Inverse dynamic analysis type of MPPT control strategy in a thermoelectric-solar hybrid energy harvesting system

A. M. Yusop, Ramizi Mohamed, Azah Mohamed

Research output: Contribution to journalArticle

5 Citations (Scopus)

Abstract

This study presents the development of a novel inverse dynamic analysis-maximum power point tracking (IDA-MPPT) scheme in a hybrid energy harvesting system between thermoelectric module (TEM) and solar array (SA). The proposed method initially changes the harvested voltage response from both sources to be the third-order exponential function. This input function selection is based on the capability of this function to stabilize the initial response system and maintain its final position despite a prolonged response time. The mV voltage value from TEM is easily boosted up to nearly 5 V using this method. With this hybridization, the total obtained voltage is doubled to become 9.7 V, which results in a total power of 0.722 W. Furthermore, the method also allows for a fast tracking system, which enables faster voltage boosting and supercapacitor charging. The supercapacitor only requires less than 5 min to complete charging and boost the voltage to almost 5 V. Thus, a satisfactory value is obtained as compared with that of the TEM system with a chosen MPPC board.

Original languageEnglish
Article number7101
Pages (from-to)682-692
Number of pages11
JournalRenewable Energy
Volume86
DOIs
Publication statusPublished - 1 Feb 2016

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Energy harvesting
Dynamic analysis
Electric potential
Exponential functions
Maximum power point trackers
Supercapacitor

Keywords

  • Exponential function
  • Hybrid energy system
  • Input shaping
  • Inverse dynamic
  • MPPT
  • Thermoelectric-solar

ASJC Scopus subject areas

  • Renewable Energy, Sustainability and the Environment

Cite this

Inverse dynamic analysis type of MPPT control strategy in a thermoelectric-solar hybrid energy harvesting system. / Yusop, A. M.; Mohamed, Ramizi; Mohamed, Azah.

In: Renewable Energy, Vol. 86, 7101, 01.02.2016, p. 682-692.

Research output: Contribution to journalArticle

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