Category Archives: Robotics

The debilitating disease of amyotrophic lateral sclerosis (ALS) leads to loss of mobility and an inability for patients to complete even basic tasks like lifting their arms, eating, or moving their hands. This brings great stress to patients and their caregivers. A team of Stony Brook University researchers is aiming to alleviate the many difficulties that accompany advancing ALS by using computer and artificial intelligence (AI) technologies, mechanical engineering, and consultation by medical experts to create a Caregiving Robot Assistant (CART) for ALS patients and their caregivers.

The project is supported by three-year, $1.5 million grant from the U.S. Army. It is led byI.V. Ramakrishnan, PhD, Professor of Computer Science and an Associate Dean in the College of Engineering and Applied Sciences at Stony Brook University. The multidisciplinary research includes faculty in Computer Science, Engineering, Nursing, the Renaissance School of Medicine (RSOM), and clinical and support staff from the Christopher Pendergast ALS Center of Excellence in the Neurosciences Institute at Stony Brook Medicine.

We are in the process now of developing CART into a usable prototype for ALS patients and their caregivers, says Ramakrishnan. The technical innovation of CART is in the development of an algorithmic approach to manipulation planning based on the screw geometry of motion along with an approach to what we call self-evaluation, where the robot evaluates its competence in performing a task and actually prompts a caregiver to provide additional demonstrations, he explains, noting that this work is led by Nilanjan Chakraborty, PhD, a Professor and roboticist in the Department of Mechanical Engineering.

The AI technology built within CART enables it to mimic how to do a task using the movements a caregiver provides manually as guidance. Crucially, CART will learn from only a few examples in an interactive manner by actively prompting the caregiver for demonstration examples as the robot needs, and thereby not overly burdening the caregiver. For example, a caregiver would provide how CART should move its robotic arms to pick up a spoon, and angle it exactly toward the patients mouth, or provide the steps to move a cup and empty it.

Additionally, because ALS patients needs change, and can change quickly, the program enables caregivers to easily train CART to perform tasks differently, or add new tasks as well. This adaptability aspect of CART is central to the project with actual patient use.

Patient Testing

Vibha Mullick, a Senior Web and Database Analyst in Computer Science and a team member on the project, will provide crucial consultation to the interdisciplinary group about CART in the areas of design, user-friendly aspect of CART, and functionality.

Her husband of 38 years, Anuraag Mullick, 64, has lived with ALS since 2016. He is treated at Stony Brook Medicines Chris Pendergast ALS Center of Excellence. Anuraag now has severe motor disability, limited range with his arms and hands, difficulty swallowing and speaking, and respiratory problems. Vibha is his primary caregiver. Together they will test CART as it is programmed and re-programmed and further developed into a prototype.

Coping with grief, fear, frustration and the uncertainties that come with advancing ALS is an ongoing challenge, says Vibha. We are hoping that by providing insight into just how effective CART can be for my husband as a patient and me as a caregiver helps to ensure this new technology bridges the gap between technological innovation and the lived experience of ALS caregiving. And we hope it will be great tool to improving the quality of life for Anuraag, and other ALS patients.

Anuraag had a long and successful career as a hotel manager and owner before his ALS diagnosis. He will experience and test CART with Vibha when it is further developed in the lab, and he may be able to use CART when at home.

Clare Whitney, PhD, and Maria Milazzo, PhD, in the School of Nursing will coordinate with Vibha to conduct the patient user aspect of the study. Simona Treidler, MD, of the Department of Neurology, along with Theresa Imperato, RN, of the ALS Center of Excellence, will recruit other ALS patients to try using CART as they assess patients disease stages and their needs.

Vibha hopes the team is able to push the technology to the point where integrating robots into physiotherapy is a routine program to assist Anuraag and other ALS patients with range of motion exercises.

While CART will be tested initially for ALS patients, it is ultimately being designed for any patient with acute or chronic locomotor disabilities.

The investigators believe that the ease with which CART can be trained, operated, and adapted to evolving patient needs will eventually usher in a new generation of assistive robots to provide reliable, round-the-clock physical assistance to people with severe locomotor disability and make caregiving much less burdensome.

Other research collaborators include C.R. Ramakrishnan in Computer Science, who leads the inferencing component; and Wei Zhu in Applied Mathematics and Statistics, the biostatistician for the project.

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On the Horizon: A Robot to Assist ALS Patients | RoboticsTomorrow - Robotics Tomorrow

Advancing obstetric and gynecologic surgery through robotic innovation| Image Credit: Summit Art Creations - Summit Art Creations - stock.adobe.com.

Robotic surgery can be used to advance techniques in obstetric and gynecologic surgery, according to a recent study published in Cureus.

Robotic surgery is defined by the use of advanced robot systems during surgery. These include robotic arms with miniature equipment and an advanced camera for improved precision and dexterity. Minimally invasive procedures can be performed with improved accuracy through these tools.

Gynecologic procedures that can benefit from robotic surgery include myomectomies, hysterectomies, and ovarian cystectomies. Obstetrical procedures that can benefit include cesarean sections and fetal interventions. Robotic surgery in obstetrics and gynecology can decrease trauma, blood loss, and hospital stays, as well as improve recovery times.

Investigators conducted a review to evaluate the evolution of robotic surgery in obstetrics and gynecology and inform providers and policy makers about the evolving landscape. Implementation of robot surgery in the field began with the da Vinci Surgical System, which allowed improved visualization, dexterity, and patient outcomes.

Changes in surgical management have been observed following the advancement of robotic surgery technology. Innovations ranging from Hippocrates' utilization of tin catheters to modern robotic systems have significantly impacted the transition to robotic-assisted surgery.

A major impact has been observed from robotic surgery on gynecology, with studies indicating increased safety and similar perioperative outcomes to traditional methods during robot-assisted gynecologic surgery. Compared to open surgery, post-surgical hospital stay lengths are significantly reduced by robotic surgery.

In hysterectomy, robotic surgery allows for smaller incisions, reduced blood loss, and faster recovery. The risks of complications are also reduced through robotic-assisted hysterectomy. Similarly, robotic-assisted myomectomy supports meticulous tissue dissection and suturing, enhancing surgical success rates and patient satisfaction.

During tubal renastomosis, robotic tools can be used for careful manipulation of delicate tubal structures. The improved precision and control granted by robotic surgery allow for a less invasive procedure, which reduces postoperative pain and recovery time.

The robotic platform also allows for improved dexterity and visualization among surgeons navigating complex pelvic anatomy during sacrocolpopexy. Finally, while robotic assisted laparoscopic sleeve gastrectomy is not directly linked to obstetrics and gynecology, it is often utilized concurrently with gynecologic procedures and is more effective when using robotic tools.

Visualization is a significant improvement offered by robotic surgery. Surgeons can confidently navigate complex pathways with the assistance of robotic tools, leading to greater precision and accuracy. Alongside improving results, this reduces the risk of complications. The use of steady robotic arms also eliminates the impact of surgeon tremors.

Currently, there are still multiple limits in robotic surgery for obstetric and gynecologic care. The cost of robotic surgery is significantly higher than traditional methods, creating a barrier for many patients. This cost is only heightened by the need for maintenance and calibration of robotic equipment.

Surgeons also must receive extensive training to effectively use the robotic tools, which can increase initial operative time and costs. Additionally, restricted availability has caused patient disparities in access to advanced surgical care.

Another significant advancement in robotic surgery is the implementation of automation in precise surgical tools for improved efficacy and precision. This innovation allows surgeons to focus on critical aspects of the procedure, while the systems facilitate tissue identification, precise instrument placement, and meticulous surgical technique.

Areas of improvement that have been given attention in recent innovation include adjustable stiffness, detectability, and bendability. These areas are given focus to reduce challenges associated with traditional methods, leading to improved patient outcomes and quality of care.

Potential future advancements in robotic surgery include miniaturization and micro-robotics, artificial intelligence, and telepresence. As these advancements bring ethical and societal considerations, the American Medical Association Code of Medical Ethics has provided guidelines to ensure safe, effective, timely, patient-centered, and equitable care.

Reference

Yadav P, Chaudhari K, Dave A, Sindhu A. Exploring the evolution of robotic surgery in obstetrics and gynecology: Past, present, and future perspectives. Cureus. 2024;16(3):e57155. doi:10.7759/cureus.57155

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Advancing obstetric and gynecologic surgery through robotic innovation - Contemporary Obgyn

The remarkable achievement of the PHS Robotics Team places them within the top 1% of VEX Robotics teams worldwide, showcasing their exceptional talent and commitment to excellence.

Plymouth Robotics Team 586E, comprised of talented students Freddy Kallenberg, Cora Hanes, Jonah Rich, and Chance Miller, alongside dedicated Coach Michael Wraight and Assistant Coach Daniel Kallenberg, returned triumphantly from the VEX Robotics World Championship held from April 25th to April 27th. The prestigious competition, spanning three intense days, hosted an impressive array of 820 teams from across the globe. Their division had other teams from across the US, along with teams from China, New Zealand, Turkey, Canada, Kazakhstan and the Czech Republic.

Team 586E soared to an outstanding 6th place finish within their division.

Throughout the competition, Team 586E not only demonstrated technical proficiency but also fostered invaluable connections with fellow robotics enthusiasts from all around the world, enriching their global perspective and fostering a spirit of camaraderie among participants.

Reflecting on the teams accomplishments, Coach Michael Wraight expressed immense pride in their achievements, emphasizing his confidence in their capacity to achieve even greater feats in the years to come. Their success serves as a beacon of inspiration for aspiring roboticists and underscores Plymouths commitment to fostering innovation and excellence in STEM education.

As Plymouth Robotics Team 586E returns home, they carry with them not only the accolades of their remarkable performance but also the invaluable experiences and friendships forged on the world stage of robotics excellence.

Article & photo provided. (Left to Right) Cora Hanes, Chance Miller, Jonah Rich, Freddy Kallenberg

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Plymouth Robotics Team 586E takes 6th place VEX Robotics World Championship in Dallas, TX - WTCA

Scientists have an impressive new trick for robots: using the invisible force of air to manipulate objects. A recent study from Aalto University showcases a unique method of controlling objects from a distance. This technique has the potential to revolutionize how we think about robotics, manufacturing, and even everyday tasks.

The fundamental concept behind this innovation is quite simple. Air, although invisible, is a physical substance with the ability to exert force. This force can cause objects within its flow to move. The key challenge was understanding and controlling those movements.

Researchers achieved this by carefully studying the interaction between air currents and objects of various shapes and sizes. With this knowledge, they were able to develop techniques to direct and manipulate airflow in a way that allows for precise control over the movement of objects.

Airflow or wind is everywhere in our living environment, moving around objects like pollen, pathogens, droplets, seeds and leaves. Wind has also been actively used in industry and in our everyday lives for example, in leaf blowers to clean leaves. But so far, we cant control the direction the leaves move we can only blow them together into a pile, said Professor Quan Zhou from Aalto University, who led the study.

To master the behavior of objects within an airflow, the scientists conducted a rigorous experimental phase. They exposed numerous objects to controlled air currents, meticulously recording their movements. This extensive dataset allowed them to identify relationships between the shape of an object and how it reacts to different airflow conditions.

Surprisingly, even within seemingly random airflow, the researchers discovered consistent patterns. These patterns became the building blocks for a control system capable of precisely directing airflow, enabling them to move objects in specific ways even against the flow of the wind itself.

The unique algorithm at the center of this technology serves as the brain for the entire system. Its primary role is to calculate and execute the precise movements of the air jet nozzle to achieve the desired object manipulation. Heres how it achieves this:

The algorithm requires several pieces of information to work:

The algorithm controls two motors that govern the air jet nozzle:

The algorithm strategically aims the air jet to manipulate the object. The nozzles positioning, along with the air pressure, dictates how the object will react within the airflow.

Crucially, this process isnt static. The algorithm continuously receives feedback on the objects position. It compares this to the intended path and makes micro-adjustments to the nozzles angle and position. This dynamic control enables the object to be guided along even complex trajectories.

In summary, the algorithm acts as a tireless conductor. It analyzes object data, sets the initial nozzle position, and then orchestrates a series of continuous airflow changes to nudge the object along the desired path.

One of the most surprising findings involved the wide range of shapes the system could manipulate effectively. Our intuition might suggest that a formless force like airflow would have limited control over objects, especially complex ones. However, the researchers discovered a remarkable level of versatility in their technique.

Regardless of the object placed under the air jet, whether it was a precisely defined geometric shape or a completely crumpled piece of paper, the system could successfully guide its movement. This adaptability suggests a deeper understanding of airflow dynamics and object interaction than previously anticipated.

It opens doors for potential applications in scenarios where manipulating objects with traditional robotic grippers might be impractical due to their delicate or irregular shapes.

While the technology is still being perfected, its potential applications are vast and promising. Professor Zhou imagines robots equipped with this innovative system, replacing traditional physical grippers with what he describes as ethereal fingers.

These are essentially directed currents of air that can manipulate objects from a distance. This would be particularly useful for handling delicate items that cannot withstand direct contact, such as sensitive electronic components, which could be damaged by conventional mechanical touch.

In everyday scenarios, this technology could transform how machines operate in common environments. For example, robots could utilize this air manipulation technique to gather scattered debris, such as leaves or trash, or to sort objects based on size or type without ever physically touching them.

The range of potential applications is extensive, especially in situations where traditional physical interaction could be problematic or potentially damaging. This could include environments that are sensitive, hazardous, or where contamination needs to be minimized, showcasing the technologys adaptability and utility in various fields and circumstances.

With additional research, the precision and efficiency of this contactless manipulation could skyrocket, opening up even more exciting applications for this natural, invisible force.

The study is published in the journal Advanced Intelligent Systems.

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Robots can use air to move objects - Earth.com

Scientists at the University of Washington have developed flying robots that change shape in mid-air, all without batteries, as originally published in the research journal Science Robotics. These miniature Transformers snap into a folded position during flight to stabilize descent. They weigh just 400 milligrams and feature an on-board battery-free actuator complete with a solar power-harvesting circuit.

Heres how they work. These robots actually mimic the flight of different leaf types in mid-air once theyre dropped from a drone at an approximate height of 130 feet. The origami-inspired design allows them to transform quickly from an unfolded to a folded state, a process that takes just 25 milliseconds. This transformation allows for different descent trajectories, with the unfolded position floating around on the breeze and the folded one falling more directly. Small robots are nothing new, but this is the first solar-powered microflier that allows for control over the descent, thanks to an onboard pressure sensor to estimate altitude, an onboard timer and a simple Bluetooth receiver.

As for the why of it all, the lil baby Starscreams can be equipped with a wide variety of sensors to make surveys as they soar around the sky, so in theory they could gauge temperature, humidity and air quality conditions, among other types of data. Produced at scale, this would be a highly-cost effective way to keep tabs on atmospheric conditions.

The current design only allows them to transition in one direction, from the tumbling state to the falling state, but researchers can control multiple microfliers at the same time, making them disperse upon launch to cover a wider area. Theyre working on perfecting the reverse transition to allow the robots to transform back from the falling position to the folded position, which should better allow the microfliers to make precise landings even in turbulent wind.

Its good to see new robots that dont resemble a Dr. Who death machine or a headless dog with a thirst for blood. Lets hear it for innovation! In the meantime, the University of Washington researchers will have plenty of funds to further develop this microflier concept, thanks to grants from the National Science Foundation, NASA and the Google fellowship program, among others.

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These flying origami-inspired robots change shape in mid-air - Engadget

Fort Collins, Colorado, Sept. 28, 2023 (GLOBE NEWSWIRE) -- DataHorizzon Research Published a report titled, "Industrial Robotics Market Size, Growth, Share, Statistics Report, By Component (Robotic Arm, Robot Accessories, Additional Robotic Hardware, System Engineering, and Software and Programming), By Payload, By Application, By End-use, By Region Forecasts, 2023-2032."

According to DataHorizzon Research, Theindustrial robotics market size was valued at USD 29.1Billion in 2022 and is anticipated to reach USD 94.8 Billion by 2032 with a CAGR of 12.6%. Industry 4.0 is influencing the growth of the industrial robotics market. Many industries are witnessing the introduction of new technologies that create entirely new ways of serving existing needs. The key trend is the development of technology-based platforms, which combine demand and supply. These technology platforms are easy to use with the help of smartphones and convenient for people, assets, and data. As the trend of Industry 4.0 continues to make deeper inroads in the manufacturing sector, industrial robotics is gaining popularity globally.

In the automotive industry, assembly lines frequently encounter problems such as injury hazards, a slow production duration, and concerns regarding final product quality. Robots help in overcoming these glitches as they are cost-effective and quick at completing the required task. Robots are very efficient in their jobs, and any job that is deemed hazardous or manually difficult can be accomplished by robots. Therefore, robots are increasingly used to assemble parts, welding, painting, material removal, and part transfer in the automotive sector. Furthermore, collaborative robots operate alongside humans in the same workspace and can do several activities in the automotive sector. Therefore, these factors are fueling the market expansion.

With the improvement of industrial robotic technology and the integration of AI and 3D computer vision, these robots are utilized for various jobs in a manufacturing warehouse, such as completely automated depalletization and mixed product handling.

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Segmentation Overview:

The global industrial robotics market has been segmented as component, deployment, application, and region. The robotic accessories segment held the largest market share in 2022. Accessories for industrial robots include end-effectors, controllers, attachments, and sensors.The chemical rubber and plastics segment is expected to register a positive CAGR during the forecast period. The demand for robots in the chemical industry is increasing due to their ability to handle hazardous and toxic chemicals, with their precise and accurate operation in dispensing, mixing, and handling a variety of chemical compounds.

North America is also expected to hold a significant industrial robotics market share. With the increasing prominence of automation in the U.S. and Canada, the need for industrial robots and collaborative bots is rising, boosting market growth. The Middle East and Africa region is expected to grow at a high CAGR during the forecast period. With the advent of IIoT and the integration of Artificial Intelligence, robot use cases in the Oil and Gas industries have increased, boosting the market demand in this region.

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Industrial Robotics Market Report Segmentation:

Industrial Robotics Market, By Component (2023-2032)

Industrial Robotics Market, By Payload (2023-2032)

Industrial Robotics Market, By Application (2023-2032)

Industrial Robotics Market, By End-use (2023-2032)

Industrial Robotics Market, By Region (2023-2032)

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Industrial Robotics Market Size To Reach USD 94.8 Billion By 2032 ... - GlobeNewswire

CHICAGO, Sept. 29, 2023 /PRNewswire/ -- In a recent collaboration,ForwardX Robotics, a renowned global leader in vision-based Autonomous Mobile Robots (AMRs), joined forces with DHL, a highly regarded and internationally recognized supply chain service enterprise. DHL implemented ForwardX's assisted picking solution in one of its flagship warehouses, dedicated to providing vital daily replenishment for approximately 600 locations for a chain brand coffee store within a single city.

The number of stores supported by the warehouse has experienced an exponential growth, doubling from 300 to 600 within just one year, with peak shipment volume reaching an impressive 400 cubic meters. Anticipating a high-speed growth trajectory this year, the warehouse is projected to support an expansion to approximately 1000 stores. However, these rapid positive developments have also presented some pressing challenges, including an increased workload for our picking personnel, difficulties in recruiting new workers, and the burden of high training costs.

To address these challenges, DHL implemented Forwardx's assisted picking solution. Within just two months of using ForwardX's Flex 300-S AMRs, the solution has had a transformative effect on the warehouse's operations. The collaborative project has yielded a remarkable increase of over 100% in UPH (units picked per hour) and substantial savings of over 30% in operational costs. These results are a testimony that showcase the solution's accuracy and reliability, reducing costly mistakes.

It is important to acknowledge that manual lift carts and forklifts are indispensable equipment for warehouses dealing with case picking of small and medium-sized items. Ensuring safe collaboration between humans and machines is of utmost significance in such settings. However, it is crucial to note that not all AMRs seamlessly work alongside forklifts. Laser-based AMRs often position their sensors in a way that may create blind spots near the ground, as these sensors rely on horizontal beams and have limited detection angles. Placing laser sensors above a forklift's fork can lead to a higher risk of collisions and safety concerns, especially when dealing with heavier payloads.

ForwardX AMRs stand out by leveraging advanced sensor fusion technology and computer vision cameras. This combination allows for a comprehensive view of the environment, enhancing perception capabilities and reducing blind spots. This integration ensures safe navigation, minimizing the risk of collisions. When combined with ForwardX's assisted case picking solution and utilizing a batch picking method, the efficiency and safety of case picking operations are greatly enhanced.

The tangible outcomes of the solution have manifested in a profound enhancement of the overall productivity and efficiency of the picking process. This has been complemented by a noteworthy reduction in picking errors and substantial cost savings. By leveraging our solution, the DHL warehouse has empowered itself with the steadfast ability to expand in capacity and elasticity, a formidable force prepared to conquer the challenges of a rapidly expanding business.

About DHL:

DHL Supply Chain, part of the DHL Group, is the world's leading logistics provider. Combining management and value-added services with our customized, integrated logistics solutions drives resilience, efficiency, improves quality and creates competitive advantage.

About ForwardX RoboticsForwardX Robotics is a global leader in vision-based AMR technology, delivering innovative end-to-end material handling solutions for warehousing and manufacturing facilities. With its advanced fleet management software and the widest range of vision-first Autonomous Mobile Robots (AMRs), ForwardX Robotics helps businesses achieve higher performance and value within their supply chain operations. The company is comprised of over 250 members hailing from top universities and leading enterprises around the world. As shown by the 350+ patents and its award-winning research work, such as Frost & Sullivan's Best Practices Award and Robotics Business Review's RBR50 Innovations Award, ForwardX Robotics continues to push the boundaries of innovation.

ForwardX has deployed over 3,000 AMRs in over 220 facilities across 4 continents. With offices in the US, Japan, Korea, and China, along with partnerships around the globe, ForwardX is expanding and applying its proven solutions to empower the workforce of tomorrow.

For more information, visit: https://www.forwardx.com/

SOURCE ForwardX Robotics

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ForwardX Robotics and DHL Collaborate To support Expansion - PR Newswire

Dexterity AI today announced a collaboration with FedEx Corp. (NYSE: FDX), to leverage AI-powered robotic technology to load boxes into trucks and trailers.

Truck loadinghas long been considered one of the most challenging tasks in parcel hubs. Manual loading is taxing and previous technology approaches have not been able to handle the complex decision making required to stack the wide range of shipments encountered in FedEx network, which vary in size, shape, weight, and packaging material.

Dexterity AI focuses on the complexity of truck loading by giving mobile robots a suite of intelligence ranging from the ability to see, touch, think, and move quickly to pack trailers with stable, dense walls of randomized boxes.

Our culture of innovation is driven by a desire to help our team members and customers succeed, said Rebecca Yeung, corporate vice president of Operations Science and Advanced Technologies for FedEx. Based on feedback from our operations team, we have been looking for a solution that helps alleviate the challenges of truck loading. Collaborating with Dexterity AI to combine the latest in AI and robotics supports our operations team while meeting growing customer demand.

DexterityAIs proprietary mobile robot design, DexR, navigates autonomously to the back of trailers and connects to a powered conveyor system that feeds the robot boxes directly from the sortation system. The DexRs unique two arm design enables the robot to pick and pack boxes simultaneously, improving throughput.

Dexteritys AI platform uses a broad set of intelligence, so it can be used to handle the complexities of truck loading required by operations.

Some unique characteristics of the platform include:

Generative Wall Planning:With every new box presented to the DexR, Dexteritys AI software takes 500 milliseconds or less to assess billions of wall build possibilities to pack trailers with tight, stable walls.

A Sense of Touch:Dexterity AI-powered force control gives robots a unique sense of touch so they know how to gently nudge boxes together in creating tightly packed walls.

Machine Learning-Based Pack Improvement:Machine learning helps ensure that with every box picked, the Dexterity AI truck loading software becomes even more efficient in handling a broader range of packing challenges.

Integrated Motion Planning:By integrating its own trajectory and motion planning, the Dexterity AI platform helps the DexRs two arms move quickly inside trailers without colliding with each other or the truck walls.

Testing of the truck load technology is ongoing by FedEx with a goal to refine the technology and deploy commercially in the future.

FedEx shares our belief that innovation should solve the most difficult tasks in operations, said Samir Menon, founder and CEO of Dexterity AI. Our collaboration is driven by a vision of AI-powered robotics that is adaptable to our customers most pressing needs.

The official unveiling of this innovative AI-powered robotics truck loading technology took place at the companies joint event Unlock the Dock in San Francisco on September 26, 2023.

About Dexterity

Dexterity, Inc. is a Redwood City, California-based robotics company specializing in creating intelligent robots with human-like dexterity. By automating repetitive tasks, Dexterity's full-stack robotics solutions unlock the maximum value of the workforce, allowing employees to focus on higher-level, cognitive work. With applications in logistics, warehousing, and supply chain operations, Dexterity's robots excel in complex manipulations in unpredictable environments. To learn more, visitwww.dexterity.ai.

About FedEx

FedEx Corp. (NYSE: FDX) provides customers and businesses worldwide with a broad portfolio of transportation, e-commerce and business services. With annual revenue of nearly $90 billion, the company offers integrated business solutions through operating companies competing collectively, operating collaboratively and innovating digitally as one FedEx. Consistently ranked among the world's most admired and trusted employers, FedEx inspires its more than 500,000 employees to remain focused on safety, the highest ethical and professional standards and the needs of their customers and communities. FedEx is committed to connecting people and possibilities around the world responsibly and resourcefully, with a goal to achieve carbon-neutral operations by 2040. To learn more, please visit fedex.com/about.

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Dexterity AI and FedEx Unveil First-of-its-Kind Robotics Trailer ... - Robotics Tomorrow

Once again, Newton High Schools Team Aperture participated in the super bowl of robotics, held in Houston, Texas, in April.

Guided, in part, by NJEA member and Assistant Coach Lisa Holder, Team Aperture qualified by winning the FIRST Mid-Atlantic District Competition in early April at Lehigh University.

FIRST is an acronym which represents For Inspiration and Recognition in Science and Technology. The organization was founded in 1989 to inspire young people to get involved in science and technology.

The FIRST Robotics Competition World Championship brings together hundreds of teams and tens of thousands of participants, coaches, mentors and spectators.

According to the FIRST website, Under strict rules, limited time and resources, teams of students are challenged to raise funds, design a team "brand," hone teamwork skills, and build and program industrial-size robots to play a difficult field game against like-minded competitors. Its as close to real-world engineering as a student can get. Volunteer professional mentors lend their time and talents to guide each team. Each season ends with an exciting FIRST Championship.

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Newton High Schools Team Aperture attends super bowl of robotics - New Jersey Education Association

The world of wearable robotics is evolving rapidly, and the latest issue of the Exoskeleton Report digital magazine is a testament to this dynamic industry. This months edition, Volume 1, Issue No. 3, is brimming with exciting news, developments, and insights and is attached to a brand new viewer.

A Glimpse into the Exoskeleton World

This issue is packed with a total of nine news stories, each offering a unique perspective on the advancements in the exoskeleton industry. From ErgoSants new US production plant to Wandercrafts pioneering Atalante X exoskeletons making their way to German neurorehabilitation clinics, the news section provides a comprehensive overview of the latest happenings.

Furthermore, readers can delve into shorter summaries of pivotal events in the headline news section, which covers topics like Fourier Intelligences humanoid robot preorders and Marsi Bionics 10th-anniversary celebrations.

Looking Ahead

The On The Horizon section is a must-read for those keen on staying updated with upcoming events. It highlights forthcoming exoskeleton-related developments, shows, conferences, and events. This section also emphasizes the importance of real-world application and research in the field, showcasing studies like the one led by Maury Nussbaum, which explores the potential benefits of exoskeletons for construction workers.

In Conclusion

The September 29, 2023, issue of the Exoskeleton Report is a treasure trove of information for enthusiasts, professionals, and anyone curious about the future of wearable robotics, exoskeletons, and exosuits. As the industry continues to grow and innovate, staying informed is crucial, and the Exoskeleton Report remains a trusted source for the latest news and insights.

If you are having trouble with the new PDF viewer, you can download the three issues directly below:

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Exoskeleton Report eMagazine: The Latest in Wearable Robotics ... - Exoskeleton Report