Low Power Explicit Pulse Triggered Flip-Flop Design Based On A Pass Transistor

In VLSI system design, power consumption is the ambitious issue for the past respective years. Advanced IC fabrication technology grants the use of nano scaled devices, so the power dissipation becomes major problem in the designing of VLSI chips. In this paper we present, a low-power flip-flop (FF) design featuring an explicit type pulse-triggered structure and a modified true single phase clock latch based on a signal feed-through scheme using pass transistor. The offered design successfully figure out the long discharging path problem in conventional explicit type pulse-triggered FF (P-FF) designs and achieves better power performance by consuming low power. The proposed design also significantly reduces delay time, set-up time and hold time. Simulation results based on TMC 180nm CMOS technology reveal that the proposed design features the best power and delay performance in several FF designs under comparison

Power-efficient high-speed interface circuit techniques

Inter- and intra-chip connections have become the new challenge to enable the scaling of computing systems, ranging from mobile devices to high-end servers. Demand for aggregate I/O bandwidth has been driven by applications including high-speed ethernet, backplane micro-servers, memory, graphics, chip-to-chip and network onchip. I/O circuitry is becoming the major power consumer in SoC processors and memories as the increasing bandwidth demands larger per-pin data rate or larger I/O pin count per component. The aggregate I/O bandwidth has approximately doubled every three to four years across a diverse range of standards in different applications. However, in order to keep pace with these standards enabled in part by process-technology scaling, we will require more than just device scaling in the near future. New energy-efficient circuit techniques must be proposed to enable the next generations of handheld and high-performance computers, given the thermal and system-power limits they start facing. ^ In this work, we are proposing circuit architectures that improve energy efficiency without decreasing speed performance for the most power hungry circuits in high speed interfaces. By the introduction of a new kind of logic operators in CMOS, called implication operators, we implemented a new family of high-speed frequency dividers/prescalers with reduced footprint and power consumption. New techniques and circuits for clock distribution, for pre-emphasis and for driver at the transmitter side of the I/O circuitry have been proposed and implemented. At the receiver side, new DFE architecture and CDR have been proposed and have been proven experimentally

Aika-digitaalimuunnin laajakaistaisiin aikapohjaisiin analogia-digitaalimuuntimiin

Modern deeply scaled semiconductor processes make the design of voltage-domain circuits increasingly challenging. On the contrary, the area and power consumption of digital circuits are improving with every new process node. Consequently, digital solutions are designed in place of their purely analog counterparts in applications such as analog-to-digital (A/D) conversion. Time-based analog-to-digital converters (ADC) employ digital-intensive architectures by processing analog quantities in time-domain. The quantization step of the time-based A/D-conversion is carried out by a time-to-digital converter (TDC). A free-running ring oscillator -based TDC design is presented for use in wideband time-based ADCs. The proposed architecture aims to maximize time resolution and full-scale range, and to achieve error resilient conversion performance with minimized power and area consumptions. The time resolution is maximized by employing a high-frequency multipath ring oscillator, and the full-scale range is extended using a high-speed gray counter. The error resilience is achieved by custom sense-amplifier -based sampling flip-flops, gray coded counter and a digital error correction algorithm for counter sampling error correction. The implemented design achieves up to 9-bit effective resolution at 250 MS/s with 4.3 milliwatt power consumption.Modernien puolijohdeteknologioiden skaalautumisen seurauksena jännitetason piirien suunnittelu tulee entistä haasteellisemmaksi. Toisaalta digitaalisten piirirakenteiden pinta-ala sekä tehonkulutus pienenevät prosessikehityksen myötä. Tästä syystä digitaalisia ratkaisuja suunnitellaan vastaavien puhtaasti analogisien rakenteiden tilalle. Analogia-digitaalimuunnos (A/D-muunnos) voidaan toteuttaa jännitetason sijaan aikatasossa käyttämällä aikapohjaisia A/D-muuntimia, jotka ovat rakenteeltaan pääosin digitaalisia. Kvantisointivaihe aikapohjaisessa A/D-muuntimessa toteutetaan aika-digitaalimuuntimella. Työ esittelee vapaasti oskilloivaan silmukkaoskillaattoriin perustuvan aika-digitaalimuuntimen, joka on suunniteltu käytettäväksi laajakaistaisessa aikapohjaisessa A/D-muuntimessa. Esitelty rakenne pyrkii maksimoimaan muuntimen aikaresoluution sekä muunnosalueen, sekä saavuttamaan virhesietoisen muunnostoiminnan minimoidulla tehon sekä pinta-alan kulutuksella. Aikaresoluutio on maksimoitu hyödyntämällä suuritaajuista monipolkuista silmukkaoskillaattoria, ja muunnosalue on maksimoitu nopealla Gray-koodi -laskuripiirillä. Muunnosprosessin virhesietoisuus on saavutettu toteuttamalla näytteistys herkillä kiikkuelementeillä, hyödyntämällä Gray-koodattua laskuria, sekä jälkiprosessoimalla laskurin näytteistetyt arvot virheenkorjausalgoritmilla. Esitelty muunnintoteutus saavuttaa 9 bitin efektiivisen resoluution 250 MS/s näytetaajuudella ja 4.3 milliwatin tehonkulutuksella

High Speed All Optical Switching and Encryption using Ultrafast Devices

The next generation of fiber-optic communication system demands ultra-high speed data processing and switching components. Conventional electro-optical parts have reached their bottleneck both speed-wise and efficiency-wise. The idea of manipulating high speed data in all-optical domain is gaining more popularity. In this PhD dissertation, I showed the design and performance analysis of two kinds of ultra-fast all-optical latches, Set-Reset latch and D-flip-flop, based on two different schemes: (1) cross gain and phase modulation (XGM and XPM) in quantum dot semiconductor optical amplifiers (QD-SOA) and (2) two-photon absorption (TPA) in bulk semiconductor optical amplifiers. Design and simulation of a scheme to realize high speed all-optical encryption and decryption using key-stream generators and XOR gates based on QD-SOA are included in this dissertation. We also proposed and simulated all-optical Boolean logic functions with improved output quality using binary phase shift keyed signal based on QD-SOA. A fiber ring laser system with charcoal nano-particles as saturable absorber inside the cavity has been designed and experimentally demonstrated. This fiber ring laser system can generate optical pulse train @ 20Gb/s with improved stability and smaller pulse width comparing with the system without nano-particles in the cavity

Testing of leakage current failure in ASIC devices exposed to total ionizing dose environment using design for testability techniques

Due to the advancements in technology, electronic devices have been relied upon to operate under harsh conditions. Radiation is one of the main causes of different failures of the electronics devices. According to the operation environment, the sources of the radiation can be terrestrial or extra-terrestrial. For terrestrial the devices can be used in nuclear reactors or biomedical devices where the radiation is man-made. While for the extra- terrestrial, the devices can be used in satellites, the international space station or spaceships, where the radiation comes from various sources like the Sun. According to the operation environment the effects of radiation differ. These effects falls under two categories, total ionizing dose effect (TID) and single event effects (SEEs). TID effects can be affect the delay and leakage current of CMOS circuits negatively. The affects can therefore hinder the integrated circuits\u27 operation. Before the circuits are used, particularly in critical radiation heavy applications like military and space, testing under radiation must be done to avoid any failures during operation. The standard in testing electronic devices is generating worst case test vectors (WCTVs) and under radiation using these vectors the circuits are tested. However, the generation of these WCTVs have been very challenging so this approach is rarely used for TIDs effects. Design for testability (DFT) have been widely used in the industry for digital circuits testing applications. DFT is usually used with automatic test patterns generation software to generate test vectors against fault models of manufacturer defects for application specific integrated circuit (ASIC.) However, it was never used to generate test vectors for leakage current testing induced in ASICs exposed to TID radiation environment. The purpose of the thesis is to use DFT to identify WCTVs for leakage current failures in sequential circuits for ASIC devices exposed to TID. A novel methodology was devised to identify these test vectors. The methodology is validated and compared to previous non DFT methods. The methodology is proven to overcome the limitation of previous methodologies

Design of a Comparator and an Amplifier in CMOS using standard logic gates

Using standard logic gates in CMOS, or standard-cells, has the advantage of full synthe- sizability, as well as the voltage scalability between technologies. In this work a general pur- pose standard-cell-based voltage comparator and amplifier are presented. The objective is to design a general purpose standard-cell-based comparator and ampli- fier in 130 nm CMOS by optimizing the already existing topologies with the aim of improving some of the specifications of the studied topologies. Various simulation testbenches were made to test the studied topologies of comparators and amplifiers, in which the results were compared. The top performing standard-cell com- parator and amplifier were then modified. After successfully designing the comparator, it was used in the design of an opamp-less Sigma-Delta modulator (ΣΔM). The proposed comparator is an OR-AND-Inverter-based comparator with dual inputs and outputs, achieving a delay of 109 ps, static input offset of 591 μV, and random offset of 10.42 μV, while dissipating 890 μW, when clocked at 1.5 GHz. The proposed amplifier is a single-path three-stage inverter-based operational transcon- ductance amplifier (OTA) with active common-mode feedback loop, achieving a DC gain of 63 dB, 1444 MHz of unity-gain bandwidth, 51º of phase margin while dissipating 1098 μW, considering a load of 1 pF. The proposed comparator was employed in the ΣΔM with a standard-cell based edge- triggered flip-flop. The ΣΔM, with a sampling frequency of 2 MHz and a signal bandwidth of 2.5 kHz, achieved a peak SNDR of 69 dB while dissipating only 136.7 μW.Utilizando portas lógicas básicas em CMOS oferece a vantagem de um circuito comple- tamente sintetizável, tal como o escalamento de tensão entre tecnologias. Neste trabalho são apresentados um comparador de tensão e um amplificador utilizando portas lógicas. O objetivo deste trabalho é desenhar um comparador e um amplificador utilizando por- tas lógicas através do estudo e otimização de topologias já existentes com a finalidade de me- lhoramento de algumas das especificações das mesmas. Foram realizados vários bancos de teste para testar as topologias estudadas de compa- radores e amplificadores, em que os resultados foram comparados. As topologias de compa- radores e amplificadores de portas lógicas com melhor performance foram então modificadas. Após o comparador ter sido projetado com sucesso, foi utilizado na projeção de um modula- dor Sigma-Delta (ΣΔM) opamp-less. O comparador proposto é um OR-AND-Inversor com duas entradas e saídas, que apre- senta um atraso de 109 ps, offset estático na entrada de 591 μV, offset aleatório de 10.42 μV, enquanto dissipando 890 μW, utilizando uma frequência de relógio de 1.5 GHz O amplificador proposto é um amplificador operacional de transcondutância single- path three-stage inverter-based com um loop ativo de realimentação do modo-comum, que apresenta um ganho DC de 63 dB, 1444 MHz de ganho-unitário de largura de banda, 51º de margem de fase e dissipando 1098 μW, considerando uma carga de 1 pF. O comparador proposto foi aplicado no ΣΔM com um flip-flop edge-triggered baseado em portas lógicas. O ΣΔM, com uma frequência de amostragem de 2 MHz e uma largura de banda de 2.5 kHz, apresentou um SNDR máximo de 69 dB enquanto dissipando apenas 136.7 μW

High Performance Logic for Arithmetic Circuits

The objective of this project is to design high performance arithmetic circuits which are faster and have lower power consumption using a new dynamic logic family of CMOS and to analyze its performance for sequential circuits and effects upon cascading. This new dynamic logic family is known as Feedthrough logic. It has two basic structures: high speed (HS0) and low power (LP0). It allows for commencement of evaluation in a computational block before its evaluation phase begins, and quickly performs a final evaluation as soon as the inputs are valid. This dynamic logic family is best suited to arithmetic circuits because the critical path is made of a long chain of cascaded inverting gates. As the major advantage of this logic which is higher speed is observed upon cascading, it’s most suitable for arithmetic circuits. We compare a set of ripple carry adders 4 bit and 16 bit in domino logic with the two basic structures derived. Experimental results have shown that the lower power structure provides for smaller power delay product when compared with domino logic. Certain modifications in the logic style are proposed to optimize the performance when applied to a single ended or double ended flip flops. The effects upon cascading are analyzed by using a 4-bit register. As delay is not propagated in a register circuit or any other synchronous sequential circuit (the circuit being edge triggered), the major advantage of this logic which is observed upon cascading cannot possibly be observed for sequential circuits. So even though the circuit can be optimised by feedthrough logic, this logic is not preferred for sequential circuits. So finally we have carried out the tapeout of 16 bit adder in LP0 using 180 UMC CMOS process flow

An Area Efficient Pulse Triggered Flipflop Design under 90nm CMOS Technology

The choice of flip-flop technologies is an essential importance in design of VLSI integrated circuits for high speed and high performance CMOS circuits. The main objective of this project is to design an area efficient Low-Power Pulse- Triggered flip-flop. It is important to reduce the power dissipation in both clock distribution networks and flip-flops. The comparison of low power pulse triggered flip-flops such as Ep-DCO, MHLFF, ACFF, Ip-DCO, conditional enhancement scheme and signal feed through scheme. Logics are carried out and the best power-performance is obtained. Here simulations are done under 90nm technology and the results are tabulated below. In that signal feed through scheme is showing better output than the other flip-flops compared here