for nonlinear Granger causality is illustrated in two examples. In the first example, we examine the main explanations of the asymmetric volatility phenomenon using high-frequency data on SP 500 Index futures contracts and find evidence of a nonlinear leverage and volatility feedback effects. In the sec- ond application, we investigate the Granger causality between SP 500 Index returns and trading volume. We find convincing evidence of linear and nonlinear feedback effects from stock returns to volume, but a weak evidence of nonlinear feedback effect from volume to stock returns. The rest of the article is organized as follows. The condi- tional independence test using the Hellinger distance and the Bernstein copula is introduced in Section 2. Section 3 provides the test statistic and its asymptotic properties. In Section 4, we investigate the finite sample size and power properties of our test and we compare with Su and White’s 2008 test. Section 5 contains the two applications described above. Section 6 con- cludes. The proofs of the asymptotic results are presented in the Technical Appendix, which is available online. 2. NULL HYPOTHESIS, HELLINGER DISTANCE, AND THE BERNSTEIN COPULA Let {X ′ t , Y ′ t , Z ′ t ′ ∈ R d 1 × R d 2 × R d 3 , t = 1, . . . , T } be a sample of stochastic processes in R d , where d = d 1 + d 2 + d 3 , with joint distribution function F XYZ and density function f XYZ . We wish to test the conditional independence between Y and Z conditionally on X. Formally, the null hypothesis can be written in terms of densities as H : Pr{f Y|X,Z y | X, Z = f Y|X y | X} = 1, ∀y ∈ R d 2 , or H : Pr{f y, X, Zf X = f y, Xf X, Z} = 1, ∀y ∈ R d 2 , 1 and the alternative hypothesis as H 1 : Pr{f Y|X,Z y | X, Z = f Y|X y | X} 1, for some y ∈ R d 2 , where f ·|· ·|· denotes the conditional density. As we mentioned in the introduction, Granger noncausality is a form of condi- tional independence and to see that let us consider the following example. For Y, Z ′ a Markov process of order 1, the null hy- pothesis that corresponds to Granger noncausality from Z to Y is given by H : Pr{f Y|X,Z y t | y t −1 , z t −1 = f Y|X y t | y t −1 } = 1, where in this case y = y t , x = y t −1 , z = z t −1 and d 1 = d 2 = d 3 = 1. Next, we reformulate the null hypothesis 1 in terms of cop- ulas. This will allow us to keep only the terms that involve the dependence among the random vectors. It is well known from Sklar 1959 that the distribution function of the joint process X ′ , Y ′ , Z ′ ′ can be expressed via a copula F XYZ

x, y, z = C

XYZ ¯ F