Category Archives: Robotics

Surgical Robots For The Spine Market Size, Status, Business Future Scenarios and Brief Analysis 2020-2026

The report titled Surgical Robots For The Spine Market has recently added by The Research Insights to get a stronger and effective business outlook. It provides an in-depth analysis of different attributes of industries such as trends, policies, and clients operating in several regions. The qualitative and quantitative analysis techniques have been used by analysts to provide accurate and applicable data to the readers, business owners and industry experts.

Surgical Robots For The Spine Market is growing at a High CAGR during the forecast period 2020-2026. The increasing interest of the individuals in this industry is that the major reason for the expansion of this market.

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The report presents the market competitive landscape and a corresponding detailed analysis of the major vendor/key players in the market. Top Companies in the Global Surgical Robots For The Spine Market: Mazor Robotics, Medtech S.A, TINA VI Medical Technologies, Globus Medical

A rapid rise in the use of spine surgical robots is attributed to a blend of technological improvements. Moreover, a rise in demand for minimally invasive surgeries has further boosted demand for surgical robots for spine. Spine surgical robots have been widely used for minimally invasive procedures, spine fusion, scoliosis correction surgery, vertebroplasty, spinal biopsies, and others. These techniques cause minimal complications, reduce the risk of infections, cause less pain, and have a faster recovery time, which leads to shorter hospital stays as compared to traditional therapies and treatments. These factors have helped increase the acceptance and adoption of spine surgical robots by many medical facilities and centers. Spine surgical robots are self-powered, computer-controlled devices programmed to aid in the positioning and manipulation of surgical instruments. The global Surgical Robots For The Spine market was valued at more than US$ 75 Mn in 2017 and is anticipated to reach US$ 320 Mn by 2026.

Global Surgical Robots For The Spine Market Split by Product Type and Applications:

This report segments the global Surgical Robots For The Spine Market on the basis of Types are:

Separate System

Combining System

On the basis of Application, the Global Surgical Robots For The Spine Market is segmented into:

Disc Replacement

Spine Fusion

Regional analysis of Global Surgical Robots For The Spine Market:

The report provides a detailed breakdown of the market region-wise and categorizes it at various levels. Regional segment analysis displaying regional production volume, consumption volume, revenue, and growth rate from 2020-2026 covers: Americas (United States, Canada, Mexico, Brazil), APAC (China, Japan, Korea, Southeast Asia, India, Australia), Europe (Germany, France, UK, Italy, Russia, Spain), Middle East & Africa (Egypt, South Africa, Israel, Turkey, GCC Countries). Each of these regions is analysed on basis of market findings across major countries in these regions for a macro-level understanding of the market.

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What are the market factors that are explained in the report?

-Key Strategic Developments: The study also includes the key strategic developments of the market, comprising R&D, new product launch, M&A, agreements, collaborations, partnerships, joint ventures, and regional growth of the leading competitors operating in the market on a global and regional scale.

-Key Market Features: The report evaluated key market features, including revenue, price, capacity, capacity utilization rate, gross, production, production rate, consumption, import/export, supply/demand, cost, market share, CAGR, and gross margin. In addition, the study offers a comprehensive study of the key market dynamics and their latest trends, along with pertinent market segments and sub-segments.

-Analytical Tools: The Global Surgical Robots For The Spine Market report includes the accurately studied and assessed data of the key industry players and their scope in the market by means of a number of analytical tools. The analytical tools such as Porters five forces analysis, SWOT analysis, feasibility study, and investment return analysis have been used to analyze the growth of the key players operating in the market.

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Table of Content:

Surgical Robots For The Spine Market Research Report 2020-2026

Chapter 1: Industry Overview

Chapter 2: Surgical Robots For The Spine Market International and China Market Analysis

Chapter 3: Environment Analysis of Market.

Chapter 4: Surgical Robots For The Spine Analysis of Revenue by Classifications

Chapter 5: Analysis of Revenue by Regions and Applications

Chapter 6: Analysis of Surgical Robots For The Spine Market Revenue Market Status.

Chapter 7: Surgical Robots For The Spine Analysis of Industry Key Manufacturers

Chapter 8: Sales Price and Gross Margin Analysis of Market.

Chapter 9: .Continue to TOC

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Surgical Robots For The Spine Market Set to Witness Huge Growth by 2026| Mazor Robotics, Medtech SA, TINA VI Medical Technologies, Globus Medical -...

As COVID-19 continues to bolster the global delivery and logistics market, warehouse robotics startup Geek+ today announced it has extended its series C funding round to $200 million, up from $150 million in July 2019. The company says the deal, which closed earlier this year, will support expansion of its robot-as-a-service program and its relationships with technology and ecosystem partners.

Worker shortages caused by the pandemic have prompted some retailer, fulfillment, and logistics companies to accelerate the rollout of mobile robots. Gap more than tripled the number of item-picking machines it uses to 106, while Amazon says its relying more heavily on automation for product sorting. According to ABI Research, more than 4 million commercial robots will be installed in over 50,000 warehouses around the world by 2025, up from just under 4,000 warehouses in 2018.

Geek+, which was founded in 2015, develops a range of AI-imbued logistics robots addressing scenarios in warehouses, factories, and sorting centers. The company claims its line of picking robots can autonomously carry thousands of pounds and says its smart factory system which replaces traditional conveyor-belt-style assembly line setups can almost double production capacity through a combination of internet of things devices, 5G, edge computing, and real-time computer vision.

Geek+ also supplies the planning software that drives its autonomous robots, most of which use lidar, collision sensors, RGB cameras, visual simultaneous localization, and mapping technologies to navigate factory floors. Algorithms facilitate things like order grouping and finding box sizes according to a products weight and measurements by mining and analyzing historical data. The robots also move inventory to easy-to-reach places within warehouses and factories based on predicted demand:

Geek+ says during Singles Day in China last year, iWMS helped process a combined 8.11 million delivery orders for ecommerce customers.

The Beijing-based startups funding extension comes after it brought its warehouse robots to the U.S. via a partnership with North American order fulfillment and distribution center system integrator Conveyco. Geek+ recently worked with Walmart to deploy robots in the retailers Shenzhen distribution center, improving picking efficiency by a claimed 3.5 times. It also installed dozens of picking robots in Dells Xiamen spare parts warehouse and Decathlons Kunshan warehouse to reduce the need for on-site operators. And in Japan, it teamed up with Nike to enable same-day delivery in the Greater Tokyo area.

Geek+ says it has over 300 customers (including Alibaba and Suning) which together have deployed more than 10,000 of its robots in over 20 countries.

This latest C2 funding round, which was led by V Fund with participation from Redview Capital and Vertex Ventures, brings Geek+s total raised to nearly $390 million with a reported post-money valuation of $2 billion. (GGV Capital, D1 Capital Partners, and Warburg Pincus contributed to last years C1.) In addition to its Beijing headquarters, the 800-employee company has offices in Germany, the U.K., the U.S., Japan, Hong Kong, and Singapore

Geek+ competes in the $3.1 billion intelligent machines market with Los Angeles-based robotics startup InVia, which leases automated robotics technologies to fulfillment centers;Gideon Brothers, a Croatia-based industrial startup backed by TransferWise cofounder Taavet Hinrikus; robotics systems company GreyOrange; Berkshire Grey, which combines AI and robotics to automate multichannel fulfillment for retailers, ecommerce, and logistics enterprises; and Otto Motors. Fulfillment alone is a $9 billion industry roughly 60,000 employees handle orders in the U.S., and companies like Apple manufacturing partner Foxconn have deployed tens of thousandsof assistive robots in assembly plants overseas.

Read more:

Geek+ raises $50 million more to bring autonomous warehouse robots to the U.S. - VentureBeat

Global Robotic Parking Systems Market Report from AMA Research highlights deep analysis on market characteristics, sizing, estimates and growth by segmentation, regional breakdowns& country along with competitive landscape, players market shares, and strategies that are key in the market. The exploration provides a 360 view and insights, highlighting major outcomes of the industry. These insights help the business decision-makers to formulate better business plans and make informed decisions to improved profitability. In addition, the study helps venture or private players in understanding the companies in more detail to make better informed decisions.

Top players in Global Robotic Parking Systems Market are:

Boomerang Systems (United States),,Parkplus (United States),,Serva Transport Systems (Germany),,Shenzhen Yeefung Automation Technology (China),,MHE-Demag (Singapore),,Stanley Robotics (France),,AIM Inc. (United States),,Fata Automation (United States),,A.P.T. Parking Technologies (United States),,LoDige Industries (Germany),,Smart City Robotics (Abu Dhabi)

Analyst at AMA have conducted special survey and have connected with opinion leaders and Industry experts from various region to minutely understand impact on growth as well as local reforms to fight the situation. A special chapter in the study presents Impact Analysis of COVID-19 on Global Robotic Parking Systems Market along with tables and graphs related to various country and segments showcasing impact on growth trends.

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The rising unavailability or the limited availability of parking spaces coupled with the increasing number of vehicles have resulted in heavy traffic congestion in several regions and countries. Moreover, it is observed that the drivers searching for vacant parking spaces account for approximately 40% of the total traffic congestion. Thus enhancing the need for a robotic Parking system across the countries. In addition to that, the main reason people want this parking space is that the time spent in finding parking space, results in wastage of fuel and increased emission. As per the study done in the market, it is seen that the German driver spends, on average, 41 hours on searching parking spaces each year. Hence causing the country to cost around USD 45 billion which included the cost of wasted time, fuel, and emission. Hence all the aforementioned reasons are sufficient to drive the market forces.

Market Drivers

Market Trend

Challenges

Region Included are: North America, Europe, Asia Pacific, Oceania, South America, Middle East & Africa

Country Level Break-Up: United States, Canada, Mexico, Brazil, Argentina, Colombia, Chile, South Africa, Nigeria, Tunisia, Morocco, Germany, United Kingdom (UK), the Netherlands, Spain, Italy, Belgium, Austria, Turkey, Russia, France, Poland, Israel, United Arab Emirates, Qatar, Saudi Arabia, China, Japan, Taiwan, South Korea, Singapore, India, Australia and New Zealand etc.

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Strategic Points Covered in Table of Content of Global Robotic Parking Systems Market:

Chapter 1: Introduction, market driving force product Objective of Study and Research Scope the Global Robotic Parking Systems market

Chapter 2: Exclusive Summary the basic information of the Global Robotic Parking Systems Market.

Chapter 3: Displaying the Market Dynamics- Drivers, Trends and Challenges of the Global Robotic Parking Systems

Chapter 4: Presenting the Global Robotic Parking Systems Market Factor Analysis Porters Five Forces, Supply/Value Chain, PESTEL analysis, Market Entropy, Patent/Trademark Analysis.

Chapter 5: Displaying the by Type, End User and Region 2013-2020

Chapter 6: Evaluating the leading manufacturers of the Global Robotic Parking Systems market which consists of its Competitive Landscape, Peer Group Analysis, BCG Matrix & Company Profile

Chapter 7: To evaluate the market by segments, by countries and by manufacturers with revenue share and sales by key countries in these various regions.

Chapter 8 & 9: Displaying the Appendix, Methodology and Data Source

Finally, Global Robotic Parking Systems Market is a valuable source of guidance for individuals and companies.

Data Sources & Methodology

The primary sources involve the industry experts from the Global Robotic Parking Systems Market including the management organizations, processing organizations, analytics service providers of the industrys value chain. All primary sources were interviewed to gather and authenticate qualitative & quantitative information and determine the future prospects.

In the extensive primary research process undertaken for this study, the primary sources Postal Surveys, telephone, Online & Face-to-Face Survey were considered to obtain and verify both qualitative and quantitative aspects of this research study. When it comes to secondary sources Companys Annual reports, press Releases, Websites, Investor Presentation, Conference Call transcripts, Webinar, Journals, Regulators, National Customs and Industry Associations were given primary weightage.

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What benefits does AMA research studies provides?

Definitively, this report will give you an unmistakable perspective on every single reality of the market without a need to allude to some other research report or an information source. Our report will give all of you the realities about the past, present, and eventual fate of the concerned Market.

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Robotic Parking Systems Market will Hit Big Revenues in Future | COVID19 Unlock opportunities - Cole of Duty

They have been compared to quantum leaps in humanitys historic journey. But they are more like Grand Canyon-style jumps in our evolution.

During the past 200 years, technological revolutions have expanded the borders of globalization and have dragged millions of people out of poverty. Yet they have come at a price.

The FourthIndustrialRevolution will be no different.

Already the landscape is changing dramatically with China at the forefront of this brave, new world for some and a nightmare for others.

China is using automation on a scale like no other country. From AI news anchors on [state-run television] to one-minute [health] clinics to robot-run factories, China is using artificial intelligence and robots to take over the entire spectrum of human capabilities, Abishur Prakash, a geopolitical futurist at the Center for Innovating the Future, a strategy consulting firm, told Asia Times.

This could transform politics in the country. It was city-jobs that drove urbanization in China. Now, however, if the blue-collar and white-collar jobs are both being automated, reverse urbanization may follow. This will create a new kind of economy for China, which in turn could change domestic politics, trade deals and foreign policy,he said.

The sheer scale of Beijings ambitions are immense. Investment in science and technology research in the worlds second-largest economy was US$355.4 billion last year or 2.5% of GDP, official data revealed.

Only the United States spent more as China edged past Japan.

Read: Chinas high-tech dream could come at a price

Moveover, funding looks certain to accelerate in 2020 with 3 trillion yuan, or $423 billion, earmarked for major projects in response to the Covid-19 pandemic.

Up to 17.5 trillion yuan, or $2.47 trillion, will be pumped into ramping up infrastructure spending in the high-tech sector during the next six years, the Shanghai Securities News reported in May.

Priority funding in the next 12 months will go to 5G base stations, EV charging outlets, big data centers, AI and the industrial internet, such as robotics.

Read: Cold War chill sweeps through China

Also, unlike previous rounds of traditional infrastructure investment on roads, bridges and high-speed rail networks, private companies will be heavily involved in the mix.

Still, the pace of change will generate a different set of problems, including the specter of unemployment.

China has dealt with large-scale layoffs or economic downturns by creating a massive state-run construction force. But, now, the people that may lose their jobs to automation may be the educated, skilled class in cities like Shenzhen and Shanghai. Whats Chinas plan for them?, Prakash, the author of The Age of Killer Robots, said.

Since 2014, the nations automation industry has expanded by 28% with 650,000 robots going online in 2018.

Yet this has generated a backlash from the Chinese public. A study released to the media by Spanish university IE showed a rise in robophobia during the coronavirus crisis.

Before the pandemic infected more than nine million people worldwide, only 27% supported limited automation in China. That number has more than doubled to 59%, with the Chinese just behind the French as the most hostile to automation.

The changing nature of work is generating fears about mass unemployment. These trends are straining the relationships among citizens, firms and governments across the globe, the World Bank stated in a report, entitled the Changing Nature of Work, last year.

Even so, the benefits of the controversial Made in China 2025 digital program proved vital during the Covid-19 crisis.

Read: Claims of a mutating virus spooks Beijing

Artificial intelligence, big data, cloud computing and 5G effectively improved the efficiency of the countrys efforts in tackling the epidemic.

It [was crucial] to monitoring virus tracking, prevention, control and treatment, [as well as] resource allocation, Qi Xiaoxia, the director-general of the Cyberspace Administration of Chinas Bureau of International Cooperation, said in a commentary published on the World Economic Forum website in April.

Even basic models of service robots appeared to play their role in delivering meals and cleaning hospital corridors.

Admittedly, the acceleration of automation may reduce certain jobs on an individual basis. Some people may suffer, which is the inevitable cost of technological transition and advancement still, new jobs will be created to replace those that have been lost,Jon Yuan Jiang, an assistant researcher at the Queensland University of Technology in Australia, told Asia Times.

Read: Vaccine race intensifies amid virus second wave

But concerns persist. In developed and developing economies, the fallout from the coronavirus catastrophe threatens to trigger economic pandemonium and ballooning unemployment across the globe.

The urban jobless numbers in China have been on the rise since the start of the year. For the upper echelons of the ruling Communist Party, unemployment is a notoriously sensitive subject.

Indeed, the FourthIndustrialRevolution risks adding to the upheaval.

Already, its projected that 51 million jobs in Europe could disappear because of automation [with Covid-19 being a factor]. The point is, the appetite for automation is rising and its no longer limited to just entry-level jobs, Prakash, of the Center for Innovating the Future, said.

Its no longer just about janitors or truck drivers or factory workers. Everyone could be on the chopping block because the pandemic has fundamentally changed how businesses operate. There are now huge geopolitical risks as automation takes off, he added.

Possibly, a revolution against a revolution?

Asia Times Financialis now live. Linking accurate news, insightful analysis and local knowledge with the ATF China Bond 50 Index, the world'sfirst benchmark cross sector Chinese Bond Indices.Read ATFnow.

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Covid-19 will accelerate march of the robots - Asia Times

Artificial intelligence (AI) is arguably the most exciting field in robotics. It's certainly the most controversial: Everybody agrees that a robot can work in an assembly line, but there's no consensus on whether a robot can ever be intelligent.

Like the term "robot" itself, artificial intelligence is hard to define. Ultimate AI would be a recreation of the human thought process -- a man-made machine with our intellectual abilities. This would include the ability to learn just about anything, the ability to reason, the ability to use language and the ability to formulate original ideas. Roboticists are nowhere near achieving this level of artificial intelligence, but they have made a lot of progress with more limited AI. Today's AI machines can replicate some specific elements of intellectual ability.

Computers can already solve problems in limited realms. The basic idea of AI problem-solving is very simple, though its execution is complicated. First, the AI robot or computer gathers facts about a situation through sensors or human input. The computer compares this information to stored data and decides what the information signifies. The computer runs through various possible actions and predicts which action will be most successful based on the collected information. Of course, the computer can only solve problems it's programmed to solve -- it doesn't have any generalized analytical ability. Chess computers are one example of this sort of machine.

Some modern robots also have the ability to learn in a limited capacity. Learning robots recognize if a certain action (moving its legs in a certain way, for instance) achieved a desired result (navigating an obstacle). The robot stores this information and attempts the successful action the next time it encounters the same situation. Again, modern computers can only do this in very limited situations. They can't absorb any sort of information like a human can. Some robots can learn by mimicking human actions. In Japan, roboticists have taught a robot to dance by demonstrating the moves themselves.

Some robots can interact socially. Kismet, a robot at M.I.T's Artificial Intelligence Lab, recognizes human body language and voice inflection and responds appropriately. Kismet's creators are interested in how humans and babies interact, based only on tone of speech and visual cue. This low-level interaction could be the foundation of a human-like learning system.

Kismet and other humanoid robots at the M.I.T. AI Lab operate using an unconventional control structure. Instead of directing every action using a central computer, the robots control lower-level actions with lower-level computers. The program's director, Rodney Brooks, believes this is a more accurate model of human intelligence. We do most things automatically; we don't decide to do them at the highest level of consciousness.

The real challenge of AI is to understand how natural intelligence works. Developing AI isn't like building an artificial heart -- scientists don't have a simple, concrete model to work from. We do know that the brain contains billions and billions of neurons, and that we think and learn by establishing electrical connections between different neurons. But we don't know exactly how all of these connections add up to higher reasoning, or even low-level operations. The complex circuitry seems incomprehensible.

Because of this, AI research is largely theoretical. Scientists hypothesize on how and why we learn and think, and they experiment with their ideas using robots. Brooks and his team focus on humanoid robots because they feel that being able to experience the world like a human is essential to developing human-like intelligence. It also makes it easier for people to interact with the robots, which potentially makes it easier for the robot to learn.

Just as physical robotic design is a handy tool for understanding animal and human anatomy, AI research is useful for understanding how natural intelligence works. For some roboticists, this insight is the ultimate goal of designing robots. Others envision a world where we live side by side with intelligent machines and use a variety of lesser robots for manual labor, health care and communication. A number of robotics experts predict that robotic evolution will ultimately turn us into cyborgs -- humans integrated with machines. Conceivably, people in the future could load their minds into a sturdy robot and live for thousands of years!

In any case, robots will certainly play a larger role in our daily lives in the future. In the coming decades, robots will gradually move out of the industrial and scientific worlds and into daily life, in the same way that computers spread to the home in the 1980s.

The best way to understand robots is to look at specific designs. The links below will show you a variety of robot projects around the world.

More here:

Robots and Artificial Intelligence | HowStuffWorks

STEM features - Robots are fun, but lets face it: A lot of the reasoning involved in splurging on a toy like this is for STEM learning. Different robots and robotics have varying levels of STEM; some have it as a primary focus, while for others its just a result of using the robot. If you specifically want your child to learn about coding or robotics, it may be better to pick a model that emphasizes these features.

Age level - The age of your child plays an important role in what kind of robot would best suit them. You may want to consider purchasing a robot that will grow with them if your child is young, offering basic features at the beginning with room to expand later. On the other hand, if your child is old enough to learn to code, a more advanced model might work better.

Personality - Its hard not to get attached to a robot, especially considering how cute some of them are. Some robots even have a personality that will develop based on interaction and use. If you think your child might enjoy having a robot companion to play with, choosing one with a personality might be a fun idea.

Read this article:

The 8 Best Robotics for Kids in 2020 - Lifewire

Telerobotics is the area of robotics concerned with the control of semi-autonomous robots from a distance, chiefly using Wireless network (like Wi-Fi, Bluetooth, the Deep Space Network, and similar) or tethered connections. It is a combination of two major subfields, teleoperation and telepresence.

Teleoperation indicates operation of a machine at a distance. It is similar in meaning to the phrase "remote control" but is usually encountered in research, academic and technical environments. It is most commonly associated with robotics and mobile robots but can be applied to a whole range of circumstances in which a device or machine is operated by a person from a distance.[1]

Teleoperation is the most standard term, used both in research and technical communities, for referring to operation at a distance. This is opposed to "telepresence", which refers to the subset of telerobotic systems configured with an immersive interface such that the operator feels present in the remote environment, projecting his or her presence through the remote robot. One of the first telepresence systems that enabled operators to feel present in a remote environment through all of the primary senses (sight, sound, and touch) was the Virtual Fixtures system developed at US Air Force Research Laboratories in the early 1990s. The system enabled operators to perform dexterous tasks (inserting pegs into holes) remotely such that the operator would feel as if he or she was inserting the pegs when in fact it was a robot remotely performing the task.[2][3][4]

A telemanipulator (or teleoperator) is a device that is controlled remotely by a human operator. In simple cases the controlling operator's command actions correspond directly to actions in the device controlled, as for example in a radio controlled model aircraft or a tethered deep submergence vehicle. Where communications delays make direct control impractical (such as a remote planetary rover), or it is desired to reduce operator workload (as in a remotely controlled spy or attack aircraft), the device will not be controlled directly, instead being commanded to follow a specified path. At increasing levels of sophistication the device may operate somewhat independently in matters such as obstacle avoidance, also commonly employed in planetary rovers.

Devices designed to allow the operator to control a robot at a distance are sometimes called telecheric robotics.

Two major components of telerobotics and telepresence are the visual and control applications. A remote camera provides a visual representation of the view from the robot. Placing the robotic camera in a perspective that allows intuitive control is a recent technique that although based in Science Fiction (Robert A. Heinlein's Waldo 1942) has not been fruitful as the speed, resolution and bandwidth have only recently been adequate to the task of being able to control the robot camera in a meaningful way. Using a head mounted display, the control of the camera can be facilitated by tracking the head as shown in the figure below.

This only works if the user feels comfortable with the latency of the system, the lag in the response to movements, the visual representation. Any issues such as, inadequate resolution, latency of the video image, lag in the mechanical and computer processing of the movement and response, and optical distortion due to camera lens and head mounted display lenses, can cause the user 'simulator sickness' that is exacerbated by the lack of vestibular stimulation with visual representation of motion.

Mismatch between the users motions such as registration errors, lag in movement response due to overfiltering, inadequate resolution for small movements, and slow speed can contribute to these problems.

The same technology can control the robot, but then the eyehand coordination issues become even more pervasive through the system, and user tension or frustration can make the system difficult to use.[citation needed]

The tendency to build robots has been to minimize the degrees of freedom because that reduces the control problems. Recent improvements in computers has shifted the emphasis to more degrees of freedom, allowing robotic devices that seem more intelligent and more human in their motions. This also allows more direct teleoperation as the user can control the robot with their own motions.[5]

A telerobotic interface can be as simple as a common MMK (monitor-mouse-keyboard) interface. While this is not immersive, it is inexpensive. Telerobotics driven by internet connections are often of this type. A valuable modification to MMK is a joystick, which provides a more intuitive navigation scheme for planar robot movement.

Dedicated telepresence setups utilize a head mounted display with either single or dual eye display, and an ergonomically matched interface with joystick and related button, slider, trigger controls.

Other interfaces merge fully immersive virtual reality interfaces and real-time video instead of computer-generated images.[6] Another example would be to use an omnidirectional treadmill with an immersive display system so that the robot is driven by the person walking or running. Additional modifications may include merged data displays such as Infrared thermal imaging, real-time threat assessment, or device schematics.[citation needed]

With the exception of the Apollo program, most space exploration has been conducted with telerobotic space probes. Most space-based astronomy, for example, has been conducted with telerobotic telescopes. The Russian Lunokhod-1 mission, for example, put a remotely driven rover on the moon, which was driven in real time (with a 2.5-second lightspeed time delay) by human operators on the ground. Robotic planetary exploration programs use spacecraft that are programmed by humans at ground stations, essentially achieving a long-time-delay form of telerobotic operation. Recent noteworthy examples include the Mars exploration rovers (MER) and the Curiosity rover. In the case of the MER mission, the spacecraft and the rover operated on stored programs, with the rover drivers on the ground programming each day's operation. The International Space Station (ISS) uses a two-armed telemanipulator called Dextre. More recently, a humanoid robot Robonaut[8] has been added to the space station for telerobotic experiments.

NASA has proposed use of highly capable telerobotic systems[9] for future planetary exploration using human exploration from orbit. In a concept for Mars Exploration proposed by Landis, a precursor mission to Mars could be done in which the human vehicle brings a crew to Mars, but remains in orbit rather than landing on the surface, while a highly capable remote robot is operated in real time on the surface.[10] Such a system would go beyond the simple long time delay robotics and move to a regime of virtual telepresence on the planet. One study of this concept, the Human Exploration using Real-time Robotic Operations (HERRO) concept, suggested that such a mission could be used to explore a wide variety of planetary destinations.[7]

The prevalence of high quality video conferencing using mobile devices, tablets and portable computers has enabled a drastic growth in telepresence robots to help give a better sense of remote physical presence for communication and collaboration in the office, home, school, etc. when one cannot be there in person. The robot avatar can move or look around at the command of the remote person.[11][12]

There have been two primary approaches that both utilize videoconferencing on a display 1) desktop telepresence robots - typically mount a phone or tablet on a motorized desktop stand to enable the remote person to look around a remote environment by panning and tilting the display or 2) drivable telepresence robots - typically contain a display (integrated or separate phone or tablet) mounted on a roaming base. Some examples of desktop telepresence robots include Kubi by Revolve Robotics, Galileo by Motrr, and Swivl. Some examples of roaming telepresence robots include Beam by Suitable Technologies, Double by Double Robotics, RP-Vita by iRobot and InTouch Health, Anybots, Vgo, TeleMe by Mantarobot, and Romo by Romotive. More modern roaming telepresence robots may include an ability to operate autonomously. The robots can map out the space and be able to avoid obstacles while driving themselves between rooms and their docking stations.[13]

Traditional videoconferencing systems and telepresence rooms generally offer Pan / Tilt / Zoom cameras with far end control. The ability for the remote user to turn the device's head and look around naturally during a meeting is often seen as the strongest feature of a telepresence robot. For this reason, the developers have emerged in the new category of desktop telepresence robots that concentrate on this strongest feature to create a much lower cost robot. The desktop telepresence robots, also called head and neck Robots[14] allow users to look around during a meeting and are small enough to be carried from location to location, eliminating the need for remote navigation.[15]

Some telepresence robots are highly helpful for some long-term illness children, who were unable to attend school regularly. Latest innovative technologies can bring people together, and it allows them to stay connected to each other, which significantly help them to overcome loneliness. [16]

Marine remotely operated vehicles (ROVs) are widely used to work in water too deep or too dangerous for divers. They repair offshore oil platforms and attach cables to sunken ships to hoist them. They are usually attached by a tether to a control center on a surface ship. The wreck of the Titanic was explored by an ROV, as well as by a crew-operated vessel.

Additionally, a lot of telerobotic research is being done in the field of medical devices, and minimally invasive surgical systems. With a robotic surgery system, a surgeon can work inside the body through tiny holes just big enough for the manipulator, with no need to open up the chest cavity to allow hands inside.

NIST maintains a set of test standards used for Emergency Response[17] and law enforcement telerobotic systems.[18][19]

Remote manipulators are used to handle radioactive materials.

Telerobotics has been used in installation art pieces; Telegarden is an example of a project where a robot was operated by users through the Web.

Link:

Telerobotics - Wikipedia

With a growing economy that has a higher demand for STEM fields, its important that the next generation learns how they can make a difference in their world. Thats why Engineering For Kids offers a variety of classes and workshops that kids of all ages can enjoy. Robotics camps and classes give students the opportunity to dive deep into the world of robotics and explore how computer programming and robot design can solve problems big and small!

Contact your local Engineering For Kids to learn more!

Not only do our robotics programs help to establish science, technology, engineering, and math concepts, they also work to build on students team-building skills as they work to complete fun challenges. These collaborative skills are essential for student success, no matter what subject they choose to pursue in the future.

Whether you have a son whos in preschool or a daughter thats going on six years old, Engineering For Kids offer robotics classes that children as young as pre-kindergartners can enjoy. Our junior robotics engineering classes use educational kits like LEGO WeDo Robots to create a perfect mixture of fun and imagination that can help expand your young childs creative mind. We introduce students to robot design and computer programming using basic machine principles to create robots capable of performing simple tasks.

Engineering For Kids is proud to offer a wide range of unique, educational, and stimulating robotics programs for young engineers ranging from 3rd grade to 8th grade. Putting the Engineering Design Process to work, students work in teams to plan, build, test, and modify their own robotic creations! We use LEGO EV3 or NXT, VEX IQ, and other educational kits that mirror programming language used by engineers and scientists to help creative minds put mathematical concepts to the test as they develop a better knowledge of robotics, computer programming, and teamwork.

To learn more about our robotics classes, dont hesitate to contact us!

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Robotics | After School Activities

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The robotics-engineering industry is a broad and changing field of study. To keep their knowledge and skills up to date, robotics engineers will need to read research and trade journals, attend professional seminars and conferences, and work with colleagues on cutting-edge research.

New robotics engineers often begin their careers as assistants or junior engineers at a robotics firm, under the supervision of an established colleague.

A bachelor's degree in engineering or a related field is required for most entry-level positions in robotics engineering. Because robotics technology draws on the expertise of many different engineering disciplines, engineers who specialize in robotics often have degrees in mechanical, manufacturing, electrical, electronic, or industrial engineering. Some colleges and universities now offer robotics engineering degrees. Robotics courses typically include training in hydraulics and pneumatics, CADD/CAM systems, numerically controlled systems, microprocessors, integrated systems, and logic. It usually takes four to five years to earn a bachelor's degree in engineering. Some colleges offer work-study programs in which students receive on-the-job training while still in school. Most universities that offer robotics courses have well-equipped labs with lasers and CADD/CAM equipment.

For some positions, and to advance in the field, you need a master's degree or PhD. A PhD is required to teach in this field as well as for most high-level research positions. A master's degree requires one to two years of additional schooling, while a PhD takes three to five additional years in school.

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Robotics is a rapidly growing field that has applications in diverse industries. A robotics engineer designs robots, maintains robots, develops new applications for robots, and conducts research to expand the potential for robots. Robots can be used in a variety of industries, including manufacturing, agriculture, aerospace, mining, and medicine. Robots are used to perform tasks too dangerous or dirty for humans to perform. Robotics engineers use computer-aided design and drafting (CADD) and computer-aided manufacturing (CAM) systems to perform their tasks. Robotics research engineers design robotic systems and research methods to manufacture them economically. Robotics engineers who work for robot manufacturers are sometimes called robotics test engineers or automation system engineers. These engineers apply the robotic system to a particular use on a manufacturing assembly line. They also create an integrated environment between people and machinery. Leaders in this field work on creating experimental mobile robots for space research (like the Mars rovers) and medical uses.

Robotics engineers must be familiar with logic, microprocessors, and computer programming so that they can design the right robot for each application. They must also prepare specifications for the robot's capabilities as they relate to the work environment. In addition, robotics engineers are responsible for developing cost proposals, efficiency studies, and quality-control reports.

Most robotics engineers are employed by private robot manufacturers or robot users. Some engineers work in military and space programs. Others work for colleges and universities or vocational and trade schools.

Most robotics engineers go to work in offices, manufacturing plants, or laboratories. Manufacturing plants maybe noisy, depending on the industry. They may also work on a factory floor where they monitor or solve on-site problems. Many robotics engineers work a standard 40-hour week. At times, deadlines or design standards may bring extra pressure to a job, requiring engineers to work longer hours.

Do you have a specific question about a career as a Robotics Engineer that isn't answered on this page? Post your question on the Science Buddies Ask an Expert Forum.

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Robotics Engineer | Science & Engineering Career

Timing is everything. Robots, it seems, are lucky that way.

The global pandemic has sidelined workers across an unthinkable swath of sectors during a particularly tight labor market. Automation solutions that were unthinkable a twenty years ago have blossomed thanks to the convergence of technologies like machine vision, machine learning & AI, open-source robotic operating systems, and mobile components and sensors. A global problem, meet futuristic solution.

Even in a turbulent market (and maybe especially in a turbulent employment environment), investors seem willing to back robots. The latest example: ForwardX Robotics, a Beijing-based robotics firm specializing in logistics, just announced a new round of Series B+ funding in the amount of $15 million, bringing the company's total funding to more than $40 million.

There are plenty of other examples. SoftBank-backed BrainCorp, which makes robotic scrubbers for, among other applications, healthcare just raised $36 million.

"We are seeing huge challenges for supply chain leaders across the logistics and manufacturing industries, from growing labor shortages and consumer expectations to a greater need for flexibility," explains Nicolas Chee, founder, and CEO of ForwardX Robotics. "Our AI-based automation solutions allow our customers to adapt to a rapidly changing landscape and boost their productivity and efficiency three-fold. With the fallout of COVID-19 already here, enterprises will be looking to futureproof their operations and we're going to be there with them as they make the transition."

Overall, the market for autonomous mobile robots (AMRs) and autonomous ground vehicles (AGVs) is forecasted to generate over $10bn by 2023 according to Interact Analysis, and that prediction relies on data from before the COVID-19 pandemic.

This certainly didn't happen overnight. The seeds of a robotic revolution have been sprouting for over a decade, going back to research lab Willow Garage and the groundbreaking robotics research that began coming out of DARPA contests in the early-2000s. Collaborative robots, still a small fraction of the overall automation industry, have become insanely good at performing repeatable tasks around humans. Mobile robots are whizzing down logistic warehouse aisles and taking inventory of products at Walmart.

All the while the party line in the industry has been that the robots aren't meant to replace workers but to make work easier for talented professionals. Marketing professionals get oodles of money to sell that premise, and it's a palatable sales pitch, certainly easy enough to swallow in a labor crunch during a strong economy when the creep of automation is tough to quantify in terms of human toll.

The pandemic may change that. Workers are furloughed in all sorts of industries, companies are closing shop or tightening belts, and that deferential tone toward the worker, whom automation was touted as helping, has been replaced by another pitch: Automation can stand in where human workers have to stay home. No one's saying it, but investors might as well be with their wallets.

"Most of the automation equipment in the industry is used to replace manual labor in repetitive and simple processes. However, in the future, we believe collaborative robots will increasingly participate in complex production processes," says Felix Yang, Accelerated Digitalization Lead, Greater China at SF DHL China, a ForwardX customer and the largest third-party logistics provider in the world.

That's about the long and short of it. Workers are an uncertain bet in a world where every human might have to stay home for a few months to avoid transmitting an infectious disease. Like it or not, robots are primed to take up the slack.

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Robots are taking over during COVID-19 (and there's no going back) - ZDNet