Difference between revisions of "Overlap"

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The massless overlap is defined by
 
The massless overlap is defined by
  
<math>\mathbf{D_0} = \rho(1+\gamma_5)\epsilon(H)</math>
+
<math>\mathbf{D_0} = \rho(1+\gamma_5)\varepsilon(H)</math>
  
 +
Where <math>\rho=  4 - 1/2\kappa</math>, <math>\kappa </math> is a positive number. 
 +
<math>H</math> is the hermitian Wilson operator, and <math>\epsilon(H)</math> is the matrix sign function.
 
Given a vector <math>\vec{\eta}</math>, we want to compute the solution <math>\vec{x}</math>, which is the matrix vector multiplication
 
Given a vector <math>\vec{\eta}</math>, we want to compute the solution <math>\vec{x}</math>, which is the matrix vector multiplication
  
 
<math>\mathbf{D_0} \vec{\eta} = \vec{x} </math>
 
<math>\mathbf{D_0} \vec{\eta} = \vec{x} </math>

Latest revision as of 09:29, 31 August 2010

The intention of these notes is to outline how we construct the overlap operator in the gwu-qcd framework. The overlap operator preserves chiral symmetry on the lattice, and is the most ideal operator used to explore low pion masses. The massless overlap is defined by

\(\mathbf{D_0} = \rho(1+\gamma_5)\varepsilon(H)\)

Where \(\rho= 4 - 1/2\kappa\), \(\kappa \) is a positive number. \(H\) is the hermitian Wilson operator, and \(\epsilon(H)\) is the matrix sign function. Given a vector \(\vec{\eta}\), we want to compute the solution \(\vec{x}\), which is the matrix vector multiplication

\(\mathbf{D_0} \vec{\eta} = \vec{x} \)