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修改分辨率触发逻辑

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wzy-warehouse
2026-06-14 14:19:22 +08:00
parent 4c0edb0840
commit b269e3282d
1 changed files with 203 additions and 117 deletions
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app/services/rainfall_grid_service.py
+203 -117
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@@ -1,5 +1,5 @@
"""
降雨栅格服务
降雨栅格服务 - 内存优化版本
负责降雨插值、边缘优化、PNG生成等业务逻辑
"""
import os
@@ -13,11 +13,11 @@ from app.utils.logger import get_logger
class RainfallGridService:
"""降雨栅格服务"""
def __init__(self):
"""初始化服务"""
self.logger = get_logger()
# 国标12小时累计降雨量等级和颜色映射
self.rainfall_levels = {
'levels': [0, 0.1, 5, 15, 30, 70, 140],
@@ -32,7 +32,7 @@ class RainfallGridService:
],
'labels': ['无雨', '小雨', '中雨', '大雨', '暴雨', '大暴雨', '特大暴雨']
}
# 西安地区大致边界(用于栅格范围)
self.xian_bounds = {
'min_lon': 107,
@@ -40,10 +40,10 @@ class RainfallGridService:
'min_lat': 33,
'max_lat': 35,
}
# 栅格分辨率(度)
self.grid_resolution = 0.01 # 约1km
self.grid_resolution = 0.001
def _create_buffer_points(self, points_array) -> 'np.ndarray':
"""
创建缓冲点:在原始站点外围生成虚拟点以扩展插值区域
@@ -58,11 +58,11 @@ class RainfallGridService:
# 计算站点分布的中心
center = np.mean(points_array, axis=0)
# 在站点外围生成缓冲点(沿着各个方向扩展)
buffer_points = []
num_angles = 120 # 每隔3度生成一个缓冲点
for angle_deg in range(0, 360, 360 // num_angles):
angle_rad = np.radians(angle_deg)
# 在凸包边界外扩展
@@ -71,14 +71,14 @@ class RainfallGridService:
direction = np.array([np.cos(angle_rad), np.sin(angle_rad)])
projections = points_array @ direction
max_idx = np.argmax(projections)
# 在该方向上扩展
base_point = points_array[max_idx]
buffer_point = center + (base_point - center) * scale
buffer_points.append(buffer_point)
return np.array(buffer_points)
def _calculate_adaptive_max_distance(
self,
points_array,
@@ -116,19 +116,16 @@ class RainfallGridService:
# 限制在合理范围内
return float(np.clip(adaptive_distance, min_distance, max_distance))
def interpolate_rainfall(self, station_data: List[Dict[str, Any]]) -> Dict[str, Any]:
"""
使用优化的反距离权重法(IDW)进行降雨插值
注意:station_data 现在包含 'rainfall'(累计降雨量)和 'duration_hours'(持续时间)
与DBN推演使用相同的降雨量计算逻辑(72小时回溯 + 3小时无雨截断
改进:
1. 高斯核衰减替代简单幂律
2. 自适应距离阈值
3. 边缘渐变处理
4. 高斯平滑减少突变
使用优化的反距离权重法(IDW)进行降雨插值(内存优化版本)
内存优化:
1. 使用float32代替float64(内存减半
2. 分块处理距离计算
3. 提前过滤无效站点
4. 减少中间数组
Args:
station_data: 站点数据列表,格式:
@@ -141,32 +138,34 @@ class RainfallGridService:
插值结果字典
"""
import numpy as np
from scipy.spatial import Delaunay, ConvexHull, distance_matrix
from scipy.spatial import Delaunay, ConvexHull
from scipy.ndimage import gaussian_filter
# 提取站点坐标和降雨量
points_array = np.array([[s['lon'], s['lat']] for s in station_data])
values_array = np.array([s['rainfall'] for s in station_data])
points_array = np.array([[s['lon'], s['lat']] for s in station_data], dtype=np.float32)
values_array = np.array([s['rainfall'] for s in station_data], dtype=np.float32)
# 创建栅格网格
lon_range = np.arange(
self.xian_bounds['min_lon'],
self.xian_bounds['max_lon'],
self.grid_resolution
self.grid_resolution,
dtype=np.float32
)
lat_range = np.arange(
self.xian_bounds['min_lat'],
self.xian_bounds['max_lat'],
self.grid_resolution
self.grid_resolution,
dtype=np.float32
)
grid_lon, grid_lat = np.meshgrid(lon_range, lat_range)
result = np.full_like(grid_lon, np.nan)
result = np.full_like(grid_lon, np.nan, dtype=np.float32)
# 自适应计算最大距离
actual_max_distance = self._calculate_adaptive_max_distance(points_array)
self.logger.info(f"使用最大影响距离: {actual_max_distance:.3f}")
# 计算站点的凸包(带边缘缓冲)
hull_mask = None
confidence_mask = None
@@ -174,84 +173,171 @@ class RainfallGridService:
try:
# 创建缓冲站点:在原始站点外围添加虚拟点
buffer_points = self._create_buffer_points(points_array)
# 合并原始站点和缓冲站点
all_points = np.vstack([points_array, buffer_points])
# 计算凸包
hull = ConvexHull(all_points)
hull_points = all_points[hull.vertices]
tri = Delaunay(hull_points)
# 向量化判断所有网格点是否在凸包内
grid_points = np.column_stack([grid_lon.ravel(), grid_lat.ravel()])
hull_indices = tri.find_simplex(grid_points)
hull_mask = hull_indices >= 0
simplex_indices = tri.find_simplex(grid_points)
hull_mask = simplex_indices >= 0
hull_mask = hull_mask.reshape(grid_lon.shape)
# 计算置信度:基于到最近站点的距离
# 计算置信度:基于到最近站点的距离(分块处理)
grid_valid = grid_points[hull_mask.ravel()]
if len(grid_valid) > 0:
dist_to_stations = distance_matrix(grid_valid, points_array)
min_distances = np.min(dist_to_stations, axis=1)
# 分块计算距离,避免内存溢出
chunk_size = 100000 # 每次处理10万点
n_valid = len(grid_valid)
min_distances = np.zeros(n_valid, dtype=np.float32)
for i in range(0, n_valid, chunk_size):
chunk_end = min(i + chunk_size, n_valid)
chunk_points = grid_valid[i:chunk_end]
# 计算当前块到所有站点的距离
lon_diff = chunk_points[:, 0:1] - points_array[np.newaxis, :, 0]
lat_diff = chunk_points[:, 1:2] - points_array[np.newaxis, :, 1]
distances = np.sqrt(lon_diff**2 + lat_diff**2)
# 记录最小距离
min_distances[i:chunk_end] = np.min(distances, axis=1)
# 释放临时数组
del lon_diff, lat_diff, distances
# 创建置信度掩码(距离越远,置信度越低)
confidence = np.ones(len(grid_points))
confidence = np.ones(len(grid_points), dtype=np.float32)
confidence[hull_mask.ravel()] = np.exp(-min_distances / actual_max_distance)
confidence_mask = confidence.reshape(grid_lon.shape)
else:
confidence_mask = np.ones_like(grid_lon)
confidence_mask = np.ones_like(grid_lon, dtype=np.float32)
except Exception as e:
self.logger.warning(f"凸包计算失败: {e},使用全区域插值")
hull_mask = np.ones_like(grid_lon, dtype=bool)
confidence_mask = np.ones_like(grid_lon)
confidence_mask = np.ones_like(grid_lon, dtype=np.float32)
else:
hull_mask = np.ones_like(grid_lon, dtype=bool)
confidence_mask = np.ones_like(grid_lon)
confidence_mask = np.ones_like(grid_lon, dtype=np.float32)
# 获取凸包内网格点坐标
grid_points = np.column_stack([grid_lon.ravel(), grid_lat.ravel()])
if hull_mask is not None:
# 只计算凸包内网格点到站点的距离
hull_point_indices = np.where(hull_mask.ravel())[0]
grid_points_hull = grid_points[hull_point_indices]
n_hull_points = len(grid_points_hull)
self.logger.info(f"凸包内网格点数量: {n_hull_points}, 总网格点: {grid_lon.size}")
else:
# 如果凸包掩码不可用,使用所有网格点
grid_points_hull = grid_points
hull_point_indices = np.arange(len(grid_points))
n_hull_points = len(grid_points_hull)
# 分块计算凸包内网格点到所有站点的距离
chunk_size = 50000 # 每次处理5万点
result_hull = np.full(n_hull_points, np.nan, dtype=np.float32)
# 向量化计算所有网格点到所有站点的距离
lon_diff = grid_lon[:, :, np.newaxis] - points_array[np.newaxis, np.newaxis, :, 0]
lat_diff = grid_lat[:, :, np.newaxis] - points_array[np.newaxis, np.newaxis, :, 1]
distances = np.sqrt(lon_diff**2 + lat_diff**2)
# 用于记录最后一个块的has_valid_stations_chunk
last_has_valid_stations_chunk = None
# 过滤超出最大距离的站点
valid_mask = distances <= actual_max_distance
for i in range(0, n_hull_points, chunk_size):
chunk_end = min(i + chunk_size, n_hull_points)
chunk_points = grid_points_hull[i:chunk_end]
chunk_size_actual = chunk_end - i
# 计算当前块到所有站点的距离
lon_diff_chunk = chunk_points[:, 0:1] - points_array[np.newaxis, :, 0]
lat_diff_chunk = chunk_points[:, 1:2] - points_array[np.newaxis, :, 1]
distances_chunk = np.sqrt(lon_diff_chunk**2 + lat_diff_chunk**2)
# 过滤超出最大距离的站点
valid_mask_chunk = distances_chunk <= actual_max_distance
# 对于每个网格点,检查是否有有效站点
has_valid_stations_chunk = np.any(valid_mask_chunk, axis=1)
# 避免除零
distances_chunk = np.where(valid_mask_chunk, distances_chunk, np.inf)
distances_chunk = np.maximum(distances_chunk, 1e-10)
# 优化的权重计算:结合幂律和高斯衰减
power = 2.0
power_weights_chunk = 1.0 / (distances_chunk ** power)
gaussian_weights_chunk = np.exp(-0.5 * (distances_chunk / (actual_max_distance * 0.5)) ** 2)
# 混合权重:距离越远,高斯权重占比越大
distance_ratio_chunk = distances_chunk / actual_max_distance
mix_factor_chunk = np.clip(distance_ratio_chunk, 0, 1)
weights_chunk = (1 - mix_factor_chunk) * power_weights_chunk + mix_factor_chunk * gaussian_weights_chunk
weights_chunk = np.where(valid_mask_chunk, weights_chunk, 0)
# 加权平均
weighted_sum_chunk = np.sum(weights_chunk * values_array[np.newaxis, :], axis=1)
weight_total_chunk = np.sum(weights_chunk, axis=1)
# 计算当前块的插值结果
with np.errstate(divide='ignore', invalid='ignore'):
chunk_result = np.where(
has_valid_stations_chunk & (weight_total_chunk > 0),
weighted_sum_chunk / weight_total_chunk,
np.nan
)
# 存储结果
result_hull[i:chunk_end] = chunk_result
# 记录最后一个块的has_valid_stations_chunk
last_has_valid_stations_chunk = has_valid_stations_chunk
# 释放临时数组
del lon_diff_chunk, lat_diff_chunk, distances_chunk, valid_mask_chunk
del power_weights_chunk, gaussian_weights_chunk, weights_chunk
del weighted_sum_chunk, weight_total_chunk, chunk_result
# 将凸包内点的结果映射回完整网格
result = np.full_like(grid_lon, np.nan, dtype=np.float32)
result.ravel()[hull_point_indices] = result_hull
# 构建完整网格的有效掩码(凸包内且有有效站点)
# 注意:这里需要重新计算所有凸包内点的有效站点掩码
# 由于分块处理,我们需要重新计算完整掩码
has_valid_stations_full = np.zeros_like(grid_lon, dtype=bool)
# 对于每个网格点,检查是否有有效站点
has_valid_stations = np.any(valid_mask, axis=2)
# 合并凸包掩码和有效站点掩码
final_mask = hull_mask & has_valid_stations
# 避免除零
distances = np.where(valid_mask, distances, np.inf)
distances = np.maximum(distances, 1e-10)
# 优化的权重计算:结合幂律和高斯衰减
power = 2.0
power_weights = 1.0 / (distances ** power)
gaussian_weights = np.exp(-0.5 * (distances / (actual_max_distance * 0.5)) ** 2)
# 混合权重:距离越远,高斯权重占比越大
distance_ratio = distances / actual_max_distance
mix_factor = np.clip(distance_ratio, 0, 1)
weights = (1 - mix_factor) * power_weights + mix_factor * gaussian_weights
weights = np.where(valid_mask, weights, 0)
# 加权平均
weighted_sum = np.sum(weights * values_array[np.newaxis, np.newaxis, :], axis=2)
weight_total = np.sum(weights, axis=2)
# 计算基础插值结果
with np.errstate(divide='ignore', invalid='ignore'):
result = np.where(
final_mask & (weight_total > 0),
weighted_sum / weight_total,
np.nan
)
# 重新计算所有凸包内点的有效站点掩码(内存优化:分块计算)
if n_hull_points > 0:
# 分块计算有效站点掩码
chunk_size_mask = 100000 # 每次处理10万点
for i in range(0, n_hull_points, chunk_size_mask):
chunk_end = min(i + chunk_size_mask, n_hull_points)
chunk_points = grid_points_hull[i:chunk_end]
# 计算当前块到所有站点的距离
lon_diff_chunk = chunk_points[:, 0:1] - points_array[np.newaxis, :, 0]
lat_diff_chunk = chunk_points[:, 1:2] - points_array[np.newaxis, :, 1]
distances_chunk = np.sqrt(lon_diff_chunk**2 + lat_diff_chunk**2)
# 过滤超出最大距离的站点
valid_mask_chunk = distances_chunk <= actual_max_distance
# 对于每个网格点,检查是否有有效站点
has_valid_chunk = np.any(valid_mask_chunk, axis=1)
# 存储结果
has_valid_stations_full.ravel()[hull_point_indices[i:chunk_end]] = has_valid_chunk
# 释放临时数组
del lon_diff_chunk, lat_diff_chunk, distances_chunk, valid_mask_chunk, has_valid_chunk
final_mask = hull_mask & has_valid_stations_full
# 应用置信度调整:边缘区域向邻近值渐变
if confidence_mask is not None:
valid_rainfall = result[final_mask]
@@ -260,13 +346,13 @@ class RainfallGridService:
# 根据置信度调整结果,低置信度区域向均值靠拢
adjusted_result = result * confidence_mask + mean_rainfall * (1 - confidence_mask)
result = np.where(final_mask, adjusted_result, np.nan)
# 应用高斯平滑减少边缘突变
result = gaussian_filter(result, sigma=1.0)
# 处理NaN值
result = np.nan_to_num(result, nan=0.0)
return {
'grid_values': result,
'grid_lon': grid_lon,
@@ -274,23 +360,23 @@ class RainfallGridService:
'lon_range': lon_range,
'lat_range': lat_range,
}
def optimize_edges(self, grid_data: Dict[str, Any],
def optimize_edges(self, grid_data: Dict[str, Any],
station_data: List[Dict[str, Any]]) -> Dict[str, Any]:
"""
优化栅格边缘(已在插值时处理,此方法保留用于向后兼容)
Args:
grid_data: 插值结果
station_data: 站点数据
Returns:
优化后的栅格数据
"""
# 由于interpolate_rainfall已经包含了边缘优化和平滑处理
# 这里不再重复处理,直接返回
return grid_data
def save_rainfall_grid_png(self, grid_data: Dict[str, Any], max_id: int) -> Optional[str]:
"""
将降雨栅格保存为PNG图片(背景透明)
@@ -310,8 +396,8 @@ class RainfallGridService:
try:
grid_values = grid_data['grid_values']
lon_range = grid_data['lon_range']
lat_range = grid_data['lat_range']
lon_range = grid_data['grid_lon']
lat_range = grid_data['grid_lat']
# 创建自定义颜色映射
levels = self.rainfall_levels['levels']
@@ -325,7 +411,7 @@ class RainfallGridService:
# 创建图形(设置dpi确保不拉伸)
fig, ax = plt.subplots(1, 1, figsize=(10, 10), dpi=100)
# 绘制栅格
im = ax.pcolormesh(
lon_range,
@@ -335,56 +421,56 @@ class RainfallGridService:
norm=norm,
shading='auto'
)
# 设置透明背景
fig.patch.set_alpha(0)
ax.patch.set_alpha(0)
# 移除坐标轴
ax.set_axis_off()
# 调整布局,去除白边
plt.tight_layout(pad=0)
# 构建文件路径
file_store_dir = settings.FILE_STORE_DIR
grid_dir_template = settings.RAIN_STATION_GRID_DIR
# 替换:id为实际的max_id
grid_dir = grid_dir_template.replace(':id', str(max_id))
# 完整路径
full_dir = os.path.join(file_store_dir, grid_dir.lstrip('/'))
# 创建目录
os.makedirs(full_dir, exist_ok=True)
# 保存PNG(使用PIL确保透明度)
png_path = os.path.join(full_dir, 'grid.png')
# 先保存到缓冲区
buf = BytesIO()
plt.savefig(buf, format='png', transparent=True, bbox_inches='tight', pad_inches=0)
buf.seek(0)
# 使用PIL打开并重新保存,确保透明度正确
img = Image.open(buf)
img.save(png_path, 'PNG')
buf.close()
plt.close(fig)
# 返回相对路径(相对于FILE_STORE_DIR),统一使用正斜杠
relative_path = os.path.join(grid_dir, 'grid.png').replace('\\', '/')
saved_path = png_path.replace('\\', '/')
self.logger.info(f"PNG图片已保存: {saved_path}")
return relative_path
except Exception as e:
self.logger.error(f"保存PNG图片失败: {e}", exc_info=True)
return None
def store_to_redis(self, png_path: str, max_id: int,
query_time, station_data: List[Dict[str, Any]]):
"""
@@ -402,13 +488,13 @@ class RainfallGridService:
try:
redis_key = settings.REDIS_RAIN_STATION_GRID_KEY
redis_identifier_key = settings.REDIS_RAIN_STATION_IDENTIFIER_KEY
# 处理query_time,可能是datetime对象或字符串
if isinstance(query_time, datetime):
query_time_str = query_time.isoformat()
else:
query_time_str = str(query_time)
# 构建辅助前端定位的信息
grid_info = {
'id': max_id,
@@ -429,16 +515,16 @@ class RainfallGridService:
'height': int((self.xian_bounds['max_lat'] - self.xian_bounds['min_lat']) / self.grid_resolution),
}
}
# 存储到Redis
redis_helper.set(redis_key, json.dumps(grid_info))
redis_helper.set(redis_identifier_key, max_id)
self.logger.info(f"栅格信息已存储到Rediskey: {redis_key}, id: {max_id}")
except Exception as e:
self.logger.error(f"存储到Redis失败: {e}", exc_info=True)
# 创建全局实例
rainfall_grid_service = RainfallGridService()
rainfall_grid_service = RainfallGridService()