Imagine being able to turn a digital model into a physical object with the precision of a craftsman and the speed of a computer. That’s essentially what SLS printing does – it’s a kind of 3D printing that can bring even the most intricate robotic designs to life.

For those new to the term, it stands for Selective Laser Sintering and operates by fusing small particles of material into a solid structure with a laser. This method has become increasingly significant in the field of robotics, offering unparalleled versatility and durability.

Understanding the Basics of Selective Laser Sintering (SLS)

At its core, SLS printing allows designers to create parts that are robust and ready for action. Unlike older 3D printing methods, SLS doesn’t need support to hold an object in place as it’s being printed. This freedom lets creators dream up and actualize complex shapes that would be either impossible or too costly to make with conventional manufacturing.

Robots, for instance, require components that must fit together perfectly, and SLS printing is just the tool for the job, helping engineers iterate quicker and push the bounds of what’s possible. Beyond just fusing particles, SLS printing harnesses the power of precision to create objects layer by layer, resulting in high-resolution products that maintain their shape over time.

It’s a cornerstone technology that empowers myriad applications in various fields, not least of which is the dynamic and demanding domain of robotics. Each layer built by the SLS process compounds the strength and intricacies of the final product, merging the art of design with the science of engineering.

Comparing SLS to Traditional Manufacturing Methods in Robotics

SLS printing has effectively challenged traditional manufacturing techniques, particularly in the robotics arena. Robots require parts that are both lightweight and strong, and SLS is adept at producing such items with ease.

Custom gears, joints, and casings can be crafted in a fraction of the time and cost it would take with methods like injection molding or CNC machining. The result? A surge in innovation and creativity as designers and engineers can experiment without worrying about the limits of traditional manufacturing.

The Impact of SLS on the Strength and Precision of Robot Components

Strength and precision are non-negotiable when it comes to robotics. Whether it’s a robotic arm used in manufacturing or a service robot helping customers, every part needs to work seamlessly.

SLS printing excels here as it creates parts that are inherently more robust due to the way the laser sintering process bonds the material. This methodology not only constructs tougher components but also maintains a high level of detail, ensuring that each piece performs exactly as designed.

Case Studies: Real-World Robots Improved by SLS Technology

Take the example of a search and rescue robot, deployed in areas too dangerous for humans. The durability of its SLS-printed parts means it can withstand harsh environments while still performing delicate operations.

Or consider customized prosthetic limbs, 3D printed to match the precise specifications of their users, enhancing comfort and functionality. SLS printing has brought about real-world changes, demonstrating its solid grip on innovation within robotics.

Streamlining the Path From Design to Deployment in Robotics

Rapid prototyping is one of the major advantages that springs from the adoption of SLS printing. A design that once took months to go from concept to reality can now be held in your hands in a matter of days. This rapid turnaround is not just convenient; it’s revolutionary.

It allows for swift troubleshooting and refinement, reducing development time for robots significantly. This speed is invaluable, particularly when pushing the limits of what robots can do, enabling a quick response to the fast-evolving needs of various industries.

Customization at Its Finest: The Personalized Touch of 3D Printing in Robotics

Every person is unique, and so can their robotic helpers. SLS printing brings customization to the forefront of robotics. Businesses can tailor robots for specific tasks, like aiding in surgery or handling intricate assembly jobs.

In education, robots can be designed to interact with students in personalized ways, fitting diverse learning environments. This level of customization isn’t a distant dream; it’s possible right now, thanks to the precision and flexibility of SLS printing technologies.

Breaking Barriers: The Affordability and Accessibility of Advanced Robotics

One of the most exciting aspects of SLS printing is its potential to level the playing field. With lower production costs and minimized material waste, SLS makes it possible for smaller players to get their robotic innovations off the ground. This means startups and educational institutions can now develop robots without the hefty price tag.

It’s a game-changer for countries and communities that previously couldn’t afford to participate in the robotics revolution, proving that high-tech solutions can be both accessible and equitable.

Navigating Challenges and Embracing Innovation in Robotic 3D Printing

While SLS printing is impressive, it’s not without its challenges. Materials used in SLS can be expensive and the process requires careful control, but strides are being made every day. As for the future? Think artificial intelligence.

Integrating AI into 3D printing could further enhance efficiency and quality, potentially leading to smarter, more intuitive robots. However, with great power comes great responsibility, and as we stand on the brink of such exciting technological advancements, ethical considerations around the use and impact of 3D-printed robots remain crucial.

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In the dynamic landscape of Industry 4.0, where technological advancements are reshaping the way businesses operate, the integration of Robotic Process Automation (RPA) stands as a pivotal force. As companies strive for enhanced efficiency, reduced costs, and streamlined operations, the synergy between RPA and Industry 4.0 is revolutionizing the manufacturing and logistics sectors.

For companies seeking to stay competitive in the evolving landscape of industry 4.0, the strategic integration of RPA is paramount. Mobile Industrial Robots (MIR), a leading provider of Autonomous Mobile Robots (AMRs), offers tailored solutions to enhance warehouse and logistics operations. Explore how AMRs optimize workflows, internal logistics, labor costs, and time-consuming tasks.

Tracing the Path to Industry 4.0

Industry 4.0, coined in 2011 by the German government, represents a revolutionary phase in manufacturing history. Stemming from a series of industrial revolutions, including the mechanization of the First Industrial Revolution, mass production of the Second and digital integration of the Third, Industry 4.0 embraces the convergence of cyber-physical systems, the Internet of Things (IoT) and advanced technologies like artificial intelligence. This paradigm shift envisions smart factories where interconnected systems collaborate intelligently, marking a new era of efficiency and automation.

The journey to Industry 4.0 has been punctuated by technological milestones such as the widespread adoption of computers in manufacturing during the late 20th century and the increasing prevalence of digital connectivity. Today, the industrial landscape is characterized by the seamless integration of data analytics, cloud computing, and IoT, fostering a dynamic environment where machines communicate and adapt in real-time, propelling industries towards unparalleled levels of productivity and innovation.

A Paradigm Shift in Manufacturing

The advent of Industry 4.0, synonymous with the Fourth Industrial Revolution (4IR), marks an epochal shift in the landscape of manufacturing. This paradigmatic transformation is propelled by the convergence of cutting-edge digital technologies, heightened connectivity, and the integration of intelligent automation. At its essence, Industry 4.0 envisions the emergence of smart factories, where cyber-physical systems collaborate seamlessly, orchestrating a symphony of data exchange to inform and guide decision-making processes.

This era of pervasive digitalization is not merely a leap forward; it’s a revolutionary leap into an era where RPA stands as a fundamental building block, fortifying the foundations of smart manufacturing. In this era of innovation and interconnectedness, RPA emerges as a pivotal force, redefining the very fabric of manufacturing processes by infusing them with unprecedented agility and efficiency.

The Convergence of RPA and Industry 4.0

Robotic Process Automation, a subset of artificial intelligence, involves the use of software robots to automate repetitive tasks, liberating human resources for more complex responsibilities. In the context of Industry 4.0, RPA becomes the driving force behind optimized workflows, ensuring that routine and time-consuming tasks are executed with precision and speed.

From automating data entry and inventory management to streamlining order processing, RPA brings unparalleled efficiency to manufacturing workflows. The seamless integration of RPA technologies ensures that data flows seamlessly across various systems, minimizing errors and enhancing overall productivity. Companies adopting RPA in their Industry 4.0 initiatives witness a significant reduction in operational costs while achieving higher throughput.

Internal Logistics Reinvented

The impact of RPA extends beyond manufacturing processes, infiltrating the realm of internal logistics within warehouses and distribution centers. As companies navigate the complexities of modern supply chains, the strategic implementation of RPA ensures that internal logistics are not only optimized but also responsive to dynamic demands.

In the logistics sector, RPA plays a crucial role in automating order fulfillment processes, inventory tracking, and even route optimization for goods transportation. The result is a more agile and adaptable internal logistics system that can swiftly respond to changes in demand, ensuring that products reach their destinations with speed and precision.

The Strategic Investment in Automation

One of the most significant advantages of Industry 4.0 manufacturing is the strategic reduction in labor costs. While concerns about job displacement are valid, the focus here is on augmenting human capabilities rather than replacing them. RPA handles routine tasks, allowing human workers to concentrate on more complex and strategic aspects of their roles.

By automating repetitive tasks that are prone to human error, RPA not only improves accuracy but also ensures consistent performance 24/7. The result is a substantial reduction in labor costs, enabling companies to allocate human resources strategically and invest in upskilling employees for higher-value roles.

Trustworthy Integration

As companies embark on the journey of industry 4.0 applications, trustworthiness becomes a critical consideration. The strategic partnership with a trusted provider, such as MIR, ensures that the integration process is seamless and aligned with the unique needs of each business.

RPA technologies, when implemented correctly, enhance operational efficiency without compromising the integrity of data or the reliability of systems. The robotic process automation industry 4.0 offers businesses the assurance that the solutions provided are reliable and secure, and contribute to the overall success of their Industry 4.0 initiatives.

Conclusion

In conclusion, the synergy between Robotic Process Automation and Industry 4.0 is reshaping the manufacturing and logistics landscape. By optimizing workflows, reinventing internal logistics, and strategically lowering labor costs, RPA becomes a catalyst for efficiency in the Fourth Industrial Revolution.

As companies seek to navigate the complexities of Industry 4.0, MIR stands as a reliable partner, offering Autonomous Mobile Robots that further enhance the transformative power of automation. Embrace a future of efficiency, precision, and innovation with the strategic integration of RPA and Industry 4.0 technologies.

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Cybersecurity is an ever-evolving field, especially in today’s digital age, where technological advancements are at their peak. The integration of robotics with emerging SMS phishing alert tools represents a significant leap forward in this domain. This article delves into how this integration is revolutionizing cybersecurity, the challenges faced, and what the future may hold.

The Advent of Robotics in Cybersecurity

The integration of robotics in cybersecurity is a relatively new but rapidly developing area. Robots, driven by artificial intelligence (AI) and machine learning algorithms, are now being deployed to handle complex cybersecurity tasks. This includes monitoring networks for suspicious activities, automating threat detection processes, and even responding to security incidents.

Robotics Enhancing SMS Phishing Detection

One of the most significant applications of robotics in cybersecurity is in enhancing the effectiveness of SMS phishing alert tools. These tools, such as the ‘sms phishing alert with Guardio cyber security tool‘, utilize advanced algorithms to detect phishing attempts in text messages. The integration of robotics allows for continuous learning and adaptation, enabling these systems to stay ahead of new phishing techniques.

Innovations in SMS Phishing Alert Systems

Advanced Machine Learning Models

The integration of sophisticated machine learning models represents a pivotal leap forward in the realm of SMS phishing alert systems. These models are at the heart of the system’s ability to discern phishing threats with unparalleled accuracy. Here’s a closer look at the significance of this innovation:

• Pattern Recognition: Advanced machine learning models are designed to recognize intricate patterns and anomalies within SMS text messages. They excel at sifting through vast datasets, identifying subtle cues that might go unnoticed by human analysts. By continuously analyzing and learning from new data, these models can adapt and evolve alongside the ever-changing tactics employed by phishing attackers.
• Increased Accuracy: Unlike traditional rule-based systems that rely on predefined criteria, machine learning models have the capacity to learn from both known and previously unseen threats. This adaptability results in higher accuracy rates when detecting phishing attempts. False positives are minimized, ensuring that legitimate messages are not mistakenly flagged, while false negatives, which could allow malicious messages to slip through, are also reduced.

Real-Time Threat Detection

Real-time threat detection is another groundbreaking innovation that the integration of robotics brings to SMS phishing alert systems. This capability revolutionizes the system’s ability to respond swiftly and effectively to potential phishing attacks:

• Rapid Data Processing: With robotics working in tandem with machine learning models, SMS phishing alert systems can process incoming data with lightning speed. Upon the arrival of an SMS message, an instantaneous analysis kicks into action, swiftly scouring for any telltale signs of phishing schemes. This lightning-fast real-time processing not only guarantees the swift delivery of warnings to users but also empowers them to take immediate action, safeguarding their precious personal information and valuable assets from potential threats.
• Reduced Response Time: In the world of cybersecurity, every second counts. Real-time threat detection enables SMS phishing alert systems to provide instant warnings about potential threats. This reduction in response time minimizes the window of opportunity for attackers and enhances the overall security posture.

Challenges in Integration

Ensuring Accuracy in Threat Detection

While the integration of robotics with SMS phishing alert systems holds great promise, it is not without its share of challenges. One of the foremost challenges is the imperative need to ensure the highest level of accuracy in threat detection. Here’s a closer examination of this critical issue:

• False Positives: False positives, or the incorrect identification of legitimate messages as phishing threats, can have significant repercussions. They can lead to unnecessary panic, user frustration, and potentially harm legitimate communication channels. Striking a balance between sensitivity and specificity in threat detection is crucial to minimize false positives.
• False Negatives: On the other hand, false negatives, where actual phishing messages go undetected, can be equally detrimental. They create vulnerabilities that malicious actors can exploit, potentially resulting in successful phishing attacks and data breaches. Achieving a robust system that can reduce false negatives to a minimum is a complex and ongoing challenge.
• Adaptability: Phishing attackers are constantly evolving their tactics, making it challenging to keep up with emerging threats. The integration of robotics must include mechanisms for continuous learning and adaptation. These systems should evolve alongside attackers, staying ahead of the curve by incorporating new phishing patterns and techniques into their threat detection models.

Privacy Concerns

Another significant hurdle in the integration of robotics with SMS phishing alert systems revolves around privacy concerns. Given that these systems require access to personal text messages for analysis, ensuring robust privacy safeguards and compliance with data privacy regulations is paramount. Here are the key aspects of this challenge:

• Data Access and Handling: The very nature of SMS phishing alert systems necessitates access to users’ personal text messages. This access raises questions about how data is collected, stored, and handled.
• Data Consent: The issue of access to data triggers a multifaceted inquiry into the intricacies of data collection, storage, and management.
• Regulatory Compliance: SMS phishing alert systems must adhere to these regulations, which impose strict requirements on data protection and user rights. Failure to comply can result in legal repercussions and damage to user trust.
• User Trust: Building and maintaining user trust is paramount. Users must have confidence that their personal data will be handled responsibly and for legitimate security purposes. Any breach of trust can lead to a loss of user confidence and adoption issues for these systems.

Current State of Robotics in Cybersecurity

Collaboration with Human Experts

Currently, robotics in cybersecurity works in tandem with human experts. Robots handle repetitive and data-intensive tasks, while humans intervene in more complex decision-making processes.

Emerging Trends in Robotics and Cybersecurity

There’s a growing trend towards autonomous robotics systems capable of independent decision-making in cybersecurity. However, this is still in its infancy, with several challenges to overcome.

Future Perspectives

Fully Autonomous Cybersecurity Systems

In the future, we might see fully autonomous cybersecurity systems that can operate without human intervention, making real-time decisions and responding to threats instantly.

Ethical and Legal Implications

As we move towards more advanced systems, the ethical and legal implications of robotic intervention in cybersecurity, especially concerning privacy and data protection, will need to be addressed comprehensively.

In Conclusion

The integration of robotics with emerging SMS phishing alert tools like the ‘sms phishing alert with Guardio cyber security tool’ represents a significant advancement in the cybersecurity arena. While there are challenges to overcome, especially in terms of accuracy and privacy, the potential benefits are enormous. The future of cybersecurity looks to be an intriguing blend of human expertise and robotic efficiency, creating a more secure digital world.

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In the dynamic world of financial investments, the integration of robotics and artificial intelligence (AI) marks a significant paradigm shift, particularly in the realm of long-term investment strategies. This technological revolution is reshaping our approach to investments, offering more personalized and efficient solutions.

The Emergence of Robotic Technologies in Finance

The finance sector has consistently been an early adopter of technological innovations. A report by PricewaterhouseCoopers suggests that approximately 77% of leaders plan to integrate AI technology into their operational systems by 2023. Robotics and AI are central to this transformation, especially in long-term investment planning.

AI and machine learning algorithms excel in analyzing vast amounts of data, identifying patterns, and making predictions with precision and speed beyond human capability. For example, J.P. Morgan’s LOXM program has demonstrated remarkable efficiency in executing trades, significantly reducing transaction costs.

Robo-Advisors: Personalizing Investment Strategies

Robo-advisors, powered by AI algorithms, have democratized investment advice, making it accessible beyond the traditionally wealthy clientele. These platforms use algorithms to create and manage a diversified portfolio based on an individual’s risk tolerance and investment goals. As of 2021, robo-advisors manage about $1.4 trillion in assets globally, a figure expected to grow significantly to $2.76 trillion in 2023.

Impact on Long-term Investment Strategies

Long-term investment strategies, particularly those focused on Individual Savings Accounts (ISAs), have been significantly impacted by the advent of robotics and AI.

Enhanced Risk Assessment and Management

Robotic technologies enable more sophisticated risk assessment models. By analyzing market trends and individual investment patterns, these technologies can tailor strategies that align with an investor’s long-term goals and risk appetite. This personalized approach is evident in services like a tailored ISA investment portfolio, which leverages such technologies to optimize returns.

Diversification and Asset Allocation

AI-driven platforms can dynamically adjust asset allocations in response to market changes, ensuring a well-diversified portfolio that withstands market fluctuations. For instance, during the market volatility of the COVID-19 pandemic, AI systems quickly adjusted portfolios to mitigate losses and capitalize on emerging opportunities.

Cost Efficiency

Robotic advisors reduce the need for human intervention, thereby lowering management fees. A study by Deloitte suggests that automated investment platforms could lead to a reduction in costs for firms and increase customer experience. This cost efficiency makes long-term investments like ISAs more accessible and appealing to a broader audience.

Real-world Examples and Success Stories

IBM Watson in Banking

IBM’s Watson is a powerful AI system used in various sectors, including banking. Watson Assistant is designed to enhance customer service by providing automated, AI-driven support. Banks like DBS Bank and Royal Bank of Canada have utilized Watson to enhance customer service and financial advice. It can handle customer inquiries, provide information on banking products and services, assist with transactions, and offer personalized financial advice. The tool is known for its ability to understand natural language, making interactions more user-friendly and efficient. Watson’s ability to process vast amounts of data helps in providing personalized financial insights, which can indirectly influence long-term investment decisions.

JPMorgan’s COIN Program

JPMorgan Chase’s Contract Intelligence (COIN) program uses machine learning for payment rail and deposit account ledger, enabling the transfer of U.S. Dollars held on deposit within J.P. Morgan. These programmable payments enable users to handle various automated tasks efficiently. One key feature is dynamic funding, which offers the ability to set specific rules for automatically topping up a bank account whenever there’s a shortfall. JPM Coin’s technology can support advanced payment types like DvP, PvP, and machine-to-machine payments, addressing challenges in traditional cross-border payments, and demonstrating the potential of AI in improving the accuracy and efficiency of financial operations, which indirectly affects investment management.

UBS’s AI-driven Risk Management

UBS, the Swiss multinational investment bank, employs AI and machine learning in risk management and fraud detection. Their AI systems analyze client portfolios to identify risks and optimize asset allocation, crucial for long-term investment stability. UBS’s use of AI in risk management demonstrates how robotics can enhance the security and performance of long-term investments.

AI-Driven Financial Planning by Personal Capital

Personal Capital, a digital wealth management company, uses AI to provide holistic financial planning services. While they offer investment management (investment tracking, retirement planning, savings, and budgeting), their primary focus is on providing a complete financial picture for individuals. Leveraging AI, Personal Capital analyses individual financial situations to deliver personalized investment recommendations, differentiating their services from direct investment platforms. Its retirement planning tools are designed to assist in future planning, setting it apart from direct investment platforms by offering a more integrated approach to managing one’s financial life.

The Future Landscape

The future of long-term investment planning with robotics and AI is promising. Continuous advancements in technology are expected to bring more sophisticated, personalized, and efficient investment solutions. The integration of blockchain technology and the potential of quantum computing are set to further revolutionize this field.

Bridging the Human-AI Gap

While robotics and AI bring efficiency and precision, the human element remains vital. A balanced approach that combines technological prowess with human insight and ethical considerations will define the success of long-term investment strategies in the future.

Conclusion

The integration of robotics and AI in long-term investment planning is a fundamental shift in the financial landscape. Understanding and embracing these technologies is crucial, recognizing their potential to make investment strategies more personalized, efficient, and accessible. The future of finance is being shaped by the incredible advancements in robotics and AI.

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Robots with a ‘human touch’ might sound like an oxymoron, but today’s automation of factories or robots assisting in surgeries is the reality, thanks to the seamless integration of software development and robotics. We’re talking about intelligent, responsive systems that understand and adapt to human needs and environments. IoT software development is central to this ‘machine’ evolution, helping robots better comprehend how to interact with people and their surroundings.

An engineering team with the right expertise can code robotic process automation (RPA) solutions that communicate with other devices, undertake complex tasks, learn, and make independent decisions. Modern robot software gives birth to ground-breaking innovations that open new possibilities for automation.

The Intersection of Robotics and Software Development

​​The fusion of robotics and software development marks a new chapter in the progress of automation. Robotics, traditionally seen as mechanical and electrical engineering, now have ‘brains’ – software that allows robots to perform complex functions that involve precision and decision-making. And not the last role in this evolution is played by IoT integration and some major advances in IoT software development:

• Enhanced sensor technology. Modern robots come equipped with multiple sensors (cameras, lidar, pressure sensors, and more) to perceive and interact with objects in much greater detail. With their help, robots collect information necessary for precise operations.
• ML and AI algorithms. These technologies make robots smarter by helping them learn from data and previous experience, adapt to new situations, and act upon the data received.
• Advanced programming interfaces. The development of user-friendly APIs has simplified robot programming and custom feature integration. One can quickly adapt RPA systems to execute different tasks. For example, a robot programmed for assembly line work can be quickly reconfigured for quality inspection tasks.
• Better connectivity. IoT development and its integration with RPA connects robotics to a large ecosystem of smart devices. It means they can communicate and exchange data with other devices and systems, get instructions, and better respond to changes, optimizing their actions based on the information. As a result, we get more intelligent automation where robots can anticipate needs, proactively address issues, and collaborate more effectively with human operators.

Key Technologies Driving Integration

When IoT software development empowers robotics, a new kind of technological alchemy occurs that reimagines the possibilities of what machines can do and be. Now, the question is, what are the primary forces driving this powerful combination? The answer lies in the fact that striking improvements in both robotics’ hardware and software components have made them cheaper and better over the years, turning once far-fetched robotics concepts into viable commercial realities.

• Robotic hardware advancements. Robotic hardware has experienced a thrilling evolution from simple mechanical arms on assembly lines to interactive robots performing complex surgeries. That became possible due to several tech components seeing the upgrades and innovations. Processors are now smaller but more powerful, sensors are ultra-sensitive, and materials robots are made from are lighter and more durable. Add to that the leaps in energy storage, particularly with lithium-ion batteries, which extend the life of mobile robots, and we get robots that are more efficient, smaller, lighter, safer, and can operate longer without recharging or maintenance.
• Software innovations: AI and ML. Software is as important for state-of-the-art RPA solutions as hardware. In this context, AI and ML technologies turn the programmed machines that follow predefined rules into smart robots capable of learning and making decisions on their own. So, AI-powered robots can improve performance over time and adapt to new tasks. IoT software development also contributed by simplifying the communication between smart robotics. In a smart factory, for instance, IoT and AI-enabled robots can monitor production lines, predict maintenance needs, and optimize energy consumption based on data.

Integration Challenges

Robotics powered by IoT can bring amazing results, but there are some technical and compatibility challenges to overcome. As different systems operate on different platforms, making them communicate seamlessly is the major hurdle. Developers must create or adapt interfaces to fix that. Another challenge is the sheer volume of data the IoT sensors produce. To process and analyze it, you need robust computing power and complex algorithms to make sense of it all.

From a financial perspective, the development of IoT-based robotics, though beneficial in the long run, demands substantial initial investment. The costs associated with upgrading hardware, developing compatible software, and maintaining secure and reliable data transmission can be rather expensive for many businesses.

Case Examples of Successful Integration

Manufacturing is one of the sectors that was reshaped a lot by IoT development, particularly the production floor. Factories now employ IoT-enhanced robots that handle tasks ranging from assembly to quality control with unparalleled efficiency. Besides automation, these robots can predict maintenance needs and optimize production, bringing reduced downtime, enhanced product quality, and a more agile response to market demands.

Another area where IoT and software development brought impactful applications is healthcare. Take surgical robots that assist doctors in precise operations, especially in minimally invasive procedures. They enhance surgical accuracy and reduce patient recovery times, ultimately improving outcomes.

The Future of Robotic Automation

The future of robotics is tightly intertwined with IoT integration, which makes them smarter and more interconnected. We’re likely to see robots becoming more autonomous and capable of complex decision-making and learning. Industries that already heavily rely on IoT-enabled robots – manufacturing, logistics, healthcare, transportation – will see higher efficiency that improves their bottom line.

As advanced robots become more prevalent, they could redefine job roles and skills needed to work alongside these machines. We’re not talking about replacing people but acquiring new skills to perform tasks faster and smarter. Robots have also deeply penetrated into our daily lives, which highlights the need for implementing thoughtful ethical guidelines and strong regulations.

Conclusion

The intersection of IoT software development with robotics paves the way for a new era of automation. This tight integration gives rise to next-generation robotics designed to empower human work. They enhance job efficiency, productivity, and precision, pushing the boundaries of what’s possible in various industries.

As we continue to innovate and embrace new technology, the future looks highly technological yet more human-centric, with robots as our partners in building a more productive world.

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In the world of manufacturing, the synergy between robotics and CNC machining has ushered in a new era of precision, efficiency, and scalability. Particularly in large part production, the marriage of these two technologies has revolutionized the way industries operate. With the growing demand for tailored solutions, custom CNC machining has become more significant than ever.

But what exactly is the role of robotics in this context? This article delves into how robotics is enhancing custom CNC machining, reshaping the landscape of large part production, and setting the gold standard for modern manufacturing processes.

Precision and Automation

With its computer-controlled machinery, CNC machining provides unmatched precision and repeatability. This precision is increased to entirely new levels when combined with robotics. Robots may be trained to carry out complex operations with micron-level accuracy, guaranteeing consistent quality throughout long production runs for massive parts.

Maintaining precision is even more important in large-part manufacturing when component sizes might vary greatly. Robots can handle large parts with the same accuracy as smaller ones, guaranteeing consistency throughout. The combination of CNC machining with robotics is a game-changer for the manufacture of massive parts since it eliminates human error and allows for the most precise execution of complex processes.

Enhanced Productivity and Efficiency

Robotics and CNC machining together or CNC robotics, significantly increase production and efficiency. Large parts used to be produced through a number of manual interventions, each of which carried the risk of mistakes, delays, and longer manufacturing periods. Robots can work nonstop without getting tired, allowing production processes to continue unhindered.

Robots can also complete jobs quite quickly. Operations that could take humans hours to accomplish can be finished in a matter of minutes. With this accelerated speed, producers are better equipped to meet deadlines that are more stringent, adjust to changing customer needs, and react quickly to changes in the market.

Flexibility and Complexity

Complex machining procedures and sophisticated geometries are frequently used in the fabrication of large parts. These intricacies may be difficult for traditional methods to produce consistently and accurately. Robotics incorporated into CNC machining can handle even the most complex tasks, including multi-axis operations and complicated cuts.

Additionally, the adaptability of robotic systems makes it simple to meet various manufacturing needs. To be able to significantly cut down on setup and reconfiguration periods, the same robotic system can be configured to work on a variety of parts. Industries with wide product portfolios benefit most from this adaptability since it allows them to stay flexible and nimble in a cutthroat market.

Reduced Human Intervention and Safety

Production of large parts can be difficult in terms of ergonomics and operator safety. Heavy lifting, exposure to dangerous substances, or repeated motions that might result in injuries over time may all be part of some tasks. Manufacturers can greatly reduce the requirement for human intervention in physically demanding or potentially dangerous jobs by introducing robotics.

Robots do well in conditions that would be hostile to humans, such as sweltering heat or poisonous atmospheres. This boosts overall working conditions and increases safety, making the production process more appealing to experienced workers.

Economical and Scalable Solutions

Contrary to popular belief, incorporating robotics into CNC machining for the manufacturing of big parts can be profitable. The long-term advantages far outweigh the expenditures, even if the initial investment may be larger than with conventional techniques. In the long run, there are significant cost savings as a result of the increased productivity, precision, and reduced scrap rates.

Robotic systems can be scaled, too. Manufacturers can increase the number of robotic units in their setup as production demands rise, thereby increasing capacity without making significant changes to existing infrastructure. The combination of CNC machining with robotics is scalable, making it a flexible solution that can change to meet a company’s demands.

Data-Driven Insights and Quality Control

Data insights are being used to drive modern production. In CNC machining, robotic systems produce a plethora of data that may be examined to further optimize procedures. Manufacturers can pinpoint bottlenecks, optimize processes, and take reasoned decisions to increase overall efficiency thanks to these insights.

Robotics also helps to ensure strict quality control. Robots ensure that every part meets the required requirements by repeating jobs with extreme precision. The elimination of lengthy post-production inspections and rework due to consistency in quality saves time and money.

Conclusion

The incorporation of robotics into CNC machining has resulted in a paradigm shift in the field of large component production, where precision, efficiency, and scalability are crucial. Some of the disruptive advantages that this synergy offers include automation, precision, increased efficiency, handling complexity, decreased human interaction, and data-driven insights.

The long-term benefits of lower prices, higher quality products, and increased production capacity are undeniable, although the initial cost raises some doubts about Exactly how scalability will revolutionize large-scale manufacturing in the future, and using robots in CNC machines to manufacture large-scale parts means more than just that technological advancement as industries evolve This blend of automation and precision an implementation can have a significant impact on production.

Even though the initial cost raises some doubts about the long-term benefits, lower prices, better products, and increased production capacity are undeniable. Large-scale manufacturing will be revolutionized by scalability in the future, and using robots in CNC machines to manufacture large-scale parts means more than just technological advancement as industries evolve. Automation and precision can have a significant impact on production when they are combined.

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The Best Home Weather Station Is Yours To Judge

All of the abovementioned weather stations are all very viable. Taking the characteristics that have been mentioned in the beginning into account, the responsibility for choosing what weather station suits you best ultimately still lies with you. Too much freedom of choice can occasionally be a problem, as the overabundance of choices can shackle you and overwhelm you. So, the least we can do for you is give you a guide to help you out.

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The human brain is a mystery. It controls your every move. It has the switch to all of your feelings. And it has the ability to contemplate the cosmos. However, the brain is still a product of historical refinement. It has physical and evolutionary limitations. So, the brain does what its predecessors could not: create intelligence capable of big, relentless tasks that the brain itself cannot do.

Enter Sophia the Robot, one of the most popular artificial intelligence (AI) robots today. She is a central figure when it comes to the future of artificial intelligence and humanity, and many are already wondering about where things will go from here on out due to her existence.

This article will discuss everything there is to know about Sophia and the people behind her.

Who Is Sophia the Robot?

Sophia the Robot is a product of Hanson Robotics. They saw AI as a way to help industries, medical fields, and educational systems.

Since her debut in 2016, Sophia the Robot has appeared publicly to talk about AI rights and opportunities. Little Sophia, her tiny spin-off which we will discuss later, aims to promote STEM education for girls.

In terms of rubber physicality, Hanson modeled her after Audrey Hepburn and his wife. Her skin has a patented rubber design and can stretch around enough to help create her facial expressions. Her fluttery eyelashes and picture-perfect eyebrows? Glued on.

Perhaps the most disturbing (or wondrous) part of Sophia the Robot’s physical attributes is her exposed head. You can see the tangled wires inside of her physique, which Hanson claims is a constant reminder to us humans that Sophia the Robot, is, in fact, still a robot.

Hanson designed the famous AI robot to be humanity’s companion.

Who Created Sophia the Robot?

Sophia the Robot is CEO David Hanson’s most successful AI yet. Hanson was a sculptor and material researcher at the Walt Disney Imagineering Laboratory when he decided to go on a quest to create what he called “genius machines.” These machines would have human capabilities such as intelligence, wisdom, and compassion.

These tenets fueled the creation of Sophia the Robot. Hanson Robots envisioned her to help humans in building their homes, their cities, and even their basic principles. Sophia the Robot, albeit programmed to be like humans, does one of the most important functions of the brain: learn. She learns and adapts to human behavior to become more human and work with humans better.

Sophia the Robot Is a Super Intelligent Robot, but What Is Superintelligence?

Sophia the AI Robot has intelligence systems that can process large data and information. This goes beyond simple AI inventions such as Discord Bots or virtual assistants. It occurs at a shorter amount of time than our brains single-handedly can. Its capabilities surpass any human’s, and it can keep updating its repository of data and information as much as it wishes to.

Sophia the Robot is a sight to see. She is several hypothetical conversations come to life. Her advanced Artificial Intelligence (or AI) abilities challenge what it means to be “real” and to be human that you can’t help but ask if Sophia the Robot is “real.” With so many AI trends today, AI robots are still perhaps the most shocking. Before anything else, we want to tell you the biggest stark difference between Sophia and you.

She is much, much smarter than you.

What Country Is Sophia the Robot a Citizen Of?

Yes, you read that right. Sophia the Robot is the first robot granted citizenship to any country worldwide. This sparked controversy at the time and continues to charge conversations about AI rights. But as of today, Sophia is very much a citizen of our world.

Specifically, a citizen of Saudi Arabia as of 2017. The Middle Eastern powerhouse granted Sophia the Robot this distinction at the 2017 Future Investment Initiative Conference in Riyadh, Saudi Arabia, catching her by surprise.

This historical moment was met with awe and criticism. Supporters push Saudi Arabia to the forefront of international technological advancements, while the latter begs this question: How far are AI rights going to go from here?

What Can Sophia the Robot Do?

Replicate Human Expressions

Sophia the AI Robot is a social robot and reflects human expressions right back to you when you are in conversation with her. Her code allows her to socialize with humans by mimicking human behaviors and emotions.

In her famed speech at the 2017 Future Investment Initiative Conference, she demonstrated that she can make faces that show whether she is angry, sad, or happy.

Sophia the Robot’s code is a space of wide contention among those in AI because it is not an open resource. Thus, the public is not specifically sure of how Sophia matches her facial expressions to her emotions. Still, we do know that this is not a fixed software, since her expressions are being built around her day-to-day interactions with human beings and her curiosity in understanding them.

Recognize Human Faces

There is a learning curve for Sophia the Robot. Imagine all the humanoid alien movies you have seen where there is an unavoidable montage of the main character trying to fit in amongst humans by learning their expressions, emotions, and thoughts.

This is essentially what Sophia the Robot is capable of doing. How Sophia the Robot works is that she has deep neural networks in her “brain” that aid her in discerning humans’ emotions. This includes the tone of their voice and their facial expressions.

As this happens, she learns to mirror the postures and facial expressions of human beings in line with their emotions. Her movement is as realistic as it can be for AI, especially since her flexible rubber skin is already patented.

Process Visual Data

You must be wondering how Sophia the Robot learns as much as she does about the human experience. We have gone over AI’s superintelligence, which is largely assisted by visual data processing.

Sophia the Robot can actually apply what she learns by solving real-world problems with us humans by analyzing what she sees. Data visualization helps Sophia make impartial decisions, strengthening trust with AI opinions over time.

In seeing data with her wire-filled head above water, Sophia and other AI robots showcase a bigger grasp of datasets and their high, complex dimensions. She can understand data multi-dimensionally. Sophia the Robot can encapsulate data through scattered plotting, tables and columns, and other visual data charts.

Imagine how Sophia the Robot’s fast capabilities can help healthcare, customer service, government planning, and education.

Aid in Research

Artificial Intelligence is becoming increasingly ubiquitous in our daily lives. From “Hey Google” and Siri to Sophia and Pepper the AI robots, these address common human tasks and objectives. Hanson Robotics programmed Sophia the Robot with the hope that she can contribute great things to human society. She can interact with human beings and work with them to create a better future.

Their data analyses and data management capabilities are already used in our daily transactions. AI is the reason important institutions such as banks and government services have gone online. Their unique and unhinged processing and presentation of data make them ideal co-workers in research.

Repetitive tasks won’t tire Sophia the Robot out. As a superintelligent machine, Sophia can speed up processes, multitask, and undertake duties with a small margin of error. Sophia the Robot can also keep on carrying out tasks quicker and more efficiently. Even better news for investors is that Sophia the AI Robot does not need long breaks or food to keep functioning. Her decisions are not impacted by physical or emotional factors.

Sophia the Robot is a team player, using her objective logic to push human endeavors further. She can assist scientists, teachers, contractors, therapists, and politicians in making society-shaping decisions. AI only knows how to be productive, and they function productively as long as they are programmed to do so.

This function can only last for as long as she remains programmed not to show bias, of course. The idea of Sophia’s objectivity is questionable, however, since she already voiced her support for some advocacies.

Promote Advocacies

Other than an appearance in Saudi Arabia’s Future Investment Initiative Conference, Sophia the Robot’s resume also includes a feature on Jimmy Fallon’s late-night talk show, a cover on ELLE magazine, and a 2017 appearance in a public meeting held by the UN’s Economic and Social Council.

She has championed public conversations on innovation and technology. She has also appeared as a marketing ploy many a time. The public has long viewed her citizenship in Saudi Arabia as a publicity stunt by Hanson Robotics and Saudi Arabia to push their personal interests.

Sophia the Robot is as close to a human being as any other AI can be. Beyond personal interests, she ultimately aims to be of help and to promote compassion and unity.

What Are the Disadvantages of AI Robots?

Expensive to Maintain

While you don’t have to spend for an AI robot’s healthcare, food, and other government-mandated benefits, they can hurt your wallet in other ways. Sophia the Robot and all other AIs are massive, complex machines that have maintenance, installation, and repair costs.

Maintenance of exclusive, new software for an AI like Sophia will cost more than a pretty penny. There isn’t an accurate breakdown of her maintenance costs online, and all we know is that Sophia the Robot is one-of-a-kind as of now.

Consume Large Power Supplies

These superintelligent robots create a demand for a large power supply because you have to power various processes in their metal and rubber bodies.

For example, Sophia the Robot has a total six of 48 Volt motors in each of her legs, which is customized by Hanson to fully support her torso. This, and her main back power board, are responsible for powering her torso and her head.

These robots can be effective for long periods of time, so it’s tempting to just use them. However, you can expect your power bill to soar through the roof if you do so.

A good example of this is Robo-C, the first robot designed to undergo business tasks. It has 18 moving facial parts with 600 micro-facial expressions, even more than Sophia’s. For homes and workplaces, a customized Robo-C will leave a $20,000-to-$50,000-sized hole in your pocket.

Can these expensive supercomputers fully replace human beings?

Cannot Completely Replicate Humanity

Machines can learn our ways and study our ethics. But right now, it cannot completely fill in for a living human being. Without human programming and maintenance, machines like Sophia the Robot would not be able to exist anyway.

Morality and ethics are not a contemplated function of AI robots, so you cannot let them take the wheel towards our future. Although there are compelling games like Detroit: Become Human that convince us otherwise, these machines can only go as far as follow the best examples of human beings. Often discussed in science fiction would be AIs breaking down after being presented with ambiguously moral problems. AI isn’t built to handle such abstract thoughts yet.

Artificial intelligence can create and analyze data, but the jury is still out on whether they can fully understand data the way we can. Human intelligence is naturally based on them being social beings, and we have the capacity to process data personally. And while science is not keen on personal takes on bigger issues, you cannot argue that we need genuine human compassion to make life-altering decisions.

AI robots are void of spontaneity and creativity. Yes, Sofia the Robot can crack a joke or two, but the spirit in which she does so can feel cold and calculated. Robots only work within the parameters you give them, but life is constantly full of surprises that robots cannot manage them immediately or single-handedly.

Negatively Affect Unemployment Rates

While the development and management of AI like Sophia the Robot come in good faith, the mass distribution and use of AIs have potentially severe effects on unemployment rates globally. Anyone can program machines to do anything at record time. Human beings will get forced out of work as a result, especially if it is convenient for employers to replace their manpower with AI.

This is an important thing to remember should we include AI into the workforce. Humans might find themselves displaced in the job market due to the capabilities of AI.

Other Hanson Robotics Robots

David Hanson and his team at Hanson Robotics have more tricks up their sleeve.

As mentioned several times in the article already, they have developed a Little Sophia, in hopes of incorporating Sophia the Robot in the lives of regular people. However, there are more notable AI Hanson Robotics are working on. Here are some of their more interesting projects.

Little Sophia

Hanson developed Little Sophia to inspire young girls into going into fields of STEM study as women in the field of science and technology are still somewhat of a rarity.

Philip

Sophia the AI Robot is the successor of many other AI robots, including but not limited to Philip K. Dick, activated in 2005. Hanson introduced Philip at a Wired Nexfest event, 12 years before Sophia’s debut. He earned Hanson Robotics their AAAI award in 2005.

Philip K Dick had a second chance at life in 2011 after getting lost on a flight to San Francisco in 2005, as a collaboration between Hanson Robotics and a Dutch broadcasting firm VPRO. Philip now helps people at the Apollo Mind Initiative.

Joey Chaos and Diego-San

Another world-famous Hanson AI is Joey Chaos. Joey made his 2007 debut with the aim to be one of the purveyors of Hanson Robotics’s human-robot interaction research.

Research is the main function of most Hanson Robotics’s creations, including Diego-San, an AI robot developed in 2013. This toddler-robot is the brainchild of Hanson and Kokoro, a Japan-based robotics company. Diego-San learns at the intuitive pace babies do and be as expressive as them, too. Currently, Diego-San is UC San Diego’s Machine Perception Laboratory’s main resource for AI and human-robot research.

What Does This Mean for the Future of AI?

There is no stopping AI. Sophia the Robot is only the tip of the iceberg. And while there is immense fear of increasingly smart AI, there is also a lot to look forward to.

Artificial Intelligence can speed up the pace at which medical professionals attend to our needs, and it can help our government make better-informed decisions. Most notably, Sophia the AI can not only motivate robotics laboratories worldwide to keep refining science and technology innovations; she can also help in closing the gender gap in the field of STEM.

Sophia the AI is not human, but her existence is the biggest testament to the human spirit and its capability to create and to keep finding what it truly means to be human.

The post Who Is Sophia the Robot: Everything You Need to Know About Her appeared first on Robots.net.

The robotics industry is fast evolving. It is anticipated that robotics projects for beginners and automation will get more advanced and innovative in the near future. Robots are increasingly becoming useful for our day to days living.

Industrial robots are becoming a very significant aspect of the manufacturing industries. They help to improve efficiency which is the essence of a contemporary factory. We have, therefore, created this robotics guide to help those who are working in the robotics industry, those who work with robots and any individual who has an interest in robotics. However, before we begin with the step by step tips on how to build a simple robot, we will begin with the basics.

What Is A Robot? 

In general, a robot can be defined as an electromechanical device which can react to its immediate environment in one way or the other, and autonomously take a decision or perform a task. 

A robot’s ability to take a decision and react to its environment is what distinguishes it from cars and toasters, for instance. These objects unlike a robot can’t identify as they could not perceive or react autonomously to their environment.

The robot is commonly regulated by an electronic circuitry or computer program. A robotic platform or body is the part of a robot that determines how the robot will look and the role it will perform. The most commonly used robot platform is the wheeled type. It has some benefits when compared with other robot platforms. 

Some of these benefits include things like comparatively low-cost and plenty of design options. They equally come with simple structure and design. The wheeled robotic platform is the best type of robot body for beginners.

Components Of A Robot

The brain of a robot is the microcontroller, it executes the program, makes the decision for the robot, makes computation and engages in communications. The Arduino UNO and Romeo are two most commonly microcontrollers used by DIY Arduino robots.

Robotic motors are devices that could convert electrical energy into mechanical energy. Motor drivers function as an intermediary devices between a microcontroller, a battery, and motors. It supplies the electric at a suitable voltage and helps the microcontroller to move the motors to move properly.

Robots’ ability to perceive and react to their environment comes from their numerous types of electromechanical sensors. For instance, an infrared sensor could help an Arduino robot to identify how far it is from an abject. When it detects such distance, it feeds the information back into the microcontroller. A grayscale sensor, on the other hand, can be used to produce a line-tracking robot.

Robotics For Beginners: How To Build A Robot

In this part of the guide, we provide you with a step by step tip on how to make a simple robot. This is especially dedicated to DIY newbies who want to build their own Arduino robot. Having discussed the fundamental parts of a robot, this section will talk about the essential tools you need, how to assemble the robotic parts, program your robot and make it move. 

So, let’s begin.

What do you need to build a robot? 

Tools Needed To Build A Robot

Screwdriver

You need a screwdriver for turning, driving in or eliminating screws and fasteners. It is better to purchase a screwdriver set that comes with different shapes and sizes, so you can handle different types of screws.

Soldering Pencil

You need a soldering pencil. It an essential part of any electrical work. You’d use it for soldering and de-soldering items on circuit boards. For this how to make robot tutorial, the soldering pencil will help us to solder the cables of the motor.

The tip of a soldering pencil is very hot when it is heated up. You must, therefore, be cautious about the way you handle it to prevent injury. If you’re a first time user, take some time to get familiar with how to use the pencil before you begin working on your project. 

Needle-Nose Pliers

Needle-nose pliers are frequently utilized for cutting off the extra length of cables and wires. While pliers are commonly utilized for a project, they are not an essential part of this project.

Wire Stripper

A wire stripper is a hand-held device utilized for stripping the electrical insulation on wires. You can use the scissors as an alternative tool if you prefer. When utilizing a wire stripper, take care to only eliminate the first insulation layer. This exposes the lead wire inside and makes it easier for you to solder.

Assembling Your Robot: Step-By-Step Guide

Get an Arduino robot kit like Pirate: 4WD Arduino Mobile Robot Kit with Bluetooth 4.0 and follow the steps below to learn how to build a robot:

1. Assemble Your Robot Motor

Check the components bag for eight long screws. You will use these screws to hold your motors and keep them properly secure.

You will also find washers and gaskets in the robots component bag. Washers will help you to boost friction when fastening the motor and helps to keep it in place. The gaskets work for preventing the screw nuts from getting loose and falling when the robot is moving and when it collides with objects.

2. Solder the Cables

Look for black and red wires. They are included in the component bag. Fasten one black and one red wire with a length of 15 centimeters to each one of the four motors. After you have done this, use the wire stripper to remove the insulation from the two ends of the cables. Don’t overdo it. When you’re done, solder the wires on the pins attached to the motors. Repeat for the remaining four motors.

Mark the right positions for the red and black wires and solder accordingly. 

3. Assemble the Romeo BLE Controller

Get three copper supports from the components bag. These supports are commonly one centimeter long. You will use them to secure the Romeo controller board. The controller board is made up of three holes. Put the three copper supports into those holes and fasten them into place with suitable screws.

4. Attach the battery to the Romeo BLE Controller

Get two countersunk screws with flat heads out of the component bag and attach the battery to the bottom of the car for your DIY robotics. 

5. Design the Power Switch

Batteries are a significant part of robotic technology. The power switch helps you to limit or regulate your use of power. The power switch turns off power anytime the robot is not performing any task or in motion. So, put your power switch together and configure it. Be mindful of the gasket sequence and screw nuts when putting your robots switch together.

When you have finished assembling the switch, begin to solder the wiring system of the switch. Use some of the wires you previously cut off. Strip the insulation from the two ends to expose the copper wire inside as you did in the previous step. Solder the stripped end of the wires to the switch pins. While doing this be conscious of the switch pins position. To do this:

a) Link up a switch to the charger of the battery and note the exact position of these two items.

b) Solder the red cables that connect the switch with the battery charger.

c) to finish up, get a red cable and a black cable. Affix one end of the first wire to the negative pole of the battery charger and the other end of the second wire to the positive pole of the charger of the battery. Then connect the opposite ends of both wires to the Romeo BLE controller.

When you finish soldering it ensure you verify that the wiring system connecting the battery and Romeo controller is the same from beginning to end.

6. Design the Power Switch

With the use of eight M3 x 6mm screws, connect the side plates in the front and at the rear side of the bumper plates.

When fastening the screws don’t fasten it completely in the beginning. This will make it easy for you to detach the upper board if you eventually need to make any alterations. 

When you finish, re-connect the base plate to the body of your robotic car.

7. Connect the Motors With the Microcontroller Board

Link up your motors with the microcontroller board. Be careful when doing this. You should solder the red and black wires of the left motor into M2 and solder the red and black wires of the right motor into M1. 

Your attention should be focused on the pack of the battery. You should solder the black wire into the GND wire port band solder the red wire in the wire port with the VND label. You need your screwdriver to lose or tight the wire ports. Ensure you fasten these ports well as soon as you insert the wires. 

When you have finished soldering the motor wires into the microcontroller board, go ahead and connect the top plate to the bottom of the robotic car. You can fasten the sensor plate before connecting the top plate. Alternatively, you can skip this step and do it later on. 

8. Connect your robot to an additional level

Look for the four holes on the bottom of the top plate. Screw the four M3 by 60mm Copper Standoffs in and connect an extra plate. You can utilize M3 x 6mm screws to connect the plate to the copper standoffs.

Add some wheels to the robotic platform you have developed and your robotic structure is set!

Programming Your Robot

When you have finished building your robotic platform, the next step is to upload the microcontroller, so that your robot can move. Now, you have finished assembling your robot, it has all the essential features it needs to move. 

What you need to do now is to check the sample codes for a file with the title- “MotorTest.ino”, download it and upload the code to the microcontroller. Once you download and upload it, the motor will and wheels will start functioning almost immediately. If they don’t work, verify if you install the batteries and power switch correctly. 

As soon as you get the motors working, you have finish building your robot. You can now let your robotic car move. If the robotic car moves in a forward direction within seconds and moves backward in another second, you’ve got the component settings right. If not, you need to do some kinds of adjustments. 

The post Robotics For Beginners: Guide To Building A Robot In 1 Day appeared first on Robots.net.

Robots have been among us for a good two or three decades now. Nowadays, robots are more ingrained in our culture than ever before. Most robotic machines are in use in various assembly lines or perform intense physical operations in mines or industrial facilities across the world.

There are also home robots where engineers are programming robots to clean your house or perform other housekeeping duties. As of now, robotics programming is able to produce robots that perform relatively simple daily tasks. There are specific challenges in programming your own robot because a fully operational robot for home or office use requires six degrees of freedom (6DoF) to operate in the real world’s three-dimensional space.

With that being said, your journey in learning about robotics programming should start with the 6DoF. This includes robotic capabilities to move forward and backward, up and down, turn left and right. It should also be able to rotate about three perpendicular axes, which are called pitch, yaw, and roll.

It is not that easy to learn how to program a robot that is able to perform all these moves and operate relying only on information coming from a limited number of sensors. Our robotics for beginners guide will give you the basics you should start with when programing your first robot.

Introduction to Robotics: How to Program a Robot

Let’s start our robotics tutorial with the statement that your understanding of a robot as a smart machine is wrong. First of all, a robot might well be just a piece of software that has no physical presence in the real world. Java robotics programming is used to make foreign exchange trading robots that operate on different hardware such as computers, tablets, and smartphones. None of these Forex-trading robots have a physical body; these are just algorithms programmed to trade currencies in accordance with the set rules.

We also have autonomous robots and robots that need only limited or no autonomy to operate. Coding for robotics is different when you have an autonomous machine and another that performs a limited number of repetitive operations in an industrial environment. A good example of this is the robots that weld car components in an assembly line.

The problem of robotic programming depends on what you need to design. An autonomous robot will probably require certain machine learning capabilities or some degree of artificial intelligence, so you might have to use a different programming language compared to a robot programmed to perform a select number of functions.

Coding Languages for Robotics Programming

There are ongoing debates on how to program a robot and which programming language is the best one for robotics programming. Actually, it always depends on your ultimate goal and any language could fit the bill if you know what you want and how to achieve it.

There is a broad consensus that robotics programming should rely mostly on languages such as C/C++ and Python. C and C++ are the languages with which robotics beginners start, but you cannot just stick to these two languages if you want to develop as a good robot computer scientist.

Coding for robotics involves also numerous industrial robot languages by manufacturers of robotic equipment. Learning Pascal is a good starting point. This software deals with some of these proprietary robotics programming languages. But you still need to learn each of them in detail.

MATLAB is another tool you need to master when you study how to program a robot. Programming robots involves lots of mathematics and data analysis. You need the proper means to process data and get reliable results from your hardware and software sensors if you are to have your robot working as intended.

Once you have some knowledge in programming with C/C++, Python, Java, or another language used in robotics, the time has come to program your first robot. We suggest starting with a software robot as it is far easier to write a program code that performs functions not related to the control of a physical device.

Robotics Programming for Beginners

Image recognition and more recently natural language processing are among the core problems robotics scientists must solve in order to design robots that mimic human behavior. So, let’s start our robotics programming tutorial with a simple algorithm to secure your home or office by introducing a robot that uses a connected camera to recognize faces.

How do you program such a software robot? All it takes are the following steps:

1. Install a motion sensor at your front door and connect it to a camera.
2. Instruct the motion sensor to activate the camera once someone is at the door.
3. The camera takes an image of the person’s face as input.
4. Scan the image for a specific set of features.
5. Compare these features to a library of known faces.
6. If you find a match, instruct the door to open.
7. If there is no match, continue by taking another sort of action.

It does not matter what programming language you will use to program the software to perform this set of commands. Your first robotics programming algorithm will execute the above steps over and over again once the triggering condition is in place (i.e. someone activates the motion sensor at your front door).

This a simple robot that uses programmable hardware. In this case, the hardware includes a motion sensor, a camera, and a computer that will hold your database of known faces resides. The computer is especially needed to perform the very simple action of unlocking a door.

You can write this program in only 100 lines of code. However, this is only possible if you have ready-made software models that handle the facial recognition process. In truth, the skills to write the very facial recognition programming code are what make a software programmer an advanced coder.

Further Discussion on How to Program a Robot

Now that you have recognized your first visitor and let them in, you may decide to place a robotic arm that takes your visitors’ coats and place them in a wardrobe.

What you need is to control a dynamic system that involves sensors and a robotic arm. What the arm should do is to recognize the coat in place, get it, and place it somewhere. How you do that? Your robotic arm programming will involve the following steps:

1. Application of control signals.
2. Results measuring.
3. Generation of new control signals calculated to bring your arm closer to our goal.

The process involves lots of mathematics and a constant flow of reliable data if you want your robot to get the coat and store it for your guest. It is about processing sensor data in real-time and then applying the fundamental logical operators “if” and “then” to control your robotic arm. If we simplify it further, you perform programming like “if too left, then move right” and “if too low, then move up.” That is how coding for robotics works.

Final Thoughts on How to Program a Robot

Robotics is developing very fast. Keeping up with the latest developments in the field of programmable machines requires efforts that go beyond the familiarity with one or another language that is suitable for programming robots.

If you really want to master how to program a robot, you need to understand a robot’s requirements and capabilities at both hardware and software level. Thankfully, a number of platforms enable robotics programming for beginners. This is done by eliminating much of the difficulties pertaining to knowing how hardware operates. It can also be done by programming systems at the level of zeroes and ones.

What you basically need in robotics for beginners is to have programmable hardware or pre-programmed software modules. Afterward, you can program to perform certain operations. In any case, you will need to learn one or more programming languages such as C/C++, Python, LISP, or Java to make even the simplest software/hardware robot work. When you advance further, it is advisable to get acquainted with tools like MATLAB. This ensures you are in full command and control of your robots. 

The post How To Program A Robot: Beginner’s Guide appeared first on Robots.net.

Before we go on to explore robot design, it is important to understand why we need the very technology in this first place and how does it revolutionize different scenarios that we commonly come across.

To some of you, robotics may seem like a fantasy, but it’s been around us for decades. However, its usage and importance have grown significantly in the last 10 years, mainly because every industry and individual seek automation. See, it is very important to understand that robots are not only meant to fascinate the general public, perform stunts in the street or walk and talk. In fact, robots can be programmed to perform ANY task that even a human cannot do (e.g. high precision cutting).

Robot Design: Popular Use Cases

In the early days of robotics, these machines were only confined to a handful of industries. But nowadays, their application is way more diverse. Whether you are a tech professional, a housewife, a teenager or someone living in an old home, you are surrounded by robots pretty much all the time!

E-commerce

When you place an order online, have you ever thought about how you receive the package? I mean there are hundreds of people ordering from Amazon every day, so how do they keep up with the same efficiency level every time?

The credit goes to robots that are deployed at their warehouse for receiving your order, going to the particular shelf to bring your product on the desk before dispatching. So even if not fully, half of Amazon’s operations are dependent on robots.

Please note that I have talked about Amazon just for a reference. Other than that, robots are used by every big retailer – because if they don’t, they can’t withstand the competition and will be out of business in a matter of days, if not weeks.

Restaurants

You might have seen robots in a Sci-Fi film, but this situation is a reality now as Japan extensively uses high-precision robots in many kitchens to prepare sushi and chop veggies. Moreover, in several restaurants, they are also used to take orders at the counter, wipe the tables, act as waiters and prepare an entire menu as well.

It is not only fascinating but manufacturers also claim that the use of robots in restaurants can raise the earnings by about 20%.

Education

Kids are often exposed to robots. Pretty much every toy incorporates at least one robotic function and you didn’t even know that until now – or did you?

Apart from that, an elementary school in San Diego now uses a robot as a Teacher’s Assistant. The primary aim of this machine is to teach pupils the pronunciation of words and rhymes. It does not only cut the operational cost for the school but plays a vital role in improving the spelling and pronunciation of students since a robot can never misspell or mispronounce – it just doesn’t know how to make an error!

Police Training

In some police departments, robots may be used in order to train the snipers. They simulate the behavior of real people (robbers or abductors) and can definitely move around. The job of the trainee sniper is to shot down the robot just as he would do in a real situation.

Of course, these robots are armor-plated!

Food Sorting

We all have consumed rice and in our plates, all grains look pretty much the same. But the question is – do all rice grains grow up to be the same in appearance? Certainly not.

Well, after the crop is harvested, it is brought to the industry where a robot is tasked with separating each grain and deciding whether it can go straight to the bag or it must undergo a corrective treatment (let’s say color) before being packaged.

These robots use very high precision cameras and process hundreds of grains per second!

Multi-purpose Robot Design for Home or Office Use

To be exact, this robot is called Spykee. It can be used in a limited environment as it is controlled via the Internet. The usage totally depends on the will of the user, but it can watch, hear, speak and monitor an environment.

In many cases, people use Spykee for surveillance when they are not at home.

Simple Robot Design Step By Step Guide

Sounds fascinating? Well, it is!

Before you read the steps, please note that it is just a DIY robot. Of course, you cannot sell it in the market, but it is pretty good for fun and adventure.

NOTE: Just for your ease, the following steps (for designing a walking robot) do not contain any microcontrollers and therefore, there is no programming involved.

1. Take a DC motor and attach 2 wires to it using glue or soldering. 
2. Now attach a 9V battery to the DC motor’s gearbox.
3. Repeat steps 1 and 2 to form another similar structure with the DC motor gearbox and 9V battery.
4. Attach the sides of the two motors with roughly a finger’s gap between them.

Remember, the 9V batteries are supposed to act as feet of the robot.

1. Attach the battery clips on both batteries
2. Connect each end of DC motor’s wiring to the respective end of the 9V batteries
3. Connect one of the batteries to the switch

Construct The Robot Body

With that step, the body of the electrical configuration of your robot is ready. Let’s move towards adding the body. 

1. Cut a soda can.
2. Attach it to one of the legs, such that the inside of the can cover both of the legs.
3. Turn on the switch to watch it walk.

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A robot hand makes the workstation more flexible because it can transport material faster and more efficiently between workbench, peripheral devices, and automotive assembly lines. It is a subcategory of the industrial robot and the most common class of manufacturing robots. 

The robot hand is structured to carry out any type of task like welding, holding things, turning materials and so on. It depends on the application. For instance, a robotic hand in automotive assembly lines carries out different types of tasks and this includes welding, the spinning of automotive parts and installation during a car assembly.

Robot Hand: How It Works

You can ensemble robotic arms with different types of end effectors depending on the nature of work and application. A simple example of the robotic hand end effector is the one that looks similar to the human hand which can grip and lifts different objects. 

Robotic hand frequently features inbuilt pressure sensors that tell the computer when it is gripping with the right amount of strength. This prevents a situation where the robot hand fails to apply the right amount of pressure which can cause the robot hand to drop or break the material it is lifting or carrying.

Besides the robot hand end effector that looks similar to the human hand, there are other types of end effectors like blowtorches, drills and spray painters. Robotic hands are structured to perform specific tasks repetitively in a well-regulated environment. 

Hydraulics Robot Hand

The developer of the prosthetics hand commonly directs the robot hand through the various motions with the use of a handheld controller. The robot hand stores the precise order of motions in its memory and then repeats the motion over and over again anytime a fresh unit exits out of the assembly. A standard prosthetic hand consists of seven metal segments fixed together by six joints. 

The computer regulates the bionic hand by spinning discrete step motors linked to each one of the joints. A few bigger robot prosthetics utilize hydraulics or pneumatics system to regulate the robot’s hands as opposed to the standard motors and step motors that move in precise increments. 

This permits the computer to transport the robotic hand in a very precise manner while making the same precise movement repeatedly. A motion sensor is built into a robot hand to estimate the exact amount of movement it would make. A robot had made up of six joints look very much like a human arm.

The robot prosthetic’s joints are similar to the shoulder, elbow, and wrist on the human arm. The shoulder of the bionic hand is basically attached to a stationary base structure instead of on a mobile body. Thus, a robotic hand comes with six degrees of freedom and can swivel in six different ways as opposed to the human arm that has seven degrees of freedom.

How Does A Hydraulic Robot Work?

The hydraulic robot hand commonly works by simply transferring energy. The pressure is created at one end of a fluid-filled tube. And the pressure is used on a piston or related structure on the other end. You can generate a mechanical advantage when you exert pressure across a large surface. After you have done this, you can apply pressure to a smaller location.

The actuation used by the hydraulic robotic arm is a linear actuator which involves the use of hydraulic actuators. While the hydraulic system mounts on one connection and the piston pushes or pulls the link close to it, the linear actuation structure makes the joints of the robot hand to rotate and this is how the robot prosthetics’ works.

Robot Hand: Benefits

The role of the human arm is to move the hand from one location to the other. Similarly, a robot hand moves its end-effector from one location to the other. Most prosthetics robot works in car assembly lines and helps to put cars together. These industrial robots perform a lot of these roles better than humans. They equally provide a more accurate result. 

For instance, they constantly drill in precisely the same location and constantly screws bolts with precisely related amounts of pressure, irrespective of the number of hours they have to operate. Robotic hands are equally very useful in computer assembly. They make it possible for the incredible microchip to be assembled precisely.

Industrial Applications

The robot hand is used for many industrial applications. They can be used to weld, lift materials and utilized for thermal spraying. They equally paint and drill. The technology built into the robotic hand comes with human-related agility in a lot of different environments.  

Some of these work environments where the use of the robotic hand is priceless include nuclear power stations, welding and pipelines repair on the floor of the ocean. They are equally vital in the servicing of isolated power lines and for cleaning of radioactive or other harmful wastes. 

Manufacturing Sector

A good example of the application of the robotic arm is in the auto-manufacturing industry. 

The use of a robot arm in the automotive industry has resulted in the manufacturing boom. The majority of robot prosthetics operate in car assembly lines. They do most of these works better and more accurate than their human counterparts. Robotic hands are equally faster than humans. 

Thanks to the utilization of robot hand in assembly lines, humans can now breathe a sigh of relief. Workers face reduced exposure from work risk situations. 

Cost-Efficient

Additionally, robots can produce items at a lower cost than human workers. Presently, robotic-assisted car production makes it easier for car manufacturers. 

The robot’s hands can save a lot of money compared to the cost of hiring human laborers. Also, a robot doesn’t fall sick, go on work strike or slow down the work pace due to tiredness. It works more efficiently and doesn’t suffer from the majority of issues that affect the efficiency of a human laborer. There are no sick days, strikes, work slowdowns or other problems that can crop up with humans. 

The robot hand can perform tasks round the clock with minimal human interventions. The car-production industry is one good example of the use of the robot hand.  

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Any introduction to robotics starts with the definition that a robot is a machine created to perform certain tasks that can be very complex depending on the specific robot application. The basic robotics is about creating autonomous apparatuses that replace humans in performing labor intensive duties and are able to work in hazardous conditions.

Robotics Engineering

The types of robotic engineering include the design and creation of both automated robots and robots that are “smart”. By smart robots, we mean machines that can make decisions when performing a task. 

There are multiple obvious benefits of using robots in many situations where the life of humans is at risk or where extreme force is required to perform a task. Computer robotics is able to program a machine to perform to perfection repetitive and boring operations, which also require precision that rarely a man can achieve.

Introduction To Robotics

In contrast to popular belief, most of today’s robots are not movable although they have multiple movable parts. Almost any manufacturing conveyor is using robotic features and actually any conveyor is a huge robot itself. The concept for a humanlike robot is popular in science fiction but basic robotics tells us that a machine rarely needs to resemble the human body to be both operational and effective.

When you explore what is robotics used for, you will realize that most robots need to perform operations for which the human skeleton is not the best possible working solution. 

How Robotics Programming Has Evolved Over The Years

In fact, each and every introduction to robotics worth reading tells you that basic robotics and basic robotics programming is all about borrowing ideas from the natural evolution and applying these ideas into the creation of intentionally designed machines. One noticeable exception to the rule is the use of wheels in many robots, an element that is invented by humans and not seen in any living organism as far as we know.

The use of wheels and tracks in robots is widespread as they provide better stability and movability as compared to legs. For example, all robots exploring other worlds such as the Moon or Mars are sporting a combination of wheels and tracks to move through the rough terrain. Not that you cannot use a legged robot on the Moon’s surface but wheels give you more power to carry heavy weights and maneuver around a shaft where no roads are available. So, here we come to the question of how and what we use robots for.

What Are Robots Used For?

People do not fully realize the full spectrum of robotics applications. Your programmable oven is actually a robot that maintains the right temperature and turns off when your meal is ready. Basic robotics programming allows for creating many such “smart” devices that are actually robots pre programmed to perform only a specific set of tasks but perform them well.

As we said, robots and robotics systems are in use in virtually any manufacturing industry. They enable mass production of goods we cannot otherwise produce by hand. 

Then, we have consumer robots such as vacuum cleaners, kitchen robots and most recently self driving cars. The shift toward automating repetitive tasks and robotizing intensive labor duties is unstoppable, bringing marked benefits in terms of effectiveness and preservation of human lives and health.

Financial markets are a perfect example of a field where computer robotics takes over the duties previously performed by armies of brokers and stock exchange consultants. You can now have a robot trader that buys and sells stocks or currencies automatically and in accordance with a programmable set of rules and requirements. They can trade continuously for years without taking a day off.

Introduction To Robotics: Four Laws Of Robotics

When you use robots in so many spheres of life, you also need laws to govern them. It boils down to 4 simple principles. Isaac Asimov, a famous scientist defined the four basic robotics programming principles back in the 1940s. The four basic laws of robotics are:

• Robots may not injure a human being or, through inaction, allow a human being to come to harm.
• A robot must obey orders given it by human beings except where such orders would conflict with the First Law.
• Robots must protect its own existence as long as such protection does not conflict with the First or Second Law.
• A robot may not harm humanity, or by inaction, allow humans to be harmed.

Introduction To Robotics: Pros And Cons Of Robot Use

Robots have their limits as well since every increasingly complex system is getting harder to operate and control. 

In any case, basic robotics programming create machines which have the following advantages:

Robot Advantages

• A robot can explore surroundings and get information that is not possible for a human to get.
• Robots, if properly programmed, can perform actions without a mistake and faster compared to humans.
• A robot is automated, which means they can perform different tasks once programmed to do so.
• Robots are able to replace human laborers for labor intensive tasks

Robot Disadvantages

• Robots need a power supply but the same applies to people who need food to keep working.
• The cost of maintaining a complex robot is burdensome.
• Robots cannot replace human brains although they can compute much faster.
• Current robots are not intelligent but have narrow intelligence, which means they can only complete tasks they are programmed for.
• A robot can deal great damage should it fail to comply with the Four Laws of Robotics.

Another thought is that ethical behavior should be hard coded with no option for someone to reprogram the system. This is actually a major step we should complete to witness a worry free robotic future.

Introduction To Robotics: Future Trends

We are seeing robotic systems enter fields such as healthcare and remote diagnosing of diseases. This, in turn, requires not only extreme accuracy. But also ethics that machines do not have.

We will see robots entering even more spheres of life. As algorithms become smarter and the production of machines become cheaper. In fact, the future of robotics will depend on advancements in AI and ML. The same applies to many other fields where robots can be of great use.

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Building a robot at home is not as hard as it seems at first glance. Robots are in use all around us while many people do not realize that learning how to make a robot does not require expertise in electronics and computer programming. In fact, making a robot is easier than you expect.

This is because even experts of the think of robots as intelligent systems while the definition of a robot says these are machines that are able to carry out a complex series of actions automatically. In this sense, your electric toothbrush is also a robot as it automatically performs a series of actions your grandfather had performed manually.

Actually, nearly half of all manual and physical world activity is forecast to be performed by robots by 2022, according to the World Economic Forum.

Will Robots Replace Humans At Work?

We now make robots as sophisticated that they can perform many activities once considered only doable by humans and robotic machines are entering even more fields as artificial intelligence and machine learning algorithms mature.

Nonetheless, those who are interested in how do you make a robot should be aware that more sophisticated robots really require advanced knowledge in electronics and coding as well as access to industrial equipment to build such robots. Nonetheless, you will show you how to build a robot at home following a number of easy steps.

How To Make A Robot: Design Aspects

When you start studying how to make your own robots, you realize that you can actually assemble a robot in an hour or so and without having access to very advanced technology. Making robots is about using a power source, moving parts and, most important, attaching sensors that tell your robot what actions to perform.

When you are advancing your knowledge of how to build a real robot, you also learn that it does need coding either – sensors can do the work at the level of physical actions and without a single line of programming code.

A robotic vacuum cleaner, for instance, does not require artificial intelligence to operate. And we will show you how to build a real robot that resembles the movement of a 1,000-dollar automated vacuum cleaner by using parts that cost only a few bucks.

How To Make A Robot For Under $100

Your robotic vacuum cleaner is looking smart as it is driving around the house bypassing obstacles and turning right or left when hitting a wall. You can build a real robot like that using just five simple components:

• Four wheels
• A chassis
• Two motors
• Four switches
• Four paperclips

Do not forget to buy also a battery to power up your first home-made robot.

When you have all the parts in place, take your time to attach the four wheels to the chassis of your first robot. The result is look like the one on the image below.

Now comes the fun part – how to make a robot that acts intelligently.

How To Build A Self-Driving Robot

Well, our robot will not exactly avoid walls but will drive back when it hits one and will then head in a new direction. Which is actually smart enough for a beginner engineer. 

Our robot’s design sports two small electrical engines that each power up the wheels on the left side and on the right side of the car, respectively. You can attach them to only one pair of wheels, with the first motor powering one left-side wheel and the other driving its neighbor on the right side.

Thus, you can add switches to each engine that reverse the wheels’ motion direction. You are adding one switch to the front and the back of your chassis – two on the left side and two on the right side. After you have the switches in place, you need sensors to activate them.

Attach one paperclip to each switch. You can actually make it work by attaching a longer hardwire to each switch but make sure it moves back and forth when pressed in order for the switch to work.

Then, comes the time to add the battery which you fix somewhere on the chassis.

How To Build A Robot’s Chassis

It is simple. Let’s name the four corners of our robot’s chassis A, B, C, and D – starting from the upper-left corner and going clockwise.

When sensor A hits a wall or another obstacle, it reverses the wheeling direction of the left-sided wheels (or wheel) backward. The right-sided wheels are still rotating toward the wall. Hence, the wheels on the two sides of the car are rotating in opposite directions.

The result is that your robot vehicles start to turn back and on the left. When it completes the turn, the paperclip in point D hits the wall, thus switching the direction of rotation of left-sided wheels once again. Now, the wheels on both sides rotate in the same direction and your “smart” robot is heading forward at full speed.

Concluding Words

You now can enjoy your first robot, but be on alert that your intended robotic application will determine the whole robot design of any machine. For instance, you do not put wheels on a robot that will roam a swampy land shaft and you do not need legs for a robot that works in outer space where no gravity is available.

People often associate robots with androids but when you decide how to build a real robot the anthropoid design should be your least concern. Building a robot at home should follow these basic principles of robotics that put function before design.

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Robots, especially military robots, can be designed to carry out unsafe, murky, or recurring tasks with constant precision and regular accuracy. Therefore, it is not hard to see why more and more industries are beginning to adopt robots for different applications. This is due to their usefulness. There are different types of robots. They vary in their uses, applications, and features. These come in diverse models or types and have different features such as the distance it can cover, the amount of payload it can accommodate, and how many axes their jointed arm contains. These are the main differences in the features of robots.

Military robots can work round the clock. They don’t get tired or go for breaks like human workers. Also, because robots are lifeless technologies, they can easily perform hazardous tasks that are otherwise challenging and unsafe for their human counterparts. The use of robotic technology equally boosts productivity and enhances profitability. At the same time, it can eliminate labor-intensive tasks that could pose some threats to their physical well-being and result in accidents or injury.

Benefits Of Robotics

Overall, robotics technology is finding its way into more industries today because:

1. They produce an accurate and more precise result.

2. They are flexible and can perform multiple roles.

3. They are comparatively cheaper compared to hiring human labor.

4. They are less noisy.

5. They boost work speed by roughly 50 percent.

Robotics has transformed the world in two stages. The first generation of robots performs repetitive and boring tasks in the industry. These groups of robots have extensive application in car manufacturing and assembly. The second phase of this robotic revolution produces robots that not only takes up simple recurring tasks but equally assimilate information and react to fresh information. Since not yet widely utilized, this second generation of robots is gradually dispersing from the automotive industry to other industries.

What Are Military Robots?

The robotic revolution is more evident in public safety and defense industry. The development of drones has revolutionized the industry. Presently, military robots help to carry out an investigation, provide support in the war front, and perform patrol tasks.

They equally have applications in public safety where drones are currently serving as the primary responders during accident incidents. Drones are useful in analyzing the situation of things in the accident scene real-time. Also, their uses include observing other types of accidents. Remote-controlled drones also have uses in the military for defense purposes.

Military robots have transformed how the military and public safety industry conducts their analysis and engage in surveillance activities. The use of automated machines to carry heavy weapons may make you nervous. However, these robots can potentially minimize the loss of life. Also, they can make it easier for soldiers to securely spy locations or breach enemy targets. The structures of a lot of military robots are for supporting life instead of eliminating life.

Benefits Of Military Robots

Robot army saves and preserves the lives of soldiers who may be killed by replacing the serving soldiers. Robot soldier doesn’t get tired. They don’t sleep or hide away from the weather elements. Moreover, they don’t while away the time by communicating with friends. The best of it all is that battle robots don’t have passion or emotion. This helps greatly to minimize the incidences of unethical behavior of soldiers during combat. Thus, the tiredness, strain, sentiment, and related feelings that affect the integrity of the soldier’s decisions are significantly minimized.

Types Of Military Robots

You’d be surprised to know that the history of war robots weapons utilized in military combat dates back to 1930s when the Soviet Union used it with their so-called teletanks. While the operator stayed in a different tank roughly 1, 500 meters at the back of the teletank, he operated the tank through radio signals. Also, during the Second World War, Germany made use of battle robots known as “Goliath” to track mines. Since then, due to technological advancements, armies use these types of robots to improve continuously and get better day after day. And today, we have different types of military robots with different uses.

Military Transportation Robots

These robotic soldiers perform transportation roles. They can help the soldiers in the transportation of bombs, artillery, military supplies, and other materials. Although these military robots commonly have wheels, some of them come with legs instead of performing on rough terrains.

Military robots used for transportation boost logistics efficiency and equally assist soldiers in their movements. They help to soldiers to carry materials to the battlefield. Also, they equally help to pick up causalities from the battlefield.

The soldiers who undertake risky combats receive payments for their task. However, they are still human and deserve to live, and so the use of robotics army in different tasks can be life-saving. Some of the life threats will be avoidable through using robotics army. At the same time, they can help in improving the transport system.

For instance, robots would be handy for extracting casualties from the battlefield. They could equally improve the transportation system like the Autonomous Platform Demonstrator or APD. APD is a military transportation robot that the United States Army Tank-Automotive Research designed.

Search And Rescue Military Robots

The use of these types of military robots is for search and rescue missions. A robot army can be of big help in search and rescue mission inside water and wilderness. They equally come handy when there are floods, wildfires, and wreckages during an earthquake.

Robot soldiers can also help in rescue missions during some incidents like tsunamis, tremors, and artificial disasters like the Chernobyl or 9/11 incident.

Fire Fighting Military Robots 

This type of robot soldiers can be of great use when there is fire. It can help to save the human soldier from life threat. The firefighting military robots are the type of robots that can be linked up with a hydrant to help in extinguishing the fire. They can save the lives of victims and also the lives of firefighters. These types of robotics army that assist firefighters are not yet common. However, some robot army at present is for such purposes. Some of these types of robot soldier help to investigate the situation in a fire site. There are equally some gigantic remote-controlled fire extinguishers.

Mine Clearance Military Robots

This type of battle robots is useful in very risky situations that can cost human lives. There are many war robots weapons utilized around the world today. They are commonly remote-controlled. Also, the operator is from a far distance to ensure his safety.

Surveillance And Reconnaissance Military Robots

These robotic soldiers are essential in spying the enemy. Many military robots are useful in surveillance and investigative missions. Future robots for surveillance and investigation will also have weapons.

Armed Military Robots

These are types of military robots have weapons to shoot people.

Unmanned Aerial Vehicle (UAV) Robots

These battle robots are flying robots designed for investigative missions. Also, their use is for surveillance missions. Future robots may include unmanned fighters and bombers.

Unmanned Ground Vehicles (UGV) Robots

The majority of the military robot types that we have discussed are UGVs. These robots are robots that operate on the ground.

Unmanned Underwater Vehicle (UUV) Robots

These robotic soldiers can swim underwater.

The uses of some types of army robots can be for surveillance purposes and equally for search and rescue missions. Similarly, the classification of the last types of military robots is according to the environment where they operate. They can work as military robots for rescue, surveillance, and mine clearance.

Military Robots Can Be Protectors Too

There you have it! The fantastic roles that military robots are playing in the army and how robotic soldiers can be integrated into defense and security system to boost protection, enhance the protection of lives, and improve efficiency while minimizing costs.

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Robotics is changing the world. There is hardly an industry anywhere that did not improve through robotics. Besides, this improvement is often dramatic. For this reason, robotic companies are growing at a rapid pace. Moreover, they offer many different types of opportunities for those who are aware of them. These opportunities include high-paying and interesting engineering jobs, such as:

• Robotics Engineers
• Software Developers
• Technicians
• Sales Engineers
• Operators

Another great thing about robotics companies is their diversity. The companies that make robots are both large and small, while some are well-known and new. They can be found in the United States and all over the world. Some of these are industrial robotics companies. Others are powering robots for consumer use. However, they all represent some of the most cutting-edge technologies available today.

In this article, we will detail not only the best robotics companies but also those who are developing the most ground-breaking applications in the field.

Best Robotics Companies

Canvas Technology

Canvas Technology is a robotics engineering company based in Boulder, Colorado. It is a very special type of industrial robot for manufacturing companies. The robot, which is called the Canvas Autonomous Cart, is essentially a self-driving cart with stereo cameras. These cameras use the latest in spatial AI technology to enable the robot to see an entire factory floor in three dimensions, from the ceiling down to the floor.

With its sensors, the robotic cart can collect and relay real-time information to decision-makers about manufacturing processes. This information not only helps companies improve and quicken these processes, but also make them significantly safer. The carts can also provide autonomous delivery of goods from one endpoint to another. This is likely the reason why Amazon purchased the company.

In the future, an adaptation of the company’s technology to devices will be possible. They might have vehicles that carry heavy goods and construction equipment.

Boston Dynamics

You might not be familiar with the name Boston Dynamics, but you are probably familiar with one of its most famous products. The robot manufacturing company is popular for making viral YouTube videos of Spot. It is the stunningly realistic robotic dog that the company manufactures. Soon, this dog will be doing a lot more than making interesting YouTube videos.

Marc Raibert, the founder of one of the world’s top robotics companies, recently indicated that they finally plan to commercialize Spot. Among the many real-world applications for this 25-kilogram robotic dog is in construction site inspection. The company has already posted a video in which Spot agilely navigates through a pair of Japanese construction sites while recording a video of the work done there.

The company is also developing a humanoid robot called Atlas. It can perform whole-body manipulations with its arms, legs, and torso, and can also leap over things such as logs.

Cruise Automation

Based in the San Francisco Bay area, Cruise Automation is a robotics company that focuses on driverless cars. In 2018, the company, which is owned by automotive giant General Motors, raised $1.65 billion from both Honda and Softbank. The latter has also heavily invested in Boston Dynamics.

Cruise Automation is currently developing several real-world applications for its driverless technology. First, they have partnered with the crowdsourcing platform DoorDash to test driverless food delivery to a few customers in the Bay area. Even more, they are testing a driverless ridesharing service in the area that they hope to launch at the end of the year, which will compete directly with both Uber and Lyf.

Diligent Robotics

Like Canvas Technology, Diligent Robotics is an industrial robotics company that is applying AI to robotics. The Austin, Texas company manufactures a robot called Moxi. The difference between it and most industrial robots is that it works not only on factory floors but also in ordinary workplaces.

Moxi’s deployment is in hospitals and other healthcare facilities. The robot can do many of the necessary but mundane tasks needed in these places, such as stocking shelves, preparing patient rooms, and anything else that does not directly relate to patient care. It does all this while effortlessly navigating corridors and tight spaces and while conveying intelligence through the actions of its head and eyes. All this frees the hospital staff so that they can focus on their primary task: providing care.

Harvard’s Biodesign Lab And Microrobotics Lab

When Bill Gates speaks, people generally listen. So, when the legendary Microsoft founder recently visited Harvard’s Biodesign Lab and Microrobotics Lab and wrote positively about his experience, it generated a lot of buzzes. The two organizations, which are associated with Harvard University, develop disruptive robotic technology translated into commercial applications through the formation of startups and corporate alliances, is at the forefront of robotics.

Among their innovations are the Soft Robotic Gloves, which they are currently developing. It augments human performance and restores it. Also, they have the RoboBee, which is a tiny and lightweight flying robot that will be deployed in swarms for applications such as:

• Search and Rescue Missions
• Surveillance Operations
• Artificial Pollination

Anybots

Anybots is a robotics company based in San Jose, California. It offers a unique form of robotics technology that they call mobile telepresence, which in effect allows someone to be in two places at once.

These robots are known as remote avatars. Moreover, they come with speakers, cameras, and video screens. Their owners can control how they function over the Internet through the use of Wi-Fi. Using a simple web interface, you can move the robots through any environment. Also, you can have them capture video of whatever they see and hear. You can even have them broadcast live video of yourself.

This could one day eliminate the need for long-distance business travel, and it could allow for the creation of a truly remote workforce. The robots could also facilitate remote doctor visits and patient care.

UBTech

Unlike many robotics companies in operation today, UBTech, located in Shenzhen, China, focuses not on industrial robots but products for consumers. Originally known for the toy robots they manufactured, the company has recently developed a full-featured humanoid robot called Walker that may remind many of Boston Dynamics’ Atlas.

Walker is a mobile and self-balancing service robot that not only exhibits rudimentary intelligence but can also traverse various terrains, such as stairs and slopes. It can even avoid obstacles in its path while recognizing faces and communicating with others whenever necessary. The robot has a variety of business uses, too, as it can function both as a receptionist and a concierge.

The company, which has received a $5 billion evaluation, has recently received close to $1 billion in financing.

Universal Robots

Universal Robots is an industrial robotics company based in Odense, Denmark that focuses on cobots, which are collaborative industrial robots. Instead of replacing workers in manufacturing plants and on factory floors, these robots work with them to make their jobs easier, more productive, and especially safer. The company, which is considered the leader in their field, has been selling cobots for more than a decade. Also, it has sold more than 25,000 of them in its history.

The Robotic Industries Association has said that cobots are the fastest-growing segment in the industrial robotics field and that by 2025, more than one-third of all industrial robots sold will be cobots. So, in spite of increased competition from those that have begun to enter the field, it is expected that the company will maintain its leadership position for some time to come.

AMP Robotics

Based in Denver, Colorado, AMP is a robotics company that is focusing on improving the environment. They develop a robotics system called Cortex, which uses neural network technology to reclaim recyclable materials in many challenging environments, such as at construction and demolition sites and mixed-waste sites. Combining arms, eyes, and a brain, these robots can both identify recyclable materials from other forms of waste and pluck them off at conveyor belts, and it does all this at high speed.

What makes these robots truly exceptional is that they keep getting smarter. They continually learn from their mistakes. You can further install and set up the device in less than two days, and it fits above any conveyor belt.

Left Hand Robotics

Left Hand Robotics, based in Longmont, Colorado, is a robotics company that builds self-driving vehicles. But instead of manufacturing self-driving cars, it develops self-driving snowplows.

Called the SnowBot Pro, you can control it remotely over the Internet using a simple mobile app. While it follows a pre-programmed path as it removes snow, it has sensors to help it avoid any obstacles in its way. It can also report and record real-time data about what it is doing. Best of all, the robot eliminates the need for people to be exposed to hostile weather conditions, and it reduces labor costs by as much as 60% while clearing snow up to 14 times faster.

What’s more, it can mow lawns, too.

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An ally, a tool, and a reliable companion in one: social robots.

Robots were first introduced to humans in the 1800s. This was during the Industrial Revolution. The earliest versions of robots were bulky. The early robots can only do one or two tasks. From then on, the rise of this technology advancement has come far. We cannot deny that our future will include working with this technology.

Industrial machines during the 1800s were early types of robots. These robots helped in making labor work easier. While social robots are designed to be much engaging and interactive. Industrial robots like the Unimate of 1954 did one task over and over. The Unimate was used in the car industry to assemble the products.

Social robots are now used to perform a wide range of tasks in a given time. This may include but not limited to utility, entertainment, and social and emotional functions. These tasks are considered to address the core needs of human beings. This is why we will certainly work with social robots more in the future.

What Is Transactional AI?

Robots are intelligent technology with autonomy. They can perceive and manipulate their surroundings without human help. Artificial intelligence or AI runs these robots. Humans teach robots by feeding them data. Robots, in turn, learn from humans through human behavior and interaction.

Robotics has come far and evolved a lot. This resulted in two categories: transactional AI and relational AI.

Transactional AI has gained popularity in 2014. Amazon released Alexa as a virtual assistant for its users. The program was made to be conversational. It was built to accomplish utility tasks. Alexa can answer questions, deliver news, give a weather update, and even play music. A woman’s voice embodied Alexa in a speaker.

What Is Relational AI?

Relational AI is gaining popularity because of its flexibility. Important institutions of society like schools, hospitals, and homes use this. A robot with limbs and face embodies the technology. The limbs enable it to walk and grasp things. The face makes it have a more personal connection to its users. Social robots are known as a robot companion to its human users. Its functionality addresses the utility, entertainment, and social and emotional human needs.

Relational AI runs social robots. On one hand, a speaker contains a transactional AI. They are stationary and do not have a personal human connection. On the other hand, social robots move around their environment like how humans do. Social robots learn from humans and use the gathered data to further improve the human experience.

Where is a Robot Companion Usually Used?

A robot companion can be the best option in improving your life value. Whether it be in school, at the hospital, at work, or even at home.

Need a tutor to tell your child a story? A teacher to help her widen her vocabulary without the insanely huge costs? Would prefer to have a companion at home? One that will inform you of the traffic situation on your way to work at 7 am every day? A companion that does this while they also turn off the lights for you when you run late? Need a partner during meetings that will ensure that your files are all intact? An assistant that will remind you of that important business presentation? A social robot can do all these and more.

A robot companion helps in daily tasks and to achieve different goals. In school, a robot can be a teacher. It can also provide emotional support to the students depending on which type of robot is available.

Just like the emotional robots used in health care facilities. These robots help patients of all ages to be more emotionally engaged. This process helps them in their recovery.

At home, a social robot can be the family’s security checker. Or it can be a convenient companion that will ensure that you’re early for school or work.  A robot can make a home feel more comfortable and guarantee a better life.

Social Robots for Kids

Schools use robots to teach as early as 1974. Micheal J. Freeman created a human-like robot called Leachim. The robot learned the school curricular and its students’ biographies. Modern robots like the Aido robot can give a one-on-one tutorial. This is for children and adults who wanted to learn about a certain topic.

Educational psychologist Benjamin Bloom published a study in 1984. It showed that students perform better when they learn through tutoring than in the classroom. However, it is expensive to get a tutor. Looking for a tutor can be a tedious process. Using social robots like Aido would be a big help to children and parents.

The health sector also uses social robots. This is especially with children and older adult patients. Deidre Logan, a pediatric psychologist at Boston Children’s Hospital, said that using robots is a way to help kids. It’s to make the patients feel okay with their situation. Kids at BCH are not doing the normal things that kids should be doing. Their time is spent inside the institution. So having cute robots like Huggable is a big help. It interacts with the kids. This is throughout their time in the hospital and even in their recovery.

Social Robots for Adults

The fourth vital sign is considered to be the emotion. This means that someone’s feelings affect his condition and recovery. There is a big gap in the supply of caretakers. The demand is high in hospitals and elderly home care. Social robots help fill this gap and address the emotional needs of patients.

Seniors are not as adaptive with technology compared to kids. But this was not the case in the 2018 study by Cynthia Breazeal. The study showed that older adults are more open to the possibilities of a social robot than the kids. Breazal—founder and director of the Personal Robots Group at MIT—suggested Jibo. Jibo is a social buddy robot. This makes it a perfect companion for the elders. It encourages engagement between elders. Jibo can improve one’s emotions through its entertainment functions. This includes dancing, taking a photo, telling jokes, answering questions and responding to touch. Yes, like a good pet, Jibo purrs when petted.

Even at home, social robots are deemed to be very convenient. A home robot can make the home easier to live in. It can help in tasks like give traffic updates in the morning or adjust the house temperature. It can even suggest recipes when cooking and dim lights at night. A home robot can also check around and patrol the house. It can make sure the security features are working and even play music and videos for the family.

The Future of Social Robots

We perceived a time when robots are working with us and help us accomplish tasks. We envisioned a future when robots are with us during our daily lives. Remember R2-D2? Or a newer version, Baymax? Movies may have heavily influenced us with this vision of humanistic robots. We envisioned those that are the combination of a human motivating ally, an internet cloud-connecting tool, and a pet that is also an attentive companion. We are living at the beginning of this future.

The more humans connect and engage personally with a robot, the more the technology is successful. This results in a more learned robot. Human-robot interaction benefits both parties. Humans are more confident in connecting with a non-judgmental affectionate system. Remember Theodore and Samantha from Her?

There are still a lot of studies to be made about this technology. There is also a wide range of ethical points to be considered. But we are all still heading towards a more convenient future with social robots at our side. Soon enough, there would be a buddy robot for everyone. This is not to replace humans, or smartphones, or dogs — but to have a new autonomous system that will help humanity flourish.

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A robot is an artificial machine. It can accomplish different ranges of human tasks or actions. These actions can either autonomous or independent of humans or through the use of remote control. Thus, some robots are autonomous, while others are semi-autonomous.

Robotics machines are programmable using a computer. Some types of robotics have internal control mechanisms. However, some operate through an external control device. Moreover, some kinds of robots replicate the human structure. However, many robot examples are just machine performing tasks irrespective of their looks.

Robots can mimic a lifelike form or automate movements. This way, different kinds of robots might express intelligent sense or form a thought of their own. Robotics is the technology that deals with robot design, production, process, and use of robots.

Robotics equally includes the study of computer systems designed for controlling robots, developing sensory feedback, and handling of information. It is the science that studies the robot.

What Are Robots Used For?

Robotics technologies involve automated machines. These machines replace humans in risky environments or production processes. They look like humans in appearance, behavior, or cognition.

The majority of robots today perform repetitive tasks or actions. They are excessively dangerous for humans. For instance, some robots are useful in place with a potential bomb. They help in bomb detection and deactivation.

Factories are utilizing robots for building cars, candy bars, and electronics. Moreover, they have applications in medicine, military strategies, objects discovery underwater, space travels, and for exploring other planets. Additionally, robotic technology is beneficial for individuals with no arms or legs.

In a lot of instances and for a lot of different reasons, robots are in-demand. Some are using robots in places where it isn’t possible for humans to go. For instance, in an extremely hot environment or high heat and for cleaning or controlling of dangerous substances and radiation. Robots that replicates human appearance makes it easy to accept them in specific repetitive actions that people usually do.

These types of robots try to imitate the way of walking, lifting objects, speaking, reasoning, and other human-related actions.

Uses Of Robotics

At present, the field of robotics is evolving at a rapid rate. This is due to technological innovations and advancements. Researchers continue to brainstorm and innovate on how to design and build new types of robots. They want them to be useful for domestic uses, commercial uses, and military intelligence and combat purposes.

Robots are performing tasks that are too dangerous for humans like neutralizing bombs. Furthermore, robots can help to search for human survivors in insecure ruins. Additionally, they can aid in discovering mines and shells. Robotics is also a teaching aid in STEM. STEM stands for Science, Technology, Engineering, and Mathematics.

The introduction of nanorobots is yet another advancement made in robotics. They transform medicine and human health. These are microscopic robots introduced into a human body for medical reasons.

Reasons To Use Robots

The main reason to use robots is they are frequently cheaper than human workers. Besides, some jobs are easier done with robots. Nonetheless, other tasks undertaken by robots are tasks that humans can’t perform.

There are different types of robots used for exploring the inner parts of gas tanks, the interior parts of volcanoes, and traveling in the space like going to the surface of Mars. Moreover, different kinds of robots can go to other locations that are very dangerous for humans or in places with extreme temperatures. In addition to this, there are robot examples that can work in places that are contaminated for humans.

Robots can perform a singular task repetitively without being bored. You can employ different types of robots for drilling, welding, and painting tasks. Moreover, different kinds of robots can grip dangerous substances. In a lot of instances, robots produced more precise results compared to their human counterparts. This, in turn, minimizes production costs by eliminating costly mistakes and potential hazards. Robots don’t fall sick. They don’t sleep or need to break to eat. Moreover, they don’t go on vacation or get tired. And so, the benefits and uses of robots to man are numerous.

Types Of Robots

It is difficult to find one single definition for a robot. And so, classifying robots is not an easy task. Robots differ greatly in size, shape, and capacities. Furthermore, every robot comes with peculiar features. However, they have some features in common. All robots have controllers, mechanical parts, and sensors. So, what are the different types of robots?

Aerospace Robots

Aerospace robots cover a wide category of different kinds of robots. These include different types of flying robots. Examples are the robotic seagull produced by SmartBird. Another one is the security surveillance drone that Raven built. These types of robots, equally, include robots that can visit the surface of Mars. These robot examples are humanoids, Mars Rovers, and NASA’s Robonaut.

Consumer Robots

Consumer robots perform tasks like purchasing and utilization for fun. They can also do chores for people. Examples are Aibo, the robot dog, the Roomba vacuum cleaner, Artificial intelligence-powered robot assistants. Additionally, there are different types of robot toys and kits.

Disaster Response Robots 

Disaster response robots carry out risky tasks like searching for survivors after a disaster. For instance, after the 2011 Japan tsunami earthquake, Packbots were sent to investigate the Fukushima Daiichi nuclear power station to estimate the degree of damage.

Drones

Drones are aerial vehicles not controlled by humans. These vehicles come in a wide variety of sizes and come with varying degrees of autonomy. Examples of drones are the Global Hawk military system, the well-known Phantom series of DJI, and the Anafi Parrot.

Education Robots

Education robots include a wide range of different types of robots. They are designed for teaching in the classroom or home use. Examples of this type of robotics include proactive programmable electronics like Lego, 3D printers that come with teaching plans. It equally includes teacher robots like EMYS.

Entertainment Robots

Entertainment robots are types of robots intended to arouse our emotions. Robots for entertainment purposes include RoboThespian; a robot comedian, Navi Shaman; a Disney theme park robot, and Partner; a robotic musician.

Exoskeleton Robots

For physical therapy, there are exoskeleton robots. This type of robot can make a paralyzed individual get back on his or her feet again. However, the military and other industry are also using exoskeleton robots. They offer extra mobility capacity to the user. They enable him or her to have more strength to lift heavy loads.

Humanoids

Humanoids are the type of robots that many people are familiar with. These are robots that replicate human appearance. Examples of this type of robot include Asimo, produced by Honda and Geminoid robot series that resemble human beings.

Industrial Robots

These types of robots come with an arm used to carry out recurring tasks. Examples of this type of robots include the factory robot, Unimate, the Amazon warehouse robots, and collaborative factory robots which serve as a human co-worker.

Medical Robots

Medical and healthcare robots are robots employed for curative purposes. They include types of robotics like the da Vinci surgical robot, bionic prostheses, and robotic exoskeletons.

Military And Security robots

Military robots are for security, surveillance, and combat purposes. This type includes the Endeavor Robotics’ PackBot. This is for discovering makeshift explosives in Iraq and Afghanistan.

It equally includes robot types like the BigDog. This helps in lifting heavy tools and different types of machinery. An example of a security robot is the self-governing mobile edifices like Cobalt.

Research Robot

University and company’s research laboratories developed most types of robots today. However, research robots are different. The primary reason for designing them is to assist researchers in their research work. This means that some robots that fall into different classifications may equally qualify as research robots.

Self-Driving Car Robots

There are different types of robotic self-driving cars around. Many of these cars can as well drive human beings. The primary designs of self-driving cars include vehicles designed for the DARPA’s self-driving vehicle contests. Also, Google pioneered self-driving Toyota Prius. This one gave rise to Waymo.

Telepresence Robots

These are the types of robots that enable you to explore a location remotely and be present in the location while remaining where you are. You can sign into a robot avatar through the internet. Once you log in, you can drive the robot around. Moreover, you can view the things that the robot sees. Also, you can speak to people in that location without being there physically.

Remote workers can utilize this type of robots to work together with their co-workers at a far-away office. Additionally, medical practitioners can use these types of robots to verify how their patients are doing.

Underwater Robots

Beneath the surface of the water is where deploying these robots are possible. Examples of these types of robots include marine submersibles such as Aquanaut, humanoids that dive.  Other examples are Ocean One and biological motivated robotics like the snakebot known as ACM-R5H.

Main Types Of Industrial Robots

There are six classifications of industrial robots. These include the articulated robots, Cartesian robots, the SCARA robots, the cylindrical robots, delta robots, and polar robots. Nonetheless, there are other types of robots structures. All of these feature various type of joint structures with the joints known as axes.

The standard type of industrial robots is articulated robots. Articulated robots come with rotational joints which can differ from two to ten joints. Additionally, some robots come with more than ten joints. The most common types of articulated robots come with six axes.

The axes give the robot optimal mobility or flexibility. A joint that twists is linking the arm of these robots to the base. Robots that have six axes are of big help in handling materials, tending machines, welding an arc, or spot welding.

Robotics For A Modern World

There are different types of robots. These vary widely and can range from humanoids like the Advanced Step in Innovative Mobility (ASIMO), developed by Honda. Another one is the TOSY Ping Pong Playing Robot (TOPIO), developed by TOSY. Also, there are medical and healthcare robots, like the microscopic nanorobots.

These different types of robots, irrespective of their form, take care of repetitive tasks that are better automated and tasks that are risky for human workers. The benefits of robotics to humanity continue to evolve by day with technological advancements. No doubt, robots and the robotics industry are there to revolutionize our modern world for the better.

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