Рубрика: Robotics

Necrobotics: Engineers find to manipulate the legs of dead spiders to grip robots

Mechanical engineers from Rice University have actually turned spider cadavers into what they call “necrobots,” able to function as mechanical grippers. The team inserted a needle into the spider’s prosoma chamber and created a seal around the tip of the needle with a glob of superglue. This advanced a novel area of research, of using dead animals as robots, known as necrobotics.

The necrobotic gripper is capable of grasping objects with irregular geometries and up to 130% of its own mass. Necrobotics can be further extended to incorporate biotic materials derived from other creatures with similar hydraulic mechanisms for locomotion and articulation. Besides being the rather creepy subject of a scientific study, the necrobotic grippers could have some practical applications. The concept of necrobotics proposed in this work takes advantage of unique designs created by nature that can be complicated or even impossible to replicate artificially.

Engineers find to manipulate the legs of dead spiders to spider grippers:

Researchers have explored a range of designs based on spiders, from rigid and hard hexapod robots inspired by the gait of spiders to soft grippers inspired by the actuation mechanism and architecture of spider joints that can blend into natural environments while picking up objects, like other insects, that outweigh them. The researchers noted smaller spiders can carry heavier loads in comparison to their size. Conversely, the larger the spider, the smaller the load it can carry in comparison to its own body weight.

Spiders are basically hydraulic grippers to move their limbs, as opposed to other mammals that synchronize opposing muscles. The dead spider isn’t controlling these valves that worked out in the study because it allowed us to control all the legs at the same time. Also, the spiders themselves are biodegradable. So researchers are not introducing a big waste stream, which can be a problem with more traditional components. But one drawback to the dead spider gripper is that it starts to experience some wear and tear after two days or after 1,000 open-and-close cycles.

Setting up the spider gripper required a single and fairly simple fabrication step. The gripper spiders were able to lift more than their own body weight, including another spider and small objects like parts on a circuit board. Its mass decrease was 17 times less than the uncoated spider over 10 days, which meant it was retaining more water and its hydraulic system might function longer.

Researchers can take advantage of the inherent properties of the material, such as biodegradability and camouflaging capabilities, to potentially deploy them in nature to grip small and delicate samples in an unobtrusive and eco-friendly manner. The researchers hope to try the necrobotics method out with smaller spiders. They also plan to work out how to trigger the legs individually and experimented with coating the wolf spiders in beeswax.

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Rather than just following scientists’ plans, it is thought that they are acting on their convictions and desires.

According to recent American Psychological Association research, humans may mistakenly believe that robots are capable of “thinking” when they interact with them and show human-like emotions. In other words, rather than just following their plans, it is thought that they are acting on their convictions and desires.

Human-robot interaction and AI

The study’s lead investigator and researcher, Agnieszka Wykowska, Ph.D., is from the Italian Institute of Technology.

The importance of comprehending how interacting with a robot that exhibits human-like actions might increase the chance of attributing international agency to the robot is stressed by Wykowska in her article.

The researchers used 119 patients in three studies to test how they would react to iCub, a humanoid robot, after interacting with it and watching films with it. A questionnaire was filled out by participants both before and after they interacted with the robot. The participants were asked to select whether the robot’s motivation in each scenario was mechanical or purposeful after seeing images of the robot in various contexts.

In the first two tests, the researchers used a remote control to instruct iCub to behave erratically. It greeted everyone, gave its name, and inquired about the names of the participants. The robot’s eyes were equipped with cameras that could detect the faces of the participants and keep eye contact. The robot, which was configured to respond with sounds and facial emotions of pain, happiness, or astonishment, was then requested to view three brief documentaries with the users.

In the third trial, iCub was designed to act more robotically while watching films with the subjects. It could not maintain eye contact because the cameras were turned off, and it only spoke recorded lines regarding the calibration procedure it was going through. The robot didn’t react to the videos with any emotion; instead, it simply beeped and made repeated movements with its head, torso, and neck.

The Significance of Human-Life Behavior

The study showed that viewers of videos featuring the human-like robot were more likely to attribute the robot’s movements to intentional, rather than programmed, behavior. However, individuals who only connected with the robotic replica were more inclined to see the acts as predetermined. These findings imply that the human-like robot must exhibit human-like behavior for humans to regard it as an intentional agent rather than just exposure to a human-like robot.

According to Wykowska, the results suggest that if artificial intelligence exhibits human-like behavior, people may be more likely to assume that it is capable of independent reasoning.

In certain situations, such as with socially assistive robots, social bonding with robots may be advantageous. For instance, social connection with robots in senior care may result in a higher level of compliance with instructions to take medication, according to Wykowska. The next stage of this research will aim to identify the situations in which social connection and intentionality are advantageous to human welfare.

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In this article, we are going to discuss the Top 10 Most Expensive Robots in the World in 2022

Robots are known as the future of technology. Robotics technology has just landed in the workplace and there is a lot of work to do. They make our lives easier and can work in situations that would be extremely dangerous or just too difficult for a human being to operate in. Robots were portrayed as cold automatons that were either programmed to destroy us or take our jobs. Now, with the rise of AI and machine learning, this is slowly changing. In this article, we are going to discuss the Top 10 most expensive robots in the world in 2022.

PR2 Robot System: The PR2 is one of the most advanced research robots ever built. Its powerful hardware and software systems let it do things like clean up tables, fold towels, and fetch you drinks from the fridge. This will look at some of the features of the robot and how it has become so popular amongst companies such as Google and M.I.T

I-Cub: I-Cub is a research-grade humanoid robot designed to help develop and test embodied AI algorithms. It is the ideal companion to your robotics laboratory. The I-Cub Project blends results from various IIT Research Lines by applying the principles of systems engineering and by seeking worldwide collaboration opportunities.

Xenex: Xenex robots were invented to save patients and hospital staff from the ravages of MRSA. It is used to sterilize rooms and is effective in killing up to 99.9% of all pathogens and bacteria. It is currently being used in hospitals worldwide and is considered a game changer in the healthcare industry.

HRP-4: HRP-4 is one of the world’s most advanced humanoids, the culmination of a decade of R&D. It’s designed to collaborate with humans and can perform remarkably natural human-like movements.

Robo Thespian Humanoid Robot: RoboThespian is a robotic actor, meaning he’s an actor who is a robot, as opposed to a bad actor who is human. It speaks more than 30 languages, and you can find it on stages worldwide. Robots help us visualize the world in our heads. The demand for robots is only growing and the technology behind them is only improving.

Hubo II: Hubo II is a full-size humanoid that can walk, run, dance, and grasp objects. It uses a straight-leg walking gait that’s an improvement over most bipedal robots, which keep their knees bent to balance.

Kuratas: Kuratas is a rideable and user-operated mecha built by the Japanese company Suidobashi Heavy Industry. It goes over its specifications, design, strengths, and weaknesses. Although the world has witnessed a lot of advancement in this field, engineers have been able to develop a robot that looks like a human being.

Atlas: Atlas, is the most advanced humanoid robot ever created. It is powered by an i7 processor, which is the same processor used in MacBooks and iMacs.a robot was a regular human, we would have robots running countries, businesses, and homes.

ASIMO: ASIMO stands for Advanced Step in Innovative Mobility and is a humanoid robot created by Honda in 2000. It can run, dance, hop, and kick a soccer ball. It travels the world as an ambassador to robot kind, making humans excited about robotics.

Valkyrie: Valkyrie robot is highly advanced in terms of its capabilities and is seen as a real competitor in the race. It is an advanced humanoid robot that will be used in future space missions.

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In medicine, a prosthesis, or a prosthetic implant, is an artificial device that replaces a missing body part, which may be lost through trauma, disease, or a condition present at birth. A pioneering project to develop advanced pressure sensors for use in robotic systems could transform prosthetics and robotic limbs. The innovative research project aspires to develop sensors that provide enhanced capabilities to robots, helping improve their motor skills and dexterity, through the use of highly accurate pressure sensors that provide haptic feedback and distributed touch.

It is led by the University of the West of Scotland (UWS), Integrated Graphene Ltd, and supported by the Scottish Research Partnership in Engineering (SRPe) and the National Manufacturing Institute for Scotland (NMIS) Industry Doctorate Programme in Advanced Manufacturing. This is not for the first time when the team of highly talented researchers have decided to bring the much needed transformative change in prosthetics and robotic limbs.

The human brain relies on a constant stream of tactile information to carry out basic tasks, like holding a cup of coffee. Yet some of the most advanced motorized limbs — including those controlled solely by a person’s thoughts — don’t provide this sort of feedback. As a result, even state-of-the-art prosthetics can often frustrate their users.

Fisher is one of more than 80 scientists, staff and trainees at the university’s Rehab Neural Engineering Labs who is working to add the sensation of touch to prosthetics. The goal is to equip artificial hands and feet with sensors that are linked to a person’s own nervous system.

Thanks to the work of scientists at Johns Hopkins University, a partially paralyzed man was able to feed himself using just his mind and a pair of robotic arms. The 49-year-old man suffered from a spinal injury nearly thirty years ago, leaving him with limited upper body mobility and an inability to use any of his fingers. Now, with the help of an advanced brain-machine interface, the man can command robotic prosthetic arms to cut and feed him food simply by making subtle movements with his wrists and hands in response to audio prompts such as “select cut location” or “moving food to fork”.

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A transformative impact of robotics in the healthcare industry is improving efficiency

Robotics in healthcare improves patient care through precise surgical procedures, assistive rehabilitation devices, automated diagnostics, and streamlined administrative tasks. Robots enhance outcomes, efficiency, and patient experience in the healthcare industry.

The healthcare industry has been rapidly adopting robotics to enhance patient care, improve surgical procedures, and streamline administrative tasks. Robotics technology offers numerous benefits, including increased precision, reduced human error, and improved efficiency. Some popular Robots in healthcare include da Vinci, Xenex Gern- Zapping Robot, PARO, TUG, CyberKnife, etc. This article explores the transformative impact of robotics in healthcare, discussing its applications in surgery, rehabilitation, diagnostics, and administrative tasks, while highlighting the potential challenges and ethical considerations.

Robots are already part of the healthcare industry and paved the path of rising the present level of care and medical aid. An integral part of the healthcare sector for the past ten years, it developed from medication to virtual support to remote diagnosis. In the past, it was considered that robots could not replace humans, regardless of how exact they were. But now that artificial Intelligence and machine learning have been included, these precision robots can carry out a range of activities in the healthcare sector.

In the healthcare industry, several popular robots are commonly used. Here are some examples:

Da Vinci: A well-known robotic surgical system used for minimally invasive procedures. It consists of robotic arms controlled by a surgeon who operates from a console.

Paro: Paro is a therapeutic robot designed to resemble a baby seal. It is used in healthcare settings, particularly with the elderly and those with dementia, to provide comfort and companionship.

TUG: TUG is an autonomous mobile robot designed to transport items in hospitals. It can deliver supplies, medications, and lab specimens, reducing the need for human labor in these tasks.

CyberKnife: A robotic radiosurgery system used for non-invasive treatment of tumors and lesions. It delivers high-dose radiation with sub-millimeter precision, allowing for targeted treatment while minimizing damage to surrounding healthy tissues

Robotic-assisted surgery has revolutionized the field of medicine. Surgeons can now perform complex procedures with greater precision and control using robotic systems like the da Vinci Surgical System. These robots provide enhanced visualization, dexterity, and range of motion, allowing for minimally invasive surgeries, reduced scarring, and faster recovery times. Robotic-assisted surgery has proven particularly effective in urological, gynecological, and cardiovascular procedures, with improved patient outcomes and reduced complications.

Robotics plays a vital role in the rehabilitation of patients with physical disabilities. Advanced exoskeletons and prosthetic limbs enable individuals with mobility impairments to regain their independence and improve their quality of life. Robotic devices assist in walking, grasping objects, and performing daily activities. Additionally, robot-assisted therapy helps patients recover from strokes, spinal cord injuries, and other neurological conditions. These robots provide personalized rehabilitation programs, precise movement analysis, and real-time feedback to optimize recovery outcomes.

The integration of robotics in diagnostic processes has led to improved accuracy, speed, and efficiency. Robots can perform repetitive and precise tasks, such as sample handling, laboratory analysis, and medical imaging. Automated systems assist in conducting tests, interpreting results, and generating reports, enabling faster diagnosis and treatment decisions. Robotic technologies like telemedicine and remote monitoring further expand access to healthcare services, especially in underserved areas. These innovations allow healthcare professionals to remotely assess patients, monitor vital signs, and provide timely interventions, thus reducing the burden on healthcare systems and improving patient outcomes.

Robots are transforming administrative tasks in healthcare, streamlining operations and enhancing efficiency. Intelligent software systems automate appointment scheduling, patient registration, and billing processes, reducing administrative burdens for healthcare providers. Robotic process automation (RPA) optimizes data entry, medical coding, and claims processing, minimizing errors and improving accuracy. Chatbots and virtual assistants offer 24/7 patient support, answering common queries and providing basic medical advice. These applications improve patient experience, increase access to information, and free up healthcare professionals to focus on critical tasks.

Challenges

While robotics brings significant benefits, it also poses challenges and ethical considerations. Safety and cybersecurity are vital concerns, as robots interact closely with patients and handle sensitive data. Ensuring the privacy and security of patient information must be prioritized. Additionally, there are concerns about the impact on employment as automation replaces certain job roles. Ethical considerations include the potential for bias in algorithms, patient autonomy in decision-making, and the need for clear regulations and guidelines to govern the use of robotics in healthcare.

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Researchers have recently developed new collaborative mobile robots, dubbed Omnid Mocobots.

Researchers at Northwestern University’s Center for Robotics and Biosystems have recently developed new collaborative mobile robots, dubbed Omnid Mocobots. These are collaborative mobile robots that are designed to cooperate with each other and with humans to pick up, handle, and transport delicate and flexible payloads. Three Omnid mocobots work collaboratively with a human on a pipe meeting activity. The 16kg pipes really feel weightless to the human and might be simply and intuitively manipulated with the help of the Omnids.

The new collaborative mobile robots, dubbed Omnid Mocobots:

The robots may be extremely useful to the manufacturing and transportation industry. In fact, the robots were inspired by the current workload in the manufacturing, warehouse, and construction industry that involved manipulating large, flexible objects. These robots, launched in a paper pre-published on arXiv, are designed to cooperate with one another and with people to soundly choose up, deal with, and transport delicate and versatile payloads.

The new robotic system has a mobile base and a robotic arm. It has three important features that set it apart from other robots. The first is the robot arms with built-in mechanical compliance. Second, the robot arms have precisely-controlled forces at their grippers. And third, the control laws governing the mobile base and manipulator allow teams of Omnids to render a huge object weightless to the human.

The Center for Robotics and Biosystems has a long history of building robots that collaborate physically with humans. These new Omnid Mocobots may soon be used to complete a lot of collaborative manipulation tasks that involve a human. The researchers would now also like to test the robot’s ability to autonomously transport and assemble different objects, including fragile, articulated, and flexible payloads. The Omnids additionally don’t have to be reprogrammed for duties with several types of payloads.

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Revolutionizing business efficiency by embracing robotics and automation for the future

In the ever-evolving landscape of technology, robotics, and automation have emerged as transformative forces, revolutionizing the way businesses operate. With their ability to perform repetitive tasks with precision and efficiency, these advanced systems are propelling industries toward a future of streamlined processes and increased productivity. The benefits they offer, such as enhanced accuracy, improved quality control, and cost optimization, are driving businesses to integrate these technologies into their operations.

From manufacturing and logistics to healthcare and agriculture, robotics and automation are reshaping industry sectors, optimizing resource allocation, and empowering businesses to stay competitive in a rapidly changing world. As we embrace the potential of robotics and automation, we unlock a future where efficiency, innovation, and strategic growth converge. Join us in exploring this exciting frontier of business automation at https://contgpt.com.

The Benefits of Robotics and Automation

Increased Efficiency and Productivity

Robotic systems and automated processes offer businesses the advantage of enhanced efficiency and increased productivity. By automating manual and repetitive tasks, companies can free up valuable human resources to focus on more strategic and creative endeavors. This not only optimizes overall productivity but also leads to significant cost savings in the long run.

Improved Accuracy and Quality Control

In industries that require precise measurements, repetitive assembly, or stringent quality control, robotics, and automation play a vital role in ensuring accuracy and consistency. Unlike humans, robots are not susceptible to human errors, fatigue, or distractions, resulting in improved quality control and reduced defects. This ultimately translates into enhanced customer satisfaction and loyalty.

Enhanced Workplace Safety

The integration of robotics and automation can create a safer work environment for employees. By delegating dangerous and physically demanding tasks to robots, businesses can reduce the risk of accidents and injuries. Additionally, automation minimizes exposure to hazardous substances and repetitive strain injuries associated with certain manual tasks, fostering a healthier and more secure workplace.

Cost Optimization and Competitive Edge

Implementing robotics and automation solutions can lead to significant cost savings for businesses. While the initial investment may be substantial, the long-term benefits outweigh the expenses. Automation reduces labor costs, minimizes errors, and optimizes resource allocation. These factors contribute to improved profitability and provide a competitive edge by enabling companies to deliver products or services more efficiently than their competitors.

Industry Applications

Manufacturing and Assembly

The manufacturing industry has been at the forefront of embracing robotics and automation. Robotic arms, automated assembly lines, and smart factories have become increasingly common. These technologies facilitate rapid production, streamlined assembly processes, and increased customization capabilities. By leveraging robotics and automation, manufacturers can meet consumer demands faster, maintain consistent product quality, and adapt to changing market trends with ease.

Logistics and Warehousing

Efficient logistics and warehousing operations are crucial for businesses to meet customer expectations in today’s fast-paced world. Robotics and automation offer solutions such as automated picking, packing, and sorting systems, optimizing order fulfillment processes. These technologies enhance inventory management, reduce shipping errors, and expedite delivery times, enabling businesses to provide exceptional service and maintain a competitive edge in the market.

Healthcare and Medicine

Robotics and automation are revolutionizing the healthcare industry, transforming patient care, diagnostics, and surgery. From robotic surgical systems that perform precise, minimally invasive procedures to automated drug dispensing systems, these advancements are improving treatment outcomes and patient safety. Additionally, robotic exoskeletons are assisting in rehabilitation and physical therapy, enhancing the quality of life for patients with mobility challenges.

Agriculture and Farming

The agricultural sector is increasingly adopting robotics and automation to address challenges such as labor shortages, rising costs, and food production scalability. Autonomous farming equipment, precision agriculture technologies, and robotic harvesting systems are revolutionizing traditional farming practices. These advancements enable farmers to monitor crops, optimize resource usage, and increase overall productivity while reducing environmental impact.

The Future of Business Automation

As technology continues to advance at an unprecedented rate, the future of business automation holds immense potential. The integration of robotics, artificial intelligence (AI), and machine learning (ML) will further amplify the capabilities of automation systems. Businesses will witness the emergence of autonomous vehicles, humanoid robots, and advanced AI-powered systems that can adapt, learn, and make intelligent decisions in real-time.

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Explore the best robotics summer camps for high school students and ignite your passion for robotics

Robotics summer camps offer the perfect opportunity for high school students to indulge in their passion for technology and innovation while enjoying the freedom and relaxation of summer break. For those with a passion for robotics and a desire to delve into the exciting world of technology and innovation, enrolling in a robotics summer camp can be the perfect choice. These summer camps for high school students offer a unique blend of education, hands-on experience, and fun, creating a supportive environment for students to learn and grow. In this article, we will explore some of the best robotics summer camps available, catering to high school students who wish to expand their knowledge and skills in robotics.

1. MIT Beaver Works Summer Institute: The Massachusetts Institute of Technology (MIT) is renowned for its cutting-edge research and development in various fields, including robotics. The Beaver Works Summer Institute offers a four-week robotics summer camp where high school students can immerse themselves in hands-on robotics projects, guided by MIT professors and researchers. Participants will work in teams to design, build, and program robots, gaining invaluable skills and knowledge. This camp provides a unique opportunity to experience the MIT campus and collaborate with like-minded students from around the world.

2. Carnegie Mellon Robotics Academy: Carnegie Mellon University has a strong reputation for its robotics programs, and the Robotics Academy offers an exceptional summer camp experience for high school students. The camp focuses on teaching robotics using the LEGO Mindstorms platform, allowing participants to engage in various challenges and projects. The curriculum covers fundamental concepts in robotics, such as programming, mechanical design, and sensor integration. With access to state-of-the-art facilities and experienced instructors, students can develop their problem-solving skills and ignite their passion for robotics.

3. Embry-Riddle Aeronautical University Robotics Camp: For high school students with a specific interest in robotics applied to aerospace, the Embry-Riddle Aeronautical University Robotics Camp is an ideal choice. This week-long camp allows participants to delve into the world of robotics in aviation and aerospace. Students will engage in activities related to drones, automation, and unmanned systems. The camp includes hands-on experiences, flight simulations, and workshops led by experts in the field, providing a unique perspective on robotics and its applications in the aerospace industry.

4. iD Tech Robotics and Engineering Camp: iD Tech is a leading provider of summer technology camps, and their Robotics and Engineering Camp is an excellent choice for high school students interested in robotics and engineering. The camp offers hands-on experience in designing and building robots using LEGO Mindstorms EV3 kits. Students learn programming, problem-solving, and teamwork skills as they complete various challenges. With small class sizes and personalized instruction, iD Tech ensures that each student receives individual attention and support.

5. NASA Robotics Academy: For high school students interested in space exploration and robotics, the NASA Robotics Academy summer camp is a dream come true. This program, organized by the National Aeronautics and Space Administration, focuses on developing robotics skills for space exploration missions. Students work on building and programming robots that can navigate challenging terrains, collect data, and perform tasks similar to those encountered in space missions. The camp includes lectures by NASA scientists and engineers, as well as hands-on activities and simulated space missions.

6. VEX Robotics Summer Camps: VEX Robotics is a well-known robotics platform used in competitions worldwide, and its summer camps provide an excellent opportunity for high school students to engage in robotics challenges. These camps offer a comprehensive curriculum where students learn the fundamentals of robot design, programming, and control systems. They work in teams to design and build robots that compete in various VEX Robotics competitions.

7. FIRST Robotics Competition (FRC) Summer Camps: FIRST Robotics Competition is one of the largest and most prestigious robotics competitions for high school students. Many FRC teams offer robotics summer camps to help students prepare for the upcoming competition season. These camps provide hands-on experience with building and programming robots, as well as mentoring from experienced team members. Students learn valuable skills in engineering, teamwork, and project management, all while working towards a common goal of building a competitive robot.

8. American Robotics Academy: The American Robotics Academy stands out as a leader in providing immersive robotics learning experiences in North Carolina and various locations across Texas, including Houston, Austin, and Dallas. Participants will primarily utilize LEGO building blocks to construct advanced robots. These LEGO sets feature specialized components like axles, wheels, microcomputers, and other tools that facilitate animation and mechanical motion. By working in small teams to build robots, students will enhance their understanding of AI, machine learning, and coding.

9. NYU Tandon: New York University’s Tandon School of Engineering offers two exceptional robotics summer camps, with the first one being the Summer Program in Automation, Robotics, and Coding (SPARC). Located in the bustling city of New York, SPARC is a two-week immersive experience designed for high school students aged 14 and above. SPARC provides a comprehensive curriculum covering robotics fundamentals, computer programming, and mechatronics.

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The best ways companies are automating workflows through mobile robots are ideal for carrying containers

One of the most intriguing characteristics of AMRs is their capacity to perform a variety of jobs and traverse nearly any environment. They are adjustable and flexible, allowing for a wide range of applications in distribution centers, industrial facilities, and warehouses. Here are some of the most typical AMR application cases from various sectors.

1. Delivering Raw Materials: AMRs in industrial plants may transport raw goods and components from the warehouse to the required position inside the facility. They may be outfitted with accessories that let them to haul pallets, containers, shelves, and other items.

2. Work-In-Process Movement: Small, nimble autonomous mobile robots are ideal for transporting packaging, supplies, or partially-finished items without obstructing traffic. This enables constant material flow in non-linear manufacturing operations.

3. End-of-Line Handling: AMRs can transport finished items from the production floor to the next stage of the operation, whether that be QA, finished goods storage, or another site. They can move pallets automatically from the palletizer to the stretch wrapper and then to the shipping dock.

4. Transporting Waste Materials: AMRs may autonomously collect garbage from various locations within the plant and transport it to the nearest waste disposal zone.

5. Case Picking: AMRs can be used to choose case quantities of a product from several storage media. Human work is reduced at warehouses and distribution hubs as a result.

6. Transporting Picking Containers: AMRs can navigate confined aisles to transfer picking containers securely and independently to the relevant shipping lane.

7. Moving Packed Pallets: Heavy-duty robots can transport stacked pallets from one location to another safely and securely. They can decrease the requirement for forklifts when fitted with lifting accessories. Because forklifts are more prone to cause damage or harm, this is especially beneficial in locations where humans operate and other technology must be maneuvered.

8. Staging Loads for Shipping: Because AMRs have sophisticated sensing capabilities, they can move with accuracy and arrange cargo for less labor-intensive, more efficient outbound logistics.

9. Delivering/Replenishing Empty Pallets: AMRs equipped with pallet platforms are skilled at transporting and restocking empty pallets at the proper moment, ensuring that pallets are always in the right spot when they are required.

10. Cross-Docking or Dock-to-Aisle: AMRs can be utilized in shipping ports for cross-docking or dock-to-aisle material handling due to their sensing skills, mobility, and ability to work alongside humans and other vehicles.

11. Long-Haul Material Transport: In big facilities, AMRs can replace fork trucks or other kinds of cars as a safer form of long-distance transfer.

12. On-Demand Material Transport: While many of these applications are self-contained and recurrent, AMRs may also be utilized for specialized, on-demand transport missions.

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NASA adds a robotics element to its deep space and deep-sea missions.

What distinguishes deep water from deep space? The answer is, “Not much,” for a robot. Both are difficult and demanding conditions, but more crucially, both are remote from the machine’s operator. To reduce expenses for the marine sectors, a team of roboticists from NASA’s Johnson Space Center in Houston decided to use their skills to create a shape-changing underwater robot.

Nic Radford, creator, chairman, president, and CEO of Houston-based Nauticus Robotics Inc., said: “NASA taught us how to bring together solid software autonomy with a powerful hardware architecture and deploy it in a remote context.” Radford worked with Johnson for 14 years, serving in a variety of capacities, including chief engineer and deputy project manager on the Robonaut 2 humanoid robot. The 80-person team he has assembled at Nauticus now includes more than 20 engineers who worked on that project and other NASA robots.

The operator is far away, has limited communication capabilities, and has little awareness of the robot’s surroundings whether the robot is operating in space or on the seafloor, according to Radford. There is no high-speed data network, even if you install one on the space station and operate it from the ground. The space station is more like dial-up when it comes to communication. The robot must thus perceive and comprehend its surroundings to avoid obstacles and manipulate items with the least amount of operator input.

Because of this, Johnson engineers had to create sophisticated hardware for Robonaut 2, including elastic joints, tendon-powered hands, and miniature load cells, as well as vision systems, force sensors, and infrared sensors to gather information. They also had to create software for image recognition, control algorithms, and ultra-high-speed joint controllers to process and act on that information.

NASA and General Motors’ partnership has allowed Robonaut 2, a robot astronaut assistant aboard the International Space Station, to show off its powers (GM). It served as a test site for all of this cutting-edge robotic technology, though. In advance of the arrival of human astronauts, NASA intends to create robots that can do hazardous tasks in space, launch “precursor missions,” and keep up with infrastructure like the proposed lunar Gateway station when people aren’t available. On the other hand, GM was eager to look into robots that may help workers in the manufacturing sector. Over 50 patents were generated by the initiative, some of which have already been implemented into a robotic glove used in the workplace by GM and other companies.

Eliminating the Cord

Deep-sea robots may link to operators through a cable, allowing for tight control and high-speed data transfer, unlike a robot in space. But according to Radford, this costs roughly $100,000 and generates 70 metric tonnes of greenhouse gas emissions every day to staff and run an enormous support vessel on the surface. By allowing its robots to operate with little oversight from a command center on a faraway coast, Nauticus is cutting that cord.

The company’s emblematic robot, Aquanaut, is bright orange, entirely electric, and roughly the size of a sports car. As it travels to its destination, Aquanaut resembles a propeller-driven torpedo. When that happens, the nose swings upward to reveal a collection of cameras and other sensors that are now facing the front, and its shell snaps open. Two arms extend in a swing, terminating in claw hands that may hold a variety of implements. To test the robot in 2019, the team went back to Johnson and made use of the Neutral Buoyancy Lab’s enormous astronaut training pool. Here, the robot could test out its systems in front of operators and cameras.

A floating factotum

Radford emphasized that a subsea robot is capable of doing a variety of duties and that Aquanaut is made to be adaptable. Offshore oil and gas production is a clear target due to the enormous amount of underwater equipment that requires inspection and maintenance. Wind energy, however, is the ocean’s fastest-growing industry. According to Radford, there are plans to run some 25,000 offshore wind turbines by 2030; each one will require upkeep and inspection.

Aquaculture, or the production of fish, shrimp, and other seafood, is expanding quickly in response to the sharp decline in wild fish populations. According to Radford, the nets and cages in these underwater farms require routine cleaning and inspection.

Port management, maintaining underwater communication lines, offshore mining for rare minerals, and defense uses are further prospective careers. About $2.5 trillion was Radford’s estimate for the marine sector as a whole.

Nauticus intended to create 20 additional Aquanauts over the next three years after producing two at the beginning of 2022. Instead of selling them, the corporation would mostly use them to deliver inexpensive services. Nauticus is developing a vessel dubbed Hydronaut that can be remotely controlled or can travel by itself for activities that call for surface help.

Radford wants the Nauticus moniker to be synonymous with ocean robotics by using space technologies to address marine issues. Space is great because it feels existential; it is far away, and people want to investigate it. However, there are a lot of genuine problems right here in the water, and we need to innovate more in the “blue economy.”

Technology transfer from NASA to the business sector has a lengthy history. To show the wider advantages of America’s commitment to its space program, the agency’s Spinoff magazine showcases NASA technology that has evolved into commercial goods and services. The spinoff is a journal produced by NASA’s Space Technology Mission Directorate’s Technology Transfer program (STMD).

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