I am trying to implement the classical RK4 algorithm in Haskell to solve systems of coupled ODEs, taking the simple pendulum as a sample system. Unfortunately I haven’t been able to fix the following error.

```
Pendulum.hs:43:27:
No instance for (Num [Double]) arising from a use of `rk4'
Possible fix: add an instance declaration for (Num [Double])
In the first argument of `iterate', namely `(rk4 fs h)'
In the expression: iterate (rk4 fs h) initial
In an equation for `result': result = iterate (rk4 fs h) initial
Failed, modules loaded: none.
```

Where Haskell has inferred the type of rk4 to be

```
rk4 :: (Fractional b, Num [b]) => [[b] -> [b] -> b] -> b -> [[b]] -> [[b]]
```

The source code

```
module Pendulum where
import Data.List
{-
The simple pendulum
This is system which obeys the following equation.
$ \frac{d^2 \theta}{dt^2} + \frac{g}{L}\theta = 0 $
where g is the acceleration due to gravity, L the length of the pendulum and theta
the angular displacement of the pendulum
By observation you could see thar for small angles the solution for simple harmonic osscilator could be used,
but for large angles a numerical solution is required.
This simulation uses the Runge Kutta 4th Order Method to solve the ODE.
-}
data PhysicalParam = PhysicalParam { pMass :: Double -- kg Pendulum mass
, pLength :: Double -- m Pendulum length
}
data PendulumState = PendulumState { omega :: Double -- rad/s Angular Velocity
, theta :: Double -- rad Angular Displacement
, time :: Double -- s Time
}
type Time = Double
type TIncrement = Double
list2State :: [[Double]] -> PendulumState
list2State [xs, ys] = PendulumState { theta = (ys !! 0)
, omega = (ys !! 1)
, time = (xs !! 0)
}
state2List :: PendulumState -> [[Double]]
state2List state = [[time state],[theta state, omega state ]]
--pendulum :: PhysicalParam -> PendulumState -> Time -> TIncrement -> [PendulumState]
pendulum physicalParam initState time dt = result -- map list2State result
where result = iterate (rk4 fs h) initial
omegaDerivative pp state = adg * sin (theta state) / (pLength pp)
thetaDerivative pp state = omega state
fs = [(\xs ys -> omegaDerivative physicalParam (list2State [xs, ys]))
,(\xs ys -> thetaDerivative physicalParam (list2State [xs, ys]))
]
initial = state2List initState
h = dt
adg = 9.81 -- m/s
--rk4 :: Floating a => [ [a] -> [a] -> a ] -> a -> [[a]] -> [[a]]
rk4 fs h [xs, ys] = [xs', ys']
where xs' = map (+h) xs
ys' = ys + map (*(h/6.0)) (k1 + (map (*2.0) k2) + (map (*2.0) k3) + k4)
where k1 = [f (xs) (ys) | f <- fs]
k2 = [f (map (+0.5*h) xs) (ys + map (*(0.5*h)) k1) | f <- fs]
k3 = [f (map (+0.5*h) xs) (ys + map (*(0.5*h)) k2) | f <- fs]
k4 = [f (map (+1.0*h) xs) (ys + map (*(1.0*h)) k3) | f <- fs]
physParam = PhysicalParam { pMass = 1.0, pLength = 0.1 }
-- Initial Conditions
initState = PendulumState { omega = 1.0, theta = 1.0, time = 0.0 }
dt = 1.0/100 -- time increment
simTime = 30.0 -- simulation time
simulatedStates = pendulum physParam initState simTime dt
```