Citations:extra-vehicular

English citations of extra-vehicular

• 2019 October 11, Nataliya Vasilyeva, Marcia Dunn, “Alexei Leonov, 1st human to walk in space, dies in Moscow”, in AP News‎^[1], archived from the original on 24 August 2022:

  “His venture into the vacuum of space began the history of extra-vehicular activity that makes today’s Space Station maintenance possible,” NASA said on Twitter.

• 2022 January 13, Cheng Pengzhou et al., “TCAN-IDS: Intrusion Detection System for Internet of Vehicle Using Temporal Convolutional Attention Network”, in Symmetry‎^[2], volume 12, number 2, published 2022, →DOI, →ISSN, page 2:

  The frightening part is that, in addition to disrupting normal communications in vehicles, they also enable malicious listening in order to obtain sensitive and valuable data. However, these valuable data are generally localized in practical applications and divided into asymmetric and symmetric data distributions. Examples include symmetrical relationships between data from extra-vehicular networks and asymmetrical probability distributions of malicious and normal network traffic [10].

• 2022 March 16, Laura M. Lucier et al., “Automating International Space Station Robotics Operations Planning: Successes and Challenges”, in Space Operations‎^[3], →DOI, →ISSN:

  Recognizing the time demands associated with executing pre-operations planning and struggling to meet increasing call for extra-vehicular robotics operations on-board the ISS, NASA’s Robotics Operations branch sought to automate their pre-operations planning process with the goal of decreasing process execution time while preserving (or ideally, improving) the process’ level of safety and mission success.

• 2022 July 6, Costantino Balestra, “Varying Oxygen Partial Pressure Elicits Blood-Borne Microparticles Expressing Different Cell-Specific Proteins—Toward a Targeted Use of Oxygen?”, in International Journal of Molecular Sciences‎^[4], volume 23, number 14, published 2022, →DOI, →ISSN, page 2:

  Conversely, the absence of detectable VGE is correlated with a very low probability of DCS in both hyperbaric [19] or hypobaric [20]settings, hence the development of pre-conditioning strategies that aim to reduce VGE production. Oxygen pre-breathing (OPB), a standard approach to remove dissolved N2 from tissues in anticipation of exposures to sub-normal pressures associated with high altitude aviation and extra-vehicular transits while in space, is one of those strategies [21].