optim.py-使用tensorflow实现一般优化算法
optim.py
Project URL:https://github.com/Codsir/optim.git
Based on: tensorflow, numpy, copy, inspect
Why Tensorflow?
Tensorflow supports symbol computation well like Automatic derivation and the program
could be excuted with GPU, which will save our time.
dogleg(p_u, p_b, delta, tau = 2)
The Dogleg method to solve the subproblems of trust region method
getGrad(f, x_value)
Get the gradient of function f with tf.gradients()
f= lambda x:100*(x[1]-x[0]**2)**2 + (1-x[0])**2
x_value = [1.0,2.0]
f_gradients = getGrad(f, x_value)
getHess(f, x_value)
Get the Hessian matrix of f with tf.hessian
TrustRegion_dogleg(f, delta = 0.5, eta = 0, *x_0, tolerance= 0.0001)
Trust region method with subproblems solved by the Dogleg method
ExactLineSearch_quadratic(f, x_k, p_k)
Exact line search method when the target function is quadratic
QuasiNewton(f, *x_0, HUpdateMethod = 'BFGS', LineSearch = ExactLineSearch_quadratic, tolerance = 0.0001)
quasi-Newton method
PenaltySimple(f, c_eq, c_leq, epsilon)
f is the target function, c_eq is a list contains equation constraints,
c_leq is a list contains unequal constrains, epsilon is the terminal parameter
these functions could be function name or anonymous functions, which defined by 'lambda'
The subproblem is solved by Newton Method, but it will be modified in the future because sometimes it's hard to compute the inverse matrix of Hessian matrix.
Example
Demo 1:trust region method with subproblems solved by the Dogleg method
f = lambda x:100*(x[1]-x[0]**2)**2 + (1-x[0])**2
f.paraLength = 2 ## 这一步不可缺少
x_k, f_k = TrustRegion_dogleg(f, delta = 10)
Demo 2:quasi-Newton method demo
print('Demo 2:quasi-Newton method demo')
f = lambda x:x[0]**2 + 2 * x[1]**2
f.paraLength = 2
x_0 = np.array([1, 1])
x_k, f_k = QuasiNewton(f, x_0)
Demo 3:penalty function method demo
print('Demo 3:penalty function method demo')
f = lambda x:x[0] + x[1]
f.paraLength = 2
c_eq = [lambda x:x[0]**2 + x[1]**2 - 2]
c_leq = []
x_k, f_k = PenaltySimple(f, c_eq, c_leq, [-3,-4])
