A cruise motor controller for the X-57 Maxwell, NASA’s first all-electric X-plane, undergoes vibration testing at NASA Armstrong Flight Research Center’s environmental lab. The cruise motor controller is exposed to two levels of vibration on three different axes, helping NASA to examine the integrity of the controller for flight conditions. The cruise motor controller will be a critical component for providing power to X-57’s motors when the aircraft takes to the skies in 2020.

A cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane, undergoes vibration testing at NASA Armstrong Flight Research Center's environmental lab. The cruise motor controller is exposed to two levels of vibration on three different axes, helping NASA to examine the integrity of the controller for flight conditions. The cruise motor controller will be a critical component for providing power to X-57's motors when the aircraft takes to the skies in 2020.

A cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane, undergoes vibration testing at NASA Armstrong Flight Research Center's environmental lab. The cruise motor controller is exposed to two levels of vibration on three different axes, helping NASA to examine the integrity of the controller for flight conditions. The cruise motor controller will be a critical component for providing power to X-57's motors when the aircraft takes to the skies in 2020.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA’s first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center’s environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA’s first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center’s environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA’s first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center’s environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA’s first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center’s environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers monitor data during vibration testing of a cruise motor controller for the X-57 Maxwell, NASA's first all-electric X-plane. Attached to a table at NASA Armstrong Flight Research Center's environmental lab, the cruise motor controller is exposed to specific levels of vibration, allowing NASA to examine the structural integrity of the hardware. Engineers, meanwhile, monitored data, including waveforms of electrical current, and recorded readings.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASAs first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA’s Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA’s all-electric X-57 Maxwell, for vibration testing at Armstrong’s environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project’s first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA’s first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA’s Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA’s all-electric X-57 Maxwell, for vibration testing at Armstrong’s environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project’s first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA’s first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA’s Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA’s all-electric X-57 Maxwell, for vibration testing at Armstrong’s environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project’s first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA’s first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA’s Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA’s all-electric X-57 Maxwell, for vibration testing at Armstrong’s environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project’s first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA’s first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

Engineers from NASA's Armstrong Flight Research Center and Empirical Systems Aerospace prepare a cruise motor controller, planned to be used on NASA's all-electric X-57 Maxwell, for vibration testing at Armstrong's environmental lab. Testing the cruise motor controller at various vibration levels, based on baseline flight testing in the project's first phase, helps ensure that the hardware will withstand similar vibration in flight conditions. X-57, NASA's first all-electric experimental aircraft, or X-plane, will fly in its first all-electric configuration in 2020.

NASA’s all-electric X-57 Maxwell prepares for ground vibration testing, or GVT, at NASA’s Armstrong Flight Research Center in California. Done in parallel with cruise motor controller testing, the GVT tested the vehicle at various vibration levels, helping engineers to examine and validate the integrity of the vehicle for flight conditions. A goal of X-57 is to help the Federal Aviation Administration set certification standards for emerging electric aircraft markets.