Change-Point Detection in Autoregressive Processes via the Cross-Entropy Method
Abstract
:1. Introduction
2. Model Selection Criteria
2.1. Change-Point Detection Problem
2.2. The Principle of Minimum Description Length
- For an integer parameter N, when its value is not bounded, approximately bits are encoded. If N is limited by the upper bound value , then approximately bits are needed.
- To encode a real parameter, if it is estimated from T observations, bits are required.
- As mentioned above, the first part of two-stage MDL can be considered as a negative log-likelihood function of the whole process, by assuming that the segments are independent, and using the approximation in McLeod et al. [42] for the exact loglikelihood for the AR(p) model, the likelihood of segment i can be written as (see [42] for further details), where is the Yule-Walker estimate, is the covariance determinant of first s observations.
- For the number N, the penalty term is . Since it can be considered as an integer parameter without being bounded, the code length is .
- The length for each of segments cannot exceed T. This means that, according to the integer parameter principle, the lengths of the segments can be encoded with bits.
- represents the order of the AR process for each segment, which should be an integer. So the parameter can be encoded with bits; see [7].
- For each segment i, , we estimate three real-valued parameters. These are mean shift ; autocorrelation coefficient , where ; and variance . Under the real parameter principle, each of these parameters can be computed from observations. Hence, each of them need bits.
3. The Cross-Entropy Algorithm
- Generate a sample from a probability distribution.
- In order to obtain a better sample, find the minimum cross-entropy distance between the sample distribution and a target distribution.
- Updating of the level parameter . Order the performance score increasingly, , . Let be the -quantile of the ordered performance scores, which can be denoted as,
- Updating the reference parameter . Given and , we can derive from Equation (10),
Algorithm 1 Basic CE optimization algorithm. |
|
Algorithm 2 The CE.AR algorithm. |
|
4. Numerical Experiments
4.1. Example 1: Simulated AR(1) Processes with No Change-Point
4.2. Example 2: Simulated AR(1) Processes with a Single Change-Point
4.2.1. Example 2.1
4.2.2. Example 2.2
4.3. Example 3: AR(1) Processes with Multiple Change-Points
5. Discussion
5.1. Simulation Results
5.2. Application
6. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
AR | Autoregressive |
AR(1) | Autoregressive model of order 1 |
AR(p) | Autoregressive model of order p |
MDL | Minimum description length |
AIC | Akaike’s information criterion |
BIC | Bayesian information criterion |
mBIC | Modified Bayesian information criterion |
ShrinkageIC | A penalty function with an adjustable shrinkage parameter |
CL | Code length |
EM | Expectation-maximization |
MCMC | Markov chain Monte Carlo |
CE | Cross-Entropy |
ARIMA | Autoregressive integrated moving average |
MA | Moving average |
AUD | Australian dollar |
CNY | Chinese yuan |
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AR parameter | |||||||||
Algorithm | 1 | 1 | 1 | ||||||
AR1seg | 95% | 4% | 1% | 89% | 3% | 8% | 36% | 17% | 47% |
strucchange | 97% | 3% | 0% | 100% | 0% | 0% | 94% | 5% | 1% |
CE.AR | 100% | 0% | 0% | 100% | 0% | 0% | 100% | 0% | 0% |
Mean Shift | |||||||||
Algorithm | |||||||||
AR1seg | 58% | 29% | 13% | 20% | 65% | 15% | 10% | 68% | 22% |
strucchange | 60% | 40% | 0% | 2% | 97% | 1% | 0% | 97% | 3% |
CE.AR | 97% | 3% | 0% | 41% | 58% | 1% | 2% | 97% | 1% |
Coefficient Shift | , | , | , | ||||||
Algorithm | |||||||||
AR1seg | 82% | 6% | 12% | 29% | 9% | 62% | 46% | 10% | 44% |
strucchange | 68% | 32% | 0% | 0% | 97% | 3% | 36% | 61% | 3% |
CE.AR | 96% | 4% | 0% | 6% | 92% | 2% | 90% | 8% | 2% |
Coefficient Shift | , | , | , | ||||||
Algorithm | |||||||||
AR1seg | 2% | 0% | 98% | 47% | 9% | 44% | 84% | 5% | 11% |
strucchange | 0% | 97% | 3% | 0% | 98% | 2% | 25% | 74% | 1% |
CE.AR | 0% | 99% | 1% | 3% | 95% | 2% | 87% | 13% | 0% |
Algorithm | ||||||
---|---|---|---|---|---|---|
0 | 1 | 2 | 4 | |||
AR1seg | 26% | 8% | 25% | 10% | 31% | 0% |
strucchange | 22% | 68% | 9% | 1% | 0% | 0% |
CE.AR | 74% | 13% | 10% | 3% | 0% | 0% |
Algorithm | ||||||
---|---|---|---|---|---|---|
0 | 1 | 2 | 4 | |||
AR1seg | 3% | 1% | 10% | 23% | 63% | 0% |
strucchange | 0% | 0% | 90% | 9% | 1% | 0% |
CE.AR | 0% | 0% | 100% | 0% | 0% | 0% |
AR1seg | strucchange | CE.AR |
---|---|---|
73 | 46 | 39 |
73 | 30 | 19 |
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Ma, L.; Sofronov, G. Change-Point Detection in Autoregressive Processes via the Cross-Entropy Method. Algorithms 2020, 13, 128. https://doi.org/10.3390/a13050128
Ma L, Sofronov G. Change-Point Detection in Autoregressive Processes via the Cross-Entropy Method. Algorithms. 2020; 13(5):128. https://doi.org/10.3390/a13050128
Chicago/Turabian StyleMa, Lijing, and Georgy Sofronov. 2020. "Change-Point Detection in Autoregressive Processes via the Cross-Entropy Method" Algorithms 13, no. 5: 128. https://doi.org/10.3390/a13050128
APA StyleMa, L., & Sofronov, G. (2020). Change-Point Detection in Autoregressive Processes via the Cross-Entropy Method. Algorithms, 13(5), 128. https://doi.org/10.3390/a13050128