## New answers tagged markov-chains

0

You could create a dataframe (df) with the indices as your Depth bin and columns (headers) as your Temperature bin. The values in the dataframe would be counts within each Depth and Temp bin. You can then plot the heat map with seaborn like in
seaborn.heatmap(df,vmin=0,vmax=maxcountvalue,cmap=cmap)
plt.show()
If you give the details of your array/range ...

1

In R you can use the markovchain package to get the transition matrix that satisfies markov property. You can use the following example code...
library(markovchain)
data(rain)
mysequence<-rain$rain
createSequenceMatrix(mysequence)
myFit<-markovchainFit(data=mysequence,,method="bootstrap",nboot=5, name="Bootstrap Mc")
myFit
The myFit is your ...

0

The multiplication of matrix in R is not * but %*%.
I wrote a simple function in R to solve the problem.
trans_mat = function(k,s_t,M){
for(i in 1:k){
M = M % * % M
}
return(M%*%s_t)}
now, what you need to do is to type in k(how long the period you want),s_t(the original state), and M(markov property).
s_t+k = ...

0

This maybe an easier way for calculating the transition probability matrix (TPM) for a given sequence of data (one vector) like this:
myS = {S1,S2,S1,S3,...} with as many states as you have;
TPM = hmmestimate(myS,myS);
hmmestimate function is defined under hidden markov models in MATLAB.

2

I'm not familiar with Markovian sequences, but this produces the same output:
xx <- strsplit(Seqdata$Seq, '>', fixed=TRUE)
table(From=unlist(lapply(xx, append, 'Start', 0L)),
To=unlist(mapply(c, xx, ifelse(Seqdata$Lives == 0L, 'Dies', 'Lives'))))

2

Solving Markov chain problems where you need to rely on floating point math (np.isclose) indicates your graph representation isn't correct for the problem you're trying to solve.
Below I've presented an alternative solution using networkx (but I assume changing to csgraph wouldn't be hard) that relies solely on connectivity and working out which edges link ...

1

The following should work, noting that the total probability in an absorbing set of states equals number of states in that set:
components,labels = csgraph.connected_components(P, directed=True, connection='strong',return_labels=True)
absorbingStates = np.zeros(P.shape[0],dtype=bool)
for component in range(components):
indices = np.where(labels==...

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