matlab_class/gcmfaces_diags/diags_set_E.m


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

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

if userStep==1;%diags to be computed
    listDiags=['zm_area zm_vol_ocn zm_vol_tot zm_vol_ice'];
    listDiags=[listDiags ' zm_heat_ocn zm_heat_tot zm_heat_ice zm_heat_ocn_diff'];
    listDiags=[listDiags ' zm_salt_ocn zm_salt_tot zm_salt_ice zm_salt_ocn_diff'];
elseif userStep==2;%input files and variables
    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;
        listFlds={listFlds{:},'ADVr_TH','DFrE_TH','DFrI_TH','ADVr_SLT','DFrE_SLT','DFrI_SLT','WVELMASS'};
    end;
    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 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/' ],[dirModel 'diags/BUDG/'],[dirModel 'diags/']};
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,'E')&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,'E')&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('E%02i',kBudget);
    end;
    fileMat=['diags_set_' tmp1 '_' num2str(tt) '.mat'];
    
    %fill in optional fields:
    %------------------------
    if isempty(who('TRELAX')); TRELAX=0*mygrid.XC; end;
    if isempty(who('SRELAX')); SRELAX=0*mygrid.XC; end;
    if isempty(who('AB_gT')); AB_gT=0*mygrid.XC; end;
    if isempty(who('AB_gS')); AB_gS=0*mygrid.XC; end;
    if isempty(who('oceSPtnd')); oceSPtnd=0*mygrid.XC; end;
    if isempty(who('oceSPflx')); oceSPflx=0*mygrid.XC; end;
    if isempty(who('PHIBOT')); PHIBOT=0*mygrid.XC; end;
    if isempty(who('geothFlux')); geothFlux=0; end;
    
    %=======MASS=========

    [budgMo,budgMi,budgMoi]=calc_budget_mass(kBudget);

    %bottom pressure for comparison:
    bp=myparms.rhoconst/9.81*PHIBOT;

    [tmp1,X,Y,zm_area]=calc_zonmean_T(budgMoi,-2,'extensive');
    zm_area=zm_area';
    zm_vol_tot=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    tmp1=calc_zonmean_T(budgMo,-2,'extensive');
    zm_vol_ocn=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    tmp1=calc_zonmean_T(budgMi,-2,'extensive');
    zm_vol_ice=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    
    %=======HEAT=======
    
    [budgHo,budgHi,budgHoi]=calc_budget_heat(kBudget);

    [tmp1]=calc_zonmean_T(budgHoi,-2,'extensive');
    zm_heat_tot=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    tmp1=calc_zonmean_T(budgHo,-2,'extensive');
    zm_heat_ocn=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    tmp1=calc_zonmean_T(budgHi,-2,'extensive');
    zm_heat_ice=[tmp1.cont';tmp1.hconv';tmp1.zconv'];

    %ocean diffusion alone
    tmpU=myparms.rcp*(DFxE_TH); tmpV=myparms.rcp*(DFyE_TH);
    budgD.hconv=calc_UV_conv(tmpU,tmpV); 
    budgD.cont=0*budgD.hconv; budgD.zconv=0*budgD.hconv;
    [tmp1]=calc_zonmean_T(budgD,-2,'extensive');
    zm_heat_ocn_diff=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    
    %=======SALT=======
    
    [budgSo,budgSi,budgSoi]=calc_budget_salt(kBudget);

    [tmp1]=calc_zonmean_T(budgSoi,-2,'extensive');
    zm_salt_tot=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    tmp1=calc_zonmean_T(budgSo,-2,'extensive');
    zm_salt_ocn=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
    tmp1=calc_zonmean_T(budgSi,-2,'extensive');
    zm_salt_ice=[tmp1.cont';tmp1.hconv';tmp1.zconv'];

    %ocean diffusion alone
    tmpU=myparms.rhoconst*(DFxE_SLT); tmpV=myparms.rhoconst*(DFyE_SLT);
    budgD.hconv=calc_UV_conv(tmpU,tmpV);
    budgD.cont=0*budgD.hconv; budgD.zconv=0*budgD.hconv;
    [tmp1]=calc_zonmean_T(budgD,-2,'extensive');
    zm_salt_ocn_diff=[tmp1.cont';tmp1.hconv';tmp1.zconv'];

%===================== 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;
        %volume budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_vol_tot,'kg/m2','Mass (incl. ice)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_vol_tot; cumbudg=cumsum(tmp1,2); 
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'kg','Mass (incl. ice)');
        %add to tex file
        myCaption={myYmeanTxt,'mass budget (ocean+ice) at each latitude in kg/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;

        %1.2) ice mass budgets
        %---------------------
        figureL;
        %volume budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_vol_ice,'kg/m2','Mass (only ice)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_vol_ice; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'kg','Mass (only ice)');
        %add to tex file
        myCaption={myYmeanTxt,'mass budget (only ice) at each latitude in kg/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
    end;

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

    %1.3) ocean mass budgets
    %-----------------------
        figureL;
        %volume budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_vol_ocn,'kg/m2','Mass (ocean only)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_vol_ocn; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'kg','Mass (ocean only)');
        %add to tex file
        myCaption={myYmeanTxt,'mass budget (ocean only) at each latitude in kg/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;

    end;

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

        %1.1) ocean+seaice heat budgets
        %------------------------------
        figureL;
        %heat budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_heat_tot,'J/m2','Heat (incl. ice)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_heat_tot; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'J','Heat (incl. ice)');
        %add to tex file
        myCaption={myYmeanTxt,'heat budget (ocean+ice) at each latitude in J/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;

        %1.2) ice heat budgets
        %---------------------
        figureL;
        %heat budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_heat_ice,'J/m2','Heat (only ice)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_heat_ice; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'J','Heat (only ice)');
        %add to tex file
        myCaption={myYmeanTxt,'heat budget (only ice) at each latitude in J/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
    end;

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

    %1.3) ocean heat budgets
    %-----------------------
        figureL;
        %heat budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_heat_ocn,'J/m2','Heat (ocean only)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_heat_ocn; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'J','Heat (ocean only)');
        %add to tex file
        myCaption={myYmeanTxt,'heat budget (ocean only) at each latitude in J/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;

    end;

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

        %1.1) ocean+seaice salt budgets
        %------------------------------
        figureL;
        %salt budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_salt_tot,'g/m2','Salt (incl. ice)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_salt_tot; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'g','Salt (incl. ice)');
        %add to tex file
        myCaption={myYmeanTxt,'salt budget (ocean+ice) at each latitude in g/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;

        %1.2) ice salt budgets
        %---------------------
        figureL;
        %salt budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_salt_ice,'g/m2','Salt (only ice)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_salt_ice; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'g','Salt (only ice)');
        %add to tex file
        myCaption={myYmeanTxt,'salt budget (only ice) at each latitude in g/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
    end;

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

    %1.3) ocean salt budgets
    %-----------------------
        figureL;
        %salt budget:
        subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_salt_ocn,'g/m2','Salt (ocean only)');
        %cumulative integral:
        tmp1=repmat(alldiag.zm_area,[3 1 1]);
        tmp1=tmp1.*alldiag.zm_salt_ocn; cumbudg=cumsum(tmp1,2);
        subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'g','Salt (ocean only)');
        %add to tex file
        myCaption={myYmeanTxt,'salt budget (ocean only) at each latitude in g/m2 (upper) and integrated from South (lower).'};
        if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); 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			%override default file name:
10			%---------------------------
11			tmp1=setDiags;
12			if kBudget>1;
13	gforget	1.2	tmp1=sprintf('E%02i',kBudget);
14	gforget	1.1	end;
15			fileMat=['diags_set_' tmp1];
16
17			if userStep==1;%diags to be computed
18			listDiags=['zm_area zm_vol_ocn zm_vol_tot zm_vol_ice'];
19			listDiags=[listDiags ' zm_heat_ocn zm_heat_tot zm_heat_ice zm_heat_ocn_diff'];
20			listDiags=[listDiags ' zm_salt_ocn zm_salt_tot zm_salt_ice zm_salt_ocn_diff'];
21			elseif userStep==2;%input files and variables
22	gforget	1.6	listFlds={ 'ETAN','SIheff','SIhsnow','THETA ','SALT ','PHIBOT','geothFlux'};
23	gforget	1.1	listFlds={listFlds{:},'SIatmFW ','oceFWflx','SItflux','TFLUX','SFLUX','oceSPflx','SRELAX'};
24			listFlds={listFlds{:},'oceQnet ','SIatmQnt','SIaaflux','SIsnPrcp','SIacSubl'};
25			listFlds={listFlds{:},'TRELAX','WTHMASS','WSLTMASS','oceSflux','oceQsw','oceSPtnd'};
26			if kBudget>1;
27			listFlds={listFlds{:},'ADVr_TH','DFrE_TH','DFrI_TH','ADVr_SLT','DFrE_SLT','DFrI_SLT','WVELMASS'};
28			end;
29			listFlds={listFlds{:},'UVELMASS','VVELMASS','AB_gT','AB_gS'};
30			listFlds={listFlds{:},'ADVx_TH ','ADVy_TH ','DFxE_TH ','DFyE_TH '};
31			listFlds={listFlds{:},'ADVx_SLT','ADVy_SLT','DFxE_SLT','DFyE_SLT'};
32			listFlds={listFlds{:},'ADVxHEFF','ADVyHEFF','DFxEHEFF','DFyEHEFF'};
33			listFlds={listFlds{:},'ADVxSNOW','ADVySNOW','DFxESNOW','DFyESNOW'};
34			listFldsNames=deblank(listFlds);
35			%
36			listFiles={'rate_budg2d_snap_set1','budg2d_hflux_set1','budg2d_zflux_set1','budg2d_zflux_set2'};
37			if kBudget==1;
38	gforget	1.6	listFiles={listFiles{:},'rate_budg2d_snap_set2','budg2d_hflux_set2','geothermalFlux'};
39	gforget	1.1	else;
40			tmp1=sprintf('rate_budg2d_snap_set3_%02i',kBudget);
41			tmp2=sprintf('budg2d_zflux_set3_%02i',kBudget);
42			tmp3=sprintf('budg2d_hflux_set3_%02i',kBudget);
43	gforget	1.6	tmp4=sprintf('geothermalFlux_%02i',kBudget);
44			listFiles={listFiles{:},tmp1,tmp2,tmp3,tmp4};
45	gforget	1.1	end;
46	gforget	1.5	listSubdirs={[dirMat 'BUDG/' ],[dirMat '../BUDG/' ],[dirModel 'diags/BUDG/'],[dirModel 'diags/']};
47	gforget	1.1	elseif userStep==3;%computational part;
48
49			%preliminary tests
50			test1=isempty(dir([dirModel 'diags/BUDG/budg2d_snap_set1*']));
51	gforget	1.2	test2=isempty(dir([dirMat 'BUDG/rate_budg2d_snap_set1*']))&...
52			isempty(dir([dirMat '../BUDG/rate_budg2d_snap_set1*']));
53	gforget	1.1
54	gforget	1.2	if (strcmp(setDiags,'E')&test1&test2);
55	gforget	1.1	fprintf('\n abort : global and regional budgets, due to missing \n');
56			fprintf(['\n ' dirModel 'diags/BUDG/budg2d_snap_set1* \n']);
57			return;
58			end;
59
60	gforget	1.2	if (strcmp(setDiags,'E')&test2);
61	gforget	1.1	fprintf('\n abort : global and regional budgets, due to missing \n');
62			fprintf(['\n ' dirModel 'diags/BUDG/rate_budg2d_snap_set1* \n']);
63			return;
64			end;
65
66			%override default file name:
67			%---------------------------
68			tmp1=setDiags;
69			if kBudget>1;
70			tmp1=sprintf('E%02i',kBudget);
71			end;
72			fileMat=['diags_set_' tmp1 '_' num2str(tt) '.mat'];
73
74			%fill in optional fields:
75			%------------------------
76			if isempty(who('TRELAX')); TRELAX=0*mygrid.XC; end;
77			if isempty(who('SRELAX')); SRELAX=0*mygrid.XC; end;
78			if isempty(who('AB_gT')); AB_gT=0*mygrid.XC; end;
79			if isempty(who('AB_gS')); AB_gS=0*mygrid.XC; end;
80			if isempty(who('oceSPtnd')); oceSPtnd=0*mygrid.XC; end;
81			if isempty(who('oceSPflx')); oceSPflx=0*mygrid.XC; end;
82			if isempty(who('PHIBOT')); PHIBOT=0*mygrid.XC; end;
83	gforget	1.6	if isempty(who('geothFlux')); geothFlux=0; end;
84	gforget	1.1
85			%=======MASS=========
86	gforget	1.6
87	gforget	1.8	[budgMo,budgMi,budgMoi]=calc_budget_mass(kBudget);
88	gforget	1.6
89	gforget	1.1	%bottom pressure for comparison:
90			bp=myparms.rhoconst/9.81*PHIBOT;
91	gforget	1.6
92	gforget	1.9	[tmp1,X,Y,zm_area]=calc_zonmean_T(budgMoi,-2,'extensive');
93			zm_area=zm_area';
94			zm_vol_tot=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
95			tmp1=calc_zonmean_T(budgMo,-2,'extensive');
96			zm_vol_ocn=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
97			tmp1=calc_zonmean_T(budgMi,-2,'extensive');
98			zm_vol_ice=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
99	gforget	1.1
100			%=======HEAT=======
101
102	gforget	1.8	[budgHo,budgHi,budgHoi]=calc_budget_heat(kBudget);
103	gforget	1.6
104	gforget	1.9	[tmp1]=calc_zonmean_T(budgHoi,-2,'extensive');
105			zm_heat_tot=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
106			tmp1=calc_zonmean_T(budgHo,-2,'extensive');
107			zm_heat_ocn=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
108			tmp1=calc_zonmean_T(budgHi,-2,'extensive');
109			zm_heat_ice=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
110	gforget	1.1
111			%ocean diffusion alone
112			tmpU=myparms.rcp(DFxE_TH); tmpV=myparms.rcp(DFyE_TH);
113	gforget	1.8	budgD.hconv=calc_UV_conv(tmpU,tmpV);
114			budgD.cont=0budgD.hconv; budgD.zconv=0budgD.hconv;
115	gforget	1.9	[tmp1]=calc_zonmean_T(budgD,-2,'extensive');
116			zm_heat_ocn_diff=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
117	gforget	1.1
118			%=======SALT=======
119
120	gforget	1.8	[budgSo,budgSi,budgSoi]=calc_budget_salt(kBudget);
121	gforget	1.6
122	gforget	1.9	[tmp1]=calc_zonmean_T(budgSoi,-2,'extensive');
123			zm_salt_tot=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
124			tmp1=calc_zonmean_T(budgSo,-2,'extensive');
125			zm_salt_ocn=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
126			tmp1=calc_zonmean_T(budgSi,-2,'extensive');
127			zm_salt_ice=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
128	gforget	1.1
129			%ocean diffusion alone
130			tmpU=myparms.rhoconst(DFxE_SLT); tmpV=myparms.rhoconst(DFyE_SLT);
131	gforget	1.8	budgD.hconv=calc_UV_conv(tmpU,tmpV);
132			budgD.cont=0budgD.hconv; budgD.zconv=0budgD.hconv;
133	gforget	1.9	[tmp1]=calc_zonmean_T(budgD,-2,'extensive');
134			zm_salt_ocn_diff=[tmp1.cont';tmp1.hconv';tmp1.zconv'];
135
136	gforget	1.1	%===================== COMPUTATIONAL SEQUENCE ENDS =========================%
137			%===================== PLOTTING SEQUENCE BEGINS =========================%
138
139			elseif userStep==-1;%plotting
140
141			if isempty(setDiagsParams);
142			choicePlot={'all'};
143			elseif isnumeric(setDiagsParams{1})&length(setDiagsParams)==1;
144			choicePlot={'all'};
145			elseif isnumeric(setDiagsParams{1});
146			choicePlot={setDiagsParams{2:end}};
147			else;
148			choicePlot=setDiagsParams;
149			end;
150
151			tt=[1:length(alldiag.listTimes)];
152			TT=alldiag.listTimes(tt);
153			nt=length(TT);
154
155			if (kBudget==1)&(sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'mass')));
156
157			%1.1) ocean+seaice mass budgets
158			%------------------------------
159			figureL;
160			%volume budget:
161			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_vol_tot,'kg/m2','Mass (incl. ice)');
162			%cumulative integral:
163	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
164			tmp1=tmp1.*alldiag.zm_vol_tot; cumbudg=cumsum(tmp1,2);
165	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'kg','Mass (incl. ice)');
166			%add to tex file
167			myCaption={myYmeanTxt,'mass budget (ocean+ice) at each latitude in kg/m2 (upper) and integrated from South (lower).'};
168			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
169
170			%1.2) ice mass budgets
171			%---------------------
172			figureL;
173			%volume budget:
174			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_vol_ice,'kg/m2','Mass (only ice)');
175			%cumulative integral:
176	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
177			tmp1=tmp1.*alldiag.zm_vol_ice; cumbudg=cumsum(tmp1,2);
178	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'kg','Mass (only ice)');
179			%add to tex file
180			myCaption={myYmeanTxt,'mass budget (only ice) at each latitude in kg/m2 (upper) and integrated from South (lower).'};
181			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
182			end;
183
184			if (sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'mass')));
185
186			%1.3) ocean mass budgets
187			%-----------------------
188			figureL;
189			%volume budget:
190			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_vol_ocn,'kg/m2','Mass (ocean only)');
191			%cumulative integral:
192	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
193			tmp1=tmp1.*alldiag.zm_vol_ocn; cumbudg=cumsum(tmp1,2);
194	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'kg','Mass (ocean only)');
195			%add to tex file
196			myCaption={myYmeanTxt,'mass budget (ocean only) at each latitude in kg/m2 (upper) and integrated from South (lower).'};
197			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
198
199			end;
200
201			if (kBudget==1)&(sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'heat')));
202
203			%1.1) ocean+seaice heat budgets
204			%------------------------------
205			figureL;
206			%heat budget:
207			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_heat_tot,'J/m2','Heat (incl. ice)');
208			%cumulative integral:
209	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
210			tmp1=tmp1.*alldiag.zm_heat_tot; cumbudg=cumsum(tmp1,2);
211	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'J','Heat (incl. ice)');
212			%add to tex file
213			myCaption={myYmeanTxt,'heat budget (ocean+ice) at each latitude in J/m2 (upper) and integrated from South (lower).'};
214			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
215
216			%1.2) ice heat budgets
217			%---------------------
218			figureL;
219			%heat budget:
220			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_heat_ice,'J/m2','Heat (only ice)');
221			%cumulative integral:
222	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
223			tmp1=tmp1.*alldiag.zm_heat_ice; cumbudg=cumsum(tmp1,2);
224	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'J','Heat (only ice)');
225			%add to tex file
226			myCaption={myYmeanTxt,'heat budget (only ice) at each latitude in J/m2 (upper) and integrated from South (lower).'};
227			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
228			end;
229
230			if (sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'heat')));
231
232			%1.3) ocean heat budgets
233			%-----------------------
234			figureL;
235			%heat budget:
236			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_heat_ocn,'J/m2','Heat (ocean only)');
237			%cumulative integral:
238	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
239			tmp1=tmp1.*alldiag.zm_heat_ocn; cumbudg=cumsum(tmp1,2);
240	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'J','Heat (ocean only)');
241			%add to tex file
242			myCaption={myYmeanTxt,'heat budget (ocean only) at each latitude in J/m2 (upper) and integrated from South (lower).'};
243			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
244
245			end;
246
247			if (kBudget==1)&(sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'salt')));
248
249			%1.1) ocean+seaice salt budgets
250			%------------------------------
251			figureL;
252			%salt budget:
253			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_salt_tot,'g/m2','Salt (incl. ice)');
254			%cumulative integral:
255	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
256			tmp1=tmp1.*alldiag.zm_salt_tot; cumbudg=cumsum(tmp1,2);
257	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'g','Salt (incl. ice)');
258			%add to tex file
259			myCaption={myYmeanTxt,'salt budget (ocean+ice) at each latitude in g/m2 (upper) and integrated from South (lower).'};
260			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
261
262			%1.2) ice salt budgets
263			%---------------------
264			figureL;
265			%salt budget:
266			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_salt_ice,'g/m2','Salt (only ice)');
267			%cumulative integral:
268	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
269			tmp1=tmp1.*alldiag.zm_salt_ice; cumbudg=cumsum(tmp1,2);
270	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'g','Salt (only ice)');
271			%add to tex file
272			myCaption={myYmeanTxt,'salt budget (only ice) at each latitude in g/m2 (upper) and integrated from South (lower).'};
273			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
274			end;
275
276			if (sum(strcmp(choicePlot,'all'))\|sum(strcmp(choicePlot,'salt')));
277
278			%1.3) ocean salt budgets
279			%-----------------------
280			figureL;
281			%salt budget:
282			subplot(2,1,1); disp_budget_mean_zonal(mygrid.LATS,alldiag.zm_salt_ocn,'g/m2','Salt (ocean only)');
283			%cumulative integral:
284	gforget	1.4	tmp1=repmat(alldiag.zm_area,[3 1 1]);
285			tmp1=tmp1.*alldiag.zm_salt_ocn; cumbudg=cumsum(tmp1,2);
286	gforget	1.1	subplot(2,1,2); disp_budget_mean_zonal(mygrid.LATS,cumbudg,'g','Salt (ocean only)');
287			%add to tex file
288			myCaption={myYmeanTxt,'salt budget (ocean only) at each latitude in g/m2 (upper) and integrated from South (lower).'};
289			if addToTex&multiTimes; write2tex(fileTex,2,myCaption,gcf); end;
290
291			end;
292
293			end;
294