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MeasurementPlot.py 17.2 KiB
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import pandas as pd
import matplotlib.pyplot as plt
import numpy as np
import time
import sys
# Different exceptions can be thrown while plotting, depending on the backend.
# We catch them all locally and raise our own exception instead
class PlottingError(Exception):
    "Raised when plotting fails"
    pass

class MeasurementPlot:
    def __init__(self, title='', legend_loc = 'upper left', legend_bbox_to_anchor = (1.09, 1)):
          # set python for opening an separate plot window when starting from anaconda, Michael
        if 'ipykernel' in sys.modules:
            from IPython import get_ipython
            get_ipython().run_line_magic('matplotlib', 'qt')
        
        # parameter for legend of subplots
        self.legend_loc = legend_loc
        self.legend_bbox_to_anchor = legend_bbox_to_anchor
        # Third, Fourth and Fifth plot for additional external sensors, Michael
        self.fig, self.ax1 = plt.subplots(5, figsize=(25, 20))
        self.fig.subplots_adjust(bottom= 0.1, right=0.8, hspace = 0.4)
        self.fig.suptitle("Measurement "+title, color="red")
        # First plot: Phase and magnitude, Michael
        self.path_collection_phase = self.ax1[0].scatter([], [], c='red', marker='<', label='DUT Phase')
        self.path_collection_fit = self.ax1[0].scatter([], [], c='green', marker='.', label = ' ')
        self.magnitude_axis = self.ax1[0].twinx()
        
        # in entry of legend for phase and magnitude the word DUT is added in front, Michael
        self.path_collection_mag = self.magnitude_axis.scatter([], [], c='#3120E0', marker='4', label='DUT Magnitude')
        self.equi_axis0 = self.ax1[0].twinx()
        self.equi_axis0.spines['right'].set_position(('outward', 75))
        self.path_collection_equi0 = self.equi_axis0.scatter([], [], c='black', marker=".", label='Equilibrium_Indicator')

        # units added to y-axes of subplot 1, Michael
        self.ax1[0].set_xlabel("TIMESTAMP")
        self.ax1[0].set_ylabel("PHASE [°]", color='red')
        self.magnitude_axis.set_ylabel("MAGNITUDE [dB]", color='#3120E0')
        # label of y-axis for equilibrium indicator is changed to Indiccator Value because it's shorter, Michael
        self.equi_axis0.set_ylabel("INDICATOR VALUE", color='black')
        # fix range to 0..31 with some extra margin for plotting
        self.equi_axis0.set_ylim(-1, 32)

        self.ax1[0].grid(True, linestyle=":")
        all_path_collections = [self.path_collection_phase, self.path_collection_mag, \
                                self.path_collection_equi0, self.path_collection_fit]
        labels = [pc.get_label() for pc in all_path_collections]
        self.phase_legend = self.ax1[0].legend(all_path_collections, labels, loc=self.legend_loc, bbox_to_anchor = \
                           self.legend_bbox_to_anchor)
            
        ax = self.fig.axes
        # plot delta values for phase and magnitude at left position outside the plot, Michael
        self.annotation = ax[0].annotate('' ,xy=(0,1), \
                                       xycoords='axes fraction', xytext=(-0.16,1), \
                                       textcoords='axes fraction',fontsize = '16', \
                                       horizontalalignment='left',verticalalignment='bottom')
        # Second plot: Humidity and temperature of climate chamber requested from internal sensors of chamber
        self.path_collection_temp = self.ax1[1].scatter([], [], c='blue', marker='p', label="Chamber Temperature")
        self.humidity_axis = self.ax1[1].twinx()
        self.path_collection_hum = self.humidity_axis.scatter([], [], c='green', marker="*", label="Chamber Humidity")
        self.equi_axis1 = self.ax1[1].twinx()
        self.equi_axis1.spines['right'].set_position(('outward', 75))
        self.path_collection_equi1 = self.equi_axis1.scatter([], [], c='black', marker=".", label="Equilibrium_Indicator")

        # units added to y-axes of subplot 2, Michael
        self.ax1[1].set_xlabel("TIMESTAMP")
        self.ax1[1].set_ylabel("TEMPERATURE [°C] ", color='blue')
        self.humidity_axis.set_ylabel("HUMIDITY [%RH]", color='green')
        # label of y-axis for equilibrium indicator is changed to Indiccator Value because it's shorter, Michael        
        self.equi_axis1.set_ylabel("INDICATOR VALUE", color='black')
        self.equi_axis1.set_ylim(-1, 32)

        self.ax1[1].grid(True, linestyle=":")
        all_path_collections = [self.path_collection_temp, self.path_collection_hum, self.path_collection_equi1]
        labels = [pc.get_label() for pc in all_path_collections]
        self.ax1[1].legend(all_path_collections, labels, loc=self.legend_loc, bbox_to_anchor = \
                           self.legend_bbox_to_anchor)
        # Third plot:  parameter of external sensors
        # DUT temperature,  DUT humidity, Michael
        # configuration of used sensor port in ext_sens_data.json, Michael
        self.path_collection_temp_dut = self.ax1[2].scatter([],[], c='red', marker='p', label='DUT temperature')
        
        self.ext_sens_hum_axis = self.ax1[2].twinx()
        self.path_collection_hum_dut = self.ext_sens_hum_axis.scatter([],[], c='purple', marker='*', label='DUT humidity')
        
        
        self.ax1[2].set_xlabel("TIMESTAMP")
        self.ax1[2].set_ylabel("TEMPERATURE [°C]", color='red')
        self.ext_sens_hum_axis.set_ylabel("HUMIDITY [%RH]", color = 'purple')

        self.ax1[2].grid(True, linestyle=":")
        all_path_collections = [self.path_collection_temp_dut, self.path_collection_hum_dut]
        labels = [pc.get_label() for pc in all_path_collections]
        self.ax1[2].legend(all_path_collections, labels, loc=self.legend_loc, bbox_to_anchor = \
                           self.legend_bbox_to_anchor)
        # Forth plot: parameter of external sensors
        # room temperature,  room humidity , air pressure room, Michael
        # configuration of used sensor port in ext_sens_data.json, Michael
        self.path_collection_temp_room = self.ax1[3].scatter([],[], c='green', marker='*', label='room temperature')    
        
        self.sec_ext_hum_sens_axis = self.ax1[3].twinx()
        self.path_collection_hum_room = self.sec_ext_hum_sens_axis.scatter([],[], c='orange', marker='>', label='room humidity')
        
        self.press_axis = self.ax1[3].twinx()
        self.press_axis.spines['right'].set_position(('outward', 60))
        self.path_collection_air_press_room = self.press_axis.scatter([],[], c='grey', marker='4', label='air pressure room')
        
        self.ax1[3].set_xlabel("TIMESTAMP")
        self.ax1[3].set_ylabel("TEMPERATURE [°C]", color='green')
        self.sec_ext_hum_sens_axis.set_ylabel("HUMIDITY [%RH]", color = 'orange')
        self.press_axis.set_ylabel("AIR PRESSURE [mb]", color ='grey')
        
        self.ax1[3].grid(True, linestyle=":")        
        all_path_collections = [self.path_collection_temp_room, self.path_collection_hum_room, \
                                self.path_collection_air_press_room]
        labels = [pc.get_label() for pc in all_path_collections]
        self.ax1[3].legend(all_path_collections, labels, loc=self.legend_loc, bbox_to_anchor = \
                           self.legend_bbox_to_anchor)
        # Fifth plot: parameter of external sensors
        # meas instruments temperature,  meas instruments humidity, Michael
        # configuration of used sensor port in ext_sens_data.json, Michael
        self.path_collection_temp_meas_instr = self.ax1[4].scatter([], [], c='black', marker='p', label="meas instr temperature")
        self.third_ext_hum_sens_axis = self.ax1[4].twinx()
        self.path_collection_hum_meas_instr = self.third_ext_hum_sens_axis.scatter([], [], c='brown', marker="*", label="meas instr humidity")

        # units added to y-axes of subplot 5, Michael
        self.ax1[4].set_xlabel("TIMESTAMP")
        self.ax1[4].set_ylabel("TEMPERATURE [°C] ", color='black')
        self.third_ext_hum_sens_axis.set_ylabel("HUMIDITY [%RH]", color='brown')

        self.ax1[4].grid(True, linestyle=":")
        all_path_collections = [self.path_collection_temp_meas_instr, \
                                self.path_collection_hum_meas_instr]
        labels = [pc.get_label() for pc in all_path_collections]
        self.ax1[4].legend(all_path_collections, labels, loc=self.legend_loc, bbox_to_anchor = \
                           self.legend_bbox_to_anchor)     
        
        ######################################################################################
        
        ## Block for plot Heater percentage in fifth subplot
        # heater activity of temperature heater and humidity heater
        # values requested from environmental test chamber
        
        # self.path_collection_temp_heater = self.ax1[4].scatter([],[], c='black', marker='<', label='Temp Heater')
        # self.path_collection_hum_heater = self.ax1[4].scatter([],[], c='brown', marker='o', label='Hum Heater')
        
        # self.ax1[4].set_xlabel("TIMESTAMP")
        # self.ax1[4].set_ylabel("HEATER PERCENTAGE [%]", color='black')
        
        # self.ax1[4].grid(True, linestyle=":")
        # all_path_collections = [self.path_collection_temp_heater, \
        #                         self.path_collection_hum_heater]
        # labels = [pc.get_label() for pc in all_path_collections]
        # self.ax1[4].legend(all_path_collections, labels, loc=self.legend_loc, bbox_to_anchor = \ self.legend_bbox_to_anchor)
        
        #######################################################################################
       
        # sclae fontsize of all plot window elements to size 16, Michael
        plt.rcParams.update({'font.size':16})
    def draw(self, data_frame, pdf_name=''):
        timestamps = data_frame.TIMESTAMP
        minimum, maximum = self.get_extended_min_max(timestamps)
        self.ax1[0].set_xlim(minimum, maximum)
        self.ax1[1].set_xlim(minimum, maximum)
        # because subplots where increase x-axis limits has to be set equal to first and second plot, Michael 
        self.ax1[2].set_xlim(minimum, maximum)
        self.ax1[3].set_xlim(minimum, maximum)
        self.ax1[4].set_xlim(minimum, maximum)
        # refresh data for phase in subplot for phase and magnitude 
        phases = data_frame.S21_PHASE
        minimum, maximum = self.get_extended_min_max(phases)
        self.ax1[0].set_ylim(minimum, maximum)
        self.path_collection_phase.set_offsets(np.c_[timestamps, phases])
        self.path_collection_fit.set_offsets(np.c_[[], []])
        # refresh data for magnitude in subplot for phase and magnitude
        magnitudes = data_frame.S21_MAGNITUDE
        minimum, maximum = self.get_extended_min_max(magnitudes)
        self.magnitude_axis.set_ylim(minimum, maximum)
        self.path_collection_mag.set_offsets(np.c_[timestamps, magnitudes])

        # refresh data for chamber temperature in subplot for chamber temperature and humidity  
        temperatures = data_frame.READBACK_TEMPERATURE
        minimum, maximum = self.get_extended_min_max(temperatures)
        self.ax1[1].set_ylim(minimum, maximum)
        self.path_collection_temp.set_offsets(np.c_[timestamps, temperatures])

        # refresh data for chamber humidity in subplot for chamber temperature and humidity
        humidities = data_frame.READBACK_HUMIDITY
        minimum, maximum = self.get_extended_min_max(humidities)
        self.humidity_axis.set_ylim(minimum, maximum)
        self.path_collection_hum.set_offsets(np.c_[timestamps, humidities])
        # refresh temperatures for used external sensors in subplots, Michael
        temp_dut = data_frame.TEMP_DUT
        temp_room = data_frame.TEMP_ROOM
        minimum, maximum = self.get_extended_min_max(temp_dut)
        self.ax1[2].set_ylim(minimum, maximum)
        self.path_collection_temp_dut.set_offsets(np.c_[timestamps, temp_dut])
        minimum, maximum = self.get_extended_min_max(temp_room)
        self.ax1[3].set_ylim(minimum, maximum)
        self.path_collection_temp_room.set_offsets(np.c_[timestamps, temp_room])
        # refresh humidities external sensors in subplots for DUT humidity and room
        # humidity, Michael
        hum_dut = data_frame.HUM_DUT
        hum_room = data_frame.HUM_ROOM
        minimum, maximum = self.get_extended_min_max(hum_dut)
        self.ext_sens_hum_axis.set_ylim(minimum, maximum)
        
        minimum, maximum = self.get_extended_min_max(hum_room)
        self.sec_ext_hum_sens_axis.set_ylim(minimum, maximum)
        self.path_collection_hum_dut.set_offsets(np.c_[timestamps, hum_dut])
        self.path_collection_hum_room.set_offsets(np.c_[timestamps, hum_room])
        # refresh air pressure of external sensor in subplot for air pressure room, Michael
        air_press_room = data_frame.AIR_PRESS_ROOM
        minimum, maximum = self.get_extended_min_max(air_press_room)
        self.press_axis.set_ylim(minimum, maximum)
        self.path_collection_air_press_room.set_offsets(np.c_[timestamps, air_press_room])
        
        # refresh temperature and humidity of external sensor in subplot for measurement
        # for instrument temperature and measurement instrument humidity, Michael  
        temp_meas_instr = data_frame.TEMP_MEAS_INSTR
        hum_meas_instr = data_frame.HUM_MEAS_INSTR
        
        minimum, maximum = self.get_extended_min_max(temp_meas_instr)
        self.ax1[4].set_ylim(minimum, maximum)
        
        minimum, maximum = self.get_extended_min_max(hum_meas_instr)
        self.third_ext_hum_sens_axis.set_ylim(minimum, maximum)
        self.path_collection_temp_meas_instr.set_offsets(np.c_[timestamps, temp_meas_instr])
        self.path_collection_hum_meas_instr.set_offsets(np.c_[timestamps, hum_meas_instr])
        
        #########################################################################
        ## Block for refreshing heater percentages in subplot for heater values
        
        # refresh heater percentage values of climate chamber in subplot of heater values, Michael
        # temp_heater = data_frame.TEMP_HEATER
        # hum_heater = data_frame.HUM_HEATER
        # min_temp_heater, max_temp_heater = self.get_extended_min_max(temp_heater)
        # min_hum_heater, max_hum_heater = self.get_extended_min_max(hum_heater)
        # minimum = min(min_temp_heater, min_hum_heater)
        # maximum = max(max_temp_heater, max_hum_heater)
        # self.ax1[4].set_ylim(minimum-0.05*(maximum-minimum), maximum+0.05*(maximum-minimum))
        # self.path_collection_temp_heater.set_offsets(np.c_[timestamps, temp_heater])
        # self.path_collection_hum_heater.set_offsets(np.c_[timestamps, hum_heater])
        
        #########################################################################
        self.path_collection_equi0.set_offsets(np.c_[timestamps, data_frame.EQUILIBRIUM_INDICATOR])
        self.path_collection_equi1.set_offsets(np.c_[timestamps, data_frame.EQUILIBRIUM_INDICATOR])

        if not pdf_name == '':
            self.fig.savefig(pdf_name)

        plt.show()
        if plt.isinteractive():
            try:
                self.fig.canvas.draw()
                self.fig.canvas.flush_events()
            except Exception as e:
                raise PlottingError from e

    # add 5 % of the distance between min and max to the range
    @staticmethod
    def get_extended_min_max(array):
        distance = array.max() - array.min()
            distance = 1
        return array.min()-0.05*distance, array.max()+0.05*distance

# test procedure for measurement plot procedure
if __name__ == '__main__':
    m = MeasurementPlot()
    plt.ion()
    measurements = []

# generation of datapoints for plot
    for i in range(20):
        measurement = {
            'TIMESTAMP': i,
            'READBACK_TEMPERATURE': 25 - i,
            'READBACK_HUMIDITY': 10 + 0.1*i,
            'EQUILIBRIUM_INDICATOR': i % 4,
            'S21_PHASE': 20 - 2*i,
            'S21_MAGNITUDE': 0.3*i,
            ###############################################################
            ##Block for simulation acivity temp heater and hum heater
            # 'TEMP_HEATER': 10,
            # # percentage humidity heater, Michael
            # 'HUM_HEATER': 3,
            # DUT Temperature of external temp sensor added, Michael
            'TEMP_DUT': i,
            # room temperature of external temp sensor added, Michael
            'TEMP_ROOM': 25-i,
            # DUT Humidity of external hum sensor added, Michael
            'HUM_DUT': 40,
            # room humidity of external hum sensor added, Michael
            'HUM_ROOM': 45,
            # Air pressure of external sensor added, Michael
            'AIR_PRESS_ROOM': 1000+10*i,
            # measurement instrument temperature of external temp sensor added, Michael
            'TEMP_MEAS_INSTR': 40-1.5*i,
            # measurement instrument humidity of external hum sensor added, Michael 
            'HUM_MEAS_INSTR': 55
            }
        
        measurements.append(measurement)
        data_frame = pd.DataFrame(measurements)
        # plot of data frame with test data for actual step
        # plot of step number
        print(str(i))
        time.sleep(0.3)

    print('I am done. ')
    plt.ioff()
    m.draw(data_frame, 'the.pdf')