Adaptive Control of Thermoelectric Cooling System with IOT-based Mobile Application
Ammar, H., Ahmed, A., Ahmed, N., Abdelhalim, S. (2025). Adaptive Control of Thermoelectric Cooling System with IOT-based Mobile Application. EKB Journal Management System, (), -. doi: 10.21608/astj.2025.398243.1083
Hossam H Ammar; Ali Ahmed; Nour El-Din Ahmed; Samy Abdelhalim. "Adaptive Control of Thermoelectric Cooling System with IOT-based Mobile Application". EKB Journal Management System, , , 2025, -. doi: 10.21608/astj.2025.398243.1083
Ammar, H., Ahmed, A., Ahmed, N., Abdelhalim, S. (2025). 'Adaptive Control of Thermoelectric Cooling System with IOT-based Mobile Application', EKB Journal Management System, (), pp. -. doi: 10.21608/astj.2025.398243.1083
Ammar, H., Ahmed, A., Ahmed, N., Abdelhalim, S. Adaptive Control of Thermoelectric Cooling System with IOT-based Mobile Application. EKB Journal Management System, 2025; (): -. doi: 10.21608/astj.2025.398243.1083

Adaptive Control of Thermoelectric Cooling System with IOT-based Mobile Application

Advanced Sciences and Technology Journal
Articles in Press, Accepted Manuscript, Available Online from 22 August 2025  XML
Document Type: Original Article
DOI: 10.21608/astj.2025.398243.1083
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Authors
Hossam H Ammar email 1; Ali Ahmed2; Nour El-Din Ahmed2; Samy Abdelhalim2
1University of Hertfordshire
2Cairo University
Abstract
Precise temperature regulation is critical in applications ranging from electronics cooling to medical storage and laboratory systems. Thermoelectric coolers (TECs), operating via the Peltier effect, offer a compact and energy-efficient solution; however, their nonlinear dynamics and susceptibility to external disturbances make stable control challenges. This research presents a novel compact thermoelectric cooling system that not only regulates the cold-side chamber temperature but also actively constrains the hot-side temperature to prevent thermal overload dual-objective control strategy rarely addressed in literature. Uniquely, both temperature setpoints can be configured in real time via a custom mobile application, enabling remote, user-defined thermal management. The system integrates dual DC fans, with a small cold-side fan introducing controlled disturbances to test robustness and a larger hot-side fan for heat dissipation. Continuous feedback from dual temperature sensors is processed using four implemented control strategies—PID, Adaptive PID, Fuzzy Logic, and Fuzzy-Tuned PID, the latter being designed to optimize nonlinear response under varying load conditions. System development follows a V-model methodology, incorporating mathematical modeling, system identification, and both open- and closed loop control design. Experimental results demonstrate that the Fuzzy-Tuned PID consistently maintained cold-side temperature within ±1–2 °C of the setpoint while safeguarding hot-side limits, even under induced disturbances, outperforming conventional controllers in stability and adaptability. This work contributes a flexible, portable, and intelligent TEC-based solution that bridges advanced control theory with embedded hardware and IoT-enabled real-time interaction, offering significant potential for next-generation compact thermal management systems.
Keywords
Thermoelectric cooler; Adaptive Control; Nonlinear Systems; Fuzzy Logic; IOT
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