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What is claimed is:
1. An apparatus for identifying an arrival time of a communicated signal
which conveys a message having a plurality of bits of data, said apparatus
comprising:
a correlator for correlating said communicated signal with a PN sequence
and to generate a correlation signal;
means, coupled to said correlator, for detecting the occurrence of a first
bit of said message; and
means, coupled to said detecting means and to said correlator, for
determining when, after said first bit, said correlation signal
corresponds to a threshold, wherein said determining means comprises a
comparison circuit which is disabled during said first bit.
2. An apparatus as claimed in claim 1 wherein said determining means
comprises means, coupled to said comparison circuit, for enabling said
comparison circuit during said second bit, said second bit immediately
following said first bit in said message.
3. An apparatus as claimed in claim 1 wherein:
said correlator is configured so that said correlation signal exhibits a
peak value when said communicated signal correlates with said PN sequence;
and
said determining means is configured so that said threshold is responsive
to said peak value.
4. An apparatus as claimed in claim 3 wherein said determining means is
configured so that said threshold corresponds to a value less than
approximately 1/2 said peak value.
5. An apparatus as claimed in claim 1 additionally comprising means,
coupled to said correlator, for recovering data from said correlation
signal and wherein:
said threshold represents a timing threshold; and
said recovering means is configured so that said recovered data are
responsive to a data threshold, said data threshold being greater than
said timing threshold.
6. An apparatus as claimed in claim 1 wherein said correlator comprises a
surface acoustic wave device configured to correlate when loaded with said
PN sequence.
7. An apparatus as claimed in claim 1 wherein said threshold represents a
timing threshold, and said detecting means comprises:
means for establishing an event threshold, said event threshold being
responsive to a signal level for said correlation signal throughout a
predetermined duration; and
a comparison circuit configured to indicate an occurrence of said first bit
when an instantaneous signal level of said correlation signal corresponds
to said event threshold.
8. A method of identifying an arrival time of a communicated signal which
conveys a message having a plurality of bits of data, said method
comprising the steps of:
initiating a clock to mark the passage of time;
establishing a threshold;
receiving first and second bits of said signal:
correlating said first and second bits of said signal with a PN sequence,
said correlating step producing a correlation signal; and stopping said
clock following said first bit at a point in time when said correlation
signal corresponds to said threshold, wherein said stopping step occurs
during said second bit.
9. A method as claimed in claim 8 wherein said receiving step receives said
second bit immediately following said first bit.
10. A method as claimed in claim 9 wherein said receiving step is
configured to indicate that:
said signal conveyed said PN sequence during said first bit; and
said signal conveyed said PN sequence during said second bit.
11. A method as claimed in claim 8 wherein:
said correlating step is configured so that said correlation signal
exhibits a peak value when said communicated signal correlates with said
PN sequence; and
said step of establishing is configured so that said threshold is
responsive to said peak value.
12. A method as claimed in claim 11 wherein said establishing step is
configured so that said threshold corresponds to a value less than
approximately 1/2 said peak value.
13. A method as claimed in claim 8 additionally comprising the step of
recovering data from said correlation signal, wherein said threshold is a
timing threshold and said recovering step comprises the steps of:
establishing a data threshold at a magnitude which is greater than said
timing threshold; and
recording in a storage element whether said correlation signal corresponds
to said data threshold.
14. A method as claimed in claim 8 wherein said correlating step comprises
the step of providing a surface acoustic wave device configured to
correlate when loaded with said PN sequence.
15. A method as claimed in claim 8 wherein said threshold is a timing
threshold, and said method additionally comprises the steps of:
establishing an event threshold, said event threshold being responsive to a
signal level for said correlation signal throughout a predetermined
duration; and detecting an occurrence of said first bit when an
instantaneous signal level of said correlation signal corresponds to said
event threshold.
16. A system for identifying an arrival time of a communicated signal, said
system comprising:
a spread spectrum transmitter configured to transmit said communicated
signal, said communicated signal conveying a message having a plurality of
bits, said bits exhibiting first or second states wherein said first state
is conveyed by encoding said communicated signal with a PN sequence and
said second state is conveyed by an absence of PN sequence encoding in
said communicated signal;
means for receiving said communicated signal:
a correlator coupled to said receiving means, said correlator being
configured to correlate said communicated signal with said PN sequence and
to generate a correlation signal;
means, coupled to said correlator, for detecting the occurrence of a first
one of said bits of said message; and
means, coupled to said detecting means and to said correlator, for
determining when, after said first bit, said correlation signal
corresponds to a threshold, wherein said determining means comprises:
a comparison circuit configured to compare said correlation signal with
said threshold; and
means, coupled to said comparison circuit, for disabling said comparison
circuit during said first one of said bits and for enabling said
comparison circuit during a second one of said bits, said second one of
said bits occurring immediately after said first one of said bits.
17. A system as claimed in claim 16 wherein said transmitter is configured
so that said first and second ones of said bits each exhibit said first
state.
18. A system as claimed in claim 16 wherein:
said correlator is configured so that said correlation signal exhibits a
peak value when said communicated signal correlates with said PN sequence;
and
said determining means is configured so that said threshold is responsive
to said peak value.
19. A system as claimed in claim 16 wherein:
said threshold represents a timing threshold; and
said system additionally comprises recovering means, coupled to said
correlator, for recovering data from said correlation signal, said
recovering means being configured so that said recovered data are
responsive to a data threshold, said data threshold being greater than
said timing threshold. |
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Claims |
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Description |
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TECHNICAL FIELD OF THE INVENTION
The present invention relates generally to an electronic system that
identifies when communicated signals arrive at a receiving apparatus. In
addition, the present invention relates to systems which convey
communicated signals that are encoded with pseudorandom noise (PN)
sequences.
BACKGROUND OF THE INVENTION
A variety of electronic systems need to identify a precise point in time
when a signal arrives at a receiver. Such systems include multilateration
location determination systems, time domain reflectometry systems, and the
like. When such systems calculate distances from the receiver based upon
the times of arrival for electronic signals traveling at or near the speed
of light, an error of as little as a few nanoseconds in identifying the
precise arrival time can lead to a distance error of over a meter.
A common problem faced by these and other systems is that of distinguishing
a legitimate signal from noise while simultaneously distinguishing a
legitimate signal from multipath and other corrupting signals.
Conventionally, the receiver generates a detection signal that is compared
against a threshold. A time of arrival is indicated when the detection
signal exceeds the threshold. However, the threshold must conventionally
be established at a level well above a noise floor to prevent the system
from falsely indicating time of arrivals in response to noise.
Unfortunately, as the threshold increases, the indicated time of arrivals
become prone to errors resulting from multipath and other factors.
Multipathing results when the signals reach the receiver by an indirect or
reflected path, and often by two or more paths. Direct path and multipath
signals reach a receiver at different times, but these different signals
may coincide to some extent. In other words, a leading edge of a multipath
signal may arrive soon after a leading edge of a direct path signal, and
then both are present simultaneously.
Direct path and multipath signals may add to one another or subtract from
one another in the receiver so that time of arrivals determined through
correspondence with the threshold are inconsistent from situation to
situation. If direct path and multipath signals do not interfere or add
together in the receiver, then a leading edge slope of a detection signal
may increase so that the detection signal actually crosses the threshold
correctly. If direct path and multipath signal subtract from one another
in the receiver, the detection signal may fail to reach the threshold or
reach the threshold too slow.
The use of spread spectrum communication signals helps the multipath
problem to some degree. Spread spectrum signals are encoded with a
pseudorandom noise (PN) spreading sequence, or code. A correlator in a
receiver generates a distinctive, high amplitude detection signal during a
period in time while the communication signal correlates with the PN
sequence. Multipath signals which arrive at the receiver after this period
in time have little or no influence. However, this period may last for
many tens of nanoseconds, and multipath signals arriving during this
period can still corrupt the detection signal.
BRIEF DESCRIPTION OF THE DRAWINGS
A more complete understanding of the present invention may be derived by
referring to the detailed description and claims when considered in
connection with the Figures, wherein like reference numbers refer to
similar items throughout the Figures, and:
FIG. 1 shows a block diagram of a first portion of a system configured in
accordance with the teaching of the present invention;
FIG. 2 shows a timing diagram that depicts some of the signals generated by
components of the system; and
FIG. 3 shows a block diagram of a second portion of the system.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows a block diagram of a first portion of a system 10 configured
in accordance with the teaching of the present invention. System 10
identifies the arrival time of a signal that has been communicated from a
transmitter 12 and is being received at a receiver 14. In the preferred
embodiment, system 10 is used by a multilateration location system in
which the location of transmitter 12 is determined relative to
known-positions of several of receivers 14, each of which is configured
like the others. However, system 10 is not limited to being used only in a
location determination system. System 10 may be used in connection with a
variety of electronic systems where the arrival time of a communicated
signal at a receiver is identified to a high degree of precision.
Transmitter 12 is configured to generate and broadcast a spread spectrum
signal. This communicated signal conveys a digital message 16, as
illustrated in the timing diagram shown in FIG. 2. As shown in FIG. 2,
message 16 may include any number of bits 18 of data. FIG. 2 illustrates a
portion of the data stream containing the first through fifth bits 18. In
the preferred embodiment, the duration of message 16 and the duration of
bits 18 within message 16 are relatively constant from message to message.
The precise value of these durations is not important to the present
invention.
Referring to FIGS. 1 and 2, a controller 20 generates message 16.
Controller 20 may include a microprocessor, memory, and related components
conventionally found in transmitters. The precise makeup of message 16 is,
for the most part, not a critical feature of the present invention.
However, controller 20 configures message 16 so that at least two
consecutive bits 18 at a consistent location in message 16 exhibit the
same state, which is preferably a logical one. This is accomplished by
configuring message 16 to include a preamble having logical values of
1-1-0 for the first bit, second bit, and third bit of FIG. 2 bits 18.
Controller 20 serially feeds message 16 to a PN code generator 22. A
phase-locked oscillator 24 couples to both PN code generator 22 and a
bi-phase modulator 26. An output of modulator 26 couples to an RF
amplifier 28, and amplifier 28 drives an antenna 30. In the preferred
embodiment, generator 22 encodes message 16 with a predetermined maximal
length, 127 bit PN sequence.
More particularly, generator 22 produces the PN sequence only during the
bits 18 of message 16 that exhibit one state, which is a logical one in
the preferred embodiment. As shown in FIG. 2, the first and second bits of
bits 18 convey the PN sequence. During bits 18 that exhibit the other
state, a logical zero in the preferred embodiment, PN code generator 22
produces no code, as shown in the third bit of bits 18 in FIG. 2.
Accordingly, for each logical one bit 18 conveyed by message 16, a
communicated signal broadcast from antenna 30 is bi-phase modulated to
convey the PN sequence. For each logical zero bit 18 conveyed by message
16, the communicated signal broadcast from antenna 30 conveys nothing, or
silence.
Receiver 14 is configured for compatibility with the communicated signal
broadcast by transmitter 12. While FIG. 1 illustrates only one receiver
14, system 10 may include any number of receivers 14, and more than one of
these receivers 14 may receive the communicated signal. The communicated
signal will arrive at the receivers 14 at different times depending upon
the relative distances between the receivers 14 and the transmitter 12. By
identifying the times at which the communicated signal arrives at the
different receivers 14, a multilateration location process may resolve a
position for transmitter 12. The precision of the resolved position will
be depend upon the precision with which the receivers 14 identify the
times at which the communicated signal arrives. While the following
discussion is directed toward a single receiver 14, those skilled in the
art will appreciate that it may apply to multiple receivers 14 as well.
Receiver 14 includes an antenna 32, which couples to an RF stage 34. The
communicated signal is received at antenna 32 and converted to an IF
signal through RF stage 34. RF stage 34 couples to a limiter 36, which
removes a large portion of amplitude variation from the bi-phase
communicated signal, leaving the signal's frequency content. Limiter 36
couples to a surface acoustic wave (SAW) correlator 38.
Correlator 38 is formed so that the predetermined PN sequence discussed
above in connection with PN code generator 22 is preprogrammed therein.
Accordingly, correlator 38 is used to perform a correlation function upon
the communicated signal. When correlator 38 is loaded with a communicated
signal conveying the PN sequence, correlation results. During the
correlation, correlator 38 generates a large amplitude output. However,
under other circumstances correlator 38 generates a smaller amplitude
output. Correlator 38 couples to an IF amplifier 40, which amplifies the
output signal from correlator 38. An output of IF amplifier 40 couples to
a detector 42, which performs an absolute value and filtering operation on
the signal. An output of detector 42 couples to a buffer amplifier 44,
which provides amplification and impedance matching for subsequent
operations. The output of buffer 44 generates a correlation signal 46, an
example of which is shown in the bottom trace of FIG. 2.
The preferred embodiment of the present invention exploits the nature of PN
sequences and SAW correlator 38 to control the behavior of correlation
signal 46. So long as correlator 38 is entirely loaded with its PN
sequence, even though it is not correlating, it generates less noise than
it generates when loaded with random noise or other signals. In theory,
for a maximal length 127 bit code the time sidelobes generated by
correlator 38 should be around 42 dB below a peak amplitude achieved
during correlation. However, in practice this value does not achieve the
42 dB attenuation due to manufacturing imperfections. Nevertheless, the
time sidelobe output produced by correlator 38 when a currently received
bit 18 and an immediately previous bit 18 convey the PN sequence are less
than the output produced by correlator 38 when it is not preloaded with
the PN sequence from the immediately previous bit 18.
FIG. 2 graphically illustrates this phenomenon. Spikes or peaks 48 of
correlation signal 46 occur when correlator 38 is completely loaded and
correlates with its PN sequence. Prior to the end of the third bit of bits
18, correlator 38 was loaded with random noise. During this prior period,
correlation signal 46 exhibited a generally high level, as illustrated
during interval 50. This generally high noise level decreases as more of
the PN sequence loads into correlator 38. After correlation for the fourth
bit 18, the fourth bit's PN sequence exits correlator 38 as the fifth
bit's PN sequence loads. Thus, during the fifth bit, which occurs after
spike 48 for the fourth bit, the noise level of correlation signal 46 is
relatively low because correlator 38 has been preloaded with its PN
sequence. This is shown in FIG. 2 as the low amplitude of correlation
signal 46 after spike 48 at the end of the fourth bit.
Referring back to FIG. 1, buffer 44 couples to inputs of a long term peak
detector 52, an event comparison circuit 54, a short term peak detector
56, a data comparison circuit 58, and a timing comparison circuit 60. An
output of long term peak detector 52 couples through a resistor divider
chain 62 to a ground node 64. An intermediate node of resistor divider
chain 62 couples to an input of event comparison circuit 54. Likewise, an
output of short term peak detector 56 couples through a resistor divider
chain 66 to ground node 64. A first intermediate node of resistor divider
chain 66 couples to an input of data comparison circuit 58, and a second
intermediate node of resistor divider chain 66 couples to an input of
timing comparison circuit 60.
Long term peak detector 52 is configured to sample the peak level of
correlation signal 46 (see FIG. 2) and to hold this peak level for a long
term, which is on the order of 2-5 seconds in the preferred embodiment.
Resistor divider chain 62 is configured so that the intermediate output
establishes an event threshold 68 which is around 1/2 of this peak value.
FIG. 2 depicts event threshold 68 as a dotted line shown in relation to
correlation signal 46. Consequently, event comparison circuit 54 finds
correspondence with event threshold 68 whenever the instantaneous value of
correlation signal 46 exceeds about 1/2 of the peak signal level achieved
by correlation signal 46 over a previous predetermined duration of more
than a couple of seconds.
By finding correspondence with a threshold, such as event threshold 68 or
other thresholds discussed below, those skilled in the art will understand
that such correspondence may result from either exceeding the threshold or
falling below the threshold. For example, in alternate embodiments of the
present invention, polarities may be reversed so that comparison circuits
find correspondence when a signal falls below a threshold.
Event comparison circuit 54 detects the occurrence of the first one of bits
18 from message 16. Subsequent logical one bits are also detected, but
this is of little consequence in the preferred embodiment of the present
invention. Long term peak detector 52 provides a mechanism so that this
detection self-compensates for false alarms.
As discussed below, the detection of the first bit 18 of message 16 starts
a chain of events that continues for longer than the duration of message
16. If event threshold 68 is set too low, event comparison circuit 54 may
trigger on noise, and the chain of events will then commence and possibly
prevent legitimate messages 16 from being recognized. If event threshold
68 is set too high, event comparison circuit 54 may fail to trigger on
weaker correlation signals 46. Thus, if receiver 14 fails to detect events
for a long term period, event threshold 68 begins to droop so that weaker
and weaker correlation signals 46 will be recognized as events. The
chances of falsely triggering on noise increase, but since receiver 14 is
not detecting many events the chances of a false trigger preventing
legitimate messages 16 from being recognized are low in this situation. On
the other hand, if receiver 14 is detecting many events, then event
threshold 68 remains high so that the likelihood of falsely triggering on
noise is reduced and the chances of legitimate messages 16 not being
recognized are likewise low.
Short term peak detector 56 is configured to quickly sample the peak level
of correlation signal 46 (see FIG. 2) and to hold this peak level for only
a short term, which is slightly longer than the duration of message 16 in
the preferred embodiment. Resistor divider chain 66 establishes a data
threshold 70, which is shown in FIG. 2, at the first intermediate output
and a timing threshold 72, which is also shown in FIG. 2, at the second
intermediate output. Desirably, data threshold 70 is set at slightly
greater than 1/2 the peak value while timing threshold 72 is set at less
than 1/2 the peak value. More preferably, data threshold 70 is set at
around 5 dB below the peak value and timing threshold 72 is set at around
12 dB below the peak value in the preferred embodiment.
Data comparison circuit 58 detects correspondence between the instantaneous
value of correlation signal 46 and data threshold 70. When correspondence
is detected, a logical one may be recovered from the communicated signal.
When correspondence is not detected at an appropriate time, a logical zero
may be recovered from the communicated signal. Timing comparison circuit
60 detects correspondence between the instantaneous value of correlation
signal 46 and timing threshold 72. When correspondence is detected, time
may be measured to identify when the communicated signal arrives at
receiver 14.
As discussed above, the noise level of correlation signal 46 increases, as
shown at interval 50 in FIG. 2, when correlator 38 has not been preloaded
with its PN sequence. Moreover, correlator 38 is not preloaded with its PN
sequence when either the current or previous bit 18 is a logical zero.
Thus, data threshold 70 is set at a higher level so that the chances of
finding correspondence with noise are very low while the chances of
finding correspondence with a legitimate spike 48 (see FIG. 2) are very
high.
On the other hand, timing threshold 72 is set at a lower level so that
correspondence will be found as soon as possible relative to the leading
edge of the spike 48 that results from the second bit of bits 18 in
message 16, as illustrated at point in time 74 in FIG. 2. The lower the
timing threshold 72 the better because the influence of multipath is
minimized. If multipath and direct path communicated signals tend to
subtract from one another at receiver 14, then the combined correlation
signal 46 may exhibit a more gradual slope than results from the direct
path signal alone. A higher value timing threshold 72 would magnify the
effects of the more gradual slope and provide a greater timing error. In
addition, since the noise level of correlation signal 46 is lower during
the second bit 18 of message 16 than it may be at other times in message
16, the low value for timing threshold 72 does not significantly risk
false triggering on noise.
The event, data, and timing thresholds against which the instantaneous
value of correlation signal 46 is compared are determined in response to
peak values for correlation signal 46 rather than in response to a noise
floor. This implementation is desirable because it provides greater
immunity from noise. In particular, receiver 14 need not be configured to
operate in accordance with worst case noise considerations. In addition, a
more consistent and robust performance is obtained because the signal
peaks and not the noise floor convey the information gathered by receiver
14.
An event clock signal 76, for which a timing diagram is shown in FIG. 2,
drives enable inputs of comparison circuits 58 and 60. When event clock
signal 76 is inactive, which is depicted as a low level in FIG. 2,
comparison circuits 58 and 60 are prevented from finding correspondence.
In the preferred embodiment, comparison circuits 58 and 60 have separate
data and timing event clocks. As shown in FIG. 2, event clock signal 76 is
inactive until after a previous spike 48 (not shown) from the first bit
crosses the event threshold 68 in message 16. Thus, through event clock
signal 76, comparison circuits 58 and 60 are prevented from finding
correspondence during the first bit of message 16.
FIG. 3 shows a block diagram of a control section 78 of receiver 14. As
shown in FIG. 3, a control logic block 80 of control section 78 generates
event clock signal 76. Control logic block 80 uses conventional counter
circuits (not shown) to generate event clock signal 76 in response to the
activation of an event signal. The event signal activates when event
comparison circuit 54 (see FIG. 1) detects the first bit of message 16
(not shown in FIG. 2). Generally speaking, event clock signal 76 activates
prior to the end of each bit 18 in message 16, except for the first bit
18. Event clock signal 76 remains active into the beginning of the next
bit 18. Thus, event clock signal 76 will be active if a spike 48 occurs
due to the conveyance of a logical one bit in message 16.
Data comparison circuit 58 (see FIG. 1) generates a data signal that sets a
flip flop 82 when correspondence with data threshold 70 (see FIG. 2) is
found. Event clock signal 76 or its inverse drives a reset input of flip
flop 82 so that flip flop 82 resets when event clock signal 76 is
inactive. An output of flip flop 82 couples to a data input of a shift
register 84, and the event clock signal 76 or its inverse also drives a
clock input of shift register 84. Polarities are arranged so that shift
register 84 clocks as event clock signal 76 goes inactive.
Flip flop 82 and shift register 84 recover data, other than the first bit
of message 16, from the communicated signal. The flip flop 82 storage
element is reset prior to the general timing interval where a spike 48
(see FIG. 2) might be present. Flip flop 82 is then set when a logical one
data bit 18 causes a spike 48 (see FIG. 2). Flip flop 82 is not set and
remains in its reset state when logical zero data bit 18 occurs. The state
of flip flop 82 is shifted into the shift register 84 storage element
after each bit 18 in message 16.
Timing comparison circuit 60 (see FIG. 1) generates a timing signal that
resets a flip flop 86 when correspondence with data threshold 72 (see FIG.
2) is found. An output of flip flop 86 couples to an enable input of a
high speed counter clock 88 and to a first input of a logic gate 90.
Polarities are arranged so that counter clock 88 refrains from counting
when flip flop 86 is reset, and flip flop 86 resets as soon as timing
comparison circuit 60 (see FIG. 1) finds correspondence with timing
threshold 72. Flip flop 86 remains reset throughout the remainder of
message 16, and counter clock 88 is prevented from counting throughout the
remainder of message 16.
A high speed clock signal, that in the preferred embodiment oscillates at
almost 1 GHz, drives a master clock 92 and a clock input of high speed
counter clock 88. Due to the high speed of the high speed clock signal,
all or at least the faster stages of clocks 88 and 92 are implemented
using an appropriate digital circuit technology, such as ECL. However,
slower stages may be implemented using CMOS or other less expensive and
complex digital circuit technologies. Master clock 92 and high speed
counter clock 88 represent counter circuits. An output, such as a terminal
count output, of clock 92 couples to a second input of logic gate 90.
However, master clock 92 may serve as a master clock for multiple ones of
receivers 14 and not just a single receiver 14 as shown in FIG. 3.
Master clock 92 and logic gate 90 provide a synchronizing function for
counter clock 88. Logic functionality and signal polarities surrounding
logic gate 90 are arranged so that counter clock 88 synchronizes with
master clock 92 from time to time by being cleared, loaded with a
predetermined value, or the like. More particularly, synchronization
occurs when flip flop 86 has enabled counter clock 88 and master clock 92
reaches a terminal count.
Once initialized or synchronized with master clock 92, high speed counter
clock 88 marks the passage of time in a manner that is consistent with
master clock 92. Counter clock 88 counts oscillations of the high speed
clock signal until disabled by flip flop 86. Counter clock 88 becomes
disabled when correlation signal 46 (see FIG. 2) corresponds to timing
threshold 72 (see FIG. 2). Counter clock 88 remains disabled throughout
the remainder of message 16 so that the count achieved at the moment of
being disabled does not change.
Control logic block 80 couples to a computer 94, as does shift register 84
and high speed counter clock 88. After the end of message 16, control
logic 80 may inform computer 94 of the presence of message 16. Computer 94
may then read the data and timing from shift register 84 and counter clock
88, respectively. After the data and timing have been read, control logic
80 is free to activate an end-of-message signal 96, for which a timing
diagram is shown in FIG. 2. End-of-message signal 96 drives a set input of
flip flop 86. By setting flip flop 86 after data and timing have been
read, counter clock 88 again becomes enabled to count. Then, after a
predetermined period of time counter clock 88 becomes synchronized with
master clock 92.
Computer 94 may use the data and timing information in any manner which is
useful to system 10 (see FIG. 1). For example, computer 94 may subtract
the duration of one bit 18 from the timing data measured by counter clock
88 to determine the time of arrival of the initial bit of message 16.
Alternatively, computer 94 may simply compare different times of arrival
measured from different receivers 14 in a conventional manner while
performing a multilateration location process.
In summary, the present invention provides an improved system for
identifying an arrival time of a communicated signal. A spread spectrum
communicated signal is used to reduce the corrupting influences of
multipath. These corrupting influences are further reduced by determining
time of arrival in correspondence with a low timing threshold. The
preferred embodiments of the present invention identify a point in time
during-the transmission of a message when noise on a correlation signal
will be reduced to lessen the chances of falsely indicating a time of
arrival in response to noise. Furthermore, the thresholds against which
the detection signal is compared are determined in response to peak values
of the correlation signal rather than in response to a noise floor.
The present invention has been described above with reference to preferred
embodiments. However, those skilled in the art will recognize that changes
and modifications may be made in these preferred embodiments without
departing from the scope of the present invention. For example, different
signals could be used to enable data and timing comparison circuits with
different timing. Moreover, different logic could be used to recover data
and timing data from the data and timing comparison circuits. In addition,
not all features described above need be included in a workable system
that incorporates the present invention. For example, the variable event
threshold discussed above may be replaced by a constant predetermined
value with only slight degradation in performance. These and other changes
and modifications which are obvious to those skilled in the art are
intended to be included within the scope of the present invention.
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