Suppose we have a coupled system of differential equations: \begin{equation} \frac{db}{dt}=(- \gamma_b -i\omega_b)b-i\frac{g}{2}p;\quad \frac{dp}{dt}=i\frac{g}{2}\Delta N(t) b-(\gamma_a+\gamma_b+2iJ)p. \end{equation} If $ \Delta N$ was fixed, the solution of the system would be like \begin{equation} \begin{pmatrix} b(t)\ p(t) \end{pmatrix}=\begin{pmatrix} a_{11}&a_{12}\ a_{21}&a_{22} \end{pmatrix}\begin{pmatrix} b(0)\ p(0) \end{pmatrix} \end{equation} Using the following code, I have found a $ 2\times 2$ matrix (called sol) whose entries are $ a_{ij}$ in the above equation:
rb=630;wb=75*10^6;g=0.63;ra=2.6*10^6;rm=3.6*10^6;J=6.3*10^7;DeltaN=0.164*10^5; m ={{-rb-I wb,-I g/2},{I g DeltaN/2,-(ra+rm+2 I J)}}; eigvec = Eigenvectors[m] // Transpose // Simplify; eigval = Eigenvalues[m] // Simplify; inv = Inverse[eigvec] // Simplify; v1 = eigval[[1]]; v2 = eigval[[2]]; sol = eigvec.{{E^(v1 t), 0}, {0, E^(v2 t) }}.inv; If we suppose that $ p(0)=0$ , then one can easily plot $ |b(t)/b(0)|^2$ : simply plot $ a_{11}(t)$ . But the problem is that $ \Delta N$ is not fixed. It is a $ N\times 1$ matrix which I have obtained from another code written with Fortran and its type is data.txt. The elements of this file are calculated by assuming the time interval between each one is $ 0.001$ . That is, for $ t=0.001$ we have $ \Delta N_1$ , for $ t=0.002$ we have $ \Delta N_2$ , etc. But the time intervals are not included in the txt file.
One way that comes to my mind is this: Assuming we know the analytical form of solfor a fixed $ \Delta N$ , we set time, i.g., equal to $ 0.001$ and then substitute the first row of the txt file (I call it $ \Delta N_1$ ) into sol and find $ a_{11}$ . Then we raise time to $ 0.002$ , substitute $ \Delta N_1$ into sol, find $ a_{11}$ , and repeat the procedure to the last row of the txt file.
Now the question is this: how can I import the txt file to the code and do the procedure that I explained above to get some data like $ \{\{0.001,a11(0.001)\},\{0.002,a11(0.002)\},….\}$ where the first elements are time intervals and the second ones are $ a_{ij}$ corresponding to that particular time?
I had asked a similar question here enter link description here, but in that problem I did not have an external file with txt format.
I could not upload my txt file, so I write the first 10 elements if necessary:
0.164E+05
0.655E+05
0.146E+06
0.258E+06
0.400E+06
0.572E+06
0.776E+06
0.101E+07
0.129E+07
0.159E+07
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