Reunion Probabilities of N One-Dimensional Random Walkers with Mixed Boundary Conditions

Reunion Probabilities of N One-Dimensional Random Walkers with Mixed Boundary Conditions. Castillo, I. P. & Dupic, T. Journal of Statistical Physics, 156(3):606–616, August, 2014.
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In this work we extend the results of the reunion probability of $\mathsl{N}$NN one-dimensional random walkers to include mixed boundary conditions between their trajectories. The level of the mixture is controlled by a parameter $\mathsl{c}$cc, which can be varied from $\mathsl{c}$=0c=0c=0 (independent walkers) to $\mathsl{c}→∞$c\textrightarrow$∞$c\ rightarrow \ infty (vicious walkers). The expressions are derived by using Quantum Mechanics formalism (QMf) which allows us to map this problem into a Lieb-Liniger gas (LLg) of $\mathsl{N}$NN one-dimensional particles. We use Bethe ansatz and Gaudin's conjecture to obtain the normalized wave-functions and use this information to construct the propagator. As it is well-known, depending on the boundary conditions imposed at the endpoints of a line segment, the statistics of the maximum heights of the reunited trajectories have some connections with different ensembles in Random Matrix Theory. Here we seek to extend those results and consider four models: absorbing, periodic, reflecting, and mixed. In all four cases, the probability that the maximum height is less or equal than $\mathsl{L}$LL takes the form $\mathsl{F}\mathsl{N}$($\mathsl{L}$)=$\mathsl{A}\mathsl{N}∑\mathsl{k}\mathsl{k}∈Ω$Be-$∑\mathsl{N}\mathsl{j}$=1$\mathsl{k}$2$\mathsl{j}$$\mathsl{N}$($\mathsl{k}\mathsl{k}$)FN(L)=AN$∑$kk$∈Ω$Be-$∑$j=1Nkj2VN(kk)F_N(L)=A_N\ sum _\\ varvec\k\\ in \ Omega _\\ text \B\\\ \ mathrm\e\\̂-\ sum _\j=1\N̂k_j2̂\\ mathcal \V\_N(\ varvec\k\), where $\mathsl{A}\mathsl{N}$ANA_N is a normalization constant, $\mathsl{N}$($\mathsl{k}\mathsl{k}$)VN(kk)\ mathcal \V\_N(\ varvec\k\) contains a deformed and weighted Vandermonde determinant, and $Ω$B$Ω$B\ Omega _\\ text \B\\ is the solution set of quasi-momenta $\mathsl{k}\mathsl{k}$kk\ varvec\k\ obeying the Bethe equations for that particular boundary condition.

@article{castilloReunionProbabilitiesOneDimensional2014,
  title = {Reunion {{Probabilities}} of {{N One-Dimensional Random Walkers}} with {{Mixed Boundary Conditions}}},
  author = {Castillo, Isaac P{\'e}rez and Dupic, Thomas},
  year = {2014},
  month = aug,
  journal = {Journal of Statistical Physics},
  volume = {156},
  number = {3},
  pages = {606--616},
  issn = {1572-9613},
  doi = {10.1007/s10955-014-1017-8},
  urldate = {2019-08-08},
  abstract = {In this work we extend the results of the reunion probability of {$\mathsl{N}$}NN one-dimensional random walkers to include mixed boundary conditions between their trajectories. The level of the mixture is controlled by a parameter {$\mathsl{c}$}cc, which can be varied from {$\mathsl{c}$}=0c=0c=0 (independent walkers) to {$\mathsl{c}\rightarrow\infty$}c\textrightarrow{$\infty$}c\textbackslash rightarrow \textbackslash infty (vicious walkers). The expressions are derived by using Quantum Mechanics formalism (QMf) which allows us to map this problem into a Lieb-Liniger gas (LLg) of {$\mathsl{N}$}NN one-dimensional particles. We use Bethe ansatz and Gaudin's conjecture to obtain the normalized wave-functions and use this information to construct the propagator. As it is well-known, depending on the boundary conditions imposed at the endpoints of a line segment, the statistics of the maximum heights of the reunited trajectories have some connections with different ensembles in Random Matrix Theory. Here we seek to extend those results and consider four models: absorbing, periodic, reflecting, and mixed. In all four cases, the probability that the maximum height is less or equal than {$\mathsl{L}$}LL takes the form {$\mathsl{F}\mathsl{N}$}({$\mathsl{L}$})={$\mathsl{A}\mathsl{N}\sum\mathsl{k}\mathsl{k}\in\Omega$}Be-{$\sum\mathsl{N}\mathsl{j}$}=1{$\mathsl{k}$}2{$\mathsl{j}$}{$\mathsl{N}$}({$\mathsl{k}\mathsl{k}$})FN(L)=AN{$\sum$}kk{$\in\Omega$}Be-{$\sum$}j=1Nkj2VN(kk)F\_N(L)=A\_N\textbackslash sum \_\{\textbackslash varvec\{k\}\textbackslash in \textbackslash Omega \_\{\textbackslash text \{B\}\}\} \textbackslash mathrm\{e\}\^\{-\textbackslash sum \_\{j=1\}\^Nk\_j\^2\}\textbackslash mathcal \{V\}\_N(\textbackslash varvec\{k\}), where {$\mathsl{A}\mathsl{N}$}ANA\_N is a normalization constant, {$\mathsl{N}$}({$\mathsl{k}\mathsl{k}$})VN(kk)\textbackslash mathcal \{V\}\_N(\textbackslash varvec\{k\}) contains a deformed and weighted Vandermonde determinant, and {$\Omega$}B{$\Omega$}B\textbackslash Omega \_\{\textbackslash text \{B\}\} is the solution set of quasi-momenta {$\mathsl{k}\mathsl{k}$}kk\textbackslash varvec\{k\} obeying the Bethe equations for that particular boundary condition.},
  langid = {english},
  keywords = {Bethe ansatz,Random matrices,Random walkers,Vicious walkers},
  file = {/home/thomas/snap/zotero-snap/common/Zotero/storage/74KJQQAY/Castillo and Dupic - 2014 - Reunion Probabilities of $$N$$NOne-Dimensional Ran.pdf}
}

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The level of the mixture is controlled by a parameter $\\mathsl{c}$cc, which can be varied from $\\mathsl{c}$=0c=0c=0 (independent walkers) to $\\mathsl{c}→∞$c\\textrightarrow$∞$c\\ rightarrow \\ infty (vicious walkers). The expressions are derived by using Quantum Mechanics formalism (QMf) which allows us to map this problem into a Lieb-Liniger gas (LLg) of $\\mathsl{N}$NN one-dimensional particles. We use Bethe ansatz and Gaudin's conjecture to obtain the normalized wave-functions and use this information to construct the propagator. As it is well-known, depending on the boundary conditions imposed at the endpoints of a line segment, the statistics of the maximum heights of the reunited trajectories have some connections with different ensembles in Random Matrix Theory. Here we seek to extend those results and consider four models: absorbing, periodic, reflecting, and mixed. In all four cases, the probability that the maximum height is less or equal than $\\mathsl{L}$LL takes the form $\\mathsl{F}\\mathsl{N}$($\\mathsl{L}$)=$\\mathsl{A}\\mathsl{N}∑\\mathsl{k}\\mathsl{k}∈Ω$Be-$∑\\mathsl{N}\\mathsl{j}$=1$\\mathsl{k}$2$\\mathsl{j}$$\\mathsl{N}$($\\mathsl{k}\\mathsl{k}$)FN(L)=AN$∑$kk$∈Ω$Be-$∑$j=1Nkj2VN(kk)F_N(L)=A_N\\ sum _\\\\ varvec\\k\\\\ in \\ Omega _\\\\ text \\B\\\\\\ \\ mathrm\\e\\\\̂-\\ sum _\\j=1\\N̂k_j2̂\\\\ mathcal \\V\\_N(\\ varvec\\k\\), where $\\mathsl{A}\\mathsl{N}$ANA_N is a normalization constant, $\\mathsl{N}$($\\mathsl{k}\\mathsl{k}$)VN(kk)\\ mathcal \\V\\_N(\\ varvec\\k\\) contains a deformed and weighted Vandermonde determinant, and $Ω$B$Ω$B\\ Omega _\\\\ text \\B\\\\ is the solution set of quasi-momenta $\\mathsl{k}\\mathsl{k}$kk\\ varvec\\k\\ obeying the Bethe equations for that particular boundary condition.","langid":"english","keywords":"Bethe ansatz,Random matrices,Random walkers,Vicious walkers","file":"/home/thomas/snap/zotero-snap/common/Zotero/storage/74KJQQAY/Castillo and Dupic - 2014 - Reunion Probabilities of $$N$$NOne-Dimensional Ran.pdf","bibtex":"@article{castilloReunionProbabilitiesOneDimensional2014,\n title = {Reunion {{Probabilities}} of {{N One-Dimensional Random Walkers}} with {{Mixed Boundary Conditions}}},\n author = {Castillo, Isaac P{\\'e}rez and Dupic, Thomas},\n year = {2014},\n month = aug,\n journal = {Journal of Statistical Physics},\n volume = {156},\n number = {3},\n pages = {606--616},\n issn = {1572-9613},\n doi = {10.1007/s10955-014-1017-8},\n urldate = {2019-08-08},\n abstract = {In this work we extend the results of the reunion probability of {$\\mathsl{N}$}NN one-dimensional random walkers to include mixed boundary conditions between their trajectories. The level of the mixture is controlled by a parameter {$\\mathsl{c}$}cc, which can be varied from {$\\mathsl{c}$}=0c=0c=0 (independent walkers) to {$\\mathsl{c}\\rightarrow\\infty$}c\\textrightarrow{$\\infty$}c\\textbackslash rightarrow \\textbackslash infty (vicious walkers). The expressions are derived by using Quantum Mechanics formalism (QMf) which allows us to map this problem into a Lieb-Liniger gas (LLg) of {$\\mathsl{N}$}NN one-dimensional particles. We use Bethe ansatz and Gaudin's conjecture to obtain the normalized wave-functions and use this information to construct the propagator. As it is well-known, depending on the boundary conditions imposed at the endpoints of a line segment, the statistics of the maximum heights of the reunited trajectories have some connections with different ensembles in Random Matrix Theory. Here we seek to extend those results and consider four models: absorbing, periodic, reflecting, and mixed. 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