## Function to Sample Uniformly from a Hypersphere

The function below uniformly samples points from a hypersphere:

```
import numpy as np
def sample(center, radius, n_samples, seed=None):
# initial values
d = center.shape[0]
# sample n_samples points in d dimensions from a standard normal distribution
rng = np.random.default_rng(seed)
samples = rng.normal(size=(n_samples, d))
# make the samples lie on the surface of the unit hypersphere
normalize_radii = np.linalg.norm(samples, axis=1)[:, np.newaxis]
samples /= normalize_radii
# make the samples lie inside the hypersphere with the correct density
uniform_points = rng.uniform(size=n_samples)[:, np.newaxis]
new_radii = np.power(uniform_points, 1/d)
samples *= new_radii
# scale the points to have the correct radius and center
samples = samples * radius + center
return samples
```

This code works as follows.

First, it first generates `n`

datapoints in `d`

dimensions from a standard normal distribution. We specifically sample from a normal distribution because normal distributions are isotropic, meaning it is uniform in all orientations. This works great for creating a hypersphere where must be uniform/the same in all orientations.

Second, it computes the radius of each datapoint with `np.linalg.norm()`

. (Note: `np.linalg.norm()`

calls the Euclidean norm which equals the radius because r^2 = x^2 + y^2 in 2D and more generally r^2 = \sum_{i=1}^d x_i^2 which is the equation for Euclidean distance.) It divides each point by its radius to normalize the radius to length 1. This is equivalent to making all the datapoints lie on the surface of the unit hypersphere with radius `r=1`

.

Third, it creates a new radius for each of the `n_samples`

datapoints by generating `n_samples`

points from a uniform distribution and then taking the `d`

th root of each of these points. Why do we do this? Consider the 2D case where we want to sample points uniformly on a circle. If we divide this circle into concentric rings, then the ring right by the circle's center will have few points on it while the ring by the circumference will have many more points on it. More generally, the larger the radius, the more points we will need to generate. More precisely, achieving uniform sampling across radii of varying lengths requires a probability distribution proportional to the D-th power of the radius r. We can express this as `F(r) \alpha r^d`

where `F(r)`

is the number of points radius `r`

away from the origin that give us a uniform distribution. We begin with a uniform distribution of points in `uniform_points`

and can rearrange the equation above as `F(r)^{1\d} \alpha r`

, meaning we must take the `d`

th root of the uniformly distributed radii.

Fourth, this code scales all the points on the surface of the unit hypersphere by this new radius, distributing these points uniformly across the volume of the hypersphere. It then shifts these points over to have the desired `center`

.

## Function Performance

My code is much faster than @Daniel's code which relies upon `scipy`

's `gammainc`

function which is quite expensive to evaluate. I benchmark the performance here:

```
def time_it():
# initial values
d = 20
center, radius = np.full(d, 2), 3
n_samples_list = np.logspace(3, 6, num=10).astype(int)
runtime_my_code, runtime_daniel_code = [], []
for n_samples in n_samples_list:
# time my code
start = time.perf_counter()
sample_hypersphere_uniformly(center, radius, n_samples)
end = time.perf_counter()
duration = end - start
runtime_my_code.append(duration)
# time Daniel's code
start = time.perf_counter()
daniels_code(center, radius, n_samples)
end = time.perf_counter()
duration = end - start
runtime_daniel_code.append(duration)
# plot the results
fig, ax = plt.subplots()
ax.scatter(n_samples_list, runtime_my_code)
ax.scatter(n_samples_list, runtime_daniel_code)
ax.plot(n_samples_list, runtime_my_code, label='my code')
ax.plot(n_samples_list, runtime_daniel_code, label='daniel\'s code')
ax.set(xlabel='n_samples',
ylabel='runtime (s)', title='runtime VS n_samples')
plt.legend()
fig.savefig('runtime_vs_n_samples.png')
```

This diagram makes it clear that my code is much more efficient than Daniel's.

## Other resources

Check out this helpful guide to sampling from a hypersphere here. It clearly explains why this math works.