matlab_class/gcmfaces_diags/diags_set_D.m


%select kBudget:
if ~isempty(setDiagsParams);
  kBudget=setDiagsParams{1};
else;
  kBudget=1;
end;

doMoreBudgetOutput=0;
%doMoreBudgetOutput=1;

%override default file name:
%---------------------------
tmp1=setDiags;
if kBudget>1;
    tmp1=sprintf('D%02i',kBudget);
end;
fileMat=['diags_set_' tmp1];

if userStep==1;%diags to be computed
    listDiags=['glo_vol_ocn glo_vol_tot glo_vol_ice glo_bp'];
    listDiags=[listDiags ' north_vol_ocn north_vol_tot north_vol_ice north_bp'];
    listDiags=[listDiags ' south_vol_ocn south_vol_tot south_vol_ice south_bp'];
    listDiags=[listDiags ' glo_heat_ocn glo_heat_tot glo_heat_ice'];
    listDiags=[listDiags ' north_heat_ocn north_heat_tot north_heat_ice'];
    listDiags=[listDiags ' south_heat_ocn south_heat_tot south_heat_ice'];
    listDiags=[listDiags ' glo_salt_ocn glo_salt_tot glo_salt_ice'];
    listDiags=[listDiags ' north_salt_ocn north_salt_tot north_salt_ice'];
    listDiags=[listDiags ' south_salt_ocn south_salt_tot south_salt_ice'];

elseif userStep==2;%input files and variables
    dirSnap=fullfile(dirModel,'diags',filesep,'BUDG',filesep);
    if ~isdir(dirSnap); dirSnap=fullfile(dirModel,'diags',filesep); end;
    tmp1=fullfile(dirSnap,'budg2d_snap_set2*meta');
    test3d=isempty(dir(tmp1));
    %
    listFlds={    'ETAN','SIheff','SIhsnow','THETA   ','SALT    ','PHIBOT','geothFlux'};
    listFlds={listFlds{:},'SIatmFW ','oceFWflx','SItflux','TFLUX','SFLUX','oceSPflx','SRELAX'};
    listFlds={listFlds{:},'oceQnet ','SIatmQnt','SIaaflux','SIsnPrcp','SIacSubl'};
    listFlds={listFlds{:},'TRELAX','WTHMASS','WSLTMASS','oceSflux','oceQsw','oceSPtnd'};
    if kBudget>1|test3d;
        listFlds={listFlds{:},'ADVr_TH','DFrE_TH','DFrI_TH','ADVr_SLT','DFrE_SLT','DFrI_SLT','WVELMASS'};
    end;
    listFlds={listFlds{:},'SDIAG1','SDIAG2','SDIAG3'};
    listFlds={listFlds{:},'UVELMASS','VVELMASS','AB_gT','AB_gS'};
    listFlds={listFlds{:},'ADVx_TH ','ADVy_TH ','DFxE_TH ','DFyE_TH '};
    listFlds={listFlds{:},'ADVx_SLT','ADVy_SLT','DFxE_SLT','DFyE_SLT'};
    listFlds={listFlds{:},'ADVxHEFF','ADVyHEFF','DFxEHEFF','DFyEHEFF'};
    listFlds={listFlds{:},'ADVxSNOW','ADVySNOW','DFxESNOW','DFyESNOW'};
    listFldsNames=deblank(listFlds);
    %
    listFiles={'rate_budg2d_snap_set1','budg2d_hflux_set1','budg2d_zflux_set1','budg2d_zflux_set2'};
    if test3d;
        listFiles={listFiles{:},'rate_budg3d_snap_set1','budg3d_hflux_set1','budg3d_zflux_set1'};
    elseif kBudget==1;
        listFiles={listFiles{:},'rate_budg2d_snap_set2','budg2d_hflux_set2','geothermalFlux'};
    else;
        tmp1=sprintf('rate_budg2d_snap_set3_%02i',kBudget);
        tmp2=sprintf('budg2d_zflux_set3_%02i',kBudget);
        tmp3=sprintf('budg2d_hflux_set3_%02i',kBudget);
        tmp4=sprintf('geothermalFlux_%02i',kBudget);
        listFiles={listFiles{:},tmp1,tmp2,tmp3,tmp4};
    end;
    listSubdirs={[dirMat 'BUDG/' ],[dirMat '../BUDG/' ],dirSnap};

elseif userStep==3;%computational part;

    %preliminary tests
    test1=isempty(dir([dirModel 'diags/BUDG/budg2d_snap_set1*']));
    test2=isempty(dir([dirMat 'BUDG/rate_budg2d_snap_set1*']))&...
          isempty(dir([dirMat '../BUDG/rate_budg2d_snap_set1*']));
    if (strcmp(setDiags,'D')&test1&test2);
        fprintf('\n abort : global and regional budgets, due to missing \n');
        fprintf(['\n   ' dirModel 'diags/BUDG/budg2d_snap_set1* \n']);
        return;
    end;

    if (strcmp(setDiags,'D')&test2);
        fprintf('\n abort : global and regional budgets, due to missing \n');
        fprintf(['\n   ' dirModel 'diags/BUDG/rate_budg2d_snap_set1* \n']);
        return;
    end;
    
    %override default file name:
    %---------------------------
    tmp1=setDiags;
    if kBudget>1;
        tmp1=sprintf('D%02i',kBudget);
    end;
    fileMat=['diags_set_' tmp1 '_' num2str(tt) '.mat'];
        
    %fill in optional fields:
    %------------------------
    if isempty(who('TRELAX')); TRELAX=0; end;
    if isempty(who('SRELAX')); SRELAX=0; end;
    if isempty(who('AB_gT')); AB_gT=0; end;
    if isempty(who('AB_gS')); AB_gS=0; end;
    if isempty(who('oceSPtnd')); oceSPtnd=0; end;
    if isempty(who('oceSPflx')); oceSPflx=0; end;
    if isempty(who('PHIBOT')); PHIBOT=0; end;
    if isempty(who('geothFlux')); geothFlux=0; end;

    %aliases from development phase (applies to 2012 core runs)
    %---------------------------------------------------------
    if ~isempty(who('SDIAG1')); SRELAX=SDIAG1; end;
    if ~isempty(who('SDIAG2')); SIatmFW=SDIAG2; end;
    if ~isempty(who('SDIAG3')); SItflux=SDIAG3; end;

    %=======indexing and sign convention======

    %- MITgcm: fluxes are >0 downward, k=1 start at free surface
    %- here, similarly: >0 downward, k=1 free surface k=2 sea floor        
    if ~test3d;
      budgO.specs.top='free surface';
      if kBudget>1; budgO.specs.top=['interface no. ' num2str(kBudget)]; end;
      budgO.specs.bottom='sea floor';
    else;
      budgO.specs.top='interface k';
      budgO.specs.bottom='interface k+1';
    end;
    budgI.specs.top='ocn-ice to atm interface';
    budgI.specs.bottom='free surface';
    
    %here we output tendencies and fluxes in kg/s
    budgMo=budgO; budgMi=budgI;
    budgMo.specs.units='kg/s';%ocean only
    budgMi.specs.units='kg/s';%ice only
    %here we output tendencies and fluxes in Watts
    budgHo=budgO; budgHi=budgI;
    budgHo.specs.units='W';%ocean only
    budgHi.specs.units='W';%ice only
    %here we output tendencies and fluxes in g/s
    budgSo=budgO; budgSi=budgI;
    budgSo.specs.units='g/s';%ocean only
    budgSi.specs.units='g/s';%ice only        

    %=======MASS=========

    [budgMo,budgMi,budgMoi]=calc_budget_mass(kBudget);
    
    %bottom pressure for comparison:
    bp=myparms.rhoconst/9.81*PHIBOT;

    %compute global integrals:
    %-------------------------
    msk=mygrid.mskC(:,:,kBudget);
    tmp1=calc_mskmean_T(budgMoi,msk,'extensive');
    glo_vol_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgMo,msk,'extensive');
    glo_vol_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgMi,msk,'extensive');
    glo_vol_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];

    glo_bp=nansum(bp.*msk.*mygrid.RAC)/nansum(msk.*mygrid.RAC);
    
    %compute northern hemisphere integrals:
    msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC>0);
    tmp1=calc_mskmean_T(budgMoi,msk,'extensive');
    north_vol_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgMo,msk,'extensive');
    north_vol_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgMi,msk,'extensive');
    north_vol_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];

    north_bp=nansum(bp.*msk.*mygrid.RAC)/nansum(msk.*mygrid.RAC);
    
    %and southern hemisphere integrals:
    msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC<=0);
    tmp1=calc_mskmean_T(budgMoi,msk,'extensive');
    south_vol_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgMo,msk,'extensive');
    south_vol_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgMi,msk,'extensive');
    south_vol_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];

    south_bp=nansum(bp.*msk.*mygrid.RAC)/nansum(msk.*mygrid.RAC);
    
    %=======HEAT=======

    [budgHo,budgHi,budgHoi]=calc_budget_heat(kBudget);

    %compute global integrals:
    %-------------------------
    msk=mygrid.mskC(:,:,kBudget);
    tmp1=calc_mskmean_T(budgHoi,msk,'extensive');
    glo_heat_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgHo,msk,'extensive');
    glo_heat_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgHi,msk,'extensive');
    glo_heat_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    
    %compute northern hemisphere integrals:
    msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC>0);
    tmp1=calc_mskmean_T(budgHoi,msk,'extensive');
    north_heat_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgHo,msk,'extensive');
    north_heat_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgHi,msk,'extensive');
    north_heat_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    
    %and southern hemisphere integrals:
    msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC<=0);
    tmp1=calc_mskmean_T(budgHoi,msk,'extensive');
    south_heat_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgHo,msk,'extensive');
    south_heat_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgHi,msk,'extensive');
    south_heat_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];

    %=======SALT=======

    [budgSo,budgSi,budgSoi]=calc_budget_salt(kBudget);

    %compute global integrals:
    %-------------------------
    msk=mygrid.mskC(:,:,kBudget);
    tmp1=calc_mskmean_T(budgSoi,msk,'extensive');
    glo_salt_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgSo,msk,'extensive');
    glo_salt_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgSi,msk,'extensive');
    glo_salt_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];

    %compute northern hemisphere integrals:
    msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC>0);
    tmp1=calc_mskmean_T(budgSoi,msk,'extensive');
    north_salt_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgSo,msk,'extensive');
    north_salt_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgSi,msk,'extensive');
    north_salt_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    
    %and southern hemisphere integrals:
    msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC<=0);
    tmp1=calc_mskmean_T(budgSoi,msk,'extensive');
    south_salt_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgSo,msk,'extensive');
    south_salt_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
    tmp1=calc_mskmean_T(budgSi,msk,'extensive');
    south_salt_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];

    if doMoreBudgetOutput;
        %list of budgets to output
        listbudg={'budgMo','budgHo','budgSo'};
        if kBudget==1; listbudg={listbudg{:},'budgMi','budgHi','budgSi'}; end;
        %the actual output
        for iibudg=1:length(listbudg);
            %set directory name
            dirbudg=dirMat;
            if ~isempty(strfind(dirMat,['diags_set_' setDiags '/']))
                dirbudg=fullfile(dirMat,'..',filesep);
            end;
            sufbudg=''; 
            if kBudget>1; sufbudg=num2str(kBudget); end;
            dirbudg=fullfile(dirbudg,['diags_set_' listbudg{iibudg} sufbudg],filesep);
            %
            if ~isdir(dirbudg); mkdir(dirbudg); end;
            %set file name
            filebudg=[listbudg{iibudg} '_' num2str(tt) '.mat'];
            %output to file
            eval(['tmpbudg=' listbudg{iibudg} ';']);
            save([dirbudg filebudg],'-struct','tmpbudg');
        end;
    end;

%===================== COMPUTATIONAL SEQUENCE ENDS =========================%
%===================== PLOTTING SEQUENCE BEGINS    =========================%

elseif userStep==-1;%plotting

    if isempty(setDiagsParams);
      choicePlot={'all'};
    elseif isnumeric(setDiagsParams{1})&length(setDiagsParams)==1;
      choicePlot={'all'};
    elseif isnumeric(setDiagsParams{1});
      choicePlot={setDiagsParams{2:end}};
    else;
      choicePlot=setDiagsParams;
    end;

    tt=[1:length(alldiag.listTimes)];
    TT=alldiag.listTimes(tt);
    nt=length(TT);

    if (kBudget==1)&(sum(strcmp(choicePlot,'all'))|sum(strcmp(choicePlot,'mass')));

        %1.1) ocean+seaice mass budgets
        %------------------------------
        figureL;
        %global volume budget:
        subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_vol_tot,'kg/m^2','Global Mean Mass (incl. ice)');
        %add bp:
        dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.glo_bp);
        plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
        %northern hemisphere budget:
        subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_vol_tot,'kg/m^2','Northern Mean Mass (incl. ice)');
        %add bp:
        dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.north_bp);
        plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
        %southern hemisphere budget:
        subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_vol_tot,'kg/m^2','Southern Mean Mass (incl. ice)');
        %add bp:
        dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.south_bp);
        plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
        %add to tex file
        myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
        myCaption={myCaption{:},'mass budget (ocean+ice) in kg/m$^2$.'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

        %1.2) ice mass budgets
        %---------------------
        figureL;
        subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_vol_ice,'kg/m^2','Global Mean Mass (only ice)');
        dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.glo_bp);
        plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
        subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_vol_ice,'kg/m^2','Northern Mean Mass (only ice)');
        dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.north_bp);
        plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
        subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_vol_ice,'kg/m^2','Southern Mean Mass (only ice)');
        dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.south_bp);
        plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
        %add to tex file
        myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
        myCaption={myCaption{:},'mass budget (ice only) in kg/m$^2$.'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

    end;

    if (sum(strcmp(choicePlot,'all'))|sum(strcmp(choicePlot,'mass')));

    %1.3) ocean mass budgets
    %-----------------------
    figureL;
    %global volume budget:
    subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_vol_ocn,'kg/m^2','Global Mean Mass (only ocean)');
    dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.glo_bp);
    plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
    subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_vol_ocn,'kg/m^2','Northern Mean Mass (only ocean)');
    dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.north_bp);
    plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
    subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_vol_ocn,'kg/m^2','Southern Mean Mass (only ocean)');
    dt=median(diff(TT))*86400; bp=dt*cumsum(alldiag.south_bp);
    plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
    %add to tex file
    myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
    myCaption={myCaption{:},'mass budget (ocean only) in kg/m$^2$.'};
    if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

    end;

    if (kBudget==1)&(sum(strcmp(choicePlot,'all'))|sum(strcmp(choicePlot,'heat')));

        %2.1) ocean+seaice heat budgets
        %------------------------------
        figureL;
        subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_heat_tot,'J/m^2','Global Mean Ocean Heat (incl. ice)');
        subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_heat_tot,'J/m^2','Northern Mean Ocean Heat (incl. ice)');
        subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_heat_tot,'J/m^2','Southern Mean Ocean Heat (incl. ice)');
        %add to tex file
        myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
        myCaption={myCaption{:},'heat budget (ocean+ice) in J/m$^2$.'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

        %2.2) ice heat budgets
        %---------------------
        figureL;
        subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_heat_ice,'J/m^2','Global Mean Ocean Heat (only ice)');
        subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_heat_ice,'J/m^2','Northern Mean Ocean Heat (only ice)');
        subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_heat_ice,'J/m^2','Southern Mean Ocean Heat (only ice)');
        %add to tex file
        myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
        myCaption={myCaption{:},'heat budget (ice only) in J/m$^2$.'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

    end;

    if (sum(strcmp(choicePlot,'all'))|sum(strcmp(choicePlot,'heat')));

    %2.3) ocean heat budgets
    %-----------------------
    figureL;
    subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_heat_ocn,'J/m^2','Global Mean Ocean Heat (only ocean)');
    subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_heat_ocn,'J/m^2','Northern Mean Ocean Heat (only ocean)');
    subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_heat_ocn,'J/m^2','Southern Mean Ocean Heat (only ocean)');
    %add to tex file
    myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
    myCaption={myCaption{:},'heat budget (ocean only) in J/m$^2$.'};
    if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

    end;

    if (kBudget==1)&(sum(strcmp(choicePlot,'all'))|sum(strcmp(choicePlot,'salt')));

        %3.1) ocean+seaice salt budgets
        %------------------------------
        figureL;
        subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_salt_tot,'g/m^2','Global Mean Ocean Salt (incl. ice)');
        subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_salt_tot,'g/m^2','Northern Mean Ocean Salt (incl. ice)');
        subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_salt_tot,'g/m^2','Southern Mean Ocean Salt (incl. ice)');
        %add to tex file
        myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
        myCaption={myCaption{:},'salt budget (ocean+ice) in g/m$^2$.'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

        %2.2) ice salt budgets
        %---------------------
        figureL;
        subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_salt_ice,'g/m^2','Global Mean Ocean Salt (only ice)');
        subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_salt_ice,'g/m^2','Northern Mean Ocean Salt (only ice)');
        subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_salt_ice,'g/m^2','Southern Mean Ocean Salt (only ice)');
        %add to tex file
        myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
        myCaption={myCaption{:},'salt budget (ice only) in g/m$^2$.'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

    end;


    if (sum(strcmp(choicePlot,'all'))|sum(strcmp(choicePlot,'salt')));

    %3.3) ocean salt budgets
    %-----------------------
    figureL;
    subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_salt_ocn,'g/m^2','Global Mean Ocean Salt (only ocean)');
    subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_salt_ocn,'g/m^2','Northern Mean Ocean Salt (only ocean)');
    subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_salt_ocn,'g/m^2','Southern Mean Ocean Salt (only ocean)');
    %add to tex file
    myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
    myCaption={myCaption{:},'salt budget (ocean only) in g/m$^2$.'};
    if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;

    end;

end;
1	gforget	1.1
2			%select kBudget:
3			if ~isempty(setDiagsParams);
4			kBudget=setDiagsParams{1};
5			else;
6			kBudget=1;
7			end;
8
9	gforget	1.9	doMoreBudgetOutput=0;
10	gforget	1.16	%doMoreBudgetOutput=1;
11	gforget	1.9
12	gforget	1.2	%override default file name:
13			%---------------------------
14			tmp1=setDiags;
15			if kBudget>1;
16			tmp1=sprintf('D%02i',kBudget);
17	gforget	1.1	end;
18	gforget	1.2	fileMat=['diags_set_' tmp1];
19	gforget	1.1
20			if userStep==1;%diags to be computed
21			listDiags=['glo_vol_ocn glo_vol_tot glo_vol_ice glo_bp'];
22			listDiags=[listDiags ' north_vol_ocn north_vol_tot north_vol_ice north_bp'];
23			listDiags=[listDiags ' south_vol_ocn south_vol_tot south_vol_ice south_bp'];
24			listDiags=[listDiags ' glo_heat_ocn glo_heat_tot glo_heat_ice'];
25			listDiags=[listDiags ' north_heat_ocn north_heat_tot north_heat_ice'];
26			listDiags=[listDiags ' south_heat_ocn south_heat_tot south_heat_ice'];
27			listDiags=[listDiags ' glo_salt_ocn glo_salt_tot glo_salt_ice'];
28			listDiags=[listDiags ' north_salt_ocn north_salt_tot north_salt_ice'];
29			listDiags=[listDiags ' south_salt_ocn south_salt_tot south_salt_ice'];
30	gforget	1.2
31	gforget	1.1	elseif userStep==2;%input files and variables
32	gforget	1.15	dirSnap=fullfile(dirModel,'diags',filesep,'BUDG',filesep);
33			if ~isdir(dirSnap); dirSnap=fullfile(dirModel,'diags',filesep); end;
34			tmp1=fullfile(dirSnap,'budg2d_snap_set2*meta');
35	gforget	1.11	test3d=isempty(dir(tmp1));
36			%
37	gforget	1.16	listFlds={ 'ETAN','SIheff','SIhsnow','THETA ','SALT ','PHIBOT','geothFlux'};
38	gforget	1.1	listFlds={listFlds{:},'SIatmFW ','oceFWflx','SItflux','TFLUX','SFLUX','oceSPflx','SRELAX'};
39			listFlds={listFlds{:},'oceQnet ','SIatmQnt','SIaaflux','SIsnPrcp','SIacSubl'};
40			listFlds={listFlds{:},'TRELAX','WTHMASS','WSLTMASS','oceSflux','oceQsw','oceSPtnd'};
41	gforget	1.11	if kBudget>1\|test3d;
42	gforget	1.1	listFlds={listFlds{:},'ADVr_TH','DFrE_TH','DFrI_TH','ADVr_SLT','DFrE_SLT','DFrI_SLT','WVELMASS'};
43			end;
44	gforget	1.4	listFlds={listFlds{:},'SDIAG1','SDIAG2','SDIAG3'};
45	gforget	1.1	listFlds={listFlds{:},'UVELMASS','VVELMASS','AB_gT','AB_gS'};
46			listFlds={listFlds{:},'ADVx_TH ','ADVy_TH ','DFxE_TH ','DFyE_TH '};
47			listFlds={listFlds{:},'ADVx_SLT','ADVy_SLT','DFxE_SLT','DFyE_SLT'};
48			listFlds={listFlds{:},'ADVxHEFF','ADVyHEFF','DFxEHEFF','DFyEHEFF'};
49			listFlds={listFlds{:},'ADVxSNOW','ADVySNOW','DFxESNOW','DFyESNOW'};
50			listFldsNames=deblank(listFlds);
51			%
52			listFiles={'rate_budg2d_snap_set1','budg2d_hflux_set1','budg2d_zflux_set1','budg2d_zflux_set2'};
53	gforget	1.11	if test3d;
54			listFiles={listFiles{:},'rate_budg3d_snap_set1','budg3d_hflux_set1','budg3d_zflux_set1'};
55			elseif kBudget==1;
56	gforget	1.16	listFiles={listFiles{:},'rate_budg2d_snap_set2','budg2d_hflux_set2','geothermalFlux'};
57	gforget	1.1	else;
58			tmp1=sprintf('rate_budg2d_snap_set3_%02i',kBudget);
59			tmp2=sprintf('budg2d_zflux_set3_%02i',kBudget);
60			tmp3=sprintf('budg2d_hflux_set3_%02i',kBudget);
61	gforget	1.16	tmp4=sprintf('geothermalFlux_%02i',kBudget);
62			listFiles={listFiles{:},tmp1,tmp2,tmp3,tmp4};
63	gforget	1.1	end;
64	gforget	1.15	listSubdirs={[dirMat 'BUDG/' ],[dirMat '../BUDG/' ],dirSnap};
65	gforget	1.2
66	gforget	1.1	elseif userStep==3;%computational part;
67	gforget	1.2
68			%preliminary tests
69			test1=isempty(dir([dirModel 'diags/BUDG/budg2d_snap_set1*']));
70	gforget	1.5	test2=isempty(dir([dirMat 'BUDG/rate_budg2d_snap_set1*']))&...
71			isempty(dir([dirMat '../BUDG/rate_budg2d_snap_set1*']));
72	gforget	1.2	if (strcmp(setDiags,'D')&test1&test2);
73			fprintf('\n abort : global and regional budgets, due to missing \n');
74			fprintf(['\n ' dirModel 'diags/BUDG/budg2d_snap_set1* \n']);
75			return;
76			end;
77
78			if (strcmp(setDiags,'D')&test2);
79			fprintf('\n abort : global and regional budgets, due to missing \n');
80			fprintf(['\n ' dirModel 'diags/BUDG/rate_budg2d_snap_set1* \n']);
81			return;
82			end;
83	gforget	1.1
84			%override default file name:
85			%---------------------------
86			tmp1=setDiags;
87			if kBudget>1;
88			tmp1=sprintf('D%02i',kBudget);
89			end;
90			fileMat=['diags_set_' tmp1 '_' num2str(tt) '.mat'];
91
92			%fill in optional fields:
93			%------------------------
94	gforget	1.11	if isempty(who('TRELAX')); TRELAX=0; end;
95			if isempty(who('SRELAX')); SRELAX=0; end;
96			if isempty(who('AB_gT')); AB_gT=0; end;
97			if isempty(who('AB_gS')); AB_gS=0; end;
98			if isempty(who('oceSPtnd')); oceSPtnd=0; end;
99			if isempty(who('oceSPflx')); oceSPflx=0; end;
100			if isempty(who('PHIBOT')); PHIBOT=0; end;
101	gforget	1.16	if isempty(who('geothFlux')); geothFlux=0; end;
102	gforget	1.4
103			%aliases from development phase (applies to 2012 core runs)
104			%---------------------------------------------------------
105			if ~isempty(who('SDIAG1')); SRELAX=SDIAG1; end;
106			if ~isempty(who('SDIAG2')); SIatmFW=SDIAG2; end;
107			if ~isempty(who('SDIAG3')); SItflux=SDIAG3; end;
108
109	gforget	1.17	%=======indexing and sign convention======
110
111			%- MITgcm: fluxes are >0 downward, k=1 start at free surface
112			%- here, similarly: >0 downward, k=1 free surface k=2 sea floor
113			if ~test3d;
114			budgO.specs.top='free surface';
115			if kBudget>1; budgO.specs.top=['interface no. ' num2str(kBudget)]; end;
116			budgO.specs.bottom='sea floor';
117			else;
118			budgO.specs.top='interface k';
119			budgO.specs.bottom='interface k+1';
120			end;
121			budgI.specs.top='ocn-ice to atm interface';
122			budgI.specs.bottom='free surface';
123	gforget	1.1
124	gforget	1.17	%here we output tendencies and fluxes in kg/s
125			budgMo=budgO; budgMi=budgI;
126			budgMo.specs.units='kg/s';%ocean only
127			budgMi.specs.units='kg/s';%ice only
128			%here we output tendencies and fluxes in Watts
129			budgHo=budgO; budgHi=budgI;
130			budgHo.specs.units='W';%ocean only
131			budgHi.specs.units='W';%ice only
132			%here we output tendencies and fluxes in g/s
133			budgSo=budgO; budgSi=budgI;
134			budgSo.specs.units='g/s';%ocean only
135			budgSi.specs.units='g/s';%ice only
136
137	gforget	1.1	%=======MASS=========
138	gforget	1.17
139	gforget	1.19	[budgMo,budgMi,budgMoi]=calc_budget_mass(kBudget);
140	gforget	1.1
141			%bottom pressure for comparison:
142			bp=myparms.rhoconst/9.81*PHIBOT;
143	gforget	1.20
144	gforget	1.1	%compute global integrals:
145			%-------------------------
146			msk=mygrid.mskC(:,:,kBudget);
147	gforget	1.20	tmp1=calc_mskmean_T(budgMoi,msk,'extensive');
148			glo_vol_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
149			tmp1=calc_mskmean_T(budgMo,msk,'extensive');
150			glo_vol_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
151			tmp1=calc_mskmean_T(budgMi,msk,'extensive');
152			glo_vol_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
153
154	gforget	1.1	glo_bp=nansum(bp.msk.mygrid.RAC)/nansum(msk.*mygrid.RAC);
155
156			%compute northern hemisphere integrals:
157			msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC>0);
158	gforget	1.20	tmp1=calc_mskmean_T(budgMoi,msk,'extensive');
159			north_vol_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
160			tmp1=calc_mskmean_T(budgMo,msk,'extensive');
161			north_vol_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
162			tmp1=calc_mskmean_T(budgMi,msk,'extensive');
163			north_vol_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
164
165	gforget	1.1	north_bp=nansum(bp.msk.mygrid.RAC)/nansum(msk.*mygrid.RAC);
166
167			%and southern hemisphere integrals:
168			msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC<=0);
169	gforget	1.20	tmp1=calc_mskmean_T(budgMoi,msk,'extensive');
170			south_vol_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
171			tmp1=calc_mskmean_T(budgMo,msk,'extensive');
172			south_vol_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
173			tmp1=calc_mskmean_T(budgMi,msk,'extensive');
174			south_vol_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
175
176	gforget	1.1	south_bp=nansum(bp.msk.mygrid.RAC)/nansum(msk.*mygrid.RAC);
177
178			%=======HEAT=======
179	gforget	1.11
180	gforget	1.19	[budgHo,budgHi,budgHoi]=calc_budget_heat(kBudget);
181	gforget	1.17
182	gforget	1.1	%compute global integrals:
183			%-------------------------
184			msk=mygrid.mskC(:,:,kBudget);
185	gforget	1.20	tmp1=calc_mskmean_T(budgHoi,msk,'extensive');
186			glo_heat_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
187			tmp1=calc_mskmean_T(budgHo,msk,'extensive');
188			glo_heat_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
189			tmp1=calc_mskmean_T(budgHi,msk,'extensive');
190			glo_heat_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
191	gforget	1.1
192			%compute northern hemisphere integrals:
193			msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC>0);
194	gforget	1.20	tmp1=calc_mskmean_T(budgHoi,msk,'extensive');
195			north_heat_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
196			tmp1=calc_mskmean_T(budgHo,msk,'extensive');
197			north_heat_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
198			tmp1=calc_mskmean_T(budgHi,msk,'extensive');
199			north_heat_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
200	gforget	1.1
201			%and southern hemisphere integrals:
202			msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC<=0);
203	gforget	1.20	tmp1=calc_mskmean_T(budgHoi,msk,'extensive');
204			south_heat_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
205			tmp1=calc_mskmean_T(budgHo,msk,'extensive');
206			south_heat_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
207			tmp1=calc_mskmean_T(budgHi,msk,'extensive');
208			south_heat_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
209	gforget	1.11
210	gforget	1.1	%=======SALT=======
211	gforget	1.17
212	gforget	1.19	[budgSo,budgSi,budgSoi]=calc_budget_salt(kBudget);
213	gforget	1.17
214	gforget	1.1	%compute global integrals:
215			%-------------------------
216			msk=mygrid.mskC(:,:,kBudget);
217	gforget	1.20	tmp1=calc_mskmean_T(budgSoi,msk,'extensive');
218			glo_salt_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
219			tmp1=calc_mskmean_T(budgSo,msk,'extensive');
220			glo_salt_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
221			tmp1=calc_mskmean_T(budgSi,msk,'extensive');
222			glo_salt_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
223
224	gforget	1.1	%compute northern hemisphere integrals:
225			msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC>0);
226	gforget	1.20	tmp1=calc_mskmean_T(budgSoi,msk,'extensive');
227			north_salt_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
228			tmp1=calc_mskmean_T(budgSo,msk,'extensive');
229			north_salt_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
230			tmp1=calc_mskmean_T(budgSi,msk,'extensive');
231			north_salt_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
232	gforget	1.1
233			%and southern hemisphere integrals:
234			msk=mygrid.mskC(:,:,kBudget).*(mygrid.YC<=0);
235	gforget	1.20	tmp1=calc_mskmean_T(budgSoi,msk,'extensive');
236			south_salt_tot=[tmp1.cont;tmp1.hconv;tmp1.zconv];
237			tmp1=calc_mskmean_T(budgSo,msk,'extensive');
238			south_salt_ocn=[tmp1.cont;tmp1.hconv;tmp1.zconv];
239			tmp1=calc_mskmean_T(budgSi,msk,'extensive');
240			south_salt_ice=[tmp1.cont;tmp1.hconv;tmp1.zconv];
241	gforget	1.2
242	gforget	1.9	if doMoreBudgetOutput;
243			%list of budgets to output
244			listbudg={'budgMo','budgHo','budgSo'};
245			if kBudget==1; listbudg={listbudg{:},'budgMi','budgHi','budgSi'}; end;
246			%the actual output
247			for iibudg=1:length(listbudg);
248			%set directory name
249			dirbudg=dirMat;
250			if ~isempty(strfind(dirMat,['diags_set_' setDiags '/']))
251			dirbudg=fullfile(dirMat,'..',filesep);
252			end;
253			sufbudg='';
254			if kBudget>1; sufbudg=num2str(kBudget); end;
255			dirbudg=fullfile(dirbudg,['diags_set_' listbudg{iibudg} sufbudg],filesep);
256			%
257			if ~isdir(dirbudg); mkdir(dirbudg); end;
258			%set file name
259			filebudg=[listbudg{iibudg} '_' num2str(tt) '.mat'];
260			%output to file
261			eval(['tmpbudg=' listbudg{iibudg} ';']);
262			save([dirbudg filebudg],'-struct','tmpbudg');
263			end;
264			end;
265	gforget	1.13
266	gforget	1.2	%===================== COMPUTATIONAL SEQUENCE ENDS =========================%
267			%===================== PLOTTING SEQUENCE BEGINS =========================%
268
269			elseif userStep==-1;%plotting
270
271			if isempty(setDiagsParams);
272			choicePlot={'all'};
273			elseif isnumeric(setDiagsParams{1})&length(setDiagsParams)==1;
274			choicePlot={'all'};
275			elseif isnumeric(setDiagsParams{1});
276			choicePlot={setDiagsParams{2:end}};
277			else;
278			choicePlot=setDiagsParams;
279			end;
280
281	gforget	1.3	tt=[1:length(alldiag.listTimes)];
282			TT=alldiag.listTimes(tt);
283			nt=length(TT);
284
285	gforget	1.2	if (kBudget==1)&(sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'mass')));
286
287			%1.1) ocean+seaice mass budgets
288			%------------------------------
289			figureL;
290			%global volume budget:
291	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_vol_tot,'kg/m^2','Global Mean Mass (incl. ice)');
292	gforget	1.2	%add bp:
293			dt=median(diff(TT))86400; bp=dtcumsum(alldiag.glo_bp);
294			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
295			%northern hemisphere budget:
296	heimbach	1.6	subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_vol_tot,'kg/m^2','Northern Mean Mass (incl. ice)');
297	gforget	1.2	%add bp:
298			dt=median(diff(TT))86400; bp=dtcumsum(alldiag.north_bp);
299			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
300			%southern hemisphere budget:
301	heimbach	1.6	subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_vol_tot,'kg/m^2','Southern Mean Mass (incl. ice)');
302	gforget	1.2	%add bp:
303			dt=median(diff(TT))86400; bp=dtcumsum(alldiag.south_bp);
304			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
305			%add to tex file
306			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
307	heimbach	1.6	myCaption={myCaption{:},'mass budget (ocean+ice) in kg/m$^2$.'};
308	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
309
310			%1.2) ice mass budgets
311			%---------------------
312			figureL;
313	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_vol_ice,'kg/m^2','Global Mean Mass (only ice)');
314	gforget	1.2	dt=median(diff(TT))86400; bp=dtcumsum(alldiag.glo_bp);
315			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
316	heimbach	1.6	subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_vol_ice,'kg/m^2','Northern Mean Mass (only ice)');
317	gforget	1.2	dt=median(diff(TT))86400; bp=dtcumsum(alldiag.north_bp);
318			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
319	heimbach	1.6	subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_vol_ice,'kg/m^2','Southern Mean Mass (only ice)');
320	gforget	1.2	dt=median(diff(TT))86400; bp=dtcumsum(alldiag.south_bp);
321			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
322			%add to tex file
323			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
324	heimbach	1.6	myCaption={myCaption{:},'mass budget (ice only) in kg/m$^2$.'};
325	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
326
327			end;
328
329			if (sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'mass')));
330
331			%1.3) ocean mass budgets
332			%-----------------------
333			figureL;
334			%global volume budget:
335	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_vol_ocn,'kg/m^2','Global Mean Mass (only ocean)');
336	gforget	1.2	dt=median(diff(TT))86400; bp=dtcumsum(alldiag.glo_bp);
337			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
338	heimbach	1.6	subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_vol_ocn,'kg/m^2','Northern Mean Mass (only ocean)');
339	gforget	1.2	dt=median(diff(TT))86400; bp=dtcumsum(alldiag.north_bp);
340			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
341	heimbach	1.6	subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_vol_ocn,'kg/m^2','Southern Mean Mass (only ocean)');
342	gforget	1.2	dt=median(diff(TT))86400; bp=dtcumsum(alldiag.south_bp);
343			plot(TT,bp,'k'); aa=legend; bb=get(aa,'String'); bb={bb{:},'bp'}; legend(bb,'Orientation','horizontal');
344			%add to tex file
345			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
346	heimbach	1.6	myCaption={myCaption{:},'mass budget (ocean only) in kg/m$^2$.'};
347	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
348
349			end;
350
351			if (kBudget==1)&(sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'heat')));
352
353			%2.1) ocean+seaice heat budgets
354			%------------------------------
355			figureL;
356	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_heat_tot,'J/m^2','Global Mean Ocean Heat (incl. ice)');
357			subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_heat_tot,'J/m^2','Northern Mean Ocean Heat (incl. ice)');
358			subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_heat_tot,'J/m^2','Southern Mean Ocean Heat (incl. ice)');
359	gforget	1.2	%add to tex file
360			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
361	heimbach	1.6	myCaption={myCaption{:},'heat budget (ocean+ice) in J/m$^2$.'};
362	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
363
364			%2.2) ice heat budgets
365			%---------------------
366			figureL;
367	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_heat_ice,'J/m^2','Global Mean Ocean Heat (only ice)');
368			subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_heat_ice,'J/m^2','Northern Mean Ocean Heat (only ice)');
369			subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_heat_ice,'J/m^2','Southern Mean Ocean Heat (only ice)');
370	gforget	1.2	%add to tex file
371			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
372	heimbach	1.6	myCaption={myCaption{:},'heat budget (ice only) in J/m$^2$.'};
373	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
374
375			end;
376
377			if (sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'heat')));
378
379			%2.3) ocean heat budgets
380			%-----------------------
381			figureL;
382	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_heat_ocn,'J/m^2','Global Mean Ocean Heat (only ocean)');
383			subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_heat_ocn,'J/m^2','Northern Mean Ocean Heat (only ocean)');
384			subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_heat_ocn,'J/m^2','Southern Mean Ocean Heat (only ocean)');
385	gforget	1.2	%add to tex file
386			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
387	heimbach	1.6	myCaption={myCaption{:},'heat budget (ocean only) in J/m$^2$.'};
388	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
389
390			end;
391
392			if (kBudget==1)&(sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'salt')));
393
394			%3.1) ocean+seaice salt budgets
395			%------------------------------
396			figureL;
397	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_salt_tot,'g/m^2','Global Mean Ocean Salt (incl. ice)');
398			subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_salt_tot,'g/m^2','Northern Mean Ocean Salt (incl. ice)');
399			subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_salt_tot,'g/m^2','Southern Mean Ocean Salt (incl. ice)');
400	gforget	1.2	%add to tex file
401			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
402	heimbach	1.6	myCaption={myCaption{:},'salt budget (ocean+ice) in g/m$^2$.'};
403	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
404
405			%2.2) ice salt budgets
406			%---------------------
407			figureL;
408	heimbach	1.6	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_salt_ice,'g/m^2','Global Mean Ocean Salt (only ice)');
409			subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_salt_ice,'g/m^2','Northern Mean Ocean Salt (only ice)');
410			subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_salt_ice,'g/m^2','Southern Mean Ocean Salt (only ice)');
411	gforget	1.2	%add to tex file
412			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
413	heimbach	1.6	myCaption={myCaption{:},'salt budget (ice only) in g/m$^2$.'};
414	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
415
416			end;
417
418
419			if (sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'salt')));
420
421			%3.3) ocean salt budgets
422			%-----------------------
423			figureL;
424	gforget	1.8	subplot(3,1,1); disp_budget_mean_mask(TT,alldiag.glo_salt_ocn,'g/m^2','Global Mean Ocean Salt (only ocean)');
425			subplot(3,1,2); disp_budget_mean_mask(TT,alldiag.north_salt_ocn,'g/m^2','Northern Mean Ocean Salt (only ocean)');
426			subplot(3,1,3); disp_budget_mean_mask(TT,alldiag.south_salt_ocn,'g/m^2','Southern Mean Ocean Salt (only ocean)');
427	gforget	1.2	%add to tex file
428			myCaption={myYmeanTxt,' global (upper) north (mid) and south (lower), '};
429	heimbach	1.6	myCaption={myCaption{:},'salt budget (ocean only) in g/m$^2$.'};
430	gforget	1.2	if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); elseif ~multiTimes; close; end;
431
432			end;
433
434	gforget	1.1	end;