又出去和女朋友快乐的玩耍了,但是不要忘了学习噢。
在过去的时间里我们学习了RNN循环神经网络,其结构示意图是这样的:
其存在的最大问题是,当w1、w2、w3这些值小于0时,如果一句话够长,那么其在神经网络进行反向传播与前向传播时,存在梯度消失的问题。
0.925=0.07,如果一句话有20到30个字,那么第一个字的隐含层输出传递到最后,将会变为原来的0.07倍,相比于最后一个字的影响,大大降低。
其具体情况是这样的:
长短时记忆网络就是为了解决梯度消失的问题出现的。
原始RNN的隐藏层只有一个状态h,从头传递到尾,它对于短期的输入非常敏感。
如果我们再增加一个状态c,让它来保存长期的状态,问题就可以解决了。
对于RNN和LSTM而言,其两个step单元的对比如下。
我们把LSTM的结构按照时间维度展开:
我们可以看出,在n时刻,LSTM的输入有三个:
1、当前时刻网络的输入值;
2、上一时刻LSTM的输出值;
3、上一时刻的单元状态。
LSTM的输出有两个:
1、当前时刻LSTM输出值;
2、当前时刻的单元状态。
LSTM用两个门来控制单元状态cn的内容:
1、遗忘门(forget gate),它决定了上一时刻的单元状态cn-1有多少保留到当前时刻;
2、输入门(input gate),它决定了当前时刻网络的输入c’n有多少保存到单元状态。
LSTM用一个门来控制当前输出值hn的内容:
输出门(output gate),它决定了当前时刻单元状态cn有多少输出。
tf.contrib.rnn.BasicLSTMCell(
num_units,
forget_bias=1.0,
state_is_tuple=True,
activation=None,
reuse=None,
name=None,
dtype=None
)
在使用时,可以定义为:
lstm_cell = tf.contrib.rnn.BasicLSTMCell(self.cell_size, forget_bias=1.0, state_is_tuple=True)
在定义完成后,可以进行状态初始化:
self.cell_init_state = lstm_cell.zero_state(self.batch_size, dtype=tf.float32)
tf.nn.dynamic_rnn(
cell,
inputs,
sequence_length=None,
initial_state=None,
dtype=None,
parallel_iterations=None,
swap_memory=False,
time_major=False,
scope=None
)
在LSTM的最后,需要用该函数得出结果。
self.cell_outputs, self.cell_final_state = tf.nn.dynamic_rnn(
lstm_cell, self.l_in_y, initial_state=self.cell_init_state, time_major=False)
返回的是一个元组 (outputs, state):
outputs:LSTM的最后一层的输出,是一个tensor。如果为time_major== False,则它的shape为[batch_size,max_time,cell.output_size]。如果为time_major== True,则它的shape为[max_time,batch_size,cell.output_size]。
states:states是一个tensor。state是最终的状态,也就是序列中最后一个cell输出的状态。一般情况下states的形状为 [batch_size, cell.output_size],但当输入的cell为BasicLSTMCell时,states的形状为[2,batch_size, cell.output_size ],其中2也对应着LSTM中的cell state和hidden state。
整个LSTM的定义过程为:
def add_input_layer(self,):
#X最开始的形状为(256 batch,28 steps,28 inputs)
#转化为(256 batch*28 steps,128 hidden)
l_in_x = tf.reshape(self.xs, [-1, self.input_size], name='to_2D')
#获取Ws和Bs
Ws_in = self._weight_variable([self.input_size, self.cell_size])
bs_in = self._bias_variable([self.cell_size])
#转化为(256 batch*28 steps,256 hidden)
with tf.name_scope('Wx_plus_b'):
l_in_y = tf.matmul(l_in_x, Ws_in) + bs_in
# (batch * n_steps, cell_size) ==> (batch, n_steps, cell_size)
# (256*28,256)->(256,28,256)
self.l_in_y = tf.reshape(l_in_y, [-1, self.n_steps, self.cell_size], name='to_3D')
def add_cell(self):
#神经元个数
lstm_cell = tf.contrib.rnn.BasicLSTMCell(self.cell_size, forget_bias=1.0, state_is_tuple=True)
#每一次传入的batch的大小
with tf.name_scope('initial_state'):
self.cell_init_state = lstm_cell.zero_state(self.batch_size, dtype=tf.float32)
#不是主列
self.cell_outputs, self.cell_final_state = tf.nn.dynamic_rnn(
lstm_cell, self.l_in_y, initial_state=self.cell_init_state, time_major=False)
def add_output_layer(self):
#设置Ws,Bs
Ws_out = self._weight_variable([self.cell_size, self.output_size])
bs_out = self._bias_variable([self.output_size])
# shape = (batch,output_size)
# (256,10)
with tf.name_scope('Wx_plus_b'):
self.pred = tf.matmul(self.cell_final_state[-1], Ws_out) + bs_out
该例子为手写体识别例子,将手写体的28行分别作为每一个step的输入,输入维度均为28列。
import tensorflow as tf
from tensorflow.examples.tutorials.mnist import input_data
import numpy as np
mnist = input_data.read_data_sets("MNIST_data",one_hot = "true")
BATCH_SIZE = 256 # 每一个batch的数据数量
TIME_STEPS = 28 # 图像共28行,分为28个step进行传输
INPUT_SIZE = 28 # 图像共28列
OUTPUT_SIZE = 10 # 共10个输出
CELL_SIZE = 256 # RNN 的 hidden unit size,隐含层神经元的个数
LR = 1e-3 # learning rate,学习率
def get_batch(): #获取训练的batch
batch_xs,batch_ys = mnist.train.next_batch(BATCH_SIZE)
batch_xs = batch_xs.reshape([BATCH_SIZE,TIME_STEPS,INPUT_SIZE])
return [batch_xs,batch_ys]
class LSTMRNN(object): #构建LSTM的类
def __init__(self, n_steps, input_size, output_size, cell_size, batch_size):
self.n_steps = n_steps
self.input_size = input_size
self.output_size = output_size
self.cell_size = cell_size
self.batch_size = batch_size
#输入输出
with tf.name_scope('inputs'):
self.xs = tf.placeholder(tf.float32, [None, n_steps, input_size], name='xs')
self.ys = tf.placeholder(tf.float32, [None, output_size], name='ys')
#直接加层
with tf.variable_scope('in_hidden'):
self.add_input_layer()
#增加LSTM的cell
with tf.variable_scope('LSTM_cell'):
self.add_cell()
#直接加层
with tf.variable_scope('out_hidden'):
self.add_output_layer()
#计算损失值
with tf.name_scope('cost'):
self.compute_cost()
#训练
with tf.name_scope('train'):
self.train_op = tf.train.AdamOptimizer(LR).minimize(self.cost)
#正确率计算
self.correct_pre = tf.equal(tf.argmax(self.ys,1),tf.argmax(self.pred,1))
self.accuracy = tf.reduce_mean(tf.cast(self.correct_pre,tf.float32))
def add_input_layer(self,):
#X最开始的形状为(256 batch,28 steps,28 inputs)
#转化为(256 batch*28 steps,128 hidden)
l_in_x = tf.reshape(self.xs, [-1, self.input_size], name='to_2D')
#获取Ws和Bs
Ws_in = self._weight_variable([self.input_size, self.cell_size])
bs_in = self._bias_variable([self.cell_size])
#转化为(256 batch*28 steps,256 hidden)
with tf.name_scope('Wx_plus_b'):
l_in_y = tf.matmul(l_in_x, Ws_in) + bs_in
# (batch * n_steps, cell_size) ==> (batch, n_steps, cell_size)
# (256*28,256)->(256,28,256)
self.l_in_y = tf.reshape(l_in_y, [-1, self.n_steps, self.cell_size], name='to_3D')
def add_cell(self):
#神经元个数
lstm_cell = tf.contrib.rnn.BasicLSTMCell(self.cell_size, forget_bias=1.0, state_is_tuple=True)
#每一次传入的batch的大小
with tf.name_scope('initial_state'):
self.cell_init_state = lstm_cell.zero_state(self.batch_size, dtype=tf.float32)
#不是主列
self.cell_outputs, self.cell_final_state = tf.nn.dynamic_rnn(
lstm_cell, self.l_in_y, initial_state=self.cell_init_state, time_major=False)
def add_output_layer(self):
#设置Ws,Bs
Ws_out = self._weight_variable([self.cell_size, self.output_size])
bs_out = self._bias_variable([self.output_size])
# shape = (batch,output_size)
# (256,10)
with tf.name_scope('Wx_plus_b'):
self.pred = tf.matmul(self.cell_final_state[-1], Ws_out) + bs_out
def compute_cost(self):
self.cost = tf.reduce_mean(
tf.nn.softmax_cross_entropy_with_logits(logits = self.pred,labels = self.ys)
)
def _weight_variable(self, shape, name='weights'):
initializer = np.random.normal(0.0,1.0 ,size=shape)
return tf.Variable(initializer, name=name,dtype = tf.float32)
def _bias_variable(self, shape, name='biases'):
initializer = np.ones(shape=shape)*0.1
return tf.Variable(initializer, name=name,dtype = tf.float32)
if __name__ == '__main__':
#搭建 LSTMRNN 模型
model = LSTMRNN(TIME_STEPS, INPUT_SIZE, OUTPUT_SIZE, CELL_SIZE, BATCH_SIZE)
sess = tf.Session()
sess.run(tf.global_variables_initializer())
#训练10000次
for i in range(10000):
xs, ys = get_batch() #提取 batch data
if i == 0:
#初始化data
feed_dict = {
model.xs: xs,
model.ys: ys,
}
else:
feed_dict = {
model.xs: xs,
model.ys: ys,
model.cell_init_state: state #保持 state 的连续性
}
#训练
_, cost, state, pred = sess.run(
[model.train_op, model.cost, model.cell_final_state, model.pred],
feed_dict=feed_dict)
#打印精确度结果
if i % 20 == 0:
print(sess.run(model.accuracy,feed_dict = {
model.xs: xs,
model.ys: ys,
model.cell_init_state: state #保持 state 的连续性
}))
希望得到朋友们的喜欢。
有不懂的朋友可以评论询问噢。