Diels-Alder Reaction Experimental Design (VPLAN)
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VPLAN
Differential equations:
c RHS of the differential equations subroutine ffcn( t, x, f, p, q, rwh, iwh, iflag ) implicit none real*8 x(*), f(*), p(*), q(*), rwh(*), t integer*4 iwh(*), iflag real*8 n1, n2, n3, n4 real*8 na1, na2, na4 real*8 fg, Temp, E , Rg , T1, Tc real*8 r1, mR real*8 kr1, kkat, Ckat, Ekat real*8 k1, lambda real*8 M1, M2, M3, M4 real*8 dm c State variables n1 = x(1) n2 = x(2) n3 = x(3) n4 = x(4) c Control variables na1 = q(1) na2 = q(2) na4 = q(3) Ckat = q(4) c Control function c DISCRETIZE1( Tc, rwh, iwh ) c Parameters kr1 = p(1) * 1.0d-2 E = p(2) * 60000.0d+0 k1 = p(3) * 0.10d+0 Ekat = p(4) * 40000.0d0 lambda = p(5) * 0.25d+0 c Molar masses (in kg/mol) M1 = 0.1362d+0 M2 = 0.09806d+0 M3 = M1 + M2 M4 = 0.236d+0 Temp = Tc + 273.0d+0 Rg = 8.314d+0 T1 = 293.0d+0 c Reaction rates mR = n1*M1 + n2*M2 +n3*M3 + n4*M4 kkat = kr1 * dexp( -E/Rg * ( 1.0d+0/Temp - 1.0d+0/T1 ) ) & + k1 * dexp( -Ekat/Rg *( 1.0d+0/Temp - 1.0d+0/T1 ) ) & * Ckat * dexp( -lambda * t ) r1 = kkat * n1 * n2 / mR f(1) = -r1 f(2) = -r1 f(3) = r1 f(4) = 0.0d0 end
Algebraic equations:
c Dummyfunction for RHS of algebraic equations subroutine gfcn( t, x, g, p, q, rwh, iwh, iflag ) implicit none real*8 x(*), g(*), p(*), q(*), rwh(*), t integer*4 iwh(*), iflag iflag=0 end
Measurement function:
c Messfunktion subroutine mess3( t, x, h, p, q, rwh, iwh, iflag ) implicit none real*8 t, x(*), h, p(*), q(*), rwh(*) integer*4 iwh(*), iflag real*8 M1, M2, M3, M4, mR c Berechnung der Reaktormasse M1 = 0.1362d+0 M2 = 0.09806d+0 M3 = M1 + M2 M4 = 0.236d+0 mR = M1*x(1) + M2*x(2) + M3*x(3) + M4*x(4) c Messwert: Massenprozent h = M3*x(3) * 100.0d+0/mR iflag = 0 end
Standard deviation of measurement function:
c Standardabweichung der Messfunktion subroutine sigma3( t, x, s, p, q, rwh, iwh, iflag ) implicit none real*8 rwh(*) integer*4 iwh(*), iflag real*8 t, x(*), p(*), q(*) real*8 s real*8 h s = 1.0d+0 iflag = 0 end