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Title:
DIGITIZATION SYSTEMS AND TECHNIQUES AND EXAMPLES OF USE IN FMCW LIDAR METHODS AND APPARATUSES
Document Type and Number:
WIPO Patent Application WO/2019/060901
Kind Code:
A1
Abstract:
Examples are provided that use multiple analog-to-digital converters (ADCs) to disambiguate FMCW ladar range returns from one or more targets that may be greater than the Nyquist frequencies of one or more of the ADCs. Examples are also provided that use a first and a second laser FMCW return signal (e.g., reflected beam) in combination with two or more ADCs to disambiguate one or more target ranges (e.g., distances to one or more objects).

Inventors:
THORPE MICHAEL JAMES (US)
ROOS PETER AARON (US)
Application Number:
PCT/US2018/052682
Publication Date:
March 28, 2019
Filing Date:
September 25, 2018
Export Citation:
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Assignee:
BRIDGER PHOTONICS INC (US)
International Classes:
G01C3/08; G01C5/00; G01S7/4911; G01S7/4913; G01S7/4915; G01S17/06; G01S17/08; G01S17/34
Foreign References:
US20120293358A12012-11-22
US20060203224A12006-09-14
US20160123720A12016-05-05
US5115468A1992-05-19
US20170131394A12017-05-11
US20110069309A12011-03-24
US20140204363A12014-07-24
Attorney, Agent or Firm:
DORSEY & WHITNEY LLP et al. (US)
Download PDF:
Claims:
CLAMS

What. is claimed is;

L A method comprising:

providing an interference signal from a fr-equency-taodutated continuous^ wave (FMCW) laser radar system, the interference signal based in part on a laser beam reflected from an. object;

digitizing the interference signal using a digitizer having a yquist freq ency- lower than an -actual beat frequency of the interference signal to produce a d gitized signal.- the digitized, signal consistent with multiple candidate beat frequencies;

processing the digitized signal to select one of the multiple candidate heat frequencies- corresponding to the actual beat frequency: and

determining a distance to at. least a portion of the object based on the heat frequency.

2. The method of claim I , wherein the digitizer comprises a first analog to digital converter (ADC), and wherein, the digitized signal comprises a first digitized signal corresponding to an output of jie first ADC and wherein the first digitized signal is consistent with first multiple heat frequencies, the method- further' comprising; digitizing the interference signal using a second ADC having a second Nyquist frequency to produce a second digitized signal,: the second digitized signal consistent with a second set of multiple candidate beat frequencies; and

wherein processing comprises selecting a matching one from the first and second set of multiple candidate heat frequencies.

3. The method of claim 1 , rther comprisin g prov iding at least anothe r interference signal the at least another interference signal based in part on another laser beam reflected from the object, and wherein the laser beam and the another laser beam are each chirped beams.

4. The method of claim 3, farther comprising:

generating the laser beam and the■'another laser beam from separate laser sources.

5.. The method of claim 3, further comprising:

generating the laser beam and the another laser beam from a same laser source.

6.. The method of claim 1 further comprising:

modulating the laser beam to generate one or more modulation sidebands.

?. The method of claim I , further comprising

providing multiple interference signals, the multiple interference signals corresponding to reflections of the laser beam from multiple objects; and

determining 'the distance to the multiple objects.

8. The method of claim 1 , further comprising;

providing a second interference signal having a second beat frequency corresponding to the distance;

digitizing the second interference -.signal .-using' the digitizer to produce a second digitized signal; ant!

selecting one of the mul tiple beat frequencies further based on the second digitized signal.

9< The method of claim 8, wherein the second interference signal is based on a reflection of a .second laser beam from the object,

10, The method of claim 8, wherein the second interference signal, is based on reflection of a modulated version of the laser beam from the object.

1 .1 . A system comprising:

at least one chirped laser beam configured to be directed toward, at least partially' reflected by, an object to provide a reflected laser beam;

a: detector configured to combine the at least one chirped laser beam with the reflected laser beam to provide an interference signal; a first analog to digits! converter configured to provide a first digital signal based on theinterference signal, the first analog to digital converter ' having, a first. Nyquist frequency below a beat frequency of the interference signal;

a .second 'analog to digital converter configured io provide a second digital signal based on the interference signal, the second analog to digital converter having a second yquist frequency- and

at least one processor configured to determine a range to the object based on the first digital signal and the second digital signal.

12 The system of claim 11 , wherein the .first digital signal is consistent with a first set of multiple candidate beat frequencies and the second digital, signal is consistent with a second set of multiple candidate beat frequencies, and wherein the at least one processor Is configured to identify an actual beat frequency based on a candidate beat frequency included in both the 'first set . of multiple candidate beat frequencies and the second set of multiple candidate heat frequencies.

13. The system o-f claim 1 15 wherein the first Nyquist frequency and the second Nyquist frequency are different frequencies.

1 . A method comprising:

chirping a first laser beam and a second laser beam in opposite directions to provide a first chirped beam and a second chirped beam;

providing a first local oscillator beam based on. the first chirped, beam and a second local oscillator beam based on the second chirped beam;

apply ing a frequenc shift to the first chirped beam and the second chirped beam to provide a frequency shifted first chirped beam and a frequency shifted second chirped hearo;

directing the first chirped beam and the second chirped beam toward an object;

receiving a first reflected beam, corresponding to reflection of the first chirped beam from the object and a second reflected beam corresponding to a reflection of the second chirped beam from the object; generating a first interference signal between the first reflected beam an the first local oscillator- beam and generating a second interference '.signal between the second reflected beam and the second local oscillator beam; and

determining a distance to the object based on the first interference signal and the second interference signal

15. The method of claim 14, wherein said applying the frequency shift comprises applying the frequency shift using an acousto-optic modulator.

16. The method of claim- 14, wherein said apply ing the frequency shift comprises applying the frequency -shift using a carrier-suppressed single-sideband modulator.

17. The method o claim 14, further comprising determining a velocity of the object based on the first interference signal and the second interference signal

18:. The method of claim 14.. further comprising;

digitizing the first interference signal using a first analog to digital converter having a first Nyquist frequency below an actual beat frequency of the first interference signal, to provide a first digitized signal

digitizing the first interference signal, using a second analog. o digital converter having a second Nyquist frequency to provide a second digitized signal; digitizing the second interference signal using the first, analog to digital converter to provide a third digitized signal;

digitizing the second interference signal using the second analog to digital converter to provide a fourth digitized signal, wherein each of the first digitized signal, the second digitized signal, the third digitized signal, and the fourth digitized signal are each consistent with respective multiple beat frequencies; identifying: multiple candidate frequencies- -consistent with both the first digitized signal and the second digitized signal; and

selecting the actual beat frequency from the multiple candidate frequencies based on the third digitized signal and the fourth digitized signal.

1 . A system comprising:

at least one laser source, the at least one laser source configured to generate a first chirped laser and a seeoiid chirped laser, the first; chirpe laser and the second chirped laser chirped m opposite directions;

a. modulator configured to provide a shifted version of the first chirped laser and the second chirped laser for use as a first local oscillator and a second local oscillator;

a combiner configured to combine the first, local oscillator with a reflection of the first chirped laser from, an bject, and to combine the second local oscillator with a reflection of the second chirped laser from the object to generate a first interference signal and second interference signal, respectively; and

a processor configured to determ ine a range to at least a portion of the object using the first interference signal and the second interference signal,

20. The system of claim 19, wherein the modulator comprises an acousto-optfc modulator,

21. The system of claim 19, wherein the modulator comprises a single-sideband modulator.

22. The system of claim 19, fur ther compris ing:

a first analog to digital converter configured to digitize the first interference signal, the first analog to digital converter having a yquist frequency below a beat frequency of the first interference signal

23. The sy stem of claim 22, further comprising:

a second analog to digital converter configured to. digitize the first, interference signal, the second analog to digital converter having a second yqaist fre uenc below the beat 'frequency.

Description:
AND EXAMPLES OF USE IN FMCW BAR METHODS Aj !>

APPARATUSES

CROSS-REFERENCE TO RELATED APPLICATIONS )

|Wt| This application claims the ' benefit under 35 U.S.C, § 1 19 of the earlier filing date of U.S. Provisional Application■Serial No, 62/562,965 filed. September 2:5, 2017, the entire contents of which are- hereby incorporated by reference in their entirety for any purpose.

TECHNICAL FIELD

2| Examples described herein relate to the field of optical distance measurerneriC 'including, light detection and ranging (LiDAR) systems and methods, such as frequency-modulated -continuous-wave (FMCW) LIDAR systems and methods, or and length .metrology. Examples of systems and methods which ma provide advantageous digitization are described,

BA££G QjJND

(003) FMCW ladar generall refers to a form of .coherent laser distance measurement that may use substantiall linear frequency modulation of a laser output, which is referred to as a form of frequency 'chirp * , to achieve distance measurements. The laser frequency may be directly chirped, or the frequency chirp may be imparted to the laser frequency by a modulator that may be external to the laser. FMCW !adar uses optical heterodyne detection, which can provide quantum-noise-limited measurement signals, and allow measurements with a large dynamic range of signal powers doe the square root dependence, .of the FMCW signal o the scattered optical power received from the target. If desired, direct modulation of the laser output frequency can result in large chirp bandwidth*, and therefore, high-resolution distance ' measurements due to the eii-kno relationship, ^ ~ c - ' 2S ; where &R is the range .resolution, c is the speed of light and B is the chirp bandwidth. Chirped sideband modulatio using an RF chirp and, for instance, an optica! modulator, is also possible. Production of highly-linear laser frequency chirps can lead to the achievement of substantially Fourier-limited

I range peaks, and the realization Cramer-Rao-Hmited distance measurement precisions « &Ri^SN^^ where SKR is the RF power slgnal-to-noise ratio of the range measurement).

|<Η> } Existing optical measurement techniques and systems (e.g., existing LiDAR systems) may require larger comp!ex% s ambiguous range, and/or greater processing time that may be available or desired in some applications.

SUMMARY

\MS\ Examples of methods are described herein. An example method includes providing an interference signal {torn a freqweney-modulated continuous-wave (FMCW) laser radar system, the interference signal based in part on a laser beam reflected from an object, digitizing the i erterence signal using a digitizer having a Nyquist frequency lower than an actual beat frequency of the interference signal to produce a digitized signal ., the digitized signal consistent with, multiple candidate beat frequencies, processing the digitized signal to select one of the multiple candidate beat frequencies corresponding to the actual beat frequency, and determining a distance to at least a portion of the object based on the beat frequency.

\MM)\ in some examples, the digitizer may include a first analog ' tis digital convener (ADC). The digitized signal may include ' a first digitized signal corresponding to an output of the first ADC and the first digitized signal may be consistent with first multiple beat frequencies. An example method may further include digitizing the Interference signal using a second ADC having a second Nyquist frequency to produce a second digitized signal, the second digitized signal consistent with a second set of multiple candidate beat frequencies, and the processing may include selecting a matching one .from the first and second set of mul tiple candidate beat frequencies, j( >7 Examples of systems are described herein.. An exampl system may include at least one chirped laser beam configured to be directed toward,, and at least partially reflected by, an object to provide a reflected laser beam. Ike system may include a detector configured to combine the at least one chirped laser beam with the reflected laser beam to provide an interference signal. The system may include a first analog to digital converter configured to provide a first digital signal based on the interference signal, the first analog to digital converter having a first Nyquist frequency below a beat fr quency of the interference signal The system: may include a secon analog to digital converter configured to provide a second digital signal based on the interference signal, the second analog to digital converter having a second yquist frequency. The system may include at least one processor configured to determine a range to the object based on the first digital signal and the second digital signal.

|088} in some examples, the first digital signal may be consistent with a first set of multiple candidate beat frequencies and the second digital signal may be consistent with a second set of multiple candidate heat frequencies.. The processor may be configured to identify an actual beat frequency based on a candidate beat frequency included in both the first set. of multiple candidate beat frequencies and the second set of multiple candidate beat .frequencies.

(889} Another example .method may include chirping first laser beam and a second laser beam in opposite directions to provide a first chirped beam and a second chirped beam, providing a first local oscillator beam based on the first chirped beam and a second local oscillator beam based on the secon chirped beam, applying a frequency shift to the first chirped beam and the second chirped beam, to provide a frequency shifted first chirped beam and a frequency shifted second chirped beam, directing the .first chirped beam and the -second chirped beam toward an. object, receiving a first reflected beam corresponding to reflection of the first chirped beam from the object and a second reflected beam correspon ing to a reflection of the second chirped beam from the object, generating first interference signal between, the first reflected beam and -the first local oscillator beam and generating a second interference signal between the second reflected beam and the second local oscillator beam, and determining a distance to the object based on the first interference signal and the second interference signal,

(818} Another example system rrsay include at least one laser source, the at least one laser source ' configured to generate a first chirped laser and a. second chirped laser, the first chirped laser and the second chirped iaser chirped in opposite directions. The system may include . a modulator configured to provide a shifted version of the first chirped laser and the second- chirped laser for use. as first local oseiilator and a second local oscillator. The: system may include a combiner configured to combine the fust local oscillator with a reflection of the first chirped laser fr m an object, and to combine the second local oscillator with a reflection of the second cliifped laser from the object to generate a first interference signal and a second interference signal, respectively. The system may include a processor configured to. detennine g an e to at least ' a portion of the object using the first interference signal and the second interference signal.

BRIEF DESCRIPTION OF THE DRA WINGS

[Oil] FIG. 1 is a schematic illustration of a system 100 arranged in accordance with examples described herein.

fM2) FIG. A is an example plot of optical frequency of the LO and Rx signals shown In Figure 1 over time; FIG. 2B Is an example plot of signal strength of a Fourier transform of n interference signal provided by the system of Figure 1 arranged in accordance with examples described herein,

[fl3f FIG. 3 is a schematic . ' illustration of a system 300 in accordance with examples described herein.

|M4f FIG. 4 A is an example plot illustrating a beat . frequency measured by an ADC with a first Nyquist frequency; FIG. 4B is an example plot illustrating a beat frequency measured by another ADC with a second, different, Nyquist frequency.

ffJiSj FIG,. .5 is a plot of the frequency measured versus object range in accotdance with examples described, herein,

j¾!6j FIG. 6 illustrates a system 600 in accordance with, one embodiment.

917J FIG. 7 includes 2 plots of measured frequency versus object range, one for each of two laser beam components, in accordanc with examples described herein..

[M8| FIG. 8 is a schematic illustration of a system 800 arranged in accordance with examples described herein.

|fil9| FIG... 9 is & schematic illustration of a system 900 arranged in accordance with examples described herein.

[9201 FIG. 1.0 is a schematic illustration of a system 1000 arranged in accordance with examples described herein,

[821. ' } FIG. 1 1 is a schematic ilhtstration of a transceiver arranged in accordance with examples described herein. ) FIG. 12 includes 2 plots of measured frequency versus object range, one for each of t o laser eam components, in aceordao.ee with examples described herein.| FIG, 33 is a schematic illustration of an automotive lidar application in accordance with examples described herein.

DETAILED DESCRIPTION

j Certain details are set forth ' herein t provide an ' understanding of described embodiments of technology. However, oilier examples may be practiced, without various of these particular details. In some instances, well-known circuits, control signals, timing protocols, LiDAR system components, automotive- components, metrology system components, software operations, and/or other components or operations have not. been shown in detail in order to avoid unnecessarily obscuring the described embodiments, Other embodiments may be utilized, and other changes may be: made, without departing from the spirit o scope of the subject matter presented here,

'j Examples described herein may be used to realize extended-range, htgh> resolution, lower processing demand, and/or lower-cost frequency-modulated ' continuous-wave (FMCW) laser radar (Mar). The terms LiDAR and LADAR may be used, interchangeably herein. ' E amples- described herein, m allow for sparse (e.g., a low fraction of signal-populated range bins compared to the total number of range bins) measurements while maintaining an. overall range of available distances. This may allow range profiles (e.g., interference signals based on .reflected laser beams) to be more expeditiously processed, since the profile may contain less data (e.g., fewer data points).. Examples described herein, may find application i auio.raot.ive lidar, where sparse range profiles may be obtained and processing is generally desired to be performed as fast as possible. Examples are provided that use multiple analog-to- digital converters (A.DCs) to disambiguate FMCW ladar range .returns from one or more targets that ma or may not be greater than the Nyquist frequencies of one or more of the ADCs, Examples are also provided that use a first and a second laser FMCW return, signal (e.g., reflected beam) in combination with two or more A.DCs to disambiguate, one or more t rget ranges (e.g.,. distances to one or more objects). Examples are also provided that «se an optical modulator to disambiguate interference signals for use with one or mo e ADCs.

|¾26| Figure 1 is a schematic llustration of a system 100 arranged in accordance with one embodiment. The system. 100 includes laser source 102, beam splitter 104, circulator 10 transceiver .108. combiner 112, detector 1 1 , digitizer 1 16 and processor 118. The system . 00 may he used to measure properties of (e.g... distance to) object HO, The laser soiree 102 is positioned to provide a laser beam to beam splitter 104. The beam splitter 104 splits the laser beam into a. transmit (Tx) beam and. a local oscillator (LD) beam. The circulator 106 may receive the transmit. beam and provide to 'transceiver 108. The transceiver 108 may -direct the transmit beam toward object 1 10. The transmit beam may be reflected from object 110, Reflection as used herein may refer to laser beams that are reflected and/or scattered from an object. The ' reflected laser beam (Rx), which ma be referred to as a range return, may be received by transceiver 108, The transceiver 108 ma provide the reflected laser beam to the circoiator 106. The circulator.106 may provide the reflected laser beam to the combiner 1 12. The combiner 1 12 may combine the local beam and the reflected laser beam to provide a combined beam, which may be directed onto a detector .1 14. The combined beam detected, by the detector 1 14 may produce an interference signal corresponding to one or more range returns ' . The interference signal resulting: from a range return may he digitized by the digitizer 116 (e.g. » an analog to digital converter (ADC)) to provide a digital signal. The digital signal may be processed by processor 1 18 to determine one or -more- properties of the object 1 0 (e.g.,- distance, t the target). The digital signal may be processed to produce signal sirengt-vas- a function of range, which may be referred to as a range profile. Additional, fewer, and/or different components may be used in some examples.

|Θ27{ The system 100 may he a reqnency-niodnlated. cont uotfs-wave (FMCW) system, e.g. an FMCW Li AR: system 100, and/or a laser radar (ladar) system,f>28) Examples of systems described herein accordingly may include one or more laser sources, such as laser source 102. Generally a laser source may produce coherent light (e.g., a laser beam) having a - frequency that is often in the optical or infrared portion of the electromagnetic spectrum. Examples of laser sources which may . he-used include, but are not limited to, semiconductor, optically pumped semiconductor, and solid-state laser sources. Laser sources described herein may provide laser beams having- a frequency - while any frequencies may be used, in some examples, frequencies in . ' the optical or Infrared range ma be used.

129} In some examples, systems described herein may provide a chirped laser beam.

For example, the .laser source 102 may provide ' a chirped laser beam. Accordingly, the laser source 102 may include an ac tuator which may be coupled to a source of the laser beam which may control a frequency or other parameter (e.g., phase) of the laser beam to provide a chirped laser beam.. Examples ' of actuators which may be used include, but are not limited to, circuitry to .control current provided to the laser source (e.g., laser injection current), or a mechanism to change the laser cavity length. Other actuators may additionally or instead be used. Actuators may be internal or external to and/or external to laser sources. Each chirped laser (e.g., each laser source) may have any number of associated actuators, including 1, 2, 3, or another number of actuators. Generally, a -chirping a laser beam or a chirped laser beam may refer to frequency modulation of a laser output (e.g., a frequency modulated laser beam). The. frequency modulation may be linear in some examples (e.g., a linear chirp). The laser frequency may be directly chirped via a frequency actuator within the laser, or the frequency chirp may be imparted to the . laser frequency by a modulator that! may be external to the laser, or the .frequency chirp may be generated in any other fashion. Generally, aft actuator may be used to modulate or otherwise adjust a frequenc of a laser source (e.g., lase source 102 of Figure 1). Any chirp rate may be used. In some examples, chirp rates of 10 i4 I¾/seeeod may be used.

036] Examples, of systems described herein may utilize any number of Chirped lasers.

While a single laser source 1.02 is shown in the example of Figure 1 , in other examples, other numbers of chirped lasers may be used. Certain of the chirped lasers may have different frequencies and or chirp rates, in some examples, certain of the chirped lasers .may have a same frequency and/Or chirp rate.

(1311 Examples of systems described herein ma include one or more splitters, such as beam splitter 104 of figure I . The beam splitter 104 may ' be used to split one or mor laser beams, e.g., from, laser source 1.02, into a portion (a transmit portion, fx) provided fo use in directing toward (e.g., illuminating) an .object (e.g., provided to the circulator 106 and transceiver 108 of Figure 1) and a portion (a local oscillator portion, LO) which may not travel to the object. Generally, an beamsplitter may be used to implement splitters described herein. Beamsplitters may generally be. implemented using one or more optical components that may refect or otherwise couple a portion of a laser beam incident on the beamsplitter Into a first . path and transmit another potio of the laser beam incident on the beamsplitter into a second path. In some examples, polarizin beamsplitters .may be used. Generally, a splitter may provide a portion of its respective incident laser eam to each of multiple paths. Generally, splitters may split incident light in any fractional portion.

[ Examples of system described .herein may include one or more circulators, such as circulator .106 of Figure L Th e circulator 1.06 may be an optical circulator, and may be implemented using a polarization-dependent or polarization independent circulator. An optical circulator may generally provide different outputs such that an input beam may be provided to a first output, and any beam reflected from the first output may be. provided to a second output. The circulator 106 may provide tire transmit portion (T ) of a laser beam from beam splitter 104 to the transceiver 108 to be directed toward object 1 10. The circulator .106 may act to separate, a reflected laser beam ( x) received back from the object 1 .10, and may provide the reflected laser beam, Rx, to combiner 112, A beam splitter or combiner- may also be used as a circulator.

Examples of systems described herein may include one or " more transceivers, such as transceiver 108 of Figure 1. The transceiver 108 may be used to direct a laser beam (e.g., the transmit portion T of a. laser beam from laser source 102 in Figure 1) toward an object; such, as object i 10 of Figure 1. A transceiver may generally direct a laser beam through optical components - ' and/or a reflector and toward -an object (eg., object 1 10) to interrogate (e.g., illuminate) the object. The laser beam output by the transceiver toward die object may accordingly be based on the output of one or more laser sources, e.g., one or more chirped lasers (e.g., laser source 102 of Figure I ). The transceiver may be stationary in some examples and ma be mobile in some examples. The transcei er may include a beam scanner or other components) to spatially scan a laser beam. The transceiver may provide a portion of an incident, beam as an. output directed toward a partial reflector and an object. In some examples, the partial reflector may reflect a portion of the laser beam received from the transceiver back to other components .of the. system, which portion may be referred to as a local oscillator (1,0) in some examples.. The partial reflector may alternatively .be placed- within or prior to •the transceiver and may serve the purpose of the beam splstier -and combiner. The object may reflect a portion of the laser ' team received from ' the transceiver back to the transceiver, and the reflected laser beam (e.g., return, or receive portion s) may be provided to circulator 106, Laser right returning from the target to circulator 1.06 may ¬ be provided to a combiner 1 12 to produce an mterference signal related to a property of the target, (e.g., a distance to the target). The transceiver may be split into a transmitter portion, and a receiver portion, which a be spatially separated (e.g., bistatic transceiver). One or more optical paths may be a fiber optic path.

$34] Examples of systems described herein may include one or more combiners, such as combiner 1 12 of f igure 1 . The combiner 112 may infcrferoraetrieaily combine the local, portion of a lase beam (e,.g., LO . ) and a reflected laser bea (e.g., Rx) and direct the interferoine ic -combination onto an optical detector to produce art interierenee signal. Accordingly, the interference signal may be a electronic signal provided by the detector 1 14.

$35] Examples of systems described herein may include one or more detectors, such as detector 1 14 of Figure 1. The detector may be implemented using any optical detector which may convert an incident interi½pmetrie- combination into an. electronic signal.

\&M\ Examples of systems described herein may include one or more digitizers, such as ' digitizer 1 1-6 of Fignre 1 . The digitizer may receive an interference signal from a detector, which may ' be an analog or denser digital signal, and may convert the interference signal into a digitized signal.

$37] Examples of systems described herein may include- one or more processors, such as processor 1 18 of Figure 1. The processor may be implemented using ' : one or more signal processors: (e.g., circuitry, filters, central processing units (CPUs), processor corefs), digital signal processors (DSPs), application specific integrated circuits (ASICs) and/or other processing elements). In some examples, memory may also be provided, and the processor may execute software (e.g., executable instructions -encoded, in. the memory). The software may include executable instructions fo signal processing a»d bf determining one or more properties of the object 1 10 based on the digitized interfe ence signal

$38J Examples of systems described herein may accordingly be used to determine one or more properties of an object. Any o a variety of objects may be used. For example, any target and/or surface. Examples include, but are not limited to s automobiles, signs, people, trees, buildings, reir -r Oectors, tooling bails, metals, or optical surfaces. Objects may be stationary or may be moving. The term object may be used synonymously with the term target herein. The term surface ma also be used. Any of a variety of properties may be determined (e.g., measured} using systems described herein. Including distance {eg., range), velocity and/or acceleration. The term distance may be used synonymously with range as described herein. The terms position or location may also be used.

\&39\ Figure 2A shows an example plot of the LO aad llx optical frequencies as functions of time, la the example of Figure 2A, both the LO and Rx. signals are chirped - e.g., their frequency changes over time.. The Rx is time delayed from the 1,0 by a time τ, which may reflect a time takes for the laser beam to travel toward the object, to he reflected from the object, and to return to the transceiver. When combined at combiner 1 12, the LO and Rx optical fields , may interfere to produce an interference signal which, may also be referred to as a beat note. The beat note ma be detected by detector 11.4 and the detector 114 may provide an electrical signal indicative of the beat note (e.g., a voltage, current, or other electrical signal). A Fourier transform of the interference signal, (which may be performed, e.g., by ' processor 118 of Figur 1 and/or other circuitry), may provide a frequency of the beat note, which may be referred to as a beat frequency . Figure 2B illustrates a plot of signal strength vs. frequency for a Fo urier transform of an in terference signal. The peak shown in Figure 2B may b e at the beat fre uency. The beat freq e cy may be given by ; J r:: trr, where κ is the chirp rate and t may be linearly proportional to the distance of the object. In this manner, the processor 1 18 may determine a distance to an object based on a chirp rate and a beat ■frequency of an interference si gnal described herein .

|0 u| While FMCW hular systems offer advantages, they have also- exhibited challenges, limitations, and problems. For example, the. Nyquis frequency of a -digitizer (e.g., an analog to -digital converter used to implement digitizer 11-6 of Figure 1} has typically set the maximum heterodyne beat frequency, and therefore the maximum range, R, that can e measured .for a given efairp rate. If frequencies above, the Nyqoist frequency are sampled by the digitizer, such frequencies may be incorrectly detected as lower ' frequencies, a process thai may be referred to as aliasing. Aliasing may occur because instantaneously sampling a periodic function at two or fewer times per cycle may result in missed cycles, and therefore the appearance of an incorrectly lower frequency, it may be possible to decrease the FMCW ladar chirp rate to increase, the maximum range that can be measured. However, reducing the chirp rate may either result in longer chirp durations, T, which can lead to slower update rates, or smaller chirp band widths, B, which result in poore resolution. ' Unfortunately, the other alternative has been to simply increase the sample rate, and therefore the Nyqoist frequency, of the ADC, which may result in larger monetary cost of the. A Gs, larger consumption ' of electrical power by the ADCs, poorer bit resolution, and increasing data, for processing, as compared with Sower-speed ADCs.. Examples described herein may provide systems and methods that may increase the maximum measurable heterodyne beat frequency, without compromising, or without compromising as significantly, the advantages of lower-speed ADCs. For some automotive Ma or metrology applications, for example, the cost and processing demand may be important con id rations in selecting an. ADC, Example described herein may m some circumstances allow the use of lower-saraple-rate ADCs, which may be lower cost, and which -may output fewer sampled points per unit time, which may allow tor fester data processing. These benefits may be achieved without compromising, or without compromising as significiuitiy {relative to systems ' not ' utilizing systems and techniques described herein) the range window, resolution, or update rate of the FMCW ladar system in some examples,

Accordingly, examples described herein ma provide and/Or improve an ability to measure and quantify an object range (or other property:) that: corresponds and/or relates to a measurement frequency that is greater than the Nyquist frequency of a particular digitizer (e.g., ADC). Example methods and. apparatuses disclosed may, for sparse FMCW ladar return signals. in the frequency domain, disambiguate ' aliased range returns .sampled by an ADC, and therefore determine the range-. unambiguously (and/or less ambiguously) even in ' the presence of aliasing. §42) in some examples described herein, an interference signal may fo digitized multiple times- using -multiple sa le rates (e.g., digitizer having different Nyquist frequencies), to disambiguate a propert (e.g., distance/range) of an object in the presence of aliasing. Figure 3 is a schematic illustration of a system arranged in accordance with examples described herein. The system ' 300 of Figure 3 utifees two digitizers (e.g., two ADCs) that may be used to measure ranges associated with beat frequencies which are greater than the Nyquist -frequency ' f either or both of the ADCs. The system 300 includes laser source 1 2, beam splitter 04, circulator 106 » transceiver 1:08, combiner 112, detector 114, first analog to digital converter 302, second analog to digital converter 304, and processor i f 8. The system 300 may: be used to measure a property of (e.g., distance to) object 1 10. The operation and implementation of laser source 102, beam splitter 104, circulator 106, transceiver 108, combiner 112, detector 11.4, and object 1 10 may be the same and/or analogous to that described herein, with reference to Figure 1. The processor M S may be implemented in the same o analogous manner to that described herein with reference to Figure 1, however the- processor 118 in Figure 3 may process signals differently and or process different signals as described herein, la some examples, additional, fewer, and/or different components may be used: than those shown in Figure 3.

t)43| As described with reference to Figure 1, the detector 114 may provide an interference signal which may be an electronic signal and may include information used to determine a. property of object 1 10 (e.g., distance to the object 110).

§44] I examples described herein, multiple digitizers may be- provided, as shown in Figure 3 including analog to digital converter 302 and analog to digital converter 304. While two digitizers are shown in Figure 3, a»y number may be used in other examples, including 3, 4, 5, or 6 digitizers. Oilier numbers of digitizers may be used in other examples. The analog to digital converter 30 and/or analog to digital converter 304 may have a Nyquist. frequency- which is less than a. beat frequency associated with a distance intended to be measured by the system. Generally, a Nyquist frequency may refer to a frequency which is half the sampling frequency of the ADC, The Nyquist frequency may also be referred to as the folding frequency. In some situations, the distance to the object 1 0 .may be such that the heat frequency of a, resulting interference signal is below the Nyquist frequency of the analog to digital converter 302 and/or analog to digital converter 304. However, the system 300 may also be used hen the distance to the object .1 .10 may he associated with interference signal beat frequency greater than the Nyquist frequency of analog to digital converter 302, analog to digital eon verie 304, or both. Typically, such, as in the example of Figure. 1, if the beat, frequency of the interference signal were greater than the Nyquist frequency of the digitizer 1 16, it ma result in ambiguity of the range, because the resulting signal may he aliased, sod the: signal at an output of the digitizer 1 16 may be: ' consistent with -two different, ranges. However, in. the example of Figure 3, the multiple digitizers may he issed to disambiguate the signal..

[0451 Accordingly, during operation, an interference signal may he provided by a frequeacy-modalated continuous-wave (F CW) laser radar system. For example, the interference signal may be provided by combiner 112 and/or detector 1 1.4. Note that the .interference signal may be based in part on a laser beam reflected front an object (e.g.. Rx reflected from object 1 10), A digitizer ie,g„ digitizer 11 of Figure 1 and/or analog to digital converter 302 and/or analog to digital converter 304 of Figure 3} may be used to digitize (e.g., sample) the interference signal. All or same of the digitizers used may have a Nyquist frequency lower than a beat frequency of the interference signal. The digitizer ma produce a digitized signal, which ma be consistent wit multiple beat .frequencies. The digitized signal may be processed (e.g., b processor II S) to select one of the multiple beat frequencies which correspond to the beat frequency actually present in the interference signal and associated with a distance to the object 1 10. l te processor 1 18 may determine distance to at least a portion, of the object 1 10 (e.g., a surface of fee object) based on the beat frequency.

[0 6} For example, the analog to digital convener 302 of Figure 3 may be used to provide a first digitized signal. The first digitized signal may be consistent with multiple candidate eat frequencies which may be contained in the interference signal (e.g., it may be unknown whether the first digitized signal has experienced aliasing). The analog to digital converter 304 of Figure 3 may be used to provide a second digitized signal based on. the interference signal. Generally, the Nyquist frequency of the analog to digital, converter 304 may be / different than the Nyquist frequency of the analog to digital converter 302. The second digitized s gnal .may be consistent with another set of multiple candidate beat frequencies. The actual beat frequency, however, will be consistent with both the output of the analog to. digital, converter 302 nd the output of the. analog to digital convener 304. Accordingly, the. candidate beat frequencies associated with an output of analog to digital converter 302 may be compared with the candidate beat frequencies associated with an outpu of ' analog to digital converter 304.. A matching beat frequency present in both candidate groups may be identified (e.g., by the processor 118.) as the correct beat frequency and used to determine a property (e.g., a distance to) object 1 10.

. 047} Figure 4A is an example plot illustrating a beat frequency measured by an ADC with a first Nyquist frequency (e.g., with, a first sample rate). The plot in Figure 4A may, for example,, reflect an output of analog to digital converter 302 of Figure 3. Figure 4B is an example plot illustrating a beat frequency measured by another ADC with a second, different, Nyquist frequency (e.g., with a second, different sampling rate). The plot in -Figure 4B may, for example, reflect an output of analog to digital converter 304 o Figure - 3.

648} Referring lo Figure 4 A, a plot is provided . ' from an ADC (e.g., analog to digital converter 302 of Figure 3) having a first sample rate (e.g., Sampl Rate 1 ) and processed by processor to produce signal strength as a f action of frequency. The AD may receive a signal including a beat frequency at f ;; m, (shown in dotted lines in Figure 4A), which may be above a Nyquist frequency, i, of the ADC; Accordingly, the ADC may provide an output having a frequency peak which is shifted (e.g., aliased). The output may include a peak at a frequency that is folded about the Nyquist frequency, e.g.,€vac.i-~ ' 2N'j « ¾«* (shown: in solid lines In Figure 4A).

&49] Referring to Figure 4S. a plot is provided from a sec nd ADC (e.g., analog to digital converter 304 of Figure 3) having a second sample rate (e.g.. Sample Rate 2) ) and processed by a processor to produce signal strength as a junction of frequency. The ADC may receive the saine signal i cbdiftg a beat frequency at f ™ ι (shown in doited lines in Figure 4B), which may be above a .Nyquist frequency, N2, of the ADC, Accordingly, the ADC may provide an output having a frequency peak which is shifted (e.g., aliased). The output may include a peak at a frequency that is folded about the Nyquist frequency, e.g., fADc INs - .† (shown in solid lines in. Figure 4B).

¾50f At least in part because the two frequencies measured by the first and second ADC ' s (£ r>ci and fkoe?) are different it may be possibl to determine- the "correct ' " i , and therefore the correct object range, even though ί¼ ¾ί does not fail below the Nyquist frequency of the APCs,

I Figure 5 is a plot of the .frequency measured versus object range in accordance with examples described herein. For .example, the plot of Figure 5 may correspond to the output of analog to digital converter 302 and analog to digital converter 304 of Figure 3 for various ranges, in some examples. Figure 5 may also be consistent with the plot of figure 4. Figure 5 illustrates two traces - trace 510 and trace 512, which may correspond to frequency versus range traces for two different ADCs (e.g., having two different Nyquist frequencies or sampling rates). The trace 512 may represent. an output of analog to digital converter 302 (e.g., f¾nei} of Figure I while the trace 510 may represent an output of analog to digital converter 304 (e.g., hioca) of Figure 1, .Horizontal lines are shown in Figure 5 corresponding to a Nyquist frequency for analog to digital converter 302 (e.g., Nl) and a Nyquist frequency for analog-, to digital converter 304 (e.g., N2). In the example of Figure 5, the analog to -digital converter 304 has a higher Nyquist frequency and sampling rate than analog to digital converter 302. Note that the. same ADC output frequency could correspond to multiple possible ranges (e.g., multiple candidate beat frequencies) for each ADC output,

j When an object is in the fust range window, indicated by wj t in Figure 5,. of the .first ADC (e.g... resultin in beat frequency, h>es.i, that is below th first Nyquist frequency) the frequency measured by each ADC may be same (e.g., .ΙΑΪΧΙ ::: IXiXj), However, when an object is In the second range window of the firs ADC, which is indicated by wn in Figure 5 (e.g., at a range corresponding to an interference signal beat frequency greater than tire Nyquist frequency of the ADC), the frequency measured by each ADC may be different (e.g., as was the case for the example illustrated in Figure 4), B observing the frequencies of the first and second ADCs (fkvjc! and respectively),, the range of an object may be unambiguously ' (and/or less ambiguously) determined. This may be true ' for frequencies- that are up to twice- the Nyquist trequency of the first ADC in same examples, and higher in some examples. For instance, if the two ADC frequencies are the same, then the measured ADC frequency directly provides the heterodyne heat frequency corresponding to the object range iks< ~ i a. On the other hand, if the two: ADC frequencies differ, then the heterodyne beat frequency corresponding to the object range may ' be given by £***™ NrK f- For example, the same an. object at one particular range shown in Figure 5 corresponds to point 502 output from analog to ' -digital convener 302 and point 504 from analog to digital converter 304. The point 502 is : above a Ny uist frequency lor analog to digital converter 302. Accordingly, because the values are different, the correct beat frequency m y be given by 1 ~ Ni+(Ni- fki j} in some examples.

feS3J Generally, the methodolog may be used in other range windows as well or a given beat ftequeacy measured by analog, to digital converter 302, the possible beat •frequencies may be given by ~ 2*m* i · ¾n ( , and .¾cas ~ 2 n*N i - (MKI, where m are positive integers starting at zero and n are positive integers starting at one. Analogous expressions can be written for the possible beat frequencies for analog to digital converter 304, The frequencies measured by the ADCs, fkxKi and fX$x;¾ may be determined by any of variety of componen ts and technique including, but not limited to, techniques implemented by processor 118 of Figure I (or another processor), such as peak fitting and maximum-finding algorithms. In some examples, it may be possible for the processor I IS to determine the "correct" beat frequency by determining the common 1 from the sets of possible values of f computed from the frequencies measured by analog to digital co verter 302 and analog to digital converter 304. For example, a set of candidate values for each of analog to digital converter 302 and analog to digital converte 304 may be calculated, such as by using me previous equations. The j¾c« value for analog to digital converter 302 may match that of analog to digital eonverter 304 in one of the range windows, which may reveal the correct fk« value corresponding to the true range to the object, from which the ' correct target range can be obtained:

[0541 The example of point 502 and point 504 provides an example when a ' true i falls in one range window for one ADC (e.g., a second range window corresponding to the second Ny ' qaist zone tor analog to digital converter 302 for point 502} and another range window for another ADC (e.g., the first range window correspondin to the fust Nyqaist zone for point 504 for analog to digital converter 304). The first and second range windows for analog to digital eonverter 302 are shown as WH and u in Figure 5. The first and second rang windows for analog to digital eonverter 304 are shown -as wn and ws?. in Figure 5, {955) it is possible thai more than one actual range return (e.g., from a plurality of targets), corresponding to mo e than one ik¾t, exists for a given measurement hi som •examples, each ADC may measure more mm one frequency. To disambiguate, multiple object range returns ' that may exceed the ADC yquist frequency, a system (e.g., processor 1 18 of Figure 3) may determine the possible i values for each frequency measured by each ADC as- described previously. For example, for two range returns, each ADC may be used to determine the possible I « values for each of -two frequencies (e.g., four .frequencies m total). A system (e.g., processor 1.18 of Figure 3 may search, the possible values ' for one pair of matchin frequencies for a first .range return, and another pair of matching frequencies for a second range return, to some examples, additional information, including ' but not limited to, the range peak ampiitudes, the range peak shapes, target ranges determined ra previous measurements and/or the target Doppler shifts determined in previous measurements, may further be used by ' example, systems (e.g., by processor US of Figure .3) to further assist in disambiguating the range returns. More than two range returns may be treated analogously,

[9.56] In some examples, and even when only one. actual range return exists, range ambiguity may .nonetheless exist: using this technique for some ranges when f¾nc2 » * frequency equals that of the second measured ADC frequency (such as point 506 in Figure 5) may be ambiguous with a range in the first ranp window that has same measured ADC frequency (such as point 508 in Figure 5). More generally, when the two frequencies from foe ADCs are equal in a range window Other than foe first, -there may be range ambiguity with the first range window. Such ambiguity may not be acceptable in some examples. Accordingly, In some examples, systems may not utilize a first range window for .measurement Of .object ' ranges. For example, she components of Figure 3: may be calibrated or otherwise configured such that first range window of frequencies of analog to digital converter 302 and/or analog to digital converter 304 are not used in measuring object distances. In other examples, the processor 118 of Figure 3 may utilize target range information from previous measurements to estimate the location of objects in eases wher the beat frequencies become: ambiguous. For example, the processor 118 may favor ranges which are within a particular distance of a previous range measurement when the frequency measured by an ADC signal contains an ambiguity.

|¾S7f Other techniques -and/or components may also be used to disambiguate (and/or reduce ambiguity} of range measurements using systems described herein. Figure 6 is a schematic illustration of a. system arranged in accordance with examples described herein. The system 600 may utilize multiple (e.g., two) chirped lasers., each with a different chirp rate. The system 600 includes laser source 602, laser source 604, combiner 606, beam splitter 104, circulator 106, transceiver 108, combiner 1 12, detecto 1 .14, analog to digital converter 302, analog to digital converter 304, and processor 118. The system 600 may be used to determine properties of {e.g., a distance to) object 1 10. The c m onents beam splitter 104, circulator 106, transceiver 108, combiner 1 12, detector 1 14, processor 118, object HO, analog to digital converter 302, and analog to digital, converter 304 may be the same as and/of analogous to the similarly numbered components described herein relative t other Figures. Additional, fewer, and/or different components may b use in other examples.

j &j The laser source 602 may provide a first chirped laser beam, while the laser source 604 may provide a second chirped laser beam. Generally, the chirp rate of the first chirped laser beam m y be different than the chirp rate of the second chirped- laser beam. While shown as two sources, in some examples the two chirped laser beams ma be provided by a single source. While two chirped laser beams are shown in Figure 6, any number may be used -in other examples, including 3, 4, 5, or 6 laser beams.

\ S9\ The chirped laser beam, from laser source 602 and the chirped laser beam from laser source 604 may be combined using combiner 606. The combined beam,, including two chirped laser beams, ma be provided to the beam splitter 104, and the system 600 may operate analogously to that described herein with respect to other Figures having like-labeled, compe ents, such as Figure 1 and Figure 3.

[860] A first interference signal may be provided to analog to digital converter 302 and analog to digital converter 304 accordingl which is based on the first chirped laser beam (e.g., from laser source 602) and a reflected beam based on a reflection of the first chirped laser beam from object .1 .10. A second interference signal m y also be provided to. analog: to digital converter 302 and analo to digital converter 304 may also include a component based on the second chirped laser beam (e.g., from laser source 604) an a reflection of the second chirped laser beam from object .1 10, In some e amples, the first and second interference signals may be. provided as a composite interference signals (e.g.,, the first and second interference signals may be components of a single interference signal). Accordingly, the analog to .digital converter 302 and analog to digital converter 304 may out ut frequency signals pertaining to both components, in some exam les, at least because the chirp rates are different for the two laser beams combined by combiner 606, the ' an e for which ambiguity exists between the output of the two ADCs (e.g,, analog t digital converter 302 and analog to digital con verter 304} lor the component relating io the first chirped laser beam may ot he the same as the range for which ambiguity may exist between the two ADCs for the component relating to the second chirped laser beam. Accordingly, an accurate range may be identified despite aliasing and despite ambiguity from a single laser beam system.,

I Θ6Ι) Figure 7 ' includes 2 plots of measured frequency versus object range, one for each of two laser beam components, in accordance with examples, described herein. The upper plot i Figure 7 includes trace 710 and trace. 716, The trace 7.10 may correspond with frequency versus object range, for an . output of analog to digital converte 302 of Figure 6 for a component of an interference signal corresponding to the laser beam from laser source 602 (e.g., 'Laser V in Figure 7). The trace 716 may correspond with frequency versus object range for an output of analog to digital converter 304 of Figure 6 .tor a component of the interference signal corresponding to the laser ' beam from ' laser source 604 (e.g., 'Laser V in Figure 7). The lower plot in Figure 7 includes trace 712 and trace 714. The trace 712 may correspond with frequency versus object range for an output of analog to digital converter 302 of Figure 6 for a component of an interference signal corresponding to the laser beam ifom laser source 604 (e.g., 'Laser 2' in Figure 7). The trace 714 may correspond with frequency versus object range for an output of analog to digital converter 304 of Figure for a component of the interference signal corresponding to the laser beam from laser source 604 (e,g,j Laser 2* in Figure 7),

ft½2| in the upper plot, for laser I. (e.g., for the component, of an. interference signal pertaining, to the laser beam from laser source 602 of Figure 6) , the range is such that the two frequencies from the two ADCs are equal in a range window greater than the first range window and therefore the range is ambiguous- with a range in the first range window (for example, it may be difficult: to disambiguate the range associated with point 702 from that associat with poin 704, because both may have a same frequency output ' from analog to digital converter 302 and analog to digital converter 304 ' ). However, for laser 2 in the lower plot (e g,, for the component of an interference signal pertaining, to the laser beam from laser source 604 of Figure 6), at the same range associated with the ambiguous range point 704, the signals correspondin with Laser 2 are not equal - e.g., point 706 and point 708. Accordingly, an unambiguous range may be identified.

I Accordingly, in some examples, processor i 18 of Figure 6 may utilize output frequencies from analo to digital converter 302 and analog to digital converter 304 pertaining to the laser beam from laser source 602 to determine a property (e.g., distance to) object 1 10. However, if the .frequencies -measured by analog to digital converter 302 and analog to digital converter 304 are the same for the component: of the interierenee signal, relating to laser source 602, then the processor i IS may utilize the frequencies measured b analog io digital converter 302 and- nalog to digital converter 304 for the component of the interference signal relating- to the laser source 604. Other methodologies are also possible io utilize the two laser beams havine different chirp rates to determine accurate range values. The addition of a second laser may also add confidence in some examples to the determination of the correct range window, when the first laser falls near zero or the Nyquist frequency, or f r other reasons including compensating lor Doppler shifts, compensating for speckle, or other reasons.

1 Generally, then, some examples of systems described herein may disambiguate (and or lessen ambiguity in) a range determination by including an additional frequency tone for one or more digitizers (e.g., ADCs) to measure that corresponds to a same range. By providing multiple frequency signals corresponding to same range, systems described herein, ma be able to discriminate between results when aliasing is present, in the example of Figure 6 and Figure 7, an. additional frequency signal was provided by providing- multiple laser sources. However, in some examples, other techniques may be used other than providing an. additional, lase source and/or an additional .chirped laser beam, in some examples, a single laser beam may be modulated either by direct modulation or modulation external to the laser. The modulation may provide a component Imvk a d fferent frequency that may be used: in analogous manner to provide more clarity to a range measurement.

¾65| Figure 8 is a schematic llustration of a system 800 arranged m accordance with examples described herein. The system 800 ncludes waveform generator 802, modulator 804, and laser source 806. The modulator 804 provides signals to beam splitter 104 which may split the received heamfjs) into a Tx portion to circulator 106 and a LO portion provided to modulator 808. The* modulator 808 may provide a modulated LO signal to combiner 1 12. The beam splitter 104, ' circulator 106, transceiver 108, combiner 11 , detector 11.4, analog to digital converter 302, analog to digital converter 304, and processor 1 18 may be implemented by and may operate as, or analogously to, the description provided herein with reference to other Figures and elements havin a same reference number. Additional, fewer, and/of different components may be used n other examples.

M6] To the example of Figure 8, th laser source 806 ma provide a laser beam, •which may not be a chirped laser beam. The lase beam ma be modulated with modulator 804, which may be an. electro-optic (BO) modulator. The modulation by modulator' 804 may provide one or more modulatio sidebands. The modulation sidebands: may be chirped using waveform generator . 802, While in some examples, multi e waveform generators may be provided to chirp the sidebands at different rates, in some examples the sidebands ma be chirped at a same rate by the same waveform generator 802. Accordingly, a modulator 808 ma be provided in the LO path (e.g., between circulator 106 and combiner 1 1.2) to cause the resulting two interference signals (and therefore beat notes) to have different frequencies when the object is at rest (e.g., no oppler shift). One interference signal (e.g., component of a composite interference signal) may pertain to one sideband, while the other may pertain to the other sideband. This may help the two ADCs to disambiguate the object range m an analogous manner to that described with reference to Figure 6 and Figure ? and components of interference signals relating to two different laser sources and/or chirped lasers.

t½7| In still oilier examples, a single-sideband modulator may be used. Figore 9 is a schematic illustration of a system 900 arranged in accordance: with examples described herein. The system ' 900 includes lase source 102, beam splitter 104, modulator 902, circulator 106, transceiver 108, combiner 112, detector 114, analog to digital convener 302, .'an log to digital converter 304, arid -processor J 18. The system ¾0 roay-be used to measure a property {e.g., distance to) object 1 10. The components: of Figure 9 may be implemented by and/or- operate io. a same or analogous manner to components of same reference number otherwise described herein. Additional, fewer, and/or different components may be used in other examples.

} in the example in Figure 9, the laser source 102 may provide s chirped L se beam. The chirped laser beam, may be provided to beam spliiier 104 to form a transmit portion. Tx.. The transmit portion, may be modulated using: modulator 90:2. The modulator 902 may be implemented using -a single-sideband (SS ) modulator; The earner (e,,g,, the chirped laser beam from laser source 102) and the single sideband provided by modulator 902 may then produce two interference signals (e.g., two components of a composite interference signal) that can be used to disambiguate the range in analogous .maimer to that described with -reference to Figure 6, Figure 7, and Figure 8,

F igure 1 is a schematic illustration of a system 1000 arranged in accordance with examples described herein. The system 1000 includes laser source 602, laser source 604, combiner 606, beam splitter 104, circulator 106, modulator 1002, transceiver 1.08·, combiner 1 1 , detector 114, analo to digital, converter 302, analog to digital converter 304, and processor 1 18. The modulator 1002 may modulate the Tx portion of the laser beam provided by beam splitter 104 and may provide a modulated laser beam to transceiver 108. The system 1000 maybe used to measure a property of (e.g., distance to) object 110. The components of Figure .10 may be implemented by and may operate in the same or analogous manner to the components having like reference .numbers described herein. Additional, fewer, and/or different components may be used i ther examples.

} I n. the. example, of Figure 10, the laser source 602 and laser source 604 may provide chirped laser beams. In some examples, the first chirped laser beam provided by laser source 602 may have a different chirp rate than the second chirped laser beam provided b laser source 604. n. some examples, the first and second, chirped laser beams may have equal, and opposite chirp rates. While described as two laser sources, the laser source 602 and laser source 604 may in some examples be implemented using a single laser source and optical modulators . or -other components used to provide two -chirped, laser beams. The chirped laser beams may be - .combined by combiner 606 and provided to circulator 106. The modulator 1002 may be implemented using an aeousto- optic modulator (AO modulator). The modulator 1002 may be a frequency shifter which may shift a frequenc of the transmit beam (Tx) and provide a frequency-shifted signal to the transceiver 108.

Ί) The beam splitter 104 and the combiner 112 ma be optional, and may be omitted in some examples, at least in part because a ftequency-shifted LO may be provided by the modulator 1002 as described subsequentl . In some . examples, die modulator 1002 m be combined with the transceiver 108. Accordingly, in some examples, the combiner 606 ma provide a combined laser ' beam to the circulator 106, The circulator 106 may provide the combined laser beam to the .modulator 1002 which may shift a frequency of the transmit signal fix) before providing a frequency-shifted Tx to the transceiver 108.. Moreover, the modulator 1 02 and/or the transceiver 1 8 may provide a frequency-shifted LO back to the modulator Ί 002 and/or circulator 106. The signals may be combined at the circulator .106 in some examples.

1\ Figure i I. is a schematic illustration of a transceiver arranged accordance with examples described herein. For example, the modulator 308 and transceiver 1002 .from . Figure 1.0 may he combined into the transceiver shown in Figure .11. The transcei ver 1 .102 includes fiber 1104, collimator 1 106, modulator 1 108, optics 1 11.0 and mirror 1 1.14, The transceiver 1102 may direct a Tx portion of a laser beam to object 11 12: and may receive a reflected R : laser beam from object ! 112, The transceiver 1102 may be used to implement for example, transceiver 108 described herein an in, for example, f igure 10. Additional, .tewer, and/or different components may be used in other examples. The solid connecting lines in Figure 1 1 indicate optical fiber, while the dotted lines indicate -a beam travellin i n. free space in some examples.

f3| The fiber 1 104 may provide a laser beam to collimator .1 .106. The collimator 1 106 may provide the laser beam to modulator 1108. The modulator 1108 may be implemented, for example, using an acoustc-opiie modulator (AO modulator). The modulator 1.108 may provide the unshiftcd (e.g., zero-order., unmodulated) laser beam (e.g.,- transmit beam Tx) to optics 1110 for directing toward object 1 ! .1 . The optics 1110 may provide an unmodulated beam from the modulator i 108 to the object 1112. The modulator i 108 may also provide a frequency-shifted (e.g. first. order, modulated) local oscillator (LO) portion by directing a freque«y~sMfted laser beam from the modulator 1 .108 toward a mirror 11.1 (or other reOeclive surface, which may be a reflective surface of the modulator) which may reflect the beam and provide a frequency-shifted LO back to the modulator 1 108 and to the eoiliraator 1:106. in some examples, at least in part because the LO portion is deflected twice by tie modulator 1 I08 x it may have a frequency shift equal to twice the modulator 1 108 drive frequency. Both the LO and a reflected laser beam received (e.g>, Rx) may be provided back to collimator 1 1 6 and output on. fiber 1104. Applying a frequency shift to one or both of the T or LO beams from one or both of the lasers may be used to ' disambiguate or determine range from velocity (e.g., Doppler) for any Nyquist zone. This is because the beat frequencies .may be different evert for equal, but opposite, chirp rates, as discussed prev iously related to Figure 8.

) Applying frequency shift may also be used to ' disambiguate range when one or more beat frequencies ere greater than the Nyquist frequency of one or more ADC. Figure 12 includes 2 plots of measured frequency versus object range, one for each of two laser beam components, in accordance with examples described herein. The plots of Figure 12 provide example plots , from a system using a transceiver, such as transceiver .1 1 2 of Figur 11. in a system, such as system 1000 that utilizes two chirped laser beams having equal and opposite chirp rates.

| The upper plot includes trace 1202 and trace 1204, The trace 1202 and trace 1204 may illustrate measurements pertaining to an interference signal based on the lase beam from laser source 602 of Figure 10 (e.g.. Laser 1 as shown in Figure 12). The trace 1202 may illustrate measurements taken by analog to digital converter 302 of Figure 10, while the trace 1204 may illustrate measurements taken by analog to digital converter 304 of Figure .! 0.

) The lower plot includes trace 1224 and trace 1 26, The trace 1224 and trace 1226 may illustrate lneasnremeats pertaining to an interference signal based on the laser beam from laser -source 604· of Figure Ί0 (e.g., Laser 2 as shown in Figure. 12). ' the trace 1224 may illustrate measurements taken, by analog to digital converter 302 of Figure 10, while the trace 1226 may illustrate measurements, taken, by analog to digital converter 304 of Figure 10. [877) In this example, the modulator 1 1 08 may have a drive, frequency ( AO ). The dr v - frequency may be selected such tlmi 2 Kf AO is above the first digitizer Nyquist frequency (e.g., the. yquisi frequency of analog to digital converter 302) and below the second digitizer Nyquist frequency (e.g., the yquist frequency of analog to digital converter 304). Here,, the beat frequencies associated with Laser 1 , and measured by analog, to digital converter 302 and analog to digital converter 304, may result in ambiguous range measurements,, such as i the first two ' Nyquist zones, in part due to the downward direction, of the Lase I frequency chirp. For example, the point 1206, point 1 208, and point 1210 may result in. ambiguous range measurements using, the Laser 1 (e.g., the frequency at those points may correspond to m lti le ranges). However, looking at the tower plot associated with Laser at the same range as point 1206, the analog to digital converter 302 and analog to digital converter 304 provide different values, as shown b point 1212· and point 1.214. Similarly, at the same range as point 1208, the analog to digital converter 302 and analog t digital converter 304 provide different values, as shown by point 1216 and point 1 2 18, At the same range as point 1210, the analog to digital converter 302 and analog to digital converter 304 provide■different values, as shown by point 1 220 and point 1222.

In the example of Figure 12, one laser may always aod/or mostly be chirping in the upward direction. Accordingly, this system and technique ma allow unambiguous measurements of the "correct" beat frequencies while also allowing for compensation or measurement of other effects, such as Doppler shifts, velocity, speckle, or others. Other methods of adding additional frequency tones to disambiguate the range may also be possible in other examples.

W&\ While examples described, herein have been described with reference to the use of two ADC's -{e.g., . two digitizers), in some examples a third (or more) ADC may be included with a sample rate that is ' different from the first or second ADC.. Signal from the third. ADC may he used, for example, to disambiguate the object range when tmti - fXi in this ease, f-vocj may he used to determine the "correct" i value in a manner analogous to those described herein.

[ 0| Figure 13 is a schematic, illustration of an automotive LiDA application arranged in accordance with examples described herein. The LiDAR application includes automobile 1302, lidar system 1304, automotive controls 1306, tree 1308, building 1310, and person 1312. Additional, fewer, ami/or different examples may be used.

| 8 f LiDAR systems described herein, such as system 100, system 300, system 600, system 800, system 900, and/or system 1000 may be used to implement Iidar system 1304. While shown as n automobile 1302, other moving objects may make us of iidar system 1304 in other examples. For example, an aircraft, drone, helicopter, boat, and/or bicycle may be .used.

jf>82) Automotive LiDAR applications may provide a IJDAR. system, such as lidar system 1304 on, in, and/or in communication with an. automobile, suc as automobile 1302. The iidar system 1304 is depicted r omited on a roof of automobile 1302:, however other positions may be used (e.g., in the dash, under the hood). The Iidar system 1304 may direct one or more laser beams toward targets in the scene.

J©83} Any number or kind of targets (e.g., surfaces) may be .measured using LiDAR systems described herein, including tree 1-308, building 1310, and/or person 1312. In some examples, targets may include other automobiles, aircraft, drones, etc. Accordingly, LiDAR systems described herein may provide distance measurements for multiple objects in a scene.

[984] The automotive controls 1306 may be in communication with the Iidar system 1304 to configure, start, stop, and/or interact with the Iidar system 1304. The automotive controls 1306 ma additionally or instead receive an output of the Iidar system 1 04 and take action based on the output, including to change speed and/or heading,

[0851 Distance and/or velocity measurements described herein may b used b the automotive controls 1306 to, for example, develop a 3D map of a scene. With a 3D map of the scene, more accurate commands and control r¾a be- provided by the automotive controls 1306. hi some examples the 3D map. distance, and/or velocity measurements may be displayed to a driver of the automobile 1:302 and/or other individuals la communication with the Iidar system 1304. In some examples (e.g., in autonomous and/or semi-autonomous vehicle operation), the automotive controls 1306 may cause the automobile 1302 to start, stop, turn, change direction, speed up and/or slow down based on the distance measuienaents and/or 3D map of the scene. (886) From, the foregoing it will be appreciated that, although specific embodiments have been described herein for purposes of Hlustratjon, various modifications ma be made while reroaining with the scope of the claimed technology,

¾87| Examples- described herein may -refer to various components as ' '• coupled" ' or Signals as being "provided to" or "received .from" certain components, it is to he understood that in some examples the component are directly coupled one to another, while in other examples: the components are coupled with intervening components disposed between ter . Similarly, signal may he provided directly to and/or received directly rom the recited com nents without itervefliag components, hat also ma be provided to and/or received from ' the. cert in components through inte ening components.