Impact of Manufacturing Flow on Yield Losses in Nanoscale Fabrics

Vijayakumar, Priyamvada

01 January 2012

Reliable and scalable manufacturing of nanofabrics entails significant challenges. Scalable nano-manufacturing approaches that employ the use of lithographic masks in conjunction with nanofabrication based on self-assembly have been proposed. A bottom-up fabrication of nanoelectronic circuits is expected to be subject to various defects and identifying the types of defects that may occur during each step of a manufacturing pathway is essential in any attempt to achieve reliable manufacturing. This thesis aims at analyzing the sources of defects in a nano-manufacturing flow and estimating the resulting yield loss. It integrates physical fabric considerations, manufacturing sequences and the resulting defect scenarios. This is in contrast to most current approaches that use conventional defect models and assume constant defect rates without analyzing the manufacturing pathway to determine the sources of defects and their probabilities. The manufacturing pathway will be analyzed for identifying the defects introduced during each manufacturing step in the sequence, followed by yield loss estimation.

Yield Analysis

Nanotechnology

NASIC

Nanowire

Electrical and Computer Engineering

Built-In Fault Masking For Defect Tolerance And Parameter Variation Mitigation In Nano-Processors

Joshi, Prachi

01 January 2011

Nanoscale manufacturing techniques enable very high density nano fabrics but may cause orders of magnitude higher levels of defects and variability than in today‟s CMOS processes. As a result, nanoscale architectures typically introduce redundancy at multiple levels of abstractions to mask faults. Schemes such as Triple Modular Redundancy (TMR) and structural redundancies are tailored to maximize yield but can impact performance significantly. For example, due to increases in circuit fan-in and fan-out, a quadratic performance impact is often projected. In this thesis, we introduce a new class of redundancy schemes called FastTrack, designed to provide fault tolerance but without their negative impact on performance. FastTrack relies on combining non-uniform structural redundancy with uniquely biased nanoscale voters. A variety of such techniques are employed on a Wire Streaming Processor (WISP-0) implemented on the Nanoscale Application Specific Integrated Circuits (NASIC) nanowire fabric. We show that FastTrack schemes can provide 23% higher effective yield than conventional redundancy schemes even at 10% defect rates. Most importantly, the yield improvement is achieved in conjunction with 79% lesser performance impact at 10% defect rate. This is the first redundancy scheme we are aware of to achieve such degree of fault masking without the considerable performance impact of conventional approaches. The same setup is also used to mask the effects of parameter variation. FastTrack techniques show up to 6X performance improvement compared to more traditional redundancy schemes even at higher defect rates. In the absence of defects, a FastTrack scheme can be up to 7X faster than a traditional redundancy scheme.

Nanoprocessors

Defect Tolerance

Parameter Variation

FastTrack

NASIC

Simution Methodology

Electrical and Computer Engineering

Parameter Variation Sensing and Estimation in Nanoscale Fabrics

Zhang, Jianfeng

01 January 2013

Parameter variations introduced by manufacturing imprecision are becoming more influential on circuit performance. This is especially the case in emerging nanoscale fabrics due to unconventional manufacturing steps (e.g., nano-imprint) and aggressive scaling. These parameter variations can lead to performance deterioration and consequently yield loss. Parameter variations are typically addressed pre-fabrication with circuit design targeting worst-case timing scenarios. However, this approach is pessimistic and much of performance benefits can be lost. By contrast, if parameter variations can be estimated post-manufacturing, adaptive techniques or reconfiguration could be used to provide more optimal level of tolerance. To estimate parameter variations during run-time, on-chip variation sensors are gaining in importance because of their easy implementation. In this thesis, we propose novel on-chip variation sensors to estimate variations in physical parameters for emerging nanoscale fabrics. Based on the characteristics of systematic and random variations, two separate sensors are designed to estimate the extent of systematic variations and the statistical distribution of random variations from measured fall and rise times in the sensors respectively. The proposed sensor designs are evaluated through HSPICE Monte Carlo simulations with known variation cases injected. Simulation results show that the estimation error of the systematic-variation sensor is less than 1.2% for all simulated cases; and for the random-variation sensor, the worst-case estimation error is 12.7% and the average estimation error is 8% for all simulations. In addition, to address the placement of on-chip sensors, we calculate sensor area and the effective range of systematic-variation sensor. Then using a processor designed in nanoscale fabrics as a target, an example for sensor placement is introduced. Based on the sensor placement, external noises that may affect the measured fall and rise times of outputs are identified. Through careful analysis, we find that these noises do not deteriorate the accuracy of the systematic-variation sensor, but affect the accuracy of the random-variation sensor. We believe that the proposed on-chip variation sensors in conjunction with post-fabrication compensation techniques would be able to improve system-level performance in nanoscale fabrics, which may be an efficient alternative to making worst-case assumptions on parameter variations in nanoscale designs.

Nanotechnology Fabrication

N3asics: Designing Nanofabrics with Fine-Grained Cmos Integration

Panchapakeshan, Pavan

01 January 2012

Nanoscale-computing fabrics based on novel materials such as semiconductor nanowires, carbon nanotubes, graphene, etc. have been proposed in recent years. These fabrics employ unconventional manufacturing techniques like Nano-imprint lithography or Super-lattice Nanowire Pattern Transfer to produce ultra-dense nano-structures. However, one key challenge that has received limited attention is the interfacing of unconventional/self-assembly based approaches with conventional CMOS manufacturing to build integrated systems. We propose a novel nanofabric approach that mixes unconventional nanomanufacturing with CMOS manufacturing flow and design rules to build a reliable nanowire-CMOS 3-D integrated fabric called N3ASICs with no new manufacturing constraints. In N3ASICs active devices are formed on a dense semiconductor nanowire array and standard area distributed pins/vias, metal interconnects route signals in 3D. The proposed N3ASICs fabric is fully described and thoroughly evaluated at all design levels. Novel nanowire based devices are envisioned and characterized based on 3D physics modeling. Overall N3ASICs fabric design, associated circuits, interconnection approach, and a layer-by-layer assembly sequence for the fabric are introduced. System level metrics such as power, performance, and density for a nanoprocessor design built using N3ASICs were evaluated and compared against a functionally equivalent CMOS design. We show that the N3ASICs version of the processor is 3X denser and 5X more power efficient for a comparable performance than the 16-nm scaled CMOS version without any new/unknown-manufacturing requirement. Systematic yield implications due to mask overlay misalignment have been evaluated. A partitioning approach to build complex circuits has been studied.

NASIC

N3ASIC

nanowires

nano-CMOS hybrid systems

3-D integration

Computer and Systems Architecture

Nanotechnology Fabrication