优化AEM

robowaiter/proto/camera.py

@@ -29,7 +29,7 @@ objects_dic = {}
 obstacle_objs_id = [114, 115, 122, 96, 102, 83, 121, 105, 108, 89, 100, 90,
                     111, 103, 95, 92, 76, 113, 101, 29, 112, 87, 109, 98,
                     106, 120, 97, 86, 104, 78, 85, 81, 82, 84, 91, 93, 94,
-                    99, 107, 116, 117, 118, 119, 255]
+                    99, 107, 116, 117, 118, 119, 255, 251]
 not_key_objs_id = {255,254,253,107,81}
 
 '''
@@ -367,12 +367,11 @@ def get_id_object_pixels(id, scene):
         world_points.append(transform_co(img_data_depth, pixel[0], pixel[1], d_depth[pixel[0]][pixel[1]][0], scene))
     return world_points
 
-
-
-
 def get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio):
     cur_obstacle_pixel_points = []
     object_pixels = {}
+    obj_detect_count = 0
+    cur_objs_id = []
     colors = [
         'red',
         'pink',
@@ -403,6 +402,7 @@ def get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio):
     for item in items:
         key, value = item.split(":")
         objs_id[int(key)] = value
+    objs_id[251] = "walker"
     # plt.imshow(d_depth, cmap="gray" if "depth" in im_depth.name.lower() else None)
     # plt.show()
     plt.subplot(2, 2, 1)
@@ -448,12 +448,14 @@ def get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio):
     # plt.tight_layout()
 
     for key, value in object_pixels.items():
-        if key == 0:
+        if key == 0 or key not in objs_id.keys():
             continue
-        if key in [91, 84, 96, 87, 102, 106, 120, 85,113, 101, 83]:
+
+        if key in [91, 84, 96, 87, 102, 106, 120, 85,113, 101, 83, 251]:
             X = np.array(value)
             db.fit(X)
             labels = db.labels_
+
             # 将数据按照聚类标签分组，并打印每个分组的数据
             for i in range(max(labels) + 1):  # 从0到最大聚类标签的值
                 group_data = X[labels == i]  # 获取当前标签的数据
@@ -463,6 +465,9 @@ def get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio):
                 y_min = min(p[1] for p in group_data)
                 if x_max - x_min < 10 or y_max - y_min < 10:
                     continue
+                if key != 251:
+                    obj_detect_count += 1
+                cur_objs_id.append(objs_id[key])
                 # 在指定的位置绘制方框
                 # 创建矩形框
                 rect = patches.Rectangle((x_min, y_min), (x_max - x_min), (y_max - y_min), linewidth=1, edgecolor=colors[key % 10],
@@ -470,7 +475,11 @@ def get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio):
                 plt.text(x_min, y_min, f'{objs_id[key]}', fontdict={'family': 'serif', 'size': 10, 'color': 'green'}, ha='center',
                          va='center')
                 plt.gca().add_patch(rect)
+
         else:
+            if key != 251:
+                obj_detect_count += 1
+            cur_objs_id.append(objs_id[key])
             x_max = max(p[0] for p in value)
             y_max = max(p[1] for p in value)
             x_min = min(p[0] for p in value)
@@ -489,12 +498,12 @@ def get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio):
         # rect = patches.Rectangle((0, 255), 15, 30, linewidth=1, edgecolor='g',
         #                          facecolor='none')
 
+    plt.subplot(2, 7, 14)  # 这里的2,1表示总共2行，1列，2表示这个位置是第2个子图
 
-        # 将矩形框添加到图像中
-        # plt.gca().add_patch(rect)
+    plt.text(0, 0.7, f'检测物体数量：{obj_detect_count}', fontsize=10)
 
     # plt.show()
-    return cur_obstacle_world_points
+    return cur_obstacle_world_points, cur_objs_id
 
 
 

robowaiter/scene/scene.py

@@ -774,7 +774,7 @@ class Scene:
             scene = stub.Do(action)
             print(scene.info)
 
-    def navigation_move(self, plt, cur_objs, objs_name_set, cur_obstacle_world_points, v_list, map_ratio, db, scene_id=0, map_id=11):
+    def navigation_move(self, plt, cur_objs, cur_obstacle_world_points, v_list, map_ratio, db, scene_id=0, map_id=11):
         print('------------------navigation_move----------------------')
         scene = stub.Observe(GrabSim_pb2.SceneID(value=scene_id))
         walk_value = [scene.location.X, scene.location.Y]
@@ -787,10 +787,10 @@ class Scene:
             print("walk_v", walk_v)
             action = GrabSim_pb2.Action(scene=scene_id, action=GrabSim_pb2.Action.ActionType.WalkTo, values=walk_v)
             scene = stub.Do(action)
-            cur_objs, objs_name_set = camera.get_semantic_map(GrabSim_pb2.CameraName.Head_Segment, cur_objs,
-                                                              objs_name_set)
+            # cur_objs, objs_name_set = camera.get_semantic_map(GrabSim_pb2.CameraName.Head_Segment, cur_objs,
+            #                                                   objs_name_set)
 
-            cur_obstacle_world_points = camera.get_obstacle_point(plt, db, scene, cur_obstacle_world_points,map_ratio)
+            cur_obstacle_world_points, cur_objs_id= camera.get_obstacle_point(plt, db, scene, cur_obstacle_world_points,map_ratio)
 
 
             # if scene.info == "Unreachable":
@@ -809,15 +809,15 @@ class Scene:
                 action = GrabSim_pb2.Action(scene=scene_id, action=GrabSim_pb2.Action.ActionType.WalkTo, values=walk_v)
                 scene = stub.Do(action)
 
-                cur_objs, objs_name_set = camera.get_semantic_map(GrabSim_pb2.CameraName.Head_Segment, cur_objs,
-                                                                  objs_name_set)
+                # cur_objs, objs_name_set = camera.get_semantic_map(GrabSim_pb2.CameraName.Head_Segment, cur_objs,
+                #                                                   objs_name_set)
 
-                cur_obstacle_world_points = camera.get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio)
+                cur_obstacle_world_points, cur_objs_id= camera.get_obstacle_point(plt, db, scene, cur_obstacle_world_points, map_ratio)
 
 
                 # if scene.info == "Unreachable":
                 print(scene.info)
-        return cur_objs, objs_name_set, cur_obstacle_world_points
+        return cur_obstacle_world_points, cur_objs_id
 
     def isOutMap(self, pos, min_x=-200, max_x=600, min_y=-250, max_y=1300):
         if pos[0] <= min_x or pos[0] >= max_x or pos[1] <= min_y or pos[1] >= max_y:

robowaiter/scene/tasks/AEM.py

@@ -23,22 +23,20 @@ class SceneAEM(Scene):
     def _reset(self):
         pass
     def _run(self):
+        print(len(self.status.objects))
         # 创建一个从白色（1）到灰色（0）的 colormap
+        objs = self.status.objects
         cur_objs = []
         cur_obstacle_world_points = []
-        objs_name_set = set()
         visited_obstacle = set()
         obj_json_data = []
+        obj_count = 0
+        added_info = 0
+
 
 
         map_ratio = 3
         db = DBSCAN(eps=map_ratio, min_samples=int(map_ratio / 2))
-        # # 创建一个颜色映射，其中0表示黑色，1表示白色
-        # cmap = plt.cm.get_cmap('gray')
-        # cmap.set_under('black')
-        # cmap.set_over('white')
-
-
 
         file_name = '../../proto/map_1.pkl'
         if os.path.exists(file_name):
@@ -54,13 +52,15 @@ class SceneAEM(Scene):
         # navigation_test(i,map_id)
         map_map = np.zeros((math.ceil(950 / map_ratio), math.ceil(1850 / map_ratio)))
 
-
+        # self.add_walker(0, 30, 520, )
+        # self.add_walker(10, 30, 420)
         while True:
+            walker_count = 0
             fig = plt.figure()
-            goal = self.explore(map, 120)  # cur_pos 指的是当前机器人的位置，场景中应该也有接口可以获取
+            goal = self.explore(map, 120)
             if goal is None:
                 break
-            cur_objs, objs_name_set, cur_obstacle_world_points= self.navigation_move(plt, cur_objs, objs_name_set, cur_obstacle_world_points, [[goal[0], goal[1]]], map_ratio, db,0, 11)
+            cur_obstacle_world_points, cur_objs_id= self.navigation_move(plt, cur_objs, cur_obstacle_world_points, [[goal[0], goal[1]]], map_ratio, db,0, 11)
 
             for point in cur_obstacle_world_points:
                 if point[0] < -350 or point[0] > 600 or point[1] < -400 or point[1] > 1450:
@@ -71,7 +71,13 @@ class SceneAEM(Scene):
             #            extent=(-400 / map_ratio, 1450 / map_ratio,
             #                    -350 / map_ratio, 600 / map_ratio))
 
-            # 使用imshow函数绘制图像，其中cmap参数设置颜色映射
+            for i in range(len(cur_objs_id)):
+                if cur_objs_id[i] == "walker":
+                    walker_count += 1
+                for obj in objs:
+                    if obj.name == cur_objs_id[i] and obj not in cur_objs:
+                        cur_objs.append(obj)
+                        break
 
             plt.subplot(2, 1, 2)  # 这里的2,1表示总共2行，1列，2表示这个位置是第2个子图
             plt.imshow(map_map, cmap='binary', alpha=0.5, origin='lower',
@@ -80,6 +86,16 @@ class SceneAEM(Scene):
             # plt.imshow(map_map, cmap='binary', alpha=0.5, origin='lower')
             # plt.axis('off')
             plt.title("地图构建过程")
+
+            plt.subplot(2, 7, 14)  # 这里的2,1表示总共2行，1列，2表示这个位置是第2个子图
+
+            # plt.text(0, 0.7, f'检测行人数量：{walker_count}', fontsize=10)
+
+            new_add_info = len(cur_objs) - added_info + walker_count
+            plt.text(0, 0.5, f'新增语义信息：{new_add_info}', fontsize=10)  # 在图中添加文字，x和y坐标是在这个图片大小内的相对位置，fontsize是字体大小
+            added_info += new_add_info
+            plt.text(0, 0.3, f'已存语义信息：{added_info}', fontsize=10)  # 在图中添加文字，x和y坐标是在这个图片大小内的相对位置，fontsize是字体大小
+            plt.axis("off")
             plt.show()
             print("------------当前检测到的物品信息--------------")
             print(cur_objs)