Paperfolding, Automata, and Rational Functions - Diagonals and ...

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Complexity of a Sequence Given an infinite string, denote by p(n) the number of its distinct subwords of length n. Almost all numbers (in base b) have p(n) = b n ; but sequences generated by a finite automaton have only a miserable complexity p(n) = O(n). Not all that long ago, BORIS ADAMCZEWSKI, YANN BUGEAUD, AND FLORIAN LUCA, ‘Sur la complexité des nombres algébriques’, C. R. Acad. Sci. Paris, Ser. I 336 (2004), applied Schlickewei’s p-adic generalisation of Wolfgang Schmidt’s subspace theorem (which is itself a multidimensional generalisation of Roth’s theorem) to proving that for the base b expansion of an irrational algebraic number lim inf p(n)/n = +∞. n→∞ A more detailed paper usefully generalising the earlier announcement: ‘On the complexity of algebraic numbers’, by BORIS ADAMCZEWSKI AND YANN BUGEAUD, has now appeared in Annals of Math. 20
Complexity of a Sequence Given an infinite string, denote by p(n) the number of its distinct subwords of length n. Almost all numbers (in base b) have p(n) = b n ; but sequences generated by a finite automaton have only a miserable complexity p(n) = O(n). Not all that long ago, BORIS ADAMCZEWSKI, YANN BUGEAUD, AND FLORIAN LUCA, ‘Sur la complexité des nombres algébriques’, C. R. Acad. Sci. Paris, Ser. I 336 (2004), applied Schlickewei’s p-adic generalisation of Wolfgang Schmidt’s subspace theorem (which is itself a multidimensional generalisation of Roth’s theorem) to proving that for the base b expansion of an irrational algebraic number lim inf p(n)/n = +∞. n→∞ A more detailed paper usefully generalising the earlier announcement: ‘On the complexity of algebraic numbers’, by BORIS ADAMCZEWSKI AND YANN BUGEAUD, has now appeared in Annals of Math. 20
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Paperfolding, Automata, and Rationa
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Paperfolding, Automata, and Rationa
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Paperfolding Take a rectangular she
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A Mahler Functional Equation Aside.
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Next, if we pair the sequence Regul
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Next, if we pair the sequence Regul
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The uniform, or regular, 2-substitu
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Characteristic Functions I found th
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An Algebraic Equation in Characteri
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An Algebraic Equation in Characteri
Page 71 and 72: An Algebraic Equation in Characteri
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Page 75 and 76: These remarks show that the paperfo
Page 77 and 78: These remarks show that the paperfo
Page 79 and 80: The Thue-Morse Sequence 0 1 10 11 1
Page 81 and 82: The Thue-Morse Sequence 0 1 10 11 1
Page 83 and 84: Euler’s Identity and a Functional
Page 89 and 90: An Algebraic Equation The function
Page 91 and 92: A Counter-example in Analysis I cla
Page 97 and 98: The Shapiro Sequence Consider, the
Page 107 and 108: A Remark on the Shapiro Function Se
Page 113: A Remark on the Shapiro Function Se
Page 116 and 117: Transcendence of Automatic Numbers
Page 124: Complexity of a Sequence Given an i
Page 127 and 128: Algebraicity and Automaticity The p
Page 135 and 136: Comments on the Proof The best proo
Page 141 and 142: But for expansions over the complex
Page 143 and 144: But for expansions over the complex
Page 145: But for expansions over the complex
Page 148 and 149: Power Series in Several Variables R
Page 158 and 159: Diagonals and Hadamard Products The
Page 160 and 161: Diagonals and Hadamard Products The
Page 162 and 163: A Theorem of Furstenberg It follows
Page 168 and 169: As said, in characteristic zero, ne
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As said, in characteristic zero, ne
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A Beautiful Transcendence Argument
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A Beautiful Transcendence Argument
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Breaking Up in Characteristic p The
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Algebraic power series in character
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Hence, since Fp is finite, there ar
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Hence, since Fp is finite, there ar
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Suppose the series P aνx ν is gen
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So we have: Theorem. P aνx ν ∈
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The Lifting Theorem Looking careful
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Diagonals of Rational Functions Now
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Whilst (i) and (ii) are reasonably
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References MICHEL DEKKING, MICHEL M
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