TY - JOUR
T1 - A Novel, Software-Defined Control Method Using Sparsely Activated Microcontroller for Low-Power, Multiple-Input, Single-Inductor, Multiple-Output DC-DC Converters to Increase Efficiency
AU - Hosseini, Arya
AU - Badeli, Amin Siahchehreh
AU - Davari, Masoud
AU - Sheikhaei, Samad
AU - Gharehpetian, Gevork B.
N1 - Publisher Copyright:
© 1982-2012 IEEE.
PY - 2023/3/1
Y1 - 2023/3/1
N2 - This article proposes a novel control for the multiple-input, single-inductor, multiple-output dc-dc converters. It is digitally and discretely implemented, which can have an outstanding performance in low-power applications so that at the power of 10 mW, it has an efficiency of 92.5%. Conventionally, in this power range, an attempt is made to take advantage of an analog design that is flexible. Thus, a fully programmable (software designed) converter with digital design using a microcontroller is in great demand. This converter design basis is to deploy the microcontroller's central processing unit (CPU) as little as possible. Also, it only turns on the CPU when necessary to be employed in low-power, portable systems, e.g., energy-harvesting technologies. Therefore, construction costs are significantly reduced. Depending on the energy level of the inputs, they can simultaneously be utilized to charge the outputs. This article uses stability analysis, time-multiplexing control method, and variable-frequency pulsewidth modulation in the proposed control design. Each output can be charged with different frequencies according to its load, and the maximum switching frequency is equal to 10 kHz. Also, the proposed technique for zero-current switching has been digitally implemented; it can be utilized to determine the optimal value of the inductor discharge duty cycle based on the inductor's left-side voltage. Comparative simulations and experimental results reveal the superiority and practicality of the proposed approach.
AB - This article proposes a novel control for the multiple-input, single-inductor, multiple-output dc-dc converters. It is digitally and discretely implemented, which can have an outstanding performance in low-power applications so that at the power of 10 mW, it has an efficiency of 92.5%. Conventionally, in this power range, an attempt is made to take advantage of an analog design that is flexible. Thus, a fully programmable (software designed) converter with digital design using a microcontroller is in great demand. This converter design basis is to deploy the microcontroller's central processing unit (CPU) as little as possible. Also, it only turns on the CPU when necessary to be employed in low-power, portable systems, e.g., energy-harvesting technologies. Therefore, construction costs are significantly reduced. Depending on the energy level of the inputs, they can simultaneously be utilized to charge the outputs. This article uses stability analysis, time-multiplexing control method, and variable-frequency pulsewidth modulation in the proposed control design. Each output can be charged with different frequencies according to its load, and the maximum switching frequency is equal to 10 kHz. Also, the proposed technique for zero-current switching has been digitally implemented; it can be utilized to determine the optimal value of the inductor discharge duty cycle based on the inductor's left-side voltage. Comparative simulations and experimental results reveal the superiority and practicality of the proposed approach.
KW - Multiple-input single-inductor multiple-outputs (MISIMO) dcâ€Â"dc converter
KW - time-multiplexing control
KW - variable-frequency pulsewidth modulation (PWM)
KW - zero-current switching (ZCS)
UR - http://www.scopus.com/inward/record.url?scp=85130433732&partnerID=8YFLogxK
U2 - 10.1109/TIE.2022.3174237
DO - 10.1109/TIE.2022.3174237
M3 - Article
AN - SCOPUS:85130433732
SN - 0278-0046
VL - 70
SP - 2959
EP - 2970
JO - IEEE Transactions on Industrial Electronics
JF - IEEE Transactions on Industrial Electronics
IS - 3
ER -