2,339 research outputs found
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Near-Zero-Power Temperature Sensing via Tunneling Currents Through Complementary Metal-Oxide-Semiconductor Transistors.
Temperature sensors are routinely found in devices used to monitor the environment, the human body, industrial equipment, and beyond. In many such applications, the energy available from batteries or the power available from energy harvesters is extremely limited due to limited available volume, and thus the power consumption of sensing should be minimized in order to maximize operational lifetime. Here we present a new method to transduce and digitize temperature at very low power levels. Specifically, two pA current references are generated via small tunneling-current metal-oxide-semiconductor field effect transistors (MOSFETs) that are independent and proportional to temperature, respectively, which are then used to charge digitally-controllable banks of metal-insulator-metal (MIM) capacitors that, via a discrete-time feedback loop that equalizes charging time, digitize temperature directly. The proposed temperature sensor was integrated into a silicon microchip and occupied 0.15 mm2 of area. Four tested microchips were measured to consume only 113 pW with a resolution of 0.21 °C and an inaccuracy of ±1.65 °C, which represents a 628× reduction in power compared to prior-art without a significant reduction in performance
Design and analysis of SRAMs for energy harvesting systems
PhD ThesisAt present, the battery is employed as a power source for wide varieties of microelectronic systems ranging from biomedical implants and sensor net-works to portable devices. However, the battery has several limitations and incurs many challenges for the majority of these systems. For instance, the design considerations of implantable devices concern about the battery from two aspects, the toxic materials it contains and its lifetime since replacing the battery means a surgical operation. Another challenge appears in wire-less sensor networks, where hundreds or thousands of nodes are scattered around the monitored environment and the battery of each node should be maintained and replaced regularly, nonetheless, the batteries in these nodes do not all run out at the same time.
Since the introduction of portable systems, the area of low power designs has witnessed extensive research, driven by the industrial needs, towards the aim of extending the lives of batteries. Coincidentally, the continuing innovations in the field of micro-generators made their outputs in the same range of several portable applications. This overlap creates a clear oppor-tunity to develop new generations of electronic systems that can be powered, or at least augmented, by energy harvesters. Such self-powered systems benefit applications where maintaining and replacing batteries are impossi-ble, inconvenient, costly, or hazardous, in addition to decreasing the adverse effects the battery has on the environment.
The main goal of this research study is to investigate energy harvesting aware design techniques for computational logic in order to enable the capa-
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bility of working under non-deterministic energy sources. As a case study, the research concentrates on a vital part of all computational loads, SRAM, which occupies more than 90% of the chip area according to the ITRS re-ports.
Essentially, this research conducted experiments to find out the design met-ric of an SRAM that is the most vulnerable to unpredictable energy sources, which has been confirmed to be the timing. Accordingly, the study proposed a truly self-timed SRAM that is realized based on complete handshaking protocols in the 6T bit-cell regulated by a fully Speed Independent (SI) tim-ing circuitry. The study proved the functionality of the proposed design in real silicon. Finally, the project enhanced other performance metrics of the self-timed SRAM concentrating on the bit-line length and the minimum operational voltage by employing several additional design techniques.Umm Al-Qura University, the Ministry of Higher Education in the Kingdom of Saudi Arabia, and the Saudi Cultural Burea
Wide-Supply-Range All-Digital Leakage Variation Sensor for On-Chip Process and Temperature Monitoring
Variation in process, voltage and temperature is a major obstacle in achieving energy-efficient operation of LSI. This paper proposes an all-digital on-chip circuit to monitor leakage current variations of both of the nMOSFET and pMOSFET independently. As leakage current is highly sensitive to threshold voltage and temperature, the circuit is suitable for tracking process and temperature variation. The circuit uses reconfigurable inhomogeneity to obtain statistical properties from a single monitor instance. A compact reconfigurable inverter topology is proposed to implement the monitor circuit. The compact and digital nature of the inverter enables cell-based design, which will reduce design costs. Measurement results from a 65 nm test chip show the validity of the proposed circuit. For a 124 sample size for both of the nMOSFET and pMOSFET, the monitor area is 4500 μm2 and active power consumption is 76 nW at 0.8 V operation. The proposed technique enables area-efficient and low-cost implementation thus can be used in product chips for applications such as dynamic energy and thermal management, testing and post-silicon tuning
Power management circuit: design and comparison of efficient techniques for ultra-low power analog switch and rectifier circuit
Dissertação de mestrado integrado em Engenharia Eletrónica Industrial e Computadores,
Instrumentação e Microssistemas EletrónicosA presente dissertação de mestrado apresenta um estudo na área de CMOS em circuitos
analógicos/digitais para extração e conversão de potência adequado para aplicações em energy
harvesting.
As principais contribuições científicas deste trabalho são: o desenvolvimento de circuitos de baixo
consumo energético, tais como um interruptor analógico e um retificador que podem extrair e converter
eficientemente a potência de saída do energy harvester. Com os dois circuitos apresentados na presente
dissertação, é possível alimentar um nó de uma rede de sensores sem fios. Estes circuitos foram
projetados utilizando a tecnologia CMOS de 130 nm e as respetivas simulações foram realizadas
utilizando o software Cadence Virtuoso Analog Environment.
Neste trabalho projetou-se novo interruptor analógico para aplicações em energy harvesting com especial
atenção para a obtenção de um baixo consumo energético. A configuração apresentada consegue atingir
uma baixa resistência, quando em condução (ON), e evitar correntes reversas indesejadas provenientes
da carga. Os resultados das simulações revelam que o circuito: consome uma potência de 200.8 nW;
atinge uma baixa resistência, quando em condução, de 216 Ω; gera uma baixa corrente de fuga de 44
pA. Assim sendo, é possível verificar que este circuito consegue operar com um baixo consumo, baixa
tensão e com uma baixa frequência. Para além disso, o mesmo interruptor analógico consegue realizar
a técnica de up-conversion dentro do circuito de controlo de potência, o que indica a possibilidade de o
mesmo contribuir para uma aplicação real com energy harvesters vibracionais.
O retificador em CMOS proposto é constituído por dois estágios: um passivo com um conversor de tensão
negativa; e um outro estágio com um díodo ativo controlado por um circuito de cancelamento de
threshold. O primeiro estágio é responsável por retificar completamente o sinal de entrada com uma
queda de tensão de 1 mV, enquanto que o último tem a função de reduzir a corrente reversa indesejada,
o que consequentemente consegue aumentar a potência transferida para a carga. Deste modo, o circuito
consegue atingir uma eficiência em tensão e potência de 99 % e 90%, respetivamente, para um sinal de
entrada com 0.45 V de amplitude e para cargas resistivas de valor baixo. Ainda assim, este circuito
consegue funcionar a uma banda de frequências desde os 800 Hz até 51.2 kHz, o que se revela ser
promissor para a aplicação prática deste projeto.The master dissertation presents a study in the area of mixed analog/digital CMOS power extraction and
conversion circuits for Power Management Circuit (PMC) suitable for energy harvesting applications.
The main contributions of the work are the development of low power circuits, such as an Analog Switch
and a Rectifier, that can efficiently extract and convert the output power of the vibrational energy harvester
into suitable electric energy for powering a Wireless Sensor Network (WSN) node. The circuit components
were fully designed in the standard 130 nm CMOS process, and the respective simulation experiments
were carried out using the Cadence Virtuoso Analog Environment.
A new Analog Switch was designed for energy harvesting applications with special consideration for
achieving low power consumption. The proposed structure can achieve a reduced ON-resistance and
avoid the reverse leakage current from the load. Simulation results reveal a power consumption of about
200.8 nW, a low ON-resistance of 244.6 Ω, and a low leakage current of around 44 pA, which indicates
that the analog switch has features of low power consumption, low voltage, and low-frequency operation.
Furthermore, this switching circuit is suitable for performing the up-conversion technique in the PMC,
which may contribute to the real application of vibrational energy harvesters.
The proposed CMOS Rectifier consists of two stages, one passive stage with a negative voltage converter,
and another stage with an active diode controlled by a threshold cancellation circuit. The former stage
conducts the signal full-wave rectification with a voltage drop of 1 mV while the latter reduces the reverse
leakage current, consequently enhancing the output power delivered to the ohmic load. As a result, the
rectifier can achieve a voltage and a power conversion efficiency of over 99 % and 90 %, respectively, for
an input voltage of 0.45 V and low ohmic loads. This circuit works for an operating frequency range from
800 Hz to 51.2 kHz, which is promising for practical applications
Ultra low power mixer with out-of-band RF energy harvesting for wireless sensor networks applications
An ultra low power mixer with out-of-band radio frequency (RF) energy harvesting suitable for the wireless sensors network (WSN) application is proposed in this paper. The presented mixer is able to harvest the out-of-band RF energy and keep it working in ultra low power condition and extend the battery life of the WSN. The mixer is designed and simulated with Global Foundries ’ 0.18 μ m CMOS RF process, and it operates at 2.4GHz industrial, scientific, and medical (ISM) band. The Cadence IC Design Tools post-layout simulation results demonstrate that the proposed mixer consumes 248 μ W from a 1V supply voltage. Furthermore, the power consumption can be reduced to 120.8 μ W by the out-of-band RF energy harvesting rectifier
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Variability-aware low-power techniques for nanoscale mixed-signal circuits.
New circuit design techniques that accommodate lower supply voltages necessary for portable systems need to be integrated into the semiconductor intellectual property (IP) core. Systems that once worked at 3.3 V or 2.5 V now need to work at 1.8 V or lower, without causing any performance degradation. Also, the fluctuation of device characteristics caused by process variation in nanometer technologies is seen as design yield loss. The numerous parasitic effects induced by layouts, especially for high-performance and high-speed circuits, pose a problem for IC design. Lack of exact layout information during circuit sizing leads to long design iterations involving time-consuming runs of complex tools. There is a strong need for low-power, high-performance, parasitic-aware and process-variation-tolerant circuit design. This dissertation proposes methodologies and techniques to achieve variability, power, performance, and parasitic-aware circuit designs. Three approaches are proposed: the single iteration automatic approach, the hybrid Monte Carlo and design of experiments (DOE) approach, and the corner-based approach. Widely used mixed-signal circuits such as analog-to-digital converter (ADC), voltage controlled oscillator (VCO), voltage level converter and active pixel sensor (APS) have been designed at nanoscale complementary metal oxide semiconductor (CMOS) and subjected to the proposed methodologies. The effectiveness of the proposed methodologies has been demonstrated through exhaustive simulations. Apart from these methodologies, the application of dual-oxide and dual-threshold techniques at circuit level in order to minimize power and leakage is also explored
Energy-Efficient Wireless Circuits and Systems for Internet of Things
As the demand of ultra-low power (ULP) systems for internet of thing (IoT) applications has been increasing, large efforts on evolving a new computing class is actively ongoing. The evolution of the new computing class, however, faced challenges due to hard constraints on the RF systems. Significant efforts on reducing power of power-hungry wireless radios have been done. The ULP radios, however, are mostly not standard compliant which poses a challenge to wide spread adoption. Being compliant with the WiFi network protocol can maximize an ULP radio’s potential of utilization, however, this standard demands excessive power consumption of over 10mW, that is hardly compatible with in ULP systems even with heavy duty-cycling. Also, lots of efforts to minimize off-chip components in ULP IoT device have been done, however, still not enough for practical usage without a clean external reference, therefore, this limits scaling on cost and form-factor of the new computer class of IoT applications.
This research is motivated by those challenges on the RF systems, and each work focuses on radio designs for IoT applications in various aspects. First, the research covers several endeavors for relieving energy constraints on RF systems by utilizing existing network protocols that eventually meets both low-active power, and widespread adoption. This includes novel approaches on 802.11 communication with articulate iterations on low-power RF systems. The research presents three prototypes as power-efficient WiFi wake-up receivers, which bridges the gap between industry standard radios and ULP IoT radios. The proposed WiFi wake-up receivers operate with low power consumption and remain compatible with the WiFi protocol by using back-channel communication. Back-channel communication embeds a signal into a WiFi compliant transmission changing the firmware in the access point, or more specifically just the data in the payload of the WiFi packet. With a specific sequence of data in the packet, the transmitter can output a signal that mimics a modulation that is more conducive for ULP receivers, such as OOK and FSK. In this work, low power mixer-first receivers, and the first fully integrated ultra-low voltage receiver are presented, that are compatible with WiFi through back-channel communication. Another main contribution of this work is in relieving the integration challenge of IoT devices by removing the need for external, or off-chip crystals and antennas. This enables a small form-factor on the order of mm3-scale, useful for medical research and ubiquitous sensing applications. A crystal-less small form factor fully integrated 60GHz transceiver with on-chip 12-channel frequency reference, and good peak gain dual-mode on-chip antenna is presented.PHDElectrical and Computer EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/162975/1/jaeim_1.pd
Design and Implementation of a Low‐Power Wireless Respiration Monitoring Sensor
Wireless devices for monitoring of respiration activities can play a major role in advancing modern home-based health care applications. Existing methods for respiration monitoring require special algorithms and high precision filters to eliminate noise and other motion artifacts. These necessitate additional power consuming circuitry for further signal conditioning. This dissertation is particularly focused on a novel approach of respiration monitoring based on a PVDF-based pyroelectric transducer. Low-power, low-noise, and fully integrated charge amplifiers are designed to serve as the front-end amplifier of the sensor to efficiently convert the charge generated by the transducer into a proportional voltage signal. To transmit the respiration data wirelessly, a lowpower transmitter design is crucial. This energy constraint motivates the exploration of the design of a duty-cycled transmitter, where the radio is designed to be turned off most of the time and turned on only for a short duration of time. Due to its inherent duty-cycled nature, impulse radio ultra-wideband (IR-UWB) transmitter is an ideal candidate for the implementation of a duty-cycled radio. To achieve better energy efficiency and longer battery lifetime a low-power low-complexity OOK (on-off keying) based impulse radio ultra-wideband (IR-UWB) transmitter is designed and implemented using standard CMOS process. Initial simulation and test results exhibit a promising advancement towards the development of an energy-efficient wireless sensor for monitoring of respiration activities
Design, analysis and implementation of voltage sensor for power-constrained systems
PhD ThesisThanks to an extensive effort by the global research community, the electronic technology has significantly matured over the last decade. This technology has enabled certain operations which humans could not otherwise easily perform. For instance, electronic systems can be used to perform sensing, monitoring and even control operations in environments such as outer space, underground, under the sea or even inside the human body. The main difficulty for electronics operating in these environments is access to a reliable and permanent source of energy. Using batteries as the immediate solution for this problem has helped to provide energy for limited periods of time; however, regular maintenance and replacement are required. Consequently, battery solutions fail wherever replacing them is not possible or operation for long periods is needed. For such cases, researchers have proposed harvesting ambient energy and converting it into an electrical form. An important issue with energy harvesters is that their operation and output power depend critically on the amount of energy they receive and because ambient energy often tends to be sporadic in nature, energy harvesters cannot produce stable or fixed levels of power all of the time. Therefore, electronic devices powered in this way must be capable of adapting their operation to the energy status of the harvester. To achieve this, information on the energy available for use is needed. This can be provided by a sensor capable of measuring voltage. However, stable and fixed voltage and time references are a prerequisite of most traditional voltage measurement devices, but these generally do not exist in energy harvesting environments. A further challenge is that such a sensor also needs to be powered by the energy harvester’s unstable voltage. In this thesis, the design of a reference-free voltage sensor, which can operate with a varying voltage source, is provided based on the capture of a portion of the total energy which is directly related to
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the energy being sensed. This energy is then used to power a computation which quantifies captured energy over time, with the information directly generated as digital code. The sensor was fabricated in the 180 nm technology node and successfully tested by performing voltage measurements over the range 1.8 V to 0.8 V
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