Beyond Photonics, Llc
Dba Beyond Photonics Llc
CAGE Code: 6NMQ6
NCAGE Code: 6NMQ6
Status: Active
Type: Commercial Supplier
Dun & Bradstreet (DUNS): 050857042
Summary
Beyond Photonics, Llc, Dba Beyond Photonics Llc is an Active Commercial Supplier with the Cage Code 6NMQ6 and is tracked by Dun & Bradstreet under DUNS Number 050857042..
Address
6205 Lookout Rd Ste B
Boulder CO 80301-3334
United States
Points of Contact
No Points of Contact...
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Frequently Asked Questions (FAQ) for CAGE 6NMQ6
- What is CAGE Code 6NMQ6?
- 6NMQ6 is the unique identifier used by NATO Organizations to reference the physical entity known as Beyond Photonics, Llc Dba Beyond Photonics Llc located at 6205 Lookout Rd Ste B, Boulder CO 80301-3334, United States.
- Who is CAGE Code 6NMQ6?
- 6NMQ6 refers to Beyond Photonics, Llc Dba Beyond Photonics Llc located at 6205 Lookout Rd Ste B, Boulder CO 80301-3334, United States.
- Where is CAGE Code 6NMQ6 Located?
- CAGE Code 6NMQ6 is located in Boulder, CO, USA.
Contracting History for CAGE 6NMQ6 Most Recent 25 Records
- 80NSSC23CA181
- P3 - Compact Power Amplifier For Hybrid Fiber/Bulk Wind Lidar Transmitters
- 12 Jul 2023
- P3 - Compact Power Amplifier For Hybrid Fiber/Bulk Wind Lidar Transmitters
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $374,976.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC23PB370
- Sbir Phase I: Long-Range Compact Economical Lidar For Wind Profiling
- 18 Jul 2023
- Sbir Phase I: Long-Range Compact Economical Lidar For Wind Profiling
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $149,986.00
- National Aeronautics And Space Administration (Nasa)
- HQ086021C7101
- Sbir/Sttr Phase Ii R&D Eo14042
- 3 Nov 2021
- Sbir/Sttr Phase Ii R&D Eo14042
- Missile Defense Agency (Mda)
- Department Of Defense (Dod)
- $1,497,936.00
- Department Of Defense (Dod)
- HQ086021C7101
- Sbir/Sttr Phase Ii R&D Compact Efficient Ladar For Target Detection And Ranging
- 22 Feb 2023
- Sbir/Sttr Phase Ii R&D Compact Efficient Ladar For Target Detection And Ranging
- Missile Defense Agency (Mda)
- Department Of Defense (Dod)
- $1,497,936.00
- Department Of Defense (Dod)
- HQ086021C7101
- Sbir/Sttr Phase Ii R&D - Compact Efficient Ladar For Target Detection And Ranging
- 6 Jun 2023
- Sbir/Sttr Phase Ii R&D - Compact Efficient Ladar For Target Detection And Ranging
- Missile Defense Agency (Mda)
- Department Of Defense (Dod)
- $1,497,936.00
- Department Of Defense (Dod)
- HQ086021C7101
- Sbir/Sttr Phase Ii R&D Compact Efficient Ladar For Target Detection And Ranging
- 30 Aug 2023
- Sbir/Sttr Phase Ii R&D Compact Efficient Ladar For Target Detection And Ranging
- Missile Defense Agency (Mda)
- Department Of Defense (Dod)
- $1,497,936.00
- Department Of Defense (Dod)
- 80NSSC21C0569
- Compact Power Amplifier For Hybrid Fiber/Bulk Wind Lidar Transmitters
- 28 Jul 2021
- Compact Power Amplifier For Hybrid Fiber/Bulk Wind Lidar Transmitters
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $749,948.96
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21C0569
- Eo14042 Compact Power Amplifier For Hybrid Fiber/Bulk Wind Lidar Transmitters
- 14 Oct 2021
- Eo14042 Compact Power Amplifier For Hybrid Fiber/Bulk Wind Lidar Transmitters
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $749,948.96
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21C0569
- P2e
- 13 Jul 2023
- P2e
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $1,124,918.96
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21C0040
- Eo14042 Autonomous Alignment Advancements For Eye-Safe Coherent Lidar
- 23 Mar 2023
- Eo14042 Autonomous Alignment Advancements For Eye-Safe Coherent Lidar
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $711,654.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21C0040
- Eo14042 Autonomous Alignment Advancements For Eye-Safe Coherent Lidar
- 26 Oct 2022
- Eo14042 Autonomous Alignment Advancements For Eye-Safe Coherent Lidar
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $646,810.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21C0040
- Eo14042 Autonomous Alignment Advancements For Eye-Safe Coherent Lidar
- 20 Apr 2022
- Eo14042 Autonomous Alignment Advancements For Eye-Safe Coherent Lidar
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $146,965.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21P2358
- This Purchase Order Is For Wind-Sp Invar Optical Bench As Per Attached Quote 7/06/2021...Delivery Date: .Ot1 Payment-24 Weeks After Atp.Ot2 Pm1:-6 Weeks After Atp.Ot2 Pm2:-16 Weeks After Atp.Ot2 Pm3:-22 Weeks After Atp.
- 11 Aug 2021
- This Purchase Order Is For Wind-Sp Invar Optical Bench As Per Attached Quote 7/06/2021...Delivery Date: .Ot1 Payment-24 Weeks After Atp.Ot2 Pm1:-6 Weeks After Atp.Ot2 Pm2:-16 Weeks After Atp.Ot2 Pm3:-22 Weeks After Atp.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $50,858.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC18C0160
- In This Phase Ii Effort We Propose To Advance The Development Of Autonomous Alignment Technology Allowing Improved Performance And Reliability From Coherent Lidar Systems And Demonstrate The Technologies In A Working Coherent Lidar System. Eye-Safe Coherent Lidar Technology Holds Great Promise Of Meeting Nasa's Demanding Remote 3D Space Winds Goal Near Term. Highly Autonomous, Long-Range Coherent Lidar Systems May However Suffer Significant Signal Loss Due To Environment-Induced Component Misalignment, As Well As Varying Receiver Lag-Angle Alignment Errors In Space-Based Platform Applications. Although Such Systems Can Be Engineered With The Required Alignment Stability, The Overall Size, Mass, And Cost To Produce Coherent Lidar Systems Will Benefit From Incorporating Technology Into The Design That Allows Alignment To Be Optimized Automatically While The System Is In The Field. Autonomous Space- And Air-Borne Lidar Systems Will Especially Benefit, Where Maintaining Peak Performance Is Critical Without Regular Human Intervention. Auto-Alignment Technologies Will Result In Lower-Cost Lidar Sensors With Greater Autonomy And Less-Exotic Opto-Mechanics, Spurring Strong Commercial Potential Due To The Rapid Introduction Of Lidar Systems Into The Commercial Marketplace For Various Applications. The Technology Aimed At Maintaining Laser And Lidar Alignment Also Has Potential To Correct For Receiver Lag Angle In Fast-Scanning Long-Range Lidar Systems, Which Will Facilitate Faster Scan Rates, Larger Apertures, And Greater Area Coverage Rate Capability. Beyond Photonics Has A Strong Interest In Solving These Technological Problems For Relevant Ground-Based, Airborne, And Space-Based Unattended Lidar Systems. This Phase Ii Effort Will Further Mature Auto-Alignment Designs Exhibiting A High Level Of Synergy Between Nasa's And Other Commercial Vendors Requirements For Laser Auto-Alignment, Transmit/Receive Transceiver Auto-Alignment, And Receiver Lag Angle Compensation.
- 15 Sep 2021
- In This Phase Ii Effort We Propose To Advance The Development Of Autonomous Alignment Technology Allowing Improved Performance And Reliability From Coherent Lidar Systems And Demonstrate The Technologies In A Working Coherent Lidar System. Eye-Safe Coherent Lidar Technology Holds Great Promise Of Meeting Nasa's Demanding Remote 3D Space Winds Goal Near Term. Highly Autonomous, Long-Range Coherent Lidar Systems May However Suffer Significant Signal Loss Due To Environment-Induced Component Misalignment, As Well As Varying Receiver Lag-Angle Alignment Errors In Space-Based Platform Applications. Although Such Systems Can Be Engineered With The Required Alignment Stability, The Overall Size, Mass, And Cost To Produce Coherent Lidar Systems Will Benefit From Incorporating Technology Into The Design That Allows Alignment To Be Optimized Automatically While The System Is In The Field. Autonomous Space- And Air-Borne Lidar Systems Will Especially Benefit, Where Maintaining Peak Performance Is Critical Without Regular Human Intervention. Auto-Alignment Technologies Will Result In Lower-Cost Lidar Sensors With Greater Autonomy And Less-Exotic Opto-Mechanics, Spurring Strong Commercial Potential Due To The Rapid Introduction Of Lidar Systems Into The Commercial Marketplace For Various Applications. The Technology Aimed At Maintaining Laser And Lidar Alignment Also Has Potential To Correct For Receiver Lag Angle In Fast-Scanning Long-Range Lidar Systems, Which Will Facilitate Faster Scan Rates, Larger Apertures, And Greater Area Coverage Rate Capability. Beyond Photonics Has A Strong Interest In Solving These Technological Problems For Relevant Ground-Based, Airborne, And Space-Based Unattended Lidar Systems. This Phase Ii Effort Will Further Mature Auto-Alignment Designs Exhibiting A High Level Of Synergy Between Nasa's And Other Commercial Vendors Requirements For Laser Auto-Alignment, Transmit/Receive Transceiver Auto-Alignment, And Receiver Lag Angle Compensation.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $896,715.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC18C0160
- Eo14042 In This Phase Ii Effort We Propose To Advance The Development Of Autonomous Alignment Technology Allowing Improved Performance And Reliability From Coherent Lidar Systems And Demonstrate The Technologies In A Working Coherent Lidar System. Eye-Safe Coherent Lidar Technology Holds Great Promise Of Meeting Nasa's Demanding Remote 3D Space Winds Goal Near Term. Highly Autonomous, Long-Range Coherent Lidar Systems May However Suffer Significant Signal Loss Due To Environment-Induced Component Misalignment, As Well As Varying Receiver Lag-Angle Alignment Errors In Space-Based Platform Applications. Although Such Systems Can Be Engineered With The Required Alignment Stability, The Overall Size, Mass, And Cost To Produce Coherent Lidar Systems Will Benefit From Incorporating Technology Into The Design That Allows Alignment To Be Optimized Automatically While The System Is In The Field. Autonomous Space- And Air-Borne Lidar Systems Will Especially Benefit, Where Maintaining Peak Performance Is Critical Without Regular Human Intervention. Auto-Alignment Technologies Will Result In Lower-Cost Lidar Sensors With Greater Autonomy And Less-Exotic Opto-Mechanics, Spurring Strong Commercial Potential Due To The Rapid Introduction Of Lidar Systems Into The Commercial Marketplace For Various Applications. The Technology Aimed At Maintaining Laser And Lidar Alignment Also Has Potential To Correct For Receiver Lag Angle In Fast-Scanning Long-Range Lidar Systems, Which Will Facilitate Faster Scan Rates, Larger Apertures, And Greater Area Coverage Rate Capability. Beyond Photonics Has A Strong Interest In Solving These Technological Problems For Relevant Ground-Based, Airborne, And Space-Based Unattended Lidar Systems. This Phase Ii Effort Will Further Mature Auto-Alignment Designs Exhibiting A High Level Of Synergy Between Nasa's And Other Commercial Vendors Requirements For Laser Auto-Alignment, Transmit/Receive Transceiver Auto-Alignment, And Receiver Lag Angle Compensation.
- 25 Jan 2022
- Eo14042 In This Phase Ii Effort We Propose To Advance The Development Of Autonomous Alignment Technology Allowing Improved Performance And Reliability From Coherent Lidar Systems And Demonstrate The Technologies In A Working Coherent Lidar System. Eye-Safe Coherent Lidar Technology Holds Great Promise Of Meeting Nasa's Demanding Remote 3D Space Winds Goal Near Term. Highly Autonomous, Long-Range Coherent Lidar Systems May However Suffer Significant Signal Loss Due To Environment-Induced Component Misalignment, As Well As Varying Receiver Lag-Angle Alignment Errors In Space-Based Platform Applications. Although Such Systems Can Be Engineered With The Required Alignment Stability, The Overall Size, Mass, And Cost To Produce Coherent Lidar Systems Will Benefit From Incorporating Technology Into The Design That Allows Alignment To Be Optimized Automatically While The System Is In The Field. Autonomous Space- And Air-Borne Lidar Systems Will Especially Benefit, Where Maintaining Peak Performance Is Critical Without Regular Human Intervention. Auto-Alignment Technologies Will Result In Lower-Cost Lidar Sensors With Greater Autonomy And Less-Exotic Opto-Mechanics, Spurring Strong Commercial Potential Due To The Rapid Introduction Of Lidar Systems Into The Commercial Marketplace For Various Applications. The Technology Aimed At Maintaining Laser And Lidar Alignment Also Has Potential To Correct For Receiver Lag Angle In Fast-Scanning Long-Range Lidar Systems, Which Will Facilitate Faster Scan Rates, Larger Apertures, And Greater Area Coverage Rate Capability. Beyond Photonics Has A Strong Interest In Solving These Technological Problems For Relevant Ground-Based, Airborne, And Space-Based Unattended Lidar Systems. This Phase Ii Effort Will Further Mature Auto-Alignment Designs Exhibiting A High Level Of Synergy Between Nasa's And Other Commercial Vendors Requirements For Laser Auto-Alignment, Transmit/Receive Transceiver Auto-Alignment, And Receiver Lag Angle Compensation.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $896,715.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21P2358
- This Purchase Order Is For Wind-Sp Invar Optical Bench As Per Attached Quote 7/06/2021...Delivery Date: .Ot1 Payment-24 Weeks After Atp.Ot2 Pm1:-6 Weeks After Atp.Ot2 Pm2:-16 Weeks After Atp.Ot2 Pm3:-22 Weeks After Atp.
- 10 Sep 2021
- This Purchase Order Is For Wind-Sp Invar Optical Bench As Per Attached Quote 7/06/2021...Delivery Date: .Ot1 Payment-24 Weeks After Atp.Ot2 Pm1:-6 Weeks After Atp.Ot2 Pm2:-16 Weeks After Atp.Ot2 Pm3:-22 Weeks After Atp.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $50,858.00
- National Aeronautics And Space Administration (Nasa)
- NNX17CS58C
- The Advanced Coherent Detection Wind Space Pathfinder (Wind Sp) Lidar Directly Advances The Overall Technology Maturation And Readiness Of Coherent Detection Wind Measurements Towards The 3D Global Wind Space Mission. It Represents A Major Next Step That Will Result In A New Instrument That Matches Form, Fit, And Function Of The Lidar Subsystem With A Spaceready Instrument While Retaining Appropriate Alignment Accessibility. The Primary Objective Of The Wind Space Pathfinder Activity Is To Design, Develop, And Demonstrate A Next Generation Coherent Detection Wind Lidar That Represents A Major Step Towards The Ultimate Wind Space Mission.
- 16 Dec 2021
- The Advanced Coherent Detection Wind Space Pathfinder (Wind Sp) Lidar Directly Advances The Overall Technology Maturation And Readiness Of Coherent Detection Wind Measurements Towards The 3D Global Wind Space Mission. It Represents A Major Next Step That Will Result In A New Instrument That Matches Form, Fit, And Function Of The Lidar Subsystem With A Spaceready Instrument While Retaining Appropriate Alignment Accessibility. The Primary Objective Of The Wind Space Pathfinder Activity Is To Design, Develop, And Demonstrate A Next Generation Coherent Detection Wind Lidar That Represents A Major Step Towards The Ultimate Wind Space Mission.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $1,799,825.00
- National Aeronautics And Space Administration (Nasa)
- NNX17CL24C
- In This Phase Ii Effort We Propose To Work With Nasa To Extend The Phase I Achievements, Which Focused On Design And Development Of Very Compact Master And Long-Pulse Slave Oscillator Lasers Operating Near 2.05 Um Wavelength.
- 18 Sep 2020
- In This Phase Ii Effort We Propose To Work With Nasa To Extend The Phase I Achievements, Which Focused On Design And Development Of Very Compact Master And Long-Pulse Slave Oscillator Lasers Operating Near 2.05 Um Wavelength.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $749,897.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC18C0160
- Eo14042 In This Phase Ii Effort We Propose To Advance The Development Of Autonomous Alignment Technology Allowing Improved Performance And Reliability From Coherent Lidar Systems And Demonstrate The Technologies In A Working Coherent Lidar System. Eye-Safe Coherent Lidar Technology Holds Great Promise Of Meeting Nasa's Demanding Remote 3D Space Winds Goal Near Term. Highly Autonomous, Long-Range Coherent Lidar Systems May However Suffer Significant Signal Loss Due To Environment-Induced Component Misalignment, As Well As Varying Receiver Lag-Angle Alignment Errors In Space-Based Platform Applications. Although Such Systems Can Be Engineered With The Required Alignment Stability, The Overall Size, Mass, And Cost To Produce Coherent Lidar Systems Will Benefit From Incorporating Technology Into The Design That Allows Alignment To Be Optimized Automatically While The System Is In The Field. Autonomous Space- And Air-Borne Lidar Systems Will Especially Benefit, Where Maintaining Peak Performance Is Critical Without Regular Human Intervention. Auto-Alignment Technologies Will Result In Lower-Cost Lidar Sensors With Greater Autonomy And Less-Exotic Opto-Mechanics, Spurring Strong Commercial Potential Due To The Rapid Introduction Of Lidar Systems Into The Commercial Marketplace For Various Applications. The Technology Aimed At Maintaining Laser And Lidar Alignment Also Has Potential To Correct For Receiver Lag Angle In Fast-Scanning Long-Range Lidar Systems, Which Will Facilitate Faster Scan Rates, Larger Apertures, And Greater Area Coverage Rate Capability. Beyond Photonics Has A Strong Interest In Solving These Technological Problems For Relevant Ground-Based, Airborne, And Space-Based Unattended Lidar Systems. This Phase Ii Effort Will Further Mature Auto-Alignment Designs Exhibiting A High Level Of Synergy Between Nasa's And Other Commercial Vendors Requirements For Laser Auto-Alignment, Transmit/Receive Transceiver Auto-Alignment, And Receiver Lag Angle Compensation.
- 14 Oct 2021
- Eo14042 In This Phase Ii Effort We Propose To Advance The Development Of Autonomous Alignment Technology Allowing Improved Performance And Reliability From Coherent Lidar Systems And Demonstrate The Technologies In A Working Coherent Lidar System. Eye-Safe Coherent Lidar Technology Holds Great Promise Of Meeting Nasa's Demanding Remote 3D Space Winds Goal Near Term. Highly Autonomous, Long-Range Coherent Lidar Systems May However Suffer Significant Signal Loss Due To Environment-Induced Component Misalignment, As Well As Varying Receiver Lag-Angle Alignment Errors In Space-Based Platform Applications. Although Such Systems Can Be Engineered With The Required Alignment Stability, The Overall Size, Mass, And Cost To Produce Coherent Lidar Systems Will Benefit From Incorporating Technology Into The Design That Allows Alignment To Be Optimized Automatically While The System Is In The Field. Autonomous Space- And Air-Borne Lidar Systems Will Especially Benefit, Where Maintaining Peak Performance Is Critical Without Regular Human Intervention. Auto-Alignment Technologies Will Result In Lower-Cost Lidar Sensors With Greater Autonomy And Less-Exotic Opto-Mechanics, Spurring Strong Commercial Potential Due To The Rapid Introduction Of Lidar Systems Into The Commercial Marketplace For Various Applications. The Technology Aimed At Maintaining Laser And Lidar Alignment Also Has Potential To Correct For Receiver Lag Angle In Fast-Scanning Long-Range Lidar Systems, Which Will Facilitate Faster Scan Rates, Larger Apertures, And Greater Area Coverage Rate Capability. Beyond Photonics Has A Strong Interest In Solving These Technological Problems For Relevant Ground-Based, Airborne, And Space-Based Unattended Lidar Systems. This Phase Ii Effort Will Further Mature Auto-Alignment Designs Exhibiting A High Level Of Synergy Between Nasa's And Other Commercial Vendors Requirements For Laser Auto-Alignment, Transmit/Receive Transceiver Auto-Alignment, And Receiver Lag Angle Compensation.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $896,715.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC21C0128
- Compact Transmitter For Methane And Wind Measurements
- 7 May 2021
- Compact Transmitter For Methane And Wind Measurements
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $124,951.00
- National Aeronautics And Space Administration (Nasa)
- NNX17CS58C
- The Advanced Coherent Detection Wind Space Pathfinder (Wind Sp) Lidar Directly Advances The Overall Technology Maturation And Readiness Of Coherent Detection Wind Measurements Towards The 3D Global Wind Space Mission. It Represents A Major Next Step That Will Result In A New Instrument That Matches Form, Fit, And Function Of The Lidar Subsystem With A Spaceready Instrument While Retaining Appropriate Alignment Accessibility. The Primary Objective Of The Wind Space Pathfinder Activity Is To Design, Develop, And Demonstrate A Next Generation Coherent Detection Wind Lidar That Represents A Major Step Towards The Ultimate Wind Space Mission.
- 30 Jun 2021
- The Advanced Coherent Detection Wind Space Pathfinder (Wind Sp) Lidar Directly Advances The Overall Technology Maturation And Readiness Of Coherent Detection Wind Measurements Towards The 3D Global Wind Space Mission. It Represents A Major Next Step That Will Result In A New Instrument That Matches Form, Fit, And Function Of The Lidar Subsystem With A Spaceready Instrument While Retaining Appropriate Alignment Accessibility. The Primary Objective Of The Wind Space Pathfinder Activity Is To Design, Develop, And Demonstrate A Next Generation Coherent Detection Wind Lidar That Represents A Major Step Towards The Ultimate Wind Space Mission.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $1,799,825.00
- National Aeronautics And Space Administration (Nasa)