输出预测结果

9 months ago · fcff6a72f3
parent 71bc236f76
commit fcff6a72f3
32 changed files with 346 additions and 376 deletions
--- a/入模数据/丽水.xlsx
+++ b/入模数据/丽水.xlsx
--- a/入模数据/台州.xlsx
+++ b/入模数据/台州.xlsx
--- a/入模数据/嘉兴.xlsx
+++ b/入模数据/嘉兴.xlsx
--- a/入模数据/宁波.xlsx
+++ b/入模数据/宁波.xlsx
--- a/入模数据/杭州.xlsx
+++ b/入模数据/杭州.xlsx
--- a/入模数据/温州.xlsx
+++ b/入模数据/温州.xlsx
--- a/入模数据/湖州.xlsx
+++ b/入模数据/湖州.xlsx
--- a/入模数据/绍兴.xlsx
+++ b/入模数据/绍兴.xlsx
--- a/入模数据/舟山.xlsx
+++ b/入模数据/舟山.xlsx
--- a/入模数据/衢州.xlsx
+++ b/入模数据/衢州.xlsx
--- a/入模数据/金华.xlsx
+++ b/入模数据/金华.xlsx
--- a/各地级市日电量模型/hangzhou.bin
+++ b/各地级市日电量模型/hangzhou.bin
--- a/各地级市日电量模型/jiaxing.bin
+++ b/各地级市日电量模型/jiaxing.bin
--- a/各地级市日电量模型/jinhua.bin
+++ b/各地级市日电量模型/jinhua.bin
--- a/各地级市日电量模型/quzhou.bin
+++ b/各地级市日电量模型/quzhou.bin
--- a/各地级市日电量模型/taizhou.bin
+++ b/各地级市日电量模型/taizhou.bin
--- a/各地级市日电量模型/wenzhou.bin
+++ b/各地级市日电量模型/wenzhou.bin
--- a/各地级市日电量模型/zhoushan.bin
+++ b/各地级市日电量模型/zhoushan.bin
--- a/各地级市日电量模型/丽水.py
+++ b/各地级市日电量模型/丽水.py
@ -27,10 +27,9 @@ def normal(nd):

 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/丽水.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-# data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -50,20 +49,18 @@ data = data.loc[normal(data['售电量']).index]

 data['season'] = data.index.map(season)

-df_eval = data.loc['2023-11']
+df_eval = data.loc['2023-12']
 # df_train = data.loc['2021-1':'2023-8']
-df_train = data[450:-1]
+
+df_train = data[-180:]
 # df_train = data.loc['2022-4':'2023-9'][:-3]
-df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]

 print(df_train.corr()['售电量'])

-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']
-# best_goal = 1
-# best_i = {}
-# for i in range(200):

 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.2, random_state=42)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
@ -72,32 +69,33 @@ y_pred = model.predict(x_test)
 result_test = pd.DataFrame({'test': y_test, 'pred': y_pred}, index=y_test.index)

 # 指标打印
-print(abs(y_test - y_pred).mean() / y_test.mean())
+print('abs_test:',abs(y_test - y_pred).mean() / y_test.mean())
 eval_pred = model.predict(X_eval)

 result_eval = pd.DataFrame({'eval': df_eval['售电量'], 'pred': eval_pred}, index=df_eval['售电量'].index)
-print(result_eval['eval'])
+print(result_eval)

 goal = (result_eval['eval'][-3:].sum() - result_eval['pred'][-3:].sum()) / result_eval['eval'].sum()
 print(goal)
 goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / result_eval['eval'].sum()
 print(goal2)

-# with open(r'C:\Users\user\Desktop\9月各地市日电量预测结果\偏差率.txt','a',encoding='utf-8') as f:
-#     f.write(f'丽水月末3天偏差率：{goal},9号-月底偏差率：{goal2}')
-# # 保存模型
-# model.save_model('lishui.bin')
 import numpy as np

 X_eval = np.array([
-    [17.2, 5.7, 10, 0, 0,2023],
-    [21.2, 4.3, 10, 0, 0,2023],
-    [11.5, 6.6, 10, 0, 0,2023]
+    [11.59, 0.6, 0, 0, 1, 2023],
+    [16.6, 2.4, 0, 0, 1, 2023],
+    [15.5, 6.7, 0, 0, 1, 2023],
+    [15, 9.4, 0, 0, 1, 2023],
+    [18.6, 7.5, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28','2023-12-29','2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
 print(result)

+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx',mode='a',if_sheet_exists='replace',engine='openpyxl') as writer:
+    result.to_excel(writer,sheet_name='丽水')
--- a/各地级市日电量模型/台州.py
+++ b/各地级市日电量模型/台州.py
@ -5,9 +5,11 @@ from sklearn.metrics import r2_score
 from sklearn.model_selection import train_test_split
 import matplotlib as mpl
 import matplotlib.pyplot as plt
-mpl.rcParams['font.sans-serif']=['kaiti']

-pd.set_option('display.width',None)
+mpl.rcParams['font.sans-serif'] = ['kaiti']
+
+pd.set_option('display.width', None)
+

 def season(x):
    if str(x)[5:7] in ('01', '02', '10', '11'):
@ -16,17 +18,19 @@ def season(x):
        return 1
    else:
        return 2
+
+
 def normal(nd):
-    high = nd.describe()['75%'] + 1.5*(nd.describe()['75%']-nd.describe()['25%'])
-    low = nd.describe()['25%'] - 1.5*(nd.describe()['75%']-nd.describe()['25%'])
-    return nd[(nd<high)&(nd>low)]
+    high = nd.describe()['75%'] + 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
+    low = nd.describe()['25%'] - 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
+    return nd[(nd < high) & (nd > low)]
+

-parent_dir = os.path.abspath(os.path.join(os.getcwd(),os.pardir))
-data = pd.read_excel(os.path.join(parent_dir,'入模数据/台州.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
+data = pd.read_excel(os.path.join(parent_dir, '入模数据/台州.xlsx'))
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-# data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -43,58 +47,55 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)

 data['season'] = data.index.map(season)
-# data = data.loc[:'2023-9']
-df_eval = data.loc['2023-11']

-df_train = data[500:-1]
-# df_train = data[500:][:-3]
+df_eval = data.loc['2023-12']
+
+df_train = data[-180:]
+
 print(df_train)

-df_train = df_train[['tem_max','tem_min','holiday','24ST','售电量','season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]

-X = df_train[['tem_max','tem_min','24ST','holiday','season','year']]
-X_eval = df_eval[['tem_max','tem_min','24ST','holiday','season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']
-# best_goal = 1
-# best_i = {}
-# for i in range(400):

-x_train,x_test,y_train,y_test = train_test_split(X,y,test_size=0.2,random_state=158)
+x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.02, random_state=158)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
-model.fit(x_train,y_train)
+model.fit(x_train, y_train)

 y_pred = model.predict(x_test)
-result_test = pd.DataFrame({'test':y_test,'pred':y_pred},index=y_test.index)
+result_test = pd.DataFrame({'test': y_test, 'pred': y_pred}, index=y_test.index)

 # 指标打印
 print(abs(y_test - y_pred).mean() / y_test.mean())
 eval_pred = model.predict(X_eval)

-result_eval = pd.DataFrame({'eval':df_eval['售电量'],'pred':eval_pred},index=df_eval['售电量'].index)
-# print(result_eval)
-# print((result_eval['eval'].sum()-result_eval['pred'].sum())/result_eval['eval'].sum())
-goal = (result_eval['eval'][-3:].sum()-result_eval['pred'][-3:].sum())/result_eval['eval'].sum()
+result_eval = pd.DataFrame({'eval': df_eval['售电量'], 'pred': eval_pred}, index=df_eval['售电量'].index)
+
+goal = (result_eval['eval'][-3:].sum() - result_eval['pred'][-3:].sum()) / result_eval['eval'].sum()
 print(goal)
-goal2 = (result_eval['eval'][-23:].sum()-result_eval['pred'][-23:].sum())/result_eval['eval'].sum()
+goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / result_eval['eval'].sum()
 print(goal2)
 print(result_eval)
-#     if abs(goal) < best_goal:
-#         best_goal = abs(goal)
-#         best_i['best_i'] = i
-# print(best_i,best_goal)

-# 保存模型
-model.save_model('taizhou.bin')
 import numpy as np

 X_eval = np.array([
-    [18.8, 6.2, 10, 0, 0,2023],
-    [21.7, 6.5, 10, 0, 0,2023],
-    [14.3, 8.4, 10, 0, 0,2023]
+    [13.1, -0.7, 0, 0, 1, 2023],
+    [17.9, 2.8, 0, 0, 1, 2023],
+    [15.8, 7.6, 0, 0, 1, 2023],
+    [15.9, 8, 0, 0, 1, 2023],
+    [19.7, 7.8, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
 print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='台州')
--- a/各地级市日电量模型/嘉兴.py
+++ b/各地级市日电量模型/嘉兴.py
@ -3,10 +3,7 @@ import pandas as pd
 import os
 from sklearn.metrics import r2_score
 from sklearn.model_selection import train_test_split
-import matplotlib as mpl
-import matplotlib.pyplot as plt

-mpl.rcParams['font.sans-serif'] = ['kaiti']
 pd.set_option('display.width', None)


@ -27,10 +24,10 @@ def normal(nd):

 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/嘉兴.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-# data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -46,22 +43,19 @@ data = data.loc[normal(data['售电量']).index]
 #         list1.append(i)
 # print(list0,list1,list2)
 data['season'] = data.index.map(season)
-# data = data.loc[:'2023-9']
-df_eval = data.loc['2023-11']
-df_train = data.iloc[450:-1]
-# df_train = data[450:][:-3]
+
+df_eval = data.loc['2023-12']
+df_train = data.iloc[-180:]
+

 print(df_train)

-df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]

-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']

-# best_goal = 1
-# best_i = {}
-# for i in range(400):

 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.1, random_state=158)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
@ -78,13 +72,7 @@ goal = (result_eval['eval'][-3:].sum() - result_eval['pred'][-3:].sum()) / resul
 goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / result_eval['eval'].sum()
 print(goal, goal2)
 print(result_eval)
-# print(goal2)
-#     if abs(goal) < best_goal :
-#         best_goal = abs(goal)
-#         best_i['best_i'] = i
-#         x = goal2
-#
-# print(best_i,best_goal,x)
+

 # 保存模型
 model.save_model('jiaxing.bin')
@ -93,13 +81,20 @@ loaded_model.load_model('jiaxing.bin')
 import numpy as np

 X_eval = np.array([
-    [14.5, 7.7, 10, 0, 1,2023],
-    [21.6, 10, 10, 0, 1,2023],
-    [11.9, 6.6, 10, 0, 1,2023]
+    [10.7, -2.2, 0, 0, 1, 2023],
+    [12.8, 2.2, 0, 0, 1, 2023],
+    [11.7, 2.3, 0, 0, 1, 2023],
+    [13, 1, 0, 0, 1, 2023],
+    [11.5, 5.8, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
 print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='嘉兴')
--- a/各地级市日电量模型/宁波.py
+++ b/各地级市日电量模型/宁波.py
@ -3,10 +3,7 @@ import pandas as pd
 import os
 from sklearn.metrics import r2_score
 from sklearn.model_selection import train_test_split
-import matplotlib as mpl
-import matplotlib.pyplot as plt

-mpl.rcParams['font.sans-serif'] = ['kaiti']
 pd.set_option('display.width', None)


@ -20,17 +17,17 @@ def season(x):


 def normal(nd):
-    high = nd.describe()['75%'] + 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
-    low = nd.describe()['25%'] - 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
+    high = nd.describe()['75%'] + 3 * (nd.describe()['75%'] - nd.describe()['25%'])
+    low = nd.describe()['25%'] - 3 * (nd.describe()['75%'] - nd.describe()['25%'])
    return nd[(nd < high) & (nd > low)]


 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/宁波.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-# data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -48,20 +45,17 @@ data = data.loc[normal(data['售电量']).index]


 data['season'] = data.index.map(season)
-df_eval = data.loc['2023-11']
-# df_train = data.loc['2022-01':'2023-09'][:-3]
+df_eval = data.loc['2023-12']
+print(df_eval)

-df_train = data.loc['2022-01':'2023-11']
+df_train = data.iloc[-180:]

-df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]

-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']

-# best_goal = 1
-# best_i = {}
-# for i in range(400):

 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.1, random_state=142)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
@ -83,19 +77,24 @@ print(goal2)
 print(result_eval)


-# 保存模型
-# model.save_model('ningbo.bin')
 import numpy as np

 X_eval = np.array([

-    [16.5, 6.8, 10, 0, 1,2023],
-    [21.7, 6.8, 10, 0, 1,2023],
-    [13, 8.8, 10, 0, 1,2023]
+    [12.9, -2.9, 0, 0, 1, 2023],
+    [16.4, 3.4, 0, 0, 1, 2023],
+    [12.8, 4.9, 0, 0, 1, 2023],
+    [12.9, 4.6, 0, 0, 1, 2023],
+    [17.9, 6.4, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
-print(result)
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
+print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='宁波')
--- a/各地级市日电量模型/杭州.py
+++ b/各地级市日电量模型/杭州.py
@ -35,10 +35,10 @@ def normal(nd):

 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/杭州.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
 # data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -55,23 +55,17 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)


-# data['month'] = data.index.strftime('%Y-%m-%d').str[6]
-# data['month'] = data['month'].astype('int')
 data['season'] = data.index.map(season)
-# data = data.loc[:'2023-9']
-df_train = data[500:-1]
-# df_train = data[500:][:-3]
-df_eval = data.loc['2023-11']
+
+df_train = data[-180:]
+
+df_eval = data.loc['2023-12']

 print(df_train)
-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']

-# best_goal = 1
-# best_i = {}
-# for i in range(400):
-
 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.2, random_state=42)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
 model.fit(x_train, y_train)
@ -91,40 +85,22 @@ goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / re
 print('goal2:', goal2)
 print(result_eval)
 print('r2:', r2_score(y_test, y_pred))
-#
-# # result_eval.to_csv('asda.csv',encoding='gbk')
-#     # if abs(goal) < best_goal:
-#     #     best_goal = abs(goal)
-#     #     best_i['best_i'] = i
-#     #     x = goal2
-# # print(best_i,best_goal,x)
-#
-#
-#
-# # result_eval.to_csv(r'C:\Users\user\Desktop\9月各地市日电量预测结果\杭州.csv')
-# # with open(r'C:\Users\user\Desktop\9月各地市日电量预测结果\偏差率.txt','a',encoding='utf-8') as f:
-# #     f.write(f'杭州月末3天偏差率：{round(goal,5)},9号-月底偏差率：{round(goal2,5)}\n')
-# 保存模型
-model.save_model('hangzhou.bin')
-
-# X_eval = df_eval[['tem_max','tem_min','24ST','holiday','season']]
-# df_eval = pd.read_excel(r'C:\Users\user\Desktop\浙江气象1027.xlsx')
-# df_eval.columns = df_eval.columns.map(lambda x:x.strip())
-# df_eval = df_eval[['city_name','dtdate','tem_max','tem_min']]
-# df_eval['city_name'] = df_eval['city_name'].map(lambda x:x.strip())
-# df_hangzhou = df_eval[df_eval['city_name']=='金华市'].sort_values(by='dtdate')
-
-
-loaded_model = xgb.XGBRegressor()
-loaded_model.load_model('hangzhou.bin')
+
 X_eval = np.array([
-    [17.2, 5.7, 10, 0, 0,2023],
-    [21.2, 4.3, 10, 0, 0,2023],
-    [11.5, 6.6, 10, 0, 0,2023]
+    [11.8, -2.8, 0, 0, 1, 2023],
+    [15.1, 0.2, 0, 0, 1, 2023],
+    [12.9, 2.2, 0, 0, 1, 2023],
+    [11.4, 1.3, 0, 0, 1, 2023],
+    [14.8, 3.6, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
 print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='杭州')
--- a/各地级市日电量模型/温州.py
+++ b/各地级市日电量模型/温州.py
@ -27,10 +27,10 @@ def normal(nd):

 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/温州.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
 # data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -48,23 +48,18 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)
 data['season'] = data.index.map(season)

-# data = data.loc[:'2023-8']
-df_eval = data.loc['2023-11']
+df_eval = data.loc['2023-12']
+
+df_train = data[-180:]

-df_train = data[450:]
-# df_train = data[450:][:-3]
 print(df_train)

-df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]

-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']

-# best_goal = 1
-# best_i = {}
-# for i in range(400):
-
 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.1, random_state=42)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
 model.fit(x_train, y_train)
@ -84,27 +79,24 @@ print(goal)
 goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / result_eval['eval'].sum()
 print(goal2)
 print(result_eval)
-# if abs(goal) < best_goal :
-#     best_goal = abs(goal)
-#     best_i['best_i'] = i
-#     x = goal2
-# print(best_i,best_goal,x)
-# 保存模型
-model.save_model('wenzhou.bin')
-
-loaded_model = xgb.XGBRegressor()

-loaded_model.load_model('wenzhou.bin')
 import numpy as np

 X_eval = np.array([
-    [19.8, 6.6, 10, 0, 1,2023],
-    [22, 6.1, 10, 0, 1,2023],
-    [18.5, 10.1, 10, 0, 1,2023]
+    [13.7, -0.1, 0, 0, 1, 2023],
+    [18.9, 3.4, 0, 0, 1, 2023],
+    [16.3, 11.3, 0, 0, 1, 2023],
+    [16.6, 9.7, 0, 0, 1, 2023],
+    [20.6, 20.2, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
-print(result)
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
+print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='温州')
--- a/各地级市日电量模型/湖州.py
+++ b/各地级市日电量模型/湖州.py
@ -21,17 +21,16 @@ def season(x):


 def normal(nd):
-    high = nd.describe()['75%'] + 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
-    low = nd.describe()['25%'] - 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
+    high = nd.describe()['75%'] + 3 * (nd.describe()['75%'] - nd.describe()['25%'])
+    low = nd.describe()['25%'] - 3 * (nd.describe()['75%'] - nd.describe()['25%'])
    return nd[(nd < high) & (nd > low)]


 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/湖州.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-# data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
-data.set_index('dtdate',inplace=True)
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]

 # list2 = []
@ -49,16 +48,16 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)

 data['season'] = data.index.map(season)
-# data = data.loc[:'2023-9']
-df_eval = data.loc['2023-11']

-df_train = data[450:-1]
-# df_train = data[450:][:-3]
+df_eval = data.loc['2023-12']
+
+df_train = data[-180:]
+
 print(df_train)
-df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]

-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']

 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.1, random_state=158)
@ -79,21 +78,26 @@ print(goal)
 goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / result_eval['eval'].sum()
 print(goal2)
 print(result_eval)
-# 保存模型
-model.save_model('huzhou.bin')
-loaded_model = xgb.XGBRegressor()
-loaded_model.load_model('huzhou.bin')
+
+
 import numpy as np

 X_eval = np.array([

-    [14.9, 7.1, 10, 0, 1,2023],
-    [17.7, 6.6, 10, 0, 1,2023],
-    [10.3, 5.8, 10, 0, 1,2023]
+    [9.7, -2.3, 0, 0, 1, 2023],
+    [13.1, 0.8, 0, 0, 1, 2023],
+    [10.3, 5.8, 0, 0, 1, 2023],
+    [10.1, 0.1, 0, 0, 1, 2023],
+    [12.8, 5.1, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
 print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='湖州')
--- a/各地级市日电量模型/绍兴.py
+++ b/各地级市日电量模型/绍兴.py
@ -3,10 +3,8 @@ import pandas as pd
 import os
 from sklearn.metrics import r2_score
 from sklearn.model_selection import train_test_split
-import matplotlib as mpl
-import matplotlib.pyplot as plt

-mpl.rcParams['font.sans-serif'] = ['kaiti']
+
 pd.set_option('display.width', None)


@ -18,18 +16,15 @@ def season(x):
    else:
        return 2

-
 def normal(nd):
    high = nd.describe()['75%'] + 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
    low = nd.describe()['25%'] - 1.5 * (nd.describe()['75%'] - nd.describe()['25%'])
    return nd[(nd < high) & (nd > low)]

-
 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/绍兴.xlsx'))
 data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-# data.index = pd.to_datetime(data.index, format='%Y-%m-%d')
 data.set_index('dtdate',inplace=True)
 data = data.loc[normal(data['售电量']).index]

@ -48,10 +43,10 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)
 data['season'] = data.index.map(season)

-df_eval = data.loc['2023-11']
-# data = data.loc[:'2023-8']
-df_train = data[450:]
-# df_train = data[450:][:-3]
+df_eval = data.loc['2023-12']
+
+df_train = data[-180:]
+
 print(df_train)

 df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
@ -80,20 +75,25 @@ goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / re
 print(goal2)

 print(result_eval)
-# # 保存模型
-# model.save_model('shaoxing.bin')
-# loaded_model = xgb.XGBRegressor()
-# loaded_model.load_model('shaoxing.bin')
+
 import numpy as np

 X_eval = np.array([
-    [17.4, 6.6, 10, 0, 0,2023],
-    [21.2, 7, 10, 0, 0,2023],
-    [12.1, 7.3, 10, 0, 0,2023]
+
+    [13.1, -3.5, 0, 0, 1, 2023],
+    [15.6, 0.1, 0, 0, 1, 2023],
+    [13.2, 3.6, 0, 0, 1, 2023],
+    [14.4, 3.2, 0, 0, 1, 2023],
+    [15.5, 5.3, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
 result = pd.concat((result_eval['eval'],result))
 result.index = result.index.map(lambda x:str(x)[:10])
-print(result)
+result.columns = ['预测值']
+print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='绍兴')
--- a/各地级市日电量模型/舟山.py
+++ b/各地级市日电量模型/舟山.py
@ -7,8 +7,6 @@ import matplotlib as mpl

 mpl.rcParams['font.sans-serif'] = ['kaiti']
 pd.set_option('display.width', None)
-import random
-import matplotlib.pyplot as plt


 def season(x):
@ -26,9 +24,9 @@ def normal(nd):

 parent_dir = os.path.abspath(os.path.join(os.getcwd(), os.pardir))
 data = pd.read_excel(os.path.join(parent_dir, '入模数据/舟山.xlsx'))
-data['dtdate'] = pd.to_datetime(data['dtdate'],format='%Y-%m-%d')
+data['dtdate'] = pd.to_datetime(data['dtdate'], format='%Y-%m-%d')
 data['year'] = data['dtdate'].dt.year
-data.set_index('dtdate',inplace=True)
+data.set_index('dtdate', inplace=True)
 data = data.loc[normal(data['售电量']).index]
 # list2 = []
 # list0 = []
@ -45,14 +43,12 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)

 data['season'] = data.index.map(season)
-df_eval = data.loc['2023-11']
-# data = data.loc[:'2023-8']
+df_eval = data.loc['2023-12']
 df_train = data.iloc[450:]
-# df_train = data.iloc[450:][:-3]

-df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season','year']]
-X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
-X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season','year']]
+df_train = df_train[['tem_max', 'tem_min', 'holiday', '24ST', '售电量', 'season', 'year']]
+X = df_train[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
+X_eval = df_eval[['tem_max', 'tem_min', '24ST', 'holiday', 'season', 'year']]
 y = df_train['售电量']

 x_train, x_test, y_train, y_test = train_test_split(X, y, test_size=0.1, random_state=42)
@ -75,19 +71,23 @@ goal2 = (result_eval['eval'][-23:].sum() - result_eval['pred'][-23:].sum()) / re
 print(goal2)
 print(result_eval)

-model.save_model('zhoushan.bin')
-loaded_model = xgb.XGBRegressor()
-loaded_model.load_model('zhoushan.bin')
 import numpy as np

 X_eval = np.array([
-    [14.7, 11.4, 10, 0, 1,2023],
-    [19.4, 11.8, 10, 0, 1,2023],
-    [14.9, 9.4, 10, 0, 1,2023]
+    [11.4, 5.1, 0, 0, 1, 2023],
+    [15.5, 9.1, 0, 0, 1, 2023],
+    [11, 7.9, 0, 0, 1, 2023],
+    [12.7, 7.2, 0, 0, 1, 2023],
+    [16, 10.3, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
-result = pd.concat((result_eval['eval'],result))
-result.index = result.index.map(lambda x:str(x)[:10])
-print(result)
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
+result = pd.concat((result_eval['eval'], result))
+result.index = result.index.map(lambda x: str(x)[:10])
+result.columns = ['预测值']
+print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='舟山')
--- a/各地级市日电量模型/衢州.py
+++ b/各地级市日电量模型/衢州.py
@ -3,9 +3,6 @@ import pandas as pd
 import os
 from sklearn.metrics import r2_score
 from sklearn.model_selection import train_test_split
-import matplotlib as mpl
-import matplotlib.pyplot as plt
-mpl.rcParams['font.sans-serif']=['kaiti']
 pd.set_option('display.width',None)
 def season(x):
    if str(x)[5:7] in ('01', '02'):
@ -42,12 +39,10 @@ data = data.loc[normal(data['售电量']).index]
 #
 # print(list0,list1,list2)
 data['season'] = data.index.map(season)
-# data = data.loc[:'2023-8']
-
-df_eval = data.loc['2023-11']
-df_train = data.iloc[450:]
-# df_train = data.iloc[450:-3]

+df_eval = data.loc['2023-12']
+df_train = data.iloc[-180:]
+print(df_train)

 df_train = df_train[['tem_max','tem_min','holiday','24ST','售电量','season','year']]

@ -71,23 +66,26 @@ print(goal)
 goal2 = (result_eval['eval'][-23:].sum()-result_eval['pred'][-23:].sum())/result_eval['eval'].sum()
 print(goal2)
 print(result_eval)
-# 保存模型
-model.save_model('quzhou.bin')
-loaded_model = xgb.XGBRegressor()
-loaded_model.load_model('quzhou.bin')
+
 import numpy as np
 X_eval = np.array([
-    [18.7, 7, 10, 0, 1,2023],
-    [20.2, 6.5, 10, 0, 1,2023],
-    [11.2, 8, 10, 0, 1,2023]
+    [11.7, -0.8, 0, 0, 1, 2023],
+    [15.2, 3.0, 0, 0, 1, 2023],
+    [14.8, 5.3, 0, 0, 1, 2023],
+    [15.1, 5.7, 0, 0, 1, 2023],
+    [17.5, 7.5, 0, 1, 1, 2023]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
 result = pd.concat((result_eval['eval'],result))
 result.index = result.index.map(lambda x:str(x)[:10])
+result.columns = ['预测值']
 print(result)

+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='衢州')

 # import torch
 # from torch import nn
--- a/各地级市日电量模型/金华.py
+++ b/各地级市日电量模型/金华.py
@ -3,9 +3,6 @@ import pandas as pd
 import os
 from sklearn.metrics import r2_score
 from sklearn.model_selection import train_test_split
-import matplotlib as mpl
-import matplotlib.pyplot as plt
-mpl.rcParams['font.sans-serif']=['kaiti']
 pd.set_option('display.width',None)

 def season(x):
@ -41,11 +38,10 @@ data = data.loc[normal(data['售电量']).index]
 # print(list0,list1,list2)
 data['season'] = data.index.map(season)

-data = data.loc[:'2023-11']
-df_eval = data.loc['2023-11']
+data = data.loc[:'2023-12']
+df_eval = data.loc['2023-12']

-# df_train = data.iloc[450:-1]
-df_train = data.iloc[450:]
+df_train = data.iloc[-180:]
 print(df_train)

 df_train = df_train[['tem_max','tem_min','holiday','24ST','售电量','season']]
@ -54,9 +50,6 @@ X = df_train[['tem_max','tem_min','24ST','holiday','season']]
 X_eval = df_eval[['tem_max','tem_min','24ST','holiday','season']]
 y = df_train['售电量']

-# best_goal = 1
-# best_i = {}
-# for i in range(400):

 x_train,x_test,y_train,y_test = train_test_split(X,y,test_size=0.1,random_state=100)
 model = xgb.XGBRegressor(max_depth=6, learning_rate=0.05, n_estimators=150)
@ -78,24 +71,23 @@ goal2 = (result_eval['eval'][-23:].sum()-result_eval['pred'][-23:].sum())/result
 print(goal2)
 print(result_eval)

-    # if abs(goal) < best_goal :
-    #     best_goal = abs(goal)
-    #     best_i['best_i'] = i
-    #     x = goal2

-# # 保存模型
-model.save_model('jinhua.bin')
-loaded_model = xgb.XGBRegressor()
-loaded_model.load_model('jinhua.bin')
 import numpy as np
 X_eval = np.array([
-    [19.5, 7.6, 10, 0, 1],
-    [21.7, 6.8, 10, 0, 1],
-    [11.6, 8.2, 10, 0, 1]
+    [11.7, -0.8, 0, 0, 1],
+    [15.2, 3.0, 0, 0, 1],
+    [14.8, 5.3, 0, 0, 1],
+    [15.1, 5.7, 0, 0, 1],
+    [17.5, 7.5, 0, 1, 1]
 ])
 print(model.predict(X_eval))
 result = model.predict(X_eval)
-result = pd.DataFrame(result,index=['2023-11-28','2023-11-29','2023-11-30'])
+result = pd.DataFrame(result, index=['2023-12-26', '2023-12-27', '2023-12-28', '2023-12-29', '2023-12-30'])
 result = pd.concat((result_eval['eval'],result))
 result.index = result.index.map(lambda x:str(x)[:10])
-print(result)
+result.columns = ['预测值']
+print(result)
+
+with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市区日电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                    engine='openpyxl') as writer:
+    result.to_excel(writer, sheet_name='金华')
--- a/浙江电压等级电量/分压_移动平均.py
+++ b/浙江电压等级电量/分压_移动平均.py
@ -1,47 +1,55 @@
 import pandas as pd
-df = pd.read_excel(r'C:\Users\鸽子\Desktop\浙江电量20231202.xlsx', sheet_name=1)
+
+df = pd.read_excel(r'C:\Users\鸽子\Desktop\浙江power1225.xlsx', sheet_name=1)
 df['pt_date'] = pd.to_datetime(df['pt_date'])

 # 移动平均
-
 dict_big = {}
 dict_ok = {}

-# for city in df['city_name'].drop_duplicates():
-#
-#     df_city1 = df[(df['city_name'] == city) & (df['county_name'].isnull())].set_index('pt_date').loc['2023-11']
-#     resut_df = pd.DataFrame({})
-#     index_level = []
-#     tq_list = []
-#     pred_list = []
-#     loss_list = []
-#     rate_list = []
-#     for level in df_city1.columns[2:]:
-#
-#         index_level.append(level)
-#
-#         df_moving_avg = pd.DataFrame(df_city1[:-3][level], index=df_city1[:-3].index)
-#         future = pd.date_range(start=df_city1.index[-3], periods=3, freq='D')
-#
-#         for date in future:
-#             df_moving_avg.loc[date, level] = df_moving_avg[-3:].mean().values
-#         loss = (df_city1[level].tail(-3).sum() - df_moving_avg.tail(-3).sum()) / df_city1[level].sum()
-#         tq_list.append(df_city1[level].sum())
-#         pred_list.append(df_moving_avg[level].sum())
-#         loss_list.append(df_city1[level].sum()-df_moving_avg[level].sum())
-#         rate_list.append((df_city1[level].sum()-df_moving_avg[level].sum())/df_city1[level].sum())
-#     resut_df = pd.DataFrame({'同期电量':tq_list,'预测电量':pred_list,'偏差':loss_list,'偏差率':rate_list},index=index_level)
-#     with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\11月移动平均分压.xlsx',mode='a',if_sheet_exists='replace',engine='openpyxl') as writer:
-#         resut_df.to_excel(writer,sheet_name=f'{city[4:6]}')
-
-excel_file = pd.ExcelFile(r'C:\Users\鸽子\Desktop\11月移动平均分压.xlsx')
-df1 = pd.read_excel(excel_file,sheet_name=1)
-df1.set_index(df1.columns[0],inplace=True)
-for sheet in excel_file.sheet_names[2:]:
-    df = pd.read_excel(excel_file,sheet_name=sheet)
-    df.set_index(df.columns[0],inplace=True)
-    df1 += df
-df1['偏差'] = df1['同期电量']-df1['预测电量']
-df1['偏差率'] = df1['偏差']/df1['同期电量']
-df1.to_excel('移动平均_11月分压汇总.xlsx')
-print(df1)
+for city in df['city_name'].drop_duplicates():
+
+    df_city1 = df[(df['city_name'] == city) & (df['county_name'].isnull())].set_index('pt_date').loc['2023-12']
+    resut_df = pd.DataFrame({})
+    index_level = []
+    tq_list = []
+    pred_list = []
+    loss_list = []
+    rate_list = []
+
+    for level in df_city1.columns[2:]:
+
+        # index_level.append(level)
+        df_moving_avg = pd.DataFrame(df_city1[level], index=df_city1.index)
+        future = pd.date_range(start='2023-12-26', periods=5, freq='D')
+
+        for date in future:
+            df_moving_avg.loc[date, level] = df_moving_avg[-3:].mean().values
+        resut_df = pd.concat([resut_df, df_moving_avg], axis=1)
+        print(city[4:6])
+        print(resut_df)
+
+        # loss = (df_city1[level].tail(-3).sum() - df_moving_avg.tail(-3).sum()) / df_city1[level].sum()
+        # tq_list.append(df_city1[level].sum())
+        # pred_list.append(df_moving_avg[level].sum())
+        # loss_list.append(df_city1[level].sum() - df_moving_avg[level].sum())
+        # rate_list.append((df_city1[level].sum() - df_moving_avg[level].sum()) / df_city1[level].sum())
+    # resut_df = pd.DataFrame({'同期电量': tq_list, '预测电量': pred_list, '偏差': loss_list, '偏差率': rate_list},
+    #                         index=index_level)
+    # resut_df = pd.DataFrame({'预测电量': pred_list},index=index_level)
+
+    with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\市分压电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                        engine='openpyxl') as writer:
+        resut_df.to_excel(writer, sheet_name=f'{city[4:6]}')
+
+# excel_file = pd.ExcelFile(r'C:\Users\鸽子\Desktop\11月移动平均分压.xlsx')
+# df1 = pd.read_excel(excel_file, sheet_name=1)
+# df1.set_index(df1.columns[0], inplace=True)
+# for sheet in excel_file.sheet_names[2:]:
+#     df = pd.read_excel(excel_file, sheet_name=sheet)
+#     df.set_index(df.columns[0], inplace=True)
+#     df1 += df
+# df1['偏差'] = df1['同期电量'] - df1['预测电量']
+# df1['偏差率'] = df1['偏差'] / df1['同期电量']
+# df1.to_excel('移动平均_11月分压汇总.xlsx')
+# print(df1)
--- a/浙江行业电量/移动平均.py
+++ b/浙江行业电量/移动平均.py
@ -1,42 +0,0 @@
-import pandas as pd
-
-df = pd.read_excel(r'C:\Users\鸽子\Desktop\浙江电量20231202.xlsx', sheet_name=2)
-df['stat_date'] = pd.to_datetime(df['stat_date'])
-
-
-# 移动平均
-city = df['city_name'].iloc[0]
-print(city)
-df_city1 = df[df['city_name'] == city].set_index('stat_date').loc['2023-11']
-
-dict_big = {}
-dict_ok = {}
-resut_df = pd.DataFrame({})
-index_industry = []
-tq_list = []
-pred_list = []
-loss_list = []
-rate_list = []
-for industry in df_city1.columns[1:]:
-    index_industry.append(industry)
-
-    df_moving_avg = pd.DataFrame(df_city1[:-3][industry], index=df_city1[:-3].index)
-    future = pd.date_range(start=df_city1.index[-3], periods=3, freq='D')
-
-    for date in future:
-        df_moving_avg.loc[date, industry] = df_moving_avg[-3:].mean().values
-    loss = (df_city1[industry].tail(-3).sum() - df_moving_avg.tail(-3).sum()) / df_city1[industry].sum()
-    tq_list.append(df_city1[industry].sum())
-    pred_list.append(df_moving_avg[industry].sum())
-    loss_list.append(df_city1[industry].sum()-df_moving_avg[industry].sum())
-    rate_list.append((df_city1[industry].sum()-df_moving_avg[industry].sum())/df_city1[industry].sum())
-resut_df = pd.DataFrame({'同期电量':tq_list,'预测电量':pred_list,'偏差':loss_list,'偏差率':rate_list},index=index_industry)
-print(resut_df)
-resut_df.to_excel(r'C:\Users\鸽子\Desktop\移动平均_丽水_行业.xlsx')
-
-#     if loss.values >= 0.005:
-#         dict_big[industry] = loss.values[0]
-#     else:
-#         dict_ok[industry] = loss.values[0]
-# print(len(dict_ok))
-# print(len(dict_big))
--- a/浙江行业电量/行业_移动平均.py
+++ b/浙江行业电量/行业_移动平均.py
@ -0,0 +1,49 @@
+import pandas as pd
+
+df = pd.read_excel(r'C:\Users\鸽子\Desktop\浙江power1225.xlsx', sheet_name=2)
+df['stat_date'] = pd.to_datetime(df['stat_date'])
+
+# 移动平均
+for city in df['city_name'].drop_duplicates():
+
+    print(city)
+    df_city = df[df['city_name'] == city].set_index('stat_date').loc['2023-12']
+
+    dict_big = {}
+    dict_ok = {}
+    resut_df = pd.DataFrame({})
+    index_industry = []
+    tq_list = []
+    pred_list = []
+    loss_list = []
+    rate_list = []
+
+    for industry in df_city.columns[2:]:
+        # index_industry.append(industry)
+        df_moving_avg = pd.DataFrame(df_city[industry], index=df_city.index)
+        future = pd.date_range(start='2023-12-26', periods=5, freq='D')
+
+        for date in future:
+            df_moving_avg.loc[date, industry] = df_moving_avg[-3:].mean().values
+        resut_df = pd.concat([resut_df, df_moving_avg], axis=1)
+        print(city[4:6])
+        print(resut_df)
+        # loss = (df_city1[industry].tail(-3).sum() - df_moving_avg.tail(-3).sum()) / df_city1[industry].sum()
+        # tq_list.append(df_city1[industry].sum())
+        # pred_list.append(df_moving_avg[industry].sum())
+        # loss_list.append(df_city1[industry].sum()-df_moving_avg[industry].sum())
+        # rate_list.append((df_city1[industry].sum()-df_moving_avg[industry].sum())/df_city1[industry].sum())
+    with pd.ExcelWriter(r'C:\Users\鸽子\Desktop\行业电量预测_1227.xlsx', mode='a', if_sheet_exists='replace',
+                        engine='openpyxl') as writer:
+        resut_df.to_excel(writer, sheet_name=f'{city[4:6]}')
+
+# resut_df = pd.DataFrame({'同期电量':tq_list,'预测电量':pred_list,'偏差':loss_list,'偏差率':rate_list},index=index_industry)
+# print(resut_df)
+# resut_df.to_excel(r'C:\Users\鸽子\Desktop\移动平均_丽水_行业.xlsx')
+
+#     if loss.values >= 0.005:
+#         dict_big[industry] = loss.values[0]
+#     else:
+#         dict_ok[industry] = loss.values[0]
+# print(len(dict_ok))
+# print(len(dict_big))