This problem is well suited for rejection sampling.
Basically you randomly choose a point, and select if a connection should be made based on a defined probability. You have to take in account that there are many more points at further distance than at # closer distances (its number grows with radius), so maybe you have to introduce an extra weighing in the probability function. In this case I choose to use an exponential decay probability.

This code is not optimal in terms of speed, particularly for higher connectivity percents, but the ideas are better presented this way: see below for a better option.

```
import numpy as np
from numpy.random import default_rng
rng = default_rng()
board = np.zeros((100, 100), dtype=bool)
percent_connected = 4
N_points = round((board.size - 1) * percent_connected/100)
center = np.array((20, 30))
board[tuple(center)] = True # remove the center point from the pool
dist_char = 35 # characteristic distance where probability decays to 1/e
endpoints = []
while N_points:
point = rng.integers(board.shape)
if not board[tuple(point)]:
dist = np.sqrt(np.sum((center-point)**2))
P = np.exp(-dist / dist_char)
if rng.random() < P:
board[tuple(point)] = True
endpoints.append(point)
N_points -= 1
board[tuple(center)] = False # clear the center point
# Graphical test
import matplotlib.pyplot as plt
plt.figure()
for ep in endpoints:
plt.plot(*zip(center, ep), c="blue")
```

A slightly faster approach is much faster at higher connectivity:

```
rng = default_rng()
board = np.zeros((100, 100), dtype=bool)
percent_connected = 4
N_points = round((board.size - 1) * percent_connected/100)
center = np.array((20, 30))
board[tuple(center)] = True # remove the center point from the pool
dist_char = 35 # characteristic distance where probability decays to 1/e
flat_board = board.ravel()
endpoints = []
while N_points:
idx = rng.integers(flat_board.size)
while flat_board[idx]:
idx += 1
if idx >= flat_board.size:
idx = 0
if not flat_board[idx]:
point = np.array((idx // board.shape[0], idx % board.shape[0]))
dist = np.sqrt(np.sum((center-point)**2))
P = np.exp(-dist / dist_char)
if rng.random() < P:
flat_board[idx] = True
endpoints.append(point)
N_points -= 1
board[tuple(center)] = False # clear the center point
plt.figure()
for ep in endpoints:
plt.plot(*zip(center, ep), c="blue")
```