|
|
- import tensorflow as tf
- import pandas as pd
- import numpy as np
-
-
- def time_series_sigmoid_classification(X, Y, k, n0, x_columns, y_columns):
- inp = X[x_columns]
- out = Y[y_columns]
- col = "day"
- x = []
- y = []
- input_shape = 0
- output_shape = 0
- for player in Y["playerID"].unique():
- XPlayer = inp[inp["playerID"] == player]
- YPlayer = out[out["playerID"] == player]
- for day in YPlayer[col][n0 - 1:]:
- prev = day - k
- xprev = XPlayer[XPlayer[col] == prev].drop(columns=[col]).to_numpy()
- if xprev.shape[0] != 1:
- continue
- else:
- xprev = xprev[0, :]
- yt = YPlayer[YPlayer[col] == day].drop(columns=[col]).to_numpy()[0, :]
- if input_shape == 0:
- input_shape = xprev.shape[0]
- else:
- if input_shape != xprev.shape[0]:
- print("INCONSISTENT INPUT DIMENSION")
- exit(2)
- if input_shape == 0:
- output_shape = yt.shape[0]
- else:
- if output_shape != yt.shape[0]:
- print("INCONSISTENT OUTPUT DIMENSION")
- exit(2)
- x.append(xprev)
- y.append(yt)
- x = np.array(x)
- y = np.array(y)
- model = tf.keras.Sequential([
- tf.keras.layers.Flatten(input_shape=input_shape),
- tf.keras.layers.Dense(output_shape, activation=tf.nn.softmax)
- ])
- model.compile(optimizer='adam', loss='sparse_categorical_crossentropy', metrics=['accuracy', 'categorical_accuracy'])
- model.fit(x, y, epochs=100)
- loss, accuracy = model.evaluate(x, y)
- print(loss, accuracy)
- return model.get_weights()
-
-
- def time_series_sigmoid_classification(X, Y, k, n0, x_columns, y_columns):
- inp = X[x_columns]
- out = Y[y_columns]
- col = "day"
- x = []
- y = []
- input_shape = 0
- output_shape = 0
- for player in Y["playerID"].unique():
- XPlayer = inp[inp["playerID"] == player]
- YPlayer = out[out["playerID"] == player]
- for day in YPlayer[col][n0 - 1:]:
- prev = day - k
- xprev = XPlayer[XPlayer[col] == prev].drop(columns=[col]).to_numpy()
- if xprev.shape[0] != 1:
- continue
- else:
- xprev = xprev[0, :]
- yt = YPlayer[YPlayer[col] == day].drop(columns=[col]).to_numpy()[0, :]
- if input_shape == 0:
- input_shape = xprev.shape[0]
- else:
- if input_shape != xprev.shape[0]:
- print("INCONSISTENT INPUT DIMENSION")
- exit(2)
- if input_shape == 0:
- output_shape = yt.shape[0]
- else:
- if output_shape != yt.shape[0]:
- print("INCONSISTENT OUTPUT DIMENSION")
- exit(2)
- x.append(xprev)
- y.append(yt)
- x = np.array(x)
- y = np.array(y)
- model = tf.keras.Sequential([
- tf.keras.layers.Flatten(input_shape=input_shape),
- tf.keras.layers.Dense(32),
- tf.keras.layers.Dense(output_shape, activation=tf.nn.softmax)
- ])
- model.compile(optimizer='adam', loss='sparse_categorical_crossentropy', metrics=['accuracy', 'categorical_accuracy'])
- model.fit(x, y, epochs=100)
- loss, accuracy = model.evaluate(x, y)
- print(loss, accuracy)
- return model.get_weights()
|