Ejemplo n.º 1
0
    def __init__(self, name='Template', parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {'Template'})
            - parent {[type]} -- [description] (default: {None})
        """
        # IMPORT THEORIES
        # Import theories specific to the Application e.g.:
        # from TheoryTemplate import TheoryA

        super().__init__(name, parent, nplot_max=1)

        # VIEWS
        # set the views that can be selected in the view combobox
        self.views['y(x)'] = View(name='y(x)',
                                  description='y as a function of x',
                                  x_label='x',
                                  y_label='y(x)',
                                  x_units='-',
                                  y_units='-',
                                  log_x=False,
                                  log_y=False,
                                  view_proc=self.viewyx,
                                  n=1,
                                  snames=['y(x)'])

        # set multiviews
        # default view order in multiplot views, set nplots=1 for single view
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        # set the type of files that ApplicationTemplate can open
        ftype = TXTColumnFile(name='content of files',
                              extension='txt',
                              description='description of the file type',
                              col_names=['col1', 'col2'],
                              basic_file_parameters=['param1', 'param2'],
                              col_units=['units_col1', 'units_col2'])
        self.filetypes[
            ftype.extension] = ftype  #add each the file type to dictionary

        # THEORIES
        # add the theories related to ApplicationTemplate to the dictionary, e.g.:
        # self.theories[TheoryA.thname] = TheoryA
        # self.theories[TheoryB.thname] = TheoryB
        self.add_common_theories()  # Add basic theories to the application

        #set the current view
        self.set_views()
Ejemplo n.º 2
0
    def __init__(self, name="MWD", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"MWD"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryDiscrMWD import TheoryDiscrMWD
        from TheoryGEX import TheoryGEX
        from TheoryLogNormal import TheoryLogNormal

        super().__init__(name, parent, nplot_max=3)

        # VIEWS
        self.views["log-lin"] = View(name="log-lin",
                                     description="MWD lin W vs log M",
                                     x_label="M",
                                     y_label="dW/dlogM",
                                     x_units="g/mol",
                                     y_units="-",
                                     log_x=True,
                                     log_y=False,
                                     view_proc=self.view_WM,
                                     n=1,
                                     snames=["W"])
        self.views["log-log"] = View(name="log-log",
                                     description="MWD log W vs log M",
                                     x_label="log(M)",
                                     y_label="log(dW/dlogM)",
                                     x_units="g/mol",
                                     y_units="-",
                                     log_x=False,
                                     log_y=False,
                                     view_proc=self.view_logWM,
                                     n=1,
                                     snames=["log(W)"])
        self.views["lin-lin"] = View(name="lin-lin",
                                     description="MWD lin W vs lin M",
                                     x_label="M",
                                     y_label="dW/dlogM",
                                     x_units="g/mol",
                                     y_units="-",
                                     log_x=False,
                                     log_y=False,
                                     view_proc=self.view_WM,
                                     n=1,
                                     snames=["W"])

        #set multiviews
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("GPC Files", "gpc",
                              "Molecular Weight Distribution",
                              ['M', 'W(logM)'], ['Mn', 'Mw', 'PDI'],
                              ["g/mol", '-'])
        #ftype=TXTColumnFile("GPC Files", "gpc", "Molecular Weight Distribution", ['M','W(logM)'], [], ['kDa', '-'])
        self.filetypes[ftype.extension] = ftype
        ftype = TXTColumnFile("React Files", "reac", "Relaxation modulus",
                              ['M', 'W(logM)', 'g', 'br/1000C'],
                              ['Mn', 'Mw', 'PDI'], ["g/mol", '-'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        self.theories[TheoryDiscrMWD.thname] = TheoryDiscrMWD
        self.theories[TheoryGEX.thname] = TheoryGEX
        self.theories[TheoryLogNormal.thname] = TheoryLogNormal
        self.add_common_theories()

        #set the current view
        self.set_views()
Ejemplo n.º 3
0
    def __init__(self, name="Gt", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"Gt"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryMaxwellModes import TheoryMaxwellModesTime
        from TheoryRouse import TheoryRouseTime
        from TheoryDTDStars import TheoryDTDStarsTime

        super().__init__(name, parent)

        # time range for view conversion to frequency domain
        self.tmin_view = -np.inf
        self.tmax_view = np.inf

        # VIEWS
        self.views["log(G(t))"] = View(name="log(G(t))",
                                       description="log Relaxation modulus",
                                       x_label="log(t)",
                                       y_label="log(G)",
                                       x_units="s",
                                       y_units="Pa",
                                       log_x=False,
                                       log_y=False,
                                       view_proc=self.viewLogGt,
                                       n=1,
                                       snames=["log(G)"])
        self.views["i-Rheo G',G''"] = View(
            name="i-Rheo G',G''",
            description="G', G'' from i-Rheo transformation of G(t)",
            x_label="$\omega$",
            y_label="G',G''",
            x_units="rad/s",
            y_units="Pa",
            log_x=True,
            log_y=True,
            view_proc=self.viewiRheo,
            n=2,
            snames=["G'", "G''"])
        self.views["i-Rheo-Over G',G''"] = View(
            name="i-Rheo-Over G',G''",
            description=
            "G', G'' from i-Rheo transformation of G(t) with Oversampling",
            x_label="$\omega$",
            y_label="G',G''",
            x_units="rad/s",
            y_units="Pa",
            log_x=True,
            log_y=True,
            view_proc=self.viewiRheoOver,
            n=2,
            snames=["G'", "G''"])
        self.views["Schwarzl G',G''"] = View(
            name="Schwarzl G',G''",
            description="G', G'' from Schwarzl transformation of G(t)",
            x_label="$\omega$",
            y_label="G',G''",
            x_units="rad/s",
            y_units="Pa",
            log_x=True,
            log_y=True,
            view_proc=self.viewSchwarzl_Gt,
            n=2,
            snames=["G'", "G''"])
        self.views["G(t)"] = View(name="G(t)",
                                  description="Relaxation modulus",
                                  x_label="t",
                                  y_label="G",
                                  x_units="s",
                                  y_units="Pa",
                                  log_x=True,
                                  log_y=True,
                                  view_proc=self.viewGt,
                                  n=1,
                                  snames=["G"])
        self.OVER = 100  # initial oversampling
        self.MIN_OVER = 1  # min oversampling
        self.MAX_OVER = 10000  # max oversampling

        #set multiviews
        self.multiviews = [
            self.views["log(G(t))"], self.views["i-Rheo G',G''"]
        ]  #default view order in multiplot views, set only one item for single view
        self.nplots = len(self.multiviews)

        #set multiviews
        self.nplots = 2
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("G(t) files", "gt", "Relaxation modulus",
                              ['t', 'Gt'], ['Mw', 'gamma'], ['s', 'Pa'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        self.theories[TheoryMaxwellModesTime.thname] = TheoryMaxwellModesTime
        self.theories[TheoryRouseTime.thname] = TheoryRouseTime
        self.theories[TheoryDTDStarsTime.thname] = TheoryDTDStarsTime

        self.add_common_theories()

        #set the current view
        self.set_views()
Ejemplo n.º 4
0
    def __init__(self, name="Creep", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"Creep"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryRetardationModes import TheoryRetardationModesTime
        super().__init__(name, parent)

        # time range for view conversion to frequency domain
        self.eta = 10000
        self.tmin_view = -np.inf
        self.tmax_view = np.inf

        # VIEWS
        self.views["log(gamma(t))"] = View(name="log(gamma(t))",
                                           description="log strain",
                                           x_label="log(t)",
                                           y_label="log($\gamma$)",
                                           x_units="s",
                                           y_units="-",
                                           log_x=False,
                                           log_y=False,
                                           view_proc=self.viewLogStraint,
                                           n=1,
                                           snames=["log(gamma)"])
        self.views["gamma(t)"] = View(name="gamma(t)",
                                      description="strain",
                                      x_label="t",
                                      y_label="$\gamma$",
                                      x_units="s",
                                      y_units="-",
                                      log_x=True,
                                      log_y=True,
                                      view_proc=self.viewStraint,
                                      n=1,
                                      snames=["gamma"])
        self.views["log(J(t))"] = View(name="log(J(t))",
                                       description="creep compliance",
                                       x_label="log(t)",
                                       y_label="log(J)",
                                       x_units="s",
                                       y_units="$\mathrm{Pa}^{-1}$",
                                       log_x=False,
                                       log_y=False,
                                       view_proc=self.viewLogJt,
                                       n=1,
                                       snames=["log(J)"])
        self.views["J(t)"] = View(name="J(t)",
                                  description="creep compliance",
                                  x_label="t",
                                  y_label="J",
                                  x_units="s",
                                  y_units="$\mathrm{Pa}^{-1}$",
                                  log_x=True,
                                  log_y=True,
                                  view_proc=self.viewJt,
                                  n=1,
                                  snames=["J"])
        self.views["t/J(t)"] = View(name="t/J(t)",
                                    description="t/creep compliance",
                                    x_label="t",
                                    y_label="t/J",
                                    x_units="s",
                                    y_units="Pa.s",
                                    log_x=True,
                                    log_y=True,
                                    view_proc=self.viewt_Jt,
                                    n=1,
                                    snames=["t/J"])
        self.views["i-Rheo G',G''"] = View(
            name="i-Rheo G',G''",
            description="G', G'' from i-Rheo transformation of J(t)",
            x_label="$\omega$",
            y_label="G',G''",
            x_units="rad/s",
            y_units="Pa",
            log_x=True,
            log_y=True,
            view_proc=self.viewiRheo,
            n=2,
            snames=["G'", "G''"])
        self.views["i-Rheo-Over G',G''"] = View(
            name="i-Rheo-Over G',G''",
            description=
            "G', G'' from i-Rheo transformation of J(t) with Oversampling",
            x_label="$\omega$",
            y_label="G',G''",
            x_units="rad/s",
            y_units="Pa",
            log_x=True,
            log_y=True,
            view_proc=self.viewiRheoOver,
            n=2,
            snames=["G'", "G''"])
        self.OVER = 100  # initial oversampling
        self.MIN_OVER = 1  # min oversampling
        self.MAX_OVER = 10000  # max oversampling

        #set multiviews
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("Creep files", "creep", "Creep files",
                              ['t', 'strain'], ['stress', 'Mw', 'T'],
                              ['s', '-', 'Pa', 'C'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        self.theories[
            TheoryRetardationModesTime.thname] = TheoryRetardationModesTime
        self.add_common_theories()

        #set the current view
        self.set_views()
Ejemplo n.º 5
0
    def __init__(self, name="SANS", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"SANS"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryDebye import TheoryDebye
        super().__init__(name, parent)

        # VIEWS
        self.views["log(I(q))"] = View(
            name="log(I(q))",
            description="log Intensity",
            x_label="log(q)",
            y_label="log(I)",
            x_units="$\mathrm{\AA}^{-1}$",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogSANS,
            n=1,
            snames=["log(I)"])
        self.views["I(q)"] = View(
            name="I(q)",
            description="Intensity",
            x_label="q",
            y_label="I",
            x_units="$\mathrm{\AA}^{-1}$",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewSANS,
            n=1, 
            snames=["I"])
        self.views["Zimm"] = View(
            name="Zimm",
            description="Zimm plot (1/I(q) vs q^2)",
            x_label="$\mathrm{q}^2$",
            y_label="1/I",
            x_units="$\mathrm{\AA}^{-2}$",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewZimm,
            n=1, 
            snames=["1/I"])
        self.views["Kratky"] = View(
            name="Kratky",
            description="Kratky plot (q^2*I(q) vs q)",
            x_label="q",
            y_label="$\mathrm{q}^2\cdot \mathrm{I}$",
            x_units="$\mathrm{\AA}^{-1}$",
            y_units="$\mathrm{\AA}^{-2}$",
            log_x=False,
            log_y=False,
            view_proc=self.viewKratky,
            n=1, 
            snames=["q2*I"])

        #set multiviews
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("SANS files", "sans", "SANS files",
                              ['q', 'I(q)'], ['Mw', 'Phi'],
                              ['1/A', '-'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        self.theories[
            TheoryDebye.thname] = TheoryDebye
        self.add_common_theories()

        #set the current view
        self.set_views()
Ejemplo n.º 6
0
    def __init__(self, name='LAOS', parent=None, nplots=1, ncols=2):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {'LAOS'})
            - parent {[type]} -- [description] (default: {None})
        """
        # IMPORT THEORIES
        # Import theories specific to the Application e.g.:
        # from TheoryLAOS import TheoryA

        super().__init__(name, parent, nplot_max=1)

        # VIEWS
        # set the views that can be selected in the view combobox
        self.views['sigma(gamma)'] = View(
            name='sigma(gamma)',
            description='Stress as a function of strain',
            x_label='$\gamma(t)$',
            y_label='$\sigma(t)$',
            x_units='-',
            y_units='Pa',
            log_x=False,
            log_y=False,
            view_proc=self.view_sigmagamma,
            n=1,
            snames=['$\sigma(t)$'])

        # self.views['sigma(gdot)'] = View(
        #     name='sigma(gdot)',
        #     description='Stress as a function of shear rate',
        #     x_label='$\dot\gamma(t)$',
        #     y_label='$\sigma(t)$',
        #     x_units='s$^{-1}$',
        #     y_units='Pa',
        #     log_x=False,
        #     log_y=False,
        #     view_proc=self.view_sigmagdot,
        #     n=1,
        #     snames=['$\sigma(t)$'])

        #set multiviews
        #default view order in multiplot views, set only one item for single view
        #if more than one item, modify the 'nplots' in the super().__init__ call
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        # set the type of files that ApplicationLAOS can open
        ftype = TXTColumnFile(name='content of files',
                              extension='laos',
                              description='file containing laos data',
                              col_names=['gamma', 'sigma', 'time'],
                              basic_file_parameters=['omega', 'gamma'],
                              col_units=['-', 'Pa'])
        self.filetypes[
            ftype.extension] = ftype  #add each the file type to dictionary

        # THEORIES
        # add the theories related to ApplicationLAOS to the dictionary, e.g.:
        # self.theories[TheoryA.thname] = TheoryA
        # self.theories[TheoryB.thname] = TheoryB
        self.add_common_theories()  # Add basic theories to the application

        #set the current view
        self.set_views()
Ejemplo n.º 7
0
    def __init__(self, name="LVE", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"LVE"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryMaxwellModes import TheoryMaxwellModesFrequency
        from TheoryLikhtmanMcLeish2002 import TheoryLikhtmanMcLeish2002
        from TheoryTTS import TheoryWLFShift
        from TheoryCarreauYasuda import TheoryCarreauYasuda
        from TheoryRouse import TheoryRouseFrequency
        from TheoryDTDStars import TheoryDTDStarsFreq
        from TheoryBobLVE import TheoryBobLVE
        from TheoryRDPLVE import TheoryRDPLVE
        super().__init__(name, parent)

        # VIEWS
        self.views["log(G',G''(w))"] = View(
            name="log(G',G''(w))",
            description="log Storage,Loss moduli",
            x_label="log($\omega$)",
            y_label="log(G'($\omega$),G''($\omega$))",
            x_units="rad/s",
            y_units="Pa",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogG1G2,
            n=2,
            snames=["log(G'(w))", "log(G''(w))"])
        self.views["G',G''(w)"] = View("G',G''(w)", "Storage,Loss moduli",
                                       "$\omega$",
                                       "G'($\omega$),G''($\omega$)", "rad/s",
                                       "Pa", True, True, self.viewG1G2, 2,
                                       ["G'(w)", "G''(w)"])
        self.views["etastar"] = View("etastar", "Complex Viscosity",
                                     "$\omega$", "$|\eta^*(\omega)|$", "rad/s",
                                     "Pa.s", True, True, self.viewEtaStar, 1,
                                     ["eta*(w)"])
        self.views["logetastar"] = View("logetastar", "log Complex Viscosity",
                                        "log($\omega$)",
                                        "log$|\eta^*(\omega)|$", "rad/s",
                                        "Pa.s", False, False,
                                        self.viewLogEtaStar, 1,
                                        ["log(eta*(w))"])
        self.views["delta"] = View("delta", "delta", "$\omega$",
                                   "$\delta(\omega)$", "rad/s", "-", True,
                                   True, self.viewDelta, 1, ["delta(w)"])
        self.views["tan(delta)"] = View("tan(delta)", "tan(delta)", "$\omega$",
                                        "tan($\delta$)", "rad/s", "-", True,
                                        True, self.viewTanDelta, 1,
                                        ["tan(delta((w))"])
        self.views["log(tan(delta))"] = View(
            "log(tan(delta))", "log(tan(delta))", "log($\omega$)",
            "log(tan($\delta$))", "rad/s", "-", False, False,
            self.viewLogTanDelta, 1, ["log(tan(delta((w)))"])
        self.views["log(G*)"] = View("log(G*)", "log(G*(omega))",
                                     "log($\omega$)", "log(G*($\omega$))",
                                     "rad/s", "Pa", False, False,
                                     self.viewLogGstar, 1, ["log(G*)"])
        self.views["log(tan(delta),G*)"] = View(
            "log(tan(delta),G*)", "log(tan($\delta$))", "log(G*)",
            "log(tan($\delta$))", "Pa", "-", False, False,
            self.viewLogtandeltaGstar, 1, ["log(tan($\delta))"])
        self.views["delta(G*)"] = View("delta(G*)", "$\delta$)", "log(G*)",
                                       "$\delta$)", "Pa", "deg", False, False,
                                       self.viewdeltatanGstar, 1, ["delta"])
        self.views["J',J''(w)"] = View("J',J''(w)", "J moduli", "$\omega$",
                                       "J'($\omega$),J''($\omega$)", "rad/s",
                                       "$Pa^{-1}$", True, True, self.viewJ1J2,
                                       2, ["J'(w)", "J''(w)"])
        self.views["Cole-Cole"] = View("Cole-Cole", "Cole-Cole plot",
                                       "$\eta'$", "$\eta''$", "Pa.s", "Pa.s",
                                       False, False, self.viewColeCole, 1,
                                       ["$eta'$"])
        self.views["log(G')"] = View(name="log(G')",
                                     description="log Storage modulus",
                                     x_label="log($\omega$)",
                                     y_label="log(G'($\omega$))",
                                     x_units="rad/s",
                                     y_units="Pa",
                                     log_x=False,
                                     log_y=False,
                                     view_proc=self.viewLogG1,
                                     n=1,
                                     snames=["log(G'(w))"])
        self.views["G'"] = View("G'", "Storage modulus", "$\omega$",
                                "G'($\omega$)", "rad/s", "Pa", True, True,
                                self.viewG1, 1, ["G'(w)"])
        self.views["log(G'')"] = View(name="log(G'')",
                                      description="log Loss modulus",
                                      x_label="log($\omega$)",
                                      y_label="log(G'($\omega$))",
                                      x_units="rad/s",
                                      y_units="Pa",
                                      log_x=False,
                                      log_y=False,
                                      view_proc=self.viewLogG2,
                                      n=1,
                                      snames=["log(G''(w))"])
        self.views["G''"] = View("G''", "Loss modulus", "$\omega$",
                                 "G''($\omega$)", "rad/s", "Pa", True, True,
                                 self.viewG2, 1, ["G''(w)"])
        self.views["log(G',G''(w),tan(delta))"] = View(
            name="log(G',G''(w),tan(delta))",
            description="log Storage,Loss moduli, tan(delta)",
            x_label="log($\omega$)",
            y_label="log(G'($\omega$),G''($\omega$),tan($\delta$))",
            x_units="rad/s",
            y_units="Pa,-",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogG1G2tandelta,
            n=3,
            snames=["log(G'(w))", "log(G''(w)),log(tan(delta))"])

        #set multiviews
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("LVE files", "tts", "LVE files",
                              ['w', 'G\'', 'G\'\''], ['Mw', 'T'],
                              ['rad/s', 'Pa', 'Pa'])
        self.filetypes[ftype.extension] = ftype
        self.filetypes['osc'] = TXTColumnFile(
            "OSC files", "osc",
            "Small-angle oscillatory masurements from the Rheometer",
            ['w', 'G\'', 'G\'\''], ['Mw', 'T'], ['rad/s', 'Pa', 'Pa'])

        self.filetypes['xlsx'] = ExcelFile("Excel File", "xlsx", "ExcelFIle",
                                           ['w', 'G\'', 'G\'\''], [],
                                           ['rad/s', 'Pa', 'Pa'])

        # THEORIES
        self.theories[
            TheoryMaxwellModesFrequency.thname] = TheoryMaxwellModesFrequency
        self.theories[
            TheoryLikhtmanMcLeish2002.thname] = TheoryLikhtmanMcLeish2002
        self.theories[TheoryCarreauYasuda.thname] = TheoryCarreauYasuda
        #self.theories[TheoryWLFShift.thname]=TheoryWLFShift
        self.theories[TheoryRouseFrequency.thname] = TheoryRouseFrequency
        self.theories[TheoryDTDStarsFreq.thname] = TheoryDTDStarsFreq
        self.theories[TheoryBobLVE.thname] = TheoryBobLVE
        self.theories[TheoryRDPLVE.thname] = TheoryRDPLVE
        self.add_common_theories()

        #set the current view
        self.set_views()
Ejemplo n.º 8
0
    def __init__(self, name="Crystal", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"LVE"})
            - parent {[type]} -- [description] (default: {None})
        """
        #from TheoryRoliePoly import TheoryRoliePoly
        #from TheoryUCM import TheoryUCM
        #from TheoryGiesekus import TheoryGiesekus
        #from TheoryPomPom import TheoryPomPom
        from TheoryRolieDoublePoly import TheoryRolieDoublePoly
        #from TheoryBobNLVE import TheoryBobNLVE
        #from TheoryPETS import TheoryPETS
        #from TheorySCCR import TheorySCCR
        # from TheorySCCROLD import TheorySCCROLD

        super().__init__(name, parent)

        # VIEWS
        self.views["log(eta(t))"] = View(
            name="log(eta(t))",
            description="log transient viscosity",
            x_label="log(t)",
            y_label="log($\eta^+$)",
            x_units="s",
            y_units="Pa$\cdot$s",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogeta,
            n=1,
            snames=["log(eta)"])
        self.views["Ndot(t)"] = View(
            name="Ndot(t)",
            description="Nucleation rate",
            x_label="t",
            y_label="$\dot{N}$",
            x_units="s",
            y_units="s$^{-1}$m$^{-3}$",
            log_x=False,
            log_y=False,
            view_proc=self.viewNdot,
            n=1,
            snames=["Ndot"])  
        self.views["phiX(t)"] = View(
            name="phiX(t)",
            description="Crystal fraction",
            x_label="t",
            y_label="$\phi_X$",
            x_units="s",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewphiX,
            n=1,
            snames=["phiX"])  
        self.views["N(t)"] = View(
            name="N(t)",
            description="Nucleation density",
            x_label="t",
            y_label="N",
            x_units="s",
            y_units="m$^{-3}$",
            log_x=False,
            log_y=False,
            view_proc=self.viewNt,
            n=1,
            snames=["N"]) 
        self.views["eta(t)"] = View(
            name="eta(t)",
            description="transient viscosity",
            x_label="t",
            y_label="$\eta^+$",
            x_units="s",
            y_units="Pa$\cdot$s",
            log_x=True,
            log_y=True,
            view_proc=self.vieweta,
            n=1,
            snames=["eta"])                      
        self.views["log(sigma(gamma))"] = View(
            name="log(sigma(gamma))",
            description="log transient shear stress vs gamma",
            x_label="log($\gamma$)",
            y_label="log($\sigma^+$)",
            x_units="-",
            y_units="Pa",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogSigmaGamma,
            n=1,
            snames=["log(sigma)"])
        self.views["sigma(gamma)"] = View(
            name="sigma(gamma)",
            description="transient shear stress vs gamma",
            x_label="$\gamma$",
            y_label="$\sigma^+$",
            x_units="-",
            y_units="Pa",
            log_x=False,
            log_y=False,
            view_proc=self.viewSigmaGamma,
            n=1,
            snames=["sigma"])            
        self.views["log(sigma(t))"] = View(
            name="log(sigma(t))",
            description="log transient shear stress vs time",
            x_label="log(t)",
            y_label="log($\sigma^+$)",
            x_units="s",
            y_units="Pa",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogSigmaTime,
            n=1,
            snames=["log(sigma)"])
        self.views["sigma(t)"] = View(
            name="sigma(t)",
            description="transient shear stress vs time",
            x_label="t",
            y_label="$\sigma^+$",
            x_units="s",
            y_units="Pa",
            log_x=False,
            log_y=False,
            view_proc=self.viewSigmaTime,
            n=1,
            snames=["sigma"])
        self.views["Flow Curve"] = View(
            name="Flow Curve",
            description="Steady state stress vs flow rate",
            x_label="Flow rate",
            y_label="$\sigma$",
            x_units="s$^{-1}$",
            y_units="Pa",
            log_x=True,
            log_y=True,
            view_proc=self.view_flowcurve,
            n=1,
            snames=["sigma"],
            with_thline=False,
            filled=True)

        #set multiviews
        self.nplots = 2
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("Start-up of shear flow with crystallisation", "shearxs",
                              "Shear crystallisation files", ['t', 'sigma_xy', 'Ndot', 'phi_X', 'N'], ['gdot', 'T','tstop'],
                              ['s', 'Pa$\cdot$s', 's$^{-1}$m$^{-3}$', '-', 'm$^{-3}$'])
        self.filetypes[ftype.extension] = ftype
        ftype = TXTColumnFile("Elongation flow with crystallisation", "uextxs",
                              "Elongation crystallisation files", ['t', 'N1', 'Ndot', 'phi_X', 'N'],
                              ['gdot', 'T','tstop'], ['s', 'Pa$\cdot$s', 's$^{-1}$m$^{-3}$', '-', 'm$^{-3}$'])
        self.filetypes[ftype.extension] = ftype
        ftype = TXTColumnFile("Start-up of shear flow", "shear",
                              "Shear flow files", ['t', 'sigma_xy'], ['gdot', 'T'],
                              ['s', 'Pa$\cdot$s'])
        self.filetypes[ftype.extension] = ftype
        ftype = TXTColumnFile("Elongation flow", "uext",
                              "Elongation flow files", ['t', 'N1'],
                              ['gdot', 'T'], ['s', 'Pa$\cdot$s'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        #self.theories[TheoryRoliePoly.thname] = TheoryRoliePoly
        #self.theories[TheoryUCM.thname] = TheoryUCM
        #self.theories[TheoryGiesekus.thname] = TheoryGiesekus
        #self.theories[TheoryPomPom.thname] = TheoryPomPom
        self.theories[TheoryRolieDoublePoly.thname] = TheoryRolieDoublePoly
        #self.theories[TheoryBobNLVE.thname] = TheoryBobNLVE
        #self.theories[TheoryPETS.thname] = TheoryPETS
        #self.theories[TheorySCCR.thname] = TheorySCCR
        # self.theories[TheorySCCROLD.thname] = TheorySCCROLD
        self.add_common_theories()
        
        #set the current view
        self.set_views()
Ejemplo n.º 9
0
    def __init__(self, name="TTSF", parent=None):
        """
        **Constructor**

        Keyword Arguments:
            - name {[type]} -- [description] (default: {"TTSFactors"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryWLF import TheoryWLF
        from TheoryArrhenius import TheoryArrhenius
        #from TheoryArrhenius import TheoryArrhenius
        super().__init__(name, parent)

        # VIEWS
        self.views["log(aT)"] = View(name="log(aT)",
                                     description="log Horizontal shift factor",
                                     x_label="T",
                                     y_label="$\log(a_T)$",
                                     x_units="°C",
                                     y_units="-",
                                     log_x=False,
                                     log_y=False,
                                     view_proc=self.viewLogaT,
                                     n=1,
                                     snames=["log(aT)"])
        self.views["aT"] = View(name="aT",
                                description="Horizontal shift factor",
                                x_label="T",
                                y_label="$a_T$",
                                x_units="°C",
                                y_units="-",
                                log_x=False,
                                log_y=True,
                                view_proc=self.viewaT,
                                n=1,
                                snames=["aT"])
        self.views["log(bT)"] = View(name="log(bT)",
                                     description="log Vertical shift factor",
                                     x_label="T",
                                     y_label="$\log(b_T)$",
                                     x_units="°C",
                                     y_units="-",
                                     log_x=False,
                                     log_y=False,
                                     view_proc=self.viewLogbT,
                                     n=1,
                                     snames=["log(bT)"])
        self.views["bT"] = View(name="bT",
                                description="Vertical shift factor",
                                x_label="T",
                                y_label="$b_T$",
                                x_units="°C",
                                y_units="-",
                                log_x=False,
                                log_y=True,
                                view_proc=self.viewbT,
                                n=1,
                                snames=["bT"])

        self.views["log(aT, bT)"] = View(
            name="log(aT, bT)",
            description="log Horizontal and Vertical shift factors",
            x_label="T",
            y_label="$\log(a_T, b_T)$",
            x_units="°C",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogaTbT,
            n=2,
            snames=["log(aT)", "log(bT)"])

        self.views["log(aT) vs 1/T"] = View(
            name="log(aT) vs 1/T",
            description="log Horizontal shift factors vs 1/T",
            x_label="1/T",
            y_label="$\log(a_T)$",
            x_units="K$^{-1}$",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogaT_invT,
            n=1,
            snames=["log(aT)"])

        #set multiviews
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("TTS factors", "ttsf", "TTS shift factors",
                              ['T', 'aT', 'bT'], ['Mw'], ['°C', '-', '-'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        self.theories[TheoryWLF.thname] = TheoryWLF
        self.theories[TheoryArrhenius.thname] = TheoryArrhenius
        #self.theories[TheoryWLFShiftTest.thname] = TheoryWLFShiftTest
        self.add_common_theories()

        #set the current view
        self.set_views()
Ejemplo n.º 10
0
    def __init__(self, name='React', parent=None, **kwargs):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {'React'})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryLDPEBatch import TheoryTobitaBatch
        from TheoryTobitaCSTR import TheoryTobitaCSTR
        from TheoryMultiMetCSTR import TheoryMultiMetCSTR
        from TheoryReactMix import TheoryReactMix
        from TheoryCreatePolyconf import TheoryCreatePolyconf
        from TheoryDieneCSTR import TheoryDieneCSTR

        super().__init__(name, parent)

        # VIEWS
        # set the views that can be selected in the view combobox
        self.views["w(M)"] = View(name="w(M)",
                                  description="Molecular weight distribution",
                                  x_label="M",
                                  y_label="w",
                                  x_units="g/mol",
                                  y_units="-",
                                  log_x=True,
                                  log_y=False,
                                  view_proc=self.view_wM,
                                  n=1,
                                  snames=["w"])
        self.views["g(M)"] = View(name="g(M)",
                                  description="g(M)",
                                  x_label="M",
                                  y_label="g(M)",
                                  x_units="g/mol",
                                  y_units="-",
                                  log_x=True,
                                  log_y=False,
                                  view_proc=self.view_gM,
                                  n=1,
                                  snames=["g(M)"])
        self.views['br/1000C'] = View(name="br/1000C",
                                      description="br/1000C(M)",
                                      x_label="M",
                                      y_label="br/1000C",
                                      x_units="g/mol",
                                      y_units="-",
                                      log_x=True,
                                      log_y=False,
                                      view_proc=self.view_br_1000C,
                                      n=1,
                                      snames=["br/1000C"])
        self.views["log(w(M))"] = View(
            name="log(w(M))",
            description="Molecular weight distribution",
            x_label="M",
            y_label="log(w)",
            x_units="g/mol",
            y_units="-",
            log_x=True,
            log_y=False,
            view_proc=self.view_logwM,
            n=1,
            snames=["log(w)"])
        self.views["log(g(M))"] = View(name="log(g(M))",
                                       description="log(g(M))",
                                       x_label="M",
                                       y_label="log(g)",
                                       x_units="g/mol",
                                       y_units="-",
                                       log_x=True,
                                       log_y=False,
                                       view_proc=self.view_loggM,
                                       n=1,
                                       snames=["log(g)"])
        self.views['p(mass br) log-lin'] = View(
            name="p(mass br) log-lin",
            description=
            "Prob. dist. of mass segement b/w branch pt log-lin scale",
            x_label="M segment",
            y_label="p(M segment)",
            x_units="g/mol",
            y_units="-",
            log_x=True,
            log_y=False,
            view_proc=self.thview_proba_mass_br,
            n=1,
            snames=["p(M segment)"],
            with_thline=False)
        self.views['p(br/molecule) log-lin'] = View(
            name="p(br/molecule) log-lin",
            description=
            "Prob. dist. of num. branch pt per molecule log-lin scale",
            x_label="Num. br/molecule",
            y_label="p(br/molecule)",
            x_units="-",
            y_units="-",
            log_x=True,
            log_y=False,
            view_proc=self.thview_proba_num_br,
            n=1,
            snames=["p(M segment)"],
            with_thline=False)
        self.views['p(br/molecule) lin-lin'] = View(
            name="p(br/molecule) lin-lin",
            description=
            "Prob. dist. of num. branch pt per molecule lin-lin scale",
            x_label="Num. br/molecule",
            y_label="p(br/molecule)",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.thview_proba_num_br,
            n=1,
            snames=["p(M segment)"],
            with_thline=False)
        #### extra views for P&S:
        self.views['<senio(prio)> log-log'] = View(
            name="<senio(prio)> log-log",
            description="Average seniority vs priority log-log scale",
            x_label="Priority",
            y_label="Average Seniority",
            x_units="-",
            y_units="-",
            log_x=True,
            log_y=True,
            view_proc=self.thview_avsenio_v_prio,
            n=3,
            snames=["av_senio"],
            with_thline=False)
        self.views['<senio(prio)> lin-log'] = View(
            name="<senio(prio)> lin-log",
            description="Average seniority vs priority lin-log scale",
            x_label="Priority",
            y_label="Average Seniority",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=True,
            view_proc=self.thview_avsenio_v_prio,
            n=3,
            snames=["av_senio"],
            with_thline=False)
        self.views['<senio(prio)> lin-lin'] = View(
            name="<senio(prio)> lin-lin",
            description="Average seniority vs priority lin-lin scale",
            x_label="Priority",
            y_label="Average Seniority",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.thview_avsenio_v_prio,
            n=3,
            snames=["av_senio"],
            with_thline=False)
        #####
        self.views['<prio(senio)> log-log'] = View(
            name="<prio(senio)> log-log",
            description="Average priority vs seniority log-log scale",
            x_label="Seniority",
            y_label="Average Priority",
            x_units="-",
            y_units="-",
            log_x=True,
            log_y=True,
            view_proc=self.thview_avprio_v_senio,
            n=3,
            snames=["av_prio"],
            with_thline=False)
        self.views['<prio(senio)> lin-log'] = View(
            name="<prio(senio)> lin-log",
            description="Average priority vs seniority lin-log scale",
            x_label="Seniority",
            y_label="Average Priority",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=True,
            view_proc=self.thview_avprio_v_senio,
            n=3,
            snames=["av_prio"],
            with_thline=False)
        self.views['<prio(senio)> lin-lin'] = View(
            name="<prio(senio)> lin-lin",
            description="Average priority vs seniority lin-lin scale",
            x_label="Seniority",
            y_label="Average Priority",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.thview_avprio_v_senio,
            n=3,
            snames=["av_prio"],
            with_thline=False)
        #####
        self.views['p(senio) log-log'] = View(
            name="p(senio) log-log",
            description="seniority prob. dist. log-log",
            x_label="Seniority",
            y_label="Probability",
            x_units="-",
            y_units="-",
            log_x=True,
            log_y=True,
            view_proc=self.thview_proba_senio,
            n=1,
            snames=["proba_senio"],
            with_thline=False)
        self.views['p(senio) lin-log'] = View(
            name="p(senio) lin-log",
            description="seniority prob. dist. lin-log scale",
            x_label="Seniority",
            y_label="Probability",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=True,
            view_proc=self.thview_proba_senio,
            n=1,
            snames=["proba_senio"],
            with_thline=False)
        #####
        self.views['p(prio) log-log'] = View(
            name="p(prio) log-log",
            description="Priority prob. dist. log-log scale",
            x_label="Priority",
            y_label="Probability",
            x_units="-",
            y_units="-",
            log_x=True,
            log_y=True,
            view_proc=self.thview_proba_prio,
            n=1,
            snames=["proba_prio"],
            with_thline=False)
        self.views['p(prio) lin-log'] = View(
            name="p(prio) lin-log",
            description="Priority prob. dist. lin-log scale",
            x_label="Priority",
            y_label="Probability",
            x_units="-",
            y_units="-",
            log_x=False,
            log_y=True,
            view_proc=self.thview_proba_prio,
            n=1,
            snames=["proba_prio"],
            with_thline=False)
        ####
        self.views['<mass br(senio)> log-log'] = View(
            name="<mass br(senio)> log-log",
            description=
            "Average mol. mass b/w branch pt vs seniority log-log scale",
            x_label="Seniority",
            y_label="Av. strand length",
            x_units="-",
            y_units="g/mol",
            log_x=True,
            log_y=True,
            view_proc=self.thview_avarmlen_v_senio,
            n=1,
            snames=["av_strand_length"],
            with_thline=False)
        self.views['<mass br(senio)> lin-lin'] = View(
            name="<mass br(senio)> lin-lin",
            description=
            "Average mol. mass b/w branch pt vs seniority lin-lin scale",
            x_label="Seniority",
            y_label="Av. strand length",
            x_units="-",
            y_units="g/mol",
            log_x=False,
            log_y=False,
            view_proc=self.thview_avarmlen_v_senio,
            n=1,
            snames=["av_strand_length"],
            with_thline=False)
        ####
        self.views['<mass br(prio)> log-log'] = View(
            name="<mass br(prio)> log-log",
            description=
            "Average mol. mass b/w branch pt vs priority log-log scale",
            x_label="Priority",
            y_label="Av. strand length",
            x_units="-",
            y_units="g/mol",
            log_x=True,
            log_y=True,
            view_proc=self.thview_avarmlen_v_prio,
            n=1,
            snames=["av_strand_length"],
            with_thline=False)
        self.views['<mass br(prio)> lin-lin'] = View(
            name="<mass br(prio)> lin-lin",
            description=
            "Average mol. mass b/w branch pt vs priority lin-lin scale",
            x_label="Priority",
            y_label="Av. strand length",
            x_units="-",
            y_units="g/mol",
            log_x=False,
            log_y=False,
            view_proc=self.thview_avarmlen_v_prio,
            n=1,
            snames=["av_strand_length"],
            with_thline=False)

        self.extra_view_names = [
            '<senio(prio)> log-log', '<senio(prio)> lin-log',
            '<senio(prio)> lin-lin', '<prio(senio)> log-log',
            '<prio(senio)> lin-log', '<prio(senio)> lin-lin',
            'p(senio) log-log', 'p(senio) lin-log', 'p(prio) log-log',
            'p(prio) lin-log', '<mass br(senio)> log-log',
            '<mass br(senio)> lin-lin', '<mass br(prio)> log-log',
            '<mass br(prio)> lin-lin'
        ]
        #set multiviews
        self.nplots = 3
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        # set the type of files that ApplicationReact can open
        ftype = TXTColumnFile(name='React files',
                              extension='reac',
                              description='Reatc file',
                              col_names=['M', 'w(M)', 'g', 'br/1000C'],
                              basic_file_parameters=[],
                              col_units=['g/mol', '-', '-', '-'])
        self.filetypes[
            ftype.extension] = ftype  #add each the file type to dictionary

        # THEORIES
        # add the theories related to ApplicationReact to the dictionary, e.g.:
        self.theories[TheoryTobitaBatch.thname] = TheoryTobitaBatch
        self.theories[TheoryTobitaCSTR.thname] = TheoryTobitaCSTR
        self.theories[TheoryMultiMetCSTR.thname] = TheoryMultiMetCSTR
        self.theories[TheoryReactMix.thname] = TheoryReactMix
        self.theories[TheoryCreatePolyconf.thname] = TheoryCreatePolyconf
        self.theories[TheoryDieneCSTR.thname] = TheoryDieneCSTR
        self.add_common_theories()

        #set the current view
        self.set_views()
        for _ in self.extra_view_names:
            self.viewComboBox.removeItem(self.viewComboBox.count() - 1)
Ejemplo n.º 11
0
    def __init__(self, name="Dielectric", parent=None):
        """
        **Constructor**
        
        Keyword Arguments:
            - name {[type]} -- [description] (default: {"Dielectric"})
            - parent {[type]} -- [description] (default: {None})
        """
        from TheoryDebyeModes import TheoryDebyeModesFrequency
        from TheoryHavriliakNegamiModes import TheoryHavriliakNegamiModesFrequency
        from TheoryKWWModes import TheoryKWWModesFrequency

        super().__init__(name, parent)

        # VIEWS
        self.views["log(e',e''(w))"] = View(
            name="log(e',e''(w))",
            description="log Relative permittivity, Dielectric Loss",
            x_label="log($\omega$)",
            y_label="log($\epsilon',\epsilon''$)",
            x_units="rad/s",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewLogE1E2,
            n=2,
            snames=["log(e')", "log(e'')"])
        self.views["semilog(e',e''(w))"] = View(
            name="semilog(e',e''(w))",
            description="semilog Relative permittivity, Dielectric Loss",
            x_label="log($\omega$)",
            y_label="$\epsilon',\epsilon''$",
            x_units="rad/s",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewSemiLogE1E2,
            n=2,
            snames=["e'(w)", "e''(w)"])
        self.views["e',e''(w)"] = View(
            "e',e''(w)", "Relative permittivity, Dielectric Loss", "$\omega$",
            "$\epsilon',\epsilon''$", "rad/s", "-", True, True, self.viewE1E2,
            2, ["e'(w)", "e''(w)"])
        self.views["log(e')"] = View(name="log(e')",
                                     description="log Relative Permittivity",
                                     x_label="log($\omega$)",
                                     y_label="log($\epsilon'$)",
                                     x_units="rad/s",
                                     y_units="-",
                                     log_x=False,
                                     log_y=False,
                                     view_proc=self.viewLogE1,
                                     n=1,
                                     snames=["log(e')"])
        self.views["semilog(e')"] = View(
            name="semilog(e')",
            description="log Relative Permittivity",
            x_label="log($\omega$)",
            y_label="$\epsilon'$",
            x_units="rad/s",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewSemiLogE1,
            n=1,
            snames=["e'"])
        self.views["e'"] = View("e'", "Relative Permittivity", "$\omega$",
                                "$\epsilon'$", "rad/s", "-", True, True,
                                self.viewE1, 1, ["e'"])
        self.views["log(e'')"] = View(name="log(e'')",
                                      description="log Dielectric Loss",
                                      x_label="log($\omega$)",
                                      y_label="log($\epsilon''$)",
                                      x_units="rad/s",
                                      y_units="-",
                                      log_x=False,
                                      log_y=False,
                                      view_proc=self.viewLogE2,
                                      n=1,
                                      snames=["log(e'')"])
        self.views["semilog(e'')"] = View(
            name="semilog(e'')",
            description="semilog Dielectric Loss",
            x_label="log($\omega$)",
            y_label="$\epsilon''$",
            x_units="rad/s",
            y_units="-",
            log_x=False,
            log_y=False,
            view_proc=self.viewSemiLogE2,
            n=1,
            snames=["e''"])
        self.views["e''"] = View("e''", "Dielectric Loss", "$\omega$",
                                 "$\epsilon''$", "rad/s", "-", True, True,
                                 self.viewE2, 1, ["e''"])
        self.views["Cole-Cole"] = View("Cole-Cole", "Cole-Cole plot",
                                       "$\epsilon'$", "$\epsilon''$", "-", "-",
                                       False, False, self.viewColeCole, 1,
                                       ["e''"])

        #set multiviews
        self.nplots = 1
        self.multiviews = []
        for i in range(self.nplot_max):
            # set views in the same order as declared above
            self.multiviews.append(list(self.views.values())[i])
        self.multiplots.reorg_fig(self.nplots)

        # FILES
        ftype = TXTColumnFile("Dielectric Spectroscopy files", "dls",
                              "Dielectric Spectroscopy files",
                              ['w', 'e\'', 'e\'\''], ['Mw', 'T'],
                              ['rad/s', '-', '-'])
        self.filetypes[ftype.extension] = ftype

        # THEORIES
        self.theories[
            TheoryDebyeModesFrequency.thname] = TheoryDebyeModesFrequency
        self.theories[TheoryHavriliakNegamiModesFrequency.
                      thname] = TheoryHavriliakNegamiModesFrequency
        self.theories[TheoryKWWModesFrequency.thname] = TheoryKWWModesFrequency
        self.add_common_theories()

        #set the current view
        self.set_views()