Example #1
0
def ellipsoid(a, b, c, step=0.5, object_color=None):
    if object_color is None:
        object_color = gs.Color(0.0, 0.2, 0.5)
    else:
        pass

    u_step = step
    v_step = step

    ellipsoid = gs.GraphicalObject()
    ellipsoid.set_name("ellipsoid")

    u_top = 2 * math.pi
    u_down = 0

    v_top = math.pi
    v_down = 0

    #coordinates: x = a cos(u) sen(v) y = b sen(u) sen(v) z = c cos(v))

    first_edge = []
    v = v_down
    for u in quat.frange(u_down, u_top, u_step):
        x_value = a * math.cos(u) * math.sin(v)
        y_value = b * math.sin(u) * math.sin(v)
        first_edge.append(gs.Point(x_value, y_value, c))

    carry_ref = first_edge[0]
    for ref_point in first_edge:
        ellipsoid.push_edge(carry_ref, ref_point, object_color)

        carry_ref = ref_point

    last_edge = []
    last_edge = first_edge

    for v in quat.frange(v_down, v_top, v_step):
        carry_edge = []
        z_value = c * math.cos(v)
        for u in quat.frange(u_down, u_top, u_step):
            x_value = a * math.cos(u) * math.sin(v)
            y_value = b * math.sin(u) * math.sin(v)
            carry_edge.append(gs.Point(x_value, y_value, z_value))

        ##SE EMPIEZA A GENERAR LOS BORDES
        carry_ref = carry_edge[0]
        index = 0
        for ref_point in carry_edge:
            ##Generan Bordes Respecto a XY
            ellipsoid.push_edge(carry_ref, ref_point, object_color)

            ##Generan Bordes respecto a Z
            ellipsoid.push_edge(carry_ref, last_edge[index], object_color)

            carry_ref = ref_point
            index += 1

        last_edge = carry_edge

    return ellipsoid
Example #2
0
def parabolic_cylinder(a, dom, step=0.5, object_color=None):
    if object_color is None:
        object_color = gs.Color(0.0, 0.2, 0.5)
    else:
        pass

    u_step = step
    v_step = step

    parabolic_cylinder = gs.GraphicalObject()
    parabolic_cylinder.set_name("parabolic_cylinder")

    u_top = dom
    u_down = -dom

    v_top = dom
    v_down = -dom

    #cilindro parabolico T(u, v) = (u, a u², v)

    first_edge = []
    v = v_down
    o = v
    for u in quat.frange(u_down, u_top, u_step):
        x_value = u
        y_value = a * u**2
        first_edge.append(gs.Point(x_value, y_value, o))

    carry_ref = first_edge[0]
    for ref_point in first_edge:
        parabolic_cylinder.push_edge(carry_ref, ref_point, object_color)

        carry_ref = ref_point

    last_edge = []
    last_edge = first_edge

    for v in quat.frange(v_down, v_top, v_step):
        carry_edge = []
        z_value = v
        for u in quat.frange(u_down, u_top, u_step):
            x_value = u
            y_value = a * u**2
            carry_edge.append(gs.Point(x_value, y_value, z_value))

        ##SE EMPIEZA A GENERAR LOS BORDES
        carry_ref = carry_edge[0]
        index = 0
        for ref_point in carry_edge:
            ##Generan Bordes Respecto a XY
            parabolic_cylinder.push_edge(carry_ref, ref_point, object_color)

            ##Generan Bordes respecto a Z
            parabolic_cylinder.push_edge(carry_ref, last_edge[index],
                                         object_color)

            carry_ref = ref_point
            index += 1

        last_edge = carry_edge

    return parabolic_cylinder
Example #3
0
def hiperboloid_1h(a, b, c, dom, step=0.5, object_color=None):
    if object_color is None:
        object_color = gs.Color(0.0, 0.2, 0.5)
    else:
        pass

    u_step = step
    v_step = step

    hiperboloid_1h = gs.GraphicalObject()
    hiperboloid_1h.set_name("hiperboloid")

    u_top = 2 * math.pi
    u_down = 0

    v_top = dom
    v_down = -1 * dom

    #hiperboloide de una hojas  x = a cos(u) cosh(v)  y = b sen(u) cosh(v) z =  c senh(v)) u = 0,2pi , v = R

    first_edge = []
    v = v_down
    o = c * math.sinh(v)
    for u in quat.frange(u_down, u_top, u_step):
        x_value = a * math.cos(u) * math.cosh(v)
        y_value = b * math.sin(u) * math.cosh(v)
        first_edge.append(gs.Point(x_value, y_value, o))

    carry_ref = first_edge[0]
    for ref_point in first_edge:
        hiperboloid_1h.push_edge(carry_ref, ref_point, object_color)

        carry_ref = ref_point

    last_edge = []
    last_edge = first_edge

    for v in quat.frange(v_down, v_top, v_step):
        carry_edge = []
        z_value = c * math.sinh(v)
        for u in quat.frange(u_down, u_top, u_step):
            x_value = a * math.cos(u) * math.cosh(v)
            y_value = b * math.sin(u) * math.cosh(v)
            carry_edge.append(gs.Point(x_value, y_value, z_value))

        ##SE EMPIEZA A GENERAR LOS BORDES
        carry_ref = carry_edge[0]
        index = 0
        for ref_point in carry_edge:
            ##Generan Bordes Respecto a XY
            hiperboloid_1h.push_edge(carry_ref, ref_point, object_color)

            ##Generan Bordes respecto a Z
            hiperboloid_1h.push_edge(carry_ref, last_edge[index], object_color)

            carry_ref = ref_point
            index += 1

        last_edge = carry_edge

    return hiperboloid_1h
Example #4
0
def hyperbolic_cylinder(a, b, dom, step=0.5, object_color=None):
    if object_color is None:
        object_color = gs.Color(0.0, 0.2, 0.5)
    else:
        pass

    u_step = step
    v_step = step

    hyperbolic_cylinder = gs.GraphicalObject()
    hyperbolic_cylinder.set_name("hyperbolic_cylinder")

    u_top = 2 * math.pi
    u_down = 0

    v_top = dom
    v_down = -dom

    #cilindro hiperbolico (a sec(u), b tg(u), v)

    first_edge = []
    v = v_down
    o = v
    for u in quat.frange(u_down, u_top, u_step):
        x_value = a * (1 / math.cos(u))
        y_value = b * math.tan(u)
        first_edge.append(gs.Point(x_value, y_value, o))

    carry_ref = first_edge[0]
    for ref_point in first_edge:
        hyperbolic_cylinder.push_edge(carry_ref, ref_point, object_color)

        carry_ref = ref_point

    last_edge = []
    last_edge = first_edge

    for v in quat.frange(v_down, v_top, v_step):
        carry_edge = []
        z_value = v
        for u in quat.frange(u_down, u_top, u_step):
            x_value = a * (1 / math.cos(u))
            y_value = b * math.tan(u)
            carry_edge.append(gs.Point(x_value, y_value, z_value))

        ##SE EMPIEZA A GENERAR LOS BORDES
        carry_ref = carry_edge[0]
        index = 0
        for ref_point in carry_edge:
            ##Generan Bordes Respecto a XY
            hyperbolic_cylinder.push_edge(carry_ref, ref_point, object_color)

            ##Generan Bordes respecto a Z
            hyperbolic_cylinder.push_edge(carry_ref, last_edge[index],
                                          object_color)

            carry_ref = ref_point
            index += 1

        last_edge = carry_edge

    return hyperbolic_cylinder
Example #5
0
def hyperbolic_parabolid(a, b, c, dom, step=0.5, object_color=None):
    if object_color is None:
        object_color = gs.Color(0.0, 0.2, 0.5)
    else:
        pass

    u_step = step
    v_step = step

    hyperbolic_parabolid = gs.GraphicalObject()
    hyperbolic_parabolid.set_name("hyperbolic_parabolid")

    u_top = dom
    u_down = -1 * dom

    v_top = dom
    v_down = -1 * dom

    #paraboloide hiperbolico  x = a (u+v) y =  b (u− v) z = 4c uv), con D = R²
    #a    u, b    v, c(u² − v²)

    first_edge = []
    v = v_down
    for u in quat.frange(u_down, u_top, u_step):
        x_value = a * u
        y_value = b * v
        z_value = c * (u**2 - v**2)
        first_edge.append(gs.Point(x_value, y_value, z_value))

    carry_ref = first_edge[0]
    for ref_point in first_edge:
        hyperbolic_parabolid.push_edge(carry_ref, ref_point, object_color)

        carry_ref = ref_point

    last_edge = []
    last_edge = first_edge

    for v in quat.frange(v_down, v_top, v_step):
        carry_edge = []
        for u in quat.frange(u_down, u_top, u_step):
            x_value = a * u
            y_value = b * v
            z_value = c * (u**2 - v**2)
            carry_edge.append(gs.Point(x_value, y_value, z_value))

        ##SE EMPIEZA A GENERAR LOS BORDES
        carry_ref = carry_edge[0]
        index = 0
        for ref_point in carry_edge:
            ##Generan Bordes Respecto a XY
            hyperbolic_parabolid.push_edge(carry_ref, ref_point, object_color)

            ##Generan Bordes respecto a Z
            hyperbolic_parabolid.push_edge(carry_ref, last_edge[index],
                                           object_color)

            carry_ref = ref_point
            index += 1

        last_edge = carry_edge

    return hyperbolic_parabolid
Example #6
0
    def create_refs_vertex(self):

        down_carry_list = []
        for j in qd.frange(self.ref_vertex[1], self.ref_vertex[1] + self.length * 4, self.length):
            for k in qd.frange(self.ref_vertex[2], self.ref_vertex[2] + self.length * 4, self.length):
                for i in qd.frange(self.ref_vertex[0], self.ref_vertex[0] + self.length * 4, self.length):
                    carry = gs.Point(i, j, k)
                    self.list_of_points.append(carry)
                    self.cube.push_point(carry)
                    down_carry_list.append(carry)

        front_carry_list = []
        for k in qd.frange(self.ref_vertex[2], self.ref_vertex[2] + self.length * 4, self.length):
            for i in qd.frange(self.ref_vertex[0], self.ref_vertex[0] + self.length * 4, self.length):
                for j in qd.frange(self.ref_vertex[1], self.ref_vertex[1] + self.length * 4, self.length):
                    carry = gs.Point(i, j, k)
                    self.list_of_points.append(carry)
                    self.cube.push_point(carry)
                    front_carry_list.append(carry)

        right_carry_list = []
        for i in qd.frange(self.ref_vertex[0], self.ref_vertex[0] + self.length * 4, self.length):
            for j in qd.frange(self.ref_vertex[1], self.ref_vertex[1] + self.length * 4, self.length):
                for k in qd.frange(self.ref_vertex[2], self.ref_vertex[2] + self.length * 4, self.length):
                    carry = gs.Point(i, j, k)
                    self.list_of_points.append(carry)
                    self.cube.push_point(carry)
                    right_carry_list.append(carry)

        ###################################

        index = 0
        color_counter = 0
        color = self.blue
        suspend_flag = False
        while index < len(front_carry_list):

            if index % 16 == 0:
                if color_counter == 0:
                    color = self.blue
                elif color_counter == 3:
                    color = self.green
                else:
                    color = self.black

                color_counter += 1
                suspend_flag = False

            if (index - 11) % 16 == 0 and index != 0:
                suspend_flag = True

            if (index - 3) % 4 == 0 or suspend_flag:
                pass
            else:
                self.list_of_sub_faces.append([front_carry_list[index], front_carry_list[index + 1],
                                               front_carry_list[index + 5], front_carry_list[index + 4], color])

            index += 1

        index = 0
        color_counter = 0
        color = self.orange
        suspend_flag = False
        while index < len(right_carry_list):

            if index % 16 == 0:
                if color_counter == 0:
                    color = self.orange
                elif color_counter == 3:
                    color = self.red
                else:
                    color = self.black

                color_counter += 1
                suspend_flag = False

            if (index - 11) % 16 == 0 and index != 0:
                suspend_flag = True

            if (index - 3)%4 == 0 or suspend_flag:
                pass
            else:
                self.list_of_sub_faces.append([right_carry_list[index], right_carry_list[index + 1],
                                               right_carry_list[index + 5], right_carry_list[index + 4], color])

            index += 1

        index = 0
        color_counter = 0
        color = self.yellow
        suspend_flag = False
        while index < len(down_carry_list):

            if index % 16 == 0:
                if color_counter == 0:
                    color = self.yellow
                elif color_counter == 3:
                    color = self.white
                else:
                    color = self.black

                color_counter += 1
                suspend_flag = False

            if (index - 11) % 16 == 0 and index != 0:
                suspend_flag = True

            if (index - 3)%4 == 0 or suspend_flag:
                pass
            else:
                self.list_of_sub_faces.append([down_carry_list[index], down_carry_list[index + 1],
                                               down_carry_list[index + 5], down_carry_list[index + 4], color])

            index += 1

        ###################################

        id = 0
        for m in self.list_of_sub_faces:
            print(id, "\t", m[0].get_coord(), m[1].get_coord(), m[2].get_coord(), m[3].get_coord())
            id += 1
Example #7
0
def control(list_of_objects):

    os.system("clear")

    print("LISTA DE OBJETOS DIBUJADOS\n\n")
    index = 0
    for graph_object in list_of_objects:
        print(graph_object.get_color_name(), " \t Indice[", index, "]\n")
        index += 1

    index = input("Opcion >>>:\t")

    try:
        index = int(index)

        if index >= len(list_of_objects):
            return None
        else:
            pass
    except:
        return None

    who_object = list_of_objects[index]

    option = input("""
        [1]Rotar - Sobre si mismo
        [2]Rotar - Respecto a un Vector
        [3]Escalar
        [4]Trasladar
        """)

    try:
        option = int(option)
    except:
        return None

    if option == 1:
        option = input("""
            [1]X
            [2]Y
            [3]Z
            """)
        try:
            option = int(option)
        except:
            return None

        who_object.update_center()
        ref_center = copy.copy(who_object.get_center())

        angle = input("Angulo >>>:\t")

        try:
            angle = float(angle)
        except:
            return None

        if option == 1:
            who_object.translate()
            who_object.rotate(angle, "x", True)
            who_object.translate(ref_center)
        elif option == 2:
            who_object.translate()
            who_object.rotate(angle, "y", True)
            who_object.translate(ref_center)
        elif option == 3:
            who_object.translate()
            who_object.rotate(angle, "z", True)
            who_object.translate(ref_center)
        else:
            return None

    elif option == 2:
        option = input("""
            [1]X
            [2]Y
            [3]Z
            [4]Otro
            """)
        try:
            option = int(option)
        except:
            return None

        angle = input("Angulo >>>:\t")

        try:
            angle = float(angle)
        except:
            return None

        if option == 1:
            who_object.rotate(angle, "x", True)
        elif option == 2:
            who_object.rotate(angle, "y", True)
        elif option == 3:
            who_object.rotate(angle, "z", True)
        elif option == 4:
            vector = eval(input("Vector >>>:\t"))
            try:
                vector[0]
            except:
                return None

            who_object.rotate(angle, vector)

        else:
            return None

    elif option == 3:
        escala = eval(input("Escala >>>:\t"))
        try:
            escala = list(escala)
        except:
            return None

        who_object.scale(None, escala)
    elif option == 4:
        to_point = eval(input("Punto >>>:\t"))
        try:
            to_point == list(to_point)
        except:
            return None

        who_object.translate(gs.Point(to_point[0], to_point[1], to_point[2]))
    else:
        return None
Example #8
0
print("Angulo respecto a X - Rad: \t", p1.angle_x() , " - Angulo respecto a Z - Seg", to_seg(p1.angle_z()), "Norma:\t", p1.norm())

v1 = edge(Point(0,0,0), Point(5,5,5))

print ("Angulo respecto a X: \t", v1.angle_x(), " - Angulo respecto a Z - Seg", to_seg(v1.angle_z()), "Norma:\t", v1.norm())
"""

ref_value = 4.3

blanco = gs.Color(1.0, 1.0, 1.0)
rojo = gs.Color(1.0, 0.0, 0.0)
verde = gs.Color(0.0, 1.0, 0.0)
azul = gs.Color(0.0, 0.0, 1.0)

p1 = gs.Point(ref_value, ref_value, ref_value)
p2 = gs.Point(0.0, 0.0, 0.0)
p3 = gs.Point(0.0, ref_value, 0.0)
p4 = gs.Point(0.0, ref_value, ref_value)

tetaedro = gs.GraphicalObject()
tetaedro.set_name("tetraedro")

tetaedro.push_edge(p1, p2, rojo)
tetaedro.push_edge(p1, p3, rojo)
tetaedro.push_edge(p1, p4, rojo)
tetaedro.push_edge(p2, p3, azul)
tetaedro.push_edge(p2, p4, azul)
tetaedro.push_edge(p3, p4, azul)

tetaedro.show_points()