first commit

2025-09-22 14:19:00 +08:00
commit 2ada26f176
16 changed files with 968 additions and 0 deletions
--- a/.idea/.gitignore
+++ b/.idea/.gitignore
@ -0,0 +1,5 @@
 # 默认忽略的文件
 /shelf/
 /workspace.xml
 # 基于编辑器的 HTTP 客户端请求
 /httpRequests/
--- a/.idea/3dof.iml
+++ b/.idea/3dof.iml
@ -0,0 +1,8 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <module type="PYTHON_MODULE" version="4">
  <component name="NewModuleRootManager">
    <content url="file://$MODULE_DIR$" />
    <orderEntry type="jdk" jdkName="drake" jdkType="Python SDK" />
    <orderEntry type="sourceFolder" forTests="false" />
  </component>
 </module>
--- a/.idea/inspectionProfiles/profiles_settings.xml
+++ b/.idea/inspectionProfiles/profiles_settings.xml
@ -0,0 +1,6 @@
 <component name="InspectionProjectProfileManager">
  <settings>
    <option name="USE_PROJECT_PROFILE" value="false" />
    <version value="1.0" />
  </settings>
 </component>
--- a/.idea/misc.xml
+++ b/.idea/misc.xml
@ -0,0 +1,7 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="Black">
    <option name="sdkName" value="Python 3.10" />
  </component>
  <component name="ProjectRootManager" version="2" project-jdk-name="drake" project-jdk-type="Python SDK" />
 </project>
--- a/.idea/modules.xml
+++ b/.idea/modules.xml
@ -0,0 +1,8 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="ProjectModuleManager">
    <modules>
      <module fileurl="file://$PROJECT_DIR$/.idea/3dof.iml" filepath="$PROJECT_DIR$/.idea/3dof.iml" />
    </modules>
  </component>
 </project>
--- a/2D/caculate/pycache/fkik.cpython-36.pyc
+++ b/2D/caculate/pycache/fkik.cpython-36.pyc
--- a/2D/caculate/fkik.py
+++ b/2D/caculate/fkik.py
@ -0,0 +1,145 @@
 import math
 import matplotlib.pyplot as plt
 # 设置中文字体（防警告）
 plt.rcParams['font.sans-serif'] = ['SimHei', 'Arial Unicode MS', 'DejaVu Sans']
 plt.rcParams['axes.unicode_minus'] = False
 class TwoLinkArm:
    def __init__(self, l1=1.0, l2=1.0):
        self.l1 = l1
        self.l2 = l2
        self.theta1 = 0.0  # 弧度
        self.theta2 = 0.0  # 弧度
        self.end_x = l1 + l2  # 初始末端位置
        self.end_y = 0.0
        self.joint1 = (l1, 0.0)
        self.joint2 = (l1 + l2, 0.0)
        self.fig, self.ax = plt.subplots(figsize=(8, 8))
        plt.subplots_adjust(bottom=0.2)
        self.ax.set_xlim(-l1 - l2 - 0.5, l1 + l2 + 0.5)
        self.ax.set_ylim(-l1 - l2 - 0.5, l1 + l2 + 0.5)
        self.ax.set_aspect('equal')
        self.ax.grid(True)
        self.ax.set_title("拖动末端执行器（粉色点）来移动机械臂")
        self.ax.set_xlabel("X")
        self.ax.set_ylabel("Y")
        # 绘制机械臂
        self.line_link1, = self.ax.plot([], [], 'b-', linewidth=4, label=f'连杆1 (L1={l1})')
        self.line_link2, = self.ax.plot([], [], 'r-', linewidth=4, label=f'连杆2 (L2={l2})')
        self.joint_point, = self.ax.plot([], [], 'go', markersize=8, label='关节2')
        self.end_point, = self.ax.plot([], [], 'mo', markersize=8, label='末端执行器')
        self.base_point, = self.ax.plot(0, 0, 'ko', markersize=10, label='基座')
        self.angle_text = self.ax.text(
            -l1 - l2 + 0.2,
            l1 + l2 - 0.3,
            '',
            fontsize=10,
            bbox=dict(boxstyle="round", facecolor="wheat")
        )
        self.ax.legend()
        # 拖动相关变量
        self.dragging = False
        self.press_xdata = None
        self.press_ydata = None
        # 连接事件
        self.cid_press = self.fig.canvas.mpl_connect('button_press_event', self.on_press)
        self.cid_release = self.fig.canvas.mpl_connect('button_release_event', self.on_release)
        self.cid_motion = self.fig.canvas.mpl_connect('motion_notify_event', self.on_motion)
        # 初始绘制
        self.update_plot()
    def fk(self, theta1, theta2):
        """正向运动学"""
        x1 = self.l1 * math.cos(theta1)
        y1 = self.l1 * math.sin(theta1)
        x2 = x1 + self.l2 * math.cos(theta1 + theta2)
        y2 = y1 + self.l2 * math.sin(theta1 + theta2)
        return (x1, y1), (x2, y2)
    def ik(self, x, y, elbow_up=True):
        """逆向运动学"""
        d_sq = x*x + y*y
        cos_theta2_numerator = d_sq - self.l1**2 - self.l2**2
        denominator = 2 * self.l1 * self.l2
        if abs(cos_theta2_numerator) > abs(denominator):
            return None  # 不可达
        cos_theta2 = max(-1, min(1, cos_theta2_numerator / denominator))
        theta2 = math.acos(cos_theta2) if elbow_up else -math.acos(cos_theta2)
        k1 = self.l1 + self.l2 * math.cos(theta2)
        k2 = self.l2 * math.sin(theta2)
        theta1 = math.atan2(y, x) - math.atan2(k2, k1)
        return theta1, theta2
    def update_plot(self):
        """根据当前末端位置计算 IK 并更新图像"""
        solution = self.ik(self.end_x, self.end_y, elbow_up=True)  # 默认肘上解
        if solution is not None:
            self.theta1, self.theta2 = solution
            (x1, y1), (x2, y2) = self.fk(self.theta1, self.theta2)
            self.joint1 = (x1, y1)
            self.joint2 = (x2, y2)
        else:
            # 如果不可达，保持上一个有效姿态，但末端显示为红色
            x2, y2 = self.end_x, self.end_y
            self.end_point.set_color('red')
        # 更新线条和点
        self.line_link1.set_data([0, self.joint1[0]], [0, self.joint1[1]])
        self.line_link2.set_data([self.joint1[0], self.joint2[0]], [self.joint1[1], self.joint2[1]])
        self.joint_point.set_data(self.joint1[0], self.joint1[1])
        self.end_point.set_data(self.joint2[0], self.joint2[1])
        self.end_point.set_color('m')  # 恢复正常颜色
        # 显示角度（现在是弧度）
        angle_str = f"θ1 = {self.theta1:+.3f} rad\nθ2= {self.theta2:+.3f} rad"
        self.angle_text.set_text(angle_str)
        self.fig.canvas.draw_idle()
    def on_press(self, event):
        if event.inaxes != self.ax:
            return
        if self.end_point.contains(event)[0]:  # 点中末端点
            self.dragging = True
            self.press_xdata = event.xdata
            self.press_ydata = event.ydata
        else:
            self.dragging = False
    def on_release(self, event):
        self.dragging = False
    def on_motion(self, event):
        if not self.dragging or event.inaxes != self.ax:
            return
        # 更新末端位置
        dx = event.xdata - self.press_xdata
        dy = event.ydata - self.press_ydata
        self.end_x += dx
        self.end_y += dy
        self.press_xdata = event.xdata
        self.press_ydata = event.ydata
        self.update_plot()
    def show(self):
        plt.show()
 # ========================
 # 主程序
 # ========================
 if __name__ == "__main__":
    print("拖动末端执行器（粉色点）来交互式控制两连杆机械臂！")
    arm = TwoLinkArm(l1=1.0, l2=1.0)
    arm.show()
--- a/2D/caculate/test.py
+++ b/2D/caculate/test.py
--- a/2D/caculate/trajectory.py
+++ b/2D/caculate/trajectory.py
@ -0,0 +1,99 @@
 # trajectory.py
 import numpy as np
 def circle_trajectory(center=(80, 0), radius=40, num_points=200):
    """ 圆形轨迹 """
    angles = np.linspace(0, 2 * np.pi, num_points)
    x_list = center[0] + radius * np.cos(angles)
    y_list = center[1] + radius * np.sin(angles)
    return x_list, y_list
 def line_trajectory(start=(40, 0), end=(120, 0), num_points=100):
    """ 直线轨迹 """
    t = np.linspace(0, 1, num_points)
    x_list = start[0] + t * (end[0] - start[0])
    y_list = start[1] + t * (end[1] - start[1])
    return x_list, y_list
 def line_trajectory_fix(start=(40, 0), end=(120, 100), vx=0.1, vy=0.1, num_points=20):
    """
    生成带速度分量的匀速斜线轨迹
    参数：
        start: 起始点 (x, y)
        end: 终点 (x, y) —— 仅用于估算运行时间（可选）
        vx: x方向速度（单位/秒）
        vy: y方向速度（单位/秒）
        num_points: 生成的轨迹点数
    返回：
        x_list, y_list: 轨迹坐标数组
    """
    # 速度大小
    speed = np.sqrt(vx**2 + vy**2)
    if speed == 0:
        raise ValueError("速度不能为零")
    # 估算从 start 到 end 的距离（用于估算总时间）
    if end is not None:
        dx = end[0] - start[0]
        dy = end[1] - start[1]
        distance = np.sqrt(dx**2 + dy**2)
        total_time = distance / speed  # 理论到达时间
        print(total_time)
    else:
        total_time = 10.0  # 默认运行10秒
    # 时间序列：从 0 到 total_time，均匀分布 num_points 个点
    t = np.linspace(0, total_time, num_points)
    # 位置 = 起点 + 速度 × 时间
    x_list = start[0] + vx * t
    y_list = start[1] + vy * t
    return x_list, y_list
 def ellipse_trajectory(center=(80, 0), rx=50, ry=25, num_points=200):
    """ 椭圆轨迹 """
    angles = np.linspace(0, 2 * np.pi, num_points)
    x_list = center[0] + rx * np.cos(angles)
    y_list = center[1] + ry * np.sin(angles)
    return x_list, y_list
 def square_trajectory(side=60, num_points=60):
    """ 正方形轨迹 """
    x_list, y_list = [], []
    for i in range(num_points):
        t = i / num_points
        if t < 0.25:
            x = 80 + 60 * t * 4
            y = 0
        elif t < 0.5:
            x = 140
            y = 0 + 60 * (t - 0.25) * 4
        elif t < 0.75:
            x = 140 - 60 * (t - 0.5) * 4
            y = 60
        else:
            x = 80
            y = 60 - 60 * (t - 0.75) * 4
        x_list.append(x)
        y_list.append(y)
    return x_list, y_list
 def triangle_trajectory(base_length=100, height=80, num_points=60):
    """ 三角形轨迹 """
    x_list, y_list = [], []
    points = [(80, 0), (130, 80), (30, 80), (80, 0)]
    for i in range(num_points):
        idx = int(i / num_points * 3)
        t = (i % (num_points // 3)) / (num_points // 3)
        x = points[idx][0] + t * (points[idx+1][0] - points[idx][0])
        y = points[idx][1] + t * (points[idx+1][1] - points[idx][1])
        x_list.append(x)
        y_list.append(y)
    return x_list, y_list
 def custom_trajectory(custom_x, custom_y):
    """ 自定义轨迹，输入两个列表即可 """
    return custom_x, custom_y
--- a/2D/main.py
+++ b/2D/main.py
@ -0,0 +1,106 @@
 import numpy as np
 import matplotlib.pyplot as plt
 from matplotlib.animation import FuncAnimation
 # -------------------------
 # 参数
 # -------------------------
 L1 = 100.0   # 连杆1长度
 L2 = 100.0   # 连杆2长度
 KP, KD = 60.0, 1.0
 DEBUG_MODE = True  # 没有电机时开启 DEBUG
 # -------------------------
 # 逆运动学
 # -------------------------
 def inverse_2link(x, y, L1, L2):
    D = (x**2 + y**2 - L1**2 - L2**2) / (2 * L1 * L2)
    if abs(D) > 1:
        raise ValueError("目标点超出二连杆工作空间")
    theta2 = np.arctan2(np.sqrt(1 - D**2), D)
    theta1 = np.arctan2(y, x) - np.arctan2(L2*np.sin(theta2), L1 + L2*np.cos(theta2))
    return theta1, theta2
 # -------------------------
 # 正运动学
 # -------------------------
 def forward_2link(theta1, theta2, L1, L2):
    x = L1*np.cos(theta1) + L2*np.cos(theta1 + theta2)
    y = L1*np.sin(theta1) + L2*np.sin(theta1 + theta2)
    return x, y
 # -------------------------
 # 控制两个电机
 # -------------------------
 def control_two_motors_mit(theta1_rad, theta2_rad):
    if not DEBUG_MODE:
        # motor_control.controlMIT(motor1, KP, KD, theta1_rad, 0.1, 0.0)
        # motor_control.controlMIT(motor2, KP, KD, theta2_rad, 0.1, 0.0)
        pass
    else:
        print(f"[DEBUG] 控制 -> θ1={theta1_rad:.2f}rad, θ2={theta2_rad:.2f}rad")
 # -------------------------
 # 轨迹生成
 # -------------------------
 def circle_trajectory(r=60, steps=100):
    angles = np.linspace(0, 2*np.pi, steps)
    x = r * np.cos(angles) + 100
    y = r * np.sin(angles) + 50
    return x, y
 def line_trajectory(x0, y0, x1, y1, steps=100):
    x = np.linspace(x0, x1, steps)
    y = np.linspace(y0, y1, steps)
    return x, y
 # -------------------------
 # 执行轨迹
 # -------------------------
 def execute_trajectory(x_list, y_list):
    for x, y in zip(x_list, y_list):
        try:
            theta1, theta2 = inverse_2link(x, y, L1, L2)
            control_two_motors_mit(theta1, theta2)
            x_fk, y_fk = forward_2link(theta1, theta2, L1, L2)
            print(f"目标 ({x:.1f},{y:.1f}) -> FK验证 ({x_fk:.1f},{y_fk:.1f})")
        except ValueError as e:
            print(f" {e}")
 # -------------------------
 # 动画演示
 # -------------------------
 def run_animation(x_list, y_list):
    fig, ax = plt.subplots()
    ax.set_xlim(-L1-L2, L1+L2)
    ax.set_ylim(-L1-L2, L1+L2)
    line, = ax.plot([], [], 'o-', lw=2)
    def draw_frame(i):
        x, y = x_list[i], y_list[i]
        try:
            theta1, theta2 = inverse_2link(x, y, L1, L2)
            x1 = L1 * np.cos(theta1)
            y1 = L1 * np.sin(theta1)
            line.set_data([0, x1, x], [0, y1, y])
        except:
            line.set_data([], [])
        return line,
    ani = FuncAnimation(fig, draw_frame, frames=len(x_list), interval=100, blit=True)
    plt.show()
 # -------------------------
 # 主程序
 # -------------------------
 if __name__ == "__main__":
    # 选择轨迹
    x_list, y_list = circle_trajectory(r=60, steps=100)
    # x_list, y_list = line_trajectory(50, 50, 150, 100, steps=100)
    # 执行轨迹
    execute_trajectory(x_list, y_list)
    # 动画演示
    run_animation(x_list, y_list)
--- a/2D/main_diaoyong.py
+++ b/2D/main_diaoyong.py
@ -0,0 +1,132 @@
 # main1.py
 import numpy as np
 import matplotlib.pyplot as plt
 from matplotlib.animation import FuncAnimation
 from caculate.fkik import TwoLinkArm
 # -------------------------
 # 参数设置
 # -------------------------
 L1 = 100.0  # 连杆1长度
 L2 = 100.0  # 连杆2长度
 KP, KD = 60.0, 1.0
 DEBUG_MODE = True  # 调试模式
 # ✅ 创建机械臂实例（关键！）
 arm = TwoLinkArm(l1=L1, l2=L2)
 # -------------------------
 # 控制两个电机（调试用）
 # -------------------------
 def control_two_motors_mit(theta1_rad, theta2_rad):
    if not DEBUG_MODE:
        # 这里可以接入真实电机控制
        # motor_control.controlMIT(motor1, KP, KD, theta1_rad, 0.1, 0.0)
        # motor_control.controlMIT(motor2, KP, KD, theta2_rad, 0.1, 0.0)
        pass
    else:
        print(f"[DEBUG] 控制 -> θ1={theta1_rad:+.2f}rad, θ2={theta2_rad:+.2f}rad")
 # -------------------------
 # 轨迹生成
 # -------------------------
 def circle_trajectory(r=60, steps=100):
    """生成圆形轨迹"""
    angles = np.linspace(0, 2 * np.pi, steps)
    x = r * np.cos(angles) + 100
    y = r * np.sin(angles) + 50
    return x, y
 def line_trajectory(x0, y0, x1, y1, steps=100):
    """生成直线轨迹"""
    x = np.linspace(x0, x1, steps)
    y = np.linspace(y0, y1, steps)
    return x, y
 # -------------------------
 # 执行轨迹
 # -------------------------
 def execute_trajectory(x_list, y_list):
    print("开始执行轨迹...")
    for i, (x, y) in enumerate(zip(x_list, y_list)):
        try:
            theta1, theta2 = arm.ik(x, y)  # ✅ 使用实例调用 ik
            control_two_motors_mit(theta1, theta2)
            _, (x_fk, y_fk) = arm.fk(theta1, theta2)  # 注意：用 _ 忽略第一个返回值 (x1,y1)
            print(f"点 {i:3d}: 目标({x:6.1f},{y:6.1f}) -> FK验证({x_fk:6.1f},{y_fk:6.1f})") # ✅ 使用实例调用 fk
        except ValueError as e:
            print(f"点 {i:3d}: 跳过不可达点 ({x:.1f}, {y:.1f}) -> {e}")
    print("轨迹执行完成。\n")
 # -------------------------
 # 动画演示
 # -------------------------
 def run_animation(x_list, y_list):
    print("启动动画...")
    fig, ax = plt.subplots(figsize=(8, 8))
    ax.set_xlim(-200, 200)
    ax.set_ylim(-200, 200)
    ax.set_aspect('equal')
    ax.grid(True, linestyle='--', alpha=0.6)
    ax.set_title("2R 机械臂轨迹跟踪动画")
    ax.set_xlabel("X (mm)")
    ax.set_ylabel("Y (mm)")
    # 绘图元素
    line_arm, = ax.plot([], [], 'o-', lw=2, color='blue', label='机械臂')
    target_point, = ax.plot([], [], 'r*', markersize=10, label='目标点')
    ax.legend()
    def draw_frame(i):
        x_target, y_target = x_list[i], y_list[i]
        try:
            # ✅ 使用实例 arm 调用 ik
            theta1, theta2 = arm.ik(x_target, y_target)
            x1 = L1 * np.cos(theta1)
            y1 = L1 * np.sin(theta1)
            (x1, y1), (x_fk, y_fk) = arm.fk(theta1, theta2)  # 实际末端位置
            # 更新机械臂：基座 -> 关节1 -> 末端
            line_arm.set_data([0, x1, x_fk], [0, y1, y_fk])
        except Exception as e:
            # IK失败，只显示目标
            line_arm.set_data([], [])
        # 始终显示目标点
        target_point.set_data([x_target], [y_target])
        return line_arm, target_point
    # 创建动画
    ani = FuncAnimation(
        fig, draw_frame,
        frames=len(x_list),
        interval=100,
        blit=True,
        repeat=True
    )
    plt.show()
    return ani  # 防止动画被回收
 # -------------------------
 # 主程序
 # -------------------------
 if __name__ == "__main__":
    # 选择轨迹
    x_list, y_list = circle_trajectory(r=40, steps=100)
    # x_list, y_list = line_trajectory(50, 50, 150, 100, steps=100)
    # 执行轨迹控制
    execute_trajectory(x_list, y_list)
    # 播放动画
    run_animation(x_list, y_list)
--- a/3D/caculate/pycache/fkik.cpython-36.pyc
+++ b/3D/caculate/pycache/fkik.cpython-36.pyc
--- a/3D/caculate/fkik.py
+++ b/3D/caculate/fkik.py
@ -0,0 +1,152 @@
 import math
 import numpy as np
 import matplotlib.pyplot as plt
 from mpl_toolkits.mplot3d import Axes3D
 from matplotlib.widgets import Slider
 # 设置中文字体
 plt.rcParams['font.sans-serif'] = ['SimHei', 'Arial Unicode MS', 'DejaVu Sans']
 plt.rcParams['axes.unicode_minus'] = False
 class SpatialTwoLinkArm:
    def __init__(self, l1=1.0, l2=1.0):
        self.l1 = l1
        self.l2 = l2
        self.theta1 = 0.0  # 绕Z轴旋转（偏航，Yaw）
        self.theta2 = 0.0  # 绕Y轴旋转（俯仰，Pitch）
        # 创建3D图形
        self.fig = plt.figure(figsize=(10, 8))
        self.ax = self.fig.add_subplot(111, projection='3d')
        self.ax.set_xlim(-2, 2)
        self.ax.set_ylim(-2, 2)
        self.ax.set_zlim(0, 2)
        self.ax.set_xlabel("X")
        self.ax.set_ylabel("Y")
        self.ax.set_zlabel("Z")
        self.ax.set_title("空间两自由度机械臂（绕Z轴 + 绕Y轴俯仰）")
        self.ax.grid(True)
        # 绘制机械臂
        self.line_link1, = self.ax.plot([], [], [], 'b-', linewidth=4, label='连杆1')
        self.line_link2, = self.ax.plot([], [], [], 'r-', linewidth=4, label='连杆2')
        self.joint_point, = self.ax.plot([], [], [], 'go', markersize=8, label='关节2')
        self.end_point, = self.ax.plot([], [], [], 'mo', markersize=8, label='末端执行器')
        self.base_point, = self.ax.plot([0], [0], [0], 'ko', markersize=10, label='基座')
        self.ax.legend()
        # 添加角度显示文本
        self.angle_text = self.ax.text2D(
            0.02, 0.95, '', transform=self.ax.transAxes,
            fontsize=10, bbox=dict(boxstyle="round", facecolor="wheat")
        )
        # 添加滑块控制
        self.slider_ax_theta1 = plt.axes([0.2, 0.1, 0.5, 0.03])
        self.slider_ax_theta2 = plt.axes([0.2, 0.05, 0.5, 0.03])
        self.slider_theta1 = Slider(self.slider_ax_theta1, 'θ1(绕Z轴)', -np.pi, np.pi, valinit=0, valfmt="%.2f rad")
        self.slider_theta2 = Slider(self.slider_ax_theta2, 'θ2(俯仰角)', -np.pi/2, np.pi/2, valinit=0, valfmt="%.2f rad")
        self.slider_theta1.on_changed(self.on_slider_change)
        self.slider_theta2.on_changed(self.on_slider_change)
        # 初始绘制
        self.update_plot()
    def rotation_matrix_z(self, theta):
        """绕Z轴旋转矩阵"""
        return np.array([
            [np.cos(theta), -np.sin(theta), 0],
            [np.sin(theta),  np.cos(theta), 0],
            [0,               0,            1]
        ])
    def rotation_matrix_y(self, theta):
        """绕Y轴旋转矩阵"""
        return np.array([
            [np.cos(theta),  0, np.sin(theta)],
            [0,               1,            0],
            [-np.sin(theta), 0, np.cos(theta)]
        ])
    def fk(self, theta1, theta2):
        """正向运动学：返回关节1和末端的位置"""
        # 关节1位置（绕Z旋转后）
        joint1 = np.array([self.l1, 0, 0])
        joint1 = self.rotation_matrix_z(theta1) @ joint1
        # 连杆2的方向：初始沿X轴，先绕Y转θ2，再绕Z转θ1
        link2_dir = np.array([self.l2, 0, 0])
        link2_dir = self.rotation_matrix_z(theta1) @ (self.rotation_matrix_y(theta2) @ link2_dir)
        end_effector = joint1 + link2_dir
        return joint1, end_effector
    def ik(self, x, y, z):
        """逆向运动学：给定末端位置(x,y,z)，求θ1和θ2"""
        # θ1 由 x,y 决定（绕Z轴）
        theta1 = math.atan2(y, x)
        # 在局部坐标系中，x' = sqrt(x^2 + y^2), z' = z
        x_prime = math.sqrt(x*x + y*y)
        z_prime = z
        # 现在是2D平面问题：连杆1长度l1，连杆2长度l2，目标(x_prime, z_prime)
        d_sq = x_prime*x_prime + z_prime*z_prime
        cos_theta2_numerator = d_sq - self.l1**2 - self.l2**2
        denominator = 2 * self.l1 * self.l2
        if abs(cos_theta2_numerator) > abs(denominator):
            return None  # 不可达
        cos_theta2 = np.clip(cos_theta2_numerator / denominator, -1.0, 1.0)
        theta2 = math.acos(cos_theta2)
        # 修正方向：确保z方向正确
        # 注意：这里假设θ2是向上为正（z>0）
        # 可扩展为elbow_up/down选择
        return theta1, theta2
    def update_plot(self):
        """更新3D图像"""
        joint1, end_effector = self.fk(self.theta1, self.theta2)
        # 确保使用numpy数组以避免shape属性问题
        joint1_np = np.array(joint1)
        end_effector_np = np.array(end_effector)
        # 更新线条
        self.line_link1.set_data_3d([0, joint1_np[0]], [0, joint1_np[1]], [0, joint1_np[2]])
        self.line_link2.set_data_3d([joint1_np[0], end_effector_np[0]], [joint1_np[1], end_effector_np[1]],
                                    [joint1_np[2], end_effector_np[2]])
        self.joint_point.set_data_3d([joint1_np[0]], [joint1_np[1]], [joint1_np[2]])
        self.end_point.set_data_3d([end_effector_np[0]], [end_effector_np[1]], [end_effector_np[2]])
        # 更新角度显示
        angle_str = f"θ1 = {self.theta1:+.3f} rad\nθ2= {self.theta2:+.3f} rad"
        self.angle_text.set_text(angle_str)
        self.fig.canvas.draw_idle()
    def on_slider_change(self, val):
        """滑块变化时更新角度"""
        self.theta1 = self.slider_theta1.val
        self.theta2 = self.slider_theta2.val
        self.update_plot()
    def show(self):
        plt.show()
 # ========================
 # 主程序
 # ========================
 if __name__ == "__main__":
    print("使用滑块控制空间两自由度机械臂！")
    arm = SpatialTwoLinkArm(l1=1.0, l2=1.0)
    arm.show()
--- a/3D/caculate/test.py
+++ b/3D/caculate/test.py
--- a/3D/caculate/trajectory.py
+++ b/3D/caculate/trajectory.py
@ -0,0 +1,146 @@
 # trajectory_3d.py
 import numpy as np
 def circle_trajectory_3d(center=(0, 0, 50), radius=30, axis='xy', num_points=200):
    """
    3D 圆形轨迹（可指定平面）
    参数：
        center: 圆心 (x, y, z)
        radius: 半径
        axis: 'xy', 'yz', 'xz' 平面
        num_points: 点数
    返回：
        x_list, y_list, z_list
    """
    angles = np.linspace(0, 2 * np.pi, num_points)
    cx, cy, cz = center
    if axis == 'xy':
        x_list = cx + radius * np.cos(angles)
        y_list = cy + radius * np.sin(angles)
        z_list = cz + np.zeros(num_points)
    elif axis == 'yz':
        x_list = cx + np.zeros(num_points)
        y_list = cy + radius * np.cos(angles)
        z_list = cz + radius * np.sin(angles)
    elif axis == 'xz':
        x_list = cx + radius * np.cos(angles)
        y_list = cy + np.zeros(num_points)
        z_list = cz + radius * np.sin(angles)
    else:
        raise ValueError("axis must be 'xy', 'yz', or 'xz'")
    return x_list, y_list, z_list
 def line_trajectory_3d(start=(40, 0, 0), end=(120, 0, 60), num_points=100):
    """ 3D 直线轨迹 """
    t = np.linspace(0, 1, num_points)
    x_list = start[0] + t * (end[0] - start[0])
    y_list = start[1] + t * (end[1] - start[1])
    z_list = start[2] + t * (end[2] - start[2])
    return x_list, y_list, z_list
 def line_trajectory_3d_uniform_speed(start=(40, 0, 0), end=(120, 60, 60), vx=0.1, vy=0.1, vz=0.05, num_points=20):
    """ 匀速 3D 斜线轨迹，按速度分量生成 """
    speed = np.sqrt(vx ** 2 + vy ** 2 + vz ** 2)
    if speed == 0:
        raise ValueError("速度不能为零")
    # 计算距离和总时间
    dx = end[0] - start[0]
    dy = end[1] - start[1]
    dz = end[2] - start[2]
    distance = np.sqrt(dx ** 2 + dy ** 2 + dz ** 2)
    total_time = distance / speed
    t = np.linspace(0, total_time, num_points)
    x_list = start[0] + vx * t
    y_list = start[1] + vy * t
    z_list = start[2] + vz * t
    return x_list, y_list, z_list
 def ellipse_trajectory_3d(center=(0, 0, 50), rx=50, ry=25, axis='xy', num_points=200):
    """ 3D 椭圆轨迹 """
    angles = np.linspace(0, 2 * np.pi, num_points)
    cx, cy, cz = center
    if axis == 'xy':
        x_list = cx + rx * np.cos(angles)
        y_list = cy + ry * np.sin(angles)
        z_list = cz + np.zeros(num_points)
    elif axis == 'yz':
        x_list = cx + np.zeros(num_points)
        y_list = cy + rx * np.cos(angles)
        z_list = cz + ry * np.sin(angles)
    elif axis == 'xz':
        x_list = cx + rx * np.cos(angles)
        y_list = cy + np.zeros(num_points)
        z_list = cz + ry * np.sin(angles)
    else:
        raise ValueError("axis must be 'xy', 'yz', or 'xz'")
    return x_list, y_list, z_list
 def helix_trajectory(center=(0, 0, 0), radius=30, height=100, turns=2, num_points=200):
    """ 螺旋轨迹（沿 Z 轴上升） """
    t = np.linspace(0, turns * 2 * np.pi, num_points)
    z_list = center[2] + height * t / (turns * 2 * np.pi)
    x_list = center[0] + radius * np.cos(t)
    y_list = center[1] + radius * np.sin(t)
    return x_list, y_list, z_list
 def square_trajectory_3d(side=60, center=(80, 0, 50), axis='xy', num_points=80):
    """ 3D 正方形轨迹（指定平面） """
    x_list, y_list, z_list = [], [], []
    cx, cy, cz = center
    half = side / 2
    if axis == 'xy':
        corners = [
            (cx - half, cy - half, cz),
            (cx + half, cy - half, cz),
            (cx + half, cy + half, cz),
            (cx - half, cy + half, cz),
            (cx - half, cy - half, cz)
        ]
    elif axis == 'yz':
        corners = [
            (cx, cy - half, cz - half),
            (cx, cy + half, cz - half),
            (cx, cy + half, cz + half),
            (cx, cy - half, cz + half),
            (cx, cy - half, cz - half)
        ]
    elif axis == 'xz':
        corners = [
            (cx - half, cy, cz - half),
            (cx + half, cy, cz - half),
            (cx + half, cy, cz + half),
            (cx - half, cy, cz + half),
            (cx - half, cy, cz - half)
        ]
    else:
        raise ValueError("axis must be 'xy', 'yz', or 'xz'")
    points_per_side = num_points // 4
    for i in range(4):
        x_start, y_start, z_start = corners[i]
        x_end, y_end, z_end = corners[i + 1]
        t = np.linspace(0, 1, points_per_side)
        x_list.extend(x_start + t * (x_end - x_start))
        y_list.extend(y_start + t * (y_end - y_start))
        z_list.extend(z_start + t * (z_end - z_start))
    return np.array(x_list), np.array(y_list), np.array(z_list)
 def custom_trajectory_3d(custom_x, custom_y, custom_z):
    """ 自定义 3D 轨迹 """
    return np.array(custom_x), np.array(custom_y), np.array(custom_z)
--- a/3D/main.py
+++ b/3D/main.py
@ -0,0 +1,154 @@
 # trajectory_control.py
 import numpy as np
 import matplotlib.pyplot as plt
 from mpl_toolkits.mplot3d import Axes3D
 from matplotlib.animation import FuncAnimation
 # 导入写好的 fkik 模块
 from caculate.fkik import SpatialTwoLinkArm
 # -------------------------
 # 参数设置
 # -------------------------
 L1 = 100.0
 L2 = 100.0
 KP, KD = 60.0, 1.0
 DEBUG_MODE = True
 # 创建机械臂实例
 arm = SpatialTwoLinkArm(l1=L1, l2=L2)
 # -------------------------
 # 3D 轨迹生成函数
 # -------------------------
 def circle_trajectory_3d(center=(100, 50, 30), radius=50, axis='xy', steps=100):
    angles = np.linspace(0, 2*np.pi, steps)
    cx, cy, cz = center
    if axis == 'xy':
        x = cx + radius * np.cos(angles)
        y = cy + radius * np.sin(angles)
        z = cz + np.zeros(steps)
    elif axis == 'yz':
        x = cx + np.zeros(steps)
        y = cy + radius * np.cos(angles)
        z = cz + radius * np.sin(angles)
    elif axis == 'xz':
        x = cx + radius * np.cos(angles)
        y = cy + np.zeros(steps)
        z = cz + radius * np.sin(angles)
    else:
        raise ValueError("axis must be 'xy', 'yz', or 'xz'")
    return x, y, z
 def line_trajectory_3d(start=(50, 50, 20), end=(150, 100, 80), steps=100):
    t = np.linspace(0, 1, steps)
    x = start[0] + t * (end[0] - start[0])
    y = start[1] + t * (end[1] - start[1])
    z = start[2] + t * (end[2] - start[2])
    return x, y, z
 def helix_trajectory_3d(center=(0,0,0), radius=60, height=100, turns=2, steps=200):
    t = np.linspace(0, turns * 2*np.pi, steps)
    x = center[0] + radius * np.cos(t)
    y = center[1] + radius * np.sin(t)
    z = center[2] + height * t / (turns * 2*np.pi)
    return x, y, z
 # -------------------------
 # 控制电机（调试用）
 # -------------------------
 def control_two_motors_mit(theta1_rad, theta2_rad):
    if not DEBUG_MODE:
        # 这里可以调用真实电机控制
        # motor_control.controlMIT(motor1, KP, KD, theta1_rad, 0.1, 0.0)
        # motor_control.controlMIT(motor2, KP, KD, theta2_rad, 0.1, 0.0)
        pass
    else:
        print(f"[DEBUG] 控制 -> θ1={np.degrees(theta1_rad):+.2f}°, θ2={np.degrees(theta2_rad):+.2f}°")
 # -------------------------
 # 执行轨迹（调用 IK 和 FK）
 # -------------------------
 def execute_trajectory(x_list, y_list, z_list):
    for i, (x, y, z) in enumerate(zip(x_list, y_list, z_list)):
        try:
            # 👉 调用你 fkik.py 中的 IK
            solution = arm.ik(x, y, z)
            if solution is None:
                print(f"跳过不可达点 ({x:.1f}, {y:.1f}, {z:.1f})")
                continue
            theta1, theta2 = solution
            # 发送控制指令
            control_two_motors_mit(theta1, theta2)
            # 👉 调用 FK 验证
            _, (x_fk, y_fk, z_fk) = arm.fk(theta1, theta2)
            error = np.sqrt((x - x_fk)**2 + (y - y_fk)**2 + (z - z_fk)**2)
            print(f"点 {i}: 目标({x:.1f},{y:.1f},{z:.1f}) -> FK({x_fk:.1f},{y_fk:.1f},{z_fk:.1f}) | 误差={error:.3f}mm")
        except Exception as e:
            print(f"IK 计算失败: {e}")
 # -------------------------
 # 3D 动画演示
 # -------------------------
 def run_animation(x_list, y_list, z_list):
    fig = plt.figure("Trajectory Animation")
    ax = fig.add_subplot(111, projection='3d')
    ax.set_xlim(-L1-L2, L1+L2)
    ax.set_ylim(-L1-L2, L1+L2)
    ax.set_zlim(-L1-L2, L1+L2)
    ax.set_xlabel("X")
    ax.set_ylabel("Y")
    ax.set_zlabel("Z")
    ax.set_title("3D Trajectory Tracking")
    # 机械臂线条
    line_arm, = ax.plot([], [], [], 'o-', lw=2, color='blue')
    target_point, = ax.plot([], [], [], 'r*', markersize=10, label='Target')
    ax.legend()
    def animate(frame):
        x, y, z = x_list[frame], y_list[frame], z_list[frame]
        try:
            sol = arm.ik(x, y, z)
            if sol is None:
                return line_arm, target_point
            theta1, theta2 = sol
            # 更新机械臂位置
            joint1, end_effector = arm.fk(theta1, theta2)
            joint1 = np.array(joint1)
            end_effector = np.array(end_effector)
            # 更新线条
            line_arm.set_data_3d([0, joint1[0], end_effector[0]],
                                 [0, joint1[1], end_effector[1]],
                                 [0, joint1[2], end_effector[2]])
            target_point.set_data_3d([x], [y], [z])
        except:
            pass
        return line_arm, target_point
    ani = FuncAnimation(fig, animate, frames=len(x_list),
                        interval=100, blit=False, repeat=True)
    plt.show()
 # -------------------------
 # 主程序
 # -------------------------
 if __name__ == "__main__":
    print("使用滑块控制空间两自由度机械臂！")
    # 选择一种轨迹
    x_list, y_list, z_list = circle_trajectory_3d(center=(40, -100, -100), radius=20, axis='xy', steps=100)
    # x_list, y_list, z_list = line_trajectory_3d(start=(60, 30, 10), end=(140, 90, 70), steps=80)
    # x_list, y_list, z_list = helix_trajectory_3d(center=(0,0,0), radius=50, height=80, turns=2, steps=200)
    # 执行轨迹（调用 IK 并打印调试信息）
    execute_trajectory(x_list, y_list, z_list)
    # 播放动画
    run_animation(x_list, y_list, z_list)