parent
4a84c42112
commit
dd0f2cfa3c
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@ -936,36 +936,36 @@ pure function utilities_getFreqDerivative(k_s)
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select case (spectral_derivative_ID)
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select case (spectral_derivative_ID)
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case (DERIVATIVE_CONTINUOUS_ID)
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case (DERIVATIVE_CONTINUOUS_ID)
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utilities_getFreqDerivative = cmplx(0.0_pReal, 2.0_pReal*PI*real(k_s,pReal)/geomSize,pReal)
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utilities_getFreqDerivative = cmplx(0.0_pReal, TAU*real(k_s,pReal)/geomSize,pReal)
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case (DERIVATIVE_CENTRAL_DIFF_ID)
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case (DERIVATIVE_CENTRAL_DIFF_ID)
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utilities_getFreqDerivative = cmplx(0.0_pReal, sin(2.0_pReal*PI*real(k_s,pReal)/real(grid,pReal)), pReal)/ &
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utilities_getFreqDerivative = cmplx(0.0_pReal, sin(TAU*real(k_s,pReal)/real(grid,pReal)), pReal)/ &
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cmplx(2.0_pReal*geomSize/real(grid,pReal), 0.0_pReal, pReal)
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cmplx(2.0_pReal*geomSize/real(grid,pReal), 0.0_pReal, pReal)
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case (DERIVATIVE_FWBW_DIFF_ID)
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case (DERIVATIVE_FWBW_DIFF_ID)
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utilities_getFreqDerivative(1) = &
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utilities_getFreqDerivative(1) = &
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cmplx(cos(2.0_pReal*PI*real(k_s(1),pReal)/real(grid(1),pReal)) - 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(1),pReal)/real(grid(1),pReal)) - 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(1),pReal)/real(grid(1),pReal)), pReal)* &
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sin(TAU*real(k_s(1),pReal)/real(grid(1),pReal)), pReal)* &
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cmplx(cos(2.0_pReal*PI*real(k_s(2),pReal)/real(grid(2),pReal)) + 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(2),pReal)/real(grid(2),pReal)) + 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(2),pReal)/real(grid(2),pReal)), pReal)* &
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sin(TAU*real(k_s(2),pReal)/real(grid(2),pReal)), pReal)* &
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cmplx(cos(2.0_pReal*PI*real(k_s(3),pReal)/real(grid(3),pReal)) + 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(3),pReal)/real(grid(3),pReal)) + 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(3),pReal)/real(grid(3),pReal)), pReal)/ &
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sin(TAU*real(k_s(3),pReal)/real(grid(3),pReal)), pReal)/ &
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cmplx(4.0_pReal*geomSize(1)/real(grid(1),pReal), 0.0_pReal, pReal)
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cmplx(4.0_pReal*geomSize(1)/real(grid(1),pReal), 0.0_pReal, pReal)
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utilities_getFreqDerivative(2) = &
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utilities_getFreqDerivative(2) = &
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cmplx(cos(2.0_pReal*PI*real(k_s(1),pReal)/real(grid(1),pReal)) + 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(1),pReal)/real(grid(1),pReal)) + 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(1),pReal)/real(grid(1),pReal)), pReal)* &
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sin(TAU*real(k_s(1),pReal)/real(grid(1),pReal)), pReal)* &
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cmplx(cos(2.0_pReal*PI*real(k_s(2),pReal)/real(grid(2),pReal)) - 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(2),pReal)/real(grid(2),pReal)) - 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(2),pReal)/real(grid(2),pReal)), pReal)* &
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sin(TAU*real(k_s(2),pReal)/real(grid(2),pReal)), pReal)* &
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cmplx(cos(2.0_pReal*PI*real(k_s(3),pReal)/real(grid(3),pReal)) + 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(3),pReal)/real(grid(3),pReal)) + 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(3),pReal)/real(grid(3),pReal)), pReal)/ &
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sin(TAU*real(k_s(3),pReal)/real(grid(3),pReal)), pReal)/ &
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cmplx(4.0_pReal*geomSize(2)/real(grid(2),pReal), 0.0_pReal, pReal)
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cmplx(4.0_pReal*geomSize(2)/real(grid(2),pReal), 0.0_pReal, pReal)
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utilities_getFreqDerivative(3) = &
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utilities_getFreqDerivative(3) = &
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cmplx(cos(2.0_pReal*PI*real(k_s(1),pReal)/real(grid(1),pReal)) + 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(1),pReal)/real(grid(1),pReal)) + 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(1),pReal)/real(grid(1),pReal)), pReal)* &
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sin(TAU*real(k_s(1),pReal)/real(grid(1),pReal)), pReal)* &
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cmplx(cos(2.0_pReal*PI*real(k_s(2),pReal)/real(grid(2),pReal)) + 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(2),pReal)/real(grid(2),pReal)) + 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(2),pReal)/real(grid(2),pReal)), pReal)* &
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sin(TAU*real(k_s(2),pReal)/real(grid(2),pReal)), pReal)* &
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cmplx(cos(2.0_pReal*PI*real(k_s(3),pReal)/real(grid(3),pReal)) - 1.0_pReal, &
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cmplx(cos(TAU*real(k_s(3),pReal)/real(grid(3),pReal)) - 1.0_pReal, &
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sin(2.0_pReal*PI*real(k_s(3),pReal)/real(grid(3),pReal)), pReal)/ &
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sin(TAU*real(k_s(3),pReal)/real(grid(3),pReal)), pReal)/ &
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cmplx(4.0_pReal*geomSize(3)/real(grid(3),pReal), 0.0_pReal, pReal)
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cmplx(4.0_pReal*geomSize(3)/real(grid(3),pReal), 0.0_pReal, pReal)
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end select
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end select
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18
src/math.f90
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src/math.f90
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@ -21,10 +21,12 @@ module math
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config
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config
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#endif
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#endif
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real(pReal), parameter :: PI = acos(-1.0_pReal) !< ratio of a circle's circumference to its diameter
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real(pReal), parameter :: &
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real(pReal), parameter :: INDEG = 180.0_pReal/PI !< conversion from radian to degree
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PI = acos(-1.0_pReal), & !< ratio of a circle's circumference to its diameter
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real(pReal), parameter :: INRAD = PI/180.0_pReal !< conversion from degree to radian
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TAU = 2.0_pReal*PI, & !< ratio of a circle's circumference to its radius
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complex(pReal), parameter :: TWOPIIMG = cmplx(0.0_pReal,2.0_pReal*PI) !< Re(0.0), Im(2xPi)
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INDEG = 360.0_pReal/TAU, & !< conversion from radian to degree
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INRAD = TAU/360.0_pReal !< conversion from degree to radian
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complex(pReal), parameter :: TWOPIIMG = cmplx(0.0_pReal,TAU) !< Re(0.0), Im(Tau)
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real(pReal), dimension(3,3), parameter :: &
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real(pReal), dimension(3,3), parameter :: &
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math_I3 = reshape([&
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math_I3 = reshape([&
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@ -984,7 +986,7 @@ impure elemental subroutine math_normal(x,mu,sigma)
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end if
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end if
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call random_number(rnd)
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call random_number(rnd)
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x = mu_ + sigma_ * sqrt(-2.0_pReal*log(1.0_pReal-rnd(1)))*cos(2.0_pReal*PI*(1.0_pReal - rnd(2)))
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x = mu_ + sigma_ * sqrt(-2.0_pReal*log(1.0_pReal-rnd(1)))*cos(TAU*(1.0_pReal - rnd(2)))
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end subroutine math_normal
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end subroutine math_normal
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@ -1088,7 +1090,7 @@ pure function math_rotationalPart(F) result(R)
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if (dNeq0(x)) then
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if (dNeq0(x)) then
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Phi = acos(math_clip((I_C(1)**3 -4.5_pReal*I_C(1)*I_C(2) +13.5_pReal*I_C(3))/x,-1.0_pReal,1.0_pReal))
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Phi = acos(math_clip((I_C(1)**3 -4.5_pReal*I_C(1)*I_C(2) +13.5_pReal*I_C(3))/x,-1.0_pReal,1.0_pReal))
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lambda = I_C(1) +(2.0_pReal * sqrt(math_clip(I_C(1)**2-3.0_pReal*I_C(2),0.0_pReal))) &
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lambda = I_C(1) +(2.0_pReal * sqrt(math_clip(I_C(1)**2-3.0_pReal*I_C(2),0.0_pReal))) &
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*cos((Phi-2.0_pReal * PI*[1.0_pReal,2.0_pReal,3.0_pReal])/3.0_pReal)
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*cos((Phi-TAU*[1.0_pReal,2.0_pReal,3.0_pReal])/3.0_pReal)
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lambda = sqrt(math_clip(lambda,0.0_pReal)/3.0_pReal)
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lambda = sqrt(math_clip(lambda,0.0_pReal)/3.0_pReal)
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else
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else
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lambda = sqrt(I_C(1)/3.0_pReal)
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lambda = sqrt(I_C(1)/3.0_pReal)
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@ -1154,8 +1156,8 @@ pure function math_eigvalsh33(m)
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phi=acos(math_clip(-Q/rho*0.5_pReal,-1.0_pReal,1.0_pReal))
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phi=acos(math_clip(-Q/rho*0.5_pReal,-1.0_pReal,1.0_pReal))
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math_eigvalsh33 = 2.0_pReal*rho**(1.0_pReal/3.0_pReal)* &
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math_eigvalsh33 = 2.0_pReal*rho**(1.0_pReal/3.0_pReal)* &
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[cos( phi /3.0_pReal), &
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[cos( phi /3.0_pReal), &
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cos((phi+2.0_pReal*PI)/3.0_pReal), &
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cos((phi+TAU)/3.0_pReal), &
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cos((phi+4.0_pReal*PI)/3.0_pReal) &
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cos((phi+2.0_pReal*TAU)/3.0_pReal) &
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] &
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] &
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+ I(1)/3.0_pReal
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+ I(1)/3.0_pReal
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endif
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endif
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@ -341,7 +341,7 @@ module subroutine dislotungsten_dotState(Mp,T,ph,en)
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dot_rho_dip_formation = merge(2.0_pReal*(d_hat-prm%d_caron)*stt%rho_mob(:,en)*dot%gamma_sl(:,en)/prm%b_sl, &
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dot_rho_dip_formation = merge(2.0_pReal*(d_hat-prm%d_caron)*stt%rho_mob(:,en)*dot%gamma_sl(:,en)/prm%b_sl, &
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0.0_pReal, &
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0.0_pReal, &
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prm%dipoleformation)
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prm%dipoleformation)
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v_cl = (3.0_pReal*mu*prm%D_0*exp(-prm%Q_cl/(K_B*T))*prm%f_at/(2.0_pReal*PI*K_B*T)) &
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v_cl = (3.0_pReal*mu*prm%D_0*exp(-prm%Q_cl/(K_B*T))*prm%f_at/(TAU*K_B*T)) &
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* (1.0_pReal/(d_hat+prm%d_caron))
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* (1.0_pReal/(d_hat+prm%d_caron))
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dot_rho_dip_climb = (4.0_pReal*v_cl*stt%rho_dip(:,en))/(d_hat-prm%d_caron) ! ToDo: Discuss with Franz: Stress dependency?
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dot_rho_dip_climb = (4.0_pReal*v_cl*stt%rho_dip(:,en))/(d_hat-prm%d_caron) ! ToDo: Discuss with Franz: Stress dependency?
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end where
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end where
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@ -198,7 +198,7 @@ subroutine fromEulers(self,eu,degrees)
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Eulers = merge(eu*INRAD,eu,degrees)
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Eulers = merge(eu*INRAD,eu,degrees)
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endif
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endif
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if (any(Eulers<0.0_pReal) .or. any(Eulers>2.0_pReal*PI) .or. Eulers(2) > PI) &
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if (any(Eulers<0.0_pReal) .or. any(Eulers>TAU) .or. Eulers(2) > PI) &
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call IO_error(402,ext_msg='fromEulers')
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call IO_error(402,ext_msg='fromEulers')
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self%q = eu2qu(Eulers)
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self%q = eu2qu(Eulers)
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@ -480,7 +480,7 @@ pure function qu2eu(qu) result(eu)
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atan2( 2.0_pReal*chi, q03-q12 ), &
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atan2( 2.0_pReal*chi, q03-q12 ), &
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atan2(( P*qu(1)*qu(3)+qu(2)*qu(4))*chi, (-P*qu(1)*qu(2)+qu(3)*qu(4))*chi )]
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atan2(( P*qu(1)*qu(3)+qu(2)*qu(4))*chi, (-P*qu(1)*qu(2)+qu(3)*qu(4))*chi )]
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endif degenerated
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endif degenerated
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where(sign(1.0_pReal,eu)<0.0_pReal) eu = mod(eu+2.0_pReal*PI,[2.0_pReal*PI,PI,2.0_pReal*PI])
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where(sign(1.0_pReal,eu)<0.0_pReal) eu = mod(eu+TAU,[TAU,PI,TAU])
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end function qu2eu
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end function qu2eu
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@ -628,7 +628,7 @@ pure function om2eu(om) result(eu)
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eu = [atan2(om(1,2),om(1,1)), 0.5_pReal*PI*(1.0_pReal-om(3,3)),0.0_pReal ]
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eu = [atan2(om(1,2),om(1,1)), 0.5_pReal*PI*(1.0_pReal-om(3,3)),0.0_pReal ]
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end if
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end if
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where(abs(eu) < 1.e-8_pReal) eu = 0.0_pReal
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where(abs(eu) < 1.e-8_pReal) eu = 0.0_pReal
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where(sign(1.0_pReal,eu)<0.0_pReal) eu = mod(eu+2.0_pReal*PI,[2.0_pReal*PI,PI,2.0_pReal*PI])
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where(sign(1.0_pReal,eu)<0.0_pReal) eu = mod(eu+TAU,[TAU,PI,TAU])
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end function om2eu
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end function om2eu
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@ -1437,7 +1437,7 @@ subroutine selfTest()
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elseif(i==2) then
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elseif(i==2) then
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qu = eu2qu([0.0_pReal,0.0_pReal,0.0_pReal])
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qu = eu2qu([0.0_pReal,0.0_pReal,0.0_pReal])
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elseif(i==3) then
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elseif(i==3) then
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qu = eu2qu([2.0_pReal*PI,PI,2.0_pReal*PI])
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qu = eu2qu([TAU,PI,TAU])
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elseif(i==4) then
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elseif(i==4) then
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qu = [0.0_pReal,0.0_pReal,1.0_pReal,0.0_pReal]
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qu = [0.0_pReal,0.0_pReal,1.0_pReal,0.0_pReal]
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elseif(i==5) then
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elseif(i==5) then
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@ -1448,10 +1448,10 @@ subroutine selfTest()
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call random_number(x)
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call random_number(x)
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A = sqrt(x(3))
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A = sqrt(x(3))
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B = sqrt(1-0_pReal -x(3))
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B = sqrt(1-0_pReal -x(3))
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qu = [cos(2.0_pReal*PI*x(1))*A,&
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qu = [cos(TAU*x(1))*A,&
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sin(2.0_pReal*PI*x(2))*B,&
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sin(TAU*x(2))*B,&
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cos(2.0_pReal*PI*x(2))*B,&
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cos(TAU*x(2))*B,&
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sin(2.0_pReal*PI*x(1))*A]
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sin(TAU*x(1))*A]
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if(qu(1)<0.0_pReal) qu = qu * (-1.0_pReal)
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if(qu(1)<0.0_pReal) qu = qu * (-1.0_pReal)
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endif
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endif
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