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Claims  |
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What is claimed is:
1. A closed loop optical gauge comprising:
laser means for producing a first beam;
means for directing at least a portion of said first beam toward a target
from which a beam is reflected;
means for providing a reference beam having the frequency of said first
beam;
frequency shift means receiving said reference beam and receiving a
modulation input signal, for providing a shifted reference beam whose
frequency is shifted from that of the reference beam in accordance with
the modulation input signal;
means for producing interference of said shifted reference beam and said
reflected beam to produce a beat frequency signal;
negative feedback means for utilizing said beat frequency signal to control
the frequency of said modulation input signal;
whereby the frequency of said shifted reference beam tracks the reference
of said reflected beam and has a known relationship to the radial
component of velocity of said target.
2. A closed loop optical gauge as defined in claim 1 and wherein said means
for producing interference of said beams comprises:
detection means for detecting the envelope of a light beam incident thereon
and producing an electrical signal corresponding to the envelope; and
means for combining said shifted reference beam and said reflected beam to
be incident upon said detection means.
3. A closed loop optical gauge as defined in claim 1 and wherein said
negative feedback means for utilizing said beat frequency signal to
control said modulation input signal comprises FM discriminator means
receiving said beat frequency signal from said interference means, for
controlling a voltage controlled oscillator to track the frequency of said
beat frequency signal, the output of said voltage controlled oscillator
being arranged to provide said modulation input signal.
4. A closed loop optical gauge as defined in claim 1 and wherein said means
for providing a reference beam having the frequency of said first beam
comprises:
beam splitter means in said first beam for redirecting a portion of said
first beam to said frequency shift means.
5. A closed loop optical gauge as defined in claim 1 and wherein said
frequency shift means comprises acoustooptical modulator means for
shifting the frequency of said reference beam by an amount dependent upon
the modulation input signal.
6. A closed loop optical gauge as defined in claim 5 and wherein said
acoustooptical modulator means comprises a Raman-Nath acoustooptical
modulator.
7. Apparatus for measuring the distance to an object by optical time of
flight measurement, comprising:
light source means for providing an envelope modulated light beam directed
to impinge upon said reflect from the object, whose envelope has a
fundamental first harmonic component and at least one higher harmonic
component;
first detector means receiving a reference sample of the direct beam, for
providing a first detected signal representing the envelope of said
reference sample;
phase locked loop means receiving said first signal, for locking the phase
locked loop to said reference envelope;
said loop comprising a controllable oscillator of predetermined output
frequency, communicating with a frequency divider having a correspondingly
predetermined divisor so that the divider's output frequency is equal to
reference envelopes' fundamental frequency;
second detector means receiving the beam reflected from the object, for
providing a second detected signal representing the envelope of said
reflected beam;
main phase comparison means receiving (a) the output signal of said
controllable oscillator and (b) at least the corresponding harmonic
frequency of said second signal, for providing a third signal indicative
of the phase difference between them.
8. Apparatus as defined in claim 7 and wherein said phase locked loop
comprises means for selecting said predetermined oscillator frequency and
said corresponding predetermined divisor from among more than one harmonic
frequency.
9. Apparatus as defined in claim 7 and wherein said light source means for
providing an envelope modulated beam comprises means for providing a
substantially rectangular pulse modulated beam.
10. Apparatus as defined in claim 7 and wherein said light source means
comprises laser means.
11. Apparatus as defined in claim 7 and wherein said phase locked loop
means comprises, in addition to said controllable oscillator;
phase lock phase comparison means receiving said first signal and the
output signal of said divider, for producing a phase error signal; and
frequency selective filter means receiving said phase error signal, for
transmitting a predetermined range of frequency components of said phase
error signal, and connected to provide a filtered phase error signal to
said controllable oscillator.
12. Apparatus as defined in claim 7 and wherein said main phase comparison
means comprises a second frequency selective filter means receiving the
phase comparison of said signals (a) and (b), adapted for transmitting a
predetermined range of frequency components thereof to constitute said
third signal.
13. Apparatus for measuring the distance to an object by optical time of
flight measurement, comprising:
pulse laser means for providing a periodic train of pulse envelopes of
linearly polarized light in a directed beam, said train of envelopes
comprising a fundamental first harmonic component and at least one higher
harmonic component;
first polarized beam splitter means receiving said directed beam for
directly transmitting a portion of it toward the object and redirecting a
portion of it to serve as a reference beam;
first photodetector means receiving said reference beam from said first
polarized beam splitter means, for providing a detected reference signal,
in accordance with the envelope of pulses of said reference beam;
controllable oscillator means for producing a local signal having the
frequency of one of said first and higher harmonic components of said
detected reference signal;
frequency divider means communicating with the output of said controllable
oscillator means, for dividing the frequency thereof by an integer that is
the harmonic number of the frequency of the controllable oscillator means
relative to the envelope of said pulse train;
phase comparison means receiving said detected reference signal and the
output signal of said divider, for producing a phase lock error signal in
accordance with the phase difference between them;
frequency selective filter means receiving said phase lock error signal,
for transmitting a predetermined range of frequency components of said
phase lock error signal, and having an output connected control the
frequency of said controllable oscillator;
quarter wave plate means for circularly polarizing said direct portion of
beam transmitted toward said object, and linearly polarizing the return
beam reflected from said object;
polarized second beam splitter means receiving said reflected beam through
said quarter wave plate means and redirecting at least a portion to
represent said reflected beam;
second photodetector means receiving said redirected portion from said
second beam splitter means, for providing a second detected signal in
accordance with the envelope of pulses of said portion of said reflected
beam;
phase comparison means receiving (a) the output signal of said controllable
oscillator and (b) said second detected signal, for providing a third
signal indicative of the phase difference between the output signal of the
controllable oscillator and said selected harmonic frequency component of
said second detected signal;
filter means receiving said third signal, for providing an output signal
responsive to the difference in the time of flight of the two signals
received by said phase comparison means.
14. A method of closed loop optical gauging comprising the steps of:
radiating a first laser beam toward a target from which a beam is
reflected;
providing a reference beam having the frequency of said first beam;
applying said reference beam and a modulation input signal in a modulator,
and modulating the reference beam to produce a shifted reference beam
whose frequency is shifted in accordance with the modulation input signal;
interfering said shifted reference beam and said reflected beam to produce
a beat frequency signal;
utilizing said beat frequency signal to control the frequency of said
modulation input signal by means of negative feedback;
whereby the frequency of said shifted reference beam tracks the frequency
of said reflected beam and corresponds to the radial component of velocity
of said target.
15. A method of closed loop optical gauging as defined in claim 14 and
wherein said step of interfering said shifted reference beam and said
reflected beam comprises:
combining said shifted reference beam and said reflected beam to produce a
light beam incident upon a detector; and,
detecting the envelope of said light beam incident upon the detector and
producing an electrical signal corresponding to the envelope.
16. A method of closed loop optical gauging as defined in claim 14 and
wherein the step of utilizing said beat frequency signal to control said
modulation input signal comprises;
communicating said beat frequency signal to an FM discriminator for
controlling the voltage controlled oscillator; and
arranging the output of said voltage controlled oscillator to provide said
modulation input signal.
17. A method for closed loop optical gauging as defined in claim 14 and
wherein said step of providing a reference beam having the frequency of
said first beam comprises:
redirecting a portion of said first beam to said modulator with a beam
splitter positioned in said first beam.
18. A method for closed loop optical gauging as defined in claim 14 and
wherein said step of modulating said reference beam comprises modulating
it in a Raman-Nath acoustooptical modulator. |
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Claims |
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Description |
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CROSS REFERENCES TO RELATED APPLICATIONS
This application is one of a group of related applications that were filed
simultaneously on Sept. 30, 1987, including Ser. No. 103,085 entitled
"Dynamic Doppler Optical Gauge"; Ser. No. 103/086 entitled "Chirp Doppler
Optical Gauge; Ser. No. 103,087 entitled "Laser Doppler and Time of Flight
Range Measurement"; and Ser. No. 103,092 entitled "Laser Distance
Measuring Method and Apparatus". All were invented by Michael T. Breen.
FIELD
The invention relates to a branch of laser metrology in which the shape
and/or the motion of an object, for example the shape of a manufactured
part that is moving on a conveyor, is measured optically.
PRIOR ART
Prior known instruments do not have capability for obtaining data regarding
both absolute and relative distance and for combining them in the manner
of the present invention. Prior known laser metrological instruments based
on Doppler shift, which ordinarily are of an open-loop configuration, are
inherently not as accurate as the disclosed form of closed-loop Doppler.
Many range measuring systems are available that operate by measuring the
time of flight of a light signal that is directed to an object and
reflected back from it. The relative time of occurrence between a
reference signal pulse initiated at the gauge and the signal pulse that
was returned from the object can be measured, and, ambiguities resolved if
necessary. In view of the known velocity of propagation, the distance to
the object can be ascertained.
SUMMARY
To obtain shape information about the object under inspection, both the
Doppler shift of a laser beam reflected from the object and the "time of
flight" of a reflected laser pulse envelope are measured. The effects of
motion of the object can be separated from the shape information, and
either set of information can be disregarded by the system or presented as
additional data.
One object of the invention is to provide a system capable of measuring a
manufactured item on a moving conveyor to ascertain its shape.
Another object is to provide a data gathering system in which components of
the data that are due to the shape of the target are separable from
components of the data that are due to motion of a conveyor upon which the
target is carried.
Another object is to provide a system for inspection of a manufactured item
that employs programed dither of the laser beam's direction in order to
help separate motion-induced data from data regarding the shape of the
item.
Another object is to provide conveyor monitoring means such as calibration
articles or fiduciary marks on the conveyor within the field scanned by
the laser beam, so that conveyer-induced data can be deleted to get only
shape-induced data.
Another object is to provide a system for inspecting an item on a moving
conveyor, in which scanning in a direction longitudinal of the conveyor is
accomplished by travel of the conveyor, and transverse scanning is
accomplished by controllably deflecting a laser beam.
Another object of the invention is provide apparatus for making very
accurate measurements of the phase of a reference laser pulse envelope
relative to the phase of a target return pulse envelope.
Another object is accurately to measure the relative phase of a laser
reference beam and a target return beam by tracking the fundamental or a
higher harmonic of the reference beam with an electronic (not optical)
phase locked loop.
Another object is to improve accuracy by tracking the fundamental or a
higher harmonic of the target return beam with an electronic (not optical)
phase locked loop.
Another object is to improve accuracy by tracking the fundamental or a
higher harmonic of both the reference beam and the target return beam with
electronic (not optical) phase locked loops.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a simplified block diagram of a preferred embodiment of the
Doppler portion of the invention.
FIG. 2 is a block diagram of a preferred embodiment of the time of flight
portion of the invention.
DETAILED DESCRIPTION OF INVENTION
Two principles of operation for measurement are combined into one gauging
apparatus. A laser beam is directed to a moving spot on an object whose
shape is to be measured, and is reflected from the object. If the
reflection spot on the surface of the object has a radial component of
velocity with respect to the gauge, the reflected beam is different in
frequency from the outbound beam due to Doppler effect. The invented
system uses the Doppler frequency shift of the reflected beam as one
means of measurement of the motion, in a closed loop system.
Simultaneously another means of measurement, a time of flight system,
measures absolute distance from the gauge to the object. The time of
flight system is "open loop" from an optical standpoint, but the return
signal from the target is tracked by a closed phase locked electronic
loop. A scanner, a computer, and various other components are used in
common by both systems.
In the Doppler portion of the gauge, a reference sample of the original
direct beam is frequency-shifted by an acoustooptical modulator to produce
a shifted reference beam. A closed feedback loop is formed by first
sensing the difference in frequency between the reflected beam and the
shifted reference beam. This is done by detecting, in a photodiode, the
interference beat frequency between the shifted reference beam and the
reflected beam. The amount of frequency shift of the shifted reference
beam is then controlled so that the reference beam's frequency
continuously tracks that of the reflected beam, (preferably with a
frequency offset).
To accomplish this, an acoustooptical modulator is provided in the
reference beam path and a modulation-controlling signal for it is provided
by a voltage controlled oscillator (VCO). The VCO is controlled by a
signal that varies in accordance with the radial velocity of the object
relative to the gauge, and that also serves as a Doppler output voltage.
Position information can be derived by integrating that Doppler output
voltage with respect to time.
As shown in FIG. 1, a single frequency laser 1 produces a monochromatic
beam, which is divided by a beam splitter 2 into a direct beam 17 and a
redirected reference beam 13. The redirected reference beam enters an
acoustooptical modulator, which is preferably a Raman-Nath cell 3. A
modulating signal for the modulator cell is input at a terminal 18 of
modulator 3. A portion 16 of the beam energy is shifted in frequency by
the modulator, and the shifted portion is arranged spatially to be the
output of the modulator. The frequency shifted radiation beam 16, which
serves as a shifted reference beam, passes directly through another beam
splitter 11 toward a photodiode 4.
The direct beam 17 passes through a beam splitter 70 and a beam splitter
59, at which the pulsed time of flight beam is input. Both beams go
through a scanner 25, and out to a target object 9, where they are
reflected. Some of the energy reflected from the target returns to the
beam splitter 70, where it is redirected as a beam 14 to a diffraction
grating 60 and to a mirror 10. Light reflected from mirror 10 is
redirected at the beam splitter 11 so as to join the shifted reference
beam 16 passing straight through 11 from 3. The shifted reference and the
reflected beam are the two components that form a composite beam 19 that
falls upon the photodiode 4.
The two components of beam 19 interfere as they propagate to photodiode 4.
Their interference envelope is detected by the photodiode 4 and converted
to an electrical signal at a beat frequency. The electrical output signal
from photodiode 4 is connected at a terminal 20 to an FM discriminator 5.
The output of discriminator 5 is input to inverting integrator 6 the
output of a switchable which has the analog data from the closed loop
Doppler system. A switch 72 of the integrator 6 can be opened to convert
integrator 6 to a mere inverter if that mode of operation is prefered.
Terminal 15 feeds on analog to digital (A/D) converter 54, whose output
goes to a computer 56.
Connection is also made from the output of the integrator 6 to a control
input terminal 23 of a voltage controlled oscillator (VCO) 7. A feedback
loop is provided. It is closed by connecting the output of VCO 7 to the
modulator 3 (at terminal 18) to modulate the frequency of the shifted
reference beam 16. That modulation affects the beat frequency of the
composite beam 19, to complete a negative feedback closed loop system.
To avoid having to operate the VCO at an inconvenient frequency, the
circuit can easily be offset in any of several ways. In the embodiment
shown, zero voltage output is provided at terminal 15 when the VCO 7 is
operating at a predetermined arbitrary offset frequency that corresponds
to zero Doppler shift of the reflected beam 14. For example, if a VCO
frequency of 40 MHz is selected to correspond to a stationary target 9, a
voltage of zero at the output of filter 6 is arranged to result in a VCO
frequency of 40 MHz, and the acoustooptical modulator 3 is modulated so
that the frequency of its shifted reference beam 16 is less than the
frequency of its incoming beam 13 by 40 MHz. The beat frequency produced
by the two component beams of the composite beam 19 is therefore 40 MHz,
and the signal at terminal 20 of the discriminator 5 is 40 MHz.
When the target 9 moves toward the laser 1, a Doppler shift increases the
frequency of the reflected beam 14. This shift transiently tends to
decrease the beat frequency at terminal 20, which promptly increases the
frequency of the VCO, which increases the frequency of the shifted
reference beam 16 by means of the modulator 3. As the target continues to
move toward the laser the beat frequency at terminal 20 becomes 40 MHz.
The voltage at terminal 15 has, in this example, a positive DC value.
This positive DC voltage at 15 is a measure of the Doppler frequency shift
of the moving target 9 as detected by the laser beam, and corresponds to a
radial velocity of the target with respect to the measurement apparatus.
It can be calibrated in terms of velocity. Position information about the
target can be obtained if desired by integrating the voltage output of
terminal 15 with respect to time. An analog to digital converter 54 places
the Doppler data in a form suitable for processing by a digital computer
56. The computer preferable includes the integration function required for
converting Doppler velocity data to radial distance data. Among other
things the computer also includes means for combining the data gathered by
the two portions of the gauge, i.e., Doppler and time of flight, to
produce unitary output information.
To operate the device to determine the shape of the target 9, an optical
beam scanner 25, forms of which are well known in the art, is interposed
in the target beam. Variations of range during scanning then create
Doppler-like shifts of the frequency of the beam reflected from the
target.
The time of flight portion of the gauge is as follows. In the present
invention, a laser produces mode locked pulses (i.e., envelope modulated
pulses), of quasi monochromatic light. A phase locked loop is used to lock
the phase of a local oscillator to the phase of envelope modulation of a
reference beam, by means of a phase detector. The frequency at which a
voltage controlled oscillator of the phase locked loop operates is
selected to be the first harmonic or a higher harmonic frequency of the
pulse envelope waveform with which the laser reference beam is pulse
modulated. The frequency of the VCO is then applied to a second phase
detector whose other input is the return signal reflected from the object.
The second phase detector produces a D.C. output signal based upon the
same harmonic of the reflected signal, and the VCO frequency. This enables
the relative phase between reference and return beams to be measured
accurately. The result is a relatively high resolution indication of the
time of flight of the pulse to the object and back, and therefore of the
range.
As shown in FIG. 2, a mode locked Argon ion laser L emits a monochromatic
beam 22 of laser pulses, which are radiated periodically in dirac delta
function like envlopes. The light is divided at a beam splitter 5, with a
portion 24 passing directly through the beam splitter 5 and a portion 26
being redirected to serve as a reference beam.
The redirected beam portion 26, FIG. 2, falls upon the photosensitive
surface of a high speed photodiode detector 3. Coming from detector 3 is
an electrical signal 28, FIG. 3 which is the envelope of the pulse
waveform of reference signal 26. The detected envelope signal 28 is
applied to an input 30 of a phase detector 8. Another input terminal 32 to
the phase detector 8 receives a signal from a frequency divider 14.
The phase detector 8, a low pass filter 9, and a voltage controlled
oscillator (VCO) 10, and the frequency divider 14 comprise a phase locked
loop. The loop tracks the signal at terminal 30. At a terminal 34 of the
phase detector 8, a phase error signal is output; it is connected to the
filter 9.
An amplifier can be interposed at point A between filter 9 and VCO 10 for
design convenience if desired. The free-running frequency of VCO 10 can be
at the fundamental frequency or a higher harmonic frequency of signal 28.
The VCO is followed by a frequency divider 14, whose output closes the
phase locked loop at terminal 32.
Selection of frequency or harmonic number is made in the VCO 10. The
divisor of the frequency divider 14 is selected correspondingly, so as to
provide the fundamental envelope frequency at terminal 32 of the phase
detector 8. On FIG. 2, a connection line 15 indicates the linkage between
the harmonic number setting of the VCO 10 and the divider 14.
The output 33 of the VCO 10 is also connected to a terminal 36 of a mixer
11. The signal at terminal 36 is a phase reference signal, and can be of
the first harmonic (fundamental) frequency or a higher numbered harmonic
frequency of the pulse envelope, as selected in the VCO.
The target-directed portion of the laser beam will now be described. A
portion 24 of the laser beam 22 passes directly through the beam splitter
5, and travels to and through a polarizing beam splitter 70. It continues
to a quarter wave plate 6, which circularly polarizes the beam, then
propagates as beam 38 toward the target 7. At the target, whose distance
from the gauge is to be measured, the laser light reflects or scatters,
with some of its energy returning as a coherent light wave 40 back to the
plate 6.
The reflected beam 40 is linearly polarized at plate 6, and redirected by
reflection at the beam splitter 70. The reflected beam 42 from splitter 70
falls on the photosensitive surface of another fast photodiode detector 2.
From photodiode 2, an output electrical signal 44, which replicates the
pulse modulation envelope of the beam 42, is conducted to a second input
terminal 46 of the mixer 11. A bandpass filter for selecting a harmonic
can be employed at a point B, whose pass frequency is selectable to match
the harmonic frequency selected at the VCO 10.
The phase comparator or mixer 11 has a reference phase signal on its input
terminal 36 and a data signal on its input terminal 46. The mixer enables
the signal at 36 to interact with the corresponding harmonic component of
the return signal at 46. Comparator 11 outputs a phase difference signal
from its terminal 48, which depends upon the phase relationship between
the signal at 36 and the corresponding harmonic component of the return
signal at 46.
That phase difference signal feeds a low pass filter network 12. To put the
data in a form that is usable by a computer 56, an analog to digital
converter 52 receives the signal from filter 12, processes it, and
delivers it to a group of terminals that are designated by the single
reference number 13. A time of flight output from the system is at
terminals 13; it is data that varies more or less linearly in accordance
with the difference in path delays, both spatial and electrical, of the
reference and the target data signal.
At higher harmonic frequencies of the VCO, ambiguities in the distance
measurement are more numerous and may have to be resolved. The system must
be calibrated to take account of the equipment-related difference in phase
between the selected harmonic of the VCO and the corresponding harmonic of
the signal reflected from the object.
The computer 56 controls the scanner 25 via control signals on lines 58, in
accordance with a program. The computer therefore always has the
coordinates of the direction of the laser beam. It receives and records
distance data corresponding to each address (i.e., at each set of
direction coordinates) of the laser beam where a reading is taken. The
computer is therefore able to provide final output data sufficient to map
the scene that lies within its scanning purview, based upon both Doppler
and time of flight data.
Successive readings are usually taken at slightly different directions of
the laser beam. Some of the (radial) distance data come from Doppler
measurements and some come from time of flight measurements. Integrated
Doppler data are utilized by "connecting the dots", i.e., by incremental
steps of distance between each point of reading and the next succeeding
point of reading. Where data from its two sources differ, the computer 56
reconciles the data in favor of that which is known to be more precise.
Preferably, differing data are reconciled by weighting the readings
according to their respective accuracies. The gauge is made more accurate
by using many system components in common for both Doppler and time of
flight measurements.
When the object whose shape is being inspected is traveling on a conveyor
or otherwise moving with respect to the gauge, the data taken by the gauge
is attributable to both the shape of the object and effects of its motion.
Several approaches to dealing with the problem of data corruption caused
by irregularities and unreproducibility of conveyor motion are possible.
The speed of the conveyor is known approximately, and to some extent can be
calibrated out by programming. Also, the gauge and its computer can be put
in a learning mode. A prototype calibration object of known shape can then
be moved along the conveyor and its readings recorded by the gauge;
subsequent inspections of similar objects traveling under the same
conditions can be compared with the learned data. If the subsequently
inspected objects yield identical readings as the prototype calibration
object, the subsequent ones are known to have the same shape.
The program of readings (i.e., beam directions and distance data points)
results in some redundancy of data because some of the readings may cover
the same reflection spot on the object or a closely neighboring reflection
spot. Consequently, there is an opportunity to separate the shape
information from the conveyor motion. To implement this approach, the
program of beam excursions includes two steps forward and one step back,
then two more steps forward and one step back, and so forth. The reading
taken at an address of one step back is partially redundant with the
reading previously taken at the address of the second step forward. Other
patterns of beam dither are also easily devised.
Thus, in order to separate the components of data that are due to shape of
the object from those that are due to motion of the conveyor, dither of
the beam's direction is employed to increase the redundancy of readings.
It is a routine computer programing task to subtract one redundant reading
from another to obtain data that are closely related to shape. The fact
the object is viewed from different angles as it proceeds along its travel
route is of no consequence if the dither method is employed along with the
prototype calibration object method, and the inspection program is
synchronized with arrival of the object. Longitudinal, transverse, and
even vertical jiggling or other aberrations of motion can be disregarded
by the gauge in its inspection process.
Similarly, other calibration objects, two dimensional or three dimensional,
can be included on the conveyor within the field of view of the beam
scanning program, to provide calibration and data purification information
to the gauge.
If desired, the scanning route of the laser beam relative to the conveyor
can be along only one axis, namely a direction transverse to the direction
of motion of the conveyor. The conveyor's motion provides scanning in the
longitudinal direction or axis. The relative motion of the object relative
to the gauge that results from travel of the conveyor permits the gauge to
operate with only a linear transverse scanning pattern. If desired, the
gauge can be angularly cocked so that its one-axis linear scanning pattern
is on a diagonal, whose longitudinal component is equal to the speed of
the conveyor. The sequence of reading spots on the object being inspected
is then a straight line perpendicular to the direction of travel of the
object.
The concepts described here are equally applicable where it is desired to
separate shape effects from motion effects in data, when the primary
purpose is to gather motion information rather than shape information.
Numerous other variations and embodiments are also possible, that are
within the scope of the claims and the inventive concepts disclosed here.
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