Latest working version

Dipolar Gas Simulator/+Scripts/test.m

@@ -17,8 +17,9 @@ OptionsStruct.CutoffType              = 'Cylindrical';
 OptionsStruct.TrapPotentialType       = 'Harmonic';
 
 OptionsStruct.SimulationMode          = 'ImaginaryTimeEvolution'; % 'ImaginaryTimeEvolution' | 'RealTimeEvolution'
-OptionsStruct.TimeStep                = 50e-06; % in s
-OptionsStruct.SimulationTime          =  4e-03; % in s
+OptionsStruct.TimeStep                = 50E-6; % in s
+OptionsStruct.SimulationTime          = 2E6;  % in s
+OptionsStruct.EnergyTolerance         = 5E-10;
 
 OptionsStruct.SaveData                = true;
 OptionsStruct.SaveDirectory           = './Data';

Dipolar Gas Simulator/+Simulator/@DipolarGas/DipolarGas.m

@@ -8,10 +8,12 @@ classdef DipolarGas < handle & matlab.mixin.Copyable
         TrapFrequencies;
         NumberOfGridPoints;
         Dimensions;
-
+        
         SimulationMode; 
         TimeStep;
         SimulationTime;
+        EnergyTolerance;
+        MinimumTimeStep;
         
         %Flags
         
@@ -46,8 +48,12 @@ classdef DipolarGas < handle & matlab.mixin.Copyable
                 @(x) any(strcmpi(x,{'ImaginaryTimeEvolution','RealTimeEvolution'})));
             addParameter(p, 'TimeStep',         5E-4,...
                 @(x) assert(isnumeric(x) && isscalar(x) && (x > 0)));  
-            addParameter(p, 'SimulationTime',      3,...
+            addParameter(p, 'SimulationTime',    2e6,...
                 @(x) assert(isnumeric(x) && isscalar(x) && (x > 0)));  
+            addParameter(p, 'EnergyTolerance',   1e-10,...
+                @(x) assert(isnumeric(x) && isscalar(x) && (x > 0)));  
+            addParameter(p, 'MinimumTimeStep',   1e-6,...
+                @(x) assert(isnumeric(x) && isscalar(x) && (x > 0)));
             addParameter(p, 'DebugMode',        false,...
                 @islogical);
             addParameter(p, 'SaveData',         false,...
@@ -68,6 +74,8 @@ classdef DipolarGas < handle & matlab.mixin.Copyable
             this.SimulationMode       = p.Results.SimulationMode;
             this.TimeStep             = p.Results.TimeStep;
             this.SimulationTime       = p.Results.SimulationTime;  
+            this.EnergyTolerance      = p.Results.EnergyTolerance;
+            this.MinimumTimeStep      = p.Results.MinimumTimeStep;
             
             this.DebugMode            = p.Results.DebugMode;
             this.DoSave               = p.Results.SaveData;

Dipolar Gas Simulator/+Simulator/@DipolarGas/setupParameters.m

@@ -1,34 +1,34 @@
 function [Params] = setupParameters(this)
 
-CONSTANTS = Helper.PhysicsConstants;
-hbar      = CONSTANTS.PlanckConstantReduced; % [J.s]
-kbol      = CONSTANTS.BoltzmannConstant;     % [J/K]
-mu0       = CONSTANTS.VacuumPermeability;    % [N/A^2]
-muB       = CONSTANTS.BohrMagneton;          % [J/T]
-a0        = CONSTANTS.BohrRadius;            % [m]
-m0        = CONSTANTS.AtomicMassUnit;        % [kg]
-w0        = 2*pi*100;                        % Angular frequency unit [s^-1]
-mu0factor = 0.3049584233607396;              % =(m0/me)*pi*alpha^2 -- me=mass of electron, alpha=fine struct. const.
+CONSTANTS      = Helper.PhysicsConstants;
+hbar           = CONSTANTS.PlanckConstantReduced; % [J.s]
+kbol           = CONSTANTS.BoltzmannConstant;     % [J/K]
+mu0            = CONSTANTS.VacuumPermeability;    % [N/A^2]
+muB            = CONSTANTS.BohrMagneton;          % [J/T]
+a0             = CONSTANTS.BohrRadius;            % [m]
+m0             = CONSTANTS.AtomicMassUnit;        % [kg]
+w0             = 2*pi*100;                        % Angular frequency unit [s^-1]
+mu0factor      = 0.3049584233607396;              % =(m0/me)*pi*alpha^2 -- me=mass of electron, alpha=fine struct. const.
                                              % mu0=mu0factor *hbar^2*a0/(m0*muB^2)
 % Number of points in each direction
-Params.Nx = this.NumberOfGridPoints(1);
-Params.Ny = this.NumberOfGridPoints(2);
-Params.Nz = this.NumberOfGridPoints(3);
+Params.Nx      = this.NumberOfGridPoints(1);
+Params.Ny      = this.NumberOfGridPoints(2);
+Params.Nz      = this.NumberOfGridPoints(3);
 
 % Dimensions (in units of l0)
-Params.Lx = this.Dimensions(1);
-Params.Ly = this.Dimensions(2);
-Params.Lz = this.Dimensions(3);
+Params.Lx      = this.Dimensions(1);
+Params.Ly      = this.Dimensions(2);
+Params.Lz      = this.Dimensions(3);
 
 % Masses
-Params.m = CONSTANTS.Dy164Mass;
-l0       = sqrt(hbar/(Params.m*w0)); % Defining a harmonic oscillator length
+Params.m       = CONSTANTS.Dy164Mass;
+l0             = sqrt(hbar/(Params.m*w0)); % Defining a harmonic oscillator length
 
 % Atom numbers
 Params.N       = this.NumberOfAtoms;
 
 % Dipole angle
-Params.theta   = this.DipolarPolarAngle; % pi/2 dipoles along x, theta=0 dipoles along z 
+Params.theta   = this.DipolarPolarAngle;   % pi/2 dipoles along x, theta=0 dipoles along z 
 Params.phi     = this.DipolarAzimuthAngle;
 
 % Dipole lengths (units of muB)
@@ -38,35 +38,34 @@ Params.mu      = CONSTANTS.DyMagneticMoment;
 Params.as      = this.ScatteringLength*a0;
 
 % Trapping frequencies
-Params.wx = 2*pi*this.TrapFrequencies(1);
-Params.wy = 2*pi*this.TrapFrequencies(2);
-Params.wz = 2*pi*this.TrapFrequencies(3);
+Params.wx      = 2*pi*this.TrapFrequencies(1);
+Params.wy      = 2*pi*this.TrapFrequencies(2);
+Params.wz      = 2*pi*this.TrapFrequencies(3);
 
 % Stochastic GPE
-Params.gamma_S = 7.5*10^(-3); % gamma for the stochastic GPE 
-Params.muchem  = 12.64*Params.wz/w0;         % fixing the chemical potential for the stochastic GPE 
-
-Params.Etol    = 5e-10; % Tolerances
-Params.rtol    = 1e-5;
-Params.cut_off = 2e6;   % sometimes the imaginary time gets a little stuck
-                 % even though the solution is good, this just stops it going on forever
-Params.mindt   = 1e-6;  % Minimum size for a time step using adaptive dt
+Params.gamma_S = 7.5*10^(-3);            % gamma for the stochastic GPE 
+Params.muchem  = 12.64*Params.wz/w0;     % fixing the chemical potential for the stochastic GPE 
 
+Params.Etol    = this.EnergyTolerance;   % Tolerances
+Params.cut_off = this.SimulationTime;    % sometimes the imaginary time gets a little stuck
+                                         % even though the solution is good, this just stops it going on forever
+Params.mindt   = this.MinimumTimeStep;   % Minimum size for a time step using adaptive dt
+ 
 % ================ Parameters defined by those above ================ %
 
 % Contact interaction strength (units of l0/m)
-Params.gs = 4*pi*Params.as/l0;
+Params.gs      = 4*pi*Params.as/l0;
 
 % Dipole lengths
-Params.add = mu0*Params.mu^2*Params.m/(12*pi*hbar^2);
+Params.add     = mu0*Params.mu^2*Params.m/(12*pi*hbar^2);
 
 % DDI strength
-Params.gdd = 12*pi*Params.add/l0; %sometimes the 12 is a 4 --> depends on how Vdk (DDI) is defined
+Params.gdd     = 12*pi*Params.add/l0; %sometimes the 12 is a 4 --> depends on how Vdk (DDI) is defined
 
 % Trap gamma
-Params.gx=(Params.wx/w0)^2;
-Params.gy=(Params.wy/w0)^2;
-Params.gz=(Params.wz/w0)^2;
+Params.gx      = (Params.wx/w0)^2;
+Params.gy      = (Params.wy/w0)^2;
+Params.gz      = (Params.wz/w0)^2;
 
 % == Calculate LHY correction == %
 eps_dd = Params.add/Params.as;
@@ -83,6 +82,11 @@ end
 Params.gammaQF = 128/3*sqrt(pi*(Params.as/l0)^5)*Q5;
 
 % Loading the rest into Params
-Params.hbar = hbar; Params.kbol = kbol; Params.mu0 = mu0; Params.muB = muB; Params.a0 = a0;
-Params.w0 = w0; Params.l0 = l0;
+Params.hbar    = hbar; 
+Params.kbol    = kbol; 
+Params.mu0     = mu0; 
+Params.muB     = muB; 
+Params.a0      = a0;
+Params.w0      = w0; 
+Params.l0      = l0;
 end