2023-12-22 16:39:03 +00:00
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---
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tags:
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- ai
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---
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2023-06-08 17:52:09 +01:00
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[Hidden Markov Models - JWMI Github](https://jwmi.github.io/ASM/5-HMMs.pdf)
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[Rabiner - A Tutorial on Hidden Markov Models and Selected Applications in Speech Recognition](https://www.cs.cmu.edu/~cga/behavior/rabiner1.pdf)
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- Stochastic sequences of discrete states
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- Transitions have probabilities
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- Desired output not always produced the same
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- Same pronunciation
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![](../../../img/markov-state.png)
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$$P(X|M)=\left(\prod_{t=1}^Ta_{x_{t-1}x_t}\right)\eta_{x_T}$$
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$$a_{x_0x_1}=\pi_{x_1}$$
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# 1st Order
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- Depends only on previous state
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- Markov assumption
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$$P(x_t=j|x_{t-1}=i,x_{t-2}=h,...)\approx P(x_t=j|x_{t-1}=i)$$
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- Described by state-transition probabilities
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$$a_{ij}=P(x_t=j|x_{t-1}=i), 1\leq i,j\leq N$$
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- $\alpha$
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- State transition
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- For $N$ states
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- $N$ by $N$ matrix of state transition probabilities
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# Weather
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![](../../../img/markov-weather.png)
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$$A=\left\{a_{ij}\right\}=\begin{bmatrix} 0.4 & 0.3 & 0.3\\ 0.2 & 0.6 & 0.2 \\ 0.1 & 0.1 & 0.8 \end{bmatrix}$$
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rain, cloud, sun across columns and down rows
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$$A=\{\pi_j,a_{ij},\eta_i\}=\{P(x_t=j|x_{t-1}=i)\}$$
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# Start/End
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- Null states
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- Entry/exit states
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- Don't generate observations
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![](../../../img/markov-start-end.png)
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$$\pi_j=P(x_1=j) \space 1 \leq j \leq N$$
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- Sub $j$ because probability of kicking off into that state
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$$\eta_i=P(x_T=i) \space 1 \leq i \leq N$$
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- Sub $i$ because probability of finishing from that state
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![](../../../img/markov-start-end-probs.png)
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![](../../../img/markov-start-end-matrix.png)
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# State Duration
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- Probability of staying in state decays exponentially
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$$p(X|x_1=i,M)=(a_{ii})^{\tau-1}(1-a_{ii})$$
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![](../../../img/markov-state-duration.png)
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- Given, $a_{33}=0.8$
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- $\times0.8$ repeatedly
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- Stay in state
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