Mechatronic Design and Optimization Using Knowledge Based Engineering Applied to an Inherently Unstable and Unmanned Aerial Vehicle

Tian, Fengnian; Voskuijl, Mark

doi:10.1109/tmech.2015.2441832

Cited by 8 publications

(8 citation statements)

References 18 publications

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“…In practice, there is no uniform standard to evaluate the design of a multicopter. According to [19,20], the multicopter design optimization problem is essentially a multiobjective optimization problem, so an "optimal design" should fully consider all factors concerned by designers and customers. Therefore, an objective function J = f J (Θ out ) is proposed in this paper to evaluate the obtained multicopter designs and find the optimal Θ * out .…”

Section: Optimization Objectivesmentioning

confidence: 99%

“…Therefore, an objective function J = f J (Θ out ) is proposed in this paper to evaluate the obtained multicopter designs and find the optimal Θ * out . Compared to the objective functions in [19,20], two improvements are introduced in this paper. First, the normalization operation is applied to each evaluation index, which makes it easier to determine the weight factor according to the preferences of designers.…”

Section: Optimization Objectivesmentioning

confidence: 99%

“…In [19], the design optimization problem was solved based on discrete-integer and continuous variables with the objectives of efficiency and flight time. In [20], based on knowledge-based engineering techniques, a design method was proposed to find a multicopter design with the minimum cost and maximum payload.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Design Automation and Optimization Methodology for Electric Multicopter UAVs

Dai¹,

Quan²,

Cai³

2019

Preprint

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The traditional multicopter design method usually requires a long iterative process to find the optimal design based on given performance requirements. The method is uneconomical and inefficient. In this paper, a practical method is proposed to automatically calculate the optimal multicopter design according to the given design requirements including flight time, altitude, payload capacity, and maneuverability. The proposed method contains two algorithms: an offline algorithm and an online algorithm. The offline algorithm finds the optimal components (propeller and electronic speed controller) for each motor to establish its component combination, and subsequently, these component combinations and their key performance parameters are stored in a combination database. The online algorithm obtains the multicopter design results that satisfy the given requirements by searching through the component combinations in the database and calculating the optimal parameters for the battery and airframe. Subsequently, these requirement-satisfied multicopter design results are obtained and sorted according to an objective function that contains evaluation indexes including size, weight, performance, and practicability. The proposed method has the advantages of high precision and quick calculating speed because parameter calibrations and time-consuming calculations are completed offline. Experiments are performed to validate the effectiveness and practicality of the proposed method. Comparisons with the brutal search method and other design methods demonstrate the efficiency of the proposed method.

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Section: Optimization Objectivesmentioning

confidence: 99%

Section: Optimization Objectivesmentioning

confidence: 99%

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Design Automation and Optimization Methodology for Electric Multicopter UAVs

Dai¹,

Quan²,

Cai³

2019

Preprint

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“…La Rocca and van Tooren [15] develop conceptual aircraft design applications based on KBE. Tian and Voskuijl [16] integrate the knowledge related to Electronic systems into the application developed by La Rocca and van Tooren to support the conceptual design of mechatronic systems. The literature review shows that most of the studies on those design methodologies based on KBE focus on the conceptual design phase.…”

Section: Related Workmentioning

confidence: 99%

Improvement of Multidisciplinary Integration in Design of Complex Systems by Implementing Knowledge-Based Engineering

Zheng

Bricogne

Duigou

et al. 2016

IFIP Advances in Information and Communication Technology

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Interface in one complex system represents the logical or physical relationship integrating the components of the complex system or the components with their environment. It plays a quite significant role to guarantee the components designed by the designers of different disciplines integrate correctly in order to achieve the multidisciplinary integration. This paper presents an interface knowledge base to capitalise the design data and rules related to the interfaces. A knowledge-based engineering (KBE) design methodology in which the interface knowledge base is implemented is then proposed to help the designers to improve the multidisciplinary integration during the detailed design phase of complex systems. This KBE design methodology is finally demonstrated by a case study based on a partial discharge (PD) detection system.

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“…Such approaches are mandatory for aerospace vehicles for instance fixed-wings [4], rotorcraft [5] or tilted-rotors [6]. To assist the designer, numerical methods have to be used to determine the best feasible configuration and can use different methods such as statistical-based [7] or optimizationbased [8,9] techniques.…”

Section: Introductionmentioning

confidence: 99%

Efficient sizing and optimization of multirotor drones based on scaling laws and similarity models

Delbecq

Budinger

Ochotorena

et al. 2020

Aerospace Science and Technology

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In contrast to the current overall aircraft design techniques, the design of multirotor vehicles generally consists of skill-based selection procedures or is based on pure empirical approaches. The application of a systemic approach provides better design performance and the possibility to rapidly assess the effect of changes in the requirements. This paper proposes a generic and efficient sizing methodology for electric multirotor vehicles which allows to optimize a configuration for different missions and requirements. Starting from a set of algebraic equations based on scaling laws and similarity models, the optimization problem representing the sizing can be formulated in many manners. The proposed methodology shows a significant reduction in the number of function evaluations in the optimization process due to a thorough suppression of inequality constraints when compared to initial problem formulation. The results are validated by comparison to characteristics of existing multirotors. In addition, performance predictions of these configurations are performed for different flight scenarios and payloads.

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Mechatronic Design and Optimization Using Knowledge Based Engineering Applied to an Inherently Unstable and Unmanned Aerial Vehicle

Cited by 8 publications

References 18 publications

Design Automation and Optimization Methodology for Electric Multicopter UAVs

Design Automation and Optimization Methodology for Electric Multicopter UAVs

Improvement of Multidisciplinary Integration in Design of Complex Systems by Implementing Knowledge-Based Engineering

Efficient sizing and optimization of multirotor drones based on scaling laws and similarity models

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