Abstract
The localization algorithm for mobile robots working in narrow space needs to handle the scenario that the geometric shape of reference nodes tends to a line, which results in the matrix of least squares localization approaches ill-conditioned. Estimator bias becomes an important factor that can degrade the localization performance. In this paper, we present a fast unbiased range-based localization algorithm to resist the ill-conditioned problem. The main strategy is to augment objective function in the resultant optimization formulations via introducing a measurement distance into the locating model, which forms a least squares problem with cone constrained. The proposed model decouples the measurement distances from the matrix of least squares, which avoids the ill-conditioned problem when the target is around the geometric center. The closed-form expression of locating position ensures that the proposed algorithm is unbiased and low computation burden in the presence of zero-mean disturbance. Moreover, the robustness improvement of the augmented objective function is analyzed. Numerical simulations are used to corroborate the analytic results which demonstrate the good performance, robustness, and fastness of the proposed method.
Highlights
Indoor localization for autonomous robots becomes an attractive subject with the rapid development and application of the autonomous robots technology [1], [2]
We focus on the range-based localization algorithm for a single target node
Proposition 2: When the target node is close to the geometry center of reference nodes, unbiased CWLS (UCWLS) avoids being ill-conditioned
Summary
Indoor localization for autonomous robots becomes an attractive subject with the rapid development and application of the autonomous robots technology [1], [2]. Range-based localization algorithms, which estimate the target position by using distance information, are widely used for robot navigation. The weighted least squares (WLS) method, which adds the information of measurement distance errors into LLS, is proposed to improve the localization accuracy. We propose a fast and robust localization algorithm that can handle the ill-conditioned problems when the target is around the geometric center and the geometric shape approaches a line. The main contributions of this paper are: a fast unbiased CWLS (UCWLS) for range-based localization in narrow space is modeled and a closed-form estimation algorithm is proposed. UCWLS introduces the measurement distance equation into the objective function keep the system linear, which improves the robustness against the ill-conditioned situation when the geometric shape approaches a line.
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