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1	Μέτρηση και μοντελοποίηση του ηλεκτρονικού θορύβου σε ημιαγωγικές διατάξεις τεχνολογίας CMOS και BiCMOS Τριάντης, Δημήτριος 18 November 2009 (has links) - / - Θόρυβος Τρανζίστορς CMOS VLSI 621.381 528 Noise Transistors CMOS VLSI
2	Εκτίμηση και βελτιστοποίηση κατανάλωσης ισχύος ψηφιακών κυκλωμάτων Θεοχάρης, Σπύρος 27 November 2009 (has links) - / - Ψηφιακά κυκλώματα 621.397 32 Digital circuits CMOS VLSI
3	High Speed Circuit Design Based on a Hybrid of Conventional and Wave Pipelining Sulistyo, Jos Budi 03 October 2005 (has links) The increasing capabilities of multimedia appliances demand arithmetic circuits with higher speed and reasonable power dissipation. A common technique to attain those goals is synchronous pipelining, which increases the throughput of a circuit at the expense of longer latency, and it is therefore suitable where throughput takes priority over latency. Two synchronous pipelining approaches, conventional pipelining and wave pipelining, are commonly employed. Conventional pipelining uses registers to divide the circuit into shorter paths and synchronize among sub-blocks, while wave pipelining uses the delay of combinational elements to perform those tasks. As wave pipelining does not introduce additional registers, in principle, it can attain a higher throughput and lower power consumption. However, its throughput is limited by delay variations, while delay balancing often leads to increased power dissipation. This dissertation proposes a hybrid pipelining method called HyPipe, which divides the circuit into sub-blocks using conventional pipelining, and applies wave pipelining to each sub-block. Each sub-block is derived from a single base circuit, leading to a better delay balance and greater throughput than with heterogeneous circuits. Another requirement for wave pipelining to achieve high speed is short signal rise and fall times. Since CMOS wide-NAND and wide-NOR gates exhibit long rise and fall times and large delay variations, they should be decomposed. We show that the straightforward decomposition using alternating levels of NAND and NOR gates results in large delay variations. Therefore, we propose a new decomposition method using only one gate type. Our method reduces delay variations by up to 39%, and it is appropriate for wave pipelining based on standard-cells or sea-of-gates. We laid out a 4x4 HyPipe multiplier as a proof of concept and performed a post-layout SPICE simulation. The multiplier achieves a throughput of 4.17 billion multiplications per second or a clock period of 2.52 four-load inverter delays, which is almost twice the speed of any existing multiplier in the open literature. When the supply voltage is reduced to 1.2 V from 1.8 V, its power consumption is reduced from 76.2 mW to 18.2 mW while performing 2.33 billion multiplications per second. / Ph. D. high-speed CMOS VLSI pipelining wave pipelining arithmetic circuits
4	High-level optimization of performance and power in very deep sub-micron interconnects Murgan, Tudor. Unknown Date (has links) (PDF) Darmstadt, Techn. University, Diss., 2006.
5	Μεθοδολογίες απεικόνισης αλγορίθμων εμφωλευμένων βρόχων σε VLSI διατάξεις επεξεργαστών Καραγιάννη, Κωνσταντίνα 24 November 2009 (has links) - / - Ψηφιακά κυκλώματα Ψηφιακή επικοινωνία Επεξεργασία σημάτων 621.395 Digital circuits Digital communication Signal processing VLSI CMOS VLSI
6	Ανάπτυξη αναλυτικών μοντέλων χρονικής απόκρισης και κατανάλωσης ενέργειας για στατικά κυκλώματα CMOS Μπισδούνης, Λάμπρος 27 November 2009 (has links) - / - Ψηφιακά κυκλώματα 621.397 32 Digital circuits Integrated circuits VLSI CMOS VLSI
7	Simulace CMOS VLSI obvodů / CMOS VLSI Circuits Simulation Šťastná, Hilda January 2017 (has links) This diploma thesis deals with processes of electrical circuits calculations in the last years' worldwide standards like Dymola, MATLAB, Maple or SPICE applications. Circuits calculations are linked with methods for solving linear differential equations, used in this work also by verification of functionality of designed models for CMOS inverter, CMOS NAND, CMOS NOR. Numerical integration method in combination with Taylor series is a suitable method also for parallel calculations of CMOS VLSI circuits. CMOS circuits simulation was implemented with this method in applications in MATLAB language, solving circuits, represented by differential equations. Functionality of the applications was verified by some real examples. Significant acceleration of calculations using Taylor series compared to other methods is an important factor in choosing methods used in circuit simulations.
8	A STANDARD CELL LIBRARY USING CMOS TRANSCONDUCTANCE AMPLIFIERS FOR CELLULAR NEURAL NETWORKS MAILAVARAM, MADHURI 03 April 2006 (has links) No description available. Cellular Neural Networks CNNs CMOS Transconductance Amplifier Standard Cell Library of CNNS Analog CMOS VLSI Implementation CNN Image Processing Applications
9	Computation with continuous mode CMOS circuits in image processing and probabilistic reasoning Mroszczyk, Przemyslaw January 2014 (has links) The objective of the research presented in this thesis is to investigate alternative ways of information processing employing asynchronous, data driven, and analogue computation in massively parallel cellular processor arrays, with applications in machine vision and artificial intelligence. The use of cellular processor architectures, with only local neighbourhood connectivity, is considered in VLSI realisations of the trigger-wave propagation in binary image processing, and in Bayesian inference. Design issues, critical in terms of the computational precision and system performance, are extensively analysed, accounting for the non-ideal operation of MOS devices caused by the second order effects, noise and parameter mismatch. In particular, CMOS hardware solutions for two specific tasks: binary image skeletonization and sum-product algorithm for belief propagation in factor graphs, are considered, targeting efficient design in terms of the processing speed, power, area, and computational precision. The major contributions of this research are in the area of continuous-time and discrete-time CMOS circuit design, with applications in moderate precision analogue and asynchronous computation, accounting for parameter variability. Various analogue and digital circuit realisations, operating in the continuous-time and discrete-time domains, are analysed in theory and verified using combined Matlab-Hspice simulations, providing a versatile framework suitable for custom specific analyses, verification and optimisation of the designed systems. Novel solutions, exhibiting reduced impact of parameter variability on the circuit operation, are presented and applied in the designs of the arithmetic circuits for matrix-vector operations and in the data driven asynchronous processor arrays for binary image processing. Several mismatch optimisation techniques are demonstrated, based on the use of switched-current approach in the design of current-mode Gilbert multiplier circuit, novel biasing scheme in the design of tunable delay gates, and averaging technique applied to the analogue continuous-time circuits realisations of Bayesian networks. The most promising circuit solutions were implemented on the PPATC test chip, fabricated in a standard 90 nm CMOS process, and verified in experiments. 621.39
10	Device-Circuit Co-Design Employing Phase Transition Materials for Low Power Electronics Ahmedullah Aziz (7025126) 12 August 2019 (has links) <div> <div> <p>Phase transition materials (PTM) have garnered immense interest in concurrent post-CMOS electronics, due to their unique properties such as - electrically driven abrupt resistance switching, hysteresis, and high selectivity. The phase transitions can be attributed to diverse material-specific phenomena, including- correlated electrons, filamentary ion diffusion, and dimerization. In this research, we explore the application space for these materials through extensive device-circuit co-design and propose new ideas harnessing their unique electrical properties. The abrupt transitions and high selectivity of PTMs enable steep (< 60 mV/decade) switching characteristics in Hyper-FET, a promising post-CMOS transistor. We explore device-circuit co-design methodology for Hyper-FET and identify the criterion for material down-selection. We evaluate the achievable voltage swing, energy-delay trade-off, and noise response for this novel device. In addition to the application in low power logic device, PTMs can actively facilitate non-volatile memory design. We propose a PTM augmented Spin Transfer Torque (STT) MRAM that utilizes selective phase transitions to boost the sense margin and stability of stored data, simultaneously. We show that such selective transitions can also be used to improve other MRAM designs with separate read/write paths, avoiding the possibility of read-write conflicts. Further, we analyze the application of PTMs as selectors in cross-point memories. We establish a general simulation framework for cross-point memory array with PTM based <i>selector</i>. We explore the biasing constraints, develop detailed design methodology, and deduce figures of merit for PTM selectors. We also develop a computationally efficient compact model to estimate the leakage through the sneak paths in a cross-point array. Subsequently, we present a new sense amplifier design utilizing PTM, which offers built-in tunable reference with low power and area demand. Finally, we show that the hysteretic characteristics of unipolar PTMs can be utilized to achieve highly efficient rectification. We validate the idea by demonstrating significant design improvements in a <i>Cockcroft-Walton Multiplier, </i>implemented with TS based rectifiers. We emphasize the need to explore other PTMs with high endurance, thermal stability, and faster switching to enable many more innovative applications in the future.</p></div></div> Circuits and Systems Microelectronics and Integrated Circuits Nanoelectronics Nanomaterials Magnetic Tunnel Junction Correlated Materials Insulator-Metal Transition Hyper-FET Phase-FET Sense Amplifier Non-Volatile Memory Ring Oscillator Steep Switching Rectifier Threshold Switching Spintronics MRAM Cross-Point Array X-Point Selector Memory Arrays Boltzmann limit Hysteresis STT MRAM Spin Transfer Torque Monte Carlo Simulation Variation Analysis Emerging Devices Post-CMOS VLSI

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