Optimizing Non-linear PID Control with Artificial Bee Colony for Temperature Regulation in a Control Plant Trainer

Luis Caiza; Marco Herrera; Diego S. Benítez; Oscar Camacho

doi:10.1109/ColCACI67437.2025.11230900

Optimizing Non-linear PID Control with Artificial Bee Colony for Temperature Regulation in a Control Plant Trainer

Luis Caiza^*
, Marco Herrera
, Diego S. Benítez
, Oscar Camacho

^*Corresponding author for this work

Ingeniería Electrónica y Automatización

Universidad San Francisco de Quito

Research output: Contribution to journal › Conference article › peer-review

2 Scopus citations

Abstract

This paper presents an optimization framework for tuning nonlinear PID controllers using the Artificial Bee Colony (ABC) algorithm. The proposed approach aims to improve tracking performance by systematically tuning the PID parameters to minimize tracking errors, improve stability, and ensure robustness against system disturbances. A comparative study was conducted using conventional tuning strategies and alternative metaheuristic techniques for temperature control in a didactic control plant trainer to validate the effectiveness of the proposed method. Experimental results on non-linear benchmark processes demonstrate that the proposed approach achieves superior results in transient behavior, overshoot reduction, and disturbance rejection, highlighting its potential for advanced process control applications.

Original language	English
Journal	IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI
Issue number	2025
DOIs	https://doi.org/10.1109/ColCACI67437.2025.11230900
State	Published - 2025
Event	2025 IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI 2025 - Armenia, Colombia Duration: 27 Aug 2025 → 29 Aug 2025

Keywords

Artificial Bee Colony Algorithm
Nonlinear PID
Optimization

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10.1109/ColCACI67437.2025.11230900

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title = "Optimizing Non-linear PID Control with Artificial Bee Colony for Temperature Regulation in a Control Plant Trainer",

abstract = "This paper presents an optimization framework for tuning nonlinear PID controllers using the Artificial Bee Colony (ABC) algorithm. The proposed approach aims to improve tracking performance by systematically tuning the PID parameters to minimize tracking errors, improve stability, and ensure robustness against system disturbances. A comparative study was conducted using conventional tuning strategies and alternative metaheuristic techniques for temperature control in a didactic control plant trainer to validate the effectiveness of the proposed method. Experimental results on non-linear benchmark processes demonstrate that the proposed approach achieves superior results in transient behavior, overshoot reduction, and disturbance rejection, highlighting its potential for advanced process control applications.",

keywords = "Artificial Bee Colony Algorithm, Nonlinear PID, Optimization",

author = "Luis Caiza and Marco Herrera and Ben{\'i}tez, \{Diego S.\} and Oscar Camacho",

note = "Publisher Copyright: {\textcopyright}2025 IEEE.; 2025 IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI 2025 ; Conference date: 27-08-2025 Through 29-08-2025",

year = "2025",

doi = "10.1109/ColCACI67437.2025.11230900",

language = "Ingl{\'e}s",

journal = "IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI",

issn = "2769-3651",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "2025",

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TY - JOUR

T1 - Optimizing Non-linear PID Control with Artificial Bee Colony for Temperature Regulation in a Control Plant Trainer

AU - Caiza, Luis

AU - Herrera, Marco

AU - Benítez, Diego S.

AU - Camacho, Oscar

PY - 2025

Y1 - 2025

N2 - This paper presents an optimization framework for tuning nonlinear PID controllers using the Artificial Bee Colony (ABC) algorithm. The proposed approach aims to improve tracking performance by systematically tuning the PID parameters to minimize tracking errors, improve stability, and ensure robustness against system disturbances. A comparative study was conducted using conventional tuning strategies and alternative metaheuristic techniques for temperature control in a didactic control plant trainer to validate the effectiveness of the proposed method. Experimental results on non-linear benchmark processes demonstrate that the proposed approach achieves superior results in transient behavior, overshoot reduction, and disturbance rejection, highlighting its potential for advanced process control applications.

AB - This paper presents an optimization framework for tuning nonlinear PID controllers using the Artificial Bee Colony (ABC) algorithm. The proposed approach aims to improve tracking performance by systematically tuning the PID parameters to minimize tracking errors, improve stability, and ensure robustness against system disturbances. A comparative study was conducted using conventional tuning strategies and alternative metaheuristic techniques for temperature control in a didactic control plant trainer to validate the effectiveness of the proposed method. Experimental results on non-linear benchmark processes demonstrate that the proposed approach achieves superior results in transient behavior, overshoot reduction, and disturbance rejection, highlighting its potential for advanced process control applications.

KW - Artificial Bee Colony Algorithm

KW - Nonlinear PID

KW - Optimization

UR - https://www.scopus.com/pages/publications/105030322937

U2 - 10.1109/ColCACI67437.2025.11230900

DO - 10.1109/ColCACI67437.2025.11230900

M3 - Artículo de la conferencia

AN - SCOPUS:105030322937

SN - 2769-3651

JO - IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI

JF - IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI

IS - 2025

T2 - 2025 IEEE Colombian Conference on Applications of Computational Intelligence, ColCACI 2025

Y2 - 27 August 2025 through 29 August 2025

ER -

Optimizing Non-linear PID Control with Artificial Bee Colony for Temperature Regulation in a Control Plant Trainer

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