JP2007300453A - Ofdm communicating system, ofdm communication method, ofdm signal transmitting device, and ofdm signal receiving device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve high transmission efficiency and frequency usage efficiency in OFDMA transmission with the minimum unit of multiple access as a tile. <P>SOLUTION: At a transmission side, input data are mapped and re-arranged into M-pieces of parallel data so as to generate N-pieces of CDM signals. A CDM tile is generated. The CDM tiles of whole users are orthogonally arranged so as to construct an OFDMA data frame. The OFDMA frame is constructed by adding common information such as control signal. Then OFDM modulation is performed so as to generate a transmission signal. At a reception side, a reception signal is demodulated by OFDM so as to re-construct the OFDMA frame. The CDM tile is extracted from the OFDMA frame and the CDM tile constituting data are re-arranged into an N-point sequence. Despreading processing is performed by the use of a code used at the transmission side so as to restore the M-row parallel data. Re-arrangement is performed to obtain one time sequential signal. Then data mapping is performed to the data in accordance with a demodulation method designated by a modulation mode. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  In the present invention, transmission data is subjected to subcarrier modulation and then subjected to inverse Fourier transform and transmitted, and this signal is received on the reception side and subjected to Fourier transform to restore transmission data. OFDM (Orthogonal Frequency Division Multiplexing) The present invention relates to an OFDM communication system, an OFDM communication method, an OFDM signal transmission apparatus, and an OFDM signal reception apparatus for performing multiple access in which a communication channel is shared by a plurality of users in a (multiplex) communication scheme.

  The OFDM communication system is a multicarrier communication technique in which a plurality of subcarriers are arranged at a minimum frequency interval such that the subcarriers are orthogonal to each other in the frequency domain, and among the multicarrier schemes using a plurality of subcarriers, It is attracting attention as a communication method with excellent frequency utilization efficiency.

  FIG. 6 shows a basic configuration of the OFDM communication system. FIG. 6 (a) shows a configuration example of a main part of an OFDM signal transmitting apparatus, and FIG. 6 (b) shows a configuration example of a main part of the OFDM signal receiving apparatus.

  In the OFDM signal transmission apparatus shown in FIG. 6A, the modulation signal mapping circuit 501 maps input data to each subcarrier (subcarrier modulation). Digital modulation schemes such as PSK (Phase Shift Keying) and QAM (Quadrature Amplitude Modulation) are used for subcarrier modulation. Next, the parallel conversion circuit 502 rearranges the data into low-speed parallel data of the same number as the total number of subcarriers, performs an inverse Fourier transform in an IFFT (Inverse Fast Fourier Transform) circuit 503, and again in the parallel-serial conversion circuit 504, Generate a time-series signal. Next, a GI addition circuit 505 adds a GI (guard interval) to the time series signal to generate a transmission signal. The series-parallel conversion 502 to GI addition circuit 505 constitutes an OFDM modulation circuit 506.

  In wireless communication in a propagation environment in which a plurality of reflections, diffraction and scattering occur, a delayed wave having a large delay spread causes a complicated and large variation in electric field strength due to frequency selective fading, which hinders accurate communication. On the other hand, in the OFDM communication system, the tail part of the output signal of the IFFT circuit 503 is added to the beginning of the OFDM symbol as GI so as not to be affected by a delayed wave having a time shorter than GI.

  In the OFDM signal receiving apparatus shown in FIG. 6B, demodulation processing is performed by a reverse operation to the transmitting apparatus. That is, the GI removal circuit 525 removes the GI from the received signal, the serial-parallel conversion circuit 524 converts it into low-speed parallel data, and the FFT (Fast Fourier Transform) circuit 523 performs Fourier transform to restore the data of each subcarrier. Then, the parallel / serial conversion circuit 522 converts the signal again into one time series signal, and the modulation signal demapping circuit 521 performs demapping of the signal. The serial / parallel conversion circuit 522 to the GI removal circuit 525 constitutes an OFDM demodulation circuit 526.

  By the way, when accommodating a plurality of users in one communication channel, it is necessary to realize multiple access in which a communication channel is allocated to each user and shared by some method. Multiple access methods in an OFDM communication system include OFDM-TDMA (time division multiple access) and OFDM-FDMA (frequency division multiple access), OFDMA (orthogonal frequency division multiple access), OFDM-CDMA (code division). Multiple access) method is being studied.

  The OFDM-TDMA scheme divides time into a certain number of OFDM symbols and assigns time slots to a plurality of users, and is used in IEEE802.11a, which is one of wireless LAN standardization standards (non-patent). Reference 1).

  FIG. 7 shows subcarrier groups occupied by a certain user in the OFDM-TDMA scheme. In the figure, 11 is one subcarrier. In the OFDM-TDMA scheme, a certain time slot is assigned to a user, for example, the user occupies all subcarriers 12 for a specific time. The maximum number of simultaneous access users depends on the total number of time slots in the OFDM frame and the number of time slots allocated per user.

  In the OFDM-FDMA scheme, division in the frequency direction is performed using the fact that an OFDM signal is composed of multiple carriers, and multiple access is realized by assigning subcarrier groups constituting an OFDM symbol to a plurality of users (non-patent document). Reference 2 in particular in section 11.2).

  FIG. 8 shows subcarrier groups occupied by a certain user in the OFDM-FDMA scheme. In the figure, 13 is one subcarrier. In the OFDM-FDMA scheme, a certain subcarrier is assigned to a user. For example, the user occupies a specific subcarrier 14 over all time slots. The maximum number of simultaneous access users depends on the total number of subcarriers in the OFDM frame and the number of subcarriers allocated per user.

  The OFDMA method divides the user in a time-frequency two-dimensional area by dividing the frequency direction by subcarriers and the time direction by time slots, and is studied by IEEE802.16, which is one of the standardization standards for wireless broadband access. (Non-Patent Document 3). In Non-Patent Document 3, a fixed number of orthogonal subcarrier groups extending over a plurality of time slots are defined as “tiles”, and multiple access control in units of tiles is shown. Access control can be performed in finer units than in the TDMA and FDMA systems.

  FIG. 9 shows a subcarrier group occupied by a certain user in the OFDMA scheme. In the figure, 15 is one subcarrier. In the OFDMA scheme, for example, tiles 16 separated by Nt time slots and Nf subcarriers are allocated to users. The maximum number of simultaneous access users depends on the number of tiles constituting the OFDMA frame.

  FIG. 10 shows a basic configuration of an OFDM communication system corresponding to the OFDMA scheme. FIG. 10A shows a configuration example of a main part of an OFDM signal transmitting apparatus that performs multiple access to a plurality of users, and FIG. 10B shows a configuration example of a main part of an OFDM signal receiving apparatus corresponding to one user. . Differences from the general OFDM communication system shown in FIG. 6 are as follows. The OFDM signal transmission apparatus includes modulation signal mapping circuits 501-1 to 501-n corresponding to each user, and subcarriers corresponding to each user output from the respective users are bundled by an OFDMA frame configuration circuit 507 and supplied to the OFDM modulation circuit 506. . The OFDM signal receiving apparatus further includes an OFDMA frame reconstruction circuit 527 and a subcarrier extraction circuit 528 that reconstruct an OFDMA frame from the output of the OFDM demodulation circuit 526 and extract a subcarrier of a specific user, and output the modulated signal as a modulated signal. This is given to the demapping circuit 521-x.

  In any of the OFDM-TDMA scheme, OFDM-FDMA scheme, and OFDMA scheme described above, subcarrier applied modulation that varies the modulation multi-level number for each subcarrier can be combined in accordance with the state of the communication channel (Non-patent Document 4). .

  FIG. 11 shows an example of assignment of modulation schemes for each subcarrier in subcarrier adaptive modulation. FIGS. 11 (a) and 11 (b) show examples in which the same transmission rate is realized by adaptively allocating modulation schemes for each subcarrier corresponding to different frequency transmission characteristics. In Non-Patent Document 4, in order to reduce the overhead of transmitting modulation scheme information in adaptive modulation, a certain number of adjacent subcarriers are grouped together to represent the transmission path characteristics within one group at the worst value, and the subcarrier group On the other hand, there is also a proposal for performing the same applied modulation control collectively. Hereinafter, this is referred to as subcarrier group adaptive modulation.

  In addition to subcarrier adaptive modulation and subcarrier group adaptive modulation, improvement of transmission characteristics of the OFDM scheme has also been proposed by pre-encoding processing using discrete inverse Fourier transform / discrete Fourier transform (Non-Patent Document 5). ). Hereinafter, this is referred to as a pre-encoded OFDM system.

  FIG. 12 shows a basic configuration of an OFDM communication system corresponding to the pre-coded OFDM scheme. FIG. 12A shows an example of the configuration of the main part of the OFDM signal transmitting apparatus, and FIG. 12B shows an example of the configuration of the main part of the OFDM signal receiving apparatus. Differences from the general OFDM communication system shown in FIG. 6 are as follows. In the OFDM modulation circuit 506 of the OFDM signal transmission apparatus, an IFFT circuit 508 is inserted between the serial-to-parallel conversion circuit 502 and the IFFT circuit 503 to perform pre-encoding processing. A configuration including the IFFT circuit 508 is a pre-encoded OFDM modulation circuit 509. On the other hand, in the OFDM demodulation circuit 526 of the OFDM signal receiving apparatus, an IFFT circuit 529 is inserted between the serial-to-parallel conversion circuit 524 and the IFFT circuit 523, and a decoding process corresponding to the pre-encoding process is performed. The configuration including the IFFT circuit 529 is referred to as a pre-encoded OFDM demodulation circuit 530. By this pre-encoding, information of all subcarriers is spread with each other, so that a frequency diversity effect can be expected.

  On the other hand, the OFDM-CDMA system is a combination of the CDMA system that separates users by code and the OFDM system (particularly, section 11.4 of Non-Patent Document 2).

  FIG. 13 shows a basic configuration of an OFDM communication system corresponding to the OFDM-CDMA system. FIG. 13 (a) shows a configuration example of a main part of an OFDM signal transmitting apparatus, and FIG. 13 (b) shows a configuration example of a main part of the OFDM signal receiving apparatus. In the OFDM signal transmission apparatus, the outputs of the modulation signal mapping circuits 501-1 to 501-n corresponding to each user are input to the corresponding spreading circuits 510-1 to 510-n, respectively, and the cross-correlation assigned to each user in advance. A spreading chip in which data is spread by multiplying a small code with data at high speed is generated, the spreading chip of each user is added by an adding circuit 511, user multiplexing is performed, and the result is input to an OFDM modulation circuit 506, and each sub symbol of an OFDM symbol Allocate to carrier and transmit. In the OFDM signal receiving apparatus, the output of the OFDM demodulation circuit 526 is input to the despreading circuit 531, multiplied by a user-specific code, code-separated, and input to the modulation signal demapping circuit 521 -x.

FIG. 14 shows a subcarrier group shared by a user in the OFDM-CDMA system. In the figure, users share all time slots and all subcarriers 17, and the maximum number of simultaneous access users depends on the number of user separation codes for realizing CDMA. When the number of code multiplexes is small, it is possible to secure a stable communication link even in a low SNR (signal power to noise power ratio) environment due to the spread spectrum effect.
IEEE Wireless LAN Edition ~ A Compilaltion based on IEEE Std 802.11-1999 (R2003) and its amendments ~, IEEE October 2003, pp.263-304 Multi-Carrier Digital Communications Theory and Applications of OFDM 2nd Edition, Ahmad RSBahai, Burton R. Saltzberg, Mustafa Ergen, Springer, September 2004 IEEE 802.16-2004: Air Interface for Fixed Broadband Wireless Access Systems, IEEE, June 2004, pp.568-571 Hideo Kobayashi, “Fundamentals and Applied Technologies of OFDM Communication System”, Trikes Publishing, May 2004, pp.121-130 Jeong Woo JWA, "An OFDM Scheme with Pre-IDFT / DFT on Frequency-Selective Rayleigh Fading Channels", IEEE Trans. Vol.E88-B, No.7, July 2005

  In the OFDM system, as a multiple access system that realizes a transmission rate that is not excessive or insufficient with respect to the SNR at the reception point, a subcarrier that supports non-flat frequency transmission characteristics and can ensure a constant communication quality for each subcarrier. The OFDMA scheme using adaptive modulation is advantageous over other access schemes. In the OFDMA scheme using subcarrier adaptive modulation, examples of assignment of modulation schemes for each subcarrier according to transmission path conditions at different times are as shown in FIGS. 11 (a) and 11 (b). However, the allocation methods (a) and (b) are set such that the number of sets of modulation schemes having different modulation multi-value numbers is equal, and the transmission rates are the same.

  While the OFDMA scheme using subcarrier adaptive modulation achieves high scalability, from the perspective of modulation scheme allocation control to each subcarrier, the same transmission as in the allocation methods (a) and (b) Since there are a plurality of combinations of assignments that realize the speed, there is a problem of generating redundancy for the speed control information. Furthermore, since it is necessary to add and transmit the modulation scheme information of each subcarrier for each frame, there is a problem that the amount of transmission rate control information becomes excessive, particularly as the total number of subcarriers increases. . In addition, an increase in overhead for the data slot causes a decrease in data transmission rate.

  In that respect, subcarrier group adaptive modulation performs adaptive modulation on multiple subcarriers at once, thus reducing the overhead of adaptive modulation control, but the modulation scheme with the smallest number of modulation multi-levels can be grouped together. When used, there is a problem that the transmission rate decreases.

  Also, in the pre-encoding OFDM method, when the total number of subcarriers is large, the amount of calculation required for the pre-encoding process becomes enormous, and interference components between spread data are also generated, so that a frequency diversity effect sufficient for the amount of calculation is obtained. That was difficult. Further, when the reception level is extremely low by the characteristic subcarrier, there is a problem that the noise component amplified by the equalization processing of the subcarrier is emphasized over all the subcarrier data. In particular, when pre-encoding is applied to the OFDMA scheme (hereinafter referred to as pre-encoded OFDMA scheme), there is a problem that a small number of subcarriers with low received power affect multiple users.

  Here, FIG. 15 shows an example of a subscriber radio communication system as a system using the OFDM-CDMA system. Further, the state of uplink information transmission in the OFDM-CDMA system is shown in FIGS. FIG. 15 assumes a case where a user station SS-1 exists in a short distance and a user station SS-2 exists in a long distance with respect to the base station BS. In this situation, it is difficult to apply the OFDM-CDMA scheme to the uplinks 23 and 24 paired with the downlinks 21 and 22 that simultaneously communicate from the BS to the SS-1 and SS-2. The reason for this is that, as shown in FIGS. 16 (d) to 16 (f), the signals (d) transmitted from the SSs are combined via independent transmission paths and arrive at the BS. In e), the inter-user level ratio of chips spread-multiplexed on each subcarrier varies for each subcarrier. For this reason, even if frequency domain equalization is performed on the BS side, since the coding levels are not uniform as shown in (f), user separation by despreading cannot be performed normally.

  In addition, although it is conceivable to apply a communication system other than the OFDM-CDMA system for the uplink, the modulation / demodulation hardware can be made economical by sharing the arithmetic system, and the inter-SS communication 25 and multi-hop communication shown in FIG. From the viewpoint of expansion, it is desirable that the uplink / downlink be the same communication method.

  In addition, the user separation code used in the OFDM-CDMA system is generally an orthogonal code with high transmission efficiency because inter-code synchronization is guaranteed in the downlink, whereas the non-orthogonal having excellent cross-correlation characteristics in the uplink. It is a sign. In the downlink, since a plurality of codes are transmitted synchronously from the BS, orthogonality between the codes is maintained at the SS reception point, whereas in the uplink, the transmission distance to the BS and the transmission path environment are limited. This is because, since different codes are transmitted from different SSs, inter-code synchronization is generally not guaranteed at the BS reception point, and orthogonal codes that generate a large cross-correlation interference component cannot be used in the asynchronous state.

  Further, regarding the OFDM-CDMA uplink non-orthogonal code, the cross-correlation characteristics and the number of codes are generally contradictory. Therefore, it is difficult to secure a code that suppresses cross-correlation between codes while accommodating a large number of users, and there is a problem that complicated code design and management of code user allocation are required under the restriction of the total number of codes. On the other hand, when the orthogonal code is applied for the uplink of the OFDM-CDMA system, in addition to the above-described problems, between the users with high accuracy such that the signal transmitted from the SS completely synchronizes when it arrives at the BS. A synchronization mechanism is required. Also, in the uplink, a transmission power control mechanism is essential in order to prevent the transmission signal of the SS located far from the BS from being buried by the transmission signal of the SS near the BS.

  The present invention achieves high transmission efficiency and frequency utilization efficiency due to frequency diversity effect, time diversity effect, noise power averaging effect, and interference power spreading effect in tiles in OFDMA transmission using a minimum unit of multiple access as a tile. An object of the present invention is to provide an OFDM communication system, an OFDM communication method, an OFDM signal transmitting apparatus, and an OFDM signal receiving apparatus that can be realized.

  The present invention provides a plurality of modulation signal mapping circuits provided for a plurality of users and mapping each input data to each modulation signal point based on a digital modulation system, and symbols generated by the plurality of modulation signal mapping circuits as symbols An OFDMA frame configuration circuit that configures an OFDMA frame arranged in a specific subcarrier of a specific time slot in units; an OFDM modulation circuit that inputs an OFDMA frame, performs OFDM modulation for each time slot, and generates a transmission signal with a GI added thereto; An OFDM signal transmission apparatus comprising: an OFDM demodulation circuit that removes GI from the received signal from the opposite OFDM signal transmission apparatus and performs OFDM demodulation; and an OFDM symbol of a plurality of time slots output from the OFDM demodulation circuit OFDMA for reconstructing an OFDMA frame A frame reconstruction circuit; a subcarrier extraction circuit that extracts a subcarrier of a specific user from an OFDMA frame; and a modulation signal demapping circuit that demaps the subcarriers extracted by the subcarrier extraction circuit and restores data. In an OFDM communication system having a configuration for performing multiple access, the OFDM signal transmission apparatus includes a modulation signal mapping circuit and M output signals of the modulation signal mapping circuit at low speed (M is A serial-to-parallel conversion circuit for converting into a parallel signal of a positive integer) and M parallel signals are input, and a plurality of different N times (N is a positive integer, N ≧ M) common to all users A spreading multiplex circuit for obtaining N CDM (Code Division Multiplexing) signals after spreading N times by N codes and then multiplying by M stages; A tile mapping circuit that inputs N CDM signals output from the overlapping circuit and arranges data in tiles represented by two-dimensional regions in the frequency direction and the time direction to form CDM tiles, and is provided for the user Modulation mode control for controlling the parallel width M in the serial-to-parallel conversion circuit and the code multiplexing number M in the spreading multiplex circuit by selecting a digital modulation system in the modulation signal mapping circuit according to the transmission path state The OFDMA frame configuration circuit includes a CDM tile of all users generated by the tile mapping circuit, and prevents CDM tiles from overlapping each other in the time domain and the frequency domain in tile units according to a predetermined mapping rule. The CDM tile position of each user, the number of code multiplexes and the modulation method By adding uncontrolled signals other common information includes a function of generating an OFDMA frame.

  Further, the OFDM signal receiving apparatus replaces the subcarrier extraction circuit with a CDM tile extraction circuit that extracts a CDM tile assigned to a specific user, and a data subcarrier with respect to the CDM tile extracted with the CDM tile extraction circuit. An equalization circuit that performs equalization processing for correcting the phase characteristics and amplitude characteristics of the image, and a CDM tile that has been subjected to equalization processing are input, and tile data that is demapped from a two-dimensional region in the frequency direction and time direction into one time series A mapping circuit, and M despreading circuits for separating M data by M despreading codes having different code lengths N each having a rate N times the symbol rate with respect to an output signal of the tile mapping circuit The data restored by the M despreading circuits are reconstructed into one M times faster serial data and output to the modulation signal demapping circuit. And a column series conversion.

  Also, the spreading code common to all users used in the spreading multiplex circuit and the despreading circuit may be an orthogonal code.

  Further, the modulation mode control circuit controls the modulation signal mapping circuit, the serial / parallel conversion circuit, and the spread multiplexing circuit for each tile or for each user according to the transmission path state, and the modulation schemes having different modulation multi-level numbers for each spread code The transmission rate per CDM tile may be variably controlled. Also, the modulation mode control circuit controls the modulation signal mapping circuit, the serial / parallel conversion circuit, and the spread multiplexing circuit for each tile or for each user according to the transmission path state, varies the number of code multiplexing, and modulates for each spreading code. A configuration may be adopted in which modulation schemes having different multi-value numbers are allocated and the transmission rate per 1 CDM tile is variably controlled. Further, the modulation mode control circuit may be configured to uniquely determine a modulation scheme to be assigned to each spread code used in the spread multiplex circuit for a required transmission rate per CDM tile.

  In the OFDM communication method of the present invention, input data is mapped to modulation signal points according to a modulation scheme specified by a modulation mode, rearranged into M parallel data, and code spread multiplexed to generate N CDM signals. The CDM signals are rearranged in a predetermined two-dimensional arrangement to generate CDM tiles, and the CDM tiles of all users are buffered and arranged orthogonally so as not to overlap each other in the time-frequency domain to construct an OFDMA data frame. An OFDM signal transmission method for constructing an OFDMA frame by adding a control signal and other common information including CDM tile position information and modulation mode of each user, and generating a transmission signal by performing OFDM modulation; Demodulate, accumulate OFDMA symbols for multiple time slots, reconstruct the OFDMA frame, CDM tiles are extracted in accordance with control signals obtained from the program, transmission path estimation and equalization are performed on the CDM tiles, CDM tile configuration data is rearranged into N-point sequences, and the codes used in the OFDM signal transmission method are used. M-row parallel data is restored by performing despreading processing, the M-row parallel data is parallel-serial converted and rearranged into one time-series signal, and demapping to data is performed according to the demodulation method specified by the modulation mode. The OFDM signal reception method and whether the current modulation mode satisfies the required communication quality after the start of processing are evaluated. If satisfied, the processing is terminated, and if not satisfied, the number of information bits allocated to one CDM tile is determined. A modulation mode control method for resetting, resetting the number of code multiplexes accordingly, and resetting the combination of modulation schemes assigned to each spreading code. Characterized in that match.

In the conventional OFDMA scheme using subcarrier adaptive modulation, many overlapping combinations occur in the modulation scheme allocation method to each subcarrier to realize the same transmission rate. On the other hand, in the present invention, the data demodulation can be supplemented with all the data subcarriers in the CDM tile by the frequency diversity effect, the time diversity effect, the noise power averaging effect, and the interference power spreading effect in the CDM tile. For this reason, it is only necessary to control the number of information bits allocated to one CDM tile, and therefore, it is possible to cope with the modulation scheme in the CDM tile and variable control of the number M of multiplexing. If the number of modulation schemes is X, the number of subcarriers per CDM tile is N, and ceil () is a function that rounds down after the decimal point, the number of overhead bits for transmission rate control is
ceil (log ₂ N + log ₂ X) / (N × ceil (log ₂ X))
Can be reduced to

  Further, in the conventional subcarrier group modulation, the transmission rate is lowered because the modulation scheme having the smallest modulation multi-level number is collectively used in the group. However, in the present invention, the subcarrier power in the CDM tile is distributed. Since it can be utilized effectively, higher transmission efficiency and frequency utilization efficiency can be obtained.

  In the CDM tile, information data is distributed and distributed by spread multiplexing, and both a frequency diversity effect and a time diversity effect inside the CDM tile using a high frequency resolution specific to OFDM modulation having a large number of subcarriers can be expected. CDM data can be assigned to any subcarrier in any time slot. For example, when Nf subcarriers are assigned in the frequency direction and Nt slot regions are assigned in the time direction as shown in tile example 16 in FIG. And Nt correspond to the frequency diversity order and the time diversity order, respectively. By setting Nf and Nt small enough to obtain these diversity effects sufficiently, the amount of CDM calculation can be remarkably suppressed as compared with the conventional pre-encoding OFDM system.

  In the conventional pre-encoded OFDM system, the total number of subcarriers corresponds to the frequency diversity order, but the intersymbol interference between received signals deteriorated due to channel characteristics and noise increases, so especially when the total number of subcarriers is large. However, it was difficult to obtain a diversity gain corresponding to a large amount of calculation. On the other hand, in the present invention, by suppressing N to be small, the amount of computation required for CDM and intersymbol interference in the CDM tile can be reduced, and diversity gain can be effectively obtained according to the transmission path state. The CDM tile shape can be varied.

  Due to the despreading of the CDM tile, the noise power superimposed on each subcarrier is averaged, and the various interference powers are spread to each other to all the data in the tile, so the uneven frequency transmission characteristics in one CDM tile is the tile. Are mutually compensated by all the data subcarriers constituting Here, the interference power is, for example, power components other than this communication system, inter-cell interference at the edge of a cell in wireless communication with a multi-cell configuration, and inter-code interference in one CDM tile due to orthogonality disturbance of orthogonal transform. Etc., including all interference power. In the present invention, one CDM tile is occupied by one user, and since each CDM tile is orthogonal to each other in the time-frequency domain, interference power components distributed in a specific CDM tile or between codes in the own tile Interference does not affect other tiles or other users, and is different in nature from the conventional OFDM-CDMA system and pre-coded OFDMA system.

  FIG. 17 shows an example of user allocation of CDM tiles according to the present invention. As described above, since one CDM tile is occupied by one user, the multiplex number / modulation scheme can be allocated adaptively and scalable independently for each user or for each CDM tile. That is, if the number of code multiplexing is reduced and the number of information bits per CDM tile is reduced, the energy per information bit can be increased by the spreading gain, so that the communication area can be easily expanded. Conversely, if the number of code multiplexes is increased and the number of information bits per CDM tile is increased, the transmission rate can be increased. Each user can maintain a constant communication quality for each SNR, and can realize a transmission rate with no excess or deficiency. Therefore, it is possible to improve resistance to an environment in which transmission path characteristics fluctuate in the frequency domain and the time domain as in wireless communication.

  In addition, since one CDM tile is occupied by one user and each CDM tile is orthogonal to each other in the time-frequency domain, transmission power can be made constant regardless of the number of simultaneous access users and the link direction. Transmission power control means can be dispensed with. In addition, in the conventional uplink OFDM-CDMA system, the total power of each subcarrier changes due to the increase or decrease of the number of simultaneous access users, and the transmission power is limited to realize simultaneous access of multiple users and solve the above-mentioned perspective problem. However, in the present invention, each user can effectively use the given upper limit value of the subcarrier transmission power, and the frequency utilization efficiency of the entire communication system can be increased.

  Since generation of CDM tiles is performed for each user, perfect synchronization between spreading codes is always established regardless of uplink / downlink. Therefore, unlike the uplink asynchronous OFDM-CDMA system that allows random access, it is not necessary to consider the cross-correlation component due to chip shift between codes, and the application of orthogonal codes to the uplink is not limited to the downlink. It becomes easy. In the case of an orthogonal code, the total number of codes Mc = N and the transmission efficiency is high. In the conventional uplink OFDM-CDMA system, even if the signal transmitted from each user is synchronized at the time of BS reception, since each code passes through an independent transmission path, the frequency domain equalization cannot be applied on the BS side. was there. In the present invention, the CDM tile is a signal (FIG. 16 (a)) that is transmitted from one user in synchronism with the code, and further, since one CDM tile passes through a single transmission line, the signal that arrives at the BS (FIG. 16 ( The inter-code level ratio of b)) is constant regardless of the subcarrier. Therefore, if an equalized signal (FIG. 16 (c)) is generated by frequency domain equalization processing of subcarriers on the BS side, the signal before spreading multiplexing can be restored.

  Also, in the present invention, user separation is performed by utilizing the orthogonality of subcarriers and time slots, so that the number of codes is not limited and user separation by codes is avoided, and all users have the same orthogonal code set. Can be shared at any time.

  Also, by assigning different modulation schemes for each code, more scalable transmission rate control can be realized. Furthermore, since signal power can be used more effectively than the conventional subcarrier adaptive modulation OFDMA scheme and subcarrier group adaptive modulation, higher transmission efficiency and scalability can be realized.

  In addition, the conventional subcarrier adaptive modulation OFDMA scheme generally has a problem in that there are a plurality of combinations in the method of assigning different modulation schemes that realize the same transmission rate to a plurality of subcarriers, resulting in excessive transmission rate control overhead. It was. In the present invention, the constellation pattern of each subcarrier signal in the CDM tile that is actually transmitted is the same, and the above-described diversity effect and noise averaging effect are used to assign different codes to a plurality of codes, that is, different modulation. The overhead can be reduced by limiting the multiplexing method to one arbitrary method. As described above, compared with the OFDMA scheme applying subcarrier adaptive modulation, the applied modulation control overhead is greatly reduced, and finer transmission rate control than the OFDMA scheme applying subcarrier group adaptive modulation is possible. Efficiency can be realized.

  1 and 2 show an embodiment of the OFDM communication system of the present invention. FIG. 1 shows a configuration example of a main part of an OFDM signal transmitting apparatus, and FIG. 2 shows a configuration example of a main part of the OFDM signal receiving apparatus. Here, the number of users (number of simultaneous accesses) is k.

(OFDM signal transmitter)
1, the OFDM signal transmission apparatus includes CDM tile generation circuits 100-1 to 100-k corresponding to each user, an OFDMA frame configuration circuit 105, an OFDM modulation circuit 106, and a modulation mode control circuit 120. Each CDM tile generation circuit 100 includes a modulation signal mapping circuit 101, a serial / parallel conversion circuit 102, a diffusion multiplexing circuit 103, and a tile mapping circuit 104.

The modulation signal mapping circuit 101 maps input data to each modulation signal point based on digital modulation such as PSK or QAM. The serial / parallel conversion circuit 102 outputs the output signal of the modulation signal mapping circuit 101 to M parallel signals D = (d ₁ , d ₂ ,..., D _M ) with a transmission rate of 1 / M (M is a positive integer). Convert to ^T. Here, T represents a transposed matrix. The parallel length M and the digital modulation method of each parallel signal are designated by the modulation mode control circuit 120, and the modulation method to be assigned can be changed for each code. A combination of these assignments is determined in correspondence with the transmission rate on a one-to-one basis. For example, the M codes C ₁ , C ₂ ,..., C _M are uniquely assigned in order from the modulation scheme having the largest modulation multilevel number.

The spread multiplexing circuit 103 has a code length of N (N is a positive integer), inputs M parallel signals output from the parallel-serial conversion circuit 102, spreads and mutually multiplexes them, and newly adds N pieces of signals. Parallel signals S = (s ₁ , s ₂ ,..., S _N ) ^T are generated and subjected to heterogeneous modulation multiplexing. Although not limited to the following, it is desirable to use orthogonal codes as spreading codes from the viewpoint of high transmission efficiency and ease of implementation. In the following description, Walsh Hadamard codes with a code length of N, which is a kind of orthogonal codes, are used. Shall. At this time, N is a power of 2, and the total number of codes Mc = N.

Here, the conversion from M signals to N signals is zero-padded at the end of the parallel signal vector D as shown in the equation (1), and the N row vectors D ′ = d ₁ , d _2. ,..., D _M , 0,0,..., 0) ^T are generated, and the M data of the vector D is spread and multiplexed into N data by the product of the orthogonal matrix Q and D ′.

In Equation (1), the calculation of the part that is determined to be multiplied by zero can be omitted. Therefore, the actual operation is the product of the (N × M) matrix, which is a submatrix of Q, and the M row vector D. It is expressed by (2).

  Next, the tile mapping circuit 104 inputs N CDM signals output from the diffusion multiplexing circuit 103 and rearranges them into a two-dimensional array. Here, the data is rearranged into a two-dimensional array of Nf × Nt, and a CDM tile that is an area of Nf subcarriers and Nt time slots is formed. However, the subcarriers and time slots constituting the CDM tile do not necessarily have to be physically adjacent.

  It is assumed that the CDM tile generation circuits 100-1 to 100-k corresponding to each user individually perform the above processing.

  Next, the OFDMA frame configuration circuit 105 receives the CDM tiles corresponding to each user output from the CDM tile generation circuits 100-1 to 100-k, respectively, and has a two-dimensional frequency-time direction frame having a predetermined size. The area is filled with an arbitrary method to form an OFDMA frame and applied to the OFDM modulation circuit 106.

  Here, the CDM tiles are arranged orthogonal to each other in terms of time and frequency. FIG. 17 shows an example of user allocation of CDM tiles according to the present invention. Here, an example of OFDMA frame arrangement using 6 CDM tiles by 3 users is shown. Each CDM tile has Nf = 4, Nt = 2, user 1 owns CDM tile 161, user 2 owns CDM tiles 162-164, and user 3 owns CDM tiles 165,166. Since each CDM tile has an independent modulation mode, as shown in FIG. 18, each CDM tile has a different number of code multiplexes, and the power allocated per information bit is different for each user.

  Separately from the OFDMA frame, control information describing the position of the CDM tile used by the Xth user, the number of code multiplexes and the modulation method assigned to each code, a training signal and a pilot signal for grasping transmission path characteristics, etc. Common control signals are inserted. A guard band is provided if necessary.

  The OFDM modulation circuit 106 has the same configuration as that of the OFDM modulation circuit 506 shown in FIG. 6, inputs an OFDMA frame having time and frequency dimensions configured as described above, and all subcarrier data paralleled for each time slot. Is subjected to inverse Fourier transform to generate a time signal of an OFDMA symbol. In general, IDFT (fast discrete inverse Fourier transform) is used for this calculation. After adding a guard interval signal to the generated OFDMA signal, it is transmitted to the transmission line after performing frequency transition and filtering according to the transmission form.

(OFDM signal receiver)
In FIG. 2, an OFDM signal receiving apparatus corresponding to a predetermined user includes an OFDM demodulation circuit 200, an OFDMA frame reconstruction circuit 201, a transmission path estimation circuit 202, a CDM tile extraction circuit 203, an equalization circuit 204, The tile demapping circuit 205, the despreading circuit 206, the parallel / serial conversion circuit 207, and the modulation signal demapping circuit 208 are configured.

  The OFDM demodulator circuit 200 has the same configuration as the OFDM demodulator circuit 526 shown in FIG. 6 and performs OFDM demodulation by performing Fourier transform on a signal obtained by removing GI from the received signal. Generally, DFT (fast discrete Fourier transform) is used for this calculation. The demodulated OFDM symbols are accumulated for a predetermined time slot by the OFDMA frame reconstruction circuit 201 to reconstruct the OFDM frame, and assign control signals, training signals / pilot signals, and data slots. Next, the CDM tile extraction circuit 203 detects and extracts a CDM tile position assigned to a predetermined user in accordance with a control signal obtained from the OFDMA frame. On the other hand, the transmission path estimation circuit 202 performs transmission path estimation in the frequency domain based on the training signal / pilot signal obtained from the OFDMA frame, and the equalization circuit 204 is extracted by the CDM tile extraction circuit 203 according to the estimation result. The CDM tile data subcarriers are subjected to amplitude / phase equalization processing.

The tile demapping circuit 205 inputs CDM tiles that have undergone equalization processing, rearranges them into R = (r ₁ , r ₂ ,..., R _N ) ^T , and the inverse diffusion circuit 206 uses the inverse matrix of the orthogonal matrix. A despreading process is performed by calculating the product of a certain (N × N) matrix Q ⁻¹ and vector R. If Q is a Walsh Hadamard matrix, its inverse matrix Q ^-1 satisfies Q ^-1 = Q. The parallel-serial conversion circuit 207 rearranges the parallel signal separated by the despreading operation into a serial signal. The modulation signal demapping circuit 208 demaps the output signal of the parallel-serial conversion circuit 207 according to the control signal obtained from the OFDMA frame, and performs data recovery.

  In modulation mode control, when operating uplink and downlink in FDD (frequency division duplex), a closed loop that estimates a transmission path state and feeds back to the modulation mode control circuit 120 for communication after the next frame. Take control. On the other hand, when TDD (Time Division Duplex) operation is used, open loop modulation mode control can be performed using reversibility of transmission path characteristics.

(Transmission algorithm)
FIG. 3 shows a transmission algorithm in the OFDM communication method of the present invention. The input data is mapped to modulation signal points according to the modulation scheme specified in the modulation mode (S1), rearranged into M parallel data (S2), and a Walsh Hadamard code which is a kind of orthogonal code is used as a spreading code, A total of N CDM signals are generated by spreading and multiplexing M pieces of parallel data (S3). Next, the CDM signals are rearranged in a predetermined two-dimensional arrangement to generate CDM tiles (S4). Note that the two-dimensional arrangement method may be different for each tile. Next, the CDM tiles of all users are buffered (S5), and the data frames are constructed by orthogonally arranging the CDM tiles in the time-frequency domain so as not to overlap each other (S6). Next, an OFDMA frame is constructed by adding a control signal such as CDM tile position information and modulation mode of each user and a pilot signal / training signal (S7), and OFDM modulation is performed (S8). The above transmission algorithm is implemented, for example, using the configuration of the OFDM signal transmission apparatus shown in FIG.

(Reception algorithm)
FIG. 4 shows a reception algorithm in the OFDM communication method of the present invention. The received signal (time signal) is OFDM demodulated (S11), OFDMA symbols for a plurality of time slots are accumulated, and an OFDMA frame is reconstructed (S12). Next, a CDM tile is extracted according to a control signal (CDM tile position information) obtained from the OFDMA frame (S13), transmission path estimation and equalization are performed for this CDM tile (S14), and the CDM tile configuration data is converted to N Rearrangement into point series (S15), despreading processing is performed using orthogonal codes used in the transmission algorithm, and M-row parallel data is restored (S16). Next, the M-row parallel data is parallel-serial converted and rearranged into one time-series signal (S17), and demapping to data is performed according to the demodulation method specified in the modulation mode (S18).

(Modulation mode control algorithm)
FIG. 5 shows a modulation mode control algorithm in the OFDM communication method of the present invention. Whether the current modulation mode satisfies the required communication quality is evaluated (S21). If not, the number of information bits allocated to one CDM tile is sequentially reduced. Specifically, the number of information bits per CDM tile is determined (S22), the number of code multiplexes is reset (S23), and the combination of modulation schemes assigned to each spreading code is reset (S24). Thereby, the energy per information bit and the transmission rate can be flexibly allocated for each CDM tile.

The figure which shows embodiment of the OFDM communication system (OFDM signal transmitter) of this invention. The figure which shows embodiment of the OFDM communication system (OFDM signal receiver) of this invention. The flowchart which shows the transmission algorithm in the OFDM communication method of this invention. The flowchart which shows the reception algorithm in the OFDM communication method of this invention. The flowchart which shows the modulation mode control algorithm in the OFDM communication method of this invention. The figure which shows the basic composition of an OFDM communication system. The figure which shows the subcarrier group which a user occupies with an OFDM-TDMA system. The figure which shows the subcarrier group which a user occupies with an OFDM-FDMA system. The figure which shows the subcarrier group which a user occupies with an OFDM system. The figure which shows the basic composition of the OFDM communication system corresponding to an OFDMA system. The figure which shows the example of allocation of the modulation system with respect to each subcarrier in subcarrier adaptive modulation. The figure which shows the basic composition of the OFDM communication system corresponding to a pre-encoding OFDM system. The figure which shows the basic composition of the OFDM communication system corresponding to an OFDM-CDMA system. The figure which shows the subcarrier group which a user occupies with an OFDM-CDMA system. The figure which shows the positional relationship of BS and SS in a subscriber radio | wireless communications system. The figure explaining collapse of the level between codes in an uplink. The figure which shows the user allocation example of the CDM tile which concerns on this invention. The figure which shows the OFDMA data frame based on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 CDM tile generation circuit 101 Modulation signal mapping circuit 102 Serial / parallel conversion circuit 103 Spreading multiplexing circuit 104 Tile mapping circuit 105 OFDMA frame configuration circuit 106 OFDM modulation circuit 120 Modulation mode control circuit 200 OFDM demodulation circuit 201 OFDMA frame reconstruction circuit 202 Transmission path Estimation circuit 203 CDM tile extraction circuit 204 Equalization circuit 205 Tile demapping circuit 206 Despreading circuit 207 Parallel / serial conversion circuit 208 Modulated signal demapping circuit

Claims (13)

A plurality of modulation signal mapping circuits which are provided for a plurality of users and map each input data to each modulation signal point based on a digital modulation system;
An OFDMA frame configuration circuit that configures an OFDMA frame in which symbols generated by the plurality of modulation signal mapping circuits are arranged on a specific subcarrier of a specific time slot in symbol units;
An OFDM signal transmission apparatus comprising: an OFDM modulation circuit that inputs the OFDMA frame, performs OFDM modulation for each time slot, and generates a transmission signal with a GI added thereto;
An OFDM demodulation circuit that removes GI from the received signal from the opposing OFDM signal transmitting apparatus and performs OFDM demodulation;
An OFDMA frame reconstruction circuit for reconstructing an OFDMA frame by accumulating OFDM symbols of a plurality of time slots output from the OFDM demodulation circuit;
A subcarrier extraction circuit for extracting a subcarrier of a specific user from the OFDMA frame;
In an OFDM communication system having a configuration for performing multiple access, an OFDM signal receiving device including a modulation signal demapping circuit that demaps subcarriers extracted by the subcarrier extraction circuit and restores data,
The OFDM signal transmitter
The modulated signal mapping circuit;
A serial-parallel conversion circuit that converts the output signal of the modulation signal mapping circuit into low-speed M (M is a positive integer) parallel signals;
The M parallel signals are input, and are spread N times by a plurality of different N times (N is a positive integer, N ≧ M) high-speed code length N code common to all users, and then M-stage multiplexed. A spreading multiplex circuit for obtaining N CDM (Code Division Multiplexing) signals;
A tile mapping circuit that inputs the N CDM signals output from the spread multiplex circuit and arranges data in tiles represented by two-dimensional regions in the frequency direction and the time direction to form CDM tiles; A CDM tile generation circuit provided correspondingly is provided,
A modulation mode control circuit that selects a digital modulation method in the modulation signal mapping circuit according to a transmission line state, and controls a parallel width M in the serial-to-parallel conversion circuit and a code multiplexing number M in the spread multiplexing circuit;
The OFDMA frame configuration circuit inputs CDM tiles of all users generated by the tile mapping circuit, and arranges the CDM tiles so as not to overlap each other in the time domain and the frequency domain in units of tiles according to a predetermined mapping rule. A function of generating an OFDMA frame by adding a CDM tile position of each user, a control signal including the code multiplexing number and the modulation scheme, and other common information;
The OFDM signal receiving apparatus includes:
In place of the subcarrier extraction circuit, a CDM tile extraction circuit that extracts a CDM tile assigned to a specific user;
An equalization circuit for performing equalization processing for correcting the phase characteristic and amplitude characteristic of the data subcarrier for the CDM tile extracted by the CDM tile extraction circuit;
A tile demapping circuit for inputting a CDM tile subjected to the equalization processing and demapping from a two-dimensional region in a frequency direction and a time direction into one time series;
M despreading circuits that separate M data by M despreading codes having different code lengths N each having a rate N times the symbol rate with respect to the output signal of the tile mapping circuit;
An OFDM communication system comprising: parallel serial conversion for reconstructing data restored by the M despreading circuits into one M-times faster serial data and outputting the data to the modulation signal demapping circuit . The OFDM communication system according to claim 1,
An OFDM communication system, wherein a spreading code common to all users used in the spreading multiplex circuit and the despreading circuit is an orthogonal code. The OFDM communication system according to claim 1,
The modulation mode control circuit controls the modulation signal mapping circuit, the serial-to-parallel conversion circuit, and the spread multiplexing circuit for each tile or for each user according to the transmission path state, and the modulation multi-level number for each spread code. An OFDM communication system characterized by allocating different modulation schemes and variably controlling a transmission rate per 1 CDM tile. The OFDM communication system according to claim 1,
The modulation mode control circuit controls the modulation signal mapping circuit, the serial-to-parallel conversion circuit, and the spread multiplexing circuit for each tile or for each user according to a transmission path state, varies the number of code multiplexing, and the spreading code An OFDM communication system characterized in that a modulation scheme having a different number of modulation levels is assigned to each, and the transmission rate per 1 CDM tile is variably controlled. In the OFDM communication system according to claim 3 or claim 4,
2. The OFDM communication system according to claim 1, wherein the modulation mode control circuit uniquely determines a modulation scheme to be assigned to each spread code used in the spread multiplex circuit for a required transmission rate per CDM tile. The input data is mapped to modulation signal points according to the modulation method specified by the modulation mode, rearranged into M parallel data, and code spread multiplexed to generate N CDM signals. The CDM tiles are generated by rearranging in the dimensional arrangement, the CDM tiles of all users are buffered, and orthogonally arranged so as not to overlap with each other in the time-frequency domain, and an OFDMA data frame is constructed. An OFDM signal transmission method for constructing an OFDMA frame by adding a control signal and other common information including information and modulation mode, and generating a transmission signal by performing OFDM modulation;
The received signal is OFDM demodulated, OFDMA symbols for a plurality of time slots are accumulated, an OFDMA frame is reconstructed, a CDM tile is extracted according to a control signal obtained from the OFDMA frame, a channel estimation and a Perform equalization, rearrange the CDM tile configuration data into N-point series, perform despreading processing with the code used in the OFDM signal transmission method to restore M-row parallel data, and convert this M-row parallel data to parallel-serial conversion An OFDM signal receiving method for rearranging to one time-series signal and performing demapping to data in accordance with a demodulation method specified by a modulation mode;
Evaluate whether the current modulation mode satisfies the required communication quality after the start of processing. If satisfied, end the processing. If not satisfied, reset the number of information bits allocated to one CDM tile and respond accordingly. A modulation mode control method for resetting the number of code multiplexes and resetting a combination of modulation schemes assigned to each spreading code. A plurality of modulation signal mapping circuits which are provided for a plurality of users and map each input data to each modulation signal point based on a digital modulation system;
An OFDMA frame configuration circuit that configures an OFDMA frame in which symbols generated by the plurality of modulation signal mapping circuits are arranged on a specific subcarrier of a specific time slot in symbol units;
An OFDM signal transmission apparatus comprising: an OFDM modulation circuit that inputs the OFDMA frame, performs OFDM modulation for each time slot, and generates a transmission signal with a GI added thereto;
The modulated signal mapping circuit;
A serial-parallel conversion circuit that converts the output signal of the modulation signal mapping circuit into low-speed M (M is a positive integer) parallel signals;
The M parallel signals are input, and are spread N times by a plurality of different N times (N is a positive integer, N ≧ M) high-speed code length N code common to all users, and then M-stage multiplexed. A spreading multiplex circuit for obtaining N CDM (Code Division Multiplexing) signals;
A tile mapping circuit that inputs the N CDM signals output from the spread multiplex circuit and arranges data in tiles represented by two-dimensional regions in the frequency direction and the time direction to form CDM tiles; A CDM tile generation circuit provided correspondingly is provided,
A modulation mode control circuit that selects a digital modulation method in the modulation signal mapping circuit according to a transmission line state, and controls a parallel width M in the serial-to-parallel conversion circuit and a code multiplexing number M in the spread multiplexing circuit;
The OFDMA frame configuration circuit inputs CDM tiles of all users generated by the tile mapping circuit, and arranges the CDM tiles so as not to overlap each other in the time domain and the frequency domain in units of tiles according to a predetermined mapping rule. An OFDM signal transmission apparatus comprising a function of adding an OFDMA frame by adding a CDM tile position of each user, a control signal including the code multiplexing number and the modulation scheme, and other common information. The OFDM signal transmission apparatus according to claim 7, wherein
An OFDM signal transmitting apparatus characterized in that a spreading code common to all users used in the spreading multiplex circuit is an orthogonal code. The OFDM signal transmission apparatus according to claim 7, wherein
The modulation mode control circuit controls the modulation signal mapping circuit, the serial-to-parallel conversion circuit, and the spread multiplexing circuit for each tile or for each user according to the transmission path state, and the modulation multi-level number for each spread code. An OFDM signal transmitting apparatus characterized by allocating different modulation schemes and variably controlling a transmission rate per 1 CDM tile. The OFDM signal transmission apparatus according to claim 7, wherein
The modulation mode control circuit controls the modulation signal mapping circuit, the serial-to-parallel conversion circuit, and the spread multiplexing circuit for each tile or for each user according to a transmission path state, varies the number of code multiplexing, and the spreading code An OFDM signal transmitting apparatus characterized in that a modulation scheme having a different number of modulation multi-values is assigned to each, and the transmission rate per 1 CDM tile is variably controlled. In the OFDM signal transmission device according to claim 9 or 10,
The OFDM signal transmitting apparatus characterized in that the modulation mode control circuit uniquely determines a modulation scheme to be assigned to each spreading code used in the spreading multiplex circuit for a required transmission rate per CDM tile. An OFDM demodulation circuit that removes GI from the received signal from the opposing OFDM signal transmitting apparatus and performs OFDM demodulation;
An OFDMA frame reconstruction circuit for reconstructing an OFDMA frame by accumulating OFDM symbols of a plurality of time slots output from the OFDM demodulation circuit;
A subcarrier extraction circuit for extracting a subcarrier of a specific user from the OFDMA frame;
In an OFDM signal receiving apparatus comprising: a modulated signal demapping circuit that demaps the subcarriers extracted by the subcarrier extraction circuit and restores data;
In place of the subcarrier extraction circuit, a CDM tile extraction circuit that extracts a CDM tile assigned to a specific user;
An equalization circuit for performing equalization processing for correcting the phase characteristic and amplitude characteristic of the data subcarrier for the CDM tile extracted by the CDM tile extraction circuit;
A tile demapping circuit for inputting a CDM tile subjected to the equalization processing and demapping from a two-dimensional region in a frequency direction and a time direction into one time series;
M despreading circuits that separate M data by M despreading codes having different code lengths N each having a rate N times the symbol rate with respect to the output signal of the tile mapping circuit;
OFDM signal reception comprising: parallel serial conversion for reconstructing data restored by the M despreading circuits into one M times faster serial data and outputting the data to the modulation signal demapping circuit apparatus. The OFDM signal receiving apparatus according to claim 12,
An OFDM signal receiving apparatus, wherein a spreading code common to all users used in the despreading circuit is an orthogonal code.

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