JP3801153B2 - Spread spectrum communication method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention efficiently handles multimedia data, such as voice data, computer-processed data, and moving image data, which have large fluctuations such as low speed and large capacity, real time and large capacity, at different transmission rates. The present invention relates to a spread spectrum communication method.
[0002]
[Prior art]
In order to perform multimedia communication, it can range from data that can be communicated at a low transmission rate of several tens of kbps (bits / second) such as audio data to data with a high transmission rate of several Mbps or more such as moving image data. Handling in the same communication system is required.
[0003]
In recent years, a code division multiple access (CDMA) system has attracted attention as a system capable of user multiplexing using the same band. This CDMA system is a spread spectrum (SS) communication system, and realizes user multiplexing within the same band by multiplying each symbol by a spreading code different for each user. The adoption of this CDMA system is also decided in the standardization of IMT2000 in the International Telecommunications Union (ITU).
[0004]
Conventionally, the following three methods have been considered in order to transmit at various transmission rates using the CDMA system.
The first method is a “spreading code multiplexing method” in which a certain user uses a plurality of spreading codes. Thereby, even if the transmission rate for each spreading code is fixed, various transmission rates can be realized by changing the number of multiplexed spreading codes.
The second method is a method of changing the number of data within a predetermined time (frame) using one spreading code. As a main means for realizing the second method, there is a “variable spreading factor transmission method” that changes the spreading code length (spreading code period) while keeping the code rate (chip rate) constant.
As a third method, it is possible to realize from low speed transmission to high speed transmission by combining the above-described first and second methods. In IMT2000 (International Mobile Telecomunications-2000), these combinations are possible. Variable transmission rate.
Hereinafter, a communication system combining the “spreading code multiplexing method” and the “variable spreading factor transmission method” will be described.
[0005]
FIG. 12 is a block diagram of a conventional spread spectrum communication system.
In the figure, 41 is a transmitter of user 1. The transmitters of a plurality of users 1 to u have the same configuration.
In IMT2000, a long code is also used for spreading for the purpose of cell identification. Moreover, although transmission power control is performed, these description is abbreviate | omitted.
In the transmitter 41, reference numeral 42 denotes a serial / parallel converter that distributes input data to one or more systems of data.
The data string of each system passes through the encoding unit 1, the interleaving unit 2, the information modulation unit 4, and the spreading unit 43, is added by the adding unit 44, becomes a transmission signal through the radio circuit unit 45, and is transmitted from an antenna (not shown). Is done.
[0006]
The number of systems in the serial / parallel converter 42 and the spreading code length n in the spreading unit 43 are controlled by rate information data specifying the transmission rate of input data.
This rate information data is sent to the receiver 46, and using this rate information data, processing opposite to that on the transmission side is performed.
[0007]
On the other hand, 46 is a receiver of the user u who is the communication partner of the user 1. The receivers of a plurality of users 1 to u have the same configuration. In the receiver 46, 47 is a radio circuit unit, and the baseband signals of the I component and Q component demodulated orthogonally are branched and output to the despreading units 48 of a plurality of systems.
The output of the despreading section 48 of each system is processed by the information demodulating section 11, the deinterleaving section 14, and the decoding section 15, respectively, and reconfigured in the parallel-serial conversion section 49 to correspond to the input data on the transmission side. Output data is obtained. The number of systems in the serial / parallel converter 42 and the spreading code length n in the despreading unit 48 are controlled by receiving rate information data transmitted from the transmitter 41.
[0008]
FIG. 13 is an explanatory diagram of spreading codes used in the conventional spread spectrum communication system shown in FIG.
FIGS. 13A to 13D show spreading code candidates with spreading code lengths n = 16, 8, 4, and 2, respectively. In each code length, a plurality of spreading codes are used according to the spreading code multiplexing number.
[0009]
FIG. 14 is an explanatory diagram of the code generation principle of the spreading code shown in FIG. Spreading codes having different code lengths have a tree structure.
The first one of the spreading codes with the code length 2 is “11” obtained by adding the same code “1” to the code “1” of the upper layer, and the second one is the code “1” of the upper layer. "10" with its complement "0" added.
The first of the spreading codes with code length 4 is “1111” obtained by adding the same code “11” to the first code “11” of the upper layer, and the second one is the upper layer of the upper layer. “1100” is obtained by adding the complement “00” to the first code “11”. The third one is “1010” obtained by adding the same code “10” to the second code “10” of the upper layer, and the fourth one is the second code “10” of the upper layer. Is “1001” with its complement “01” added.
In the same manner, 16 spreading code candidates can be obtained for a spreading code with a code length of 16, but a description thereof will be omitted.
[0010]
A spreading code generated by the above-described method is called a hierarchical orthogonal code. Spreading codes in the same layer are orthogonal. The spreading codes that are not in the same hierarchy are kept orthogonal to those that are not in the same branch. In other words, when the spreading code at the top of the tree structure is being used, the spreading code at the lower branch cannot be used at the same time.
[0011]
Again, referring back to FIG.
For input data such as voice and moving images, a “code multiplexing method” corresponding to rate information data is used. That is, the serial / parallel converter 42 distributes the signals to multiple circuits of the encoder 1 according to the transmission code multiplexing number. Here, when the transmission code multiplexing number is 1, code multiplexing is not performed, so that only one encoding unit 1 is output. The distributed data of each system is subjected to processing such as convolutional encoding in each encoding unit 1.
In order to reduce the influence of fading fluctuations in the interleaving unit 2, the data of each system after encoding is interleaved in a predetermined frame unit, and then the information modulation unit 4 performs QPSK (Quadrature Phase Shift Keying) modulation or the like. After that, the spreader 43 performs spread spectrum processing using spreading codes having different spreading code lengths of n.
[0012]
The spread output of each system of the user 1 is added by the adding unit 44 and becomes a transmission signal by the radio circuit unit 45. All users from user 1 to user u perform similar processing using different spreading codes for each user, thereby realizing user multiplexing.
In order to realize the “variable spreading factor transmission method”, the spreading unit 43 changes the spreading code length n while keeping the chip rate constant. As a result, the symbol rate changes, so the processing time for one symbol of information modulation is changed. Therefore, other processing blocks need to be changed. The processing for the “variable spreading factor transmission method” and the processing change for changing the “code multiplexing number” are performed by rate information data.
[0013]
On the other hand, in the receiver 46, the received signal is converted into a baseband signal by the radio circuit unit 47. After that, despreading is performed by a plurality of systems of despreading sections 48 using the spreading code of the code length n used in the spreading section 43 in accordance with the spreading code multiplexing number.
Subsequently, the information demodulator 11 performs level determination on the I and Q components of each system and demodulates them. The demodulated data of each system is restored to its original state by the deinterleave unit 14, and data in which the influence of fading fluctuation is reduced is obtained. For the data of each system, the decoding unit 15 decodes the convolutional code, the parallel / serial conversion unit 49 returns the serial data, and the output data is reconstructed.
Similar to the transmitter 41, the despreading unit 48, the information demodulating unit 11, the deinterleaving unit 14, and the decoding unit 15 are set as processing circuits according to the change of the spreading code length n.
[0014]
Since the transmitter 41 changes the number of code multiplexes and the code length n, the receiver 46 needs to make the number of code multiplexes and the code length n known by some means before processing. Therefore, by transmitting the rate information data from the transmitter 41 to the receiver 46 using some means, each process is changed in the receiver 46 according to the rate information data as in the transmitter 41. Is done.
[0015]
A specific example of transmitting rate information data from the transmitter 41 to the receiver 46 is as follows. First, as a channel different from user data, the spread code of this channel is fixed and the rate information data is transmitted. There is a way. If this other channel is a control channel, it can be transmitted together with the data for estimating the propagation state in addition to the rate information data.
Secondly, there is a method in which rate information data is time-multiplexed with user data and transmitted before changing the rate.
In either case, it is not impossible to change the transmission rate for each symbol, but normally, the rate information data is transmitted in units of frames of a predetermined time length to enable switching.
[0016]
In addition, the interleaving cycle is set to a predetermined time length in consideration of the fading cycle, but when the transmission rate changes, the number of symbols per predetermined time, and thus the number of bits per predetermined time, changes. The setting of the interleaving unit 2 is changed according to the rate information data.
[0017]
As described above, settings of other blocks other than the spreading unit 43 may be changed by the rate information data depending on a specific processing method. This setting change is the same for other blocks other than the despreading section 48 of the receiver 46.
Note that base station identification and user identification are performed based on the type of long code whose explanation is omitted or the time difference from the reference timing of the long code.
[0018]
When the conventional communication system described above is viewed from the aspect of "spreading code multiplex transmission system", the influence of cross-correlation increases due to an increase in the number of spreading codes transmitted simultaneously. In particular, since it is difficult to maintain synchronization between different users in the uplink of land mobile communication, there is a problem that characteristic deterioration due to the influence of this cross-correlation becomes remarkable.
[0019]
FIG. 15 is an explanatory diagram of an example of autocorrelation and cross-correlation of the spreading code shown in FIG. The horizontal axis represents the phase difference expressed by the number of chips, and the vertical axis represents the correlation value. The spread code 1 is converted as it is and the spread code 0 is converted to −1 to calculate the correlation value.
FIG. 15A is a diagram showing the autocorrelation value of the spreading code “10010110”, and FIG. 15B is a diagram showing the cross-correlation value between the spreading code “11110000” and the spreading code “10010110”.
[0020]
Since the autocorrelation value shown in FIG. 15A has a code length of 8, peak outputs are obtained at 0, 8, and 16 on the horizontal axis. Such characteristics are shown because orthogonal codes are used as spreading codes. However, even in other places, there are places where the autocorrelation shows a value of 0.5.
[0021]
The cross-correlation values shown in FIG. 15B are 0 at the same 0, 8, and 16 on the horizontal axis. Therefore, even if the number of code multiplexing of the local station increases, the spreading codes are orthogonal. there is no problem. However, when the spread codes are out of sync, such as spread codes of different users, the cross-correlation value does not become 0, and the intersymbol interference component increases as the number of spread codes used simultaneously increases. Become. In addition, as will be described later, even when orthogonal codes are used as spreading codes, the main wave and the delayed waves 1 to 3 are not orthogonal. Becomes larger.
[0022]
On the other hand, in the downlink, transmission data to other users can also be transmitted in synchronization, but similar characteristic degradation is seen due to the influence of cross-correlation caused by multipath and interference from other cells.
[0023]
FIG. 16 is an explanatory diagram of the relationship between the multipath in the multipath propagation path and the conventional spreading code shown in FIG. An example of a delay profile is shown with relative reception power on the vertical axis and time on the horizontal axis. Here, an example in which the main wave and the delayed waves 1 to 3 arrive is shown.
[0024]
(A)-(c) shows a spreading code according to the time of the horizontal axis | shaft which showed the spreading code period.
The spreading code (a) is a spreading code having a spreading code length of 8. Since one symbol is transmitted per spreading code period, when QPSK is used as information modulation, 2-bit data can be transmitted in this spreading code period (8 chips). The transmission rate per chip is 0.25 bits.
The spreading code (b) is a spreading code with a code length of 2. When the same QPSK is used for information modulation, 2-bit data can be transmitted in each spreading code period (2 chips), so the transmission rate per chip is 1 bit.
The spreading code (c) shows a case where four spreading codes with a code length of 8 are multiplexed. When the same QPSK is used as information modulation, 2-bit data can be transmitted with each spreading code, so the transmission rate per chip is 8 bits.
[0025]
In the case of the spreading code shown in (a), since the delay wave 1 to the delay wave 3 are within the spreading period, the main wave and the delay waves 1 to 3 can be separated in the despreading section. However, since the signals spread by different spreading codes included in the delay waves 1 to 3 are not synchronized with the spread spectrum signal of the main wave, intersymbol interference is caused between the main wave and the delay waves 1 to 3. .
As shown in (c), when four spreading codes are used simultaneously, the main wave and the delayed waves 1 to 3 can be separated, but the intersymbol interference increases as the number of simultaneous uses increases.
[0026]
In order to remove the influence of such intersymbol interference, an interference cancellation technique has been conventionally used. However, in order to eliminate the interference of other users, it is necessary to detect the correlation of other users at the synchronization timing of the own station, and the complexity of the circuit and the increase in scale are required due to the increase in the number of code multiplexes. There's a problem.
[0027]
On the other hand, from the aspect of the “variable spreading factor transmission method”, if code multiplexing is not performed, each of the users 1 to u transmits with one spreading code. There is no cross-correlation. Therefore, there is no complication or increase in scale of the interference cancellation circuit.
However, the chip rate is limited by the transmission band, and the spreading code length, in other words, the spreading code period cannot be shorter than the multipath delay time.
That is, in FIG. 16, in the spreading code with the code length 2 shown in FIG. 16B, the delayed waves 1 to 3 arrive beyond the spreading code period (2 chips). 3 cannot be separated from each other, and the above-described interference cancellation circuit becomes complicated.
Further, since the symbol transmission rate is determined by the product of the chip rate and the spreading code length, a symbol transmission rate higher than this cannot be realized.
[0028]
By combining the “spread code multiplex transmission method” and the “variable spreading factor transmission method” described above, it is possible to realize high-speed transmission to low-speed transmission. Variable is realized.
However, when the transmission rate is variable by a combination of these, intersymbol interference during high-speed transmission remains complex, and a higher transmission rate, such as about 10 Mb / s, is required, such as moving image transmission. In the next generation spread spectrum communication system, there is a problem that the interference removal circuit needs to be complicated and scaled up.
In order to suppress the circuit scale in the same way as IMT2000, it is conceivable to keep the spread code multiplexing number low by increasing the chip rate, but the spread code cycle becomes short, and in the environment of land mobile communication, there are multiple Since the path exceeds the spreading code period, there is a problem that the interference cancellation circuit becomes complicated.
[0029]
[Problems to be solved by the invention]
The present invention has been made to solve the above-described conventional problems, and can be controlled according to a transmission rate required for transmission data and the like, and characteristic deterioration due to complicated cross-correlation at the high transmission rate, It is another object of the present invention to provide a spread spectrum communication method that can reduce the influence of multipath fading.
[0030]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention provides a spread spectrum communication method having the following configuration.
A spread spectrum communication method for transmitting a spread spectrum signal as a plurality of channels and transmitting the spread spectrum signals of the plurality of channels as signals of different carriers or different subcarriers, respectively,
A spread spectrum communication method for receiving a spread spectrum signal as a plurality of channels and receiving the spread spectrum signals of the plurality of channels as signals of different carriers or different subcarriers, respectively,
Transmission data distributed to a plurality of channels on the transmission side is distributed to first to (k + 1) th (k + 1) (k is an integer of 1 or more) data strings for the channel, and a code length n (n is an integer of 2 or more). K spreading codes are selected from the m spreading code candidates assigned from the spreading code candidates (m is an integer of 2 or more) according to the (k + 1) th data string, and are selected. The k-spread codes are used to spread the information-modulated signals by the first to k-th data strings, thereby obtaining the multi-channel spread spectrum signal, and the multi-channel spread spectrum signal. And m spreading codes with a code length of n inserted into one of the channels. Receiving control information for controlling the value of the auxiliary contact Yopi the k as common to the respective channels,
Despreading the received spectrum spread signal for each channel using the m spreading code candidates;
Outputting the (k + 1) th data string by specifying the k spreading codes selected at the time of transmission based on the despreading output;
Outputting the first to k-th data sequences by demodulating the despread output using the identified k spreading codes; and
Reconstructing the outputted first to k-th data strings and the (k + 1) -th data string for the plurality of channels to receive data;
And a step of variably controlling at least one of the values of n, m, and k as a value common to the respective channels according to the control information.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block configuration diagram of a first embodiment of the present invention. 1A is a transmitter, and FIG. 1B is a receiver. Although a plurality of users have the same configuration, transmission / reception operations will be described as transmitters and receivers of different users.
In FIG. 1A, 1 is an encoding unit, 2 is an interleaving unit, 3 is a distribution unit, 4 is an information modulation unit, 5 is a spreading code selection unit, 6 is a spreading unit, and 7 is a radio circuit unit. is there.
The encoding unit 1, the interleaving unit 2, and the information modulating unit 4 are the same as each one system of the encoding unit 1, the interleaving unit 2, and the information modulating unit 4 in FIG. The wireless circuit unit 7 is the same as the wireless circuit unit 45 of FIG.
Input data obtained by converting voice, moving images, and the like into digital data is encoded by the encoding unit 1, and the order is changed by the interleaving unit 2. Thereafter, the distribution unit 3 distributes the interleaved transmission data to two systems.
The data string of the first system is output to the information modulation unit 4 as in the conventional case, and becomes two types of modulation data of I and Q by predetermined information modulation, for example, QPSK modulation.
The data string of the second system is output to the spread code selection unit 5.
[0032]
Unlike the conventional case, the spreading unit 6 spreads the information-modulated first system data string using a spreading code selected according to the second system data series.
The radio circuit unit 7 becomes an analog transmission signal in which a spectrum-spread signal is modulated by a carrier wave.
Also in this embodiment, the spread code length n used is variable as in the prior art. In addition, the spread code generated by the spread code selection unit 5 and used by the spread unit 6 is M spreading code candidates are allocated from among a plurality of spreading code candidates having a code length of n, and one is selected according to the data series of the second system. The number m of candidates for the spreading code is variable. The above-described values n and m are changed in the spread code selection unit 5 based on the rate information data.
Accordingly, in general, the setting is also controlled based on the rate information data in the encoder 1, the interleaver 2, the distributor 3, the information modulator 4, and the spreader 6.
A technique for transmitting data by selecting one spreading code from among a plurality of spreading code candidates is conventionally known as “M-ary spread spectrum communication system”. For the purpose of control, change control of the number m of spreading code candidates to be assigned was not performed.
[0033]
On the other hand, on the receiver side shown in FIG. 1B, 8 is a radio circuit unit, 9 _{1 to} 9 _m are despreading units, 10 is a comparison unit, 11 is an information demodulation unit, 12 is an information generation unit, and 13 is a re-transmission unit. A configuration unit, 14 is a deinterleaving unit, and 15 is a decoding unit.
The radio circuit unit 8 is the same as the radio circuit unit 47 of FIG. Information demodulator 11, deinterleaver 14 and decoder 15 are the same as each system of information demodulator 11, deinterleaver 14 and decoder 15 in FIG.
The m despreading units 9 _{1 to} 9 _m are spread code candidates (m) selected on the transmission side from the I and Q components of the baseband signal obtained by converting the received signal by the radio circuit unit 8. Is despread using a spreading code that matches Here, since the number of spreading code candidates used when the spreading code is selected in the transmitter is m, m despreading means are required.
Since the value of m is also variable and there are n spreading codes having a spreading code length n, when all spreading code candidates are used, m = n and n despreading units 9 ₁ to 9 ₁ to 9 are used. 9 _n is used.
[0034]
The comparison unit 10 selects, as the most probable one, the spreading code used by one despreading unit that outputs the maximum peak value from the despread outputs of the plurality of despreading units 9 _{1 to} 9 _m. Then, the selected spreading code is determined to be the same as the despreading code selected by the transmitter (maximum likelihood determination). The comparison unit 10 outputs an output signal (selection despread output signal) despread with the selected spreading code and selection data indicating which despreading code is determined.
In the information generation unit 12, data of the second system used when the spread code selection unit 5 on the transmitter side selects a spread code is generated according to the selection data.
If the comparison unit 10 has the same function as the information generation unit 12, the selection signal output from the comparison unit 10 can be immediately used as the data of the second system.
[0035]
On the other hand, the selected despread output signal is demodulated by the information demodulator 11 and outputs a data string of the first system on the transmission side. The reconstruction unit 13 reconstructs the data strings of the first and second systems, and then performs deinterleaving and decoding processing to obtain output data.
In the above description, QPSK has been described as an example of information modulation, but the information modulation method is not particularly limited. As in BPSK, only the I phase may be used. In the spread modulation, the I phase and the Q phase are independently spread, but the I phase and the Q phase may be spread using the same spread code.
The spreading code length n and the number of uses m of the spreading code candidates to be used change over time based on the rate information data, and the despreading units 9 _{1 to} 9 _m and the comparison unit 10 are controlled by the rate information data. . Accordingly, the setting of the information demodulating unit 11, the information generating unit 12, the reconstruction unit 13, the deinterleaving unit 14, and the decoding unit 15 may be changed and controlled based on the rate information data.
[0036]
In the above description, the rate information data is transmitted to the receiver by being transmitted on another channel such as a control channel or by being time-multiplexed with the user information as in the prior art. For example, the rate information data may be transmitted in units of frames having a predetermined time length.
The combination of the transmission rate, the spreading code length n of the used spreading code candidate, and the allocation number m does not necessarily correspond one-to-one. However, if a correspondence table between transmission rates and m spreading code candidates is prepared in advance in the transmitter and the receiver, each numerical value can be determined simply by transmitting rate information data. As will be described later, spread code candidates may be assigned to a plurality of users. In such a case, rate information data and the number of users are transmitted, and the above-described correspondence table is also created with the number of users as a condition.
It is not always necessary to transmit rate information data and the number of users, and any control information that can identify m spreading code candidates may be used, and the allocated m spreading code candidates themselves may be transmitted to the receiver. .
[0037]
In the above description, a case has been described in which each numerical value is determined on the transmitter side according to the transmission rate and the rate information data is transmitted to the receiving side. Instead, a transmission rate or control information indicating m spreading code candidates as described above is transmitted from the reception side to the transmission side to the transmission side, and each numerical value is determined according to the received rate information data, etc. A decision may be made.
[0038]
Next, a specific operation of the block configuration shown in FIG. 1 will be specifically described with reference to FIGS.
2 to 5, in the embodiment shown in FIG. 1, a plurality of m spreading codes are assigned from a plurality of n spreading code candidates based on the data string of the second system, and one of them is assigned. It is explanatory drawing which shows an example of the conversion table at the time of selecting a spreading code. Further, the spreading code length n indicates a case where the same value is set in the assigned candidates.
An orthogonal code is used as a spreading code candidate. Therefore, when the code length n = 8, there are 8 spreading code candidates. As an example of the orthogonal code, the hierarchical orthogonal code described with reference to FIGS. 13 and 14 is used, but other orthogonal codes may be used.
[0039]
FIG. 2 is an explanatory diagram of a conversion table when one user selects one of all spread code candidates having a spread code length n = 16.
According to 4 bits of input data of the second system, m = 16 spreading codes are assigned. Since all 16 spreading codes are assigned to one user, one spreading code is selected for every 3 bits of the data string of the second system. In the prior art, the spread code is not changed by the input data. For this reason, in the embodiment of the present invention, by selecting one spreading code, a large amount of data can be transmitted by 4 bits as the second system data per symbol.
[0040]
Here, the symbol of information modulation is composed of an I component in phase with the reference frequency signal and a Q component orthogonal thereto in multi-level modulation higher than QPSK modulation. Therefore, the processing for selecting such spreading codes can be performed independently for each of the I-phase component and the Q-phase component. In other words, spreading codes can be assigned independently, and a larger amount of data can be transmitted by 4 + 4 = 8 bits.
With regard to information modulation, when QPSK similar to the conventional one is used, 2 bits per symbol of the data string of the first system are processed by information modulation. Therefore, although only 2 bits per symbol can be transmitted in the prior art, when the spreading code candidate of FIG. 2 is used, 4 + 4 + 2 = 10 bits per symbol can be processed and transmitted. That is, 10/16 = 0.625 bits are transmitted per chip. In the encoding unit 1, the transmission rate is described assuming that the encoding rate = 1, that is, the encoding unit 1 does not perform encoding. Note that the chip rate is set to the same value as in the prior art.
[0041]
FIG. 3 is an explanatory diagram of a conversion table when one user selects one of all spread code candidates with a spread code length n = 8.
M = 8 spreading codes are assigned in accordance with 3 bits of the data string of the second system. Therefore, it is possible to transmit as much data as 3 bits per symbol. When spreading codes are assigned independently to the I component and Q component and QPSK is used as information modulation, 3 + 3 + 2 = 8 bits can be transmitted per symbol. That is, 8/8 = 1 bit is transmitted per chip.
[0042]
FIG. 4 is an explanatory diagram of a conversion table when two users select one of four spreading code candidates having a spreading code length of 8, respectively.
For example, when transmitting to users of a plurality of mobile stations that transmit at the same time in the base station, or when receiving from users of a plurality of mobile stations that receive at the same time, spreading code candidates of code length n are assigned to a plurality of users. Assign.
There are eight spread code candidates with a spread code length n = 8, which are divided into two and assigned to two users. In order to discriminate two users by the spread spectrum signal, each user uses different m = 4 spreading code candidates.
As a result, each user selects one spreading code for every 2 bits of the data string of the second system, and one is selected from m = 4 spreading codes according to the 2 bits. The Therefore, each user can transmit more data by 2 bits per symbol. When spreading codes are assigned independently to the I component and Q component and QPSK is adopted as information modulation, each user can transmit or receive 2 + 2 + 2 = 6 bits per symbol. That is, 6/8 = 0.75 bits are transmitted per chip.
When the number of users is further increased, if the spreading code length n is 8, 8 users is the maximum number of users. Further, in the case of the maximum number of users, as in the conventional example, since one spreading code is assigned, there is no second system data string.
A predetermined number of spreading code candidates not yet assigned to other users among the spreading code candidates of code length n are assigned to users who have newly requested the assignment of spreading code candidates of code length n.
[0043]
FIG. 5 shows a conversion table when one user selects one of all spreading code candidates with a spreading code length n = 4 and when one user selects one of all spreading code candidates with a spreading code length n = 2. It is explanatory drawing of.
In FIG. 5 (a), m = 4 spreading codes are assigned according to 2 bits of the data string of the second system. Therefore, it is possible to transmit as much data as 2 bits per symbol. When spreading codes are assigned independently to the I component and Q component and QPSK is adopted as information modulation, 2 + 2 + 2 = 6 bits can be transmitted per symbol. That is, 6/4 = 1.5 bits are transmitted per chip.
In FIG. 5B, m = 2 spreading codes are assigned in accordance with 1 bit of the data string of the second system. Therefore, a large amount of data can be transmitted by 1 bit per symbol. When spreading codes are assigned independently to the I component and Q component and QPSK is adopted as information modulation, 1 + 1 + 2 = 4 bits can be transmitted per symbol. That is, 4/2 = 2 bits are transmitted per chip.
[0044]
FIG. 6 is a description summarizing the results of studying each code length n with reference to FIGS. 2, 3, and 5 described above, only when one user selects one of all spread code candidates. FIG.
FIGS. 6A to 6D show spreading codes having code lengths n = 16, 8, 4, and 2, respectively. FIG. 6E is an explanatory diagram showing the number of transmission bits per symbol and the number of bits per chip for each spreading code length n. In FIG. 6 (e), numerical values in parentheses are values in the prior art. Compared with the prior art, the number of bits that can be transmitted per chip increases, but as the spreading code length increases, the difference in the number of transmitted bits between the two increases.
Generally, in the case of assigning m out of n spreading code candidates having a spreading code length n and selecting one code according to the data string of the second system, the number of transmission bits per chip is When QPSK is used as information modulation and encoding is not performed, 2 (log ₂ m + 1) / n.
[0045]
In order to change the bit rate on the assumption that the chip rate is fixed, a plurality of methods can be employed.
(1) In order to increase the bit rate, the symbol rate may be increased. For this purpose, the spreading code length n is shortened.
(2) To reduce the bit rate, decrease the value of m.
In the block configuration diagram shown in FIG. 1, the bit rate can be made variable by combining the two methods described above.
[0046]
On the other hand, the bit rate can be increased by simply increasing the spreading code multiplexing number as in the prior art described above. Accordingly, the first embodiment described above may be used for each system of spreading code multiplexing.
However, in the prior art, since the selection of the spread code itself is not used for data transmission, the following method can be used as the second embodiment of the present invention.
(3) In order to increase the bit rate, k spreading codes are selected from the allocated m spreading codes and used in parallel at the same time, and the user data corresponds to the combination of the k spreading codes. Let In the first embodiment, k = 1 spreading code can be selected from m spreading codes, and it can be considered that they are used in parallel at the same time. This is an embodiment.
[0047]
This will be described using specific numerical values.
(A) When using all spreading code candidates m = 8 having a spreading code length n = 8 and selecting and using a combination of k = 2 spreading codes according to the second data string, _m C _k = ₈ C ₂ = 28 selections are possible. As a result, log ₂ 28≈4.8 bits per symbol can be transmitted by spreading code selection, and the I-phase component and Q-phase component of information modulation can be independently spread-modulated. Therefore, twice as much data can be transmitted as the second data string. In addition, when QPSK is used as orthogonal modulation, a 2-bit first-system data string can be spread-modulated for each spreading code, so that 2k = 4-bit data is transmitted as the first-system data string. Can do.
Therefore, in total, 2k + log ₂ ( _m C _k ) ≈4 + 4.8 = 8.8 bits of data can be transmitted per symbol. For each chip, 1 / n (= 1/8) of the bits can be transmitted.
[0048]
(B) When using all spreading code candidates m = 8 having a spreading code length n = 8 and selecting and using a combination of k = 3 spreading codes according to the second data string, ₈ C ₃ = 56 spreading codes can be selected, and 2k + log ₂ ( _m C _k ) = 6 + log ₂ 56≈11.8 bits of data can be transmitted per symbol, and 11.8 / per chip. n = 1.475 bits can be transmitted.
In the receiver of FIG. 1B, the comparison unit 10 detects k outputs that output peak values at the same timing from the outputs of the plurality of despreading units 9 _{1 to} 9 _m in parallel. The combined spreading code is determined. The information generation unit 12 generates data that matches the second series of data used for spreading code selection in the transmitter of FIG. 1B from the determined k spreading codes.
In the above description, the value of k is set to the same value for the I-phase component and the Q-phase component of information modulation, but can also be set independently.
[0049]
The transmission rate can be varied by combining the above first to third methods.
Also in this embodiment, the information modulation method is not particularly limited. It may be the case of only the I phase as in BPSK. In the spread modulation, the I phase and the Q phase are independently spread, but the I phase and the Q phase may be spread using the same spread code.
The method of transmitting user data by a combination of a plurality of spreading codes has been conventionally known as a “parallel combination spread spectrum communication method”. However, usable spread code candidates are fixed and the transmission rate is fixed. It is not intended to make the variable.
[0050]
Also in the second embodiment, the transmission rate (or the transmission rate and the number of users), the spreading code length n of the used spreading code candidates, the assigned number m of spreading code candidates, and the number of spreading codes used in parallel Since a certain k combination does not necessarily correspond one-to-one, a correspondence table or the like is prepared, and rate information data (or rate information data and the number of users) is simply transmitted, and m spreading code candidates and Either the value of k is set, or some control information for setting m spreading code candidates and the value of k is transmitted from the transmission side.
Alternatively, the transmission rate (or transmission rate and number of users) or each numerical value is determined on the receiver side, and the rate information data (or rate information data and number of users) or the control information described above is transmitted to the transmitter side. Each spreading code candidate and k value may be set according to the received rate information data (or rate information data and the number of users).
[0051]
In the above description, the explanation has been made on the premise that spread code candidates having different spread code lengths n are not used simultaneously. As described with reference to FIG. 14, even if the spreading code lengths n are different, those having an orthogonal relationship can be selected. Thus, the transmission rate can also be changed by combining codes having different spreading code lengths. In addition, the information modulation unit 4 can change the transmission rate even if the modulation multi-level number is changed.
[0052]
As described above, the first embodiment of the present invention can increase the transmission rate as a result as compared with the prior art. However, since the spreading code length can be made longer than the conventional one, the processing capability for multipath is also improved.
FIG. 7 is an explanatory diagram of the relationship between multipaths and spreading codes used in the first embodiment of the present invention.
In the figure, the horizontal axis represents time, and the vertical axis represents relative received power. In the same propagation path as the multipath propagation path described with reference to FIG. 16, a spreading code having a code length of 8 is shown with its spreading code period aligned with the time on the horizontal axis.
Consider the case of transmission at the same bit rate (1 bit per chip) as before. In this assumption, the 4-symbol length in the prior art corresponds to the 1-symbol length in the embodiment of the present invention.
Therefore, in the case of the embodiment of the present invention, all of the delayed waves 1 to 3 are included within one symbol length. On the other hand, in the prior art described with reference to FIG. 6, all the delayed waves 1 to 3 exceed one symbol length. Therefore, each of the delayed waves 1 to 3 becomes an interference signal unless separation using a long code or the like that is not described is performed.
[0053]
In addition, as described with reference to FIG. 16C, when code multiplexing is performed by the conventional technique, spreading code multiplexing is performed using four spreading codes, so that the first embodiment of the present invention is implemented. Similarly, all the delay waves 1 to 3 do not exceed one symbol length. However, in the embodiment of the present invention, transmission can be performed at the same bit rate without performing spreading code multiplexing, so the number of cross-correlations that need to be considered is reduced compared to the prior art. In other words, the embodiment of the present invention may be an interference cancellation circuit having a smaller scale than the prior art.
[0054]
Similarly, interference cancellation circuits such as cross-correlation caused by delayed waves of other users in the downlink, cross-correlation caused by wraparound of transmission signals of other cells, and cross-correlation caused by asynchronous users in the uplink are also provided in the first embodiment of the present invention. In this embodiment, since the number of spread codes being transmitted can be reduced, this is simplified.
[0055]
In the second embodiment of the present invention, when transmitting at the same bit rate as in the first embodiment, the length of one symbol can be further increased. In this case, since a plurality of codes are used in parallel, the amount of interference due to cross-correlation increases. However, since the number of cross-correlations that need to be considered is reduced when performing interference removal, an interference removal circuit having a smaller scale than that of the prior art may be used.
[0056]
In the above description, the values of n, m, and k described above can be changed in order to make the transmission rate variable.
However, the numerical values of n, m, and k described above can be changed to realize an object other than the change of the transmission rate. That is, even if the transmission rate is fixed, there are a plurality of combinations of the above-described numerical values. Even if the transmission rates are the same, these combinations are different in the number of users and transmission characteristics that can be used simultaneously.
[0057]
In the third embodiment of the present invention, the numerical values described above are determined according to the accuracy of transmission required for transmission data and / or the number of users to which the spreading code candidates are assigned and / or the state of the propagation path. The combination is selected.
As a result, it is not only controlled according to the transmission rate, but also adapted to the accuracy of transmission required for transmission data and / or the number of users to which the spreading code candidates are assigned and / or the situation of the propagation path It can be controlled in the form of spread spectrum.
[0058]
The accuracy of transmission required for the transmission data is expressed by a transmission error rate allowed for the transmission data, and is also related to the service type or medium of the transmission data. For example, audio data is not required to be very accurate, but computer processing data is required to be accurate. Therefore, it can be automatically determined according to the service type of transmission data or media (for example, voice data, computer processing data, still image data, moving image data).
In the case of transmission data for which accuracy is required under the condition of a constant transmission rate, for example, the above-described n may be large, k may be small, and m may be large.
In addition, the number m of spread code candidates to be allocated has to be reduced as the number of users who use spread code candidates with the same code length n increases so that transmission / reception can be performed for each user. Therefore, the mode of diffusion is controlled according to the number of users.
In addition, the condition of the propagation path means the received signal level at the receiver (the received signal level from the transmitter may be the received signal level from other transmitters), the interference wave level, the delay time of the delay wave, etc. It is represented by
When the condition of the propagation path is poor under the condition of a constant transmission rate, for example, the above-described n may be large, k may be small, and m may be large.
[0059]
The block diagram of this embodiment is not shown. However, in FIG. 1, “rate information data” may be replaced with the above-described conditions and used as information for setting the values of n, m, and k. A correspondence table between the various conditions described above and the numerical values described above may be prepared in advance. Also in this case, m spread code candidates of code length n and control information for controlling the value of k are transmitted from the transmission side to the reception side from the transmission side of the spread spectrum signal, or conversely, The control information may be transmitted from the receiver side to the transmission side. When the transmitting side or the receiving side is a base station, the base station may control the spread spectrum mode of the mobile station.
[0060]
FIG. 8 is an explanatory diagram of a combination example of a spreading code length n at which transmission rates are equal, a number m of spreading code candidates to be assigned, and k which is the number of spreading codes used in parallel.
FIG. 8A shows that one user is assigned a candidate of m = 8 = 2 ³ among spreading code candidates of spreading code length n = 16, and one spreading code is assigned to the second data string from among them. The case where it selects according to is shown. When QPSK is used as information modulation, the data bits per symbol are 3 + 3 + 2 = 8 bits, which is 0.5 bits per chip.
FIG. 8B shows that one user is assigned m = 2 = 2 ¹ candidates among spreading code candidates with a spreading code length of 8, and one spread code is assigned to the second data series from among them. Shows the selection. When QPSK is used as information modulation, the data bits per symbol are 1 + 1 + 2 = 4 bits, which is 0.5 bits per chip.
Accordingly, the transmission rates of both FIG. 8A and FIG. 8B are equal.
However, from the viewpoint of spreading gain (the number of chips per symbol), the spreading gain = 16 in the case of FIG. 8A, but 8 in the case of FIG. 8B. Therefore, the accuracy of transmission is better in FIG.
On the other hand, from the viewpoint of the number of users that can be transmitted simultaneously, the case of FIG. 8A is limited to two users, whereas in the case of FIG. 8B, it can be assigned to four users.
[0061]
Next, the first embodiment described with reference to FIG. 1 is applied to a CDMA communication system using a plurality of subcarriers, for example, a spread spectrum signal generation unit in each subcarrier of OFDM (Orthogonal Frequency-Division Multiplexing). The case of applying to this configuration will be described with reference to FIGS. The total number of subcarriers is s. The second embodiment using a combination of a plurality of spreading codes for data transmission and the third embodiment used for purposes other than making the transmission rate variable can be applied in the same manner.
[0062]
FIG. 9 is a block configuration diagram of a transmitter in the spread spectrum communication system according to the fourth embodiment of this invention.
In the figure, the same parts as those in FIG. Reference numeral 21 denotes a distribution unit. A spread spectrum signal generator 22 has the same configuration for each subcarrier. However, in the block of subcarrier 1, a rate information insertion unit 23 is provided.
Reference numeral 24 denotes an inverse fast Fourier transform processing unit, 25 denotes a parallel / serial conversion unit, and 26 denotes a guard insertion unit. Although not shown, a pilot signal for fading distortion compensation is inserted into user data for each subcarrier and subjected to inverse fast Fourier transform. Reference numeral 27 denotes a wireless circuit unit having the same configuration as that of the wireless circuit unit 7 of FIG.
[0063]
The input data is distributed by the distribution unit 21 to the channels of the subcarriers 1 to s of the spread spectrum signal generation unit 22. The rate information data is inserted for each frame in the rate information insertion unit 23 provided in the subcarrier 1.
In addition, since each frequency band is the same, the information modulation unit 4, the spread code number selection unit 5, and the spread unit 6 in all the channels of the subcarriers 1 to s are determined in advance by the rate information data. , Common information modulation rate (symbol rate; since chip rate is fixed, determined by spread code length n), common spread code candidate allocation number m (in the second embodiment, a common parallel use is further used. The number of spreading codes k) can be processed. Therefore, it is not necessary to add rate information data for each subcarrier 1 to s.
[0064]
The spread spectrum signal for each of the subcarriers 1 to s processed in this way is converted into a time signal by the inverse fast Fourier transform (inverse FFT) processing unit 24.
The signal after the inverse fast Fourier transform processing is converted into a serial signal by the parallel / serial conversion unit 25, a guard interval is inserted by the guard insertion unit 26, and transmitted through the radio circuit unit 27.
The guard interval is a process of adding data for t / N time in the latter half to the head of one processing unit for each processing unit (1 FFT symbol) of the inverse FFT. Here, the constant t indicates one FFT symbol period, and the constant N is a real number of 1 <N. In MMAC (Multimedia Mobile Access Communication system) and the like, a value of about N = 10 is used.
On the receiving side, this guard interval prevents the delayed wave from entering the subsequent inverse FFT processing unit to cause interference. Also, since this guard interval uses a part of its own signal, the frequency component is the same as the original, and the influence of insertion is small.
[0065]
FIG. 10 is a block configuration diagram of a receiver in the spread spectrum communication system according to the fourth embodiment of this invention.
In the figure, reference numeral 31 denotes a radio circuit unit, which has the same configuration as the radio circuit unit 8 of FIG. 32 is a guard removing unit, 33 is a serial / parallel conversion processing unit, 34 is a fast Fourier transform processing unit, and 35 is a rate information determination unit.
[0066]
The received signal becomes a baseband signal in the radio circuit unit 31. After the guard interval is removed by the guard removing unit 32, the serial / parallel conversion processing unit 33 performs conversion processing to a parallel signal. Thereafter, the fast Fourier transform processing unit 34 converts the signal into signals for each subcarrier.
The despreading units 9 _{1 to} 9 _m , the comparison unit 10, the information demodulation unit 11, and the information generation unit 12 are the same as those in FIG. 1, and the same configuration is provided for each of the subcarriers 1 to s.
Reference numeral 36 denotes a fading distortion compensator provided for each subcarrier 1 to s system. For example, a pilot signal inserted on the transmission side for each subcarrier 1 to s is extracted and received by fading. The phase fluctuation and amplitude fluctuation of the signal are estimated to compensate for the fading distortion that the received signal has received.
[0067]
Based on the result of the rate information data inserted into the spread spectrum signal of subcarrier 1 on the transmission side being determined by rate determination unit 35 of subcarrier 1, the processing of despreading units 9 _{1 to} 9 _{m of} subcarriers _{1 to s,} etc. Is done.
Reference numeral 37 denotes a reconstruction unit, which outputs output data obtained by reconstructing output data of all subcarriers 1 to s. Also in the reconstruction unit 37, the rate information data obtained by the rate information determination unit 35 may be used.
[0068]
FIG. 11 is an explanatory diagram of a signal format including rate information data in the fourth embodiment of the present invention shown in FIGS.
FIG. 11A and FIG. 11B show two specific examples. In any example, the relationship between transmission data and rate information data is shown for each subcarrier 1 to s.
In FIG. 11A, rate information data is inserted only in the channel of subcarrier 1 every 1 FFT symbol period.
On the other hand, in FIG. 11B, the rate information data is inserted into the data string for every 1 FFT symbol period in each of the subcarriers 1 to s.
When the same transmission rate is used for the channels of subcarriers 1 to s, it is not necessary to send rate information for each subcarrier by using the transmission format of FIG. be able to.
Different transmission rates can be used for the respective subchannels. In this case, transmission may be performed in the transmission format of FIG.
Note that the above-described rate information data is an example, and may be replaced with the control information described in the first to third embodiments.
The CDMA communication system using a plurality of subcarriers has been described as the fourth embodiment. In addition, there is a CDMA communication system using a plurality of carriers. In this system, the channel configuration of each subcarrier in FIGS. 9 and 10 may be adopted as the channel configuration of carriers 1 to s.
[0069]
The spread spectrum communication system according to the present invention can be implemented as a combination of the spread spectrum communication method of the prior art.
That is, when following the spread spectrum communication method of the prior art, transmission data is not distributed for selection of spreading codes. The selected spreading code is not changed depending on the information of the user transmission data, but is changed only by changing the transmission rate or the like according to the control method of the prior art. Even when spreading code multiplexing is performed by the control method of the prior art, a plurality of selected spreading codes are not changed depending on information of user transmission data.
[0070]
Specifically, when the spread spectrum communication method of the prior art is followed, the transmission data is directly or distributed to form first to kth (k is an integer of 1 or more) data strings, and the first to kth data strings. Information is modulated, and m = k spreading code candidates are allocated and selected from spreading code candidates of code length n (n is an integer of 2 or more), and the selected k spreading codes are used, respectively. The information modulated first to k-th data strings are spread, transmitted as a spread spectrum signal, the spread spectrum signal is received, and the spread spectrum signal is inverted using the m = k spread codes. By spreading and demodulating the despread output, the first to kth data strings are output, and the output first to kth data strings are received as they are or reconfigured. And over motor, the n, at least one value of the values of m = k, is variably controlled in accordance with a transmission rate required for the transmission data.
[0071]
Whether to follow the spread spectrum communication system according to the present invention or the spread spectrum communication method of the prior art depends on the transmission rate required for transmission data, the accuracy of transmission required for transmission data, and the number of users to which spreading code candidates are assigned. Switching may be performed according to at least one condition such as a propagation path condition.
Alternatively, when either the transmission side or the reception side is a device that can only support the spread spectrum communication method of the prior art, the other device does not follow the spread spectrum communication system according to the present invention, and The spread spectrum communication method of technology may be followed.
[0072]
【The invention's effect】
As is apparent from the above description, the present invention has the effect of reducing the number of codes to be multiplexed when performing high-speed transmission.
By suppressing the chip rate of the spreading code when performing high-speed transmission to a low speed, it is possible to reduce multipath exceeding the code period and to suppress an increase in the circuit scale of the interference removal circuit due to its own multipath.
As a result, communication at various transmission rates from high-speed data to low-speed data can be processed at a low chip rate with a small number of spreading code multiplexes.
As a result, the symbol period can be lengthened and the transmission efficiency is good, so that multipath interference due to a long-period delayed wave exceeding the symbol period can be prevented.
[Brief description of the drawings]
FIG. 1 is a block configuration diagram of a first embodiment of the present invention.
FIG. 2 is an explanatory diagram of a conversion table when one user selects one of all spread code candidates with a spread code length n = 16.
FIG. 3 is an explanatory diagram of a conversion table when one user selects one of all spread code candidates with a spread code length n = 8.
FIG. 4 is an explanatory diagram of a conversion table when two users each select one of four spreading code candidates having a spreading code length of 8;
FIG. 5 shows a conversion table when one user selects one of all spreading code candidates with spreading code length n = 4 and when one user selects one of all spreading code candidates with spreading code length n = 2. It is explanatory drawing of.
FIG. 6 is an explanatory diagram summarizing the results of studying each code length n with reference to FIGS. 2, 3, and 5 only when one user selects one of all spread code candidates. is there.
FIG. 7 is an explanatory diagram of a relationship between multipaths and spreading codes used in the first embodiment of the present invention.
FIG. 8 is an explanatory diagram of a combination example of a spreading code length n at which transmission rates are equal, a number m of assigned spreading code candidates, and a number k of spreading codes used in parallel.
FIG. 9 is a block diagram of a transmitter in a spread spectrum communication system.
FIG. 10 is a block configuration diagram of a receiver according to a fourth embodiment of the present invention.
11 is an explanatory diagram of a signal format including rate information data in the block configuration diagram shown in FIGS. 9 and 10. FIG.
FIG. 12 is a block diagram of a conventional spread spectrum communication system.
13 is an explanatory diagram of a spreading code used in the conventional spread spectrum communication system shown in FIG.
14 is an explanatory diagram of a code generation principle of the spreading code shown in FIG.
15 is an explanatory diagram of an example of autocorrelation and cross-correlation of the spreading code shown in FIG.
16 is an explanatory diagram of the relationship between the multipath in the multipath propagation path and the conventional spreading code shown in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Coding part, 2 ... Interleaving part, 3 ... Distribution part, 4 ... Information modulation part, 5 ... Spreading code selection part, 6 ... Spreading part, 7 ... Radio circuit part, 8 ... Radio circuit part, 9 ... Despreading , 10 ... comparison unit, 11 ... information demodulation unit, 12 ... information generation unit, 13 ... reconstruction unit, 14 ... deinterleave unit, 15 ... decoding unit

Claims (1)

A spread spectrum communication method for receiving a spread spectrum signal as a plurality of channels and receiving the spread spectrum signals of the plurality of channels as signals of different carriers or different subcarriers, respectively,
Transmission data distributed to a plurality of channels on the transmission side is distributed to first to (k + 1) th (k + 1) (k is an integer of 1 or more) data strings for the channel, and a code length n (n is an integer of 2 or more). K spreading codes are selected from the m spreading code candidates assigned from the spreading code candidates (m is an integer of 2 or more) according to the (k + 1) th data string, and are selected. The k-spread codes are used to spread the information-modulated signals by the first to k-th data strings, thereby obtaining the multi-channel spread spectrum signal, and the multi-channel spread spectrum signal. And m spreading codes with a code length of n inserted into one of the channels. Receiving control information for controlling the value of the auxiliary contact Yopi the k as common to the respective channels,
Despreading the received spectrum spread signal for each channel using the m spreading code candidates;
Outputting the (k + 1) th data string by specifying the k spreading codes selected at the time of transmission based on the despreading output;
Outputting the first to k-th data sequences by demodulating the despread output using the identified k spreading codes; and
Reconstructing the outputted first to k-th data strings and the (k + 1) -th data string for the plurality of channels to receive data;
And a step of variably controlling at least one of the values of n, m, and k as a value common to the respective channels according to the control information.

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