The PaTH (University of Pittsburgh/UPMC, Penn State College of Medicine, Temple University Hospital, and Johns Hopkins University) clinical data research network initiative is a collaborative effort among four academic health centers in the Mid-Atlantic region. PaTH will provide robust infrastructure to conduct research, explore clinical outcomes, link with biospecimens, and improve methods for sharing and analyzing data across our diverse populations. Our disease foci are idiopathic pulmonary fibrosis, atrial fibrillation, and obesity. The four network sites have extensive experience in using data from electronic health records and have devised robust methods for patient outreach and recruitment. The network will adopt best practices by using the open-source data-sharing tool, Informatics for Integrating Biology and the Bedside (i2b2), at each site to enhance data sharing using centrally defined common data elements, and will use the Shared Health Research Information Network (SHRINE) for distributed queries across the network.
The limiting factor for high-performance systems is being set by interconnection delay rather than transistor switching speed. The advances in circuits speed and density are placing increasing demands on the performance of interconnections, for example chip-to-chip interconnection on multichip modules. To address this extremely important and timely research area, we analyze in this paper the circuit property of a generic distributed RLC tree which models interconnections in high-speed IC chips. The presented result can be used to calculate the waveform and delay in an RLC tree. The result on the RLC tree is then extended to the case of a tree consisting of transmission lines. Based on an analytical approach a two-pole circuit approximation is presented to provide a closed form solution. The approximation reveals the relationship between circuit performance and the design parameters which is essential to IC layout designs. A simplified formula is derived to evaluate the performance of VLSI layout.
Abstract. The limiting factor for high-performance systems is being set by interconnection delay rather than transistor switching speed. The advances in circuits speed and density are placing increasing demands on the performance of interconnections, for example chip-to-chip interconnection on multichip modules. To address this extremely important and timely research area, we analyze in this paper the circuit property of a generic distributed RLC tree which models interconnections in high-speed IC chips. The presented result can be used to calculate the waveform and delay in an RLC tree. The result on the RLC tree is then extended to the case of a tree consisting of transmission lines. Based on an analytical approach a two-pole circuit approximation is presented to provide a closed form solution. The approximation reveals the relationship between circuit performance and the design parameters which is essential to IC layout designs. A simplified formula is derived to evaluate the performance of VLSI layout.
Cohesion has been a topic of interest since structured design in the 1970’s. Cohesion may also be viewed as a characterization of a system attribute. Today, there are numerous researchers continuing this work into object-oriented designs. Most of the current research has focused on the interaction of methods within a class, the inter-method cohesion. In this paper, we consider both the inter-method cohesion and the intra-method cohesion of a class. We have utilized the concept of program slice (Weiser, 1981) and have extended Functional Cohesion (Bieman & Ott, 1994) to devise a new intra-method cohesion metric, ITRA-C, for measuring cohesion of each method within the class. This intra-method cohesion is based on the notion of effects and chaining in an effect-slice. We further combine the (inter-method, intra-method)-tuple into one combined Class Cohesion, which provides a quick view of bands of cohesion for categorizing classes.
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