18 research outputs found
Ultra-Low-Power Embedded SRAM Design for Battery- Operated and Energy-Harvested IoT Applications
Internet of Things (IoT) devices such as wearable health monitors, augmented reality goggles, home automation, smart appliances, etc. are a trending topic of research. Various IoT products are thriving in the current electronics market. The IoT application needs such as portability, form factor, weight, etc. dictate the features of such devices. Small, portable, and lightweight IoT devices limit the usage of the primary energy source to a smaller rechargeable or non-rechargeable battery. As battery life and replacement time are critical issues in battery-operated or partially energy-harvested IoT devices, ultra-low-power (ULP) system on chips (SoC) are becoming a widespread solution of chip makers’ choice. Such ULP SoC requires both logic and the embedded static random access memory (SRAM) in the processor to operate at very low supply voltages. With technology scaling for bulk and FinFET devices, logic has demonstrated to operate at low minimum operating voltages (VMIN). However, due to process and temperature variation, SRAMs have higher VMIN in scaled processes that become a huge problem in designing ULP SoC cores. This chapter discusses the latest published circuits and architecture techniques to minimize the SRAM VMIN for scaled bulk and FinFET technologies and improve battery life for ULP IoT applications
Yield-Aware Leakage Power Reduction of On-Chip SRAMs
Leakage power dissipation of on-chip static random access memories (SRAMs) constitutes a significant fraction of the total chip power consumption in state-of-the-art microprocessors and system-on-chips (SoCs). Scaling the supply voltage of SRAMs during idle periods is a simple yet effective technique to reduce their leakage power consumption. However, supply voltage scaling also results in the degradation of the cells’ robustness, and thus reduces their capability to retain data reliably. This is
particularly resulting in the failure of an increasing number of cells that are already weakened by excessive process parameters variations and/or manufacturing imperfections in nano-meter technologies. Thus, with technology scaling, it is becoming increasingly challenging to maintain the yield while attempting to reduce the leakage
power of SRAMs. This research focuses on characterizing the yield-leakage tradeoffs and developing novel techniques for a yield-aware leakage power reduction of SRAMs.
We first demonstrate that new fault behaviors emerge with the introduction of a low-leakage standby mode to SRAMs. In particular, it is shown that there are some
types of defects in SRAM cells that start to cause failures only when the drowsy mode is activated. These defects are not sensitized in the active operating mode, and thus escape the traditional March tests. Fault models for these newly observed fault behaviors are developed and described in this thesis. Then, a new low-complexity test algorithm, called March RAD, is proposed that is capable of detecting all the drowsy faults as well as the simple traditional faults.
Extreme process parameters variations can also result in SRAM cells with very weak data-retention capability. The probability of such cells may be very rare in small memory arrays, however, in large arrays, their probability is magnified by the huge number of bit-cells integrated on a single chip. Hence, it is critical also to account for such extremal events while attempting to scale the supply voltage of SRAMs. To estimate the statistics of such rare events within a reasonable computational time, we have employed concepts from extreme value theory (EVT). This has enabled us to accurately model the tail of the cell failure probability distribution versus the supply voltage. Analytical models are then developed to characterize the yield-leakage tradeoffs in large modern SRAMs. It is shown that even a moderate scaling of the supply voltage of large SRAMs can potentially result in significant yield losses, especially in processes with highly fluctuating parameters. Thus, we have investigated the application of fault-tolerance techniques for a more efficient leakage reduction of SRAMs. These techniques allow for a more aggressive voltage scaling by providing tolerance to the failures that might occur during the sleep mode. The results show that in a 45-nm technology, assuming 10% variation in transistors threshold voltage, repairing a 64KB memory using only 8 redundant rows or incorporating single error correcting codes (ECCs) allows for ~90% leakage reduction while incurring only ~1% yield loss. The combination of redundancy and ECC, however, allows to reach the practical limits of leakage reduction in the analyzed benchmark, i.e., ~95%.
Applying an identical standby voltage to all dies, regardless of their specific process parameters variations, can result in too many cell failures in some dies with heavily skewed process parameters, so that they may no longer be salvageable by the employed fault-tolerance techniques. To compensate for the inter-die variations, we
have proposed to tune the standby voltage of each individual die to its corresponding minimum level, after manufacturing. A test algorithm is presented that can be used to identify the minimum applicable standby voltage to each individual memory die. A possible implementation of the proposed tuning technique is also demonstrated. Simulation results in a 45-nm predictive technology show that tuning standby voltage of SRAMs can enhance data-retention yield by an additional 10%−50%, depending on
the severity of the variations
Solid State Circuits Technologies
The evolution of solid-state circuit technology has a long history within a relatively short period of time. This technology has lead to the modern information society that connects us and tools, a large market, and many types of products and applications. The solid-state circuit technology continuously evolves via breakthroughs and improvements every year. This book is devoted to review and present novel approaches for some of the main issues involved in this exciting and vigorous technology. The book is composed of 22 chapters, written by authors coming from 30 different institutions located in 12 different countries throughout the Americas, Asia and Europe. Thus, reflecting the wide international contribution to the book. The broad range of subjects presented in the book offers a general overview of the main issues in modern solid-state circuit technology. Furthermore, the book offers an in depth analysis on specific subjects for specialists. We believe the book is of great scientific and educational value for many readers. I am profoundly indebted to the support provided by all of those involved in the work. First and foremost I would like to acknowledge and thank the authors who worked hard and generously agreed to share their results and knowledge. Second I would like to express my gratitude to the Intech team that invited me to edit the book and give me their full support and a fruitful experience while working together to combine this book
Improved state integrity of flip-flops for voltage scaled retention under PVT variation
Through measurements from 82 test chips, each with a state retention block of 8192 flip-flops, implemented using 65-nm design library, we demonstrate that state integrity of a flip-flop is sensitive to process, voltage, and temperature (PVT) variation. It has been found at 25?C that First Failure Voltage (FFV) of flip-flops varies from die to die, ranging from 245-mV to 315-mV, with 79% of total dies exhibiting single bit failure at FFV, while the rest show multi-bit failure. In terms of temperature variation, it has been found that FFV increases by up to 30-mV with increase in temperature from 25?C to 79?C, demonstrating its sensitivity to temperature variation. This work proposes a PVT-aware state-protection technique to ensure state integrity of flip-flops, while achieving maximum leakage savings. The proposed technique consists of characterization algorithm to determine minimum state retention voltage (MRV) of each die, and employs horizontal and vertical parity for error detection and single bit error correction. In case of error detection, it dynamically adjusts MRV per die to avoid subsequent errors. Silicon results show that at characterized MRV, flip-flop state integrity is preserved, while achieving up to 17.6% reduction in retention voltage across 82-dies
Ultra-low-power SRAM design in high variability advanced CMOS
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2009.Cataloged from PDF version of thesis.Includes bibliographical references (p. 163-181).Embedded SRAMs are a critical component in modern digital systems, and their role is preferentially increasing. As a result, SRAMs strongly impact the overall power, performance, and area, and, in order to manage these severely constrained trade-offs, they must be specially designed for target applications. Highly energy-constrained systems (e.g. implantable biomedical devices, multimedia handsets, etc.) are an important class of applications driving ultra-low-power SRAMs. This thesis analyzes the energy of an SRAM sub-array. Since supply- and threshold-voltage have a strong effect, targets for these are established in order to optimize energy. Despite the heavy emphasis on leakage-energy, analysis of a high-density 256x256 sub-array in 45nm LP CMOS points to two necessary optimizations: (1) aggressive supply-voltage reduction (in addition to Vt elevation), and (2) performance enhancement. Important SRAM metrics, including read/write/hold-margin and read-current, are also investigated to identify trade-offs of these optimizations. Based on the need to lower supply-voltage, a 0.35V 256kb SRAM is demonstrated in 65nm LP CMOS. It uses an 8T bit-cell with peripheral circuit-assists to improve write-margin and bit-line leakage. Additionally, redundancy, to manage the increasing impact of variability in the periphery, is proposed to improve the area-offset trade-off of sense-amplifiers, demonstrating promise for highly advanced technology nodes. Based on the need to improve performance, which is limited by density constraints, a 64kb SRAM, using an offset-compensating sense-amplifier, is demonstrated in 45nm LP CMOS with high-density 0.25[mu]m2 bit-cells.(cont.) The sense-amplifier is regenerative, but non -strobed, overcoming timing uncertainties limiting performance, and it is single-ended, for compatibility with 8T cells. Compared to a conventional strobed sense-amplifier, it achieves 34% improvement in worst-case access-time and 4x improvement in the standard deviation of the access-time.by Naveen Verma.Ph.D
Low energy digital circuit design using sub-threshold operation
Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, February 2006.Includes bibliographical references (p. 189-202).Scaling of process technologies to deep sub-micron dimensions has made power management a significant concern for circuit designers. For emerging low power applications such as distributed micro-sensor networks or medical applications, low energy operation is the primary concern instead of speed, with the eventual goal of harvesting energy from the environment. Sub-threshold operation offers a promising solution for ultra-low-energy applications because it often achieves the minimum energy per operation. While initial explorations into sub-threshold circuits demonstrate its promise, sub-threshold circuit design remains in its infancy. This thesis makes several contributions that make sub-threshold design more accessible to circuit designers. First, a model for energy consumption in sub-threshold provides an analytical solution for the optimum VDD to minimize energy. Fitting this model to a generic circuit allows easy estimation of the impact of processing and environmental parameters on the minimum energy point. Second, analysis of device sizing for sub-threshold circuits shows the trade-offs between sizing for minimum energy and for minimum voltage operation.(cont.) A programmable FIR filter test chip fabricated in 0.18pum bulk CMOS provides measurements to confirm the model and the sizing analysis. Third, a low-overhead method for integrating sub-threshold operation with high performance applications extends dynamic voltage scaling across orders of magnitude of frequency and provides energy scalability down to the minimum energy point. A 90nm bulk CMOS test chip confirms the range of operation for ultra-dynamic voltage scaling. Finally, sub-threshold operation is extended to memories. Analysis of traditional SRAM bitcells and architectures leads to development of a new bitcell for robust sub-threshold SRAM operation. The sub-threshold SRAM is analyzed experimentally in a 65nm bulk CMOS test chip.by Benton H. Calhoun.Ph.D
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Intrinsic Functions for Securing CMOS Computation: Variability, Modeling and Noise Sensitivity
A basic premise behind modern secure computation is the demand for lightweight cryptographic primitives, like identifier or key generator. From a circuit perspective, the development of cryptographic modules has also been driven by the aggressive scalability of complementary metal-oxide-semiconductor (CMOS) technology. While advancing into nano-meter regime, one significant characteristic of today\u27s CMOS design is the random nature of process variability, which limits the nominal circuit design. With the continuous scaling of CMOS technology, instead of mitigating the physical variability, leveraging such properties becomes a promising way. One of the famous products adhering to this double-edged sword philosophy is the Physically Unclonable Functions (PUFs), which extract secret keys from uncontrollable manufacturing variability on integrated circuits (ICs). However, since PUFs take advantage of microscopic process variations, thus many specialized issues including variability, modeling attacks and noise sensitivity need to be considered and addressed.
In this dissertation, we present our recent work on PUF based secure computation from three aspects: variability, modeling and noise sensitivity, which are deemed the foundations of our study. Moreover, we found that the three factors coordinate with each other in our study, for example, the modeling technique can be utilized to improve the unsatisfied reliability caused by noise sensitivity, quantifying the variability can effectively eliminate the impact from noise, and modeling can help with characterizing the physical variability precisely
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In-situ and In-field temperature and transistor BTI sensing techniques with microprocessor level implementation
In modern deep-scaled CMOS technologies, various silicon-related pitfalls present challenges to the long-term performance of microprocessors. Such challenges include (1) local hot spots, which breach the thermal limitations of a microprocessor, and (2) transistor aging, especially NBTI, which degrades transistor threshold voltage, ultimately threatening the reliability of the entire memory block. In previous systems, the dummy circuit was placed next to the subject, where the dummy was frequently analyzed, and the readout was used to infer the condition of the target. Due to rapidly changing ambient conditions (e.g., temperature and voltage) and the potential scale of the target dimensions, such metrics may not accurately represent the condition of the target. Moreover, such temperature sensors and canary circuits occupy a significant area.
Therefore, it would be highly preferable to monitor the target circuit in-situ, i.e., to sense the precise transistor at operation. It is also important to achieve an accurate sensing metric. When the temperature is analyzed, the readout should account for voltage and process variations. While sensing the aging degradation, the readout should account for voltage and temperature fluctuations. This would allow testing during in-field operation, while the circuits achieve area-efficiency.
This research had two stages. One result of the first stage was a silicon test chip that was a compact temperature sensor. It involved a family of PTAT+CTAT sensor front-ends that unitized only 6 to 8 conventional CMOS logic devices, yielding a smaller sized chip. The sensor demonstrates accuracy within the target and achieves a 14.3x smaller foot print than preceding published designs. The second product of the first stage was a PMOS aging sensor used in 6T SRAM circuits. The test chip has a real SRAM array, integrated with the proposed PMOS NBTI sensor. It can sense real PMOS NBTI effects in any bit cell (in-situ) and provide robust readings of temperature and voltage (in-field). Intensive aging tests validated the proposed sensing technique.
The second stage was focused on implementing the in-situ and in-field sensing techniques in a real processor. The MIPS microprocessor had a modified instruction cache (I$) and instruction set architecture. With the addition of new instruction aging sensing and minor modification of the circuits, the processor can execute aging sensing opportunistically to evaluate the aging level of its instruction cache. A software framework was developed and verified to estimate the retention voltage of the instruction cache over the lifetime of the chip.
An area-efficient SoC was developed that could transform the instruction cache into an ambient temperature sensor. It had a physically unclonable function (PUF), and it was built with an area-saving technique similar to the earlier work.
This thesis has four chapters. They are presented in chronological and they are aligned with the research described above