Aric R. Aumann scite author profile

OLTARIS: On-line tool for the assessment of radiation in space

Singleterry

¹

,

Blattnig

²

,

Clowdsley

³

et al. 2011

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The effects of ionizing radiation on humans in space is a major technical challenge for exploration to the moon and beyond. The radiation shielding team at NASA Langley Research Center has been working for over 30 years to develop techniques that can efficiently assist the engineer throughout the entire design process. OLTARIS: On-Line Tool for the Assessment of Radiation in Space is a new NASA website (http://oltaris.larc.nasa.gov) that allows engineers and physicists to access a variety of tools and models to study the effects of ionizing space radiation on humans and shielding materials. The site is intended to be an analysis and design tool for those working radiation issues for current and future manned missions, as well as a research tool for developing advanced material and shielding concepts. The site, along with the analysis tools and models within, have been developed using strict software practices to ensure reliable and reproducible results in a production environment. They have also been developed as a modular system so that models and algorithms can be easily added or updated. Vehicle Thickness DistributionEnvironmental Model

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Comparison of the transport codes HZETRN, HETC and FLUKA for galactic cosmic rays

Heinbockel¹,

Slaba²,

Tripathi³

et al. 2011

Advances in Space Research

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Auralization of Hybrid Wing–Body Aircraft Flyover Noise from System Noise Predictions

Rizzi

¹

,

Aumann

²

,

Lopes

³

et al. 2014

Journal of Aircraft

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System noise assessments of a state-of-the-art reference aircraft (similar to a Boeing 777-200ER with GE90-like turbofan engines) and several hybrid wing body (HWB) aircraft configurations were recently performed using NASA engine and aircraft system analysis tools. The HWB aircraft were sized to an equivalent mission as the reference aircraft and assessments were performed using measurements of airframe shielding from a series of propulsion airframe aeroacoustic experiments. The focus of this work is to auralize flyover noise from the reference aircraft and the best HWB configuration using source noise predictions and shielding data based largely on the earlier assessments. For each aircraft, three flyover conditions are auralized. These correspond to approach, sideline, and cutback operating states, but flown in straight and level flight trajectories. The auralizations are performed using synthesis and simulation tools developed at NASA. Audio and visual presentations are provided to allow the reader to experience the flyover from the perspective of a listener in the simulated environment.

show abstract

Auralization of Hybrid Wing Body Aircraft Flyover Noise from System Noise Predictions

Rizzi

¹

,

Aumann

²

,

Lopes

³

et al. 2013

View full text Add to dashboard Cite

System noise assessments of a state-of-the-art reference aircraft (similar to a Boeing 777-200ER with GE90-like turbofan engines) and several hybrid wing body (HWB) aircraft configurations were recently performed using NASA engine and aircraft system analysis tools. The HWB aircraft were sized to an equivalent mission as the reference aircraft and assessments were performed using measurements of airframe shielding from a series of propulsion airframe aeroacoustic experiments. The focus of this work is to auralize flyover noise from the reference aircraft and the best HWB configuration using source noise predictions and shielding data based largely on the earlier assessments. For each aircraft, three flyover conditions are auralized. These correspond to approach, sideline, and cutback operating states, but flown in straight and level flight trajectories. The auralizations are performed using synthesis and simulation tools developed at NASA. Audio and visual presentations are provided to allow the reader to experience the flyover from the perspective of a listener in the simulated environment.

show abstract

OLTARIS: On-Line Tool for the Assessment of Radiation In Space

Singleterry

¹

,

Blattnig²,

Clowdsley³

et al. 2009

View full text Add to dashboard Cite

The effects of ionizing radiation on humans in space is a major technical challenge for exploration to the moon and beyond. The radiation shielding team at NASA Langley Research Center has been working for over 30 years to develop techniques that can efficiently assist the engineer throughout the entire design process. OLTARIS: On-Line Tool for the Assessment of Radiation in Space is a new NASA website (http://oltaris.larc.nasa.gov) that allows engineers and physicists to access a variety of tools and models to study the effects of ionizing space radiation on humans and shielding materials. The site is intended to be an analysis and design tool for those working radiation issues for current and future manned missions, as well as a research tool for developing advanced material and shielding concepts. The site, along with the analysis tools and models within, have been developed using strict software practices to ensure reliable and reproducible results in a production environment. They have also been developed as a modular system so that models and algorithms can be easily added or updated. Vehicle Thickness DistributionEnvironmental Model

show abstract

Aric R. Aumann

OLTARIS: On-line tool for the assessment of radiation in space

Comparison of the transport codes HZETRN, HETC and FLUKA for galactic cosmic rays

Auralization of Hybrid Wing–Body Aircraft Flyover Noise from System Noise Predictions

Auralization of Hybrid Wing Body Aircraft Flyover Noise from System Noise Predictions

OLTARIS: On-Line Tool for the Assessment of Radiation In Space

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