Source code for pyleecan.Methods.Slot.SlotW15.plot_schematics

import matplotlib.pyplot as plt
from numpy import pi, exp

from ....Classes.Arc1 import Arc1
from ....Classes.LamSlot import LamSlot
from ....Classes.Segment import Segment
from ....definitions import config_dict
from ....Functions.Plot import (
    ARROW_COLOR,
    ARROW_WIDTH,
    MAIN_LINE_COLOR,
    MAIN_LINE_STYLE,
    MAIN_LINE_WIDTH,
    P_FONT_SIZE,
    SC_FONT_SIZE,
    SC_LINE_COLOR,
    SC_LINE_STYLE,
    SC_LINE_WIDTH,
    TEXT_BOX,
    plot_quote,
)
from ....Methods import ParentMissingError

MAGNET_COLOR = config_dict["PLOT"]["COLOR_DICT"]["MAGNET_COLOR"]


[docs]def plot_schematics( self, is_default=False, is_add_point_label=False, is_add_schematics=True, is_add_main_line=True, type_add_active=1, save_path=None, is_show_fig=True, fig=None, ax=None, ): """Plot the schematics of the slot Parameters ---------- self : SlotW15 A SlotW15 object is_default : bool True: plot default schematics, else use current slot values is_add_point_label : bool True to display the name of the points (Z1, Z2....) is_add_schematics : bool True to display the schematics information (W0, H0...) is_add_main_line : bool True to display "main lines" (slot opening and 0x axis) type_add_active : int 0: No active surface, 1: active surface as winding, 2: active surface as magnet, 3: active surface as winding + wedges save_path : str full path including folder, name and extension of the file to save if save_path is not None is_show_fig : bool To call show at the end of the method fig : Matplotlib.figure.Figure existing figure to use if None create a new one ax : Matplotlib.axes.Axes object Axis on which to plot the data Returns ------- fig : Matplotlib.figure.Figure Figure containing the schematics ax : Matplotlib.axes.Axes object Axis containing the schematics """ # Use some default parameter if is_default: slot = type(self)( Zs=12, W0=30e-3, W3=30e-3, H0=15e-3, H1=17.5e-3, H2=70e-3, R1=15e-3, R2=15e-3, ) lam = LamSlot( Rint=0.135, Rext=0.3, is_internal=False, is_stator=True, slot=slot ) return slot.plot_schematics( is_default=False, is_add_point_label=is_add_point_label, is_add_schematics=is_add_schematics, is_add_main_line=is_add_main_line, type_add_active=type_add_active, save_path=save_path, is_show_fig=is_show_fig, fig=fig, ax=ax, ) else: # Getting the main plot if self.parent is None: raise ParentMissingError("Error: The slot is not inside a Lamination") lam = self.parent fig, ax = lam.plot( alpha=pi / self.Zs, is_show_fig=False, fig=fig, ax=ax ) # center slot on Ox axis point_dict = self._comp_point_coordinate() if self.is_outwards(): sign = 1 else: sign = -1 Rbo = self.get_Rbo() sp = 2 * pi / self.Zs # Adding point label if is_add_point_label: for name, Z in point_dict.items(): ax.text( Z.real, Z.imag, name, fontsize=P_FONT_SIZE, bbox=TEXT_BOX, ) # Adding schematics if is_add_schematics: # H0 line = Segment( Rbo * exp(1j * sp), (point_dict["Z2"] + point_dict["Z12"]) / 2 * exp(1j * sp), ) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="H0", offset_label=self.W0 * 0.3, is_arrow=True, fontsize=SC_FONT_SIZE, ) # H1 line = Segment( (point_dict["Zc1"] + point_dict["Zc4"]) / 2, (point_dict["Z2"] + point_dict["Z12"]) / 2, ) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="H1", offset_label=-self.W0 * 0.5 + 1j * self.W0 * 0.3, is_arrow=True, fontsize=SC_FONT_SIZE, ) # H2 line = Segment( (point_dict["Zc1"] + point_dict["Zc4"]) / 2, point_dict["Z7"] ) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="H2", offset_label=1j * self.W0 * 0.3, is_arrow=True, fontsize=SC_FONT_SIZE, ) # R1 line = Segment(point_dict["Zc1"], point_dict["Z4"]) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="R1", offset_label=self.W0 * 0.3, is_arrow=True, fontsize=SC_FONT_SIZE, ) # R2 line = Segment(point_dict["Zc2"], point_dict["Z5"]) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="R2", offset_label=self.W0 * 0.3, is_arrow=True, fontsize=SC_FONT_SIZE, ) # W3 line = Segment(point_dict["Z10"], point_dict["Z4"] * exp(1j * sp)) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="W3", offset_label=self.W0 * 0.4, is_arrow=True, fontsize=SC_FONT_SIZE, ) line = Segment( point_dict["Z13"] * exp(-1j * sp), point_dict["Z1"] * exp(-1j * sp) ) line.plot( fig=fig, ax=ax, color=ARROW_COLOR, linewidth=ARROW_WIDTH, label="W0", offset_label=self.W0 * 0.4, is_arrow=True, fontsize=SC_FONT_SIZE, ) if is_add_main_line: # Ox axis line = Segment(0, lam.Rext * 1.5) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # Tooth axis line = Segment(0, lam.Rext * 1.5 * exp(1j * pi / self.Zs)) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # Top arc line = Arc1( begin=Rbo * exp(-1j * pi / 2 * 0.9), end=Rbo * exp(1j * pi / 2 * 0.9), radius=Rbo, is_trigo_direction=True, ) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # Bottom Arc line = Arc1( begin=abs(point_dict["Z7"]) * exp(-1j * pi / 2 * 0.9), end=abs(point_dict["Z7"]) * exp(1j * pi / 2 * 0.9), radius=abs(point_dict["Z7"]), is_trigo_direction=True, ) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # H0 line line = Segment(point_dict["Z2"], point_dict["Z12"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment( point_dict["Z2"] * exp(1j * sp), point_dict["Z12"] * exp(1j * sp) ) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # H1 line line = Segment(point_dict["Zc1"], point_dict["Zc4"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # R1 lines line = Segment(point_dict["Zc1"], point_dict["Z3"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment(point_dict["Zc1"], point_dict["Z4"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment(point_dict["Z10"], point_dict["Zc4"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment(point_dict["Z11"], point_dict["Zc4"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # R2 lines line = Segment(point_dict["Zc2"], point_dict["Z5"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment(point_dict["Zc2"], point_dict["Z6"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment(point_dict["Z9"], point_dict["Zc3"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) line = Segment(point_dict["Z8"], point_dict["Zc3"]) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) # W3 line line = Segment(point_dict["Z9"], point_dict["Z5"] * exp(1j * sp)) line.plot( fig=fig, ax=ax, color=MAIN_LINE_COLOR, linestyle=MAIN_LINE_STYLE, linewidth=MAIN_LINE_WIDTH, ) if type_add_active in [1, 3]: # Wind and Wedge is_add_wedge = type_add_active == 3 self.plot_active( fig=fig, ax=ax, is_show_fig=False, is_add_wedge=is_add_wedge ) elif type_add_active == 2: # Magnet self.plot_active( fig=fig, ax=ax, is_show_fig=False, enforced_default_color=MAGNET_COLOR, ) # Zooming and cleaning W = (point_dict["Z7"] * exp(1j * sp)).imag * 1.2 Rint = min(point_dict["Z5"].real, point_dict["Z1"].real) Rext = max(point_dict["Z5"].real, point_dict["Z1"].real) ax.axis("equal") ax.set_xlim(Rint, Rext) ax.set_ylim(-W, W) manager = plt.get_current_fig_manager() if manager is not None: manager.set_window_title(type(self).__name__ + " Schematics") ax.set_title("") ax.get_legend().remove() ax.set_axis_off() # Save / Show if save_path is not None: fig.savefig(save_path) plt.close(fig=fig) if is_show_fig: fig.show() return fig, ax