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I have an physical instrument of measurement (force platform with load cells) which gives me three values, A, B and C. It happens, though, that these values - that should be orthogonal - actually are somewhat coupled, due to physical characteristics of the measuring device, which causes cross-talk between applied and returned values of force and torque.

Then, it is recommended that a calibration matrix be used to transform the measured values into a better estimate of the actual values, like this:

enter image description here

The problem is that it is necessary to perform a SET of measurements, so that different measured(Fz, Mx, My) and actual(Fz, Mx, My) are least-squared to get some C matrix that works best for the system as a whole.

I can solve Ax = B problems with scipy.linalg.lststq, or even scipy.linalg.solve (giving an exact solution) for ONE measurement, but how should I proceed to consider a set of different measurements, each one with its own equation giving a potentially different 3x3 matrix?

Any help is much appreciated, thanks for reading.

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If I understand correctly, you want to have a to solve a 3-variables equation for every values of (Fz,Mx,My) ? If Fz, Mx and My are coded in 6 bits (eq 128 values), that give you about a million 3x3matrices to store .. –  georgesl Nov 8 '12 at 10:29
@georgesl I posted a similar question containing just the mathematical part of this at math.stackexchange.com, and this answer solved the problem: math.stackexchange.com/a/232124/27435 –  heltonbiker Nov 8 '12 at 13:51
in that case you should anwser you own question and close the thread –  georgesl Nov 8 '12 at 14:19

1 Answer 1

up vote 0 down vote accepted

I posted a similar question containing just the mathematical part of this at math.stackexchange.com, and this answer solved the problem:


In case anyone have a similar problem in the future, here is the almost literal Scipy implementation of that answer (first lines are initialization boilerplate code):

import numpy
import scipy.linalg

### Origin of the coordinate system: upper left corner!
    |          |
    |          |

platform_width = 600
platform_height = 400

# positions of each load cell (one per corner)
loadcell_positions = numpy.array([[0, 0],
                                  [platform_width, 0],
                                  [platform_width, platform_height],
                                  [0, platform_height]])

platform_origin = numpy.array([platform_width, platform_height]) * 0.5

# applying a known force at known positions and taking the measurements
measurements_per_axis = 5
total_load = 50

results = []
for x in numpy.linspace(0, platform_width, measurements_per_axis):
    for y in numpy.linspace(0, platform_height, measurements_per_axis):
        position = numpy.array([x,y])
        for loadpos in loadcell_positions:
            moments = platform_origin-loadpos * total_load
            load = numpy.array([total_load])
            result = numpy.hstack([load, moments])
results = numpy.array(results)
noise = numpy.random.rand(*results.shape) - 0.5
measurements = results + noise

# now expand ("stuff") the 3x3 matrix to get a linearly independent 3x3 matrix
expands = []
for n in xrange(measurements.shape[0]):
    k = results[n,:]
    m = measurements[n,:]

    expand = numpy.zeros((3,9))
    expand[0,0:3] = m
    expand[1,3:6] = m
    expand[2,6:9] = m
expands = numpy.vstack(expands)

# perform the actual regression
C = scipy.linalg.lstsq(expands, measurements.reshape((-1,1)))
C = numpy.array(C[0]).reshape((3,3))

# the result with pure noise (not actual coupling) should be
# very close to a 3x3 identity matrix (and is!)
print C

Hope this helps someone!

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