Comparison and Interpretation Methods for Predictive Control of Mechanics

Sands, Timothy

doi:10.3390/a12110232

Cited by 25 publications

(36 citation statements)

References 41 publications

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“…for UUVs lies in the elimination of the necessity for backgrounds in robotics and/or controls, substituting instead with a prerequisite understanding of (1) dynamics and (2) regression. In model predictive control [75][76][77], the dynamics are used to predict system behavior, which is compared to the behavior of a desired (simpler) dynamic model, and the difference between the two is used to formulate a control that seeks to drive the actual dynamic behavior to mimic the behavior of the desired dynamic. Reference [76] also highlights a very realistic issue: actuator saturation and under actuation (driven by hardware selection).…”

Section: Why Use the Proposed Approach On A Uuv?mentioning

confidence: 99%

“…References [67][68][69][70][71][72][73] utilize data-derived models in the various adaptive schemes, while [74] substantiates the first evolution from simple adaptive systems with the innovation of deterministic self-awareness applied to the forced van der Pol equation. References [75][76][77][78] illustrate the utilization of the system models towards optimization and prediction. Lastly, [79] is the first book devoted to the application of the methods developed here applied to space systems, while this manuscript applies the methods to underwater vehicles.…”

Section: Introductionmentioning

confidence: 99%

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Development of Deterministic Artificial Intelligence for Unmanned Underwater Vehicles (UUV)

Sands

2020

JMSE

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The major premise of deterministic artificial intelligence (D.A.I.) is to assert deterministic self-awareness statements based in either the physics of the underlying problem or system identification to establish governing differential equations. The key distinction between D.A.I. and ubiquitous stochastic methods for artificial intelligence is the adoption of first principles whenever able (in every instance available). One benefit of applying artificial intelligence principles over ubiquitous methods is the ease of the approach once the re-parameterization is derived, as done here. While the method is deterministic, researchers need only understand linear regression to understand the optimality of both self-awareness and learning. The approach necessitates full (autonomous) expression of a desired trajectory. Inspired by the exponential solution of ordinary differential equations and Euler’s expression of exponential solutions in terms of sinusoidal functions, desired trajectories will be formulated using such functions. Deterministic self-awareness statements, using the autonomous expression of desired trajectories with buoyancy control neglected, are asserted to control underwater vehicles in ideal cases only, while application to real-world deleterious effects is reserved for future study due to the length of this manuscript. In totality, the proposed methodology automates control and learning merely necessitating very simple user inputs, namely desired initial and final states and desired initial and final time, while tuning is eliminated completely.

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Section: Why Use the Proposed Approach On A Uuv?mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of Deterministic Artificial Intelligence for Unmanned Underwater Vehicles (UUV)

Sands

2020

JMSE

Self Cite

View full text Add to dashboard Cite

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“…Deterministic AI methods have been successfully applied in large engineering systems such as altitude control of spaceships suffering from loss of vital parts [25]. It has also been applied for achieving better precision in AI algorithms [26] used for adaptive control of actuators [24,27], in system identification [26], and in plant control [28], with results indicating that the deterministic AI method often leads to better precision in prediction performance and in reducing superfluous network data.…”

Section: Hf ðþ ¼mentioning

confidence: 99%

Random Forest-Based Ensemble Machine Learning Data-Optimization Approach for Smart Grid Impedance Prediction in the Powerline Narrowband Frequency Band

Oyekanlu¹,

Uddin²

2020

Deterministic Artificial Intelligence

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In this chapter, the random forest-based ensemble regression method is used for the prediction of powerline impedance at the powerline communication (PLC) narrowband frequency range. It is discovered that while PLC load transfer function, phase, and frequency are crucial to powerline impedance estimation, the problem of data multicollinearity can adversely impact accurate prediction and lead to excessive mean square error (MSE). High MSE is obtained when multiple transfer functions corresponding to different PLC load transfer functions are used for random forest ensemble regression. Low MSE indicating more accurate impedance prediction is obtained when PLC load transfer function data is selectively used. Using data corresponding to 200, 400, 600, 800, and 1000 W PLC load transfer functions together led to poor impedance prediction, while using lesser amount of carefully selected data led to better impedance prediction. These results show that artificial intelligence (AI) methods such as random forest ensemble regression and deterministic data-optimization approach can be utilized for smart grid (SG) health monitoring applications using PLC-based sensors. Machine learning can also be applied to the design of better powerline communication signal transceivers and equalizers.

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“…Model Predictive Control (MPC) algorithms [1][2][3][4][5][6] are frequently used in industrial applications [7], especially as a technique for efficient control of Multiple-Input Multiple-Output (MIMO) processes. Compared with the classical PID controller, MPC algorithms give very good control quality and tuning is much easier, especially for non-minimum phase objects, objects with long time delays, as well as MIMO objects with internal coupling between inputs and outputs.…”

Section: Introductionmentioning

confidence: 99%

The Model Order Reduction Method as an Effective Way to Implement GPC Controller for Multidimensional Objects

Plamowski

Kephart

2020

Algorithms

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The paper addresses issues associated with implementing GPC controllers in systems with multiple input signals. Depending on the method of identification, the resulting models may be of a high order and when applied to a control/regulation law, may result in numerical errors due to the limitations of representing values in double-precision floating point numbers. This phenomenon is to be avoided, because even if the model is correct, the resulting numerical errors will lead to poor control performance. An effective way to identify, and at the same time eliminate, this unfavorable feature is to reduce the model order. A method of model order reduction is presented in this paper that effectively mitigates these issues. In this paper, the Generalized Predictive Control (GPC) algorithm is presented, followed by a discussion of the conditions that result in high order models. Examples are included where the discussed problem is demonstrated along with the subsequent results after the reduction. The obtained results and formulated conclusions are valuable for industry practitioners who implement a predictive control in industry.

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Comparison and Interpretation Methods for Predictive Control of Mechanics

Cited by 25 publications

References 41 publications

Development of Deterministic Artificial Intelligence for Unmanned Underwater Vehicles (UUV)

Development of Deterministic Artificial Intelligence for Unmanned Underwater Vehicles (UUV)

Random Forest-Based Ensemble Machine Learning Data-Optimization Approach for Smart Grid Impedance Prediction in the Powerline Narrowband Frequency Band

The Model Order Reduction Method as an Effective Way to Implement GPC Controller for Multidimensional Objects

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