45 research outputs found
The Movement Imagery Questionnaire-Revised, Second Edition (MIQ-RS) Is a Reliable and Valid Tool for Evaluating Motor Imagery in Stroke Populations
Mental imagery can improve motor performance in stroke populations when combined with physical therapy. Valid and reliable instruments to evaluate the imagery ability of stroke survivors are needed to maximize the benefits of mental imagery therapy. The purposes of this study were to: examine and compare the test-retest intra-rate reliability of the Movement Imagery Questionnaire-Revised, Second Edition (MIQ-RS) in stroke survivors and able-bodied controls, examine internal consistency of the visual and kinesthetic items of the MIQ-RS, determine if the MIQ-RS includes both the visual and kinesthetic dimensions of mental imagery, correlate impairment and motor imagery scores, and investigate the criterion validity of the MIQ-RS in stroke survivors by comparing the results to the KVIQ-10. Test-retest analysis indicated good levels of reliability (ICC range: .83–.99) and internal consistency (Cronbach α: .95–.98) of the visual and kinesthetic subscales in both groups. The two-factor structure of the MIQ-RS was supported by factor analysis, with the visual and kinesthetic components accounting for 88.6% and 83.4% of the total variance in the able-bodied and stroke groups, respectively. The MIQ-RS is a valid and reliable instrument in the stroke population examined and able-bodied populations and therefore useful as an outcome measure for motor imagery ability
SABRE: A bio-inspired fault-tolerant electronic architecture
As electronic devices become increasingly complex, ensuring their reliable, fault-free operation is becoming correspondingly more challenging. It can be observed that, in spite of their complexity, biological systems are highly reliable and fault tolerant. Hence, we are motivated to take inspiration for biological systems in the design of electronic ones. In SABRE (self-healing cellular architectures for biologically inspired highly reliable electronic systems), we have designed a bio-inspired fault-tolerant hierarchical architecture for this purpose. As in biology, the foundation for the whole system is cellular in nature, with each cell able to detect faults in its operation and trigger intra-cellular or extra-cellular repair as required. At the next level in the hierarchy, arrays of cells are configured and controlled as function units in a transport triggered architecture (TTA), which is able to perform partial-dynamic reconfiguration to rectify problems that cannot be solved at the cellular level. Each TTA is, in turn, part of a larger multi-processor system which employs coarser grain reconfiguration to tolerate faults that cause a processor to fail. In this paper, we describe the details of operation of each layer of the SABRE hierarchy, and how these layers interact to provide a high systemic level of fault tolerance. © 2013 IOP Publishing Ltd
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Secondary (additional) findings from the 100,000 Genomes Project: disease manifestation, healthcare outcomes and costs of disclosure
Purpose
The UK 100,000 Genomes Project offered participants screening for additional findings (AFs) in genes associated with familial hypercholesterolaemia (FH) or hereditary cancer syndromes including breast/ovarian cancer (HBOC), Lynch, familial adenomatous polyposis, MYH-associated polyposis, multiple endocrine neoplasia, von Hippel-Lindau. Here we report disclosure processes, manifestation of AF-related disease, outcomes and costs.
Methods
An observational study in an area representing one-fifth of England.
Results
Data were collected from 89 adult AF recipients. At disclosure, among 57 recipients of a cancer predisposition-associated AF and 32 recipients of an FH-associated AF, 35% and 88% respectively had personal and/or family history evidence of AF-related disease. During post-disclosure investigations, four cancer-AF recipients had evidence of disease, including one medullary thyroid cancer. Six women with an HBOC AF, three women with a Lynch syndrome AF, and two individuals with a MEN AF elected for risk-reducing surgery. New hyperlipidaemia diagnoses were made in six FH-AF recipients, and treatment (re-)initiated for seven with prior hyperlipidaemia. Generating and disclosing AFs in this region cost £1.4m; £8,680 per clinically significant AF.
Conclusion
Generation and disclosure of AFs identifies individuals with, and without personal or familial evidence of disease, and prompts appropriate clinical interventions. Results can inform policy towards secondary findings
New high speed CMOS self-checking voter
Faults possibly affecting voters of TMR systems, employed in high reliability applications, can make them provide the fan-out logic with incorrect data, hence making the adoption of the TMR technique useless. In this paper we instantiate the need for self-checking voters and we propose a new self-checking voting scheme that, compared to alternate self-checking solutions, features the advantage of being faster, while requiring comparable power consumption. This is achieved at the cost of a small increase in area overhead
Low-Cost and Highly Reliable Detector for Transient and Crosstalk Faults Affecting FPGA Interconnects*
In this paper we present a novel circuit for the on-line detection of transient and crosstalk faults affecting the interconnects of systems implemented using Field Programmable Gate-Arrays (FPGAs). The proposed detector features self-checking ability with respect to faults possibly affecting itself, thus being suitable for systems with high reliability requirements, like those for space applications. Compared to alternate solutions, the proposed circuit requires a significantly lower area overhead, while implying a comparable, or lower, impact on system performance. We have verified our circuit operation and self-checking ability by means of post-layout simulations
Pseudo-Philon. Les Antiquités Bibliques,
t. 1 Introduction et texte critiques par D.J. Harrington, Traduction par J. Cazeaux revue par Ch. Perrot et P.-M. Bogaert (SC 229), t. 2 Introduction littéraire, commentaire et index par Ch. Perrot et P.-M. Bogaert avec la collaboration de D.J. Harrington
Low-cost and highly reliable detector for transient and crosstalk faults affecting FPGA interconnects
In this paper we present a novel circuit for the on-line detection of transient and crosstalk faults affecting the interconnects of systems implemented using Field Programmable Gate-Arrays (FPGAs). The proposed detector features self-checking ability with respect to faults possibly affecting itself, thus being suitable for systems with high reliability requirements, like those for space applications. Compared to alternate solutions, the proposed circuit requires a significantly lower area overhead, while implying a comparable, or lower, impact on system performance. We have verified our circuit operation and self-checking ability by means of post-layout simulations
A novel dual-walled CNT bus architecture with reduced cross-coupling features
Carbon Nano Tubes (CNTs) have been widely proposed as interconnect fabric for nano and very deep submicron (silicon-based) technologies due to their robustness to electromigration. In this paper, a novel bus architecture with low crosstalk features is proposed. It is made of dual-walled nanotubes (DWNTs) arranged in parallel. It achieves reductions up to 72% of the crosstalk-induced delay, and up to 76% for the crosstalk-induced peak voltage, at a modest area increase. Therefore, the proposed bus arrangement significantly improves performance and provides reliable operation in an interconnect. © 2006 IEEE
On transistor level gate sizing for increased robustness to transient faults
In this paper we present a detailed analysis on how the critical charge (Q crit) of a circuit node, usually employed to evaluate the probability of transient fault (TF) occurrence as a consequence of a particle hit, depends on transistors' sizing. We derive an analytical model allowing us to calculate a node's Q crit given the size of the node's driving gate and fan-out gate(s), thus avoiding time costly electrical level simulations. We verified that such a model features an accuracy of the 97% with respect to electrical level simulations performed by HSPICE. Our proposed model shows that Q crit depends much more on the strength (conductance) of the gate driving the node, than on the node total capacitance. We also evaluated the impact of increasing the conductance of the driving gate on TFs' propagation, hence on Soft Error Susceptibility (SES). We found that such a conductance increase not only improves the TF robustness of the hardened node, but also that of the whole circuit. © 2005 IEEE