Analysis and application of improved feedthrough logic

Continuous technology scaling and increased frequency of operation of VLSI circuits leads to increase in power density which raises thermal management problem. Therefore design of low power VLSI circuit technique is a challenging task without sacrificing its performance. This thesis presents the design of a low power dynamic circuit using a new CMOS domino logic family called feedthrough (FTL) logic. Dynamic logic circuits are more significant because of its faster speed and lesser transistor requirement as compared to static CMOS logic circuits. The need for faster circuits compels designers to use FTL as compared static and domino CMOS logic and the requirement of output inverter for cascading of various logic blocks in domino logic are eliminated in the proposed design. The proposed circuit for low power (LP-FTL) improves dynamic power consumption as compared to the existing FTL and to further improve its speed we propose another circuit (HS-FTL). This logic family improves speed at the cost of dynamic power consumption and area. Proposed modified FTL circuit families provide better PDP as compared to the existing FTL. Simulation results of both the proposed circuit using 0.18 µm, 1.8 V CMOS process technology indicate that the LP-FTL structure reduces the dynamic power approximately by 42% and the HS-FTL structure achieves a speed up- 1.4 for 10-stage of inverters and 8-bit ripple carry adder in comparison to existing FTL logic. Furthermore, we present various circuit design techniques to improve noise tolerance of the proposed FTL logic families. Noise in deep submicron technology limits the reliability and performance of ICs. The ANTE (average noise threshold energy) metric is used for the analysis of noise tolerance of proposed FTL. A 2-input NAND and NOR gate is designed by the proposed technique. Simulation results for a 2-input NAND gate at 0.18-µm, 1.8 V CMOS process technology show that the proposed noise tolerant circuit achieves 1.79X ANTE improvement along with the reduction in leakage power. Continuous scaling of technology towards the nanometer range significantly increases leakage current level and the effect of noise. This research can be further extended for performance optimization in terms of power, speed, area and noise immunity

Noise shaping Asynchronous SAR ADC based time to digital converter

Time-to-digital converters (TDCs) are key elements for the digitization of timing information in modern mixed-signal circuits such as digital PLLs, DLLs, ADCs, and on-chip jitter-monitoring circuits. Especially, high-resolution TDCs are increasingly employed in on-chip timing tests, such as jitter and clock skew measurements, as advanced fabrication technologies allow fine on-chip time resolutions. Its main purpose is to quantize the time interval of a pulse signal or the time interval between the rising edges of two clock signals. Similarly to ADCs, the performance of TDCs are also primarily characterized by Resolution, Sampling Rate, FOM, SNDR, Dynamic Range and DNL/INL. This work proposes and demonstrates 2nd order noise shaping Asynchronous SAR ADC based TDC architecture with highest resolution of 0.25 ps among current state of art designs with respect to post-layout simulation results. This circuit is a combination of low power/High Resolution 2nd Order Noise Shaped Asynchronous SAR ADC backend with simple Time to Amplitude converter (TAC) front-end and is implemented in 40nm CMOS technology. Additionally, special emphasis is given on the discussion on various current state of art TDC architectures.Electrical and Computer Engineerin

Analog/RF Circuit Design Techniques for Nanometerscale IC Technologies

CMOS evolution introduces several problems in analog design. Gate-leakage mismatch exceeds conventional matching tolerances requiring active cancellation techniques or alternative architectures. One strategy to deal with the use of lower supply voltages is to operate critical parts at higher supply voltages, by exploiting combinations of thin- and thick-oxide transistors. Alternatively, low voltage circuit techniques are successfully developed. In order to benefit from nanometer scale CMOS technology, more functionality is shifted to the digital domain, including parts of the RF circuits. At the same time, analog control for digital and digital control for analog emerges to deal with current and upcoming imperfections

Current Comparison Domino based CHSK Domino Logic Technique for Rapid Progression and Low Power Alleviation

The proposed domino logic is developed with the combination of Current Comparison Domino (CCD) logic and Conditional High Speed Keeper (CHSK) domino logic. In order to improve the performance metrics like power, delay and noise immunity, the redesign of CHSK is proposed with the CCD. The performance improvement is based on the parasitic capacitance, which reduces on the dynamic node for robust and rapid process of the circuit. The proposed domino logic is designed with keeper and without keeper to measure the performance metrics of the circuit. The outcomes of the proposed domino logic are better when compared to the existing domino logic circuits. The simulation of the proposed CHSK based on the CCD logic circuit is carried out in Cadence Virtuoso tool

Analysis of Dynamic Logic Circuits in Deep Submicron CMOS Technologies

Dynamic logic circuits are utilized to minimize the delay in the critical path of high-performance designs such as the datapath circuits in state-of-the-art microprocessors. However, as integrated circuits (ICs) scale to the very deep submicron (VDSM) regime, dynamic logic becomes susceptible to a variety of failure modes due to decreasing noise margins and increasing leakage currents. The objective of this thesis is to characterize the performance of dynamic logic circuits in VDSM technologies and to evaluate various design strategies to mitigate the effects of leakage currents and small noise margins

Per-Core DVFS with Switched-Capacitor Converters for Energy Efficiency in Manycore Processors

Integrating multiple power converters on-chip improves energy efficiency of manycore architectures. Switched-capacitor (SC) dc-dc converters are compatible with conventional CMOS processes, but traditional implementations suffer from limited conversion efficiency. We propose a dynamic voltage and frequency scaling scheme with SC converters that achieves high converter efficiency by allowing the output voltage to ripple and having the processor core frequency track the ripple. Minimum core energy is achieved by hopping between different converter modes and tuning body-bias voltages. A multicore processor model based on a 28-nm technology shows conversion efficiencies of 90% along with over 25% improvement in the overall chip energy efficiency