Is it possible to estimate the initial distribution of (hidden) state using Baum-Welch algorithm?

I have implemented the Baum-Welch algorithm and I am playing with some toy data, generated with a known distribution. The data is normally distributed, had different mean and standard deviation depending on the hidden state. There are 2 states. The algorithm seems to converge for most of the parameters apart from the initial distribution of the hidden state, which always converges to either (0; 1) or (1; 0) depending on the random data.

Is it normal in this algorithm? If so I would appreciate some references, if not some hints how to find the bug.

Code (F#). First a helper module:

module MyMath

let sqr (x:float) = x*x

let inline (./) (array:float[]) (d:float) =
Array.map (fun x -> x/d) array

let inline (.*) (array:float[]) (d:float) =
Array.map (fun x -> x*d) array

let map f s =
s |> Seq.map f |> Seq.toArray

let normalize v =
let sum = Seq.sum v
map (fun x -> x/sum) v

let row i array = seq { for j in 0 .. (Array2D.length2 array)-1 do yield array.[i,j]}
let column j array = seq { for i in 0 .. (Array2D.length1 array)-1 do yield array.[i,j]}

let sum (v:float[]) = v |> Array.sum
let sumTo N (f:int->float) = Seq.init N f |> Seq.sum
let sum_column j (array:float[,]) = column j array |> Seq.sum
let sum_row i (array:float[,]) = row i array |> Seq.sum

let mean data = (sum data)/(float (Array.length data))
let var data =
let m=mean data
let N=Array.length data
let sum=Seq.sumBy (fun x -> sqr(x)) data
sum/(float N)

let induction start T nextRow =
let result =  Array.zeroCreate T
result.[0] <- start
for t=1 to T-1 do
result.[t] <- nextRow t result.[t-1]
result

let backInduction last T previousRow =
let result =  Array.zeroCreate T
result.[T-1] <- last
for t=T-2 downto 0 do
result.[t] <- previousRow t result.[t+1]
result

let inductionNormalized start T nextRow =
let result =  Array.zeroCreate T
let norm = Array.zeroCreate T
norm.[0] <- sum start
result.[0] <- start./norm.[0]
for t=1 to T-1 do
result.[t] <- nextRow t result.[t-1]
norm.[t] <- sum result.[t]
result.[t] <- result.[t]./norm.[t]
(result, norm)


The main module:

module BaumWelch

open System
open MyMath

let mu (theta : float[,]) q = theta.[q,0]
let sigma (theta : float[,]) q = theta.[q,1]

let likelihood getDrift getVol dt parameters state observation  =
let mu = getDrift parameters state
let sigma =  Math.Abs (getVol parameters state:float)
let sqrt_dt = Math.Sqrt dt
let residueSquared =
let r = Likelihood.normalizedResidue mu sigma dt sqrt_dt observation in r*r
let result = (Math.Exp (-0.5*residueSquared))/(sigma * (Math.Sqrt (2.0*Math.PI*dt)))
if result<0.0 then failwith "Negative density, it certainly shouldn't have happened"
else result

let alphaBeta b (initialPi:float[]) initialA observations= //notation in comments from the Erratum for Rabiner
let T = Array.length observations
let N = Array2D.length1 initialA
let alphaStart = Array.init N (fun i -> initialPi.[i] * (b i observations.[0]))  //this contains \bar{\alpha}
let alpha_j_t (previousRow:float[]) t j  = (sumTo N (fun i -> previousRow.[i]*initialA.[i, j]))* (b j observations.[t]) //this contains \bar{\alpha}
let alphaInductionStep t previousRow = Array.init N (alpha_j_t previousRow t)
let (alpha, norm) = inductionNormalized alphaStart T alphaInductionStep
let betaStart = Array.init N (fun i -> 1.0/norm.[T-1])
let beta_j_t (nextRow:float[]) t j = (sumTo N (fun i -> initialA.[j, i]*nextRow.[i]*(b i observations.[t+1])))/norm.[t]
let betaInductionStep t nextRow = Array.init N (beta_j_t nextRow t)
let beta = backInduction betaStart T betaInductionStep
(alpha, beta, norm) //c_t = 1/norm_t

let log_P_O norm =
let result = norm |> Seq.sumBy (fun norm_t -> Math.Log norm_t)//c_t = 1/norm_t
if Double.IsNaN result then failwith "log likelihood is NaN"
else result

let gamma (alpha:float[][], beta:float[][], norm:float[])  i t =
alpha.[t].[i]*beta.[t].[i]*norm.[t]

let xi b (initialA:float[,]) (alpha:float[][]) (beta:float[][]) (observations:float[]) i j t =
alpha.[t].[i]*initialA.[i,j]*(b j observations.[t+1])*beta.[t+1].[j]

let oneStep llFunction dt (initialPi, initialA, initialTheta) observations =
let T = Array.length observations
let N = Array2D.length1 initialA
let b = llFunction dt initialTheta
let (alpha, beta, norm) = alphaBeta b initialPi initialA observations
let gamma = gamma (alpha, beta, norm)
let xi = xi b initialA alpha beta observations
let pi = Array.init N (fun i -> gamma i 0) //Rabiner (40a)
let A =  //Rabiner (40b)
let A_func i j = (sumTo (T-1) (xi i j))/(sumTo (T-1) (gamma i))
Array2D.init N N A_func
let mean i = (sumTo T (fun t -> (gamma i t) * observations.[t]))/(sumTo T (gamma i))//Rabiner (53)
let var i =
let numerator = sumTo T (fun t -> (gamma i t) * (sqr (observations.[t]-(mean i))))
let denumerator = sumTo T (gamma i)
numerator/denumerator
let mu i = ((mean i) + 0.5*(var i))/dt
let sigma i = Math.Sqrt ((var i)/dt)
let theta = Array2D.init N 2 (fun i k -> if k=0 then mu i else sigma i)
let logLikelihood = log_P_O norm //Rabiner (103)
(logLikelihood, (pi, A, theta))

let print (ll, (pi, A, theta)) =
printfn "pi = %A" pi
printfn "A = %A" A
printfn "theta = %A" theta
printfn "logLikelihood = %f" ll

let baumWelch likelihood dt initialParams observations =
let tolerance = 10e-5
let rec doStep parameters previousLL =
//print (previousLL, parameters)
let (logLikelihood, parameters) = oneStep likelihood dt parameters observations
if Math.Abs(previousLL - logLikelihood) < tolerance then (logLikelihood, parameters)
else doStep parameters logLikelihood
doStep initialParams -10e100

-

I haven't tried to guess my way through the F#, but here are some observations:

1) How many initial states do you have observations for? If the answer is "just one" then the probability of the observations can be written as P(state 0) P(obs | state is 0) + P(state 1) P(obs | state 1). Depending on which of the two P(obs | state is X) is higher, the maximum likelihood solution will have either P(state 0) = 1 or P(state 1) = 1. I would only expect to see intermediate probabilities for the initial state when it is possible that you are observing observations that derive from a number of different initial states - for instance, if you have more than one stretch of toy data to analyse at the same time.

2) In looking for a bug, it can help to produce toy data where the answer is entirely obvious. If I had n stretches of data of the form {0, 0, 0, 0...} and m stretches of data of the form {1, 1, 1, 1...} I might hope to see state 0 assigned initial probability n/(m +n) - or of course m/(n + m), since the program doesn't know which state I wish to link with which sequence.

3) Another way to check programs is to look for some sort of consistency or conservation check. Since the model of two initial states can be made the same as a model with just one initial state, a special set of transition probabilities for the first observation, and possibly a special dummy first observation, you could check its behaviour with two initial states against its behaviour with just one initial state and some fudging.

-