Neurocomputing and Associative Memories Based on Emerging Technologies: Co-optimization of Technology and Architecture

Calayir, Vehbi

01 September 2014

Neurocomputers offer a massively parallel computing paradigm by mimicking the human brain. Their efficient use in statistical information processing has been proposed to overcome critical bottlenecks with traditional computing schemes for applications such as image and speech processing, and associative memory. In neural networks information is generally represented by phase (e.g., oscillatory neural networks) or amplitude (e.g., cellular neural networks). Phase-based neurocomputing is constructed as a network of coupled oscillatory neurons that are connected via programmable phase elements. Representing each neuron circuit with one oscillatory device and implementing programmable phases among neighboring neurons, however, are not clearly feasible from circuits perspective if not impossible. In contrast to nascent oscillatory neurocomputing circuits, mature amplitude-based neural networks offer more efficient circuit solutions using simpler resistive networks where information is carried via voltage- and current-mode signals. Yet, such circuits have not been efficiently realized by CMOS alone due to the needs for an efficient summing mechanism for weighted neural signals and a digitally-controlled weighting element for representing couplings among artificial neurons. Large power consumption and high circuit complexity of such CMOS-based implementations have precluded adoption of amplitude-based neurocomputing circuits as well, and have led researchers to explore the use of emerging technologies for such circuits. Although they provide intriguing properties, previously proposed neurocomputing components based on emerging technologies have not offered a complete and practical solution to efficiently construct an entire system. In this thesis we explore the generalized problem of co-optimization of technology and architecture for such systems, and develop a recipe for device requirements and target capabilities. We describe four plausible technologies, each of which could potentially enable the implementation of an efficient and fully-functional neurocomputing system. We first investigate fully-digital neural network architectures that have been tried before using CMOS technology in which many large-size logic gates such as D flip-flops and look-up tables are required. Using a newly-proposed all-magnetic non-volatile logic family, mLogic, we demonstrate the efficacy of digitizing the oscillators and phase relationships for an oscillatory neural network by exploiting the inherent storage as well as enabling an all-digital cellular neural network hardware with simplified programmability. We perform system-level comparisons of mLogic and 32nm CMOS for both networks consisting of 60 neurons. Although digital implementations based on mLogic offer improvements over CMOS in terms of power and area, analog neurocomputing architectures seem to be more compatible with the greatest portion of emerging technologies and devices. For this purpose in this dissertation we explore several emerging technologies with unique device configurations and features such as mCell devices, ovenized aluminum nitride resonators, and tunable multi-gate graphene devices to efficiently enable two key components required for such analog networks – that is, summing function and weighting with compact D/A (digital-to-analog) conversion capability. We demonstrate novel ways to implement these functions and elaborate on our building blocks for artificial neurons and synapses using each technology. We verify the functionality of each proposed implementation using various image processing applications based on compact circuit simulation models for such post-CMOS devices. Finally, we design a proof-of-concept neurocomputing circuitry containing 20 neurons using 65nm CMOS technology that is based on the primitives that we define for our analog neurocomputing scheme. This allows us to fully recognize the inefficiencies of an all-CMOS implementation for such specific applications. We share our experimental results that are in agreement with circuit simulations for the same image processing applications based on proposed architectures using emerging technologies. Power and area comparisons demonstrate significant improvements for analog neurocomputing circuits when implemented using beyond- CMOS technologies, thereby promising huge opportunities for future energy-efficient computing.

neurocomputing

associative memory

neuromorphic

neural networks

post-CMOS devices

emerging technologies

Statistical Modeling Of Transistor Mismatch Effects In 100nm CMOS Devices

Srinivasaiah, H C

07 1900

No description available.

CMOS Devices

Transistor Mismatch

Electronic Engineering

Evaluation of hydrogen trapping in HfO2 high-κ dielectric thin films.

Ukirde, Vaishali

08 1900

Hafnium based high-κ dielectrics are considered potential candidates to replace SiO2 or SiON as the gate dielectric in complementary metal oxide semiconductor (CMOS) devices. Hydrogen is one of the most significant elements in semiconductor technology because of its pervasiveness in various deposition and optimization processes of electronic structures. Therefore, it is important to understand the properties and behavior of hydrogen in semiconductors with the final aim of controlling and using hydrogen to improve electronic performance of electronic structures. Trap transformations under annealing treatments in hydrogen ambient normally involve passivation of traps at thermal SiO2/Si interfaces by hydrogen. High-κ dielectric films are believed to exhibit significantly higher charge trapping affinity than SiO2. In this thesis, study of hydrogen trapping in alternate gate dielectric candidates such as HfO2 during annealing in hydrogen ambient is presented. Rutherford backscattering spectroscopy (RBS), elastic recoil detection analysis (ERDA) and nuclear reaction analysis (NRA) were used to characterize these thin dielectric materials. It was demonstrated that hydrogen trapping in bulk HfO2 is significantly reduced for pre-oxidized HfO2 prior to forming gas anneals. This strong dependence on oxygen pre-processing is believed to be due to oxygen vacancies/deficiencies and hydrogen-carbon impurity complexes that originate from organic precursors used in chemical vapor depositions (CVD) of these dielectrics.

Thin films.

Dielectrics.

Hafnium.

Hydrogen.

hydrogen

CMOS devices

high-κ dielectric

Robust, Enhanced-Performance SRAMs via Nanoscale CMOS and Beyond-CMOS Technologies

Gopinath, Anoop

12 1900

Indiana University-Purdue University Indianapolis (IUPUI) / In this dissertation, a beyond-CMOS approach to Static Random Access Memory (SRAM) design is investigated using exploratory transistors including Tunnel Field Effect Transistor (TFET), Carbon Nanotube Field Effect Transistor (CNFET) and Graphene NanoRibbon Field Effect Transistor (GNRFET). A Figure-of-Merit (FOM) based comparison of 6-transistor (6T) and a modified 8-transistor (8T) single-port SRAMs designed using exploratory devices, and contemporary devices such as a FinFET and a CMOS process, highlighted the performance benefits of GNRFETs and power benefits of TFETs. The results obtained from the this work show that GNRFET-based SRAM have very high performance with a worst-case memory access time of 27.7 ps for a 16x4-bit 4-word array of 256-bitcells. CNFET-based SRAM bitcell consume the lowest average power during read/write simulations at 3.84 uW, while TFET-based SRAM bitcell show the best overall average and static power consumption at 4.79 uW and 57.8 pW respectively. A comparison of these exploratory devices with FinFET and planar CMOS showed that FinFET-based SRAM bitcell consumed the lowest static power at 39.8 pW and CMOS-based SRAM had the best read, write and hold static noise margins at 201 mV, 438 mV and 413 mV respectively. Further, the modification of 8T-SRAMs via dual wordlines for individually controlling read and write operations for uni-directional transistors TFET and CNFET show improvement in read static noise margin (RSNM). In dual wordline CNFET 8T-SRAM, an RSNM improvement of approximately 23.6x from 6 mV to 142 mV was observed by suppressing the read wordline (RWL) from a nominal supply of 0.71 V down to 0.61 V. In dual wordline TFET 8T-SRAM, an RSNM improvement of approximately 16.2x from 5 mV to 81 mV was observed by suppressing the RWL from a nominal supply of 0.6 V down to 0.3 V. Next, the dissertation explores whether the robustness of SRAM arrays can be improved. Specifically, the robustness related to noise margin during the write operation was investigated by implementing a negative bitline (NBL) voltage scheme. NBL improves the write static noise margin (WSNM) of the SRAM bitcells in the row of the array to which the data is written during a write operation. However, this may cause degraded hold static noise margin (HSNM) of un-accessed cells in the array. Applying a negative wordline voltage (NWL) on un-accessed cells during NBL shows that the NWL can counter the degraded HSNM of un-accessed cells due to NBL. The scheme, titled as NBLWL, also allows the supply of a lower NBL, resulting in higher WSNM and write-ability benefits of accessed row. By applying a complementary negative wordline voltage to counter the half-select condition in columns, the WSNM of cells in accessed rows was boosted by 10.9% when compared to a work where no negative bitline was applied. In addition, the HSNM of un-accessed cells remain the same as in the case where no negative bitline was implemented. Essentially, a 10.9% boost in WSNM without any degradation of HSNM in un-accessed cells is observed. The dissertation also focuses on the impact of process-related variations in SRAM arrays to correlate and characterize silicon data to simulation data. This can help designers remove pessimistic margins that are placed on critical signals to account for expected process variation. Removing these pessimistic margins on critical data paths that dictate the memory access time results in performance benefits for the SRAM array. This is achieved via an in-situ silicon monitor titled SRAM process and ageing sensor (SPAS), which can be used for silicon and ageing characterization, and silicon debug. The SPAS scheme is based on a process variation tolerant technique called RAZOR that compares the data arriving on the output of the sense amplifiers during the read operation. This scheme can estimate the impact of process variation and ageing induced slow-down on critical path during read operation of an array with high accuracy. The estimation accuracy in a commercially available 65nm CMOS technology for a 16x16 array at TT, and global SS and FF corners at nominal supply and testing temperature were found to be 99.2%, 94.9% and 96.5% respectively. Finally, redundant columns, an architectural-level scheme for tolerating failing SRAM bitcells in arrays without compromising performance and yield, is studied. Redundant columns are extra columns that are programmed when bitcells in the regular columns of an array are slower or have higher leakage than expected post-silicon. The regular columns are often permanently disabled and remain unused for the chip lifetime once redundant columns are enabled. In the SRRC scheme proposed in this thesis, the regular columns are only temporarily disabled, and re-used at a later time in chip life cycle once the previously awakened redundant columns become slower than the disabled regular columns. Essentially, the scheme can identify and temporarily disable the slowest column in an array until other mitigating factors slow down active columns. This allows the array to operate at a memory access time closer to the target access time regardless of other mitigating factors slowing down bitcells in arrays during chip life cycle. An approximate 76.4% reduction in memory access time was observed from a 16x16 array from simulations in a commercially available 65nm CMOS technology with respect to a work where no redundancy was employed.

SRAM

Beyond-CMOS devices

Reprogrammable redundancy

Vmin lowering

Negative Bitline

Negative Wordline

Process sensor

Ageing sensor