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Purbowaskito, Widagdo; Hsu, Chung-Hao

doi:10.20895/infotel.v9i4.253

Cited by 3 publications

(8 citation statements)

References 7 publications

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“…Notation Kp: Proportional Gain Ki: Integral Gain Kd: Derivative Gain e: error (Setpoint -Parameter Value) t: Time (Second) Ƭ: a variable of integration, with values between 0 to the present state Ƭ 1) Proportional: The proportional characteristic enhances the transient response during the rise and settling times, thereby mitigating steady-state errors. However, a drawback of the proportional control lies in its propensity to yield a persistent offset value increase [5], [17]. The formulation of the proportional control system can be expressed as follows:…”

Section: A Proportional Integral Derivative (Pid)mentioning

confidence: 99%

“…Unmanned ground vehicles (UGVs) hold a prominent position among the prevailing robot types utilized in contemporary times. The development of a UGV entails the integration of a microcontroller and a motor, serving as the primary propellant for the robot [5].…”

Section: Introductionmentioning

confidence: 99%

“…In the design of a UGV robot, there arises a need for a control mechanism that surpasses the efficiency of conventional joystick-based controls [5]. This requirement can be met by employing a LoRa E32 433MHz wireless module, enabling the connection of an Android device as the controller for the robot [11], [12].…”

Section: Introductionmentioning

confidence: 99%

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433Mhz based Robot using PID (Proportional Integral Derivative) for Precise Facing Direction

Hariyadi,

Fadila,

Sifaulloh

2023

JOIV : Int. J. Inform. Visualization

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This research endeavor aims to evaluate the effectiveness of the robot's direction control system by employing PID (Proportional Integral Derivative) output and utilizing wireless communication LoRa E32 433MHz. The experimental robot used in this study was a tank model robot equipped with 4 channels of control. LoRa was implemented in the robot control system, in conjunction with an Android control application, through serial data communication. The LoRa E32 module system was selected based on its established reliability in long-range communication applications. However, encountered challenges included the sluggishness of data transmission when using LoRa for transferring control data and the decreased performance of the robot under Non-Line of Sight conditions. To overcome these challenges, the PID method was employed to generate control data for the robot, thereby minimizing the error associated with controlling its movements. The PID system utilized feedback from a compass sensor (HMC5883L) to evaluate the setpoint data transmitted by the user, employing Kp, Ki, and Kd in calculations to enable smooth movements toward the setpoint. The findings of this study regarding the direct control of the robot using wireless LoRa E32 communication demonstrated an error range of 0.6% to 13.34%. A trial-and-error approach for control variables determined the optimal values for Kp, Ki, and Kd as 10, 0.1, and 1.5, respectively. Future investigations can integrate additional methodologies to precisely and accurately determine the PID constants (Kp, Ki, and Kd) mathematically.

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Section: A Proportional Integral Derivative (Pid)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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433Mhz based Robot using PID (Proportional Integral Derivative) for Precise Facing Direction

Hariyadi,

Fadila,

Sifaulloh

2023

JOIV : Int. J. Inform. Visualization

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“…Pada Tahun 2019 Ahmadan Ainul Fikri meneliti yang berjudul Sistem Pengaturan PID Motor DC Sebagai Penggerak Mini konveyor Berbasis Matlab Penelitian ini menggunakan metode analitic sehingga didapatkan respon riil motor dan mendapatkan nilai kp=0,94624747, ki=51,4023958 dan kd=0,01941504 [2]. Sistem kendali PID untuk pengendalian kecepatan motor penggerak unmanned ground vehicle untuk aplikasi industri pertanian yang diteliti Widagdo Purbowaskito dan Chung-Hao Hsu mengatakan sistem perancangan kendali ini diperuntukkan bagi sebuah robot UGV, Sistem kendali untuk mengendalikan kecepatan sudut motor dc pada roda penggerak UGV telah dirancang menggunakan PID dengan metode trial and error dan didapatkan nilai kp=0,03; ki=0;0000001; dan kd=0,005 [3].…”

Section: Pendahuluanunclassified

Implementation of DC Motor PID Control On Conveyor for Separating Potato Seeds by Weight

Febriyan

Puriyanto

2021

IJRCS

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Dieng area is a mountainous area, dieng has land with high fertility levels so that they are increasingly high in the agricultural sector, especially potatoes. During the time, the technology for sorting potato seeds was still manual with humans, so it was less effective. The conveyor here is very useful as this device which will later work with loadcell as a weigher, and this device will be driven using a dc motor then the speed stabilization uses the PID algorithm with trial and error methods and this tool is supported using ultrasonic sensors and two servo sorting. This device works with 1 cycle, namely with 1 command with a value of KP 55, KI 20 and KD 0.001. The conveyor movement is quite stable with an average error value of 0.276 load cell with a standard deviation of 0.211877 with an achievement level of 80%.

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“…Kecepatan putar masing-masing roda ditentukan berdasarkan perkalian antara kecepatan lurus robot dengan nilai gain Kp dan nilai error dari selisih antara setpoint dengan jarak sensor [22] IV. HASIL DAN PEMBAHASAN Pengujian robot dilakukan pada sebuah lorong dengan dinding acak seperti yang terlihat pada Gambar 4, yang memiliki lorong lurus, belokan ke kanan, dan belokan ke kiri.…”

Section: B Desain Simulasi Menggunakan V-repunclassified

Sistem Kendali Proporsional pada Robot Penghindar Halangan (Avoider) Pioneer P3-DX

Jayadi¹,

Susanto²,

Adhinata³

2021

JTE

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Kemampuan dasar yang harus dimiliki oleh mobile robot adalah menghindari halangan, dengan dapatnya robot menghindari halangan, robot akan mampu melakukan tugas dengan baik tanpa harus menabrak halangan yang ada, karena dengan menabrak halangan akan membuat robot semakin lama menyelesaikan misi bahkan robot dapat mengalami disorientasi sikap, dengan diterapkannya sistem kendali pada robot penghindar halangan membuat robot dapat mengatasi halangan yang ada. Kendali proporsional merupakan kendali sederhana dan mudah digunakan pada mobile robot, dengan delapan sensor yang ada pada robot membuat robot lebih peka terhadap halangan yang ada di depannya sehingga digunakanlah mobile robot jenis Pioneer P3-DX dalam penelitian ini. Robot telah mampu melewati halangan yang ada dengan nilai Kp sebesar 2 dan kecepatan konstan sebesar 4 tanpa menabraknya.

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Untitled

Cited by 3 publications

References 7 publications

433Mhz based Robot using PID (Proportional Integral Derivative) for Precise Facing Direction

433Mhz based Robot using PID (Proportional Integral Derivative) for Precise Facing Direction

Implementation of DC Motor PID Control On Conveyor for Separating Potato Seeds by Weight

Sistem Kendali Proporsional pada Robot Penghindar Halangan (Avoider) Pioneer P3-DX

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