Max Gadget, GPG Dragon Latest Version, Install Android, Sony Xperia, Xiaomi Mi Robot Vacuum, Verizon, Android Marshmallow, Network, stock firmware

Rabu, 16 Juli 2014

Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor

Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor - this blog we have built a few years ago and already very many blog visitors Max Gadget who are satisfied with the information we convey and we say thanks for that, we will then improve the quality of information we convey to you, well according to what you are looking for we will now discuss first about Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor this information we framework from various trusted sources, please see:

Articles : Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor
full Link : Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor

You can also see our article on:


Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor

A novel design of an adaptive neuro fuzzy inference strategy  (ANFIS) for controlling some of the parameters, such as speed,  torque, flux, voltage, current, etc. of the induction motor is  presented in this paper. Induction motors are characterized by  highly non-linear, complex and time-varying dynamics and
inaccessibility of some of the states and outputs for  measurements. Hence it can be considered as a challenging  engineering problem in the industrial sector. Various advanced  control techniques has been devised by various researchers across  the world. Some of them are based on the fuzzy techniques.



 Fuzzy logic based controllers are considered as potential candidates for such an application. Fuzzy based controllers develop a control signal which yields on the firing of the rule base, which is written on the previous experiences & these rules are fired which is random in nature. As a result of which, the  outcome of the controller is also random & optimal results may not be obtained. Selection of the proper rule base depending
 upon the situation can be achieved by the use of an ANFIS  controller, which becomes an integrated method of approach for the control purposes & yields excellent results, which is the  highlight of this paper. In the designed ANFIS scheme, neural network techniques are used to select a proper rule base, which is
 achieved using the back propagation algorithm. This integrated  approach improves the system performance, cost-effectiveness, efficiency, dynamism, reliability of the designed controller. The simulation results presented in this paper show the effectiveness of the method developed & has got faster response time or settling
times. Further, the method developed has got a wide number of advantages in the industrial sector & can be converted into a real time application using some interfacing cards.



so much information Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor

hopefully the information Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor that we convey can make you satisfied because it can be useful to determine the gadget according to your needs.

you just read the article titled Modeling, Design & Simulation of an Adaptive Neuro- Fuzzy Inference System (ANFIS) for Speed Control of Induction Motor if you feel this information is useful and want to bookmark or share please use the link https://maxyaquos.blogspot.com/2014/07/modeling-design-simulation-of-adaptive.html do not forget to go back to this blog to get more information about gadgets.

Tag :
Share on Facebook
Share on Twitter
Share on Google+
Tags :

0 komentar:

Posting Komentar