function [GI_AngoloKL,GI_NumKL,GI_DateKL,ATTIVA,FIG,FIG_ENG] = report_KL(rKL,m,... NodoKlinoLink,toolrif,unitrif,datarif,contunit,Font_caption,Font_tools,... siteID,DT,DT_ENG,FIG,FIG_ENG,br,status,ATTIVA,activeEN,colonna4,conn,FileName) fileID = fopen(FileName,'a'); fmt = '%s \r'; text = 'report_KL function started'; fprintf(fileID,fmt,text); import mlreportgen.dom.* import mlreportgen.report.* % Make sure DOM is compilable makeDOMCompilable() GI_AngoloXKL = []; GI_AngoloYKL = []; GI_AngoloKL = []; GI_NumKL = []; GI_DateKL = []; NODATA(m,1) = 0; check = 0; while check == 0 if status(m,1) == 1 if ATTIVA == 1 ATTIVA = 0; testo = Paragraph('Catena non ancora installata o inattiva.'); add(DT,testo); if activeEN == 1 testo = Paragraph('Array not installed or inactive.'); add(DT_ENG,testo); end end check = 1; elseif status(m,1) == 3 if ATTIVA == 1 ATTIVA = 0; testo = Paragraph(['Monitoraggio completato. Invitiamo a visitare la '... 'piattaforma web per la visione dei dati storici.']); add(DT,testo); if activeEN == 1 testo = Paragraph(['Monitoring completed. Please log into the web-based platform '... 'to access the complete dataset.']); add(DT_ENG,testo); end end check = 1; else KE = Section(); if activeEN == 1 KE_EN = Section(); end titolo = 1; if strcmp(char(colonna4(m+1,1)),'Klino Array D2W') == 1 % Clinometro Wi-Fi comando = ['select Date, Time, UnitName, ToolNameID, BatLevel, Temperature from RawDataView where Date >= ''' ... datarif ''' and UnitName = ''' char(unitrif) ''' and ToolNameID = '''... char(toolrif) ''' and NodeNum = 1 ']; curs = exec(conn,comando); curs = fetch(curs); BatTemp = curs.Data; [~,cc] = size(BatTemp); if cc ~= 1 %ci sono dati riferiti all'ultimo mese/periodo di interesse DataPlot = [BatTemp(:,1) BatTemp(:,2)]; % sistemo date, batteria e temperatura [rD,~] = size(DataPlot); T = [cell2mat(DataPlot(:,1)) repmat(' ', [rD,1]) cell2mat(DataPlot(:,2))]; Date = datenum(T); Batteria = cell2mat(BatTemp(:,5)); Temperatura = cell2mat(BatTemp(:,6)); % testo introduttivo testoB1 = Paragraph(['I valori di tensione di alimentazione del modulo Wi-Fi registrati '... 'durante il periodo di monitoraggio sono riportati di seguito. Il corretto funzionamento '... 'del sistema ' char(232) ' assicurato per una carica superiore a 7 V. L''ultimo dato '... 'disponibile ' char(232) ' pari a ' num2str(Batteria(end,1)) ' V.']); testoB2 = Paragraph(['Il modulo integra al proprio interno un termometro '... 'per monitorate la temperatura di esercizio ed identificare eventuali '... 'anomalie. I dati di temperatura registrati sono riportati di seguito.']); testoB1.HAlign = 'justify'; testoB2.HAlign = 'justify'; % grafico batteria figure(19) plot(Date,Batteria); hold on title('Batteria e Temperatura del D2W'); xlabel('Data [gg/mm/aaaa]'); ylabel('Livello di Batteria [V]'); ylim([floor(min(Batteria(:,1))) ceil(max(Batteria(:,1)))]); yyaxis right GMUX = plot(Date,Temperatura,':','LineWidth',1.1); ylim([floor(min(Temperatura(:,1))) ceil(max(Temperatura(:,1)))]); ylabel(['Temperatura [' char(176) 'C]']); set(gca,'YColor','k'); str(1,1) = cellstr('Batteria'); str(2,1) = cellstr('Temperatura'); legend(str,'Location','northwest'); h = gca; h.XAxis.MinorTick = 'on'; datetick('x','dd/mm/yyyy','keepticks','keeplimits'); xtickangle(20); grid on grid minor xlim([Date(1)-1 Date(end)+1]); TempName = char(strcat('Report',siteID,'-', contunit,'-', num2str(m) ,'-D2W.png')); saveas(GMUX,TempName); ChartGMUX = Image(TempName); ChartGMUX.Style = {Height('8cm'),HAlign('center')}; if Batteria(end,1) > 6.5 TempNameB = char(strcat('B_13.jpg')); elseif Batteria(end,1) > 6 TempNameB = char(strcat('B_12.jpg')); elseif Batteria(end,1) > 5.8 TempNameB = char(strcat('B_115.jpg')); elseif Batteria(end,1) > 5.6 TempNameB = char(strcat('B_11.jpg')); else TempNameB = char(strcat('B_10.jpg')); end Batt = Image(TempNameB); Batt.Style = {Height('4cm'),HAlign('center')}; lot = Table({ChartGMUX, Batt}); lot.TableEntriesStyle = {HAlign('center'),VAlign('middle')}; lot.Style = {ResizeToFitContents(false),Width("100%")}; grps(1) = TableColSpecGroup; grps(1).Span = 2; specs(1) = TableColSpec; specs(1).Span = 1; specs(1).Style = {Width("80%")}; specs(2) = TableColSpec; specs(2).Span = 1; specs(2).Style = {Width("20%")}; grps(1).ColSpecs = specs; lot.ColSpecGroups = grps; lot_cap = Paragraph(['Fig. ' num2str(FIG) ' - Livello di carica della batteria e temperatura del '... 'D2W registrati durante il periodo di riferimento']); FIG = FIG+1; lot_cap.Style = {HAlign('center'),FontSize(Font_caption),Italic(1),Color('midnightblue')}; Batt = Section(); sezBATT = Heading3('D2W - Batteria e Temperatura'); sezBATT.Style = {FontSize(Font_tools),Bold(1),Italic(1)}; Batt.Title = sezBATT; add(DT,sezBATT); add(DT,testoB1); add(DT,testoB2); add(DT,lot); add(DT,lot_cap); add(DT,br); close(figure(19)); if activeEN == 1 testoB1 = Paragraph(['The following chart reports the D2W battery level trend recorded '... 'during the reference time period. '... 'The correct functioning of the data acquisition system is guaranteed for a '... 'minimum level of 7 V. The last available data is equal to ' num2str(Batteria(end,1)) ' V.']); testoB2 = Paragraph(['The module equips also a thermometer that allows the monitoring '... 'of the working temperature and the identification of eventual malfunctioning. The same '... 'chart displays also temperature data recorded.']); testoB1.HAlign = 'justify'; testoB2.HAlign = 'justify'; % grafico batteria figure(19) plot(Date,Batteria); hold on title('D2W battery level and temperature'); xlabel('Date [dd/mm/yyyy]'); ylabel('Battery Level [V]'); ylim([floor(min(Batteria(:,1))) ceil(max(Batteria(:,1)))]); yyaxis right GMUX = plot(Date,Temperatura,':','LineWidth',1.1); ylim([floor(min(Temperatura(:,1))) ceil(max(Temperatura(:,1)))]); ylabel(['Temperature [' char(176) 'C]']); set(gca,'YColor','k'); str(1,1) = cellstr('Battery'); str(2,1) = cellstr('Temperature'); legend(str,'Location','northwest'); h = gca; h.XAxis.MinorTick = 'on'; datetick('x','dd/mm/yyyy','keepticks','keeplimits'); xtickangle(20); grid on grid minor xlim([Date(1)-1 Date(end)+1]); TempName = char(strcat('Report',siteID,'-', contunit,'-D2W_ENG.png')); saveas(GMUX,TempName); ChartGMUX = Image(TempName); ChartGMUX.Style = {Height('8cm'),HAlign('center')}; Batt = Image(TempNameB); Batt.Style = {Height('4cm'),HAlign('center')}; lot = Table({ChartGMUX, Batt}); lot.TableEntriesStyle = {HAlign('center'),VAlign('middle')}; lot.Style = {ResizeToFitContents(false),Width("100%")}; grps(1) = TableColSpecGroup; grps(1).Span = 2; specs(1) = TableColSpec; specs(1).Span = 1; specs(1).Style = {Width("80%")}; specs(2) = TableColSpec; specs(2).Span = 1; specs(2).Style = {Width("20%")}; grps(1).ColSpecs = specs; lot.ColSpecGroups = grps; lot_cap = Paragraph(['Fig. ' num2str(FIG_ENG) ' - Battery level and temperature recorded '... 'by the D2W during the reference time period']); FIG_ENG = FIG_ENG+1; lot_cap.Style = {HAlign('center'),FontSize(Font_caption),Italic(1),Color('midnightblue')}; Batt_ENG = Section(); sezBATT_ENG = Heading3('D2W - Battery and temperature'); sezBATT_ENG.Style = {FontSize(Font_tools),Bold(1),Italic(1)}; Batt_ENG.Title = sezBATT_ENG; add(DT_ENG,sezBATT_ENG); add(DT_ENG,testoB1); add(DT_ENG,testoB2); add(DT_ENG,lot); add(DT_ENG,lot_cap); add(DT_ENG,br); close(figure(19)); end end end for k = 1:rKL(m,1) NodeNum = num2str(NodoKlinoLink(k,m)); comando = ['select EventDate, EventTime, XShift, YShift, T_node from ElabDataView where EventDate >= ''' ... datarif ''' and ToolNameID = ''' char(toolrif) ''' and UnitName = ''' char(unitrif) ... ''' and NodeNum = ''' NodeNum ''' ']; curs = exec(conn,comando); curs = fetch(curs); Dati = curs.Data; % Modifico il formato di data e ora [rD,rC] = size(Dati); if rC ~= 1 T = [cell2mat(Dati(:,1)) repmat(' ', [rD,1]) cell2mat(Dati(:,2))]; Date = datenum(T); % Data TiltX(:,k) = cell2mat(Dati(:,3)); % asse x TiltY(:,k) = cell2mat(Dati(:,4)); % asse y TempKL(:,k) = cell2mat(Dati(:,5)); % temperatura if k == 1 % Il primo lo scrivo e creo la variabile di controllo check = 1; else [rS,~] = size(TiltX(:,k-1)); if rD ~= rS NODATA(m,1) = 2; check = 0; break else check = 1; end end else NODATA(m,1) = 1; check = 1; end if NODATA(m,1) == 0 % grafico inclinazione-tempo asse X,Y NELL'ULTIMO MESE figure(1) subplot(2,1,1); % (righe colonne posizione) pbaspect([3 1 1]); yyaxis left plot(Date,TiltX(:,k)); MAX = max(TiltX(:,k)); MIN = min(TiltX(:,k)); if MIN > -0.1 && MAX < 0.1 ylim([-0.1 0.1]); end if isnan(TempKL(:,k)) == 0 yyaxis right hold on plot(Date,TempKL,':','LineWidth',1.1); yyaxis right ylabel(['Temperatura [' char(176) 'C]']); set(gca,'YColor','k'); end xlim([Date(1)-1 Date(end)+1]); title(['Inclinazione clinometro ' NodeNum ' - asse X']); xlabel('Data [gg/mm/aaaa]'); yyaxis left ylabel(['Inclinazione [' char(176) ']']); set(gca,'YColor','k'); % str(1,1) = cellstr('Tilt X'); % str(2,1) = cellstr('Temperature'); % legend(str,'Location','southwest','FontSize',9); h = gca; h.XAxis.MinorTick = 'on'; datetick('x','dd/mm/yyyy','keepticks','keeplimits'); xtickangle(20); grid on grid minor hold off subplot(2,1,2) pbaspect([3 1 1]); yyaxis left InclY = plot(Date,TiltY(:,k)); MAX = max(TiltY(:,k)); MIN = min(TiltY(:,k)); if MIN > -0.1 && MAX < 0.1 ylim([-0.1 0.1]); end if isnan(TempKL) == 0 yyaxis right hold on InclY = plot(Date,TempKL(:,k),':','LineWidth',1.1); yyaxis right ylabel(['Temperatura [' char(176) 'C]']); set(gca,'YColor','k'); end xlim([Date(1)-1 Date(end)+1]); title(['Inclinazione clinometro ' NodeNum ' - asse Y']); xlabel('Data [gg/mm/aaaa]'); yyaxis left ylabel(['Inclinazione [' char(176) ']']); set(gca,'YColor','k'); h = gca; h.XAxis.MinorTick = 'on'; datetick('x','dd/mm/yyyy','keepticks','keeplimits'); xtickangle(20); grid on grid minor % str(1,1) = cellstr('Tilt Y'); % str(2,1) = cellstr('Temperature'); % legend(str,'Location','southwest'); legendaKL = Image(('legendaKL.png')); legendaKL.Style = {Height('0.4cm'),HAlign('center')}; TempName = char(strcat('Report',siteID,'-', char(toolrif),'-Klino', NodeNum, '.png')); saveas(InclY,TempName); ChartKL = Image(TempName); ChartKL.Style = {ScaleToFit}; ChartKL_cap = Paragraph(['Fig. ' num2str(FIG) ' - Inclinazione in direzione '... 'strumentale X e Y registrata dal sensore MEMS '... 'del nodo ' NodeNum ' durante il periodo temporale di riferimento']); FIG = FIG+1; ChartKL_cap.Style = {HAlign('justify'),FontSize(Font_caption),Italic(1),Color('midnightblue')}; if titolo == 1 sezKlino = Heading3('Klino Link'); sezKlino.Style = {OuterMargin('0in','0in','0.15in','0in'),FontSize(Font_tools),Bold(1),Italic(1)}; KE.Title = sezKlino; add(DT,sezKlino); if activeEN == 0 titolo = 0; end end if k == 1 testo = Paragraph(['I grafici seguenti riportano i valori di inclinazione assoluta misurati '... 'nel periodo temporale di riferimento lungo gli assi strumentali X e Y dai clinometri '... 'presenti in sito.']); testo.HAlign = 'justify'; add(DT,testo); end testo2 = Paragraph(['Il nodo numero ' NodeNum ' ha rilevato un''inclinazione massima lungo l''asse X '... 'pari a ' num2str(round(max(TiltX(:,k)),2),'%0.2f') '' char(176) ' ed un valore minimo pari a '... num2str(round(min(TiltX(:,k)),2), '%0.2f') '' char(176) ', per una variazione massima uguale a '... num2str(round(max(TiltX(:,k)),2)-round(min(TiltX(:,k)),2), '%0.2f')... char(176) '. Per quanto riguarda l''asse Y, i valori massimi e minimi sono rispettivamente '... ' pari a ' num2str(round(max(TiltY(:,k)),2), '%0.2f') '' char(176) ' e ' num2str(round(min(TiltY(:,k)),2), '%0.2f')... char(176) ', con una variazione massima di ' num2str(round(max(TiltY(:,k)),2)-round(min(TiltY(:,k)),2), '%0.2f')... char(176) ' di inclinazione.']); testo2.HAlign = 'justify'; add(DT,testo2); add(DT,ChartKL); add(DT,legendaKL); add(DT,ChartKL_cap); add(DT,br); close(figure(1)); if activeEN == 1 % grafico inclinazione-tempo asse X,Y NELL'ULTIMO MESE figure(1) subplot(2,1,1); % (righe colonne posizione) pbaspect([3 1 1]); yyaxis left plot(Date,TiltX(:,k)); if isnan(TempKL(:,k)) == 0 yyaxis right hold on plot(Date,TempKL,':','LineWidth',1.1); yyaxis right ylabel(['Temperature [' char(176) 'C]']); set(gca,'YColor','k'); end % str(1,1) = cellstr('Tilt X'); % str(2,1) = cellstr('Temperature'); % legend(str,'Location','southwest'); xlim([Date(1)-1 Date(end)+1]); title(['Tilt ' NodeNum ' - X axis']); xlabel('Date [dd/mm/yyyy]'); yyaxis left ylabel(['Tilt [' char(176) ']']); set(gca,'YColor','k'); h = gca; h.XAxis.MinorTick = 'on'; datetick('x','dd/mm/yyyy','keepticks','keeplimits'); xtickangle(20); grid on grid minor hold off subplot(2,1,2) pbaspect([3 1 1]); yyaxis left InclY = plot(Date,TiltY(:,k)); if isnan(TempKL) == 0 yyaxis right hold on InclY = plot(Date,TempKL(:,k),':','LineWidth',1.1); yyaxis right ylabel(['Temperature [' char(176) 'C]']); set(gca,'YColor','k'); end xlim([Date(1)-1 Date(end)+1]); title(['Tilt ' NodeNum ' - Y axis']); xlabel('Date [dd/mm/yyyy]'); yyaxis left ylabel(['Tilt [' char(176) ']']); % str(1,1) = cellstr('Tilt Y'); % str(2,1) = cellstr('Temperature'); % legend(str,'Location','southwest'); set(gca,'YColor','k'); h = gca; h.XAxis.MinorTick = 'on'; datetick('x','dd/mm/yyyy','keepticks','keeplimits'); xtickangle(20); grid on grid minor TempName = char(strcat('Report',siteID,'-', char(toolrif),'-Klino', NodeNum, '_ENG.png')); saveas(InclY,TempName); ChartKL = Image(TempName); ChartKL.Style = {ScaleToFit}; ChartKL_cap = Paragraph(['Fig. ' num2str(FIG_ENG) ' - Tilt recorded by MEMS sensor '... 'during the reference monitoring period along X and Y instrumental axes of node '... NodeNum '']); FIG_ENG = FIG_ENG+1; ChartKL_cap.Style = {HAlign('justify'),FontSize(Font_caption),Italic(1),Color('midnightblue')}; if titolo == 1 if activeEN == 0 KE_ENG.Title = sezKlino; add(DT_ENG,sezKlino); titolo = 0; end end if k == 1 testo = Paragraph(['The following graphs show the tilt angles recorded along X and Y '... 'instrumental axes during the reference monitoring period.']); testo.HAlign = 'justify'; add(DT_ENG,testo); end testo2 = Paragraph(['Node number ' NodeNum ' highlighted a maximum and a minimum tilt of '... num2str(round(max(TiltX(:,k)),2),'%0.2f') '' char(176) ' and '... num2str(round(min(TiltX(:,k)),2),'%0.2f') '' char(176) ' respectively, along X axis. '... 'The angle variation equals ' num2str(round(max(TiltX(:,k)),2)-round(min(TiltX(:,k)),2), '%0.2f')... char(176) '. Y axis showed maximum and minimum values equal to '... num2str(round(max(TiltY(:,k)),2), '%0.2f') '' char(176) ' and ' num2str(round(min(TiltY(:,k)),2), '%0.2f')... char(176) '. The variation is ' num2str(round(max(TiltY(:,k)),2)-round(min(TiltY(:,k)),2), '%0.2f')... char(176) '.']); testo2.HAlign = 'justify'; add(DT_ENG,testo2); add(DT_ENG,ChartKL); add(DT_ENG,legendaKL); add(DT_ENG,ChartKL_cap); add(DT_ENG,br); close(figure(1)); end else if ATTIVA == 1 testo = Paragraph('Non sono presenti dati relativi al periodo temporale considerato.'); ATTIVA = 0; add(DT,testo); if activeEN == 1 testo = Paragraph('No data available for the reference time period.'); add(DT_ENG,testo); if m == 1 add(DT_ENG,br); end end check = 1; end end end if rC ~= 1 var1 = max(abs(TiltX-TiltX(1,:))); varX = max(var1); indX = find(var1 == varX); var2 = max(abs(TiltX-TiltX(1,:))); varY = max(var2); indY = find(var2 == varX); MAX = max(varX,varY); indM = find(max(varX,varY)==MAX); if indM == 1 % X GI_AngoloXKL = TiltX(:,indX)-TiltX(1,indX); GI_AngoloYKL = TiltY(:,indX)-TiltY(1,indX); GI_NumKL = NodoKlinoLink(indX,m); GI_DateKL = Date; else % Y GI_AngoloXKL = TiltX(:,indY)-TiltX(1,indY); GI_AngoloYKL = TiltY(:,indY)-TiltY(1,indY); GI_NumKL = NodoKlinoLink(indY,m); GI_DateKL = Date; end end end end if isempty(GI_AngoloXKL) == 0 GI_AngoloKL(:,1) = GI_AngoloXKL; GI_AngoloKL(:,2) = GI_AngoloYKL; end text = 'report_KL function executed correctly'; fprintf(fileID,fmt,text); fclose(fileID); end