5,304 research outputs found
A 1.1 nW Energy-Harvesting System with 544 pW Quiescent Power for Next-Generation Implants
This paper presents a nW power management unit (PMU) for an autonomous wireless sensor that sustains itself by harvesting energy from the endocochlear potential (EP), the 70-100 mV electrochemical bio-potential inside the mammalian ear. Due to the anatomical constraints inside the inner ear, the total extractable power from the EP is limited close to 1.1-6.25 nW. A nW boost converter is used to increase the input voltage (30-55 mV) to a higher voltage (0.8-1.1 V) usable by CMOS circuits in the sensor. A pW charge pump circuit is used to minimize the leakage in the boost converter. Furthermore, ultralow-power control circuits consisting of digital implementations of input impedance adjustment circuits and zero current switching circuits along with Timer and Reference circuits keep the quiescent power of the PMU down to 544 pW. The designed boost converter achieves a peak power conversion efficiency of 56%. The PMU can sustain itself, and a duty-cyled ultralow-power load while extracting power from the EP of a live guinea pig. The PMU circuits have been implemented on a 0.18- μm CMOS process.Semiconductor Research Corporation. Focus Center for Circuit and System Solutions (C2S2)Interconnect Focus Center (United States. Defense Advanced Research Projects Agency and Semiconductor Research Corporation)National Institutes of Health (U.S.) (Grant K08 DC010419)National Institutes of Health (U.S.) (Grant T32 DC00038)Bertarelli Foundatio
Vibration-powered sensing system for engine condition monitoring
Condition monitoring is becoming an established technique for managing the maintenance of machinery in transport applications. Vibration energy harvesting allows wireless systems to be powered without batteries, but most traditional generators have been designed to operate at fixed frequencies. The variety of engine speeds (and hence vibration frequencies) in transport applications therefore means that these are not usable. This paper describes the application-driven specification, design and implementation of a novel vibration-powered sensing system for condition monitoring of engines. This demonstrates that, through careful holistic design of the entire system, condition monitoring systems can be powered solely from machine vibration, managing their energy resources and transmitting sensed data wirelessly
Integrated DC-DC boost converters using CMOS silicon on Sapphire Technology
With the recent advancements in semiconductor manufacturing towards smaller, faster and more efficient microelectronic systems, the problems of increasing leakage current and reduced breakdown voltage in bulk-CMOS transistors have become substantial in the sub-100-nanometer era. The Peregrine UltraCMOS Silicon-on-Sapphire (SOS) technology that uses highly-insulating sapphire substrate as insulator was introduced to meet the continually growing need for higher performance RF products. The electrically isolated circuit elements in the UltraCMOS technology lead to increased switching speeds and lower power consumption due to reduced junction and parasitic capacitances. Furthermore, the growing need for high-speed switching applications such as boosting a lower voltage level to a higher one gives the UltraCMOS technology an upper hand over the bulk-CMOS process.
The limitation to using an UltraCMOS transistor is that its maximum drain to source voltage (VDS ) swing is 2.5V. This thesis aims to address this limitation by studying and implementing various stacking techniques in high power switching applications where voltage switching of higher than 2.5V are required. Fully-integrated DC to DC boost converters with switching circuits based on dynamically self-biased stacked transistors are proposed. For high voltage and high power handling, the proposed stacking techniques equally distribute the overall output voltage to less than 2.5V across each stacked transistor in the switch (V DS of 2.5V)
Modeling and Analysis of Power Processing Systems (MAPPS), initial phase 2
The overall objective of the program is to provide the engineering tools to reduce the analysis, design, and development effort, and thus the cost, in achieving the required performances for switching regulators and dc-dc converter systems. The program was both tutorial and application oriented. Various analytical methods were described in detail and supplemented with examples, and those with standardization appeals were reduced into computer-based subprograms. Major program efforts included those concerning small and large signal control-dependent performance analysis and simulation, control circuit design, power circuit design and optimization, system configuration study, and system performance simulation. Techniques including discrete time domain, conventional frequency domain, Lagrange multiplier, nonlinear programming, and control design synthesis were employed in these efforts. To enhance interactive conversation between the modeling and analysis subprograms and the user, a working prototype of the Data Management Program was also developed to facilitate expansion as future subprogram capabilities increase
Wind energy harvester interface for sensor nodes
The research topic is developping a power converting interface for the novel FLEHAP wind energy harvester allowing the produced energy to be used for powering small wireless nodes. The harvester\u2019s electrical characteristics were studied and a strategy was developped to control and mainting a maximum power transfer. The electronic power converter interface was designed, containing an AC/DC Buck-Boost converter and controlled with a low power microcontroller. Different prototypes were developped that evolved by reducing the sources of power loss and rendering the system more efficient. The validation of the system was done through simulations in the COSMIC/DITEN lab using generated signals, and then follow-up experiments were conducted with a controllable wind tunnel in the DIFI department University of Genoa. The experiment results proved the functionality of the control algorithm as well as the efficiency that was ramped up by the hardware solutions that were implemented, and generally met the requirement to provide a power source for low-power sensor nodes
A Biofuel-Cell-Based Energy Harvester With 86% Peak Efficiency and 0.25-V Minimum Input Voltage Using Source-Adaptive MPPT
This article presents an efficient cold-starting energy harvester system, fabricated in 65-nm CMOS. The proposed harvester uses no external electrical components and is compatible with biofuel-cell (BFC) voltage and power ranges. A power-efficient system architecture is proposed to keep the internal circuitry operating at 0.4 V while regulating the output voltage at 1 V using switched-capacitor dc–dc converters and a hysteretic controller. A startup enhancement block is presented to facilitate cold startup with any arbitrary input voltage. A real-time on-chip 2-D maximum power point tracking with source degradation tracing is also implemented to maintain power efficiency maximized over time. The system performs cold startup with a minimum input voltage of 0.39 V and continues its operation if the input voltage degrades to as low as 0.25 V. Peak power efficiency of 86% is achieved at 0.39 V of input voltage and 1.34 μW of output power with 220 nW of average power consumption of the chip. The end-to-end power efficiency is kept above 70% for a wide range of loading powers from 1 to 12 μW. The chip is integrated with a pair of lactate BFC electrodes with 2 mm of diameter on a prototype-printed circuit board (PCB). Integrated operation of the chip with the electrodes and a lactate solution is demonstrated
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Pico-grid: Multiple Multitype Energy Harvesting System
This thesis focuses on the development of a low power energy harvesting system specifically
targeted for wireless sensor nodes (WSN) and wireless body area network (WBAN)
applications. The idea for the system is derived from the operation of a micro-grid and therefore
is termed as a pico-grid and it is capable of simultaneously delivering power from multiple and
multitype energy harvesters to the load at the same time, through the proposed parallel load
sharing mechanism achieved by a voltage droop control method. Solar panels and
thermoelectric generator (TEG) are demonstrated as the main energy harvesters for the system.
Since the magnitude of the output power of the harvesters is time-varying, the droop gain in
the droop feedback circuitry should be designed to be dynamic and self-adjusted according to
this variation. This ensures that the maximum power is capable to be delivered to the load at
all times. To achieve this, the droop gain is integrated with a light dependent resistor (LDR)
and thermistor whose resistance varies with the magnitude of the source of energy for the solar
panel and TEG, respectively. The experimental results demonstrate a successful variation
droop mechanism and all connected sources are able to share equal load demands between
them, with a maximum load sharing error of 5 %. The same mechanism is also demonstrated
to work for maximum power point tracking (MPPT) functionality. This concept can potentially
be extended to any other types of energy harvester.
The integration of energy storage elements becomes a necessity in the pico-grid, in order to
support the intermittent and sporadic nature of the output power for the harvesters. A
rechargeable battery and supercapacitor are integrated in the system, and each is accurately
designed to be charged when the loading in the system is low and discharged when the loading
in the system is high. The dc bus voltage which indicates the magnitude of the loading in the
system is utilised as the signal for the desired mode of operation. The constructed system
demonstrates a successful operation of charging and discharging at specific levels of loading
in the system.
The system is then integrated and the first wearable prototype of the pico-grid is built and
tested. A successful operation of the prototype is demonstrated and the load demand is shared
equally between the source converters and energy storage. Furthermore, the pico-grid is shown to possess an inherent plug-and-play capability for the source and load converters. Few
recommendations are presented in order to further improve the feasibility and reliability of the
prototype for real world applications.
Next, due to the opportunity of working with a new semiconductor compound and accessibility
to the fabrication facilities, a ZnON thin film diode is fabricated and intended to be
implemented as a flexible rectifier circuit. The fabrication process can be done at low
temperature, hence opening up the possibility of depositing the device on a flexible substrate.
From the temperature dependent I-V measurements, a novel method of extracting important
parameters such as ideality factor, barrier height, and series resistance of the diode based on a
curve fitting method is proposed. It is determined that the ideality factor of the fabricated diode
is high (> 2 at RT), due to the existence of other transport mechanism apart from thermionic
emission that dominates the conduction process at lower temperature. It is concluded that the
high series resistance of the fabricated diode (3.8 kΩ at RT) would mainly hinder the
performance of the diode in a rectifier circuit.Yayasan Khazanah & Cambridge Trus
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