surveilling-surveillance/streetview/sample.py

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Python
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2021-05-20 22:20:48 +02:00
import numpy as np
import pandas as pd
from tqdm import tqdm
import random
import os
from geopy.distance import distance
from shapely.geometry import MultiPoint
from .util import get_heading
def random_points(edges,
n=100,
d=None,
verbose=False):
m = len(edges)
lengths = edges['length'].tolist()
total_length = edges.sum()['length']
lengths_normalized = [l/total_length for l in lengths]
rows = []
points = []
indices = np.random.choice(range(m),
size=2*n,
p=lengths_normalized)
pbar = tqdm(total=n)
i = j = 0
while i < n:
index = indices[j]
row = edges.iloc[index]
u, v, key = edges.index[index]
line = row['geometry']
offset = np.random.rand() * line.length
point = line.interpolate(offset)
lat = point.y
lon = point.x
flag = 1
if d is not None:
for _lat, _lon in points:
_d = np.sqrt(np.square(lat-_lat) + np.square(lon-_lon))
if _d < 1e-4 and distance((lat, lon), (_lat, _lon)).m < d:
flag = 0
break
if flag:
i += 1
pbar.update(1)
start = line.interpolate(offset*0.9)
end = line.interpolate(min(line.length, offset*1.1))
heading = get_heading(start.y, start.x, end.y, end.x)
rows.append({"lat": lat,
"lon": lon,
"id": i,
"u": u,
"v": v,
"heading": heading,
"offset": offset,
"key": key})
points.append((lat, lon))
j += 1
pbar.close()
return pd.DataFrame(rows)
def random_stratified_points(edges, n=10):
m = len(edges)
rows = []
for index in range(len(edges)):
row = edges.iloc[index]
u, v, key = edges.index[index]
line = row['geometry']
for _ in range(n):
offset = np.random.rand() * line.length
point = line.interpolate(offset)
lat = point.y
lon = point.x
rows.append({"lat": lat,
"lon": lon,
"u": u,
"v": v,
"key": key})
return pd.DataFrame(rows)
def select_panoid(meta,
n=5000,
distance=10,
selection="closest",
seed=123):
YEARS = ["2010<year<2016", "2016<=year"]
# Set random seed
np.random.seed(seed)
random.seed(seed)
# Filter by distance
meta = meta.query(f"distance < {distance}")
# Filter by occurance for both pre and post
meta_pre = meta.query(YEARS[0]).drop_duplicates(["lat_anchor", "lon_anchor"])
meta_post = meta.query(YEARS[1]).drop_duplicates(["lat_anchor", "lon_anchor"])
meta_both = meta_pre.merge(meta_post, on=["lat_anchor", "lon_anchor"], how="inner")
# Sample anchor points
meta_sample = meta_both.drop_duplicates(['lat_anchor', 'lon_anchor']).sample(n, replace=False)
lat_anchor_chosen = meta_sample.lat_anchor.unique()
lon_anchor_chosen = meta_sample.lon_anchor.unique()
# Sample for pre and post
meta_sub = meta[meta.lat_anchor.isin(lat_anchor_chosen)]
meta_sub = meta_sub[meta_sub.lon_anchor.isin(lon_anchor_chosen)]
# Select panoid
groups = []
for years in YEARS:
group = meta_sub.query(years)
if selection == "closest":
group = group.sort_values(['lat_anchor','lon_anchor', 'distance'])
else:
group = group.sort_values(['lat_anchor','lon_anchor', 'year'], ascending=False)
group = group.groupby(['lat_anchor','lon_anchor']).first().reset_index()
group['year'] = group.year.apply(int)
groups.append(group)
# Random select the orthogonal heading
merged = groups[0].merge(groups[1],
on=['lat_anchor', 'lon_anchor', 'u', 'v', 'key', 'heading', 'offset'],
suffixes=("_pre", "_post"))
merged['heading_pre'] = merged['heading_post'] = (merged.heading + 360 + 90 - 180 * (np.random.rand(n) > 0.5)) % 360
merged['heading_pre'] = merged['heading_pre'].apply(int)
merged['heading_post'] = merged['heading_post'].apply(int)
return merged
def select_panoid_recent(meta,
year,
n=5000,
distance=10,
seed=123):
# Set random seed
np.random.seed(seed)
random.seed(seed)
# Filter by distance
meta = meta.query(f"distance < {distance}")
meta = meta.query(f"year >= {year}")
# Sample anchor points
meta_sample = meta.drop_duplicates(['id']).sample(n, replace=False)
lat_anchor_chosen = meta_sample.lat_anchor.unique()
lon_anchor_chosen = meta_sample.lon_anchor.unique()
# Sample for pre and post
meta_sub = meta[meta.lat_anchor.isin(lat_anchor_chosen)]
meta_sub = meta_sub[meta_sub.lon_anchor.isin(lon_anchor_chosen)]
# Select panoid
meta = meta_sub.sort_values(['lat_anchor','lon_anchor', 'distance']) \
.groupby(['lat_anchor','lon_anchor']) \
.first().reset_index()
# Random select the orthogonal heading
meta['road_heading'] = meta.heading
meta['heading'] = (meta.heading + 360 + 90 - 180 * (np.random.rand(n) > 0.5)) % 360
meta['heading'] = meta['heading'].apply(int)
meta['year'] = meta['year'].apply(int)
meta['month'] = meta['month'].apply(int)
meta['save_path'] = meta.apply(get_path, 1)
return meta
def get_path(row):
panoid = row['panoid']
heading = row['heading']
return os.path.join("/scratch/haosheng/camera/", panoid[:2], panoid[2:4], panoid[4:6], panoid[6:], f"{heading}.png")