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I'm looking for a fast way to sample points on a spline such that a polygon or linestring through those points does not exceed a given chordal error to the original spline. I have an algorithm I wrote some time ago that produces the results in the picture (see code below if interested; I'm not expecting anyone to pore over it). It works OK, but fast it is not (~2 seconds on my computer to generate that graphic). Is there something easier, maybe built into numpy or scipy that will accomplish this?


enter image description here

import numpy as np
from scipy.optimize import brentq
from scipy.interpolate import splev

def get_rhos(ts, tck):
    """Get (signed) rhos (1/rad of curvature) for a given
    set of t values.
    tanvs = np.array(splev(ts, tck, der=1)).T
    accvs = np.array(splev(ts, tck, der=2)).T
    if tanvs.ndim == 1:
        tanvs = tanvs.reshape(1, -1)
        accvs = accvs.reshape(1, -1)

    crossp = np.cross(accvs, tanvs, axis=1)
    tanvms = np.array([np.sqrt(np.dot(v, v)) for v in tanvs])
    rhos = crossp / tanvms**3
    return rhos

def calc_rad(pt0, pt1, pt2, calcdrop=False):
    """Calculate a radius from three points on the arc.
    Lifted from http://www.physicsforums.com/showthread.php?t=173847
    pt0 = np.array(pt0)
    pt1 = np.array(pt1)
    pt2 = np.array(pt2)

    v0 = pt1 - pt0
    v1 = pt2 - pt0
    v2 = pt2 - pt1
    a = np.sqrt(np.dot(v0, v0))
    b = np.sqrt(np.dot(v1, v1))
    c = np.sqrt(np.dot(v2, v2))
    R = (a*b*c) / np.sqrt(  2 * a**2 * b**2
                          + 2 * b**2 * c**2
                          + 2 * c**2 * a**2
                          - a**4 - b**4 - c**4)
    if calcdrop:
        # Calculate arc drop
        drop = R - np.sqrt(R**2 - (b/2.)**2)
        return R, drop
        return R

def chordal_sample(tck, chordaltol, oversample=10):
    """Given a spline definition and a chordal tolerance
    (intol/outol), get the t-values for the spline such
    that, when adjacent points are connected, the chordal
    tolerance is not violated.

    Accomplishes this by bracketing a solution, then using
    the brentq solver to find the point where the chordal
    error equals the chordal tolerance.

    Note that a few extra points may be inserted where there
    are inflections in the cubic; these are sometimes missed
    by the arc-radius-calculating portion of the code.

    # This is the function we'll need when we have to
    # go searching for the answer via brentq
    def makeerrfunc(st, spt, tck, chordaltol):
        def errfunc(et):
            mt = (st + et) / 2.0
            mpt = np.array(splev(mt, tck))
            ept = np.array(splev(et, tck))
            _, arcdrop = calc_rad(spt, mpt, ept, calcdrop=True)
            diff = arcdrop - chordaltol
            return diff
        return errfunc

    # Make sure we're sampling enough points
    # TODO: How can we be sure?
    ts = np.linspace(0, 1, oversample * len(tck[1][0]))
    newts = [0]
    # Loop through the time values
    for nt in ts:
        st = newts[-1]
        rts = ts[ts > st] # Only consider remaining time values
        # Step through adjacent pairs of time values and find
        # ones that bracket the solution.
        for et0, et1 in zip(rts[0:-1], rts[1:]):
            # Get a 'middle time' that we can use to calc
            # a 'middle point' for our arc calculations
            mt0 = (st + et0) / 2.
            mt1 = (st + et1) / 2.

            # Interpolate points at the critical t values
            ipts = np.array(splev([st, mt0, et0, mt1, et1], tck))
            spt, mpt0, ept0, mpt1, ept1 = ipts.T

            _, arcdrop0 = calc_rad(spt, mpt0, ept0, calcdrop=True)
            _, arcdrop1 = calc_rad(spt, mpt1, ept1, calcdrop=True)

            # Have we bracketed the solution yet? If so, use
            # brentq to find a better one within the bracketed
            # range, then move on to a new start t.
            if arcdrop0 > chordaltol: # Check the initial pair
                errfunc = makeerrfunc(st, spt, tck, chordaltol)
                mdt = brentq(errfunc, st, et0)
            if arcdrop0 <= chordaltol and arcdrop1 > chordaltol:
                errfunc = makeerrfunc(st, spt, tck, chordaltol)
                mdt = brentq(errfunc, et0, et1)
            # Check for the existence of an inflection point
            # in the bracketed range by checking the signs
            # of the two calculated curvatures and looking for
            # a reversal.
            if get_rhos(et0, tck)[0] * get_rhos(et1, tck)[0] < 0:
                newts.append((et0 + et1) / 2.0)
        if et1 == 1.0: # No more points to try
    return newts

if __name__ == '__main__':
    import matplotlib.pyplot as plt
    from scipy.interpolate import splprep

    # Create a hi-res sample spline. Start with some
    # low-res points and then resample at a higher
    # res.
    XY = np.array([[0.0,  1.0,  2.0, 3.0, 2.0, 1.0, 0.0],
                   [0.0, -1.0, -0.5, 0.0, 2.5, 1.2, 2.0]])
    tck, u = splprep(XY, s=0)
    XY = splev(np.linspace(0, 1, 400), tck)
    tck, u = splprep(XY, s=0)

    # Get a set of t values that will plot out
    # a linestring with no more than 0.1 chordal
    # error to the original.
    ts = chordal_sample(tck, 0.1)

    fig, ax = plt.subplots()
    # Plot the hi-res spline
    # Plot the approximated spline
    ax.plot(*np.array(splev(ts, tck)), marker='o')

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1 Answer 1

up vote 2 down vote accepted

I found a great solution in one of my favorite modules - Shapely. There's a simplify() method on Shapely geometric objects that takes a tolerance and produces this for the same 0.1 value: enter image description here

Looks better to me, and only took 1.65 ms (for a ~1200x speedup)!

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