{"projectId":4259,"project":{"projectId":4259,"title":"Optimal Aerodynamic Forms for High-Lift, Low-Drag Planetary Entry","startDate":"2011-08-01","startYear":2011,"startMonth":8,"endDate":"2015-07-31","endYear":2015,"endMonth":7,"programId":69,"program":{"ableToSelect":false,"acronym":"STRG","isActive":true,"description":"<p> \tThe Space Technology Research Grants Program will accelerate the development of &quot;push&quot; technologies to support the future space science and exploration needs of NASA, other government agencies and the commercial space sector. Innovative efforts with high risk and high payoff will be encouraged. The program is composed of two competitively awarded components.</p> ","parentProgram":{"ableToSelect":false,"isActive":true,"description":"Catalyst is a portfolio of early stage programs that specialize in different innovation constituencies and mechanisms to push the state of the art in aerospace technology development","programId":92327,"responsibleMd":{"canUserEdit":false,"locationEdit":false,"organizationRolePretty":"","organizationTypePretty":""},"title":"Catalyst","manageGaps":false,"acronymOrTitle":"Catalyst"},"parentProgramId":92327,"programId":69,"responsibleMd":{"organizationId":4875,"organizationName":"Space Technology Mission Directorate","acronym":"STMD","organizationType":"NASA_Mission_Directorate","canUserEdit":false,"locationEdit":false,"organizationRolePretty":"","organizationTypePretty":"NASA Mission Directorate"},"responsibleMdOffice":4875,"stockImageFileId":36658,"title":"Space Technology Research Grants","manageGaps":false,"acronymOrTitle":"STRG"},"description":" This proposed effort will examine high-lift forms that can use aerodynamics to maneuver in planetary atmospheres, decelerate gradually from space, or to enter from orbital trajectories in ways not available to blunt forms. The potential benefits of such high lift-vehicles include a wide range of planetary applications, including atmospheric survey missions and trajectories to the outer solar system in which aerodynamic forces augment planetary gravity for increased delta-v. This proposed effort will take a multidisciplinary approach to the optimization of high lift-to-drag ratio interplanetary vehicle designs, tailored to the specific requirements of the atmospheres of the other planets in our solar system. Primary effort will focus on the class of shapes known as ìwaveriders,î designed inversely from known shock flowfields. Optimization routines will be adopted which value not only high-lift, low-drag forms coupled on an optimized trajectory, but also the designís stability performance. 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Traditionally, the decelerator is an enveloping rigid aeroshell that surrounds the payload. Other concepts include inflatable or mechanically deployed aerosurfaces either on the front-facing spacecraft or trailing tethered devices. Hypersonic decelerators may be largely passive or may be actively controlled to achieve a desired trajectory while maintaining operational constraints on heating, deceleration rate, and other parameters.","exampleTechnologies":"Sample return capsules, entry vehicles with lift/drag (l/d) 0.4 to < 2.0, enhanced aerodynamics for slender vehicles, entry vehicles with lift/drag (l/d) > 2.0, aerodynamics modulation hardware, control modulation software, entry guidance software","level":3,"hasChildren":false,"selected":false,"isPrimary":true,"hasInteriorContent":true},"primaryTxTree":[[{"taxonomyNodeId":11235,"taxonomyRootId":8817,"code":"TX09","title":"Entry, Descent, and Landing","level":1,"hasChildren":true,"selected":false,"hasInteriorContent":true},{"taxonomyNodeId":11236,"taxonomyRootId":8817,"parentNodeId":11235,"code":"TX09.1","title":"Aeroassist and Atmospheric Entry","description":"Aeroassist and atmospheric entry (AAE) is a mission segment in which a spacecraft transits a planetary atmosphere from direct entry or orbit. 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Hypersonic decelerators may be largely passive or may be actively controlled to achieve a desired trajectory while maintaining operational constraints on heating, deceleration rate, and other parameters.","exampleTechnologies":"Sample return capsules, entry vehicles with lift/drag (l/d) 0.4 to < 2.0, enhanced aerodynamics for slender vehicles, entry vehicles with lift/drag (l/d) > 2.0, aerodynamics modulation hardware, control modulation software, entry guidance software","level":3,"hasChildren":false,"selected":true,"hasInteriorContent":true}]],"technologyOutcomes":[{"technologyOutcomeId":89805,"projectId":4259,"project":{"projectId":4259,"title":"Optimal Aerodynamic Forms for High-Lift, Low-Drag Planetary Entry","startDate":"2011-08-01","startYear":2011,"startMonth":8,"endDate":"2015-07-31","endYear":2015,"endMonth":7,"programId":69,"program":{"ableToSelect":false,"acronym":"STRG","isActive":true,"description":"<p> \tThe Space Technology Research Grants Program will accelerate the development of &quot;push&quot; technologies to support the future space science and exploration needs of NASA, other government agencies and the commercial space sector. Innovative efforts with high risk and high payoff will be encouraged. The program is composed of two competitively awarded components.</p> ","parentProgram":{"ableToSelect":false,"isActive":true,"description":"Catalyst is a portfolio of early stage programs that specialize in different innovation constituencies and mechanisms to push the state of the art in aerospace technology development","programId":92327,"responsibleMd":{"canUserEdit":false,"locationEdit":false,"organizationRolePretty":"","organizationTypePretty":""},"title":"Catalyst","manageGaps":false,"acronymOrTitle":"Catalyst"},"parentProgramId":92327,"programId":69,"responsibleMd":{"organizationId":4875,"organizationName":"Space Technology Mission Directorate","acronym":"STMD","organizationType":"NASA_Mission_Directorate","canUserEdit":false,"locationEdit":false,"organizationRolePretty":"","organizationTypePretty":"NASA Mission Directorate"},"responsibleMdOffice":4875,"stockImageFileId":36658,"title":"Space Technology Research Grants","manageGaps":false,"acronymOrTitle":"STRG"},"description":" This proposed effort will examine high-lift forms that can use aerodynamics to maneuver in planetary atmospheres, decelerate gradually from space, or to enter from orbital trajectories in ways not available to blunt forms. The potential benefits of such high lift-vehicles include a wide range of planetary applications, including atmospheric survey missions and trajectories to the outer solar system in which aerodynamic forces augment planetary gravity for increased delta-v. This proposed effort will take a multidisciplinary approach to the optimization of high lift-to-drag ratio interplanetary vehicle designs, tailored to the specific requirements of the atmospheres of the other planets in our solar system. Primary effort will focus on the class of shapes known as ìwaveriders,î designed inversely from known shock flowfields. Optimization routines will be adopted which value not only high-lift, low-drag forms coupled on an optimized trajectory, but also the designís stability performance. ","benefits":"The potential benefits of such high lift-vehicles include a wide range of planetary applications, including atmospheric survey missions and trajectories to the outer solar system in which aerodynamic forces augment planetary gravity for increased delta-v.","releaseStatus":"Released","status":"Completed","destinationType":["Mars"],"trlBegin":2,"trlCurrent":3,"trlEnd":3,"favorited":false,"detailedFunding":false,"programContacts":[{"contactId":183514,"canUserEdit":false,"firstName":"Hung","lastName":"Nguyen","fullName":"Hung D Nguyen","fullNameInverted":"Nguyen, Hung D","middleInitial":"D","email":"hung.d.nguyen@nasa.gov","receiveEmail":"Subscribed_User","programContactRole":"Program_Manager","programContactId":162,"programId":69,"programContactRolePretty":"Program Manager","projectContactRolePretty":""},{"contactId":321177,"canUserEdit":false,"firstName":"Matthew","lastName":"Deans","fullName":"Matthew C Deans","fullNameInverted":"Deans, Matthew C","middleInitial":"C","email":"matthew.c.deans-1@nasa.gov","receiveEmail":"Subscribed_User","programContactRole":"Program_Director","programContactId":267,"programId":69,"programContactRolePretty":"Program Director","projectContactRolePretty":""}],"endDateString":"Jul 2015","startDateString":"Aug 2011"},"technologyOutcomeDate":"2015-07-31","technologyOutcomePath":"Closed_Out","details":"This work examines the use of high-lift, low drag vehicles which perform orbital transfers within a planet's atmosphere to reduce propulsive requirements. For the foreseeable future, spacecraft mission design will include the objective of limiting the mass of fuel required. One means of accomplishing this is using aerodynamics as a supplemental force, with what is termed an aero-assist maneuver. Further, the use of a lifting body enables a mission designer to explore candidate trajectory types wholly unavailable to nonlifting  analogs. Examples include missions to outer planets by way of an aero-gravity assist, aero-assisted plane change, aero-capture, and steady atmospheric periapsis probing missions. Engineering level models are created in order to simulate both atmospheric and extra-atmospheric space flight. Each mission is parameterized using discrete variables which control multiple areas of design. This work combines the areas of hypersonic aerodynamics, re-entry aerothermodynamics, spacecraft orbital mechanics, and vehicle shape optimization. In particular, emphasis is given to the parametric design of vehicles known as ”waveriders'' which are inversely designed from known shock flowfields. An entirely novel means of generating a class of waveriders known as ”starbodies'' is presented. A complete analysis is performed of asymmetric starbody forms and compared to a better understood parameterization, “osculating cone'' waveriders. This analysis includes characterization of stability behavior, a critical discipline within hypersonic flight. It is shown that asymmetric starbodies have significant stability improvement with only a 10% reduction in the lift-to-drag ratio. By combining the optimization of both the shape of the vehicle and the trajectory it flies, much is learned about the benefit that can be expected from lifting aero-assist missions. While previous studies have conceptually proven the viability, this work provides thorough quantification of the optimized outcome. In examining an aero-capture of Mars, it was found that with a lifting body, the increased maneuverability can allow completion of multiple mission objectives along with the aero-capture, such as atmospheric profiling or up to 80º of orbital plane change. Completing a combined orbital plane change and aero-capture might save as much as 4.5 km/s of velocity increment while increasing the feasible entry corridor by an order of magnitude. Analyzing a higher energy mission type, a database of maximum aero-gravity assist performance is developed at Mars, Earth and Venus. Finally, a methodology is presented for designing end-to-end interplanetary missions using aero-gravity assists. As a means of demonstrating the method, promising trajectories are propagated which reduce the time of flight of an interstellar probe mission by up to 50%. 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