Spatial Disorientation (Physiology of Flight No. 10a) ~1990 Federal Aviation Administration (FAA) Pilot Training (Patreon)

more at http://quickfound.net/

Federal Aviation Administration

Physiology of Flight: Spatial Disorientation, Part 1

Civil Aerospace Medical Institute.

Originally a public domain film from the National Archives, slightly cropped to remove uneven edges, with the aspect ratio corrected, and one-pass brightness-contrast-color correction & mild video noise reduction applied.

The soundtrack was also processed with volume normalization, noise reduction, clipping reduction, and/or equalization (the resulting sound, though not perfect, is far less noisy than the original).

https://en.wikipedia.org/wiki/Spatial_disorientation

Wikipedia license: http://creativecommons.org/licenses/by-sa/3.0/

Spatial disorientation of an aviator is the inability to determine angle, altitude or speed. It is most critical at night or in poor weather, when there is no visible horizon, since vision is the dominant sense for orientation. Auditory systems and the vestibular (inner ear) system for co-ordinating movement with balance can also create illusory nonvisual sensations, as can other sensory receptors located in the skin, muscles, tendons and joints...

Senses during flight

There are four physiologic systems that interact to allow humans to orient themselves in space. Vision is the dominant sense for orientation, but the vestibular system, proprioceptive system and auditory system also play a role. During the abnormal acceleratory environment of flight, the vestibular and proprioceptive systems do not respond truthfully. Because of inertial forces created by acceleration of the aircraft along with centrifugal force caused by turning, the net gravitoinertial force sensed primarily by the otolith organs is not aligned with gravity, leading to perceptual misjudgment of the vertical. In addition, the inner ear contains rotational accelerometers, known as the semicircular canals, which provide information to the lower brain on rotational accelerations in the pitch, roll and yaw axes. However, prolonged rotation (beyond 15–20 s) results in a cessation of semicircular output, and cessation of rotation thereafter can even result in the perception of motion in the opposite direction. Under ideal visual conditions the above illusions are unlikely to be perceived, but at night or in poor weather the visual inputs are no longer capable of overriding these illusory nonvisual sensations. In many cases, illusory visual inputs such as a sloping cloud deck can also lead to misjudgments of the vertical and of speed and distance or even combine with the nonvisual ones to produce an even more powerful illusion. The result of these various visual and nonvisual illusions is spatial disorientation. Various models have been developed to yield quantitative predictions of disorientation associated with known aircraft accelerations.

Effects of disorientation

Once an aircraft enters conditions under which the pilot cannot see a distinct visual horizon, the drift in the inner ear continues uncorrected. Errors in the perceived rate of turn about any axis can build up at a rate of 0.2 to 0.3 degrees per second. If the pilot is not proficient in the use of gyroscopic flight instruments, these errors will build up to a point that control of the aircraft is lost, usually in a steep, diving turn known as a graveyard spiral. During the entire time, leading up to and well into the maneuver, the pilot remains unaware of the turning, believing that the aircraft is maintaining straight flight. One of the most famous mishaps in aviation history involving the graveyard spiral is the crash involving John F. Kennedy Jr. in 1999.

The graveyard spiral usually terminates when the g-forces on the aircraft build up to and exceed the structural strength of the airframe, resulting in catastrophic failure, or when the aircraft contacts the ground. In a 1954 study (180 – Degree Turn Experiment), the University of Illinois Institute of Aviation found that 19 out of 20 non-instrument-rated subject pilots went into a graveyard spiral soon after entering simulated instrument conditions. The 20th pilot also lost control of his aircraft, but in another maneuver. The average time between onset of instrument conditions and loss of control was 178 seconds.

Spatial disorientation can also affect instrument-rated pilots in certain conditions. A powerful tumbling sensation (vertigo) can be set up if the pilot moves his or her head too much during instrument flight. This is called the Coriolis illusion. Pilots are also susceptible to spatial disorientation during night flight over featureless terrain...