Find real solution of system of algebraic equations (solved in Maple, but can't do it in Matlab)

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Dear Matlab community,
I have solved a system of algebraic equations in Maple and would now like to solve the exact same system in Matlab. I thought this would be quite easy, but turns out I am wrong. Matlab returns an imaginary solution to the system while Maple finds the real one.
To write the script in Matlab I copied the code straight from Maple and then replaced Maple specific commands with Matlab specific commands. The code is attached in a file and you will also find it below. Could anyone urgently help me with finding the real solution in Matlab? Thank you!
The solutions to the system should be
  • Pct_Al2O3_i = 55.6042 ...
  • Pct_Al_i = 0.1792 ...
  • Pct_SiO2 = 0.04636 ...
  • Pct_Si_i = 0.09427 ...
clc; clear;
% Initialisation parameters & variables
Pct_Al_i = sym('Pct_Al_i');
Pct_Si_i = sym('Pct_Si_i');
Pct_Al2O3_i = sym('Pct_Al2O3_i');
Pct_SiO2_i = sym('Pct_SiO2_i');
A_int=0.025^2*pi;
T_proc=1600;
Rho_m=7000*10^3;
Rho_s=2850*10^3;
W_m=500;
W_s=75;
m_Al=3*10^(-4);
m_Si=3*10^(-4);
m_SiO2=3*10^(-5);
m_Al2O3=3*10^(-5);
Pct_Al_b=0.3;
Pct_Si_b=0;
Pct_SiO2_b=5;
Pct_Al2O3_b=50;
Pct_Al_beq=0.132;
Pct_Si_beq=0.131;
Pct_SiO2_beq=3.13;
Pct_Al2O3_beq=52.12;
AW_Al=26.9815385;
AW_Si=28.085;
AW_O=15.999;
AW_Mg=24.305;
AW_Ca=40.078;
AW_Fe=55.845;
MW_SiO2=AW_Si+2*AW_O;
MW_Al2O3=2*AW_Al+3*AW_O;
MW_MgO=AW_Mg+AW_O;
MW_CaO=AW_Ca+AW_O;
R_cst=8.3144621;
% Mass balance equations
Mass_eq1=0==(Pct_Al_b-Pct_Al_i)+4*AW_Al*m_Si/(3*AW_Si*m_Al)*(Pct_Si_b-Pct_Si_i);
Mass_eq2=0==(Pct_Al_b-Pct_Al_i)-4*Rho_s*m_SiO2*AW_Al/(3*Rho_m*m_Al*MW_SiO2)*(Pct_SiO2_b-Pct_SiO2_i);
Mass_eq3=0==(Pct_Al_b-Pct_Al_i)+2*Rho_s*m_Al2O3*AW_Al/(Rho_m*m_Al*MW_Al2O3)*(Pct_Al2O3_b-Pct_Al2O3_i);
% Equilibrium equation
delta_G0=-720680+133*T_proc;
x_SiO2_i=(Pct_SiO2_i/(100*MW_SiO2))/(Pct_Al2O3_i/(100*MW_Al2O3) + Pct_SiO2_i/(100*MW_SiO2) + (100-Pct_SiO2_i-Pct_Al2O3_i)/(100*MW_CaO));
e_AlonSi=0.058;
e_AlonAl=0.045;
e_SionSi=0.11;
e_SionAl=0.0056;
Gamma_Al_Hry=1;
Gamma_Si_Hry=1;
Gamma_SiO2_Ra=0.01;
ln_h_Al=log(Gamma_Al_Hry)+log(10)*e_SionAl*Pct_Si_i/100+log(Pct_Al_i/100);
ln_h_Si=log(Gamma_Si_Hry)+log(10)*e_AlonSi*Pct_Al_i/100+log(Pct_Si_i/100);
ln_a_Al2O3=log(0.30);
ln_a_SiO2=log(Gamma_SiO2_Ra*x_SiO2_i);
K_cst=-delta_G0/(R_cst*T_proc);
Equil_eq=K_cst==3*ln_h_Si+2*ln_a_Al2O3-4*ln_h_Al-3*ln_a_SiO2;
% Solving
S = solve([Mass_eq1, Mass_eq2, Mass_eq3, Equil_eq], [Pct_Al_i, ...
Pct_Si_i, Pct_SiO2_i, Pct_Al2O3_i]);

Answers (1)

Philip Caplan
Philip Caplan on 14 Apr 2015
In order to get a real solution to your system of equations, you need to tell MATLAB to assume your variables are real. You can do this by passing the 'real' option to "sym":
% Initialisation parameters & variables
Pct_Al_i = sym('Pct_Al_i','real');
Pct_Si_i = sym('Pct_Si_i','real');
Pct_Al2O3_i = sym('Pct_Al2O3_i','real');
Pct_SiO2_i = sym('Pct_SiO2_i','real');
I get the correct solution you mentioned when using this modification. For more information about assumptions on symbolic variables, please refer to

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