Beispiel #1
0
 def run(self):
     """
     This initialise process called when QGIS started
     """
     # create and show the dialog
     self.dlg = PlotStatisticsDialog()
     # show the dialog
     self.dlg.show()       
     QObject.connect(self.dlg, SIGNAL("okClicked(QString, QString)"), self.readData) 
Beispiel #2
0
class PlotStatistics:

    def __init__(self, iface):
        # Save reference to the QGIS interface
        self.iface = iface

    def initGui(self):
              
        self.canvas = self.iface.mapCanvas()
        self.mainWindow = self.iface.mainWindow()
        
        # Create action that will start plugin configuration
        self.action = QAction(QIcon(":/plugins/plotstatistics/icon.png"), \
            "plot statistics", self.mainWindow)
        # connect the action to the run method
        QObject.connect(self.action, SIGNAL("triggered()"), self.run)

        # Add toolbar button and menu item
        self.iface.addToolBarIcon(self.action)
        self.iface.addPluginToMenu("&plot statistics", self.action)

    def unload(self):
        # Remove the plugin menu item and icon
        self.iface.removePluginMenu("&plot statistics",self.action)
        self.iface.removeToolBarIcon(self.action)

    # run method that performs all the real work
    def run(self):
        """
        This initialise process called when QGIS started
        """
        # create and show the dialog
        self.dlg = PlotStatisticsDialog()
        # show the dialog
        self.dlg.show()       
        QObject.connect(self.dlg, SIGNAL("okClicked(QString, QString)"), self.readData) 
        
        
    def readData(self, layerName, outFile):
        """
        selected layer and output file name are passed in from dialog box, from the layer
        its attribute values are extracted to plot diagrams.
        Note this function currently extract data from Vector layer only.  
        """
        dateTimeList = []
        magList = []
        depList = []
           
        vlayer = utils.getVectorLayerByName( layerName )
              
        vprovider = vlayer.dataProvider()
        feat = QgsFeature()
        allAttrs = vprovider.attributeIndexes()
        vprovider.select( allAttrs )
        
        # field description
        myFields = vprovider.fields()
    
        while vprovider.nextFeature(feat):
            atmap = feat.attributeMap()
            for key, value in atmap.iteritems():
                if key == 6:
                    dateTime = "%-22s" % atmap[key].toString()
                    dateTimeList.append(dateTime)
                elif key == 3:
                    #mag = "%-22s" % atmap[key].toString()
                    mag = "%-22s" % atmap[key].toString()
                    magList.append(mag)
                elif key == 4: 
                    dep = "%-22s" % atmap[key].toString()
                    depList.append(dep)
                else:
                    pass
        
        self.plotTimes(dateTimeList,magList, depList, outFile)
        
                    
    def plotTimes(self, dateTimeList,magList, depList, outFile):
        """
        This function plots following diagrams calculating Bin/histogram values
        - date vs Frequency 
        - time vs Frequency
        - magnitude vs Frequency
        - depth vs Frequency
        """
        outputfile = str(outFile) + "_date_freq.png"
        timeoutputfile = str(outFile) + "_time_freq.png"
        magoutputfile = str(outFile) + "_mag_freq.png"
        depoutputfile = str(outFile) + "_dep_freq.png"
        
        yearList = []
        timeList = []
        magOutList = []
        depOutList = []
        
        for mag in magList:       
            mag_en = float(mag)  
            magOutList.append(mag_en)
            
        for dep in depList:       
            dep_en = float(dep)
            depOutList.append(dep_en)
        
        for dateTime in dateTimeList:
            year = dateTime[:4]
            time = dateTime[11:13]

            year_e = int(year)
            time_e = int(time)  
           
            yearList.append(year_e)
            timeList.append(time_e)
            
        # Frequency vs Year plot    
        startYear = min(yearList)
        endYear = max(yearList)
 
        step = 1 #bin width
        
        bins = np.arange(startYear, endYear, step)
        hist, edges = np.histogram(yearList, bins)
        
        plt.figure()
        plt.bar(bins[:-1]+0.5,hist, width=1, color='k')
        #plt.bar(bins[:-1]+0.02,hist, width=0.8, color='k')
        plt.axis([startYear, endYear, 0, 100])
        plt.ylabel('Number of Eruptions per Year')
        plt.xlabel('Year')
        plt.savefig(outputfile)
        
        
        # Frequency vs Time plot    
        startTime = min(timeList)
        endTime = max(timeList)
        step = 1 #bin width
      
        bins = np.arange(startTime, endTime, step)  
        hist, edges = np.histogram(timeList, bins)
        
        plt.figure()
        plt.bar(bins[:-1]+0.5,hist, width=1, color='k')
        plt.axis([startTime, endTime, 0, 100])
        plt.ylabel('Number of Eruptions per Time')
        plt.xlabel('Time')
        plt.savefig(timeoutputfile)        
        
              
        # Frequency vs Mag plot    
        startMag = min(magOutList)
        endMag = max(magOutList)
        
        step = 1 #bin width
        
        bins = np.arange(startMag, endMag, step)
        hist, edges = np.histogram(magOutList, bins)
        
        plt.figure()
        plt.bar(bins[:-1]+0.5,hist, width=0.8, color='k')
        plt.axis([startMag, endMag, 0, 50])
        plt.ylabel('Number of Eruptions ')
        plt.xlabel('Mag')
        plt.savefig(magoutputfile)  
        
        
        # Frequency vs Dep plot    
        startDep = min(depOutList)
        endDep = max(depOutList)
        step = 1 #bin width
        
        bins = np.arange(startDep, endDep, step)
        hist, edges = np.histogram(depOutList, bins)
        
        plt.figure()
        plt.bar(bins[:-1]+0.5,hist, width=0.8, color='k')
        #plt.bar(bins[:-1]+0.02,hist, width=0.8, color='k')
        plt.axis([startDep, endDep, 0, 50])
        plt.ylabel('Number of Eruptions')
        plt.xlabel('Depth')
        plt.savefig(depoutputfile)