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-rw-r--r--bezout.bib82
-rw-r--r--bezout.tex14
2 files changed, 91 insertions, 5 deletions
diff --git a/bezout.bib b/bezout.bib
index e598045..d0945bf 100644
--- a/bezout.bib
+++ b/bezout.bib
@@ -1,3 +1,30 @@
+@article{Anninos_2016_Disordered,
+ author = {Anninos, Dionysios and Anous, Tarek and Denef, Frederik},
+ title = {Disordered quivers and cold horizons},
+ journal = {Journal of High Energy Physics},
+ publisher = {Springer Science and Business Media LLC},
+ year = {2016},
+ month = {12},
+ number = {12},
+ volume = {2016},
+ url = {https://doi.org/10.1007%2Fjhep12%282016%29071},
+ doi = {10.1007/jhep12(2016)071}
+}
+
+@article{Antenucci_2015_Complex,
+ author = {Antenucci, F. and Crisanti, A. and Leuzzi, L.},
+ title = {Complex spherical {$2+4$} spin glass: A model for nonlinear optics in random media},
+ journal = {Physical Review A},
+ publisher = {American Physical Society (APS)},
+ year = {2015},
+ month = {5},
+ number = {5},
+ volume = {91},
+ pages = {053816},
+ url = {https://doi.org/10.1103%2Fphysreva.91.053816},
+ doi = {10.1103/physreva.91.053816}
+}
+
@book{Bezout_1779_Theorie,
author = {Bézout, Etienne},
title = {Théorie générale des équations algébriques},
@@ -7,6 +34,47 @@
address = {rue S. Jacques, Paris}
}
+@article{Bray_2007_Statistics,
+ author = {Bray, Alan J. and Dean, David S.},
+ title = {Statistics of Critical Points of Gaussian Fields on Large-Dimensional Spaces},
+ journal = {Physical Review Letters},
+ publisher = {American Physical Society (APS)},
+ year = {2007},
+ month = {4},
+ number = {15},
+ volume = {98},
+ pages = {150201},
+ url = {https://doi.org/10.1103%2Fphysrevlett.98.150201},
+ doi = {10.1103/physrevlett.98.150201}
+}
+
+@article{Fyodorov_2004_Complexity,
+ author = {Fyodorov, Yan V.},
+ title = {Complexity of Random Energy Landscapes, Glass Transition, and Absolute Value of the Spectral Determinant of Random Matrices},
+ journal = {Physical Review Letters},
+ publisher = {American Physical Society (APS)},
+ year = {2004},
+ month = {6},
+ number = {24},
+ volume = {92},
+ pages = {240601},
+ url = {https://doi.org/10.1103%2Fphysrevlett.92.240601},
+ doi = {10.1103/physrevlett.92.240601}
+}
+
+@article{Kac_1943_On,
+ author = {Kac, M.},
+ title = {On the average number of real roots of a random algebraic equation},
+ journal = {Bulletin of the American Mathematical Society},
+ publisher = {American Mathematical Society},
+ year = {1943},
+ month = {4},
+ number = {4},
+ volume = {49},
+ pages = {314--320},
+ url = {https://projecteuclid.org:443/euclid.bams/1183505112}
+}
+
@article{Nguyen_2014_The,
author = {Nguyen, Hoi H. and O'Rourke, Sean},
title = {The Elliptic Law},
@@ -21,6 +89,20 @@
doi = {10.1093/imrn/rnu174}
}
+@article{Rice_1939_The,
+ author = {Rice, S. O.},
+ title = {The Distribution of the Maxima of a Random Curve},
+ journal = {American Journal of Mathematics},
+ publisher = {JSTOR},
+ year = {1939},
+ month = {4},
+ number = {2},
+ volume = {61},
+ pages = {409},
+ url = {https://doi.org/10.2307%2F2371510},
+ doi = {10.2307/2371510}
+}
+
@article{Weyl_1912_Das,
author = {Weyl, Hermann},
title = {Das asymptotische Verteilungsgesetz der Eigenwerte linearer partieller Differentialgleichungen (mit einer Anwendung auf die Theorie der Hohlraumstrahlung)},
diff --git a/bezout.tex b/bezout.tex
index caa634a..83e748e 100644
--- a/bezout.tex
+++ b/bezout.tex
@@ -46,16 +46,20 @@ The most tractable family of these are the mean-field spherical p-spin models d
where the $J_{i_1\cdots i_p}$ are real Gaussian variables and the $z_i$ are real and constrained
to a sphere $\sum_i z_i^2=N$. If there is a single term of a given $p$, this is known as the `pure $p$-spin' model, the case we shall study here.
-This problem has been attacked from several angles: the replica trick to compute the Boltzmann-Gibbs distribution,
-a Kac-Rice \cite{Kac,Fyodorov} procedure (similar to the Fadeev-Popov integral) to compute the number of saddle-points of the energy function, and the gradient-descent -- or more generally Langevin -- dynamics staring from a high-energy configuration.
-Thanks to the relative simplicity of the energy, all these approaches are possible analytically in the large $N$ limit.
+This problem has been attacked from several angles: the replica trick to
+compute the Boltzmann--Gibbs distribution, a Kac--Rice \cite{Kac_1943_On,
+Rice_1939_The, Fyodorov_2004_Complexity} procedure (similar to the Fadeev--Popov
+integral) to compute the number of saddle-points of the energy function, and
+the gradient-descent -- or more generally Langevin -- dynamics staring from a
+high-energy configuration. Thanks to the relative simplicity of the energy,
+all these approaches are possible analytically in the large $N$ limit.
In this paper we shall extend the study to the case where $z\in\mathbb C^N$ are and $J$ is a symmetric tensor
whose elements are complex normal with $\overline{|J|^2}=p!/2N^{p-1}$ and
$\overline{J^2}=\kappa\overline{|J|^2}$ for complex parameter $|\kappa|<1$. The constraint becomes $z^2=N$.
The motivations for this paper are of two types. On the practical side, there are situations in which complex variables
-have in a disorder problem appear naturally: such is the case in which they are {\em phases}, as in random laser problems \cite{Leuzzi-Crisanti, etc}. Another problem where a Hamiltonian very close to ours has been proposed is the Quiver Hamiltonians \cite{Anninos-Anous-Denef} modeling Black Hole horizons in the zero-temperature limit.
+have in a disorder problem appear naturally: such is the case in which they are {\em phases}, as in random laser problems \cite{Antenucci_2015_Complex, etc}. Another problem where a Hamiltonian very close to ours has been proposed is the Quiver Hamiltonians \cite{Anninos_2016_Disordered} modeling Black Hole horizons in the zero-temperature limit.
There is however a more fundamental reason for this study: we know from experience that extending a problem to the complex plane often uncovers an underlying simplicity that is hidden in the purely real case. Consider, for example, the procedure of starting from a simple, known Hamiltonian $H_{00}$ and studying $\lambda H_{00} + (1-\lambda H_{0} )$, evolving adiabatically from $\lambda=0$ to $\lambda=1$, as is familiar from quantum annealing. The $H_{00}$ is a polynomial of degree $p$ chosen to have simple, known roots. Because we are working in
complex variables, and the roots are simple all the way (we shall confirm this), we may follow a root from $\lambda=0$ to $\lambda=1$. With real
@@ -98,7 +102,7 @@ $N \Sigma=
\overline{\ln \mathcal N_J} = \int dJ \; \ln N_J$, a calculation that involves the replica trick. In most, but not all, of the parameter-space that we shall study here, the {\em annealed approximation} $N \Sigma \sim
\ln \overline{ \mathcal N_J} = \ln \int dJ \; N_J$ is exact.
-A useful property of the Gaussian distributions is that gradient and Hessian may be seen to be independent \cite{BrayDean,Fyodorov},
+A useful property of the Gaussian distributions is that gradient and Hessian may be seen to be independent \cite{Bray_2007_Statistics, Fyodorov_2004_Complexity},
so that we may treat the delta-functions and the Hessians as independent.
}