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Amelie Introduction"
In amelie: Anomaly Detection with Normal Probability Functions
Introduction
This vignette describes the anomaly detection algorithm and provides some examples.
Description
The anomaly detection problem is set up here as a binary classification task, where each observation $x$ is classified as anomalous (class 1) or non-anomalous (class 0). We assume that anomalies are much less frequent than normal observations.
The scoring method is as follows. Given an observation $x$ consisting of features ${x_1, ..., x_n}$, compute the probability density $p(x)$ of the features. If the $p(x) < \epsilon$, where $\epsilon$ is a tuned parameter, the observation is classified as anomalous.
Concepts
Univariate normal distribution
In the univariate case, each of the features $x_i$ is assumed to be normally distributed with mean $\mu_i$ and variance $\sigma_i^2$: $x_i \sim \mathcal{N}(\mu_i,\sigma_i^2)$.
For a variable with mean $\mu$ and variance $\sigma^2$, the probability density is given by:
$$p(x; \mu, \sigma^2) = \frac{1}{\sqrt{2\pi\sigma^2}}e^{-\frac{(x-\mu)^2}{2\sigma^2}}$$
Parameter estimation
The univariate normal distribution is parametrized by mean $\mu$ and variance $\sigma^2$. For a data set ${x_1,x_2, ..., x_m}$, the parameters are estimated using maximum likelihood:
$$\mu = \frac{1}{m}\sum_{i=1}^{m}x_i$$
$$\sigma^2 = \frac{1}{m}\sum_{i=1}^{m}(x_i-\mu)^2$$
Density estimation
For the univariate case, the joint probability density is calculated under the assumptions that features are independent of each other, and each feature is normally distributed. For a set of observations ${x_1,x_2, ..., x_m}$ where each observation $x_i \in R^n$, the joint probability then is a product of the individual densities:
$$p(x) = \prod_{j=1}^{n}p(x_j;\mu_j,\sigma_j^2)$$
Algorithm
Using the above assumptions and definitions, the algorithm is implemented as follows:
- Given a data set $(x,y)$, split it into training and cross-validation sets, ${x^{(1)},...,x^{(m)}}$ and ${(x_{cv}^{(1)},y_{cv}^{(1)}), ..., (x_{cv}^{(k)},y_{cv}^{(k)})}$.
- The training set is not required to have any positive (anomalous) examples.
- It is a good idea to set aside a separate test data set before the call to
anode, for final evaluation.
- Fit model $p(x){train}$ on training set.
a. Fit parameters $\mu$ and $\sigma^2$ for each feature.
b. Calculate $p(x){train}$ for each row in training set.
- Tune $\epsilon$ on cross-validation data set.
a. Pick starting value for $\epsilon$; $min(p(x){train})$ is used here.
b. Calculate $p(x){cv}$ for each row in CV set using $\mu$ and $\sigma^2$ from
step 2.
c. For each row $i$ in CV set, predict $y = 1$ if $p(x_i) < \epsilon$ (anomaly), else predict $y=0$.
d. Evaluate prediction accuracy on CV set using a score (e.g., f1).
e. Update $\epsilon$ if the score improves.
f. Stop when best $\epsilon$ value is found.
- Evaluate algorithm accuracy on the training set.
- Use $p(x)_{train}$ from
step 2 and $\epsilon$ from step 3.
- After training, evaluate algorithm accuracy on a separate test set.
- Compute $p(x_i)_{test}$ using $\mu$ and $\sigma^2$ from
step 2 and $\epsilon$ from step 3.
Multivariate anomaly detection algorithm
It is possible to extend the above algorithm by using the multivariate version of the normal distribution. In this case, the features are not assumed to be independent, and $p$ is not a product of independent densities.
For parameters $\mu \in R^n$ (vector of means) and $\Sigma \in R^{n * n}$ (covariance matrix), the multivariate probability density function is given by:
$$p(x; \mu, \Sigma) = \frac{1}{(2\pi)^{n/2}|\Sigma|^{1/2}}e^{(-\frac{1}{2}(x-\mu)^T\Sigma^{-1}(x-\mu))},$$
Where $|\Sigma|$ is the determinant of $\Sigma$.
Unlike the univariate version, the multivariate pdf approach automatically captures correlations between features. However, the latter approach is computationally more expensive due to having to compute the inverse of $\Sigma$. The univariate algorithm works even when the training set size is small. For the multivariate version, $\Sigma$ is non-invertible if the number of observations is smaller than the number of features or the data contains features that are linearly dependent on others.
Examples
Create a small data set and train the algorithm using formula notation and matrix notation:
library(amelie)
x1 <- c(1,.2,3,1,1,.7,-2,-1)
x2 <- c(0,.5,0,.4,0,1,-.3,-.1)
x <- do.call(cbind,list(x1,x2))
y <- c(0,0,0,0,0,0,1,1)
dframe <- data.frame(x,y)
df_fit <- ad(y ~ x1 + x2, dframe)
mat_fit <- ad(x = x, y = y)
References
Machine Learning Course - the package is based on anomaly detection lectures from Andrew Ng's Machine Learning course.
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amelie documentation built on May 2, 2019, 12:21 p.m.
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Introduction
This vignette describes the anomaly detection algorithm and provides some examples.
Description
The anomaly detection problem is set up here as a binary classification task, where each observation $x$ is classified as anomalous (class 1) or non-anomalous (class 0). We assume that anomalies are much less frequent than normal observations.
The scoring method is as follows. Given an observation $x$ consisting of features ${x_1, ..., x_n}$, compute the probability density $p(x)$ of the features. If the $p(x) < \epsilon$, where $\epsilon$ is a tuned parameter, the observation is classified as anomalous.
Concepts
Univariate normal distribution
In the univariate case, each of the features $x_i$ is assumed to be normally distributed with mean $\mu_i$ and variance $\sigma_i^2$: $x_i \sim \mathcal{N}(\mu_i,\sigma_i^2)$.
For a variable with mean $\mu$ and variance $\sigma^2$, the probability density is given by:
$$p(x; \mu, \sigma^2) = \frac{1}{\sqrt{2\pi\sigma^2}}e^{-\frac{(x-\mu)^2}{2\sigma^2}}$$
Parameter estimation
The univariate normal distribution is parametrized by mean $\mu$ and variance $\sigma^2$. For a data set ${x_1,x_2, ..., x_m}$, the parameters are estimated using maximum likelihood:
$$\mu = \frac{1}{m}\sum_{i=1}^{m}x_i$$ $$\sigma^2 = \frac{1}{m}\sum_{i=1}^{m}(x_i-\mu)^2$$
Density estimation
For the univariate case, the joint probability density is calculated under the assumptions that features are independent of each other, and each feature is normally distributed. For a set of observations ${x_1,x_2, ..., x_m}$ where each observation $x_i \in R^n$, the joint probability then is a product of the individual densities:
$$p(x) = \prod_{j=1}^{n}p(x_j;\mu_j,\sigma_j^2)$$
Algorithm
Using the above assumptions and definitions, the algorithm is implemented as follows:
- Given a data set $(x,y)$, split it into training and cross-validation sets, ${x^{(1)},...,x^{(m)}}$ and ${(x_{cv}^{(1)},y_{cv}^{(1)}), ..., (x_{cv}^{(k)},y_{cv}^{(k)})}$.
- The training set is not required to have any positive (anomalous) examples.
- It is a good idea to set aside a separate test data set before the call to
anode, for final evaluation.
- Fit model $p(x){train}$ on training set. a. Fit parameters $\mu$ and $\sigma^2$ for each feature. b. Calculate $p(x){train}$ for each row in training set.
- Tune $\epsilon$ on cross-validation data set.
a. Pick starting value for $\epsilon$; $min(p(x){train})$ is used here.
b. Calculate $p(x){cv}$ for each row in CV set using $\mu$ and $\sigma^2$ from
step 2. c. For each row $i$ in CV set, predict $y = 1$ if $p(x_i) < \epsilon$ (anomaly), else predict $y=0$. d. Evaluate prediction accuracy on CV set using a score (e.g., f1). e. Update $\epsilon$ if the score improves. f. Stop when best $\epsilon$ value is found. - Evaluate algorithm accuracy on the training set.
- Use $p(x)_{train}$ from
step 2and $\epsilon$ fromstep 3.
- Use $p(x)_{train}$ from
- After training, evaluate algorithm accuracy on a separate test set.
- Compute $p(x_i)_{test}$ using $\mu$ and $\sigma^2$ from
step 2and $\epsilon$ fromstep 3.
- Compute $p(x_i)_{test}$ using $\mu$ and $\sigma^2$ from
Multivariate anomaly detection algorithm
It is possible to extend the above algorithm by using the multivariate version of the normal distribution. In this case, the features are not assumed to be independent, and $p$ is not a product of independent densities.
For parameters $\mu \in R^n$ (vector of means) and $\Sigma \in R^{n * n}$ (covariance matrix), the multivariate probability density function is given by:
$$p(x; \mu, \Sigma) = \frac{1}{(2\pi)^{n/2}|\Sigma|^{1/2}}e^{(-\frac{1}{2}(x-\mu)^T\Sigma^{-1}(x-\mu))},$$ Where $|\Sigma|$ is the determinant of $\Sigma$.
Unlike the univariate version, the multivariate pdf approach automatically captures correlations between features. However, the latter approach is computationally more expensive due to having to compute the inverse of $\Sigma$. The univariate algorithm works even when the training set size is small. For the multivariate version, $\Sigma$ is non-invertible if the number of observations is smaller than the number of features or the data contains features that are linearly dependent on others.
Examples
Create a small data set and train the algorithm using formula notation and matrix notation:
library(amelie) x1 <- c(1,.2,3,1,1,.7,-2,-1) x2 <- c(0,.5,0,.4,0,1,-.3,-.1) x <- do.call(cbind,list(x1,x2)) y <- c(0,0,0,0,0,0,1,1) dframe <- data.frame(x,y) df_fit <- ad(y ~ x1 + x2, dframe) mat_fit <- ad(x = x, y = y)
References
Machine Learning Course - the package is based on anomaly detection lectures from Andrew Ng's Machine Learning course.
Try the amelie package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
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