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NASA astronaut Bob Behnken stops for the camera moments before going inside the Air Force Research Laboratory’s centrifuge for his spin during testing Nov. 2, 2018 at the Air Force Research Laboratory's centrifuge facility. (U.S. Air Force photo / Keith Lewis)
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During the two-day testing with NASA and Boeing astronauts Nov. 1-2, 2018, the centrifuge spins with one of the astronauts inside. This centrifuge is the Department of Defense’s only human-rated centrifuge with interchangeable cockpits, a capability that enabled NASA and AFRL engineers to create the astronauts' cockpit. (U.S. Air Force photo/Keith Lewis)
AFRL, NASA partner on aerospace physiology to spin into next era of space travel
NASA astronaut Douglas Hurley speaks with a NASA engineer just before getting into the Air Force Research Laboratory’s centrifuge. Ten astronauts participated in the testing Nov. 1 and 2 – one with Boeing and nine with NASA. (U.S. Air Force photo/Richard Eldridge)
AFRL, NASA partner on aerospace physiology to spin into next era of space travel
NASA astronaut candidate Zena Cardman speaks with a NASA physician following her spin in the centrifuge during testing in the Air Force Research Laboratory's 711th Human Performance Wing Nov. 1 and 2. (U.S. Air Force photo/Richard Eldridge)
AFRL, NASA partner on aerospace physiology to spin into next era of space travel
Brig. Gen. Mark Koeniger, 711th Human Performance Wing commander, speaks with Boeing astronaut Chris Ferguson during the two-day astronaut testing in the 711HPW’s centrifuge Nov. 1 and 2. (U.S. Air Force photo/Richard Eldridge)
AFRL, NASA partner on aerospace physiology to spin into next era of space travel
NASA spacesuit engineer Ian Meginnis is helped down from the centrifuge by KBRwyle contractor Brent Ochs with the Air Force Research Laboratory and NASA astronaut and physician Dr. Michael Barratt following his spin during centrifuge testing Nov. 1 and 2. (U.S. Air Force photo/Richard Eldridge)
NASCAR driver Darrell “Bubba” Wallace Jr. visits WPAFB
Capt. Adam Lohn, U.S. Air Force School of Aerospace Medicine flight commander, shows NASCAR driver, Darrell “Bubba” Wallace Jr., the unit’s Centrifuge in motion through a display window during a tour of Wright-Patterson Air Force Base, Ohio, Sept. 7, 2018. The purpose of the Centrifuge is to provide optimum physical conditioning, appropriate functioning of anti-G equipment, and adequate G-oriented situational awareness for aircrew G-tolerance. (U.S. Air Force photo by Michelle Gigante)
NASCAR driver Darrell “Bubba” Wallace Jr. visits WPAFB
Capt. Adam Lohn, U.S. Air Force School of Aerospace Medicine flight commander, shows NASCAR driver, Darrell “Bubba” Wallace Jr., the operating movements of the Centrifuge from the inside of the control room during a tour of Wright-Patterson Air Force Base, Ohio, Sept. 7, 2018. Centrifuge training enhances combat capability and safety by optimizing aircrew defense against G-induced loss of consciousness. (U.S. Air Force photo by Michelle Gigante)
NASCAR driver Darrell “Bubba” Wallace Jr. visits WPAFB
NASCAR driver, Darrell “Bubba” Wallace Jr., takes a simulated ride in the Centrifuge during a tour of the U.S. Air Force School of Aerospace Medicine at Wright-Patterson Air Force Base, Ohio, Sept. 7, 2018. Centrifuge training enhances combat capability and safety by optimizing aircrew defense against G-induced loss of consciousness. (U.S. Air Force photo by Michelle Gigante)
NASCAR driver Darrell “Bubba” Wallace Jr. visits WPAFB
Dr. Andy McKinley, Cognitive Performance Optimization section chief at U.S. Air Force School of Aerospace Medicine, shows NASCAR driver, Darrell “Bubba” Wallace Jr., where to find his carotid pulse, prior to lining up the transcutaneous vagal nerve stimulation device during a demonstration at Wright-Patterson Air Force Base, Ohio, Sept. 7, 2018. The device stimulates the transcutaneous vagal nerve and is used for airway diseases and migraines. (U.S. Air Force photo by Michelle Gigante)
NASCAR driver Darrell “Bubba” Wallace Jr. visits WPAFB
NASCAR driver Darrell “Bubba” Wallace Jr., tests his central and peripheral vision acuity on a vision motor training device as part of a demonstration on his tour inside the Strong Lab at the U.S. Air Force School of Aerospace Medicine, Wright-Patterson Air Force Base, Ohio, Sept. 7, 2018. The training device helps enhance visual reaction time and is used for rehabilitation of visual injuries, impairments such as from a concussion. (U.S. Air Force photo by Michelle Gigante)
NASCAR driver Darrell “Bubba” Wallace Jr. visits WPAFB
Dr. Adam Strang, 711th Human Performance Wing scientist, points to a TRX mapping of NASCAR driver, Darrell “Bubba” Wallace Jr. as part of a body movement assessment demonstration used for helping trainers develop personalized training plans inside the Strong Lab at the U.S. Air Force School of Aerospace Medicine Wright-Patterson Air Force Base, Ohio, Sept. 7, 2018. Strang analyzed Wallace’s TRX map for individual mobility, muscle activation, symmetry, and posture during his visit to USAFSAM. (U.S. Air Force photo by Michelle Gigante)
AFRL, NASA partner on aerospace physiology to spin into next era of space travel
During the two-day testing with NASA and Boeing astronauts Nov. 1 and 2, the centrifuge spins with one of the astronauts inside. This new centrifuge is the Department of Defense’s only human-rated centrifuge with interchangeable cockpits, a capability that enabled NASA and AFRL engineers to create the astronauts' cockpit. (U.S. Air Force photo/Richard Eldridge)
USAFSAM aerospace physiology training optimizes airmen’s performance
U.S. Air Force Tech. Sgt. Adam Tyler, USAF School of Aerospace Medicine operational physiology technician, enters preflight configurations for the school’s Centrifuge from the control room as part of a training program at Wright-Patterson Air Force Base, Ohio, April 26, 2017. The centrifuge simulates a high-G environment used for training and evaluating aircrew on a properly performed anti-G straining maneuver, in a controlled environment. (U.S. Air Force photo/Michelle Gigante)
USAFSAM aerospace physiology training optimizes airmen’s performance
U.S. Air Force School of Aerospace Medicine operational physiology technicians, Staff Sgt. Mary Longbrake (left), Tech. Sgt. Adam Tyler (middle) and Senior Airman Luciano Cattaneo (right), operate the movements of the Centrifuge from inside the control room as part of USAFSAM training at Wright-Patterson Air Force Base, Ohio, April 26, 2017. Centrifuge training enhances combat capability and safety by optimizing aircrew defense against G-induced loss of consciousness. (U.S. Air Force photo/Michelle Gigante)
USAFSAM aerospace physiology training optimizes airmen’s performance
U.S. Air Force School of Aerospace Medicine operational physiology technicians, Senior Airman Luciano Cattaneo and Tech. Sgt. Adam Tyler, prepare to climb into the training centrifuge at Wright-Patterson Air Force Base, Ohio, April 26, 2017. The purpose of the centrifuge is to provide optimum physical conditioning, appropriate functioning of anti-G equipment, and adequate G-oriented situational awareness for aircrew G-tolerance. (U.S. Air Force photo/Michelle Gigante)
USAFSAM aerospace physiology training optimizes airmen’s performance
U.S. Air Force Senior Airman Luciano Cattaneo, School of Aerospace Medicine operational physiology technician, performs a foreign object debris inspection around the centrifuge in USAF School of Aerospace Medicine at Wright-Patterson Air Force Base, Ohio, April 26, 2017. Centrifuge training teaches proper anti-G straining maneuver, physiology of high-G flight and awareness factors that affect an aircrew’s G-tolerance.(U.S. Air Force photo/Michelle Gigante)