# How to solve ODEs with an internal threshold?

I have the following function containing some odes:

``````myfunction <- function(t, state, parameters) {
with(as.list(c(state, parameters)),{
if (X>20) {           # this is an internal threshold!
Y <- 35000
dY <- 0
}else{
dY <- b * (Y-Z)
}
dX <- a*X^6 + Y*Z
dZ <- -X*Y + c*Y - Z
# return the rate of change
list(c(dX, dY, dZ),Y,dY)
})
}
``````

Here are some results:

``````library(deSolve)
parameters <- c(a = -8/3, b = -10, c = 28)
state <- c(X = 1, Y = 1, Z = 1)
times <- seq(0, 10, by = 0.1)
out <- ode(y = state, times = times, func = myfunction, parms = parameters)
out
time         X            Y            Z            Y          dY
1    0.0  1.000000     1.000000     1.000000     1.000000     0.00000
2    0.1  1.104670     2.132728     4.470145     2.132728    23.37417
3    0.2  1.783117     6.598806    14.086158     6.598806    74.87351
4    0.3  2.620428    20.325966    42.957134    20.325966   226.31169
5    0.4  3.775597    60.969424   126.920014    60.969424   659.50590
6    0.5  5.358823   176.094907   358.726482   176.094907  1826.31575
7    0.6  7.460841   482.506706   953.270570   482.506706  4707.63864
8    0.7 10.122371  1230.831764  2330.599161  1230.831764 10997.67398
9    0.8 13.279052  2859.284114  5113.458479  2859.284114 22541.74365
10    0.9 16.711405  5912.675147  9823.406760  5912.675147 39107.31613
11    1.0 24.452867 10590.600567 16288.435139 35000.000000     0.00000
12    1.1 25.988924 10590.600567 23476.343542 35000.000000     0.00000
13    1.2 26.572411 10590.600567 26821.703961 35000.000000     0.00000
14    1.3 26.844240 10590.600567 28510.668725 35000.000000     0.00000
15    1.4 26.980647 10590.600567 29391.032472 35000.000000     0.00000
...
``````

States Y are different, can anybody explain me why please?

I believe I haven't set my threshold correctly. Is there a way to that?

Thanks!

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I tried to decipher the help file for `ode` but w/o success. All I can suggest is to try a very simple function and see what the various returned columns represent. I suspect the two "Y" columns are looking at different things. –  Carl Witthoft Oct 31 '12 at 12:29
I have amended the code to highlight that columns 3 and 5 should both look at the same thing. However when the threshold becomes active (from line number 11) they return different results?! –  Lilith Oct 31 '12 at 13:07
Again, I don't know what the underlying `soda*` algorithm does, but my guess now is that `10590.600567` is the output of the previous cycle (when `dY` was still nonzero), and that value remains in whatever the "Y input" column represents, while the "Y output" is properly frozen at 35000 . –  Carl Witthoft Oct 31 '12 at 17:06
`?events` could be a way to get around this –  user1981275 Apr 12 '13 at 15:10

Think the simplest method to solve ODEs, i.e. Euler method:

`````` state = state+myfunction(t,state,parameters)*h
f(t+h)=f(t) + f'(t) *h
``````

`h` is a small time step, `myfunction` is the `f'(t)` derivative of `f(t)` and only evaluates the derivative, it does not have access to the actual `state` nor `Y`. Both are set internally in `ode` using a method which in principle is similar to Euler's: given the numerical values of `f(t),f'(t),h` it just updates state `f(t+h)`.

So the threshold adjusts `dY` but cannot access `state["Y"]`. The process just manipulates a local variable which is evaluated as `35000` in `dX <- a*X^6 + Y*Z` and `dZ <- -X*Y + c*Y - Z` but the actual `state["Y"]` is overwritten after the `myfuction` has returned inside the `ode` function.

I am afraid that I cannot think of a simple way to bypass this design. I would just use `out[5]`.

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