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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
211

Static Task Scheduling Algorithms Based on Greedy Heuristics for Battery-Powered DVS Systems

TAKADA, Hiroaki, TOMIYAMA, Hiroyuki, ZENG, Gang, YOKOYAMA, Tetsuo 01 October 2010 (has links)
No description available.
212

Design and Analysis of Low-power SRAMs

Sharifkhani, Mohammad January 2006 (has links)
The explosive growth of battery operated devices has made low-power design a priority in recent years. Moreover, embedded SRAM units have become an important block in modern SoCs. The increasing number of transistor count in the SRAM units and the surging leakage current of the MOS transistors in the scaled technologies have made the SRAM unit a power hungry block from both dynamic and static perspectives. Owing to high bitline voltage swing during write operation, the write power consumption is dominated the dynamic power consumption. The static power consumption is mainly due to the leakage current associated with the SRAM cells distributed in the array. Moreover, as supply voltage decreases to tackle the power consumption, the data stability of the SRAM cells have become a major concern in recent years. <br /><br /> To reduce the write power consumption, several schemes such as row based sense amplifying cell (SAC) and hierarchical bitline sense amplification (HBLSA) have been proposed. However, these schemes impose architectural limitations on the design in terms of the number of words on a row. Beside, the effectiveness of these methods is limited to the dynamic power consumption. Conventionally, reduction of the cell supply voltage and exploiting the body effect has been suggested to reduce the cell leakage current. However, variation of the supply voltage of the cell associates with a higher dynamic power consumption and reduced cell data stability. Conventionally qualified by Static Noise Margin (SNM), the ability of the cell to retain the data is reduced under a lower supply voltage conditions. <br /><br /> In this thesis, we revisit the concept of data stability from the dynamic perspective. A new criteria for the data stability of the SRAM cell is defined. The new criteria suggests that the access time and non-access time (recovery time) of the cell can influence the data stability in a SRAM cell. The speed vs. stability trade-off opens new opportunities for aggressive power reduction for low-power applications. Experimental results of a test chip implemented in a 130 <em>nm</em> CMOS technology confirmed the concept and opened a ground for introduction of a new operational mode for the SRAM cells. <br /><br /> We introduced a new architecture; Segmented Virtual Grounding (SVGND) to reduce the dynamic and static power reduction in SRAM units at the same time. Thanks to the new concept for the data stability in SRAM cells, we introduced the new operational mode of Accessed Retention Mode (AR-Mode) to the SRAM cell. In this mode, the accessed SRAM cell can retain the data, however, it does not discharge the bitline. The new architecture outperforms the recently reported low-power schemes in terms of dynamic power consumption, thanks to the exclusive discharge of the bitline and the cell virtual ground. In addition, the architecture reduces the leakage current significantly since it uses the back body biasing in both load and drive transistors. <br /><br /> A 40Kb SRAM unit based on SVGND architecture is implemented in a 130 <em>nm</em> CMOS technology. Experimental results exhibit a remarkable static and dynamic power reduction compared to the conventional and previously reported low-power schemes as expect from the simulation results.
213

Low Power Clock and Data Recovery Integrated Circuits

Ardalan, Shahab 22 October 2007 (has links)
Advances in technology and the introduction of high speed processors have increased the demand for fast, compact and commercial methods for transferring large amounts of data. The next generation of the communication access network will use optical fiber as a media for data transmission to the subscriber. In optical data or chip-to-chip data communication, the continuous received data needs to be converted to discrete data. For the conversion, a synchronous clock and data are required. A clock and data recovery (CDR) circuit recovers the phase information from the data and generates the in-phase clock and data. In this dissertation, two clock and data recovery circuits for Giga-bits per second (Gbps) serial data communication are designed and fabricated in 180nm and 90nm CMOS technology. The primary objective was to reduce the circuit power dissipation for multi-channel data communication applications. The power saving is achieved using low swing voltage signaling scheme. Furthermore, a novel low input swing Alexander phase detector is introduced. The proposed phase detector reduces the power consumption at the transmitter and receiver blocks. The circuit demonstrates a low power dissipation of 340µW/Gbps in 90nm CMOS technology. The CDR is able to recover the input signal swing of 35mVp. The peak-to-peak jitter is 21ps and RMS jitter is 2.5ps. Total core area excluding pads is approximately 0.01mm2.
214

Evaluation of power management strategies on actual multiprocessor platforms

Khan Jadoon, Jabran 25 March 2013 (has links) (PDF)
The purpose of this study is to investigate how power management strategies can be efficiently exploited in actual platforms. Primarily, the challenges in multicore based embedded systems lies in managing the energy expenditure, determining the scheduling behavior and establishing methods to monitor power and energy, so as to meet the demands of the battery life and load requirements. The work presented in this dissertation is a study of low power-aware strategies in the practical world for single and multiprocessor platforms. The approach used for this study is based on representative multiprocessor platforms (real or virtual) to identify the most influential parameters, at hardware as well as application level, unlike many existing works in which these parameters are often underestimated or sometimes even ignored. The work analyzes and compares in detail various experimentations with different power policies based on Dynamic Voltage and Frequency Scaling (DVFS) and Dynamic Power Switching (DPS) techniques, and investigates the conditions at which these policies are effective in terms of energy savings. The results of these investigations reveal many interesting and notable conclusions that can serve as prerequisites for the efficient use of power management strategies. This work also shows the potential of advanced domain specific power strategies compared to real world available strategies that are general purpose based in their majority. Finally, some high level consumption models are derived from the different energy measurement results to let the estimation of power management benefits at early stages of a system development.
215

Low-power 8-bit Pipelined ADC with current mode Multiplying Digital-to-Analog Converter (MDAC)

Shahzad, Khurram January 2009 (has links)
In order to convert the analog information in the digital domain, pipelined analog-to-digital converter (ADC) offers an optimum balance of resolution, speed, power consumption, size and design effort. In this thesis work we design and optimize a 8-bit pipelined ADC for low-power. The ADC has stage resolution of 1.5-bit and employ current mode multiplying analog-to-digital converter (MDAC). The main focus is to design and optimize the MDAC. Based on the analysis of "On current mode circuits" discussed in chapter 2, we design and optimize the MDAC circuit for the best possible effective number of bits (ENOB), speed and power consumption. Each of the first six stages consisting of Sample-and-Hold, 1.5-bit flash ADC and MDAC is realized at the circuit level. The last stage consisting of 2-bit flash ADC is also realized at circuit level. The delay logic for synchronization is implemented in Verilog-A and MATLAB. A first order digital error-correction algorithm is implemented in MATLAB. The design is simulated in UMC 0.18um technology in Cadence environment. The choice of technology is made as the target application for the ADC, 'X-ray Detector System' is designed in the same technology. The simulation results obtained in-term of ENOB and power consumption are satisfactory for the target application.
216

Power Efficient Digital Decimation Filters for Sigma-Delta ADCs

Cederström, Love January 2009 (has links)
The development of integrated circuit technology seen in the last decades has enabled a large variety of battery operated equipment to emerge, such as smallsensors and medical implants. These applications often has low requirements on sampling frequency but require a very low power consumption to achieve a longbattery life. This thesis investigates one aspect of implementing a low power and low frequency analog to digital converter (ADC) using a technique called Sigma Delta-modulation.The Sigma Delta-ADC uses few analog components but instead it requires a digital filter to extract the wanted resolution. It is this filter which is under investigation in this work. To investigate the power consumption under the presumption that the filter would be a custom circuit implemented on-chip, a simplistic approach has been taken. Based on a high-level algorithmic investigation and the fact that it is popularly used together with Sigma Delta-modulators the Cascaded Integrator Comb (CIC) filter was chosen for implementation. The CIC-filter uses only adders and delay elements which is a great advantage when aiming at a low power consumption. The drawback is that this filter has a poor passband which can introduce distortion within the signal band. Using the Spectre simulator provided in the Cadence Virtuoso suite the lowest power consumption achieved was 16 nW, extracting 80 % of the theoretically available resolution.
217

High Level Ultra Low Power Transmitters for the MICS Standard

Eidenvall, Per, Gran, Nils January 2010 (has links)
Today, medical implants such as cardiac pacemakers, neurostimulators, hearing aids anddrug delivery systems are increasinglymore important and frequently used in the health caresystem. This type of devices have historically used inductive coupling as communicationmedium. Newdemands on accessibility and increased performance in technology drives newresearch toward using radio communications. The FCCMICS radio standard are specificallydevoted for implantable devices.Basically all published research on transmitters in this area are using frequency shift keying(FSK) modulation. The purpose of this thesis is to explore the viability of using phase shiftkeying (PSK) modulation in ultra low power transmitters and suggest suitable architectures.
218

Low Power and Area Efficient Semi-Digital PLL Architecture for High Brandwidth Applications

Elangovan, Vivek January 2011 (has links)
The main scope of this thesis is to implement a new architecture of a high bandwidth phase-locked loop (PLL) with a large operating frequency range from 100~MHz to 1~GHz in a 150~$nm$ CMOS process. As PLL is the time-discrete system, the new architecture is mathematically modelled in the z-domain. The charge pump provides a proportionally damped signal, which is unlikely as a resistive or capacitive damping used in the conventional charge pump. The new damping results in a less update jitter and less peaking to achieve the lock frequency and fast locking time of the PLL. The new semi-digital PLL architecture uses $N$ storage cells. The $N$ storage cells is used to store the oscillator tuning information digitally and also enables analogue tuning of the voltage controlled oscillator (VCO). The storage cells outputs are also used for the process voltage temperature compensation. The phase-frequency detector (PFD) and VCO are implemented like a conventional PLL. The bandwidth achieved is 1/4th of the PFD update frequency for all over the operating range from 100~MHz to 1~GHz. The simulation results are also verified with the mathematical modelling. The new architecture also consumes less power and area compared to the conventional PLL.
219

Implementation and Evaluation of Single Filter Frequency Masking Narrow-Band High-Speed Recursive Digital Filters / Implementering och utvärdering av smalbandiga rekursiva digitala frekvensmaskningsfilter för hög hastighet med identiska subfilter

Mohsén, Mikael January 2003 (has links)
In this thesis two versions of a single filter frequency masking narrow-band high-speed recursive digital filter structure, proposed in [1], have been implemented and evaluated considering the maximal clock frequency, the maximal sample frequency and the power consumption. The structures were compared to a conventional filter structure, that was also implemented. The aim was to see if the proposed structure had some benefits when implemented and synthesized, not only in theory. For the synthesis standard cells from AMS csx 0.35 mm CMOS technology were used.
220

Design andImplementation of a Module Generator for Low Power Multipliers

Sun, Kaihong January 2003 (has links)
Multiplication is an important part of real-time system applications. Various hardware parallel multipliers used in such applications have been proposed. However, when the operand sizes of the multipliers and the process technology need to be changed, the existing multipliers have to be redesigned. From the point of library cell reuse, this master thesis work aims at developing a module generator for parallel multipliers with the help of software programs. This generator can be used to create the gate-level schematic for fixed point two's complement number multipliers. Based on the generated schematic, the entire multiplier can be implemented by small manual intervention. This feature can reduce the time of chip design. The design phases consist of the logic, circuit and physical designs. The logic design includes gate-level schematic generation with C and SKILL programs and structural VHDL-code descriptions as well as validation. The circuit and physical design are custom in Cadence and the routing uses automatic place and route tools. To demonstrate the design method, an 18 by 18-bit modified Booth recoded multiplier was implemented in 0.18 µm CMOS process with a supply voltage of 1.2 V and simulated using simulator (Spectre). The number of integrated transistors is 13000 and the active area is 85000 µm2. The postlayout simulation shows the critical path with a delay of 17 ns.

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