JP3987858B2 - Wireless communication system, wireless transmission device, wireless reception device, and wireless communication method - Google Patents

Description

  The present invention generally belongs to the technical field of wireless communication, and particularly relates to an Orthogonal Frequency Division Multiplexing (OFDM) wireless communication system, a wireless transmission device, a wireless reception device, and a wireless communication method.

  In this type of technical field, OFDM wireless communication that is advantageous for a multipath propagation environment and the like is considered promising. In the OFDM scheme, an information channel (symbol sequence) to be transmitted is associated with a number of subcarriers selected to be orthogonal to each other, inversely Fourier transformed, added with a guard interval, and then wirelessly transmitted as an OFDM symbol. . On the receiving side, the guard interval is removed from the received signal, and the subsequent signal is Fourier transformed to extract information for each subcarrier, and the transmitted information channel is restored. In this case, the radio receiving apparatus receives not only the information channel but also the control channel, and the control channel transmits a pilot channel formed of a predetermined known signal and common information to all the radio receiving apparatuses. And a dedicated control channel for transmitting individual information to each wireless reception device. A predetermined dedicated resource is allocated to the control channel, and the control channel is multiplexed with the OFDM symbol transmitted from the wireless transmission device. The wireless reception device extracts a control channel such as a pilot channel from the received OFDM symbol, and performs channel estimation, securing synchronization timing, and the like. Such an OFDM wireless communication technique is described in Patent Document 1, for example.

FIG. 1 is a conceptual diagram showing a relationship between an information channel and a control channel. FIG. 1A shows a state where a pilot channel is multiplexed with an information channel by assigning a predetermined frequency band to the pilot channel. FIG. 1B shows that the pilot channel is multiplexed with the information channel by assigning a predetermined time slot to the pilot channel.
JP 2001-144724 A

  In this kind of technical field, mainly from the viewpoint of providing high-quality services, it will be increasingly required to respond to higher speeds of mobile terminals, wider bandwidths for communications, higher frequencies, etc. Is done. For this reason, it is required to provide a communication service that can sufficiently withstand a communication environment in which signal levels change drastically in the frequency and time axis directions.

  On the other hand, as shown in FIG. 1, a control channel such as a pilot channel is inserted only in a specific region on the frequency axis or the time axis. Therefore, when the signal level fluctuates drastically in a region where it is not inserted, channel estimation or the like cannot be performed satisfactorily. In such a case, the function of the pilot channel or the like is not sufficiently exhibited and the purpose is not sufficiently achieved, so that the resources allocated to the control channel are not effectively utilized.

  Furthermore, since dedicated resources are allocated to the control channel, the resources allocated to the information channel are reduced accordingly. If resources are allocated to the control channel only when they are not effectively used, the significance of securing resources in the control channel is lost until the resources allocated to other channels are reduced.

  The present invention has been made in view of the above-described problems, and the problem is that a wireless communication system, a wireless communication system capable of effectively using resources allocated to information channels and control channels in OFDM wireless communication To provide a transmission device, a wireless reception device, and a wireless transmission method.

  According to the present invention, an orthogonal frequency division multiplexing (OFDM) wireless communication system comprising a wireless transmission device and a wireless reception device is used. The wireless transmission device includes a determination unit that determines a spreading factor and an amplitude set for a control channel based on quality information of a transmission signal or an interference amount from information data, a spreading factor that is determined as an information channel, and Means for multiplexing the control channel code-spread based on the amplitude, and means for wirelessly transmitting the modulated signal modulated by the OFDM method. The wireless reception device includes means for extracting the control channel by demodulating and despreading the received signal using the OFDM method.

  According to the present invention, it is possible to effectively use resources allocated to an information channel and a control channel in OFDM wireless communication.

  In one embodiment of the present invention, a wireless transmission device for performing orthogonal frequency division multiplexing (OFDM) wireless communication is used. The apparatus includes a determination unit that determines a spreading factor and an amplitude set for the control channel based on quality information of the transmission signal or an interference amount from the information data, and an information channel and the determined spreading factor and amplitude. And a means for multiplexing the control channel that has been code-spread based thereon and a means for wirelessly transmitting the modulated signal by modulating the multiplexed signal using the OFDM method.

  In one aspect of the present invention, the control channel is code-spread using the MC-CDMA scheme. Since the control channel is continuously inserted in a wide frequency domain, it is possible to accurately perform channel estimation and the like in the entire section even for a sudden change in the signal level in the frequency domain.

  In one aspect of the present invention, the control channel is code-spread using the DS-CDMA method. Since the control channel is continuously inserted continuously over the entire frame period, it is possible to accurately perform channel estimation and the like in the entire section even for a sudden change in the signal level in the time domain.

  According to one aspect of the present invention, a radio communication apparatus according to the present invention is provided in a radio base station of an isolated cell. In such a communication environment, the advantage of not performing code spreading on the information channel is particularly great.

  According to an aspect of the present invention, the determination unit adjusts the spreading factor and the amplitude so that the control channel has a lower amplitude level than the information channel. Thereby, the control channel is more appropriately multiplexed on the information channel so as not to prevent the restoration of the information channel.

  According to one aspect of the present invention, information indicating the spreading factor of a spreading code and information indicating the amplitude of a code-spread control channel are wirelessly transmitted. As a result, the receiving apparatus can quickly restore the control channel from the received signal.

  According to one aspect of the present invention, a wireless receiver for performing OFDM wireless communication is used. The apparatus includes: a determination unit that determines a spreading factor and a channel type; and a unit that restores a control channel from a received signal multiplexed with an information channel and a control channel according to the determined spreading factor and channel type. .

  According to one aspect of the present invention, an OFDM wireless communication method is used. The method determines the spreading factor and amplitude set for the control channel based on the quality information of the transmission signal or the amount of interference from the information data, and based on the spreading factor and amplitude determined for the information channel. A step of multiplexing the control channel that has been code-spread, a step of modulating the multiplexed signal using the OFDM method, and wirelessly transmitting the signal, and a signal received by the wireless receiving device is demodulated using the OFDM method and despreading To extract the control channel.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. In the figure, it should be noted that among the various functional elements of the radio transmission apparatus and radio reception apparatus in the OFDM system, elements that are particularly relevant to the present invention are drawn.

  FIG. 2 is a partial block diagram of a wireless transmission device according to an embodiment of the present invention. The radio transmission apparatus 200 includes a channel encoding unit 202, a data modulation unit 204, serial-parallel conversion units (S / P conversion units) 206 and 208, a two-dimensional spreading unit 210, a control channel multiplexing unit 212, a high-speed In addition to the inverse Fourier transform unit (IFFT) 214, a diffusion rate and amplitude determination unit 216, a diffusion rate control unit 218, and an amplitude control unit 220 are included.

  The channel encoding unit 202 receives an information bit stream expressing the content that the user intends to transmit as an OFDM symbol, and performs appropriate encoding. This encoding may be error correction encoding such as convolutional encoding or turbo encoding.

  The data modulation unit 204 modulates an appropriately encoded information bit stream using a predetermined modulation method. As the modulation scheme, any appropriate scheme such as QPSK, 16QAM, or 64QAM may be employed.

  The serial / parallel converter 206 converts the modulated series of information bit streams into parallel bit streams. For simplicity, the number of parallel bit streams is the number of subcarriers Nc in this embodiment, but is not limited to this. The parallel bit stream is input to the control channel multiplexing unit 212.

  On the other hand, the serial-parallel conversion unit 208 converts a series of control bit streams representing a control channel such as a pilot channel into parallel control bit streams. In this case, the number of control bitstreams in this case is assumed to be the number obtained by dividing the number of subcarriers Nc by the code spreading factor SF (Nc / SF) in this embodiment, but is not limited to this.

  The two-dimensional spreading unit 210 multiplies the parallel control bit stream converted by the serial / parallel conversion unit 208 by a spreading code.

  FIG. 3 shows a more detailed block diagram of the two-dimensional diffusion unit 210. As shown in the figure, the two-dimensional spreading unit 210 is an element for performing code spreading by a multi-carrier code division multiple access (MC-CDMA) system, and includes a symbol duplicating unit 302, a spreading code generating unit 304, And a spread code multiplication unit 306. Note that the MC-CDMA system may also be referred to as the OFCDM system. The symbol duplicating unit 302 converts one of the parallel control bit streams into a predetermined number (for example, spreading factor SF) of parallel control bit streams, and converts the converted control bit stream to one of the spreading code multiplication unit 306. Give to the input. The spreading code generation unit 304 generates a predetermined spreading code for code spreading and supplies it to the other input of the spreading code multiplication unit 306. Each of the spreading code multipliers 306 performs code spreading of the control bit stream by multiplying the control bit stream by the spreading code. The code-spread control bit stream is supplied to the control channel multiplexing unit 212 via the multiplication unit 222 for appropriately adjusting the amplitude level.

  2 acquires, measures, or estimates information related to signal quality (for example, reception quality information) required in the current wireless communication, information channel interference with the control channel, and the like. The spreading factor / amplitude determination unit 216 determines the coding rate and amplitude for the control channel based on the acquired information and the like, and notifies the spreading factor control unit 218 and the amplitude control unit 220 of the determined contents.

  FIG. 10 shows a more detailed block diagram of the spreading factor and amplitude determination unit 216. The spreading factor and amplitude determining unit 216 includes a control channel transmission power determining unit 1002, a spreading factor determining unit 1004, and an amplitude determining unit 1006.

The control channel transmission power determining unit 1002 obtains a transmission power P _control that will be assigned when a non-spreading control channel is transmitted. This transmission power can be made to correspond to the power of the output signal of the two-dimensional spreading unit 210 in FIG. 2, and can be determined based on feedback information from a radio receiving apparatus described later. The feedback information may include reception quality (for example, SINR, etc.) at the wireless reception device, interference amount for the control channel due to the information channel, and the like. For example, the transmission power P _control may be calculated according to the following equation.

P _control > (interference amount from information channel + noise component) × α (fixed value)
Here, the noise component is an amount that can be estimated from the received SINR, and α is a predetermined scaling factor. The power P _control obtained in this way is notified to the spreading factor determining unit 1004.

The spreading factor determining unit 1004 obtains the spreading factor SF so that the ratio of the transmission power (P _control / SF) of the control channel after spreading to the transmission power P _data of the information channel does not exceed a predetermined threshold Th. The threshold Th may be a fixed constant value or may be dynamically set based on the received SINR in the feedback information. The spreading factor SF may be calculated, for example, so that the following formula is established.

(P _control / SF) / P _data <Th.
The spreading factor obtained in this way is notified to the amplitude determining unit 1006 and the spreading factor control unit 218 in FIG.

The amplitude determination unit 1006 obtains the amplitude A _control of the signal that realizes the transmission power (P _control / SF) of the control channel after spreading, calculated as described above. In general, since the power of a signal is proportional to the square of the amplitude, such an amplitude can be calculated by the following equation, for example.

A _control = √ (P _control / SF).
The amplitude A _control obtained in this way is notified to the amplitude control unit 220.

FIG. 11 schematically shows the relationship between the control channel power P _control before spreading, the information channel power P _data, and the control channel power after spreading (P _control / SF). In the present embodiment, since the control channel is continuously inserted in the frequency axis direction, in FIG. 11, the vertical axis corresponds to power, and the horizontal axis corresponds to frequency. By setting the power of each signal in this way, the amount of interference exerted on the information channel by the control channel can be made less than the threshold Th.

  The spreading factor control unit 218 in FIG. 2 sends a control signal for setting an appropriate code spreading factor based on the information given from the spreading factor and amplitude determination unit 216 to the two-dimensional spreading unit 210 (symbol duplication unit 302). To give. The target value SF is input to the spreading factor control unit 218, and a control signal for realizing the target value SF is output therefrom.

The amplitude control unit 220 also gives a control signal for appropriately setting the amplitude level or power to the multiplication unit 222 based on the information given from the spreading factor and the amplitude determination unit 216. A target value A _control is input to the amplitude control unit 220, and a control signal for realizing the target value A _control is output therefrom.

  The control channel multiplexing unit 212 adds the parallel information bit stream from the serial / parallel conversion unit 206 and the code-spread parallel control bit stream for each subcarrier, and outputs Nc bit streams. That is, the Nc bit streams are obtained by multiplexing a control bit stream that is code-spread on an information bit stream.

  The IFFT unit 214 converts the information carried on each subcarrier into a time-domain bit stream by performing a fast inverse Fourier transform on the Nc bit streams. This bit stream is then wirelessly transmitted through a wireless unit including a band limitation processing unit, a frequency conversion unit, a power amplification unit, and the like (not shown).

  FIG. 4 shows a partial block diagram of a wireless receiver according to an embodiment of the present invention. Radio receiving apparatus 400 includes a spreading factor and channel type determination unit 408 and a two-dimensional despreading unit 410 in addition to symbol timing synchronization unit 402, guard interval removal unit 404, and fast Fourier transform unit 406.

  The symbol timing synchronization unit 402 performs synchronization based on the received OFDM symbol (received signal) to ensure an appropriate timing. The guard interval removing unit 404 removes the guard interval from the OFDM symbol and extracts the subsequent part. The FFT unit 406 outputs information associated with each subcarrier by performing a fast Fourier transform. Thereafter, processing is performed to restore the transmitted information through elements not shown.

  On the other hand, the two-dimensional despreading unit 410 despreads the parallel bitstreams after the Fourier transform by multiplying them by an appropriate spreading code. In this case, the spreading factor and channel type determination unit 408 provides information regarding the spreading factor of the spreading code to the two-dimensional despreading unit 410 and also determines what the code spread information is. For example, only the pilot channel of the control channels may be code-spread, and the other control channels may not be spread and transmitted in a different manner. The spreading factor, channel type information, and the like are obtained from the wireless transmission device.

  FIG. 5 shows a more detailed block diagram of the two-dimensional despreading unit 410. As shown in the figure, the two-dimensional despreading unit 410 is an element for performing despreading by the MC-CDMA system, and includes a spreading code generating unit 502, a spreading code multiplying unit 504, and a symbol combining unit 506. . For example, several subcarrier (Nc) bit streams obtained from the FFT unit 406 are provided to one input of a plurality of spreading code multiplication units 504. The other input of the spread code multiplication unit 504 is given the spread code from the spread code generation unit 502. The spreading code multiplication unit 504 extracts the control bitstream by multiplying the bitstream and the spreading code and performing despreading. Each symbol combining unit 506 combines, for example, a predetermined number of bit streams (SF) corresponding to the spreading factor into one bit stream. Thereafter, the control channel is restored through an element (not shown).

  With reference to FIG. 9, the multiplexing of the control channel and the information channel and the separation thereof in this embodiment will be further described. In this embodiment, the information channel is an information bit stream included in a normal OFDM symbol, and the control channel is a control bit stream code-spread by the MC-CDMA system. These are added by the control channel multiplexer 212 (step 904). The signal after the addition is then modulated by IFFT section 214, and after being added with a guard interval, it is wirelessly transmitted as an OFDM symbol (step 906). Since the control channel is code-spread, the spectrum in the frequency domain is as shown in FIG. In this respect, it is greatly different from that shown in FIG.

The wireless reception device identifies the control channel and the information channel from the received signal and restores their contents (step 908). When the information channel is restored by the wireless receiver, the control channel is treated as noise. As shown in FIG. 6A, this noise has a low amplitude level over a wide frequency range, and does not prevent the information channel from being restored. In other words, the spreading factor / amplitude determination unit 216 determines the code spreading factor SF and the amplitude A _control so that the control channel has noise that does not hinder the restoration of the information channel, and the determined content is the spreading factor control unit. 218 and the amplitude control unit 220 are notified, and the code spreading factor SF and the amplitude A _control (or power) are appropriately adjusted. Information related to the spreading factor and the like may be notified to the radio reception apparatus by a non-coded control channel such as a broadcast channel, a part of the information channel, or the like, but may be notified by other methods. This is because the information necessary for restoring the transmitted content only needs to be usable by the wireless reception device.

  The control channel is continuously inserted over the entire frequency domain. For this reason, it is possible to accurately follow a sudden amplitude level change and fading on the frequency axis in all sections. Furthermore, since the control channel and the information channel are distinguished depending on whether or not they are encoded, it is not necessary to allocate dedicated resources to the control channel. Therefore, it is possible to assign resources that have been uniformly assigned to the control channel in the past to information channels. Of the control channels, only the pilot channel, for example, can be code spread.

  FIG. 7 is a partial block diagram of another wireless transmission device according to an embodiment of the present invention. The wireless transmission device 700 includes a channel encoding unit 702, a data modulation unit 704, a serial-parallel conversion unit (S / P conversion unit) 706, a fast inverse Fourier transform unit (IFFT) 708, a spreading unit 710, and a control In addition to the channel multiplexing unit 712, a spreading factor and amplitude determination unit 716, a spreading factor control unit 718, an amplitude control unit 720, and a multiplication unit 722 are included.

  The channel encoding unit 702 receives an information bit stream representing the content that the user intends to transmit as an OFDM symbol, and performs appropriate encoding. This encoding may be error correction encoding such as convolutional encoding or turbo encoding.

  The data modulation unit 704 modulates an appropriately encoded information bit stream using a predetermined modulation method. The serial / parallel converter 706 converts the modulated series of information bit streams into a parallel bit stream having Nc subcarriers, for example. These parallel information bit streams are input to the IFFT unit 708.

  The IFFT unit 708 converts information carried on each subcarrier into a time-domain information bitstream by performing fast inverse Fourier transform on the bitstream of several subcarriers (Nc). This information bit stream is input to the control channel multiplexing unit 712.

  On the other hand, the spreading unit 710 multiplies the control bitstream by a spreading code. The spreading unit 710 is an element for performing code spreading by a direct sequence CDMA (DS-CDMA) system, and includes a spreading code generation unit (not shown) and a spreading code multiplication unit. The code-spread control bit stream is provided to the control channel multiplexing unit 712 via a multiplication unit 722 for appropriately adjusting the amplitude level.

  The spreading factor and amplitude determination unit 716 acquires, measures, or estimates information related to signal quality (for example, reception quality information) required in the current wireless communication, the amount of interference of the information channel with respect to the control channel, and the like. These pieces of information are given to the spreading factor control unit 718 and the amplitude control unit 720. The spreading factor and amplitude determination unit 716 may include the same elements as described with reference to FIG. However, the present embodiment is different in that the control channel is continuously inserted not in the frequency axis direction but in the time axis direction.

  Based on the information, the spreading factor control unit 718 gives the spreading unit 710 a control signal for setting an appropriate code spreading factor. Based on the information, the amplitude control unit 720 gives a control signal for appropriately setting the amplitude level or power to the multiplication unit 722.

  The control channel multiplexing unit 712 adds the information bit stream from the IFFT unit 708 and the code bit-diffused control bit stream, and outputs one bit stream. That is, this bit stream is obtained by multiplexing a control bit stream subjected to code spreading on an information bit stream. A guard interval is added to the bit stream thus created to create an OFDM symbol, which is wirelessly transmitted through a wireless unit including a band limiting processing unit, a frequency conversion unit, a power amplification unit, and the like (not shown).

  FIG. 8 shows a partial block diagram of another radio receiving apparatus according to an embodiment of the present invention. Radio receiving apparatus 800 includes symbol timing synchronization section 802, guard interval removal section 804, fast Fourier transform section 806, rake combining section 808, path search section 810, channel estimation section 812, A spreading factor and channel type determination unit 814;

  The symbol timing synchronization unit 802 performs synchronization based on the received OFDM symbol (reception signal) to ensure an appropriate timing. The guard interval removing unit 804 removes the guard interval from the OFDM symbol and extracts the subsequent part. The FFT unit 806 outputs information transmitted for each subcarrier by performing fast Fourier transform. Thereafter, processing is performed to restore the transmitted information through elements not shown.

  On the other hand, the received OFDM symbol is input to the rake combining unit 808 and also to the path search unit 810. The path search unit 810 detects the timing of the multipath propagation path (path) regarding the received OFDM symbol. The channel estimation unit 812 gives a control signal for compensating for fading fluctuation regarding each path to the rake synthesis unit 808. The spreading factor and channel type determination unit 814 provides information on the spreading factor of the spreading code to the rake combining unit 808 and also determines what the code spread information is. The rake combining unit 808 combines the signals from the respective paths while compensating for the fading effect for each path based on the control signal or the like, thereby obtaining a control bit stream related to the appropriately despread control channel. Based on this control bit stream, the transmitted control channel is restored through elements not shown.

  Next, multiplexing of the control channel and information channel and their separation in this embodiment will be further described. The basic processing procedure is the same as that described with reference to FIG. Also in this embodiment, the information channel is an information bit stream included in a normal OFDM symbol, but the control channel is a control bit stream code-spread by the DS-CDMA system. They are added by the control channel multiplexer 712, added with a guard interval, and wirelessly transmitted as an OFDM symbol. Since the control channel is code-spread in the time domain, the spectrum in the time domain is as shown in FIG. In this respect, it is greatly different from that shown in FIG.

  When the information channel is restored by the wireless receiver, the control channel is treated as noise. As shown in FIG. 6B, this noise has a low amplitude level over the entire frame period and does not hinder the restoration of the information channel. In other words, the spreading factor control unit 718 and the amplitude control unit 720 appropriately adjust the code spreading factor and the amplitude (or power) so that the control channel becomes noise that does not hinder the restoration of the information channel. .

  In the present embodiment, the control channel is continuously inserted over the entire time domain (note that in the first embodiment, the control channel is continuously inserted in the frequency domain). For this reason, it is possible to accurately follow sudden amplitude level changes and fading on the time axis in all sections. Furthermore, since the control channel and the information channel are distinguished depending on whether or not they are encoded, it is not necessary to allocate dedicated resources to the control channel. Therefore, it is possible to assign resources that have been uniformly assigned to the control channel as in the prior art to information channels. Of the control channels, only the pilot channel, for example, can be code spread.

  By the way, regarding both the embodiment in which the control channel is spread in the frequency domain and the embodiment in which the control channel is spread in the time domain, it is technically possible to code spread the information channel in addition to code spreading the control channel. Is possible. Such an approach is advantageous when a large number of cells are adjacent and provide a wide service area. In the CDMA system, all signals related to other than itself become noise, and this noise mainly includes own cell interference and other cell interference. When the information channel is code-spread, interference with other cells can be effectively suppressed when extracting the information channel. Therefore, it is advantageous to encode the information channel in such a communication environment.

  However, there may be a communication environment in which it is not necessary to consider other cell interference. For example, this is a case where a cell or a communicable area is provided in a spot manner like an isolated cell. In such a communication environment, if the information channel is coded, the own-cell interference increases due to interference between the spreading codes of the control channel and the information channel, and the resources of the information channel are restricted on the contrary. There is a risk that it will end up. In such a case, it is advantageous to transmit the information channel as a normal OFDM symbol without code spreading the information channel. Therefore, the wireless communication system in which the control channel is spread but the information channel is not spread is particularly advantageous when an isolated cell is formed. For example, the wireless transmitter according to the present invention is provided in a wireless base station of an isolated cell, and a useful application such as multiplexing a pilot channel on an information channel while code spreading is conceivable.

It is a conceptual diagram which shows the relationship between an information channel and a control channel. 1 shows a block diagram of a wireless transmission device according to an embodiment of the present invention. FIG. The block diagram of a two-dimensional spreading | diffusion part is shown. 1 shows a block diagram of a wireless receiver according to an embodiment of the present invention. FIG. The block diagram of a two-dimensional despreading part is shown. It is a conceptual diagram which shows the relationship between the information channel and control channel in one Example of this invention. 1 shows a block diagram of a wireless transmission device according to an embodiment of the present invention. FIG. 1 shows a block diagram of a wireless receiver according to an embodiment of the present invention. FIG. 2 shows a flowchart of a wireless communication method according to an embodiment of the present invention. The block diagram of a spreading | diffusion rate and an amplitude judgment part is shown. It is a figure which shows the relationship between the transmission power of the information channel and the control channel before and behind spreading | diffusion.

Explanation of symbols

200 wireless transmission apparatus; 202 channel encoding unit; 204 data modulation unit; 206, 208 serial-parallel conversion unit; 210 two-dimensional spreading unit; 212 control channel multiplexing unit; 214 IFFT unit; 216 spreading factor and amplitude judging unit; Rate control unit; 220 amplitude control unit; 222 multiplication unit;
302 symbol duplicating unit; 304 spreading code generating unit; 306 spreading code multiplying unit;
400 radio receiver; 402 symbol timing; 404 guard interval removal unit; 406 FFT unit; 408 spreading factor and channel type determination unit; 410 two-dimensional despreading unit;
502 spreading code generation unit; 504 spreading code multiplication unit; 506 symbol synthesis unit 700 wireless transmission device; 702 channel coding unit; 704 data modulation unit; 706 serial-parallel conversion unit; 706 IFFT unit; 710 spreading unit; 716 spreading factor and amplitude determination unit; 718 spreading factor control unit; 720 amplitude control unit; 722 multiplication unit;
802 symbol timing; 804 guard interval removal unit; 806 FFT unit; 808 rake combining unit; 810 path search unit; 812 channel estimation unit; 814 spreading factor and channel type determination unit;
1002 Control channel transmission power determination unit; 1004 Spreading factor determination unit; 1006 Amplitude determination unit

Claims (8)

An orthogonal frequency division multiplexing (OFDM) wireless communication system comprising a wireless transmission device and a wireless reception device, wherein the wireless transmission device comprises:
A determination unit that determines a spreading factor and an amplitude set for the control channel based on the quality information of the transmission signal or the amount of interference from the information data;
Means for multiplexing an information channel that is not code spread and a control channel that is code spread based on a determined spreading factor and amplitude;
Means for modulating and wirelessly transmitting a multiplexed signal by OFDM;
The wireless receiving device comprises:
Demodulating the received OFDM symbol, e Bei means for extracting the control channel by despreading,
The spreading factor and the transmission rate so that the ratio between the transmission power per unit band or unit time of the control channel after spreading and the transmission power per unit band or unit time of the information channel does not exceed a predetermined threshold. A wireless communication system, wherein the amplitude is set . A wireless transmission device for performing orthogonal frequency division multiplexing (OFDM) wireless communication,
A determination unit that determines a spreading factor and an amplitude set for the control channel based on the quality information of the transmission signal or the amount of interference from the information data;
Means for multiplexing an information channel that is not code spread and a control channel that is code spread based on a determined spreading factor and amplitude;
The multiplexed signal is modulated by the OFDM method, e Bei and means for wireless transmission, and transmission power per or unit time per unit bandwidth of the control channel after spreading, or unit time per unit bandwidth of the information channel The wireless transmission apparatus according to claim 1, wherein the spreading factor and the amplitude are set so that a ratio with a per unit transmission power does not exceed a predetermined threshold .   The radio transmission apparatus according to claim 2, wherein the control channel is code-spread by a multi-carrier code division multiple access (MC-CDMA) system.   The radio transmission apparatus according to claim 2, wherein the control channel is code-spread by a direct sequence code division multiple access (DS-CDMA) system.   The radio communication apparatus according to claim 2, further comprising a radio base station of an isolated cell. The radio transmission apparatus according to claim 2 , wherein the amplitude of the control channel is derived from a square root of transmission power per unit band or unit time of the spread control channel . An orthogonal frequency division multiplexing (OFDM) wireless communication method,
Determining a spreading factor and amplitude for the control channel based on the quality information of the transmission signal or the amount of interference from the information data;
Multiplexing an information channel that is not code spread and a control channel that is code spread based on the determined spreading factor and amplitude;
Modulating the multiplexed signal by OFDM and wirelessly transmitting;
And a step of extracting the control channel by demodulating and despreading a signal received by the wireless reception device , and transmitting power per unit band or unit time of the control channel after spreading. The wireless communication method , wherein the spreading factor and the amplitude are set so that a ratio of the transmission power per unit band or unit time of the information channel does not exceed a predetermined threshold . The amplitude of the control channel is derived from the square root of the transmission power per unit band or unit time after spreading.
  The wireless communication method according to claim 7.

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