Flexible Smart Display with Integrated Graphics Rasterizor using Single Grain TFTs

Flexible electronics is a fast emerging market and includes electronics fabricated on flexible substrates, large area displays, low cost and  disposable electronics. Both research and commercial institutions around the world have been trying to develop low temperature processes which will enable fabrication of electronic devices on arbitrary substrates including glass and plastic. While most of these technologies are still in the research phase, many approaches have shown promising results. One such  technology is being developed in DIMES, TU Delft which uses single grain silicon crystals to fabricate Single Grain Thin Film Transistors (SG-TFTs) at plastic compatible temperatures. SG-TFTs and other similar technologies can potentially enable fabricating electronics directly on arbitrary  substrates. This would further enable integration of embedded intelligence in devices that would enhance the current functionalists of displays. This paper is an effort in this direction as it undertakes a study to design a  flexible display with an integrated graphics rasterizor unit. The paper  introduces the novel idea to move parts of the graphics pipeline from the CPU/GPU to the display. This will add intelligence to the display so as to realize a smart-display. The paper proposes several architectures for  implementing a rasterizor unit on smart-display, conceptually fabricated on a flexible substrate using SG-TFT technology. While the transistors  fabricated with SG-TFT and similar technologies are relatively slower than the standard CMOS, this paper proposes and concludes that a tile based system design can potentially result into enhanced system performance

Logical effort based design exploration of 64-bit adders using a mixed dynamic-CMOS/threshold-logic approach

Copyright © 2004 IEEEThis paper presents the design exploration of CMOS 64-bit adders designed using threshold logic gates based on systematic transistor level delay estimation using Logical Effort (LE). The adders are hybrid designs consisting of domino and the recently proposed Charge Recycling Threshold Logic (CRTL). The delay evaluation is based LE modeling of the delay of the domino and CRTL gates. From the initial estimations, we select the 8-bit sparse carry look-ahead/carry-select scheme. Simulations indicate a delay of less than 5 FO4, which is 1.1 FO4 or 17% faster than the nearest domino design.Peter Celinski, Said Al-Sarawi, Derek Abbott, Sorin Cotofana and Stamatis Vassiliadi

Is loss in femorotibial cartilage thickness related to severity of contra-lateral radiographic knee osteoarthritis? – Longitudinal data from the Osteoarthritis Initiative

SummaryObjectiveAnti-catabolic disease modifying drugs (DMOADs) aim to reduce cartilage loss in knee osteoarthritis (KOA). Testing such drugs in clinical trials requires sufficient rates of loss in the study participants to occur, preferably at a mild disease stage where cartilage can be preserved. Here we analyze a “progression” model in mild radiographic KOA (RKOA), based on contra-lateral radiographic status.MethodsWe studied 837 participants (62.4 ± 9 yrs; 30 ± 4.9 kg/m²; 61.8% women) from the Osteoarthritis Initiative (OAI) with mild to moderate RKOA (Kellgren Lawrence grade [KLG] 2–3) and with/without Osteoarthritis Research Society International (OARSI) atlas radiographic joint space narrowing (JSN). These had quantitative measurements of subregional femorotibial cartilage thickness from magnetic resonance imaging (MRI) at baseline and 1-year follow-up. They were stratified by contra-lateral knee status: no (KLG 0/1), definite (KLG2) and moderate RKOA (KLG 3/4).ResultsKLG2 knees with JSN and moderate contra-lateral RKOA had (P = 0.008) greater maximum subregional cartilage loss −220 μm [95% confidence interval (CI) −255, −184 μm] than those without contra-lateral RKOA −164 μm [−187, −140 μm]. Their rate of subregional cartilage loss was similar and not significantly different (P = 0.61) to that in KLG 3 knees without contra-lateral RKOA (−232 μm; [−266; −198 μm]). The effect of contra-lateral RKOA status was less in KLG2 knees without JSN, and in KLG3 knees.ConclusionKLG2 knees with JSN and moderate contra-lateral RKOA, display relatively high rates of subregional femorotibial cartilage loss, despite being at a relatively mild stage of RKOA. They may therefore provide a unique opportunity for recruitment in clinical trials that explore the efficacy of anti-catabolic DMOADs on structural progression

A composable, energy-managed, real-time MPSOC platform.

Multi-processors systems on chip (MPSOC) platforms emerged in embedded systems as hardware solutions to support the continuously increasing functionality and performance demands in this domain. Such a platform has to execute a mix of applications with diverse performance and timing constraints, i.e., real-time or non-real-time, thus different application schedulers should co-exist on an MPSOC. Moreover, applications share many MPSOC resources, thus their timing depends on the arbitration at these resources. Arbitration may create inter-application dependencies, e.g., the timing of a low priority application depends on the timing of all higher priority ones. Application inter-dependencies make the functional and timing verification and the integration process harder. This is especially problematic for real-time applications, for which fulfilling the time-related constraints should be guaranteed by construction. Moreover, energy and power management, commonly employed in embedded systems, make this verification even more difficult. Typically, energy and power management involves scaling the resources operating point, which has a direct impact on the resource performance, thus influences the application time behaviour. Finally, a small change in one application leads to the need to re-verify all other applications, incurring a large effort. Composability is a property meant to ease the verification and integration process. A system is composable if the functionality and the timing behaviour of each application is independent of other applications mapped on the same platform. Composability is achieved by utilising arbiters that ensure applications independence. In this paper we present the concepts behind a composable, scalable, energy-managed MPSOC platform, able to support different real-time and nonreal time schedulers concurrently, and discuss its advantages and limitations

Is constant needle motion during soft tissue filler injections a safer procedure?:A theoretical mathematical model for evaluating patient safety

BackgroundThe safety rationale behind the constant needle motion injection technique is based on the assumption that due to the constant needle motion and simultaneous soft tissue filler material administration a smaller amount of product per area may be injected into an artery if an artery within the range of the moving needle is inadvertently entered.ObjectiveTo perform mathematical calculations for determining the probability for causing intra-arterial product administration when constantly moving the needle during facial aesthetic soft tissue filler injections.MethodsThis study was designed as a theoretical investigation into the probabilities for causing adverse events due to intravascular injection of soft tissue filler material when constantly moving a 27-G needle during facial soft tissue filler administration.ResultsIt was revealed that with a higher number of conducted injection passes a greater soft tissue area can be covered by the needle. The odds of encountering an artery within the covered soft tissue volume and the odds of injecting any volume greater than zero into the arterial blood stream increases with the number of performed injection passes. This increase is greatest between 1 and 10 performed injection passes.ConclusionThis model demonstrates that the constant needle motion technique increases the probability of encountering an artery within the treatment area and thus increases the odds for intra-arterial product administration. The constant needle motion technique does not increase safety but rather may increase the odds of causing intra-arterial product administration with the respective adverse consequences for the patient