Range identification for perspective vision systems

“…2-5 indicate that the proposed observer can be used to identify the range and hence, the Euclidean coordinates of an object feature moving with affine motion dynamics and a nonaffine PDS, provided the observability conditions are satisfied. These results are comparable to the results obtained in [5] which applied the range identification observer to a planar imaging surface.…”

“…Remark 3: Once 4 ( ) is identified, the complete 3D Euclidean coordinates of the object feature can be determined using (5) and (13). Provided the observability conditions given in (15) and (16) are satisfied 4 ( ) can be identified ifˆ ( ) approaches ( ) as (i.e.,ˆ 1 ( ),ˆ 2 ( ) and 3 ( ) approach 1 ( ), 2 ( ) and 3 ( ) as ) since the parameters ( ) = 1 2 3 are assumed to be known, and 1 ( ), 2 ( ) and 3 ( ) are measurable.…”

“…Motivated to generalize the object motion beyond the skewsymmetric form in [7], Chen and Kano developed a new discontinuous observer in [3] that exponentially forces the state observation error to be uniformly ultimately bounded (UUB) for known motion parameters. In comparison to the UUB result in [3], a continuous observer was constructed in [5] to asymptotically identify the range information for a general affine system with known motion parameters (i.e., the result in [5] eliminated the skew-symmetric assumption and yielded an asymptotic result with a continuous observer). More recently, Ma et al developed a state estimation strategy in [9] and [10] for affine systems with known motion parameters where only a single homogeneous observation point is provided (i.e., a single image coordinate).…”

“…The structure of the nonlinear observer is based on our previous observer in [5]; however, new observability conditions are imposed due to the nonaffine form of the projection resulting from the paraboloid image surface. A Lyapunov-based analysis is used to prove the range and the 3D coordinates of an object moving with general affine Euclidean motion (and nonaffine image dynamics) are asymptotically identified.…”

Lyapunov-based range and motion identification for a nonaffine perspective dynamic system

“…2-5 indicate that the proposed observer can be used to identify the range and hence, the Euclidean coordinates of an object feature moving with affine motion dynamics and a nonaffine PDS, provided the observability conditions are satisfied. These results are comparable to the results obtained in [5] which applied the range identification observer to a planar imaging surface.…”

“…Remark 3: Once 4 ( ) is identified, the complete 3D Euclidean coordinates of the object feature can be determined using (5) and (13). Provided the observability conditions given in (15) and (16) are satisfied 4 ( ) can be identified ifˆ ( ) approaches ( ) as (i.e.,ˆ 1 ( ),ˆ 2 ( ) and 3 ( ) approach 1 ( ), 2 ( ) and 3 ( ) as ) since the parameters ( ) = 1 2 3 are assumed to be known, and 1 ( ), 2 ( ) and 3 ( ) are measurable.…”

“…Motivated to generalize the object motion beyond the skewsymmetric form in [7], Chen and Kano developed a new discontinuous observer in [3] that exponentially forces the state observation error to be uniformly ultimately bounded (UUB) for known motion parameters. In comparison to the UUB result in [3], a continuous observer was constructed in [5] to asymptotically identify the range information for a general affine system with known motion parameters (i.e., the result in [5] eliminated the skew-symmetric assumption and yielded an asymptotic result with a continuous observer). More recently, Ma et al developed a state estimation strategy in [9] and [10] for affine systems with known motion parameters where only a single homogeneous observation point is provided (i.e., a single image coordinate).…”

“…The structure of the nonlinear observer is based on our previous observer in [5]; however, new observability conditions are imposed due to the nonaffine form of the projection resulting from the paraboloid image surface. A Lyapunov-based analysis is used to prove the range and the 3D coordinates of an object moving with general affine Euclidean motion (and nonaffine image dynamics) are asymptotically identified.…”

Lyapunov-based range and motion identification for a nonaffine perspective dynamic system

“…Given the coordinates p i of a set of feature points at different times, there are numerous methods to solve for the relative displacement of the camera to the points, the motion of the points over time, the motion of the camera over time, etc. These methods include multi-view (epipolar) geometry [19][20][21], Kalman filtering [22][23][24] and nonlinear estimation [25,26]. Using this data in the feedback loop of a control system constitutes vision-based controls.…”

A hardware in the loop simulation platform for vision-based control of unmanned air vehicles

Robust face tracking control of a mobile robot using self‐tuning Kalman filter and echo state network