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Airbus Defence and Space has developed a unique NATO Response Force Deployable Communications and Information Systems solution to support today's rapid reaction needs. Be it for peacekeeping, humanitarian aid or other military operations, communication and information systems are the building blocks for remotely executed operations.
Come through boys- hit the like and subscribe button Music: Steal Away, Reprise (Celtic part)
EPFL scientists have developed electrode arrays that can be funneled through a small hole in the skull and deployed over a relatively large surface over the brain’s cortex. The technology may be particularly useful for providing minimally invasive solutions for epileptic patients. Full article: 🤍 Article en français: 🤍 DOI: 🤍 Altmetric: 🤍 Neuro X Institute: 🤍 EPFL: 🤍 #neurotechnology #bioelectronics #electrodes #flexibleelectrodes
Natalia Torres, explain us, her thesis about the deployable domes methodology as from the geometry of regular polygons
The Allied Rapid Reaction Corps (ARRC) is NATO’s quick deployable command centre. The ARRC is usually based in Gloucester UK, however it is currently deployed in Lielvarde, Latvia on exercise Arrcade Fusion. Commanded by Lieutenant General Tim Evans, the exercise tests the ARRC’s ability to set up a large headquarters quickly and efficiently, and also to control simulated troop formations in a fictional security or humanitarian crisis. ▬▬▬▬▬▬▬▬▬▬▬▬▬▬▬▬▬▬ SUBSCRIBE to this channel 🤍 SUBSCRIBE to NATO News 🤍 SUBSCRIBE to NATO History 🤍 Connect with NATO online: Visit the Official NATO Homepage: 🤍 Receive NATO updates via email: 🤍 Find NATO on FACEBOOK: 🤍 Follow 🤍NATO on TWITTER: 🤍 Follow NATO on Instagram: 🤍 Find NATO on LinkedIn: 🤍 Find NATO on Flickr: 🤍 #NATO #OTAN #ARRC
DEPLOYABLE MECHANISMS Among the many deployable mechanisms currently available on the market, the most famous one is the Hoberman sphere. This mechanism which is mainly used as a toy, can be deployed from 24 to 75 cm (9.5 to 30 inches), thus increasing its volume by more than 30 times. Since deployable mechanisms do not all function in the same manner, each mechanism has its own advantages and disadvantages. Several deployable mechanisms have been developed in the laboratory, their main characteristics being the following: - the mechanisms have only 1 DOF; - the mechanisms always keep the same geometric shape; - the mechanisms always have an empty center; - the mechanisms are based on the five Platonic solids. This sequence illustrates the deployment of a triangular face MÉCANISMES DÉPLOYABLES Parmi la multitude de mécanismes déployables actuellement sur le marché, le plus célèbre est sans aucun doute la sphère de Hoberman. Ce mécanisme, utilisé principalement comme jouet, permet de s'agrandir de 24 à 75 cm (9,5 à 30 pouces), augmentant ainsi son volume de plus de 30 fois. Les mécanismes déployables n'ont pas tous le même type de fonctionnement, conférant alors des avantages et des inconvénients différents à chacun d'eux. Plusieurs mécanismes déployables ont ainsi été développés au laboratoire. Les principales particularités étant que : - les mécanismes ne possèdent qu'un seul degré de liberté ; - les mécanismes conservent toujours leur forme géométrique ; - les mécanismes ont toujours un centre vide ; - les mécanismes sont construits à partir des cinq solides de Platon. Cette vidéo montre le déploiement d'une face triangulaire. Pour plus d'information, For more information, 🤍
DEPLOYABLE STRUCTURES WORKSHOP Foldable Pavilion 26 Sep – 03 Oct 2017 Abdullah Gül University Kayseri, Turkey SMiA Research Group 🤍smia-experimental.com info🤍smia-experimental.com
OTTER is a bridge and ferry system designed for safe and fast transport of combat and logistic military vehicles across the wet during river crossing operations. OTTER system can also be used in natural disasters such as floods. Being the only 8x8 vehicle in its class in the market today, the OTTER has unprecedented redundancy, operational capability in soft soil, cross-country mobility and amphibious performance. Exceptional road and off-road performance with its all-wheel 8x8 driveline with central tire inflation and adjustable ride height control features provides an incomparable off-road driving performance and speed especially on loose, muddy and rough terrains. The ability to operate in soft soils allows for significantly less preparation on riverbanks for water entrance and exit. The all-wheel-steering feature minimizes the vehicle’s turning radius. The vertical obstacle and trench crossing capabilities are also superior due to the shorter distance between axles in 8x8 concept. Moreover, 8x8 driveline with maximum axle load of around 9 tons has significantly low ground pressure and provides longer wheel life due to less wear. The OTTER can achieve up to 60% gradient and 30% side slopes.
20 seconds is all it took to build a branded first-party data landing page on Deployable. Our latest update coming soon, is customer data driven and opens up: 🚀 New templates 🚀 Responsive design 🚀 Upgraded pre-populated sections 🚀 Brand new first-party data collection tools 🚀 Upgraded games system An easy-to-use, no-code audience engagement digital experience builder. Stay tuned for the update release date 🚀
Origami-inspired, on-demand deployable and collapsible mechanical metamaterials with tunable stiffness. Zirui Zhai et al (2018), PNAS 🤍 Origami has been employed to build deployable mechanical metamaterials through folding and unfolding along the crease lines. Deployable metamaterials are usually flexible, particularly along their deploying and collapsing directions, which unfortunately in many cases leads to an unstable deployed state, i.e., small perturbations may collapse the structure along the same deployment path. Here we create an origami-inspired mechanical metamaterial with on-demand deployability and selective collapsibility through energy analysis. This metamaterial has autonomous deployability from the collapsed state and can be selectively collapsed along two different paths, embodying low stiffness for one path and substantially high stiffness for another path. The created mechanical metamaterial yields load-bearing capability in the deployed direction while possessing great deployability and collapsibility. The principle in this work can be utilized to design and create versatile origami-inspired mechanical metamaterials that can find many applications. Good channel: 🤍 Subscribe, like and comment. Good website: 🤍 Bookmark, subscribe and comment.
HO RO that subscribe and like button MUSIC: 🤍 British Grenadiers.WELSH GUARDS
Whether it's MW19 or MW2, I seem to be one of the only people that actually uses deployable covers. In this video im showing a bunch of spots I found with deployables to either create a new peak/headglitch, or get to an area you're not normally supposed to be able to get to. Most of these are mainly used for hardpoint and domination, if you enjoyed the video i'd appreciate a like, sub, or comment :3
An example of a self-synchronized, 'mobility 1' deployable mechanism, produced by an academic partner of Oxford Space Systems. Contact OSS for details.
The Deployable Air Traffic Awareness (DATA) Systems Prototype developed with Defence industry partner Sigma Bravo, was tested in a field environment before deployment during Exercise Talisman Sabre 2021. The rapidly deployable, small self supported kit provides immediate air traffic awareness to air traffic controllers in situations where systems do not exist or are incapacitated. This prototype was developed by Jericho Disruptive Innovation and will be trialled by Air Force No. 44 Wing.
Prof SeungDeog Kim (Emeritus Professor of Architectural Engineering at Semyung University, Korea) talks to us about deployable façades. Watch the full interview here: 🤍 #IASS #IASS2020_21 #MoversandShakers #Interview #SpatialStructures #Architecture #Structures #Engineering #LightweightStructures #CivilEngineering #StructuralEngineering #Conference #SemyungUni #Korea #SEWC #ComputationalDesign #DeployableStructures #DeployableSystems #DeployableDomes #DeployableShelters #DeployableFacades
In this video walkthrough, we demonstrated the exploitation of a vulnerable Tomcat Webserver to gain initial access to the remote host. We escalated our privileges by exploiting an unquoted service path in Windows. Receive video documentation 🤍 Do you need private cybersecurity training? sign up here 🤍 Twitter 🤍 LinkedIn 🤍 Instagram 🤍 Facebook 🤍
Deployable Soft Composite Structures. Wei Wang et al (2016), Scientific Reports 🤍 Deployable structure composed of smart materials based actuators can reconcile its inherently conflicting requirements of low mass, good shape adaptability, and high load-bearing capability. This work describes the fabrication of deployable structures using smart soft composite actuators combining a soft matrix with variable stiffness properties and hinge-like movement through a rigid skeleton. The hinge actuator has the advantage of being simple to fabricate, inexpensive, lightweight and simple to actuate. This basic actuator can then be used to form modules capable of different types of deformations, which can then be assembled into deployable structures. The design of deployable structures is based on three principles: design of basic hinge actuators, assembly of modules and assembly of modules into large-scale deployable structures. Various deployable structures such as a segmented triangular mast, a planar structure comprised of single-loop hexagonal modules and a ring structure comprised of single-loop quadrilateral modules were designed and fabricated to verify this approach. Finally, a prototype for a deployable mirror was developed by attaching a foldable reflective membrane to the designed ring structure and its functionality was tested by using it to reflect sunlight onto to a small-scale solar panel. Good channel: 🤍 Subscribe, like and comment. Good website: 🤍 Bookmark, subscribe and comment.
🤍GhostCraft1984 go check out that channel please :D
This video sequence shows the deployment of a pentagonal face. Cette séquence illustre le déploiement d'une face pentagonale. Pour la description complète de ce projet, For the full description of this project, 🤍 Pour plus d'information, For more information, 🤍
Sequence illustrating the deployment of a triangular prism. Séquence illustrant le déploiement d'un prisme triangulaire. Pour la description complète de ce projet, For the full description of this project, 🤍 Pour plus d'information, For more information, 🤍
The Deployable SSE Bag is the perfect way to keep an extra bag on hand for SSE (sensitive site exploitation) or other situations. Featuring a main compartment and two exterior pockets, the lightweight 70D nylon ripstop material helps protect your gear from the elements. Built with an integrated stuff sack, the bag quickly collapses so it can conveniently be worn on your belt or kit. It’s compact size allows you to easily pack the bag with the rest of your gear while traveling.
A nearly $9 million Transportation Safety Administration pilot program tested a cockpit voice and flight data recorder that ejects and floats when a plane crashes into water. While cost may be deterring airlines from installing the technology, one congressman says the price of an underwater search is much higher. Jeff Pegues reports.
A short video on how to turn on /off the Deployable Side steps on a 2017 Range Rover Autobiography.
Research at the EPFL Geometric Computing Laboratory (GCM) aims at empowering creators. We develop efficient simulation and optimization algorithms to build computational design methodologies for advanced material systems and digital fabrication technology. Mathematical reasoning, geometric abstractions, and powerful numerical methods are key ingredients in our work. In this talk I will show how these tools can be used to solve challenging inverse problems for deployable structures that can transition between multiple geometric states. Several design studies will highlight how the interplay of geometry, computation, and digital fabrication technologies facilitates the discovery of new material systems with superior functional performance. Such systems offer a wide variety of potential applications, for example in industrial and consumer products, soft robotics, medical devices, or architecture.
During any kind of deployed operations, reliable communication immediately becomes paramount. By using a deployable, flexible and modular solution, all sorts of communication needs are taken care of. This is one example where we have applied it on a mobile airbase, connecting all pieces of the operation into a smooth and efficient communication flow for maximum operational availability. 🤍 Follow Saab on Facebook: 🤍 Follow Saab on Twitter: 🤍 Follow Saab on Instagram:🤍 Follow Saab on LinkedIn: 🤍
by Changxi Zheng, Timothy Sun, and Xiang Chen Technical Paper at SCA 2016: 🤍 Music from Audio Jungle Abstract: We present a pipeline that allows ordinary users to create deployable scissor linkages in arbitrary 3D shapes, whose mechanisms are inspired by Hoberman's Sphere. From an arbitrary 3D model and a few user inputs, our method can generate a fabricable scissor linkage resembling that shape that aims to save as much space as possible in its most contracted state. Self-collisions are the primary obstacle in this goal, and these are not addressed in prior work. One key component of our algorithm is a succinct parameterization of these types of linkages. The fast continuous collision detection that arises from this parameterization serves as the foundation for the discontinuous optimization procedure that automatically improves joint placement for avoiding collisions. While linkages are usually composed of straight bars, we consider curved bars as a means of improving the contractibility. To that end, we describe a continuous optimization algorithm for locally deforming the bars.
Shaun Connors talks to WFEL about their Leguan AVLB (Armoured Vehicle Launched Bridge) with a Titan interface at DVD 2018
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LimbForge is focused on delivering better lives for patients with new, faster, and culturally appropriate prosthetic design and device fabrication via software and 3D printing. 🤍
AWS Public Sector Summit 2018 - Washington, D.C. During and after a disaster, the speed, timeliness, and accuracy of response and recovery efforts can be the difference that saves many lives. In this session, you will be introduced to the Amazon Web Services Disaster Response Program (AWS DRP). We will provide an overview of the program, its purpose, services, and the capabilities designed to assist customers responding to disasters and/or emergencies. This session will also provide insights into “the Art of the Possible” as it relates to how the various native AWS Services can be used to deliver the capabilities required to assist customers in accessing critical data, infrastructure, and decision making tools during disasters. Speaker: Paul Bockelman
NASA’s Strategic Space Technology Investment Plan has identified entry, descent and landing (EDL) as one of eight core technology investment areas and, within the EDL core area, deployable hypersonic decelerators are identified as a key technology area. The Adaptable, Deployable, Entry and Placement Technology, ADEPT SR-1 project is developing a mechanically deployable low-ballistic coefficient aeroshell entry system to perform EDL functions for planetary missions. For more information, visit 🤍
At DLA Distribution at Hill Air Force Base, Utah, shelters that serve as field operating rooms and x-ray rooms are refurbished and made mission-ready at a significant cost savings to the Army.
*How to USE the Deployable Cover Correctly* Twitch- 🤍 Twitter-🤍 Tiktok-🤍 #cod #warzone #callofduty #fyp #battleroyale
Speaker: Srinivas Peeta, Frederick R. Dickerson Chair and Professor, School of Civil and Environmental Engineering, H. Milton Stewart School of Industrial and Systems Engineering, Georgia Institute of Technology Abstract: Routing strategies using dynamic traffic assignment have been proposed in the literature to optimize system performance. However, challenges have persisted in their deployability and effectiveness due to inherent strong assumptions on traveler behavior and availability of network-level real-time traffic information, and the high computational burden associated with computing network-wide flows in real-time. To address these gaps, this study proposes an incentive-based decentralized routing strategy to nudge the network performance closer to the system optimum in a traffic system with connected and autonomous vehicles (CAVs). The strategy consists of three stages. The first stage incorporates a local route switching dynamical system to approximate the system optimal route flow in a local area based on vehicles’ knowledge of local traffic information. This system is decentralized in the sense that it only updates the local route choices of vehicles in this area to circumvent the high computational burden associated with computing the flows on the entire network. The second stage optimizes the route for each CAV by considering individual heterogeneity in traveler preferences (e.g., the value of time) to maximize the utilities of all travelers in the local area. Constraints are also incorporated to ensure that these routes can achieve the approximated local system optimal flow of the first stage. The third stage leverages an expected envy-free incentive mechanism to ensure that travelers in the local area can accept the optimal routes determined in the second stage. We prove that the incentive mechanism is expected individual-rational and budget-balanced. The study analytically shows that the proposed incentive-based decentralized routing strategy can enhance network performance and user satisfaction in a connected and autonomous traffic environment
Base Camp Connect is a portable rapid-deploy kit that creates a local area network, interconnects radios and auto-manages backhaul networks to provide phone, Internet and radio interoperability,