Decentralized Phase Shedding with Low Power Mode for Multiphase Converter

Marc Cousineau, Martin Monroy, William Lorenzi Pol, Loic Hureau, Guillaume Aulagnier, Philippe Goyhenetche, Eric Rolland and Didier Flumian
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Marc Cousineau: LAPLACE, Department of Electronics, Electrical Energy and Automation, ENSEEIHT Engineering School, University de Toulouse, CNRS, INPT, UPS, 3 Rue Charles Camichel, 31071 Toulouse, France
Martin Monroy: LAPLACE, Department of Electronics, Electrical Energy and Automation, ENSEEIHT Engineering School, University de Toulouse, CNRS, INPT, UPS, 3 Rue Charles Camichel, 31071 Toulouse, France
William Lorenzi Pol: NXP Semiconductors, Division Advanced Power System, 134 Avenue du Général Eisenhower, 31023 Toulouse, France
Loic Hureau: NXP Semiconductors, Division Advanced Power System, 134 Avenue du Général Eisenhower, 31023 Toulouse, France
Guillaume Aulagnier: NXP Semiconductors, Division Advanced Power System, 134 Avenue du Général Eisenhower, 31023 Toulouse, France
Philippe Goyhenetche: NXP Semiconductors, Division Advanced Power System, 134 Avenue du Général Eisenhower, 31023 Toulouse, France
Eric Rolland: NXP Semiconductors, Division Advanced Power System, 134 Avenue du Général Eisenhower, 31023 Toulouse, France
Didier Flumian: LAPLACE, Department of Electronics, Electrical Energy and Automation, ENSEEIHT Engineering School, University de Toulouse, CNRS, INPT, UPS, 3 Rue Charles Camichel, 31071 Toulouse, France

Energies, 2021, vol. 14, issue 20, 1-15

Abstract: With a multiphase converter, the phase-shedding function dedicated to maximizing the power efficiency, in a manner that is dependent on the load current, is always provided by a centralized controller that induces a Single Point of Failure (SPOF). The objective of this study is to obtain a decentralized control approach to implement this function by removing any SPOF. The method consists of using identical local controllers, each associated with a converter phase, that communicate with each other in a daisy-chain structure. Instead of measuring the global output current to determine the optimal number of active phases required, each local controller measures its own leg current and takes a local decision based on threshold crossing management and inter-controller communications. Functional simulations are carried out on a 5-leg 12 V/1.2 V 60 W multiphase converter supplying a modern microcontroller. They demonstrate that the number of active phases is well adjusted, in a dynamic manner, depending on the load current level. Specific events such as load current inrush or the start-up sequence are analyzed to guarantee optimal transient responses. A maximum power efficiency tracking ability is also demonstrated. Finally, it is shown that this control strategy allows phase shedding to be implemented using as many phases as desired, in a modular manner, thereby avoiding any centralized processing.

Keywords: multiphase converter; phase shedding; decentralized control (search for similar items in EconPapers)
JEL-codes: Q Q0 Q4 Q40 Q41 Q42 Q43 Q47 Q48 Q49 (search for similar items in EconPapers)
Date: 2021
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