I am new at neural networks. I tried to create a neural network that predicts the values I give using GEKKO. However, even though the code works I am not able to obtain an accurate prediction.

Additionally, are 6 data point enough to create a neural network?

Can please someone help? Code can be found below

```
from gekko import GEKKO
import numpy as np
import matplotlib.pyplot as plt
x_m = 0.0,24.0,72.0,96.0,120.0,144.0
y_m = (0.023027367, 0.02636238, 0.024316255, 0.001705467, -0.004823068, -0.016863735)
x = np.array(x_m)
y = np.array(y_m)
# option for fitting function
# =============================================================================
# Size with hyperbolic tangent function
nin = 1 # inputs
n1 = 2 # hidden layer 1 (linear)
n2 = 3 # hidden layer 2 (nonlinear)
n3 = 2 # hidden layer 3 (linear)
nout = 1 # outputs
#
# =============================================================================
# Initialize gekko
train = GEKKO()
test = GEKKO()
model = [train,test]
for m in model:
# input(s)
m.inpt = m.Param()
# layer 1
m.w1 = m.Array(m.FV, (nin,n1))
m.l1 = [m.Intermediate(m.w1[0,i]*m.inpt) for i in range(n1)]
# layer 2
m.w2a = m.Array(m.FV, (n1,n2))
m.w2b = m.Array(m.FV, (n1,n2))
m.l2 = [m.Intermediate(sum([m.tanh(m.w2a[j,i]+m.w2b[j,i]*m.l1[j]) \
for j in range(n1)])) for i in range(n2)]
# layer 3
m.w3 = m.Array(m.FV, (n2,n3))
m.l3 = [m.Intermediate(sum([m.w3[j,i]*m.l2[j] \
for j in range(n2)])) for i in range(n3)]
# output(s)
m.outpt = m.CV()
m.Equation(m.outpt==sum([m.l3[i] for i in range(n3)]))
# flatten matrices
m.w1 = m.w1.flatten()
m.w2a = m.w2a.flatten()
m.w2b = m.w2b.flatten()
m.w3 = m.w3.flatten()
# Fit parameter weights
m = train
m.inpt.value=x
m.outpt.value=y
m.outpt.FSTATUS = 1
for i in range(len(m.w1)):
m.w1[i].FSTATUS=1
m.w1[i].STATUS=1
m.w1[i].MEAS=1.0
for i in range(len(m.w2a)):
m.w2a[i].STATUS=1
m.w2b[i].STATUS=1
m.w2a[i].FSTATUS=1
m.w2b[i].FSTATUS=1
m.w2a[i].MEAS=1.0
m.w2b[i].MEAS=0.5
for i in range(len(m.w3)):
m.w3[i].FSTATUS=1
m.w3[i].STATUS=1
m.w3[i].MEAS=1.0
m.options.IMODE = 2
m.options.SOLVER = 3
m.options.EV_TYPE = 2
m.solve(disp=False)
# Test sample points
m = test
for i in range(len(m.w1)):
m.w1[i].MEAS=train.w1[i].NEWVAL
m.w1[i].FSTATUS = 1
print('w1['+str(i)+']: '+str(m.w1[i].MEAS))
for i in range(len(m.w2a)):
m.w2a[i].MEAS=train.w2a[i].NEWVAL
m.w2b[i].MEAS=train.w2b[i].NEWVAL
m.w2a[i].FSTATUS = 1
m.w2b[i].FSTATUS = 1
print('w2a['+str(i)+']: '+str(m.w2a[i].MEAS))
print('w2b['+str(i)+']: '+str(m.w2b[i].MEAS))
for i in range(len(m.w3)):
m.w3[i].MEAS=train.w3[i].NEWVAL
m.w3[i].FSTATUS = 1
print('w3['+str(i)+']: '+str(m.w3[i].MEAS))
m.inpt.value= np.linspace(0,140)
m.options.IMODE = 2
m.options.SOLVER = 3
m.solve(disp=True)
plt.figure()
plt.plot(x,y,'bo', label = 'measured')
plt.plot(test.inpt.value,test.outpt.value,'r-', label = 'predicted')
plt.legend()
plt.show()
```

Here's the output: