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200 10$aSpirit leveling in Michigan, 1896-1938 /$fJ.G. Staack, Chief Topographic Engineer
210  1$a[Washington, D.C.] :$cUnited States Department of the Interior, Geological Survey,$d1941.
210  2$aWashington :$cUnited States Government Printing Office.
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225 1 $aBulletin / United States Department of the Interior, Geological Survey ;$v919
300   $aTitle from title screen (viewed July 9, 2014).
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200 10$aKnowledge Discovery and Emergent Complexity in Bioinformatics $eFirst International Workshop, KDECB 2006, Ghent, Belgium, May 10, 2006, Revised Selected Papers /$fedited by Karl Tuyls, Ronald Westra, Yvan Saeys, Ann Nowé
205   $a1st ed. 2007.
210  1$aBerlin, Heidelberg :$cSpringer Berlin Heidelberg :$cImprint: Springer,$d2007.
215   $a1 online resource (X, 184 p.) 
225 1 $aLecture Notes in Bioinformatics,$x2366-6331 ;$v4366
300   $aBibliographic Level Mode of Issuance: Monograph
311 08$a3-540-71036-1 
327   $aKnowledge Discovery and Emergent Complexity in Bioinformatics -- Boolean Algebraic Structures of the Genetic Code: Possibilities of Applications -- Discovery of Gene Regulatory Networks in Aspergillus fumigatus  -- Complexity Measures for Gene Assembly -- Learning Relations from Biomedical Corpora Using Dependency Trees -- Advancing the State of the Art in Computational Gene Prediction -- Enhancing Coding Potential Prediction for Short Sequences Using Complementary Sequence Features and Feature Selection -- The NetGenerator Algorithm: Reconstruction of Gene Regulatory Networks -- On the Neuronal Morphology-Function Relationship: A Synthetic Approach -- Analyzing Stigmergetic Algorithms Through Automata Games -- The Identification of Dynamic Gene-Protein Networks -- Sparse Gene Regulatory Network Identification.
330   $aThis book contains selected and revised papers of the International Symposium on Knowledge Discovery and Emergent Complexity in Bioinformatics (KDECB 2006), held at the University of Ghent, Belgium, May 10, 2006. In February 1943, the Austrian physicist Erwin Schrodi ¨ nger, one of the founding fathers of quantum mechanics, gave a series of lectures at Trinity College in Dublin titled ?What Is Life? The Physical Aspect of the Living Cell and Mind. ? In these l- tures Schrodi ¨ nger stressed the fundamental differencesencountered between observing animate and inanimate matter, and advanced some, at the time, audacious hypotheses aboutthe nature andmolecularstructureof genes, some ten yearsbeforethe discoveries of Watson and Crick. Indeed, the rules of living matter, from the molecular level to the level of supraorganic ocking behavior, seem to violate the simple basic interactions found between fundamental particles as electrons and protons. It is as if the organic molecules in the cell ?know? that they are alive. Despite all external stochastic uct- tions and chaos, process and additive noise, this machinery has been ticking for at least 3. 8 billion years. Yet, we may safely assume that the laws that governphysicsalso steer these complex associations of synchronous and seemingly intentional dynamics in the cell.
410  0$aLecture Notes in Bioinformatics,$x2366-6331 ;$v4366
606   $aBiochemistry
606   $aData mining
606   $aArtificial intelligence
606   $aInformation storage and retrieval systems
606   $aBioinformatics
606   $aComputer science$xMathematics
606   $aMathematical statistics
606   $aBiochemistry
606   $aData Mining and Knowledge Discovery
606   $aArtificial Intelligence
606   $aInformation Storage and Retrieval
606   $aComputational and Systems Biology
606   $aProbability and Statistics in Computer Science
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615 24$aData Mining and Knowledge Discovery.
615 24$aArtificial Intelligence.
615 24$aInformation Storage and Retrieval.
615 24$aComputational and Systems Biology.
615 24$aProbability and Statistics in Computer Science.
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