I have a predator-prey model with parameters and initial values as specified. I solve the differential equations two ways here 1. using a for loop and 2. using the deSolve package. I believe the for loop is correct, and should give output as seen in the plot below.

```
##################
#For loop attempt
##################
r=0.1; k=100; v=40; s=.1; tbeg=0; tend=1200; nints=1200
c=.06; a=.12; predator0=c(15); prey0=c(50)
dt=(tend-tbeg)/nints
prey=matrix(0,nints+1,length(prey0))
predator=matrix(0, nints+1, length(predator0))
predator[1, ]=predator0
time=numeric(nints+1)
prey[1, ]=prey0
for(i in 1:nints) {
dprey=r*prey[i, ]-(r*prey[i, ]*prey[i, ]/k)-(s*prey[i, ]*predator[i, ])/(v+prey[i, ])*dt
prey[i+1, ]=prey[i, ]+dprey
dpredator=(a*prey[i, ]*predator[i, ])/(v+prey[i, ])-(c*predator[i, ])*dt
predator[i+1, ]=predator[i, ]+dpredator
time[i+1]=time[i]+dt}
matplot(time, prey, type="l", lty=1, main="Case 1: Predator and Prey Populations over Time", ylab="Population", xlab="Time")
points(time, predator, type="l", lty=2)
```

I am attempting to use the package deSove to solve this system of DE's and expect similar output. The code runs, but provides a different answer. (Following "A Primer on Ecology" examples)

```
##################
#deSolve attempt
##################
library(deSolve)
#the case of a prey with a logistic growth and predator functional response
predprey_FuncResp <- function(t, y, parms) {
n0 <- y[[1]]
p0 <- y[[2]]
with(as.list(parms), {
dpdt <- (a*n0*p0)/(v+n0) - c*p0
# dndt <- r*n0 - (r*n0^2)/k - (s*n0*p0)/(v+n0)
dndt <- r*n0*(1-n0/k) - (s*n0*p0)/(v+n0)
return(list(c(dpdt, dndt)))
})
}
parms <- c(a=.12, c=.06 , r=.1,s=.1,k=100, v=40)
Tmax = 1000 # time horizon
TimeStep = 1 # integration time step
Time <- seq(0, Tmax, by = TimeStep) # the corresponding vector
LV.out <- lsoda(c(n0 = 50, p0 = 15), Time, predprey_FuncResp, parms)
matplot(LV.out[,1],LV.out[,-1], type='l')
```

I assume I am using deSolve incorrectly but cannot see my error. Thanks to anyone who takes the time to look at this.