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Claims  |
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What is claimed is:
1. A spread spectrum radio transmission system comprising:
a radio transmitter comprising:
pulse generating means for generating reoccurring pulses, said pulses
appearing at a selected time spacing,
a source of intelligence signals, and
modulation means responsive to said pulses generating means and said source
of intelligence signals for providing as an output a train of pulses
wherein the leading edge of pulses is varied in time position as a
function of intelligence signal;
avalanche semiconductor switching means, having a control signal input
responsive to said output of said modulation means, a bias power input,
and a switched power output, for switching power on and off to said
switched power output;
a D.C. bias source coupled to said bias power input comprising a delay line
having a delay of 1 picosecond to 50 nanoseconds and delay line charging
means coupled to said delay line for charging said delay line between
pulses of said train of pulses;
transmitting antenna means comprising an aresonant antenna coupled to said
switched power output and to space for transmitting a signal received from
said switched power output; and
a radio receiver comprising:
receiving antenna means comprising an aresonant antenna for receiving
transmissions from said transmitting antenna means and for providing as an
output electrical pulses responsive to the transmitted pulse signals,
amplification means responsive to the output of said receiving antenna
means for amplifying received pulses,
synchronous detection means, including signal sensitive windowing means
having a signal input responsive to the ouput of said amplification means,
for responding to, and providing an output for, signals appearing within
reoccurring windows of time generally coincident with the average time of
occurrence of pulses received by said receiving means and including means
for being insensitive to received signals appearing between the occurrence
of said windows of time,
signal conversion means for converting the output of said detection means
into a replica of signals of said intelligence signals, and
signal reproduction means responsive to the output of said signal
conversion means for reproducing said intelligence signals.
2. A system as set forth in claim 1 wherein said avalanche semiconductor
switching means comprises at least one avalanche transistor connected in a
common emitter configuration including said switched power output between
the emitter and a common ground, a base as said control signal input, and
having a collector as said bias power input.
3. A system as set forth in claim 1 wherein:
said delay line charging means comprises a D.C. power supply;
said bias power input and switched power output together comprises first
and second terminals; and
said charging means further comprises a resistor connected between said
first terminal and said D.C. power supply of a value which, upon the onset
of avalanche conditions of said avalanche semiconductor switching means,
would drop the voltage across said avalanche semiconductor switching means
to essentially zero.
4. A system as set forth in claim 3 wherein said aresonant antenna of said
transmitting antenna means is coupled between said second terminal and
said D.C. power supply.
5. A system as set forth in claim 2 wherein said delay line comprises
parallel connected 1 to 25 sections of coaxial cable of lengths of from
0.25" to 300", one end of the inner conductor of each said coaxial cable
being connected to said collector, the outer conductor of the coaxial
delay line being grounded, and the opposite end of the inner conductor
being open.
6. A system as set forth in claim 3 wherein said avalanche semiconductor
means comprises a transistor, in turn including an emitter coupled to said
transmitting antenna means.
7. A system as set forth in claim 6 wherein said switching means comprises
at least two avalanche transistors with their collector-emitter circuits
connected in series, a resistor, and power output being connected to the
emitter of one of said transistors, and said D.C. bias source is connected
between said resistor and a collector of another of said avalanche
transistors.
8. A system as set forth in claim 1 wherein said synchronous detection
means comprises an avalanche transistor having a signal input connected to
the output of said amplification means and including adjustable gating
means responsive to the occurrence of the leading edge of a signal output
of said last-named avalanche transistor for disabling the input of said
last named avalanche transistor for selected periods of time between said
reoccurring windows of time.
9. A system as set forth in claim 1 wherein said synchronous detection
means comprises:
a ring demodulator having a gating input, a signal input responsive to the
output of said amplification means, and a signal output, said signal
output comprising an output of said synchronous detection means;
voltage controlled oscillator means responsive to an average output of said
output of said ring demodulation means for providing a pulse output at a
frequency corresponding to an average rate of signal output of said ring
demodulator means; and
gating means responsive to the output of said voltage controlled oscillator
means for providing a gating input pulse to said ring demodulator means
having a selected duration period defining a said reoccurring window of
time.
10. A system as set forth in claim 9 wherein said gating means comprises:
a monostable multivibrator having an input coupled to said voltage
controlled oscillator means and an output; and
a pulse transformer connected between the output of said monostable
multivibrator and said gating input of said ring demodulator.
11. A system as set forth in claim 1 wherein said signal conversion means
comprises an active type low pass filter.
12. A spread spectrum radio transmission system comprising:
a radio transmitter comprising:
pulse generating means for generating reoccurring pulses, said pulses
appearing at a selected time spacing,
a source of intelligence signals, and
modulation means responsive to said pulses generating means and said source
of intelligence signals for providing as an output a train of pulses
wherein the leading edge of pulses is varied in time position as a
function of intelligence signal;
transmitting antenna means comprising an aresonant antenna having a
switching power input and coupled to space for transmitting a signal;
switching means, having a control signal input responsive to said output of
said modulation means, a bias power input, and a switched power output
coupled to said switched power input of said antenna, for switching power
on and off to said antenna;
a D.C. bias source coupled to said bias power input of said switching
means; and
a radio receiver comprising:
receiving antenna means comprising an aresonant antenna for receiving
transmission from said transmitting antenna means and for providing as an
output electrical pulses responsive to the transmitted pulse signals,
amplification means responsive to the output of said receiving antenna
means for amplifying received pulses,
synchronous detection means, including signal sensitive windowing means
having a signal input responsive to the output of said amplification
means, for responding to, and providing an output for, signals appearing
within reoccurring windows of time generally coincident with the average
time of occurrence of pulses received by said receiving means and
including means for being insensitive to received signals appearing
between the occurrence of said windows of time,
signal conversion means for converting the output of said detection means
into a replica of signals of said intelligence signals, and
signal reproduction means responsive to the output of said signal
conversion means for reproducing said intelligence signals. |
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Claims |
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Description |
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FIELD OF THE INVENTION
The invention relates generally to radio transmission systems, and
particularly to a spread spectrum type system wherein discrete frequency
signal components are generally below noise level and are thus not
discernable by conventional radio receiving equipment.
BACKGROUND OF THE INVENTION
The radio transmission of communications signals, for example, audio
signals, is normally effected by one of two methods. In one, referred to
as an amplitude modulation system, a sinusoidal radio frequency carrier is
modulated in amplitude in terms of the intelligence or communications
signal, and when the signal is received at a receiving location, the
reverse process, that is, demodulation of the carrier, is effected to
recover the communications signal. The other system employs what is termed
frequency modulation, and instead of amplitude modulation of the carrier
signal, it is frequency modulated. When an FM frequency modulation or FM
signal is received, circuitry is employed which performs what is termed
discrimination wherein changes in frequency are changed to changes in
amplitude and in accordance with the original modulation, and thereby a
communications signal is recovered. In both systems, there is as a basis a
sinusoidal carrier which is assigned and occupies a distinctive frequency
band width, or channel, and this channel occupies spectrum space which
cannot be utilized by other transmissions within the range of its
employment. At this time, almost every nook and cranny of spectrum space
is being utilized, and there is a tremendous need for some method of
expanding the availability of communications channels. In consideration of
this, it has been suggested that instead of the use of discrete frequency
channels for radio communications links, which is the conventional
approach, a radio transmission link employing a wider frequency spectrum
which may extend over a range of 10 to 100 times the intelligence band
width being transmitted, but wherein the energy of any single frequency
making up that spectrum be very low, typically below normal noise levels.
Thus, it would be obvious that this type of transmission would be
essentially non-interfering with other services. Making use of this
approach, it has been proposed that coded sequence modulations be somehow
employed and that each such communications link be non-interfering by
virtue of different coded sequences, which would be turnable features.
Significantly, however, as far as the applicant is aware, no known
practical systems has been as yet developed by others.
It is the object of this invention to extend the spectrum range of spread
spectrum communications to operate in the range of approximately 1,000 to
1,000,000 or more rather than 10 to 100 times the intelligence modulation
rate, and to accomplish this with an exceedingly simple and low cost
electronic assembly.
SUMMARY OF THE INVENTION
In accordance with this invention, a pulse signal of a fixed or programmed
rate is varied or modulated as to the time of turnon of pulses as a
function of an intelligence signal. The resultant pulse signals effect the
turn-on, or triggering, of an avalanche mode operated semiconductor switch
powered via a delay line or other similar short duration power sources
which may be charged between the time of occurrence of triggering pulses,
the switch being turned off within a range of time of from a few
picoseconds to on the order of 50 nanoseconds. The resultant pulse output
of the switch is coupled to an aresonant transmitting antenna coupled to
the atmosphere or space for transmission. Reception of the transmission is
effected by a receiver which synchronously effects detection by rendering
insensitive detection between the anticipated occurrence of pulse signals.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a combination block-schematic diagram of a spread spectrum
transmitter.
FIG. 2 is a combination block-schematic diagram of a spread spectrum
receiver as contemplated by this invention.
FIG. 3 is a combined block-schematic electrical diagram of an alternate
form of synchronous detector to the one shown in FIG. 2.
FIG. 4 is a set of electrical waveforms A-L illustrative of aspects of the
circuitry shown in FIGS. 1 and 2.
DETAILED DESCRIPTION OF THE DRAWINGS
Referring to FIG. 1, and initially to transmitter 10, a base frequency of
100 KHz is generated by oscillator 12, typically being a crystal
controlled oscillator which includes conventional circuitry for providing
as an output square wave pulses at 100 KHz rate. This pulse signal is
applied to divide-by-4 divider 14 to provide at its output a square wave
25 KHz, 0-5 volt, signal shown in waveform A of FIG. 4. Further references
to waveforms will simply identify them by their letter identity and will
not further refer to the figure, which is FIG. 4 in all cases. This output
is employed as a general transmission signal and as an input to power
supply 16. The latter is regulated, one which supplies a 300-volt D.C.
bias on a non-interfering basis for the output stage 18 of transmitter 10,
which is also keyed at the 25 KHz rate.
The output of divide-by-4 divider 14 is employed as a signal base and as
such is supplied through capacitor 20 to pulse position modulator 22.
Pulse position modulator 22 includes in its input an RC circuit consisting
of resistor 24 and capacitor 26 which convert the square wave input to an
approximately triangular wave as shown in waveform B, it being applied
across resistor 25 to the non-inverting input of comparator 28. A selected
or reference positive voltage, filtered by capacitor 27, is also applied
to the non-inverting input of comparator 28, it being supplied from +5
volt terminal 29 of D.C. bias supply 30 through resistor 32. Accordingly,
for example, there would actually appear at the non-inverting input a
triangular wave biased upward positively as illustrated by waveform C.
The actual conduction level of comparator 28 is determined by an audio
signal input from microphone 34 supplied through capacitor 36, across
resistor 37, to the inverting input of comparator 28, as biased from
supply 30 through resistors 38 and across resistor 32. The combined audio
signal and bias is illustrated in waveform D. By virtue of the thus
described input combination, the output of comparator 28 would rise to a
positive saturation level when triangular wave signal 40 (waveform E) is
of a higher value than modulation signal 42 and drop to a negative
saturation level when modulation signal 42 is of a greater value than the
triangular wave signal 40. The output signal of comparator 28 is shown in
waveform F.
In the present case, we are interested in employing the negative going or
tailing edge 44 (waveform F) of the output of comparator 28, and it is to
be noted that this trailing edge will vary in its time position as a
function of the signal modulation. This trailing edge of the waveform in
waveform F triggers "on" mono, or monostable multivibrator, 46 having an
"on" time of approximately 50 nanoseconds, and its output is shown in
waveform G. For purposes of illustration, while the pertinent leading or
trailing edges of related waveforms are properly aligned, pulse widths and
spacings (as indicated by break lines, spacings are 40 microseconds) are
not related in scale. Thus, the leading edge of pulse waveform G
corresponds in time to the trailing edge 44 (waveform F) and its time
position within an average time between pulses of waveform G is varied as
a function of the input audio modulation signal to comparator 28.
The output of mono 46 is applied through diode 48 across resistor 50 to the
base input of NPN transistor 52 operated as a triggering amplifier. It is
conventionally biased through resistor 54, e.g., 1.5K ohms, from +5 volt
terminal 29 of 5 volt power supply 30 to its collector. Capacitor 56
having an approximate capacitance of 0.1 mf is connected between the
collector and ground of transistor 52 to enable full bias potential to
appear across the transistor for its brief turn-on interval, 50
nanoseconds. The output of transistor 52 is coupled between its emitter
and ground to the primary 58 of trigger transfomer 60. Like secondary
windings 62 and 64 of trigger transformer 60 separately supply
base-emitter inputs of NPN avalanche, or avalanche mode operated,
transistors 66 and 68 of power output stage 18. Although two are shown,
one or more than two may be employed when appropriately coupled.
Avalanche mode operated transistors 66 and 68, many type 2N2222 with a
metal can, have the characteristic that when they are triggered "on",
their resistance goes low (e.g., approximately 30 ohms for each) and stays
at this state until collector current drops sufficiently to cut off
conduction (at a few microamperes). Their collector-emitter circuits are
connected in series, and collector bias of +300 volts is applied to them
from power supply 16, across filter capacitor 72, and through resistor 74
to one end 76 of parallel connected delay lines DL. While three sections
S.sub.1 -S.sub.3 are shown, typically five to ten would be employed. They
may be constructed of type RG58 coaxial cable, and each being
approximately three inches in length as required to totally effect an
approximately 3 nanosecond pulse. As shown, the positive input potential
from resistor 74 is connected to the center conductor of each of the delay
lines, and the outer conductors are connected to ground. Resistor 74 is on
the order of 50K ohms and is chosen to enable charging of the delay lines
DL in approximately one microsecond. Voltage dividing resistors 71 and 73,
typically of equal values of 1 meg ohm each, provide a load balancing
function between the transistors. Delay lines DL are charged to 300 volts
bias during the period when transistors 66 and 68 are turned off, between
input pulses. When the inputs to transistors 66 and 68 are triggered "on"
by a triggering pulse they begin to conduct within 0.5 nanoseconds, and by
virtue of the low voltage drop across them (when operated in an avalanche
mode as they are), about 120 volts appears as a pulse across output
resistor 78, e.g., 50 ohms.
Significantly, the turn-on or leading edge of this pulse is effected by the
trigger pulse applied to the inputs of transistors 66 and 68, and the
trailing edge of this output pulse is determined by the discharge time of
delay lines DL. By this technique, and by choice of length and Q of the
delay lines, a well-shaped, very short pulse, on the order of 3
nanoseconds and with a peak power of approximately 300 watts, is
generated. Following turn-off, delay lines DL are recharged through
resistor 74 before the arrival of the next triggering pulse. As will be
apparent, power stage 18 is extremely simple and is constructed of quite
inexpensive circuit elements. For example, transistors 66 and 68 are
available at a cost of approximately $0.12.
The output of power output stage 18 appears across resistor 78 and is
supplied through coaxial cable 80 to a time domain shaping filter 82 which
would be employed to affix a selected signature to the output as a form of
encoding or recognition signal. Alternately, filter 82 may be omitted
where such security measures are not deemed necessary; and, as indicative
of this, a bypass line 84 including a switch 86 diagrammatically
illustrates such omission.
The signal output of filter 82, or directly the output of power stage 18,
is supplied through coaxial cable 88 to discone antenna 90, which is an
aresonant antenna. This type of antenna relatively uniformly radiates all
signals of a frequency above its cut-off frequency, which is a function of
size, for example, signals above approximately 50 MHz for a relatively
small unit. In any event, antenna 90 radiates a wide spectrum signal, an
example being shown in the time domain in waveform H, this waveform being
the composite of the shaping effects of filter 82, if used, and, to an
extent, discone antenna 90.
The output of discone antenna 90 is typically transmitted over a discrete
space and would typically be received by a like discone antenna 92 of
receiver 96 at a second location. Although transmission effects may
distort the waveform some, for purposes of illustration, it will be
assumed that the waveform received will be a replica of waveform H. The
received signal is amplified by broad band amplifier 94, having a broad
band frequency response over the range of the transmitted signal. In
instances where a filter 82 is employed in transmitter 10, a reciprocally
configured filter 98 would be employed. As illustrative of instances where
no matched filter would be employed, there is diagrammatically illustrated
a switch 100 connecting the input and output of filter 98, denoting that
by closing it, filter 98 would be bypassed. Assuming that no match filter
is employed, the output of broad band amplifier as an amplified replica of
waveform H is illustrated in waveform I. In either case, it appears across
resistor 101.
Signal waveform I is applied to synchronous detector 102. Basically, it has
two functional units, avalanche transistor 104 and adjustable mono 106.
Mono 106 is driven from an input across emitter-resistor 110, connected
between the emitter of avalanche transistor 104 and ground. Avalanche
transistor 104 is biased from variable voltage D.C. source 112, e.g., 100
to 130 volts, through variable resistor 114, e.g., 100K to 1M ohms. A
delay line 116 is connected between the collector and ground of transistor
104 and provides the effective operation bias for transistor 104, it being
charged between conduction periods as will be described.
Assuming now that a charging interval has occurred, avalanche transistor
104 will be turned on, or triggered, by a signal applied to its base from
across resistor 101. It will be further assumed that this triggering is
enabled by the Q output, waveform J, of mono 106 being high. Upon being
triggered, the conduction of avalanche transistor 104 will produce a
rising voltage across emitter resistor 110, waveform K, and this voltage
will in turn trigger mono 106 to cause its Q output to go low. This in
turn causes diode 108 to conduct and thus effectively shorting out the
input of avalanche transistor 104, this occurring within 2 to 20
nanoseconds from the positive leading edge of the input signal, waveform
I. The conduction period of transistor 104 is precisely set by the charge
capacity of delay line 116. With a delay line formed of 12" of RG58
coaxial cable, and with a charging voltage of approximately 110 volts,
this period is set, for example, at approximately 2 nanoseconds. One to 25
sections of coaxial cable having lengths of from 0.25" to 300" may be
employed, with appropriate variation in on-time.
Mono 106 is adjustable to set a switching time for its Q output to return
high at a selected time, following it being a triggered as described. When
it does, diode 108 would again be blocked and thus the shorted condition
on the base input of avalanche transistor 104 removed, enabling it to be
sensitive to an incoming signal. For example, this would occur at time
T.sub.1 of waveform J. The period of delay before switching by mono 106 is
set such that renewed sensitivity for avalanche amplifier 104 occurs at
time point T.sub.1, just before it is anticipated that a signal of
interest will occur. As will be noted, this will be just before the
occurrence of a signal pulse of waveform I. Thus, with a repetition rate
of 25 KHz for the signal of interst, as described, mono 106 would be set
to switch the Q output from low to high after an essentially 40
microsecond, or 40,000 nanosecond, period. Considering that the width of
the positive portion of the input pulse is only about 20 nanoseconds,
thus, during most of the time, synchronous detector 102 is insensitive.
The window of sensitivity is illustrated as existing from time T.sub.1 to
T.sub.2 and is tunable in duration by conventional timing adjustment of
mono 106. Typically, it would be first tuned fairly wide to provide a
sufficient window for rapid locking into a signal and then be tuned to
provide a narrower window for a maximum compression ratio.
The output signal of avalanche transistor 104, waveform K, is a train of
constant width pulses having a leading edge varying as a function of
modulation. Thus, we have a form of pulse position modulation present. It
appears across emitter-resistor 110, and it is fed from the emitter of
transistor 104 to an active type low pass filter 117. Low pass filter 117
translates, demodulates, this thus varying pulse signal to a base band
intelligence signal, and this is fed to, and amplified by, audio amplifier
119. Then, assuming a voice transmission as illustrated here, the output
of audio amplifier 119 is fed to and reproduced by loud speaker 120. If
the intelligence signal were otherwise, appropriate demodulation would be
employed to detect the modulation present.
It is to be particularly noted that receiver 96 has two tuning features:
sensitivity and window duration. Sensitivity is adjusted by adjustment of
variable voltage source 112, and signal "lock on" is effected by tuning of
the period of high output state of mono 106 as described. Typically, this
period would be adjusted to the minimum necessary to capture the range of
excursion of the position modulated signal pulses of interest.
FIG. 4 illustrates an alternate form of detector for receiver 96, it being
designated detector 122. In it a form of synchronous signal detection is
effected employing ring demodulator 124, formed of four matched diodes
D.sub.1 -D.sub.4. In essence, it is operated as a single pole, single
throw switch, or simply a gate, with an input appearing across resistor
101 and applied to its input terminal I. Its gated output appears at
terminal 0 and is fed through capacitor 113 and across resistor 115 to the
input of demodulating, active type, low pass filter 117. Ring demodulator
124 is gated by a pulse PG illustrated in dashed lines in waveform L of
FIG. 4 and applied across terminal G. Pulse PG is generated by mono
(monostable multivibrator) 126 as controlled by VCO (voltage controlled
oscillator) 127. VCO 127 is in turn controlled to effect synchronization
with the average rate of the incoming signals shown in solid lines in
waveform L. To accomplish this, the output voltage from ring demodulator
124 is fed through resistor 128 and across a (averaging) capacitor 130,
connected to the control input of VCO 127. The thus controlled signal
frequency output of VCO 127 is fed to the input of mono 126 which then
provides as an output gating pulse PG. This pulse is rectangular as shown
and having a selected pulse width, typically from 2 to 20 nanoseconds,
being selected in terms of the time modulation of the transmitted pulse.
It is fed to the primary winding of pulse transformer 132, and the
secondary of this transformer is coupled across gate terminals G of ring
demodulator 124. Diode 134 is connected across the secondary of
transformer 132 and functions to effectively short out the negative
transition which would otherwise occur by virtue of the application of the
pulse output of mono 126 to transformer 132. In this manner, the gating
pulse PG operates to bias all of the diodes of ring demodulator 124
conductive for its duration and thereby gating through the signal input
from terminal I to terminal 0. As stated above, this signal input is
applied through capacitor 113 and across resistor 115 to the input of low
pass filter 117.
The function of detector 122 is provided to low pass filter 117 that
portion of the input signal shown in waveform L of FIG. 4 appearing within
the confines of gating pulse PG. The time position of gating pulse PG is
set by the timing of the pulse outputs of VCO 127, and the rate of the
output of VCO 127 is determined by the voltage input of VCO 127 as
appearing across capacitor 130. Capacitor 130 is chosen to have a time
constant which is just below that corresponding to the lowest frequency of
modulation to be demodulated. Thus, the output pulse rate of VCO 127 will
be such as not to vary the pulse position of gating pulse PG during
modulation induced time positions of the input signal (as shown in solid
lines in waveform H). As a result, the average value of the signal which
is gated through demodulator 124 will vary as a function of the modulation
originally applied to the signal. This average value is translated into an
amplitude type intelligence signal by passing it through low pass filter
117. It is then amplified, as desired, by audio amplifier 119 and then
reproduced by loud speaker 120.
From the foregoing, it should be appreciated that the applicant has
provided at both inexpensive and practical spread spectrum system of
communications. It employs the combination of an avalanche mode gated
transistor charged from a delay line; and when fed with a modulation
induced variable position pulse, provides, as an output, a variable
position pulse having a width of one to three nanoseconds. This in turn,
of course, enables a large spectrum commencing at about 50 megacycles and
extending downward to on the order of 500 megacycles. Thus, with an audio
frequence of, say, 5,000 Hz, the energy radiated to transmit this signal
is dispersed or spread an almost unbelievable 100,000 times. As a result,
interference with a conventional restricted bandwidth signal is
essentially eliminated. As an example of the effectiveness of such a
system, and employing 20-cent transistors in an avalanche mode, an audio
modulated audio leading edge modulated pulse was provided as an output
having a peak power of approximately 280 watts. The signal received at a
distance of 200 feet had a peak voltage of approximately 1 volt into a 50
ohm load. Actually, the power level necessary to receive has been found to
be approximately a few micro-watts, thus the effective range with this
power level is considerable. At the same time, a spectrum analyzer at the
receiving point failed to reveal any signal present or thus possibility of
intereference with other services. Actually, in view of the distribution
of the spectrum of the transmitted signal, the level present which might
interfere with a standard signal, for example, a 5 KHz width signal, would
be on the order of 2.8 micro-watts at the antenna. One way of describing
the advantage that this type of transmission has over more conventional
ones is to note that power appears in the example during an essentially
3-nanosecond period and appears only every 1,000,000 nanoseconds. Thus, it
has a natural power ratio of 33,000:1. Then, by limiting the listening
period for that signal at essentially its pulse width, the receiving
circuitry is only concerned with its appearance within a tiny window.
Accordingly, the overall signal-to-noise ratio is tremendous. It is to be
further appreciated that a vast number of users, employing slightly
different repetition rates, may be accommodated and even this may be
expanded by discrete patterns of pulse timing. Either analog or digital
patterns may be employed which, for example, may effect a dithering of the
modulated pulse base, with a like or complementary dithering employed on
the receiving end. In fact, with little degrees of sophistication,
extremely confidential communications can be achieved even as against a
receptor who has general knowledge of the presence of this type
transmission. Beyond this, its application to radar and motion detectors
is essentially unlimited, enabling detection without delays typically
required for signal intergration as often required.
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