ترکیب کنترل کننده های PID مقاوم و عصبی- فازی برای بهینه سازی چند هدفه سیستم ترمز ضد قفل

ملخص المقالة :

در مسائل بهينه سازي چند هدفه، چند هدف بطور همزمان بهينه می‌گردند. یک راه آن است که برای هر هدف یک کنترل کنننده طراحی گردد. سپس ترکیب کنترل کننده‌ها با وزن مشخص منجر به پاسخ بهینه می‌شود. در سيستم هاي صنعتي به علت وجود خطاي مدل سازي يا تغييرات پارامترهای سيستم همواره عدم‌قطعیت در سيستم وجود خواهد داشت. عدم‌قطعیت باعث مي شود يک سيستم واقعي را نتوان توسط يک مدل رياضي توصيف نمود. در این مقاله ابتدا دو کنترل‌کننده PID مقاوم و عصبی- فازی برای رسیدن به اهداف عملکرد مقاوم و پایداری مقاوم در سیستم ترمز ضد‌قفل طراحی شده اند. سیستم مذکور که یک سیستم مرتبه 4، غیرخطی و چند متغیره است توسط کنترل غیرمتمرکز به 4 سیستم تک ورودی- تک خروجی تبدیل می‌شود. دو رویکرد جدید برای ترکیب کنترل کننده‌ها و طراحی توابع وزنی ارائه شده است. در رویکرد اول یک تابع وزنی برای سیگنال خطای سیستم با کنترل‌کننده PID و تابع وزنی دیگر برای سیگنال خطای سیستم با کنترل‌کننده عصبی- فازی با شرط پایداری مقاوم طراحی می‌شود. رویکرد دوم توسط فلوچارتی، دو فیلتر پایین گذر و بالا گذر ارائه می‌دهد که سه شرط خطای حالت ماندگار، حداکثر فراجهش و زمان نشست مطلوب برآورده شوند. نتایج شبیه سازی نشان می‌دهند رویکرد اول بهترین عملکرد در کاهش زمان و مسافت توقف و کاهش حداکثر لغزش در دو جاده خشک و لغزنده را در مقایسه با کنترل‌کننده های PID، عصبی- فازی، سوئیچینگ و رویکرد دوم دارد.

highlights:

Weight function is designed for the system error signal with the each controllers in first approach.

The second approach provides two low-pass and high-pass filters that satisfy the three conditions.

The combination of controllers can have a suitable response in all frequencies.

The comparison of two controllers, two approaches and switching control on the ABS has been done.

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