view Resources/Computations/ComputeShearOnSlice.py @ 1510:1005c1cbe4dd

fix
author Sebastien Jodogne <s.jodogne@gmail.com>
date Tue, 07 Jul 2020 09:45:27 +0200
parents 46cb2eedc2e0
children
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#!/usr/bin/python

from sympy import *
import pprint

init_printing(use_unicode=True)


# Setup "T * S * M_shear" (Equation A.16)

ex, ey, ew = symbols('ex ey ew')
sx, sy = symbols('sx, sy')
ti, tj = symbols('ti tj')

T = Matrix([[ 1, 0, 0, ti ],
            [ 0, 1, 0, tj ],
            [ 0, 0, 1, 0  ],
            [ 0, 0, 0, 1  ]])

# Equation (A.15), if "sx == sy == f"
S = Matrix([[ sx, 0,  0, 0 ],
            [ 0,  sy, 0, 0 ],
            [ 0,  0,  1, 0 ],
            [ 0,  0,  0, 1 ]])

# MM_shear, in Equation (A.14)
M = Matrix([[ 1, 0, ex, 0 ],
            [ 0, 1, ey, 0 ],
            [ 0, 0, 1,  0 ],
            [ 0, 0, ew,  1 ]])


x, y, z, w = symbols('x y z w')
p = Matrix([ x, y, z, w ])

print("\nT =" % T)
pprint.pprint(T);

print("\nS =" % T)
pprint.pprint(S);

print("\nM'_shear =" % T)
pprint.pprint(M);

print("\nGeneral form of a Lacroute's shear matrix (Equation A.16): T * S * M'_shear =")
pprint.pprint(T * S * M);

print("\nHence, alternative parametrization:")
a11, a13, a14, a22, a23, a24, a43 = symbols('a11 a13 a14 a22 a23 a24 a43')

A = Matrix([[ a11, 0,   a13, a14 ],
            [ 0,   a22, a23, a24 ],
            [ 0,   0,   1,   0   ],
            [ 0,   0,   a43, 1   ]])
pprint.pprint(A);

v = A * p
v = v.subs(w, 1)

print("\nAction of Lacroute's shear matrix A on plane z (taking w=1):\n%s\n" % v)

print('Output x\' = %s\n' % (v[0]/v[3]))
print('Output y\' = %s\n' % (v[1]/v[3]))
print('Output z\' = %s\n' % (v[2]/v[3]))