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Claims  |
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We claim:
1. A range limiting system for differentiating between a first received
signal having a recognizable characteristic which is an amplitude above a
predetermined threshold level and at least one other recognizable
predetermined characteristic, and a second received signal below said
predetermined threshold amplitude, comprising:
means for combining a received signal of unknown amplitude, which may be a
first received signal above said predetermined threshold amplitude or a
second received signal below said predetermined threshold amplitude, with
a known signal of said predetermined amplitude having at least one other
predetermined characteristic which is distinguishable from said other
recognizable predetermined characteristic of said first received signal;
and
signal processing means including amplitude comparison means for detecting
relative signal amplitudes, having the combined signal as its input and
which produces an output signal whose other recognizable characteristic is
determined by said received signal only when said received signal is above
said predetermined threshold amplitude, and by said known signal when said
received signal is below said predetermined threshold amplitude, whereby
the presence or absence of said first received signal may be determined on
the basis of analysis of said other predetermined characteristic of said
output signal of said signal processing means.
2. The range limiting system of claim 1 further characterized by said other
predetermined characteristic of said first received signal being
distinguishable from said other characteristic of said known signal on the
basis of time-related features.
3. The range limiting system of claim 2 further characterized by said
time-related features being frequency differences.
4. The range limiting system of claim 2 further characterized by said
time-related features being phase differences.
5. The range limiting system of claim 1 further characterized by said
signal processing means being a limiting amplifier.
6. The range limiting system of claim 1 further characterized by said
signal processing means being a voltage comparator.
7. The range limiting system of claim 1 further characterized by said
signal processing means being a limiting amplifier combined with a voltage
comparator.
8. The range limiting system of claim 1 further characterized by said
combining means being an r.f. coupler.
9. A range limiting system for differentiating between a first received
signal having a recognizable characteristic which is an amplitude above a
predetermined threshold level and at least one other recognizable
predetermined characteristic, and a second received signal below said
predetermined threshold amplitude, comprising:
means for supplying a known signal of said predetermined threshold
amplitude having at least one other predetermined characteristic which is
distinguishable from said other recognizable predetermined characteristic
of said first received signal;
means for combining a received signal of unknown amplitude, which may be
above or below said predetermined threshold amplitude, with said known
signal;
signal processing means including amplitude comparison means for detecting
relative signal amplitudes, having the combined signal as its input and
which produces an output signal whose other recognizable characteristic is
determined by said received signal only when said received signal is above
said predetermined threshold amplitude, and by said known signal when said
received signal is below said predetermined threshold amplitude, whereby
the presence or absence of said first received signal may be determined on
the basis of analysis of said other predetermined characteristic of said
output signal of said signal processing means.
10. The range limiting system of claim 9 further characterized by said
first received signal being supplied by a modulated backscatterer.
11. The range limiting system of claim 10 further characterized by said
known signal being supplied by an additional modulated backscatterer.
12. The range limiting system of claim 10 further characterized by said
second undesireable signals being supplied by an aditional modulated
backscatterer of the same general type that supplies the desired received
signals.
13. A range limiting system for differentiating between a first received
signal having a recognizable characteristic which is an amplitude above a
predetermined threshold level and at least one other recognizable
predetermined characteristic, and a second received signal below said
predetermined threshold amplitude, comprising:
means for combining a received signal of unknown amplitude, which may be a
first received signal above said predetermined threshold amplitude or a
second received signal below said predetermined threshold amplitude, with
a known signal of said predetermined amplitude having at least one other
predetermined characteristic which is distinguishable from said other
recognizable predetermined characteristic of said first received signal;
signal processing means including amplitude threshold comparison means for
detecting signal amplitudes, having the combined signal as its input and
which produces an output signal whose other recognizable characteristic is
determined by said received signal only when said received signal is above
said predetermined threshold amplitude, and by said known signal when said
received signal is below said predetermined threshold amplitude, whereby
the presence or absence of said first received signal may be determined on
the basis of analysis of said other predetermined characteristic of said
output signal of said signal processing means; and
means for determining the presence of a first received signal from the
output of said signal processing means by distinguishing the between said
first and said known signals on the basis of said other predetermined
characteristic.
14. The range limiting system of claim 13 further characterized by said
other predetermined characteristic of said first received signal being
distinguishable from said other characteristic of said known signal on the
basis of time-related features.
15. The range limiting system of claim 14 further characterized by said
signal presence determining means being a frequency detection circuit.
16. A range limiting system for differentiating between a first received
signal having a recognizable characteristic which is an amplitude above a
predetermined threshold level and at least one other recognizable
predetermined characteristic, and a second received signal below said
predetermined threshold amplitude, comprising:
means for supplying a known signal whose amplitude is selected to be the
threshold amplitude above which it is desired to receive signals, said
known signal having at least one other recognizable predetermined
characteristic which is distinguishable from said other recognizable
predetermined characteristic of said first received signals;
means for combining a received signal of unknown amplitude, which may be
above or below said predetermined threshold amplitude, with said known
signal; and
signal processing means including amplitude threshold comparison means for
detecting relative signal amplitudes, having the combined signal as its
input and which produces an output signal whose other recognizable
characteristic is determined by said received signal only when said
received signal is above said predetermined threshold amplitude, and by
said known signal when said received signal is below said predetermined
threshold amplitude, whereby the presence or absence of said first
received signal may be determined on the basis of analysis of said other
predetermined characteristic of said output signal of said signal
processing means.
17. The range limiting system of claim 16 further characterized by means
for supplying a known signal being a backscatter modulator whose
predetermined threshold amplitude is determined by the extent to which it
is coupled to said combining means.
18. The range limiting system of claim 16 further characterized by means
for supplying a known signal being a backscatter modulator whose
predetermined threshold amplitude is determined by the depth of
modulation. |
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Claims |
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Description |
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BACKGROUND AND FIELD OF THE INVENTION
This invention relates to a range limiting system which permits detection
of desired backscatter-modulated signals but prevents detection of
undesired backscatter-modulated signals and also effectively discriminates
against system and radiated noise. More particularly, the system of the
invention uses a deliberately injected signal which is combined both with
desired and undesired signals to generate a combined signal from which
desired backscatter-modulated signals can readily be detected. Systems of
this type are described in U.S. Pat. No. 4,739,328 assigned to the same
assignee as the subject invention.
The signals used in the invention to be detected come from small
backscatterers, called "tags". These tags are located on moving or movable
objects, such as vehicles, trains, or shipping containers. In the case of
vehicles, for example, it is desirable to obtain specific information
relating to the car or truck. The information is contained in the tag
mounted on the vehicle, and is transmitted by backscatter modulation from
the moving vehicle as it passes through a toll lane. However, other tagged
vehicles also are passing through adjacent lanes or moving behind the
desired vehicle in the same lane at the same time. If the backscattered
signal-collecting antenna is aimed properly, there will be a small
difference in signal strength between a desired and an undesired
backscattered signal. However, in the presence of other noise, as well as
system noise in the detection system itself, these small amplitude
differences have been found to be hard to distinguish.
One technique used to improve the discrimination ability of the system is
described in U.S. Patent Application Ser. No. 254,254 filed Oct. 6, 1988
and assigned to the same assignee as the subject invention. However, the
technique of this invention is an alternative, and may indeed be employed
together with the technique of the above-identified patent application to
produce the most effective signal discrimination, particularly in areas of
heavy signal traffic.
THE PRIOR ART
White noise has been used in the past to modulate the carrier frequency of
transmitted radar signals. The return echo from the target is mixed with a
portion of the transmitted signal. The mixer output is amplified in a
bandpass amplifier. The coherent and incoherent portions of the amplified
signal are then compared. If the coherent portion is greater by a
predetermined amount than the incoherent portion, the target is known to
have been detected by the radar. Such as system using white noise is
described in U.S. Pat. No. 3,906,493. A similar system using colored noise
is described in U.S. Pat. No. 3,668,702. Another radar thresholding
technique which varies the threshold level up and down to eliminate noise
and clutter is described in U.S. Pat. No. 3,701,149. This system stores
sample pulse doppler echo returns in a filter bank. The samples are
sequenced into a string of shift register networks and compared on the
basis of their thresholds to an averaged threshold level which varies in
accordance with the noise and clutter level. The frequency average of the
noise and clutter is separated by varying the threshold sampling level up
and down to eliminate the noise and clutter from the detected signal,
which then protrudes above the threshold.
All of these prior art systems mix noise or other non-deterministic signals
with the transmitted signal for purposes of signal discrimination. Noise
and clutter are signals unintentionally present in the system. To the
contrary, the range limiting system of the present invention purposely
introduces a deterministic signal, having no desired information to be
obtained, with the received signal to prevent the detection of a received
signal from a tag that is of lower amplitude level than desired.
Noise which affects signal detection and reliability can come from many
sources. In addtional to the external radiated noise picked up by the
system antenna, whose type and amplitude are unpredictable, there also
will be reader and amplifier noise, which is more predictable, but which
may vary somewhat from one piece of equipment to another. Moreover, the
amount of this system noise may also vary with ambient conditions such as
temperature, making it unpredictable as well.
The amplitude of the desired returned signal also varies. For example, the
amplitude may vary with the transmitted r.f. power, the distance between
the reader antenna and the tag, the orientation of the tag vis-a-vis the
antenna, the efficiency of the tag, as well as environmental factors such
as fog, rain, snow and physical obstructions between the tag and the
reader. It is not always possible to have geographic and environmental
conditions sufficiently clear to discriminate between close tags without
the improvement of this invention.
BRIEF DESCRIPTION OF THE INVENTION
Briefly, the range limiting system of the invention is capable of
differentiating desired received signals having an amplitude above a
predetermined threshold level and at least one other recognizable
predetermined charactistic, from other received signals below that
predetermined threshold amplitude. The system has a means for combining
the received signal, which is of unknown amplitude which may be above or
below the predetermined threshold amplitude, with a known signal of the
predetermined threshold amplitude having at least one other predetermined
characteristic which is distinguishable from the other recognizable
characteristic of the received signal. The output of the combining means
passes to a signal processing means which produces an output signal whose
other recognizable characteristic is determined by the received signal
only when the received signal is above the predetermined threshold
amplitude, and by the known signal when the received signal is below the
predetermined threshold amplitude. The presence or absence of the desired
received signal is determined on the basis of analysis of the other
predetermined characteristic of the output signal of the signal processing
means.
The use of a known, deterministic signal, as described, has significant
advantages over the prior art systems which introduce random signals, or
"noise". Even though the return signal from the tag in the system of the
invention is somewhat uncertain, the known signal against which the return
signal is compared is no longer uncertain or variable. Contrary to noise
signals, it is possible to make the known signal in this invention
insufficiently larger than the natural noise floor of the system so that
variations in the natural noise do not affect the system sensitivity of
range. Moreover, the known signal used in this invention does not have the
fuzzy or random properties of white or colored noise, allowing the setting
of a sharp threshold and preventing the desired range setting to be
unaffected by the statistical properties of random noise.
Still another advantage of the system of the invention is, because the
known signal is not random, that the r.f. transmitted power level may be
kept higher than if random noise were used as the threshold setting
criterion. This ensures that the return signal level is comfortably above
that of system, amplifier and environmental noise levels.
It is also important that the known signal have at least one property in
addition to amplitude which makes it distinguishable from real returned,
backscatter-modulated signals from a real tag. In a preferred embodiment,
the known signal is a steady 40 kHz square wave signal which is injected
into the system within the signal path between the tag and the reader.
Alternatively, the known signal may be coupled to the reader itself. Such
a steady 40 kHz signal can readily be distinguished from return tag
signals which typically alternate between 40 kHz and 20 kHz.
One option for supplying the known signal is to use a special tag-like
device, such as an extra tag, that interacts in space with the r.f. field
of the tag to be detected. The known signal enters the system in the same
way that the real return, backscatter-modulated signal from the tag does.
The amplitude of the known signal can be set either by spatial placement
of an additional tag, or by regulating the drive to the modulating element
in the additional tag. If the known signal from this additional tag is of
greater amplitude than other return tag signals, the system will not read
any of the normal return tags. Thus, the known signal provides an
effective mask against reading unwanted tags. Desired tags will have a
signal amplitude in excess of the tag providing the known signal.
If the direct coupling method is employed, the known signal may be coupled
using a coupling device placed in the r.f. coaxial cable connection
between the r.f module and the antenna. The amplitude ma be controlled by
using controllable attenuation in the coupling between the r.f.
module-to-antenna r.f. cable and the modulating element. Alternatively,
the 40kHz signal drive to the modulating element may be varied.
DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of a preferred embodiment of the invention;
FIG. 2 is a schematic diagram of another preferred embodiment of the
invention;
FIG. 3 (a)-(d) are a series of graphs showing the output during the receipt
of a desired signal in the range limiting system of a preferred embodiment
of the invention; and
FIG. 4 (a)-(d) are a series of graphs showing the output in the absence of
the receipt of a desired signal in the range limiting system of a
preferred embodiment of the invention.
Referring to FIG. 1, an r.f. signal is transmitted by transmitter/receiver
10, through circulator 11 to antenna 12 to tag 13. The transmitted signal
is backscatter-modulated by tag 13 using an alternating 20 kHz-to-40 kHz
signal as the modulator. The desired information from the tag is contained
in the shifts between 20 and 40 kHz. The return signal from tag 13 is
received by antenna 12, fed through circulator 11 to mixer 14. The
transmitted signal from transmitter/receiver 10, also fed to mixer 14, is
used in the decoding process, as described is U.S. Patent Application Ser.
No. 254,254, filed Oct. 6, 1988 and assigned to the same assignee as the
subject invention. The return signal passes from mixer 14 through
capacitor 16 and limiting amplifier 17 to decoder 18.
The known signal, for example, in the preferred embodiment, a 40 kHz square
wave signal, is injected into amplfier 20 and is fed through variable
attenuator 21 and capacitor 22, into a modulating circuit 25. Modulating
circuit 25 is made up of resistor 26, which may for example be lK ohms,
capacitor 27, which may, for example be 68 picofarads, and diode 28, which
may, for example, be a No. 5082-2800 diode manufactured by the Hewlett
Packard Corporation. Modulating circuit 25 causes a small change in the
impedance between circulator 11 and antenna 12. The modulated output of
modulating circuit 25 flows back through circulator 11 into mixer 14, and
on to decoder 18, where its effect will be described below. A small part
of its output signal power will also be transmittted through antenna 12.
However, the level of this portion is sufficiently small to pass all
regulatory requirements. The amplitude of the 40 kHz signal can be
adjusted using variable attenuator 21, preferably a log taper
potentiometer.
The circuit of FIG. 2 represents another preferred embodiment of the
invention. Components corresponding to those shown in FIG. 1 bear the same
reference numbers. In this embodiment, the 40 kHz known signal is injected
into modulating FET device 41. The strength of the 40 kHz modulated r.f.
signal is varied using variable attenuator 42. The output of attenuator 42
is coupled to the r.f. line between circulator 11 and antenna 12. The
microstrip coupler 50, which may be used to couple these signals, must be
well designed, preferably using coaxial construction, since the isolation
between the transmitter/receiver 10 and the modulating FET 41 should be on
the order of 20 to 100 dB, depending on the level of the injected 40 kHz
signal. Modulation is provided by changing the r.f. impedance of the FET
41. In this embodiment as well, very little of the injected, known 40 kHz
signal arrives at antenna 12 again well within Federal regulation.
Resistor 43 is the normal back-termination resistance for coupler 50.
The operation of the range limiter of the invention may be best understood
by reference to FIGS. 1 and 2 together with the graphs of FIGS. 3 and 4. A
representative returned tag signal is shown in FIG. 3(a). This signal
typically is a square wave having pulses either at 20 or 40 kHz. Using the
apparatus of FIGS. 1 or 2, this tag return signal is combined with the
injected, known 40 kHz signal shown in FIG. 3(b). In the preferred
embodiment of this invention, the two signals are combined as modulated
r.f. signals before r.f. detection. The detector or mixer output would
have the appearance of the signals shown in FIGS. 3 and 4 if such signals
were viewed on an oscilloscope. The combination of these signals as r.f
signals before detection ensures that they are linearly combined.
Alternatively one could combine the signals as "baseband" signals after
detection and before amplification, but this is disadvantageous because,
in the preferred embodiment of the system of this invention, there are
three parallel channels of amplification and therefore three injection
circuits would have to be used. Additionally, combination as modulated
r.f. signals has the advantage of making the threshold setting
substantially independent of variations in the transmitted r.f. level.
It should be obvious to one skilled in the art that the amplitude and
polarity of the output of mixer 14 is dependent upon the relative r.f.
phasing between the reference input to the mixer from transmitter/receiver
10 and the modulated backscatter signals both from tag 13 and from the
injected known signal, whether it is derived as in the circuit of FIG. 1
or in the circuit of FIG. 2. Apparatus for working around this r.f.
phasing problem have been described in U.S. Pat. Nos. 4,075,632 and
4,739,328, assigned to the same assignee as the subject invention, and it
is apparent that the phasing problems between the returned tag signal and
the known signal can be dealt with in the same way as described in these
previous inventions.
The discussion which follows assumes that there is no relative phasing
problem and that both the returned r.f. signal from the tag and the known
signal are in the most favorable phase state so that the principles of the
subject invention can be described without discussion of phasing. While
there is a slight variation in threshold level setting depending on the
relative r.f. phasing, and there is a preferred phase for the known
injected signal, the effect is relatively minor and does not substantially
detract from the usefulness of this method.
In this illustration of FIG. 3, the known signal of FIG. 3(b) is of smaller
amplitude than the returned tag signal in FIG. 3(a). When they arrive at
the output of mixer 14, these signals have been summed, and appear as
shown in FIG. 3(c). The combined signals have the odd pulse shapes shown.
They are then passed through limiting amplifier 17 which produces an
output signal as shown in FIG. 3(d). Since the known 40 kHz signal is of
lower amplitude than the returned tag signal in this illustration,
limiting amplifier 17, which constructs pulses at the intersections of
dotted line 51, representing the threshold amplitude limit of amplifier
17, produces an output signal which has the exact distinguishable
characteristics of the original returned tag signal, as shown by comparing
FIGS. 3(a) and 3(d). This amplitude-limited sum signal will provide the
user with all the data encoded in the tag, which was backscatter modulated
onto the return signal.
Where the return signal from the tag is of lower amplitude than the known
40 kHz injected signal, the results are shown in FIGS. 4(a)-(d). The small
tag signal is shown in FIG. 4(a). The larger known injected 40 kHz signal
is shown in FIG. 4(b). The combined signals from mixer 14 are shown in
FIG. 4(c). After limiting, the signal from amplifier 17 is shown in FIG.
4(d). Note that the limiting amplifier always reconstructs the larger in
amplitude of the combined signals. In this case, the larger is the
injected 40 mHz known signal, which is reconstructed in FIG. 4(d). Since
the known signal has a known characteristic in addition to its amplitude
which is different from the tag signal, it can readily be identified. For
example, using the apparatus described in U.S. Patent Application Ser. No.
149,609, filed Jan. 28, 1988, and assigned to the same assignee as this
invention, the regular, single frequency nature of the injected signal may
readily be distinguished from the tag signal which mixes 20 and 40 kHz
frequency components. In this case, the range limiting circuit of this
invention will prevent an undesired tag signal, whose amplitude is below
the threshold desired, as set by the known signal threshold amplitude,
from being read.
Although a 40 kHz square wave is preferred as the known signal, any signal
which has a characteristic other than its amplitude which distinguishes it
from a tag signal may be used. Square wave signals are compatible with the
equipment described in the decoder of the above-referenced U.S. Patent
Application.
Although the invention has been described with respect to its preferred
embodiments, many modifications may be made without departing from the
spirit and scope of the invention as set forth in the claims which follow.
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Description |
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