Device scaling limits of Si MOSFETs and their application dependencies

Frank, D.J.; Dennard, R.H.; Nowak, E.; Solomon, P. M.; Taur, Yuan; Wong, Hang

doi:10.1109/5.915374

Cited by 1,269 publications

(571 citation statements)

References 87 publications

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“…For example, device size fluctuations may result in a large spread in device characteristics at the nanoscale, affecting key parameters such as the threshold voltage and on/off currents. The increasing costs associated with lithography equipment and operating facilities needed for traditional manufacturing might also create an economic barrier to continued increases in the capabilities of conventional processor and memory chips [1][2][3] .…”

mentioning

confidence: 99%

“…But as device features are pushed towards the deep sub-100-nm regime, the conventional scaling methods of the semiconductor industry face increasing technological and fundamental challenges [1][2][3] . For example, device size fluctuations may result in a large spread in device characteristics at the nanoscale, affecting key parameters such as the threshold voltage and on/off currents.…”

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confidence: 99%

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Nanoelectronics from the bottom up

2007

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confidence: 99%

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Nanoelectronics from the bottom up

2007

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“…The process technology also plays a significant role for the speed because smaller transistors switch faster. The shrinking effect of transistors can be estimated by the ideas of scaling [58]- [60]. A larger transistor is scaled down by a factor α to attain the corresponding behavior of a smaller transistor.…”

Section: Comparison Of the Nearest Distance Searching Speedmentioning

confidence: 99%

A K-Means-Based Multi-Prototype High-Speed Learning System with FPGA-Implemented Coprocessor for 1-NN Searching

Koide

Mattausch

2012

IEICE Trans. Inf. & Syst.

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SUMMARYIn this paper, we propose a hardware solution for overcoming the problem of high computational demands in a nearest neighbor (NN) based multi-prototype learning system. The multiple prototypes are obtained by a high-speed K-means clustering algorithm utilizing a concept of software-hardware cooperation that takes advantage of the flexibility of the software and the efficiency of the hardware. The one nearest neighbor (1-NN) classifier is used to recognize an object by searching for the nearest Euclidean distance among the prototypes. The major deficiency in conventional implementations for both K-means and 1-NN is the high computational demand of the nearest neighbor searching. This deficiency is resolved by an FPGA-implemented coprocessor that is a VLSI circuit for searching the nearest Euclidean distance. The coprocessor requires 12.9% logic elements and 58% block memory bits of an Altera Stratix III E110 FPGA device. The hardware communicates with the software by a PCI Express (×4) local-bus-compatible interface. We benchmark our learning system against the popular case of handwritten digit recognition in which abundant previous works for comparison are available. In the case of the MNIST database, we could attain the most efficient accuracy rate of 97.91% with 930 prototypes, the learning speed of 1.3 × 10 −4 s/sample and the classification speed of 3.94 × 10 −8 s/character.

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“…For , operates in the weak inversion region while is turned on (strong inversion). The total subthreshold leakage current at steady state is (4) where is the subthreshold leakage current through for . For , and are cutoff.…”

Section: B Stack Effect In Domino Logic Circuitsmentioning

confidence: 99%