TY - GEN
T1 - Workspace analysis of parallel mechanisms through neural networks and genetic algorithms
AU - Kuzeci, Zeynep Ekicioglu
AU - Omurlu, Vasfi Emre
AU - Alp, Huseyin
AU - Ozkol, Ibrahim
PY - 2012
Y1 - 2012
N2 - Stewart Platform Mechanism (SPM) is a type of parallel mechanism (PM) which has 6 degrees of freedom. Due to features like precise positioning and high load carrying capacity, PMs have been used in many areas in recent years. But relatively small workspace of the mechanism is the major disadvantage. This paper aims to improve the method for PM workspace analysis. The structure of Artificial Neural Network (ANN) which was used to analyze 63 SPM's workspace, is determined by Genetic Algorithms (GA). This structure of ANNs, i.e., weights, biases are very effective on catching highly accurate results of the ANNs. Therefore, calculation of these values and appropriate structure, i.e., number of neurons in hidden layers, by trial and error approach, results in spending too much time. To prevent the loss time and to determine the problem most fitted structure of hidden layers, a GA is developed and tested in simulation environment, i.e., software developed data. It is noted that by using software-calculated-parameters instead of using trial-error-approach parameters gives the user as accurate as trial-error-approach in short time span.
AB - Stewart Platform Mechanism (SPM) is a type of parallel mechanism (PM) which has 6 degrees of freedom. Due to features like precise positioning and high load carrying capacity, PMs have been used in many areas in recent years. But relatively small workspace of the mechanism is the major disadvantage. This paper aims to improve the method for PM workspace analysis. The structure of Artificial Neural Network (ANN) which was used to analyze 63 SPM's workspace, is determined by Genetic Algorithms (GA). This structure of ANNs, i.e., weights, biases are very effective on catching highly accurate results of the ANNs. Therefore, calculation of these values and appropriate structure, i.e., number of neurons in hidden layers, by trial and error approach, results in spending too much time. To prevent the loss time and to determine the problem most fitted structure of hidden layers, a GA is developed and tested in simulation environment, i.e., software developed data. It is noted that by using software-calculated-parameters instead of using trial-error-approach parameters gives the user as accurate as trial-error-approach in short time span.
KW - Genetic algorithms
KW - Neural networks
KW - Stewart Platform
KW - Workspace analysis
UR - http://www.scopus.com/inward/record.url?scp=84861625631&partnerID=8YFLogxK
U2 - 10.1109/AMC.2012.6197147
DO - 10.1109/AMC.2012.6197147
M3 - Conference contribution
AN - SCOPUS:84861625631
SN - 9781457710711
T3 - International Workshop on Advanced Motion Control, AMC
BT - Abstracts - 2012 12th IEEE International Workshop on Advanced Motion Control, AMC 2012
T2 - 2012 12th IEEE International Workshop on Advanced Motion Control, AMC 2012
Y2 - 25 March 2012 through 27 March 2012
ER -