volatility: Volatility

A object of the same class as OHLC or a vector (if try.xts fails) containing the chosen volatility estimator values.

• Close-to-Close Volatility (calc="close") $$ \sigma_{cl} = \sqrt{\frac{N}{n-2} \sum_{i=1}^{n-1}(r_i-\bar{r})^2} $$ $$where\;\; r_i = \log \left(\frac{C_i}{C_{i-1}}\right) $$ $$and\;\; \bar{r} = \frac{r_1+r_2+\ldots +r_{n-1}}{n-1} $$

• OHLC Volatility: Garman and Klass (calc="garman.klass") The Garman and Klass estimator for estimating historical volatility assumes Brownian motion with zero drift and no opening jumps (i.e. the opening = close of the previous period). This estimator is 7.4 times more efficient than the close-to-close estimator. $$ \sigma = \sqrt{ \frac{N}{n} \sum \left[ \textstyle\frac{1}{2}\displaystyle \left( \log \frac{H_i}{L_i} \right)^2 - (2\log 2-1) \left( \log \frac{C_i}{O_i} \right)^2 \right] } $$

• High-Low Volatility: Parkinson (calc="parkinson") The Parkinson formula for estimating the historical volatility of an underlying based on high and low prices. $$ \sigma = \sqrt{ \frac{N}{4 n \times \log 2} \sum_{i=1}^{n} \left(\log \frac{H_i}{L_i}\right)^2} $$

• OHLC Volatility: Rogers and Satchell (calc="rogers.satchell") The Roger and Satchell historical volatility estimator allows for non-zero drift, but assumed no opening jump. $$ \sigma = \sqrt{ \textstyle\frac{N}{n} \sum \left[ \log \textstyle\frac{H_i}{C_i} \times \log \textstyle\frac{H_i}{O_i} + \log \textstyle\frac{L_i}{C_i} \times \log \textstyle\frac{L_i}{O_i} \right] } $$

• OHLC Volatility: Garman and Klass - Yang and Zhang (calc="gk.yz") This estimator is a modified version of the Garman and Klass estimator that allows for opening gaps. $$ \sigma = \sqrt{ \textstyle\frac{N}{n} \sum \left[ \left( \log \textstyle\frac{O_i}{C_{i-1}} \right)^2 + \textstyle\frac{1}{2}\displaystyle \left( \log \textstyle\frac{H_i}{L_i} \right)^2 - (2 \times \log 2-1) \left( \log \textstyle\frac{C_i}{O_i} \right)^2 \right] } $$

• OHLC Volatility: Yang and Zhang (calc="yang.zhang") The Yang and Zhang historical volatility estimator has minimum estimation error, and is independent of drift and opening gaps. It can be interpreted as a weighted average of the Rogers and Satchell estimator, the close-open volatility, and the open-close volatility.

  Users may override the default values of \(\alpha\) (1.34 by default) or \(k\) used in the calculation by specifying alpha or k in …, respectively. Specifying k will cause alpha to be ignored, if both are provided. $$ \sigma^2 = \sigma_o^2 + k\sigma_c^2 + (1-k)\sigma_{rs}^2 $$ $$ \sigma_o^2 =\textstyle \frac{N}{n-1} \sum \left( \log \frac{O_i}{C_{i-1}}-\mu_o \right)^2 $$ $$ \mu_o=\textstyle \frac{1}{n} \sum \log \frac{O_i}{C_{i-1}} $$ $$ \sigma_c^2 =\textstyle \frac{N}{n-1} \sum \left( \log \frac{C_i}{O_i}-\mu_c \right)^2 $$ $$ \mu_c=\textstyle \frac{1}{n} \sum \log \frac{C_i}{O_i} $$ $$ \sigma_{rs}^2 = \textstyle\frac{N}{n} \sum \left( \log \textstyle\frac{H_i}{C_i} \times \log \textstyle\frac{H_i}{O_i} + \log \textstyle\frac{L_i}{C_i} \times \log \textstyle\frac{L_i}{O_i} \right) $$ $$ k=\frac{\alpha-1}{alpha+\frac{n+1}{n-1}} $$