outputs complex correlation responses of signals of all the paths of info channels of all the users, are the first outputs of demodulation unit; the second outputs of sub-unit for delay and grouping of correlation responses of signals of all the paths of info and pilot channels of all the users, generating at these outputs complex correlation responses of signals of all the paths of pilot channels of all the users, are the second outputs of demodulation unit; the fourth outputs of controller are the third outputs of demodulation unit; the fifth outputs of controller are joined with the inputs of cross-correlation matrix element former; the outputs of cross-correlation matrix element former that forms at these outputs the elements of cross-correlation matrix of the PN sequences of pilot components of signals of all the paths of all the users to each other, the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users, the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users, and the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to each other, are the fourth outputs of demodulation unit.  
           [0076]    Sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other further comprises controller and P l  successively connected nodes for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other, l taking the integer values of 1 to L, the first outputs of the previous node for compensation of the interfering effect of signals of all the paths of info channels on each other are connected to the first inputs of subsequent node for compensation of the interfering effect of signals of all the paths of user info channels on each other; the first inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other are formed by the first inputs of controller; the second inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other are formed by the second inputs of nodes for compensation of the interfering effect of signals of all the paths of info channels on each other; the third inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other are formed by the first inputs of first node for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other; the fourth inputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other are formed by the third inputs of nodes for compensation of the interfering effect of signals of all the paths of user info channels on each other; the first outputs of controller are connected to the fourth inputs of nodes for compensation of the interfering effect of signals of all the paths of user info channels on each other; the second outputs of controller are the outputs of sub-unit for compensation of the interfering effect of signals of all the paths of info channels of all the users on each other; the second outputs of nodes for compensation of the interfering effect of signals of all the paths of user info channels on each other are connected to the second inputs of controller. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0077]    The features, objects, and advantages of the present invention will become more apparent from the detailed description set forth below when taken in conjunction with the drawings in which like reference characters correspond throughout and wherein:  
         [0078]    [0078]FIG. 1 is a block diagram of the filed device of multipath signal receiving in a CDMA radio communications system;  
         [0079]    [0079]FIG. 2 is demodulation unit  1 ;  
         [0080]    [0080]FIGS. 3 a  and  3   b  are time positions of signals of user info channels with various info symbol length before and after delay;  
         [0081]    [0081]FIG. 4 is accumulator  2 ;  
         [0082]    [0082]FIG. 5 is first signal processing unit  3   1 ;  
         [0083]    [0083]FIG. 6— 1 -th signal processing unit  3   l, l  taking the values of 1 to L;  
         [0084]    [0084]FIG. 7 is sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other;  
         [0085]    [0085]FIG. 8 is sub-unit  24  for compensation of the interfering effect of signals of all the pilot channel paths of all the users on each other;  
         [0086]    [0086]FIG. 9—is node  33   jn  for isolation of signal from the j-th pilot channel path of the n-th user of first signal processing unit  3   1  (or node  35   jn  for isolation of signal from the j-th pilot channel path of the n-th user of the l-th signal processing unit  3   l , which is similar to node  33   jn );  
         [0087]    [0087]FIG. 10 is sub-unit  37   ik  of formation of interference the signal of the i-th pilot channel path of the k-th user to the signal of the q-th symbol of the j-th pilot channel path of the n-th user of node  33   jn  (or node  35   jn , which is similar to node  35   jn );  
         [0088]    [0088]FIG. 11 is subtractor  18   n  of sub-unit  15  of unit  3   1  (or subtractor  28   n  of sub-unit  25  of unit  3   l .), this block diagram is given as an exemplary embodiment of subtractors  18   1 - 18   N  and  28   1 - 28   N , accomplished similarly;  
         [0089]    [0089]FIG. 12 is node  44   jm  for isolation of signal from the j-th path of the m-th info channel of subtractor  18   n  of sub-unit  15  and subtractor  28   n  of sub-unit  25 ;  
         [0090]    [0090]FIG. 13 is sub-unit  46   ik  of formation of the interference of the signal of the s-th bit of the i-th pilot channel path of the k-th user to the info signal of the q-th symbol of the j-th path of the m-th info channel of the n-th user of node  44   jm ;  
         [0091]    [0091]FIG. 14 is switch  21  of sub-unit  16  (or switch  30  of sub-unit  26  accomplished similarly to switch  21 );  
         [0092]    [0092]FIG. 15 is switching node  51   jn  of the signal from the j-th path of the n-th user of switch  21  of sub-unit  16  and switch  30  of sub-unit  26 ;  
         [0093]    [0093]FIG. 16 is sub-node  53   imk  of former of k-th user m-th info channel i-th path signal interference to the signal of n-th user pilot channel j-th path q-th symbol of switching node  51   jn  of switch  21  of sub-unit  16  and switch  30  of sub-unit  26 ;  
         [0094]    [0094]FIG. 17 is subtractor  20  of sub-unit  16  (or subtractor  29  of sub-unit  26 , which is accomplished similarly to subtractor  20  of sub-unit  16 );  
         [0095]    [0095]FIG. 18 is node  23   p  for compensation of the interfering effect of signals of all the user info channel paths on each other of sub-unit  15  of unit  3   1  or node  32   p  for compensation of the interfering effect of signals of all the user info channel paths on each other of sub-unit  25  of unit  31 , the block diagram is given as an exemplary embodiment of nodes  23   l - 23   p     l    and  32   1 - 32   p     l   , accomplished similarly.  
         [0096]    [0096]FIG. 19 is sub-node  62   p  for combining and selection of soft decisions about the info parameters of signals from user info channels of node  23   p  or node  32   p  accomplished similarly;  
         [0097]    [0097]FIG. 20 is switch  64   p  of nodes  23   p  and  32   p ;  
         [0098]    [0098]FIG. 21 is sub-node  68   jrn  of formation of signal from j-th path of r-th info channel of n-th user of switch  64   p ;  
         [0099]    [0099]FIG. 22 is element  71   ikm  of formation of k-th user m-th info channel i-th path signal interference to the signal of n-th user r-th info channel j-th path q-th symbol of sub-node  68   jrn . 
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0100]    The filed device of multipath signal receiving in a CDMA mobile communications system shown on FIG. 1 comprises the following: demodulation unit  1  that generates at the first outputs delayed complex correlation responses of signals of all the user info channel paths, at the second outputs—delayed complex correlation responses of signals of all the user pilot channel paths, at the third outputs—control signals, at the fourth outputs—the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the user paths to each other, the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of all the paths of all the users, the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users, and the elements of cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to each other, accumulator  2  of complex correlation responses of signals of each path of each pilot channel, generating at the outputs averaged complex correlation responses of signals of all the user pilot channel paths, L- 1  first delay units  4   2 - 4   L,  L−1 second delay units  5   2 - 5   L  and L signal processing units  3   1 - 3   L , providing estimation of the info parameters of info channel signals of N users and at the first outputs of each forming soft decisions about the info parameters of signal from all the user info channels, at the second outputs of each of them but the last L-th signal processing unit  3   L —the estimates of complex envelopes of signals of all the user paths, where first signal processing unit implements first iteration of the method, subsequent signal processing units with corresponding first and second delay units implement subsequent method iterations; the input of demodulation unit  1  being a signal input of the device, the first outputs of demodulation unit  1  are linked to the first inputs of L signal processing units  3   1 - 3   L , wherein to first signal processing unit  3   1  directly and to the rest of signal processing units  3   1  via first delay units  4   1  and all the previous first delay units  4   2 - 4   1-1  corresponding to them, l taking the integer values of 2 to L, the second outputs of demodulation unit  1  are joined with the inputs of accumulator  2  whose outputs are linked to the second inputs of L signal processing units  3   1 - 3   L , wherein to first signal processing unit  3   1  directly and to the rest of signal processing units  3   1  via first delay units  4   1  and all the previous first delay units  4   2 - 4   1-1  corresponding to them, l taking the integer values of 2 to L, the first and second outputs of previous first delay unit  4   1-1  are connected to the first and second inputs of subsequent first delay unit  41 , the third outputs of demodulation unit  1  are joined with the third inputs of L signal processing units  3   1 - 3   L , the fourth outputs of demodulation unit  1  are linked to the fourth inputs of L signal processing units  3   1 - 3   L , wherein to first signal processing unit  3   1  directly and to the rest of signal processing units  3   1  via second delay units  51  and all the previous second delay units  5   2 - 5   1-1  the first outputs of previous second delay unit  5   1-1  are connected to the fourth inputs of signal processing unit  3   1-1  corresponding to it and to the first inputs of subsequent second delay unit  51 , the first and second outputs of previous signal processing unit  3   1-1  are joined with the fifth and sixth inputs of subsequent signal processing unit  3   1  via second delay unit  51 , corresponding to this subsequent signal processing unit, l taking the integer values of 2 to L, the second and third inputs of second delay unit  5   1  are joined with first and second outputs of previous signal processing unit  3   1-1  and the second and third outputs of second delay unit  51  are coupled to the fifth and sixth inputs of corresponding signal processing unit  3   1 , the outputs of the last L-th signal processing unit  3   L , the soft decisions about the info parameters of all the user info channel signals, are the outputs of the device.  
         [0101]    Demodulation unit  1  as per FIG. 2 comprises, in the present embodiment, searcher  6 , correlators  7   11 - 7   j     N     N  for signal of each path of each user, sub-unit  8  for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users, controller  9 , and cross-correlation matrix element former  10 , wherein the first inputs of correlators  7   11 - 7   J     N     N  and searcher  6  are combined thus forming signal input of demodulation unit  1 , the second inputs of correlators  7   11 - 7   J     N     N  and searcher  6  are connected to the first and second control outputs of controller  9 , respectively; the first outputs of each correlator  7   11 - 7   J     N     N  and searcher  6  are connected to the first and second inputs of controller  9 , respectively; the second outputs of correlators  7   11 - 7   J     N     N  are joined with the first inputs of sub-unit  8  for delay and grouping of the correlation responses of signals of all the user info and pilot channel paths; the second inputs of sub-unit  8  for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users are linked to the third control outputs of controller  9 ; the first outputs of sub-unit  8  for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users, generating at these outputs complex correlation responses of signals of all the paths of info channels of all the users, are the first outputs of demodulation unit  1 ; the second outputs of sub-unit  8  for delay and grouping of the correlation responses of signals of all the paths of info and pilot channels of all the users, generating at these outputs complex correlation responses of signals of all the paths of info channels, are the second outputs of demodulation unit  1 ; the fourth outputs of controller  9  are the third outputs of demodulation unit  1 ; the fifth outputs of controller  9  are joined with the inputs of cross-correlation matrix element former  10 ; the outputs of cross-correlation matrix element former  10 , that forms at these outputs the elements of cross-correlation matrices KPP, KPS, KSP, KSS, are the fourth outputs of demodulation unit  1 .  
         [0102]    Accumulator  2  for the filed device as per FIG. 4 in the present embodiment comprises  
         ∑     n   =   1     N          J   n                           
 
         [0103]    accumulation branches  11   11 - 11   j     N     N  that accumulate the complex correlation responses of signals of all the user pilot channel paths. Each accumulation branch  11   jn , n taking the integer values of 1 to N, j taking the integer values of 1 to J n , comprises tapped delay line  12   jn  and combiner  13   jn  The inputs of delay line  12 - 12  in each accumulation branch make up the inputs of accumulator  2 ; the outputs of tapped delay line  12   11 - 12   J     N     N  in each accumulation branch are coupled with the inputs of combiners  13   11 - 13   J     N     N . The outputs of combiners  13   11 - 13   J     N     N  of all the accumulation branches  11   11 - 11   J     N     N  make up the outputs of accumulator  2 .  
         [0104]    First signal processing unit  3   1  comprising according to FIG. 5 in the present embodiment sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, and sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths on each other carries out formation of soft decisions about the info parameters of signals from all the user info channels through P l  stages.  
         [0105]    The first inputs of unit  3   1  are formed by the first inputs of sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths; the second inputs of unit  3   1  are formed by the first inputs of sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other; the third inputs of unit  3   1  are formed by the second inputs of sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, the second inputs of sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, the first inputs of sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, and the first inputs of sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths on each other; the fourth inputs are formed by the third inputs of sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, the third inputs of sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, the second inputs of sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, and the second inputs of sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths on each other; the outputs of sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, forming at these output more accurate complex correlation responses of signals of all the user pilot channels, are joined to the fourth inputs of sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths and third inputs of sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths; the outputs of sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, forming at these outputs more accurate complex correlation responses of signals of all the user info channels, are connected to the fourth inputs of sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths and to third inputs of sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths on each other; the outputs of sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, forming at these outputs the estimates of complex envelopes of signals from all the user paths, are linked to the forth inputs of sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths on each other are present second outputs of first signal processing unit  3   1 ; the outputs of sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths on each other, forming at these outputs soft decisions about the info parameters of signals of all the user info channels, are the first outputs of first signal processing unit  3   1 .  
         [0106]    Each subsequent signal processing unit  3   1  according to FIG. 6 in the present embodiment comprising sub-unit  24  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, and sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other, carries out formation of the soft-decisions about the info parameters of signals of all the user info channels through P l  stages, where/is the number of signal processing unit taking the values of 1 to L. The first inputs of unit  3   1  are formed by the first inputs of sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths. The second inputs of unit  3   1  are formed by the first inputs of sub-unit  24  for compensation of the interfering effect of signals of all the user pilot channel paths on each other. The third inputs of unit  3   1  are formed by the second inputs of sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, the second inputs of sub-unit  24  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, the first inputs of sub-unit  26  for compensation of the interfering effect of signals of all the user info channels, and the first inputs of sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other. The fourth inputs of unit  3   1  are formed by the third inputs of sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, the third inputs of sub-unit  24  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, the second inputs of sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, and the second inputs of sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other. The fifth inputs of unit  3   1  are formed by the third inputs of sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths. The sixth inputs of unit  3   1  are formed by the fourth inputs of sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, the fourth inputs of sub-unit  24  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, and the fourth inputs of sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths. The outputs of sub-unit  24  for compensation of the interfering effect of signals of all the user pilot channel paths on each other, forming at these outputs more accurate complex correlation responses of signals of all the user pilot channel paths, are joined to the fifth inputs of sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths. The outputs of sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, forming at these outputs more accurate complex correlation responses of all the user info channel paths, are coupled to the third inputs of sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other. The outputs of sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths, forming at these outputs the estimates of complex envelopes of signals of all the user paths, are connected to the fourth inputs of sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other and to each signal processing unit except the last L-th one are the second outputs of unit  3   1 . The outputs of sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other, forming at these outputs soft decisions about the info parameters of signals of all the user info channels, are the first outputs of signal processing unit  3   1 . The outputs of the last L-th signal processing unit  3   L  are the outputs of the device.  
         [0107]    Sub-unit  14  for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other of signal processing unit  3   1  according to FIG. 7 in the present embodiment comprises  
         ∑     n   =   1     N          J   n                           
 
         [0108]    parallel nodes  33   11 - 33   J     N     N  for isolation of signal of each pilot channel path of each user and controller  34 .  
         [0109]    Sub-unit  24  for compensation of the interfering effect of signals of all the paths of pilot channels of all the users on each other of signal processing unit  3   1  according to FIG. 8 in the current embodiment comprises  
         ∑     n   =   1     N          J   n                           
 
         [0110]    parallel nodes  33   11 - 33   J     N     N  for isolation of signal of each pilot channel path of each user and controller  36 .  
         [0111]    Nodes  33   11 - 33   J     N     N  and  33   11 - 33   J     N     N  are accomplished in a similar way. In the described embodiment FIG. 9 present the block diagram of node  33   jn  (or  35   jn ) for isolation of signal n-th user j-th pilot channel path. According to the present embodiment node  33   jn  in is composed of  
           ∑     n   =   1     N          J   n       -   1                         
 
         [0112]    sub-units  
         [0113]    [0113] 37   ik  of formation of the interference from signal of k-th user i-th pilot channel path to the signal of n-th user j-th pilot channel path q-th symbol, k taking the values of 1 to N, i taking the values of 1 to J k , except simultaneous meeting of the equalities i=j, k=n; combiner  38 ; tapped delay line  39 ; combiner  40 ; subtractor  41 .  
         [0114]    Sub-unit  37   ik  of formation of the interference from signal of k-th user i-th pilot channel path to the signal of n-th user j-th pilot channel path q-th symbol according to FIG. 10 in the present embodiment comprises multiplier  42  and reset combiner  43 .  
         [0115]    Sub-unit  15  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths of unit  3   1  according to FIG. 5 in the present embodiment comprises N parallel subtractors  18   1 - 18   N .  
         [0116]    Sub-unit  25  for compensation of the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths of unit  3   1 , l taking the integer values of 2 to L, according to FIG. 6 in the present embodiment N parallel subtractors  28   1 - 28   N .  
         [0117]    Subtractors  18   1 - 18   N  and  28   1 - 28   N  are accomplished similarly. As an exemplary embodiment FIG. 11 shows the block diagram of subtractor  18   n  (or  28   n ). Subtractor  18   n  in the present embodiment comprises J n M n  nodes  44   jm  for isolation of m-th info channel j-th path, and controller  45 .  
         [0118]    Node  44   jm  for isolation of signal of m-th info channel j-th path according to FIG. 12 in the current embodiment comprises  
           ∑     n   =   1     N          J   n       -   1                         
 
         [0119]    sub-units  46   ik  of formation of the interference from signal of k-th user i-th path to the signal of n-th user m-th info channel j-th path q-th symbol, k taking the integer values of 1 to N, i taking the integer values of 1 to J k , except simultaneous meeting the equalities of i=j, k=n; combiner  47 , and subtractor  48 .  
         [0120]    Sub-unit  46   ik  of formation of the interference from signal of k-th user i-th path to the signal of n-th user m-th info channel j-th path q-th symbol according to FIG. 13 in the present embodiment comprises multiplier  49  and reset combiner  50 .  
         [0121]    Sub-unit  16  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths of unit  3   1  (FIG. 5) comprise N parallel multipath user signal receivers  19   1 - 19   N , subtractor  20 , and switch  21 .  
         [0122]    Sub-unit  26  for compensation of the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel paths of unit  3   1 , where l taking the integer values of 2 to L, according to FIG. 6 in the present embodiment comprises subtractor  29  and switch  30 .  
         [0123]    Note that switch  21  of sub-unit  16  and switch  30  of sub-unit  26  are accomplished similarly. As an exemplary embodiment FIG. 14 shows the block diagram of switch  21  (or  30 ). Switch  21  according to FIG. 14 in the present embodiment comprises  
         ∑     n   =   1     N          J   n                           
 
         [0124]    nodes  51   jn  of n-th user j-th signal switching, n taking the integer values of 1 to N, j taking the integer values of 1 to J n , and controller  52 .  
         [0125]    Node  51   jn  of n-th user j-th path signal switch according to FIG. 5 in the present embodiment comprises  
           ∑     n1   =   1     N          (       J   n1          M   n1       )       -     M   n                           
 
         [0126]    sub-nodes  53   imk  of formation of the interference from signal of k-th user m-th info channel i-th path to the signal of n-th user j-th pilot channel path q-th symbol, where k taking the integer values of 1 to N, i taking the integer values of 1 to J k , m taking the integer values of 1 to M k , except simultaneous meeting the equalities of i=j, k=n, and combiner  54 .  
         [0127]    An exemplary embodiment of sub-node  53   imk  shown on FIG. 16 in comprises threshold comparison element  55 , multipliers  56 ,  57 , and reset combiner  58 .  
         [0128]    Subtractor  20  of sub-unit  16  and subtractor  29  of sub-unit  26  are accomplished similarly. As an exemplary embodiment FIG. 17 shows the block diagram of subtractor  20  (or  29 ). Subtractor  20  according to FIG. 17 in the present embodiment comprises  
         ∑     n   =   1     N          J   n                           
 
         [0129]    subtraction branches  
         [0130]    [0130] 59   11 - 59   j   N . Each subtraction branch  59   jn  comprises tapped delay line  60   jn  and subtractor  61   jn .  
         [0131]    Sub-unit  17  for compensation of the interfering effect of signals of all the user info channel paths-on each other of unit  3   1  according to FIG. 5 and sub-unit  27  for compensation of the interfering effect of signals of all the user info channel paths on each other of unit  3   1  according to FIG. 6 are accomplished in the same way.  
         [0132]    Sub-unit  17  according to FIG. 5 in the present embodiment comprises controller  22  and P 1  successively connected nodes for compensation of the interfering effect of signals of all the user info channel paths on each other  231 - 23  P 1   
         [0133]    Sub-unit  27  of FIG. 6 comprises controller  31  and P 1  successively connected nodes for compensation of the interfering effect of signals of all the user info channel paths on each other  32   1 - 32   p     l   . Nodes  23   i - 23   p  and  32   1 - 32   p  are accomplished in the same way. As an exemplary embodiment FIG. 18 shows the block diagram of node  23   p  (or  32   p ). Node  23   p  of FIG. 18 in the present embodiment comprises sub-node  62  of combining and selection of the soft decisions about the info parameters of user info channel signals, subtractor  63 , and switch  64 .  
         [0134]    Sub-node  62  of combining and selection of the soft decisions about the info parameters of user info channel signals of FIG. 19 in the present embodiment comprises user info channel path combining element  65 , maximum selection element  66 , and control element  67 .  
         [0135]    Switch  64  of FIG. 20 according to the present embodiment comprises  
         ∑     n   =   1     N            J   n          M   n                             
 
         [0136]    sub-nodes  68   jrn  of formation of the interference from signal of n-th user r-th info channel j-th path and the same number of controllable keys  65   jrn  corresponding to them, where n takes the integer values of 1 to N, j takes the integer values of 1 to J n  r takes the integer values of 1 to M n , and controller  70 .  
         [0137]    Sub-node  68   jrn  of formation of the interference from signal of n-th user r-th info channel of j-th path of FIG. 21 according to the present embodiment comprises  
         ∑     n   =   1     N            J   n          M   n                             
 
         [0138]    elements  71   imk  of formation of the interference from signal of k-th user m-th info channel i-th path to the signal of n-th user r-th info channel j-th path q-th bit, k taking the integer values of 1 to N, i taking the integer values of 1 to J k , m taking the integer values of 1 to M k ,  
         ∑     n   =   1     N            J   n          M   n                             
 
         [0139]    controllable keys  72   imk , and combiner  73 .  
         [0140]    Element  71   jmk  of formation of the interference from signal of k-th user m-th info channel i-th path to the signal of n-th user r-th info channel j-th path of FIG. 22 according to the present embodiment comprises threshold comparison element  74 , multiplier  75  and  76 , reset combiner  77 .  
         [0141]    Let us consider implementation of this method of multipath signal receiving in a CDMA communications system. In order to make operation of the filed method more understandable, references will be made to the block diagrams of the filed device shown on FIGS.  1 - 22 .  
         [0142]    For example, there are N users in a CDMA communications system. Signal of each user composed of a collection of independently fading path signals comprises the pilot component and M n  info components received via pilot and info channels respectively. The value n denotes user number and takes the integer values of 1 to N, there may be various data transmission rates in user info channels.  
         [0143]    An additive mixture of user signals and noise is supplied to the input of demodulation unit  1  (FIG. 1). In demodulation unit  1  (FIG. 2) the additive mixture of user signals and noise is supplied to the first inputs of correlators  7   11 - 7   J     N     N  and to the first input of searcher  6 .  
         [0144]    Searcher  6  searches for the input signal detecting path signals of each user and transmits the information about intensity and time positions of path signals to the second inputs of controller  9 .  
         [0145]    Controller  9  controls operations of demodulation unit  1  and signal processing units  3   1 - 3   L . From the detected paths of each user controller  9  isolates J n  ones whose signals are of maximum power; n being the integer of 1 to N denoting user number.  
         [0146]    Controller  9  from the second outputs sends the data on individual PN sequences of registered communications system users to the second inputs of searcher  6 . The individual PN sequences are understood to be a collection of the PN sequences of all the info and pilot channels of a given user.  
         [0147]    Controller  9  from the first outputs sends the information about time positions of isolated user paths and individual PN sequences of these users to the second inputs of correlators  7   11 - 7   J     N     N .  
         [0148]    Controller  9  from the fifth outputs sends control information about time positions of signals of isolated user paths and individual PN sequences of these users to the inputs of cross-correlation matrix element former  10  in order to form the elements of cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to each other, cross correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users, cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users, and cross-correlation matrix of the info components of signals of all the paths of all the users to each other.  
         [0149]    Controller  9  from the third outputs sends the data on time positions of signals of isolated user paths to the second inputs of sub-unit  8  of delay and grouping of the correlation responses of signals of all the user info and pilot channel paths.  
         [0150]    Controller  9  from the fourth outputs sends control signals and information about user signals to the third inputs of all signal processing units  3   1 - 3   L .  
         [0151]    In every correlator  7   jn , n being the integer of 1 to N, j- 1  to J n , the signal of j-th path of all the info and pilot channels of the n-th user is demodulated, i.e. M n +1 complex correlation responses of signals of the j-th path corresponding to M n  info channels and one pilot channel of the n-th user are formed. From the second outputs of each correlator the generated complex correlation responses are supplied to the first inputs of sub-unit  8 .  
         [0152]    From the first outputs of correlators  7   11 - 7   J     N     N  the information about signals of user paths is sent to the first inputs of controller  9 .  
         [0153]    Sub-unit  8  delays the correlation responses of signals of all the user info channel paths, the delay, for example, being a half of the accumulation interval of correlation responses of signals the corresponding user pilot channel paths, and also delays all the generated complex correlation responses of all the user pilot and info channel paths so that while compensating their interfering effect on each other the interfering effect estimates be generated. This principle is illustrated in FIG. 3.  
         [0154]    Let us consider FIG. 3, where two time position diagrams of correlation responses before and after being delayed in sub-unit  8  are presented. The signals of three user info channels having different length of one info symbol and different time positions are shown. To the first symbol of second channel the first symbols of first and third channels are interfering. Therefore, in order to compensate their interfering effect the signal from second channel should be delayed by the time necessary for generation of complex correlation response of the longest symbol out of the interfering ones, in this very case it is the first symbol of first channel. Similarly delay for other channels is selected.  
         [0155]    Coming back to FIG. 2. Sub-unit  8  at the first outputs generates  
         ∑     n   =   1     N            J   n          M   n                             
 
         [0156]    complex correlation responses of signals of all the user info channel paths. These responses are supplied to the first inputs of signal processing units  3   1 - 3   L , wherein to first signal processing unit  3   1  directly and to subsequent signal processing units  3   2 - 3   L  via first delay units and all subsequent delay units respectively.  
         [0157]    Sub-unit  8  at the second outputs generates  
         ∑     n   =   1     N          J   n                           
 
         [0158]    complex correlation responses of signals of all the user pilot channel paths. These signals are supplied to the corresponding inputs of accumulator  2 .  
         [0159]    Cross-correlation matrix element former  10  forms the elements of four types of cross-correlation matrices.  
         [0160]    According to the current embodiment implementation of the device is based on compensation of the interfering effect of signals of all the user info and pilot channel paths on each other and requires knowledge of the elements of cross-correlation matrices of all the components of received signals to each other. The elements of these matrices are correlation of the PN sequences of different users via all the channels and paths. Therefore, the matrices of four types need to be formed:  
         [0161]    the cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to each other; this matrix will be referred to as the KPP cross-correlation matrix;  
         [0162]    the cross-correlation matrix of the PN sequences of the pilot components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users; this matrix will be referred to as the KPS cross-correlation matrix;  
         [0163]    the cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the info components of signals of all the paths of all the users to the PN sequences of the pilot components of signals of all the paths of all the users; this matrix will be referred to as the KSP cross-correlation matrix;  
         [0164]    the cross-correlation matrix of the PN sequences of the info components of signals of all the paths of all the users to each other; this matrix will be referred to as the KSS cross-correlation matrix.  
         [0165]    The above listed cross-correlation matrices are calculated by some known method.  
         [0166]    The elements of cross-correlation matrices from the outputs of former  10  are supplied to the fourth inputs of signal processing units, wherein to first signal processing unit  3   1  directly and to subsequent signal processing units  3   2 - 3   L  via second delay units and all previous second delay units corresponding to them.  
         [0167]    N  
         [0168]    Let us consider FIG. 4. Accumulator  2  generates  
         ∑     n   =   1     N          J   n                           
 
         [0169]    averaged complex correlation responses of signals of all the user pilot channel paths. For this purpose each accumulation branch  11   j,n , where n taking the integer values of 1 to N, j taking the integer values of 1 to J n , using tapped delay line and combiner, accumulates complex correlation responses of signal from the j-th path of pilot channel of the n-th user within the accumulation intervals of determined by the time of user path signal invariance.  
         [0170]    averaged complex correlation responses of signals of all the user pilot channel paths are delivered to the second inputs of signal processing units, wherein to first signal processing unit  3   1  directly and to subsequent signal processing units  3   2 - 3   L  via first delay units and all previous first delay units corresponding to them.  
         [0171]    N  
         [0172]    The soft decisions about the info parameters  
         ∑     n   =   1     N          M   n                           
 
         [0173]    of info channels of N users are formed successively through L iterations, L&gt;1, for which L signal processing units and first and second delay units are used, wherein first signal processing unit provides the first method iteration and subsequent signal processing units with first and second delay units corresponding to them provide subsequent method iterations.  
         [0174]    Each signal processing unit compensates the interfering effect of signals of all the user pilot channel paths on each other, the interfering effect of signals of all the user pilot channel paths on the signals of all the user info channel paths, the interfering effect of signals of all the user info channel paths on the signals of all the user pilot channel path, and the interfering effect of signals of all the user info channel paths on each other. Every signal processing unit at the firs outputs generates the soft decisions about the info parameters of signals from all the user info channels. Every signal processing unit except the last one generates at the second outputs the estimates of complex envelopes of signals from all the paths of all the users.  
         [0175]    First delay units delay the complex correlation responses of signals from all the user info and pilot channel paths by the time of signal processing in previous signal processing unit.  
         [0176]    Second delay units delay the soft decisions about the info parameters of signals from all the user info channels of previous signal processing unit, the estimates of complex envelopes of signals from all the paths of all the users of previous signal processing units, and the elements of all the cross-correlation matrices by the time of signal processing in previous signal processing unit.  
         [0177]    The output of the device is soft decisions about the info parameters of signals from all the user info channels of last signal processing unit  
         [0178]    Let us consider FIG. 5 that illustrates operation of first signal processing unit in more detail.  
         [0179]    From accumulator  2  averaged complex correlation responses of signals of all the user pilot channel paths are supplied to the first inputs of sub-unit  14  for compensation of the interfering effect of signals of all the user pilot channel paths on each other. To the second inputs of sub-unit  14  control signals from demodulation unit  1  are delivered. To the third inputs of sub-unit  14  the elements of the KPP cross-correlation matrix are supplied.  
         [0180]    Sub-unit  14  compensates the interfering effect of signals of all the user pilot channel paths on each other and generates more accurate complex correlation responses of signals from all the user pilot channel paths. Let us consider how this is accomplished using FIG. 7.  
         [0181]    To the first input of each node for isolation of the n-th user j-th pilot channel path of sub-unit  14 , where being the integer of 1 to, −1 to, the averaged complex correlation responses of the signal from the n-th user j-th pilot channel path are applied; to the second input the rest of the averaged complex correlation responses of signals of user pilot channel paths are delivered; to the third inputs control signals of controller  34  are sent; to the fourth inputs the KPP matrix elements are supplied. Control signals from controller  9  of demodulation unit  1  are delivered to controller  34 . Each node isolates the signal of the n-th user j-th pilot channel path thus forming