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The Analytic Renormalization Group
Finite temperature Euclidean two-point functions in quantum mechanics or quantum field theory are characterized by a discrete set of Fourier coefficients $G_{k}$, $k\in\mathbb Z$, associated with the Matsubara frequencies $\nu_{k}=2\pi k/\beta$. We show that analyticity implies that the coefficients...
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| Lenguaje: | eng |
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2016
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| Acceso en línea: | https://dx.doi.org/10.1016/j.nuclphysb.2016.06.003 http://cds.cern.ch/record/2134239 |
| _version_ | 1780949885498949632 |
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| author | Ferrari, Frank |
| author_facet | Ferrari, Frank |
| author_sort | Ferrari, Frank |
| collection | CERN |
| description | Finite temperature Euclidean two-point functions in quantum mechanics or quantum field theory are characterized by a discrete set of Fourier coefficients $G_{k}$, $k\in\mathbb Z$, associated with the Matsubara frequencies $\nu_{k}=2\pi k/\beta$. We show that analyticity implies that the coefficients $G_{k}$ must satisfy an infinite number of model-independent linear equations that we write down explicitly. In particular, we construct "Analytic Renormalization Group" linear maps $\mathsf A_{\mu}$ which, for any choice of cut-off $\mu$, allow to express the low energy Fourier coefficients for $|\nu_{k}|<\mu$ (with the possible exception of the zero mode $G_{0}$), together with the real-time correlators and spectral functions, in terms of the high energy Fourier coefficients for $|\nu_{k}|\geq\mu$. Operating a simple numerical algorithm, we show that the exact universal linear constraints on $G_{k}$ can be used to systematically improve any random approximate data set obtained, for example, from Monte-Carlo simulations. Our results are illustrated on several explicit examples. |
| id | cern-2134239 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2016 |
| record_format | invenio |
| spelling | cern-21342392023-03-14T18:35:46Zdoi:10.1016/j.nuclphysb.2016.06.003http://cds.cern.ch/record/2134239engFerrari, FrankThe Analytic Renormalization GroupParticle Physics - LatticeFinite temperature Euclidean two-point functions in quantum mechanics or quantum field theory are characterized by a discrete set of Fourier coefficients $G_{k}$, $k\in\mathbb Z$, associated with the Matsubara frequencies $\nu_{k}=2\pi k/\beta$. We show that analyticity implies that the coefficients $G_{k}$ must satisfy an infinite number of model-independent linear equations that we write down explicitly. In particular, we construct "Analytic Renormalization Group" linear maps $\mathsf A_{\mu}$ which, for any choice of cut-off $\mu$, allow to express the low energy Fourier coefficients for $|\nu_{k}|<\mu$ (with the possible exception of the zero mode $G_{0}$), together with the real-time correlators and spectral functions, in terms of the high energy Fourier coefficients for $|\nu_{k}|\geq\mu$. Operating a simple numerical algorithm, we show that the exact universal linear constraints on $G_{k}$ can be used to systematically improve any random approximate data set obtained, for example, from Monte-Carlo simulations. Our results are illustrated on several explicit examples.Finite temperature Euclidean two-point functions in quantum mechanics or quantum field theory are characterized by a discrete set of Fourier coefficients Gk , k∈Z , associated with the Matsubara frequencies νk=2πk/β . We show that analyticity implies that the coefficients Gk must satisfy an infinite number of model-independent linear equations that we write down explicitly. In particular, we construct “Analytic Renormalization Group” linear maps Aμ which, for any choice of cut-off μ , allow to express the low energy Fourier coefficients for |νk|<μ (with the possible exception of the zero mode G0 ), together with the real-time correlators and spectral functions, in terms of the high energy Fourier coefficients for |νk|≥μ . Operating a simple numerical algorithm, we show that the exact universal linear constraints on Gk can be used to systematically improve any random approximate data set obtained, for example, from Monte-Carlo simulations. Our results are illustrated on several explicit examples.Finite temperature Euclidean two-point functions in quantum mechanics or quantum field theory are characterized by a discrete set of Fourier coefficients $G_{k}$, $k\in\mathbb Z$, associated with the Matsubara frequencies $\nu_{k}=2\pi k/\beta$. We show that analyticity implies that the coefficients $G_{k}$ must satisfy an infinite number of model-independent linear equations that we write down explicitly. In particular, we construct "Analytic Renormalization Group" linear maps $\mathsf A_{\mu}$ which, for any choice of cut-off $\mu$, allow to express the low energy Fourier coefficients for $|\nu_{k}|<\mu$ (with the possible exception of the zero mode $G_{0}$), together with the real-time correlators and spectral functions, in terms of the high energy Fourier coefficients for $|\nu_{k}|\geq\mu$. Operating a simple numerical algorithm, we show that the exact universal linear constraints on $G_{k}$ can be used to systematically improve any random approximate data set obtained, for example, from Monte-Carlo simulations. Our results are illustrated on several explicit examples.arXiv:1602.07355CERN-TH-2016-023CERN-TH-2016-023oai:cds.cern.ch:21342392016-02-23 |
| spellingShingle | Particle Physics - Lattice Ferrari, Frank The Analytic Renormalization Group |
| title | The Analytic Renormalization Group |
| title_full | The Analytic Renormalization Group |
| title_fullStr | The Analytic Renormalization Group |
| title_full_unstemmed | The Analytic Renormalization Group |
| title_short | The Analytic Renormalization Group |
| title_sort | analytic renormalization group |
| topic | Particle Physics - Lattice |
| url | https://dx.doi.org/10.1016/j.nuclphysb.2016.06.003 http://cds.cern.ch/record/2134239 |
| work_keys_str_mv | AT ferrarifrank theanalyticrenormalizationgroup AT ferrarifrank analyticrenormalizationgroup |