JP2001111519A - Transmitter-receiver, and transmitting and receiving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To hold both transmission efficiency and error rate characteristics in satisfactory conditions, even when a delayed wave exists. SOLUTION: A control part 106 outputs a control signal, that a guard section with first section length or second section length is used, according to the number of multiplexed signals to a selector 107. A signal for indicating first section length and a signal to indicate the second section length are inputted in the selector 107. The selector 107 outputs either of the signals to a guard section inserting part 105 according to the control signal. The guard section inserting part 105 inserts the guard section with the length according to the signal from the selector 107 with respect to a signal subjected to IFFT processing. The guard section with the same length as the guard section inserted by the guard section inserting part 105 is removed from a received signal from an antenna 108 by a guard section removing part 110.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmitting / receiving apparatus used in a mobile communication system, and more particularly, to a CDMA (CDM).
Ode Division Multiple Acc
ESS) OFDM (Orthogonal Fr)
EQEQUENCY DIVISION MULTIPLE
xing) and a transmission / reception apparatus of the OFDM-CDMA scheme which combine the schemes.

[0002]

2. Description of the Related Art In recent years, studies have been actively conducted on a transmission / reception apparatus of the OFDM-CDMA system in which the OFDM system is combined with the CDMA system. Hereinafter, the conventional OFDM
-A CDMA transmitting / receiving apparatus will be described with reference to FIG. FIG. 5 is a block diagram showing a configuration of a conventional OFDM-CDMA transmission / reception apparatus.

In the transmitting system of the transmitting / receiving device shown in FIG.
The n transmission signal of the transmission signal 1 transmitted signal n is the respective diffusion portions 501a ₁ ~ spreading unit 501a _n, spreading code 1
~ Spreading process using spreading code n. The spreading ratio of each spreading code is k.

[0006] The n transmission signals subjected to the spreading process are code-division multiplexed by an adder 502. Code-division multiplexed (one series) signals are serial-parallel (Seria)
1-Parallel (S / P) conversion section 503
The signal is converted into a plurality of signals. Here, the code-division multiplexed signal is used for each spread signal (chip), that is, for the first signal.
It is decomposed into a chip to a k-th chip. A plurality of series of signals of the first chip to the k-th chip are sent to IFFT section 504.

[0005] IFFT section 504 performs an inverse Fourier transform (IFFT) process on a plurality of series of signals. That is, the signals of the first chip to the k-th chip are allocated to subcarriers prepared for the spreading ratio (k) and frequency division multiplexed.

More specifically, as shown in FIG. 6, code division multiplexed first signals of transmission signals 1 to n which are subjected to spreading processing are arranged on subcarrier 1, and subcarrier k is arranged on subcarrier k. , Code-division multiplexed transmission signals 1 to
The k-th chip of the transmission signal n is arranged.

In FIG. 5, the signal after the IFFT processing is
A guard section is inserted by guard section insertion section 505. FIG. 7 shows a format of a signal generated by inserting the guard section. The format of the OFDM signal shown in FIG. 7 is, for example, the waveform 703 of the terminal side 1/4 in the signal (effective symbol 702) after the IFFT processing.
Are inserted at the tip of the effective symbol 702.

[0008] By inserting the guard interval as described above, even if a delay wave is present on the communication partner side, if the delay time of the delay wave is shorter than the guard interval, a certain OFDM signal is generated. Does not include a component of the effective symbol section in the previous OFDM signal. That is, it is possible to suppress intersymbol interference between a certain OFDM signal and a previous OFDM signal.

In FIG. 5, a signal into which a guard section is inserted by guard section insertion section 505 is transmitted to a communication partner via antenna 506.

On the other hand, the signal transmitted by the communication partner is received by the transmitting / receiving device shown in FIG. Note that the communication partner includes a transmission device similar to that described above, and transmits a signal on which the above-described processing has been performed.

In the receiving system, a signal (received signal) received via antenna 506 is transmitted to guard interval removing section 50.
7, the guard interval inserted by the communication partner is removed.

The received signal from which the guard section has been removed is FF
The signal transmitted by each subcarrier is extracted by T section 508. Signals transmitted by each subcarrier, by respective channel compensation unit 509a ₁ ~ channel compensation unit 509a _k, after channel compensation process for fading or the like has been made, a parallel-to-serial (Paral
ll-Serial (P / S) conversion section 510.

The P / S converter 510 includes a transmission path compensator 5
09a ₁ ~ a plurality of sequences of signals from the channel compensation unit 509a _k is converted to a sequence of signals. Here, at time t ₁ , the signal from the transmission path compensator 509a ₁ , that is, the first chip in the transmission signal 1 to the transmission signal n after the spread processing that is code division multiplexed by the communication partner is output,
At time t _k, the signal from the channel compensation unit 509a _k, i.e., the k chip in the transmission signal 1 transmitted signal n after the code division multiplexed spreading processing is output to the communication partner.

One series of signals from P / S conversion section 510 is subjected to despreading processing by despreading sections 511a ₁ to 511an using spreading codes 1 to _n , respectively. As a result, despreading sections 511a ₁ ~ despreader 51
The 1a _n, each demodulated signal 1 demodulated signal n is taken out.

Here, a case has been described in which communication is performed for transmission signals for n users. However, transmission signals corresponding to the number of users to be transmitted are spread and then code division multiplexed. You. That is, the adder 5
02 (hereinafter, referred to as “multiplexed signal number”) corresponds to the number of users to be transmitted.

[0016]

However, in the conventional OFDM-CDMA transmitting / receiving apparatus,
There are the following problems. That is, as described above, in order to suppress intersymbol interference due to a previous OFDM signal in a certain OFDM signal, the length of the guard section 701 in the OFDM signal format shown in FIG. Also need to be set long.

However, since this guard section is not used for the FFT processing in the receiving system, the transmission efficiency is reduced by the guard section inserted into the OFDM signal format. For example, when the guard section length is set to 1/4 of the effective symbol length, the transmission efficiency is:
This is 20% lower than the case where no guard section is inserted.

In order to prevent the transmission efficiency from being lowered, there is a method of setting the guard interval short. However, if the delay time of the delayed wave is longer than the short guard interval length, the influence of inter-symbol interference due to the previous OFDM signal in a certain OFDM signal increases, and the error rate characteristics of the demodulated signal deteriorate. become.

As described above, the conventional OFDM-CDMA
In the transmission / reception apparatus of the system, there is a problem that when a delayed wave is present, either the transmission efficiency or the error rate characteristic deteriorates.

The present invention has been made in view of the above, and an object of the present invention is to provide a transmission / reception apparatus that maintains good transmission efficiency and error rate characteristics even when a delayed wave exists.

[0021]

According to the present invention, there is provided a transmitting apparatus capable of executing a spreading process using different spreading codes for a plurality of transmission signals, and a spreading process performed by the spreading unit. OFDM signal generation means for generating an OFDM signal by code division multiplexing and frequency division multiplexing of each transmitted signal, and a guard interval having a length corresponding to the number of transmission signals spread by the spreading means. And guard interval insertion means for inserting the signal into a signal.

According to the present invention, the communication partner side changes the length of the guard interval to be inserted into the OFDM signal according to the number of spread-processed transmission signals, that is, the number of multiplexed signals. Since the influence of intersymbol interference due to the previous OFDM signal can be reduced, the error rate characteristics of the demodulated signal can be kept good. In other words, when the number of multiplexed signals is small, the OFF is set within a range where the error rate characteristic of the demodulated signal on the communication partner side is not deteriorated.
When the length of the guard interval to be inserted into the DM signal is reduced and the number of multiplexed signals is large, the guard interval to be inserted into the OFDM signal is adjusted so that the error rate characteristic of the demodulated signal on the communication partner side becomes a desired characteristic. By increasing the length,
Both transmission efficiency and error rate characteristics can be kept good.

The receiving apparatus according to the present invention provides an OFD in which a guard section having a length corresponding to the number of spread-processed transmission signals is inserted.
It is characterized by comprising receiving means for receiving an M signal from a communication partner via a transmission path, and removing means for removing the guard interval from a received OFDM signal.

According to the present invention, since the guard interval is removed from the OFDM signal in which the guard interval according to the number of multiplexed signals is inserted by the communication partner, the influence of intersymbol interference due to the previous OFDM signal in a certain OFDM signal is reduced. Therefore, the error rate characteristics of the demodulated signal can be kept good.

[0025] A communication terminal device according to the present invention includes the above-mentioned transmitting device and the above-mentioned receiving device.

According to the present invention, since a transmission device and a reception device capable of maintaining good transmission efficiency and good error rate characteristics are mounted, good and efficient communication can be performed.

[0027] A base station apparatus according to the present invention includes the above-mentioned transmitting apparatus and the above-mentioned receiving apparatus.

According to the present invention, since a transmitting device and a receiving device capable of maintaining good transmission efficiency and good error rate characteristics are mounted, good and efficient communication can be performed.

A transmitting / receiving method according to the present invention comprises: a spreading step of performing spreading processing using different spreading codes on a plurality of transmission signals to be transmitted; OFDM by multiplexing
Generating a signal, inserting a guard interval having a length corresponding to the number of spread-processed transmission signals into the OFDM signal, and transmitting the OFDM signal with the guard interval inserted to a transmission path. A receiving step of receiving the OFDM signal with the guard section inserted through the transmission path, and a removing step of removing the guard section from the received OFDM signal. .

According to the present invention, in the transmitting step, according to the number of transmission signals subjected to spread processing, that is, the number of multiplexed signals,
By changing the length of the guard interval inserted in the OFDM signal, the influence of intersymbol interference due to the previous OFDM signal in a certain OFDM signal can be reduced in the receiving process, so that the error rate characteristics of the demodulated signal can be kept good. it can.

[0031]

DETAILED DESCRIPTION OF THE INVENTION The present inventor has found that the relationship between the number of multiplexed signals and intersymbol interference, that is, as the number of multiplexed signals increases, the influence of intersymbol interference due to a previous OFDM signal on a given OFDM signal increases. Conversely, as the number of multiplexed signals decreases, attention is paid to the fact that the influence of the intersymbol interference is reduced.If the number of multiplexed signals is small, even if the guard section length is shorter than the delay time of the delay wave, Since the influence of intersymbol interference is small, it has been found that the deterioration of the error rate characteristic in the demodulated signal can be reduced, and the present invention has been made.

The gist of the present invention is that the number of multiplexed signals is
This is to change the length of the guard section inserted in the FDM signal.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment 1) FIG. 1 is a block diagram showing a configuration of a transmitting / receiving apparatus according to Embodiment 1 of the present invention. In this embodiment, a case will be described where the total number of transmission signals of communicable users is n, for example.

[0035] If the number i.e. multiplex signal number of the transmission signal of the user to be transmitted is n, the transmission signal 1 transmitted signal n are each the spreading unit 101a ₁ ~ spreading unit 101a _n, spreading code 1 After being spread using the spreading code n, it is sent to the adding section 102. Here, the spreading ratio of each spreading code is k.

When the number of transmission signals of the user to be transmitted is smaller than n, for example, when the number of multiplexed signals is n / 2, transmission signals 1 to n / 2 are respectively spread out by spreading section 101a _1. after being spread processing is input to any of the ~ spreading section 101a _n, is sent to the adder 102.

[0037] The adder unit 102, the transmission signal after the spreading process from spreading portions 101a ₁ ~ spreading unit 101a _n is code division multiplexed. The code-division multiplexed signal is sent to S / P conversion section 103.

In the S / P conversion section 103, the code-division multiplexed (one series) signal is converted into a plurality of series signals. Here, the code-division multiplexed signal is decomposed for each spread signal (chip), that is, a first chip to a k-th chip. The signals of a plurality of streams of the first chip to the k-th chip are sent to IFFT section 104.

In the IFFT section 104, an inverse Fourier transform (IFFT) process is performed on a plurality of series of signals. That is, the signals of the first chip to the k-th chip are allocated to subcarriers prepared for the spreading ratio (k) and frequency division multiplexed. The frequency division multiplexed signal is sent to guard interval insertion section 105.

The guard interval insertion section 105 inserts a guard interval having a length corresponding to the number of multiplexed signals into the frequency division multiplexed signal. The method of inserting the guard section will be specifically described.

It is possible to prepare a plurality of guard sections, but here, for the sake of simplicity, the case of preparing two types will be described. The two types of guard section lengths, that is, the first section length and the second section length are, for example, １ ／ and ８ of the effective symbol length, respectively.

When the number of multiplexed signals is larger than a threshold value (for example, n / 2), the control unit 106 outputs a control signal to the selector 107 to use the guard interval having the first interval length. Conversely, when the number of multiplexed signals is equal to or less than the threshold, the control unit 106 outputs a control signal to the selector 107 to the effect that a guard section having the second section length is used. The threshold is set in consideration of the relationship between the number of multiplexed signals and the error rate characteristics of the demodulated signal on the communication partner side.

Further, the first section length and the second section length are:
The threshold is set in consideration of the error rate characteristics of the demodulated signal on the communication partner side and the like. 1st section length and 2nd section
The section length is set so that desired characteristics can be obtained when the number of multiplexed signals is larger than the threshold and when the number of multiplexed signals is equal to or smaller than the threshold.

The selector 107 receives a signal indicating the first section length and a signal indicating the second section length. Further, the selector 107 outputs a signal indicating the first section length or a second section length as a signal to be output to the guard section insertion section 105.
One of the signals indicating the section length is selected according to a control signal from the control unit 106. The selected signal is output to guard interval insertion section 105.

The guard section insertion section 105 inserts a guard section having a length corresponding to the signal indicating the first section length or the signal indicating the second section length from the selector 107 into the frequency division multiplexed signal. You. The format of an OFDM signal generated by inserting such a guard section will be described with reference to FIGS.

FIG. 2 is a schematic diagram showing an example of the format of an OFDM signal in which a guard section having a first section length is inserted in the transmitting and receiving apparatus according to the first embodiment of the present invention. FIG. OFDM in which guard section of second section length is inserted in transmission / reception apparatus according to Embodiment 1
FIG. 3 is a schematic diagram illustrating an example of a signal format.

The format of the OFDM signal shown in FIG. 2 is such that the waveform 203 on the terminal side of the signal (effective symbol 202) after the IFFT processing is the effective symbol 202.
It has been inserted at the tip of the. The format of the OFDM signal shown in FIG. 3 is such that the waveform 303 on the terminal side ８ of the signal (effective symbol 302) after the IFFT processing is inserted at the leading end of the effective symbol 302.

Here, the guard section insertion timing in guard section insertion section 105 will be described with reference to FIG. 4 by taking as an example a case where a guard section having a first section length is inserted into a signal after IFFT processing. FIG. 4 is a schematic diagram showing a timing of inserting a guard section having a first section length into a signal after the IFFT processing in the transmitting and receiving apparatus according to the first embodiment of the present invention.

In FIG. 4, (a) shows the IFFT unit 1
04 shows the signal after IFFT processing output from
(B) shows a case where the guard interval insertion unit 10
5 shows a signal indicating the first section length, which is output to (c).
3 shows a signal output from the guard interval insertion section 105 and into which a guard interval has been inserted.

As shown in (b), the signal indicating the first section length is turned “ON” at the time when the end on the terminal side １ ／ of the signal after the IFFT processing is output, and the signal after the IFFT processing is output. Is set to "OFF" at the time when the end of "."

In the guard section insertion section 105 which receives such a signal of the first section length, first, the signal (effective symbol 202) after the IFFT processing from the IFFT section 104 is held, while the first section length is changed. Between the time when the indicated signal is turned “ON” and the time when the signal is turned “OFF”,
The signal from the FT unit 104 is output, and the retained effective symbol 202 is output from the time when the signal indicating the first section length becomes “OFF”.

As a result, an OFDM signal as shown in (c), that is, an OFDM signal shown in FIG. 2 is output from guard interval insertion section 105. Note that here, the first
The timing of inserting the guard interval of the section length has been described, except for the timing of inserting the guard section of the second section length except that the signal indicating the second section length is used instead of the signal indicating the first section length. This is the same as the case where the guard section having the first section length is inserted.

Referring to FIG. 1 again, the signal after the IFFT processing in which the guard section is inserted is transmitted to the communication partner via the antenna 108.

On the other hand, the signal transmitted by the communication partner is received by the antenna 108 via the transmission path. In addition,
The communication partner includes a transmission system device similar to that described above, and transmits a signal on which the above-described processing has been performed.

In the receiving system, a signal (received signal) received via the antenna 108 is transmitted to the guard interval removing unit 11.
By 0, the guard section inserted by the communication partner is removed. The guard section removing method by the guard section removing unit 110 will be specifically described.

When the guard interval having the first interval length is inserted into the OFDM signal by the communication partner, the control unit 106
In response to the selector 109, the first
A control signal for removing the guard section having the section length is output. Conversely, when a guard interval having the second interval length is inserted into the OFDM signal by the communication partner, the control unit 106 removes the guard interval having the second interval length for each OFDM signal from the selector 109. Is output.

In order to recognize the guard section length used by the communication partner, the control unit 106 may adopt, for example, the following method. That is, for example,
The communication partner includes a signal for notifying the guard interval length used in the transmission signal, and the control unit 106 controls the guard interval length used by the communication partner based on the included signal in the received signal. It is a way to recognize.
Further, since the guard section length is set according to the number of multiplexed signals as described above, the control unit 106 recognizes the guard section length used by the communication partner by recognizing the number of multiplexed signals. can do.

The selector 109 receives a signal indicating the first section length and a signal indicating the second section length. Further, in the selector 109, a signal indicating the first section length or a second section length is output as a signal to be output to the guard section removing section 110.
One of the signals indicating the section length is selected according to a control signal from the control unit 106. The selected signal is output to guard interval elimination section 110.

In the guard section removing section 110, the selector 1
Based on the signal indicating the first section length from 09 or the signal indicating the second section length, the guard section is removed from the received signal from the antenna 108 for each OFDM signal. That is, the guard section removing section 110 sets the received signal from the antenna 108 for each OFDM signal by a length corresponding to the signal indicating the first section length or the signal indicating the second section length from the selector 109 from the front end. Are removed. The received signal from which the guard section has been removed is output to the FFT unit 11.
1 is output.

The received signal from which the guard section has been removed is FF
The signal transmitted by each subcarrier is extracted by T section 111. Signals transmitted by each subcarrier, by respective channel compensation unit 112a ₁ ~ channel compensation unit 112a _k, after phase compensation process for fading or the like is made and sent to the P / S conversion unit 113.

In the P / S converter 113, the transmission path compensator 1
Signals a plurality of sequences from 12a ₁ ~ channel compensation unit 112a _k is converted to a sequence of signals. Here, at time t ₁ , the signal from the transmission path compensator 112a ₁ , that is, the first chip in the transmission signal 1 to the transmission signal n after the spread processing that is code division multiplexed by the communication partner is output,
At time t _k, the signal from the channel compensation unit 112a _k, i.e., the k chip in the transmission signal 1 transmitted signal n after the code division multiplexed spreading processing is output to the communication partner.

One series of signals from P / S conversion section 113 are subjected to despreading processing by despreading sections 114a ₁ to 114an using spreading codes 1 to _n , respectively. As a result, the despreading sections 114a ₁ to 11d
By 4a _n, each demodulated signal 1 demodulated signal n is taken out.

When the number of multiplexed signals is smaller than n, for example, when the number of multiplexed signals is n / 2, the despreading unit 1
14a n / 2 pieces of demodulated signal is of course the retrieved from n / 2 pieces of despreading sections of ₁ to despreading section 114a _n. That is, the same number of demodulated signals as the transmission signals multiplexed by the communication partner are extracted.

A communication partner is determined by a certain O in accordance with the number of multiplexed signals.
Since the length of the guard section inserted into the OFDM signal is changed so that the influence of intersymbol interference due to the previous OFDM signal on the FDM signal is reduced, the despreading unit 114a ₁
The error rate characteristic of the demodulated signal extracted by ~ despreader 114a _n is good in quality.

As described above, according to the present embodiment, by changing the length of a guard section inserted into an OFDM signal on the transmitting side according to the number of multiplexed signals, on the receiving side, a certain OFDM signal Since the influence of intersymbol interference due to the previous OFDM signal can be reduced, the error rate characteristics of the demodulated signal can be kept good.

That is, when the number of multiplexed signals is small,
As long as the error rate characteristic of the demodulated signal on the receiving side does not deteriorate, the length of the guard section inserted in the OFDM signal is reduced on the transmitting side, and when the number of multiplexed signals is large, the error rate characteristic of the demodulated signal on the receiving side is reduced. The length of the guard section to be inserted into the OFDM signal on the transmission side is increased such that the desired characteristics are obtained. As a result, it is possible to provide a transmission / reception apparatus that maintains both transmission efficiency and error rate characteristics.

In the present embodiment, the case has been described where the guard interval length is changed according to the number of multiplexed signals, but the present invention is not limited to this. The present invention is also applicable when the guard section length to be changed is three or more. In this case, since the guard section length can be changed in detail according to the number of multiplexed signals, it is possible to further improve the transmission efficiency while maintaining good error rate characteristics of the demodulated signal.

Further, in the present embodiment, a case has been described in which the length of a guard section inserted into an OFDM signal is changed according to the number of multiplexed signals, which is realized by the configuration shown in FIG. The present invention is not limited to this, and it goes without saying that the present invention is applicable to a case where the configuration shown in FIG. 1 is appropriately changed as long as the guard section length can be changed according to the number of multiplexed signals. .

Further, in the present embodiment, the case where the guard section length is changed according to the number of multiplexed signals has been described. However, the present invention is also applicable to the case where the guard section length is changed according to the following conditions. Applicable. That is, first, when transmitting a specific signal (for example, control information or retransmission information), the guard section length is increased. Second, when transmitting a specific packet (for example, a multicast packet), the guard section length is increased. Third, when the line quality is poor, the guard section length is increased.

The transmitting / receiving device according to the present invention can be mounted on a mobile station device or a base station device in a digital mobile communication system.

[0071]

As described above, according to the present invention,
Since the length of the guard interval to be inserted into the OFDM signal is changed according to the number of multiplexed signals, it is possible to provide a transmission / reception apparatus that maintains good transmission efficiency and error rate characteristics even when a delayed wave exists.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a transmitting and receiving apparatus according to a first embodiment of the present invention.

FIG. 2 is a schematic diagram showing a format of an OFDM signal in which a guard section having a first section length is inserted in the transmitting and receiving apparatus according to the first embodiment of the present invention;

FIG. 3 is a schematic diagram showing a format of an OFDM signal in which a guard section having a second section length is inserted in the transmitting and receiving apparatus according to the first embodiment of the present invention;

FIG. 4 is a schematic diagram showing a timing of inserting a guard section having a first section length into a signal after IFFT processing in the transmitting and receiving apparatus according to the first embodiment of the present invention;

FIG. 5 is a block diagram showing a configuration of a conventional OFDM-CDMA transmission / reception apparatus.

FIG. 6 is a schematic diagram showing a state of subcarriers in a conventional OFDM-CDMA transmission / reception apparatus.

FIG. 7 is a schematic diagram showing the format of an OFDM signal used in a conventional OFDM-CDMA transmission / reception apparatus.

[Explanation of symbols]

101a ₁ ~101a _n diffusion unit 102 adding unit 103 S / P conversion unit 104 IFFT unit 105 guard interval insertion unit 106 control unit 108 antenna 107, 109 selector 110 guard interval removal unit

Claims (5)

[Claims] 1. A spreading means capable of executing spreading processing using different spreading codes for a plurality of transmission signals, and code-division multiplexing each transmission signal spread by the spreading means to obtain a frequency. OF by dividing and multiplexing
An OFDM signal generating unit for generating a DM signal, and a guard interval inserting unit for inserting a guard interval having a length corresponding to the number of transmission signals spread by the spreading unit into the OFDM signal. Transmission device. 2. A receiving means for receiving, via a transmission path, an OFDM signal in which a guard interval having a length corresponding to the number of spread-processed transmission signals is inserted from a communication partner, and receiving the OFDM signal.
A receiver for removing the guard interval from a DM signal. 3. The transmission device according to claim 1, wherein
A communication terminal device comprising: the receiving device according to claim 1. 4. The transmission device according to claim 1, and a transmission device according to claim 2.
A base station apparatus, comprising: the receiving apparatus according to claim 1. 5. A spreading step of performing spreading processing using different spreading codes on a plurality of transmission signals to be transmitted, and OFDM by code division multiplexing and frequency division multiplexing of each of the spread transmission signals. Generating a signal, inserting a guard interval having a length corresponding to the number of spread-processed transmission signals into the OFDM signal, and transmitting the OFDM signal with the guard interval inserted to a transmission path. A receiving step of receiving the OFDM signal with the guard section inserted through the transmission path, and a removing step of removing the guard section from the received OFDM signal. Transmission / reception method.