Qualitative Assessment of Aerocapture and Applications to Future Missions

Spilker, Thomas R.; Adler, Mark; Arora, Nitin; Beauchamp, P.; Cutts, J. A.; Munk, Michelle M.; Powell, Richard W.; Braun, Robert D.; Wercinski, Paul

doi:10.2514/1.a34056

Cited by 43 publications

(36 citation statements)

References 11 publications

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“…Studies over several decades have shown that the technical risks associated with aerocapture can be mitigated, for example many of the technologies a future aerocapture vehicle would use such as guided hypersonic flight has been demonstrated by Apollo and Mars Science Laboratory (MSL). 12 The cost and schedule risks for aerocapture are substantially less understood, along with programmatic and political risks. The present study recommends that future aerocapture studies apply quantitative risk assessment techniques which NASA has matured though numerous manned and robotic missions.…”

Section: Subsystem Design Cost and Risk Assessmentmentioning

confidence: 99%

“…13 A recent study initiated by the NASA Planetary Science Division concluded that a technology demonstration mission is not required before use of aerocapture on a mission, but remarks that ice giants require additional study. 12 Quantitative cost and risk estimate for an ice giant aerocapture mission concept is highly desired and will inform the upcoming Decadal survey studies regarding the readiness of its use for a large strategic mission.…”

Section: Subsystem Design Cost and Risk Assessmentmentioning

confidence: 99%

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A Unified Framework for Aerocapture Systems Analysis

Girija¹

2019

Preprint

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A unified framework for aerocapture systems analysis studies is presented, taking into account the interconnected nature of interplanetary trajectory design and vehicle design. One of the limitations of previous aerocapture systems studies is their focus on a single interplanetary trajectory for detailed subsystem level analysis. The proposed framework and aerocapture feasibility charts enable a mission designer to perform rapid trajectory and vehicle design trade-offs, and is illustrated with its application to a Neptune mission. The approach can be applied to other atmosphere-bearing Solar System destinations. The framework can be be implemented in an aerocapture software suite to enable rapid mission design studies.

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Section: Subsystem Design Cost and Risk Assessmentmentioning

confidence: 99%

Section: Subsystem Design Cost and Risk Assessmentmentioning

confidence: 99%

A Unified Framework for Aerocapture Systems Analysis

Girija¹

2019

Preprint

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“…since the last such study was performed could allow the navigation uncertainty component to be reduced and hence lower the vehicle L/D requirement. Atmospheric uncertainties at Neptune have been modeled in Neptune-Global Reference Atmospheric Model (GRAM), but no improvements are available over the data used by Lockwood et al 1 Spilker et al 4 recommends performing opportunistic stellar occultations of Uranus and Neptune to improve the atmospheric models, but also notes that the technique may only provide information at high altitudes and extrapolating to altitudes relevant to aerocapture carries greater uncertainties. A dedicated research program for combined ground-based observations and modeling efforts is required to reduce the atmospheric uncertainties at altitudes relevant to aerocapture.…”

Section: Mission Designmentioning

confidence: 99%

“…The large navigation and atmospheric uncertainties drive the need for a vehicle with sufficient control authority to perform aerocapture without the spacecraft risking escape or getting trapped in the atmosphere. 4 Several mission concepts and technology demonstration flights have proposed the use of aerocapture, but have never been flown. [5][6][7][8][9] Hall et al 10 showed that aerocapture could enhance missions to Venus, Mars, Titan, and Uranus and enable some missions to Jupiter, Saturn, and Neptune.…”

Section: Introductionmentioning

confidence: 99%

“…Heritage low lift-to-drag ratio (L/D ≤ 0.4 ) blunt-body aeroshells and existing thermal protection system (TPS) materials are sufficient for aerocapture at Venus, Mars, and Titan. 4,[11][12][13][14] Aerocapture studies have historically used a mid lift-to-drag (L/D) vehicle with L/D of 0.6-0.8 to accommodate the large navigation and other uncertainties at Neptune. 15,16 Planetary entry vehicles flown to date are low-L/D vehicles with L/D less than 0.4.…”

Section: Introductionmentioning

confidence: 99%

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Aerocapture Performance Analysis for a Neptune Mission Using a Heritage Blunt-Body Aeroshell

Girija¹

2019

Preprint

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The large navigation and atmospheric uncertainties at Neptune have historically driven the need for a mid-lift-to-drag L/D vehicle with L/D of 0.6--0.8. All planetary entry vehicles flown to date are low-L/D blunt-body aeroshells with L/D less than 0.4. The lack of a heritage mid-L/D aeroshell presents a long pole for Neptune aerocapture, as the development and testing of a new entry vehicle incurs significant cost, risk, and time. Techniques which may allow Neptune aerocapture to be performed using heritage low-L/D blunt-body aeroshells are investigated, and obviate the need for mid-L/D aeroshells. A navigation study is performed to quantify the delivery errors, and a new guidance algorithm with on-board density estimation is developed to accommodate atmospheric uncertainties. Monte Carlo simulation is used to analyze aerocapture performance of a vehicle with L/D = 0.4. One hundred percent of the cases captured successfully and show a 99.87% probability of achieving the desired science orbit with a total of 396 m/s propulsive Delta V budget, even with worst-case atmospheric uncertainties.

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Future Missions to the Giant Planets that Can Advance Atmospheric Science Objectives

et al. 2020

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Other papers in this special issue have discussed the diversity of planetary atmospheres and some of the key science questions for giant planet atmospheres to be addressed in the future. There are crucial measurements that can only be made by orbiters of giant planets and probes dropped into their atmospheres. To help the community be more effective developers of missions and users of data products, we summarize how NASA and ESA categorize their planetary space missions, and the restrictions and requirements placed on each category. We then discuss the atmospheric goals to be addressed by currently approved giant-planet missions as well as missions likely to be considered in the next few years, such as a joint NASA/ESA Ice Giant orbiter with atmospheric probe. Our focus is on interplanetary spacecraft, but we acknowledge the crucial role to be played by ground-based and near-Earth telescopes, as well as theoretical and laboratory work.

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Qualitative Assessment of Aerocapture and Applications to Future Missions

Cited by 43 publications

References 11 publications

A Unified Framework for Aerocapture Systems Analysis

A Unified Framework for Aerocapture Systems Analysis

Aerocapture Performance Analysis for a Neptune Mission Using a Heritage Blunt-Body Aeroshell

Future Missions to the Giant Planets that Can Advance Atmospheric Science Objectives

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