Stacking apertures and estimation strategies for reflection and diffraction enhancement

Abstract: It is well known that the quality of stacking results (e.g., noise reduction, event enhancement, and continuity) can be greatly influenced not only by the traveltime operator chosen but also by the apertures used. We have considered two so-called diffraction-stack traveltimes, together with the corresponding apertures, designed to enhance reflections and diffractions, respectively. The first one is the common-reflection-surface (CRS) diffraction traveltime that is obtained from the general CRS traveltime upon … Show more

“…Due to its approximated nature, it demands appropriate midpoints and offsets apertures, which in our case are based on Faccipieri et al . () for the real aforementioned data set. Figure illustrates a seismic event and the CRS stacking surface depending on midpoint and half offset limited by apertures in both directions.…”

“…The CRS approach assumes locally continuous reflectors, in the subsurface, which have their traveltime approximation given by a squared second-order Taylor polynomial. Due to its approximated nature, it demands appropriate midpoints and offsets apertures, which in our case are based on Faccipieri et al (2016) for the real aforementioned data set. Figure 12 illustrates a seismic event and the CRS stacking surface depending on midpoint and half offset limited by apertures in both directions.…”

“…Coimbra, Novaes and Schleicheret (2016b) derived an accurate traveltime equation capable of identifying the common reflection point contribution along half offsets and midpoints that can be used in a finite-offset case. 52 C 2018 European Association of Geoscientists & Engineers Faccipieri et al (2016) proposed estimation and stacking apertures to ensure reliable fitting of the CRS traveltime and minimize event smoothing. Sarkar, Baumel and Larner (2002) and Fomel (2009) proposed modified coherence measures that consider amplitude variations along reflection events.…”

“…Faccipieri et al . () proposed estimation and stacking apertures to ensure reliable fitting of the CRS traveltime and minimize event smoothing. Sarkar, Baumel and Larner () and Fomel () proposed modified coherence measures that consider amplitude variations along reflection events.…”

Stretch‐free generalized normal moveout correction

“…Due to its approximated nature, it demands appropriate midpoints and offsets apertures, which in our case are based on Faccipieri et al . () for the real aforementioned data set. Figure illustrates a seismic event and the CRS stacking surface depending on midpoint and half offset limited by apertures in both directions.…”

“…The CRS approach assumes locally continuous reflectors, in the subsurface, which have their traveltime approximation given by a squared second-order Taylor polynomial. Due to its approximated nature, it demands appropriate midpoints and offsets apertures, which in our case are based on Faccipieri et al (2016) for the real aforementioned data set. Figure 12 illustrates a seismic event and the CRS stacking surface depending on midpoint and half offset limited by apertures in both directions.…”

“…Coimbra, Novaes and Schleicheret (2016b) derived an accurate traveltime equation capable of identifying the common reflection point contribution along half offsets and midpoints that can be used in a finite-offset case. 52 C 2018 European Association of Geoscientists & Engineers Faccipieri et al (2016) proposed estimation and stacking apertures to ensure reliable fitting of the CRS traveltime and minimize event smoothing. Sarkar, Baumel and Larner (2002) and Fomel (2009) proposed modified coherence measures that consider amplitude variations along reflection events.…”

“…Faccipieri et al . () proposed estimation and stacking apertures to ensure reliable fitting of the CRS traveltime and minimize event smoothing. Sarkar, Baumel and Larner () and Fomel () proposed modified coherence measures that consider amplitude variations along reflection events.…”

Stretch‐free generalized normal moveout correction

“…where x is the source-receiver offset of the trace, t 0 is the traveltime for zero offset. This equation uses only one parameter to stack, that is the stacking velocity v. On the other hand, the CRS-2D uses the following traveltime equation (Jäger et al, 2001;Faccipieri et al, 2016)…”

Common Reflection Surface using Particle Swarm Optimization on Graphical Processing Unit Devices

Common-reflection-point time migration