Baum–Welch algorithm

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In electrical engineering, statistical computing and bioinformatics, the Baum–Welch algorithm is a special case of the expectation–maximization algorithm used to find the unknown parameters of a hidden Markov model (HMM). It makes use of the forward-backward algorithm to compute the statistics for the expectation step. The Baum–Welch algorithm, the primary method for inference in hidden Markov models, is numerically unstable due to its recursive calculation of joint probabilities. As the number of variables grows, these joint probabilities become increasingly small, leading to the forward recursions rapidly approaching values below machine precision.[1]

History

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The Baum–Welch algorithm was named after its inventors Leonard E. Baum and Lloyd R. Welch. The algorithm and the Hidden Markov models were first described in a series of articles by Baum and his peers at the IDA Center for Communications Research, Princeton in the late 1960s and early 1970s.[2] One of the first major applications of HMMs was to the field of speech processing.[3] In the 1980s, HMMs were emerging as a useful tool in the analysis of biological systems and information, and in particular genetic information.[4] They have since become an important tool in the probabilistic modeling of genomic sequences.[5]

Description

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A hidden Markov model describes the joint probability of a collection of "hidden" and observed discrete random variables. It relies on the assumption that the i-th hidden variable given the (i − 1)-th hidden variable is independent of previous hidden variables, and the current observation variables depend only on the current hidden state.

The Baum–Welch algorithm uses the well known EM algorithm to find the maximum likelihood estimate of the parameters of a hidden Markov model given a set of observed feature vectors.

Let   be a discrete hidden random variable with   possible values (i.e. We assume there are   states in total). We assume the   is independent of time  , which leads to the definition of the time-independent stochastic transition matrix

 

The initial state distribution (i.e. when  ) is given by

 

The observation variables   can take one of   possible values. We also assume the observation given the "hidden" state is time independent. The probability of a certain observation   at time   for state   is given by

 

Taking into account all the possible values of   and  , we obtain the   matrix   where   belongs to all the possible states and   belongs to all the observations.

An observation sequence is given by  .

Thus we can describe a hidden Markov chain by  . The Baum–Welch algorithm finds a local maximum for   (i.e. the HMM parameters   that maximize the probability of the observation).[6]

Algorithm

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Set   with random initial conditions. They can also be set using prior information about the parameters if it is available; this can speed up the algorithm and also steer it toward the desired local maximum.

Forward procedure

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Let  , the probability of seeing the observations   and being in state   at time  . This is found recursively:

  1.  
  2.  

Since this series converges exponentially to zero, the algorithm will numerically underflow for longer sequences.[7] However, this can be avoided in a slightly modified algorithm by scaling   in the forward and   in the backward procedure below.

Backward procedure

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Let   that is the probability of the ending partial sequence   given starting state   at time  . We calculate   as,

  1.  
  2.  

Update

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We can now calculate the temporary variables, according to Bayes' theorem:

 

which is the probability of being in state   at time   given the observed sequence   and the parameters  

 

which is the probability of being in state   and   at times   and   respectively given the observed sequence   and parameters  .

The denominators of   and   are the same ; they represent the probability of making the observation   given the parameters  .

The parameters of the hidden Markov model   can now be updated:

  •  

which is the expected frequency spent in state   at time  .

  •  

which is the expected number of transitions from state i to state j compared to the expected total number of transitions away from state i. To clarify, the number of transitions away from state i does not mean transitions to a different state j, but to any state including itself. This is equivalent to the number of times state i is observed in the sequence from t = 1 to t = T − 1.

  •  

where

 

is an indicator function, and   is the expected number of times the output observations have been equal to   while in state   over the expected total number of times in state  .

These steps are now repeated iteratively until a desired level of convergence.

Note: It is possible to over-fit a particular data set. That is,  . The algorithm also does not guarantee a global maximum.

Multiple sequences

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The algorithm described thus far assumes a single observed sequence  . However, in many situations, there are several sequences observed:  . In this case, the information from all of the observed sequences must be used in the update of the parameters  ,  , and  . Assuming that you have computed   and   for each sequence  , the parameters can now be updated:

  •  
  •  
  •  

where

 

is an indicator function

Example

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Suppose we have a chicken from which we collect eggs at noon every day. Now whether or not the chicken has laid eggs for collection depends on some unknown factors that are hidden. We can however (for simplicity) assume that the chicken is always in one of two states that influence whether the chicken lays eggs, and that this state only depends on the state on the previous day. Now we don't know the state at the initial starting point, we don't know the transition probabilities between the two states and we don't know the probability that the chicken lays an egg given a particular state.[8][9] To start we first guess the transition and emission matrices.

Transition
State 1 State 2
State 1 0.5 0.5
State 2 0.3 0.7
Emission
No Eggs Eggs
State 1 0.3 0.7
State 2 0.8 0.2
Initial
State 1 0.2
State 2 0.8

We then take a set of observations (E = eggs, N = no eggs): N, N, N, N, N, E, E, N, N, N

This gives us a set of observed transitions between days: NN, NN, NN, NN, NE, EE, EN, NN, NN

The next step is to estimate a new transition matrix. For example, the probability of the sequence NN and the state being   then   is given by the following,  

Observed sequence Highest probability of observing that sequence if state is   then   Highest Probability of observing that sequence
NN 0.024 = 0.2 × 0.3 × 0.5 × 0.8 0.3584  , 
NN 0.024 = 0.2 × 0.3 × 0.5 × 0.8 0.3584  , 
NN 0.024 = 0.2 × 0.3 × 0.5 × 0.8 0.3584  , 
NN 0.024 = 0.2 × 0.3 × 0.5 × 0.8 0.3584  , 
NE 0.006 = 0.2 × 0.3 × 0.5 × 0.2 0.1344  , 
EE 0.014 = 0.2 × 0.7 × 0.5 × 0.2 0.0490  , 
EN 0.056 = 0.2 × 0.7 × 0.5 × 0.8 0.0896  , 
NN 0.024 = 0.2 × 0.3 × 0.5 × 0.8 0.3584  , 
NN 0.024 = 0.2 × 0.3 × 0.5 × 0.8 0.3584  , 
Total 0.22 2.4234

Thus the new estimate for the   to   transition is now   (referred to as "Pseudo probabilities" in the following tables). We then calculate the   to  ,   to   and   to   transition probabilities and normalize so they add to 1. This gives us the updated transition matrix:

Old Transition Matrix
State 1 State 2
State 1 0.5 0.5
State 2 0.3 0.7
New Transition Matrix (Pseudo Probabilities)
State 1 State 2
State 1 0.0598 0.0908
State 2 0.2179 0.9705
New Transition Matrix (After Normalization)
State 1 State 2
State 1 0.3973 0.6027
State 2 0.1833 0.8167

Next, we want to estimate a new emission matrix,

Observed Sequence Highest probability of observing that sequence
if E is assumed to come from  
Highest Probability of observing that sequence
NE 0.1344  ,  0.1344  , 
EE 0.0490  ,  0.0490  , 
EN 0.0560  ,  0.0896  , 
Total 0.2394 0.2730

The new estimate for the E coming from   emission is now  .

This allows us to calculate the emission matrix as described above in the algorithm, by adding up the probabilities for the respective observed sequences. We then repeat for if N came from   and for if N and E came from   and normalize.

Old Emission Matrix
No Eggs Eggs
State 1 0.3 0.7
State 2 0.8 0.2
New Emission Matrix (Estimates)
No Eggs Eggs
State 1 0.0404 0.8769
State 2 1.0000 0.7385
New Emission Matrix (After Normalization)
No Eggs Eggs
State 1 0.0441 0.9559
State 2 0.5752 0.4248

To estimate the initial probabilities we assume all sequences start with the hidden state   and calculate the highest probability and then repeat for  . Again we then normalize to give an updated initial vector.

Finally we repeat these steps until the resulting probabilities converge satisfactorily.

Applications

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Speech recognition

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Hidden Markov Models were first applied to speech recognition by James K. Baker in 1975.[10] Continuous speech recognition occurs by the following steps, modeled by a HMM. Feature analysis is first undertaken on temporal and/or spectral features of the speech signal. This produces an observation vector. The feature is then compared to all sequences of the speech recognition units. These units could be phonemes, syllables, or whole-word units. A lexicon decoding system is applied to constrain the paths investigated, so only words in the system's lexicon (word dictionary) are investigated. Similar to the lexicon decoding, the system path is further constrained by the rules of grammar and syntax. Finally, semantic analysis is applied and the system outputs the recognized utterance. A limitation of many HMM applications to speech recognition is that the current state only depends on the state at the previous time-step, which is unrealistic for speech as dependencies are often several time-steps in duration.[11] The Baum–Welch algorithm also has extensive applications in solving HMMs used in the field of speech synthesis.[12]

Cryptanalysis

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The Baum–Welch algorithm is often used to estimate the parameters of HMMs in deciphering hidden or noisy information and consequently is often used in cryptanalysis. In data security an observer would like to extract information from a data stream without knowing all the parameters of the transmission. This can involve reverse engineering a channel encoder.[13] HMMs and as a consequence the Baum–Welch algorithm have also been used to identify spoken phrases in encrypted VoIP calls.[14] In addition HMM cryptanalysis is an important tool for automated investigations of cache-timing data. It allows for the automatic discovery of critical algorithm state, for example key values.[15]

Applications in bioinformatics

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Finding genes

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Prokaryotic
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The GLIMMER (Gene Locator and Interpolated Markov ModelER) software was an early gene-finding program used for the identification of coding regions in prokaryotic DNA.[16][17] GLIMMER uses Interpolated Markov Models (IMMs) to identify the coding regions and distinguish them from the noncoding DNA. The latest release (GLIMMER3) has been shown to have increased specificity and accuracy compared with its predecessors with regard to predicting translation initiation sites, demonstrating an average 99% accuracy in locating 3' locations compared to confirmed genes in prokaryotes.[18]

Eukaryotic
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The GENSCAN webserver is a gene locator capable of analyzing eukaryotic sequences up to one million base-pairs (1 Mbp) long.[19] GENSCAN utilizes a general inhomogeneous, three periodic, fifth order Markov model of DNA coding regions. Additionally, this model accounts for differences in gene density and structure (such as intron lengths) that occur in different isochores. While most integrated gene-finding software (at the time of GENSCANs release) assumed input sequences contained exactly one gene, GENSCAN solves a general case where partial, complete, or multiple genes (or even no gene at all) is present.[20] GENSCAN was shown to exactly predict exon location with 90% accuracy with 80% specificity compared to an annotated database.[21]

Copy-number variation detection

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Copy-number variations (CNVs) are an abundant form of genome structure variation in humans. A discrete-valued bivariate HMM (dbHMM) was used assigning chromosomal regions to seven distinct states: unaffected regions, deletions, duplications and four transition states. Solving this model using Baum-Welch demonstrated the ability to predict the location of CNV breakpoint to approximately 300 bp from micro-array experiments.[22] This magnitude of resolution enables more precise correlations between different CNVs and across populations than previously possible, allowing the study of CNV population frequencies. It also demonstrated a direct inheritance pattern for a particular CNV.

Implementations

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See also

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References

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  1. ^ "Scaling Factors for Hidden Markov Models". gregorygundersen.com. Retrieved 2024-10-19.
  2. ^ Rabiner, Lawrence. "First Hand: The Hidden Markov Model". IEEE Global History Network. Retrieved 2 October 2013.
  3. ^ Jelinek, Frederick; Bahl, Lalit R.; Mercer, Robert L. (May 1975). "Design of a linguistic statistical decoder for the recognition of continuous speech". IEEE Transactions on Information Theory. 21 (3): 250–6. doi:10.1109/tit.1975.1055384.
  4. ^ Bishop, Martin J.; Thompson, Elizabeth A. (20 July 1986). "Maximum likelihood alignment of DNA sequences". Journal of Molecular Biology. 190 (2): 159–65. doi:10.1016/0022-2836(86)90289-5. PMID 3641921.
  5. ^ Durbin, Richard (23 April 1998). Biological Sequence Analysis: Probabilistic Models of Proteins and Nucleic Acids. Cambridge University Press. ISBN 978-0-521-62041-3.
  6. ^ Bilmes, Jeff A. (1998). A Gentle Tutorial of the EM Algorithm and its Application to Parameter Estimation for Gaussian Mixture and Hidden Markov Models. Berkeley, CA: International Computer Science Institute. pp. 7–13.
  7. ^ Rabiner, Lawrence (February 1989). "A Tutorial on Hidden Markov Models and Selected Applications in Speech recognition" (PDF). Proceedings of the IEEE. Retrieved 29 November 2019.
  8. ^ "Baum-Welch and HMM applications" (PDF). Johns Hopkins Bloomberg School of Public Health. Archived from the original (PDF) on 2021-04-14. Retrieved 11 October 2019.
  9. ^ Frazzoli, Emilio. "Intro to Hidden Markov Models: the Baum-Welch Algorithm" (PDF). Aeronautics and Astronautics, Massachusetts Institute of Technology. Retrieved 2 October 2013.
  10. ^ Baker, James K. (1975). "The DRAGON system—An overview". IEEE Transactions on Acoustics, Speech, and Signal Processing. 23: 24–29. doi:10.1109/TASSP.1975.1162650.
  11. ^ Rabiner, Lawrence (February 1989). "A Tutorial on Hidden Markov Models and Selected Applications in Speech Recognition". Proceedings of the IEEE. 77 (2): 257–286. CiteSeerX 10.1.1.381.3454. doi:10.1109/5.18626. S2CID 13618539.
  12. ^ Tokuda, Keiichi; Yoshimura, Takayoshi; Masuko, Takashi; Kobayashi, Takao; Kitamura, Tadashi (2000). "Speech Parameter Generation Algorithms for HMM-Based Speech Synthesis". IEEE International Conference on Acoustics, Speech, and Signal Processing. 3.
  13. ^ Dingel, Janis; Hagenauer, Joachim (24 June 2007). "Parameter Estimation of a Convolutional Encoder from Noisy Observations". IEEE International Symposium on Information Theory.
  14. ^ Wright, Charles; Ballard, Lucas; Coull, Scott; Monrose, Fabian; Masson, Gerald (2008). "Spot me if you can: Uncovering spoken phrases in encrypted VoIP conversations". IEEE International Symposium on Security and Privacy.
  15. ^ Brumley, Bob; Hakala, Risto (2009). "Cache-Timing Template Attacks". Advances in Cryptology – ASIACRYPT 2009. Lecture Notes in Computer Science. Vol. 5912. pp. 667–684. doi:10.1007/978-3-642-10366-7_39. ISBN 978-3-642-10365-0.
  16. ^ Salzberg, Steven; Delcher, Arthur L.; Kasif, Simon; White, Owen (1998). "Microbial gene identification using interpolated Markov Models". Nucleic Acids Research. 26 (2): 544–548. doi:10.1093/nar/26.2.544. PMC 147303. PMID 9421513.
  17. ^ "Glimmer: Microbial Gene-Finding System". Johns Hopkins University - Center for Computational Biology.
  18. ^ Delcher, Arthur; Bratke, Kirsten A.; Powers, Edwin C.; Salzberg, Steven L. (2007). "Identifying bacterial genes and endosymbiont DNA with Glimmer". Bioinformatics. 23 (6): 673–679. doi:10.1093/bioinformatics/btm009. PMC 2387122. PMID 17237039.
  19. ^ Burge, Christopher. "The GENSCAN Web Server at MIT". Archived from the original on 6 September 2013. Retrieved 2 October 2013.
  20. ^ Burge, Chris; Karlin, Samuel (1997). "Prediction of Complete Gene Structures in Human Genomic DNA". Journal of Molecular Biology. 268 (1): 78–94. CiteSeerX 10.1.1.115.3107. doi:10.1006/jmbi.1997.0951. PMID 9149143.
  21. ^ Burge, Christopher; Karlin, Samuel (1998). "Finding the Genes in Genomic DNA". Current Opinion in Structural Biology. 8 (3): 346–354. doi:10.1016/s0959-440x(98)80069-9. PMID 9666331.
  22. ^ Korbel, Jan; Urban, Alexander; Grubert, Fabien; Du, Jiang; Royce, Thomas; Starr, Peter; Zhong, Guoneng; Emanuel, Beverly; Weissman, Sherman; Snyder, Michael; Gerstein, Marg (12 June 2007). "Systematic prediction and validation of breakpoints associated with copy-number variations in the human genome". Proceedings of the National Academy of Sciences of the United States of America. 104 (24): 10110–5. Bibcode:2007PNAS..10410110K. doi:10.1073/pnas.0703834104. PMC 1891248. PMID 17551006.
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