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Detection and Correction of Inconsistencies in the Multilingual Treebank HamleDT / Detection and Correction of Inconsistencies in the Multilingual Treebank HamleDTMašek, Jan January 2015 (has links)
We studied the treebanks included in HamleDT and partially unified their label sets. Afterwards, we used a method based on variation n-grams to automatically detect errors in morphological and dependency annotation. Then we used the output of a part-of-speech tagger / dependency parser trained on each treebank to correct the detected errors. The performance of both the detection and the correction of errors on both annotation levels was manually evaluated on a randomly selected samples of suspected errors from several treebanks. Powered by TCPDF (www.tcpdf.org)
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Cost Beneficial Solution for High Rate Data ProcessingMirchandani, Chandru, Fisher, David, Ghuman, Parminder 10 1900 (has links)
International Telemetering Conference Proceedings / October 25-28, 1999 / Riviera Hotel and Convention Center, Las Vegas, Nevada / GSFC in keeping with the tenets of NASA has been aggressively investigating new
technologies for spacecraft and ground communications and processing. The application
of these technologies, together with standardized telemetry formats, make it possible to
build systems that provide high-performance at low cost in a short development cycle.
The High Rate Telemetry Acquisition System (HRTAS) Prototype is one such effort that
has validated Goddard's push towards faster, better and cheaper. The HRTAS system
architecture is based on the Peripheral Component Interconnect (PCI) bus and VLSI
Application-Specific Integrated Circuits (ASICs). These ASICs perform frame
synchronization, bit-transition density decoding, cyclic redundancy code (CRC) error
checking, Reed-Solomon error detection/correction, data unit sorting, packet extraction,
annotation and other service processing. This processing in performed at rates of up to
and greater than 150 Mbps sustained using a high-end performance workstation running
standard UNIX O/S, (DEC 4100 with DEC UNIX or better). ASICs are also used for the
digital reception of Intermediate Frequency (IF) telemetry as well as the spacecraft
command interface for commands and data simulations.
To improve the efficiency of the back-end processing, the level zero processing sorting
element is being developed. This will provide a complete hardware solution to extracting
and sorting source data units and making these available in separate files on a remote disk
system. Research is on going to extend this development to higher levels of the science
data processing pipeline. The fact that level 1 and higher processing is instrument
dependent; an acceleration approach utilizing ASICs is not feasible. The advent of field
programmable gate array (FPGA) based computing, referred to as adaptive or reconfigurable computing, provides a processing performance close to ASIC levels while
maintaining much of the programmability of traditional microprocessor based systems.
This adaptive computing paradigm has been successfully demonstrated and its cost
performance validated, to make it a viable technology for the level one and higher
processing element for the HRTAS.
Higher levels of processing are defined as the extraction of useful information from
source telemetry data. This information has to be made available to the science data user
in a very short period of time. This paper will describe this low cost solution for high rate
data processing at level one and higher processing levels. The paper will further discuss
the cost-benefit of this technology in terms of cost, schedule, reliability and performance.
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A HIGH-SPEED, RUGGEDIZED, MINIATURE INSTRUMENTATION RECORDER UTILIZING COMMERCIAL TECHNOLOGYRicker, William, Kolb, John Jr 10 1900 (has links)
International Telemetering Conference Proceedings / October 26-29, 1992 / Town and Country Hotel and Convention Center, San Diego, California / Due to the vast amount of data required to be collected for design/performance analysis of
operational and development systems, there has evolved a real requirement for a
high-speed, large capacity, data collection/record system in a small Flight/Ruggedized
package. This need is realized by several user communities and factors which include the
evolution of small operational vehicles (airborne, land and UAV’s), the desire of weapons
manufacturers/integrators to be independent from the vehicle during vehicle integration,
and a general need for a field/airborne, reliable portable data collection system for
intelligence gathering, operational performance verification and on-board data processing.
In the Air Defence community, the need for a ruggedized record system was highlighted
after Desert Storm, in which the operational performance of the Patriot Missile was
questioned and data collection was not performed to support the performance. The Aydin
Vector Division in conjunction with the prime contractor, has come up with a solution to
this problem which utilizes a commercially available helical scan 8mm data storage unit.
This solution provides a highly reliable record system, ruggedized for airborne and field
environments and a low price in comparison with the more traditional approaches currently
offered.
This paper will describe the design implementation of this small ruggedized, flight worthy
Data collection system deemed the ATD-800. It will also discuss the performance and
limitations of implementing such a system, as well as provide several applications and
solutions to different operational environments to be encountered. Additionally, the paper
will conclude with several product enhancements which may benefit the flight test,
operational and intelligence communities in the future.
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Error control with binary cyclic codesGrymel, Martin-Thomas January 2013 (has links)
Error-control codes provide a mechanism to increase the reliability of digital data being processed, transmitted, or stored under noisy conditions. Cyclic codes constitute an important class of error-control code, offering powerful error detection and correction capabilities. They can easily be generated and verified in hardware, which makes them particularly well suited to the practical use as error detecting codes.A cyclic code is based on a generator polynomial which determines its properties including the specific error detection strength. The optimal choice of polynomial depends on many factors that may be influenced by the underlying application. It is therefore advantageous to employ programmable cyclic code hardware that allows a flexible choice of polynomial to be applied to different requirements. A novel method is presented in this thesis to realise programmable cyclic code circuits that are fast, energy-efficient and minimise implementation resources.It can be shown that the correction of a single-bit error on the basis of a cyclic code is equivalent to the solution of an instance of the discrete logarithm problem. A new approach is proposed for computing discrete logarithms; this leads to a generic deterministic algorithm for analysed group orders that equal Mersenne numbers with an exponent of a power of two. The algorithm exhibits a worst-case runtime in the order of the square root of the group order and constant space requirements.This thesis establishes new relationships for finite fields that are represented as the polynomial ring over the binary field modulo a primitive polynomial. With a subset of these properties, a novel approach is developed for the solution of the discrete logarithm in the multiplicative groups of these fields. This leads to a deterministic algorithm for small group orders that has linear space and linearithmic time requirements in the degree of defining polynomial, enabling an efficient correction of single-bit errors based on the corresponding cyclic codes.
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