# ウェイトごとのレイヤーウェイト制約を設定するには （How to set Layer weight constraints for each weight）

tc = args[0]　(1<args[0]<2)
m = args[1] (0<args[1]<1)

shape=(self.parameters, ),
initializer=self.initializer,
trainable=True,
constraint=max_norm(2))

としてしまうとすべてのweightに対して最大値が２の制約がかかってしまいます。

#Kerasオリジナルレイヤークラス
class CurveFit(Layer):
def __init__(self,
parameters: int,     # the number of parameters
# of our function
function: Callable,  # the function we want to fit
initializer='uniform', # how to initialize the
# parameters
**kwargs):
super().__init__(**kwargs)
self.parameters = parameters
self.function = function
self.initializer = initializer
#学習可能な重みを定義します。
def build(self, input_shape):
# Create a trainable weight variable for this layer.
shape=(self.parameters, ),
initializer=self.initializer,
trainable=True)

# Be sure to call this at the end
super().build(input_shape)
#Forwardの計算で行いたいことを実装します
def call(self, inputs, **kwargs):
# here we gonna invoke our function and return the result.
# the loss function will do whatever is needed to fit this
# function as good as possible by learning the parameters.
return self.function(inputs, self.kernel)
#出力のshapeを計算します。 作成したレイヤーの内部で入力のshapeを変更する場合には，
#ここでshape変換のロジックを指定します。
def compute_output_shape(self, input_shape):
return input_shape

class LPPLLayer(CurveFit):
# original model:
#  dt = tc - t
#  dtPm = dt ^ m
#  A + B * dtPm + C * dtPm * cos(w * ln(dt) - phi)
def __init__(self):
super().__init__(3, LPPLLayer.lppl, Constant(0.5))
def get_tc(self):
return self.get_weights()[0][0]
@staticmethod
def lppl(x, args):
N = K.constant(int(x.shape[-1]), dtype=x.dtype)
t = K.arange(0, int(x.shape[-1]), 1, dtype=x.dtype)
# note that we need to get the variables to be centered
# around 0 so to correct the magnitude we offset them by
# constants.
# w just has a mangitude of 10s from empirical results
# for tc we apply a factor of 20 which should be
# interpreted as a month (~20 trading days).
# A tc of 0.5 means half a month in the future
tc = args[0] * K.constant(20, dtype=x.dtype) + N
m = args[1]
w = args[2] * K.constant(10, dtype=x.dtype)
# then we calculate the lppl with the given parameters
dt = (tc - t)
dtPm = K.pow(dt, m)
dtln = K.log(dt)
abcc = LPPLLayer.matrix_equation(x, dtPm, dtln, w, N)
a, b, c1, c2 = (abcc[0], abcc[1], abcc[2], abcc[3])
return a + b * dtPm + c1 * dtPm * K.cos(w * dtln) + c2 *\
dtPm * K.sin(w * dtln)    # nothing to see here, this is just used to simplify the
# parameter space and fit for the LPPL function
@staticmethod
def matrix_equation(x, dtPm, dtln, w, N):
fi = dtPm
gi = dtPm * K.cos(w * dtln)
hi = dtPm * K.sin(w * dtln)
fi_pow_2 = K.sum(fi * fi)
gi_pow_2 = K.sum(gi * gi)
hi_pow_2 = K.sum(hi * hi)
figi = K.sum(fi * gi)
fihi = K.sum(fi * hi)
gihi = K.sum(gi * hi)
yi = x
yifi = K.sum(yi * fi)
yigi = K.sum(yi * gi)
yihi = K.sum(yi * hi)
fi = K.sum(fi)
gi = K.sum(gi)
hi = K.sum(hi)
yi = K.sum(yi)
A = K.stack([
K.stack([N, fi, gi, hi]),
K.stack([fi, fi_pow_2, figi, fihi]),
K.stack([gi, figi, gi_pow_2, gihi]),
K.stack([hi, fihi, gihi, hi_pow_2])
], axis=0)
b = K.stack([yi, yifi, yigi, yihi])        # do a classic x = (A'A)⁻¹A' b
return tf.linalg.solve(A, K.reshape(b, (4, 1)))