在实际的神经网络搭建过程中,前向传播是比较容易实现的,正确性较高;而反向传播的实现是有一定难度的,时常会出现bug。对于准确性要求很高的项目,梯度检验尤为重要。
梯度检验的原理
数学中对导数(梯度)的定义是
∂ J ∂ θ = lim ε → 0 J ( θ + ε ) − J ( θ − ε ) 2 ε \frac{\partial J}{\partial \theta} =\lim_{\varepsilon \to 0} \frac{J(\theta + \varepsilon) - J(\theta - \varepsilon)}{2\varepsilon} ∂θ∂J=ε→0lim2εJ(θ+ε)−J(θ−ε)
我们需要验证反向传播计算得到的 ∂ J ∂ θ \frac{\partial J}{\partial \theta} ∂θ∂J是否准确,就可以用另一种方式,即上述的公式,利用前向传播分别计算出 J ( θ + ε ) J(\theta + \varepsilon) J(θ+ε)和 J ( θ − ε ) J(\theta - \varepsilon) J(θ−ε)来求得 ∂ J ∂ θ \frac{\partial J}{\partial \theta} ∂θ∂J,验证它是否与反向传播计算得到的一样。
梯度检验的Python实现
我们简单构建一个3层神经网络,如下图所示
def gradient_check_n_test_case():
np.random.seed(1)
x = np.random.randn(4,3)
y = np.array([1, 1, 0])
W1 = np.random.randn(5,4)
b1 = np.random.randn(5,1)
W2 = np.random.randn(3,5)
b2 = np.random.randn(3,1)
W3 = np.random.randn(1,3)
b3 = np.random.randn(1,1)
parameters = {
"W1": W1,
"b1": b1,
"W2": W2,
"b2": b2,
"W3": W3,
"b3": b3}
return x, y, parameters
分别实现其前向传播和反向传播(反向传播故意加了两处错误)
def forward_propagation_n(X, Y, parameters):
m = X.shape[1]
W1 = parameters["W1"]
b1 = parameters["b1"]
W2 = parameters["W2"]
b2 = parameters["b2"]
W3 = parameters["W3"]
b3 = parameters["b3"]
# RELU -> RELU -> SIGMOID
Z1 = np.dot(W1, X) + b1
A1 = relu(Z1)
Z2 = np.dot(W2, A1) + b2
A2 = relu(Z2)
Z3 = np.dot(W3, A2) + b3
A3 = sigmoid(Z3)
logprobs = np.multiply(-np.log(A3), Y) + np.multiply(-np.log(1 - A3), 1 - Y)
cost = 1. / m * np.sum(logprobs)
cache = (Z1, A1, W1, b1, Z2, A2, W2, b2, Z3, A3, W3, b3)
return cost, cache
def backward_propagation_n(X, Y, cache):
m = X.shape[1]
(Z1, A1, W1, b1, Z2, A2, W2, b2, Z3, A3, W3, b3) = cache
dZ3 = A3 - Y
dW3 = 1. / m * np.dot(dZ3, A2.T)
db3 = 1. / m * np.sum(dZ3, axis=1, keepdims=True)
dA2 = np.dot(W3.T, dZ3)
dZ2 = np.multiply(dA2, np.int64(A2 > 0))
dW2 = 1. / m * np.dot(dZ2, A1.T) * 2 # 错误1
db2 = 1. / m * np.sum(dZ2, axis=1, keepdims=True)
dA1 = np.dot(W2.T, dZ2)
dZ1 = np.multiply(dA1, np.int64(A1 > 0))
dW1 = 1. / m * np.dot(dZ1, X.T)
db1 = 4. / m * np.sum(dZ1, axis=1, keepdims=True) # 错误2
gradients = {
"dZ3": dZ3, "dW3": dW3, "db3": db3,
"dA2": dA2, "dZ2": dZ2, "dW2": dW2, "db2": db2,
"dA1": dA1, "dZ1": dZ1, "dW1": dW1, "db1": db1}
return gradients
我们通过一维列向量 g r a d a p p r o x gradapprox gradapprox保存通过前向传播获得的梯度,其每一个元素都对应着一个参数的梯度。再通过反向传播的梯度列向量 g r a d grad grad与其进行对比,判断误差是否过大。
计算对比的公式为
d i f f e r e n c e = ∥ g r a d − g r a d a p p r o x ∥ 2 ∥ g r a d ∥ 2 + ∥ g r a d a p p r o x ∥ 2 difference = \frac{\left \|grad - gradapprox \right \| _2}{\left \|grad \right \| _2+\left \|gradapprox \right \| _2} difference=∥grad∥2+∥gradapprox∥2∥grad−gradapprox∥2
其中计算矩阵的范数使用numpy的norm函数。
def gradient_check_n(parameters, gradients, X, Y, epsilon=1e-7):
parameters_values, _ = dictionary_to_vector(parameters)
grad = gradients_to_vector(gradients)
num_parameters = parameters_values.shape[0]
J_plus = np.zeros((num_parameters, 1))
J_minus = np.zeros((num_parameters, 1))
gradapprox = np.zeros((num_parameters, 1))
# 计算gradapprox
for i in range(num_parameters):
thetaplus = np.copy(parameters_values)
thetaplus[i][0] = thetaplus[i][0] + epsilon
J_plus[i], _ = forward_propagation_n(X, Y, vector_to_dictionary(thetaplus))
thetaminus = np.copy(parameters_values)
thetaminus[i][0] = thetaminus[i][0] - epsilon
J_minus[i], _ = forward_propagation_n(X, Y, vector_to_dictionary(thetaminus))
gradapprox[i] = (J_plus[i] - J_minus[i]) / (2 * epsilon)
numerator = np.linalg.norm(grad - gradapprox)
denominator = np.linalg.norm(grad) + np.linalg.norm(gradapprox)
difference = numerator / denominator
if difference < 2e-7:
print("backward propagation is wrong! difference = " + str(difference))
else:
print("backward propagation is right! difference = " + str(difference))
return difference
运行结果如下
X, Y, parameters = gradient_check_n_test_case()
cost, cache = forward_propagation_n(X, Y, parameters)
gradients = backward_propagation_n(X, Y, cache)
difference = gradient_check_n(parameters, gradients, X, Y)
关于本实验完整代码详见:
https://github.com/PPPerry/AI_projects/tree/main/6.gradient_check
提示
- 梯度检验是很缓慢的。使用近似公式来计算梯度非常消耗计算力。只在需要验证代码是否正确时才开启。确认代码没有问题后,就关闭掉梯度检验。
- 梯度检验是无法与dropout共存的。
往期人工智能系列实验:
人工智能系列实验(一)——用于识别猫的二分类单层神经网络
人工智能系列实验(二)——用于区分不同颜色区域的浅层神经网络
人工智能系列实验(三)——用于识别猫的二分类深度神经网络
人工智能系列实验(四)——多种神经网络参数初始化方法对比(Xavier初始化和He初始化)
人工智能系列实验(五)——正则化方法:L2正则化和dropout的Python实现