Time‐multiplexed hysteretic control for single‐inductor dual‐input single‐output DC‐DC power converter
Summary Single‐inductor multi‐input single‐output (SI‐MISO) switching DC‐DC power converter architecture is a cost effective solution to applications where multiple input sources are required to be managed with a limited space and cost. This paper presents a new time‐multiplexed hysteretic control (...
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Veröffentlicht in: | International journal of circuit theory and applications 2022-04, Vol.50 (4), p.1235-1249 |
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Format: | Artikel |
Sprache: | eng |
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Single‐inductor multi‐input single‐output (SI‐MISO) switching DC‐DC power converter architecture is a cost effective solution to applications where multiple input sources are required to be managed with a limited space and cost. This paper presents a new time‐multiplexed hysteretic control (TMHC) scheme for SI‐DISO topology to decouple the power sharing among two input sources. Unlike previously reported solutions with discontinuous conduction or pseudo‐continuous conduction operation of the inductor, this paper focuses on how to keep the inductor current in a continuous conduction mode (CCM) and proposed a control scheme with considerably lower ripple current with fast transition time upon switching and higher efficiency. The mathematical proof using the expressions of inductor ripple current, comparison between efficiency and transition time from one level to other, is derived. Additionally, a low‐cost analog circuitry has been implemented to incorporate the proposed control scheme. Experimental results from the hardware prototype are given to verify the proposed control scheme.
This paper presents a new time‐multiplexed hysteretic control (TMHC) scheme for SI‐DISO topology to decouple the power‐sharing among two input sources in continuous conduction mode (CCM). The mathematical proof using the expressions of inductor ripple current, comparison between efficiency and transition time from one level to other, is derived. Additionally, a low‐cost analog circuitry has been implemented to incorporate the proposed control scheme. |
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ISSN: | 0098-9886 1097-007X |
DOI: | 10.1002/cta.3199 |