第87步 时间序列建模实战：LSTM回归建模

基于WIN10的64位系统演示

一、写在前面

这一期，我们介绍大名鼎鼎的LSTM回归。

同样，这里使用这个数据：

《PLoS One》2015年一篇题目为《Comparison of Two Hybrid Models for Forecasting the Incidence of Hemorrhagic Fever with Renal Syndrome in Jiangsu Province, China》文章的公开数据做演示。数据为江苏省2004年1月至2012年12月肾综合症出血热月发病率。运用2004年1月至2011年12月的数据预测2012年12个月的发病率数据。

二、LSTM回归

（1）LSTM简介

LSTM (Long Short-Term Memory) 是一种特殊的RNN（递归神经网络）结构，由Hochreiter和Schmidhuber在1997年首次提出。LSTM 被设计出来是为了避免长序列在训练过程中的长期依赖问题，这是传统 RNNs 所普遍遇到问题。

（a）LSTM 的主要特点：

（a1）三个门结构：LSTM 包含三个门结构：输入门、遗忘门和输出门。这些门决定了信息如何进入、被存储或被遗忘，以及如何输出。

（a2）记忆细胞：LSTM的核心是称为记忆细胞的结构。它可以保留、修改或访问的内部状态。通过门结构，模型可以学会在记忆细胞中何时存储、忘记或检索信息。

（a3）长期依赖问题：LSTM特别擅长学习、存储和使用长期信息，从而避免了传统RNN在长序列上的梯度消失问题。

（b）为什么LSTM适合时间序列建模：

（b1）序列数据的特性：时间序列数据具有顺序性，先前的数据点可能会影响后面的数据点。LSTM设计之初就是为了处理带有时间间隔、延迟和长期依赖关系的序列数据。

（b2）长期依赖：在时间序列分析中，某个事件可能会受到很早之前事件的影响。传统的RNNs由于梯度消失的问题，很难捕捉这些长期依赖关系。但是，LSTM结构可以有效地处理这种依赖关系。

（b3）记忆细胞：对于时间序列预测，能够记住过去的信息是至关重要的。LSTM的记忆细胞可以为模型提供这种存储和检索长期信息的能力。

（b4）灵活性：LSTM模型可以与其他神经网络结构（如CNN）结合，用于更复杂的时间序列任务，例如多变量时间序列或序列生成。

综上所述，由于LSTM的设计和特性，它非常适合时间序列建模，尤其是当数据具有长期依赖关系时。

（2）单步滚动预测

import pandas as pd
import numpy as np
from sklearn.metrics import mean_absolute_error, mean_squared_error
from tensorflow.python.keras.models import Sequential
from tensorflow.python.keras import layers, models, optimizers
from tensorflow.python.keras.optimizers import adam_v2

# 读取数据
data = pd.read_csv('data.csv')

# 将时间列转换为日期格式
data['time'] = pd.to_datetime(data['time'], format='%b-%y')

# 创建滞后期特征
lag_period = 6
for i in range(lag_period, 0, -1):
    data[f'lag_{i}'] = data['incidence'].shift(lag_period - i + 1)

# 删除包含 NaN 的行
data = data.dropna().reset_index(drop=True)

# 划分训练集和验证集
train_data = data[(data['time'] >= '2004-01-01') & (data['time'] <= '2011-12-31')]
validation_data = data[(data['time'] >= '2012-01-01') & (data['time'] <= '2012-12-31')]

# 定义特征和目标变量
X_train = train_data[['lag_1', 'lag_2', 'lag_3', 'lag_4', 'lag_5', 'lag_6']].values
y_train = train_data['incidence'].values
X_validation = validation_data[['lag_1', 'lag_2', 'lag_3', 'lag_4', 'lag_5', 'lag_6']].values
y_validation = validation_data['incidence'].values

# 对于LSTM，我们需要将输入数据重塑为 [samples, timesteps, features]
X_train = X_train.reshape(X_train.shape[0], X_train.shape[1], 1)
X_validation = X_validation.reshape(X_validation.shape[0], X_validation.shape[1], 1)

# 构建LSTM回归模型
input_layer = layers.Input(shape=(X_train.shape[1], 1))

x = layers.LSTM(50, return_sequences=True)(input_layer)
x = layers.LSTM(25, return_sequences=False)(x)
x = layers.Dropout(0.1)(x)
x = layers.Dense(25, activation='relu')(x)
x = layers.Dropout(0.1)(x)
output_layer = layers.Dense(1)(x)

model = models.Model(inputs=input_layer, outputs=output_layer)

model.compile(optimizer=adam_v2.Adam(learning_rate=0.001), loss='mse')

# 训练模型
history = model.fit(X_train, y_train, epochs=200, batch_size=32, validation_data=(X_validation, y_validation), verbose=0)

# 单步滚动预测函数
def rolling_forecast(model, initial_features, n_forecasts):
    forecasts = []
    current_features = initial_features.copy()

    for i in range(n_forecasts):
        # 使用当前的特征进行预测
        forecast = model.predict(current_features.reshape(1, len(current_features), 1)).flatten()[0]
        forecasts.append(forecast)

        # 更新特征，用新的预测值替换最旧的特征
        current_features = np.roll(current_features, shift=-1)
        current_features[-1] = forecast

    return np.array(forecasts)

# 使用训练集的最后6个数据点作为初始特征
initial_features = X_train[-1].flatten()

# 使用单步滚动预测方法预测验证集
y_validation_pred = rolling_forecast(model, initial_features, len(X_validation))

# 计算训练集上的MAE, MAPE, MSE 和 RMSE
mae_train = mean_absolute_error(y_train, model.predict(X_train).flatten())
mape_train = np.mean(np.abs((y_train - model.predict(X_train).flatten()) / y_train))
mse_train = mean_squared_error(y_train, model.predict(X_train).flatten())
rmse_train = np.sqrt(mse_train)

# 计算验证集上的MAE, MAPE, MSE 和 RMSE
mae_validation = mean_absolute_error(y_validation, y_validation_pred)
mape_validation = np.mean(np.abs((y_validation - y_validation_pred) / y_validation))
mse_validation = mean_squared_error(y_validation, y_validation_pred)
rmse_validation = np.sqrt(mse_validation)

print("验证集：", mae_validation, mape_validation, mse_validation, rmse_validation)
print("训练集：", mae_train, mape_train, mse_train, rmse_train)

看结果：

（3）多步滚动预测-vol. 1

import pandas as pd
import numpy as np
from sklearn.metrics import mean_absolute_error, mean_squared_error
import tensorflow as tf
from tensorflow.python.keras.models import Model
from tensorflow.python.keras.layers import Input, LSTM, Dense, Dropout, Flatten
from tensorflow.python.keras.optimizers import adam_v2

# 读取数据
data = pd.read_csv('data.csv')
data['time'] = pd.to_datetime(data['time'], format='%b-%y')

n = 6
m = 2

# 创建滞后期特征
for i in range(n, 0, -1):
    data[f'lag_{i}'] = data['incidence'].shift(n - i + 1)

data = data.dropna().reset_index(drop=True)

train_data = data[(data['time'] >= '2004-01-01') & (data['time'] <= '2011-12-31')]
validation_data = data[(data['time'] >= '2012-01-01') & (data['time'] <= '2012-12-31')]

# 准备训练数据
X_train = []
y_train = []

for i in range(len(train_data) - n - m + 1):
    X_train.append(train_data.iloc[i+n-1][[f'lag_{j}' for j in range(1, n+1)]].values)
    y_train.append(train_data.iloc[i+n:i+n+m]['incidence'].values)

X_train = np.array(X_train)
y_train = np.array(y_train)
X_train = X_train.astype(np.float32)
y_train = y_train.astype(np.float32)

# 构建LSTM模型
inputs = Input(shape=(n, 1))
x = LSTM(64, return_sequences=True)(inputs)
x = LSTM(32)(x)
x = Dense(50, activation='relu')(x)
x = Dropout(0.1)(x)
outputs = Dense(m)(x)

model = Model(inputs=inputs, outputs=outputs)

model.compile(optimizer=adam_v2.Adam(learning_rate=0.001), loss='mse')

# 训练模型
model.fit(X_train, y_train, epochs=200, batch_size=32, verbose=0)

def lstm_rolling_forecast(data, model, n, m):
    y_pred = []

    for i in range(len(data) - n):
        input_data = data.iloc[i+n-1][[f'lag_{j}' for j in range(1, n+1)]].values.astype(np.float32).reshape(1, n, 1)
        pred = model.predict(input_data)
        y_pred.extend(pred[0])

    for i in range(1, m):
        for j in range(len(y_pred) - i):
            y_pred[j+i] = (y_pred[j+i] + y_pred[j]) / 2

    return np.array(y_pred)

# Predict for train_data and validation_data
y_train_pred_lstm = lstm_rolling_forecast(train_data, model, n, m)[:len(y_train)]
y_validation_pred_lstm = lstm_rolling_forecast(validation_data, model, n, m)[:len(validation_data) - n]

# Calculate performance metrics for train_data
mae_train = mean_absolute_error(train_data['incidence'].values[n:len(y_train_pred_lstm)+n], y_train_pred_lstm)
mape_train = np.mean(np.abs((train_data['incidence'].values[n:len(y_train_pred_lstm)+n] - y_train_pred_lstm) / train_data['incidence'].values[n:len(y_train_pred_lstm)+n]))
mse_train = mean_squared_error(train_data['incidence'].values[n:len(y_train_pred_lstm)+n], y_train_pred_lstm)
rmse_train = np.sqrt(mse_train)

# Calculate performance metrics for validation_data
mae_validation = mean_absolute_error(validation_data['incidence'].values[n:len(y_validation_pred_lstm)+n], y_validation_pred_lstm)
mape_validation = np.mean(np.abs((validation_data['incidence'].values[n:len(y_validation_pred_lstm)+n] - y_validation_pred_lstm) / validation_data['incidence'].values[n:len(y_validation_pred_lstm)+n]))
mse_validation = mean_squared_error(validation_data['incidence'].values[n:len(y_validation_pred_lstm)+n], y_validation_pred_lstm)
rmse_validation = np.sqrt(mse_validation)

print("训练集：", mae_train, mape_train, mse_train, rmse_train)
print("验证集：", mae_validation, mape_validation, mse_validation, rmse_validation)

结果：

（4）多步滚动预测-vol. 2

import pandas as pd
import numpy as np
from sklearn.model_selection import train_test_split
from sklearn.metrics import mean_absolute_error, mean_squared_error
from tensorflow.python.keras.models import Sequential, Model
from tensorflow.python.keras.layers import Dense, LSTM, Input
from tensorflow.python.keras.optimizers import adam_v2

# Loading and preprocessing the data
data = pd.read_csv('data.csv')
data['time'] = pd.to_datetime(data['time'], format='%b-%y')

n = 6
m = 2

# 创建滞后期特征
for i in range(n, 0, -1):
    data[f'lag_{i}'] = data['incidence'].shift(n - i + 1)

data = data.dropna().reset_index(drop=True)

train_data = data[(data['time'] >= '2004-01-01') & (data['time'] <= '2011-12-31')]
validation_data = data[(data['time'] >= '2012-01-01') & (data['time'] <= '2012-12-31')]

# 只对X_train、y_train、X_validation取奇数行
X_train = train_data[[f'lag_{i}' for i in range(1, n+1)]].iloc[::2].reset_index(drop=True).values
X_train = X_train.reshape(X_train.shape[0], X_train.shape[1], 1)

y_train_list = [train_data['incidence'].shift(-i) for i in range(m)]
y_train = pd.concat(y_train_list, axis=1)
y_train.columns = [f'target_{i+1}' for i in range(m)]
y_train = y_train.iloc[::2].reset_index(drop=True).dropna().values[:, 0]

X_validation = validation_data[[f'lag_{i}' for i in range(1, n+1)]].iloc[::2].reset_index(drop=True).values
X_validation = X_validation.reshape(X_validation.shape[0], X_validation.shape[1], 1)

y_validation = validation_data['incidence'].values

# Building the LSTM model
inputs = Input(shape=(n, 1))
x = LSTM(50, activation='relu')(inputs)
x = Dense(50, activation='relu')(x)
outputs = Dense(1)(x)

model = Model(inputs=inputs, outputs=outputs)
optimizer = adam_v2.Adam(learning_rate=0.001)
model.compile(optimizer=optimizer, loss='mse')

# Train the model
model.fit(X_train, y_train, epochs=200, batch_size=32, verbose=0)

# Predict on validation set
y_validation_pred = model.predict(X_validation).flatten()

# Compute metrics for validation set
mae_validation = mean_absolute_error(y_validation[:len(y_validation_pred)], y_validation_pred)
mape_validation = np.mean(np.abs((y_validation[:len(y_validation_pred)] - y_validation_pred) / y_validation[:len(y_validation_pred)]))
mse_validation = mean_squared_error(y_validation[:len(y_validation_pred)], y_validation_pred)
rmse_validation = np.sqrt(mse_validation)

# Predict on training set
y_train_pred = model.predict(X_train).flatten()

# Compute metrics for training set
mae_train = mean_absolute_error(y_train, y_train_pred)
mape_train = np.mean(np.abs((y_train - y_train_pred) / y_train))
mse_train = mean_squared_error(y_train, y_train_pred)
rmse_train = np.sqrt(mse_train)

print("验证集：", mae_validation, mape_validation, mse_validation, rmse_validation)
print("训练集：", mae_train, mape_train, mse_train, rmse_train)

结果：

（5）多步滚动预测-vol. 3

import pandas as pd
import numpy as np
from sklearn.metrics import mean_absolute_error, mean_squared_error
from tensorflow.python.keras.models import Sequential, Model
from tensorflow.python.keras.layers import Dense, LSTM, Input
from tensorflow.python.keras.optimizers import adam_v2

# 数据读取和预处理
data = pd.read_csv('data.csv')
data_y = pd.read_csv('data.csv')
data['time'] = pd.to_datetime(data['time'], format='%b-%y')
data_y['time'] = pd.to_datetime(data_y['time'], format='%b-%y')

n = 6

for i in range(n, 0, -1):
    data[f'lag_{i}'] = data['incidence'].shift(n - i + 1)

data = data.dropna().reset_index(drop=True)
train_data = data[(data['time'] >= '2004-01-01') & (data['time'] <= '2011-12-31')]
X_train = train_data[[f'lag_{i}' for i in range(1, n+1)]]
m = 3

X_train_list = []
y_train_list = []

for i in range(m):
    X_temp = X_train
    y_temp = data_y['incidence'].iloc[n + i:len(data_y) - m + 1 + i]
    
    X_train_list.append(X_temp)
    y_train_list.append(y_temp)

for i in range(m):
    X_train_list[i] = X_train_list[i].iloc[:-(m-1)].values
    X_train_list[i] = X_train_list[i].reshape(X_train_list[i].shape[0], X_train_list[i].shape[1], 1)
    y_train_list[i] = y_train_list[i].iloc[:len(X_train_list[i])].values

# 模型训练
models = []
for i in range(m):
    # Building the LSTM model
    inputs = Input(shape=(n, 1))
    x = LSTM(50, activation='relu')(inputs)
    x = Dense(50, activation='relu')(x)
    outputs = Dense(1)(x)

    model = Model(inputs=inputs, outputs=outputs)
    optimizer = adam_v2.Adam(learning_rate=0.001)
    model.compile(optimizer=optimizer, loss='mse')
    model.fit(X_train_list[i], y_train_list[i], epochs=200, batch_size=32, verbose=0)
    models.append(model)

validation_start_time = train_data['time'].iloc[-1] + pd.DateOffset(months=1)
validation_data = data[data['time'] >= validation_start_time]
X_validation = validation_data[[f'lag_{i}' for i in range(1, n+1)]].values
X_validation = X_validation.reshape(X_validation.shape[0], X_validation.shape[1], 1)

y_validation_pred_list = [model.predict(X_validation) for model in models]
y_train_pred_list = [model.predict(X_train_list[i]) for i, model in enumerate(models)]

def concatenate_predictions(pred_list):
    concatenated = []
    for j in range(len(pred_list[0])):
        for i in range(m):
            concatenated.append(pred_list[i][j])
    return concatenated

y_validation_pred = np.array(concatenate_predictions(y_validation_pred_list))[:len(validation_data['incidence'])]
y_train_pred = np.array(concatenate_predictions(y_train_pred_list))[:len(train_data['incidence']) - m + 1]
y_validation_pred = y_validation_pred.flatten()
y_train_pred = y_train_pred.flatten()

mae_validation = mean_absolute_error(validation_data['incidence'], y_validation_pred)
mape_validation = np.mean(np.abs((validation_data['incidence'] - y_validation_pred) / validation_data['incidence']))
mse_validation = mean_squared_error(validation_data['incidence'], y_validation_pred)
rmse_validation = np.sqrt(mse_validation)

mae_train = mean_absolute_error(train_data['incidence'][:-(m-1)], y_train_pred)
mape_train = np.mean(np.abs((train_data['incidence'][:-(m-1)] - y_train_pred) / train_data['incidence'][:-(m-1)]))
mse_train = mean_squared_error(train_data['incidence'][:-(m-1)], y_train_pred)
rmse_train = np.sqrt(mse_train)

print("验证集：", mae_validation, mape_validation, mse_validation, rmse_validation)
print("训练集：", mae_train, mape_train, mse_train, rmse_train)

结果：

三、数据

链接：https://pan.baidu.com/s/1EFaWfHoG14h15KCEhn1STg?pwd=q41n

提取码：q41n