klipper-dgus/klippy/mathutil.py

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# Simple math helper functions
#
# Copyright (C) 2018-2019 Kevin O'Connor <kevin@koconnor.net>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import math, logging, multiprocessing, traceback
import queuelogger
######################################################################
# Coordinate descent
######################################################################
# Helper code that implements coordinate descent
def coordinate_descent(adj_params, params, error_func):
# Define potential changes
params = dict(params)
dp = {param_name: 1. for param_name in adj_params}
# Calculate the error
best_err = error_func(params)
logging.info("Coordinate descent initial error: %s", best_err)
threshold = 0.00001
rounds = 0
while sum(dp.values()) > threshold and rounds < 10000:
rounds += 1
for param_name in adj_params:
orig = params[param_name]
params[param_name] = orig + dp[param_name]
err = error_func(params)
if err < best_err:
# There was some improvement
best_err = err
dp[param_name] *= 1.1
continue
params[param_name] = orig - dp[param_name]
err = error_func(params)
if err < best_err:
# There was some improvement
best_err = err
dp[param_name] *= 1.1
continue
params[param_name] = orig
dp[param_name] *= 0.9
logging.info("Coordinate descent best_err: %s rounds: %d",
best_err, rounds)
return params
# Helper to run the coordinate descent function in a background
# process so that it does not block the main thread.
def background_coordinate_descent(printer, adj_params, params, error_func):
parent_conn, child_conn = multiprocessing.Pipe()
def wrapper():
queuelogger.clear_bg_logging()
try:
res = coordinate_descent(adj_params, params, error_func)
except:
child_conn.send((True, traceback.format_exc()))
child_conn.close()
return
child_conn.send((False, res))
child_conn.close()
# Start a process to perform the calculation
calc_proc = multiprocessing.Process(target=wrapper)
calc_proc.daemon = True
calc_proc.start()
# Wait for the process to finish
reactor = printer.get_reactor()
gcode = printer.lookup_object("gcode")
eventtime = last_report_time = reactor.monotonic()
while calc_proc.is_alive():
if eventtime > last_report_time + 5.:
last_report_time = eventtime
gcode.respond_info("Working on calibration...", log=False)
eventtime = reactor.pause(eventtime + .1)
# Return results
is_err, res = parent_conn.recv()
if is_err:
raise Exception("Error in coordinate descent: %s" % (res,))
calc_proc.join()
parent_conn.close()
return res
######################################################################
# Trilateration
######################################################################
# Trilateration finds the intersection of three spheres. See the
# wikipedia article for the details of the algorithm.
def trilateration(sphere_coords, radius2):
sphere_coord1, sphere_coord2, sphere_coord3 = sphere_coords
s21 = matrix_sub(sphere_coord2, sphere_coord1)
s31 = matrix_sub(sphere_coord3, sphere_coord1)
d = math.sqrt(matrix_magsq(s21))
ex = matrix_mul(s21, 1. / d)
i = matrix_dot(ex, s31)
vect_ey = matrix_sub(s31, matrix_mul(ex, i))
ey = matrix_mul(vect_ey, 1. / math.sqrt(matrix_magsq(vect_ey)))
ez = matrix_cross(ex, ey)
j = matrix_dot(ey, s31)
x = (radius2[0] - radius2[1] + d**2) / (2. * d)
y = (radius2[0] - radius2[2] - x**2 + (x-i)**2 + j**2) / (2. * j)
z = -math.sqrt(radius2[0] - x**2 - y**2)
ex_x = matrix_mul(ex, x)
ey_y = matrix_mul(ey, y)
ez_z = matrix_mul(ez, z)
return matrix_add(sphere_coord1, matrix_add(ex_x, matrix_add(ey_y, ez_z)))
######################################################################
# Matrix helper functions for 3x1 matrices
######################################################################
def matrix_cross(m1, m2):
return [m1[1] * m2[2] - m1[2] * m2[1],
m1[2] * m2[0] - m1[0] * m2[2],
m1[0] * m2[1] - m1[1] * m2[0]]
def matrix_dot(m1, m2):
return m1[0] * m2[0] + m1[1] * m2[1] + m1[2] * m2[2]
def matrix_magsq(m1):
return m1[0]**2 + m1[1]**2 + m1[2]**2
def matrix_add(m1, m2):
return [m1[0] + m2[0], m1[1] + m2[1], m1[2] + m2[2]]
def matrix_sub(m1, m2):
return [m1[0] - m2[0], m1[1] - m2[1], m1[2] - m2[2]]
def matrix_mul(m1, s):
return [m1[0]*s, m1[1]*s, m1[2]*s]