You choose the optimization algorithm Resilient Backpropagation (Rprop) in this line:

```
fann_set_training_algorithm(ann, FANN_TRAIN_RPROP);
```

Rprop is a **batch update** algorithm. This means you have to present the whole training set for each update. The documentation for fann_train says

This training is always incremental training (see fann_train_enum), since only one pattern is presented.

So the appropriate optimization option would be `FANN_TRAIN_INCREMENTAL`

. You have to use one of these methods for batch learning: `fann_train_on_data`

, `fann_train_on_file`

or `fann_train_epoch`

.

What I noticed when I changed your code was:

- Your steepness is too high. I used the default value (0.5).
- You have too few training epochs. I use about 20,000.
- Your function is too complex for only 3 hidden neurons. It is not easy at all because it is a periodic function. So I changed the range of the sine function I approximated to [0,3] which is much simpler.
- The bit fail limit is too hard. :) I set it to
`0.02f`

.
- Rprop is not a very good training algorithm, they should implement something like Levenberg-Marquardt, which is much faster.

The solution I got is not perfect but it is at least approximately correct:

```
0 0.060097 0.000000
1 0.119042 0.099833
2 0.188885 0.198669
3 0.269719 0.295520
4 0.360318 0.389418
5 0.457665 0.479426
6 0.556852 0.564642
7 0.651718 0.644218
8 0.736260 0.717356
9 0.806266 0.783327
10 0.860266 0.841471
11 0.899340 0.891207
12 0.926082 0.932039
...
```

I used this modified code:

```
#include <cstdio>
#include <cmath>
#include <fann.h>
#include <floatfann.h>
int main()
{
const unsigned int num_input = 1;
const unsigned int num_output = 1;
const unsigned int num_layers = 3;
const unsigned int num_neurons_hidden = 2;
const float angleRange = 3.0f;
const float angleStep = 0.1;
int instances = (int)(angleRange/angleStep);
struct fann *ann;
ann = fann_create_standard(num_layers, num_input, num_neurons_hidden, num_output);
fann_set_activation_function_hidden(ann, FANN_SIGMOID_SYMMETRIC);
fann_set_activation_function_output(ann, FANN_SIGMOID_SYMMETRIC);
fann_set_train_stop_function(ann, FANN_STOPFUNC_BIT);
fann_set_bit_fail_limit(ann, 0.02f);
fann_set_training_algorithm(ann, FANN_TRAIN_INCREMENTAL);
fann_randomize_weights(ann, 0, 1);
fann_train_data *trainingSet;
trainingSet = fann_create_train(instances, 1, 1); // instances, input dimension, output dimension
float angle=0;
for(int instance=0; instance < instances; angle+=angleStep, instance++) {
trainingSet->input[instance][0] = angle;
trainingSet->output[instance][0] = sinf(angle);
}
fann_train_on_data(ann, trainingSet, 20000, 10, 1e-8f); // epochs, epochs between reports, desired error
int k = 0;
angle=0;
for(int instance=0; instance < instances; angle+=angleStep, instance++) {
float sin_angle = sinf(angle);
float *o = fann_run(ann, &angle);
printf("%d\t%f\t%f\t\n", k++, *o, sin_angle);
}
fann_destroy(ann);
return 0;
}
```

Note that `fann_create_train`

is available since FANN 2.2.0.