1 research outputs found
A Nonlinear Observability Analysis of Ambient Wind Estimation with Uncalibrated Sensors, Inspired by Insect Neural Encoding
Estimating the direction of ambient fluid flow is key for many flying or
swimming animals and robots, but can only be accomplished through indirect
measurements and active control. Recent work with tethered flying insects
indicates that their sensory representation of orientation, apparent flow,
direction of movement, and control is represented by a 2-dimensional angular
encoding in the central brain. This representation simplifies sensory
integration by projecting the direction (but not scale) of measurements with
different units onto a universal polar coordinate frame. To align these angular
measurements with one another and the motor system does, however, require a
calibration of angular gain and offset for each sensor. This calibration could
change with time due to changes in the environment or physical structure. The
circumstances under which small robots and animals with angular sensors and
changing calibrations could self-calibrate and estimate the direction of
ambient fluid flow while moving remains an open question. Here, a methodical
nonlinear observability analysis is presented to address this. The analysis
shows that it is mathematically feasible to continuously estimate flow
direction and perform regular self-calibrations by adopting frequent changes in
course (or active prevention thereof) and orientation, and requires fusion and
temporal differentiation of three sensory measurements: apparent flow,
orientation (or its derivative), and direction of motion (or its derivative).
These conclusions are consistent with the zigzagging trajectories exhibited by
many plume tracking organisms, suggesting that perhaps flow estimation is a
secondary driver of their trajectory structure.Comment: 8 pages, 3 figures, submitted to CDC 202