Difference between revisions of "Lattice spacing"
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− | * <math>n_{ | + | * <math>n_{or}</math>: this is computed using the formula from page 3 of [http://xxx.lanl.gov/abs/hep-lat?papernum=9806005 hep-lat/9806005]: <math>n_{or} \approx 1.5 r_0/a</math>. |
− | * <math>n_{skip}</math>: You should also skip <math>20\times (n_{ | + | * <math>n_{skip}</math>: You should also skip <math>20\times (n_{or}+1)</math> steps between two measurements. |
==Lattice spacing for Iwasaki action== | ==Lattice spacing for Iwasaki action== |
Revision as of 19:55, 11 June 2011
Lattice spacing for Wilson action
This page describes the connection between the coupling parameter \(\beta\) that defines the Wilson gauge action and the lattice spacing as determined from measuring the interquark potential.
The relevant studies are:
- Nonperturbatively\[\beta\] obtained from Necco and Sommer (hep-lat/0108008, (2.6), valid up to 6.92)
- Perturbatively: perturbative \(\beta\) ((3.6) in hep-lat/9609025), matched with Necco-Sommer at 6.92
The most common formula we are going to use is the non-perturbative parametrization:
$$ \ln(a/r_0)=-1.6805-1.7139(\beta-6)+0.8155(\beta-6)^2- 0.6667(\beta-6)^3 $$
Since we use a heatbath algorithm together with over-relaxation steps we need to also insure that the parameters used in generating the configuration are chosen properly.
- \(n_{or}\): this is computed using the formula from page 3 of hep-lat/9806005\[n_{or} \approx 1.5 r_0/a\].
- \(n_{skip}\): You should also skip \(20\times (n_{or}+1)\) steps between two measurements.
Lattice spacing for Iwasaki action
This note describes the connection between the coupling parameter \(\beta\) that defines the Iwasaki gauge action and the lattice spacing as determined from measuring the interquark potential.
The relevant papers are
- CP-PACS Collaboration Collaboration, M. Okamoto et. al., Equation of state for pure SU(3) gauge theory with renormalization group improved action, Phys.Rev. D60 (1999) 094510, hep-lat/9905005
The pure gauge partition function for Iwasaki action is given by $$ Z = \int {\cal D}U\, e^{\beta S_g(U)}\,,\qquad S_g(U) = c_0 \sum_p U_p + c_1 \sum_{dp} U_{dp}\,. $$ Here $p$ is the sum over plaquettes and $dp$ indicates the sum over double plaquettes ($1\times 2$ plaquettes). The coefficients are set to $c_0=1-8 c_1$ and $c_1=-0.331$.
The connection between $\beta$ and the lattice spacing is determined non-perturbatively: lattice measurements for the string tension, $\sigma$, are fitted to the following ansatz: $$ a\sqrt{\sigma}\vert_\beta = f(\beta) \frac{1+c_2 \hat{a}(\beta)^2 + c_4 \hat{a}(\beta)^4}{c_0}\,,\qquad \hat{a}(\beta) \equiv \frac{f(\beta)}{f(\beta_1)}\,, $$ where $f(\beta)$ is the two loop scaling function of $SU(3)$ (a perturbative result): $$ f(\beta=6/g^2)\equiv (b_0 g^2)^{-b_1/2b_0^2} e^{-\frac1{2b_0 g^2}} \,, \qquad b_0 = \frac{11}{(4\pi)^2}\,\quad b_1=\frac{102}{(4\pi)^4} \,. $$ The fit uses $\beta_1=2.40$ and the coefficients are $$ c_0=0.524(15)\,, \quad c_2=0.274(76)\,, \quad c_4=0.105(36)\,. $$ The physical value of $\sigma$ is usually set to $440\,{\tt MeV}$. A Mathematica notebook implementing these formulas can be downloaded from here.
As in the case of Wilson action, if we are using heat-bath with over-relaxation, we should set the number of quasi-heat-bath hits to $5$ and the number of over-relation steps to $n_{or}=1.5 r_0/a$ and skip $20\times(n_{or}+1)$ between measurements.