Abstract
This paper proposes an efficient approach for modelling a high frequency continuous time diffusion process for the dynamics of crude oil. While various applications of continuous time models are considered in the literature, the results on choosing the right model are mixed. We employ a very general non-parametric approach to capture the dynamics of the crude oil market proxied by United States Oil (USO) exchange traded fund. This approach is purely data driven and does not require specification of the drift or the diffusion coefficient function. The proposed nonparametric kernel-based estimation procedure relies on the local polynomial kernel regression, where the choice of a bandwidth parameter plays a significant role. We demonstrate that besides offering a convenient way of estimating the continuous-time models for energy prices, our estimation procedure performs well when dealing with predicting USO prices out-of-sample. The analysis is extended by incorporating possible jump diffusion, where the assumption of continuity of the stochastic process is relaxed and a jump component is added to the diffusion process. In addition, we extend our model by adding possible seasonalities in the underlying dynamics, which requires decomposing the price by means of the Maximum Overlap Discrete Wavelet Transform (MODWT) algorithm and applying nonparametric kernel-based estimation procedure to modelling of the deseasonalized prices.
Appendix A: Automated Bandwidth Parameter Algorithm Testing
A.1 Numerical Experiment Bandwidth Selection, Regression
In this subsection we test the automated bandwidth parameter procedures based on Eqs. (2.11) and (2.12), outlined in Section 2.2. For that purpose we use Examples 6.2 and 6.5 from Racine (2019), which study the regression function g(x) = E[Y|X] = sin(2πx). Similar numerical experiments are performed in Köhler, Schindler, and Sperlich (2014), who note difficulty of estimation of trigonometric functions.
We simulate N = 2,000 i.i.d samples {X
t
, Z
t
} using the model Z
t
= sin(2πX
t
) + ϵ
t
, with X
t
∼ U[0, 1] and the noise term, ϵ ∼ N(0, σ
2), for 0 ≤ t ≤ N − 1. From Eq. (2.10), one can find the theoretically “optimal” bandwidth parameter for the local linear kernel regression,
where
with
Figure 8 shows h* together with the automatically selected bandwidth parameters for varying volatility parameter of the noise term, σ. One can make two observations from this plot. Firstly, the bandwidth parameters selected by the automated procedures are very close to each other. Secondly, the automatically selected bandwidth parameters are close to the theoretically “optimal” bandwidth, h*, for most of the values of σ. Unsurprisingly, as the noise, ϵ, becomes more volatile, i.e., the volatility parameter, σ, increases, the automated bandwidth selection procedures become less accurate.
![Figure 8:
Theoretically optimal bandwidth parameter,
h
*
=
1.719
⋅
σ
2
/
(
8
π
4
)
1
/
5
⋅
N
−
1
/
5
${h}^{{\ast}}=1.719\cdot {\left[{\sigma }^{2}/\left(8{\pi }^{4}\right)\right]}^{1/5}\cdot {N}^{-1/5}$
together with the automatically selected bandwidth parameters obtained using the generalized cross-validation, information-theoretic criteria, and average squared error with Rice (1984) and Shibata (1981) penalty terms, for varying volatility parameter of the noise term, σ.](/document/doi/10.1515/snde-2022-0113/asset/graphic/j_snde-2022-0113_fig_008.jpg)
Theoretically optimal bandwidth parameter,
A.2 Numerical Experiments for Bandwidth Selection Parameter
In this subsection, we investigate the accuracy of the automated methods for selecting the bandwidth parameter in the density estimator presented in Section 2.3. For this purpose, we simulate artificial datasets using random distributions with a known density function, f, and compute theoretically optimal bandwidth parameters from Eq. (2.14) together with the data-driven bandwidths in Eqs. (2.15)–(2.17).
First, we use normal distribution with mean μ and standard deviation σ to simulate artificial datasets. For the Gaussian family, it can be shown that
We repeat a similar numerical experiment with the artificial data simulated from the chi-square distribution with the number of degrees of freedom k. One can show that the integrated squared curvature of the density function is given by
where ς
1 = 4 − 2k and ς
2 = k
2 − 6k + 8. For k = 7.5 and N = 1,000, one computes from Eq. (2.14) the optimal bandwidth parameter h* = 1.6175. The automatically selected bandwidth parameters are
We notice that in both numerical experiments, the least-squares cross-validation procedure results in the bandwidth parameter selection closer to the optimal value as measured by the lower MSE.
Appendix B: Estimation of the Drift and Diffusion Coefficients from an Artificial Dataset
In this section we present the results of the drift and diffusion coefficients estimation through the nonparametric kernel-based numerical procedure outlined in Section 2. For that purpose, we generate a time series {X t } for 0 ≤ t ≤ N − 1 with N = 2,000 and Δt = 0.004, using the CIR-model[7] given by
where the set of parameters: κ = 0.035, α = 0.5, η = 0.1, and β = 0.5 is chosen in line with the numerical experiment in Stanton (1997).
For the simulated time series, {X
t
}, (see top panel in Figure 9), we select an evenly spaced set of grid points, [x
1, …, x
m
], where m = 250 with x
0 = min{X
t
} and x
m
= max{X
t
}. At each of these points, we obtain estimates of the drift function with the procedures outlined in Section 2.4. These estimates constitute a set of values

In the top subplot, we show the simulated path of the CIR-process, X
t
with drift μ(x) = 0.04 − 0.5 ⋅ x and diffusion σ(x) = 0.1 ⋅ x
0.5. The middle subplot depicts the “true” drift function, μ(x) and the fitted drift function
Furthermore, we use the three estimation algorithms to obtain three sets of estimates
For all four datasets, i.e., one
From Figure 9 we notice that the estimated parameters
We notice that the bandwidth parameters selected using the automated procedure in Eq. (2.11) are different for all four regressions performed in this numerical experiment. This observation highlights the importance of selecting a bandwidth parameter using some data-driven methodology and avoiding “plug-in” approaches.
Appendix C: Jump Diffusion Modelling
We rewrite the diffusion model in Eq. (2.1) as
where, similarly to Eq. (2.1), W t is a one-dimensional standard Brownian motion, μ and σ are the drift and the diffusion coefficients, respectively. Furthermore, J t is a compensated jump process with intensity λ(X t ) ≥ 0, Y is a random jump size with stationery distribution p Y independent of W t and J t .
Under this setting, the conditional moments in Eq. (2.2),
for k ≥ 3.
The estimation of
Optimal bandwidth parameter, h
k
, selected using the automated procedure based on the Information-Theoretic criteria, for the local linear estimator,
k | 1 | 2 | 3 | 4 | 5 | 6 |
---|---|---|---|---|---|---|
h k | 2.3152 | 0.1980 | 0.1814 | 0.1806 | 0.1798 | 0.1794 |

Nonparametric estimates of the moments,
Let us further assume that the stationary distribution of the random jump size, p y , is a centred Gaussian with volatility parameter σ Y . Following the derivations in Figa-Talamanaca (2015), one can show that
From the equations above, one obtains the estimate of the jump volatility parameter as
Using the daily observations of the oil price, Figa-Talamanaca (2015) estimate the volatility parameters of the random jump size to be approximately 0.0066, which is 2.5 times lower than our estimate obtained using the 5-min observations. This indicates that random jumps estimated from high-frequency data experience higher volatility compared to those estimated using lower frequency data.
Furthermore, from Eqs. (C.5)–(C.7) one can obtain the estimate of the random jump intensity, which corresponds to

Nonparametric estimates of the drift, the diffusion and the jump intensity functions. The red dotted curves represent the 95 % confidence bands obtained with the wild bootstrap.
By relaxing the assumption of constant volatility of the random jumps, we get

Nonparametric estimate for the drift, the diffusion, the jump intensity and the jump volatility function.
Appendix D: Seasonality Modelling
We denote by P = {P t , t ∈ [0, N − 1]} a collection of observations from the USO price process. It can be decomposed into two parts, a slow-varying component, S t , and a fast-varying component, X t :
for t ∈ [0, N − 1]. A slow-varying component, S t , is associated with medium- and long-term variations in the price process. Sometimes, in the literature, it is referred to as a “deterministic” or “seasonal” component. The term “deterministic” is used because deterministic functions of time, t, are implemented to describe the dynamics of this component, see, for example, Brix, Lunde, and Wei (2018), Janczura et al. (2013), and Nowotarski, Tomczyk, and Weron (2013). Popular choices of these functions are: (i) piecewise constant functions and dummy variables; (ii) Fourier-based sine or cosine functions which may be coupled with an exponentially weighted moving average of the price process. Although these methods are easy to implement and interpret, we do not use them in our analysis due to several shortcoming. Specifically, piecewise constant functions and dummy variables are not smooth and could introduce artificial artefacts such as jumps and kinks in the transformed data. In addition, using Fourier-based functions results in a parametric approach to seasonality modelling, which contradicts our goal to develop fully nonparametric methodology for modelling crude oil prices. Moreover, the adoption of sine or cosine functions to represent variations in the seasonal component is based on the assumption that the frequencies of these variations are constant. While this assumption could be partially justified for some time series (e.g., electricity prices, see Ignatieva 2014), for the oil market, it is less reasonable in our setting.
Instead, we use a smooth component of the Maximal Overlap Discrete Wavelet Decomposition (MODWT) to model the slow-varying component of the price process. MODWT’s ability to decompose time series into various frequency components without losing information makes it particularly adept at capturing both the slow-varying trends and the more volatile components of energy prices. This technique is a fundamental in time series modelling and financial econometrics, as analysed by Percival and Walden (2000) and Gencay, Selcuk, and Whitcher (2002). The wavelet approach offers distinct advantages in effectively capturing the complexities of energy price movements. Recognised for its flexibility, it models the nonlinear and non-stationary characteristics of energy prices by decomposing time series data into multiple frequency components. This allows the approach to capture both long-term trends and short-term fluctuations without adhering to a predetermined functional form. By breaking down the price series into stationary sub-series, each modelled separately, the method yields more precise forecasts. Studies such as Pindoriya, Singh, and Singh (2008) demonstrate that wavelet-based models excel beyond traditional forecasting techniques like ARIMA, MLP, and RBF neural networks, including fuzzy neural networks (FNN), in predicting energy prices. This superior performance is largely attributed to the wavelet method’s effectiveness in addressing the market’s nonlinear dynamics.
Furthermore, the integration of wavelet transform with ARIMA and GARCH models, as explored by Tan et al. (2010), presents a novel and more effective way to address the inherent volatility in energy markets compared to conventional methods. By segmenting historical price series into approximation and detail series, the wavelet transform enables more accurate predictions of volatile components, enhancing overall forecasting accuracy. Additionally, the combination of wavelet transforms with other predictive techniques, such as Particle Swarm Optimisation (PSO) and Adaptive-Network-Based Fuzzy Inference System (ANFIS), has been shown to improve forecasting accuracy significantly by capturing both linear and non-linear patterns in energy prices efficiently (Catalão, Pousinho, and Mendes 2011). The efficacy of the wavelet approach extend further, as demonstrated by Qiao and Yang (2020), through a hybrid model that integrates wavelet transform and long short-term memory (LSTM) networks for U.S. electricity price forecasting. This novel model surpasses other AI models in accuracy, showcasing the wavelet transform’s ability to optimise forecasting through parameter selection and to adeptly manage the non-linear and volatile nature of energy markets. Additionally, the combination of wavelet decomposition with machine learning models, as explored by Risse (2019), underlines the effectiveness of wavelet-based approaches in forecasting gold prices. This research shows how wavelet decomposition can disentangle predictors according to their time and frequency domains, leading to enhanced forecasting performance. While not directly focused on energy prices, the principles and findings are readily applicable to energy markets, evidencing the wavelet transform’s broad applicability and its potential to refine predictive models by capturing both short-term and long-term trends.
This suite of advantages, from flexibility and enhanced accuracy to improved handling of non-stationarity, volatility and data non-stationarity, underscores the suitability of wavelet-based models for forecasting energy prices, offering considerable improvements over existing methodologies in terms of adaptability and forecasting precision. The following subsection (Appendix D.1) describes the methodology for the price decomposition by the MODWT algorithm.
D.1 Price Decomposition via Maximum Overlap Discrete Wavelet Transform
Based on the frequency of variations in the data-generating process, the set of price observations in Eq. (D.1) is decomposed with the aid of the Maximum Overlap Discrete Wavelet Transform (MODWT); see Chapter 5 in Percival and Walden (2000) for a detailed description of the procedure. In this subsection, we briefly review the key aspects of this methodology.
Let
where,
Furthermore, at level 1 ≤ j ≤ J one defines
In practice, the wavelet and scaling coefficients in the vectors W
(j) and V
(j), for 1 ≤ j ≤ J, are obtained through the so-called “pyramid” algorithm. This algorithm is formulated as a multi-step iterative procedure. Namely, let the vector of scaling coefficients at level 0 be V
(0) = P. Then, for the levels of decomposition j = 1, …, J and the time instances t = 0, …, N − 1, the elements of the wavelet coefficient vectors,
This procedure results in the set of (J + 1) vectors
The MODWT wavelet and scaling filters
The latter condition represents the orthogonality of the wavelet filter to even shifts. Furthermore, the (DWT) scaling filter {g
l
}, for 0 ≤ l ≤ L − 1 is defined through the “quadrature mirror” relationship: g
l
= (−1)
l+1
h
L−1−l
. In general, the conditions in Eq. (D.4) do not imply DWT coefficients that can be interpreted in terms of changes in the original time series on particular scales. Thus, one has to apply additional regularity conditions that result in a very diverse groups of wavelet filters that approximate high-pass filters, i.e., filters with nominal pass-band in
It should be noted that the MODWT pyramid algorithm has a more considerable computational complexity of O(N log2(N))[9] as compared to the standard DWT pyramid algorithm, whose complexity is O(N). Nevertheless, the key advantage of using the MODWT is twofold. Unlike the DWT, which restricts the sample size to an integer multiple of 2
J
, the MODWT algorithm can be applied to a time series of any length N. Furthermore, the detail and smooth components of the MODWT algorithm are associated with zero phase filters, which make it easy in practice to align the variations on the MRA series,
The inverse of the pyramid MODWT algorithm provided in Eq. (D.3) is given by
for t = 0, …, N − 1 and j = 1, …, J. This algorithm being applied to a set of (J + 1) vectors of wavelet and scaling coefficients,
Moreover, using the procedure in , the detail components,
Figure 13 shows the MODWT smooth components,

Original USO price data for the period 03–07/06/2019 (blue) and its MODWT smooth components at level J = {5, 6, 7} obtained with aid of the LA(8) DWT filter.
As we are interested in analysing the high-frequency dynamics of the USO price data, we remove the seasonal variations with periods of one day and larger. Thus, in what follows, we set the slow-varying (“seasonal”) component of the USO price, S in Eq. (D.1), to be equal to
For modelling of the stochastic component we utilize the non-parametric kernel-based statistical methodology outlined in Section 2. Figure 14 shows the estimated drift and diffusion coefficients in the dynamics of the stochastic component. The nonparametrically estimated drift coefficient function (top panel) is almost linear and decreases with increasing values of the deseasonalised prices, while the diffusion function (bottom panel) is concave. For low values of the USO prices, there is only a very slight mean reversion. Sharp decline in the drift that was estimated at high values of deseasonalised prices has the effect of preventing crude oil prices from exploding towards infinity, despite the increase in volatility shown in the bottom panel of Figure 14. The shapes of the drift and the diffusion coefficient functions are largely consistent with the results reported in Figa-Talamanaca (2015) as well as Ignatieva (2014) for the nonparametric estimates of the drift and diffusion coefficients for energy and commodity prices. Along with the estimates we plot the pointwise 95 % confidence bands (red dotted lines) for the drift and the diffusion estimates. As expected, the confidence bands are tight for the center values of deseasonalised prices and widen in the tails where the data become sparse.

Nonparametric estimates of the drift and diffusion coefficients,
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