Linearly reconfigurable Kalman filtering for a vector process

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An Indirect Adaptive Control Scheme in the Presence of Actuator and Sensor Failures

The problem of controlling a system in the presence of unknown actuator and sensor faults is addressed. The system is assumed to have groups of actuators, and groups of sensors, with each group consisting of multiple redundant similar actuators or sensors. The types of actuator faults considered consist of unknown actuators stuck in unknown positions, as well as reduced actuator effectiveness. The sensor faults considered include unknown biases and outages. The approach employed for fault detection and estimation consists of a bank of Kalman filters based on multiple models, and subsequent control reconfiguration to mitigate the effect of biases caused by failed components as well as to obtain stability and satisfactory performance using the remaining actuators and sensors. Conditions for fault identifiability are presented, and the adaptive scheme is applied to an aircraft flight control example in the presence of actuator failures. Simulation results demonstrate that the method can rapidly and accurately detect faults and estimate the fault values, thus enabling safe operation and acceptable performance in spite of failures

Design and implementation of an FPGA-based piecewise affine Kalman Filter for Cyber-Physical Systems

The Kalman Filter is a robust tool often employed as a process observer in Cyber-Physical Systems. However, in the general case the high computational cost, especially for large plant models or fast sample rates, makes it an impractical choice for typical low-power microcontrollers. Furthermore, although industry trends towards tighter integration are supported by powerful high-end System-on-Chip software processors, this consolidation complicates the ability for a controls engineer to verify correct behavior of the system under all conditions, which is important in safety-critical systems and systems demanding a high degree of reliability. Dedicated Field-Programmable Gate Array (FPGA) hardware can provide application speedup, design partitioning in mixed-criticality systems, and fully deterministic timing, which helps ensure a control system behaves identically to offline simulations. This dissertation presents a new design methodology which can be leveraged to yield such benefits. Although this dissertation focuses on the Kalman Filter, the method is general enough to be extended to other compute-intensive algorithms which rely on state-space modeling. For the first part, the core idea is that decomposing the Kalman Filter algorithm from a strictly linear perspective leads to a more generalized architecture with increased performance compared to approaches which focus on nonlinear filters (e.g. Extended Kalman Filter). Our contribution is a broadly-applicable hardware-software architecture for a linear Kalman Filter whose operating domain is extended through online model swapping. A supporting application-agnostic performance and resource analysis is provided. For the second part, we identify limitations of the mixed hardware-software method and demonstrate how to leverage hardware-based region identification in order to develop a strictly hardware-only Kalman Filter which maintains a large operating domain. The resulting hardware processor is partitioned from low criticality software tasks running on a supervising software processor and enables vastly simplified timing validation

A Survey of Prediction and Classification Techniques in Multicore Processor Systems

In multicore processor systems, being able to accurately predict the future provides new optimization opportunities, which otherwise could not be exploited. For example, an oracle able to predict a certain application\u27s behavior running on a smart phone could direct the power manager to switch to appropriate dynamic voltage and frequency scaling modes that would guarantee minimum levels of desired performance while saving energy consumption and thereby prolonging battery life. Using predictions enables systems to become proactive rather than continue to operate in a reactive manner. This prediction-based proactive approach has become increasingly popular in the design and optimization of integrated circuits and of multicore processor systems. Prediction transforms from simple forecasting to sophisticated machine learning based prediction and classification that learns from existing data, employs data mining, and predicts future behavior. This can be exploited by novel optimization techniques that can span across all layers of the computing stack. In this survey paper, we present a discussion of the most popular techniques on prediction and classification in the general context of computing systems with emphasis on multicore processors. The paper is far from comprehensive, but, it will help the reader interested in employing prediction in optimization of multicore processor systems

Identifiability of Additive Actuator and Sensor Faults by State Augmentation

A class of FDI (fault detection and identification) methods for bias-type actuator and sensor faults was explored from the point of view of fault identifiability. The methods use banks of Kalman-Bucy filters (KBFs) to detect faults, determine the fault pattern, and estimate the fault values. A complete characterization of conditions for identifiability of bias-type actuator faults, sensor faults, and simultaneous actuator and sensor faults was presented. It was shown that FDI of simultaneous actuator and sensor faults is not possible using these methods when all sensors have unknown biases. The fault identifiability conditions were demonstrated via numerical examples. The analytical and numerical results indicate that caution must be exercised to ensure fault identifiability for different fault patterns when using such methods

RIS-Enabled NLoS Near-Field Joint Position and Velocity Estimation under User Mobility

In the context of single-base station (BS) non-line-of-sight (NLoS) single-epoch localization with the aid of a reflective reconfigurable intelligent surface (RIS), this paper introduces a novel three-step algorithm that jointly estimates the position and velocity of a mobile user equipment (UE), while compensating for the Doppler effects observed in near-field (NF) at the RIS elements over the short transmission duration of a sequence of downlink (DL) pilot symbols. First, a low-complexity initialization procedure is proposed, relying in part on far-field (FF) approximation and a static user assumption. Then, an alternating optimization procedure is designed to iteratively refine the velocity and position estimates, as well as the channel gain. The refinement routines leverage small angle approximations and the linearization of the RIS response, accounting for both NF and mobility effects. We evaluate the performance of the proposed algorithm through extensive simulations under diverse operating conditions with regard to signal-to-noise ratio (SNR), UE mobility, uncontrolled multipath and RIS-UE distance. Our results reveal remarkable performance improvements over the state-of-the-art (SoTA) mobility-agnostic benchmark algorithm, while indicating convergence of the proposed algorithm to respective theoretical bounds on position and velocity estimation.Comment: 11 pages, 9 figures, journa