• 한국마린엔지니어링학회:학술대회논문집
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• 한국마린엔지니어링학회 2001년도 춘계학술대회 논문집
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• pp.243-248
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• 2001

The stabilization control of Inverted Pendulum(IP) system is difficult because of its nonlinearity and structural unstability. Thus, in this paper, an Evolving Neural Network Controller(ENNC) without Error Back Propagation(EBP) is presented. An ENNC is described simply by genetic representation using an encoding strategy for types and slope values of each active functions, biases, weights and so on. By an evolutionary programming which has three genetic operation; selection, crossover and mutation, the predetermine controller is optimally evolved by updating simultaneously the connection patterns and weights of the neural networks. The performances of the proposed ENNC(PENNC) are compared with the ones of conventional optimal controller and the conventional evolving neural network controller(CENNC) through the simulation and experimental results. And we showed that the finally optimized PENNC was very useful in the stabilization control of an IP system.

• Journal of Advanced Marine Engineering and Technology
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• 제25권2호
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• pp.383-394
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• 2001

The stabilization control of inverted pendulum (IP) system is difficult because of its nonlinearity and structural unstability. In this paper, an Evolving Neural Network Controller (ENNC) without Error Back Propagation (EBP) is presented. An ENNC is described simply by genetic representation using an encoding strategy for types and slope values of each active functions, biases, weights and so on. By an evolutionary programming which has three genetic operation; selection, crossover and mutation, the predetermine controller is optimally evolved by updating simultaneously the connection patterns and weights of the neural networks. The performances of the proposed ENNC(PENNC)are compared with the one of conventional optimal controller and the conventional evolving neural network controller (CENNC) through the simulation and experimental results. And we showed that the finally optimized PENNC was very useful in the stabilization control of an IP system.

• 대한전기학회논문지:시스템및제어부문D
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• 제49권3호
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• pp.157-163
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• 2000

In this paper, an Evolving Neural Network Controller(ENNC) which its structure and its connection weights are optimized simultaneously by Real Variable Elitist Genetic Algoithm(RVEGA) was presented for stabilization of an Inverter Pendulum(IP) system with nonlinearity. This proposed ENNC was described by a simple genetic chromosome. And the deletion of neuron, the determinations of input or output neuron, the deleted neuron and the activation functions types are given according to the various flag types. Therefore, the connection weights, its structure and the neuron types in the given ENNC can be optimized by the proposed evolution strategy. Through the simulations, we showed that the finally acquired optimal ENNC was successfully applied to the stabilization control of an IP system.

• 조명전기설비학회논문지
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• 제14권3호
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• pp.68-76
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• 2000

로켓이나 2족 보행 로봇(Biped Robots)의 자세 제어에 응용되는 도립진자 시스템(Inverted Penduhum System)은 대표적 비선행 시스템으로 수학적 모델링이 대단히 어려우며, 모델링올 하였다 하더라도 복잡한 구조가 된다. 이의 해결을 위한 고전적인 제어 기법으로 1970년대 이후부터는, 신경회로망과 퍼지, 카오스, 유전 알고리증을 이용한 제어 기법들이 도립진자의 안정화 제어에 적용되어져고 있으며, 최근 신경회로망의 자동설계 기법들과 유전 또는 전화 알고리즘올 이용한 신경회로망의 구축 기법인 종래의 진화형 선정회로 제어기(ENNC : Evohing Neural Network Controller)가 시도되어지고 있다. 그러나 종래의 ENNC의 전화방식은 노드(뉴런)단위로 교배하며, 특히, 활성화 함수를 지닌 은닉층의 뉴런이 입력층의 뉴런으로 대체되는 경우, 입력층 뉴런과 출력층 뉴런 사이의 결합 가중치가 삭제되지 않는 등의 문제점이 지적될 수 있다. 따라서, 본 논문에서는 도립진자 시스템의 안정화 제어를 위하여 선택, 교배, 돌연변이의 진화 연산자에 의해 일시에 최적의 구조와 결합가중치로 진화시켜 가능 새로운 형태의 ENNC를 제안하고자 한디. 또한, 다양한 초기치에 적응된 최적 구조와 결합가중치를 갖는 새로운 형태의 ENNC를 시뮬레이션율 통하여 얻고, 이를 ADA-2310보드 및 80586 마이크로 프로세서로 실현하여, 도립진자 시스템의 안정화 제어에 적용함으로써 본 논운에서 제안한 ENNC의 우수성과 강인성을 입증하고자 한다.

• 대한전기학회:학술대회논문집
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• 대한전기학회 2000년도 하계학술대회 논문집 D
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• pp.3013-3015
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• 2000

The stabilization control of Inverted Pendulum(IP) system is difficult because of its nonlinearity and structural unstability. Futhermore, a series of conventional techniques such as the pole placement and the optimal control based on the local linearizations have narrow stabilizable regions, At the same time, the fine tunings of their gain parameters are also troublesome, Thus, in this paper, an Evolving Neural Network ControlleY(ENNC) which its structure and its connection weights are optimized simultaneously by Real Variable Elitist Genetic Algorithm (RVEGA) was presented for stabilization of an IP system with nonlinearity, This proposed ENNC was described by a simple genetic chromosome. Through the simulation and experimental results, we showed that the finally acquired optimal ENNC was very useful in the stabilization control of IP system.