Identification of a thermal system using continuous linear parameter-varying fractional modelling

“…A multi-step procedure is then implemented (Tóth, 2008): local experiments are first carried out in which the ultracapacitor bias voltage is held constant and the input charging current is excited; local linear time invariant (LTI) continuous fractional models are then estimated based on these sets of local input/output (I/O) measurements and finally, an interpolation phase is performed to derive a final global parameter-dependent model. Such a viewpoint has already been considered in Steinbuch et al (2003), Van Helvoort, Steinbuch, Lambrechts, and van de Molengraft (2004), and Paijmans, Symens, Van Brussel, and Swevers (2008) for motion and robot control or in Gabano and Poinot (2011) for thermal system identification. The resulting LPV fractional model is then validated by comparing the estimated low level voltage provided for different sets of charging or discharging current profiles with the voltage measurements acquired on an available commercial ultracapacitor at any initial bias voltage.…”

LPV continuous fractional modeling applied to ultracapacitor impedance identification

“…A multi-step procedure is then implemented (Tóth, 2008): local experiments are first carried out in which the ultracapacitor bias voltage is held constant and the input charging current is excited; local linear time invariant (LTI) continuous fractional models are then estimated based on these sets of local input/output (I/O) measurements and finally, an interpolation phase is performed to derive a final global parameter-dependent model. Such a viewpoint has already been considered in Steinbuch et al (2003), Van Helvoort, Steinbuch, Lambrechts, and van de Molengraft (2004), and Paijmans, Symens, Van Brussel, and Swevers (2008) for motion and robot control or in Gabano and Poinot (2011) for thermal system identification. The resulting LPV fractional model is then validated by comparing the estimated low level voltage provided for different sets of charging or discharging current profiles with the voltage measurements acquired on an available commercial ultracapacitor at any initial bias voltage.…”

LPV continuous fractional modeling applied to ultracapacitor impedance identification

“…The PRBS technique has previously been applied to thermal systems [17]. The results can be used to assess thermal performance; however, the long time constants and significant noise associated with thermal systems make the PRBS process time consuming.…”

Improved Bandwidth and Noise Resilience in Thermal Impedance Spectroscopy by Mixing PRBS Signals

“…In an analysis of the past ten years of trends and results in the fractional calculus application to dynamic problems of solid mechanics, the method of mechanical system dynamics analysis based on fractional calculus has gradually become one of main methods in the dynamics analysis of engineering [21]. Fractional calculus has been introduced into the various engineering and science domains [22,23], including image processing [24][25][26], thermal systems identification [27,28], biological tissues identification [29][30][31], control theory and application [32][33][34][35][36], signal processing [37,38], path planning [39] and path tracking [40,41], robotics [42,43], mechanical damping [10,44], battery [45,46], mechanics [47,48], diffusion [49,50], chaos [51,52], and others. Therefore, the application of fractional calculus has become a focus of international academic research.…”

Genetic Algorithm-Based Identification of Fractional-Order Systems