Abstract :
The output variables of an MRIG (Microscale Rate Integrating Gyroscope), x, y, satisfy the equations of motion of a two-dimensional oscillator. (Ref. [1]) To examine the role of a mismatch of the two principal frequencies, ω1 and ω 2, we look at the response to a constant rate input, Ω, for times short compared to the damping time constants. Eqs. (7) of Ref. [1], when specialized to principal-axis coordinates, reduce to x - 2kΩy + ω22 x = 0 (1) ÿ + 2kΩx + ω21 y = 0 when the damping and external-force terms are omitted. k is the angular gain factor. The solution for x(t), y(t) in terms of the initial values x(0), y(0), x(0), y(0) is readily obtained using Laplace transforms. To reduce the writing, we introduce the definitions (Eq. (8) of Ref. [1]).
Keywords :
Laplace transforms; damping; gyroscopes; mechanical variables control; motion control; oscillations; Laplace transforms; MRIG frequency mismatch; angular gain factor; constant rate input; damping time constants; external-force terms; microscale rate integrating gyroscope; principal-axis coordinates; quadrature control; two-dimensional oscillator motion; Couplings; Damping; Equations; Force; Frequency control; Mathematical model; Time-frequency analysis;
