Solve the ODE with NDSolve and dependet variables

I have intialconditions:

``````sf = 200;
sm = 100;
p = 40;
betaf = 0.15;
betam = 0.15;
mums = 0.02;
mufs = 0.02;
sigma = 0.20;
mum = 0.02;
muf = 0.02;
``````

and the ODE:

``````sf' := -muf*sf + (betaf + mums + sigma)*p - HarmonicMean[sf, sm];
sm' := -mum*sm + (betam + mufs + sigma)*p - HarmonicMean[sf, sm}];
p' := p - (mufs + mums + sigma)*p + HarmonicMean[{sf, sm}];
``````

That i want is an abstract solution (sf(t),sm(t),p(t)) with NDSolve to plot it later. My problem is that all variables are dependet in all 3 equations, so i don't know how to write the NDSolve call.

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If you have an abstract (analytic) solution, then you don't need `NDSolve` to plot it, just use `Plot` on the functions `DSolve` returns. If it returns anything... –  István Zachar Jan 24 '12 at 12:47

I could not manage to get an analytic solution, but the numerical one goes like this. Note that not all symbols you listed are variables of the system: those not being dependent of the independent variable t are parameters. (Also note that there are some typos in the OP's code).

``````variables = {sf[t], sm[t], p[t]};
parameters = {betaf -> 0.15, betam -> 0.15, mums -> 0.02,
mufs -> 0.02, sigma -> 0.20, mum -> 0.02, muf -> 0.02};

equations = {
sf'[t] == -muf*sf[t] + (betaf + mums + sigma)*p[t] -
HarmonicMean[{sf[t], sm[t]}],
sm'[t] == -mum*sm[t] + (betam + mufs + sigma)*p[t] -
HarmonicMean[{sf[t], sm[t]}],
p'[t] ==
p[t] - (mufs + mums + sigma)*p[t] + HarmonicMean[{sf[t], sm[t]}],
sf[0] == 200,
sm[0] == 100,
p[0] == 40
};

sol = NDSolve[equations /. parameters, variables, {t, 0, 100}];

Plot[Evaluate[variables /. sol], {t, 0, 100}]
``````

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