rRTSCov: Robust two time scale covariance estimation

an \(N x N\) matrix

The rRTSCov requires the tick-by-tick transaction prices. (Co)variances are then computed using log-returns calculated on a rolling basis on stock prices that are \(K\) (slow time scale) and \(J\) (fast time scale) steps apart.

The diagonal elements of the rRTSCov matrix are the variances, computed for log-price series \(X\) with \(n\) price observations at times \( \tau_1,\tau_2,\ldots,\tau_n\) as follows: $$ (1-\frac{\overline{n}_K}{\overline{n}_J})^{-1}(\{X,X\}_T^{(K)^{*}}-\frac{\overline{n}_K}{\overline{n}_J}\{X,X\}_T^{(J)^{*}}), $$ where \(\overline{n}_K=(n-K+1)/K\), \(\overline{n}_J=(n-J+1)/J\) and $$\{X,X\}_T^{(K)^{*}} =\frac{c_\eta^{*}}{K}\frac{\sum_{i=1}^{n-K+1}(X_{t_{i+K}}-X_{t_i})^2I_X^K(i;\eta)}{\frac{1}{n-K+1}\sum_{i=1}^{n-K+1}I_X^K(i;\eta)}.$$ The constant \(c_\eta\) adjusts for the bias due to the thresholding and \(I_{X}^K(i;\eta)\) is a jump indicator function that is one if $$ \frac{(X_{t_{i+K}}-X_{t_{i}})^2}{(\int_{t_{i}}^{t_{i+K}} \sigma^2_sds +2\sigma_{\varepsilon_{\mbox{\tiny X}}}^2)} \ \ \leq \ \ \eta $$ and zero otherwise. The elements in the denominator are the integrated variance (estimated recursively) and noise variance (estimated by the method in Zhang et al, 2005).

The extradiagonal elements of the rRTSCov are the covariances. For their calculation, the data is first synchronized by the refresh time method proposed by Harris et al (1995). It uses the function refreshTime to collect first the so-called refresh times at which all assets have traded at least once since the last refresh time point. Suppose we have two log-price series: \(X\) and \(Y\). Let \( \Gamma =\{ \tau_1,\tau_2,\ldots,\tau_{N^{\mbox{\tiny X}}_{\mbox{\tiny T}}}\}\) and \(\Theta=\{\theta_1,\theta_2,\ldots,\theta_{N^{\mbox{\tiny Y}}_{\mbox{\tiny T}}}\}\) be the set of transaction times of these assets. The first refresh time corresponds to the first time at which both stocks have traded, i.e. \(\phi_1=\max(\tau_1,\theta_1)\). The subsequent refresh time is defined as the first time when both stocks have again traded, i.e. \(\phi_{j+1}=\max(\tau_{N^{\mbox{\tiny{X}}}_{\phi_j}+1},\theta_{N^{\mbox{\tiny{Y}}}_{\phi_j}+1})\). The complete refresh time sample grid is \(\Phi=\{\phi_1,\phi_2,...,\phi_{M_N+1}\}\), where \(M_N\) is the total number of paired returns. The sampling points of asset \(X\) and \(Y\) are defined to be \(t_i=\max\{\tau\in\Gamma:\tau\leq \phi_i\}\) and \(s_i=\max\{\theta\in\Theta:\theta\leq \phi_i\}\).

Given these refresh times, the covariance is computed as follows: $$ c_{N}( \{X,Y\}^{(K)}_T-\frac{\overline{n}_K}{\overline{n}_J}\{X,Y\}^{(J)}_T ), $$

where $$\{X,Y\}^{(K)}_T =\frac{1}{K} \frac{\sum_{i=1}^{M_N-K+1}c_i (X_{t_{i+K}}-X_{t_{i}})(Y_{s_{i+K}}-Y_{s_{i}})I_{X}^K(i;\eta) I_{Y}^K(i;\eta)}{\frac{1}{M_N-K+1}\sum_{i=1}^{M_N-K+1}{I_X^K(i;\eta)I_Y^K(i;\eta)}},$$ with \(I_{X}^K(i;\eta)\) the same jump indicator function as for the variance and \(c_N\) a constant to adjust for the bias due to the thresholding.

Unfortunately, the rRTSCov is not always positive semidefinite. By setting the argument makePsd = TRUE, the function makePsd is used to return a positive semidefinite matrix. This function replaces the negative eigenvalues with zeroes.