TY - GEN
T1 - 17.7 A 0.03mV/mA Low Crosstalk and 185nA Ultra-Low-Quiescent Single-Inductor Multiple-Output Converter Assisted by 5-Input Operational Amplifier for 94.3% Peak Efficiency and 3.0W Driving Capability
AU - Yang, Tzu Hsien
AU - Wen, Yong Hwa
AU - Ouyang, Yu Jheng
AU - Chiu, Chun Kai
AU - Wu, Bo Kuan
AU - Chen, Ke-Horng
AU - Lin, Ying Hsi
AU - Lin, Shian Ru
AU - Tsai, Tsung Yen
N1 - Publisher Copyright:
© 2021 IEEE.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
PY - 2021/2/13
Y1 - 2021/2/13
N2 - The single-inductor multi-output (SIMO) converter offers the advantage of small size and can provide distributive voltage/current for wearable electronic devices. However, there are still some design challenges to solve. In continuous-conduction-mode (CCM) control, it is difficult to reduce crosstalk between multiple outputs [1- 5]. Any crosstalk will result in excessive or insufficient energy in other outputs, resulting in severe voltage ripple. In the upper left of Fig. 17.7.1, when there is any load change on \mathrm{V}_{O2}, crosstalk will occur at \mathrm{V}_{O1} and \mathrm{V}_{O4}. On the other hand, in the discontinuous-conduction-mode (DCM) control [6, 7], if any one of the multiple outputs changes from light load to heavy load, serious crosstalk occurs due to the extension of the switching period \mathrm{T}_{SW}, as shown in the upper right of Fig. 17.7.1. Although constant frequency control can avoid the expansion of \mathrm{T}_{SW} [8], the limited peak inductor current will reduce the driving capability (\mathrm{I}_{LOAD(MAX)} \quad =100 mA [8]). In this paper, the proposed SIMO converter, shown at the bottom left of Fig. 17.7.1, uses an adaptive switchable CCM and DCM (ASCD) technique that takes advantage of the high driving capability of CCM and the advantage of reducing crosstalk in DCM under light loads. To effectively reduce the crosstalk in CCM (Mode1 in this paper), a 5-input crosstalk-reduction error amplifier (CREA) with a feedback rotator is proposed to reduce the shortcomings of hardware overhead in [1- 10]. For achieving low crosstalk and high driving capability under medium load, the SIMO converter works in a combination of stacked DCM and sequential DCM, which are classified as Mode2 to Mode4 to change the energy distribution path of each output (Fig. 17.7.1 bottom right). Under ultra-light load conditions, the switching cycle \mathrm{T}_{SW} can be extended to reduce switching power loss, and SIMO will enter the ultra-low-power (ULP) mode (Mode5) to further reduce the quiescent current and increase the battery runtime.
AB - The single-inductor multi-output (SIMO) converter offers the advantage of small size and can provide distributive voltage/current for wearable electronic devices. However, there are still some design challenges to solve. In continuous-conduction-mode (CCM) control, it is difficult to reduce crosstalk between multiple outputs [1- 5]. Any crosstalk will result in excessive or insufficient energy in other outputs, resulting in severe voltage ripple. In the upper left of Fig. 17.7.1, when there is any load change on \mathrm{V}_{O2}, crosstalk will occur at \mathrm{V}_{O1} and \mathrm{V}_{O4}. On the other hand, in the discontinuous-conduction-mode (DCM) control [6, 7], if any one of the multiple outputs changes from light load to heavy load, serious crosstalk occurs due to the extension of the switching period \mathrm{T}_{SW}, as shown in the upper right of Fig. 17.7.1. Although constant frequency control can avoid the expansion of \mathrm{T}_{SW} [8], the limited peak inductor current will reduce the driving capability (\mathrm{I}_{LOAD(MAX)} \quad =100 mA [8]). In this paper, the proposed SIMO converter, shown at the bottom left of Fig. 17.7.1, uses an adaptive switchable CCM and DCM (ASCD) technique that takes advantage of the high driving capability of CCM and the advantage of reducing crosstalk in DCM under light loads. To effectively reduce the crosstalk in CCM (Mode1 in this paper), a 5-input crosstalk-reduction error amplifier (CREA) with a feedback rotator is proposed to reduce the shortcomings of hardware overhead in [1- 10]. For achieving low crosstalk and high driving capability under medium load, the SIMO converter works in a combination of stacked DCM and sequential DCM, which are classified as Mode2 to Mode4 to change the energy distribution path of each output (Fig. 17.7.1 bottom right). Under ultra-light load conditions, the switching cycle \mathrm{T}_{SW} can be extended to reduce switching power loss, and SIMO will enter the ultra-low-power (ULP) mode (Mode5) to further reduce the quiescent current and increase the battery runtime.
UR - http://www.scopus.com/inward/record.url?scp=85102366925&partnerID=8YFLogxK
U2 - 10.1109/ISSCC42613.2021.9365976
DO - 10.1109/ISSCC42613.2021.9365976
M3 - Conference contribution
AN - SCOPUS:85102366925
T3 - Digest of Technical Papers - IEEE International Solid-State Circuits Conference
SP - 267
EP - 269
BT - 2021 IEEE International Solid-State Circuits Conference, ISSCC 2021 - Digest of Technical Papers
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2021 IEEE International Solid-State Circuits Conference, ISSCC 2021
Y2 - 13 February 2021 through 22 February 2021
ER -