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A METHOD FOR SPREAD- SPECTRUM DIGITAL COMMUNICATION
BY GOLAY COMPLEMENTARY SEQUENCE MODULATION
DESCRIPTION
FIELD OF THE ART
The present invention refers to the modulation and
demodulation merhod as well as the transmitter and receiver
which makes it possible to transmit and receive data by means
of any transmission means, particularly when it is necessary
or preferable to use spread spectrum techniques.
STATE OF THE ART
The spread spectrum concept was developed for use in military
communications due to its immunity features towards noise and
interference. Its principle is based on the use of certain
binary sequences having certain features similar to noise and
which, however, a receiver which knows said sequence is
capable to detect as a signal. In the same manner the
compression of impulses by means of binary sequences is useful
also in RADAR, SONAR and echograph applications since it
allows better resolution of the detected objects. However, in
recent years its use has become widespread in space
applications and civil communications such as mobile
telephony, DS-CDMA (Direct Sequence Code-Division Multiple-
Access), radio telephone access loops, Internet access,
wireless local area networks, deep space communications, etc.
All of which are based on digital modulation by means of using
of sequences which are suitable for this type of applications
due to their auto-correlation and cross-correlation features
are suitable for this kind of applications. Therefore,
international organisations (IEEE, UIT, etc.), have begun
norrralising and standardising modulation systems v/hich
facilitates the use of certain sequences to modulate the
transmitted binary data and thus obtain characteristics which
makes it possible to use, among others, certain frequencies
reserved for industrial, scientific and medical applications
(ISM bands) and whose use and exploitation do not require any
kind of administrative license. The need to send as much
information as possible with the same bandwidth has made the
telecommunications industry to develop commercial applications
which use the IEEE 802.11 standard for the transmission of
information by radio in local networks obtaining increasingly
higher speeds by means of the use of binary sequences such as
the 11-bit Barker (to obtain a minimum processing gain of 10.4
dB) or 5-bit Walsh, and dif ferent modulation techniques (BPSK,
QPSK, MBOK, QMBOK, etc.) which makes it possible to attain
transmission speeds of up to 11 Mbps. This standard makes it
possible to work within three frequency bands with a null-to-
null bandwidth of 22 MHz, in the so-called 2.4GHz band.
Likewise, reliable transmission methods are needed for the so-
called deep space communications between spaceships and the
bases on Earth, allowing a big processing gain due to the need
to limit the emission power of the ship"s transmission
equipment, and due to the reduced signal to noise ratio of
said signals when they are received.
In the present applications (Figure 1) the length of the
coding sequence (Barker, PN, Walsh, etc.,....) determines both
the processing gain and the bandwidth used. Generally, the
transmission speed will be reduced if we attempt to increase
the processing gain, which is why a compromise between the two
parameters must always be found. The transmission speed may be
increased by increasing the number of modulation phases,
however, the restrictions of this technique increase with the
decrease in the signal to noise ratio during reception.
Based on the above it can be deduced that there is a need for
a spread spectrum digital modulation technique which on the
one hand makes it possible to increase transmission speed and
on the other to obtain a bigger processing gain to make it
possible to reduce the needed transmission power or improve
the signal to noise ratio during reception, and at the same
time to reduce the complexity of the present modulation
tables.
No patent or utility model whatsoever is known whose features
are the object of the present invention.
DESCRIPTION OF THE INVENTION
The present invention uses pairs of Golay complementary
sequences for the modulation by means of spread spectrum and
DS-CDMA of the amplitude modulated binary data in combination
with an N-PSK modulation widely used in digital communication
systems.
The main property of the sequences used in this invention is
that in contrast to the Barker sequences, which have side
lobes, the Golay sequences are characterised by an ideal auto-
correlation, that is, they correspond to a perfect Kronecker
delta so that they meet:
2M, n=0
CA[n]+ CA[n] = { 0, n?O
where CA and Cn are the individual autocorrelations of the A
and B sequences of the pair of selected Golay complementary
sequences, M length; and whose values belong to the bi-valued
set (1,-1) .
The generation of such sequences is based on the so-called
kernel basics of 2, 10 and 26 bits, known hitherto (the rules
of Golay sequence generation are discussed in the article
called "Complementary Sequences" by M.J.E. Golay, published in
IRE Transactions on Information Theory, vol. IT-7, pp. 82-87,
April 1961).
The communication system object of the present invention makes
it possible to establish a physical end-to-end or end-to-
multi-point connection at a transmission rate, which will
depend on the employed means and on the available bandwidth
and on the acceptable error rate.
It consists of two pieces of equipment or devices: One is a
transmitter and the other one is a receiver.
The transmitter equipment is used to perform the following
tasks:
• Receive the data and generate the symbols corresponding
to each group of (m) bits as a function of the Golay
sequence number (n) of the selected length (M) , number
of amplitudes (A) per symbol, number of phases (N) used
for the modulation and processing gain needed to comply
with the quality requirements of the system.
• Carry out the adding up of the different phases to form
an N-PSK modulation and thus generating the transmission
signal.
• Transmit the composite signal to the transmitter means,
for example by means of an RF stage and antenna.
The receiver equipment is used to perform the following
operations:
• Demodulate the N-PSK information and extract the
components of each of the different phases.
• Adapt, filter and correlate the extracted components
with their corresponding complementary pairs or Golay.
• Sum up the correlations and thus obtain the original
data stream as digital levels.
• Perform the level decoding to obtain the original data.
The first advantage of this method is being able to obtain as
biq a processing gain as one wishes, independently from the
transmission rate, as will be seen later, and only by
increasing the length of the selected Golay sequences, for
which reason high transmissin power is not needed to obtain a
high signal to noise ration during reception. The processing
gain (in decibel) in this case is defined as:
GP = 10 log10 (2M) dB. (1.1)
where M corresponds to the length of the Golay sequences used
in the modulation. This feature is very important in
applications where a low transmission power is
desired(portable terminals, space ships and communication
satellites), the communication is performed over great
distances (deep space transmissions), and even military
applications in which the interference caused by the enemy or
the need to encrypt the transmission determine the security
and quality of the communication.
Furthermore, this method makes it possible to transmit
simultaneous information flows in the same frequency bands
over the channel by means of using n different low cross-
correlation Golay sequences, thus facilitating the creation of
n communication sub-net works within a same band, or to
multiply the transmission rate by a factor proportional to rj.
Likewise, it is possible to increase the transmission rate
even more if a prior amplitude modulation of the entry data by
means of A amplitudes is performed.
Therefore, from the aforementioned it can be deduced that the
transmission speed, or capacity (C), that can be obtained in a
spread spectrum communication system using this method will
be:
C= n • log2A • (1/2) • log2N • (B/2) n bits/sec. (1.2)
where B (Hertz) is the null-to-null bandwidth used, N is the
number of phases used in the modulation (power of 4), A is the
number of amplitudes used in the binary data encoding and rj is
the number of pairs of Golay complementary sequences used. In
the previous expression it is observed that C is independent
of M.
Therefore, the described invention constitutes a powerful
communication system for use in spread spectrum applications,
DS-CDMA, hostile environments, when restrictions on the
transmission power exists, or simply when there is a wish to
improve the quality of the communication without a
transmission rate degradation.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
Figure 1 shows the present basic transmission technique of a
spread spectrum system and particularly using an 11-bit Barker
sequence, which by means of an exclusive OR function performs
the spreading of the spectrum of the original data signal. It
is seen that the bit frequency is 11 times lower to the one
used for the Barker sequence, which makes it possible to
obtain a processing gain of 10 • loglO (11) ˜ 10.4 dB.
Figure 2 shows the basic outline of the transmission method
and a possible implementation of the transmitter which uses
this method for N=4. The binary data (1) enter the emitter in
groups of nxm bits. Each i group of m bits multiply with sign
(3) by both Golay sequences A and B (2) corresponding to the
BMB i number. The result of both multipliers independently
accumulates in each of the phases, and in each element, within
the displacement register (4) and moves towards the right to
wait for the next symbol.
The output values of the shift register of each BMB are summed
(5) and the result is phase and quadrature modulated by means
of the product with, for example, a sine and cosine symbol
(6). The result is sent to a conventional transmission stage
(7).
Figure 3 shows a basic outline of the reception method and
particularly an example of a receiver using this method for N
= 4. Both phases are reduced by a 4-PSK demodulation obtaining
one in-phase signal and another in quadrature (1). The
obtained analogue in-phase (I) and quadrature (Q) signals are
quantified and introduced into all the BDBs, and the result of
both is correlated with the corresponding original sequences
(2), the sum (3) of both flows will provide us with an
amplitude coded signal corresponding to the data of each
subgroup of m original bits which are demodulated. A
multiplexer block (4) manages the decoding and arrangement of
the bits to recover the original data flow.
Figure 4 corresponds to a possible embodiment of the
modulation. For the sake of simplification only the embodiment
of phase 1 is shown. Phase Q is identical but modulating with
the complementary sequence. Therefore, only one of the Golay
registers (1), one of the accumulators and shift registers (2)
and one multiplier (3) is shown.
PREFERRED EMBODIMENT
A possible embodiment of this method applied to a end-to-end
open-air radio communication system is shown below. For
reasons of clarity the implementation in the case of a QPSK
transmitter (N=4) is outlined in figure 2, performing data
modulation using n Golay sequences, amplitude modulated by
means of A amplitudes. Therefore, by applying the formula
(1.2), the transmission rate will be:
C= n • log2A • (B/2) bits/sec. (1.3)
In accordance with what has been explained above, the starting
point is a set of n pairs of Golay sequences of M bits
generated and stored in the transmitter by means of,
generally, 2xg binary registers (values 1 and -1) which we aim
to amplitude modulate with A amplitudes and with 4 Q PSK
phases (4-PSK) . In the same figure 2 one of the basic
modulator blocks (BMB) of which the transmitter consists is
shown in detail.
The transmitter performs the following operations where R is
the transmission rate in symbols:
(1) Encoder (a. 2) : The NRZ digital data received at nxmxR
bits/sec. arrive encoded and are grouped in n groups of
m=log2A bits. Each BMB processes in parallel a group of m
bits, so that the system will transmit nxm bits per symbol.
The bit with the highest weight of each group corresponds to
the sign, and the m-1 of less weight, to the module.
(2)Golay register(a.3): Formed by two binary registers of M
length which store the pair of A and B complementary sequences
whose values belong to the set (1, -1), which will modulate
the data processed by the corresponding BMB.
(3)Multiplier (a. 4): Consists of two multipliers with sign
(highest weight bit) of the pair of A and B Golay sequences of
the BMB with the arithmetic value of the corresponding group
within the set of groups of the input symbol.
(4)Double accumulator (a.5) and Shift register (a. 6): Perform the
arithmetic summing of the result of the multipliers with the
content of the double shift register (the upper path with A
and the inner path with B) and shifts a register to the right
for each symbol cycle, updating the register, located furthest
to the left of the same, to the value of zero. The shift
register is formed by basic elements which store signal
values, and therefore, the number (n) of bits used in each
basic element of said register, must be dimensioned to avoid
overflow during the accumulation operations. Thus, the number
of elements in the shift register must be equal to or higher
than M for each of the paths A and B.
(5) Adder(a. 7): Independently sums up the data corresponding
to the output of each shift register of each of the BMBs thus
obtaining the total IT and QT signals which are afterwards
modulated.
(6) QPSK modulator(a.8): Modulates the output signals from
the adder by multiplying the exit signals of the adders by two
quadrature symbols, for example, a sinusoidal symbol with
phase o (via IT) and another quadrature 0 - n/2 (via Qr) , and
adding the result of both phases, thus obtaining the
transmission signal in QPSK.
(7) Exit stage (a. 9) :Consists of a D/A converter stage (a. 9 .1) and a
conventional radio frequency stage(a.9.2), for example, sending the
signal to the transmission means.
Figure 3 shows an example outline of a receiver for N=4,
which is formed by ? basic demodulator blocks (BDB) detailed
in the same figure, and the structure of the receiver which
consists of the following blocks:
{1) QPSK receiver (b. 1) :Amplifies the RF input signal and if
necessary converts the signal to an intermediate frequency
(IF), obtains the phase information and makes it possible to
demodulate (b.2)and recover the different flows in-phase I and
quadrature Q corresponding to the phases 0 and 0 - n/2. The I
and Q signals are digitised and their output passed on to the
correlator blocks. This block is common for all the BDBs.
(2) Golay correlators (b.3): Makes it possible to correlate
the different flows received with their corresponding Golay
sequences. Given that the sequences are normalised between +1
and -1, the correlation is reduced to performing adding and
subtraction.
(3) Adder and detector(b. 4): Performs the adding up of the
correlations, two and two, so that the result are the original
amplitude modulated data. These are thresholded and converted
into binary data generated at the symbol rate at the output of
each block.
(4) Decoder (b.5) : Performs the grouping of the ? groups
received within the data stream, corresponding to the
transmitted data in the order in which they were transmitted
at ?xmxR bits/sec.
Both devices together make up the transmission system.
CLAIMS
1. A method for spread spectrum digital communication by Golay complementary
sequence modulation, said method being carried out by a communication system,
whereby transmission of information is caused to be allowed through a communication
channel, and binary data, and its spread spectrum are caused to be encoded and modulated
in amplitude, using Golay complementary sequences modulated in N-PSK, wherein said
communication system comprises the following elements :
a) a transmitter apparatus; formed of at least the following parts :
(i) a receiver;
(ii) an encoder for receiving NRZ digital data, encoding and grouping
together the received NRZ digital data ;
(iii) a Golay register, formed by two binary registers of M length ;
(iv) a multiplier, formed by two multipliers with a symbol;
(v) a double accumulator for performing the arithmetic additions of the
result of the multipliers ;
(vi) a shift register, formed by basic elements which store signal values;
(vii) an adder for adding up the data corresponding to the output of each
register independently;
(viii) a QPSK modulator for modulating the output signals of the adders,
for obtaining the transmission signal and QPSK ;
(ix) an exit stage, made up of two sub-stages, and comprising a D/A
converter stage, and a conventional radio frequency stage ; and
b) a receiver apparatus formed of at least the following parts :
(i) a QPSK receiver for amplifying the RF and IF signals from the exit
stage ;
(ii) a demodulator for recovering the different digitalised flows in
phases I and Q ;
(iii) Golay correlators for correlating the different flows received with
their corresponding Golay sequences ;
(iv) an adder and a detector for performing the addition of the
correlations ; and
(v) a decoder for performing the grouping of the ? groups received.
2. A method as claimed in claim 1, wherein said communication system is adapted
to generate ? binary Golay sequences with low cross-correlation, encoding entry data
which in turn are amplitude modulated by means of A amplitudes.
3. A method as claimed in claim 2, wherein the transmitter apparatus (a) is adapted
to generate the binary sequences for spread spectrum applications by using Golay
complementary sequences and the same with changed sign to represent and send at least
one bit of information per symbol.
4. A method as claimed in claim 2, wherein the transmitter apparatus (a) is adapted
to generate the binary sequences for spread spectrum applications by using Golay
complementary sequences and to add them unchanged or with changed sign and position,
displaced within the transmission symbol.
5. A method as claimed in claim 2, wherein the transmitter apparatus (a) is adapted
to generate the binary sequences for spread spectrum applications, and to multiply Golay
complementary sequences modulated by A amplitude values, which represent the digit
input, making it possible to multiply the quantity of information bits per symbol interval
by m=log2A.
6. A method as claimed in claim 2, wherein the transmitter apparatus (a) is adapted
to generate the binary sequences for spread spectrum applications and to generate a
processing gain in decibels equal to 10 log10(2M) dB, where M is the selected Golay
sequences.
7. A method as claimed in claim 6, wherein the double accumulator and shift register
of the transmitter apparatus (a) are adapted to accumulate and displace the pattern of
sequences generated in order to obtain the different phases.
8. A method as claimed in any of claims 2, 3, 4, 5, 6 and 7, wherein the adder of the
transmitter apparatus (a) is adapted to add all the elements generated in the previous
phases, be they all together, or in any other combination, and to obtain the signals which
are subsequently modulated by means of the N-PSK modulation and sent to the
transmission medium by means of a conventional radio frequency stage.
9. A method as claimed in claim 8, wherein the transmitter apparatus (a) is adapted
to modulate and transmit the information of a data flow at a rate of C= ? log2A (1/2)
log2N (B/2) bits / second, where ? is the number of Golay pairs used, A is the number of
amplitudes used to modulate the input data, N is the power of 4, being the number of
phases used in the modulation, and B is the null-to-null bandwidth used in the N-PSK
modulation.
10. A method as claimed in any of claims 2, 3, 4, 5, 6, 7, 8 and 9, wherein modulation
is caused to be generated by the steps of:
- amplitude modulation with A amplitudes of the binary input data
grouped in r| groups of m = log2A bits, which are introduced into r| basic
modulator blocks - BMB.
- storing of the ? pairs of Golay complementary sequences, of length M, in
binary registers of length M, the values of which are comprised within the
range of 1 and-1.
- determining product with sign of each group of m bits, whose sign
corresponds to the heaviest bit and whose module is the remaining m-1
bits, for each one of the Golay complementary sequences of length M
corresponding to the said group, which will form two I and Q phases of M
length elements.
- accumulation, element by element, of the first actual M values
contained in a double shift register of length M with the corresponding M
elements of the products of each of the phases obtained in the previous
stage.
- displacement of the said registers in a basic element towards the M
element of said registers - output - adding the value zero in the basic
elements of first order of the double register.
- providing the sum of the ? values obtained at the output of the I and Q
phases of each one of the BMBs independently in order to obtain the total
It and Qt phases.
- modulation of both lT and QT phases by means of quadrature
symbols and the sum of both to obtain the transmission signal.
- transmitting the obtained signal to a transmission stage.
11. A method as claimed in claim 10, wherein demodulation is caused to occur on the
basis of an N-PSK reception, coherent or non-coherent, which extracts the specific phases
and performs the correlation with the corresponding ? sequences per phase, adding them
and obtaining the binary data flow transmitted at origin by means of amplitude detection.
12. A method as claimed in claim 10, which involves the steps of:
- adapting and synchronising the signal received and demodulating the
quadrature phases which make up the said signal and inserting all these
into each one of the ? basic demodulator blocks (BDB);
- filtration by means of correlation, convolution or filter adapted to the
? pairs of Golay complementary sequences of the various recovered
phases, the ? sums of the results of every two correlations corresponding
to the same pair of Golay complementary sequence to obtain an
information stream, modulated in amplitude with A amplitudes ;
demodulating the ? modulated flows in amplitude to obtain r| groups of
m = log2A bits ; and
- multiplexing said groups to form the original data flow.
The frequency spectrum of a transmission system is spread in the transmitter (1)
by information bit encoding by means of Golay complementary sequence pairs. The
spectrum is picked up in the receiver (2) and passed through a filter that is adapted to the
characteristics of said frequencies enabling detection of digital levels corresponding to the
transmitted original information. If ? pairs of orthogonal sequences, A amplitudes for
data modulation and N- PSK modulation are used, it is possible to obtain transmission
speed (C) which equals formula (I), wherein B is the null-to-null bandwidth used in
Hertz. This makes it possible to improve quality in comparison with other digital
communication systems using spread-spectrum techniques and CDMA. A process gain
independent of transmission speed is obtained. |