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Recursive function within an NDSolve is not updating

The code below models a simple SIR model (used in disease control) in Mathematica. (I copied it directly from my notebook).

The equations can be solved using `NDSolve` and the solutions are inserted into three different functions for further use.

As can be seen the Beta term on the first line varies depending on the value of Inf[t], which is one of the three solutions of the `NDSolve` function.

This code works fine and I have included this in order to better explain my quesion below.

``````Beta = Piecewise[{{0.01, Inf[t] > 20}, {.06, Inf[t] <= 20}}];
Mu = 0.1;
Pop = 100;
ans = NDSolve[{S'[t] == -Beta S[t] Inf[t],
Inf'[t] == Beta S[t] Inf[t] - Mu Inf[t],
R'[t] == Mu Inf[t],
S[0] == Pop - 1, Inf[0] == 1,
R[0] == 0}, {S[t], Inf[t], R[t]}, {t, 0, 10}];
Sus[t_] = S[t] /. ans[[1, 1]];
Infected[t_] = Inf[t] /. ans[[1, 2]];
Rec[t_] = R[t] /. ans[[1, 3]];
``````

I now wanted to update the code so that instead of having an either/or value for the `Beta` parameter based on the `Inf[t]` value, I would have the Beta value being equal to the output of a function where `Inf[t]` is the input. This can be seen below where `UpdateTransmission[]` is the function.

When I try and run the code below though the `Beta` value remains at 0 and does not increase. The problem is not with the `UpdateTransmission` function as I have tested this independently.

``````Beta = UpdateTransmission[SpinMatrix, ThresholdMatrix, Inf[t]];
Mu = 0.1;
Pop = 100;
ans = NDSolve[{S'[t] == -Beta S[t] Inf[t],
Inf'[t] == Beta S[t] Inf[t] - Mu Inf[t],
R'[t] == Mu Inf[t], S[0] == Pop - 1, Inf[0] == 1,
R[0] == 0},
{S[t], Inf[t], R[t]}, {t, 0, 10}];
Sus[t_] = S[t] /. ans[[1, 1]];
Infected[t_] = Inf[t] /. ans[[1, 2]];
Rec[t_] = R[t] /. ans[[1, 3]];

Plot[{Sus[t], Infected[t], Rec[t]}, {t, 0, 5}]
``````

Can anyone shed some light on why this may not be running correctly?

Edit: here is the updated function

``````UpdateTransmission[S_, Th_, Infect_] := Module[{BetaOverall},
P = S;
For[i = 1, i <= Pop, i++,
P[[i]] = Sign[Infect - Th[[i]]];];
BetaOverall = ((Count[P, 1]*.02) + (Count[P, -1]*.5))/Pop
]
``````

Here are the two lists that are referred to in the code above:

``````SpinMatrix = Table[-1, {Pop}]

val := RandomReal[NormalDistribution[.5, .1]]
ThresholdMatrix = Table[Pop*val, {Pop}]
``````

Edit Edit

Ok I've put everything together and tried to plot my three curves. Now as can be seen here they are all flat-lining. The Sus[t] line is staying at 100 whilst the other two seem to be staying below 1. What should be happening here is that the Sus[t] line should drop considerably and the other two lines should ramp up.

(I tried to insert and image but I can't as I don't have the reputation points required so I'll just past in the code and you can see the plot yourself on your own machine)

`````` Pop = 100;
SpinMatrix = Table[-1, {Pop}];
val := RandomReal[NormalDistribution[.5, .1]];
ThresholdMatrix = Table[Pop*val, {Pop}];

updateTransmission[S_, Th_, Infect_] := Module[{}, P = S;
For[i = 1, i <= Pop, i++, P[[i]] = Sign[Infect - Th[[i]]];];
Return[((Count[P, 1]*.02) + (Count[P, -1]*.5))/Pop]];

beta[t_] := updateTransmission[SpinMatrix, ThresholdMatrix, Inf[t]];
mu = 0.1;
ans = NDSolve[{S'[t] == -beta[t] S[t] Inf[t],
Inf'[t] == beta[t] S[t] Inf[t] -
mu Inf[t], R'[t] == mu Inf[t], S[0] == Pop - 1, Inf[0] == 1,
R[0] == 0}, {S[t], Inf[t], R[t]}, {t, 0, 10}];
Sus[t_] = S[t] /. First@ans;
Infected[t_] = Inf[t] /. First@ans;
Rec[t_] = R[t] /. First@ans;
Plot[{Sus[t], Infected[t], Rec[t]}, {t, 0, 10}]
``````

The output that I am expecting should look similar to that of the code given below:

``````Beta = Piecewise[{{0.5, Inf[t] > 20}, {.02, Inf[t] <= 20}}];
Mu = 0.1;
Pop = 100;
ans = NDSolve[{S'[t] == -Beta S[t] Inf[t],
Inf'[t] == Beta S[t] Inf[t] - Mu Inf[t],
R'[t] == Mu Inf[t], S[0] == Pop - 1, Inf[0] == 1,
R[0] == 0}, {S[t], Inf[t], R[t]}, {t, 0, 10}];
Sus[t_] = S[t] /. ans[[1, 1]];
Infected[t_] = Inf[t] /. ans[[1, 2]];
Rec[t_] = R[t] /. ans[[1, 3]];
Plot[{Sus[t], Infected[t], Rec[t]}, {t, 0, 10}]
``````
-
again, welcome to Stackoverflow. I formatted your code for readability by placing it in a code block and removing the Mathematica markup. I'd suggest learning to use markdown, the html engine used here to format posts. Above each question and answer text box is a question mark that details how to use markdown, and it is quite extensive. Also, internally Mathematica represents the character, beta, with `\[Beta]`, and the internal version is what is copied. For readability, the mark up should be removed. – rcollyer May 4 '11 at 17:19
I should note a trade off here, `Beta` is a reserved word in Mathematica, but `\[Beta]` is not. So, the above code is not directly executable any longer, and I don't think the veteran members have come to a consensus on exactly what needs to be done. My thinking is that the mark-up should be removed and the symbols made lower case. Any one else have any thoughts on this? – rcollyer May 4 '11 at 17:34
Ok thanks for the advice. I'll try that out in my future questions – Sperick May 4 '11 at 18:05
Ok thanks for that advice. I have tried voting up answers but I am unable to as my total is too low for the time being. I certainly hope that I can answer other people's questions as my own knowledge grows. – Sperick May 5 '11 at 16:45

The culprit is Sign[ ]

I don't know why, but I traced the problem to the Sign[ ] function that is not working properly inside NDSolve!

Removing it:

``````Pop = 100;
SpinMatrix = Table[-1, {Pop}];
val := RandomReal[NormalDistribution[.5, .1]];

ThresholdMatrix = Table[Pop*val, {Pop}];

updateTransmission[Th_, Inf_] :=
Total[Table[If[Inf >= Th[[i]], 2/100, 1/2]/Pop , {i, Pop}]];

beta[t_] := updateTransmission[ThresholdMatrix, Inf[t]];
mu = 0.1;

ans = NDSolve[{
S'[t] == -beta[t] S[t] Inf[t],
Inf'[t] == beta[t] S[t] Inf[t] - mu Inf[t],
R'[t] == mu Inf[t],
S[0] == Pop - 1,
R[0] == 0,
Inf[0] == 1}, {S[t], Inf[t], R[t]}, {t, 0, 10}];

Sus[t_] = S[t] /. First@ans;
Infected[t_] = Inf[t] /. First@ans;
Rec[t_] := R[t] /. First@ans;
Plot[{Sus[t], Infected[t], Rec[t]}, {t, 0, 10}]
``````

Gives:

Probably someone with better knowledge of Mma could explain what is happening in your code.

HTH!

-
Hi, thanks for replying. What I'm trying to output is a graph of the 3 functions at the end versus time. When I do this though I get three flatlines which is a result of the fact that my Beta value is not updating (staying at 0). I've tried making Beta into a function like you have done above but it didn't change things. – Sperick May 4 '11 at 18:05
@Sperick, using the definition of `updateTransmission` above in `beta = updateTransmission[ Inf[t] ]`, I get the same result as belisarius. Could you post the definition of `UpdateTransmission` as belisarius's operates by replacing `updateTransmission[ Inf[t] ]` with `2 Inf[t] + 1.`, which remains unevaluated as I noted in my answer. This implies that your definition is interpreting `Inf[t]` as having a value, when it should just leave it unevaluated. – rcollyer May 4 '11 at 18:16
Ok-I simplified UpdateTransmission in order to make the question less complicated. It is in fact a Module but hopefully that shouldn't make too much of a difference. Here it is (is the comment the best place to do this by the way? I can't seem to start new paragraphs) UpdateTransmission[S_, Th_, Infect_] := Module[{[Beta]Overall}, P = S; For[i = 1, i <= Pop, i++, P[[i]] = Sign[Infect - Th[[i]]];]; [Beta]Overall = ((Count[P, 1]*.02) + (Count[P, -1]*.5))/Pop ] – Sperick May 4 '11 at 18:28
@Sperick Please post that code as an update to your question (click on Edit below the question), so you can format it properly – Dr. belisarius May 4 '11 at 18:34
Ok I've done that-see above – Sperick May 4 '11 at 18:47

In some ways, you are encountering the difference between `Set` (`=`) and `SetDelayed` (`:=`). For instance, if you wrote `f = 7`, `f` becomes `7` in all occurrences of `f` after it was initialized. But, if you wrote `f = 7 t` instead, and tried to use it as you would a function, i.e. `f[8]`, you'd get `(7 t)[8]` because `Set` says that the value of `f` is unchanging. `SetDelayed`, however, implies that the value of `f` will change and must be reevaluated every time it occurs. Your initial case, though, is special.

When you wrote

``````Beta = Piecewise[{{0.01, Inf[t] > 20}, {.06, Inf[t] <= 20}}]
``````

`Inf[t]` was undefined, so that it remained unevaluated. But, every occurence of `Beta` in your differential equations was replaced by the above formula, courtesy of `Set`, so `NDSolve` only saw the `Piecewise` functions. In your second case, you wrote

``````Beta = UpdateTransmission[Inf[t]]
``````

Here the problem is that `UpdateTransmission` is executed only when `Beta` is initially defined, and while `Piecewise` remains unevaluated, `UpdateTransmission` most likely still gives a result for a purely symbolic input. I'd try one of three things,

1. replace every occurrence of `Beta` in you equations with `UpdateTransmission[Inf[t]]`,
2. redefine `Beta` using `SetDelayed`, e.g.

``````Beta := UpdateTransmission[Inf[t]]
``````

so that it will be reevaluated every time it is encountered, or

3. redefine `UpdateTransmission` to not accept symbols via either

``````UpdateTransmission[x_?(Head[#]=!=Symbol&)] := ...
``````

or

``````UpdateTransmission[x_] /; Head[x]=!= Symbol := ...
``````

Option 3 works by forcing `UpdateTransmission[Inf[t]]` to remain unevaluated, and effectively does the same thing as option 1. But, it requires a minimum of change. Personally, I'm in favor of options 1 or 3, as I don't know how many times `Beta` will need to be reevaluated as `NDSolve` operates.

-
Thanks for the very detailed and interesting reply. I have tried each of the three suggestions but I'm still getting the same output as I did before. As I said in my reply to the other person who answered I'm trying to plot a graph of the three functions at the end of the code versus time. I would expect them to vary (the Sus[t] should begin at 100 and drop down and the other two should start at 0 and 1 and rise up). Instead they are all stayin in their initial states as a result of the Beta values remaining at zero – Sperick May 4 '11 at 18:08
@sperick, I replied to you on belisarius' answer. But, this brings up an interesting point: with `beta = 0`, `Infected` should be a decaying exponential, `Exp[-0.1 t]`. Plotting `Sus[t]` in a `LogPlot` between 0 and 0.1, shows that it falls off extremely rapidly (using Belisarius' def below), as it is below `10^-8` by `t = 0.01`. However, the inability to see the decay (rise) of `Infected` (`Rec`) implies something else is going on. Have you tried quitting the kernel and restarting? – rcollyer May 4 '11 at 18:30