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Cover photo: SCaN testbed under GRC thermal vacuum testing.
Cover photo: Laser Communication RelayDemonstration (LCRD).
—I—
NASA’s mission to pave the future of space exploration through innovations
in science and technology is reflected in a balanced technology development
and maturation program supported by all NASA Mission Directorates.
Stimulating technology innovation through Small Business Innovation
Research (SBIR)/Small Business Technology Transfer (STTR) programs, NASA
has empowered U.S. small businesses to make significant contributions to
the future of space exploration.
This technology investment portfolio highlights SBIR Phases I and II
investments in optical communications technology development for the
Space Operations Mission Directorate (SOMD)/Human Exploration and
Operations Mission Directorate (HEOMD) from 2005 to 2014. This report
summarizes technology challenges addressed and advances made by the
SBIR community in optical communications technology. The goal of this
document is to encourage program and project managers, stakeholders,
and prime contractors to take advantage of these technology advancements
to leverage their own efforts and to help facilitate infusion of technology
advancements into future NASA projects. A description of NASA’s SBIR
Program can be found at www.sbir.nasa.gov.
Foreword
—II—
Small BuSineSS innovation reSearch
—III—
The Small Business Innovation Research (SBIR) Program provides opportunities for small high-
technology companies to participate in Government-sponsored research and development efforts
in key technology areas of interest to NASA. The SBIR Program provides significant sources of seed
funding to foster technology innovation. The SBIR Phase I contracts are awarded for 6 months with
funding up to $125,000; Phase II contracts are awarded for 24 months with funding up to $750,000.
—IV—
human exploration
—V—
The Human Exploration and Operations Mission Directorate (HEOMD) is chartered with the development
of core transportation elements, key systems, and enabling technologies required for beyond-low-Earth-
orbit (LEO) human exploration that will provide the foundation for the next half-century of American
leadership in space exploration.
This new space exploration era starts with increasingly challenging test missions in cislunar space,
including flights to the Lagrange points, followed by human missions to near-Earth asteroids (NEAs),
the Moon, the moons of Mars, and Mars as part of a sustained journey of exploration in the inner
solar system. HEOMD was formed in 2011 by combining the Space Operations Mission Directorate
(SOMD) and the Exploration Systems Mission Directorate (ESMD) to optimize the elements, systems,
and technologies of the precursor directorates to the maximum extent possible.
HEOMD mission goals include key technology developments in Space Communications and Navigation,
Space Transportation, Human Research and Health Maintenance, Radiation Protection, Life Support
and Habitation, High-Efficiency Space Power Systems, and Ground Processing/International Space
Station (ISS) Utilization.
HEOMD looks forward to incorporating SBIR-developed technologies into current and future systems
to contribute to the expansion of humanity across the solar system while providing continued cost-
effective space access and operations for its customers, with a high standard of safety, reliability, and
affordability.
andoperationS miSSion directorate
—VI—
Scan: Keeping theSCaN NotioNal iNtegrated Network arChiteCture
—VII—
univerSe connectedProgram aNd teChNology develoPmeNt overview
The Space Communications and Navigation (SCaN) Program resides within HEOMD and is responsible for the development of
technologies and capabilities to support all current and future NASA missions. The SCaN Program provides the communication,
navigation, and mission science data transfer services that are vital to the successful operation of NASA space flight missions. To
accomplish this, SCaN operates three networks: the Deep Space Network (DSN), the Near Earth Network (NEN), and the Space
Network (SN). Combined together, the services and network assets provide capabilities that enable space exploration for over
100 NASA and non-NASA missions. SCaN also provides scheduling services to new missions through the Network Integration
Management Office (NIMO) and Deep Space Network Commitment Office (DSNO).
To accomplish the above, the SCaN Program’s vision is to build and maintain a scalable, integrated, and mission support
infrastructure that can evolve to accommodate new and changing technologies, while providing comprehensive, robust,
cost-effective, and exponentially higher data rate services to enable NASA’s science and exploration missions. Today, NASA
communication and navigation capabilities using radiofrequency technology can support spacecraft to the fringes of the solar
system and beyond. The anticipated new missions for science and exploration of the universe are expected to challenge the
current data rates of 300 Mbps in LEO and of 6 Mbps at Mars to rise significantly. The SCaN Program aims to
• DevelopaSCaNnetworkinfrastructurecapableofmeetingbothroboticandhumanexplorationmissionneeds.
• Evolveinfrastructuretoprovidethehighestdataratesfeasible.
• Developinternationallyinteroperabledatacommunicationsprotocolsforspacemissions.
• OffercommunicationsandnavigationinfrastructureforlunarandMarssurfaces.
• OffercommunicationsandnavigationservicestoenablelunarandMarshumanmissions.
SCaN technology development interests include optical communications, advanced antenna technology and Earth stations,
cognitive networks, access links, reprogrammable communications systems, spacecraft positioning, navigation, and timing (PNT),
and communications in support of launch services. Innovative solutions to operational issues are needed in all of the areas.
Emphasis is placed on size, weight, and power improvements. All SBIR technologies developed under the SCaN topic area are
aligned with the SCaN Program technical directions.
This document catalogs SCaN SBIR investments in optical communications technology development from 2005 to 2014.
—VIII—
SBir phaSe i awardS
—IX—
CoNteNtSOptical Communication Technology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Optical Communication TechnologySBIR Phase I Awards(2005to2014) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
AdvancedThree-Dimensional(3D)ObjectIdentificationSystem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4OPTRA Inc. (2005)
Three-Dimensional(3D)VisualizationSystemforTrackingandIdentificationofObjects. . . . . . . . . . . . . . . . . . . . . . . . . 5Photon-X, Inc. (2005)
DigitalImage-BasedAutomaticTrackingCapability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6OPTRA, Inc. (2005)
High-CountingRatePhotonDetectorsforSpaceOpticalCommunications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7aPeak, Inc. (2006)
Space-Qualifiable1064-nmFiber-BasedTransmitterforLong-RangeOpticalCommunications . . . . . . . . . . . . . . . . . . . . . 8Fibertek, Inc. (2006)
HyperspectralFoveatedImagingSensorforObjectsIdentificationandTracking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9New Span Optot-Technology Inc. (2006)
Range-BasedAuto-Focus(RBAF) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10Maracel Systems & Software Technologies, LLC (2006)
SpectralImagingVisualizationandTracking(SPIVAT)System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11Physical Optics Corporation (2007)
HyperspectralImager-Tracker. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12Light Prescriptions Innovators, LLC (2007)
VeryLargeSolarRejectionFilterforLaserCommunication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13Surface Optics Corporation (2007)
High-BandwidthPhoton-CountingDetectorsWithEnhancedNear-InfraredResponse . . . . . . . . . . . . . . . . . . . . . . . . . 14aPeak, Inc. (2008)
High-Efficiency,High-PowerLaserTransmitterforDeepSpaceCommunication . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15Vega Wave Systems, Inc. (2008)
High-PowerUplinkAmplifierforDeepSpaceCommunications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16Optical Engines, Inc. (2009)
High-PerformanceNegative-FeedbackNear-Infrared(NIR)Single-PhotonCountingDetectorsandArrays. . . . . . . . . . . . . . . 17Amplification Technologies, Inc. (2009)
NegativeFeedbackAvalancheDiode(NFAD)ArraysforSingle-PhotonOpticalCommunications. . . . . . . . . . . . . . . . . . . . 18Princeton Lightwave, Inc. (2009)
Hole-Initiated-Avalanche,Linear-Mode,Single-Photon-SensitiveAvalanchePhotodetectorWithReducedExcessNoiseandLowDarkCountRate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19Voxtel, Inc. (2010)
Multi-kWUplinkFiber-LaserBeaconWithAgileSignalFormat. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20Fibertek, Inc. (2010)
High-EfficiencyData-Rate-ScalableLaserTransmitterforInterplanetaryOpticalCommunication . . . . . . . . . . . . . . . . . . . 21RAM Photonics (2011)
DownlinkFiberLaserTransmitterforDeepSpaceCommunication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22Fibertek, Inc. (2011)
—X—
SBir phaSe i awardScontinued
—XI—
High-EfficiencyReasonantlyPumped1550-nmFiber-BasedLaserTransmitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23nLight Photonics (2012)
AMiniaturePointingandTrackingIsolationPlatform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24American GNC Corporation (2012)
VibrationIsolationPlatformforLong-RangeOpticalCommunications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25Controlled Dynamics, Inc. (2012)
Compact,LightweightIsolationPlatform(CLIP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26Applied Technology Associates (2012)
LargeOpticalTelescopeBasedonHigh-EfficiencyThin-FilmPlanarDiffractiveOptics . . . . . . . . . . . . . . . . . . . . . . . . . 27BEAM Engineering for Advanced Measurements (2014)
HighCountRateSingle-PhotonCountingDetectorArray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28Voxtel, Inc. (2014)
HighEfficeiencyandPowerLaserTransmitterforDeepSpaceCommunications. . . . . . . . . . . . . . . . . . . . . . . . . . . . 29Freedom Photonics LLC (2014)
20-WHigh-Efficiency1550nmPulsedFiberLaser . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30Polaronyx, Inc. (2014)
—XII—
SBir phaSe ii awardS
—XIII—
CoNteNtS (CoNtiNued)Optical Communication Technology
Optical Communication TechnologySBIR Phase II Awards(2005to2012) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
AdvancedAutomatedDebrisTrackingandRecognitionSystem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32OPTRA, Inc. (2005)
VeryLargeSolarRejectionFilterforLaserCommunication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33Surface Optics Corporation (2007)
High-BandwidthPhoton-CountingDetectorsWithEnhancedNear-InfraredResponse . . . . . . . . . . . . . . . . . . . . . . . . . 34aPeak, Inc. (2008)
High-Efficiency,High-PowerLaserTransmitterforDeepSpaceCommunication . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35Vega Wave Systems, Inc. (2008)
High-PowerUplinkAmplifierforDeepSpaceCommunication. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36Optical Engines, Inc. (2009)
High-PerformanceNegative-Feedbacknear-Infrared(NIR)SinglePhotonCountingDetectorsandArrays . . . . . . . . . . . . . . . 37Amplification Technologies, Inc. (2009)
NegativeFeedbackAvalancheDiode(NFAD)ArraysforSingle-PhotonOpticalCommunicationsat1.5mm . . . . . . . . . . . . . . 38Princeton Lightwave, Inc. (2009)
Multi-kWUplinkFiber-LaserBeaconWithAgileSignalFormat. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39Fibertek, Inc. (2010)
DownlinkFiberLaserTransmitterforDeepSpaceCommunication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40Fibertek, Inc. (2011)
IsolationPlatformforLong-RangeOpticalCommunications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41Controlled Dynamics, Inc. (2012)
Compact,LightweightIsolationPlatform(CLIP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42Applied Technology Associates (2012)
Company Names. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
SBIR Points of Contact . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
—XIV—
optical communicationtechnology
Optical Ground Station
—1—
NASAseeksinnovativetechnologiesforlong-rangeInterplanetaryOpticalTelecommunicationssupportingthe
needsofspacemissionswhereroboticexplorerswillvisitdistantbodieswithinthesolarsystemandbeyond.
NASA’sgoalsareincreasedduplexdata-ratecapability,alongwithsignificantreductionsofsize,weightand
power(SWAP)consumptionatthespacecraft.Proposalsaresoughtinthefollowingareas:
Systemsandtechnologiesrelatingtoacquisition, trackingandsubmicroradianpointingof theopticalcommunicationsbeamundertypicaldeepspacerangesandspacecraftmicrovibrationenvironmenttechnologyreadinesslevel(TRL)3atPhaseI,andTRL4atPhaseII).
• Vibration IsolationandRejectionPlatformsandRelatedTechnologies—Compact, lightweight,spacequalifiablevibrationisolationandrejectionplatformsforpayloadswithamassbetween3and20kgthatrequirelessthan5Wofpowerandhavemasslessthan3kgthatwillattenuateanintegratedspacecraftmicrovibrationangulardisturbanceof150microradianstolessthan0.5microradians(1-sigma),from<0.1to~500Hz(TRL3PhaseIandTRL4PhaseII).Also,innovativelow-noise,low-mass,low-power,directcurrent(DC)kHzinertial,angular,position,orratesensors.Compact,ultra-low-power,low-mass,kHzbandwidth,tip-tiltmechanismswithsubmicroradianpointingaccuracies,angularrangesof±5mradandsupportingupto50-grampayloads.
• LaserTransmitters—Space-Qualifiable,>25%DC-to-optical(wall-plug)efficiency,0.2to16nspulsewidth1550-nmlasertransmitterforpulse-position-modulated(PPM)datawithrandompulsesatdutycyclesof0.3%to6.25%,<35pspulseriseandfalltimesandjitter,<25%pulse-topulseenergyvariation(atagivenpulsewidth)neartransformlimitedspectralwidth,singlepolarizationoutputwithatleast20dBpolarizationextinctionratio,amplitudeextinctionratiogreaterthan45dB,averagepowerof5to20W,massinglessthan500g/W.Lasertransmittertofeatureslot-serialPPMdatainputatCMLoralternatingcurrent(AC)-coupledPCEL levelsandanRS–422orUSBcontrolport.AllpowerconsumedbycontrolelectronicswillbeconsideredaspartofDC-to-opticalefficiency.Alsoofinterestforthelasertransmitterisrobustandcompactpackagingwith>100-kradradiationtolerantelectronicsinherentinthedesign.Detaileddescriptionofapproachestoachievethestatedefficiencyisamust(TRL3PhaseIandTRL4PhaseII).
• PhotonCountingNear-InfraredDetectorsArraysforGroundReceivers—Readoutelectronicsandclose-packed(notlens-coupled)kilo-pixel arrayssensitive to1520 to1650nmwavelength rangewith singlephotondetectionefficienciesgreaterthan90%.Singlephotondetectionjitterslessthan40picoseconds1-sigma,activediametergreaterthan500microns,1dBsaturationratesofat least10mega-photons(detected)perpixel,falsecountratesoflessthan1MHz/square-mm,allatanoperationaltemperature>1.2K.
• PhotonCountingNear-InfraredDetectorsArraysforFlightReceivers—64x64orlargerarraywithread-outintegratedcircuitforthe1030to1080nmor1520to1650nmwavelengthrangewithsingle-photondetectionefficienciesgreaterthan40%and1dBsaturationlossratesofatleast2mega-photons/pixelandoperationaltemperaturesabove220Kanddarkcountratesof<10MHz/mm.Radiationdosesofatleast5Krad(unshielded)shallresultinlessthan10%dropinsingle-photondetectionefficiencyandlessthan2Xincreaseindarkcountrate.
• Ground-BasedTelescopeAssembly—Groundstationtelescope/photon-buckettechnologiesfordevelopingeffectiveaperturediameterofe10meteratmodestcost.Operationswavelengthismonochromaticatawavelengthintherangeof1000to1600nm.Keyrequirements:amaximumimagespotsizeof<20microradian;capableofoperationwhilepointingtowithin5°oftheSun;andfield-of-viewof>50microradian.Telescopeshallbepositionedwithatwo-axisgimbalcapableof<50microradianpointingaccuracy,withdynamicerror<10microradianRMSwhiletrackingaftertip-tiltcorrection.
Research should be conducted to convincingly prove technical feasibility (proof-of-concept) during Phase I ideally throughhardwaredevelopment,withclearpathwaystodemonstratinganddeliveringfunctionalhardware,meetingallobjectivesandspecificationsinPhaseII.
—2—
—3—
optical communication technology
SBir phaSe i awardS2005 to 2014
Lunar Lasercomm Ground Terminal
—4——4—
ADVANCED ThrEE-DimENsioNAl (3D) oBJECT iDENTiFiCATioN sYsTEm
OPTRAInc.
2005PhaseI02.01-7854
Identification and Significance of Innovation
• There is a requirement for improvedcapabilities to record the initial phaseof spacecraft launches. The goal is toobtain high-resolution optical data withthe capability of identifying and trackingmultiple objects, down to 1 m² in area,along the track of the launch vehicle.By using multiple cameras and object-tracking algorithms (to be developed) itwillbepossibletorecognizeobjectsandto determine trajectories in near realtime. Knowledge of these trajectoriesandidentificationoftheseobjectswillaidgreatlyduringsearchandrecoveryefforts.
• The significance of optical trackingsystems, rather than the radar trackingsystemscurrentlyinuse,isthatitshouldbe possible to significantly improvethe resolution with which objects areidentified, while at the same timereducingthesizeandcostofthetrackingstations.Byachievingnear-real-timedataacquisition and interpretation, it may bepossible to take immediate responsiveactions in response to launch vehiclesystemfailures.
Technical Objectives
• Developrobustalgorithmsforrecognizingandtrackingobjectswiththreecamerasandforestablishingtheirabsolutepositionsandvelocitiesatmoderateframerates.
• Developthedigitalcameraandlenssystemsneededtoachievetheneededspatialresolution,field-of-view,andpositionaccuracy.
• Maximizetheframeratethatcanbeachievedwhilemeetingallothersystemrequirements.
WorkPlan
• Reviewprogramobjectiveswithtechnicalmonitor.
• Reviewexistingvideodataofrelevantevents.
• Clearlydefinetherequirementsforobjectrecognitionandtracking
algorithms.
• Developthesealgorithms.
• Testrecognitionandtrackingalgorithms.
• Writefinalreport.
NASA Applications
• Trackingspacecraftlaunches
• Aidinginrecoveryofjettisonedcomponents
• Providingaccidentanalysisdata
• Aidinginreal-timeresponsetolaunchmishaps
Non-NASA Applications
• Aircrafttrackingandidentification
• Surveillance
—5——5—
ThrEE-DimENsioNAl (3D) VisuAlizATioN sYsTEm For TrACkiNg ANDiDENTiFiCATioN oF oBJECTs
Photon-X,Inc.
2005PhaseI02.01-7857
Identification and Significance of Innovation
The Photon-X imaging technology is calledspatialphaseandgeneratesacrisp3Dimagemosaicusingthefollowinginnovations.
• Single camera to generate 3D real-timemosaics
• Image is angle invariant to the surfaceareabeingmeasured
• Image is resolution and scale invariantoverextendedranges
• Image is invariant to lighting changes,surface area, and textures or curvatureand can detect objects better in smokeandfog
• Small in size and easily adaptable touniqueconfigurations
Theoutputofthe3DVisualizationSystemforTrackingObjectshasaresolutionsufficienttodetectmany3Dobjectsandtracktheobjectsthrough space. ThePhoton-X technology isthefirst3Dtechnologythathasthepotentialto be used in a space application, with itsstrong passive techniques coupled with ahigh-precision measurement in a singlecamerapackage.
Technical Objectives
ThePhaseIobjectivesaretodemonstratehowPhoton-X’soptical-basedspatialphasetechnologycanbeusedtogenerateefficientandhigh-resolution3Dviewsoftumblingobjectsinspace.Aproof-of-conceptdemonstrationoftheunderlyingtechnologywillbeperformedtodemonstratetheapplicabilityofthetechnologyforthisapplication.InPhaseI,weproposetodemonstratetheabilitytotrackmultiple3Dobjectsinascaledversionofobjectsinspace.
Initiallaboratorytestswillbeperformedonscaled3Dtumblingmodelsandafinalproof-of-concepttestwillbeperformedonseveral3Dobjectsthatwillbetumblingthroughthefieldofviewwhilebeingidentifiedbyshapeaswellasbeingtracked.Thesuccesswillbebasedonsuccessfultrackingofseveral3Dtumblingobjectsthroughthecamerasfieldofview.
NASA and Non-NASA Applications
Photon-Xhasdevelopedapatentedimagingprocessthatcanprovideanefficientandaccuratemeanstogenerateahigh-resolution3Dimagemosaicoutputtobeusedfortracking3Dtumblingobjectsinrealtime.ThePhoton-Xtechnologyusesasinglecamerathatwouldpassivelyallowforcrisp3Dimagemosaicstobeconstructedfromflybysnapshotviewsgeneratingavolumetricviewofthesurfaceareaunderinspection.Thesystemcouldalsobeusedasapretactilesensorallowingforobjectrecognitionorroboticvision.Thesensorhaspotentialinmanycommercialapplicationssuchas3Danimation,sportsmotion,andmachinevision.
—6——6—
DigiTAl imAgE-BAsED AuTomATiC TrACkiNg CApABiliTY
OPTRA,Inc.
2005PhaseI02.01-7865
Technical Objectives
• DeveloparobusttrackingalgorithmtogenerateALTandAZerrorsignals;servocontroleachtrackingmounttokeepitsopticalaxisaccuratelyalignedwiththetarget.
• Developaprotocoltogeneratereal-timetrajectorydatabasedontheinputsfromtrackingstations.
• Designandassembleaprototypefocalplanearray(digitalimager),opticalsystem(telescope),andservo-controlledALT/AZmounttotestandevaluatetargetacquisitionandtrackingalgorithms.
• Determinetrackingdistance,errorsasafunctionofdistance,processingspeed,anddatadeliverytimetocommandcenter.
WorkPlan
• Developtargetacquisitionalgorithm(s).
• Developautomatedtrackingalgorithm.
• Designprototypetrackingsystem(digitalcamera,telescope,servo-controlledtrackingmount,andPCwithfastframe-grabbercard).
• Determinetrackingdistance,errorsasafunctionofdistance,processingspeed,andmeansfordeliveringanalyzeddatatocommandcenter.
• Testprototypesystemandassessresults.
• Writefinalreport.
NASA Applications
Trackingspacecraftlauncheswithhigh-resolutionimagery
Non-NASA Applications
• Monitoringofmilitaryweaponsandaircrafts
Identification and Significance of Innovation
Thelaunchesandlandingsofspacecraftarethe most demanding phases of missions.Duringlaunchitiscriticalthatthespaceve-hiclebeaccuratelytrackedtoensureitssuc-cessful insertion into orbit, and to monitorseveralphasesofthelaunchsequence(liftoff,boosterseparation,separationfromthemainfueltank,transitiontoorbitalflight,etc.).
To date, optical tracking atNASA’sKennedySpace Center has been accomplished bymanually guided tracking stations, whichmay carry auxiliary video cameras. Thisproposal describes an automated approachto optical tracking where multiple opticaltrackingstationscanautomaticallytrackthespacevehicle following launch,whileat thesametimeprovidinghigh-resolutionimageryofthespacevehicle.Thecombineddatafrommultipletrackingstationswillallowaccuratedetermination of vehicle trajectory and ex-trapolationof real-timetrajectory tostayontarget.
GRAPHICUNAVAILABLE
—7——7—
high-CouNTiNg rATE phoToN DETECTors For spACE opTiCAl CommuNiCATioNs
aPeak,Inc.
2006PhaseIO1-06-9886
Technical Objectives
• Modificationofthehigh-gaindetectorfabricationflowfortheintegrationoftheinfraredconverterdepositionprocess
• Processdevelopment,verification,andperformancequalification• Development,qualification,andidentificationofpathwaysforimproving
thebandwidthofhigh-gaindetectorarrays
WorkPlan
• Task1:Kickoff/updatemeeting
• Task2:Processmodificationtoimproveinperformanceininfrared
• Task3:Infraredconverter-high-gaindetectorprocessintegration
• Task4:Test-structurefabrication
• Task5:Timingperformanceimprovement
NASA ApplicationsFree-spacecommunications,intersatellitelinks,spacedocking,landing,mapping,andhigh-resolutionaltimetry,LaserDetectionandRanging(LADAR)andLightDetectionandRanging(LIDAR).
Non-NASA Applications
Low-lightleveltwo-dimensional(2D)andthree-dimensional(3D)imagingcamerasfordefenseandsecurityapplications,airportsecurity,collisionavoidance,roboticsystems,andautonomousvehicles,aswellasgenericapplicationsrequiringactivelaserilluminationateye-safewavelengths.
Identification and Significance of Innovation
Weproposedtodemonstrateanovel,photon-counting detector, with integrated infraredconverter,gain>106,>50%detectionefficien-cyfrom1064to1550nm,morethan500MHztarget bandwidth, and more than 100 MHzbackgroundcountingratecapabilitybyusinghigh gain silicon detector arrays in conjunc-tionwith infrared converters.This innovationprovidesasimplesolutiontohigh-bandwidthground-space and space-space optical com-munications by mitigating conflicting opticalaperture-noise requirements,while providingphoton-counting sensitivity at infraredwave-lengths.Thisnovelphotoncountingdetectorarchitecturepromises tomeetall the techni-calrequirementsofthedetectorsforthelong-range optical telecommunications programand has the potential to exceed the targetbandwidth.
Technologyreadinesslevel(TRL)attheendofPhaseI
• 2to3
ExpectedTRLattheendofcontract
• 4
—8——8—
spACE-QuAliFiABlE 1064-nm FiBEr-BAsED TrANsmiTTEr For loNg-rANgE opTiCAl CommuNiCATioNs
Fibertek,Inc.
2006PhaseI06-9244
Technical Objectives• Demonstratearbitrarypatternopticalpulsegeneration,withpulse
widthfrom0.15to10nsec,andatupto60MHzrate.• Addressopticalnonlinearityimpairmentsanddemonstrate
amplificationofopticalpulsetrainto~10Waveragepowers.• Developanoverallpackagingdesignandsystemreliabilitymodel,
targetinganeventualspacequalification.
WorkPlan
• DesignofanFPGA-basedarchitectureforlasercontroller• PCBdesign,development,andtestingforabovearchitecture• DemonstrateopticalamplificationtoPo~1Wandassessnonlinear
opticalimpairmentsforfurtherpowerscaling• Assesspackagingforaradiation-hardeneddesign• Developasystemreliabilitymodelwithredundancy
NASA Applications• High-bandwidthdeepspaceopticalcommunicationsforplanetary
mission• High-bandwidthintersatellitecommunication
Non-NASA Applications• Free-spaceopticalcommunicationlinks• Applyingaboveapproachtohigh-speedmodulatedimagingand
communicationforunderwaterapplication
Identification and Significance of Innovation
An all-fiber polarization-maintaining trans-mitter operating at 1064-nm wavelengthis proposed, suited for deep space opticalcommunication. The compact, rugged andefficientdesignisbasedonamaster-oscilla-tor-power-amplifier(MOPA)architecture.Theoscillatorisafiber-coupledsingle-frequencylaserdiode, fromwhichanarbitrarypatternofpulse-trainsasshortas150pseccanbecarvedout,basedonaproprietarydesignus-ingstate-of-the-arthigh-speedFPGAsfortheelectronic modulation. A multistage poweramplifier using Yb-doped fibers is used forpower-scalingwhilemitigatingall nonlinearoptical impairments.The design is compat-ible with M-ary pulse-position-modulation(PPM)scheme(M=2,4,…,256),withtime-slot down to 150 ps, that is required forhigh-bandwidth high-sensitivity deep-spaceoptical communications. Space qualifiablepackagingandoverallsystemreliabilitymod-elarealsoaddressed.
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hYpErspECTrAl FoVEATED imAgiNg sENsor For oBJECTs iDENTiFiCATioN AND TrACkiNg
NewSpanOptot-TechnologyInc.
2006PhaseIO2.01-8509
Identification and Significance of Innovation
• Optical identification and tracking sen-sorshavenumerousNASAandnon-NASAapplications.
• These applications require sensors thathavewidefield-of-view,highspatialreso-lution,highspectraldiscriminationability,andfastresponse.
• Existing sensors cannot satisfy all of theaboverequirements.
• Proposedhyperspectral foveated imagingsensor simultaneously possesses proper-ties ofwide field of view for global situ-ationawareness,hyperspectral ability forspectralsignatureidentification,highlocalspatialresolutionforobjectdetailsreveal-ing, and potentially multiplying objects’trackingability.
• Using fully“solid-state”opticalandelec-tronicdevicesenablesfastresponse,light-weightandlowpowerconsumption.
• Allinvolvedcomponentsarecommerciallyavailableoreasytofabricateresultinginacost-effectivesystem.
Technical Objectives
DevelopanddemonstrateaninnovativeopticalhyperspectralimagingsensorforidentificationandtrackingofNASA’slaunchandlandingobjects.Thesensorisexpectedtopossesswidefield-of-viewwithhigh-resolutionmeasurementofspectral,spatial,andtemporalsignatures.
WorkPlan
• Exploreoveralltechnicalscheme;constructpanoramicimagingoptics.
• Buildcomputedhyperspectralimagingsystem.
• Constructlocalimagemagnificationchannel.
• Developalgorithmforsimplifiedhyperspectralimagereconstruction.
• Constructbenchtopexperimentalsetuptodemonstratefeasibility.
NASA Applications
• Launchobjecttrackingandidentification
• Roboticperceptionandmappingforunmannedspaceoperations
• Tackingandidentificationofspacedebrisorothermanmadeobjects
• Detectingandtrackingofon-Earthobjectsmovementfromspacevehiclesorballoons
Non-NASA Applications
• Missiledefense,weaponandsensorplatformguidance
• Wideareasurveillance
• Aero-vehiclerendezvous,docking,navigation,andguidance
• Qualitycontrol,mechanicalpartsinspection,andnondestructiveevaluation
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rANgE-BAsED AuTo-FoCus (rBAF)
MaracelSystems&SoftwareTechnologies,LLC
2006PhaseIO2.01-9758
Identification and Significance of Innovation
Range-Based Auto-Focus (RBAF) is a real-time capability that combines both range-basedandpixel-basedfocustechniquesandwill represent a significant increase in thefocus performance of exisiting and newlydevelopedlong-rangeopticalsystems.
ThesignificanceoftheRBAFsystemdevelop-ment is twofold: consistently accurate real-timedataproductswillbecomeavailable toendusers,andmoreusabledatacanbereli-ablycollected.
Technical Objectives
• Determineanoptimalstatisticalmeasureofimagequalitythatisidealformovingtargets.
• Designandvalidateanalgorithmthatcombinesexternalrangewithimagequalitytocontrolfocus.
• Refinethealgorithmstoachieveidealfocus.• Implementanarchitecturalframeworkthatfacilitatesfieldcalibration,
variousvideoinputtypes,andintegrationwithdifferenttypesoffocuscontrollers;takeadvantageofexistingsystems’capabilities;andfocusonlyonthesubjectoftheimagery.
WorkPlan• Task1:Captureanddisplayliveimages.• Task2:Implementcomputer-basedfocusalgorithm.• Task3:Developrange-basedfocusalgorithm.• Task4:Determineimagequality.• Task5:Developimagery-aidedfocusalgorithm.• Task6:UseRegion-of-Interestforauto-focuszones.• Task7:Developfeaturetrackingcapability.• Task8:Developautomatedcalibrationtechniques.
NASA Applications
• Long-rangeoptics
• Videodocumentationsystems
• Opticaltrackingsystems
Non-NASA Applications
• U.S.andforeigntestranges
• Tacticalsystems
• Surveillanceandsecurity
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spECTrAl imAgiNg VisuAlizATioN AND TrACkiNg (spiVAT) sYsTEm
PhysicalOpticsCorporation
2007PhaseIO2.01-9551
Identification and Significance of Innovation
NASA is seeking technologies to enable asaferandmorereliablespacetransportationcapability; specifically, innovative ways areneededtovisualizeandtrackvehiclesduringlaunchand landing.Current optical imagingsystemsusuallyusestandardcameras,whichare light sensitive, only to visible light,withsufficientcontrastonly indaytimeoperationunder good weather conditions. POC’sproposedSPIVATsystemoffersasuperiorandreliable visualization and tracking capabilityfordayandnightoperationunderallweatherconditions.
Expected technology readiness level (TRL)rangeattheendofcontract(1–9)• PhaseI:4• PhaseII:6
Technical Objectives
TheoverallgoalofthisprojectistodemonstrateforthefirsttimethefeasibilityofSPIVATinPhaseI.Specifictechnicalobjectivesinclude• DevelopmentofapreliminarydesignoftheproposedSPIVATsystem• IdentificationoftechnologiesforimplementingtheSPIVATsubsystems• Integration,testing,andevaluationoftheSPIVATsystemforenhanced
visualizationandtracking• PreliminaryestablishmentoftheSPIVATtechnologyforcommercial
applications
WorkPlan• DevelopdetailedtechnicalrequirementsforproposedSPIVATsystem• DesignSPIVATPhaseIsystem.• AnalyzeCOTScomponentstoensurethesystemrequirementsare
fulfilled.• ProcureandtestCOTScomponents.• Develophyperspectral/multispectralimagefusionalgorithmsfortarget
visualizationandtracking.• Performfeasibilityanalysis.• Explorethecommercialpotentialandproductviability.
NASA and Non-NASA Applications
• ThesuccessoftheSPIVATprojectwillensuretechnologyisavailabletoNASAtovisualizeandtrackvehiclesduringlaunchandlanding,withgreatlyextendedcapability.TheSPIVATtechnologycanbedirectlyappliedtoairtrafficcontrol,lawenforcement,security,searchandrescue,firefighting,hunting,andtheautomotiveindustry.
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hYpErspECTrAl imAgEr-TrACkEr
LightPrescriptionsInnovators,LLC
2007PhaseIO2.01-9731
Identification and Significance of Innovation
The challenges of launching and landingspace vehicles put extreme requirementson NASA operational centers. Use of opticaltracking techniqueallowprecisecontrolandin-flightinspection.However,theenvironmentof the two landing areas make visibilitydifficult. Light Prescriptions Innovators (LPI)proposestoimprovethetargetimagingusingahyperscopewithhighlight-gatheringpowerand high magnification. Adaptive spectralfilteringalgorithmwillproduceahighcontrastimage.
Expectedtechnologyreadiness level (TRL)attheendofPhase1• 4
Technical Objectives
• Developdesignoftheimager.
• Developoptomechanicaldesignofimagerprototype.
• Developalgorithmsandsoftwareforspectrallyadaptivefiltering.
• Demonstratefeasibilityoftheproposedconceptbyfabricatingproof-of-conceptprototypeandevaluatingitsperformanceinlaboratoryconditions.
• Evaluatepotentiallycommercialapplications.
NASA Applications
NASAapplicationswillincludeopticalspaceobjectsdetectionandtracking,spacebiologybyimplementationofthistechnologyinmicroscopy,remoteEarthobservationforenvironmental,andresourcemonitoring.
Non-NASA Applications
Commercialapplicationswillincludethedevelopmentofcamerasforenvironmentalmonitoring(hazardgasesandwastedetection),camerasforforensicanalysis,andcamerasforsearchandrescueteams.TheimportantapplicationareaofhyperscopetechnologyisdetectionandtrackingofcamouflageobjectsforDepartmentofDefense(DOD)programs.Itcanincludecompactunmannedvehiclescamerasandhand-heldcamerasforMarineCorpsandarmy.
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VErY lArgE solAr rEJECTioN FilTEr For lAsEr CommuNiCATioN
SurfaceOpticsCorporation
2007PhaseIO1.08-8373
Identification and Significance of Innovation
Surface Optics Corporation will develop aband-passfiltercomprisesavisibledielectricmirror and an induced transmission filterapplied to two sides of a cast polyimidemembrane.Themirror/filtercombinationwillblock 95% of the incident solar radiation,while allowing a narrowpass-band forYAG-lasercommunication.
Expectedtechnologyreadiness level (TRL)attheendofPhaseIContract(1–9)• 6
Technical Objectives
• Generateopticalconstantsforthinmetalfilms.
• Generateandevaluatecoatingdesigns.
• Buildandtestcoatingdesigns.
• Optimizeadhesionofcoatingstopolymersubstrate.
• Fabricatesubscalefiltersonpolymersubstrate.
• Environmentaltestingofsubscalefilters.
NASA and Non-NASA Applications
• Long-rangelasercommunications;interplanetarymissions
• Solarcoverforlasercommunicationreceiverondefensesatellite
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high-BANDwiDTh phoToN-CouNTiNg DETECTors wiTh ENhANCED NEAr-iNFrArED rEspoNsE
aPeak,Inc.
2008PhaseIO1.06-9563
Identification and Significance of Innovation
Newest designs in long-range optical com-munication systems require high-gain,photon-counting arrays operated with highdetection efficiency, outstanding temporalresolution,andcapabilitytohandlehighpho-tondetectionrates.
We propose to develop a novel large area,silicon photon-counting detector array innearinfrared,operatedwithmoderatecool-ing, high-detection efficiency, high satura-tioncountingrate,andcapableof20pstim-ing resolution. Detector and readout circuitdesignwillbe improved tomeet thedetec-tion efficiency, noise, timing resolution, andlinearityrequirementsoftheapplication.
Expected technology readiness level (TRL)rangeattheendofcontract
• 5
Technical Objectives
• Developmentofthetunedcavityandmirrorfabrication.
• Developmentofphotoncountingarraysandfastelectronicsforincreaseddatarateandimprovedtimingresolution.
WorkPlan
• Detectorstructuremodeling
• Detectorprocessdevelopment
• Detectorarrayprototyping
• Electronicsdevelopment
NASA and Non-NASA Applications
Thenovelphoton-countingarraywillfindapplicationinfreespaceopticalcommunications,space-groundopticallinks,detectionorimaginginmediawithhighturbidity,interferometry,mapping,roboticvision,veryhighresolutionthree-dimensional(3D)imaging,hyperspectralimaging,andspacedocking.Inadditiontolong-rangeopticalcommunications,largerarrayscouldbefabricatedforsingle-photonimagingintheinfraredandvisiblewithapplicationstosecuritycameras,imagingofnoncooperativetargets,single-moleculedetection,integrationintomicrofluidicdevices,biochipsforbiomedicalapplications,fluorescencecorrelationspectroscopy,etc.
Exampleoftheinnovationembodimentofthedetectorarraywithintegratedelectronics.Thecenterpackagecontainsthephoton-countingarraymountedinflip-chip,andtheperimetercontainstheelectronics.
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high-EFFiCiENCY, high-powEr lAsEr TrANsmiTTEr For DEEp spACE CommuNiCATioN
VegaWaveSystems,Inc.
2008PhaseIO1.06-9602
Identification and Significance of Innovation
We propose improvements to fiber MOPAtransmittersfordeepspacecommunicationslinksusingseveralnewtechniques:
• Operating wavelength of 1560 nmreducesthesizeandweightoftheopticalcomponents
• Resonant pumping in the 1430 to 1530nmbandimprovespumpabsorptionandhence,wallplugefficiency
• Wavelength-stabilized laser (WSL) pumpsources: eliminates power-hungry ther-moelectric (TE) coolers, producing asignificant improvement in wall plugefficiency
• High-powerseed laserwithdouble-passfirst-stage amplifier: reduces number ofamplifierstagesandimprovesefficiency
Technical Objectives
• Design,fabricate,andcharacterizeawavelength-stabilizedpumpsourceforresonantpumpinginthe1430to1530nmEr+-dopedabsorptionband.
• ModeltheEr+-dopedMasterOscillatorPowerAmplifier(MOPA)todeterminefiberlengths,pumpcouplingmethods,andpowerrequirementstoachieve1kWpeakpulsepower.
WorkPlan
• Wavelength-stabilizedpumplasers
–Design,fabricate,andcharacterizepumpsourceforresonant pumpinginthe1430to1530nmrangeusingproprietary technology.
• ModeltheEr+-dopedMOPAtodeterminefiberlengths,pumpcouplingmethods,andpowerrequirementstoachieve1kWpeakpulsepower.
NASA Applications
• High-speed,high-powerpulsepositionmodulationopticalcommunicationslinksfordeepspaceapplications
Non-NASA Applications
• Eyesafepulsedfiber-laser-basedsourcesformaterialprocessingandotherscientificapplications
• High-powerwavelength-stabilizedpumpsourcesatlongwavelength
—16——16—
Identification and Significance of Innovation
Weproposetodemonstrateacompact1-kWfiberamplifiersuitedforuplinkapplications:
• Useofmultifibercoupled2.5-Kwlaserdi-odestackgreatlyreducessizeandcost
• Etchedtaperbundlecombinercreatesanallfiberarchitectureforreliableoperation
• PCFFiberamplifiersimprovetheefficien-cyofthesystem,andallowsforahigherlevel of pump integration also reducingpotentialnonlinearities
Expectedtechnologyreadinesslevel(TRL)attheendofthecontract
• 4
Technical Objectives
Usethemultifibercoupled2.5-kWlaserdiodestackandetchedtaperbundleallfiber4+1to1combinerwithphotoniccrystalfiber(PCF)toassemble,demonstrate,andcharacterizeandYb-based1064-nm1-kWpoweramplifier.
WorkPlan• Construct2.5-kWfibercoupledstackinto4500-umfibers.
• Construct4+1to1etchedtaperbundlefibercombiner.
• AssemblefiberamplifierwithabovecomponentsandPCFFiber.
• Demonstrateandcharacterize1-kWfiberamplifier.
NASA Applications
• High-poweropticalcommunicationsuplinktransmitterandbeaconlaser
• Highpowersourceforremotesensing
Non-NASA Applications
• Highpowersourcefordirectedenergyapplications
• Fiberlasersourceformaterial-processingapplications
high-powEr upliNk AmpliFEr For DEEp spACE CommuNiCATioNs
OpticalEngines,Inc.
2009PhaseIO1.06-8122
—17——17—
Identification and Significance of Innovation New photon-counting photodetectors andarraysareproposedtoadvancethestateoftheart in long-rangespaceopticalcommu-nications.Theproposeddetectoroperatesat1000to1600nmwavelengthsandhavehighdetection efficiency, low jitter, high band-width,veryhighinternalgain,andextremelylowexcessnoise.Thedetectordesignwillbebased on the invented breakthrough tech-nology of discrete amplification. The newdetector will enable meeting the goals oflong-range space optical communicationapplications.
Technical Objectives
• DeveloptheinternaldiscreteamplificationdesigninInGaAs/InPmaterialsystemtoachievestatedgoals.
• Developinitialdesignofthedetectorarraythatmeetsorexceedsthedesiredperformancecharacteristics.
• Developfabricationprocessesforthefabricationoftheinternaldiscreteamplifierdetectorsandarrays.
• Fabricate,test,andanalyzetheresultsofthefabricateddevicesinPhaseII.
• DeliverfullyfunctionalInGaAs/InP-basedphotodetectorsandarrayswithinternaldiscreteamplificationtoNASAattheconclusionofPhaseII.
NASA Applications
• Long-rangespacetogroundcommunicationlinks
• Intersatellitelinks
• Earthorbitingtogroundopticalcommunication
• Quantumcryptography
• Three-dimensional(3D)imaging
• Nightvision
NASA and Non-NASA Applications
• Opticalcommunication
• LightDetectionandRanging/LaserDetectionandRanging(LIDAR/LADAR)remotesensing
high-pErFormANCE NEgATiVE FEEDBACk NEAr iNFrArED (Nir) siNglE phoToN CouNTiNg DETECTors AND ArrAYs
AmplificationTechnologies,Inc.
2009PhaseIO1.06-8219
—18——18—
Identification and Significance of Innovation
We propose to develop large pixel-count(e.g.,80x80)singlephotoncountingdetectorarrayssuitablefordeploymentinspacecraftterminal receivers supporting long-rangelaser communications. We will leverageinitial success inmonolithically integrating“negative feedback” elements with state-of-the-art single photon avalanche diodestorealizelarge-scale(NFAD)arraysinwhicharray pixels have high counting rate, highdetectionefficiency,lowdarkcountrate,lowafter pulsing, and low timing jitter. Thesedevices rapidlyself-quench,which reducesafterpulsing and supports higher photoncounting rates. Since NFADs self-quenchand self-arm, they can be deployed withgreatly simplified back-end circuitry. NFADarrayshavesignificantpromiseforenablingspace-qualifiable focal plane arrays thatserve applications requiring 1.5 µm singlephotondetection.
Expectedtechnologyreadinesslevels(TRLs)atstartandendofcontract• 2• 4
Technical Objectives
• DesignNFADtoreduceafterpulsingby3X.• DesignNFADtoachievetimingjitter<70ps.• Establishreproducibilityanduniformityofnegativefeedbackonscale
oflargearrays.WorkPlan• 1.A.CharacterizeafterpulsingofexistingPLIdiscreteNFADs.• 1.B.DevelopafterpulsingmodelstodescribeTask1.A.results.• 1.C.DefineoptimalNFADdesignfor3Xreductioninafterpulsing.• 2.A.CharacterizetimingjitterofexistingPLIdiscreteNFADs.• 2B.DeveloptimingjittermodelstodescribeTask2.A.results.• 2C.DefineoptimalNFADdesigntoachieve<70pstimingjitter.• 3.A.Fabricatenegativefeedbackthin-filmteststructures.• 3.B.Characterizefeedbackteststructuresforuniformityand
scalability.• 4.DefinitionofoptimalNFADpixeldesignandarraystructure.
NASA Applications
• Free-spaceopticalcommunications,includingspace-basedlasercommunicationslinks
• ActiveremotesensingopticalinstrumentsLightDetectionandRanging(LIDAR)
Non-NASA Applications
• Range-findingandLaserDetectionandRanging(LADAR)applications• CommercialLIDARsystems• Freespaceoptical(satellite)communications• Singlephotoncountingforfluorescence,photoluminescence,and
photoemissionapplications
NEgATiVE FEEDBACk AVAlANChE DioDE (NFAD) ArrAYs For siNglE- phoToN opTiCAl CommuNiCATioNs AT 1.5 mm
PrincetonLightwave,Inc.
2009PhaseIO1.06-9687
—19——19—
Identification and Significance of Innovation
• Multi-gain-stage APD process proventoexhibithighgain(M>1000)with lowexcessnoise(k=0.02).
• Reliable back-illuminated mesa InGaAs/InPAPDprocess.
• Proven tolerant toproton irradiation>10krad.
• Eliminating aluminum alloys will reducedarkcurrentby2ordersofmagnitude.
• Hole-initiatedavalancheisanticipatedtoincrease temporal response by 5 to 10times,allowingGHzcountratesinsingle-elementdevices.
• Technology readiness levels (TRLs)3 and 4 at commencement. Electronavalanchedevicehasbeenbuilt, thoughthe hole-initiated multistage device hasnot.Similarly, radiation testinghasbeenperformed on the electron-avalanchedevice.
Technical Objectives
• Fabricatesingleelementsofvaryingdiameter
–Allowsverificationofchangesingainanddarkcurrentvs.diameter
• Testandcharacterizedevicegain,darkcurrent,capacitance,andcountrate
–Verifygain(>1200),excessnoise(k<0.02),breakdownuniformity
(<2VPhaseIand<1VPhaseII)
• Fabricatesegmentedarrays
• Designsegmenteddetectorreadoutintegratedcircuit(ROIC),includinglow-noise(<40e−RMS)segmentedpixeluniformitycorrection,in-pixelthresholding,etc.
• PhaseII:Fabricateworkingsingle-photon-sensitivereceiver,testforgammaandprotonradiationtolerance,lifetimetest,anddeliverworkingreceiverinhermetichousing
NASA Applications
• Deepspaceopticalcommunications• LightDetectionandRanging(LIDAR)receiverforatmosphericprofiling• Rangefinderforprofiling• Startrackers• Three-dimensional(3D)imagingLightDetectionandRanging/Laser
DetectionandRanging(LIDAR/LADAR),whenconfiguredintoarrays• AstronomicalimagingoverUV-SWIRrange(withsubstrateremoved)
Non-NASA Applications
• Automotivenavigation(adaptivecruisecontrol)• Telecommunications• Quantumcryptography• Militarymissileseekersandunmannedaerialvehicles/unmanned
groundvehicle(UAV/UGV)navigation
holE-iNiTiATED-AVAlANChE, liNEAr-moDE, siNglE-phoToN-sENsiTiVE AVAlANChE phoToDETECTor wiTh rEDuCED ExCEss NoisE AND low
DArk CouNT rATE
Voxtel,Inc.
2010PhaseIO1.04-9119
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mulTi-kw upliNk FiBEr-lAsEr BEACoN wiTh AgilE sigNAl FormAT
Fibertek,Inc.
2010PhaseIO1.04-9435
Identification and Significance of Innovation
Uplink laser beacons for deep space com-munications,benefitgreatlyfrommigratingto 1010 to 1030 nmwavelengths, via useof siliconAPD receivers on the spacecraft.Fibertek has developed an uplink lasertransmittertestbedusingamultistagefiberMOPA platform, that is scalable to a mul-tiaperturearchitecture.Preliminarydemon-stration for 1064 nm operation has shownmulti-kW peak powers using long-pulseslot (>100nsec)basedM-aryPPM format.The highly flexible platform developed atFibertek, also corrects for pulse-distortion,andpulse-trainvariations, inherentinsuchmulti-kW long-pulse variable-symbol PPMdataformat.ThisSBIRproposalaimstode-velop and demonstrate the feasibility of acleartechnicalroadmaptotranslatethistoshorterwavelengths<1030nm,aswellastofurtheroptimizetheuplinklaserbeacontransmitterforM-aryPPMdataformats,us-ingFPGA-basedadaptivecontrol.
Expected technology readiness level (TRL)atendofSBIRPhII
• 6
Technical Objectives
• DemonstrateCWandpulsed(M-arypulsepositionmodulation(PPM))fiberMasterOscillatorPowerAmplifier(MOPA)forefficientoperationinthe1010to1030nmwavelengthregion.
• Developanoverallsystemdesignforuplinklaserbeaconontheroadmapfordeepspacemissions.
WorkPlan• BuildandtestverificationofmultistagefiberMOPAproducing
Pavg>30W,optimizedfor1010to1030nmwavelengthregion.• Developaniterative/adaptivealgorithmcontrolofM-aryPPMsymbol
format,withneededopticalpulsecontrol.
NASA Applications
• Uplinklaserbeaconfordeepspacecommunicationandtelemetry.• Subscaleversionasuplinkbeaconforlunarcommunicationsand
ground-stationtolow-Earth-orbit/geostationary-Earth-Orbit(LEO/GEO)satellitecommunication.
Non-NASA Applications
• Groundstationtomilitarysatellitecommunication/telemetry• Groundtospace(near-Earth)powerprojectionforsmallpayload
propulsion• Powerprojectionfordirectedenergyapplicationandtesting
—21——21—
Identification and Significance of Innovation
Identificationofopportunity:
• High-ratedirectionalcommunication
• Deepspaceandintermediate-rangedatalinks
Significanceofinnovation:
• Self-regeneratedparametricamplifier
• High-fidelity, high-power pulse genera-tion
• Brillouin-mitigatedpoweramplification
• Propagationpenaltymitigation
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 1
• 2
Technical Objectives
• Modulatorqualification• Digitizingparametricamplifierextinctionassessment• Digitizingparametricamplifiergainlimits• Pulsesharpeningqualification• SBSlimitationsonfiberamplification• Poweramplifierefficiencyandin-bandnoiseassessment• Assessmentofpropagationpenalty• Lasertransmittersystemdesign• Documentationandreporting
WorkPlan• Task1:Masteroscillatorandmodulatorqualification(1month)• Task2:Parametricamplifiermodeldevelopment(2months)• Task3:Digitizingparametricamplifieroptimization(3months)• Task4:ImposedSBSlimitations(1month)• Task5:Er-dopedfiberamplifiermodeldevelopment(1month)• Task6:Confined-gainfiberpoweramplifierefficiencyoptimization(3months)• Task7:Receiverpenaltyduetobeamquality(1month)• Task8:Documentationandreporting
NASA Applications
• Rate-scalableopticalcommunication• Sensorandimaginglinks• High-precisionranging•Non-NASA Applications
• Deep-seasensing• Opticalwireless
high-EFFiCiENCY DATA-rATE-sCAlABlE lAsEr TrANsmiTTEr For iNTErplANETArY opTiCAl CommuNiCATioN
RAMPhotonics
2011PhaseIO1.04-8043
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DowNliNk FiBEr lAsEr TrANsmiTTEr For DEEp spACE CommuNiCATioN
Fibertek,Inc.
2011PhaseIO1.04-9718
Identification and Significance of Innovation
NASA’s SCaN roadmap, calls for an inte-grated network approach to communica-tion and navigation needs, fromnear-Earthto planetary missions. Laser based opticalcommunication links for spaceprovidesanorder of magnitude higher data rates thancorresponding RF links. In addition, due tomuchsmaller size,weight&powerburdentospacecraft,resourcesareavailabletoen-hanceorextendsciencemissions.Tremen-dousprogressmadein1.5um&1-umfiberlaser/amplifier technologies, their powerscaling, and availability of reliable high-power components, makes such transmit-tersfeasibleforspacemission.InthisSBIRproposal, we propose to develop 1.5 umfiber-amplifierbasedlasertransmitters,withPav>4W, and compatible with a variety ofM-aryPPM formats, thathaveaclearpathtospace-qualificationroadmap. Inaddition,power-scaling to 10W, athermal operationovertemperaturerange,andimprovedpow-er efficiency, are addressed. Limited scopequalificationtestsarealsoplanned.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 4• 6
Technical Objectives• 1.5umfiberlasertransmitter,withP>4W(Ppk>0.64kW)compatible
witharangeofM-arypulsepositionmodulation(PPM)formats.StretchgoalofdesignvalidationtoPav~10W,Ppk1.6kW.
• Athermaloperationoverwidetemperaturerange,whilemaintaininghighoverallpowerefficiency(>15%)
• Packagingdesign(fiber-amplifierassemblyonly,i.e.,excludingelectronics)consistentwithspace-qualificationroadmap
• Limitedscopequalificationtesting(inPhaseII)WorkPlan• DesignandLabverificationof1.5mmfiberMasterOscillatorPower
Amplifier(MOPA)forallkeyperformanceparameters,withtechniquesforSBSmitigation
• OptimizeandvalidatedesignbycomparingwithpredictedperformancefromacomprehensivefiberMOPAsimulationmodel
• Evaluateathermaloperation,viauseofwavelengthstabilizedpumps,andfiber-amplifierthermalmanagement
• Packagingconceptandqualificationplanforaspacequalificationroadmap
NASA Applications
• High-bandwidthlasercomflightterminalforplanetarymissions,aswellasforvariouslunarandMarsrelaylinks,perSpaceCommunicationsandNavigation(SCaN)roadmap.
• Space-qualifiable,robust,compact,andefficientLightDetectionandRanging(LIDAR)component,e.g.,CO2sensing,pumpingopticalparametricoscillator/opticalparametricamplifier(OPO/OPA)foramid-InfraredLIDARsource.
• CoherentLIDARcomponenttechnologyforaviation-safetysensor,e.g.windshear/turbulence,wake-vortexhazard,etc.
Non-NASA Applications• Highbandwidthlow-Earth-orbit/geostationary-Earth-Orbit(LEO/GEO)
satellitecommunicationforthemilitary• Highbandwidthreal-timefeedfrommultipleunmannedaerialvehicles
(UAVs),viaLEO/GEOcrosslinks• HighbandwidthGEOcrosslinksforcommercialsatcom• In-flightwindsensor,toaidprecisiondroppingofsuppliesinwarzone.
—23——23—
high-EFFiCiENCY rEsoNANTlY pumpED 1550-nm FiBEr-BAsED lAsEr TrANsmiTTEr
nLightPhotonics
2012PhaseIH9.01-8264
Identification and Significance of Innovation
Thereisaconsiderableinterestindevelopingfiber-basedlasertransmittersatthe1.5umwavelengthforfree-spaceopticalcommuni-cations.Atthiswavelengthrange,theatmo-sphere is largely transparent. Also, reliablecommercial off-the-shelf components foropticalpulsegenerationandcontrol,aswellas mature, high-performance detectors arereadilyavailable.Tomeetthehighwall-plugefficiency requirement of laser transmittersin space communication, nLight proposeshigh-efficiency, high-average power 1550-nmlasertransmittersystemthatisbasedonEr-dopedfiber amplifier resonantly pumpedby high efficiency 1532-nm fiber-coupleddiode laser pumps. The overall efficiencyis improved by (1) optimizing diode laserand fiber coupling for maximum efficiencyof1532-nmpumps, (2)developingresonantpumpingof thefiberamplifier forminimumquantumdefect,and(3)designanddevelop-mentofEr-dopedfiberamplifier capableofachievinghighoptical-to-opticalefficiency.
EstimatedTechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 3
• 4
Technical Objectives
UndertheproposedPhaseIprogram,nLightwilldesignanddemonstratehigh-efficiency1532-nmsingleemitterdiodelasersthatmeetthespecifiedpowerandefficiencyobjective.nLightwilldesign,fabricate,test,anddelivertoNASA(orarecipientoftheirchoosing)two15-W(rated)conductivelycooleddiodelaserpumpmodules,coupledtoa105-umcore,0.22-NAfiber,with>32%wall-plugefficiency.ThemodulesarebasedonnLight’sPearlplatform.ThiseffortwillrepresenttheconfluenceofmultipletechnologiesinwhichnLighthasdeepexperience,makingnLightwell-positionedtomeetthespecificationssetforthinthesolicitation.Ifsuccessful,nLightwillproposeaPhaseIIcontinuationoftheprogramtofurtherimprovethepowerandefficiencyofthe1532-nmpumpmoduleto>20Wand40%,respectively.DuringthePhaseIprogram,nLightwillperformmodelingandassessmentoneye-safefiberamplifierarchitecturessuitableasalasertransmitterforspacecommunication,anddevelopinPhaseIIahigh-efficiency1550-nm-fiberlasertransmitterbasedonresonantlypumpedEr-dopedfiberamplifiersystem,demonstrating>23Waveragepowerand>23%wall-plugefficiency.
NASA Applications
ApotentialNASAapplicationoftheproposedfiber-basedmasteroscillatorpoweramplifiersat1550nmislasertransmittersthatmeettheefficiency,powerandmodulationrequirementofdeepspaceopticalcommunication.Inaddition,suchsystemcanprovideprecisionrangeandvelocitytrackingforspacecraftnavigation,andcanalsobeusedindirectenergydetectionLightDetectionandRanging(LIDAR)systemsforatmosphericresearchandmeteorology.
Non-NASA Applications
Commercialapplicationsmaybeinmaterialsprocessingwheretheeye-safewavelengthandhighpeakpowercapabilityofthefibersdevelopedmayprovideanadvantageintermsofapplicationspeedorquality.Itisexpectedthatthesehighaveragepower,highpulseenergyeye-safefiberlaserswillbeusefulinmaterialsprocessing,biomedical,andotherlightindustrialapplications.
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A miNiATurE poiNTiNg AND TrACkiNg isolATioN plATForm
AmericanGNCCorporation
2012PhaseIH9.01-8425
Identification and Significance of Innovation
Inertial stabilization and relative attitudecontrolarethetwokeyelementsconstitut-ingtheproposedaccuratepointingcontrol.Inertial stabilization allows isolation frominterferenceandvibration.Relativeattitudecontrol is used for target tracking and tocompensate pointing drift caused by gyrodrift and the Earth’s rotation. The point-ing and tracking platform is an inertiallycontrolled/stabilized compact, light weight,low power, broad bandwidth disturbancerejection and/or isolation platform. Theoperation of the laser designator requiresstableandaccurate line-of-sightalignmentandstabilizationforthebeamline.Theaccu-ratepointingandattitude/orientationcontrolisrealizedbytwoparts:inertialstabilization/controlandrelativeattitude/orientationcon-trol.Theformeristhebasisfortheaccurateattitude/orientationcontrolthatisolatestheinterferenceandvibrationofthevehicle.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract• 3• 4
Technical Objectives
Theobjectiveofthisprojectistodemonstratethefeasibilityofaminiature,microelectromechanicalsystems(MEMS)intertialmeasurementunit(IMU)based,accuratealignmentandstabilizationsystemforbeampointingofalaserdesignator.InPhaseIofthisproject,first,usingthesimulationtoolsandexperimentalsystemsofAmericanGNCCorporation,modelingandimplementationevaluationoftheproposedMEMS-basedinertialpointingsystemareperformed.Throughthemodelingandsimulationoftheclosed-loopsystem,theimplementationmethodandthespecificationoftheMEMSdevicesandpointingsystemwillbefurtherinvestigated.Then,aninertialmotionmeasurementdevicetestandtuningareperformed.MEMSgyrosforpointingstabilizationareintegratedintotheplatformstructure.Next,systemintegrationoftheMEMSstabilizationplatformisinvestigated.Anaccuracyevaluationofthepointingstabilizationsystemisperformed.Finally,themechanicalstructureofthestabilizationplatformandtheintegrationoftheMEMSwiththesystem’smechanicalandelectroniccomponentsisproposedandinvestigated.
NASA Applications
Thisstabilizationpointingandtrackingisolationplatformisofsmallsize,lightweight,lowpower,faststeering,andreducescostindesignandproduction.Itfindswideapplicationsinspacebornevehiclesforlargetelescopestabilizationcontrol,opticalcommunications,antennapointing,telescopestabilization,laserpointingandcontrol,andvehicleguidance.
Non-NASA Applications
Itspropertiesofsmallsize,lowcost,lightweightandbroadbandwidthdisturbancerejectionallowsitsutilizationinmanycommercialapplicationsincludingpointingcontrol,motion,andvibrationisolation.Specificexamplesincludetargetdesignation,stabilizationcontrol,opticalpointing,andlaserandtelescopepointingcontrol.
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ViBrATioN isolATioN plATForm loNg-rANgE opTiCAl CommuNiCATioNs
ControlledDynamics,Inc.
2012PhaseIH9.01-9372
Identification and Significance of Innovation
Optical communication links provide higherdatatransferrateswith lowermass,power,andvolumethanconventionalradiofrequencylinks. For deep space applications at longoperational ranges, high performance sta-bilization of the space terminal data link isrequired.Tomeet this need, ControlledDy-namics,Inc.,proposesanovelapplicationofour free-floating isolation platform. Basedupon a shuttle-proven technology, this ap-proach yields 6 degrees of freedom (DOF)isolation from the disturbances of the hostvehiclewhile providing high-bandwidth ac-tive stabilization to attenuate both payloaddisturbances as well as any residual dis-turbances transferred fromthebaseacrossthepower/dataumbilical.Theproposedap-proachisdesignedtoachievebetterthan0.5microradian-rmsstabilizationforallfrequen-ciesabove0.1Hzwhenoperatinginaspaceenvironment.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 3
• 5
Technical Objectives
PhaseIdevelopstheproposeddesignconcept,performsarchitecturetradestudies,andpredictsperformancetoestablishthefeasibilityoftheapproach.Usinganavailablefree-floatingisolationplatformandatwo-axislow-gtestbed,thedesignconceptisprototypedanddemonstratedonhardwareinasimulatedlow-genvironmenttechnologyreadinesslevelof5(TRL–5).
PhaseIIproceedswiththedevelopmentofaprototypesystemthatwillbespacequalifiedthroughcomprehensivegroundtesting(TRL–6).TechnologydemonstrationflighttestswillbeproposedonsRLVsand/orInternationalSpaceStation(ISS)platforms(e.g.,WORFandOPALSupgrade),achievingaTRL–7maturitybytheendofPhaseII.
NASA Applications
• DeepSpacePlanetaryMissions• DeepSpaceOpticalTerminal(DOT)Project• SpaceCommunicationsandNavigation(SCaN)Program• LaserCommunicationsRelayDemonstration(LCRD)Mission• OpticalPayloadforLAsercommScience(OPALS)upgrade
Non-NASA Applications
Byprovidingcomponent-levelisolationandstabilizationattheopticalpayload,thisapproachdoesnotimposeanyunusualconstraintsonthehostvehicle.ThismakesthetechnologybroadlyapplicabletoawiderangeofvehiclesincludingsRLVs,orbitalRLVs,Earth-orbitingsatellites(eventhesimplestthruster-onlydesigns),anddeepspacevehicles.
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CompACT, lighTwEighT isolATioN plATForm (Clip)
AppliedTechnologyAssociates
2012PhaseIH9.01-9621
Identification and Significance of Innovation
NASA has a critical need for improved bi-directional data transmission rates from avariety of spacecraft to Earth. NASA esti-matesthatthecurrentMarstoEarthtrans-ferrateof6Mbpsmightbeincreasedto600Mbpsusingalasercommunicationsystem.Beam jitter caused by spacecraft-basedmotionmustbereducedtosubmicroradianlevels to enable beaconless optical beampointing.ATAwillcreateaCLIPthatwillhostthe laser communication (LC) collimatortelescopeandprovideastabilizedplatformto prevent the 150-microradian spacecraftdisturbance environment from reachingthe LC terminal. To enable that stabiliza-tion,ATAwill develop an ultra-low angularnoiseCAPS.Theproposedsensorwillhavelowpowerandhighreliability,whichATAwilldemonstratebyproducingTRL4prototypesinPhaseI. ATAwilldeveloptheCLIP,a0.5microradianresidualmotionstableplatform,inPhaseIIforprogramslikeiROC.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract• 3• 4
Technical Objectives
• DeveloptheCapacitiveAngularPositionSensor(CAPS).• DevelopdesignconceptforCompact,LightweightIsolationPlatform
(CLIP)withCAPS.
Thegoalistoproduceastableplatformattechnologyreadinesslevel(TRL)4tohostlasercommunicationpayloadsbyreducingspacecraftjitterto0.5micro-rad.PhaseIIwillbuild(CLIP)engineeringdevelopmentunit(EDU)tosupportlong-rangeopticalcommunicationsforspace.
WorkPlan• DesignandcharacterizeprototypehardwarefortheCAPSusingap-
pliedtechnologyassociates(ATA’s)newinnovativecapacitivesensingtechnology.TheCAPSwillprovidebasemotionmeasurementsimilartoworld-classgyros,butforsmallersize,weight,andpower.
• Gatherrequirements,developsystemarchitecture,andperformancemodelsfortheCLIP.
• SpecifydesignconceptanddevelopplanforbuildingaCLIPEDUforaPhaseIIproof-of-conceptdemonstration.
NASA Applications
ATA-developedCLIPconceptisthebasisforNASA’slasercommunicationterminalfortheLLCDandLCRDprograms.ATA’sproposedCLIPandCAPSmaysupportNASAintegratedRadioandOpticalCommunications(iROC)project’slasercollimator.
Non-NASA Applications
AirForce’sSpaceLaserCommunicationTerminal(SLCT),DARPA’sLaserWeaponSystemModule(LWSM),LockheedMartin’sSpaceOpticalTracking(SpOT),Navy’sLaserWeaponSystem(LaWS),andMarine’sGroundBasedAirDefense(GBAD).
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lArgE opTiCAl TElEsCopE BAsED oN high-EFFiCiENCY ThiN-Film plANAr DiFFrACTiVE opTiCs
BEAMEngineeringforAdvancedMeasurements
2014PhaseIH9.02-8530
Identification and Significance of Innovation
• Apply diffractive optics to the designof the optical telescope, a part of theGround-BasedTelescopeAssembly.
• Useofdiffractiveopticswillallowdras-tic optical telescope cost and weightreductions.
• Costreductionisduetotheeliminationof tightly toleranced reflective opticsusedinconventionaltelescopes.
• Weightreductionisduetoreplacementoftightlytoleranced,massivereflectiveopticswith looselytoleranced, thindif-fractiveoptics.
• Additional indirect cost reduction ofpointingsystemduetoreducedweightoftelescopestructure.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract• 5• 7
Technical Objectives
• Subscalediffractiveopticalelementswillbedesigned,fabricated,andtestedinPhaseI.
• Intermediateobjectiveistodevelopmethodsforpreciseandaccuratewritingofgratingpatternonlargeaperturediffractiveopticalelements.
• Testingwilladdresscriticalperformanceparametersrelatedtotop-leveltelescoperequirements.
• Opticalresolutiontestingonsubscalediffractiveelementswillvalidatedesignconceptforachieving<20micro-radspotsizewithfull-scaleelements.
• Testingoftheamplitudesofscatteringandparasiticdiffractionwillvalidatedesignconceptforachievingoperationascloseas5degreesfromtheSun.
NASA Applications
• MajorapplicationistotheGround-BasedTelescopeAssemblyfordeep-spaceopticalcommunications
• AlsoapplicabletootherfutureNASAlasercommunicationsprograms
• Possibleapplicationtotheflightlasertransceiverofdeepspaceopticalcommunicationssystems
Non-NASA Applications
• Fabricationmethodstobedevelopedonthisprogramareapplicabletocommerciallasercommunicationstransmittersandreceivers
• PossibleDepartmentofDefense(DoD)applicationsincludelaserrangefinders,lasertargetmarkers,andlaserdesignators
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high CouNT rATE siNglE-phoToN CouNTiNg DETECTor ArrAY
Voxtel,Inc.
2014PhaseIH9.01-8912
Identification and Significance of Innovation
Anopticalcommunicationsreceiverrequiresefficient and high-rate photon-countingcapability so that the information fromevery photon, received at the aperture, isprocessed.Thisisparticularlytrueinspaceplatforms,wherethe informationcontainedineveryadditionalphotondetecteddirectlytranslates into lower system size, weightandpower (SWAP).Toaddress thisneed,anear-infrared (NIR) high-gain, low-excessnoiseAPDarraywillbedevelopedforphotoncountingflightreceivers.
The proposed APD array technology iscapable of a single photon detectionefficiency (SPDE) greater than 50% at 100Mhzcountrate.Itwillbeshownpossibletodiscriminate photo-generated events fromdark-initiatedevents,sothatwhentheAPDis configuredwitha lownoise readout cir-cuit,withsufficientbandwidthdetectioncir-cuits, that lowfalsealarmrates(FARs)canbeachieved.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 3• 4
Technical Objectives
• Usingnumericalmodels,optimizeavalanchephotodiode(APD)epitaxiallayers.
• GrowtheAPDepitaxialmaterial.• FabricateAPDdetectorarraysandtesttheirperformance.• PrepareaGHz-ratereadoutintegratedcircuit(ROIC)fortestingand
characterizetheSCMAPD.
WorkPlan• UsingMonteCarloanalysis,theAPDdesignwillbeoptimized.
Simulationswillshowahighprobabilityofphotondetectionat10sMhzcountrates.
• Candidatedevicedesignswillbeepitaxiallygrown,andaseriesofsingle-elementandsmallsizearrayswillbefabricatedandtested.Amulti-GHzROIC,withsamplingcircuits,willbepreparedtotestandevaluatetheAPD.
Tasks• Performsystemengineering.• Optimizehigh-gainAPDepitaxialstructures.• OptimizeAPDarchitecture,fabrication,andprocessing.• PrepareVX–805bROICfortestinganddemonstratingAPD.
NASA Applications
NASAapplicationsfortheinnovationincludeopticalcommunications,LaserDetectionandRanging(LADAR)basedautonomousnavigationandlandingsystems,three-dimensional(3D)imagingfordockingsystems,andlaserranging.
Non-NASA Applications
Militaryapplicationsincludelaserrangefinding,LADARimagingandautonomousnavigation.Commercialapplicationsincludeautomobiledriverassistancesystemsandcollisionavoidancesystems.
A high gain APD is proposed, which hasextremely low excess noise during thedecision event of the optical receiver.
Using time-over-threshold photo-eventsare discriminated from dark events
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high-EFFiCiENCY AND powEr lAsEr TrANsmiTTEr For DEEp spACE CommuNiCATioNs
FreedomPhotonicsLLC
2014PhaseIO9.02-8941
Identification and Significance of Innovation
WeproposeaninnovativeresonantlypumpedEr-based1550-nmlasertransmittersuitablefor PPM for deep space communications.ResonantlypumpedErlasersprovideforhighopticalconversionefficiency,whichcoupledwith high-efficiency pumping using highlyefficientdiodepumplasersat1480nmcanlead tounprecedentedwallplugefficienciesfortheselasers.
We will use a novel diode laser pumped,actively Q-switched solid-state laser archi-tecture.Ouruniqueapproach, of optimizingthediodepumplaserdesigntotheErcavitydesign,willallowustoextractmaximumeffi-ciencyfromthesystem(greater>25%).Thisisauniquelaser,notavailableonthemarket.Usingourminiaturecommunicationsmodulebackground and commercial products, weintend to integrate this solution in a mini-mumfootprintpossible,minimizingthesize,weightandpower(SWaP)andlaunchcosts.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 3
• 6
Technical Objectives
TheoveralltechnicalobjectiveforthisPhaseIeffortistoperformcriticaldesignstudies,simulations,andkeyexperimentalevaluationtoprovethefeasibilityoftheapproachforgeneratingaradiationhardPhaseIIprototypepulse-position-modulation(PPM)transmitterdesignwithrobustpackaging,whichmeetsthefollowingperformancetargets:• Wavelength:1550nm• Spectralbandwidth:Transform-limited• Optical-to-opticalefficiency:>70%• Pulsewidth:0.2to16ns• Averageoutputpower:20W• Totalwallplugefficiency:>25%• Totalmass:<5kg
WorkPlan• Task1:Epitaxialdesignandgrowthof1480-nmpumplasermaterial• Task2:High-efficiency1480-nmpumplaserfabricationandtesting• Task3:Er-dopedglassQ-switchedlaserdesignandbenchtop
demonstration• Task4:PhaseIIPPMtransmitterdesignandlayoutThedeliverablesofthePhaseIprogramwillbeprogressreportsandacriticalhardwaredemonstration
NASA ApplicationsThefirstplannedproductforthePPMopticaltransmittertechnologytobedevelopedinthisprogramisalong-rangeFreeSpaceOptics(FSO)linkforInterplanetaryOpticalTelecommunicationssupportingroboticexplorers.ThesecondplannedproductswillbeFSOlinksforNASAsatellite-to-groundapplicationsaswellasintersatellitecommunications.Subsequentproductswillbeforair-to-ground,air-to-air,andground-togroundcommunications.
Non-NASA ApplicationsCommerciallasercommlinks—bothintersatellite,andterrestrial.Air-to-airandair-to-groundapplicationsintheUnmannedAerialVehiclesapplications.
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Identification and Significance of Innovation
A pulse shaping and spectral shaping 20W high-efficiency (>25%) short pulse fiberlaserisintroducedforthefirsttimetomeetthe needs of deep space communications.Theinnovationsare• Pulse shaping technique to obtain >45
dB extinction ratio shaped pulses with<35psrise/falltime
• Spectral shaping technique to obtaintransform limited spectrum and highopticalsignaltoratio(OSNR).
• Pulseshapingtechniquetomitigatenon-linear effects such as stimulated Bril-louinscattering(SBS).
• State-of-the-artfiberamplifier,electron-ics,andthermalmanagementtechniqueto achieve compact 20-W fiber laseroriginal equipmentmanufacturer (OEM)modulewith>25%wallplugefficiency.
PolarOnyx has been leading both the R&Dandcommercialproductionintheworld.Wehave recently commercialized the highestenergy (0.5 mJ) fs fiber laser product andwon2014PrismAwardFinalist(categoryofindustrial lasers).Weareconfident that theproposedshortpulsefiber laserwillbeac-complished in both scientific breakthroughandcommercialization.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 3• 6
Technical Objectives
• Studyandapplythepulseshapingtechniquetoachieveshortpulseoperationwiththerequiredwaveformat(<35psrise/falltime).Incooperatingwithourpulseshapingtechnologyandsuccessfulexperienceindevelopinghighefficiencyandhighpowershortpulsefiberlasers,aproof-of-conceptdemonstrationfora10-Wfiberlaserwillbegiven.
• Investigatepulseinteractionwithnonlinearmediaandpulse/spectralshapingeffectsoftheproposedshortpulsefiberlaser.DesignandselectFBGandEYDFtoachievehigherpowerconversionefficiency,mitigatenonlineareffects,andcorrectpulsedistortionandmodulationchirp.
• Investigatehigh-speedelectronicsforprocessingandsynchronization,protocolinterfaces,andradiofrequencysignalgenerationforthemodulator.Designradiationhardnesselectronicsforbothhigh-speedelectronicsandhigh-powerdiodedrivers.
NASA Applications
InadditiontoNASA’sdeepspacecommunications,theproposedshortpulsehigh-powerfiberlaserapproachcanalsobeusedinotherapplications,suchasspace,aircraft,andsatelliteapplicationsofLaserDetectionandRanging(LADAR)systemsandcommunications.PolarOnyxwilldevelopaseriesofproductstomeetvariousrequirementsforNASA/militarydeployments.
Non-NASA Applications
High-powerfiberlasersrepresentthenextgenerationofcriticalopticalcomponentsneededtobuildthecoherentopticalcommunicationsofthefutureandcableTVsthatwilldeliverincreasedcommunicationbandwidthandimprovedQualityofService(QoS)endusers.Themarketfortheapplicationisgrowingandwillbeofgreatpotentialofhundredsofmillionsmarket.
20-w high-EFFiCiENCY 1550-nm pulsED FiBEr lAsEr
PolarOnyx,Inc.
2014PhaseIH9.02-9962
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optical communication technology
SBir phaSe ii awardS2005 to 2012
Optical Module for Space
—32——32—
ADVANCED AuTomATED DEBris TrACkiNg AND rECogNiTioN sYsTEm
OPTRA,Inc.
2005PhaseIIO2.01-7854
Identification and Significance of Innovation
Thisprogramconcernsthedevelopmentofadigital imagingand tracking capabilitywithtwoprimarygoals:(1)toprovidethemeansfortrackingandpredictingthetrajectoriesofmultiple objects following the breakup of alaunchedspacevehicleand(2)toprovideameansforidentifyingsuchobjectsbyshapeand3Dsizeparameters.
Providingadetailedreportthatdetailsshape,size, and ground impact positions for eachpiece of a debris cloud minutes after thefailureoccurssignificantlyincreasesNASA’scurrent capabilities during search andrecovery efforts following a launch failure.Theinnovationliesbothintheuseofastate-of-the-artopticalsystemtocarryoutataskpreviously performed by radar and in thetrackingand identificationalgorithmsbeingdeveloped.
Technical Objectives
ThegoalofthePhaseIIeffortistocontinuethedevelopmentofthedetection,tracking,andidentificationalgorithms,designandbuildaprototypesystemutilizingcommercial-off-the-shelf(COTS)components,andtestthesystemwithrepresentativescenarios.
• Review/refine/improveeachstepinthecurrentalgorithmicprocessfordetection,tracking,andidentification.
• DevelopandbuildacompletesystemarchitectureusingCOTScomponent.
• Fusedatafromtwoorsensortoproducethree-dimensional(3D)objecttrajectoriesandgroundimpactpointsinGPScoordinates.
• FieldtestthesystematOPTRAandatNASA.
NASA and Non-NASA Applications
ThisprogramhasaclearandimmediateNASAapplication:toestablish3Dtrajectoryandshape/sizeinformationforsearchandrecoveryeffortsfollowingalaunchfailure.
ThesystemisapplicabletoDepartmentofDefense(DoD)inweaponstestingapplicationsandtotheDoDandcommercialaircraftmanufacturersformonitoringtestflightsofmannedandunmannedaircraft.
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VErY lArgE solAr rEJECTioN FilTEr For lAsEr CommuNiCATioN
SurfaceOpticsCorporation
2007PhaseIIO1.08-8373
Identification and Significance of Innovation
Surface Optics Corporation will developa band-pass filter comprising a visibledielectricmirrorandaninducedtransmissionfilter,appliedtotwosidesofacastpolyimidemembrane.Themirror/filtercombinationwillblock 95% of the incident solar radiation,whileallowinganarrowpass-bandforlasercommunication.
Expectedtechnologyreadinesslevel(TRL)attheendofPhaseIcontract
• 6
Technical Objectives
• Fabricate2-mfilterwithgoodcoatingadhesionatallpositionsoncoatedsurface.
• Developn,kdataforselectedmaterialsoutto1.1-meterradius.• Gainfundamentalunderstandingoftheeffectofionizedgason
coatingadhesiontothepolymermembrane.• Buildandtestcoatingdesignsonsubscalemembranes.• Applymultilayerdesignto2-metersubstrates.
NASA and Non-NASA Applications
• Long-rangelasercommunications;interplanetarymissions
• Solarcoverforlasercommunicationreceiverondefensesatellite
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high-BANDwiDTh phoToN-CouNTiNg DETECTors wiTh ENhANCED NEAr-iNFrArED rEspoNsE
aPeak,Inc.
2008PhaseIIO1.06-9563
Identification and Significance of Innovation
Newest designs in long-range opticalcommunication systems require high-gain,photon-counting arrays operated with highdetection efficiency, outstanding temporalresolution, and capability to handle highphotondetectionrates.Weproposetodevelopa novel large area, silicon photon-countingdetectorarrayinnearinfrared,operatedwithmoderate cooling, high detection efficiency,high saturation counting rate, and capableof 500 ps timing resolution. Detector andreadout circuit design will be improved tomeet the detection efficiency, noise, timingresolution,and linearity requirementsof theapplication.
Expectedtechnologyreadinesslevel(TRL)attheendofthecontract
• 4
Technical Objectives
• Developmentoftheintegratedelectronicstoperformcounting,afterpulsingcontrolandhigh-resolutionfunctionsanddataoutcontrol
• Developmentofthehardwareandtuningproceduresofthecavityresonanceatthetargetwavelength(1050,1060,or1064nmasperinputfromJPL)
• SeamlessprocessintegrationofDBR,flip-chipstepsintotheprocessflow
• RC–GPDarraydesign,fabrication,andqualification
WorkPlan• Task1:Readoutintegratedcircuit(ROIC)arraydesignandsimulation• Task2:RC–GPDarraydesignandsimulation• Task3:Arrayfabricationplan
NASA and Non-NASA Applications
Thenovelphotoncountingarraywillfindapplicationinfreespaceopticalcommunications,space-groundopticallinks,detectionorimaginginmediawithhighturbidity,interferometry,mapping,roboticvision,veryhigh-resolutionthree-dimensional(3D)imaging,hyperspectralimaging,andspacedocking.Inadditiontolong-rangeopticalcommunications,largerarrayscouldbefabricatedforsingle-photonimagingintheinfraredandvisiblewithapplicationstosecuritycameras,imagingofnoncooperativetargets,single-moleculedetection,integrationintomicrofluidicdevices,biochipsforbiomedicalapplications,fluorescencecorrelationspectroscopy,etc.
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high-EFFiCiENCY, high-powEr lAsEr TrANsmiTTEr For DEEp spACE CommuNiCATioN
VegaWaveSystems,Inc.
2008PhaseIIO1.06-9602
Identification and Significance of Innovation
We propose improvements to fiber MOPAtransmittersfordeepspacecommunicationslinksusingseveralnewtechniques:
• Operating wavelength of 1560 nm re-duces thesizeandweightof theopticalcomponents
• Resonant pumping in the 1430-to 1530-nmbandimprovespumpabsorptionand,hence,wallplugefficiency
• Wavelength-stabilized laser (WSL) pumpsources: eliminates power-hungry ther-moelectric (TE)coolers,producingasig-nificant improvement in wall plug effi-ciency
• PhotonicCrystalFiberamplifiersimprovetheefficiencyofthesystem
Expectedtechnologyreadinesslevel(TRL)attheendofthecontract
• 4
Technical Objectives
• Design,fabricate,andcharacterizeawavelength-stabilizedpumpsourceforresonantpumpinginthe1430to1530nmEr+-dopedabsorptionband
• DesignandfabricateanEr+-dopedMasterOscillatorPowerAmplifier(MOPA)toachieve1kWpeakpulsepower
WorkPlan• Wavelength-stabilizedpumplasers• Design,fabricate,andcharacterizepumpsourceforresonantpumping
inthe1430to1530nmrangeusingproprietarytechnology• FabricatetheEr+-dopedMOPAtoachieve1kWpeakpulsepowerat
1560nm.
NASA Applications
High-speed,high-powerpulsepositionmodulationopticalcommunicationslinksfordeepspaceapplications
Non-NASA Applications
• Eyesafepulsedfiber-laser-basedsourcesformaterialprocessingandotherscientificapplications
• Highpowerwavelength-stabilizedpumpsourcesatlongwavelengths
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high-powEr upliNk AmpliFiEr For DEEp spACE CommuNiCATioN
OpticalEngines,Inc.
2009PhaseIIO1.06-8122
Identification and Significance of Innovation
We propose improvements to fiberMaster Oscillator Power Amplifier (MOPA)uplink power amplifiers for deep spacecommunications links using several newtechniques:• 2.5-kWmulti-fibercoupledlaserdiode
stack technology adapted to pumpingfiberlasersandamplifiers
• Efficient Etched Air Taper Combinersallow for integration of high pumppowers into fiber based amplifiers andLasers
• PCFamplifiersprovidehighpeakpoweroperation while also providing for highaveragepoweroperation
• Ahybridamplificationsystemthatusesbothcoiledandrod-typePCFs
Expectedtechnologyreadinesslevel(TRL)attheendofthecontract
• 4
Technical Objectives
• Design,fabricate,andcharacterizeacoiledandrod-typephotoniccrystalfiber(PCF)amplifierandcompareitsperformancetorequirements.
• Fromtheresultsobtainedfrombothamplifiers,design,fabricate,characterize,anddeliveranuplinktransmitterchannelthatmeetsorexceedsthecurrentrequirementsforintegrationintoexistingNASAuplinktestbedinfrastructure.
WorkPlan
• Designhighpeakpowerfiberamplifiers
• Design,fabricate,andcharacterizebothacoiledandrod-typePCF-basedamplifierandcompareunderworstcaseoperationalscenarios
• Fabricateanddeliveranuplinktransmittermeetingthecurrentproposedrequirements
NASA Applications
High-speed,high-powerpulsepositionmodulationopticalcommunicationslinksfordeepspaceapplicationsLightDetectionandRanging(LIDAR)andremotesensingapplications.
Non-NASA Applications
• Pulsedfiber-laser-basedsourcesformaterialprocessingandotherscientificapplications
• Directedenergyapplications
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high-pErFormANCE NEgATiVE-FEEDBACk NEAr-iNFrArED (Nir) siNglE-phoToN CouNTiNg DETECTors AND ArrAYs
AmplificationTechnologies,Inc.
2009PhaseIIO1.06-8219
Identification and Significance of Innovation
New photon-counting photodetectors andarrays are proposed to advance the stateof the art in long-range space opticalcommunications. The proposed detectoroperatesat1000nmto1600nmwavelengthsand have high detection efficiency, lowjitter, high bandwidth, very high internalgain, and extremely low excess noise. Thedetectordesignwillbebasedontheinventedbreakthrough technology of discreteamplification. The new detector enablesmeeting the goals of long-range spaceopticalcommunicationapplications.
Technical Objectives
• DeveloptheinternaldiscreteamplificationdesigninInGaAs/InPmaterialsystemtoachievestatedgoals.
• Developthedesignofthedetectorarraythatmeetsorexceedsthedesiredperformancecharacteristics.
• Developfabricationprocessesforthefabricationoftheinternaldiscreteamplifierdetectorsandarrays.
• Fabricate,test,andanalyzetheresultsofthefabricateddevices.• DeliverfullyfunctionalInGaAs/InP-basedphotodetectorsandarrays
withinternaldiscreteamplificationtoNASAattheonclusionofPhaseII.
NASA and Non-NASA Applications
• Long-rangespace-to-groundcommunicationlinks
• Intersatellitelinks
• Earthorbitingtogroundopticalcommunication
• Quantumcryptography
• Three-dimensional(3D)imaging
• Nightvision
NASA and Non-NASA Applications
• Opticalcommunication
• LightDetectionandRanging/LaserDetectionandRanging(LIDAR/LADAR)remotesensing
—38——38—
Identification and Significance of Innovation
We propose to develop large-format128 x 128 single-photon counting detectorarrayssuitablefordeploymentinspacecraftterminal receivers supporting long-rangelaser communications. We will leverageinitial success in monolithically integrating“negative feedback” elements with state-of-the-art single-photon avalanche diodesto realize large-scaleNFADarrays inwhicharray pixels have good detection efficiency,low dark count rate, low afterpulsing, lowtiming jitter, and high counting rate. SinceNFADsself-quenchandself-arm,theycanbeimplementedwithgreatlysimplifiedbackendcircuitryandenablesingle-photonsensitivefocalplanearrayswithvastlyreducedsingle-photonsensitivefocalplanearrayswithvastlyreduced complexity relative to the state-of-the-art. NFAD arrays have significantpromiseforenablingspace-qualifiablefocalplanearraysthatserveapplicationsrequiring1.5µmsinglephotondetection.
Expectedtechnologyreadinesslevels(TRLs)atstartandendofcontract• 2• 4
Technical Objectives
• Optimizepixel-levelNFADdesign.• Implementoptimizedpixel-levelNFADsintolarge-formatarrays.• Developcharacterizationcapabilityfortestinglarge-formatNFAD
arrays(i.e.,128x128x100μmpitch).
WorkPlan• NFADwaferepitaxialdesignandfabrication• NFAD32x32array-leveldesignandphotomaskfabrication• NFAD32x32arraywaferprocessingandwafer-leveltesting• Designoffan-outboardtestplatform• Testelectronicsdevelopment,includingFPGAandtestcode• NFAD32x32arrayprototypecharacterization• SeconditerationofA.1toA.6for128x128NFADformat• SummarizeresultsanddefineinputsforfullFPAdevelopment
NASA Applications
• Free-spaceopticalcommunications,includingspace-basedlasercommunicationslinks
• ActiveremotesensingopticalinstrumentsLightDetectionandRanging(LIDAR)
Non-NASA Applications
• Range-findingandLADARapplications• CommercialLaserDetectionandRanging(LADAR)systems• Freespaceoptical(satellite)communications• Singlephotoncountingforfluorescence,photoluminescence,and
photoemissionapplications
NEgATiVE FEEDBACk AVAlANChE DioDE (NFAD) ArrAYs For siNglE- phoToN opTiCAl CommuNiCATioNs AT 1.5 mm
PrincetonLightwave,Inc.
2009PhaseIIO1.06-9687
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Identification and Significance of Innovation
Laser beacons with scalable powers areneeded for ground to deep space opticalcommunication uplinks. They serve asabsolutereferencefortrackingofspacecraftduringthedownlinklasercommunication.Forsuchspacecommunicationlinkdistancesthebeamspreadduetodiffractionissignificantenough thatonly fewphotonsarecollectedby a moderate size optical telescopes onthe spacecraft. This necessitates photon-counting detectors suited for the spaceenvironment,alongwithincreasingtheoutputpower of the laser beacon. Ultralow noisesilicon avalanche photodetector (Si-APD)based position-sensing detectors are usedonthespacecrafttodetectthelaserbeacons.Such Si-APDs are also radiation-hardenedand compatible with space-environmentoperation.Itisthereforedesirabletooperateatshorterwavelengths~1000nm,whereSi-APDs have improved spectral responsivity.Thishelps to improve theSNR for tracking,and consequently reduce the uplink laserpowerrequirements.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 3
• 5
Technical Objectives
• High-efficiencyYb-fiberamplifiersofPavg~500W,withhighspectralresponsivitySi-APDphoton-countingdetectors
• Fibermaster-oscillatorpower-amplifier(fiberMOPA)design,withtailoredspectralandtemporalcharacteristicsofnear-diffractionlimitedbeam-quality(M2<1.5)
• Widerangerepetition-ratesandpulse-pattern/formatscapability,likethetwo-levelnestedpulsepositionmodulation(PPM)desiredforanuplinklaserbeacon.
• DesignisaidedbycomprehensivefiberMOPAsimulationtool,robust“all-fiberoptic”design,withnolaseralignmentrequirements
• Operatewithelectro-opticpowerefficiency(estimated>25%).Modulararchitecturescalabletoatemporallysynchronized,multi-apertureconfiguration
WorkPlan
• Reconfigurepoweramplifierfromafree-spacesignalcoupledtoanall-fiberform,leadingtoanall-fiberimplementationofthelaserchannel
• Averageandpeakpowerat1030-nmto500Wunder500kHzPPM-16aryoperation
• Improvemultistageseedamplifierchain
• Design,build,test,anddeliverprototypehardware
NASA Applications• Compacthigh-efficiency1030-nmlasertransmitterfordeep-space
communication
• Lowpoweruplinklaserbeaconsfornear-Earthopticalcommunicationlinks,or,smallerapertureopticaltelescopes(~30-cm)toenablehigh-bandwidthopticallinks
Non-NASA ApplicationsLaserilluminatorfordirected-energy(DE)applications.MDAapplicationsfortargetidentificationanddesignation.
mulTi-kw upliNk FiBEr-lAsEr BEACoN wiTh AgilE sigNAl FormAT
Fibertek,Inc.
2010PhaseIIO1.04-9435
—40——40—
DowNliNk FiBEr lAsEr TrANsmiTTEr For DEEp spACE CommuNiCATioN
Fibertek,Inc.
2011PhaseIIO1.04-9718
Identification and Significance of Innovation
NASA’s Space Communications and Navi-gation (SCaN) roadmap, calls for an inte-grated network approach to communica-tionandnavigationneeds, fromnear-Earthto planetary missions. Laser-based opticalcommunication linksforspaceprovidesanorder ofmagnitude higher data rates thancorrespondingradiofrequencylinks.Inaddi-tion,due tomuchsmallersize,weightandpowerburden to spacecraft, resources areavailabletoenhanceorextendsciencemis-sions.Tremendousprogressmadein1.5umand1-umfiberlaser/amplifiertechnologies,theirpowerscaling,andavailabilityof reli-able high-power components,makes suchtransmitters feasible for spacemission. Inthis Small Business Innovation Research(SBIR)proposal,weproposetodevelop1.5-umfiber-amplifier-basedlasertransmitters,withPav>4W,andcompatiblewithavarietyofM-aryPPMformatsthathaveaclearpathto a space-qualification roadmap. In addi-tion,power-scalingto10W,athermaloper-ationovertemperaturerangeandimprovedpower efficiency are addressed. Limitedscopequalificationtestsarealsoplanned.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 4• 6
Technical ObjectivesProposedprogramobjective:design,build,andtestatechnologyreadinesslevel(TRL)6qualitylaserandconductNASAGEVsvibrationandthermalvacuumtestingtovalidatethedesign.Phase1experimentalresultsdemonstratesthatthelasercomplieswithJetPropulsionLaboratory(JPL)specifiedM-arypulse-position-modulation(PPM)variableformattingwithpeakpowers>640Wover10C-50C.Duetoplanetarylasercomdemonstrationmissionbeingthetargetapplication,thedesignisbasedontheuseofmatureandhigh-reliability1.5-umfiber-opticcomponenttechnologyandafiber-amplifierarchitectureconsistentwithaspacequalificationroadmap.
WorkPlan:• CompleteOpticalDesignTradeStudies:Finalizetheopticaldesignand
improveefficiency.• DesignFlightQualityTransmitterPackage:Acomprehensiveoptical,
thermal,mechanical,electricaldesign.• MissionAssurance:Continuereliabilityassessmentsandopticalparts
ImprovementsfromphaseITVACtestparts.• Fabricateaflight-likeprototype.Afull-scalelasertransmitterwillbebuilt
andperformancetested.• TRL6Testing:Thelaserwillbevibrationandthermalvacuumtestedto
NASAGEVslevels.
NASA ApplicationsHighbandwidthlasercomflightterminalforplanetarymissions,aswellasforlunarandMarsrelaylinks.• Space-qualifiable,robust,compact,andefficientLightDetection
andRanging(LIDAR)component,e.g.,CO2sensing,pumpingopticalparametricoscillator/opticalparametricamplifier(OPO/OPA)foramid-infraredLIDARsource.
• CoherentLIDARcomponenttechnologyforaviation-safetysensor,e.g.,wind-shear/turbulence,wake-vortexhazard,etc.
Non-NASA Applications• High-bandwidthlow-Earth-orbit/geostationary-Earth-Orbit(LEO/GEO)
satellitecommunicationformilitary• High-bandwidthreal-timefeedfrommultipleunmannedaerialvehicles
(UAVs),viaLEO/GEOcrosslinks• High-bandwidthGEOcrosslinksforcommercialsatcom.
—41——41—
Identification and Significance of Innovation
Optical communication links provide higherdata transfer rateswith lowermass, power,andvolumethanconventionalradiofrequencylinks. For deep space applications at longoperational ranges, high-performancestabilization of the space terminal data linkis required. To meet this need, ControlledDynamics Inc., has developed a novelapplication of our free-floating isolationplatform. Based upon a shuttle-proventechnology, this approach yields 6 DOFisolation from the disturbances of the hostvehicle while providing high-bandwidthactive stabilization to attenuate bothpayloaddisturbancesaswellasanyresidualdisturbancestransferredfromthebaseacrossthe power/data umbilical. The proposedapproach isdesignedtoachievebetter than0.5 microradian-rms stabilization for allfrequenciesabove0.1Hzwhenoperating inaspaceenvironment.
Estimatedtechnologyreadinesslevels(TRLs)atbeginningandendofcontract
• 4• 6
Technical Objectives
Compact,LightweightIsolationPlatform(CLIP)conceptwasdevelopedtomeasureandestablishthefeasibilitytomeetspaceterminalisolationrequirements.Sensorandactuatorcomponenttestinghavefurtherdemonstrateddesignattechnologyreadinesslevel(TRL)4.
PhaseIIgoalsaretogroundtestanend-to-endprototypeonasoftsuspensiontestbedtodemonstrateperformanceinasimulatedlow-goperationalenvironment.Bothsearchandbeacontrackwillbedemonstrated.Environmenttestingiterationswillbeperformedtoproducespacequalifiedtwo-axisstrutassembliesfordeliverytoNASA.Three-strutassembliesrigidlymountedtoanyspaceterminalwillprovide6degreesoffreedom(DOF)isolationandhigh-bandwidthstabilization.Thesestrutsaredesignedforrobustnessandcanbeusedasadd-ontoanyrigidstructure,thusenablingabroadrangeofspaceapplicationsrequiringhigh-precisionstabilization,isolation,andpointing.
NASA Applications
• DeepSpacePlanetaryMissions(e.g.,Mars2020)• DeepSpaceOpticalTerminal(DOT)Project• SpaceCommunicationsandNavigation(SCaN)Program• IntegratedRadioandOpticalCommunications(iROC)Project• AlternativeforLaserCommunicationsRelayDemonstration(LCRD)
Mission
• UpgradeforOpticalPayloadforLAsercommScience(OPALS)
Non-NASA Applications
Thetwo-axisisolationstrutstechnologybroadlyisapplicabletoawiderangeofvehiclesincludingorbitalRLVs,Earth-orbitingsatellites,anddeepspacevehicles.
isolATioN plATForm For loNg-rANgE opTiCAl CommuNiCATioNs
ControlledDynamics,Inc.
2012PhaseIIH9.01-9372
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Identification and Significance of Innovation
NASA has a critical need for improvedbidirectional data transmission rates froma variety of spacecraft to Earth. NASAestimates that the current Mars-to-Earthtransfer rateof6Mbpsmightbe increasedto600Mbpsusinga lasercommunication(LC) system. Beam jitter caused byspacecraft-basedmotionmustbereducedtosubmicroradianlevelstoenablebeaconlessoptical beam pointing. ATA will create aCLIP thatwill provide a stabilized platformto prevent the 150-microradian spacecraftdisturbanceenvironment fromreaching theLC terminal. To enable that stabilization,ATAwilldevelopanultra lowangularnoiseCAPS. CAPSwill have low-power and highreliability, which ATA will demonstrate byproducingprototypes inPhase IandaCLIPEDU inPhase II. ATAwilldevelop theCLIP,a 0.5 microradian residual motion stableplatform,forprogramslikeiROC.
Estimated technology readiness levels(TRLs)atbeginningandendofcontract
• 4• 5
Technical Objectives
• Fine-tuneCapacitiveAngularPositionSensor(CAPS)sensorelectronicsandmeasuresensornoise
• IncorporatelessonslearnedfromtheCAPSprototypebuild/testintoanupdatedCAPSdesignforuseontheCompact,LightweightIsolationPlatform(CLIP)
• Design,build,andtesttheimprovedCAPSsensors• Designanengineeringdevelopmentunit(EDU)CLIPplatformthatwill
interfacetoacommercialoff-the-shelf(COTS)control/drivesystem• BuildtheCLIPEDU• TesttheCLIPEDUinaquiescentenvironmentandarepresentative
vibrationenvironment
Thegoalistoproduceastableplatformthatcanhostlasercommunicationpayloadsbyreducing150micro-radspacecraftjitterdownto0.5micro-rad.PhaseI,willproducealowfrequencyCAPSdesignattechnologyreadinesslevel(TRL)4.PhIIplanstobuildaCLIPandEDUtosupportlong-rangeopticalcommunicationsinspace.
WorkPlanCAPSprototypecharacterization;buildathirdsensorusingalternatepottingmaterial;buildafinalversionforCLIPassembly.Performassemblyintegrationandtest.CompletedetailedCLIPdesignandbuildandtestacompletedCLIPplatform.
NASA Applications
AppliedTechnologyAssociates(ATA)developedCLIPconceptisthebasisforNASA’slasercommunicationterminalfortheLLCDandLCRDprograms.ATA’sproposedCLIPandCAPSmaysupportNASAintegratedRadioandOpticalCommunications(iROC)project’slasercollimator.
Non-NASA Applications
AirForce’sSpaceLaserCommunicationTerminal(SLCT),DARPA’sLaserWeaponSystemModule(LWSM),LockheedMartin’sSpaceOpticalTracking(SpOT),Navy’sLaserWeaponSystem(LaWS),andMarine’sGroundBasedAirDefense(GBAD).
CompACT, lighTwEighT isolATioN plATForm (Clip)
AppliedTechnologyAssociates
2012PhaseIIH9.01-9621
—43——43—
—44——44—
—45——45—
American GNC Corporation, Simi Valley, CA ....................................................................24
Amplification Technologies, Inc., New York ...............................................................17, 37
aPeak, Inc., Newton, MA ..................................................................................... 7, 14, 34
Applied Technology Associates, Albuquerque, NM .....................................................26, 42
BEAM Engineering for Advanced Measurements, Winter Park, FL .....................................27
Controlled Dynamics, Inc., Huntington Beach, CA ......................................................25, 41
Fibertek, Inc., Herndon, VA ....................................................................... 8, 20, 22, 39, 40
Freedom Photonics LLC, Santa Barbara, CA ....................................................................29
Light Prescriptions Innovators, LLC, Altadena, CA ............................................................12
Maracel Systems & Software Technologies, LLC, Crestview, FL ........................................10
New Span Optot-Technology Inc., Miami, FL .....................................................................9
nLight Photonics, Vancouver, WA ....................................................................................23
Optical Engines, Inc., Crystal Lake, IL .......................................................................16, 36
OPTRA, Inc., Topsfield, MA .................................................................................... 4, 6, 32
Photon-X, Inc., Huntsville, AL. ..........................................................................................5
Physical Optics Corporation, Torrance, CA .......................................................................11
PolarOnyx, Inc., San Jose, CA ........................................................................................30
Princeton Lightwave, Inc., Cranbury, NJ ....................................................................18, 38
RAM Photonics, San Diego, CA ......................................................................................21
Surface Optics Corporation, San Diego, CA ...............................................................13, 33
Vega Wave Systems, Inc., West Chicago, IL ..............................................................15, 35
Voxtel, Inc., Beaverton, OR .......................................................................................19, 28
company nameS
—46—
JamesD.StegemanTechnologyManagerSpaceCommunicationsandNavigationProgramNASAGlennResearchCenterM.S.142–2Cleveland,Ohio44135Telephone:216–433–3389E-mail:[email protected]
AfrozJ.ZamanNASAGlennResearchCenterM.S.54–1Cleveland,Ohio44135Telephone:216–433–3415E-mail:[email protected]
PS–01398–0914
SBirpointS oF contact
—46—
Cover photo: SCaN testbed under GRC thermal vacuum testing.
Cover photo: Laser Communication RelayDemonstration (LCRD).