Category Archives: Robotics

ChatGPT and Epic Systems

This years buzzword in academic and now business technology is ChatGPT. Epic Systems, Microsoft, and OpenAI (the owners of ChatGPT) have announced the release of the next evolution in artificial intelligence (AI) called GPT-4. This new system integrates AI with electronic health records with the hopes of advancing medical care and associated services.

In-basket messaging is the first section of electronic health records that will be significantly changed. Typically, provider emails, phone calls, and patient messages are loaded in chronological order. With the integration and advancement of AI, in-basket messages are prioritized and distributed to make the most efficient use of provider time.

Presenters at HIMSS 2023 lectured about the potential application of language models like GPT-4 for automating clinical documentation, decision support, and prescribing. This advancement is done by software that has been trained using a language model on a large dataset of health care-related messages and responses. Eventually, it may be possible to develop a system that can generate appropriate responses to different types of in-basket messages automatically.

However, it is important to note that the use of such systems would need to be carefully monitored and controlled to ensure that patient privacy and confidentiality are maintained at all times. Additionally, a health care provider must carefully review any automated response generated by a language model to ensure that it is accurate and appropriate for the specific context.

Mixed reality (medical extended reality)

Medical extended reality (MXR) or the use of virtual, augmented, and mixed reality technologies in health care is a relatively new field that is being explored for its potential to improve patient care and medical training. Exhibits at the conference demonstrated a variety of ways that MXR can be used, such as medical training, patient education, pain management, and patient rehabilitation.

In the realm of medical training, MXR can be used to simulate medical scenarios and procedures for training purposes. Medical students, nurses, and training allied professionals can use virtual and augmented reality to practice surgical procedures, diagnose medical conditions, or learn about human anatomy.

Medical extended reality can also be used to educate patients about their medical conditions and treatment options. For example, virtual reality can be used to show patients what happens during a surgical procedure or how their medications work in their bodies. It is hoped that using this advanced technology can help in some of the most pressing aspects of modern medical care, such as pain management. For instance, it can be used to distract patients from pain and discomfort post-medical procedures, similar to using a mirror box to relieve a patients pain after a limb amputation.

Lastly, MXR has the potential to aid in the rehabilitation of patients. Virtual and augmented reality can be used to simulate real-world scenarios and activities to help patients recover from injuries and improve their motor skills. There are a number of potential ways to improve patient outcomes and enhance medical education and training. However, it is important to note that MXR is still in the early stages of development, and more research is needed to fully understand its potential benefits and limitations.

Robotics (Cobot)

ChristianaCare has integrated cobots, short for collaborative robots; it is a type of robot designed to assist their medical staff. Cobots complete various tasks throughout the hospital, including reducing the need for human workers to move heavy or bulky items. This can help reduce the risk of workplace injuries and improve efficiency. Cobots are also being used at pharmacies to automate tasks such as medication dispensing and inventory management. It is theorized that this type of automation can help reduce errors and improve efficiency. Overall, cobots are not replacements for human workers but rather a tool to augment their capabilities and improve their working conditions.

Fast Healthcare Interoperability Resources (FHIR)

Fast Healthcare Interoperability Resources intend to deliver the exchange of health care information between different EHR systems. This product helps existing EHR software come into compliance with the EHR interoperability requirements created by the 21st Century Cures Act. Unfortunately, there needs to be much improvement for FHIR to be more meaningful.

Another exciting advancement announced at the HIMSS 23 conference was the partnership between Oracle Health and Athena Health to explore the potential use of biometrics (face recognition directory) to verify the identity of providers. This could be used to increase efficiency for prescribing controlled substances. Many of these exciting developments are still in the planning stages and may not come to fruition.

Afua Aningis a physician informaticist.

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Seen at HIMSS: the latest innovations in artificial intelligence, mixed ... - Kevin MD

LAS VEGAS, June 29, 2023 /PRNewswire/ --KEENON Robotics proudly participated in and sponsored The Hospitality Show 2023, showcasing it's innovative hotel robotics technology and solutions. As a leading global robotic service provider, KEENON Robotics delivered an exceptional robot service experience to attendees, highlighting their commitment to advancing the service robot industry.

The Hospitality Show, a premier hospitality industry event in North America, is the brainchild of AHLA (The American Hotel and Lodging Association, the largest hotel association in the U.S.) and Hotel Management Magazine (the premier source of information about the hotel industry for more than 140 years). It is one of the main hospitality industry event in North America, aimed at driving operational efficiency and profitability in hotels.

As an official sponsor, KEENON Robotics showcased seven hotel and restaurant robots, with BUTLERBOT W3, DINERBOT T9 PRO and GUIDERBOT G2 stationed in the exhibition hall to provide services for information consultation, guidance, and distribution of exhibition materials to attendees. Attendees were impressed by the robots' capabilities and their significant contribution to streamlining the exhibition front desk.

KEENON BUTLERBOT W3 delivered a personalized and privacy-focused hotel service with front desk reception and 24-hour room delivery capabilities. These robots autonomously navigated elevators, optimizing workflow and enhancing operational efficiency. They also minimized human errors, provided real-time data analysis, and assisted hotel management in decision-making, resulting in improved effectiveness and profitability. By enhancing service efficiency and reducing operating costs, KEENON BUTLERBOT alleviates the workload on staff, allowing them to focus on delivering exceptional customer experiences.

KEENON Robotics eagerly anticipates collaborating with industry stakeholders to explore the future of the hotel industry and collectively work towards intelligent, efficient, and sustainable hotel services.

About KEENON Robotics:

KEENON Robotics is a global leader in cutting-edge service robots and solutions that transform businesses and enhance customer experiences. Since 2010, KEENON Robotics has been at the forefront of the service robot revolution, leveraging the latest technologies in robotics and cloud computing. Their advanced robots cater to various sectors, including delivery, hospitality, retail, and education. As a trusted partner, KEENON Robotics is dedicated to creating value, driving innovation, and contributing to the growth of the service robot industry.

SOURCE Keenon Robotics Co., Ltd.

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KEENON Robotics Empowers Future of Hotel Experiences as ... - PR Newswire

Here is a brief overview of investing in robotics in 2023 will offer the potential for returns

Investing in robotics can be a promising opportunity for investors looking to tap into the future of technology. The robotics industry is experiencing rapid growth and is poised to revolutionize various sectors, including manufacturing, healthcare, transportation, and more.

The growth of robotics is mainly influenced by automation. As businesses strive for increased efficiency, they turn to robotics to streamline operations and reduce costs. The advantages of investing in robotics are providing exposure to an industry with immense potential, the robotic companies operating in niche markets create opportunities for differentiation, and investing allows diversification within the broader technology sector, reducing risk. This remarks that advancements in the field of robotics have been revolutionalizing the way we live and work. This brief overview of investing in robotics in 2023 highlights key trends, potential investment areas, and considerations for those interested in venturing into the world of robotics.

The increasing adoption of automation across various sectors creates a strong demand for robotics solutions. This demand is expected to fuel significant revenue growth for robotics companies. These companies can capitalize on the expanding market and drive their revenue growth by offering advanced technologies and robotic systems that enhance efficiency, reduce costs, and improve productivity.

The robotics market continues to expand rapidly, driven by increased automation, advancements in artificial intelligence (AI), and the need for enhanced productivity and efficiency across various sectors. In 2023, the market is projected to reach new heights, with a focus on the following trends:

While robotics encompasses a wide range of applications, several key areas stand out as potential investment opportunities:

Investing in robotics, like any other industry, requires careful evaluation and consideration of several factors:

However, its important to consider potential risks. Rapid technological advancements may lead to obsolescence, and competition in the industry is intensifying. Additionally, regulatory challenges and ethical concerns surrounding robotics could impact the industrys growth.

Overall, investing in robotics can be an exciting venture, offering the potential for substantial returns. As with any investment, thorough research, diversification, and a long-term perspective are essential to make informed investment decisions in the rapidly evolving robotics landscape.

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Brief Overview of Investing in Robotics in 2023 - Analytics Insight

Two years after introducing LiBiao robotic parcel sortation technology at its sorting centre in Athens, Hellenic Post (ELTA), the state-owned provider of postal services in Greece, has introduced additional robots, chutes and induction stations at the site.

The investment means throughput capacity at the Athens facility has been significantly increased and allows ELTA to provide next-day delivery services to several additional destinations throughoutGreece.

In all a total of 120 LiBiao autonomous mobile robots (AMR) are now deployed at the sorting centre in Athens. They scan each parcels barcode, weigh the package and, directed by sensors, empty it into the appropriate mail sack sited around the platform on which the robots travel.

Initially introduced as part of ELTAs digital restructuring programme which was established to tackle the growing number of parcels generated by the growth of online shopping, the AMR-based sortation solution has enabled ELTA to improve the efficiency of its workforce by assigning personnel to more productive tasks.

Before the LiBiao sorting system went live, ELTA had undertaken parcel sorting manually which was obviously extremely time consuming and labour intensive. It was also prone to errors which caused parcels to be delayed. Late deliveries were not only frustrating for ELTAs customers and courier partners but also extremely costly for the company.

Since the parcel sorting function has been handed over to the LiBiao robots the process is three times faster, ensuring next-day delivery, while errors have been virtually eliminated.

With the additional robots, ELTA can now handle close to 125,000 parcels weighing up to 10 kg every day and, because each robot only needs to be recharged for five minutes every four hours, on-site power consumption and energy costs are minimised.

Based on the performance of the first phase of the installation ELTA expect this latest investment to pay for itself within two years.

Evi Arguriadou, ELTAs head of sorting operations, comments: Since the introduction of robotic technology our Athens facility has come to be regarded as a centre of excellence within our industry. We regularly host visits from executives from other parcel delivery services companies across Europe who are interested in the technology we have deployed. We are happy and proud to do so.

LiBiao Robotics founder and CEO, Xia Hulling,commented: The initial installation at ELTA and the recent extension highlights perfectly why LiBiao autonomous mobile robot (AMR)-based sortation technology is proving an attractive alternative tothe high CapEx fixed tilt-tray and cross-belt conveyor-based systems that have historically been used within many busy parcel and e-commerce operations.

Xia Hulling continued: With no fixed infrastructure requirements, modular AMR-based systems are scalable and offer complete flexibility with additional robots easily introduced as and when they are needed.

And, I am pleased to say that several of the companies that have visited ELTAs Athens site to see the system in operation for themselves have become LiBiao customers too! she added.

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Greek post office makes further commitment to Robotics parcel ... - Post and Parcel

For people who have suffered neurotrauma such as a stroke, everyday tasks can be extremely challenging because of decreased coordination and strength in one or both upper limbs. These problems have spurred the development of robotic devices to help enhance their abilities. However, the rigid nature of these assistive devices can be problematic, especially for more complex tasks like playing a musical instrument.

A first-of-its-kind robotic glove is lending a "hand" and providing hope to piano players who have suffered a disabling stroke. Developed by researchers from Florida Atlantic University's College of Engineering and Computer Science, the soft robotic hand exoskeleton uses artificial intelligence to improve hand dexterity.

Combining flexible tactile sensors, soft actuators and AI, this robotic glove is the first to "feel" the difference between correct and incorrect versions of the same song and to combine these features into a single hand exoskeleton.

"Playing the piano requires complex and highly skilled movements, and relearning tasks involves the restoration and retraining of specific movements or skills," said Erik Engeberg, Ph.D., senior author, a professor in FAU's Department of Ocean and Mechanical Engineering within the College of Engineering and Computer Science, and a member of the FAU Center for Complex Systems and Brain Sciences and the FAU Stiles-Nicholson Brain Institute. "Our robotic glove is composed of soft, flexible materials and sensors that provide gentle support and assistance to individuals to relearn and regain their motor abilities."

Researchers integrated special sensor arrays into each fingertip of the robotic glove. Unlike prior exoskeletons, this new technology provides precise force and guidance in recovering the fine finger movements required for piano playing. By monitoring and responding to users' movements, the robotic glove offers real-time feedback and adjustments, making it easier for them to grasp the correct movement techniques.

To demonstrate the robotic glove's capabilities, researchers programmed it to feel the difference between correct and incorrect versions of the well-known tune, "Mary Had a Little Lamb," played on the piano. To introduce variations in the performance, they created a pool of 12 different types of errors that could occur at the beginning or end of a note, or due to timing errors that were either premature or delayed, and that persisted for 0.1, 0.2 or 0.3 seconds. Ten different song variations consisted of three groups of three variations each, plus the correct song played with no errors.

To classify the song variations, Random Forest (RF), K-Nearest Neighbor (KNN) and Artificial Neural Network (ANN) algorithms were trained with data from the tactile sensors in the fingertips. Feeling the differences between correct and incorrect versions of the song was done with the robotic glove independently and while worn by a person. The accuracy of these algorithms was compared to classify the correct and incorrect song variations with and without the human subject.

Results of the study, published in the journal Frontiers in Robotics and AI, demonstrated that the ANN algorithm had the highest classification accuracy of 97.13 percent with the human subject and 94.60 percent without the human subject. The algorithm successfully determined the percentage error of a certain song as well as identified key presses that were out of time. These findings highlight the potential of the smart robotic glove to aid individuals who are disabled to relearn dexterous tasks like playing musical instruments.

Researchers designed the robotic glove using 3D printed polyvinyl acid stents and hydrogel casting to integrate five actuators into a single wearable device that conforms to the user's hand. The fabrication process is new, and the form factor could be customized to the unique anatomy of individual patients with the use of 3D scanning technology or CT scans.

"Our design is significantly simpler than most designs as all the actuators and sensors are combined into a single molding process," said Engeberg. "Importantly, although this study's application was for playing a song, the approach could be applied to myriad tasks of daily life and the device could facilitate intricate rehabilitation programs customized for each patient."

Clinicians could use the data to develop personalized action plans to pinpoint patient weaknesses, which may present themselves as sections of the song that are consistently played erroneously and can be used to determine which motor functions require improvement. As patients progress, more challenging songs could be prescribed by the rehabilitation team in a game-like progression to provide a customizable path to improvement.

"The technology developed by professor Engeberg and the research team is truly a gamechanger for individuals with neuromuscular disorders and reduced limb functionality," said Stella Batalama, Ph.D., dean of the FAU College of Engineering and Computer Science. "Although other soft robotic actuators have been used to play the piano; our robotic glove is the only one that has demonstrated the capability to 'feel' the difference between correct and incorrect versions of the same song."

Study co-authors are Maohua Lin, first author and a Ph.D. student; Rudy Paul, a graduate student; and Moaed Abd, Ph.D., a recent graduate; all from the FAU College of Engineering and Computer Science; James Jones, Boise State University; Darryl Dieujuste, a graduate research assistant, FAU College of Engineering and Computer Science; and Harvey Chim, M.D., a professor in the Division of Plastic and Reconstructive Surgery at the University of Florida.

This research was supported by the National Institute of Biomedical Imaging and Bioengineering of the National Institutes of Health (NIH), the National Institute of Aging of the NIH and the National Science Foundation. This research was supported in part by a seed grant from the FAU College of Engineering and Computer Science and the FAU Institute for Sensing and Embedded Network Systems Engineering (I-SENSE).

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Robotic glove that 'feels' lends a 'hand' to relearn playing piano after ... - Science Daily

To students in his University of Toronto lab, Brokoslaw Laschowski is known as the bionic professor a superhuman nickname that speaks to both his fascination with wearable robotics and passion for helping others.

Their work includes bionic prosthetic legs, exoskeletons, AI-powered smart glasses and neural interfaces.

We are trying to help individuals with physical disabilities. Its such a challenging problem, how do you design technology that interface with humans and allows them to synergistically move in a meaningful way?

For Laschowski, who says he has long been fascinated with the concept of cyborgs, computer vision can help seamlessly merge humans with machines.

Humans use their vision for path planning and control, which inspired the use of vision in autonomous cars, he says. I started looking into how we could possibly use vision with walking robots.

For the teams prosthetic leg and exoskeleton, tiny cameras allow the devices to sense their environments in real-time an idea that Laschowski says is unique to his research.

There arent many labs in the world that are using computer vision to improve human-robot walking, he says.

The teams smart glasses interact with both the exoskeleton and bionic prosthetic leg. The system works by combining computer vision and deep-learning AI to recognize the surrounding environment and adapt to obstacles and changes in terrain.

We can accurately and quickly identify features of the environment and relay that information to the bionic legs, he says.

Laschowski says he became passionate about assistive technology while he was pursuing his second masters degree at the University of Waterloo. At the time, he was working with Paralympic athletes from Team Canada on design optimization of wheelchairs using computer simulations.

He completed a PhD in engineering at Waterloo before coming to U of T to do a postdoctoral fellowship in the Temerty Faculty of Medicine.

Laschowskis drive to help others extends well beyond the realm of assistive devices.

Last year, he worked with Michael Brudno, chief data scientist for the University Health Network and a professor of computer science in the Faculty of Arts & Science, to launch a summer research program for students fleeing the Russian invasion and war in Ukraine.

As a Ukrainian-Canadian, Laschowski says the initiative is close to his heart.

We took students out of war zones and gave them a safe learning environment especially last year.

We feel a huge sense of responsibility, Laschowski says. They are under our care. We promised that we would help them while their brothers and fathers are fighting for freedom.

Oleksii Tsepa, a masters student in computer science at U of T, left his home in Kyiv on the first day of the war, with his parents urging him to go aboard. The borders were still open, he recalls. I understood that I wouldnt be able to leave Ukraine later.

He stayed in Cyprus for a couple of months before finding out about the U of T program.

I feel lucky that I qualified and that I worked with Professor Laschowski, Tsepa says. He taught me that I always have to answer myself. I understood that achievements cant be reached without putting in effort.

The effort put in by Laschowski and his team is evident in their potentially game-changing technologies, which are being tested in environments both inside and outside the lab.

I am a huge proponent of getting out of the lab as fast as possible because these devices are going to have the greatest impact in the real world. Laschowski says.

His lab is also developing neural interfaces, which would give humans direct control over the bionic prosthetic leg and exoskeleton. Far into the future, he imagines hell be working on connecting his smart glasses to a brain implant.

We could potentially map images of the walking environment from the glasses directly onto the visual cortex of the brain essentially bypassing the eyes and giving users bionic vision, he says.

If somebody has macular degeneration or some age-related visual impairment, we may be able to use the smart glasses to bypass that and interface directly to the brain.

Laschowski says he believes humans are beginning to go through a technological evolution one that he is helping to make reality.

If we could allow the visually impaired to see and the paralyzed to walk through advances in technology those are some of my career goals.

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'Bionic professor' aims to transform the field of wearable robotics - University of Toronto

The energy sector is constantly evolving, and as the world moves towards cleaner and more sustainable energy sources, the need for efficient and safe maintenance of energy infrastructure becomes increasingly important. One of the most promising solutions to this challenge is the adoption of robotics. The integration of advanced robotics technologies into the maintenance of energy infrastructure offers numerous advantages, including enhanced safety, increased efficiency, and reduced costs.

Safety is a top priority in the energy sector, and the use of robotics can significantly improve the safety of workers involved in the maintenance of energy infrastructure. Many maintenance tasks, such as inspecting pipelines, power lines, and wind turbines, can be hazardous and require workers to operate in dangerous environments. By utilizing robotics, these tasks can be performed remotely, reducing the risk of accidents and injuries. For example, drones equipped with high-resolution cameras and sensors can inspect power lines and pipelines from a safe distance, while robotic crawlers can navigate through confined spaces to perform inspections and repairs.

In addition to improving safety, robotics can also increase the efficiency of energy infrastructure maintenance. Traditional methods of inspection and maintenance can be time-consuming and labor-intensive, often requiring manual processes and the use of heavy equipment. Robotics can automate many of these tasks, allowing for faster and more accurate inspections and repairs. For instance, autonomous underwater vehicles (AUVs) can be used to inspect offshore oil and gas platforms, while robotic arms can perform maintenance tasks on wind turbines, such as cleaning and repairing blades. This increased efficiency can lead to reduced downtime and improved productivity, ultimately resulting in cost savings for energy companies.

The adoption of robotics in energy infrastructure maintenance can also lead to significant cost savings. The use of robotics can reduce the need for manual labor, which can be expensive and difficult to find, especially in remote locations. Additionally, the increased efficiency and reduced downtime associated with robotic maintenance can lead to lower operating costs. Furthermore, the use of robotics can extend the lifespan of energy infrastructure by enabling more frequent and thorough inspections, identifying potential issues before they become critical and costly to repair.

Another advantage of adopting robotics for energy infrastructure maintenance is the ability to collect and analyze large amounts of data. Advanced sensors and cameras on robotic systems can capture high-resolution images and other data during inspections, which can be used to create detailed digital models of the infrastructure. This data can then be analyzed using artificial intelligence and machine learning algorithms to identify patterns and trends, allowing for predictive maintenance and more informed decision-making. This data-driven approach can help energy companies optimize their maintenance strategies, further reducing costs and improving the overall performance of their infrastructure.

In conclusion, the adoption of robotics in the maintenance of energy infrastructure offers numerous advantages, including enhanced safety, increased efficiency, and reduced costs. As the energy sector continues to evolve and the demand for clean and sustainable energy sources grows, the integration of advanced robotics technologies will become increasingly important in ensuring the safe and efficient operation of energy infrastructure. By embracing robotics, energy companies can not only improve the safety and well-being of their workers but also ensure the long-term sustainability and success of their operations.

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The Advantages of Adopting Robotics for Energy Infrastructure ... - EnergyPortal.eu

NEW DELHI: Five mechanical and electrical engineers, among the nine accused chargesheeted by NIA in the IS Shivamogga conspiracy case, were asked by their foreign-based handler to pursue a course in robotics to pick up skills to carry out terrorist attacks as part of terror group Islamic State's subversive agenda for India. NIA on Friday filed a supplementary chargesheet in the case, charging the nine accused with carrying out a trial IED blast in Shivamogga, Karnataka, reconnaissance of multiple targets and arson of properties and vehicles to spread terror among people as part of an anti-India IS conspiracy. The chargesheet names Mohamed Shariq (25), Maaz Muneer Ahmed (23), Syed Yasin (22), Reeshaan Thajuddin Sheikh (22), Huzair Farhan Baig (22), Mazin Abdul Rahman (22), Nadeem Ahmed K A (22), Zabiulla (32) and Nadeem Faizal N (27). All of them belong to Karnataka. The accused have been charged under UA(P) Act 1967, IPC, and KS Prevention of Destruction and Loss of Property Act, 1981. Maaz Muneer Ahmed and Syed Yasin had figured in the original chargesheet filed in March this year, but now other offences have been invoked against them in the supplementary chargesheet. NIA on Saturday said its investigations have revealed that Mohamed Shariq, Maaz Muneer Ahmed and Syed Yasin had hatched a criminal conspiracy, in connivance with an IS operative based abroad, to promote terror & violence on the directions of the proscribed terror outfit, in the region. The trio had actively radicalised and recruited the co-accused with the intention to disturb the national security, unity and sovereignty of the country, said the agency. The online handler of the chargesheeted accused had funded them through crypto currencies, according to NIA. The Shivamogga IS case was initially registered by the Shivamogga rural police on September 19,2022, and later taken over and re-registered by NIA on November 15, 2022.

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Upskill with course in robotics, IS handler told terrorists: NIA - Times of India

Coral reefs are considered to be the most biodiverse ecosystems on the planet. They provide societies around the world with$375 billionin ecosystem services each year, but theyre in trouble.

As of this year, the world has already lost halfof its coral reefs and is on track to lose up to 90 percent by 2050, even if global warming is capped at 1.5 degrees Celsius. While governments and NGOs around the world are making policies and enacting programsto stop the demise of coral reefs, one company is turning to artificial intelligence (AI) and robotics.

Coral Maker, founded by coral biologist Taryn Foster, manufactures and deploys premade coral skeletons seeded with coral fragments. The use of premade coral skeletons significantly reduces the number of years corals take to reach their mature, adult size.

Coral Makers goal is to quickly scale up in order to restore 250 acres of coral reefs annually. And it's utilizing the robotics and engineering expertise of design software giant Autodeskto help make that happen.

We are always seeking new ways of engaging with innovators and entrepreneurs. They push our thinking, said Rick Rundell, senior director of research programs at Autodesk Research. Coral Maker first joined us through a program at our technology center that allows people to do their own technology work. Dr. Taryn Foster collaborated with our researchers working in robotics and AI.

The first project that Foster and the Autodesk Research team collaborated on was automating the placement of seed coral into a frame or skeleton. Then, Foster worked with a different team to design and manufacture the coral skeletons utilizing recycled construction materials. By providing underwater skeletons for the coral to inhabit, they can more quickly grow to maturity and propagate themselves.

Coral Maker can now manufacture 10,000 coral skeletons per day, and each skeleton holds six to eight coral fragments. The manufacturing equipment is deployed at coral reefrestoration sites in order to reduce shipping and transportation emissions. Foster hopes to deliver tens of millions of coral fragments to restoration sites annually.

The global risk is that the reefs will die faster than they can reseed, Rundell said. Coral Maker is seeding reefs in areas that will be more suitable for reefs in the long term. They are moving them to places where temperatures will be more suitable as the oceans warm.

While millions of hectares of coral reefs are currently at risk of degradation, bleaching or die-offs, traditional reef restoration projects using manual methods restore less than one hectare per year. To protect and restore reefs at scale, restoration must advance quickly which is why Coral Maker utilizes automation, robotics and AI.

One of the things that is so challenging when youre dealing with big, global problems like coral reef degradation is that its not always clear as to what one person can do, Rundell said. We know we need to cool the planet, but that is difficult. It is inspiring to our researchers and employees to be involved with a group like Coral Maker which is biting off a big, challenging problem in a way that seems like it could really work. They can help make it successful. Thats exciting for us.

Images courtesy of Coral Maker andAutodesk Research

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Saving the World's Coral Reefs with AI and Robotics - TriplePundit

The rise of automation in various sectors has made pursuing a career in robotics a practical option. However, if you have ambitions of delving into the field of robotics and coding, you should be prepared to tackle difficulties by utilizing your coding skills.

When students utilize an essay writing service to complete their assignments, they have the opportunity to integrate robotics education into their schoolwork. This frees up additional time for them to concentrate on coding projects and develop a portfolio.

No matter how old or what kind of education someone has, coding can be learned by anyone. Here are some practical methods to acquire coding and robotics skills.

To pursue a profession in robotics, it is necessary to acquire proficiency in a programming language. For beginners, it is advisable to prioritize a language that is devoid of intricate data structures or algorithms.

Once you have made a decision about which programming language to learn, establish a specific timeframe and begin your learning journey. While certain languages may be comprehensible within a few weeks, others demand daily practice for several months.

HTML and CSS, while not considered traditional programming languages, are markup languages that are suitable for beginners. Eventually, you have the option to transition to more advanced languages like JavaScript or Python.

There are numerous online coding courses available that range from introductory HTML to advanced robotics programming. Some of these courses are free, while others have a subscription fee.

Visit websites such as freeCodeCamp, w3Schools, and Codecademy and choose courses based on the amount of time you can dedicate each day.

More individuals, especially students, are motivated to utilize legit paper writing services that can effortlessly write my thesis while they learn coding due to their accessibility. Prior to enrolling in any course, it is advisable to carefully examine the reviews on the website. If there is an absence of reviews, one can explore the option of free trials in order to gain an understanding of their teaching style prior to making a commitment.

For any inquiries regarding programming, YouTube is the ultimate platform to turn to. A multitude of videos related to robotics and coding can be found on this online video-sharing platform. It offers a valuable resource for beginners, providing access to expert-led videos and coding shortcuts.

Additionally, YouTube permits global interaction with programmers by enabling individuals to leave comments on videos, thus offering supplementary guidance to those new to programming.

In addition to that, there are more options available. You have the ability to watch YouTube tutorials and practice at the same time. People who are new to the subject can also take advantage of live classes and webinars provided on the platform in order to broaden their understanding.

If you want to develop a strong background in programming, it is recommended that you engage in reading introductory books on robotics and coding. Although it is not mandatory to read these materials prior to coding, they can be beneficial in helping you understand fundamental programming principles.

Look for crash courses and books that cover HTML/CSS, JavaScript, and Python. These resources provide explanations for coding concepts and models that will be helpful in managing complicated projects.

Studying programming literature can provide a valuable academic understanding. Nevertheless, acquiring an academic degree is not necessary for enhancing ones abilities and imaginative thinking.

Practicing robotics and coding can be made less monotonous with the help of certain tools. For instance, IDEs such as Visual Studio Code provide useful functionalities like color coding, find-and-replace, and dark mode, which aid programmers in generating well-organized code.

In English, you can utilize your console, which is a text-based interface, to find files and perform actions on your computer. Additionally, project management tools enable you to modify timelines and handle different aspects of a coding project simultaneously.

Having troubleshooting tools is crucial for novice programmers. If you encounter any bugs, a debugger can help identify the issue and provide valuable solutions.

In order to learn coding, the most effective approach is to practice regularly and consistently. There are no shortcuts or quick fixes to becoming proficient in coding. Although reading books and enrolling in courses can be helpful, it is essential to actually write and implement code in order to truly learn and improve.

This is the reason why it is important for you to create coding projects. Engaging in a coding project allows you to gain practical experience while you are learning. It can be a program of any duration, whether short or long, that you develop using the programming language of your preference.

In general, online courses often offer coding assignments as you progress. If you are learning by yourself, consider creating a calculator, time converter, address book, or a hangman game.

A group of programmers on the internet can provide support and encouragement to help you improve your coding skills. You have the opportunity to join coding communities on various social media platforms where you can connect with like-minded individuals. These communities can also assist in finding mentors who offer guidance and feedback to make your learning process smoother.

In addition to online communities, it is important to actively search for local events and gatherings taking place in your vicinity. Participating in hackathons and technology-related events not only provides opportunities to connect with other experts in your field but also opens doors to improved career prospects.

Virtual coding boot camps are a great option for enhancing your programming knowledge and skills. These boot camps are typically led by experts and are specifically designed to assist learners in improving their abilities and attaining more favorable prospects.

Online boot camps like Simplilearn, HackerRank, and Code Academy offer opportunities for learners to acquire proof of their participation, which could prove advantageous while seeking employment.

Signing up for a boot camp also provides the opportunity to form connections with individuals who share common interests. Within this community, you can readily seek assistance, offer help to others, and receive valuable insights and guidance for your professional journey.

Are you prepared to put your coding abilities to the test? Participating in robotics competitions and hackathons will provide you with the opportunity to display your skills, innovations, and projects in front of an audience.

They provide an opportunity for you to try out your innovations and receive input from professionals and enthusiasts. If you are unsure about joining a competition, you can always take part in one to gain confidence. Afterward, familiarize yourself with how hackathons operate and determine if it is an event that you would enjoy participating in.

If you want to become skilled in coding, it is necessary to code on a daily basis. While robotics may present difficulties, with regular practice, one can achieve expertise. To lessen your workload, you have the option to assign your essays to a reputable online research paper writing service.

Begin by selecting the programming language you desire to master, and then proceed by enrolling in an internet-based course. It might be necessary for you to engage in reading materials, viewing tutorial videos, and utilizing coding aids for enhanced ease and productivity.

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How To Learn Robotics and Coding - StartupGuys.net