If you want to calculate this with your bare hands and the std lib, you can base your calculation on the following formula. This is only valid for two points on the upper half of the ellipse because of the `acos`

but we're going to use it with the angles directly.

The calculation consists in these steps:

- Start with the SVG data: start point, a ,b rotation, long arc, sweep, end point
- Rotate the coordinate system to match the horizontal axis of the ellipse.
- Solve a system of 4 equations with 4 unknowns to get the centre point and the angles corresponding to the start and end point
- Approximate the integral by a discreet sum over small segments. This is where you could use
`scipy.special.ellipeinc`

, as suggested in the comments.

Step 2 is easy, just use a rotation matrix (note the angle `rot`

is positive in the clockwise direction):

```
m = [
[math.cos(rot), math.sin(rot)],
[-math.sin(rot), math.cos(rot)]
]
```

Step 3 is very well explained in this answer. Note the value obtained for `a1`

is modulo pi because it is obtained with `atan`

. That means that you need to calculate the centre points for the two angles `t1`

and `t2`

and check they match. If they don't, add pi to `a1`

and check again.

Step 4 is quite straightforward. Divide the interval [`t1`

, `t2`

] into n segments, get the value of the function at the end of each segment, time it by the segment length and sum all this up. You can try refining this by taking the value of the function at the mid-point of each segment, but I'm not sure there is much benefit to that. The number of segments is likely to have more effect on the precision.

Here is a very rough Python version of the above (please bear with the ugly coding style, I was doing this on my mobile whilst traveling 🤓)

```
import math
PREC = 1E-6
# matrix vector multiplication
def transform(m, p):
return ((sum(x * y for x, y in zip(m_r, p))) for m_r in m)
# the partial integral function
def ellipse_part_integral(t1, t2, a, b, n=100):
# function to integrate
def f(t):
return math.sqrt(1 - (1 - a**2 / b**2) * math.sin(t)**2)
start = min(t1, t2)
seg_len = abs(t1 - t2) / n
return - b * sum(f(start + seg_len * (i + 1)) * seg_len for i in range(n))
def ellipse_arc_length(x1, y1, a, b, rot, large_arc, sweep, x2, y2):
if abs(x1 - x2) < PREC and abs(y1 - y2) < PREC:
return 0
# get rot in radians
rot = math.pi / 180 * rot
# get the coordinates in the rotated coordinate system
m = [
[math.cos(rot), math.sin(rot)],
[- math.sin(rot), math.cos(rot)]
]
x1_loc, y1_loc, x2_loc, y2_loc = *transform(m, (x1,y1)), *transform(m, (x2,y2))
r1 = (x1_loc - x2_loc) / (2 * a)
r2 = (y2_loc - y1_loc) / (2 * b)
# avoid division by 0 if both points have same y coord
if abs(r2) > PREC:
a1 = math.atan(r1 / r2)
else:
a1 = r1 / abs(r1) * math.pi / 2
if abs(math.cos(a1)) > PREC:
a2 = math.asin(r2 / math.cos(a1))
else:
a2 = math.asin(r1 / math.sin(a1))
# calculate the angle of start and end point
t1 = a1 + a2
t2 = a1 - a2
# calculate centre point coords
x0 = x1_loc - a * math.cos(t1)
y0 = y1_loc - b * math.sin(t1)
x0s = x2_loc - a * math.cos(t2)
y0s = y2_loc - b * math.sin(t2)
# a1 value is mod pi so the centres may not match
# if they don't, check a1 + pi
if abs(x0 - x0s) > PREC or abs(y0 - y0s) > PREC:
a1 = a1 + math.pi
t1 = a1 + a2
t2 = a1 - a2
x0 = x1_loc - a * math.cos(t1)
y0 = y1_loc - b * math.sin(t1)
x0s = x2_loc - a * math.cos(t2)
y0s = y2_loc - b * math.sin(t2)
# get the angles in the range [0, 2 * pi]
if t1 < 0:
t1 += 2 * math.pi
if t2 < 0:
t2 += 2 * math.pi
# increase minimum by 2 * pi for a large arc
if large_arc:
if t1 < t2:
t1 += 2 * math.pi
else:
t2 += 2 * math.pi
return ellipse_part_integral(t1, t2, a, b)
print(ellipse_arc_length(0, 0, 40, 40, 0, False, True, 80, 0))
```

The good news is that the sweep flag doesn't matter as long as you're just looking for the length of the arc.

I'm not 100% sure the modulo pi problem is handled correctly and the implementation above may have a few bugs.
Nevertheless, it gave me a good approximation of the length in the simple case of a half circle, so I dare calling it WIP. Let me know if this is worth pursuing, I can have a further look when I'll be seated at a computer. Or maybe someone can come up with a clean way of doing this in the meantime?

`scipy.special.ellipeinc`

, I presume? – hidefromkgb Nov 4 at 20:57`ellipenc`

by subtracting for phi1 and phi2. – fpbhb Nov 7 at 0:07