I prefer to describe them as sulphide body lineations. In other instances, in nickel-sulphide exploration, we might see sulphide blebs or droplets that, by flattening or imposing flow, or both, develop an ellipsoidal shape. Occasionally, these blebs connect themselves along opposite faces of the core. In this case, I prefer to call them droplets-blebs sulphide lineations.

Despite their formational origin, we should first try to understand their shape, orientation and distribution. They are vectors! They are the most basic type of mineralization vectors at the core scale. Now we want to know what are they aiming at? How pervasive are they? These are questions that can be simply addressed at the drill site and validated as drilling progresses.

Indeed, if many of these mineralization vectors are distributed within or nearby mineralization envelops, they can distinctively show grade distribution and its continuity in space. They have the inherent capacity to direct towards the best locations for new drilling, which saves you time and money in your budget.

Continuity, in these cases, is pre-emptively determined by using multimeters – as indicated in the following images. Normally these lineations are not particularly constrained into planes, therefore we use the vSET Method© to fully read their parameters from the core. In this way our 3D models give the most robust picture possible.

ROGERIO MONTEIRO OCTOBER 23, 2014

The post How conductivity is highlighted through vectoring of sulphide lineations appeared first on Vektore Structural Geology and Technology.

Nevertheless, if you want to consistently drill for exploration success, take note of the following: drill into the mineral body, not the mineral target!

The discovery hole and the holes that follow must reveal the most reliable information to allow for an accurate valuation of a mineral property. The collection of mineral intersections created by drilling is the result of the interplay between two distinct geometries: the drilling configuration and the mineral body. I call this cloud of piercing-points mineral intersection geometry or MIG. MIG is not to be confused with the mineral envelope. MIG is about the orientation, distribution, quantity and quality of the mineral intersections provided by a drilling campaign. MIG is the set of mineral intersections used to produce a mineral envelope. Different exploration teams will surely come up with diverse MIGs and therefore they would be susceptible to create different mineral envelopes. Some mineral envelopes will be very good and some others will require additional drilling to approach a reasonable MIG. The best MIGs are the result of a real-time and dynamic review of each borehole that cuts through the mineral envelope. Necessary changes should be carried out to the next borehole and so forth – so the drilling geometry must be highly interactive, otherwise the MIGs will be poor. Well configured MIGs are more predictive and less expensive than the poor ones and will speak volumes about the experience and strengths of the exploration team. A mineral body with a reliable estimate of grade distribution and geometry is a required product to raise interest and investments.

How can one accomplish an effective drilling workflow task, which allows the drilling results to generate the best MIG possible, in a timely manner, within budget and thereby deliver value to investors?

In order to tackle this question one must recognize the power of drilling into the mineral body – a three-dimensional entity, to understand the grade distribution in the context of a particular geometry. This may seem simple and straightforward, but good exploration practices need to be followed to maximize value and minimize risk. The broad framework of such workflow is already out there in the industry (Vearncombe, J. & Vearncombe, S., 1998; Marjoribanks, R., 2010; Davis, B., 2012; Holcombe, R., 2014; and Monteiro, R.N., 2015).  However, it needs to be reconfigured in such a way that it would allow for early predictionsabout the shape of the mineralization, and its continuity and grade distribution. In this context, I expect that if the current industry XYZG Exploration System is augmented with the addition of mineralization-related structural vectors to build the concept of the XYZGV Exploration System the reward should be significant – as it will be explained ahead. By adopting this practice, and optimizing the MIG, exploration geologists should be able to better manage their exploration time and budget, while reducing risk and controlling uncertainties.

The XYZG stands for (x, y, z) coordinates of a sample that returns G, which is the grade. The G of the XYZG is just a scalar property! This is the traditional geochemical or assay sample we collect from core. It is a one-dimensional value that has no directional information to be projected into the three-dimensional space – unless, for instance, it can be vectorized by variography; however, such vectorization requires a large amount of mineral intersections – increasing time and investments – before spatial inferences can be drawn.

On the other hand, XYZGV is geometry-based at each sample site. XYZGV stands for (x, y, z) coordinates that returns not only G but also V, which is a type of vector (Allemendinger, Cardozo and Fisher, 2012) – a structural vector! The XYZGV implies that a grade value, obtained from a sample at (x, y, z) coordinates can be described as a vector or axis.Therefore, this grade can be projected along the mineralization-related structural vector. It not only empowers the exploration geologists to early detect and understand the hidden architecture of the mineralization and continuity, but also prompts them to fast redirect drilling to better intersect the mineral body (Figure 1). Vektore has improved such practices (Monteiro, 2013a and c) with proven record of significant successful applications.

Figure 1 The XYZGV Exploration System allows us to predict the mineralization architecture and its continuity in early stages of exploration by vectorizing the mineralization-related structural features. Note that “V” represents the structural mineralization vector symbolized by the sulphide lineation in this nickel sulphide intersection. The red vector likely describes the flow direction during the mineralization event at this point in space with high probability of pointing towards the mineralization center. Grade and mineralization vectors are fully harmonized and as such they are powerful geometrical predictors.

How can grades and related structural vectors boost efficiency of exploration projects and improve the use of exploration resources?

The best possible path from target to deposit can become apparent and acted on, early in the exploration process, if V is considered; otherwise investments can be denied and discovery postponed. As it is indicated on Figure 1, structural mineralization vectors can effectively influence the decision-making process and its exploration path. The XYZGV Exploration System has the potential for providing explorers with a robust exploration workflow that should enable success! So, how can one move from XYZG to XYZGV? By adding two key players to the current exploration practices: oriented core and structural economic geology analysis. One needs to find and characterize the mineralization-related structural features and place them into a reference frame – 3D space, for further projections and predictions; and this is the basis for structural vectoring within the mineralization space. Structural vectoring leads us to better MIGs and more accurate mineral envelopes.

In order to justify the shift towards the XYZGV Exploration System one needs to recognize its potential benefits. Although the use of oriented core and structural geology has increased recently, the current industry practice needs to be improved. Very few companies use core-orientation as part of their best practices, and some of those that have implemented it in the past are still challenged by its workflow and QAQC – fortunately, such issues can be resolved and streamlined if good practices and methods are applied (Monteiro, R. N., 2015 – vektore.com/services/technology-transfer/).

The mining sector is in its critical downturn at the moment. Investments are sparse and investors are carefully scrutinizing potential projects based on their well demonstrated value. Perception of project value and timing are critical! It is vital we extract the maximum amount of relevant information from core and quickly react to avoid costs that do not add value and are detrimental to the project. Such costs could potentially drive us to dead ends. By adopting the XYZGV Exploration System, one is able to capture and understand the broad architecture and structural controls of the mineral body in the early stages of its exploration, with fewer intersections. Adding V to the exploration geologist’s toolbox should provide sufficient and robust information to direct drilling with the goal of solving geometrical uncertainties as soon as they appear – improving efficiency. For this reason, the XYZGV Exploration System empowers us to act earlier and more effectively in the decision making process. Its inherent capacity of quickly determine the most reliable MIG is substantial and it brings excellent backing for an effective press release.

Exploration companies that incorporate V into their current practices would be able to generate better MIGs and interactively and effectively better dissect a mineral body. Therefore, it is not difficult to predict that the XYZGV Exploration System and its capacity to work with structural mineralization vectors will become a valuable requirement in the mineral exploration business in the near future. The current industry situation represents a great opportunity to test the value of implementing the XYZGV Exploration System. Within this context, in a recent interview published by the Northern Miner Daily News (2015), Mr. Cochrane, a senior research analyst at the Metals and Mining Consultancy in London, stated that if gold price fall below US$1,000/oz., miners will have to raise their cut-off grades and focus on richer zones. In this case the understanding of the internal features of their mineral bodies (patterns, linkages, oreshoots’ geometry and continuities) are paramount – adding “V” to the XYZG most definitively helps addressing this need. Today’s mantra is to be fast, within budget and to efficiently deliver results to your investors.

So, why should one drill into the mineral body and not into the mineral target?

The mineral body is a three-dimensional entity, while the mineral target is usually expressed in two dimensions – the surface. Although related, the mineral body and the mineral target have very distinctive features. By adding the structural vector component to the XYZG we are able to better individualize and set them apart. As such, if one vectorizes the mineralization-related geometrical features observed at each drilling intersection, and progressively takes it into account on subsequent drilling, one is definitively drilling into the mineral body, which is far more effective and rewarding than drilling the mineral target. Interactive drilling and dynamic assessment of the exploration drilling based on the diligent vectorization of the mineralization-related structures is the key concept I am conveying! Since drilling into the mineral body requires a distinct and organized deployment of tools, methods and exploration drive in tune with the concepts presented above, it is very important to understand the roles and values of the following big players: MIG, XYZG, XYZGV, mineral target, mineral body and mineralization-related structures. Such drilling campaign definitely requires a well-designed oriented core program combined with a comprehensive structural economic geology analysis! This proposition is presented in

Figure 2, (based on the Blue Ocean Strategy – Kim and Mauborgne, 2005) where we present some of the main players or competing factors that best describe the differences between the two exploration approaches in consideration – XYZG and XYZGV. The competing factors grouped under “create” are critical for structural vectoring and efficiency of an exploration approach, and they are only available in the XYZGV Exploration System. This diagram provides another dimension to our discussion.

Figure 2 Strategy canvas comparing the XYZG (red line) and XYZGV (blue line) exploration systems based on competing factors. Eleven competing factors are considered in this diagram – scores are from low to high at each competing factor. These factors are grouped into “Reduce”, “Raise” and “Create”, which should be lowered, increased or added, respectively, to create a more efficient exploration approach. Note that the competing factors grouped under “Create” are only available to the XYZGV Exploration System. The XYZGV Exploration System outperforms its industry standard competitor, and adds desirable capacities to our toolbox.

Do you to have intersected mineralization without oriented core? Where to drill next?

Instead of using the trial-and-error drilling approach, with the hope of intersecting mineralization, one should test ways of figuring out the architecture of the target. In this regard, various methods to resolve this problem have been proposed in the literature. More recently, Holcombe (2010 and references herein) reinstated the idea of using the known orientation of a particular reference structure to re-position non-oriented core intervals in its likely original orientation. He called this procedure partially oriented core technique. As a different approach, the Structural Inversion© Method, devised in 2005, is a significant development in the field of processing structural data from non-oriented core. It uses a robust algebraic algorithm to recast the likely orientation of key structural mineralization vectors, which allows significant geometrical predictions (Monteiro, R.N., 2005; Monteiro, R.N. and Koronovich, J., 2006; and Monteiro, R.N., 2013b). This method was single-blind tested before it was deployed for use (Monteiro, 2013b and d and references herein). Since then, it has been used in various exploration sites with significant results by re-directing drilling towards unknown mineral body extensions; notably: IOCGs in Carajas and copper-related mineral targets in the Vale do Curaçá (Brazil). This method should not only conveniently help you to quickly understand the mineral body geometry, but also to acquire sufficient information to predict its extensions and to design a better drilling geometry. Indeed, such application should show you the benefits of capturing the structural mineralization vectors of your mineral target, even before you have been able to implement your own XYZGV program with oriented core.

As a final point, if we drill into the mineral body guided by vectoring the mineralization-related structural features we will significantly augment the probability of an exploration success outcome. This statement comes from our experience derived from different deposit types and exploration sites in a diverse range of mineral districts (nickel sulphides in the Thompson Nickel Belt and in the Sudbury Igneous Complex in Canada; IOCGs in the Carajas Mineral District, gold mineralization in the Iron Quadrangle, copper mineralization in the Vale do Curaçá in Brazil; and copper mineralization in the Copper Belt in Africa). The XYZGV Exploration System has the potential of being one of the much-needed changes in our industry! So, let us drill into the mineral body, not the mineral target! This action will not only potentially increase the return of exploration investments but also strengthen the credibility of the exploration team. Serious investors are on the look for that!

Consulted References:

Allemendinger, R.W., Cardozo, N. and Fisher, D.M. (2012) – Structural Geology Algorithms: Vectors and Tensors. Cambridge University Press. 289 pp.

Davis, B. (2012) Drill core orientation – An Inconvenient Truth – Parts 1, 2 and 3. http://www.orefind.com/

Holcombe, R. (2010) Oriented Drillcore: Measurement, Conversion, and QA/QC procedures for Structural and Exploration Geologists. 36 pp.

Kim, W.C., Mauborgne, R. (2005). Blue Ocean Strategy: How to Create Uncontested Market Space and Make the Competition Irrelevant. Boston: Harvard Business School Press. ISBN 978-1591396192.

Marjoribanks, R. (2010) Geological Methods in Mineral Exploration and Mining. Springer-Verlag Berlin Heidelberg, 2nd Edition. 238 pp.

Monteiro, R. N. (2003). Structural Analysis of Borehole Data and Structural Scenario Design. Inco Internal Peer Reviewed Report.

Monteiro, R.N. (2005) Structural Inversion: Concepts, Procedures and Implications to Mineral Exploration/Exploitation. Internal ITSL Memorandum. December 20, 2005.

Monteiro, R.N. and Koronovich, J. (2006). Structural Inversion. Vale’s Technical Journal, OreShape Vol. 2, Issue 2, pg. 1..20-24. Inco Technical Services Structural Economic Geology Quarterly Newsletter.

Monteiro, R.N. (2011) Best Practices in Applied Structural Geology – Exploration and Exploitation of Mineral Deposits. Vale Global Exploration Technical Services.

Monteiro, R.N. (2013d) – Structural Economic Geology in Mineral Exploration – Day Three, Short Course, 51 slides.

Monteiro, R.N. (2013c) – The V-SET© Method. Vektore Exploration Consulting Corporation internal report.

Monteiro, R.N. (2013b) – The Structural Inversion© Method. Vektore Exploration Consulting Corporation internal report.

Monteiro, R.N. (2013a) Best Practices in Applied Structural Economic Geology – Mineral Exploration. Vektore Exploration Consulting Corporation internal report.

Monteiro, R.N. (2015) Vektore Webpage at www.vektore.com

Northern Miner Daily News (2015) Gold price fall may trigger another round of write-downs – interview with Cochrane, R. on July 24th, 2015. http://www.northernminer.com/news/gold-price-fall-may-trigger-another-round-of-write-downs/1003695595/sv64s8vMxvwq48svWo4zqvs4M2vx/?ref=enews_NM&utm_source=NM&utm_medium=email&utm_campaign=NM-EN07272015. Accessed on July 27th, 2015.

Vearncombe, J. & Vearncombe, S. (1998) Structural Data from Drill Core. In: More meaningful data in the mining industry. AIG Bulleting 22, pp 67-82.

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Indeed, the industry downturn for the past few years – combined with the increasing difficulty to find the new generation of mineral deposits, hidden and deeper – requires immediate attention on meaningful and efficient innovation in the exploration mindset to start reverting the process from the inside-out.

Geophysics and geochemistry, outfitted with their exploration vectoring capacities, have been used with great success in pointing towards new deposits. Nevertheless, explorers still need to significantly escalate discoveries within this very apprehensive industry. It is Vektore’s opinion that there is much to be gained with the combination of the current geophysical and geochemical exploration practices with that of applied structural geology. We foresee that the combined harmonization of these three fields will take place in the near future as we seek solutions for finding greater numbers and new variations of mineral deposits.

It is well recognized that shape and continuity of the mineralization system, as well as its geometry and topology, are critical in unravelling the real potential of a target. For such features to be fully characterized and understood, the incorporation of other tools and methods is required.

We believe that Structural Vectoring is the next layer of exploration rationale, which should be further developed and harmonized with the already known vectoring capacities of geophysics and geochemistry. We foresee that the amalgamation of these three fields will take place in the near future, leading to the solutions we seek to significantly increase our exploration capacities.

These three players, embedded into a sound geology, should lead not only to much-needed new discoveries, but also to elucidating and expanding existing projects, while reducing expenditures. Geophysical-geochemical-structural vectoring is a robust proposition for an inside-out exploration mindset change. Keep in touch with Vektore for the upcoming posts regarding structural vectoring.

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Organizer: Rogerio Noal Monteiro, Ph.D. (Vektore Exploration Consulting Corporation) – this course will have the special participation of Mr. Ben Polzer, M.Sc. from Nova Mining Exploration Solutions.

The goal of Structural Vectoring is to define the linkage between structural features and mineralization processes and use it to predict location, shape, orientation and continuity of mineral bodies. This linkage is particularly useful when drilling a mineral target. In this course we will present and discuss the concept of Structural Vectoring in mineral exploration and recommend a suitable workflow. In addition, we will show plausible ways to harmonize Structural Vectoring with geochemistry and geophysics to significantly improve exploration of mineral targets. Since this course is centered on target evaluation and development, we will focus on Structural Vectoring concepts, tools and methods at the drilling stage.

The instructors will present samples of real cases mineralization-related structural features and discuss how to collect such data, and use these features as predictive tools for direct drilling towards mineral bodies. Strategies on what, why and how many structures should be collected to provide a robust dataset will be proposed to the group and debated. The guidelines for structural logging of core will be carried out by using core samples.

A new method of collecting structural features from oriented and non-oriented core, the vSET© Method, will be introduced to the attendants, who will have the opportunity to compare its characteristics and strengths with current industry standard methods. The Structural Inversion© Method will also be discussed during the course. This practical exercise will help prepare attendants to solve their real case geometrical problems, leading to a better understanding of mineralization processes and their interactions with host architecture. The geometry of drilling and its interaction with a mineral body will be also discussed and viewed from the Structural Vectoring perspective.

Furthermore, the instructors will illustrate the usefulness of Structural Vectoring through a series of case studies that have significantly changed the outcome of exploration projects.

Level of Comprehension: Intermediate

Course Agenda

09:00 – 09:30   1. Introduction to Exploration Vectoring

Rogerio Noal Monteiro, Vektore

09:30 – 10:15   2. Use of Electromagnetic Sensing Methods in the Discovery and Evaluation of Sulphide Deposits

Ben Polzer, Nova Mining Exploration Solutions

10:15 – 10:30   Coffee Break

10:30 – 12:00   3. Structural Vectoring in Mineral Exploration – Part 1

Rogerio Noal Monteiro, Vektore

12:00 – 13:00   Lunch Break

13:00 – 14:00   4. Structural Vectoring in Mineral Exploration – Part 2

Rogerio Noal Monteiro, Vektore

14:00 – 15:00   5. Vectoring: Structural Logging of Core – Practical Exercises – Part 1

Rogerio Noal Monteiro, Vektore

15:00 – 15:15   Coffee Break

15:15 – 17:00   5. Vectoring: Structural Logging of Core – Practical Exercises – Part 2

Rogerio Noal Monteiro, Vektore

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The synergies between Vektore’s and Objectivity’s new developments provide a means to better ranking, budgeting and designing step-out and delineation borehole geometries of mineral exploration projects.

Vektore will take this opportunity to share with you our most recently developed tools and methods of applying Structural Vectoring to mineral exploration projects (vektore.com/2015/07/28/exploration-success-whats-the-drill/ and www.pdac.ca/convention/programming/short-courses/sessions/short-courses/structural-vectoring-in-mineral-exploration-what-it-is-and-how-when-and-why-we-should-use-it). At this venue, we will be showcasing the Structural Module of our in-house vKore software and the 3DKore Reader and Software. The vKore software is a modular, node-based 3-D software application, which is used to carry out our structural vectoring assignments on client’s exploration projects.

Vektore’s 3DKore Reader and Software, at the advanced prototype & evaluation stage, is the first 3-D core imaging tool designed to obtain a permanent record of significant structural features observed in core samples – particularly the mineralization-related structures, which are significant for structural vectoring. The resultant 3-D virtual core can be digitally stored and electronically transferred off-site to any location worldwide for processing of lines and planes, including kinematic features associated to faults and folds. Their spatial location, orientation, and characteristics are directly extracted from within the software’s 3-D viewport. The structural information can be live-linked to 3DKore’s 3-D stereonet and their project digital space for analysis and visualization, which is key in allowing the structural information to be validated and audited by experts or prospective investors, even after the core has been cut, split and pulverized for chemical analysis. In addition, the 3-DKore Reader (hardware) is light-weight, rugged and portable, and can be run from car batteries if the exploration project is located in remote areas.

If you would like to schedule a meeting with us during the event, please send us an email at rogerio.monteiro@vektore.comindicating your preferred time. Otherwise, we will be happy to see you at the Vektore’s and Objectivity’s Structural Vectoring andOptimal Resource Drilling showcase on Monday, March 7th. However, if you cannot make it to our event, please contact us to schedule a personal meeting.

The time is right for a meaningful discussion on new ways to maximize exploration ventures. We await your presence and welcome your input!

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Vektore would like to take this opportunity to thank all attendants of our workshop on Structural Vectoring. It was a pleasure to meet such a multifaceted group of individuals. This multidisciplinary exchange made the course more engaging, and we must say that we also learned also a lot from you. We had a blast showing off our rock collection, and bringing the field and core shack into the PDAC! We also would like to thank Mr.Ben Polzer  for showing us his views and experience on how to use the electromagnetic field as a vectoring component in mineral exploration, which merged quite well with the course goals.

Our core objective was to convey the concept of Structural Vectoring to the participants. From basic principles to practical exercises (including structural logging of a core set from a highly complex mineral body), the audience was exposed to a new core logging technique that focuses on identifying and extracting mineralization-related structural features. These features are the building blocks of a mineral body geometry, continuity and spatial orientation, and should be monitored during follow-up drilling (Monteiro, 2015). The Mineralization-related structural features are fundamental geological indicators to be incorporated in mineral resource studies from PEA to Feasibility and beyond.

The audience was exposed to real case mineralization-related structural features and was shown how such features can be efficiently used as predictive tools to direct drilling towards mineral bodies. Strategies on what, why and how many structures should be collected to provide a robust dataset were proposed to the group and debated.

In addition, a new method of collecting structural features from oriented and non-oriented core, the vSET Method© (Monteiro, 2013a) was introduced to the attendants, who had the opportunity to compare its characteristics and strengths with current industry standard methods. The geometry of drilling and its interaction with a mineral body was also discussed and viewed from the Structural Vectoring perspective. In addition, a real case study was presented involving non-oriented core and a significant mineral intersection in which the extension of the mineralization was not realized and properly followed up until the application of the Structural Inversion Method© a new method to build the local geometry of a mineralization space when it is intersected by non-oriented core (Monteiro, 2005 and 2013b).

Below are some of the photos obtained when the PDAC room was transformed into a core shack. We would love to stay in contact with the attendants and any interested party. If you have any further questions or if you are interested in discussing how to improve exploration with the use of Structural Vectoring, please send us an email.

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We met with so many people who were interested in our expanding tools and methods and got to share our latest case study in Sierra Leone – where our tools were essential to solving a challenging mineralization scenario.

Our team defined key features that had gone unnoticed by previous structural works. A strong correlation between gold and arsenic was already known. However, the shape alignments of arsenopyrite and their clusters were never used and systematically measured to follow positive gold intersections (even though most boreholes from the last campaigns had their cores oriented). Some types of lineations are directly linked to grade distribution and they are easily measured using the vSET™ software and workflow – Vektore’s structural data acquisition and real-time 3D analysis tools which will be described in a future post.

We were able to monitor, from selected boreholes, the spatial orientation of arsenopyrite lineations (shape and clusters) with ease using vSET, despite the fact that most cores were cut in half. It provided us with the most likely orientation expression of the gold mineralizaton vectors at the core scale. The distribution and orientation of the arsenopyrite lineations significantly matched the grade-thickness maps we produced, allowing us to use them as proxy for the gold mineralization patterns. Such lineations were therefore fundamental for the understanding of high-grade domains segmentation and continuity along the deposit. A detailed follow-up study of the arsenopyrite lineations will allow for improved predictability of shape, direction and continuity of the mineralization. We will support our client to incorporate our findings into the upcoming drilling phase and resource modeling.

We would be happy to discuss the application of the vSET to enhance your project results. Vektore is currently finishing up a commercial version of the vSET software that we have been successfully using in-house for years. If you work for a mining or exploration company and are interested in being one of the first to try the beta version, click the button bellow to request early access!

REQUEST EARLY ACCESS

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The OreNode™ Software is our 3-D node-based modular and scalable software designed for Exploration Vectoring in Mineral Exploration. It has a simple and intuitive interface, which is easy to master. The node-based editor carries out the user-defined workflow, which is reusable and portable. Its modular paradigm allows the addition of new expert components. It is fully integrated with the vKore™ Reader/Software. Our software development strategy is harmonized to our client’s needs.

The vKore™ Reader and Software were designed to capture, simultaneously and instantaneously, a 360° digital image of a borehole core and to accurately generate its three-dimension digital representation – the virtual core. This is the first devise capable of capturing the geometry, the color, the texture, and structural features from a quarter, a half or a full core – which is particularly helpful since cut core is the norm near and along mineralized areas. The virtual core is displayed in its exact spatial position and orientation on the vKore’s viewport. Structural features (planes, lines, fold vergence/facing, fault kinematics) are then extracted from this high definition virtual core. Their structural orientations are linked to and directly transferred into the internal database, and into 3-D stereonet for visual inspection, analysis and further processing. In addition, the virtual core can be electronically transferred to any location worldwide, or it can be sent to an expert for a second opinion and processing. It can also be treated as a perpetual core and used for auditing even after the core has been cut, split and pulverized for chemical analysis. It preserves the most important structural and textural features of a borehole with a workable 3-D representation. In addition, borehole images (OTV and ATV) are also renderized within the vKore Software, displaying the de-surveyed borehole wall image in 3-D, from which their structural features (lines, planes, fold vergence/facing) can be directly extracted.

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