Fixed decorators (not elegant but working)
Former-commit-id: 8f54570f4413fdbc7544a2b4fe3ea183290026e7
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@ -29,20 +29,24 @@ except ImportError:
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Accordingly, we define our own jit decorator that handles
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Accordingly, we define our own jit decorator that handles
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different versions of numba or does nothing if numba is not
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different versions of numba or does nothing if numba is not
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present. Note that functions that include unicode identifiers
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present. Note that functions that include unicode identifiers
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must be decorated with @jit(u=True)
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must be decorated with @ujit
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'''
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'''
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def jit(u=False):
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#def dummywrap(f):
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def resdec(f):
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# return f
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if u and use_jit_utf8:
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def jit(f):
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return numba.jit(f)
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if use_jit:
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if (not u) and use_jit:
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return numba.jit(f)
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return numba.jit(f)
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else:
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return f
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def ujit(f):
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if use_jit_utf8:
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return numba.jit(f)
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else:
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return f
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return f
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return resdec
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# Coordinate transforms for arrays of "arbitrary" shape
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# Coordinate transforms for arrays of "arbitrary" shape
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@jit(u=True)
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@ujit
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def cart2sph(cart,axis=-1):
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def cart2sph(cart,axis=-1):
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if (cart.shape[axis] != 3):
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if (cart.shape[axis] != 3):
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raise ValueError("The converted array has to have dimension 3"
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raise ValueError("The converted array has to have dimension 3"
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@ -54,7 +58,7 @@ def cart2sph(cart,axis=-1):
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φ = np.arctan2(y,x) # arctan2 handles zeroes correctly itself
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φ = np.arctan2(y,x) # arctan2 handles zeroes correctly itself
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return np.concatenate((r,θ,φ),axis=axis)
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return np.concatenate((r,θ,φ),axis=axis)
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@jit(u=True)
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@ujit
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def sph2cart(sph, axis=-1):
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def sph2cart(sph, axis=-1):
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if (sph.shape[axis] != 3):
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if (sph.shape[axis] != 3):
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raise ValueError("The converted array has to have dimension 3"
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raise ValueError("The converted array has to have dimension 3"
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@ -66,7 +70,7 @@ def sph2cart(sph, axis=-1):
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z = r * np.cos(θ)
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z = r * np.cos(θ)
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return np.concatenate((x,y,z),axis=axis)
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return np.concatenate((x,y,z),axis=axis)
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@jit(u=True)
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@ujit
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def sph_loccart2cart(loccart, sph, axis=-1):
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def sph_loccart2cart(loccart, sph, axis=-1):
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"""
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"""
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Transformation of vector specified in local orthogonal coordinates
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Transformation of vector specified in local orthogonal coordinates
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@ -116,7 +120,7 @@ def sph_loccart2cart(loccart, sph, axis=-1):
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out=inr̂*r̂+inθ̂*θ̂+inφ̂*φ̂
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out=inr̂*r̂+inθ̂*θ̂+inφ̂*φ̂
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return out
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return out
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@jit(u=True)
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@ujit
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def sph_loccart_basis(sph, sphaxis=-1, cartaxis=None):
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def sph_loccart_basis(sph, sphaxis=-1, cartaxis=None):
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"""
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"""
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Returns the local cartesian basis in terms of global cartesian basis.
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Returns the local cartesian basis in terms of global cartesian basis.
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@ -152,7 +156,7 @@ def sph_loccart_basis(sph, sphaxis=-1, cartaxis=None):
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out = np.concatenate((x,y,z),axis=cartaxis)
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out = np.concatenate((x,y,z),axis=cartaxis)
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return out
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return out
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@jit(u=False)
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@jit
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def lpy(nmax, z):
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def lpy(nmax, z):
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"""
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"""
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Associated legendre function and its derivatative at z in the 'y-indexing'.
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Associated legendre function and its derivatative at z in the 'y-indexing'.
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@ -259,7 +263,7 @@ def zJn(n, z, J=1):
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# FIXME: this can be expressed simply as:
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# FIXME: this can be expressed simply as:
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# $$ -\frac{1}{2}\sqrt{\frac{2n+1}{4\pi}n\left(n+1\right)}(\delta_{m,1}+\delta_{m,-1}) $$
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# $$ -\frac{1}{2}\sqrt{\frac{2n+1}{4\pi}n\left(n+1\right)}(\delta_{m,1}+\delta_{m,-1}) $$
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@jit(u=True)
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@ujit
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def π̃_zerolim(nmax): # seems OK
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def π̃_zerolim(nmax): # seems OK
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"""
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"""
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lim_{θ→ 0-} π̃(cos θ)
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lim_{θ→ 0-} π̃(cos θ)
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@ -277,7 +281,7 @@ def π̃_zerolim(nmax): # seems OK
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π̃_y = prenorm * π̃_y
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π̃_y = prenorm * π̃_y
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return π̃_y
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return π̃_y
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@jit(u=True)
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@ujit
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def π̃_pilim(nmax): # Taky OK, jen to možná není kompatibilní se vzorečky z mathematiky
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def π̃_pilim(nmax): # Taky OK, jen to možná není kompatibilní se vzorečky z mathematiky
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"""
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"""
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lim_{θ→ π+} π̃(cos θ)
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lim_{θ→ π+} π̃(cos θ)
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@ -297,7 +301,7 @@ def π̃_pilim(nmax): # Taky OK, jen to možná není kompatibilní se vzorečky
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# FIXME: this can be expressed simply as
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# FIXME: this can be expressed simply as
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# $$ -\frac{1}{2}\sqrt{\frac{2n+1}{4\pi}n\left(n+1\right)}(\delta_{m,1}-\delta_{m,-1}) $$
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# $$ -\frac{1}{2}\sqrt{\frac{2n+1}{4\pi}n\left(n+1\right)}(\delta_{m,1}-\delta_{m,-1}) $$
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@jit(u=True)
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@ujit
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def τ̃_zerolim(nmax):
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def τ̃_zerolim(nmax):
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"""
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"""
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lim_{θ→ 0-} τ̃(cos θ)
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lim_{θ→ 0-} τ̃(cos θ)
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@ -308,7 +312,7 @@ def τ̃_zerolim(nmax):
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p0[minus1mmask] = -p0[minus1mmask]
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p0[minus1mmask] = -p0[minus1mmask]
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return p0
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return p0
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@jit(u=True)
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@ujit
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def τ̃_pilim(nmax):
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def τ̃_pilim(nmax):
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"""
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"""
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lim_{θ→ π+} τ̃(cos θ)
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lim_{θ→ π+} τ̃(cos θ)
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@ -319,7 +323,7 @@ def τ̃_pilim(nmax):
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t[plus1mmask] = -t[plus1mmask]
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t[plus1mmask] = -t[plus1mmask]
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return t
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return t
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@jit(u=True)
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@ujit
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def get_π̃τ̃_y1(θ,nmax):
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def get_π̃τ̃_y1(θ,nmax):
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# TODO replace with the limit functions (below) when θ approaches
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# TODO replace with the limit functions (below) when θ approaches
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# the extreme values at about 1e-6 distance
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# the extreme values at about 1e-6 distance
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@ -339,7 +343,7 @@ def get_π̃τ̃_y1(θ,nmax):
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τ̃_y = prenorm * dPy * (- math.sin(θ)) # TADY BACHA!!!!!!!!!! * (- math.sin(pos_sph[1])) ???
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τ̃_y = prenorm * dPy * (- math.sin(θ)) # TADY BACHA!!!!!!!!!! * (- math.sin(pos_sph[1])) ???
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return (π̃_y,τ̃_y)
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return (π̃_y,τ̃_y)
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@jit(u=True)
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@ujit
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def vswf_yr1(pos_sph,nmax,J=1):
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def vswf_yr1(pos_sph,nmax,J=1):
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"""
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"""
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As vswf_yr, but evaluated only at single position (i.e. pos_sph has
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As vswf_yr, but evaluated only at single position (i.e. pos_sph has
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@ -396,7 +400,7 @@ def vswf_yr1(pos_sph,nmax,J=1):
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# return 1j**ny * np.sqrt((2*ny+1)*factorial(ny-my) /
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# return 1j**ny * np.sqrt((2*ny+1)*factorial(ny-my) /
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# (ny*(ny+1)*factorial(ny+my))
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# (ny*(ny+1)*factorial(ny+my))
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# )
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# )
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@jit(u=True)
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@ujit
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def zplane_pq_y(nmax, betap = 0):
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def zplane_pq_y(nmax, betap = 0):
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"""
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"""
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The z-propagating plane wave expansion coefficients as in [1, (1.12)]
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The z-propagating plane wave expansion coefficients as in [1, (1.12)]
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@ -415,7 +419,7 @@ def zplane_pq_y(nmax, betap = 0):
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#import warnings
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#import warnings
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@jit(u=True)
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@ujit
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def plane_pq_y(nmax, kdir_cart, E_cart):
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def plane_pq_y(nmax, kdir_cart, E_cart):
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"""
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"""
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The plane wave expansion coefficients for any direction kdir_cart
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The plane wave expansion coefficients for any direction kdir_cart
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@ -472,13 +476,13 @@ def plane_pq_y(nmax, kdir_cart, E_cart):
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# Functions copied from scattering_xu, additionaly normalized
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# Functions copied from scattering_xu, additionaly normalized
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from py_gmm.gmm import vec_trans as vc
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from py_gmm.gmm import vec_trans as vc
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@jit(u=True)
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@ujit
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def q_max(m,n,μ,ν):
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def q_max(m,n,μ,ν):
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return min(n,ν,(n+ν-abs(m+μ))/2)
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return min(n,ν,(n+ν-abs(m+μ))/2)
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# returns array with indices corresponding to q
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# returns array with indices corresponding to q
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# argument q does nothing for now
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# argument q does nothing for now
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@jit(u=True)
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@ujit
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def a_q(m,n,μ,ν,q = None):
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def a_q(m,n,μ,ν,q = None):
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qm=q_max(m,n,μ,ν)
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qm=q_max(m,n,μ,ν)
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res, err= vc.gaunt_xu(m,n,μ,ν,qm)
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res, err= vc.gaunt_xu(m,n,μ,ν,qm)
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@ -489,7 +493,7 @@ def a_q(m,n,μ,ν,q = None):
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# All arguments are single numbers (for now)
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# All arguments are single numbers (for now)
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# ZDE VYCHÁZEJÍ DIVNÁ ZNAMÉNKA
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# ZDE VYCHÁZEJÍ DIVNÁ ZNAMÉNKA
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@jit(u=True)
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@ujit
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def Ã(m,n,μ,ν,kdlj,θlj,φlj,r_ge_d,J):
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def Ã(m,n,μ,ν,kdlj,θlj,φlj,r_ge_d,J):
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"""
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"""
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The à translation coefficient for spherical vector waves.
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The à translation coefficient for spherical vector waves.
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@ -548,7 +552,7 @@ def Ã(m,n,μ,ν,kdlj,θlj,φlj,r_ge_d,J):
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return presum * np.sum(summandq)
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return presum * np.sum(summandq)
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# ZDE OPĚT JINAK ZNAMÉNKA než v Xu (J. comp. phys 127, 285)
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# ZDE OPĚT JINAK ZNAMÉNKA než v Xu (J. comp. phys 127, 285)
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@jit(u=True)
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@ujit
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def B̃(m,n,μ,ν,kdlj,θlj,φlj,r_ge_d,J):
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def B̃(m,n,μ,ν,kdlj,θlj,φlj,r_ge_d,J):
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"""
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"""
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The B̃ translation coefficient for spherical vector waves.
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The B̃ translation coefficient for spherical vector waves.
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@ -613,7 +617,7 @@ def B̃(m,n,μ,ν,kdlj,θlj,φlj,r_ge_d,J):
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# In[7]:
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# In[7]:
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# Material parameters
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# Material parameters
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@jit(u=True)
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@ujit
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def ε_drude(ε_inf, ω_p, γ_p, ω): # RELATIVE permittivity, of course
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def ε_drude(ε_inf, ω_p, γ_p, ω): # RELATIVE permittivity, of course
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return ε_inf - ω_p*ω_p/(ω*(ω+1j*γ_p))
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return ε_inf - ω_p*ω_p/(ω*(ω+1j*γ_p))
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@ -621,7 +625,7 @@ def ε_drude(ε_inf, ω_p, γ_p, ω): # RELATIVE permittivity, of course
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# In[8]:
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# In[8]:
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# Mie scattering
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# Mie scattering
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@jit(u=True)
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@ujit
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def mie_coefficients(a, nmax, #ω, ε_i, ε_e=1, J_ext=1, J_scat=3
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def mie_coefficients(a, nmax, #ω, ε_i, ε_e=1, J_ext=1, J_scat=3
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k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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"""
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"""
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@ -701,7 +705,7 @@ def mie_coefficients(a, nmax, #ω, ε_i, ε_e=1, J_ext=1, J_scat=3
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TH = -(( η_inv_e * že * zs - η_inv_e * ze * žs)/(-η_inv_i * ži * zs + η_inv_e * zi * žs))
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TH = -(( η_inv_e * že * zs - η_inv_e * ze * žs)/(-η_inv_i * ži * zs + η_inv_e * zi * žs))
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return (RH, RV, TH, TV)
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return (RH, RV, TH, TV)
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@jit(u=True)
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@ujit
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def G_Mie_scat_precalc_cart_new(source_cart, dest_cart, RH, RV, a, nmax, k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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def G_Mie_scat_precalc_cart_new(source_cart, dest_cart, RH, RV, a, nmax, k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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"""
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"""
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Implementation according to Kristensson, page 50
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Implementation according to Kristensson, page 50
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@ -738,7 +742,7 @@ def G_Mie_scat_precalc_cart_new(source_cart, dest_cart, RH, RV, a, nmax, k_i, k_
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RV[ny][:,ň,ň] * Ñlo_cart_y[:,:,ň].conj() * Ñhi_cart_y[:,ň,:]) / (ny * (ny+1))[:,ň,ň]
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RV[ny][:,ň,ň] * Ñlo_cart_y[:,:,ň].conj() * Ñhi_cart_y[:,ň,:]) / (ny * (ny+1))[:,ň,ň]
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return 1j* k_e*np.sum(G_y,axis=0)
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return 1j* k_e*np.sum(G_y,axis=0)
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@jit(u=True)
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@ujit
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def G_Mie_scat_precalc_cart(source_cart, dest_cart, RH, RV, a, nmax, k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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def G_Mie_scat_precalc_cart(source_cart, dest_cart, RH, RV, a, nmax, k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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"""
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"""
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r1_cart (destination), r2_cart (source) and the result are in cartesian coordinates
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r1_cart (destination), r2_cart (source) and the result are in cartesian coordinates
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@ -793,7 +797,7 @@ def G_Mie_scat_precalc_cart(source_cart, dest_cart, RH, RV, a, nmax, k_i, k_e,
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G_source_dest = sph_loccart2cart(G_source_dest, sph=orig2dest_sph, axis=-1)
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G_source_dest = sph_loccart2cart(G_source_dest, sph=orig2dest_sph, axis=-1)
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return G_source_dest
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return G_source_dest
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@jit(u=True)
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@ujit
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def G_Mie_scat_cart(source_cart, dest_cart, a, nmax, k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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def G_Mie_scat_cart(source_cart, dest_cart, a, nmax, k_i, k_e, μ_i=1, μ_e=1, J_ext=1, J_scat=3):
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"""
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"""
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TODO
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TODO
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@ -813,7 +817,7 @@ def cross_section_Mie(a, nmax, k_i, k_e, μ_i, μ_e,):
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# In[9]:
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# In[9]:
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# From PRL 112, 253601 (1)
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# From PRL 112, 253601 (1)
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@jit(u=True)
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@ujit
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def Grr_Delga(nmax, a, r, k, ε_m, ε_b):
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def Grr_Delga(nmax, a, r, k, ε_m, ε_b):
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om = k * c
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om = k * c
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z = (r-a)/a
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z = (r-a)/a
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@ -835,7 +839,7 @@ def Grr_Delga(nmax, a, r, k, ε_m, ε_b):
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# Test if the decomposition of plane wave works also for absorbing environment (complex k).
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# Test if the decomposition of plane wave works also for absorbing environment (complex k).
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# From PRL 112, 253601 (1)
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# From PRL 112, 253601 (1)
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@jit(u=True)
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@ujit
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def Grr_Delga(nmax, a, r, k, ε_m, ε_b):
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def Grr_Delga(nmax, a, r, k, ε_m, ε_b):
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om = k * c
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om = k * c
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z = (r-a)/a
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z = (r-a)/a
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@ -844,7 +848,7 @@ def Grr_Delga(nmax, a, r, k, ε_m, ε_b):
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s = np.sum( (n+1)**2 * (ε_m-ε_b) / ((1+z)**(2*n+4) * (ε_m + ((n+1)/n)*ε_b)))
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s = np.sum( (n+1)**2 * (ε_m-ε_b) / ((1+z)**(2*n+4) * (ε_m + ((n+1)/n)*ε_b)))
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return (g0 + s * c**2/(4*π*om**2*ε_b*a**3))
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return (g0 + s * c**2/(4*π*om**2*ε_b*a**3))
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@jit(u=True)
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@ujit
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def G0_dip_1(r_cart,k):
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def G0_dip_1(r_cart,k):
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"""
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"""
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Free-space dyadic Green's function in terms of the spherical vector waves.
|
Free-space dyadic Green's function in terms of the spherical vector waves.
|
||||||
|
@ -861,15 +865,15 @@ def G0_dip_1(r_cart,k):
|
||||||
|
|
||||||
# Free-space dyadic Green's functions from RMP 70, 2, 447 =: [1]
|
# Free-space dyadic Green's functions from RMP 70, 2, 447 =: [1]
|
||||||
# (The numerical value is correct only at the regular part, i.e. r != 0)
|
# (The numerical value is correct only at the regular part, i.e. r != 0)
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def _P(z):
|
def _P(z):
|
||||||
return (1-1/z+1/(z*z))
|
return (1-1/z+1/(z*z))
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def _Q(z):
|
def _Q(z):
|
||||||
return (-1+3/z-3/(z*z))
|
return (-1+3/z-3/(z*z))
|
||||||
|
|
||||||
# [1, (9)] FIXME The sign here is most likely wrong!!!
|
# [1, (9)] FIXME The sign here is most likely wrong!!!
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def G0_analytical(r #cartesian!
|
def G0_analytical(r #cartesian!
|
||||||
, k):
|
, k):
|
||||||
I=np.identity(3)
|
I=np.identity(3)
|
||||||
|
@ -883,7 +887,7 @@ def G0_analytical(r #cartesian!
|
||||||
))
|
))
|
||||||
|
|
||||||
# [1, (11)]
|
# [1, (11)]
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def G0L_analytical(r, k):
|
def G0L_analytical(r, k):
|
||||||
I=np.identity(3)
|
I=np.identity(3)
|
||||||
rn = sph_loccart2cart(np.array([1.,0.,0.]), cart2sph(r), axis=-1)
|
rn = sph_loccart2cart(np.array([1.,0.,0.]), cart2sph(r), axis=-1)
|
||||||
|
@ -896,7 +900,7 @@ def G0L_analytical(r, k):
|
||||||
def G0T_analytical(r, k):
|
def G0T_analytical(r, k):
|
||||||
return G0_analytical(r,k) - G0L_analytical(r,k)
|
return G0_analytical(r,k) - G0L_analytical(r,k)
|
||||||
|
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def G0_sum_1_slow(source_cart, dest_cart, k, nmax):
|
def G0_sum_1_slow(source_cart, dest_cart, k, nmax):
|
||||||
my, ny = get_mn_y(nmax)
|
my, ny = get_mn_y(nmax)
|
||||||
nelem = len(my)
|
nelem = len(my)
|
||||||
|
@ -1067,7 +1071,7 @@ def _scuffTMatrixConvert_EM_01(EM):
|
||||||
else:
|
else:
|
||||||
return None
|
return None
|
||||||
|
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def loadScuffTMatrices(fileName):
|
def loadScuffTMatrices(fileName):
|
||||||
"""
|
"""
|
||||||
TODO doc
|
TODO doc
|
||||||
|
@ -1186,7 +1190,7 @@ def scatter_plane_wave(omega, epsilon_b, positions, Tmatrices, k_dirs, E_0s, #sa
|
||||||
pass
|
pass
|
||||||
|
|
||||||
import warnings
|
import warnings
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_dirs, E_0s,
|
def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_dirs, E_0s,
|
||||||
return_pq_0 = False, return_pq= False, return_xy = False, watch_time = False):
|
return_pq_0 = False, return_pq= False, return_xy = False, watch_time = False):
|
||||||
"""
|
"""
|
||||||
|
@ -1418,7 +1422,7 @@ def scatter_plane_wave_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, k_
|
||||||
|
|
||||||
|
|
||||||
import warnings
|
import warnings
|
||||||
@jit(u=True)
|
@ujit
|
||||||
def scatter_constmultipole_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, pq_0_c = 1,
|
def scatter_constmultipole_rectarray(omega, epsilon_b, xN, yN, xd, yd, TMatrices, pq_0_c = 1,
|
||||||
return_pq= False, return_xy = False, watch_time = False):
|
return_pq= False, return_xy = False, watch_time = False):
|
||||||
"""
|
"""
|
||||||
|
|
2
setup.py
2
setup.py
|
@ -12,7 +12,7 @@ qpms_c = Extension('qpms_c',
|
||||||
sources = ['qpms/qpms_c.pyx'])
|
sources = ['qpms/qpms_c.pyx'])
|
||||||
|
|
||||||
setup(name='qpms',
|
setup(name='qpms',
|
||||||
version = "0.1.3",
|
version = "0.1.5",
|
||||||
packages=['qpms'],
|
packages=['qpms'],
|
||||||
# setup_requires=['setuptools_cython'],
|
# setup_requires=['setuptools_cython'],
|
||||||
install_requires=['cython>=0.21','quaternion','spherical_functions','py_gmm'],
|
install_requires=['cython>=0.21','quaternion','spherical_functions','py_gmm'],
|
||||||
|
|
Loading…
Reference in New Issue