Theoretical and Experimental DNA Computation (Natural ...

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References 165 157. Ingo Wegener. The Complexity of Boolean Functions. Wiley-Teubner, 1987. 158. R. Weiss, G. Homsy, and T.F. Knight Jr. Toward in-vivo digital circuits. In L.F. Landweber and E. Winfree, editors, DIMACS Workshop on Evolution as Computation. Springer, January 1999. 159. N.E. Weste and K. Eshragan. Principles of CMOS VLSI Design. Addison- Wesley, 1993. 160. J. Williams, A. Ceccarelli, and N. Spurr. Genetic Engineering. βios Scientific Publishers, 1993. 161. E. Winfree, F. Liu, L. Wenzler, and N.C. Seeman. Design and self-assembly of two-dimensional DNA crystals. Nature, 394:539–544, 1998. 162. Erik Winfree. On the computational power of DNA annealing and ligation. In Baum and Lipton [25], pages 199–221. 163. Erik Winfree. Algorithmic self-assembly of DNA. PhD thesis, California Institute of Technology, May 1998. 164. C. Yanisch-Perron, J. Vieira, and J. Messing. Improved m13 phage cloning vectors and host strains: nucleotide sequences of the m13mp18 and puc19 vectors. Gene, 33(1):103–119, 1985. 165. Claudio Zandron, Claudio Ferretti, and Giancarlo Mauri. Solving NP-complete problems using P systems with active membranes. In I. Antoniou, C.S. Calude, and M.J. Dinneen, editors, Unconventional Models of Computation, UMC’2K, Solvay Institutes, Brussel, 13–16 December 2000, DIMACS: Series in Discrete Mathematics and Theoretical Computer Science, pages 289–301. Centre for Discrete Mathematics and Theoretical Computer Science, International Solvay Institute for Physics and Chemistry, and the Vrije Universiteit Brussel, Theoretical Physics Division, 2000.
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Natural Computing Series Series Edi
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Martyn Amos Department of Computer
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Preface DNA computation has emerged
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Preface IX acknowledged. Finally, I
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XII Contents 4 Complexity Issues ..
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Introduction “Where a calculator
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Introduction 3 Even though their un
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1 DNA: The Molecule of Life “All
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1.3 DNA as the Carrier of Genetic I
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1.3 DNA as the Carrier of Genetic I
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Synthesis 1.4 Operations on DNA 11
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Gel electrophoresis 1.4 Operations
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5’ 3’ A T A G A G T T 3’ TCA
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1.4 Operations on DNA 17 Others may
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Vector Strand to be inserted (targe
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1.5 Summary 1.6 Bibliographical Not
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24 2 Theoretical Computer Science:
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46 3 Models of Molecular Computatio
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72 4 Complexity Issues is that, alt
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74 4 Complexity Issues The weak par
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76 4 Complexity Issues 4.3 A Strong
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78 4 Complexity Issues Ω = {∧,
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80 4 Complexity Issues 0 1 0 1 x1 x
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82 4 Complexity Issues connecting a
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84 4 Complexity Issues Level simula
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86 4 Complexity Issues At level D(S
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88 4 Complexity Issues xANDy)) and
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90 4 Complexity Issues Input matrix
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92 4 Complexity Issues memory acces
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94 4 Complexity Issues denoted by P
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96 4 Complexity Issues The final st
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98 4 Complexity Issues 1)), ADDR[])
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100 4 Complexity Issues Size(STI)=O
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102 4 Complexity Issues best attain
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104 4 Complexity Issues 10. LDC 0 1
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106 4 Complexity Issues ACC[] := bi
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5 Physical Implementations “No am
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5.3 Initial Set Construction Within
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Vertex 1 Vertex 2 Vertex 3 ¡ ¡ ¡
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Page 171 and 172: 156 6 Cellular Computing 6.7 Biblio
Page 173 and 174: 158 References 14. Martyn Amos, Ste
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Page 183 and 184: 168 Index clause, 42, 49, 139-141,
Page 185 and 186: 170 Index maximum independent set,
Page 187 and 188: 172 Index Taq, see enzyme, Taq targ
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