介绍
组成
1.PointNet classification network分类网络
- part segmentation network
数据集
1.point clouds sampled from 3D shapes
2.ShapeNetPart dataset.
结构
其主要分成以下三部分:
- 数据处理
- model构建
- 结果选择
数据处理
将点云处理成程序可用的格式,具体实现在 provider.py 中,主要包含了数据下载、预处理(shuffle->rotate->jitter)、格式转换(hdf5->txt)
shuffle
def shuffle_data(data, labels): """ Shuffle data and labels. Input: data: B,N,... numpy array label: B,... numpy array Return: shuffled data, label and shuffle indices """ idx = np.arange(len(labels))#返回一个列表 # print('idx=',idx)#idx= [ 0 1 2 ... 2045 2046 2047] np.random.shuffle(idx)#把idx进行shuffle # print('idx=', idx) return data[idx, ...], labels[idx], idx
rotate旋转处理
def rotate_point_cloud(batch_data): # print('batch data shape=',batch_data.shape)#(32, 1024, 3) rotated_data = np.zeros(batch_data.shape, dtype=np.float32) for k in range(batch_data.shape[0]): rotation_angle = np.random.uniform() * 2 * np.pi#生成一个随机数 cosval = np.cos(rotation_angle) sinval = np.sin(rotation_angle) rotation_matrix = np.array([[cosval, 0, sinval], [0, 1, 0], [-sinval, 0, cosval]]) shape_pc = batch_data[k, ...] rotated_data[k, ...] = np.dot(shape_pc.reshape((-1, 3)), rotation_matrix) #先让shape_pc的形状变成(?,3),因为旋转矩阵为(3,3) return rotated_data
jitter抖动处理
def jitter_point_cloud(batch_data, sigma=0.01, clip=0.05): B, N, C = batch_data.shape assert(clip > 0) jittered_data = np.clip(sigma * np.random.randn(B, N, C), -1*clip, clip)#将数组范围限制在(-1*clip, clip) jittered_data += batch_data return jittered_data
model构建
Feature transform net
with tf.variable_scope('transform_net1') as sc:#T-net transform = input_transform_net(point_cloud, is_training, bn_decay, K=3) print('point cloud=',point_cloud)#(32, 1024, 3) # print('input transform=',transform)#(32, 3, 3) point_cloud_transformed = tf.matmul(point_cloud, transform) # print('point_cloud_transformed=',point_cloud_transformed)#(32, 1024, 3)
mlp(64,128,1024)
net = tf_util.conv2d(net_transformed, 64, [1,1], padding='VALID', stride=[1,1], bn=True, is_training=is_training, scope='conv3', bn_decay=bn_decay) print('net3=',net)#(32, 1024, 1, 64) net = tf_util.conv2d(net, 128, [1,1], padding='VALID', stride=[1,1], bn=True, is_training=is_training, scope='conv4', bn_decay=bn_decay) print('net4=',net)#(32, 1024, 1, 128) net = tf_util.conv2d(net, 1024, [1,1], padding='VALID', stride=[1,1], bn=True, is_training=is_training, scope='conv5', bn_decay=bn_decay) print('net5=',net)#(32, 1024, 1, 1024)
类别投票
实现方法
batch_pred_sum.shape=(?,40) # 每个data对40个类的可能性
pred_val.shape=(?,) # 每个data所属的可能性最大的类
pred_val = np.argmax(batch_pred_sum, 1) #返回沿轴axis最大值的索引,即得到预测值最大的那一类的idx(label)
评估
输出(预测label,真实label)
</dump/pred_label.txt>
4, 4 0, 0 2, 2 8, 8 14, 23 ...
<shape_names.txt>
airplane
bathtub
bed
bench
bookshelf
bottle
bowl
car
chair
cone
cup
保存预测错误的图片,并可视化
</dump/xxxx_pred_name.jpg>
命名=第几个预测错误的图片+真实label+预测label
例子 /dump/1028_label_bed_pred_sofa.jpg
三张点云图片,分别是当前点云数据旋转三个不同角度之后的样子
save code
for i in range(start_idx, end_idx): l = current_label[i] total_seen_class[l] += 1 total_correct_class[l] += (pred_val[i-start_idx] == l) fout.write('%d, %d\n' % (pred_val[i-start_idx], l)) # print('!!!!!!!!!!','%d, %d\n' % (pred_val[i-start_idx], l)) if pred_val[i-start_idx] != l and FLAGS.visu: # ERROR CASE, DUMP!如果预测错了 img_filename = '%d_label_%s_pred_%s.jpg' % (error_cnt, SHAPE_NAMES[l], SHAPE_NAMES[pred_val[i-start_idx]]) #第几个预测错误的图片+真实label+预测label img_filename = os.path.join(DUMP_DIR, img_filename) output_img = pc_util.point_cloud_three_views(np.squeeze(current_data[i, :, :])) scipy.misc.imsave(img_filename, output_img) error_cnt += 1
画点云图的code
draw_point_cloud()
Input:
points: Nx3 numpy array
Output:
gray image
记录loss,预测精确度
/dump/log_evaluate.txt
eval mean loss: 1.816358 eval accuracy: 0.501216 eval avg class acc: 0.421297 airplane: 0.980 bathtub: 0.440 bed: 0.940 bench: 0.450 ...