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wr_rain_pred.py
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wr_rain_pred.py
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# -*- coding: utf-8 -*-
"""CS3237_wr_rain_pred.ipynb
Automatically generated by Colaboratory.
Original file is located at
https://colab.research.google.com/drive/1q0nOgrfmsGDrrW0jbj8YfIqrYMkCyLu1
"""
"""
Before running this code:
1. Clone the RainNet's repository
2. Download the RainNet's pretrained weights and CNN rain classifier weights
3. Install cmapy package (used to import custom colormaps for use in OpenCV)
"""
import io
import os
from PIL import Image
import cv2
import cmapy
import matplotlib.colors as mcolors
import numpy as np
import requests
from datetime import datetime
from dateutil import tz
from numpy import asarray
import time
from rainnet import rainnet
from keras.models import load_model
################################
# Helper functions for RainNet #
################################
cmap_data = [(1.0, 1.0, 1.0),
(0.3137255012989044, 0.8156862854957581, 0.8156862854957581),
(0.0, 1.0, 1.0),
(0.0, 0.8784313797950745, 0.501960813999176),
(0.0, 0.7529411911964417, 0.0),
(0.501960813999176, 0.8784313797950745, 0.0),
(1.0, 1.0, 0.0),
(1.0, 0.6274510025978088, 0.0),
(1.0, 0.0, 0.0),
(1.0, 0.125490203499794, 0.501960813999176),
(0.9411764740943909, 0.250980406999588, 1.0),
(0.501960813999176, 0.125490203499794, 1.0)]
# (0.250980406999588, 0.250980406999588, 1.0),
# (0.125490203499794, 0.125490203499794, 0.501960813999176),
# (0.125490203499794, 0.125490203499794, 0.125490203499794),
# (0.501960813999176, 0.501960813999176, 0.501960813999176),
# (0.8784313797950745, 0.8784313797950745, 0.8784313797950745),
# (0.9333333373069763, 0.8313725590705872, 0.7372549176216125),
# (0.8549019694328308, 0.6509804129600525, 0.47058823704719543),
# (0.6274510025978088, 0.42352941632270813, 0.23529411852359772),
# (0.4000000059604645, 0.20000000298023224, 0.0)]
precipitation_cmap = mcolors.ListedColormap(cmap_data, 'precipitation')
def Scaler(array):
return np.log(array+0.01)
def invScaler(array):
return np.exp(array) - 0.01
def pad_to_shape(array, from_shape=900, to_shape=928, how="mirror"):
# calculate how much to pad in respect with native resolution
padding = int( (to_shape - from_shape) / 2)
# for input shape as (batch, W, H, channels)
if how == "zero":
array_padded = np.pad(array, ((0,0),(padding,padding),(padding,padding),(0,0)), mode="constant", constant_values=0)
elif how == "mirror":
array_padded = np.pad(array, ((0,0),(padding,padding),(padding,padding),(0,0)), mode="reflect")
return array_padded
def pred_to_rad(pred, from_shape=928, to_shape=900):
# pred shape 12,928,928
padding = int( (from_shape - to_shape) / 2)
return pred[::, padding:padding+to_shape, padding:padding+to_shape].copy()
def data_preprocessing(X):
# 0. Right shape for batch
X = np.moveaxis(X, 0, -1)
X = X[np.newaxis, ::, ::, ::]
# 1. To log scale
X = Scaler(X)
# 2. from 900x900 to 928x928
X = pad_to_shape(X)
return X
def data_postprocessing(nwcst):
# 0. Squeeze empty dimensions
nwcst = np.squeeze(np.array(nwcst))
# 1. Convert back to rainfall depth
nwcst = invScaler(nwcst)
# 2. Convert from 928x928 back to 900x900
nwcst = pred_to_rad(nwcst)
# 3. Return only positive values
nwcst = np.where(nwcst>0, nwcst, 0)
return nwcst
def prediction(model_instance, input_data, lead_time):
input_data = data_preprocessing(input_data)
nwcst = []
print("Forecasting the probability of rain within the next {} minutes...\n".format(lead_time*15))
for i in range(lead_time):
# make prediction
pred = model_instance.predict(input_data)
# print(pred.dtype)
# pred_copy = pred.squeeze()
# pred_copy = cv2.normalize(pred_copy, None, 0, 255, cv2.NORM_MINMAX, cv2.CV_8U)
# print(pred_copy.shape, type(pred_copy))
# heatmap = cv2.applyColorMap(pred_copy, cmapy.cmap(precipitation_cmap))
# cv2.imwrite('prediction_{}.png'.format(i), heatmap)
# append prediction to holder
nwcst.append(pred)
# append prediction to the input shifted on one step ahead
input_data = np.concatenate([input_data[::, ::, ::, 1:], pred], axis=-1)
nwcst = data_postprocessing(nwcst)
new_nwcst = cv2.normalize(nwcst[lead_time - 1], None, 0, 255, cv2.NORM_MINMAX, cv2.CV_8U)
heatmap = cv2.applyColorMap(new_nwcst, cmapy.cmap(precipitation_cmap))
#cv2.imwrite(output_img_name, heatmap)
#for i in range(lead_time):
#new_nwcst = cv2.normalize(nwcst[i], None, 0, 255, cv2.NORM_MINMAX, cv2.CV_8U)
#heatmap = cv2.applyColorMap(new_nwcst, cmapy.cmap(precipitation_cmap))
#cv2.imwrite('nwcst_{}.png'.format(i), heatmap)
return heatmap
######################################
# Helper functions for rain_pred_CNN #
######################################
def generate_timestamp(look_back=10):
timestamps = []
first_img = True
from_zone = tz.gettz('UTC')
to_zone = tz.gettz('Asia/Singapore')
utc = datetime.utcnow()
# Change timezone from UTC to Singapore time
utc = utc.replace(tzinfo=from_zone)
# Convert time zone
sg_time = utc.astimezone(to_zone)
year = '2020'
month = '11'
day = str(sg_time.strftime("%d"))
hour = int(sg_time.strftime("%H"))
minute = int(sg_time.strftime("%M"))
minute -= 10
if (minute < 0):
minute += 60
hour -= 1
second = '0000'
while(minute % 5 != 0):
minute -= 1
while (len(timestamps) < look_back):
minute = str(minute)
if (minute == '0'):
minute = '00'
if (minute == '5'):
minute = '05'
if len(str(hour)) == 1:
hour = '0' + str(hour)
name = year + month + day + str(hour) + str(minute) + second
timestamps.append(name)
minute = int(minute)
minute -= 15
if (minute < 0):
hour -= 1
minute += 60
if (hour < 0):
day = str(int(day) - 1)
hour = 23
if first_img:
#print("\nCollecting weather radar images for the current timestamp (2020-11-17-13-10-0000) and 30 minutes before...".format(year, month, day, hour, minute, second))
print("\nCollecting weather radar images for the current timestamp ({}-{}-{}-{}-{}-{}) and 30 minutes before...".format(year, month, day, hour, minute, second))
first_img = False
#timestamps.reverse() # reverse list so that the oldest timestamp is first in the list
return timestamps
def download_SG_data(name):
try:
startTime = time.time()
url = "http://www.weather.gov.sg/files/rainarea/50km/v2/dpsri_70km_{}dBR.dpsri.png".format(name)
r = requests.get(url)
with open('rainnet/live/{}.png'.format(name), 'wb') as f:
f.write(r.content)
print("Downloaded", url)
print("Time Taken:", time.time() - startTime)
return True
except:
print("unable to fetch")
return False
def resize_image(image):
imageName = image
image = Image.open('rainnet/live/{}.png'.format(imageName))
new_image = image.resize((900,900)).convert("L")
# new_image.save('rainnet/live/{}.png'.format(imageName)) # for debugging
data = asarray(new_image)
# print(data.shape) # for debugging
return data
def concat_images(timestamp_list):
prev = []
downloaded_imgs = []
for i in timestamp_list:
if (download_SG_data(i)):
downloaded_imgs.append(i)
if (len(downloaded_imgs) > 3):
break
downloaded_imgs.reverse()
for i in downloaded_imgs:
current = resize_image(i)
if i == downloaded_imgs[-1]:
latest = current
else:
prev.append(current)
S_latest = np.concatenate([prev, latest[np.newaxis, ::, ::]], axis=0)
# print(S_latest.shape) # for debugging
S_latest_timestep = downloaded_imgs[-1]
# print(S_latest_timestep) # for debugging
print("All images collected.\n")
return S_latest
def load_image(image_fname):
img = cv2.imread(image_fname)
# Resize the colored images to (450 x 450)
# Too bad that the Google Colab GPU doesn't have enough
# memory for me to train the CNN with a bigger input size.
img = cv2.resize(img,(450,450))
return img
def white2black(image):
new_img = image
white_px = np.asarray([255, 255, 255])
black_px = np.asarray([0 , 0 , 0 ])
(row, col, _) = image.shape
for r in range(row):
for c in range(col):
px = image[r][c]
if all(px == white_px):
new_img[r][c] = black_px
cv2.imwrite('nwcst_b.png', new_img)
return new_img
def predict_rain(wr_image, rain_pred_CNN):
# Use custom CNN to classfiy radar images as "rain" or "no_rain"
# image = load_image(wr_image)
image = white2black(wr_image) # convert to black background (because training images had black background)
# Resize the colored images to (450 x 450)
# Too bad that the Google Colab GPU doesn't have enough
# memory for me to train the CNN with a bigger input size.
image = cv2.resize(image,(450,450))
image = np.array(image)/255.0 # scale pixel values
image = np.expand_dims(image, axis=0) # change dimensions to (1, 450, 450, 3)
result = rain_pred_CNN.predict(image)
pr_rain = result[0][0]
if result[0][0] >= 0.5:
is_rain = True
#print("{} prediction: rain with probability {}".format(filename, result[0][0]))
else:
is_rain = False
#print("{} prediction: no rain with probability {}".format(filename, 1- result[0][0]))
return is_rain, pr_rain
def download_Overlay_data():
try:
url = "http://www.weather.gov.sg/wp-content/themes/wiptheme/images/SG-Township.png".format()
r = requests.get(url)
with open('rainnet/live/SG_Township.png', 'wb') as f:
f.write(r.content)
except:
print("unable to fetch")
def resize_image_pred(image):
# imageName = image
# image = Image.open('./{}.png'.format(imageName))
new_image = Image.fromarray(image).resize((853, 479)).convert("RGBA")
# overlay = Image.open('rainnet/live/{}.png'.format('SG_Township')).convert("RGBA")
#new_image.paste(overlay, (0, 0), overlay)
#new_image.save('rainnet/predictions/{}.png'.format(imageName))
#data = asarray(new_image)
# print(data.shape)
return new_image
def overlay_SG_map(pred_wr_img):
new_image = resize_image_pred(pred_wr_img)
overlay = Image.open('rainnet/live/{}.png'.format('SG_Township')).convert("RGBA")
new_image.paste(overlay, (0, 0), overlay)
new_image.save('rainnet/predictions/sg_nwcst.png')
data = asarray(new_image)
# print(data.shape) # for debugging
def load_models():
RN_model = rainnet.rainnet()
RN_model.load_weights("rainnet_weights.h5")
rain_pred_CNN = load_model("rain_classifier.h5")
return RN_model, rain_pred_CNN
def CNN_get_rain_prediction(lead_time=2):
print("Loading CNN models...")
RN_model , rain_pred_CNN = load_models()
print("Done!\n\n")
timestamp_list = generate_timestamp()
#timestamp_list = ['2020111713350000', '2020111713200000','2020111713050000', '2020111712500000']
#timestamp_list = ['2020111715000000', '2020111714450000','2020111714300000', '2020111714150000']
#print(timestamp_list)
SG_latest = concat_images(timestamp_list)
#print(SG_latest.shape)
pred_wr_img = prediction(RN_model, SG_latest, lead_time)
download_Overlay_data()
overlay_SG_map(pred_wr_img)
is_rain, pr_rain = predict_rain(pred_wr_img, rain_pred_CNN)
return is_rain, pr_rain
# Set lead_time (in hours) to be larger than 1
# CNN_get_rain_prediction(lead_time=4)