David Z. Pan scite author profile

This work presents a new multi-chemical experimental platform for molecular communication where the transmitter can release different chemicals. This platform is designed to be inexpensive and accessible, and it can be expanded to simulate different environments including the cardiovascular system and complex network of pipes in industrial complexes and city infrastructures. To demonstrate the capabilities of the platform, we implement a time-slotted binary communication system where a bit-0 is represented by an acid pulse, a bit-1 by a base pulse, and information is carried via pH signals. The channel model for this system, which is nonlinear and has long memories, is unknown. Therefore, we devise novel detection algorithms that use techniques from machine learning and deep learning to train a maximum-likelihood detector. Using these algorithms the bit error rate improves by an order of magnitude relative to the approach used in previous works. Moreover, our system achieves a data rate that is an order of magnitude higher than any of the previous molecular communication platforms.

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Layout Decomposition for Triple Patterning Lithography

Yuan

Ding

et al. 2015

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

100

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As minimum feature size and pitch spacing further scale down, triple patterning lithography is a likely 193 nm extension along the paradigm of double patterning lithography for 14-nm technology node. Layout decomposition, which divides input layout into several masks to minimize the conflict and stitch numbers, is a crucial design step for double/triple patterning lithography. In this paper, we present a systematic study on triple patterning layout decomposition problem, which is shown to be NP-hard. Because of the NP-hardness, the runtime required to exactly solve it increases dramatically with the problem size. We first propose a set of graph division techniques to reduce the problem size. Then, we develop integer linear programming (ILP) to solve it. For large layouts, even with the graph-division techniques, ILP may still suffer from serious runtime overhead. To achieve better trade-off between runtime and performance, we present a novel semidefinite programming (SDP)-based algorithm. Followed by a mapping process, we can translate the SDP solutions into the final decomposition solutions. Experimental results show that the graph division can reduce runtime dramatically. In addition, SDP-based algorithm can achieve great speedup even compared with accelerated ILP, with very comparable results in terms of the stitch number and the conflict number.Index Terms-Graph division, integer linear programming (ILP), layout decomposition, semidefinite programming (SDP), triple patterning lithography (TPL).

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AppSAT: Approximately deobfuscating integrated circuits

Shamsi

Meade

et al. 2017

256

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RADAR: RET-aware detailed routing using fast lithography simulations

Mitra¹,

Yu²,

Pan³

2005

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David Z. Pan

Buffer block planning for interconnect-driven floorplanning

A Novel Experimental Platform for In-Vessel Multi-Chemical Molecular Communications

Layout Decomposition for Triple Patterning Lithography

AppSAT: Approximately deobfuscating integrated circuits

RADAR: RET-aware detailed routing using fast lithography simulations

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