{"project":{"acronym":"","projectId":33500,"title":"SOUL System Maturation","primaryTaxonomyNodes":[{"taxonomyNodeId":10612,"taxonomyRootId":8816,"parentNodeId":10611,"level":3,"code":"TX04.1.1","title":"Sensing for Robotic systems","definition":"Robotic sensing capabilities and situational awareness are needed for robotic operations that involve interaction with the environment. Additional sensing types increase the exploration range of surface and below-surface mobility systems, assist in detecting landing hazards in planetary exploration, and enable robotic manipulation in space without close human supervision.","exampleTechnologies":"Space-qualifiable force and torque sensors; space-qualifiable tactile sensors; three dimensional (3D) range imaging sensors for surface mobility, above-surface mobility, and manipulation; in-situ camera geometric calibration diagnostics and self-calibration","hasChildren":false,"hasInteriorContent":true}],"startTrl":4,"currentTrl":5,"endTrl":5,"benefits":"Possible NASA applications include: 1) Inspection of ISS external systems reducing requirement for costly and dangerous manned EVAs. 2) Inspection of heat shield on reentry vehicles to prevent disasters such as Columbia. Integrating SOUL into such vehicles for routine use prior to re-entry would greatly increase the crew safety; 3) Collect small samples from asteroid/comet surface without landing the larger mother ship/host. If Philae was on an umbilical line or if the harpoons were on an umbilical, the Rosetta mission would have been greater success; 4) Create large deployable space system such as large antennas/apertures by coupling multiple satellites using the umbilical line (e.g. rotating formation for stability or artificial gravity); 5) Enhance manned the EVA capability: a) The SOUL robot could carry lights, bring tools, spare consumables (e.g. air tank) to the EVA astronaut working on the ISS or any other future ship; b) The SOUL robot could provide real time video of EVA activity from vantage points unreachable by either other astronauts or conventional robotic arms; c) The SOUL robot could provide auxiliary heat management system or even water vapor capture system reducing weight and power requirements for the EVA suit; d) The SOUL-like umbilical line could carry power and fiber optics comm link reducing reliance on EVA suit batteries while the fiber optics can relay high resolution video from the EVA suit camera.
Many of the NASA and non-NASA applications overlap and some were listed above. Purely commercial applications are also numerous centering on the commercial GEO sat. Examples include: 1) Self-inspection leading to on-orbit servicing/repair of host spacecraft. This of particular interest to GEO Com sat owners/primes during deployment of appendages, anomaly diagnostic and aging assessment; 2) Inspection of other spacecraft with development proceeding to on-orbit servicing/repair and even refueling (when the umbilical contains a propellant transfer tube); 3) Autonomous operations enabling on-orbit assembly and repurposing as envisioned by DARPA's Phoenix Program; 4) Capture of large debris which could then be towed to disposal orbit by the larger host vehicle, Small SOUL mass decreases the danger of additional debris produced by inadvertent collisions due to SOUL low momentum; 5) Function as a long boom with sensors on the end, (e.g. Langmuir probes, magnetometers etc.) enabling better measurements via greater distance from the large host vehicle causing less disturbance to local plasma/environment; 6) Assist in space situational awareness by sensing RF, presence of effluent molecules some distance away from the host etc; 7) Calibrate RF/radar antennas by measuring near-field pattern by flying the SOUL vehicle with the appropriate sensors in front of the antenna/aperture.","description":"Busek Co. Inc. proposes to advance the maturity of an innovative Spacecraft on Umbilical Line (SOUL) System suitable for a wide variety of applications of interest to NASA, DoD and commercial missions. SOUL is a small (<10kg) robotic, self-propelled, self-navigating, autonomous vehicle equipped with a tool (e.g. gripper, light, camera etc.). The SOUL vehicle/robot is attached via the umbilical line to a larger host spacecraft that stows it in a marsupial-like manner and communicates with ground. The umbilical delivers power and commands to SOUL from the host spacecraft. Conceptually, the SOUL is a tool on the end of tens of meters long robotic arm with infinite degrees of freedom (flexible umbilical) that can access locations unreachable by conventional robotic arms. The initial purpose of the USAF and Navy funded SOUL development was removal of large space debris (1000kg class). SOUL has broad applicability including visual inspection and servicing of the host vehicle or other spacecraft and asteroid sample pickup. Under this program, the development of the SOUL vehicle was extremely successful exceeding all goals. The SOUL autonomously recognized simulated debris, estimated its pose relative to the target (fusing visible, IR images and IMU information), planned a path to the debris and executed the path and the touched the target with minimal momentum transfer. The demonstrations were performed on large, low friction air table. In the proposed effort Busek will focus on the development of the deployment/retrieval subsystem which is the least mature technology of the SOUL system. Demonstration of the integrated system will be performed on the air table. The ultimate goal is to make a flight worthy system and demonstrate it on the ISS. The specific objective of the Phase 1 is to design, build and test the umbilical line winch and its control system designed on the basis of numerical model that predicts the umbilical line dynamic behavior.","startYear":2015,"startMonth":6,"endYear":2015,"endMonth":12,"statusDescription":"Completed","principalInvestigators":[{"contactId":485297,"canUserEdit":false,"firstName":"Vlad","lastName":"Hruby","fullName":"Vlad Hruby","fullNameInverted":"Hruby, Vlad","primaryEmail":"vhruby@busek.com","publicEmail":true,"nacontact":false}],"programDirectors":[{"contactId":206378,"canUserEdit":false,"firstName":"Jason","lastName":"Kessler","fullName":"Jason L Kessler","fullNameInverted":"Kessler, Jason L","middleInitial":"L","primaryEmail":"jason.l.kessler@nasa.gov","publicEmail":true,"nacontact":false}],"programExecutives":[{"contactId":215154,"canUserEdit":false,"firstName":"Jennifer","lastName":"Gustetic","fullName":"Jennifer L Gustetic","fullNameInverted":"Gustetic, Jennifer L","middleInitial":"L","primaryEmail":"jennifer.l.gustetic@nasa.gov","publicEmail":true,"nacontact":false}],"programManagers":[{"contactId":62051,"canUserEdit":false,"firstName":"Carlos","lastName":"Torrez","fullName":"Carlos Torrez","fullNameInverted":"Torrez, Carlos","primaryEmail":"carlos.torrez@nasa.gov","publicEmail":true,"nacontact":false}],"projectManagers":[{"contactId":224595,"canUserEdit":false,"firstName":"Jodi","lastName":"Graf","fullName":"Jodi S Graf","fullNameInverted":"Graf, Jodi S","middleInitial":"S","primaryEmail":"jodi.s.graf@nasa.gov","publicEmail":true,"nacontact":false},{"contactId":461333,"canUserEdit":false,"firstName":"Theresa","lastName":"Stanley","fullName":"Theresa M Stanley","fullNameInverted":"Stanley, Theresa M","middleInitial":"M","primaryEmail":"theresa.m.stanley@nasa.gov","publicEmail":true,"nacontact":false}],"website":"","libraryItems":[{"file":{"fileExtension":"pdf","fileId":295458,"fileName":"SBIR_2015_1_BC_H6.01-9110","fileSize":1752446,"objectId":291985,"objectType":{"lkuCodeId":889,"code":"LIBRARY_ITEMS","description":"Library Items","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"objectTypeId":889,"fileSizeString":"1.7 MB"},"files":[{"fileExtension":"pdf","fileId":295458,"fileName":"SBIR_2015_1_BC_H6.01-9110","fileSize":1752446,"objectId":291985,"objectType":{"lkuCodeId":889,"code":"LIBRARY_ITEMS","description":"Library Items","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"objectTypeId":889,"fileSizeString":"1.7 MB"}],"id":291985,"title":"Briefing Chart","description":"SOUL System Maturation Briefing 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Image","file":{"fileExtension":"png","fileId":306681,"fileName":"SBIR_15_1_H6.01-9110","fileSize":8140879,"objectId":66979,"objectType":{"lkuCodeId":1841,"code":"TRANSITION_FILES","description":"Transition Files","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"fileSizeString":"7.8 MB"},"transitionId":66979,"fileId":306681}],"infoText":"Closed out","infoTextExtra":"","dateText":"December 2015"},{"transitionId":66981,"projectId":33500,"partner":"Other","transitionDate":"2016-05-01","path":"Advanced To","relatedProjectId":89518,"relatedProject":{"acronym":"","projectId":89518,"title":"SOUL System Maturation","startTrl":4,"currentTrl":5,"endTrl":5,"benefits":"Possible NASA applications include: 1) Inspection of ISS external systems reducing requirement for costly and dangerous manned EVAs. 2) Inspection of heat shield on reentry vehicles to prevent disasters such as Columbia. Integrating SOUL into such vehicles for routine use prior to re-entry would greatly increase the crew safety; 3) Collect small samples from asteroid/comet surface without landing the larger mother ship/host. If Philae was on an umbilical line or if the harpoons were on an umbilical, the Rosetta mission would have been greater success; 4) Create large deployable space system such as large antennas/apertures by coupling multiple satellites using the umbilical line (e.g. rotating formation for stability or artificial gravity); 5) Enhance manned the EVA capability: a) The SOUL robot could carry lights, bring tools, spare consumables (e.g. air tank) to the EVA astronaut working on the ISS or any other future ship; b) The SOUL robot could provide real time video of EVA activity from vantage points unreachable by either other astronauts or conventional robotic arms; c) The SOUL robot could provide auxiliary heat management system or even water vapor capture system reducing weight and power requirements for the EVA suit; d) The SOUL-like umbilical line could carry power and fiber optics comm link reducing reliance on EVA suit batteries while the fiber optics can relay high resolution video from the EVA suit camera.
Many of the NASA and non-NASA applications overlap and some were listed above. Purely commercial applications are also numerous centering on the commercial GEO sat. Examples include: 1) Self-inspection leading to on-orbit servicing/repair of host spacecraft. This of particular interest to GEO Com sat owners/primes during deployment of appendages, anomaly diagnostic and aging assessment; 2) Inspection of other spacecraft with development proceeding to on-orbit servicing/repair and even refueling (when the umbilical contains a propellant transfer tube); 3) Autonomous operations enabling on-orbit assembly and repurposing as envisioned by DARPA�s Phoenix Program; 4) Capture of large debris which could then be towed to disposal orbit by the larger host vehicle, Small SOUL mass decreases the danger of additional debris produced by inadvertent collisions due to SOUL low momentum; 5) Function as a long boom with sensors on the end, (e.g. Langmuir probes, magnetometers etc.) enabling better measurements via greater distance from the large host vehicle causing less disturbance to local plasma/environment; 6) Assist in space situational awareness by sensing RF, presence of effluent molecules some distance away from the host etc.; 7) Calibrate RF/radar antennas by measuring near-field pattern by flying the SOUL vehicle with the appropriate sensors in front of the antenna/aperture.","description":"Busek Co. Inc. proposes to advance the maturity of an innovative Spacecraft on Umbilical Line (SOUL) System suitable for a wide variety of applications of interest to NASA, DoD and commercial missions. SOUL is a small (<10kg) robotic, self-propelled, self-navigating, autonomous vehicle equipped with a tool (e.g. gripper, light, camera etc.). The SOUL vehicle/robot is attached via the umbilical line to a larger host spacecraft that stows it in a marsupial-like manner and communicates with ground. The umbilical delivers power and commands to SOUL from the host spacecraft. Conceptually, the SOUL is a tool on the end of tens of meters long robotic arm with infinite degrees of freedom (flexible umbilical) that can access locations unreachable by conventional robotic arms. The initial purpose of the USAF and Navy funded SOUL development was removal of large space debris (1000kg class). Under this program, the development of the SOUL vehicle was extremely successful. The SOUL, tested on a air table, autonomously recognized simulated debris, estimated its pose relative to the target (fusing visible, IR images and IMU information), planned a path to the debris and executed the path and the touched the target with minimal momentum transfer. In Phase 1 of the present program, Busek designed, build and tested a winch that is the key part of the SOUL deployment and retrieval system, panning out or reeling in the umbilical line. In the proposed Phase 2 effort Busek will build the entire SOUL system consisting of the SOUL vehicle, umbilical, the Deployment/Retrieval system and the Command Module. The entire system will be housed for launch in a 6U CubeSat deployer which will also stow SOUL when inactive. Demonstration of the integrated system including the 6U deployer will be performed on the air table. The ultimate goal is to make a flight worthy system and demonstrate it on the ISS. Flight readiness will be achieved by qualifying program on the Phase 2 hardware.","startYear":2016,"startMonth":5,"endYear":2018,"endMonth":11,"statusDescription":"Completed","website":"","program":{"acronym":"SBIR/STTR","active":true,"description":"
The NASA SBIR and STTR programs fund the research, development, and demonstration of innovative technologies that fulfill NASA needs as described in the annual Solicitations and have significant potential for successful commercialization. If you are a small business concern (SBC) with 500 or fewer employees or a non-profit RI such as a university or a research laboratory with ties to an SBC, then NASA encourages you to learn more about the SBIR and STTR programs as a potential source of seed funding for the development of your innovations.
The SBIR and STTR programs have 3 phases:
The SBIR and STTR Phase I contracts last for 6 months with a maximum funding of $125,000, and Phase II contracts last for 24 months with a maximum funding of $750,000 - $1.5 million.
Opportunity for Continued Technology Development Post-Phase II:
The NASA SBIR/STTR Program currently has in place two initiatives for supporting its small business partners past the basic Phase I and Phase II elements of the program that emphasize opportunities for commercialization. Specifically, the NASA SBIR/STTR Program has the Phase II Enhancement (Phase II-E) and Phase II eXpanded (Phase II-X) contract options.
Please review the links below to obtain more information on the SBIR/STTR programs.
Provides an overview of the SBIR and STTR programs as implemented by NASA
Provides access to the annual SBIR/STTR Solicitations containing detailed information on the program eligibility requirements, proposal instructions and research topics and subtopics
Schedule and links for the SBIR/STTR solicitations and selection announcements
Federal and non-Federal sources of assistance for small business
Search our complete archive of awarded project abstracts to learn about what NASA has funded
Still have questions? Visit the program FAQs
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The SBIR and STTR programs have 3 phases:
The SBIR and STTR Phase I contracts last for 6 months with a maximum funding of $125,000, and Phase II contracts last for 24 months with a maximum funding of $750,000 - $1.5 million.
Opportunity for Continued Technology Development Post-Phase II:
The NASA SBIR/STTR Program currently has in place two initiatives for supporting its small business partners past the basic Phase I and Phase II elements of the program that emphasize opportunities for commercialization. Specifically, the NASA SBIR/STTR Program has the Phase II Enhancement (Phase II-E) and Phase II eXpanded (Phase II-X) contract options.
Please review the links below to obtain more information on the SBIR/STTR programs.
Provides an overview of the SBIR and STTR programs as implemented by NASA
Provides access to the annual SBIR/STTR Solicitations containing detailed information on the program eligibility requirements, proposal instructions and research topics and subtopics
Schedule and links for the SBIR/STTR solicitations and selection announcements
Federal and non-Federal sources of assistance for small business
Search our complete archive of awarded project abstracts to learn about what NASA has funded
Still have questions? Visit the program FAQs
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