Investigation of a family of dual-output coupled/decoupled switched capacitor converter for low-power applications

Here, accurate transresistance calculations for the coupled case and mathematical modelling are provided for dual input–output switched capacitor converter (SCC). This converter offers two different output voltages and produces 36 voltage conversion ratios. The dual input–output SCC is portable and...

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Bibliographic Details
Published in:IET circuits, devices & systems devices & systems, 2019-05, Vol.13 (3), p.352-360
Main Authors: Subburaj, Vivekanandan, Zhaikhan, Ainur, Jena, Debashisha, Perumal, Parthiban, Mustafa, Yerzhan, Ruderman, Alex
Format: Article
Language:English
Subjects:
accurate transresistance calculations
Alternative energy sources
Capacitors
Circuits
Conversion ratio
coupled decoupled load cases
current 10.0 muA to 100.0 mA
Design specifications
dual input–output SCC
dual-output coupled SCC
dual-output decoupled SCC
dual-output voltages
Efficiency
Electric potential
Energy resources
Inductors
Light emitting diodes
Load resistance
low-power applications
low-power electronics
low-power SCC
Regulation
Renewable resources
Research Article
switched capacitor converter
switching convertors
Voltage
voltage 1.0 V to 10.0 V
voltage conversion ratios
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Description
Summary:Here, accurate transresistance calculations for the coupled case and mathematical modelling are provided for dual input–output switched capacitor converter (SCC). This converter offers two different output voltages and produces 36 voltage conversion ratios. The dual input–output SCC is portable and operates by considering either sources or the combination of both $V_{s1}$Vs1 and $V_{s2}$Vs2 as input sources. The proposed dual input–output SCC has the ability to vary 54 voltage ratios. An efficient low-power SCC is designed for an input voltage range of 1.5–5 V and it gives dual-output voltages of 1–10 V. The proposed converter can operate in both buck and boost modes. The SCC has high drive capability of load current in the range of 10 µA to 100 mA that is adjusted by varying the operating frequency. The accurate equivalent resistance for both coupled and decoupled load cases is found and validated. The results are verified through PSIM simulations and validated experimentally. The mathematical, simulation, and experimental results give excellent proof for proposing the newly designed converter for applications requiring large conversion ratios eliminating inductors.
ISSN:1751-858X
1751-8598
1751-8598
DOI:10.1049/iet-cds.2018.5419