Seismic hazard around the World!

This map shows the most hazardous areas all over the world regarding seismic activity! One of the most affected industries is the mining industry, so this spatial analysis presents also some of the mines at a very high risk, with most of the clustering around the Pacific Rim and in a band through Central Asia.

Follow the link here, for more interesting risk maps on the mining industry and critical ecosystems.

Teledyne Optech going to Geomatics Indaba in South Africa

Teledyne Optech is pleased to announce that it is displaying its latest technologies for surveying land and sea at the Geomatics Indaba 2015 conference on August 11 to 13 in Johannesburg, South Africa.

Geomatics Indaba is one of Africa’s largest exhibition and training events for strategic infrastructure planning and spatial technology, and Teledyne Optech will display several solutions to the challenges faced by this industry in Africa. Attendees interested in wide-area surveying for infrastructure development, mapping, and engineering and construction applications can hear about how the Optech Galaxy airborne lidar makes multipulse blind zones a thing of the past with its revolutionary PulseTRAK™ technology while still collecting accurate data from high altitudes. Teledyne Optech staff will also show how surveyors can use the Optech Titan to collect multispectral data for purposes like environmental monitoring and automated land classification. Surveyors wanting to use the Optech CZMIL Nova for river and coastline monitoring will be excited to learn that they can take advantage of its unparalleled depth penetration in turbid waters without a large cost outlay thanks to the CZMIL Project Program.

Underground, Teledyne Optech will show several solutions for engineering and mining applications, including the new wireless Cavity Monitoring System (CMS) V500 model, which improves mine safety and productivity by enabling remote lidar and video surveys of dangerous and inaccessible parts of the mine. On the surface, the Optech ILRIS terrestrial laser scanner has two new options to complement its highly accurate data: The ILRIS UAV quickly produces rich colorized point clouds by pairing the ILRIS with a camera-equipped UAV-mounted camera, while Gexcel’s Open Pit Mine Monitoring System turns ILRIS into an early-warning system against landslides through automated survey execution, data analysis, and alarms. Finally, attendees who need rapid 3D mapping of urban areas and open-pit mines can see which model of Optech Lynx mobile mapper is right for them, the dual-scanner survey-grade Lynx SG1 or the single-scanner mapping-grade Lynx MG1.

Visitors can find Teledyne Optech at booth #69 in the exhibition hall.

Find out more at www.teledyneoptech.com.

About Teledyne Optech

Teledyne Optech is the world leader in high-accuracy lidar 3D survey systems, integrated cameras, and productivity-enhancing workflows. With operations and staff worldwide, Teledyne Optech offers both standalone and fully integrated lidar and camera solutions for airborne mapping, airborne lidar bathymetry, mobile mapping, terrestrial laser scanning, mine cavity monitoring, and industrial process control, as well as space-proven sensors. Teledyne Optech systems are also fully warrantied, with extended warranty packages offered by Optech Technical Solutions. Accuracy and productivity matter!

For further information, please contact your Regional Sales Manager or:


Wayne Szameitat
International Sales Manager
Teledyne Optech
300 Interchange Way
Vaughan, Ontario, Canada L4K 5Z8
+1 905 660 0808
Email Contact
www.teledyneoptech.com

Source

CMC acquires Maptek Sentry for survey and monitoring at Portia Gold Mine

Consolidated Mining & Civil Pty Ltd (CMC) has acquired a Maptek Sentry monitoring system, primarily for use at Havilah Resources Limited’s Portia gold mine in South Australia.

The Sentry solution is an active monitoring system for tracking movement and notifying stakeholders about potentially unsafe areas of an open pit operation. A long range I-Site 8820 laser scanner and dedicated software help sites measure and analyse unpredictable wall movement.

The I-Site point cloud data which is used in the Sentry solution can also be processed and modelled for survey reconciliation, stockpile volumetrics, geological mapping and kinematic analysis. Sentry allows several areas to be monitored within a single scan extent. Animations, continual analysis and graphical reports provide comprehensive information for reviewing results to guide future monitoring.

CMC is responsible for removing all of the overburden and bringing the ore to the surface at the Portia gold mine which lies 100 km northwest of the Broken Hill regional mining centre. At Portia the gold occurs in a
2-3 metre layer below 75 metres of clay overburden (about 7 million cubic metres), which is being removed to access the ore.

At Portia the Sentry solution will be applied to track movement and stability of walls in the open pit. The I-Site laser scanner will also be used for routine survey applications throughout the operation. A rugged Maptek mountattaching the I-Site laser scanner to the roof of a site vehicle, gives CMC greater flexibility
for surveying large areas efficiently.

‘We went with Maptek for several reasons. Price, local support, ease of use and the combination of survey and monitoring applications makes the choice obvious’, said CMC Principal Steve Radford.

‘Prior to mining commencement we’ve remodelled and constructed 35 km of access roads and an airstrip as well as establishing infrastructure such as workers’ camp, on-site concrete batching plant and maintenance facilities.’

‘In remote environments where you need to ensure worker safety, Sentry provides a diagnostic tracking tool with clear visualisation and analysis capabilities so we can make reliable engineering decisions’ he said.

About CMC

The Consolidated Group of companies employs more than 450 people and owns and operates more than 700 items of plant in its general contracting business across Australia. CMC has a long term solid affiliation with the Broken Hill region in New South Wales, successfully conducting major earth moving contracts, specialising in open cut mining. Activities include contract crushing and screening, bulk haulage and open cut mining.

About Maptek

Founded more than 30 years ago, Maptek™ is a leading provider of innovative software, hardware and services for global mining. Maptek products are used at more than 1700 sites in 75 countries, with solutions across the mining cycle from exploration to reclamation. Vulcan™ is the premier 3D mine planning and modelling package.

I-Site™ is integrated hardware and software for 3D laser scanning, surveying and imaging. PerfectDig™ provides a platform for design conformance. BlastLogic™ is intelligent 3D drill and blast management software. The Eureka™ environment is ideal for visualising and interpreting geophysical and seismic data. Sentry is a laser-based system for identifying trends in surface movements. Evolution provides strategic and tactical scheduling and optimisation tools.

Source

Introducing: Planetery resources, the Asteroid Mining Company

by Alexandros Dourtmes




It has come to my attention the last few days, this spectacular attempt to conquer space once more, only this time on a whole new level! I'm referring to Planetary Resources, an Asteroid Mining Company, a team of scientists, advisors, investors and partners who are pioneering in the mining industry, by preparing a spacecraft launch which is gonna take place in 20 weeks and 2 days.


Here follows an extract from the company's site, where the company itself presents a brief, yet in depth analysis of the technology and details of its mission.



Text taken from : http://www.planetaryresources.com/technology/#technology-overview

Our Mission Demands the Best.

Our spacecraft are headed into deep space. It’s a challenging environment: outside Earth’s protective magnetosphere, without navigational references and tens of minutes away traveling at the speed of light from home. This is where our spacecraft must thrive.
That’s why kilo for kilo, we build the most capable commercial space systems ever designed. Simply put, the business of asteroid mining demands nothing less.
To prospect the asteroids, we need miniaturized sensors that communicate effectively over long distances on an autonomous, mobile, and resilient platform. These are the systems we’re building today.

LOW COST AVIONICS & SOFTWARE

How did it come to be that your cell phone wields significantly more computing power than NASA’s most complicated, most expensive robotic explorers?

Interplanetary space is a challenging environment for spacecraft avionics. Not only can the thermal, vacuum, and radiation environments damage electronics, the sheer distance from Earth drives designers to take conservative approaches to new technology adoption. Solutions today often rely on redundant architectures using expensive, centralized, heritage components specifically designed for operations in deep space. This philosophy limits the design team’s ability to benefit from the tremendous advancements in the microelectronics industry, leaving them consistently behind the technological curve. The Mars Curiosity rover, for instance, is controlled by a redundant system that uses a CPU originally developed almost two decades ago.
At Planetary Resources, we are breaking away from this model. Instead of an architecture that relies on a single, centralized and expensive set of avionics hardware, we take a tiered and modular approach to spacecraft avionics. In our model, a distributed set of commercially-available, low-level hardened elements each handle local control of a specific spacecraft function. This disaggregation of functional responsibility has a number of advantages:

• It is easier to accommodate modern components and COTS hardware because we can replace a single component or sub-system without perturbing the rest of the design.
• We can rapidly iterate on spacecraft design because the exact form and configuration of the system can be modified late in a design flow.
• We can reduce system inter-dependencies as each component has its own independent compute element that coordinates with other parts of the system.
• We can decouple hardware and software through virtualization so that each may advance at their own pace.

Even with this change in architecture, the radiation environment of space is still challenging. Instead of making our system completely “hardened”, we make our systems resilient to the effects of radiation by designing the system to allow normal operations to continue despite random reset events on various elements of the architecture. A modular de-centralized hardware approach allows for a fault to be contained locally at only the component affected. The ramifications of such an event do not propagate through power, data, and functional interfaces to the rest of the system.

ATTITUDE DETERMINATION & CONTROL SYSTEMS

Planning for the future

Traditional spacecraft control systems are designed to meet the pointing requirements for a single vehicle with specific mission goals. This narrow scope produces an architecture that is unique and rigid, driving up development costs and effort for the attitude control system of each new vehicle. Planetary Resources is developing a spacecraft control architecture that is both modular and upgradable, right from the beginning. This investment supports the rapid deployment and evolution of our spacecraft as internal and external demands change.

Vertically Integrated

With spacecraft control, you are only as good as your hardware. And in some cases, the right sensor or actuator for this critical function may not be available or cost-effective. That’s why we have built a new suite of sensors and actuators right here at Planetary Resources. These systems can measure a spacecraft rotating at a rate slower than the hour hand of a clock while pointing a beam within the width of a dime one mile away. By controlling the design of both the components and the system, we can balance capabilities and risks where they are appropriately taken rather than depend on historical vendor decisions. And when the time is right to upgrade, we control our own path.

A System-level Solution to Reliability

Controlling spacecraft attitude is inherently a system level function. This has driven us to reimagine how the role of ADCS is distributed within a spacecraft. We have moved away from a traditional, centralized approach in which a single compute element is responsible for the ADCS system and have instead adopted the idea of basic, instinctual behaviors. Instincts are a way of commanding and protecting critical spacecraft components locally, using an integrated and distributed network of low-level hardened compute elements. Similar to a person instinctively removing their hand from a hot surface, the ADCS system has built-in instinctual responses that react to protect the system without relying on the central brain.

SPACE COMMUNICATIONS

Interplanetary space can be lonely, especially if there is no one to talk to.

“Talking” is a difficult task for any intrepid robotic explorer on its way to near Earth asteroids (NEA), as the distance back to Earth can exceed 2 Astronomical Units (AUs), or nearly 200 million miles. Traditional spacecraft use radio frequency, or RF, communications to solve this problem. While proven and reliable, RF systems require massive and power-intensive hardware that drive the cost of deep-space probes outside of the constraints of commercial budgets. At the same time, very large, sensitive receivers on Earth are necessary to pick up the incredibly faint signals from the spacecraft. NASA’sDeep Space Network, which includes some of the largest radio telescopes on Earth (as large as 70 meters in diameter), was specifically designed to communicate with interplanetary probes in this way. And it does so everyday, providing critical communications for dozens of US government and international spacecraft around the solar system. Unfortunately, this makes for a pretty busy interplanetary network, one that is difficult to rely on for commercial operations in deep space.
Fortunately, Planetary Resources has found a solution to this problem in the form of optical communications. Due to the shorter wavelength of optical communications when compared to RF, lasers allow for information to be communicated through a more tightly controlled beam using a significantly smaller aperture. This narrower focus greatly reduces the power required for a given communications data rate and distance, allowing a small spacecraft to effectively relay scientific and technical data, even when it is on the other side of the Solar System.
Planetary Resources is developing a multi-function main instrument for its Arkyd spacecraft platform, one that integrates remote imaging, optical navigation, and optical communications into a single, resource-efficient tool. The system will take advantage of many of the advancements made in free space optical communications here on Earth, as well as previous work performed for NASA, with MIT as a partner, on miniaturized stabilization for optical communications on nano-satellites.

HIGH ΔV SMALL SATELLITE PROPULSION SYSTEMS

Sending a spacecraft into deep space is an energetically expensive proposition.

Conventionally, a spacecraft headed out into the Solar System would be placed directly on its outbound trajectory by its own launch vehicle. This launch vehicle alone can be a $100 Million proposition, or more. We are taking a different path. Our Arkyd prospecting spacecraft are small enough to hitch a ride into space with larger, primary payloads. We launch one at a time into an orbit based on the needs of the rocket’s primary payload. This presents a challenge, as a rendezvous with a solar-orbiting asteroid requires departing Earth at a very specific time, at a specific speed, and in a very specific direction. Otherwise, you could miss your rendezvous by thousands, or even millions, of kilometers.
Planetary Resources solves this problem by being able to make its own way to near Earth asteroids directly from the low Earth orbit where it is placed as a secondary payload. Once in orbit, the Arkyd spacecraft uses its onboard propulsion system and an advantage of the Earth’s gravitational influence called theOberth effect to escape Earth’s gravity well and head towards a future rendezvous with the NEA of interest.
The Arkyd spacecraft also employs two key technologies to enable this scale of propulsive capability on such a small platform. First, the system uses one of a new family of green, non-toxic monopropellants. This allows the spacecraft, as a secondary payload, to be successfully integrated for launch without significant schedule impact or safety risk to the rocket’s primary satellite customer. Second, this propellant is stored and managed within a propulsion system that is directly integrated into the spacecraft’s primary structure. Working with its strategic investor and partner 3D Systems, Planetary Resources is using additive manufacturing techniques to directly integrate the system’s manifold, plenum, and routing geometries directly into structural elements that support the spacecraft’s elements during the rigors of launch. By doing so, a system that conventionally consists of hundreds of parts and countless workmanship-sensitive assembly operations is now simplified down to just a handful of components, resulting in a system that is at once lighter, cheaper, safer, and much easier to build again and again.

SPACE-BASED OBSERVATION

Specialized systems to prospect asteroids, and much more.

Asteroid prospecting requires tools that can determine mineralogy, water composition, macroporosity, and other ore body characteristics. We are developing sensors that operate over a wide spectral range beyond traditional visible wavelength sensors to achieve these goals. When combined with Planetary Resources’s agile small spacecraft platform, these sensors also have major applications closer to home: Earth Observation and Space Situational Awareness.

Earth Observation

Traditional Earth Observation systems operate in the visible and near-IR with panchromatic or multispectral capabilities. To enable asteroid prospecting, Planetary Resources has invested in the miniaturization of hyperspectral capabilities and the space-based utilization of miniaturized mid-wavelength infrared (MWIR) sensors. In addition to supporting the characterization of asteroids, these systems provide extraordinary insights closer to home.

Space Situational Awareness

With over 50 years of human activity, the prime real estate in space has become crowded and more complex than ever before. Knowing where your asset is, characterizing its health, and assessing proximity to other objects and obstacles ensures safe and reliable operations. The same technologies we use to rendezvous with an asteroid, carry out remote sensing, and perform proximity operations can be applied to the local space environment to serve several critical applications:

• Space debris monitoring and collision avoidance
• Tracking of spacecraft position and orbital transfers
• Satellite monitoring and characterization for safe on-orbit operations