Contents Lithium-ion batteries are generally used in mobile devices, but the voltage range of the battery varies from 2.7 to 4.2V. To provide a mid-3V-range output from the battery, a converter capable of step-up/down-conversion is necessary. For this purpose, non-inverting buck-boost topologies with multimode control [1]–[3] have been widely used. However, they have limited efficiency slightly higher than 90%, which comes from the fact that a main current path always encompasses two switches. To increase the efficiency in the buck mode where the converter operates for most of the usage time, a flying capacitor buck-boost (FCBB) was proposed in [4]. Despite its high power efficiency, it requires large-size LDMOS to endure a large voltage range up to 8V at switching node, resulting in cost inefficiency. Since all these topologies have a common controller that covers both buck and boost modes of operation, compensator design is challenging. Moreover, a non-minimum-phase system of boost operation makes it hard to achieve a fast loop response. this paper, we propose a step-up/down DC-DC converter based on buck operation only over the whole input voltage range, which greatly simplifies the controller design and consequently gives fast response. Furthermore, it achieves high efficiency because of the reduced effective resistance on the main current path.
Abstract:
Lithium-ion batteries are generally used in mobile devices, but the voltage range of the battery varies from 2.7 to 4.2V. To provide a mid-3V-range output from the batter...Show MoreMetadata
Abstract:
Lithium-ion batteries are generally used in mobile devices, but the voltage range of the battery varies from 2.7 to 4.2V. To provide a mid-3V-range output from the battery, a converter capable of step-up/down-conversion is necessary. For this purpose, non-inverting buck-boost topologies with multimode control [1-3] have been widely used. However, they have limited efficiency slightly higher than 90%, which comes from the fact that a main current path always encompasses two switches. To increase the efficiency in the buck mode where the converter operates for most of the usage time, a flying capacitor buck-boost (FCBB) was proposed in [4]. Despite its high power efficiency, it requires large-size LDMOS to endure a large voltage range up to 8V at switching node, resulting in cost inefficiency. Since all these topologies have a common controller that covers both buck and boost modes of operation, compensator design is challenging. Moreover, a non-minimum-phase system of boost operation makes it hard to achieve a fast loop response. In this paper, we propose a step-up/down DC-DC converter based on buck operation only over the whole input voltage range, which greatly simplifies the controller design and consequently gives fast response. Furthermore, it achieves high efficiency because of the reduced effective resistance on the main current path.
Date of Conference: 11-15 February 2018
Date Added to IEEE Xplore: 12 March 2018
ISBN Information:
Electronic ISSN: 2376-8606
Citations are not available for this document.
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Cites in Papers - IEEE (24)
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1.
Jae-Hyun Kim, Yousung Park, Doyoung Kwon, Dae-Hyeon Kim, Dong-Kyu Kim, Sung-Chun Park, Yongjae Lee, Jung-Bong Lee, Hyun-Sik Kim, "A Single-Duty-Cycled Buck-Boost Converter Achieving Low Output Ripple and Seamless Mode Transition", IEEE Journal of Solid-State Circuits, vol.60, no.4, pp.1248-1264, 2025.
2.
Dae-Hyeon Kim, Hyun-Sik Kim, "A Power-Efficient Single-Mode Buck-Boost DC–DC Converter With Bilaterally Symmetrical Hybrid Topology", IEEE Journal of Solid-State Circuits, vol.59, no.12, pp.4137-4149, 2024.
3.
Ji Jin, Yufa Zhou, Weiwei Xu, Lin Cheng, "A 97.3%-Peak-Efficiency Always-Dual-Path Buck-Boost Converter with Single-Mode Operation and Fast Transient Responses", 2024 IEEE Custom Integrated Circuits Conference (CICC), pp.1-2, 2024.
4.
Shuangxing Zhao, Chenchang Zhan, Yan Lu, "8.4 A Fast-Transient 3-Fine-Level Buck-Boost Hybrid DC-DC Converter with Half-Voltage-Stress on All Switches and 98.2% Peak Efficiency", 2024 IEEE International Solid-State Circuits Conference (ISSCC), vol.67, pp.150-152, 2024.
5.
Dae-Hyeon Kim, Hyun-Sik Kim, "8.2 A 96.9%-Peak-Efficiency Bilaterally-Symmetrical Hybrid Buck-Boost Converter Featuring Seamless Single-Mode Operation, Always-Reduced Inductor Current, and the Use of All CMOS Switches", 2024 IEEE International Solid-State Circuits Conference (ISSCC), vol.67, pp.146-148, 2024.
6.
Junyi Ruan, Junmin Jiang, Chenzhou Ding, Kai Yuan, Ka Nang Leung, Xun Liu, "A Li-ion-Battery-Input 1-to-6V-Output Bootstrap-Free Hybrid Buck-or-Boost Converter Without RHP Zero Achieving 97.3% Peak Efficiency 6μs Recovery Time and 1.13μs/V DVS Rate", 2024 IEEE International Solid-State Circuits Conference (ISSCC), vol.67, pp.148-150, 2024.
7.
Caiyu Tong, Zihao Fan, Yuan Gao, "A Li-Ion Battery Input Highly Integrated LED Driver With 96.8% Peak Efficiency and Dual-Color Mixing Capability", IEEE Journal of Solid-State Circuits, vol.59, no.3, pp.794-803, 2024.
8.
Yan Lu, Junwei Huang, Zhiguo Tong, Tingxu Hu, Wen-Liang Zeng, Mo Huang, Xiangyu Mao, Guigang Cai, "An Overview of Hybrid DC–DC Converters: From Seeds to Leaves", IEEE Open Journal of the Solid-State Circuits Society, vol.4, pp.12-24, 2024.
9.
Shuangxing Zhao, Chenchang Zhan, Yan Lu, "A Battery-Input Three-Mode Buck–Boost Hybrid DC–DC Converter With 97.6% Peak Efficiency", IEEE Journal of Solid-State Circuits, vol.59, no.5, pp.1567-1577, 2024.
10.
Caolei Pan, Chenchang Zhan, Rui P. Martins, Chi-Seng Lam, "A Continuous-Output-Current Buck-Boost Converter Without Right-Half-Plane-Zero (RHPZ)", IEEE Transactions on Circuits and Systems I: Regular Papers, vol.70, no.12, pp.4719-4728, 2023.
11.
Si-Yi Li, Sheng Cheng Lee, Sheng-Hsi Hung, Zheng-Lun Huang, Ke-Horng Chen, Kuo-Lin Zheng, Ying-Hsi Lin, Shian-Ru Lin, Tsung-Yen Tsai, "A 4–40 V Wide Input Range Boost Converter With the Protection Re-Cycling Technique for 200 W High Power LiDAR System in a Long-Distance Object Detection", IEEE Journal of Solid-State Circuits, vol.58, no.7, pp.1850-1859, 2023.
12.
Xiaorui Jie, Ronald van Langevelde, Kejun Xia, Lei Chao, Colin C. McAndrew, Qilin Zhang, Matthew Bacchi, Wuxia Li, "Accurate Gate Charge Modeling of HV LDMOS Transistors for Power Circuit Applications", 2023 35th International Conference on Microelectronic Test Structure (ICMTS), pp.1-5, 2023.
13.
Ji Jin, Yufa Zhou, Changjin Chen, Xu Han, Weiwei Xu, Lin Cheng, "30.6 A 98.6%-Peak-Efficiency 1.47A/mm2-Current-Density Buck-Boost Converter with Always Reduced Conduction Loss", 2023 IEEE International Solid-State Circuits Conference (ISSCC), pp.448-450, 2023.
14.
Donghee Cho, Hyungjoo Cho, Sein Oh, Yoontae Jung, Sohmyung Ha, Chul Kim, Minkyu Je, "A High-Efficiency Single-Mode Dual-Path Buck-Boost Converter With Reduced Inductor Current", IEEE Journal of Solid-State Circuits, vol.58, no.3, pp.720-731, 2023.
15.
Arindam Mishra, Wei Zhu, Bernhard Wicht, Valentijn De Smedt, "An All-1.8-V-Switch Hybrid Buck–Boost Converter for Li-Battery-Operated PMICs Achieving 95.63% Peak Efficiency Using a 288-m DCR Inductor", IEEE Transactions on Power Electronics, vol.38, no.3, pp.3444-3454, 2023.
16.
Yong Zhou, Junwen Li, Xun Liu, Yanqi Zheng, Ka Nang Leung, "Bidirectional Buck–Boost Converter With Reduced Power Loss and No Right-Half-Plane Zero", IEEE Transactions on Power Electronics, vol.38, no.2, pp.2127-2142, 2023.
17.
Se-Un Shin, "Research of Dual-Path DC-DC Power Converter", 2022 IEEE International Symposium on Radio-Frequency Integration Technology (RFIT), pp.147-147, 2022.
18.
Van Ha Nguyen, Xuan-Dien Do, Yves Blaquière, Glenn Cowan, "A 3.3 V 0.1–1 A Hybrid Buck-Boost Converter with 85–97 % Power Efficiency Range Highly-Suited for Battery-Powered Devices using Low-Profile High-DCR Inductor", 2022 20th IEEE Interregional NEWCAS Conference (NEWCAS), pp.303-307, 2022.
19.
Donghee Cho, Hyungjoo Cho, Sein Oh, Yoontae Jung, Sohmyung Ha, Chul Kim, Minkyu Je, "A Single-Mode Dual-Path Buck-Boost Converter with Reduced Inductor Current Across All Duty Cases Achieving 95.58% Efficiency at 1A in Boost Operation", 2022 IEEE Custom Integrated Circuits Conference (CICC), pp.1-2, 2022.
20.
Si-Yi Li, Yen-An Lin, Zheng-Lun Huang, Jia-Jyun Lee, Ke-Horng Chen, Ying-Hsi Lin, Shian-Ru Lin, Tsung-Yen Tsai, "A High Conversion Ratio and 97.4% High Efficiency Three-Switch Boost Converter With Duty-Dependent Charge Topology for 1.2-A High Driving Current and 20% Reduction of Inductor DC Current in MiniLED Applications", IEEE Journal of Solid-State Circuits, vol.57, no.6, pp.1877-1887, 2022.
21.
Zhiguo Tong, Peng Cao, Peng Xu, Dehong Lv, Danzhu Lu, Jie He, Zhiliang Hong, "A Charge-Pump-Based SIMO Buck-Boost DC-DC Converter with Three Operation Modes", 2021 IEEE International Symposium on Circuits and Systems (ISCAS), pp.1-4, 2021.
22.
Arindam Mishra, Valentijn De Smedt, "A Novel Hybrid Buck-Boost Converter Topology for Li-ion Batteries with Increased Efficiency", 2020 27th IEEE International Conference on Electronics, Circuits and Systems (ICECS), pp.1-4, 2020.
23.
Jongbeom Baek, Takahiro Nomiyama, Seungchan Park, Young-Ho Jung, Dongsu Kim, Jaeyeol Han, Jun-Suk Bang, Yumi Lee, Ik-Hwan Kim, Ji-Seon Paek, Jongwoo Lee, Thomas Byunghak Cho, "11.7 A Voltage-Tolerant Three-Level Buck-Boost DC-DC Converter with Continuous Transfer Current and Flying Capacitor Soft Charger Achieving 96.8% Power Efficiency and 0.87µs/V DVS Rate", 2020 IEEE International Solid- State Circuits Conference - (ISSCC), pp.202-204, 2020.
24.
Se-Un Shin, Sung-Wan Hong, Hyung-Min Lee, Gyu-Hyeong Cho, "High-Efficiency Hybrid Dual-Path Step-Up DC–DC Converter With Continuous Output-Current Delivery for Low Output Voltage Ripple", IEEE Transactions on Power Electronics, vol.35, no.6, pp.6025-6038, 2020.
