JP2003244093A - Multicarrier modulation circuit and multicarrier demodulation circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multicarrier modulation circuit or the like capable of attaining communication in a single cell and a multi-cell without the need for using information under single cell/multi-cell environment and attaining aerial deployment depending on the improvement of a transmission rate. <P>SOLUTION: The multicarrier modulation circuit is configured to include: a first fallback control means; a modulation section control signal generating means for controlling a modulation section according to an output signal from the first fallback control means; a first data input output changeover means for changing input output orders of the subcarrier modulation signal according to an output signal from the generating means; a generating means for generating a plurality of spread codes by varying a spread rate of the spread codes; and a means for applying spreading and code multiplexing the output signal generated from the first data input output changeover means in a frequency axis direction and outputting the result to a multicarrier simultaneous modulation means, which are placed between the subcarrier modulation means and the multicarrier simultaneous modulation means. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a modulation circuit and a demodulation circuit for transmitting / receiving a multicarrier modulation signal in a digital radio communication system, and more particularly to an OFDM circuit.
(Orthogonal frequency div
Ion transmission multiplex) modulation system and one extension of this OFDM modulation system, which is multi-carrier CDMA in which spreading is performed before multi-carrier collective modulation.
(Code division multiple a
access method modulation circuit and demodulation circuit.

[0002]

2. Description of the Related Art A multi-carrier modulation system is a system for transmitting information using a plurality of subcarriers. In this system, the input data signal is QPSK (Quadra).
It is modulated for each subcarrier, such as true phase shift keying). A multicarrier modulation scheme in which the frequencies of subcarriers are orthogonal to each other is called an orthogonal multicarrier modulation scheme or orthogonal frequency division multiplexing (OFDM). Since OFDM is a modulation method that is not easily affected by multipath and is suitable for wideband transmission, it is widely applied in wireless communication systems in which multipath propagation poses a problem.

In a wireless communication system to which OFDM is applied, when wideband transmission is realized with a limited frequency, 1
The occupied bandwidth per carrier becomes large. Therefore, in this case, the frequency is insufficient. If this shortage is attempted to be solved by repeating the same frequency in neighboring cells, co-channel interference cannot be avoided. For example, CIR (Carrier to Int)
Under severe co-channel interference such as interference ratio) = OdB, the OFDM characteristics are significantly degraded.

As a method of reducing this co-channel interference, multi-carrier (Multi carrier) is used.
The r: MC) -CDMA system is known. This method is an extension of OFDM, and IFFT (Inv.
erse fast Fourier transform
By performing the spreading process in the frequency axis direction before the rotation, the error rate characteristic is improved against co-channel interference.

In MC-CDMA, a subcarrier signal after serial-parallel conversion is converted into a plurality of spreading factors (S) in the frequency axis direction.
precoding Factor (SF) Replicates over SF subcarriers. In MC-CDMA, the SF subcoded subcarrier signals are multiplied by a spreading code in the frequency axis direction. Then, a multicarrier modulation signal is generated for this spread subcarrier signal. Therefore, in MC-CDMA, the transmission rate is reduced to 1 / SF by the spreading process. In order to avoid this decrease, normally, in MC-CDMA, code spreading is performed in which a plurality of codes are simultaneously used in the own station, considering that spreading codes are orthogonal codes.

However, in the MC-CDMA system,
When the number of code multiplexes is increased, a correlation occurs between the spreading codes used in the own station due to multipath interference. Therefore, in the MC-CDMA system, a required CNR (Ca
or the required CIR increases.

[0007] Therefore, conventionally, in order to realize a high transmission rate in a single cell having one base station with a low CNR, OFDM is applied and a multi-cell environment in which multiple base stations exist and severe co-channel interference is present. Then, in order to realize communication in a low CIR environment, MC-CDMA with SF = 4 or more.
A multi-carrier modulation circuit and a multi-carrier demodulation circuit were applied (references: Sawahashi et al.,
"Variable spreading factor CO for broadband packet transmission
FDM, 2001 IEICE Basic and Boundary Society Conference, PA-4-1, 2001-9).

FIG. 11 is a block diagram of a conventional multicarrier modulation circuit. The encoding circuit 1 receives the data s1 and outputs the error correction encoded data s2. The subcarrier modulation circuit 2 receives the error correction coded data s2 as input, performs subcarrier modulation, and outputs a modulated signal s3.

A switching control signal s5 for OFDM and MC-CDMA is input to the spreading factor control signal generation circuit according to station placement information s4 indicating whether the environment is a single cell or a multi-cell environment. In addition, the spreading factor control signal generation circuit receives the delay dispersion estimation information s4, which is one of the indexes indicating the severity of multipath in the multi-cell environment, and outputs the control signal s5 that changes the SF value. In some cases.

The spread code generating circuit 4 selects the spread code according to the control information s5 and outputs the spread code s8. The serial-parallel conversion circuit 5 receives the modulation signal s3 and the control signal s5, performs serial-parallel conversion, and outputs a subcarrier signal s6. The subcarrier signal duplication circuit 6 receives the subcarrier signal s6 and the control signal s5, and generates a copy signal s7 of SF subcarrier signals. Multiplication circuit 7
Receives the copy signal s7 and the spreading code s8 and performs spreading processing in the frequency axis direction. Of course, when OFDM is selected as the transmission method in the single cell environment, the multiplication circuit 7 does not perform the spreading process.

The code multiplex circuit 8 receives the spread signal s9 and the control signal s5 and generates a code multiplex signal s10.
The IFFT circuit 9 receives the code-multiplexed signal s10, performs multi-carrier batch modulation, and multi-carrier signal s1.
1 is output. The parallel-serial conversion circuit 11 receives the multi-carrier signal s11 and the control signal s12 from the guard interval addition control circuit 10, performs time series conversion and adds a guard interval, and outputs a transmission signal s13.

FIG. 12 is a block diagram of a conventional multicarrier demodulation circuit. The serial-parallel conversion circuit 21 receives the reception signal s21 and outputs the parallel signal s22. F
The FT circuit 22 receives the parallel signal s22, performs multicarrier batch modulation, and outputs a subcarrier signal s23. Similar to the case of the modulation circuit shown in FIG. 11, the spreading factor control signal generation circuit 23 uses the OFDM,
The MC-CDMA switching control signal s5 is input. Further, the spreading factor control signal generation circuit 23 receives the delay dispersion estimation information s24 which is one of the indexes indicating the severity of multipath in the multi-cell environment, and outputs the control signal s25 for changing the value of SF. In some cases.

The spread code generating circuit 24 controls the control information s25.
The spread code is selected according to the above, and the spread code s26 is output. The multiplication circuit 25 receives the subcarrier signal s23 and the spreading code s26, performs despreading, and despreads the signal s2.
7 is output. Note that, as a matter of course, when OFDM is selected as the transmission method in the single cell environment, the multiplication circuit 25 does not perform the despreading process.

The adder circuit 26 receives the despread signal s26 and the control signal s25 as input and performs a combining process of SF subcarrier signals to generate a combined signal s28. The parallel-serial conversion circuit 27 receives the combined signal s28 and the control signal s25, performs parallel-serial conversion, and sequentially combines the combined signal s29.
Is output. The subcarrier demodulation circuit 28 uses the composite signal s
29 is demodulated to generate a demodulated data signal s30.
The decoding circuit 29 performs error correction coding processing on the demodulated data signal s30 to generate output data s31.

As described above, the conventional multi-carrier modulation circuit shown in FIG. 11 and the conventional multi-carrier demodulation circuit shown in FIG. 12 use information of a single cell or multi-cells to perform OFDM and MC-CDMA. Unique switching is performed for transmission / reception, and the SF is variable based on the delay dispersion value.

[0016]

However, the information of single cell or multi-cell is generally provided by the station location information. If the station information is not relied on, co-channel interference may exist even if it is determined to be a single cell (therefore, in the OFDM system,
Even if it is determined to be a multi-cell environment, co-channel interference does not exist depending on the area (for this reason, it is difficult to increase the transmission speed in the configuration using only MC-CDMA). In particular, in order to increase the transmission speed, it is effective to apply a modulation method having a large multivalue such as 16QAM or 64QAM to the subcarrier modulation, but in MC-CDMA, the orthogonality of the spreading code between the own signals is high. This is because the required CNR characteristics and the required CIR characteristics are greatly deteriorated due to the collapse in the multipath environment).

Therefore, the conventional multi-carrier modulation circuit and multi-carrier demodulation circuit are feasible when reliable station placement information can be obtained, but a certain frequency is used by different operators. In the case where it is difficult to obtain station placement information, there is a problem that the feasibility is low. In addition, the judgment of single cell or multi-cell,
A wireless LAN in which a user arbitrarily opens a base station is very difficult.

Further, the delay dispersion value always fluctuates when communication is performed for each packet at an arbitrary timing, not when communication is performed by forming a frame targeted by the conventional multicarrier modulation circuit and multicarrier demodulation circuit. Therefore, an error occurs in the estimation of the delay dispersion value. Therefore, when the conventional multi-carrier modulation circuit and multi-carrier demodulation circuit are used, there is a problem that throughput is lowered due to generation of unnecessary traffic in order to perform highly accurate estimation.

Further, in the conventional multi-carrier modulation circuit and multi-carrier demodulation circuit, the packet may not reach the receiver in the packet communication due to the above estimation error. In this case, it is necessary to operate the upper layer packet retransmission function according to an arbitrary algorithm. Therefore, in the conventional multi-carrier modulation circuit and multi-carrier demodulation circuit, there is a problem that the reduction of throughput is accelerated due to the operation of the retransmission function.

On the other hand, in a wireless LAN environment, estimation of the delay dispersion value in the slave unit is not desirable because it leads to an increase in circuit scale. Further, it is not desirable that the base station estimates the delay dispersion value for each slave unit to which it belongs and makes the SF variable, because this leads to an increase in the circuit scale.

Therefore, in view of the above situation, the present invention can be realized without using the information of the single cell or multi-cell environment.
Enables single-cell and multi-cell communication, and
An object of the present invention is to provide a multi-carrier modulation circuit and a multi-carrier demodulation circuit that can be expanded in a plane by improving the transmission speed.

[0022]

According to the present invention, the above problems can be solved by the means described in the claims. That is, the invention according to claim 1 is: encoding means for performing error correction encoding of input data; and subcarrier modulating means for performing subcarrier modulation on the encoded data output from the encoding means, Multi-carrier batch modulation means for performing multi-carrier batch modulation on the sub-carrier modulation signal output from the sub-carrier modulation means, and guard for receiving an output signal of the multi-carrier batch modulation means and performing additional control of guard intervals Based on the output signal from the interval addition control means, the output signal of the multicarrier batch modulation means is output in time series, a parallel-serial conversion means for generating a transmission signal, a multicarrier modulation circuit comprising:

According to a first fallback control means for inputting a signal indicating a line state between the subcarrier modulation means and the multicarrier batch modulation means, and an output signal of the first fallback control means, Modulation section control signal generation means for controlling the modulation section, first data input / output switching means for switching the input / output order of the subcarrier modulation signal according to the output signal of the modulation section control signal generation means, and the modulation section According to the output signal of the control signal generating means, the spreading factor of the spreading code for spreading in the frequency axis direction is variable, and a spreading code generating means capable of generating a plurality of spreading codes used for code multiplexing,

In accordance with the output signal of the modulation section control signal generating means, the spreading code generated by the spreading code generating means is used for the output signal of the first data input / output switching means in the frequency axis direction. A multi-carrier modulation circuit comprising: a spreading factor / code multiplex number variable spreading unit having a variable spreading factor and number of code multiplexes, which performs spreading and code multiplexing and outputs to the multi-carrier batch modulating unit. .

The invention described in claim 1 is characterized in that the spreading factor and the number of code multiplexes can be changed by fallback.

According to a second aspect of the present invention, the encoding means receives the output signal of the modulating section control signal generating means and makes the encoding rate variable, and the subcarrier modulating means controls the modulating section. The multi-carrier modulation circuit according to claim 1, wherein the output signal of the signal generation means is input and the modulation multi-value number of sub-carrier modulation is made variable.

The invention described in claim 2 is characterized in that, in addition to the characteristics of the invention described in claim 1, the modulation multilevel number and the coding rate can be changed by fallback.

According to a third aspect of the present invention, a coding means for performing error correction coding of input data, a multi-carrier batch modulation means for performing multi-carrier batch modulation, and an output signal of the multi-carrier batch modulation means are input. And parallel-serial conversion means for generating a transmission signal by outputting the output signal of the multi-carrier batch modulation means in time series based on the output signal from the guard interval addition control means for performing the addition control of the input guard interval. A multi-carrier modulation circuit comprising:

Modulation is performed in accordance with a first fallback control means to which a signal indicating a line state is input between the encoding means and the multicarrier batch modulation means, and an output signal of the first fallback control means. A modulation unit control signal generation unit for controlling the unit, and a first data input / output switching unit for switching the input / output order of the subcarrier modulation signal according to the output signal of the modulation unit control signal generation unit,

A modulation multilevel variable subcarrier modulation in which the output signal of the first data input / output switching means and the output signal of the modulation section control signal generation means are input and the number of modulation levels of subcarrier modulation is variable. And a spreading code generation means capable of varying the spreading factor of the spreading code for spreading in the frequency axis direction and generating a plurality of spreading codes used for code multiplexing in accordance with the output signal of the modulation section control signal generating means. When,

In accordance with the output signal of the modulator control signal generating means, the spreading code generated by the spreading code generating means is used in the frequency axis direction with respect to the output signal of the first data input / output switching means. A multi-carrier modulation circuit comprising: a spreading factor / code multiplex number variable spreading unit having a variable spreading factor and number of code multiplexes, which performs spreading and code multiplexing and outputs to the multi-carrier batch modulating unit. .

According to a third aspect of the present invention, when code multiplexing is performed, the spreading factor, the number of code multiplexes, and the number of modulation levels can be made variable by fallback for each multiplex code.

According to a fourth aspect of the present invention, a multi-carrier batch modulation means for performing multi-carrier batch modulation and a guard interval addition control for receiving an output signal of the multi-carrier batch modulation means and performing additional control of an input guard interval. Based on the output signal from the means, output the output signal of the multi-carrier batch modulation means in time series, parallel-serial conversion means for generating a transmission signal, a multi-carrier modulation circuit comprising:

The modulator is controlled in accordance with the first fallback control means to which a signal indicating the line state is input, and the output signal of the first fallback control means before the multicarrier batch modulation means. Modulation section control signal generation means, and first data input / output switching means for switching the input / output order of input data signals according to the output signal of the modulation section control signal generation means,

Variable coding rate coding means for inputting the output signal of the first data input / output switching means and the output signal of the modulation section control signal generating means, and the variable coding rate coding means for varying the coding rate. An output signal of the rate coding means and an output signal of the modulation section control signal generating means are input, and the modulation multi-level variable sub-carrier modulation means in which the modulation multi-level number of subcarrier modulation is variable,

According to the output signal of the modulator control signal generating means, the spreading factor of the spreading code for spreading in the frequency axis direction is variable, and the spreading code generating means capable of generating a plurality of spreading codes used for code multiplexing. According to the output signal of the modulation section control signal generating means, the spreading code generated from the spreading code generating means is used to spread the output signal of the modulation multi-level subcarrier modulating means in the frequency axis direction. And a spread factor / code multiplex number variable spreader having a variable spread factor and a variable code multiplex number, which is output to the multicarrier batch modulation unit by performing code multiplexing, and a multicarrier modulation circuit.

The invention described in claim 4 is characterized in that, in addition to the features of the invention described in claim 3, when code multiplexing is performed, the coding rate can be made variable by fallback for each multiplex code. .

According to a fifth aspect of the invention, serial-parallel conversion means for receiving the received multi-carrier signal and performing serial-parallel conversion of the received multi-carrier signal, and multi-carrier batch demodulation for the output signal of the serial-parallel conversion means. Multi-carrier batch demodulation means for performing, a sub-carrier demodulation means for performing a demodulation operation of sub-carrier modulation on the output signal of the multi-carrier batch demodulation means, and an error correction for output data from the sub-carrier demodulation means. A decoding unit for performing decoding, comprising:

According to an output signal of the second fallback control means and a second fallback control means for inputting a signal indicating a line state between the multicarrier batch demodulation means and the subcarrier demodulation means, According to the output signal of the demodulation unit control signal generation unit that controls the demodulation unit and the demodulation unit control signal generation unit, the spreading factor of the spreading code that performs despreading in the frequency axis direction is variable and used for code multiplexing. Spreading code generation means capable of generating a plurality of spreading codes,

In accordance with the output signal of the demodulation unit control signal generating means, the spreading code generated from the spreading code generating means is used to despread and output in the frequency axis direction the output signal of the multi-carrier batch demodulating means. Spreading rate / code multiplex number variable despreading means for varying the spread rate and the number of code multiplexes for performing synthesis according to the number of code multiplexes,

Second data input / output switching means for switching the input / output order of the spreading factor / code multiplexing number variable despreading means according to the output signal of the demodulation section control signal generating means and inputting to the subcarrier demodulation means, Is a multi-carrier demodulation circuit.

The invention described in claim 5 demodulates a signal transmitted from the multicarrier modulation circuit according to claim 1 or a modulation circuit equivalent to this, in which the spreading factor and the code multiplexing number can be varied by fallback. It is characterized by doing.

According to a sixth aspect of the present invention, the subcarrier demodulation means receives the output signal of the demodulation part control signal generation means, makes the modulation multi-value number of subcarrier demodulation variable, and the encoding means 6. The multicarrier demodulation circuit according to claim 5, wherein the output signal of the demodulation unit control signal generation means is input to make the coding rate variable.

According to a sixth aspect of the present invention, in addition to the features of the fifth aspect of the invention, a multi-valued modulation signal transmitted from the multi-carrier modulation circuit of the second aspect or a modulation circuit equivalent thereto is transmitted. It is characterized by demodulating a signal whose number and coding rate can be changed by fallback.

According to a seventh aspect of the present invention, serial-parallel conversion means for receiving the received multi-carrier signal and performing serial-parallel conversion of the received multi-carrier signal, and multi-carrier batch demodulation for the output signal of the serial-parallel conversion means. In a multi-carrier demodulation circuit comprising: a multi-carrier batch demodulation means for performing and a decoding means for performing error correction decoding on error correction coded data,

A second fallback control means for receiving a signal indicating a line state between the multicarrier batch demodulation means and the coding means, and a demodulation section according to an output signal of the second fallback control means. According to the output signal of the demodulation unit control signal generation means for controlling the, and the demodulation unit control signal generation means, the spreading factor of the spreading code for performing despreading in the frequency axis direction is made variable, Spreading code generating means for generating a spreading code,

In accordance with the output signal of the demodulation unit control signal generating means, the spreading code generated by the spreading code generating means is used to despread in the frequency axis direction with respect to the output signal of the multicarrier batch demodulating means. Spreading rate / code multiplex number variable despreading means for varying the spread rate and the number of code multiplexes for performing synthesis according to the number of code multiplexes,

A modulation multilevel variable subcarrier demodulation which receives the output signal of the spreading factor / code multiplex number variable despreading means and the output signal of the demodulation part control signal generating means and makes the modulation multiplex number of subcarrier demodulation variable. Means and

Second data input / output switching means for switching the input / output order of the output signals of the modulation multilevel variable subcarrier demodulation means according to the output signal of the demodulation section control signal generation means and outputting to the decoding means. And a multi-carrier demodulation circuit.

According to the invention described in claim 7, when the code multiplexing is performed, the spreading factor and the code multiplex number transmitted from the multicarrier modulation circuit according to claim 3 or a modulation circuit equivalent thereto are multiplexed. It is characterized by demodulating a signal that can be varied by fallback for each.

According to the eighth aspect of the present invention, serial-parallel conversion means for receiving the received multi-carrier signal and performing serial-parallel conversion of the received multi-carrier signal, and multi-carrier batch demodulation for the output signal of the serial-parallel conversion means. In a multi-carrier demodulation circuit comprising:

A demodulation for controlling the demodulation section according to the second fallback control means to which a signal indicating the line state is input after the multicarrier batch demodulation means and the output signal of the second fallback control means. According to the output signals of the unit control signal generation means and the demodulation part control signal generation means, the spreading factor of the spreading code for despreading in the frequency axis direction is made variable, and a plurality of spreading codes used for code multiplexing are generated. Spreading code generation means,

In accordance with the output signal of the demodulation unit control signal generating means, the spreading code generated from the spreading code generating means is used to despread and output in the frequency axis direction the output signal of the multicarrier batch demodulating means. Spreading rate / code multiplex number variable despreading means for varying the spread rate and the number of code multiplexes for performing synthesis according to the number of code multiplexes,

A modulation multi-level variable subcarrier demodulation which receives the output signal of the spreading factor / code multiplex number variable despreading means and the output signal of the demodulation section control signal generating means and makes the modulation multiplex number of subcarrier demodulation variable. Means and

Variable coding rate decoding means for inputting the output signal of the modulation multilevel variable subcarrier demodulation means and the output signal of the demodulation section control signal generation means to make the coding rate variable, and the demodulation section control And a second data input / output switching means for switching the input / output order of the output signals of the variable coding rate decoding means according to the output signal of the signal generating means.

According to the invention described in claim 8, in addition to the features of the invention described in claim 7, the code multiplex signal transmitted from the multicarrier modulation circuit according to claim 4 or an equivalent modulation circuit is transmitted. When performing, the signal is demodulated so that the coding rate can be varied by fallback for each multiplex code.

In the present invention, unlike the prior art, when a packet is transmitted in packet communication, an ACK is received from the receiving side.
The fact that the (Acknowledge) signal is transmitted back is used. The present invention determines that the communication environment is good when the ACK signal is properly received, and the OFD
The M modulation method is applied.

The present invention further performs control such that the number of subcarrier modulation levels is increased or the coding rate is increased sequentially. On the contrary, the present invention performs fallback such as reducing the modulation level of OFDM or reducing the coding rate when ACK is not received.

If communication is still not secured, the present invention performs fallback to MC-CDMA, which is an extension of OFDM, and increases SF, or decreases the number of code multiplexes while securing SF, or MC-CDMA
The number of modulation multi-levels in, or MC-CDM
A feature is that a communication line is secured by performing a fallback in which the coding rate is reduced in A or a fallback in which the fallback is combined. Therefore, according to the present invention, the information of single cell and multi-cell, which is conventionally required, is not necessary at all.

Further, according to the present invention, fallback is performed according to a normal packet communication procedure without applying an estimated value of delay dispersion. Therefore, according to the present invention,
It is also possible to avoid a decrease in throughput due to an estimation error.

FIG. 9 is a diagram showing the principle of the present invention. The present invention operates to select OFDM in areas where the communication environment is good. On the other hand, the present invention operates so as to select the modulation method so as to fall back to MC-CDMA in a region where the communication environment is severe. Therefore, the present invention operates in a multi-cell environment to meet the maximum transmission rate at the center of the cell. In addition, according to the present invention, interference resistance is increased at the cell edge, so that planar expansion can be realized.

Alternatively, according to the present invention, it is possible to perform communication in a low CNR environment, which is difficult to realize with OFDM alone. Therefore, according to the present invention, the cell radius can be improved in a single-single-cell environment.

As a fallback means, A
Although it is preferable to use CK transmission / reception, the present invention is not limited to this. Therefore, in addition to the transmission and reception of ACK, the correlation amount between adjacent subcarriers, single cell,
Switching information of the multi-cell environment, estimation information of delay dispersion value, and the like can also be used as the fallback means according to the present invention.

Further, since the present invention is characterized by being variable, it does not necessarily have to be variable and may be fixed. Therefore, in the present invention, for example,
If the spreading factor is 1 and the number of multiplex codes is 1, then OF
A DM modulation circuit or demodulation circuit can be realized.

[0065]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a block diagram according to an embodiment of the invention described in claim 1. The encoding circuit 101 receives the data s101,
The error correction coded data sl02 is output. The subcarrier modulation circuit 102 receives the error correction coded data sl02 as input, performs subcarrier modulation, and outputs a modulated signal sl03.
Is output.

The fallback signal control circuit 103 receives the line information s104 indicating the state of the line and outputs the control signal sl05 for controlling the fallback. The modulator control signal generation circuit 104 generates the modulator control signal s106 according to the control signal sl05.

The spread code generation circuit 105 selects a spread code according to the modulation unit control information s106, and spread code s10.
7 is output. The data input / output switching circuit 106 receives the modulation signal s103 and the modulation section control signal s106, performs input / output conversion, and outputs a subcarrier signal s108.

Spreading factor / code multiplexing number variable spreading circuit 107
Is the subcarrier signal s108 and the modulator control signal s10.
6 and the spread code s107 are input, spread processing and code multiplex processing in the frequency axis direction are performed, and a subcarrier signal s109 is output. Note that the spreading factor / code multiplex number variable spreading circuit 107 does not naturally perform the spreading process when OFDM is selected as the transmission method.

The IFFT circuit 108 receives the subcarrier signal s109, performs multicarrier batch modulation,
The multicarrier signal s110 is output. The parallel-serial conversion circuit 110 receives the multicarrier signal s110 and the control signal sll from the guard interval addition control circuit 109.
Is input, conversion to a time series and addition of a guard interval are performed, and a transmission signal s112 is output.

FIG. 2 is a block diagram according to an embodiment of the invention described in claim 2. In FIG. The embodiment of the invention described in claim 2 has a variable coding rate coding circuit 201 and a variable multilevel variable subcarrier modulation circuit 202, and thus the embodiment of the invention described in claim 1 Is different from.

The variable coding rate coding circuit 201 receives the data s201 and the modulation section control signal s206 and outputs the error correction coded data s202. The variable multilevel variable subcarrier modulation circuit 202 receives the error correction coded data s202 and the modulation unit control signal s206, performs subcarrier modulation, and outputs a modulation signal s203.

The operation of the other circuits in the embodiment of the invention described in claim 2 is the same as that of the embodiment of the invention described in claim 1.

FIG. 3 is a block diagram according to an embodiment of the invention described in claim 3. In FIG. The embodiment of the invention described in claim 3 is different from the embodiment of the invention described in claim 2 in the point of the encoding circuit 301.

The coding circuit 301 receives the data s301 and outputs the error correction coded data s302. The data input / output switching circuit 302 uses the error correction coded data s
302 and the modulator control signal s306 are input, input / output conversion is performed, and a subcarrier signal s303 is output.

Modulation multilevel variable subcarrier modulation circuit 30
6 is a subcarrier signal s303 and a modulator control signal s3
06 is input, subcarrier modulation is performed, and a modulation signal s308 is output. The operation of the other circuits in the embodiment of the invention described in claim 3 is the same as that of the embodiment of the invention described in claim 2.

FIG. 4 is a block diagram according to an embodiment of the invention described in claim 4. In FIG. The embodiment of the invention described in claim 4 is different from the embodiment of the invention described in claim 3 in that it has a data input / output switching circuit 401.

The data input / output switching circuit 401 uses the data s
401 and the modulator control signal s406 are input, input / output conversion is performed, and a subcarrier signal s402 is output. The variable coding rate coding circuit 402 uses the subcarrier signal s4.
02 and the modulation section control signal s406 are input, and error correction coded data s403 is output.

Modulation Multilevel Variable Subcarrier Modulation Circuit 40
6 receives the error correction coded data s403 and the modulator control signal s406 as input, performs subcarrier modulation, and outputs a modulated signal s408. The operation of the other circuits in the embodiment of the invention described in claim 4 is similar to that in the embodiment of the invention described in claim 3.

FIG. 5 is a block diagram according to an embodiment of the invention described in claim 5. In FIG. Serial-parallel conversion circuit 501
Receives a received signal s501 and outputs a parallel signal s502. The FFT circuit 502 receives the parallel signal s502, performs multi-carrier batch modulation, and outputs a subcarrier signal s503.

The fallback signal control circuit 503 receives the line information s504 indicating the line state, and outputs the control signal s505 for controlling the fallback. The demodulation unit control signal generation circuit 504 generates the demodulation unit control signal s506 according to the control signal s505. Spread code generation circuit 50
5 selects a spreading code according to the demodulation unit control information s506 and outputs a spreading code s507.

Spreading factor / code multiplex number variable despreading circuit 506
Is a subcarrier signal s503 and a demodulation unit control signal s50.
6 and the spreading code s507 are input, despreading is performed, and a synthetic signal s508 is generated. The spreading factor / code multiplexing number variable despreading circuit 506 naturally does not perform the spreading process when OFDM is selected as the transmission method in the single cell environment.

The data input / output switching circuit 507 receives the combined signal s508 and the demodulation unit control signal s506, switches the input / output, and sequentially outputs the combined signal s509.
The subcarrier demodulation circuit 508 demodulates the combined signal s509 and generates a demodulated data signal s510. The decoding circuit 509 performs error correction decoding processing on the demodulated data signal s510 and outputs data s511.

FIG. 6 is a block diagram according to an embodiment of the invention described in claim 6. In FIG. The embodiment of the invention described in claim 6 has a variable multi-level variable subcarrier demodulation circuit 608 and a variable coding rate coding circuit 609, and thus the embodiment of the invention described in claim 5 Is different from.

Variable multilevel variable subcarrier demodulation circuit 60
8 receives the demodulation unit control signal s606 and outputs the combined signal s
609 is demodulated to generate a demodulated data signal s610. The variable coding rate coding circuit 609 performs an error correction decoding process on the demodulated data signal s610 to obtain the data s
611 is output.

The operation of the other circuits in the embodiment of the invention described in claim 6 is the same as that of the embodiment of the invention described in claim 5.

FIG. 7 is a block diagram according to an embodiment of the invention described in claim 7. In FIG. The variable multilevel variable subcarrier demodulation circuit 707 receives the demodulation unit control signal s706, demodulates the combined signal s708, and generates a demodulated data signal s709.

The data input / output switching circuit 708 receives the demodulated data signal s709 and the demodulation unit control signal s706, switches the input / output, and sequentially outputs the combined signal s710. The operation of the other circuits in the embodiment of the invention described in claim 7 is the same as that of the embodiment of the invention described in claim 6.

FIG. 8 is a block diagram according to an embodiment of the invention described in claim 8. In FIG. The variable coding rate decoding circuit 808 includes a demodulated data signal s809 and a demodulation unit control signal s.
806, the demodulated data signal s809 is subjected to error correction decoding processing, and data s810 is output. The data input / output switching circuit 809 receives the data s810, switches the input / output, and sequentially outputs the combined signal s81.
1 is output.

The operation of the other circuits in the embodiment of the invention described in claim 8 is the same as in the case of the embodiment of the invention described in claim 7.

FIG. 10 is a comparison diagram of system capacities according to the present invention. In FIG. 10, a comparison of system capacities based on required C / (N + I) obtained from link level computer simulations is shown to confirm the effect of the present invention.

In FIG. 10, when only OFDM is used, when only MC-CDMA is used, and when OFDM is used.
The case where the line is not satisfied even if the number of modulation levels is reduced to MC-CDMA (hereinafter, referred to as “an example of the present invention”) is compared.

In the case of the example of the present invention, the number of code multiplexes is reduced in addition to the number of modulation levels to reduce the transmission rate. Table 1 shows the OFDM used in the comparison of FIG.
10 is a table showing system specifications, Table 2 is a table showing MC-CDMA system specifications used for comparison in FIG. 10, and Table 3 is an example of the present invention used for comparison in FIG. 6 is a table showing system specifications.

[0093]

[Table 1]

[0094]

[Table 2]

[0095]

[Table 3]

The evaluation standard is the average transmission rate R in the cell.
_ave (downlink, upper layer efficiency = 1, propagation loss =
3.1 power law). Derivation follows the following. Allowable C / from the desired signal power, noise power, and sum of interference power of all surrounding cells
Calculate (N + 1). This allowable C / (N + 1) and each transmission rate R _i obtained from the link level simulation
Then, the communicable distance d _i is determined from the required C / (N + 1) and the area S _{i of the} hexagonal cell is obtained from Equation 1. From this value, the in-cell average transmission rate R _ave is defined by Equation 2. M
Indicates the defined number of transmission rates in the system.

[0097]

[Equation 1]

[0098]

[Equation 2]

The horizontal axis of FIG. 10 shows the normalized cell radius (= 1: cell edge) in each system. In OFDM using only the modulation multilevel fallback, it is difficult to satisfy the standardized cell radius = 1. On the other hand, in the example of the present invention, since the fallback to MC-CDMA is performed, the standardized cell radius is expanded by about 2.2 times as compared with OFDM, and it is possible to develop the same area as MC-CDMA. Has become.

The vertical axis of FIG. 10 shows R _ave when the normalized cell radius = 1. In OFDM, since it is difficult to communicate around the cell edge, the transmission rate was evaluated as R _M = 0. Therefore, OFDM has a low R _ave .

In one example of the present invention, the required C / (N +
Since OFDM is used when I) can be secured, MC-
Compared with the case of CDMA alone, R _ave is increased about 1.3 times, and the system capacity is increased.

[0102]

As described above, according to the multi-carrier modulation circuit and the multi-carrier modulation circuit according to the present invention, the single cell and the multi-cell environment can be realized without using the information of the single cell and the multi-cell environment which has been essential in the past. Communication is possible. Therefore, it is possible to realize a multi-carrier modulation circuit and a multi-carrier modulation circuit that enable planar development while improving the transmission speed.

[Brief description of drawings]

FIG. 1 is a block diagram according to an embodiment of the invention described in claim 1.

FIG. 2 is a block diagram according to an embodiment of the invention described in claim 2.

FIG. 3 is a block diagram according to an embodiment of the invention described in claim 3.

FIG. 4 is a block diagram according to an embodiment of the invention described in claim 4.

FIG. 5 is a block diagram according to an embodiment of the invention described in claim 5.

FIG. 6 is a block diagram according to an exemplary embodiment of the invention described in claim 6;

FIG. 7 is a block diagram according to an embodiment of the invention described in claim 7.

FIG. 8 is a block diagram according to an embodiment of the invention described in claim 8;

FIG. 9 is a diagram showing the principle of the present invention.

FIG. 10 is a comparative diagram of system capacity for the present invention.

FIG. 11 is a block diagram of a conventional multicarrier modulation circuit.

FIG. 12 is a block diagram of a conventional multicarrier demodulation circuit.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Satoshi Hori             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Toru Sakata             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation (72) Inventor Masahiro Morikura             2-3-1, Otemachi, Chiyoda-ku, Tokyo             Inside Telegraph and Telephone Corporation F term (reference) 5K022 DD01 DD13 DD19 DD23 DD33                       EE02 EE14 EE21 EE31 FF01

Claims (8)

[Claims] 1. A coding means for performing error correction coding of input data, a subcarrier modulation means for performing subcarrier modulation on coded data output from the coding means, and the subcarrier modulation means. From the multi-carrier batch modulation means for performing multi-carrier batch modulation on the output sub-carrier modulation signal and the guard interval addition control means for receiving the output signal of the multi-carrier batch modulation means and performing the guard interval addition control means. A multi-carrier modulation circuit comprising: a parallel-serial conversion unit that outputs the output signal of the multi-carrier batch modulation unit in time series based on the output signal and generates a transmission signal, wherein the sub-carrier modulation unit and the The first fall-bar to which a signal indicating the line state is input between the multi-carrier batch modulation means. A click control means, in accordance with the output signal of the first fall-back control means,
Modulation section control signal generation means for controlling the modulation section, first data input / output switching means for switching the input / output order of the subcarrier modulation signals according to the output signal of the modulation section control signal generation means, and the modulation section According to the output signal of the control signal generating means, the spreading rate of the spreading code for spreading in the frequency axis direction is variable, and the spreading code generating means capable of generating a plurality of spreading codes used for code multiplexing; According to the output signal of the signal generating means, the spreading code generated by the spreading code generating means is used to perform spreading and code multiplexing in the frequency axis direction on the output signal of the first data input / output switching means. And a spreading factor / code multiplexing number variable spreading unit for varying the spreading factor and the code multiplexing number, which is output to the multicarrier batch modulating unit. circuit. 2. The encoding means receives the output signal of the modulating section control signal generating means and makes the coding rate variable, and the subcarrier modulating means outputs the output signal of the modulating section control signal generating means. The multi-carrier modulation circuit according to claim 1, wherein the modulation multi-level number of the sub-carrier modulation that is input is made variable. 3. A guard interval to which an encoding means for performing error correction encoding of input data, a multi-carrier collective modulating means for performing multi-carrier collective modulation, and an output signal of the multi-carrier collective modulating means are inputted and inputted. Multi-carrier modulation circuit for outputting the output signal of the multi-carrier batch modulation means in time series based on the output signal from the guard interval addition control means for performing the addition control of the parallel-serial conversion means for generating the transmission signal. Wherein, between the encoding means and the multicarrier batch modulation means, a first fallback control means to which a signal indicating a line state is input, and according to an output signal of the first fallback control means,
A modulation section control signal generating means for controlling a modulation section; a first data input / output switching means for switching an input / output order of the subcarrier modulation signal according to an output signal of the modulation section control signal generating means; Of the data input / output switching means and the output signal of the modulating section control signal generating means, and the modulation multilevel variable subcarrier modulating means for varying the modulation multilevel number of subcarrier modulation; According to the output signal of the control signal generating means, the spreading rate of the spreading code for spreading in the frequency axis direction is variable, and the spreading code generating means capable of generating a plurality of spreading codes used for code multiplexing; According to the output signal of the signal generating means, the spreading code generated by the spreading code generating means is used to expand the output signal of the first data input / output switching means in the frequency axis direction. A multi-carrier modulation circuit comprising: a spread factor / code multiplex number variable spreader having a variable spread factor and code multiplex number, which performs dispersion and code multiplex and outputs the result to the multicarrier batch modulation unit. 4. A multi-carrier batch modulation means for performing multi-carrier batch modulation and an output signal from the guard interval addition control means for inputting an output signal of the multi-carrier batch modulation means and performing additional control of an input guard interval. And a parallel-serial conversion means for outputting the output signal of the multi-carrier batch modulation means in time series to generate a transmission signal, wherein a line is provided in front of the multi-carrier batch modulation means. According to an output signal of the first fallback control means, a first fallback control means to which a signal indicating a state is input,
A modulation section control signal generation means for controlling the modulation section; a first data input / output switching means for switching the input / output order of the input data signal according to the output signal of the modulation section control signal generation means; Of the data input / output switching means and the output signal of the modulation section control signal generating means, and a variable coding rate coding means for varying the coding rate; and an output of the variable coding rate coding means. A signal and an output signal of the modulation section control signal generation means are input, and a modulation multilevel variable subcarrier modulation means in which the modulation multilevel number of subcarrier modulation is variable, and an output signal of the modulation section control signal generation means A spreading code generating means capable of varying the spreading factor of a spreading code for spreading in the frequency axis direction and capable of generating a plurality of spreading codes used for code multiplexing; According to the input signal, the spreading code generated by the spreading code generating means is used to perform spreading and code multiplexing in the frequency axis direction on the output signal of the modulation multi-valued subcarrier modulating means, and to perform the multi-carrier batch modulation. A multi-carrier modulation circuit, comprising: a spreading factor / code multiplexing number variable spreading unit that outputs a spreading factor and a code multiplexing number to the unit. 5. A serial-parallel conversion means for receiving the received multi-carrier signals and performing serial-parallel conversion of the received multi-carrier signals, and a multi-carrier batch demodulation means for performing multi-carrier batch demodulation on the output signals of the serial-parallel conversion means. A subcarrier demodulation means for performing a demodulation operation of subcarrier modulation on the output signal of the multicarrier batch demodulation means, and a decoding means for performing error correction decoding on the output data from the subcarrier demodulation means. And a second fallback control means for receiving a signal indicating a line state between the multicarrier batch demodulation means and the subcarrier demodulation means, According to the output signal of the fallback control means,
A demodulation unit control signal generation unit that controls the demodulation unit, and according to the output signal of the demodulation unit control signal generation unit, the spreading factor of the spreading code that performs despreading in the frequency axis direction is variable,
And, the spread code generation means capable of generating a plurality of spread codes used for code multiplexing, and the spread code generated from the spread code generation means according to the output signal of the demodulation part control signal generation means Despreading in the frequency axis direction with respect to the output signal of the batch demodulation means, and combining according to the number of code multiplexes,
According to the output signal of the spreading factor / code multiplex number variable despreading unit and the spreading factor / code multiplex number variable despreading unit, the input / output order of the spreading factor / code multiplex number variable despreading unit is set according to the output signal of the demodulation unit control signal generation unit. And a second data input / output switching means for switching and inputting to the subcarrier demodulation means. 6. The subcarrier demodulation means receives the output signal of the demodulation section control signal generation means and makes the modulation multilevel number of subcarrier demodulation variable, and the encoding means generates the demodulation section control signal generation. The multi-carrier demodulation circuit according to claim 5, wherein the output signal of the means is input and the coding rate is made variable. 7. A serial-parallel conversion means for receiving the received multi-carrier signal and performing serial-parallel conversion of the received multi-carrier signal, and a multi-carrier batch demodulation means for performing multi-carrier batch demodulation on the output signal of the serial-parallel conversion means. And a decoding means for performing error correction decoding on the error correction coded data, wherein a signal indicating a line state is provided between the multicarrier batch demodulation means and the coding means. Second fallback control means, a demodulation part control signal generation means for controlling a demodulation part according to the output signal of the second fallback control means, and an output signal of the demodulation part control signal generation means , The spreading factor of the spreading code that performs despreading in the frequency axis direction is variable,
And, the spreading code generation means for generating a plurality of spreading codes used for code multiplexing, and the spreading code generated from the spreading code generation means according to the output signal of the demodulation part control signal generation means A spreading factor / code multiplex variable despreading unit having a variable spread factor and code multiplex number, which performs despreading in the frequency axis direction on the output signal of the demodulating unit and performs synthesis according to the number of code multiplexes; A modulation multilevel variable subcarrier demodulation means for inputting an output signal of the rate / code multiplex number variable despreading means and an output signal of the demodulation part control signal generation means, and varying the modulation multiplex number of subcarrier demodulation; Second data to be output to the decoding means by switching the input / output order of the output signal of the modulation multilevel variable subcarrier demodulation means according to the output signal of the unit control signal generation means Multicarrier demodulation circuit, characterized in that and an output switching unit. 8. A serial-parallel conversion means for receiving the received multi-carrier signal and performing serial-parallel conversion of the received multi-carrier signal, and a multi-carrier batch demodulation means for performing multi-carrier batch demodulation on the output signal of the serial-parallel conversion means. A multi-carrier demodulation circuit comprising: a second fallback control means to which a signal indicating a line state is input after the multi-carrier batch demodulation means, and an output signal of the second fallback control means. A demodulation unit control signal generation unit that controls the demodulation unit, and according to the output signal of the demodulation unit control signal generation unit, the spreading factor of the spreading code that performs despreading in the frequency axis direction is variable,
And, the spreading code generation means for generating a plurality of spreading codes used for code multiplexing, and the spreading code generated from the spreading code generation means according to the output signal of the demodulation part control signal generation means A spreading factor / code multiplex variable despreading unit having a variable spread factor and code multiplex number, which performs despreading in the frequency axis direction on the output signal of the demodulating unit and performs synthesis according to the number of code multiplexes; A modulation multilevel variable subcarrier demodulation means for inputting the output signal of the rate / code multiplex number variable despreading means and the output signal of the demodulation part control signal generation means to make the modulation multiplex number of subcarrier demodulation variable; Variable coding rate decoding means for inputting an output signal of the multilevel variable subcarrier demodulation means and an output signal of the demodulation part control signal generation means to make the coding rate variable, A multi-carrier demodulation circuit comprising: a second data input / output switching unit that switches the input / output order of the output signal of the variable coding rate decoding unit according to the output signal of the demodulation unit control signal generation unit.