scholarly journals Desain dan analisis pengaruh parameter PI dan variasi kecepatan pada respon sistem kontrol arah hadap prototype kendaraan listrik

2020 ◽  
Vol 9 (2) ◽  
Author(s):  
Afif Caesar Distara ◽  
Fatkhur Rohman
Keyword(s):  
Control System ◽  
Steady State ◽  
Electric Vehicles ◽  
Rise Time ◽  
Small Error ◽  
Settling Time ◽  
System Stability ◽  
Prototype System ◽  
Stability Parameters ◽  
The Stability

Electric vehicles are alternative vehicles that carry energy efficient. At this time the dominant vehicle uses ordinary wheels so that it will become an obstacle in the maneuver function that requires movement in various directions. With mechanum wheels the vehicle can move in various directions by adjusting the direction of rotation of each wheel. The problem is choosing the right control system for the control system needed by the vehicle. The purpose of this study is to determine and analyze the effect of variations in the value of PI (Proportional Integral) and speed of the vehicle to the stability response of the system to control the direction of prototype electric vehicles. This study method is an experiment that is by giving a treatment, then evaluating the effects caused by the research object. The results of this study can be concluded that the variation of PI constant values and speed variations have an effect on the stability parameters of the system, namely rise time, settling time, overshot, and steady state error. To get the best system stability response results can use the constant value PI Kp = 2; and Ki = 17; where the stability response of the system for direction control at each speed condition has a fairly good value with a fast rise time, fast settling time, small overshot and a small error steady state compared to other PI constant values in this study.Keywords: mechanum wheel, PI control, direction, prototype, system stability

scholarly journals Ball On Plate Balancing System Pada KIT Praktek PID Mata Kuliah Dasar Sistem Kendali

2017 ◽  
Vol 3 (3) ◽  
pp. 134
Author(s):  
Anwar Mujadin ◽  
Dwi Astharini
Keyword(s):  
Control System ◽  
Steady State ◽  
Rise Time ◽  
Input Image ◽  
Settling Time ◽  
Loop System ◽  
Close Loop System ◽  
Intelligent Control System ◽  
Arduino Uno ◽  
State Error

<p><em>Abstrak – </em><strong>Ball on plate adalah sistem pengendalian cerdas untuk mengarahkan bola  yang ada diatas plate sesuai dengan pola gerakan yang diinginkan tanpa menjatuhkan bola. Ball on plate ini digerakan oleh dua buah motor servo sebagai aktuator (keluaran) untuk menentukan posisi bola. Sedangkan kamera ditempatkan diatas plate sebagai sensor (masukan). Image yang ditangkap oleh kamera kemudian diolah oleh labview menjadi pixel posisi X dan Y. Kerjasama antar mikrokontroler Arduino Uno  dan Labview membentuk sebuah pengendalaian close loop system. Pada tulisan ini akan dibahas parameter penting dalam menganalisa  rise time, overshoot, settling time dan steady state error pada pengendalian sistem ball on plate menggunakan PID.</strong></p><p><strong><br /></strong></p><p><strong><em>Kata kunci </em></strong><em>- Arduino Uno R3 Ball on plate Controller,</em></p><p><em> </em></p><p><em>Abstract –</em> <strong>Ball on the plate is an intelligent control system to steer the ball over the plate that is in accordance with the desired pattern of movement without dropping the ball. Ball on plate is controlled  by two servo motors as actuators (output) to determine the position of the ball. While the camera is placed on the plate as a sensor (input). Image captured by the camera and processed by labview to pixel positions X and Y. The cooperation among the microcontroller Arduino Uno and Labview configurate a close loop system. In this paper will discuss important parameter in analyzing the rise time, overshoot, settling time and steady state error in the control system using PID ball on the plate.</strong></p><p><strong><br /></strong></p><strong><em>Keywords</em></strong><em> – Arduino Uno R3 Ball on plate Controller </em>

scholarly journals Implementation of Fuzzy Logic Control System on Rotary Car Parking System Prototype

2018 ◽  
Vol 12 (2) ◽  
pp. 706
Author(s):  
Nanang Ismail ◽  
Iim Nursalim ◽  
Hendri Maja Saputra ◽  
Teddy Surya Gunawan
Keyword(s):  
Fuzzy Logic ◽  
Control System ◽  
Steady State ◽  
Fuzzy Control ◽  
Rise Time ◽  
Settling Time ◽  
Inference Model ◽  
Time Value ◽  
Parking System ◽  
State Error

Rotary car parking system (RCPS) is one of the effective parking models used in the metropolitan area because the mechanical parking system is designed vertically to conserve the land usage. This paper discussed the implementation of fuzzy logic with the Sugeno Inference Model on the RCPS miniature control system. The research started with kinematics analysis and a mathematical model was derived to determine the slot position and optimal power requirements for each condition. Furthermore, the Fuzzy Inference model used was the Sugeno Model, taking into account two variables: distance and angle. These two variables were selected because in the designed miniature RCPS there will be rotational changes of rotation and rotation in turn. Variable distance was divided into four clusters, such as Zero, Near, Medium and Far. While the angle variables were divided into four clusters as well, such as Zero, Small, Medium, and Big. The test results on a miniature RCPS consisting of six parking slots showed that fuzzy based control provided better results when compared to conventional systems. Step response on the control system without fuzzy control showed the rise time value of 0.58 seconds, peak time of 0.85 seconds, settling time of 0.89, percentage overshoot of 0.20%, and steady state error of 4.14%. While the fuzzy control system provided the rise time value of 0.54 seconds, settling time of 0.83 seconds, steady state error of 2.32%, with no overshoot.

Desain dan Komparasi Kontrol Kecepatan Motor DC

2020 ◽  
Vol 7 (2) ◽  
pp. 127-134
Author(s):  
Safah Tasya Aprilyani ◽  
Irianto Irianto ◽  
Epyk Sunarno
Keyword(s):  
Steady State ◽  
Rise Time ◽  
Settling Time ◽  
Proportional Integral

Penggunaan kontrol sangat diperlukan dalam pengaturan kecepatan motor DC. Dalam pengaturan kecepatan motor DC, salah satu jenis kontrol yang digunakan adalah kontrol Proportional Integral (PI). Untuk 4 jenis metode pada kontrol PI yang digunakan adalah metode Ziegler Nichole, Chien Servo 1, Chien Regulator 1 dan perhitungan secara analitik yang telah diperoleh dari data yang sudah ada.  Namun kontrol dengan PI 4 metode yang digunakan  sebagai pembanding memiliki waktu respon kecepatan saat stabil cenderung lambat baik dari nilai settling time, rise time dan steady state. Maka dari itu dilakukan komparasi antara 4 metode kontrol PI dengan penggunaan kontrol fuzzy. Dalam membandingkan antara 4 metode kontrol PI dan kontrol fuzzy terdapat beberapa parameter sebagai perbandingan yaitu maximum overshoot, steady state, rise time dan settling time. Hasil dari perbandingan tersebut adalah kontrol fuzzy dapat menghasilkan performa lebih baik jika dibandingkan dengan 4 metode pada kontrol PI. Kontrol fuzzy memiliki nilai rise time sebesar 0,015 detik, nilai settling time sebesar 0,025 detik dengan kecepatan sebesar 2900 rpm serta error steady state sebesar 3,33% tanpa adanya overshoot dan osilasi.

STABILISASI TEGANGAN KELUARAN BUCK CONVERTER DENGAN METODE FUZZY LOGIC CONTROLLER

JURNAL ELTEK ◽  
2018 ◽  
Vol 16 (2) ◽  
pp. 125
Author(s):  
Oktriza Melfazen
Keyword(s):  
Fuzzy Logic ◽  
Steady State ◽  
Rise Time ◽  
Fuzzy Logic Controller ◽  
Buck Converter ◽  
Settling Time

Buck converter idealnya mempunyai keluaran yang stabil, pemanfaatandaya rendah, mudah untuk diatur, antarmuka yang mudah dengan pirantiyang lain, ketahanan yang lebih tinggi terhadap perubahan kondisi alam.Beberapa teknik dikembangkan untuk memenuhi parameter buckconverter. Solusi paling logis untuk digunakan pada sistem ini adalahmetode kontrol digital.Penelitian ini menelaah uji performansi terhadap stabilitas tegangankeluaran buck converter yang dikontrol dengan Logika Fuzzy metodeMamdani. Rangkaian sistem terdiri dari sumber tegangan DC variable,sensor tegangan dan Buck Converter dengan beban resistif sebagaimasukan, mikrokontroler ATMega 8535 sebagai subsistem kontroldengan metode logika fuzzy dan LCD sebagai penampil keluaran.Dengan fungsi keanggotaan error, delta error dan keanggotaan keluaranmasing-masing sebanyak 5 bagian serta metode defuzzifikasi center ofgrafity (COG), didapat hasil rerata error 0,29% pada variable masukan18V–20V dan setpoint keluaran 15V, rise time (tr) = 0,14s ; settling time(ts) = 3,4s ; maximum over shoot (%OS) = 2,6 dan error steady state(ess) = 0,3.

Tuning pi untuk stabilitas kecepatan putaran motor induksi 1 fasa pada mesin penyaring bubur kedelai

JURNAL ELTEK ◽  
2020 ◽  
Vol 18 (2) ◽  
pp. 48
Author(s):  
Achmad Afandi ◽  
Mila Fauziyah Fauziyah ◽  
Denda Dewatama
Keyword(s):  
Steady State ◽  
Conventional Method ◽  
Rise Time ◽  
Settling Time ◽  
Screening Process ◽  
Pi Method ◽  
Filter Tube ◽  
Manual Methods ◽  
No Innovation

Perusahaan tahu di Indonesia pada umumnya, masih menggunakan cara manual, dalam pembuatannya khususnya pada proses penyaringan bubur kedelai yang membutuhkan waktu yang, lama. Hal tersebut didasarkan pada belum ditemukannya mesin pemeras bubur kedelai. Dewasa ini telah ditemukan inovasi mesin, pemeras bubur kedelai yang bisa meningkatkan kuantitas dan, kualitas produksi dibanding dengan cara manual. Penerapan, teknologinya adalah bubur kedelai diletakkan pada tabung, penyaring kemudian tabung tersebut diputar menggunakan motor, yang dihubungkan melalui fanbelt dan pulley. Ketika motor, diputar, tabung akan ikut berputar sehingga menimbulkan gerak, sentrifugal dimana air kedelai akan terpisah dari ampas. Kecepatan putar motor yang dikontrol adalah 750 rpm dengan, nilai Kp 0,108 , Ki 0,83 sehingga mendapatkan air sari kedelai, sebesar 1,3 liter dengan perbandingan 1 kg kedelai : 1 liter air. Parameter dari penerapan metode PI ini meliputi rise time 4 detik, settling time 4,5 detik, overshoot 0 dan error steady state 2,4%. Dengan penerapan metode PI maka hasil perasan kedelai dari, peyaringan menjadi semakin banyak dan waktu yang dibutuhkan 4 menit lebih singkat dibandingkan dengan cara konvensional.   Tofu companies in Indonesia generally still use manual methods in their manufacture, especially in the soybean slurry screening process which certainly has many disadvantages such as extortion time needed. This was based on the fact that there was no innovation in the soybean pulp squeezer. Currently, it has been found that innovations of soybean slurry machines can increase the quantity and quality of production compared to manual methods. The application of the technology is soybean slurry placed on the filter tube then the tube is rotated using a motor connected with fanbelt and pulley. When the motor is rotated, the tube will rotate, causing centrifugal motion where the soybean water will separate from the pulp. The speed of the motor controlled in 750 rpm with the Kp 0,108, Ki 0,83, to get soybean essence up to 1,3 liter within comparison 1 kg soybean : 1 liter water. The parameter PI method including rise time 4 second, settling time 4,5 second, overshoot 0 and error steady state 2,4%. By applying PI method, the result of filtering is 4 minute faster comparing with conventional method.

scholarly journals APLIKASI KONTROL PID PADA PROSES PENGOLAHAN AIR LAUT MENGGUNAKAN METODE REVERSE OSMOSIS BERBASIS DCS

JURNAL ELTEK ◽  
2019 ◽  
Vol 17 (2) ◽  
pp. 32
Author(s):  
Hariyadi Singgih Singgih ◽  
Subiyantoro Subiyantoro ◽  
Siswoko Siswoko
Keyword(s):  
Steady State ◽  
Reverse Osmosis ◽  
Rise Time ◽  
Delay Time ◽  
Settling Time ◽  
Set Point ◽  
Pressure Transmitter

Metode pemurnian air laut menggunakan pengaturan kecepatan motor dalam proses reverse osmosis sangat dibutuhkan, dikarenakan proses penyaringan dalam membran reverse osmosis membutuhkan tekanan yang sesuai dengan kemampuan membran. Selain itu juga dibutuhkan kontrol ketinggian air untuk mengotomatisasi tangki yang telah penuh dan mempertahankan ketinggian air. Solusi untuk mengurangi permasalahan ini digunakan DCS yang berfungsi untuk memonitor dan mengontrol plant dari jarak jauh, Metode kontrol yang digunakan pada DCS untuk menstabilkan set point menggunakan metode kontrol PID Ziegler-Nichols. Dalam penelitian ini dirancang mini plant kontrol ketinggian air dan tekanan menggunakan metode PID Ziegler-Nichols yang diimplementasikan pada DCS-PCS7. Sensor yang digunakan untuk ketinggian air adalah HC-SR04, dan untuk sensor tekanan menggunakan pressure transmitter. Dengan aplikasi kontrol PID diperoleh kestabilan set point dengan parameter kontrol ketinggian air : Kp=134.4, Ti=0 dan Td=1. Waktu untuk mencapai set point 120 detik dan  error steady state sebesar 0.94% tanpa gangguan. Untuk parameter Kontrol tekanan air sebesar: Kp=3, Ti=0 dan Td=1.375 dan Delay time = 4s, Rise time = 7s, Settling time = 25s, Osilasi output PID rendah, Error steady state = 1.03% tanpa gangguan.    

Frequency-domain analysis method for analyzing and improving the steady-state characteristics of microcantilever in tapping-mode atomic force microscopy

2018 ◽  
Vol 82 (1) ◽  
pp. 10701
Author(s):  
Xiaohui Gu ◽  
Lining Sun ◽  
Changhai Ru
Keyword(s):  
Steady State ◽  
Frequency Domain ◽  
Stability Margin ◽  
Domain Analysis ◽  
Frequency Domain Analysis ◽  
System Stability ◽  
Analysis Method ◽  
External Interference ◽  
Tapping Mode ◽  
The Stability

In tapping-mode AFM, the steady-state characteristics of microcantilever are extremely important to determine the AFM performance. Due to the external excitation signal and the tip-sample interactions, the solving process of microcantilever motion equation will become very complicated with the traditional time-domain analysis method. In this paper, we propose the novel frequency-domain analysis method to analyze and improve the steady-state characteristics of microcantilever. Compared with the previous methods, this new method has three prominent advantages. Firstly, the analytical expressions of amplitude and phase of cantilever system can be derived conveniently. Secondly, the stability of the cantilever system can be accurately determined and the stability margin can be obtained quantitatively in terms of the phase margin and the magnitude margin. Thirdly, on this basis, external control mechanism can be devised quickly and easily to guarantee the high stability of the cantilever system. With this novel method, we derive the frequency response curves and discuss the great influence of the intrinsic parameters on the system stability, which provides theoretical guidance for selecting samples to achieve better AFM images in the experiments. Moreover, we introduce a new external series correction method to significantly increase the stability margin. The results indicate that the cantilever system is no longer easily disturbed by external interference signals.

scholarly journals DESAIN SISTEM KENDALI UMPAN BALIK STATE PADA KASUS KONTINYU UNTUK MEJA KERJA CNC

2019 ◽  
Vol 20 (2) ◽  
pp. 32
Author(s):  
Fakhruddin Mangkusasmito ◽  
Tsani Hendro Nugroho
Keyword(s):  
Control System ◽  
Rise Time ◽  
Manufacturing Industry ◽  
Position Control ◽  
Control Method ◽  
Tracking System ◽  
Settling Time ◽  
Numerical Control ◽  
Pole Placement ◽  
Work Table

Fakhruddin Mangkusasmito, Tsani Hendro Nugroho in this paper explain that One of the important control system in the manufacturing industry is the position control. Mainly in the Computer Numerical Control (CNC) machine, work-table motion control system is used to regulate work-table movements when the machine process a workpieces on it. On standard machines, work-table movements are two axes (X-Y), which is driven by a motor and lead-screw. The discussion in this research only focus on one axis assuming that the systems on both axes are the same and independent. In this research, MATLAB is used to describe the behaviour of the system and also to design appropriate control system in continuos system using state feedback linear controller such as pole placement , tracking system, full order compensator and reduced order compensator. The goal is to obtain a fast response with a rapid rise time and settling time to a step command, while not exceeding an overshoot of 5%. The specification are than a percent overshoot equal to1%, 0,05s settling time and 0,03s rise time. The performance of each control methods are simulated and analyzed to decide the best suit control method for the systems with such criteria. And the result verify that using tracking system controller method achieve such specification with 0% overshoot, 0,04s settling time and 0,028s rise time.

Adaptive coordinated leader–follower control of autonomous over-actuated electric vehicles

2016 ◽  
Vol 39 (12) ◽  
pp. 1798-1810 ◽  
Author(s):  
Jinghua Guo ◽  
Yugong Luo ◽  
Keqiang Li
Keyword(s):  
Control System ◽  
Electric Vehicles ◽  
Formation Control ◽  
Level Control ◽  
Inverse Control ◽  
Level Control System ◽  
Actuation System ◽  
Uniform Ultimate Boundedness ◽  
The Stability ◽  
High Level

In this paper, the leader–follower formation control problem of autonomous over-actuated electric vehicles on a highway is studied. As the autonomous over-actuated electric vehicles have the characteristics of non-linearities, external disturbances and strong coupling, a novel coordinated three-level control system is constructed to supervise the longitudinal and lateral motions of autonomous electric vehicles. Firstly, an adaptive terminal sliding high-level control algorithm is designed to compute a vector of total forces and torque of vehicles, and the stability of the high-level control system is proven via Lyapunov analysis where uniform ultimate boundedness of the closed-loop signals is guaranteed. Then, a pseudo-inverse control allocation algorithm, which can achieve fault tolerance and reconfiguration of the redundant tyre actuation system, is presented to generate the desired longitudinal and lateral tyre forces. Then, a separate low-level controller consisting of an inverse tyre model and two inner loops for each wheel is designed to achieve its desired forces. Finally, simulation results demonstrate that the proposed control system not only enhance the tracking performance, but also improve the stability and riding comfort of autonomous over-actuated electric vehicles in a platoon.

scholarly journals Kontrol Kecepatan Putar Motor Pengaduk Nira Menggunakan Metode PID pada Alat Pembuat Gula Merah Tebu

2020 ◽  
Vol 3 (2) ◽  
pp. 33
Author(s):  
Dian Ayu Widianti ◽  
Mila Fauziyah ◽  
Denda Dewatama
Keyword(s):  
Steady State ◽  
Rise Time ◽  
Delay Time ◽  
Settling Time ◽  
Peak Time

Gula merah tebu terbuat dari cairan nira yang dikumpulkan dari tanaman tebu. Pada pengolahan gula merah tebu dipengaruhi oleh kecepatan pengadukan. Pengadukan diperlukan untuk mempercepat penguapan air dari nira dan untuk membentuk kristal gula yang kompak serta menghasilkan warna gula yang seragam. Semakin tinggi kecepatan pengadukan, gula merah yang dihasilkan memiliki kadar air yang semakin rendah, sehingga tekstur (kekerasan) gula merah tebu yang dihasilkan semakin baik. Kecepatan pengadukan yang digunakan yaitu 100 rpm, 110 rpm dan 130 rpm. Pengontrolan kecepatan pengadukan dengan aktuator motor DC menggunakan metode kontrol PID yang ditanamkan pada arduino. Metode kontrol ini diharapkan mampu  menjaga kestabilan putaran motor DC  agar sesuai dengan  setpoint. Dari hasil pengujian didapatkan nilai parameter PID dengan metode tuning Zeigler – Nichols yaitu Kp= 0.3, Ki = 0.4 dan Kd = 0.056. Analisa hasil respon sistem pada setpoint 100 rpm diperoleh delay time (Td) = 0.47 s, rise time (Tr) = 1.7 s, settling time (Ts)= 7.6, peak time (Tp) = 3, Overshoot = 6% dan Error Steady State = 3%. Hasil pengujian menunjukkan bahwa kontrol PID mampu mempertahankan kecepatan sesuai setpoint yang diharapkan. Hasil gula merah terbaik yaitu pada kecepatan pengadukan 100rpm. Warna gula merah yang dihasilkan coklat kekuningan, tekstur gula keras dan rasa yang manis.

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