A Guide to Target Zones

Abstract The high reservoir uncertainty, due to the lateral distribution of fluids, results in variable water saturation, which is very challenging in drilling horizontal wells. In order to reduce uncertainty, the plan was to drill a pilot hole to evaluate the target zones and plan horizontal sections based on the information gained. To investigate the possibility of avoiding pilot holes in the future, an advanced ultra-deep resistivity mapping sensor was deployed to map the mature reservoirs, to identify formation and fluid boundaries early before penetrating them, avoiding the need for pilot holes. Prewell inversion modeling was conducted to optimize the spacing and firing frequency selection and to facilitate an early real-time geostopping decision. The plan was to run the ultra-deep resistivity mapping sensor in conjunction with shallow propagation resistivity, density, and neutron porosity tools while drilling the 8 ½-in. landing section. The real-time ultra-deep resistivity mapping inversion was run using a depth of inversion up to 120 ft., to be able to detect the reservoir early and evaluate the predicted reservoir resistivity. This would allow optimization of any geostopping decision. The ultra-deep resistivity mapping sensor delivered accurate mapping of low resistivity zones up to 85 ft. TVD away from the wellbore in a challenging low resistivity environment. The real-time ultra-deep resistivity mapping inversion enabled the prediction of resistivity values in target zones prior to entering the reservoir; values which were later crosschecked against open-hole logs for validation. The results enabled identification of the optimal geostopping point in the 8 ½-in. section, enabling up to seven rig days to be saved in the future by eliminating a pilot hole. In addition this would eliminate the risk of setting a whipstock at high inclination with the subsequent impact on milling operations. In specific cases, this minimizes drilling risks in unknown/high reservoir pressure zones by improving early detection of formation tops. Plans were modified for a nearby future well and the pilot-hole phase was eliminated because of the confidence provided by these results. Deployment of the ultra-deep resistivity mapping sensor in these mature carbonate reservoirs may reduce the uncertainty associated with fluid migration. In addition, use of the tool can facilitate precise geosteering to maintain distance from fluid boundaries in thick reservoirs. Furthermore, due to the depths of investigation possible with these tools, it will help enable the mapping of nearby reservoirs for future development. Further multi-disciplinary studies remain desirable using existing standard log data to validate the effectiveness of this concept for different fields and reservoirs.

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Target Zones and Realignment Expectations: The Israeli and Mexican Experience

SSRN Electronic Journal ◽

10.2139/ssrn.883260 ◽

1995 ◽

Author(s):

Alejandro M. Werner

Keyword(s):

Target Zones

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On the Sustainability of Exchange Rate Target Zones with Central Parity Realignments

SSRN Electronic Journal ◽

10.2139/ssrn.2619389 ◽

2015 ◽

Author(s):

Enrique Martinez-Garcia

Keyword(s):

Exchange Rate ◽

Target Zones ◽

Exchange Rate Target Zones

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An Interpretation of Recent Research on Exchange Rate Target Zones

The Journal of Economic Perspectives ◽

10.1257/jep.6.4.119 ◽

1992 ◽

Vol 6 (4) ◽

pp. 119-144 ◽

Cited By ~ 140

Author(s):

Lars E. O Svensson

Keyword(s):

Exchange Rate ◽

Central Bank ◽

Exchange Rates ◽

Interest Rates ◽

Empirical Research ◽

Target Zones ◽

The Difference ◽

Exchange Rate Target Zones ◽

Main Ideas ◽

Central Bank Interventions

How do exchange rate bands work compared to completely fixed rates (between realignments); or, more precisely, what are the dynamics of exchange rates, interest rates, and central bank interventions within exchange rate bands? Does the difference between bands and completely fixed exchange rates matter, and if so, which of the two arrangements is best; or, more precisely, what are the tradeoffs that determine the optimal bandwidth? This article will present an interpretation of some selected recent theoretical and empirical research on exchange rate target zones, with emphasis on main ideas and results and without technical detail.

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Optimising predictor domains for spatially coherent precipitation downscaling

Hydrology and Earth System Sciences ◽

10.5194/hess-17-4189-2013 ◽

2013 ◽

Vol 17 (10) ◽

pp. 4189-4208 ◽

Cited By ~ 30

Author(s):

S. Radanovics ◽

J.-P. Vidal ◽

E. Sauquet ◽

A. Ben Daoud ◽

G. Bontron

Keyword(s):

Statistical Downscaling ◽

Prediction Models ◽

Target Location ◽

Weather Prediction ◽

Target Zones ◽

Southeastern Part ◽

Global Circulation Models ◽

Downscaling Method ◽

Starting Point ◽

East West

Abstract. Statistical downscaling is widely used to overcome the scale gap between predictors from numerical weather prediction models or global circulation models and predictands like local precipitation, required for example for medium-term operational forecasts or climate change impact studies. The predictors are considered over a given spatial domain which is rarely optimised with respect to the target predictand location. In this study, an extended version of the growing rectangular domain algorithm is proposed to provide an ensemble of near-optimum predictor domains for a statistical downscaling method. This algorithm is applied to find five-member ensembles of near-optimum geopotential predictor domains for an analogue downscaling method for 608 individual target zones covering France. Results first show that very similar downscaling performances based on the continuous ranked probability score (CRPS) can be achieved by different predictor domains for any specific target zone, demonstrating the need for considering alternative domains in this context of high equifinality. A second result is the large diversity of optimised predictor domains over the country that questions the commonly made hypothesis of a common predictor domain for large areas. The domain centres are mainly distributed following the geographical location of the target location, but there are apparent differences between the windward and the lee side of mountain ridges. Moreover, domains for target zones located in southeastern France are centred more east and south than the ones for target locations on the same longitude. The size of the optimised domains tends to be larger in the southeastern part of the country, while domains with a very small meridional extent can be found in an east–west band around 47° N. Sensitivity experiments finally show that results are rather insensitive to the starting point of the optimisation algorithm except for zones located in the transition area north of this east–west band. Results also appear generally robust with respect to the archive length considered for the analogue method, except for zones with high interannual variability like in the Cévennes area. This study paves the way for defining regions with homogeneous geopotential predictor domains for precipitation downscaling over France, and therefore de facto ensuring the spatial coherence required for hydrological applications.

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Improving Fluoroscopic Visualization for Lower Cervical Medial Branch Blocks with a Modified Swimmer’s View: A Technical Report

January 2018 - Pain Physician ◽

10.36076/ppj.2018.3.303 ◽

2018 ◽

Vol 1 (21;1) ◽

pp. 303-308

Author(s):

David Stolzenberg

Keyword(s):

Facet Joint ◽

Lateral View ◽

Medial Branch ◽

X Rays ◽

Zygapophyseal Joint ◽

Target Zones ◽

Technical Report ◽

Future Prospective Study ◽

Medial Branch Block ◽

Practice Methods

Background: Neural blockade of the cervical medial branches is a validated procedure in the diagnosis and treatment of cervical zygapophyseal joint pain. Fluoroscopic visualization of the lower cervical medial branch target zones (CMBTZs) in lateral view is sometimes challenging or not possible due to the patient’s shoulders obscuring the target. Large shoulders and short necks often exacerbate the problem. Clear visualization is critical to accuracy and safety. Objective: We aim to describe a method for optimal fluoroscopic visualization of the lower CMBTZs using a modified swimmer’s view. Study Design: A technical report. Setting: A private practice. Methods: Discussion with accompanying fluoroscopic images of the cervical spine, focusing on the lateral aspects of the lower cervical articular pillars in both the traditional lateral view and modified swimmer’s view. Four authors served as volunteers for undergoing fluoroscopic x-rays in both views. Visualization of each lower CMBTZ was attempted and stored. The most caudal, clearly visualized levels were compared in both views for each participant. Results: Visualization of the lower CMBTZs can be successfully obtained with the modified swimmer’s view and in select patients is superior to a lateral view. Limitations: A limitation to this study is the design as a technical report. A future prospective study is warranted. Conclusions: Modified swimmer’s view can serve as a primary method of visualizing the lower CMBTZs or an alternate view when a lateral view is unable to clearly demonstrate target landmarks. This can improve the ease, accuracy, and safety of performing diagnostic cervical medial branch blocks (CMBBs). Key words: Swimmer’s view, cervical medial branch block, facet joint, fluoroscopy

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