JP2002111631A - System and apparatus for radio communication - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system and an apparatus wherein the effect of multipath waves due to a wide band is reduced, many users are accommodated and an efficient transmission is realized. SOLUTION: The total transmission band is divided into a plurality of bands. An access operation by a frequency division which uses the divided bands as a unit, an access operation by a code division in the respective divided bands, and an access operation by a time division by constituting a time slot in a time-base direction are used. Consequently, the access operations can be controlled flexibly. The code division may be either (a) a multicarrier CDMA system or (b) a DS-CDMA system. When the frequency of the divided bands to be used, the number of the divided bands, the number of diffusion codes to be used or the number of time slots to be allocated is changed, the transmission capacity of the system and the apparatus can be made variable.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a frequency division multiplex,
TECHNICAL FIELD The present invention relates to a multiple access scheme for performing communication using code division multiplexing and time division multiplexing, and relates to a wireless communication system and a wireless communication apparatus that realize flexible and efficient multiple access.

[0002]

2. Description of the Related Art In recent years, voice,
There is an increasing demand for multimedia communication for transmitting and receiving various types of data, such as texts and images, so that high-speed transmission is required. Also, with the spread of mobile communication, it is desired to accommodate an extremely large number of users in a limited frequency band. However, it is known that, in mobile communication, frequency-selective fading occurs due to multipath waves, and this is particularly affected by high-speed transmission that requires wideband transmission.

As one of the countermeasures, orthogonal frequency multiplexing (Orthogonal frequency multiplexing), which is one of the representative frequency division multiplexing systems, is proposed.
A mobile communication system using a Band Division Multiple Access (BDMA) scheme that enables multiple access in a Frequency Division Multiplex (OFDM) scheme has been proposed (Chihiro Fujita,
Hiroaki Takahashi, Kazuyuki Sakota, Mihiro Suzuki, "Basic Transmission Characteristics of BDMA System", IEICE Technical Report RCS99-2, pp.7-12, April 1999
Month). FIG. 5 shows the spectrum of the BDMA system. B
The DMA system is a communication system using frequency division multiple access and time division multiple access. Each subcarrier in the BDMA system transmits information to be transmitted by performing QPSK modulation or the like. The entire transmission band is divided into a plurality of bands, and different users are accommodated using the divided bands.

On the other hand, Code Division Multiple Access (CDMA) is used in the OFDM communication system.
CDMA (Multi-Carrie)
r CDMA) is known. Multi-carrier CDMA
Due to its characteristics, the schemes allocate each chip of a spreading code to each subcarrier and perform CDMA on the frequency axis, and the conventional direct sequence CDMA (Direct Sequence CDMA:
Signals spread on the time axis according to the DS-CDMA (DS-CDMA) method are broadly classified as those arranged on the frequency axis as one subcarrier. Conventional multi-carrier CDMA system and DS-
FIG. 6 shows each spectrum of the CDMA system. Information to be transmitted in the multi-carrier CDMA system includes:
The signal is subjected to QPSK modulation or the like, further spread using mutually orthogonal spreading codes assigned to each user, and arranged on the frequency axis. In the multi-carrier CDMA system in which CDMA is performed on the frequency axis, each chip (C
_{1 to} C _n ) are subcarriers (f _{1 to} f _n ) of the OFDM signal.
It corresponds to.

[0005]

As described above, the OFDM communication system and the BDMA system, which is one of the multiple access systems, are resistant to delay waves and resistant to frequency selective fading as described above. When the bandwidth is widened due to the necessity of transmission and the number of subcarriers is increased, there is a problem that the number of devices for realizing it is extremely increased. In particular, the fast Fourier transformer (FFT) and the inverse fast Fourier transformer (IFFT) used in the transmission / reception device require multipliers of the square of the number of subcarriers used.
Further, in the CDMA system, if the band is widened for realizing high-speed transmission, there is a problem that the influence of multipath waves increases and communication performance deteriorates. Alternatively, a compensating device for the deterioration is required, and the scale of the receiving device increases. In addition, there is a problem that it is difficult to model a propagation path, separate and combine multipaths with the increase in bandwidth. Furthermore, in multimedia communication, depending on the user's communication purpose,
It is necessary to realize multiple transmission speeds and to be able to change the speeds adaptively, realize a variable transmission speed with simple control, and efficiently use frequency and power to efficiently use transmission and efficiency. Access control is expected. Furthermore, in the cellular system, it is also important to take measures against performance degradation due to interference signals from other cells.

Accordingly, the present invention has been made in view of the above problems,
It is an object of the present invention to provide a wireless communication system capable of realizing a high transmission rate, flexible access control, and reducing interference. Another object of the present invention is to provide a wireless communication device that can realize a variable transmission rate with a simple configuration and that can reduce the scale of a receiver and use power efficiently in a mobile station.

[0007]

In order to achieve the above object, a radio communication system according to the present invention provides a means for performing band division multiplexing in units of bands obtained by dividing the entire transmission band of the system into a plurality of units. It has means for performing code division multiplexing in each band and means for performing time division multiplexing using time slots formed in the time axis direction. The code division multiplexing includes a multi-carrier CDMA system in which one chip of a spreading code corresponds to each subcarrier of a plurality of subcarriers included in the band.
Alternatively, a direct spreading method may be used. Further, a means for performing frequency hopping between the plurality of divided bands may be provided. Furthermore, according to the type of information to be transmitted or the propagation environment, the apparatus has means for changing the divided band, the number of the divided bands, the number of the spreading codes, or the number of the time slots to be allocated to the user. You may do so.

Further, a wireless communication apparatus according to the present invention is a wireless communication apparatus for transmitting a signal using one or a plurality of bands obtained by dividing an entire transmission band of a system into a plurality of bands, Control means for selecting a band to be used among the bands, means for dividing transmission information into a number corresponding to the number of the selected bands, and designation by the control means for each of the divided transmission information. Spreading means for performing spread modulation using the spread code, and a carrier frequency signal corresponding to a band selected from the frequency signals corresponding to the plurality of divided bands based on a control signal from the control means. A carrier selecting means for selecting and outputting at a designated timing; and a transmitting signal by multiplying an output of the spreading means by a carrier frequency signal selected from the carrier selecting means. And has a means for generating a. Still further, the spreading means performs spreading by a multi-carrier method in which one chip of a spreading code is made to correspond to each subcarrier of a plurality of subcarriers included in the band, or directly multiplies the input signal by a spreading code. It may perform diffusion. Still further, the control means may perform frequency hopping by changing the band to be used every predetermined time. Furthermore, the control means changes the divided band, the number of divided bands, the number of spreading codes or the timing to be allocated to the user according to the type of information to be transmitted or the propagation environment. There may be.

Still another wireless communication apparatus of the present invention is a wireless communication apparatus that receives a signal transmitted using one or more of a plurality of divided bands of the entire transmission band of the system. Controlling means for supplying a control signal for selecting a band corresponding to a signal to be received among the plurality of divided bands; and selecting at a designated timing in accordance with a control signal from the control means. Band selecting means for outputting a received signal of the set band, despreading means for despreading the received signal from the band selecting means using a spreading code designated by the control means, and output from the despreading means. Means for generating reception information.

According to the radio communication system and the radio communication apparatus of the present invention, extremely flexible access control can be performed by using three types of multiplex access systems of frequency division multiplex, code division multiplex and time division multiplex. Thus, multiple access with high transmission efficiency in mobile communication becomes possible. In addition, by using a multi-carrier CDMA system in which a code division multiplexing unit spreads using a code on a frequency axis, frequency use efficiency can be improved.
Furthermore, since the entire wireless transmission band can be divided into a plurality of parts and transmitted and received independently, by independently receiving each divided band, deterioration due to multipath waves can be suppressed and the transmission speed can be reduced. It can be improved efficiently. Also, the scale of the fast Fourier transformer (FFT) and the inverse Fourier transformer (IFFT) of the transceiver can be reduced,
In the mobile station, it is possible to reduce the weight and power consumption of the device. Furthermore, by adopting a configuration of a necessary number of divisions according to a desired maximum transmission rate for a communication purpose, a simple device configuration and a reduction in transmission power can be achieved. Furthermore, the frequency band of the band used for transmission, the number of bands, the number of codes, or the time-divided communication time (the number of allocated time slots) is changed according to the type of information to be transmitted or the propagation environment. Thus, the transmission speed can be changed. Such a configuration in which the transmission rate is variable can be a simple configuration because there is no need to change the modulator. Furthermore, by performing frequency hopping, it is possible to improve communication performance due to the frequency diversity effect, and to take measures against interference waves in a multi-cell environment.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a spectrum according to the wireless communication system of the present invention. FIG. 1A shows a spectrum when a multicarrier CDMA system is used as a code division multiplexing system, and FIG. 1B shows a spectrum when a DS-CDMA system is used. As shown in the figure, the entire transmission band of the system is divided into a plurality of bands, and each of the divided bands (divided bands) is made an orthogonal, that is, independent communication band by a filter or the like. Then, band division multiplexing (frequency division multiplexing) is possible in units of the divided band. In each of the divided bands, a multi-carrier CDMA system (FIG. 1) in which spreading is performed in the frequency axis direction using a spreading code.
(A)) or code division multiplexing is performed by the DS-CDMA method (FIG. 1 (b)). In FIG. 1, the difference in spectrum design indicates different spreading codes, that is, different users. The frequency band of the divided band to be used and the type of code to be used are determined according to the propagation environment and the communication state of another user. Further, on the time axis, a time slot is formed by dividing time, thereby enabling time division multiplexing. As described above, in the wireless communication system of the present invention, three types of frequency division multiplexing, code division multiplexing, and time division multiplexing are used.
By performing access that adaptively changes the type,
It realizes flexible access control.

Further, according to the communication purpose of each user, the frequency band of the divided band to be used, the number of divided bands,
By changing the number of spreading codes used, some or all of the number of time slots to communicate, the transmission capacity can be changed. That is, a user with a large transmission capacity uses a large number of bands and spreading codes, and a user with a small transmission capacity uses one band and one spreading code. Thus, the transmission capacity can be made variable. Furthermore, when determining the frequency band of the split band,
A band to be used is determined by a random number or a random code, and frequency hopping is performed by temporally changing the frequency band. As a result, a frequency diversity effect can be obtained, and in a multi-cell environment, the influence of interference from other cells can be reduced.

An example of a transmitting section and a receiving section constituting the wireless communication system of the present invention will be described with reference to FIGS.
FIG. 2 shows a configuration of a transmission / reception unit of the wireless communication system according to the present invention. FIG. 2A is a block diagram showing a configuration of a transmission unit. FIG. 2B is a block diagram showing a configuration of a reception unit. is there. In the transmitting unit of FIG. 2A, reference numeral 1070 denotes a controller, which controls the number of the divided bands used for transmission from the transmitting unit, the frequency band of each divided band, the allocation of the time slot, and the spread signal used. Specify the type and number.

An information modulation symbol 1010 on which modulation such as QPSK modulation has been performed is subjected to serial / parallel conversion by a serial / parallel converter 1020 in accordance with the number of bands to be simultaneously transmitted. This parallel number is specified by the controller 1070, and FIG. 2 shows a case where the number of bands to be transmitted simultaneously is four. The parallelized information modulation symbol is output to the spreader 1031.
The spreading is performed using the spreading code 1080 designated by the controller 1070 in 1034. As described above, this spreading method is a multicarrier CDMA method or a D
Any of the S-CDMA systems may be used. The configurations of the spreaders 1031 to 1034 and the corresponding despreaders in each system will be described later.

The output signals of spreaders 1031 to 1034 are applied to carrier frequency signals 1120 corresponding to the respective divided bands.
Is multiplied by the multipliers 1051 to 1054. Here, the carrier frequency signal 1120 is a frequency signal 1110 prepared in advance so that each divided band is orthogonal on the frequency axis.
Are selected by the carrier selection unit 1040 by the carrier control signal 1090 from the controller 1070. In FIG. 2 (a), the frequency signal 1110 have f ₈ is prepared from f _1, the number of sub-bands to be transmitted in parallel 4
Are selected (f _{c1 to} f _c4 ). In addition, the carrier selection unit 1040 receives the selected carrier frequency 1 at a timing corresponding to the time slot assigned to the transmission unit according to a carrier control signal from the control unit 1070.
120 is output. The signal of each divided band is added to an adder 1055.
And a transmission signal 1060 is generated. Information such as the number of divided bands to be used in the control unit 1070, the frequency band of each divided band, the allocation of the time slot, and the type and number of spreading codes to be used are transmitted to the receiving side via a control channel or the like. The control unit 2070 is notified.

In the receiving unit shown in FIG. 2B, band selecting units 2021 to 2024 select a divided band to be received by a band selection control signal 2070 from the controller 2060, and convert the received signal 2010 into a signal of each divided band. To separate. Each of the band selection units 2021 to 2024 includes a band-pass filter, a multiplier for performing frequency conversion to a baseband band by a carrier frequency signal of a band selected in an assigned time slot, and the like. The demultiplexed baseband signal for each band is despread using a spreading code 2080 by despreaders 2031 to 2034 of the same system as the code division multiplexing system on the transmission side, and the original information modulation symbol is output by a parallel / serial converter 2040. 2050, which is demodulated to obtain information data.

In FIG. 2A, four spreaders 1031 to 103 corresponding to four bands to be used are used.
4, only the multipliers 1051 to 1054 are shown, and in FIG. 4B, four band selectors 2021 to 2024 and despreaders 2031 to 2034 are shown. Equipped with a number of diffusers and despreaders,
Under the control of the controller 1070 and the controller 2060, the number of devices assigned at that time is selected and used. Further, the controller 1070 adaptively changes the frequency band of the used band, the number of bands, the type and number of spreading codes to be used, the allocation of time slots, and the like according to the communication purpose or propagation environment of the user. can do. Thereby, the transmission capacity can be made variable. In this case, the changed information is notified to the controller 2060 on the receiving side through a control channel or the like. Further, the controller 1070 and the controller 2060 can have a function of performing frequency hopping for changing a division band to be selected using a random number or a random code at every predetermined time synchronized with the time slot. As a result, a frequency diversity effect can be expected.

FIG. 3 is a diagram showing a configuration example of the spreaders 1031 to 1034 and the despreaders 2031 to 2034 in the case of the multi-carrier CDMA system. As the spreaders 1031 to 1034 in FIG. 2, the spreaders based on the multi-carrier CDMA system in FIG. 3A are used. The information modulation symbols 3010 of this band input from the serial / parallel converter 1020 are copied by the number of chips of the spreading code 3040 by the copying unit 3020, and each of the copied information modulation symbols and each chip 3041 of the spreading code is copied.
044 is multiplied by multipliers 3031 to 3034. FIG. 3 shows a case where the length of the spreading code, that is, the number of chips of the spreading code is four. Here, the type of the spreading code is determined by the controller 1070. The inverse fast Fourier transformer (IFFT) 3050 arranges the information modulation symbols multiplied by the spreading code chips on subcarriers orthogonal on the frequency axis and converts them into signals on the time axis. A guard period for eliminating the effect of the multipath wave is inserted by the guard period inserter 3060, and the guard signal is output as a spreader signal 3070.
The output signal 3070 is output from the multipliers 1051 to 1054.
Is output to the corresponding one of.

FIG. 3B shows a multi-carrier CDMA.
FIG. 3 is a diagram illustrating a configuration example of a despreader in the case of a system. The received input signal 3110 of the divided band selected by the band selection units 2021 to 2024 is used as the guard period deleter 31
The guard period is deleted at 20 and the fast Fourier transformer (F
FT) 3130. Here, the signal on the time axis is returned to the subcarrier on the frequency axis, and the
Each chip of 0 is multiplied by each of the multipliers 3151 to 3154, despread, and synthesized by the synthesizer 3160 to become an output signal 3170 of the despreader. This output signal 3170
Is input to the parallel / serial converter 2040.

FIG. 4 is a diagram showing one configuration example of the spreaders 1031 to 1034 and the despreaders 2031 to 2034 when the DS-CDMA system is adopted. As the spreaders 1031 to 1034 in FIG. 2, the spreaders based on the DS-CDMA system in FIG. 4A may be used. In this case, the parallelized information modulation symbols are spread on the time axis. In the spreader shown in FIG. 4A, the input information modulation symbol 4010 corresponding to this band is divided into a spreading code 4020 and a multiplier 4030.
To obtain an output signal 4040 of this spreader. As shown, one information symbol period corresponds to a spreading code period (four chips in this example). The type of the spread signal is determined by the controller 1070. FIG.
In the despreader shown in FIG.
The received input signal 4110 of the relevant divided band selected by 2024 is multiplied by the same spreading code 4130 as the spreading code on the transmitting side by the multiplier 4020 and integrated by the integrator 4140, whereby the input signal 4110 and the spreading code are 41
30 is obtained, and the output signal 4 of this despreader is obtained.
It becomes 150.

By using the above configuration, it is possible to transmit and receive the spectrum shown in FIG.
In the above description, CDMA for each divided band is used.
As a scheme, a multi-carrier CDMA scheme in which one chip of a spreading code corresponds to each subcarrier and a direct spreading C
Although the case where the DMA method is adopted has been described, the present invention is not limited to this. As described above, multicarrier C
Various schemes are known as the DMA scheme, such as a scheme in which a signal spread on the time axis by the DS-CDMA scheme is arranged as one subcarrier on the frequency axis, and such a scheme may be adopted.

[0022]

As described above, according to the radio communication system and radio communication apparatus of the present invention, flexible access control can be achieved by using three types of frequency division multiplexing, time division multiplexing, and code division multiplexing. Can be realized. In addition, since the broadband wireless transmission band is divided into multiple bands, each of the divided bands can be narrower than the entire original transmission band, and since each is a band that can communicate independently, multipath Interference can be reduced,
Does not degrade communication performance. Further, since one independent communication band becomes narrower, it is possible to reduce the device scale and improve power efficiency. Further, according to the present invention using the multi-carrier CDMA system as the code division multiplexing system, it is possible to reduce the guard bandwidth between the divided bands for making the divided bands independent communication bands, and to reduce the frequency use efficiency. Is good. Further, in a terminal device that may have a small maximum transmission rate, the size and transmission power of the device can be reduced, so that a device with small size and low power consumption can be realized. Furthermore, the transmission capacity can be made variable by changing the number of divided bands to be used or the number of codes to be used according to the communication purpose or propagation environment of the user. Such a configuration in which the transmission rate is variable can be a simple configuration because there is no need to change the modulator. Especially when this is applied to a mobile station, the configuration of the transceiver can be reduced, and power efficiency is good. Furthermore, by performing frequency hopping that randomly changes the frequency band of the divided band for communication with time,
A frequency diversity effect can be obtained, and communication performance can be improved. Further, by doing so, it is possible to improve performance such as reducing interference from other cells in a multi-cell environment.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a spectrum of a wireless communication system according to the present invention, in which (a) illustrates a case where multi-carrier CDMA is used and (b) illustrates a case where DS-CDMA is used as a code division multiplexing system.

FIG. 2 is a block diagram illustrating a configuration example of a transmission unit and a reception unit in the wireless communication system according to the present invention. FIG. 2A is a diagram illustrating a configuration of a transmission unit, and FIG.

FIG. 3 shows a multi-carrier CDM as a code division multiplexing system.
It is a block diagram which shows the example of a structure of the spreading | diffusion part and despreading part in embodiment using A system.

FIG. 4 is a block diagram illustrating a configuration example of a spreading unit and a despreading unit in an embodiment using a DS-CDMA system as a code division multiplexing system.

FIG. 5 is a diagram showing a spectrum of a band division multiple access (BDMA) system.

FIG. 6 shows a conventional multi-carrier CDMA system and DS-C.
FIG. 3 is a diagram illustrating a spectrum of a DMA system.

[Explanation of symbols]

 Reference Signs List 1010 Information symbol 1020 Serial / parallel converter 1031 to 1034 Spreader 1040 Carrier selection unit 1051 to 1054 Multiplier 1055 Adder 1060 Transmission signal 1070 Controller 2010 Received signal 2021 to 2024 Band selection unit 2031 to 2034 Despreader 2040 Parallel / Serial converter 2050 information symbol 2060 controller 3020 duplication unit 3050 inverse fast Fourier transformer 3060 guard period inserter 3120 guard period deleter 3130 fast Fourier transformer 3160 synthesizer

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Yoshihide Kamio 3-4 Hikarinooka, Yokosuka City, Kanagawa Prefecture F-term in the R & D Laboratories Mobile Communication Technology Laboratories (reference) 5K022 AA12 AA22 EE01 EE22 EE32 FF01 5K028 AA11 HH00 KK12 MM18 RR02 SS04 SS14

Claims (11)

[Claims] 1. A means for performing band division multiplexing in units of bands obtained by dividing the entire transmission band of a system into a plurality of units, a means for performing code division multiplexing in each of the divided bands, and a time constituted in a time axis direction. A wireless communication system comprising means for performing time division multiplexing using slots. 2. The code division multiplexing method according to claim 1, wherein each of a plurality of subcarriers included in the band has a spreading code of 1
2. The wireless communication system according to claim 1, wherein the wireless communication system is a multi-carrier CDMA system that supports chips. 3. The code division multiplexing method according to claim 1, wherein said code division multiplexing is direct spread CDMA.
The wireless communication system according to claim 1, wherein the wireless communication system is a system. 4. The wireless communication system according to claim 1, further comprising means for performing frequency hopping between said plurality of divided bands. 5. The divided band allocated to the user according to a type of information to be transmitted or a propagation environment,
The wireless communication system according to any one of claims 1 to 4, further comprising means for changing the number of the divided bands, the number of the spreading codes, or the number of the time slots. 6. A wireless communication apparatus for transmitting a signal using one or a plurality of bands obtained by dividing a whole transmission band of a system into a plurality of bands, and selecting a band to be used among the plurality of bands. Control means for dividing transmission information into a number corresponding to the number of the selected bands, and spreading modulation using a spreading code specified by the control means for each of the divided transmission information. And a carrier frequency signal corresponding to a band selected from the frequency signals corresponding to the plurality of divided bands based on a control signal from the control unit, and at a specified timing. A carrier selecting means for outputting, and a means for generating a transmission signal by multiplying an output of the spreading means by a carrier frequency signal selected from the carrier selecting means. Wireless communication apparatus according to symptoms. 7. The spreading means according to claim 6, wherein said spreading means performs spreading by a multi-carrier method in which one chip of a spreading code is associated with each sub-carrier of a plurality of sub-carriers included in said band. The wireless communication device according to claim 1. 8. The radio communication apparatus according to claim 6, wherein said spreading means performs direct spreading by multiplying said input signal by a spreading code. 9. The radio communication apparatus according to claim 6, wherein the control unit changes the band to be used every predetermined time and performs frequency hopping. 10. The control unit changes the divided band, the number of divided bands, the number of spreading codes, or the timing assigned to the user according to a type of information to be transmitted or a propagation environment. The wireless communication device according to claim 6, wherein: 11. A wireless communication apparatus for receiving a signal transmitted using one or more of a plurality of divided bands of a whole transmission band of a system, wherein: Control means for supplying a control signal for selecting a band corresponding to a signal to be received; band selection for outputting a reception signal of a band selected at a designated timing according to a control signal from the control means Means, despreading means for despreading a received signal from the band selecting means using a spreading code designated by the control means, and means for generating reception information from an output of the despreading means. A wireless communication device characterized by the following.