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Biblioteca (s) : |
INIA Tacuarembó. |
Fecha : |
21/02/2014 |
Actualizado : |
22/02/2014 |
Autor : |
Malvárez, G.; Rodríguez, A.; Zorrilla, A. |
Título : |
Alternativas de abonos orgánicos compostaje con lombrices |
Fecha de publicación : |
1994 |
Fuente / Imprenta : |
Montevideo (Uruguay): Caritas Uruguaya, 1994. |
Páginas : |
38 p. |
Idioma : |
Español |
Notas : |
Bibliografía : p34-37 |
Thesagro : |
ABONOS ORGANICOS; FERTILIDAD DEL SUELO; MATERIA ORGANICA DEL SUELO; OLIGOCHAETA; ORGANISMOS DEL SUELO; TECNOLOGIA DE ABONOS. |
Asunto categoría : |
-- |
Marc : |
LEADER 00624nam a2200217 a 4500 001 1015850 005 2014-02-22 008 1994 bl uuuu u00u1 u #d 100 1 $aMALVÁREZ, G. 245 $aAlternativas de abonos orgánicos compostaje con lombrices 260 $aMontevideo (Uruguay): Caritas Uruguaya$c1994 300 $a38 p. 500 $aBibliografía : p34-37 650 $aABONOS ORGANICOS 650 $aFERTILIDAD DEL SUELO 650 $aMATERIA ORGANICA DEL SUELO 650 $aOLIGOCHAETA 650 $aORGANISMOS DEL SUELO 650 $aTECNOLOGIA DE ABONOS 700 1 $aRODRÍGUEZ, A. 700 1 $aZORRILLA, A.
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INIA Tacuarembó (TBO) |
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| Acceso al texto completo restringido a Biblioteca INIA Las Brujas. Por información adicional contacte bibliolb@inia.org.uy. |
Registro completo
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Biblioteca (s) : |
INIA Las Brujas. |
Fecha actual : |
29/09/2014 |
Actualizado : |
09/10/2019 |
Tipo de producción científica : |
Artículos en Revistas Indexadas Internacionales |
Circulación / Nivel : |
A - 1 |
Autor : |
COLE, J.B.; NEWMAN, S.; FOERTTER, F.; AGUILAR, I. |
Afiliación : |
IGNACIO AGUILAR GARCIA, Instituto Nacional de Investigación Agropecuaria (INIA), Uruguay. |
Título : |
Breeding and genetics symposium: Really big data: Processing and analysis of very large data sets. |
Fecha de publicación : |
2012 |
Fuente / Imprenta : |
Journal of Animal Science, 2012, v.90, no.3, p.723-733. |
ISSN : |
0021-8812 |
DOI : |
10.2527/jas.2011-4584 |
Idioma : |
Inglés |
Notas : |
Article history: Received: 11 August 2011 / Accepted: 13 November 2011 / Published: 01 March 2012 . |
Contenido : |
ABSTRACT.
Modern animal breeding data sets are large and getting larger, due in part to recent availability of high-density SNP arrays and cheap sequencing technology. High-performance computing methods for efficient data warehousing and analysis are under development. Financial and security considerations are important when using shared clusters. Sound software engineering practices are needed, and it is better to use existing solutions when possible. Storage requirements for genotypes are modest, although full-sequence data will require greater storage capacity. Storage requirements for intermediate and results files for genetic evaluations are much greater, particularly when multiple runs must be stored for research and validation studies. The greatest gains in accuracy from genomic selection have been realized for traits of low heritability, and there is increasing interest in new health and management traits. The collection of sufficient phenotypes to produce accurate evaluations may take many years, and high-reliability proofs for older bulls are needed to estimate marker effects. Data mining algorithms applied to large data sets may help identify unexpected relationships in the data, and improved visualization tools will provide insights. Genomic selection using large data requires a lot of computing power, particularly when large fractions of the population are genotyped. Theoretical improvements have made possible the inversion of large numerator relationship matrices, permitted the solving of large systems of equations, and produced fast algorithms for variance component estimation. Recent work shows that single-step approaches combining BLUP with a genomic relationship (G) matrix have similar computational requirements to traditional BLUP, and the limiting factor is the construction and inversion of G for many genotypes. A naïve algorithm for creating G for 14,000 individuals required almost 24 h to run, but custom libraries and parallel computing reduced that to 15 m. Large data sets also create challenges for the delivery of genetic evaluations that must be overcome in a way that does not disrupt the transition from conventional to genomic evaluations. Processing time is important, especially as real-time systems for on-farm decisions are developed. The ultimate value of these systems is to decrease time-to-results in research, increase accuracy in genomic evaluations, and accelerate rates of genetic improvement.
© 2012 American Society of Animal Science. All rights reserved. MenosABSTRACT.
Modern animal breeding data sets are large and getting larger, due in part to recent availability of high-density SNP arrays and cheap sequencing technology. High-performance computing methods for efficient data warehousing and analysis are under development. Financial and security considerations are important when using shared clusters. Sound software engineering practices are needed, and it is better to use existing solutions when possible. Storage requirements for genotypes are modest, although full-sequence data will require greater storage capacity. Storage requirements for intermediate and results files for genetic evaluations are much greater, particularly when multiple runs must be stored for research and validation studies. The greatest gains in accuracy from genomic selection have been realized for traits of low heritability, and there is increasing interest in new health and management traits. The collection of sufficient phenotypes to produce accurate evaluations may take many years, and high-reliability proofs for older bulls are needed to estimate marker effects. Data mining algorithms applied to large data sets may help identify unexpected relationships in the data, and improved visualization tools will provide insights. Genomic selection using large data requires a lot of computing power, particularly when large fractions of the population are genotyped. Theoretical improvements have made possible the inversion of large numerator relationship matri... Presentar Todo |
Thesagro : |
EVALUACIONES GENÉTICAS; FENOTIPOS; GENETICA ANIMAL; MEJORAMIENTO GENETICO ANIMAL. |
Asunto categoría : |
L10 Genética y mejoramiento animal |
Marc : |
LEADER 03346naa a2200241 a 4500 001 1050707 005 2019-10-09 008 2012 bl uuuu u00u1 u #d 022 $a0021-8812 024 7 $a10.2527/jas.2011-4584$2DOI 100 1 $aCOLE, J.B. 245 $aBreeding and genetics symposium$bReally big data: Processing and analysis of very large data sets.$h[electronic resource] 260 $c2012 500 $aArticle history: Received: 11 August 2011 / Accepted: 13 November 2011 / Published: 01 March 2012 . 520 $aABSTRACT. Modern animal breeding data sets are large and getting larger, due in part to recent availability of high-density SNP arrays and cheap sequencing technology. High-performance computing methods for efficient data warehousing and analysis are under development. Financial and security considerations are important when using shared clusters. Sound software engineering practices are needed, and it is better to use existing solutions when possible. Storage requirements for genotypes are modest, although full-sequence data will require greater storage capacity. Storage requirements for intermediate and results files for genetic evaluations are much greater, particularly when multiple runs must be stored for research and validation studies. The greatest gains in accuracy from genomic selection have been realized for traits of low heritability, and there is increasing interest in new health and management traits. The collection of sufficient phenotypes to produce accurate evaluations may take many years, and high-reliability proofs for older bulls are needed to estimate marker effects. Data mining algorithms applied to large data sets may help identify unexpected relationships in the data, and improved visualization tools will provide insights. Genomic selection using large data requires a lot of computing power, particularly when large fractions of the population are genotyped. Theoretical improvements have made possible the inversion of large numerator relationship matrices, permitted the solving of large systems of equations, and produced fast algorithms for variance component estimation. Recent work shows that single-step approaches combining BLUP with a genomic relationship (G) matrix have similar computational requirements to traditional BLUP, and the limiting factor is the construction and inversion of G for many genotypes. A naïve algorithm for creating G for 14,000 individuals required almost 24 h to run, but custom libraries and parallel computing reduced that to 15 m. Large data sets also create challenges for the delivery of genetic evaluations that must be overcome in a way that does not disrupt the transition from conventional to genomic evaluations. Processing time is important, especially as real-time systems for on-farm decisions are developed. The ultimate value of these systems is to decrease time-to-results in research, increase accuracy in genomic evaluations, and accelerate rates of genetic improvement. © 2012 American Society of Animal Science. All rights reserved. 650 $aEVALUACIONES GENÉTICAS 650 $aFENOTIPOS 650 $aGENETICA ANIMAL 650 $aMEJORAMIENTO GENETICO ANIMAL 700 1 $aNEWMAN, S. 700 1 $aFOERTTER, F. 700 1 $aAGUILAR, I. 773 $tJournal of Animal Science, 2012$gv.90, no.3, p.723-733.
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