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Claims  |
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What is claimed is:
1. A spread spectrum transmitter comprising:
a generator for generating a pseudo-noise code sequence;
combining means for combining the pseudo-noise code sequence from the
generator and a data information signal provided as an input to the
transmitter to generate a spread spectrum data information output signal;
a modulator/combiner for separately modulating each of (1) the spread
spectrum data information output signal from the combining means and (2)
the pseudo-noise code sequence from the generator to place both modulated
signals into a predetermined synchronous multiplexing relationship to each
other so that each signal is capable of being simultaneously received,
separated and multiplied together to provide self-synchronous
instantaneous despreading at a remote receiver, and combining the two
modulated signals into a multiplexed modulator/combiner output signal; and
means for transmitting the multiplexed output signal from the
modulator/combiner in an appropriate frequency band to a remote receiver.
2. A spread spectrum transmitter according to claim 1 wherein the
predetermined multiplexing relationship is a frequency division
multiplexed relationship and the modulator/combiner comprises:
modulating means for modulating a first predetermined carrier with the
spread spectrum data information output signal from the combining means to
generate a modulated spread spectrum data information output signal
disposed in a first frequency band, and for separately modulating a second
predetermined carrier with the pseudo-noise code sequence from the
generator to generate a modulated pseudo-noise code sequence output signal
in a second frequency band which does not overlap the first frequency
band; and
a combiner for combining the modulated spread spectrum data information
output signal and the modulated pseudo-noise code sequence output signal
to generate the modulator/combiner frequency division multiplexed output
signal.
3. A spread spectrum transmitter according to claim 2 wherein the
modulating means of the modulator/combiner comprises:
generating means for generating both a first predetermined frequency output
signal, and a second predetermined frequency output signal which includes
a different frequency band from the first frequency output signal;
means for mixing the first and second predetermined frequency output
signals from the generating means to produce (1) a first sideband signal
corresponding to the first predetermined carrier, and (2) a second
sideband signal corresponding to the second predetermined carrier signal;
mixing means for (1) mixing the first predetermined carrier with the spread
spectrum data information output signal from the combining means to
generate the modulated spread spectrum data information output signal, and
(2) mixing the second predetermined carrier with the pseudo-noise code
sequence from the generator to generate the modulated pseudo-noise code
sequence output signal.
4. A spread spectrum transmitter according to claim 1 wherein the
predetermined multiplexing relationship is a quadrature signal
relationship, the modulator/combiner comprising:
carrier generating means for generating from a predetermined carrier a
separate in-phase and quadrature carrier component;
mixing means for (1) mixing either one of the spread spctrum data
information signal and the pseudo-noise code sequence with the in-phase
carrier component to provide an in-phase output signal, and (2) mixing the
other one of the spread spectrum data signal and the pseudo-noise code
sequence with the quadrature carrier component to provide a quadrature
output signal; and
a combiner for combining the in-phase and quadrature output signals from
the mixing means to generate the multiplexed modulator/combiner output
signal.
5. A spread spectrum transmitter according to claim 1 wherein the
predetermined multiplexing relationship is a time division multiplexed
relationship, the modulator/combiner comprising:
delay means for delaying only one of the spread spectrum data information
output signal from the combining means and the pseudo-noise code sequence
from the generator by a predetermined amount of time;
a generator for generating a predeterming carrier;
means for separately modulating the spread spectrum data information signal
and the pseudo-noise code sequence signal, subsequent to a delay
introduced to one of the signals by the delay means, to generate a
modulated spread spectrum data information output signal and a modulated
pseudo-noise code sequence output signal, respectively; and
a combiner for combining the modulated spread spectrum data information
output signal and the modulated pseudo-noise code sequence output signal
to generate the modulator/modulator output signal.
6. A spread spectrum transmitter according to claim 5 wherein
the predetermined amount of delay time provided by the delay means is equal
to KT.sub.Chip, where K is an integer and T.sub.Chip is the chip rate
associated with the pseudo-noise code sequence.
7. A method of transmitting signals from a transmitter in a spread spectrum
communication system, the method comprising the steps of:
(a) generating a predetermined pseudo-noise code sequence signal;
(b) combining the pseudo-noise code sequence signal with a data information
input signal received by the transmitter to generate a spread spectrum
data information output signal;
(c) separately modulating each of (1) the spread spectrum data information
output signal generated in step (b), and (2) the pseudo-noise code
sequence signal generated in step (a) to generate a modulated spread
spectrum data information output signal and a modulated pseudo-noise code
sequence output signal, respectively, which signals are disposed in a
predetermined synchronous multiplexing relationship with each other;
(d) combining the modulated spread spectrum data information signal and the
modulated pseudo-noise code sequence signal from step (c) to generate a
multiplexed output transmission signal wherein each modulated signal is
capable of being simultaneous received at a remote receiver to provide
self-synchronous instantaneous despreading at the remote receiver; and
(e) transmitting the multiplexed output transmission signal from step (d)
to the remote receiver in an appropriate frequency band.
8. The method according to claim 7 wherein in performing step (c),
performing the steps of:
(c1) modulating a first predetermined carrier with the spread spectrum data
information signal to generate the modulated spread spectrum data
information output signal disposed a first frequency band; and
(c2) modulating a second predetermined carrier with the pseudo-noise code
sequence to generate the modulated pseudo-noise code sequence output
signal disposed in a second frequency band which is different from the
first frequency band.
9. The method according to claim 7 wherein in performing step (c),
performing the steps of:
(c1) generating a first and a second sideband carrier signal of a
predetermined carrier frequency;
(c2) modulating the first sideband carrier signal with the spread spectrum
data information signal to generate the modulated spread spectrum data
information output signal: and
(c3) modulating the second sideband carrier signal with the pseudo-noise
code sequence to generate the modulated pseudo-noise code sequence output
signal.
10. The method according to claim 7 wherein in performing step (c),
performing the steps of:
(c1) generating an in-phase and a quadrature component of a predetermined
carrier signal;
(c2) modulating one of the in-phase and quadrature components of the
predetermined carrier signal with the spread spectrum data information
signal to generate the modulated spread spectrum data information output
signal; and
(c3) modulating the other one of the in-phase and quadrature components of
the predetermined carrier signal, not used in step (c2), with the
pseudo-noise code sequence signal to generate the modulated pseudo-noise
code sequence output signal.
11. The method according to claim 7 wherein in performing step (c),
performing the steps of:
(c1) delaying only one of the spread spectrum data information signal and
the pseudo-noise code sequence by a predetermined amount of time; and
(c2) separately modulating a predetermined carrier with each of (1) the
spread spectrum data information signal and (2) the pseudo-noise code
sequence signal, subsequent to any delay imposed in one of the signals in
step (c1), to provide the modulated spread spectrum data information
output signal and the modulated pseudo-noise code sequence output signal,
respectively. |
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Claims |
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Description |
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TECHNICAL FIELD
The present invention relates to a technique for realizing a
self-synchronous spread spectrum transmitter/receiver which does not need
pseudo-noise code acquisition and tracking circuits.
DESCRIPTION OF THE PRIOR ART
Spread spectrum is a signal coding and transmission technique wherein a
sequence of different electromagnetic or electrooptic frequencies are used
in a pseudo-random sequence to transmit a given information signal. With
such technique the bandwidth is made deliberately larger than the
information signal which is desired to be transmitted. The spread spectrum
technique has grown in interest in the recent years for use in various
radio and lightwave systems and networks to provide multiple access to the
same frequency band with virtually no interference, and for purpose of
secure communications. With the spread spectrum transmission technique,
however, it is imperative that the transmission and reception functions
are achieved by means of frequency modulation of the transmitter and
receiver in precise synchronism in order to recover the information. In
commercial satellite systems, the use of spread spectrum is also of
interest since such technique permits the use of smaller antennas than
needed with standard radio transmissions because a substantial reduction
in the radiated power flux density can be achieved with a comparable
predetermined level of recovered intelligence in the transmitted signal
using the spread spectrum technique.
A typical spread spectrum communication system is disclosed in U.S. Pat.
No. 4,351,064 issued to W. Ewanus on Sept. 21, 1982, where the spectrum is
spread for transmission by superimposing a pseudo-noise code modulation on
the intelligence modulation of a carrier. On reception, the spectrum is
despread by auto-correlation of the pseudo-noise code. A tracking
reference oscillator signal, which is impressed on the auto-correlated
carrier at the receiver, is a periodic phase modulation which is passed by
the receiver network to produce an error signal for maintaining the
pseudo-noise encoder of the receiver in synchronism with the received code
via tracking loop.
Various techniques have been used to use provide synchronization for a
spread spectrum communication receiver. In this regard see, for example,
U.S. Pat. No. 4,423,517, issued to T. Danno et al. of Dec. 27, 1983, where
a synchronization circuit in the receiver generates a receiving code
sequence which is identical to the input code sequence and then varies the
timing of the receiving code sequence using a correlator until the two
code sequences are correlated. Another code sequence synchronization
system for a spread spectrum receiver is disclosed in U.S. Pat. No.
4,653,069 issued to A. W. Roeder on Mar. 24, 1987, where the receiver
synchronizes to the transmitted signal by performing a continuous sequence
of correlations until a correlation output exceeding a predetermined
threshold is achieved, after which a plurality of correlations are
performed during a sampling period interval when high subsequent
correlation output signals are likely to occur. A technique for providing
a spread spectrum code tracking loop is disclosed in, for example, FIG. 5
of U.S. Pat. No. 4,285,060 issued to R. F. Cobb et al. on Aug. 18, 1981.
There, the arrangement includes signal power measuring circuitry, the
output of which has a polarity which is effectively independent of the
gains of the separate channels, whereby gain variations for the separate
channels, which would cause mistiming of the lcoally generated
pseudo-noise codes in a conventional delay lock loop configuration, do not
influence the code correlation process.
The problem remaining in the prior art is to provide a technique for spread
spectrum transmissions which could eliminate the need for the expensive
pseudo-noise code acquisition and tracking systems and thereby provide a
low-cost, compact design spread spectrum transmitter/receiver. Present
pseudo noise code acquisition systems also have long acquisition times and
a further problem would be to provide a technique which can be useful in
conjunction with existing code acquisition systems to provide a composite
system with low acquisition times.
SUMMARY OF THE INVENTION
The foregoing problems in the prior art have been solved in accordance with
the present invention which relates to a technique for eliminating the
necessity for providing pseudo-noise (PN) code acquisition and tracking
circuits in a spread spectrum transmitter/receiver, or for providing a
composite system that operates with an existing code acquisition system to
provide low acquisition times. More particularly, the present transmitter
transmits both (a) the PN spreading code and (b) the combined PN spreading
code plus the data information signal, where the PN and PN+data signals
can be sent either (1) on different frequencies, (2) on a quadrature
carrier, or (3) with a time offset. At the receiver the received PN
spreading code and the PN+data signals are separately recovered and used
to decode the PN+data signal to obtain the despread data information
signal.
Other and further aspects of the present invention will become apparent
during the course of the following description and by reference to the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of an exemplary spread spectrum transmitter and
receiver that communicate with each other via a PNC and a PNC+data spread
spectrum signal which is offset in frequency by 2.DELTA.f;
FIG. 2 is a frequency spectrum of an exemplary resultant signal from the
modulator/combiner in the transmitter of the arrangement of FIG. 1;
FIG. 3 is a block diagram of an exemplary spread spectrum transmitter and
receiver that communicate with each other via a PNC and a PNC+data spread
spectrum signal on a quadrature carrier;
FIG. 4 is a frequency spectrum of an exemplary resultant signal from the
modulator/combiner in the transmitter of the arrangement of FIG. 3;
FIG. 5 is a block diagram of an exemplary spread spectrum transmitter and
receiver that communicate with each other via a PNC and a PNC+data spread
spectruum signal with a time offset; and
FIG. 6 illustrates an exemplary data and a PNC signal in the time domain
for describing exemplary delays necessary in the arrangement of FIG. 5.
DETAILED DESCRIPTION
The present invention is described hereinafter with reference to a
satellite communication system. It should be understood, however, that the
concept of the present invention can also be applied to terrestrial radio
or lightwave communication systems. A spread spectrum system in a
commercial satellite system can reduce the satellite system's
susceptibility to, and generation of, both adjacent satellite interference
and terresterial interference, and allows the use of small and less costly
earth stations. Since earth station cost is an important parameter in
satellite systems, one way to reduce the cost of the earth station design
for a spread spectrum system is to simplify, or eliminate, the need for a
Pseudo Noise (PN) code acquisition and tracking circuit. In accordance
with the present invention, this is accomplished by transmitting both a
first signal comprising just the PN spreading code (PNC), and a second
signal comprising the PNC plus the information data signal (PNC+data
corresponding to the spread spectrum data signal) through the satellite to
the remote destined receiver in the manner shown in FIG. 1.
FIG. 1 is a block diagram of a self-synchronous transmitter 10 and receiver
30 for concurrently transmitting and receiving, respectively, the PNC and
the PNC+data signals in separate frequency bands in accordance with one
aspect of the present invention. The phrase homodyne-type
transmitter/receiver is used to define the transmission of the spread
spectrum PNC and PNC+data signals which are despread at the receiver by a
direct mixing of the two signals to baseband. In transmitter 10, the PNC
signal is generated in a generator 11. The generated PNC signal is then
combined with an input data signal, which may be received directly from a
remote user or from storage in a data buffer 12, in an adder 13 to produce
the PNC+data signal at the output of binary adder 13. The PNC signal
generated by generator 11 and the PNC+data signal from adder 12 are
provided as separate inputs to a modulator/combiner 14. In
modulator/combiner 14, a first oscillator 15 generates an output frequency
designated f.sub.IF while a second oscillator 16 generates an output
frequency designated .DELTA.f which is small compared to f.sub.IF.
The output frequencies from oscillators 15 and 16 are mixed in mixer 17 to
produce the products including the two sidebands of f.sub.IF. A first
bandpass filter 18 is tuned to only pass the upper sideband frequency of
f.sub.IF +.DELTA.f from the output of mixer 17, which acts as a carrier
that is modulated in mixer 19 with the PNC+data signal generated by mixer
13 to produce the PNC+data signal in a first frequency band. Similarly, a
second bandpass filter 20 is tuned to only pass the lower sideband
frequency of f.sub.IF -.DELTA.f from the output of mixer 17, which
frequency acts as a carrier that is modulated in mixer 21 with the PNC
signal generated by PNC generator 11 to produce the PNC signal in a second
frequency band. The modulated PNC+data signal from mixer 19 and the
modulated PNC signal from mixer 21 are combined in combiner 22 to produce
an output signal as depicted in FIG. 2. The output signal from combiner
shown in FIG. 2 is then upconverted in upconverter 23 to the proper
frequency band for transmission, amplified in amplifier 24 to a proper
level for transmission, and trasmitted via antenna 25 either directly or
via a satellite (not shown) to receiver 30.
At receiver 30, an antenna 31 receives the electromagnetic signal
transmission from transmitter 10 and delivers it to an amplifier 32 where
the signal is amplified to a desired level. The output signal from
amplifier 32 is then provided to the input of a hybrid circuit 33 where
the received signal is divided into two parts, with each part of the
amplified signal propagating along a separate path. A bandpass filter 34
which is tuned to only pass the frequency band of the received PNC+data
signal and block all other is disposed in a first one of the output paths
from hybrid 33, while a second bandpass filter 35 which is tuned to pass
only the frequency band of the PNC signal and block all others is disposed
in the second output path from hybrid 33. The PNC+data and PNC output
signals from bandpass filters 34 and 35, respectively, are mixed in a
mixer 36, which can take the form of a double balanced mixer, to despread
and recover the data signal at its output. This despread data signal is
recovered at the IF frequency of 2.DELTA.f and can then be demodulated
accordingly with any suitable technique.
Another aspect of the present invention is to transmit the PNC and the
PNC+data signals on a quadrature carrier. An arrangement for accomplishing
this aspect is shown in FIG. 3, where elements in transmitter 10 and
receiver 30 having corresponding numbers to the elements in FIG. 1
function as described for those elements in FIG. 1. Modulator/combiner 26
in transmitter 10 of FIG. 3 includes an oscillator 15 which provides the
carrier f.sub.IF as found with oscillator 15 of FIG. 1. This carrier is
used to directly modulate the PNC signal in mixer 21 to provide the
in-phase PNC output signal to combiner 22 while the carrier is shifted in
phase by 90 degrees in phase shifter 27 and used in mixer 19 to provide a
quadrature PNC+data output signal to combiner 22. For this aspect, mixers
19 and 21 are preferably double balanced mixers. The output signal from
combiner 22 is depicted in FIG. 4 where the PNC and the PNC+data signals
lie in the same frequency band but are transmitted on quadrature carriers
at a frequency f.sub.IF. The output signal from combiner 22 is transmitted
to receiver 30 via upconverter 23, amplifier 24 and antenna 25.
In receiver 30, the received signal passes through amplifier 32 and
downconverter 50, hybrid circuit 33 again divides the amplified received
downconverted signal into two parts for propagation along separate paths.
A carrier recovery circuit 37 recovers the carrier f.sub.IF from the
received signal which is used directly in mixer 39 to recover the in-phase
PNC signal from a first part of the received signal at the output of mixer
39. The recovered carrier is shifted in phase by 90 degrees in shifter 38
and the quadrature carrier is mixed with the second part of the received
signal in mixer 40 to provide an in-phase PNC+data signal at the output of
mixer 40. The two in-phase signals are mixed in mixer 36 to obtain the
despread recovered data signal at the output of receiver 30 for further
demodulation by any suitable technique. It is to be understood that any
other suitable technique can be used to recover the data signal in
receiver 30.
A third aspect of the present invention is to transmit the PNC and PNC+data
signals with a time offset. A transmitter 10 and reciver 30 for providing
such time offset feature is shown in FIG. 5 where the PNC generated by
generator 11 is delayed in time by a predetermined amount before being
mixed in mixer 21 with the carrier f.sub.IF generated by oscillator 15.
Concurrent therewith, an undelayed PNC+data signal from mixer 13 is mixed
in mixer 19 with the carrier f.sub.IF. It is preferable that mixers 19 and
21 comprise double balanced mixers for this aspect of the invention. The
resultant delayed and mixed PNC signal from mixer 21, and the undelayed
and mixed PNC+data signal from mixer 19 are combined in combiner 22 and
transmitted via upconverter 23, amplifier 24 and antenna 25 to receiver
30. At receiver 30, the received spread spectrum signal is amplified in
amplifier 32 and divided into two parts for propagation along two separate
paths. A predetermined delay, corresponding to the delay provided in delay
circuit 29 of transmitter 10, is produced in one of the parts of the
received signal by delay circuit 41. This delayed part and the undelayed
part of the received signal are mixed in a double balanced mixer 36 and
the resultant output signal is transmitted through a low-pass filter 42 to
produce the despread data signal. A downconverter 50 can be placed between
amplifier 32 and hybrid 33 if desired.
The predetermined amount of delay provided in delay circuits 29 and 41 can
be determined as follows. For a spread spectrum system, the chip rate is
much greater than the data rate, and the individual PNC sequences are
orthogonal or uncorrelated when offset by any integer multiple K of
T.sub.Chip if the multiple, K, is not equal to T.sub.Data/T.sbsb.Chip =N
or an integer multiple of N. This suggests that the delay in circuits 29
and 41 should be equal to, for example, K T.sub.Chip. In transmitter 10,
the output of mixer 19 can be designated as A(t) and the output from mixer
21 can be designated as B(t-KT.sub.Chip) which two signals are added in
combiner 22 and transmitted to receiver 30. At receiver 30, the undelayed
received signal at both the outputs of hybrid 33 and at one of the inputs
to mixer 36 is designated as
A(t)+B(t-KT.sub.Chip). (1)
The delayed signal at the other input of mixer 36 can be designated by
A(t-KT.sub.Chip)+B(t-2KT.sub.Chip). (2)
When these two signals are mixed in mixer 36 an output signal results which
can be designated by:
A(t)A(t-KT.sub.Chip)+A(t-KT.sub.Chip)B(t-KT.sub.Chip)+A(t)B(t-2KT.sub.Chip)
+B(t-KT.sub.Chip)B(t-2KT.sub.Chip). (3)
Therefore, at the output of double balanced mixer 36, three high frequency
components or spread sequences are obtained and the second term, which
when despread, is the desired data signal. This collapsing of the second
term can be shown by the following:
##EQU1##
which is the desired data output.
The low pass filter 42 is tuned to pass the second term of equation (3)
since this is the desired despread data signal.
It is to be understood that the transmission of a PNC and PNC+data signal
with either a frequency or time offset, or via a quadrature carrier can
also be accomplished in a lightwave or infrared communication system by,
for example, using the output of modulator/combiner 14, 26 or 18 to
intensity modulate a lasing means.
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