Exemple #1
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def main() -> None:
    wheel1 = (
        ps.Circle(ps.Point(w_1, R), R)
        .set_fill_color(ps.Style.Color.BLUE)
        .set_line_width(6)
    )
    wheel2 = wheel1.translate(ps.Point(L, 0))
    under = ps.Rectangle(ps.Point(w_1 - 2 * R, 2 * R), 2 * R + L + 2 * R, H)
    under.style.fill_color = ps.Style.Color.RED
    under.style.line_color = ps.Style.Color.RED
    over = ps.Rectangle(ps.Point(w_1, 2 * R + H), 2.5 * R, 1.25 * H).set_fill_color(
        ps.Style.Color.WHITE
    )
    over.style.line_width = 14
    over.style.line_color = ps.Style.Color.RED
    over.style.fill_pattern = ps.Style.FillPattern.UP_RIGHT_TO_LEFT

    ground = ps.Wall([ps.Point(w_1 - L, 0), ps.Point(w_1 + 3 * L, 0)], -0.3 * R)
    ground.style.fill_pattern = ps.Style.FillPattern.UP_LEFT_TO_RIGHT

    model = ps.Composition(
        {
            "wheel1": wheel1,
            "wheel2": wheel2,
            "under": under,
            "over": over,
            "ground": ground,
        }
    )

    fig = ps.Figure(
        0, w_1 + 2 * L + 3 * R, -1, 2 * R + 3 * H, backend=MatplotlibBackend
    )
    fig.add(model)
    fig.show()
Exemple #2
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def main() -> None:
    c = ps.Point(w_1, R)

    wheel1 = ps.Circle(c, R)
    wheel2 = wheel1.translate(ps.Point(L, 0))
    under = ps.Rectangle(ps.Point(w_1 - 2 * R, 2 * R), 2 * R + L + 2 * R, H)
    over = ps.Rectangle(ps.Point(w_1, 2 * R + H), 2.5 * R,
                        1.25 * H).set_fill_color(ps.Style.Color.WHITE)
    ground = ps.Wall(
        [ps.Point(w_1 - L, 0), ps.Point(w_1 + 3 * L, 0)], -0.3 * R)
    ground.style.fill_pattern = ps.Style.FillPattern.UP_RIGHT_TO_LEFT

    vehicle = ps.Composition({
        "wheel1": wheel1,
        "wheel2": wheel2,
        "under": under,
        "over": over,
        "ground": ground,
    })

    vehicle.style.line_color = ps.Style.Color.RED

    wheel1_dim = ps.LinearDimension("$w_1$", c + ps.Point(2, 0.25), c)
    hdp = w_1 + L + 3 * R  # horizontal dimension position
    R_dim = ps.LinearDimension("$R$", ps.Point(hdp, 0), ps.Point(hdp, R))
    H_dim = ps.LinearDimension("$H$", ps.Point(hdp, 2 * R),
                               ps.Point(hdp, 2 * R + H))
    H2_dim = ps.LinearDimension("$\\frac{5}{4}H$", ps.Point(hdp, 2 * R + H),
                                ps.Point(hdp, 2 * R + (9 / 4) * H))

    vdp = 2 * R + H + 3 / 2 * H
    R2_dim = ps.LinearDimension("$2R$", ps.Point(w_1 - 2 * R, vdp),
                                ps.Point(w_1, vdp))
    L_dim = ps.LinearDimension("$L$", ps.Point(w_1, vdp),
                               ps.Point(w_1 + L, vdp))
    R3_dim = ps.LinearDimension("$2R$", ps.Point(w_1 + L, vdp),
                                ps.Point(w_1 + L + 2 * R, vdp))

    dimensions = ps.Composition({
        "wheel1_dim": wheel1_dim,
        "R_dim": R_dim,
        "H_dim": H_dim,
        "H2_dim": H2_dim,
        "R2_dim": R2_dim,
        "L_dim": L_dim,
        "R3_dim": R3_dim,
    })

    model = ps.Composition({"vehicle": vehicle, "dimensions": dimensions})

    figure = ps.Figure(0,
                       w_1 + 2 * L + 3 * R,
                       -1,
                       2 * R + 3 * H,
                       backend=MatplotlibBackend)
    figure.add(model)
    figure.show()
Exemple #3
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def main() -> None:
    d = make_dashpot(0)
    s = make_spring(0)

    M = ps.Rectangle(ps.Point(0, H), 4 * H, 4 * H).set_line_width(4)
    left_wall = ps.Rectangle(ps.Point(-L, 0), H / 10, L).set_fill_pattern(
        ps.Style.FillPattern.UP_LEFT_TO_RIGHT)
    ground = ps.Wall([ps.Point(-L / 2, 0), ps.Point(L, 0)], thickness=-H / 10)
    wheel1 = ps.Circle(ps.Point(H, H / 2), H / 2)
    wheel2 = wheel1.translate(ps.Point(2 * H, 0))

    fontsize = 24
    text_m = ps.Text("$m$", ps.Point(2 * H, H + 2 * H))
    text_m.style.font_size = fontsize
    text_ku = ps.Text("$ku$", ps.Point(-L / 2, H + 4 * H))
    text_ku.style.font_size = fontsize
    text_bv = ps.Text("$bu'$", ps.Point(-L / 2, H))
    text_bv.style.font_size = fontsize
    x_axis = ps.Axis(ps.Point(2 * H, L), H, "$u(t)$")
    x_axis_start = ps.Line(ps.Point(2 * H, L - H / 4),
                           ps.Point(2 * H, L + H / 4)).set_line_width(4)

    model = ps.Composition({
        "spring": s,
        "mass": M,
        "left wall": left_wall,
        "ground": ground,
        "wheel1": wheel1,
        "wheel2": wheel2,
        "text_m": text_m,
        "text_ku": text_ku,
        "x_axis": x_axis,
        "x_axis_start": x_axis_start,
    })

    fig = ps.Figure(-L, x_max, -1, L + H, backend=MatplotlibBackend)
    fig.add(model)

    damping = ps.Composition({"dashpot": d, "text_bv": text_bv})

    # or fig = Composition(dict(fig=fig, dashpot=d, text_bv=text_bv))
    fig.add(damping)
    fig.show()
Exemple #4
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P = ps.Point(W / 6, 0.85 * H)  # rotation point
a = 2 * np.pi / 9  # angle

vertical = ps.Line(P, P - ps.Point(0, L))
path = ps.Arc(P, L, -np.pi / 2, a)
theta = ps.ArcWithText(r"$\theta$",
                       P,
                       L / 4,
                       -np.pi / 2,
                       a,
                       text_spacing=1 / 30.0)

mass_pt = path.end
rod = ps.Line(P, mass_pt)

mass = ps.Circle(mass_pt, L / 20.0)

rod_vec = rod.end - rod.start
unit_rod_vec = rod_vec.unit_vector()
mass_symbol = ps.Text("$m$", mass_pt + unit_rod_vec * (L / 10.0))

length = ps.DistanceWithText("$L$", P, mass_pt)
# Displace length indication
length = length.translate(rod_vec.normal() * (L / 15))
gravity = ps.Gravity(start=P + ps.Point(0.8 * L, 0), length=L / 3)


def set_dashed_thin_blackline(*objects: ps.Shape):
    """Set linestyle of objects to dashed, black, width=1."""
    for obj in objects:
        obj.set_line_style(ps.Style.LineStyle.DASHED)
Exemple #5
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def pendulum(theta, S, mg, drag) -> ps.Composition:
    """Draw a free body animation of a pendulum.

    params:
        theta: the angle from the vertical at which the pendulum is.
        S: the force exerted toward the pivot.
        mg: the force owing to gravity.
        drag: the force acting against the motion of the pendulum.

    return: A composition of the pendulum
    """
    a = theta
    P = ps.Point(W / 2, 0.9 * H)  # rotation point

    path = ps.Arc(P, L, -ps.Angle(np.pi / 2), a)
    mass_pt = path.end
    rod = ps.Line(P, mass_pt)

    theta = ps.AngularDimension(r"$\theta$", P + ps.Point(0, -L / 4),
                                P + (mass_pt - P).unit_vector * (L / 4), P)
    theta.extension_lines = False

    mass = ps.Circle(mass_pt, L / 30.0).set_fill_color(ps.Style.Color.BLUE)
    rod_vec = rod.end - rod.start

    length = ps.LinearDimension("$L$", mass_pt, P)
    # Displace length indication
    length = length.translate(ps.Point(-np.cos(a), -np.sin(a)) * (L / 15.0))
    length.style.line_width = 0.1
    gravity_start = ps.Point(0.8 * L, 0)
    gravity = ps.Gravity(P + gravity_start, L / 3)

    dashed_thin_black_line = ps.Style()
    dashed_thin_black_line.line_style = ps.Style.LineStyle.DASHED
    dashed_thin_black_line.line_color = ps.Style.Color.BLACK
    dashed_thin_black_line.line_width = 1.0

    path.style = dashed_thin_black_line
    vertical = ps.Line(rod.start, rod.start + ps.Point(0, -L))
    vertical.style = dashed_thin_black_line
    rod.style = dashed_thin_black_line

    comp = ps.Composition({
        "body": mass,
        "rod": rod,
        "vertical": vertical,
        "theta": theta,
        "path": path,
        "g": gravity,
        # "L": length,
    })

    magnitude = 1.2 * L / 6  # length of a unit force in figure
    force = mg  # constant (scaled eq: about 1)
    force *= magnitude
    mg_force = (ps.Force(
        "$mg$",
        mass_pt,
        mass_pt + ps.Point(0, 1) * force,
        text_position=ps.TextPosition.END,
    ) if force != 0 else None)

    force = S
    force *= magnitude
    rod_force = (ps.Force(
        "S",
        mass_pt,
        mass_pt - rod_vec.unit_vector * force,
        text_position=ps.TextPosition.END,
    ) if force != 0 else None)

    force = drag
    force *= magnitude
    air_force = (ps.Force(
        "",
        mass_pt,
        mass_pt - rod_vec.normal * force,
    ) if force != 0 else None)

    x0y0 = ps.Text("$(x_0,y_0)$", P + ps.Point(-0.4, -0.1))

    ir = ps.Force(
        r"$\mathbf{i}_r$",
        P,
        P + rod_vec.unit_vector * (L / 10),
        text_position=ps.TextPosition.END,
        # spacing=ps.Point(0.015, 0)
    )
    ith = ps.Force(
        r"$\mathbf{i}_{\theta}$",
        P,
        P + rod_vec.normal * (L / 10),
        text_position=ps.TextPosition.END,
        # spacing=ps.Point(0.02, 0.005)
    )

    body_diagram = ps.Composition({
        "mg": mg_force,
        "S": rod_force,
        "air": air_force,
        "ir": ir,
        "ith": ith,
        "origin": x0y0,
    })

    comp = comp.merge(body_diagram)
    return comp
Exemple #6
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t_max = t_mesh[-1] + 0.3 * t_axis_extent
logging.info(t_max)
u_max = 1.3 * max([u(t) for t in t_mesh])
logging.info(u_max)
u_min = -0.2 * u_max
logging.info(u_max)

r = 0.005 * (t_max - t_min)  # radius of circles placed at mesh points
# import random; random.seed(12)
perturbations = [0, 0.1, 0.1, 0.2, -0.4, -0.1]
u_points = {}
u_values = []
for i, t in enumerate(t_mesh):
    u_value = u(t) + perturbations[i]
    u_values.append(u_value)
    circle = ps.Circle(ps.Point(t, u_value),
                       r).set_fill_color(ps.Style.Color.BLACK)
    text = ps.Text(
        "$u^%d$" % i,
        ps.Point(t, u_value) +
        (ps.Point(0.0, 3 * r) if i > 0 else ps.Point(-3 * r, 0.0)),
    )
    u_points[i] = ps.Composition({"circle": circle, "u_point": text})
u_discrete = ps.Composition(u_points)

i_lines = {}
for i in range(1, len(t_mesh)):
    i_lines[i] = ps.Line(ps.Point(t_mesh[i - 1], u_values[i - 1]),
                         ps.Point(t_mesh[i], u_values[i])).set_line_width(1)
interpolant = ps.Composition(i_lines)

x_axis_extent: float = t_mesh[-1] + 0.2 * t_axis_extent
Exemple #7
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def main() -> None:
    u = ps.SketchyFunc3()
    Nt = 5
    t_mesh = np.linspace(0, 6, Nt + 1)

    # Add 20% space to the left and 30% to the right of the coordinate system
    t_axis_extent = t_mesh[-1] - t_mesh[0]
    logging.info(t_axis_extent)
    t_min = t_mesh[0] - 0.2 * t_axis_extent
    logging.info(t_min)
    t_max = t_mesh[-1] + 0.3 * t_axis_extent
    logging.info(t_max)
    u_max = 1.3 * max([u(t) for t in t_mesh])
    logging.info(u_max)
    u_min = -0.2 * u_max
    logging.info(u_max)

    r = 0.005 * (t_max - t_min)  # radius of circles placed at mesh points
    # import random; random.seed(12)
    perturbations = [0, 0.1, 0.1, 0.2, -0.4, -0.1]
    u_points = {}
    u_values = []
    for i, t in enumerate(t_mesh):
        u_value = u(t) + perturbations[i]
        u_values.append(u_value)
        circle = ps.Circle(ps.Point(t, u_value),
                           r).set_fill_color(ps.Style.Color.BLACK)
        text = ps.Text(
            "$u^%d$" % i,
            ps.Point(t, u_value) +
            (ps.Point(0.0, 3 * r) if i > 0 else ps.Point(-3 * r, 0.0)),
        )
        u_points[i] = ps.Composition({"circle": circle, "u_point": text})
    u_discrete = ps.Composition(u_points)

    i_lines = {}
    for i in range(1, len(t_mesh)):
        i_lines[i] = ps.Line(ps.Point(t_mesh[i - 1], u_values[i - 1]),
                             ps.Point(t_mesh[i],
                                      u_values[i])).set_line_width(1)
    interpolant = ps.Composition(i_lines)

    x_axis_extent: float = t_mesh[-1] + 0.2 * t_axis_extent
    logging.info(x_axis_extent)
    axes = ps.Composition({
        "x":
        ps.Axis(
            ps.Point(0.0, 0.0),
            x_axis_extent,
            "$t$",
        ),
        "y":
        ps.Axis(ps.Point(0.0, 0.0),
                0.8 * u_max,
                "$u$",
                rotation_angle=np.pi / 2),
    })

    h = 0.03 * u_max  # tickmarks height
    i_nodes = {}
    for i, t in enumerate(t_mesh):
        i_nodes[i] = ps.Composition({
            "node":
            ps.Line(ps.Point(t, h), ps.Point(t, -h)),
            "name":
            ps.Text("$t_%d$" % i, ps.Point(t, -3.5 * h)),
        })

    nodes = ps.Composition(i_nodes)

    fig = ps.Figure(t_min, t_max, u_min, u_max, backend=MatplotlibBackend)

    # Draw t_mesh with discrete u points
    illustration = ps.Composition(dict(
        u=u_discrete,
        mesh=nodes,
        axes=axes,
    ))
    fig.erase()
    fig.add(illustration)
    fig.show()

    # Add exact u line (u is a Spline Shape that applies 500 intervals by default
    # for drawing the curve)
    exact = u.set_line_style(ps.Style.LineStyle.DASHED).set_line_width(1)

    fig.add(exact)
    fig.show()

    # Add linear interpolant
    fig.add(interpolant)
    fig.show()

    # Linear interpolant without exact, smooth line
    fig.erase()
    fig.add(illustration)
    fig.add(interpolant)
    fig.show()
Exemple #8
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import pysketcher as ps
from pysketcher.backend.matplotlib import MatplotlibBackend

R = 1  # radius of wheel
L = 4  # distance between wheels
H = 2  # height of vehicle body
w_1 = 5  # position of front wheel

# TODO : draw grids
# drawing_tool.set_grid(True)

c = ps.Point(w_1, R)

wheel1 = ps.Circle(c, R)
wheel2 = wheel1.translate(ps.Point(L, 0))
under = ps.Rectangle(ps.Point(w_1 - 2 * R, 2 * R), 2 * R + L + 2 * R, H)
over = ps.Rectangle(ps.Point(w_1, 2 * R + H), 2.5 * R,
                    1.25 * H).set_fill_color(ps.Style.Color.WHITE)
ground = ps.Wall([ps.Point(w_1 - L, 0), ps.Point(w_1 + 3 * L, 0)], -0.3 * R)
ground.style.fill_pattern = ps.Style.FillPattern.UP_RIGHT_TO_LEFT

vehicle = ps.Composition({
    "wheel1": wheel1,
    "wheel2": wheel2,
    "under": under,
    "over": over,
    "ground": ground
})

vehicle.style.line_color = ps.Style.Color.RED
Exemple #9
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def main():
    u = ps.SketchyFunc3()
    t_mesh = np.linspace(0, 6, Nt + 1)
    t_mesh_staggered = np.linspace(0.5 * (t_mesh[0] + t_mesh[1]),
                                   0.5 * (t_mesh[-2] + t_mesh[-1]), Nt)

    # Add 20% space to the left and 30% to the right of the coordinate system
    t_axis_extent = t_mesh[-1] - t_mesh[0]
    t_min = t_mesh[0] - 0.2 * t_axis_extent
    t_max = t_mesh[-1] + 0.3 * t_axis_extent
    u_max = 1.3 * max([u(t) for t in t_mesh])
    u_min = -0.2 * u_max

    r = 0.005 * (t_max - t_min)  # radius of circles placed at mesh Points
    u_discrete = ps.Composition({
        i: ps.Composition(
            dict(
                circle=ps.Circle(ps.Point(t, u(t)),
                                 r).set_fill_color(ps.Style.Color.BLACK),
                u_Point=ps.Text(
                    "$u_%d$" % i,
                    ps.Point(t, u(t)) +
                    (ps.Point(0, 5 * r) if i > 0 else ps.Point(-5 * r, 0)),
                ),
            ))
        for i, t in enumerate(t_mesh)
    })

    # u' = v
    # v = u.smooth.derivative(n=1)
    v = ps.SketchyFunc4()

    v_discrete = ps.Composition({
        i: ps.Composition(
            dict(
                circle=ps.Circle(ps.Point(t, v(t)),
                                 r).set_fill_color(ps.Style.Color.RED),
                v_Point=ps.Text(
                    r"$v_{%d/2}$" % (2 * i + 1),
                    ps.Point(t, v(t)) + (ps.Point(0, 5 * r)),
                ),
            ))
        for i, t in enumerate(t_mesh_staggered)
    })

    axes = ps.Composition(
        dict(
            x=ps.Axis(ps.Point(0, 0), t_mesh[-1] + 0.2 * t_axis_extent, "$t$"),
            y=ps.Axis(ps.Point(0, 0),
                      0.8 * u_max,
                      "$u,v$",
                      rotation_angle=np.pi / 2),
        ))

    h = 0.03 * u_max  # tickmarks height
    u_nodes = ps.Composition({
        i: ps.Composition(
            dict(
                node=ps.Line(ps.Point(t, h), ps.Point(t, -h)),
                name=ps.Text("$t_%d$" % i, ps.Point(t, -3.5 * h)),
            ))
        for i, t in enumerate(t_mesh)
    })
    v_nodes = ps.Composition({
        i: ps.Composition(
            dict(
                node=ps.Line(ps.Point(t, h / 1.5), ps.Point(
                    t, -h / 1.5)).set_line_color(ps.Style.Color.RED),
                name=ps.Text(r"$t_{%d/2}$" % (2 * i + 1),
                             ps.Point(t, -3.5 * h)),
            ))
        for i, t in enumerate(t_mesh_staggered)
    })
    illustration = ps.Composition(
        dict(u=u_discrete,
             v=v_discrete,
             u_mesh=u_nodes,
             v_mesh=v_nodes,
             axes=axes))

    fig = ps.Figure(t_min, t_max, u_min, u_max, backend=MatplotlibBackend)

    # Staggered t mesh and u and v Points
    fig.add(illustration)
    fig.show()

    # Exact u line (u is a Spline Shape that applies 500 intervals by default
    # for drawing the curve)
    u_exact = u.set_line_style(ps.Style.LineStyle.DASHED).set_line_width(1)
    fig.add(u_exact)
    fig.show()

    # v = Curve(u.xcoor, v(u.xcoor))
    t_mesh_staggered_fine = np.linspace(t_mesh_staggered[0],
                                        t_mesh_staggered[-1], 501)
    t_mesh_staggered_points = [
        ps.Point(x, v(x)) for x in t_mesh_staggered_fine
    ]
    v_exact = (ps.Curve(t_mesh_staggered_points).set_line_style(
        ps.Style.LineStyle.DASHED).set_line_width(1))
    fig.add(v_exact)
    fig.show()
def make_spring(x):
    s_start = ps.Point(-L, 4 * H)
    s = ps.Spring(start=s_start, length=L + x, bar_length=3 * H / 2)
    s = s.rotate(-np.pi / 2, s_start)
    return s


d = make_dashpot(0)
s = make_spring(0)

M = ps.Rectangle(ps.Point(0, H), 4 * H, 4 * H).set_line_width(4)
left_wall = ps.Rectangle(ps.Point(-L, 0), H / 10, L).set_fill_pattern(
    ps.Style.FillPattern.UP_LEFT_TO_RIGHT
)
ground = ps.Wall([ps.Point(-L / 2, 0), ps.Point(L, 0)], thickness=-H / 10)
wheel1 = ps.Circle(ps.Point(H, H / 2), H / 2)
wheel2 = wheel1.translate(ps.Point(2 * H, 0))

fontsize = 24
text_m = ps.Text("$m$", ps.Point(2 * H, H + 2 * H))
text_m.style.font_size = fontsize
text_ku = ps.Text("$ku$", ps.Point(-L / 2, H + 4 * H))
text_ku.style.font_size = fontsize
text_bv = ps.Text("$bu'$", ps.Point(-L / 2, H))
text_bv.style.font_size = fontsize
x_axis = ps.Axis(ps.Point(2 * H, L), H, "$u(t)$", label_spacing=(0.04, -0.01))
x_axis_start = ps.Line(
    ps.Point(2 * H, L - H / 4), ps.Point(2 * H, L + H / 4)
).set_line_width(4)

model = ps.Composition(
t_mesh = np.linspace(0, 6, Nt + 1)
t_mesh_staggered = np.linspace(0.5 * (t_mesh[0] + t_mesh[1]),
                               0.5 * (t_mesh[-2] + t_mesh[-1]), Nt)

# Add 20% space to the left and 30% to the right of the coordinate system
t_axis_extent = t_mesh[-1] - t_mesh[0]
t_min = t_mesh[0] - 0.2 * t_axis_extent
t_max = t_mesh[-1] + 0.3 * t_axis_extent
u_max = 1.3 * max([u(t) for t in t_mesh])
u_min = -0.2 * u_max

r = 0.005 * (t_max - t_min)  # radius of circles placed at mesh Points
u_discrete = ps.Composition({
    i: ps.Composition(
        dict(
            circle=ps.Circle(ps.Point(t, u(t)),
                             r).set_fill_color(ps.Style.Color.BLACK),
            u_Point=ps.Text(
                "$u_%d$" % i,
                ps.Point(t, u(t)) +
                (ps.Point(0, 5 * r) if i > 0 else ps.Point(-5 * r, 0)),
            ),
        ))
    for i, t in enumerate(t_mesh)
})

# u' = v
# v = u.smooth.derivative(n=1)
v = ps.SketchyFunc4()

v_discrete = ps.Composition({
    i: ps.Composition(
Exemple #12
0
"""Illustrate forward, backward and centered finite differences in four figures."""

import pysketcher as ps
from pysketcher.backend.matplotlib import MatplotlibBackend

xaxis = 2

f = ps.SketchyFunc1("$u(t)$")
x = 3  # center point where we want the derivative
xb = 2  # x point used for backward difference
xf = 4  # x point used for forward difference
p = ps.Point(x, f(x))  # center point
pf = ps.Point(xf, f(xf))  # forward point
pb = ps.Point(xb, f(xb))  # backward point
r = 0.1  # radius of circles placed at key points
c = ps.Circle(p, r).set_line_color(ps.Style.Color.BLUE)
cf = ps.Circle(pf, r).set_line_color(ps.Style.Color.RED)
cb = ps.Circle(pb, r).set_line_color(ps.Style.Color.GREEN)

# Points in the mesh
p0 = ps.Point(x, xaxis)  # center point
pf0 = ps.Point(xf, xaxis)  # forward point
pb0 = ps.Point(xb, xaxis)  # backward point
tick = 0.05

axis = ps.Composition(
    {
        "hline": ps.Line(pf0 - ps.Point(3, 0), pb0 + ps.Point(3, 0))
        .set_line_color(ps.Style.Color.BLACK)
        .set_line_width(1),
        "tick_m1": ps.Line(pf0 + ps.Point(0, tick), pf0 - ps.Point(0, tick))
Exemple #13
0
import pysketcher as ps
from pysketcher.backend.matplotlib import MatplotlibBackend

R = 1  # radius of wheel
L = 4  # distance between wheels
H = 2  # height of vehicle body
w_1 = 5  # position of front wheel

wheel1 = (ps.Circle(ps.Point(w_1, R),
                    R).set_fill_color(ps.Style.Color.BLUE).set_line_width(6))
wheel2 = wheel1.translate(ps.Point(L, 0))
under = ps.Rectangle(ps.Point(w_1 - 2 * R, 2 * R), 2 * R + L + 2 * R, H)
under.style.fill_color = ps.Style.Color.RED
under.style.line_color = ps.Style.Color.RED
over = ps.Rectangle(ps.Point(w_1, 2 * R + H), 2.5 * R,
                    1.25 * H).set_fill_color(ps.Style.Color.WHITE)
over.style.line_width = 14
over.style.line_color = ps.Style.Color.RED
over.style.fill_pattern = ps.Style.FillPattern.UP_RIGHT_TO_LEFT

ground = ps.Wall([ps.Point(w_1 - L, 0), ps.Point(w_1 + 3 * L, 0)], -0.3 * R)
ground.style.fill_pattern = ps.Style.FillPattern.UP_LEFT_TO_RIGHT

model = ps.Composition({
    "wheel1": wheel1,
    "wheel2": wheel2,
    "under": under,
    "over": over,
    "ground": ground
})