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Mini Shell
Mini Shell
from sympy import (symbols, Symbol, pi, sqrt, cos, sin, Derivative,
Function, simplify, I, atan2)
from sympy.abc import epsilon, mu
from sympy.functions.elementary.exponential import exp
from sympy.physics.units import speed_of_light, m, s
from sympy.physics.optics import TWave
from sympy.testing.pytest import raises
c = speed_of_light.convert_to(m/s)
def test_twave():
A1, phi1, A2, phi2, f = symbols('A1, phi1, A2, phi2, f')
n = Symbol('n') # Refractive index
t = Symbol('t') # Time
x = Symbol('x') # Spatial variable
E = Function('E')
w1 = TWave(A1, f, phi1)
w2 = TWave(A2, f, phi2)
assert w1.amplitude == A1
assert w1.frequency == f
assert w1.phase == phi1
assert w1.wavelength == c/(f*n)
assert w1.time_period == 1/f
assert w1.angular_velocity == 2*pi*f
assert w1.wavenumber == 2*pi*f*n/c
assert w1.speed == c/n
w3 = w1 + w2
assert w3.amplitude == sqrt(A1**2 + 2*A1*A2*cos(phi1 - phi2) + A2**2)
assert w3.frequency == f
assert w3.phase == atan2(A1*sin(phi1) + A2*sin(phi2), A1*cos(phi1) + A2*cos(phi2))
assert w3.wavelength == c/(f*n)
assert w3.time_period == 1/f
assert w3.angular_velocity == 2*pi*f
assert w3.wavenumber == 2*pi*f*n/c
assert w3.speed == c/n
assert simplify(w3.rewrite(sin) - w2.rewrite(sin) - w1.rewrite(sin)) == 0
assert w3.rewrite('pde') == epsilon*mu*Derivative(E(x, t), t, t) + Derivative(E(x, t), x, x)
assert w3.rewrite(cos) == sqrt(A1**2 + 2*A1*A2*cos(phi1 - phi2)
+ A2**2)*cos(pi*f*n*x*s/(149896229*m) - 2*pi*f*t + atan2(A1*sin(phi1)
+ A2*sin(phi2), A1*cos(phi1) + A2*cos(phi2)))
assert w3.rewrite(exp) == sqrt(A1**2 + 2*A1*A2*cos(phi1 - phi2)
+ A2**2)*exp(I*(-2*pi*f*t + atan2(A1*sin(phi1) + A2*sin(phi2), A1*cos(phi1)
+ A2*cos(phi2)) + pi*s*f*n*x/(149896229*m)))
w4 = TWave(A1, None, 0, 1/f)
assert w4.frequency == f
w5 = w1 - w2
assert w5.amplitude == sqrt(A1**2 - 2*A1*A2*cos(phi1 - phi2) + A2**2)
assert w5.frequency == f
assert w5.phase == atan2(A1*sin(phi1) - A2*sin(phi2), A1*cos(phi1) - A2*cos(phi2))
assert w5.wavelength == c/(f*n)
assert w5.time_period == 1/f
assert w5.angular_velocity == 2*pi*f
assert w5.wavenumber == 2*pi*f*n/c
assert w5.speed == c/n
assert simplify(w5.rewrite(sin) - w1.rewrite(sin) + w2.rewrite(sin)) == 0
assert w5.rewrite('pde') == epsilon*mu*Derivative(E(x, t), t, t) + Derivative(E(x, t), x, x)
assert w5.rewrite(cos) == sqrt(A1**2 - 2*A1*A2*cos(phi1 - phi2)
+ A2**2)*cos(-2*pi*f*t + atan2(A1*sin(phi1) - A2*sin(phi2), A1*cos(phi1)
- A2*cos(phi2)) + pi*s*f*n*x/(149896229*m))
assert w5.rewrite(exp) == sqrt(A1**2 - 2*A1*A2*cos(phi1 - phi2)
+ A2**2)*exp(I*(-2*pi*f*t + atan2(A1*sin(phi1) - A2*sin(phi2), A1*cos(phi1)
- A2*cos(phi2)) + pi*s*f*n*x/(149896229*m)))
w6 = 2*w1
assert w6.amplitude == 2*A1
assert w6.frequency == f
assert w6.phase == phi1
w7 = -w6
assert w7.amplitude == -2*A1
assert w7.frequency == f
assert w7.phase == phi1
raises(ValueError, lambda:TWave(A1))
raises(ValueError, lambda:TWave(A1, f, phi1, t))
Zerion Mini Shell 1.0