Directional-change intrinsic time

Directional-change intrinsic time is an event-based operator to dissect a data series into a sequence of alternating trends of defined size .

Figure 1: A financial market price curve (grey) dissected by a set of directional-changes (grey squares). The size of the threshold of the operator is shown in the middle of the figure. Local extremes are marked by grey circles. The timeline contains intervals of equal length in physical time and the length of the intervals based on the directional-change operator.

The directional-change intrinsic time operator was developed for the analysis of financial market data series. It is an alternative methodology to the concept of continuous time.[1] Directional-change intrinsic time operator dissects a data series into a set of drawups and drawdowns or up and down trends that alternate with each other. An established trend comes to an end as soon as a trend reversal is observed. A price move that extends a trend is called overshoot and leads to new price extremes.

Figure 1 provides an example of a price curve dissected by the directional change intrinsic time operator.

The frequency of directional-change intrinsic events maps (1) the volatility of price changes conditional to (2) the selected threshold . The stochastic nature of the underlying process is mirrored in the non-equal number of intrinsic events observed over equal periods of physical time.

Directional-change intrinsic time operator is a noise filtering technique. It identifies regime shifts, when trend changes of a particular size occur and hides price fluctuations that are smaller than the threshold .

Application

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The directional-change intrinsic time operator was used to analyze high frequency foreign exchange market data and has led to the discovery of a large set of scaling laws that have not been previously observed.[2] The scaling laws identify properties of the underlying data series, such as the size of the expected price overshoot after an intrinsic time event or the number of expected directional-changes within a physical time interval or price threshold. For example, a scaling relating the expected number of directional-changes   observed over the fixed period to the size of the threshold  :

 ,

where   and   are the scaling law coefficients.[3]

Other applications of the directional-change intrinsic time in finance include:

The methodology can also be used for applications beyond economics and finance. It can be applied to other scientific domains and opens a new avenue of research in the area of BigData.

References

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  •   Text in this draft was copied from Petrov, Vladimir; Golub, Anton; Olsen, Richard (2019). "Instantaneous Volatility Seasonality of High-Frequency Markets in Directional-Change Intrinsic Time". Journal of Risk and Financial Management. 12 (2): 54. doi:10.3390/jrfm12020054. hdl:10419/239003., which is available under a Creative Commons Attribution 4.0 International License.
  1. ^ Guillaume, Dominique M.; Dacorogna, Michel M.; Davé, Rakhal R.; Müller, Ulrich A.; Olsen, Richard B.; Pictet, Olivier V. (1997-04-01). "From the bird's eye to the microscope: A survey of new stylized facts of the intra-daily foreign exchange markets". Finance and Stochastics. 1 (2): 95–129. doi:10.1007/s007800050018. ISSN 0949-2984.
  2. ^ Glattfelder, J. B.; Dupuis, A.; Olsen, R. B. (2011-04-01). "Patterns in high-frequency FX data: discovery of 12 empirical scaling laws". Quantitative Finance. 11 (4): 599–614. arXiv:0809.1040. doi:10.1080/14697688.2010.481632. ISSN 1469-7688. S2CID 154979612.
  3. ^ Guillaume, Dominique M.; Dacorogna, Michel M.; Davé, Rakhal R.; Müller, Ulrich A.; Olsen, Richard B.; Pictet, Olivier V. (1997-04-01). "From the bird's eye to the microscope: A survey of new stylized facts of the intra-daily foreign exchange markets". Finance and Stochastics. 1 (2): 95–129. doi:10.1007/s007800050018. ISSN 0949-2984.
  4. ^ Golub, Anton; Glattfelder, James B.; Olsen, Richard B. (February 2018). "The Alpha Engine: Designing an Automated Trading Algorithm". In Dempster, M. A. H.; Kanniainen, Juho; Keane, John; Vynckier, Erik (eds.). High-Performance Computing in Finance. Chapman and Hall/CRC. pp. 49–76. doi:10.1201/9781315372006-3. ISBN 9781315372006. SSRN 2951348.
  5. ^ Golub, Anton; Chliamovitch, Gregor; Dupuis, Alexandre; Chopard, Bastien (2016-01-01). "Multi-scale representation of high frequency market liquidity". Algorithmic Finance. 5 (1–2): 3–19. arXiv:1402.2198. doi:10.3233/AF-160054. ISSN 2158-5571.