I need to non-linearly expand on each pixel value from 1 dim pixel vector with taylor series expansion of specific non-linear function (`e^x or log(x) or log(1+e^x)`

), but my current implementation is not right to me at least based on taylor series concepts. The basic intuition behind is taking pixel array as input neurons for a CNN model where each pixel should be non-linearly expanded with taylor series expansion of non-linear function.

**new update 1**:

From my understanding from taylor series, taylor series is written for a function `F`

of a variable `x`

in terms of the value of the function `F`

and it's derivatives in for another value of variable `x0`

. In my problem, `F`

is function of non-linear transformation of features (a.k.a, pixels), `x`

is each pixel value, `x0`

is maclaurin series approximation at 0.

**new update 2**

if we use taylor series of `log(1+e^x)`

with approximation order of 2, each pixel value will yield two new pixel by taking first and second expansion terms of taylor series.

**graphic illustration**

Here is the graphical illustration of the above formulation:

Where `X`

is pixel array, `p`

is approximation order of taylor series, and `α`

is the taylor expansion coefficient.

I wanted to non-linearly expand pixel vectors with taylor series expansion of non-linear function like above illustration demonstrated.

**My current attempt**

This is my current attempt which is not working correctly for pixel arrays. I was thinking about how to make the same idea applicable to pixel arrays.

```
def taylor_func(x, approx_order=2):
x_ = x[..., None]
x_ = tf.tile(x_, multiples=[1, 1, approx_order+ 1])
pows = tf.range(0, approx_order + 1, dtype=tf.float32)
x_p = tf.pow(x_, pows)
x_p_ = x_p[..., None]
return x_p_
x = Input(shape=(4,4,3))
x_new = Lambda(lambda x: taylor_func(x, max_pow))(x)
```

**my new updated attempt**:

```
x_input= Input(shape=(32, 32,3))
def maclurin_exp(x, powers=2):
out= 0
for k in range(powers):
out+= ((-1)**k) * (x ** (2*k)) / (math.factorial(2 * k))
return res
x_input_new = Lambda(lambda x: maclurin_exp(x, max_pow))(x_input)
```

This attempt doesn't yield what the above mathematical formulation describes. I bet I missed something while doing the expansion. Can anyone point me on how to make this correct? Any better idea?

**goal**

I wanted to take pixel vector and make non-linearly distributed or expanded with taylor series expansion of certain non-linear function. Is there any possible way to do this? any thoughts? thanks

`N`

by`M`

with pixel values`x[i]`

by a concatenated array of a size`pN`

by`M`

with blocks of elements of a form`x[i]**k`

, with`k=1...p`

, and`p`

as a truncation power of Taylor series? – Aramakus Jul 10 '20 at 14:36`F`

of a variable`x`

in terms of the value of the function`F`

and it's derivatives in for another value of variable`x0`

. So it is unclear to me what is the function and what is the variable when you say`expand pixel vector with Taylor series expansion`

. Does the function represent the value of the pixel, while the variable are its coordinates in a 2D array (discrete values)? – Aramakus Jul 11 '20 at 0:40`function is Taylor expansion of non-linear function`

. Consider a simple power 2 truncated Taylor series, as it is in your original post`F(x) = F(x0) + F'(x0)*(x-x0) + 0.5*F''(x0)*(x-x0)**2`

. What`F`

,`x`

and`x0`

are here? If`x`

is the original image, then what`x0`

is? – Aramakus Jul 11 '20 at 1:375more comments