http://chineseinput.net/에서 pinyin(병음)방식으로 중국어를 변환할 수 있습니다.
변환된 중국어를 복사하여 사용하시면 됩니다.
A Piezoelectric Energy Harvester with High Efficiency and Low Circuit Complexity
Do, Xuan-Dien,Nguyen, Huy-Hieu,Han, Seok-Kyun,Ha, Dong Sam,Lee, Sang-Gug The Institute of Electronics and Information Engin 2015 Journal of semiconductor technology and science Vol.15 No.3
This paper presents an efficient vibration energy harvester with a piezoelectric (PE) cantilever. The proposed PE energy harvester increases the efficiency through minimization of hardware complexity and hence reduction of power dissipation of the circuit. Two key features of the proposed energy harvester are (i) incorporation synchronized switches with a simple control circuit, and (ii) a feed-forward buck converter with a simple control circuit. The chip was fabricated in $0.18{\mu}m$ CMOS processing technology, and the measured results indicate that the proposed rectifier achieves the efficiency of 77%. The core area of the chip is 0.2 mm2.
A Piezoelectric Energy Harvester with High Efficiency and Low Circuit Complexity
Xuan-Dien Do,Huy-Hieu Nguyen,Seok-Kyun Han,Dong Sam Ha,Sang-Gug Lee 대한전자공학회 2015 Journal of semiconductor technology and science Vol.15 No.3
This paper presents an efficient vibration energy harvester with a piezoelectric (PE) cantilever. The proposed PE energy harvester increases the efficiency through minimization of hardware complexity and hence reduction of power dissipation of the circuit. Two key features of the proposed energy harvester are (i) incorporation synchronized switches with a simple control circuit, and (ii) a feed-forward buck converter with a simple control circuit. The chip was fabricated in 0.18 μm CMOS processing technology, and the measured results indicate that the proposed rectifier achieves the efficiency of 77%. The core area of the chip is 0.2 mm2.
Liao Wu,Xuan-Dien Do,Sang-Gug Lee,Dong Sam Ha IEEE 2017 IEEE transactions on circuits and systems. a publi Vol.64 No.3
<P>This paper presents a piezoelectric energy harvest-which integrates a Synchronized Switch Harvesting on Inductor (SSHI) circuit and an active rectifier. The major design challenge of the SSHI method is flipping the capacitor voltage at optimal times. The proposed SSHI circuit inserts an active diode on each resonant loop, which ensures flipping of the capacitor voltage at optimal times and eliminates the need to tune the switching time. The diodes of the SSHI circuit are also used as a rectifier to further simplify the controller. The key advantage of the proposed circuit is a simple controller, which leads to low power dissipation of the proposed circuit to result in high efficiency. The proposed circuit isself-powered and capable of starting even when the battery is completely drained. The circuit was fabricated in BiCMOS 0.25 mu m technology with a die size of 0.98 x 0.76 mm(2). Measured results indicate that the proposed circuit increases the amount of power harvested from a piezoelectric cantilever by 2.1 times when compared with a full bridge (FB) rectifier and achieves a power conversion efficiency of 85%. The proposed circuit dissipates about 24 mu W while the controller alone only 1.5 mu W.</P>
A Long Reset-Time Power-On Reset Circuit With Brown-Out Detection Capability
Huy-Binh Le,Xuan-Dien Do,Sang-Gug Lee,Seung-Tak Ryu IEEE 2011 IEEE transactions on circuits and systems. a publi Vol.58 No.11
<P>A compact low-power on-chip power-on reset circuit with a brown-out detection capability is presented. With a pico-farad-order on-chip MOS capacitor, a long reset time is achieved. A prototype design implemented in a 0.18-μm CMOS process provides a reset signal with duration of hundreds of milliseconds. The embedded brown-out detection circuit can detect the event, as long as the brown-out duration is longer than the millisecond range. The chip consumes only 1 μA under a 1.8-V supply and occupies a 120 μm × 100 μm active area.</P>