JP4313434B1 - COMMUNICATION SYSTEM, TRANSMISSION DEVICE, RECEPTION DEVICE, AND INFORMATION RECORDING MEDIUM - Google Patents

Abstract

The communication system (101) using the prime root q of the prime number p determines each row of a matrix U of p rows and p columns whose main element is a value obtained by raising the pth root of 1 according to a value determined based on q. Using the p p-dimensional vectors b [i] formed and the p p-dimensional vectors c [i] forming each row of the conjugate transpose matrix V, the transmission device (111) parallelizes the transmission signal, An inner product with each vector b [i] is taken, a guard interval is inserted, serialized and transmitted, and the receiving device (131) removes the guard interval from the received signal, synchronizes and parallelizes each vector. The inner product with c [i] is taken to obtain a serialized signal.
[Selection] Figure 7

Description

  The present invention uses CDMA (Code Division Multiple Access) and OFDM (Orthogonary Frequency Division Multiplex) by using a code having perfect orthogonality and good autocorrelation characteristics. The present invention relates to a communication system, a transmission device, a reception device, and a computer readable / writable information recording medium in which a program for realizing these on a computer is recorded.

  Conventionally, use of orthogonal codes such as Walsh codes has been proposed in technical fields such as CDMA and OFDM, while codes having sharp peaks in autocorrelation characteristics are also used. On the other hand, the inventor of the present application has proposed a chaos code as a code used for communication. Such techniques are disclosed in the literature listed later.

  Here, Patent Document 1 proposes a technique for generating an optimal chaotic spreading code sequence with a simple electronic circuit.

JP 2002-290274 A

  However, there is still a strong demand for a communication technique that can increase the number of channels by using codes with good orthogonality and autocorrelation characteristics and high diversity.

  The present invention solves the problems as described above, and uses a code having perfect orthogonality and good autocorrelation characteristics, so that CDMA and OFDM are naturally fused to improve communication performance. It is an object of the present invention to provide a computer-readable / writable information recording medium in which a communication system, a transmitting device, a receiving device, and a program for realizing these on a computer are recorded.

  In order to achieve the above object, the following invention is disclosed in accordance with the principle of the present invention.

A communication system according to a first aspect of the present invention includes:
A primitive root q of a prime number p, a predetermined angle θ, and a p-by-p matrix,
The first line is b [0] = (exp (iθ), exp (iθ), exp (iθ), ..., exp (iθ)),
The second line is b [1] = (exp (iθ), exp (2πi × q ^{0 + 0} / p), exp (2πi × q ^{1 + 0} / p), exp (2πi × q ^{2 + 0} / p ), ..., exp (2πi × q ^{p-2 + 0} / p)),
The third line is b [2] = (exp (iθ), exp (2πi × q ^{0 + 1} / p), exp (2πi × q ^{1 + 1} / p), exp (2πi × q ^{2 + 1} / p ), ..., exp (2πi × q ^{p-2 + 1} / p)),
…,
The k-th line is b [k-1] = (exp (iθ), exp (2πi × q ^{0 + k-2} / p), exp (2πi × q ^{1 + k-2} / p), exp (2πi × q ^{2 + k-2} /p),...,exp(2πi×q ^{p-2 + k-2} / p)),
…,
The p-th line is b [p-1] = (exp (iθ), exp (2πi × q ^{0 + p-2} / p), exp (2πi × q ^{1 + p-2} / p), exp (2πi × q ^{2 + p-2} /p),...,exp(2πi×q ^{p-2 + p-2} / p))
P p-dimensional vectors b [0], b [1], b [2], ..., b [p-2], b [p-1] defined by a matrix U
A conjugate transpose of the matrix U,
The first line is c [0],
The second line is c [1],
The third line is c [2],
…,
The k-th line is c [k-1]
…,
The pth line is c [p-1]
P p-dimensional vectors c [0], c [1], c [2], ..., c [p-2], c [p-1] defined by a conjugate transpose matrix V,
And having a transmission device and a reception device, and configured as follows.

  That is, the transmission device includes a serial-parallel conversion unit, a transmission-side inner product unit, an insertion unit, and a transmission unit.

  On the other hand, the receiving device includes a receiving unit, a synchronizing unit, a receiving-side inner product unit, and a parallel-serial conversion unit.

Here, the serial-to-parallel converter of the transmission device divides the signal to be transmitted into predetermined time lengths T, and performs serial-parallel conversion on each of the divided signals to generate a p-dimensional signal vector.
s = (s [0], s [1], s [2], s [3], ..., s [p-1])
Get.

On the other hand, the transmission-side inner product portion of the transmission device is obtained from the obtained signal vector s and the determined vector b [i] for each of the integers i = 0, 1, 2,... (P−1). ,inner product
w [i] = 〈s, b [i]〉
Calculate

  Further, the insertion unit of the transmission device inserts a guard interval between the calculated inner products w [0], w [1], w [2],. Signal.

  And the transmission part of a transmitter transmits the signal with which the guard interval was inserted.

  The receiving unit of the receiving device receives a signal transmitted from the transmitting device.

On the other hand, the synchronization unit of the reception device refers to the guard interval inserted in the received signal, and calculates the inner product calculated for each of the signals divided by the predetermined time length T in the transmission device.
w [0], w [1], w [2], ..., w [p-1]
Received value synchronized to
u [0], u [1], u [2], ..., u [p-1]
Get.

Furthermore, the receiving-side inner product section of the receiving device, for each of the integers i = 0, 1, 2,..., (P−1), the received value u [i] obtained and the determined p-dimensional vector c [ i], and inner product
v [i] = 〈u [i], c [i]〉
Calculate

  The parallel-to-serial converter of the receiving device then calculates a signal obtained by dividing the calculated inner product v [0], v [1], v [2],..., V [p-1] for each predetermined time length T. As a result, the transmitted signal is obtained.

In the communication system of the present invention, as the matrix U,
The first line is b [0] = (exp (iθ), exp (iθ), exp (iθ), ..., exp (iθ)),
The second line is b [1] = (exp (iθ), exp (2πi × 1 × q ⁰ / p), exp (2πi × 2 × q ⁰ / p), exp (2πi × 3 × q ⁰ / p ), ..., exp (2πi × (p-1) × q ⁰ / p)),
The third line is b [2] = (exp (iθ), exp (2πi × 1 × q ¹ / p), exp (2πi × 2 × q ¹ / p), exp (2πi × 3 × q ¹ / p ), ..., exp (2πi × (p-1) × q ¹ / p)),
…,
The k-th line is b [k-1] = (exp (iθ), exp (2πi × 1 × q ^k-2 / p), exp (2πi × 2 × q ^k-2 / p), exp (2πi × 3 × q ^k-2 / p),…, exp (2πi × (p-1) × q ^k-2 / p)),
…,
The p-th line is b [p-1] = (exp (iθ), exp (2πi × 1 × q ^p-2 / p), exp (2πi × 2 × q ^p-2 / p), exp (2πi × 3 × q ^p-2 / p),…, exp (2πi × (p-1) × q ^p-2 / p))
A matrix can be used.

  In the communication system of the present invention, (p-1) / 2 can be configured to be a prime number.

Further, in the communication system of the present invention, p is configured to be a prime number obtained by adding 1 to the power of 2, that is, a prime number for which p = 2 ⁿ +1 is established using a certain integer n. Can do.

  Also, in the communication system of the present invention, each of the different primitive roots for the prime number p is assigned to a plurality of users, and the transmitting device and the receiving device associated with each of the plurality of users are assigned to the primitive roots. Can be configured as the primitive root q.

  Further, in the communication system of the present invention, the receiving device assumes that each of the primitive roots that are not assigned to an existing user among the different primitive roots for the prime number p is the primitive root q, and the inner product v [0], Find v [1], v [2], ..., v [p-1], and minimize the power of the inner product v [0], v [1], v [2], ..., v [p-1] Can be configured to acquire a primitive root q to be assigned to a new user.

  The communication system of the present invention can be configured as follows.

  That is, each of the different primitive roots for the prime number p is assigned to a plurality of users, and the transmitting apparatus associated with each of the plurality of users sets the primitive root assigned to the user as the primitive root q.

  On the other hand, the receiving device obtains inner products v [0], v [1], v [2],..., V [p-1], assuming that each of the different primitive roots is the primitive root q, A primitive root having the maximum power of the inner product v [0], v [1], v [2], ..., v [p-1] is acquired, and the acquired primitive root is defined as a primitive root q.

  A transmission device according to another aspect of the present invention is the transmission device of the communication system.

  A receiving device according to another aspect of the present invention is a receiving device of the communication system.

  A computer-readable information recording medium according to another aspect of the present invention is configured to record a program that causes a computer having a communication function to function as the transmission device.

  A computer-readable information recording medium according to another aspect of the present invention is configured to record a program that causes a computer having a communication function to function as the receiving device.

  The computer-readable information recording medium uses, for example, the same type as a compact disk, the same type as a flexible disk, a hard disk, a magneto-optical disk, the same type as a digital video disk, a magnetic tape, or a semiconductor memory can do.

  The information recording medium can be distributed and sold independently of the computer, and the program itself can be distributed and sold via a computer communication network such as the Internet.

  The present invention is the result of research and development under the theme “Research and development of ICA communication chip” adopted by the New Energy and Industrial Technology Development Organization (NEDO) 2005 Second Industrial Technology Research Grant Program. It is such a thing.

  According to the present invention, a communication system, a transmission device, and a reception suitable for improving communication performance by naturally merging CDMA and OFDM by using a code having perfect orthogonality and good autocorrelation characteristics. It is possible to provide an apparatus and a computer-readable information recording medium in which a program for realizing these on a computer is recorded.

It is a code transition diagram of prime number p = 59 and primitive root q = 31. FIG. 5 is a code transition diagram of a prime number p = 59 and a primitive root q = 11. FIG. 6 is a code transition diagram of a prime number p = 173 and a primitive root q = 11. FIG. 6 is a code transition diagram of a prime number p = 173 and a primitive root q = 3. It is a graph which shows the magnitude | size of the element of the product of the matrix U and conjugate transpose matrix V in case of prime numbers p = 59 and q = 2. It is a graph which shows the magnitude | size of the element of the product of the matrix U in the case of prime numbers p = 59 and q = 2, and the matrix V in the case of prime numbers p = 59 and q = 6. It is explanatory drawing which shows schematic structure of the communication system which concerns on one of embodiment of this invention. It is explanatory drawing which shows the process in which the signal is converted in the said embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 Communication system 111 Transmission apparatus 112 Serial / parallel conversion part 113 Transmission side inner product part 114 Insertion part 115 Transmission part 131 Reception apparatus 132 Reception part 133 Synchronization part 134 Reception side inner product part 135 Parallel / serial conversion part 601 Signal to be transmitted 602 Signal vector 603 Inner product value vector 604 transmitted signal 605 received signal 606 received value vector 607 inner product value vector 608 transmitted signal 651 guard interval 652 received guard interval

  Embodiments of the present invention will be described below. The embodiments described below are for illustrative purposes and do not limit the scope of the present invention. Accordingly, those skilled in the art can employ embodiments in which each or all of these elements are replaced with equivalent ones, and these embodiments are also included in the scope of the present invention. .

  In the present embodiment, a chaos code that takes a value on a unit circle of the complex plane is used as the orthogonal code. The method of generating the chaos code was devised by the inventor of the present application. This will be described in detail below.

For some prime p, a set for some integer q {q ⁰ mod p, q ¹ mod p, q ² mod p, ..., q ^p-2 mod p}
Is a set of (p-1) natural numbers {1, 2, 3, ..., p-1}
, That is, the domain is {1, 2, 3, ..., p-1}
Map
f _{p, q} (k) = q ^k-1 mod p
The range of is also {1, 2, 3, ..., p-1}
If the map f _{p, q} (·) is bijective, the integer q is called the primitive root of the prime number p.

The map f _{p, q} (·) can be thought of as a permutation that rearranges the order of natural numbers from 1 to p-1. For example, if p = 61, q = 2, and k = 1, 2, ..., p-1 = 60, f _{p, q} (k) is calculated in order,
1,2,4,8,16,32,3,6,12,24,48,35,9,
18,36,11,22,44,27,54,47,33,5,10,
20,40,19,38,15,30,60,59,57,53,45,
29,58,55,49,37,13,26,52,43,25,50,
39,17,34,7,14,28,56,51,41,21,42,
23,46,31
The natural numbers from 1 to 60 are rearranged.

In general, the number of primitive roots q of prime number p is given by φ (p−1) by Euler's tortient function φ (•). When the prime number p is moved from 2 to 1223, the pair (p, φ (p-1)) of the prime number p and the number of primitive roots q (p-1) is as follows.
(2,1), (3,1), (5,2) ^* , (7,2) ^* , (11,4) ^* ,
(13,4), (17,8) ^* , (19,6), (23,10) ^* , (29,12),
(31,8), (37,12), (41,16), (43,12), (47,22) ^* ,
(53,24), (59,28) ^* , (61,16), (67,20), (71,24),
(73,24), (79,24), (83,40) ^* , (89,40), (97,32),
(101,40), (103,32), (107,52) ^* , (109,36), (113,48),
(127,36), (131,48), (137,64), (139,44), (149,72) ^* ,
(151,40), (157,48), (163,54), (167,82) ^* , (173,84),
(179,88) ^* , (181,48), (191,72), (193,64), (197,84),
(199,60), (211,48), (223,72), (227,112) ^* , (229,72),
(233,112), (239,96), (241,64), (251,100), (257,128) ^* ,
(263,130) ^* , (269,132), (271,72), (277,88), (281,96),
(283,92), (293,144), (307,96), (311,120), (313,96),
(317,156), (331,80), (337,96), (347,172) ^* , (349,112),
(353,160), (359,178) ^* , (367,120), (373,120), (379,108),
(383,190) ^* , (389,192), (397,120), (401,160), (409,128),
(419,180), (421,96), (431,168), (433,144), (439,144),
(443,192), (449,192), (457,144), (461,176), (463,120),
(467,232) ^* , (479,238) ^* , (487,162), (491,168), (499,164),
(503,250) ^* , (509,252), (521,192), (523,168), (541,144),
(547,144), (557,276), (563,280) ^* , (569,280), (571,144),
(577,192), (587,292) ^* , (593,288), (599,264), (601,160),
(607,200), (613,192), (617,240), (619,204), (631,144),
(641,256), (643,212), (647,288), (653,324), (659,276),
(661,160), (673,192), (677,312), (683,300), (691,176),
(701,240), (709,232), (719,358) ^* , (727,220), (733,240),
(739,240), (743,312), (751,200), (757,216), (761,288),
(769,256), (773,384), (787,260), (797,396), (809,400),
(811,216), (821,320), (823,272), (827,348), (829,264),
(839,418), (853,280), (857,424), (859,240), (863,430),
(877,288), (881,320), (883,252), (887,442) ^* , (907,300),
(911,288), (919,288), (929,448), (937,288), (941,368),
(947,420), (953,384), (967,264), (971,384), (977,480),
(983,490), (991,240), (997,328), (1009,288), (1013,440),
(1019,508) ^* , (1021,256), (1031,408), (1033,336), (1039,344),
(1049,520), (1051,240), (1061,416), (1063,348), (1069,352),
(1087,360), (1091,432), (1093,288), (1097,544), (1103,504),
(1109,552), (1117,360), (1123,320), (1129,368), (1151,440),
(1153,384), (1163,492), (1171,288), (1181,464), (1187,592) ^* ,
(1193,592), (1201,320), (1213,400), (1217,576), (1223,552)

Among these, the pair with ^* is considered to be an “excellent” pair in which the number φ (p−1) of the primitive root q with respect to the prime number p is relatively large.

  For example, for a prime number p, if (p-1) / 2 is also a prime number, the number of primitive roots q is on the order of (p-3) / 2, ie about p / 2.

  Now, consider a p-by-p matrix U defined by a prime number p and its primitive root q, and its conjugate transpose matrix V.

The matrix U is defined using a predetermined angle θ and an imaginary unit i, and may have the following two modes.
(1) The first aspect is
The first line is b [0] = (exp (iθ), exp (iθ), exp (iθ), ..., exp (iθ)),
The second line is b [1] = (exp (iθ), exp (2πi × q ^{0 + 0} / p), exp (2πi × q ^{1 + 0} / p), exp (2πi × q ^{2 + 0} / p ), ..., exp (2πi × q ^{p-2 + 0} / p)),
The third line is b [2] = (exp (iθ), exp (2πi × q ^{0 + 1} / p), exp (2πi × q ^{1 + 1} / p), exp (2πi × q ^{2 + 1} / p ), ..., exp (2πi × q ^{p-2 + 1} / p)),
…,
The k-th line is b [k-1] = (exp (iθ), exp (2πi × q ^{0 + k-2} / p), exp (2πi × q ^{1 + k-2} / p), exp (2πi × q ^{2 + k-2} /p),...,exp(2πi×q ^{p-2 + k-2} / p)),
…,
The p-th line is b [p-1] = (exp (iθ), exp (2πi × q ^{0 + p-2} / p), exp (2πi × q ^{1 + p-2} / p), exp (2πi × q ^{2 + p-2} /p),...,exp(2πi×q ^{p-2 + p-2} / p))
Is a matrix.
(2) The second aspect is
The first line is b [0] = (exp (iθ), exp (iθ), exp (iθ), ..., exp (iθ)),
The second line is b [1] = (exp (iθ), exp (2πi × 1 × q ⁰ / p), exp (2πi × 2 × q ⁰ / p), exp (2πi × 3 × q ⁰ / p ), ..., exp (2πi × (p-1) × q ⁰ / p)),
The third line is b [2] = (exp (iθ), exp (2πi × 1 × q ¹ / p), exp (2πi × 2 × q ¹ / p), exp (2πi × 3 × q ¹ / p ), ..., exp (2πi × (p-1) × q ¹ / p)),
…,
The k-th line is b [k-1] = (exp (iθ), exp (2πi × 1 × q ^k-2 / p), exp (2πi × 2 × q ^k-2 / p), exp (2πi × 3 × q ^k-2 / p),…, exp (2πi × (p-1) × q ^k-2 / p)),
…,
The p-th line is b [p-1] = (exp (iθ), exp (2πi × 1 × q ^p-2 / p), exp (2πi × 2 × q ^p-2 / p), exp (2πi × 3 × q ^p-2 / p),…, exp (2πi × (p-1) × q ^p-2 / p))
Is a matrix.

  Typically, θ = 0. The elements other than the first row and the first column of the matrix are all powers of “1 complex p-th root”.

  Thus, for a matrix U defined by p p-dimensional vectors b [0], b [1], b [2], ..., b [p-2], b [p-1] The conjugate transpose matrix V is uniquely determined.

On the other hand, the first row of the conjugate transpose matrix V is c [0],
The second line is c [1],
The third line is c [2],
…,
The k-th line is c [k-1]
…,
The pth line is c [p-1]
In this way, it is associated with p p-dimensional vectors c [0], c [1], c [2], ..., c [p-2], c [p-1].

  When these vectors are adopted as codes, each component takes a value on a unit circle on the complex plane, so that it is clearly a code with constant power.

Moreover, in these aspects, all about the inner product,
<B [k], c [k]> = p
If i ≠ j, the inner product is
<B [i], c [j]> = 0
Is established.

  That is, a complex square matrix obtained by multiplying the matrix U in these modes by (1 / √p), or a complex square matrix obtained by multiplying the conjugate transpose matrix V by (1 / √p) is a unitary matrix that is a complex orthogonal matrix. Become.

  FIG. 5 is a graph showing the size of the element of the product of the matrix U and the conjugate transpose matrix V when the prime numbers p = 59 and q = 2.

  FIG. 6 is a graph showing the size of the element of the product of the matrix U when the prime numbers p = 59 and q = 2 and the matrix V when the prime numbers p = 59 and q = 6.

  Hereinafter, the properties of the matrices U and V generated in this way will be described with reference to these drawings.

  As is clear from FIG. 5, the product of the matrix U and its conjugate transpose matrix V has a non-zero diagonal component and zero other components, and when used for communication, the original signal is restored. It will be possible.

  On the other hand, FIG. 6 shows the product of a matrix U made from different primitive roots and a conjugate transpose matrix V.

  In these figures, normalization is performed so that the size of the diagonal component is 1.

  As is apparent from FIG. 6, the component of the first row and the first column has a size p, which is the same as the diagonal component of the product of FIG. Is small enough to be discriminated from p.

  Therefore, it can be seen that signal separation is sufficiently possible even when a plurality of users communicate simultaneously using different primitive roots. Note that when the value of the prime number p is increased, the size of elements other than the first row and first column of the matrix as shown in FIG. 6 is relatively decreased. Therefore, the larger p is, the higher the separation performance is.

Therefore, on the sending side, p data
b [0], b [1], ..., b [p-1]
On the receiving side
c [0], c [1], ..., c [p-1]
The original p data can be obtained by converting with.

  Thus, the inventor succeeded in creating p complex vectors that are completely orthogonal to each other in the p dimension from the prime number p and its primitive root q.

The number of orthogonal vector systems is given by the number of primitive roots q. Therefore, the larger the number of primitive roots q, the greater the number of channels used simultaneously during communication. From this point of view, what is more suitable as the prime number p is considered to be an “excellent” pair with the above ^* added.

It was also found that the elements of vectors b [1], b [2], ..., b [p-2] have chaotic properties related to the recurrence formula based on the Chebyshev polynomial T _q (·). The movement of the elements of the code of the present invention is chaotic. The Chaos Lyapunov exponent and Kolomogorov Sinai entropy are known to be Log q, and for the same prime p, if the primitive root q is different, orthogonal vectors with different chaotic behavior can be obtained. is there.

Of the above “excellent” pairs, (5,2), (17,8), and (257,128) are prime numbers p obtained by adding 1 to the power of 2, that is, p = ²ⁿ + It can be expressed as 1. When such a prime number p is adopted, if the elements of the above vector are arranged on the unit circumference, they are arranged at the apex of a regular p-gon that can be drawn with a compass and a triangle ruler, but the number of primitive roots is Since (p-1) / 2, there are relatively many types of primitive roots, which are “excellent”.

  In the following, the properties of this code will be further considered while showing a transition diagram of this code.

  FIG. 1 is a code transition diagram of a prime number p = 59 and a primitive root q = 31. FIG. 2 is a code transition diagram of a prime number p = 59 and a primitive root q = 11. FIG. 3 is a code transition diagram of a prime number p = 173 and a primitive root q = 11. FIG. 4 is a code transition diagram of a prime number p = 173 and a primitive root q = 3. Hereinafter, description will be given with reference to these drawings.

  These figures are diagrams in which the codes obtained by the above method are connected by points on the complex plane.

  Orthogonal vectors can be obtained for the discrete Fourier transform used in OFDM, and the same figure can be drawn, but the figure in that case is a figure with extremely high rotational symmetry. That is, when the figure is rotated, the rotation angle that overlaps the original shape is small, and when the figure is rotated 360 degrees, the figure is almost overlapped many times. Here, the fact that conventional orthogonal codes generally have poor autocorrelation characteristics is due to the high rotational symmetry of the code state transition diagram.

  On the other hand, as can be seen from FIGS. 1 to 4, the transition destination points are uniformly distributed on the circumference of the unit circle, but are asymmetric with respect to rotation. That is, the rotational symmetry is much lower than the transition diagram of orthogonal codes used in OFDM. That is, in the process of rotating the figure 360 degrees, the number of times of overlapping with the original figure is extremely small, from 1 to several times.

  Therefore, it can be seen that the autocorrelation characteristic of this code is better than that of a conventional general orthogonal code because of its asymmetry with respect to the rotation.

When a specific calculation is performed, the autocorrelation characteristics for b [0], b [1], ..., b [p-2] and c [0], c [1], ..., c [p-2] are Regardless of the code length p, the square of the absolute value of the second peak is known to be (2√2) ² = 8 or less.

  Considering that the square of the absolute value of the maximum peak is equal to the square of the code length p, the maximum peak and the second peak can be sufficiently separated if a sufficiently large value is adopted as the prime number p.

  For example, when p = 59, the square of the absolute value of the second peak is about 1/500 of the square of the absolute value of the maximum peak. Even if p = 5, it is about one third.

  Thus, it can be said that the autocorrelation characteristic by this code is extremely good as compared with the conventional method.

  It is known from the calculation that the correlation characteristics between vectors generated when different primitive roots q are selected for the same prime number p.

  For example, for a prime number p = 59, a vector with a primitive root 6 (except for a vector with all 1 elements) and all vectors with a primitive root 2 (with all 1 elements) The maximum absolute value of the cross-correlation between them is 14.93.

  For prime number p = 59, a vector with primitive root 2 selected (except for vectors with all 1 elements) and all vectors with primitive root 10 selected (vectors with all elements 1) The maximum absolute value of cross-correlation is 14.99.

  These are sufficiently smaller than the code length 59.

  Therefore, when a certain prime number p is selected, different primitive roots are assigned to each user, and when each user communicates with a maximum of p-1 channels, this code exhibits extremely good communication performance. I understand that.

  Hereinafter, a specific configuration of the communication system will be described.

  FIG. 5 is an explanatory diagram showing a schematic configuration of a communication system according to one embodiment of the present invention. Hereinafter, a description will be given with reference to FIG.

  A communication system 101 shown in the figure includes a transmission device 111 and a reception device 131.

  Here, the communication system 101 uses a primitive root q having a certain prime number p. The p and q can be appropriately selected as described above.

  On the transmitting device 111 side, p p-dimensional vectors b [0], b [1], b [2],..., B [p-2] representing each row of the matrix U defined as described above. , B [p-1].

  On the other hand, on the receiving apparatus 131 side, p-dimensional vectors c [0], c [1], c [2],..., C [p-2], c [p representing each row of the conjugate transpose matrix V of the matrix U are provided. -1].

  a matrix of b [0], b [1], b [2], ..., b [p-2], b [p-1] and c [0], c [1], c [2] ,..., C [p-2], c [p-1] and the product of the matrix, the value of the diagonal element is p, and the other elements are 0 or extremely small values.

  Therefore, instead of the above definition, each vector element may be multiplied by an appropriate non-zero constant. To multiply by a constant is simply to change the scale of the numerical value.

  The transmission device 111 includes a serial-parallel conversion unit 112, a transmission-side inner product unit 113, an insertion unit 114, and a transmission unit 115.

  On the other hand, the reception device 131 includes a reception unit 132, a synchronization unit 133, a reception-side inner product unit 134, and a parallel / serial conversion unit 135.

Here, the serial-parallel conversion unit 112 of the transmission device 111 divides a signal to be transmitted into predetermined time lengths T, and performs serial-parallel conversion on each of the divided signals to generate a p-dimensional signal vector.
s = (s [0], s [1], s [2], s [3], ..., s [p-1])
Get.

  FIG. 6 is an explanatory diagram illustrating a process in which a signal is converted. Hereinafter, a description will be given with reference to FIG.

  Typically, the signal 601 to be transmitted includes p signal values per predetermined time length T. The signal 601 to be transmitted is a binary signal consisting of +1 and -1 as values, or a binary signal consisting of +1 and 0 as values, as well as a variety of 16QAM using a combination of amplitude and phase. Various signals can be used such as a signal converted by a value signal.

  This signal value is converted into a signal vector 602 composed of p signal values s [0], s [1], s [2], s [3],..., S [p−1] having a predetermined time length T. Will do.

On the other hand, the transmission-side inner product unit 113 of the transmission device 111 has the obtained signal vector s and the determined vector b [i] for each of the integers i = 0, 1, 2,..., (P−1). From, inner product
w [i] = 〈s, b [i]〉
Calculate This calculation may be performed every predetermined time length T. From the transmission-side inner product unit 113, an inner product value consisting of p inner product values w [0], w [1], w [2], w [3],. A vector 603 is output.

  Next, the insertion unit 114 of the transmission device 111 inserts a guard interval between the calculated inner products w [0], w [1], w [2],. A long T signal is assumed.

  The insertion unit 114 performs a kind of parallel-serial conversion function, and converts p inner product value vectors 603 into signal values of one transmission signal 604. However, a guard interval is inserted as appropriate so that the receiver 131 can be synchronized.

  In the example shown in the figure, one guard interval 651 is inserted at the end of the predetermined time length T, but each inner product w [0], w [1], w [2], ..., w [p-1 You may employ | adopt the method of inserting suitably between].

  And the transmission part 115 of the transmitter 111 transmits the transmission signal 604 in which the guard interval was inserted.

  In addition, the reception unit 132 of the reception device 131 receives the reception signal 605 in which the transmission signal 604 transmitted from the transmission device 111 has changed due to the influence of the radio wave propagation path.

On the other hand, the synchronization unit 133 of the reception device 131 refers to the guard interval 652 that is a result of the influence of the radio wave propagation path on the guard interval 651 in the transmission signal 604 from the received signal 605. The inner product calculated for each of the signals divided for each predetermined time length T
w [0], w [1], w [2], ..., w [p-1]
Received value synchronized to
u [0], u [1], u [2], ..., u [p-1]
Get.

  As described above, since the guard interval is inserted with the period T, it is possible to achieve synchronization by correlating the elapsed time of the received signal with the time distribution of the guard interval.

  The received values u [0], u [1], u [2],..., U [p−1] are p signals 606 (received value vector u) having a predetermined time length T.

Further, the receiving-side inner product unit 134 of the receiving device 131 uses the obtained received value u [i] and the determined p-dimensional vector for each of the integers i = 0, 1, 2,... (P−1). c [i] and inner product
v [i] = 〈u [i], c [i]〉
Calculate

  This inner product calculation is performed every predetermined time length T as in the transmission-side inner product unit 113, and p signals v [0], v [1], v [2],. 607 (inner product value vector v) is obtained.

  Then, the receiving-side inner product unit 134 of the receiving device 131 divides the calculated inner products v [0], v [1], v [2],..., V [p−1] for each predetermined time length T. The signal is parallel-to-serial converted as a signal to obtain a transmitted signal 608.

  This signal 608 is equivalent to a binary signal or a multi-level signal, and it is common that the phase and the amplitude are shifted due to the influence of the radio wave propagation path. Various known techniques can be applied.

  As described above, the communication system 101 performs an operation of taking an inner product with a vector consisting of a value representing a unit circle point as described above, instead of the Fourier transform in OFDM. You can think of it as a natural fusion.

  In the various calculation processes related to these communications, an electronic circuit such as an FPGA (Field Programmable Gate Array) or an ASIC (Application Specific Integrate Circuit) is loaded with a predetermined program (corresponding to a design drawing of the electronic circuit). It can be implemented by applying software radio technology or the like.

  In addition, by executing the program on a normal computer or the like, the serial-parallel conversion unit 112, the transmission-side inner product unit 113, and the insertion unit 114 of the transmission device 111 are calculated, the synchronization unit 133 of the reception device 131, and the reception-side inner product. Unit 134 and parallel-serial converter 135 can be calculated. In this case, the transmission unit 115 and the reception unit 132 are realized by a wireless communication module connected to the computer.

  Hereinafter, embodiments in which the above embodiment is modified or applied will be described.

  In the above embodiment, the pair of the transmission device 111 and the reception device 131 in which the primitive root q with respect to the prime number p is fixed is considered, but multi-user communication can be handled using the same prime number. This can be considered to correspond to OFDMA (Orthogonal Frequency Division Multiple Access).

  As described above, the number of primitive roots with respect to the prime number p is φ (p−1), and the prime number p having a large number of primitive roots can be selected as described above.

That is, the primitive root for some prime number p
q ₁ , q ₂ , ..., q _{φ (p-1)}
Are assigned to different users so as not to overlap each other.

Transmission is performed using the primitive root q _i assigned to itself as the primitive root q in the above embodiment.

In addition, the reception device 131 performs reception using each of the primitive roots assigned to each user among q ₁ , q ₂ ,..., Q _{φ (p−1)} as the primitive root q in the above embodiment. Do.

  By performing such processing, a function corresponding to OFDMA can be realized in transmission from a large number of mobile terminals (corresponding to the transmitting device 111) to the base station (corresponding to the receiving device 131). .

  In addition, for the transmission from the base station to each of a large number of mobile terminals, the reverse process to the above may be performed.

  Thus, by determining one prime number p, it is possible to realize a multi-user communication system that can handle the total number of users up to φ (p−1).

  In such a communication system, the number of users may change dynamically. At this time, in order to determine a primitive root to be assigned to a new user on the base station side, the following is performed.

  That is, among the different primitive roots for the prime number p, for each of the primitive roots that are not assigned to existing users, the inner product v [0], v [1 ], V [2], ..., v [p-1] are obtained. Next, the power of the inner product v [0], v [1], v [2], ..., v [p-1] is obtained.

  The power is typically the sum of the squares of v [0], v [1], v [2], ..., v [p-1], or the sum of the squares of their absolute values. Yes, corresponding to the correlation value in the current communication situation.

  And the primitive root with the minimum said power is acquired. Since this primitive root has the smallest correlation in the current radio wave propagation path state, it can be considered that interference and the like are least likely to occur.

  Then, the acquired primitive root is set as a primitive root q to be assigned to a new user.

  When the primitive root to be assigned to the user is determined in this way, the transmission root 111 and the reception apparatus 131 for the user define the primitive root defined as the primitive root q, and the vectors b [0] and b [ Communication can be performed by initializing 1], ..., b [p-1] and vectors c [0], c [1], ..., c [p-1].

  When performing such multi-user communication, if the prime p is selected such that (p-1) / 2 is also a prime, the number of primitive roots q becomes (p-3) / 2, It becomes possible to deal with a large number of users.

At this time, the base station which is the receiving device 131 is connected to any one of the plurality of transmitting devices 111 associated with each of the primitive roots q ₁ , q ₂ ,..., Q _{φ (p−1).} When communicating, each of q ₁ , q ₂ ,..., Q _{φ (p−1)} is received as the primitive root q of the above embodiment, and then the inner product v [0] as in the above embodiment. , V [1], v [2], ..., v [p-1].

  Then, the primitive root having the maximum power may be estimated to be the primitive root q used by the transmitting apparatus 111 that is currently communicating, and the shift reception process and the communication process may be performed.

  Note that the present application is based on the international application PCT / JP2008 / 062865 (the basic application was filed on July 16, 2008 with Japan as the receiving Office and all Contracting States as designated countries). The content of the basic application shall be incorporated into the present application as long as the laws of the designated country permit.

  As described above, according to the present invention, communication suitable for improving communication performance by naturally merging CDMA and OFDM by using a code having perfect orthogonality and good autocorrelation characteristics. It is possible to provide a system, a transmission device, a reception device, and a computer-readable information recording medium in which a program that realizes these on a computer is recorded.

Claims (11)

A primitive root q of a prime number p, a predetermined angle θ, and a p-by-p matrix,
The first line is b [0] = (exp (iθ), exp (iθ), exp (iθ), ..., exp (iθ)),
The second line is b [1] = (exp (iθ), exp (2πi × q ^{0 + 0} / p), exp (2πi × q ^{1 + 0} / p), exp (2πi × q ^{2 + 0} / p ), ..., exp (2πi × q ^{p-2 + 0} / p)),
The third line is b [2] = (exp (iθ), exp (2πi × q ^{0 + 1} / p), exp (2πi × q ^{1 + 1} / p), exp (2πi × q ^{2 + 1} / p ), ..., exp (2πi × q ^{p-2 + 1} / p)),
…,
The k-th line is b [k-1] = (exp (iθ), exp (2πi × q ^{0 + k-2} / p), exp (2πi × q ^{1 + k-2} / p), exp (2πi × q ^{2 + k-2} /p),...,exp(2πi×q ^{p-2 + k-2} / p)),
…,
The p-th line is b [p-1] = (exp (iθ), exp (2πi × q ^{0 + p-2} / p), exp (2πi × q ^{1 + p-2} / p), exp (2πi × q ^{2 + p-2} /p),...,exp(2πi×q ^{p-2 + p-2} / p))
P p-dimensional vectors b [0], b [1], b [2], ..., b [p-2], b [p-1] defined by a matrix U
A conjugate transpose of the matrix U,
The first line is c [0],
The second line is c [1],
The third line is c [2],
…,
The k-th line is c [k-1]
…,
The pth line is c [p-1]
P p-dimensional vectors c [0], c [1], c [2], ..., c [p-2], c [p-1] defined by a conjugate transpose matrix V,
Use
A communication system (101) having a transmission device (111) and a reception device (131),
(A) The transmitting device (111)
A signal to be transmitted is divided every predetermined time length T, and each of the divided signals is serial-parallel converted to be a p-dimensional signal vector.
s = (s [0], s [1], s [2], s [3], ..., s [p-1])
A serial-parallel converter (112) for obtaining
For each of the integers i = 0, 1, 2,..., (P−1), an inner product is obtained from the obtained signal vector s and the determined vector b [i].
w [i] = 〈s, b [i]〉
Transmitting side inner product part (113) for calculating
An insertion unit (114) that inserts a guard interval between the calculated inner products w [0], w [1], w [2],..., W [p−1] to obtain a signal having the predetermined time length T. ),
Transmitter (115) for transmitting a signal with the guard interval inserted
With
(B) The receiver (131)
A receiver (132) for receiving a signal transmitted from the transmitter (111);
Referring to the guard interval inserted in the received signal, the inner product calculated for each of the signals divided for each predetermined time length T in the transmitter (111)
w [0], w [1], w [2], ..., w [p-1]
Received value synchronized to
u [0], u [1], u [2], ..., u [p-1]
Synchronization unit (133) to obtain
For each of the integers i = 0, 1, 2,..., (P−1), the inner product is obtained from the obtained received value u [i] and the determined p-dimensional vector c [i].
v [i] = 〈u [i], c [i]〉
Receiving inner product part (134) for calculating
The calculated inner product v [0], v [1], v [2],..., V [p-1] is converted into a parallel signal after being divided into predetermined time lengths T and transmitted. Parallel to serial converter (135) for obtaining signals
A communication system (101) comprising: A primitive root q of a prime number p, a predetermined angle θ, and a p-by-p matrix,
The first line is b [0] = (exp (iθ), exp (iθ), exp (iθ), ..., exp (iθ)),
The second line is b [1] = (exp (iθ), exp (2πi × 1 × q ⁰ / p), exp (2πi × 2 × q ⁰ / p), exp (2πi × 3 × q ⁰ / p ), ..., exp (2πi × (p-1) × q ⁰ / p)),
The third line is b [2] = (exp (iθ), exp (2πi × 1 × q ¹ / p), exp (2πi × 2 × q ¹ / p), exp (2πi × 3 × q ¹ / p ), ..., exp (2πi × (p-1) × q ¹ / p)),
…,
The k-th line is b [k-1] = (exp (iθ), exp (2πi × 1 × q ^k-2 / p), exp (2πi × 2 × q ^k-2 / p), exp (2πi × 3 × q ^k-2 / p),…, exp (2πi × (p-1) × q ^k-2 / p)),
…,
The p-th line is b [p-1] = (exp (iθ), exp (2πi × 1 × q ^p-2 / p), exp (2πi × 2 × q ^p-2 / p), exp (2πi × 3 × q ^p-2 / p),…, exp (2πi × (p-1) × q ^p-2 / p))
P p-dimensional vectors b [0], b [1], b [2], ..., b [p-2], b [p-1] defined by a matrix U
A conjugate transpose of the matrix U,
The first line is c [0],
The second line is c [1],
The third line is c [2],
…,
The k-th line is c [k-1]
…,
The pth line is c [p-1]
P p-dimensional vectors c [0], c [1], c [2], ..., c [p-2], c [p-1] defined by a conjugate transpose matrix V,
Use
A communication system (101) having a transmission device (111) and a reception device (131),
(A) The transmitting device (111)
A signal to be transmitted is divided every predetermined time length T, and each of the divided signals is serial-parallel converted to be a p-dimensional signal vector.
s = (s [0], s [1], s [2], s [3], ..., s [p-1])
A serial-parallel converter (112) for obtaining
For each of the integers i = 0, 1, 2,..., (P−1), an inner product is obtained from the obtained signal vector s and the determined vector b [i].
w [i] = 〈s, b [i]〉
Transmitting side inner product part (113) for calculating
An insertion unit (114) that inserts a guard interval between the calculated inner products w [0], w [1], w [2],..., W [p−1] to obtain a signal having the predetermined time length T. ),
Transmitter (115) for transmitting a signal with the guard interval inserted
With
(B) The receiver (131)
A receiver (132) for receiving a signal transmitted from the transmitter (111);
Referring to the guard interval inserted in the received signal, the inner product calculated for each of the signals divided for each predetermined time length T in the transmitter (111)
w [0], w [1], w [2], ..., w [p-1]
Received value synchronized to
u [0], u [1], u [2], ..., u [p-1]
Synchronization unit (133) to obtain
For each of the integers i = 0, 1, 2,..., (P−1), the inner product is obtained from the obtained received value u [i] and the determined p-dimensional vector c [i].
v [i] = 〈u [i], c [i]〉
Receiving inner product part (134) for calculating
The calculated inner product v [0], v [1], v [2],..., V [p-1] is converted into a parallel signal after being divided into predetermined time lengths T and transmitted. Parallel to serial converter (135) for obtaining signals
A communication system (101) comprising: A communication system (101) according to claim 1 or 2, wherein
The communication system (101), wherein (p-1) / 2 is a prime number. A communication system (101) according to claim 1 or 2, wherein
p is a prime number obtained by adding 1 to the power of 2 (101). Communication system (101) according to claim 1 or 2,
Each of the different primitive roots for the prime number p is assigned to a plurality of users, and the transmitting device (111) and the receiving device (131) associated with each of the plurality of users assign the primitive roots assigned to the user to the A communication system (101) characterized by a primitive root q. Communication system (101) according to claim 5,
The receiving device (131) assumes that each of the primitive roots not assigned to an existing user among the different primitive roots for the prime number p is the primitive root q, and the inner product v [0], v [1], Obtain v [2], ..., v [p-1] and obtain the primitive root with the smallest power of the inner product v [0], v [1], v [2], ..., v [p-1] And
The communication system (101), wherein the acquired primitive root is a primitive root q to be assigned to a new user. Communication system (101) according to claim 1 or 2,
Each of the different primitive roots for the prime number p is assigned to a plurality of users, and the transmission device (111) associated with each of the plurality of users has the primitive root assigned to the user as the primitive root q,
The receiving device (131) obtains inner products v [0], v [1], v [2],..., V [p-1] by regarding each of the different primitive roots as the primitive root q. , To obtain a primitive root with the maximum power of the inner product v [0], v [1], v [2], ..., v [p-1], and make the obtained primitive root a primitive root q A communication system characterized by the above.   The transmission device (111) in the communication system (101) according to claim 1 or 2.   The receiving device (131) in the communication system (101) according to claim 1 or 2.   A computer-readable information recording medium on which a program is recorded, which causes a computer to function as the transmission device (111) in the communication system (101) according to claim 1 or 2.   A computer-readable information recording medium on which a program is recorded, which causes a computer to function as the receiving device (131) in the communication system (101) according to claim 1 or 2.

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