Optimal estimator model for human spatial orientationA model is being developed to predict pilot dynamic spatial orientation in response to multisensory stimuli. Motion stimuli are first processed by dynamic models of the visual, vestibular, tactile, and proprioceptive sensors. Central nervous system function is then modeled as a steady-state Kalman filter which blends information from the various sensors to form an estimate of spatial orientation. Where necessary, this linear central estimator has been augmented with nonlinear elements to reflect more accurately some highly nonlinear human response characteristics. Computer implementation of the model has shown agreement with several important qualitative characteristics of human spatial orientation, and it is felt that with further modification and additional experimental data the model can be improved and extended. Possible means are described for extending the model to better represent the active pilot with varying skill and work load levels.
Document ID
19800040095
Acquisition Source
Legacy CDMS
Document Type
Conference Proceedings
Authors
Borah, J. (G & W Applied Science Laboratories Waltham, Mass., United States)
Young, L. R. (MIT Cambridge, Mass., United States)
Curry, R. E. (NASA Ames Research Center Moffett Field, Calif., United States)