THE SCIENCE BEHIND SWING ANALYSIS: HOW HIGH SPEED CAMERAS ARE BOOSTING ATHLETICISM

 

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Gone are the days of relying solely on coaches’ eyes to improve athletic performance. Thanks to the advancements in technology, high-speed cameras have taken over the sports world, revolutionizing swing analysis and boosting athleticism like never before. In this blog post, we’ll dive into the science behind how these powerful tools are changing the game for athletes everywhere.

INTRODUCTION TO SWING ANALYSIS

There are a lot of different ways to analyze a golf swing, but high-speed cameras are becoming increasingly popular. Why? Because they can provide detailed information about the mechanics of the swing that can help golfers make necessary adjustments.

While there are many factors that go into a good golf swing, there are three main elements that a high-speed camera can help identify: clubhead speed, clubface angle, and attack angle. By analyzing these elements, golfers and their instructors can pinpoint areas of improvement.

Clubhead speed is perhaps the most important factor in determining distance. A high-speed camera can capture clubhead speed at impact, which can then be used to calculate how fast the club was moving at various points throughout the swing. This information can be used to help a golfer generate more speed or make necessary adjustments to their swing.

Clubface angle is another important element that can affect both accuracy and distance. A high-speed camera can help identify when the clubface is open or closed at impact, which can be used to make necessary corrections. Attack angle is also captured by high-speed cameras, and this information can be used to ensure that the club is entering the ball on the correct path.

By using high-speed cameras to capture all of this data, golfers and their instructors can get a much clearer picture of what’s happening during the swing. With this information, they can make more informed decisions about what needs to be changed.

HOW HIGHSPEED CAMERAS ARE USED IN SWING ANALYSIS

Highspeed cameras are becoming increasingly popular in the world of swing analysis. This is because they offer a level of detail and accuracy that was previously impossible to achieve. By analyzing a player’s swing at high speeds, coaches and trainers can identify small flaws and correct them. This can lead to big improvements in performance.

There are many different ways that highspeed cameras can be used to analyze a swing. One common method is to use two cameras, set up at different angles, to capture the action. This allows for a side-by-side comparison of the two swings. Another method is to use a single camera to capture the action from start to finish. This provides a more detailed view of the entire swing.

Once the footage has been captured, it can be slow down and studied frame by frame. This allows coaches and trainers to see exactly what is happening at each stage of the swing. By identifying small flaws, they can make corrections that will lead to big improvements in performance.

THE BENEFITS OF USING HIGHSPEED CAMERAS

Highspeed cameras are becoming increasingly popular in the world of sports. Their ability to capture very fast movements makes them ideal for analyzing an athlete’s technique. Here are some of the benefits of using highspeed cameras for swing analysis:

1. Increased accuracy
   Highspeed cameras allow you to slow down the action and see things that you would miss if you were just watching in real time. This can help you identify small improvements that can make a big difference in your performance.


2. Better understanding of the mechanics
   When you analyze your swing with a highspeed camera, you can get a better understanding of the mechanics involved. This can help you make adjustments to improve your technique.


3. Greater insight into your strengths and weaknesses
   By looking at your swing from different angles, you can get a better idea of what areas need improvement. This knowledge can help you focus your training so that you can make the most progress possible.


4. Improved performance
   The ability to see your swing in slow motion and identify areas for improvement can lead to better performance on the field or court. Highspeed cameras can help you take your game to the next level.

HOW SWING ANALYSIS IS IMPROVING SPORTS PERFORMANCE

Swing analysis is the process of using high-speed cameras to capture and analyze an athlete’s movement. This technology is often used in golf and baseball, but can be applied to any sport where improving performance through proper technique is a priority.

There are many benefits to swing analysis, but the most important is that it provides athletes with feedback that they can use to improve their technique. When an athlete knows exactly what they need to work on, they can make the necessary adjustments and see real results on the field or court.

Another benefit of swing analysis is that it can help coaches identify areas where their athletes need improvement. By analyzing an athlete’s swing, coaches can pinpoint specific areas that need attention and create customized training programs to help their athletes reach their full potential.

Finally, swing analysis is a valuable tool for research purposes. By studying how athletes move, scientists can learn more about human movement and performance. This knowledge can then be used to develop new training methods and techniques that will help athletes of all levels reach their goals.

CASE STUDIES OF PROFESSIONAL ATHLETES UTILIZING SWING ANALYSIS

Swing analysis is a field of study that uses high-speed cameras to capture and analyze the motion of an athlete’s swing. This information can be used to improve the athlete’s performance and prevent injury.

There are many case studies of professional athletes who have utilized swing analysis to improve their game. One such example is golfer Tiger Woods. Woods used swing analysis early in his career to help him make minor adjustments to his swing that led to major improvements in his game. As a result, Woods became one of the most successful golfers in history.

Other professional athletes who have used swing analysis include baseball players Alex Rodriguez and Miguel Cabrera, as well as tennis player Rafael Nadal. Each of these athletes has benefited from using swing analysis to fine-tune their respective swings and take their game to the next level.

If you’re looking to improve your own athletic performance, utilizing swing analysis could be a great option for you. By working with a certified coach or trainer, you can get started on making small changes that could lead to big results down the road.

FUTURE APPLICATIONS OF HIGHSPEED CAMERAS IN ATHLETICS

The use of highspeed cameras in athletics is still in its infancy, but the potential applications are vast. Here are just a few examples of how highspeed cameras could be used to improve athletic performance in the future:

1. Measuring and improving pitching mechanics
   Highspeed cameras can capture a pitcher’s delivery in incredible detail, allowing coaches to identify and correct any mechanical flaws


2. Tracking the movement of athletes during competition
   By tracking the movements of athletes during a game or match, coaches can better understand their strengths and weaknesses. This information can be used to tailor training programs and improve performance.


3. Analyzing an athlete’s biomechanics
   Highspeed cameras can provide invaluable insights into an athlete’s biomechanics, which can be used to optimize their technique and prevent injuries.


4. Studying the effects of fatigue on performance
   Fatigue is a major factor in athletic performance, and highspeed cameras can help researchers understand how it affects different athletes. This information can be used to develop strategies for managing fatigue and maximizing performance.


5. Investigating concussions
   Concussions are a serious issue in sports, and highspeed cameras could be used to study their effects on athletes’ brains. This research could lead to improved treatments and prevention strategies.

CONCLUSION

Highspeed cameras have revolutionized the way athletes train and perform on the field. By being able to accurately measure a variety of metrics, athletes can gain an advantage over their opponents and increase their athleticism by making small adjustments in their swing analysis. With such a powerful tool at our disposal, it is no wonder that highspeed cameras are becoming increasingly popular among coaches and players alike for analyzing performance and technique.

FOR MORE INFORMATION ON COGNEX MACHINE VISION SYSTEMS INDIA CONTACT US AT MVASIA INFOMATRIX PTE LTD +65 6329-6431 OR EMAIL US AT INFO@MVASIAONLINE.COM

WATEC: PIONEERING EXCELLENCE IN LOW-LIGHT CAMERA TECHNOLOGY

 

In the fast-paced world of technology, the demand for high-quality low-light cameras in Singapore has never been greater. As low-light environments pose unique challenges for capturing clear and detailed imagery, it's imperative to have access to reliable solutions that can thrive in such conditions. This article explores the landscape of low-light cameras in Singapore, focusing on the pioneering work of companies like Watec in delivering cutting-edge technology to meet the country's specific needs.

THE FOUNDATION: UNDERSTANDING LOW-LIGHT CHALLENGES IN SINGAPOR

Singapore's urban landscape, known for its vibrant night scene, presents numerous low-light challenges that require advanced camera technology. From surveillance in dimly lit alleys to capturing elusive wildlife after sunset, the demand for cameras that excel in low-light conditions is on the rise. Watec, a renowned name in the field, has consistently strived to meet these unique requirements with innovative solutions.

WATEC IN SINGAPORE: A LEGACY OF EXCELLENCE

Watec, with its legacy of excellence in low-light cameras, has been a key player in addressing these challenges. For years, Watec has pushed the boundaries of low-light camera technology, leading the way in true low-light gathering capabilities. Their dedication to delivering high-quality solutions aligns perfectly with Singapore's need for advanced low-light cameras.

MEETING THE MISSION: TAILORED SOLUTIONS FOR SINGAPORE

To meet the specific demands of the Singaporean market, Watec embarked on a mission to develop low-light cameras that could cater to the unique requirements of the region. Understanding that a one-size-fits-all solution wouldn't suffice, Watec adopted a versatile approach. Instead of a single universal camera, they designed a range of cameras, each tailored to address specific low-light challenges in Singapore.

THE SINGAPOREAN LOW-LIGHT ARSENAL

1. WAT-3500: Brilliant Analog Performance (0.00003Lux)
   Watec's analog offering, the WAT-3500, stands as a testament to their commitment to delivering top-tier performance. With a remarkable low-light rating of 0.00003Lux, this camera excels in low-light conditions, capturing details that were once considered elusive. It doesn't just replace the 902H series; it surpasses it in terms of low-light capabilities.


2. WAT-933IP: Full HD IP Camera (0.00007Lux)
   In Singapore's world of high-definition video, the WAT-933IP takes center stage. Boasting full HD capabilities and a remarkable low-light rating of 0.00007Lux, it's the perfect solution for those who demand unparalleled clarity in low-light conditions.


3. WAT-3200: SDI Expertise (0.00005Lux)
   The WAT-3200 is tailored to meet the requirements of the Serial Digital Interface (SDI) in Singapore. With a low-light rating of 0.00005Lux, it excels in low-light environments, providing top-notch performance for challenging scenarios.


4. WAT-07U2 Series: USB Flexibility (0.0001Lux)
   The WAT-07U2 series offers flexibility and adaptability through the USB interface, catering to a wide range of project demands. With a low-light rating of 0.0001Lux, these cameras ensure versatility without compromising on quality.

QUALITY ASSURANCE IN THE SINGAPOREAN LOW-LIGHT MARKET

In a niche market like Singapore's low-light technology sector, the importance of quality cannot be overstated. Authentic low-light performance is a necessity, as it directly impacts outcomes in diverse applications, from security to wildlife preservation. Customers in Singapore understand the significance of high-quality low-light camera solutions but may face challenges in identifying trustworthy providers.

WATEC'S DEDICATION TO QUALITY

Watec stands out in the Singaporean low-light camera market not only due to their impressive low-light capabilities but also because of their unwavering commitment to quality. They employ only the highest-grade components in their cameras, ensuring that every aspect of their technology meets the highest standards. In addition, Watec employs advanced engineering techniques, including triple and quadruple layering of their board designs. These design strategies effectively regulate temperatures and reduce noise, preserving image clarity even in the most challenging low-light scenarios.

PATENTED LOW-LIGHT TECHNOLOGY: WATEC'S DISTINCTIVE EDGE

One of Watec's defining features is their patented low-light technology. This proprietary innovation sets them apart in Singapore's low-light camera market. It's the key to their ability to offer the lowest light-gathering cameras available. This technology is the culmination of years of research and development, driven by a commitment to pushing the boundaries of what is possible in the low-light camera space.

CONCLUSION

WATEC'S journey from the pioneering 902H series to their latest range of low-light cameras is a testament to their dedication to quality and innovation. They haven't just met industry standards; they've exceeded them, offering tailored solutions for Singapore's unique low-light challenges.

In a market where impostors make lofty claims, Watec's track record of delivering on promises and their proprietary low-light technology make them a trusted and reliable partner for those who demand the best in low-light camera performance in Singapore. When you need true low-light camera capabilities in the Lion City, look no further than Watec, a company that consistently redefines the boundaries of low-light camera technology.

FOR MORE INFORMATION ON COGNEX MACHINE VISION SYSTEMS INDIA CONTACT US AT MVASIA INFOMATRIX PTE LTD +65 6329-6431 OR EMAIL US AT INFO@MVASIAONLINE.COM

THE PIVOTAL ROLE OF CONNECTIVITY IN MACHINE VISION INDUSTRIES

 

Machine vision technology has been a revolutionary force in transforming the way we perceive and interact with the world. Its applications span across diverse industries, from revolutionizing manufacturing processes to enhancing medical diagnostics. At the heart of this cutting-edge field lies the remarkable capability of machines to not only capture visual data but also interpret it. This pivotal role has made machine vision an indispensable component in the realms of automation and quality control across various sectors.

In this comprehensive exploration, we delve into the critical role that connectivity plays in augmenting the effectiveness and efficiency of machine vision systems. By understanding the various components of connectivity in the machine vision industry and their ultimate importance, we gain insight into the transformative power of this technology.

MACHINE VISION CONNECTIVITY COMPONENTS

To comprehend the significance of connectivity in machine vision, it's essential to first dissect the core components involved in the process. These components are the building blocks that enable machine vision systems to function seamlessly and efficiently.

1. Cameras and Sensors:
   At the epicenter of machine vision are cameras and sensors, which serve as the eyes of the system, capturing images and data. These devices are responsible for acquiring the visual information essential for machine vision applications. The connectivity of cameras and sensors is crucial for facilitating data transfer and system control. In modern machine vision, cameras often feature various interfaces such as GigE Vision, USB, or CoaXPress, which ensure the smooth transmission of data.


2. Frame Grabbers:
   Frame grabbers serve as intermediaries between cameras and computers. Their primary function is to capture data from cameras and make it available for processing. These devices come equipped with diverse interfaces to accommodate different camera types and are essential for ensuring data continuity and integrity.


3. Cabling and Interfaces:
   High-quality cables and interfaces are vital for transferring data between machine vision system components without interference or loss. The choice of cables and interfaces should be carefully considered to meet the specific requirements of the machine vision system, ensuring that data flows seamlessly and without degradation.


4. Networking and Communication:
   Connectivity within the machine vision environment extends to networking and communication between various components and even between different machines. Ethernet connections are commonly used to link multiple devices and facilitate data exchange, enabling coordinated efforts among different parts of the system.


5. Software and Processing Units:
   Software is a critical component of machine vision, as it plays a pivotal role in interpreting visual data and making decisions based on that data. Machine vision software must be compatible with all hardware components and should facilitate seamless communication. In addition, processing units, whether located on-site or in the cloud, are essential for data analysis and decision-making.


6. Industrial Protocols:
   In an industrial setting, machine vision systems often need to interact with other machinery and control systems. Implementing standard industrial communication protocols, such as OPC-UA or MQTT, ensures interoperability and connectivity with the broader industrial ecosystem. This allows machine vision to be seamlessly integrated into larger industrial processes.

THE IMPORTANCE OF CONNECTIVITY IN MACHINE VISION

Connectivity in the realm of machine vision is not a mere convenience; it is a fundamental requirement. Its significance is highlighted by the following key factors:

1. Real-time Decision Making:
   In industries where speed and precision are of paramount importance, such as manufacturing, connectivity is the linchpin that enables machine vision systems to make real-time decisions. This capability is crucial in delivering quality control, defect detection, and automation, ensuring that products meet rigorous standards consistently.


2. Remote Monitoring and Control:
   Connectivity facilitates remote monitoring of machine vision systems, a capability that proves especially useful in quality control within distributed manufacturing plants. It also aids in diagnosing issues without the need for physical presence, saving time and resources.


3. Data Sharing and Integration:
   Machine vision systems generate vast amounts of data. Connectivity is the conduit that allows for the sharing of this data with other systems, thereby enabling better decision-making across the organization. Integration with enterprise resource planning (ERP) systems and other databases becomes possible, creating a more streamlined and efficient workflow.


4. Scalability:
   As the needs of the industry change and evolve, machine vision systems must be equally adaptable. Connectivity is the key that makes it easier to add or upgrade components without disrupting any existing system. This ensures that machine vision systems can grow and change in tandem with the industry they serve.


5. Reduced Downtime:
   Effective connectivity can often lead to proactive maintenance. By monitoring the status of cameras, sensors, and other components in real-time, issues can be identified proactively and resolved before they cause significant downtime. This not only saves time but also ensures continuous, reliable operations.


6. Quality and Consistency:
   Connectivity is the linchpin that ensures machine vision systems maintain consistency in quality control and inspection processes. This is particularly crucial in industries such as pharmaceuticals, automotive manufacturing, and food production, where precision and adherence to stringent quality standards are non-negotiable.

CONCLUSION

In summary, connectivity is an indispensable enabler of the machine vision industry. The ability of machines to see and interpret visual data is entirely contingent on reliable and seamless connections between components. As technological advancements in connectivity continue to emerge, they will undoubtedly play a significant role in the evolution and growth of the machine vision industry, driving efficiency, accuracy, and innovation across various sectors.

As industries continue to embrace automation and data-driven decision-making, connectivity in machine vision will remain at the forefront of these exciting and transformative changes. By recognizing its pivotal role and investing in cutting-edge connectivity solutions, organizations can position themselves at the vanguard of this dynamic and ever-evolving field.

FOR MORE INFORMATION ON COGNEX MACHINE VISION SYSTEMS INDIA CONTACT US AT MVASIA INFOMATRIX PTE LTD +65 6329-6431 OR EMAIL US AT INFO@MVASIAONLINE.COM

AI DECISION-SUPPORT IN MANUFACTURING: ENHANCING QUALITY AND EFFICIENCY

 

In an era of rapid technological advancements, the manufacturing industry has witnessed significant progress. While automation and robotics have transformed various aspects of production, humans continue to play a vital role in many manufacturing processes. Small and medium-sized enterprises (SMEs) often find it economically unviable to automate production for short-run or customized products. However, from a quality assurance perspective, these enterprises are keen to leverage technological advancements that can assist human operators in making subjective decisions, ultimately ensuring consistent and reliable product quality.

This article delves into the integration of AI-based decision-support tools into manual manufacturing, production, and assembly processes. We will explore how these tools can accelerate assembly and inspection rates, enhance end-to-end quality, and provide valuable qualitative product evaluation and operational data, thus ensuring repeatable and traceable processes.

AI AND DECISION-SUPPORT APPLICATIONS

Two real-world examples of companies harnessing AI-based decision-support tools to aid their operators in manufacturing products not well-suited to fully automated quality inspection processes are Vodkow, a dairy distillery, and DICA, an electronics manufacturer.

VODKOW'S AI INTEGRATION

Vodkow employs a suite of AI-based decision-support tools during their manual in-process manufacturing and final inspection steps. These tools eliminate subjective decision-making and reduce the potential for human error. The outcome is not only a smoother production process but also a significant reduction in downtime, minimized waste, and consistent brand appearance for their products.

DICA'S AI AND MACHINE LEARNING IMPLEMENTATION

On the other hand, DICA leverages AI and machine learning to assist their operators in detecting errors that are commonly missed by automated optical inspection (AOI). These errors encompass issues related to component orientation, solder defects, through-hole problems, and labeling discrepancies. Furthermore, DICA employs product tracking and reporting apps to gather data pertaining to their manual processes. This data serves to expedite issue resolution when a problem is identified in the field.

KEY BENEFITS OF AI DECISION-SUPPORT

The integration of AI-based decision-support tools into manufacturing processes offers several notable advantages:

1. Consistency and Reliability: AI ensures consistent and reliable human decision-making throughout the production process, from incoming materials inspection to in-process manufacturing and final product inspection.


2. Training Support: AI aids in training new employees, providing them with valuable insights into assembly techniques, key brand elements, and product packaging variations. This training reduces errors, minimizes waste, and prevents production delays.


3. Real-time Insights: AI enables manufacturers to gain real-time data from manual manufacturing processes. This data provides end-to-end operational insights, allowing for quicker responses to potential issues.


4. Data Eliminates "Data Black Holes": AI closes the gap on "data black holes" in manual manufacturing by providing the necessary data for analysis, tracking, reporting, and continuous improvement initiatives.


5. Expertise Amplification: With AI decision-support tools, the skills and expertise of the best inspectors can be leveraged across multiple production runs, facilities, or even with newly hired operators. This amplification of expertise leads to higher quality, reduced costs, and ultimately increased profitability.

AI DECISION-SUPPORT IN TRAINING AND DEPLOYMENT

One of the most significant advantages of AI decision-support tools is the simplification of training and deployment. Manufacturers can empower their operators to benefit from these tools without requiring extensive technical expertise. This democratization of advanced technology levels the playing field for businesses of all sizes.

AI decision-support aids in training new employees, as mentioned earlier, but it also offers a standardized, consistent approach to instruction. Operators can quickly learn and apply best practices across various manufacturing processes.

In addition to training, AI facilitates the deployment of expert knowledge. Manufacturers can replicate the decision-making capabilities of their most experienced inspectors across multiple production runs and facilities. This not only ensures quality consistency but also mitigates the risk of relying solely on human judgment, which can be subject to errors and inconsistencies.

REAL-TIME OPERATIONAL INSIGHTS

AI decision-support tools provide real-time insights into manufacturing operations. This capability is invaluable for identifying issues and optimizing processes on the fly. Operators can access data that reflects the current status of production, enabling them to make informed decisions.

These insights also contribute to proactive maintenance and issue resolution. With AI, manufacturers can detect anomalies or deviations from expected outcomes in real time. This early detection allows for quicker intervention, reducing the likelihood of costly production delays or quality issues.

CLOSING THE GAP ON "DATA BLACK HOLES"

"Data black holes" refer to areas in manufacturing processes where data is lacking or insufficient for meaningful analysis. In manual manufacturing, such gaps can hinder a company's ability to improve processes, optimize quality, and reduce waste. AI decision-support tools bridge these data gaps by capturing and analyzing information at critical points in the production process.

The data collected can be used for various purposes, including root cause analysis, quality improvement initiatives, and regulatory compliance. It also aids in maintaining product traceability, a crucial aspect for quality assurance and recalls.

ENHANCING QUALITY AND EFFICIENCY

AI decision-support tools not only ensure consistent and reliable decision-making but also contribute to a significant enhancement in the overall quality and efficiency of manufacturing processes. By minimizing human error and standardizing best practices, these tools lead to reduced downtime and waste, as evidenced by Vodkow's success. Similarly, DICA's use of AI to detect errors missed by automated inspection has a direct impact on product quality.

Furthermore, the benefits extend beyond the manufacturing floor. The data collected and analyzed by AI supports decision-making at various levels of the organization. From real-time operational insights to data-driven continuous improvement initiatives, AI enables manufacturers to make informed choices that drive quality, reduce costs, and, ultimately, increase profitability.

CONCLUSION

The integration of AI-based decision-support tools into manual manufacturing, production, and assembly processes represents a powerful strategy for enhancing product quality and efficiency. By providing consistent and reliable decision-making, aiding in training, and offering real-time insights, AI decision-support tools empower manufacturers to improve their operations and make more informed choices.

Furthermore, these tools close the gap on "data black holes," enabling companies to capture and analyze critical data for analysis, tracking, and reporting. The result is a manufacturing process that is not only more robust but also more adaptable, capable of meeting the demands of short-run or customized products, which may not be well-suited for full automation. In conclusion, AI decision-support tools provide a pathway to higher quality, lower costs, and increased profitability for manufacturers of all sizes. As technology continues to advance, their role in manufacturing will only become more prominent, ensuring that human operators remain an integral part of the manufacturing landscape.

FOR MORE INFORMATION ON COGNEX MACHINE VISION SYSTEMS INDIA CONTACT US AT MVASIA INFOMATRIX PTE LTD +65 6329-6431 OR EMAIL US AT INFO@MVASIAONLINE.COM

INNOVATIONS IN MEDICAL IMAGING CAMERAS AND THEIR VERSATILE APPLICATIONS

 

In the realm of medical examinations and endoscopy, the development of cutting-edge cameras has been a pivotal driving force in enhancing diagnostic capabilities. The commitment to delivering top-tier medical imaging cameras and endoscope cameras at affordable prices is the cornerstone of our mission. This dedication to excellence begins with our meticulous multi-layer board designs, precision engineering processes, and the careful selection of high-quality components. It culminates in the provision of reliable and flawless viewing capabilities. In this article, we delve into the world of medical imaging cameras, their multifaceted applications, and the innovative solutions offered by Watec, a proven leader in the industry.

THE EVOLUTION OF WATEC:

Watec's journey into the domain of medical imaging cameras and endoscope cameras is steeped in a rich history of over 25 years. What began as a provider of miniature CCD cameras for Factory Automation and Machine Vision has now evolved into a digital imaging powerhouse. Watec has adapted to the changing technological landscape, offering a diverse range of miniature USB, HD, IP, and Camera Link technology options to meet the evolving demands of its customers.

One of Watec's distinctive features lies in its multi-layered board designs, which play a pivotal role in minimizing noise and eliminating unwanted imaging artifacts. This commitment to engineering excellence results in some of the highest quality images available in the market. Whether it's for scientific research, laboratory applications, laser measurement, pharmaceutical manufacturing, or imaging reproduction monitoring, Watec stands as a reliable provider of high-quality cameras that cater to a myriad of needs.

LOW LIGHT IMAGING EXCELLENCE:

One of the most remarkable achievements in the field of medical imaging cameras is the development of low light cameras. At Watec, we define a low light camera device as one with the unparalleled ability to clearly identify objects of interest in Near Infrared Reflectance (NIR) environments, akin to starlight conditions. This entails the provision of sharp, crisp lines and easily identifiable features in a minimal low noise output, all under extremely low light settings.

Watec's expertise in this domain is exemplified by its ability to produce cameras capable of capturing clear and detailed images in conditions where conventional cameras fail. This capability has far-reaching implications in fields such as astronomy, where the need for high-quality imaging in low light is paramount. Moreover, applications in surveillance, law enforcement, and military operations benefit immensely from Watec's low light camera technology, ensuring that critical details are not lost in the shadows.

REVOLUTIONIZING IP CAMERAS:

In the era of digital imaging, Watec has been at the forefront of innovation in the development of miniature IP cameras. These cameras offer a host of advantages, including full HD resolution, exceptional sensitivity in low and ultra-low light conditions, and a compact form factor. What sets Watec's IP cameras apart is their patented low light camera technology and the integration of double and triple layered board designs.

This cutting-edge technology allows Watec's IP cameras to deliver crisp and clear images even in ultra-low light environments, surpassing the capabilities of analog cameras. The reduction of noise and elimination of unwanted imaging artifacts under extreme dark conditions further solidify Watec's position as a leader in the industry. These cameras are ideally suited for applications where image quality cannot be compromised, such as in medical imaging, where the accurate representation of diagnostic images is of utmost importance.

THE VERSATILITY OF EXTREME SPORT CAMERAS:

Beyond medical and industrial applications, Watec's innovation extends to the realm of extreme sports with the WAT-05U2M. This wearable, unobtrusive single-cable camera boasts a 180-degree wide-angle lens, enabling users to capture Full HD ultra-wide videos. Designed to withstand challenging conditions, this waterproof camera is built to endure rain and wind, making it an ideal companion for outdoor adventures.

What sets the WAT-05U2M apart is its seamless integration with Android smartphones and select Windows operating systems. This compatibility ensures a user-friendly experience, allowing individuals to effortlessly capture and share their extreme sports endeavors. Whether it's recording daring feats or documenting breathtaking landscapes, this camera offers an unmatched combination of durability and ease of use.

APPLICATIONS ACROSS DIVERSE SECTORS:

The impact of Watec's innovative camera technology extends far beyond the realms of medicine, industry, and extreme sports. It finds applications in a myriad of sectors, each benefiting from the exceptional quality and reliability of Watec cameras.

1. Medical Imaging: In the field of medical imaging and endoscopy, Watec's cameras are indispensable tools for healthcare professionals. These cameras facilitate precise and detailed examination of internal organs and tissues, aiding in the diagnosis and treatment of various medical conditions. The ability to capture high-quality images in low light conditions is particularly valuable during minimally invasive procedures.


2. Astronomy: Astronomers rely on Watec's low light cameras to capture the wonders of the night sky with unparalleled clarity. These cameras excel in capturing faint celestial objects, making them invaluable for research and amateur astronomers alike.


3. Surveillance and Law Enforcement: Law enforcement agencies and security organizations leverage Watec's technology to enhance surveillance capabilities. The ability to capture clear images in low light conditions is crucial for identifying individuals and monitoring areas of interest.


4. Factory Automation: In the realm of factory automation and machine vision, Watec's cameras play a critical role in quality control and production processes. These cameras enable the automated inspection of products, ensuring that manufacturing standards are met consistently.


5. Pharmaceutical Manufacturing: Pharmaceutical companies utilize Watec cameras to monitor and document the manufacturing process of drugs and medical products. The cameras' precision and image quality are essential for quality assurance and compliance with regulatory standards.


6. Extreme Sports and Outdoor Adventures: The WAT-05U2M is the ideal companion for adventurers and extreme sports enthusiasts. Its rugged design and exceptional image quality allow users to capture their adrenaline-pumping experiences in vivid detail.

CONCLUSION

In the rapidly evolving landscape of medical imaging and beyond, WATEC stands as a beacon of innovation and reliability. With a storied history spanning over two decades, the company's commitment to excellence in camera technology has yielded groundbreaking solutions that cater to diverse industries and applications. From enabling precise medical diagnoses in challenging conditions to capturing the mysteries of the cosmos, Watec's cameras have become indispensable tools.

Moreover, the foray into extreme sports and outdoor adventures showcases Watec's adaptability and dedication to providing versatile solutions for a wide range of users. As technology continues to advance, Watec remains at the forefront, driving progress in the world of imaging. In essence, Watec's cameras are not just devices; they are the enablers of discovery, the guardians of security, and the storytellers of extraordinary human experiences.

FOR MORE INFORMATION ON COGNEX MACHINE VISION SYSTEMS INDIA CONTACT US AT MVASIA INFOMATRIX PTE LTD +65 6329-6431 OR EMAIL US AT INFO@MVASIAONLINE.COM

VISIONARY INSIGHTS: REVOLUTIONIZING MANUFACTURING WITH MACHINE VISION LENSES

 

In the fast-paced world of manufacturing and production, efficiency reigns supreme. The relentless demand for high-quality products delivered promptly has forced businesses to continually seek innovative solutions to enhance their production processes. One such revolutionary solution is the use of machine vision lenses, a critical component of automated inspection systems. These lenses play a pivotal role in optimizing manufacturing efficiency, precision, and quality control. In this article, we will delve deep into the world of machine vision lenses, exploring their significance, benefits, and the transformative impact they have on modern production processes.

THE ROLE OF MACHINE VISION LENSES IN AUTOMATION

Machine vision lenses, also known as industrial lenses, are indispensable in automated inspection, measurement, and identification processes within manufacturing industries. They are designed to capture high-resolution, precise images of products and components, providing the necessary data for machine vision software to analyze and make informed decisions. This automation reduces the reliance on manual inspection, resulting in a substantial increase in the speed of production lines.

1. Precision and Accuracy
   
   One of the most significant advantages of machine vision lenses is their unparalleled precision. Traditional manual inspections are susceptible to human error and can often yield inconsistent results. In contrast, machine vision lenses ensure consistent, accurate inspections, leading to a reduction in errors and less waste. The enhanced precision directly translates to an improvement in the overall quality of the end product, meeting and often exceeding customer expectations.
   
   Machine vision systems equipped with advanced lenses can detect even the slightest defects or deviations from specifications, ensuring that every product meets the required quality standards. This level of accuracy is difficult to achieve through manual inspection processes and underscores the value of machine vision lenses in quality control.


2. Continuous Operation
   
   Machine vision lenses possess a unique advantage over human inspectors – they can operate continuously without fatigue. While human workers may need breaks and rest periods, machine vision systems can tirelessly inspect products around the clock. This capability not only increases production uptime but also allows for 24/7 manufacturing, a crucial factor in meeting the demands of today's globalized markets.
   
   Moreover, these lenses can simultaneously inspect multiple product features, further amplifying inspection speed and efficiency. This multitasking ability ensures that no detail is overlooked and that production lines can maintain peak performance at all times.


3. Predictive Maintenance
   
   Machine vision lenses contribute significantly to predictive maintenance strategies in manufacturing. By identifying minute defects or changes in the production line, these lenses can alert operators to potential issues before they escalate into costly repairs or unplanned downtime. This proactive approach to maintenance saves both time and money while minimizing resource wastage, further enhancing production efficiency.

INVESTMENT IN EFFICIENCY

It is understandable that some manufacturers may initially view the integration of machine vision lenses as a substantial investment. However, it is crucial to consider the long-term benefits these lenses bring to the table. Increased efficiency, reduced waste, improved product quality, and minimized downtime are just a few of the advantages that make this investment not only worthwhile but essential for modern manufacturing operations.

CONCLUSION

In conclusion, machine vision lenses have ushered in a new era of production efficiency, revolutionizing manufacturing processes across industries. As businesses continue to seek ways to improve productivity and product quality, the adoption of machine vision lenses in production lines is no longer merely beneficial but essential. In an age characterized by automation and Industry 4.0, machine vision lenses will undoubtedly continue to play a pivotal role in enhancing production efficiency.

As you embark on your journey to harness the full potential of machine vision lenses, we invite you to explore COMPUTAR'S collection of revolutionary machine vision lenses. Discover how they can be seamlessly integrated into your operations to improve efficiency, reduce waste, and elevate the quality of your products. Embrace the future of manufacturing with machine vision lenses, and watch as your production processes evolve into streamlined, efficient, and highly competitive operations.

FOR MORE INFORMATION ON COGNEX MACHINE VISION SYSTEMS INDIA CONTACT US AT MVASIA INFOMATRIX PTE LTD +65 6329-6431 OR EMAIL US AT INFO@MVASIAONLINE.COM

GIGABYTE'S INNOVATIVE 3D SENSING TOF SOLUTIONS: TRANSFORMING INDUSTRIES WITH ADVANCED TECHNOLOGY

 

In today's rapidly evolving technological landscape, GIGABYTE stands out as a pioneer in providing cutting-edge solutions that cater to diverse industries. With a commitment to enhancing lives through innovation, GIGABYTE has developed a comprehensive product lineup that spans consumer electronics, gaming, business systems, and cloud solutions. Renowned for its award-winning products such as motherboards, graphics cards, laptops, mini PCs, and various PC components and accessories, GIGABYTE has firmly established itself as an industry leader. This article explores GIGABYTE's groundbreaking contributions to the field of 3D sensing Time of Flight (TOF) technology, particularly in applications such as 3D sensing cameras and people counting solutions.

THE EVOLUTION OF GIGABYTE: A LEADER IN TECHNOLOGICAL ADVANCEMENTS

GIGABYTE's journey as a developer of PC and server hardware solutions has been marked by a commitment to continuous innovation. The brand's reputation for excellence has been built upon its ability to anticipate industry trends and customer needs. With a focus on catering to a wide range of sectors, including consumer electronics, gaming enthusiasts, and businesses, GIGABYTE has consistently delivered products that elevate user experiences.

3D SENSING TIME OF FLIGHT (TOF) SOLUTIONS

GIGABYTE's foray into 3D sensing TOF solutions has opened up new avenues for industries to harness the power of advanced technology. TOF technology utilizes the principle of measuring the time taken for light to travel from a source to an object and back to the sensor, enabling highly accurate depth perception. This technology has found applications in various sectors, including automotive, industrial automation, security, and more.

1. T01-NP / 3D TOF Sensing Camera Ethernet Version
   
   One of GIGABYTE's pioneering offerings is the T01-NP 3D TOF Sensing Camera Ethernet Version. This advanced camera leverages TOF technology to capture precise depth information, enabling applications such as object detection, gesture recognition, and spatial mapping. With the ability to integrate seamlessly into different environments, the T01-NP empowers industries to enhance their processes and functionalities.


2. M03-U3 / 3D TOF VGA Sensing Camera
   
   GIGABYTE's M03-U3 3D TOF VGA Sensing Camera exemplifies the brand's commitment to pushing the boundaries of technology. This camera offers high-resolution depth sensing, making it a valuable tool for industries that require accurate spatial understanding. From robotics to augmented reality, the M03-U3 plays a pivotal role in enabling machines to interact intelligently with the world around them.


3. E02-U3 / 3D TOF Outdoor Sensing Camera
   
   The E02-U3 3D TOF Outdoor Sensing Camera showcases GIGABYTE's versatility in catering to various environments. With rugged construction and advanced sensing capabilities, this camera thrives in outdoor settings, making it an ideal solution for industries such as agriculture, construction, and surveillance.

PEOPLE COUNTING TOF SOLUTION

GIGABYTE's 3D sensing TOF solutions extend beyond object detection and spatial mapping. The brand's expertise has led to the development of people counting solutions that offer insights into crowd management and behavior analysis.

1. M03-U3 / 3D TOF VGA Sensing Camera for People Counting
   
   The M03-U3, already known for its high-resolution depth sensing capabilities, finds a unique application in people counting. In retail, events, and public spaces, this solution aids in understanding foot traffic patterns, optimizing space utilization, and enhancing security measures.


2. T01-NP-PC / 3D TOF People Counter
   
   The T01-NP-PC is a specialized people counting solution that capitalizes on GIGABYTE's advanced TOF technology. Its ability to accurately track individuals in dynamic environments makes it an indispensable tool for businesses and institutions seeking data-driven insights into customer behavior and space usage.

TRANSFORMING INDUSTRIES THROUGH INTEGRATION OF AI AND ALOT APPLICATIONS

GIGABYTE's commitment to innovation extends beyond hardware solutions. The brand's vision includes integrating Artificial Intelligence (AI) and the Internet of Things (IoT) to unlock new possibilities for industries. By harnessing AI and AloT applications, GIGABYTE enables customers to gather, analyze, and convert digital information into valuable economic data. This approach not only streamlines processes but also accelerates business success from the edge to the cloud.

DRIVING PROGRESS IN THE AUTOMOTIVE SECTOR: A SINGAPOREAN PERSPECTIVE

GIGABYTE's impact is felt globally, including in Singapore's automotive industry. As an automotive system dealer in Singapore, staying ahead of technological advancements is imperative. GIGABYTE's 3D sensing TOF solutions offer transformative possibilities for the automotive sector, from enhancing driver assistance systems to enabling more accurate object detection in autonomous vehicles. The precision and reliability of GIGABYTE's TOF solutions align with Singapore's commitment to cutting-edge automotive technologies.

CONCLUSION

In an era where technology is the driving force behind progress, GIGABYTE emerges as a beacon of innovation. With a diverse product lineup that caters to consumers, businesses, gamers, and cloud systems, the brand's contributions have left an indelible mark on various industries. GIGABYTE's 3D sensing TOF solutions, coupled with its integration of AI and AloT applications, exemplify its commitment to pushing the boundaries of what's possible. As a renowned automotive system dealer in Singapore, GIGABYTE's technological prowess resonates deeply with the nation's drive toward a technologically advanced future. With each innovation, GIGABYTE reaffirms its position as a leader, dedicated to upgrading lives through transformative technology.

Also Read: TIRE PROFILE DETERMINED WITH DEEP LEARNING

BASLER BLAZE TIMEOF FLIGHT CAMERA – FREQUENTLY ASKED QUESTIONS (FAQ)

HERE YOU’LL FIND ANSWERS TO THE MOST COMMON TECHNICAL QUESTIONS CONCERNING TIME-OF-FLIGHT CAMERAS.

1. WHAT IS TIME OF FLIGHT?

Time of Flight is a method for distance measurement--the time it takes for light to travel from the light source to the object then return to the sensor is measured and used to calculate a distance.

2. HOW ACCURATE IS THE MEASUREMENT OF A TOF CAMERA?

ToF cameras are accurate to a few millimeters, depending on the situation. Basler’s user manual contains a graphic with detailed accuracy measurement data.

3. WHAT RESOLUTION DOES THE BASLER BLAZE CAMERA OFFER?

ToF cameras have lower resolutions than modern 2D cameras due to the complexity of the ToF pixel design. The Basler blaze-101 camera offers a state-of-the-art resolution of 640 pixels (horizontal) x 480 pixels (vertical).

4. WHICH SENSOR IS USED IN THE BASLER BLAZE-101 CAMERA?

The Basler blaze camera uses the latest ToF-specific Sony DepthSense™ IMX556PLR sensor.

5. DOES A TOF CAMERA NEED TO BE CALIBRATED IN THE FIELD?

Every ToF camera requires calibration to achieve a reasonable accuracy. The Basler blaze-101 camera comes pre-calibrated ex-works. In-field calibration or re-calibration of the sensor is not necessary. Each blaze-101 camera has an individual calibration for lens distortion, distance error and thermal drift compensation.
However, you can configure the camera parameters further with the blaze-101 API based on the scene and object.

6. WHICH APPLICATIONS ARE SUITABLE FOR THE TOF CAMERA?

The Basler ToF cameras are used in a variety of applications in the fields of logistics, factory automation, robotics, AGV, agriculture and medicine.

7. WHAT IS THE FRAMERATE OF TOF CAMERAS?

The Basler blaze-101 camera runs at up to 30 fps.

8. HOW DOES THE OPERATING TEMPERATURE AFFECT THE ACCURACY OF A TOF CAMERA?

Due to the high demands on the precision of light pulses and shutter speeds, ToF cameras are sensitive to temperature fluctuations. The Basler blaze-101 has several temperature sensors, which are used for individually calibrated compensation of possible signal shifts. Thus, the influence of temperature on a blaze-101 camera is negligible.

9. CAN I CHANGE THE LENS OR BUY A TOF CAMERA WITH ANOTHER LENS?

A ToF camera is a calibrated system. If focus, aperture or lens are changed, the calibration is lost. Furthermore, the illumination and lens are optimally tuned to each other in wavelength and field of view. Thus, it is not advisable to modify the lens.

10. WHAT IS THE FOV OF THE LENS?

It depends on the camera model. The field of view of the Basler blaze-101 camera is 67° x 51° (H x V). This large measuring range can cover approximately two Euro pallets or a small car at 5 m distance.

11. WHAT KIND OF LIGHT SOURCE IS USED IN TOF CAMERAS?

ToF cameras typically use LED or laser diodes. The Basler blaze-101 camera uses four VCSEL laser diodes as its light source.

12. ARE THE INBUILT LASER DIODES EYE-SAFE?

Eye safety is very important to us and we make high demands on the safety of our products.
Basler blaze-101 is classified as a Class 1 laser product according to EN/IEC 60825-1:2014 Edition 3. This classification means the camera is eye safe under all reasonably foreseeable conditions of normal use. The Basler blaze includes technical safety elements that ensure that the accessible emissions--e.g. via the electrical power control (electronic safety circuitry), the optical diffusor and the cover glass on the illumination--stay within safe limits. Correct functioning is guaranteed by quality management measures that include a 100% test after assembly.

13. WHAT IS THE WAVELENGTH SPECTRUM OF TOF CAMERAS?

In principle, a ToF camera can work at any wavelength as long as the illumination and sensor operate in the same spectrum. For practical reasons, the near infrared is preferred because the photoelectric effect works well in that range, but people are not disturbed because they cannot perceive the light.
The Basler blaze-101 camera works with a wavelength spectrum of 940nm. When comparing the 940nm ToF cameras with the 850nm cameras it is important to know that 940nm is completely invisible for humans, so it is a better choice in situations involving illumination of a person’s face or deployment close to humans. At 850nm, human eye sensitivity is very low but 850nm light can still be seen, especially in dark conditions. This can be uncomfortable and or confusing.

14. WHAT IS THE MODULATION FREQUENCY OF THE TOF CAMERAS?

A typical modulation frequency for a ToF camera is between 10 and 100Mhz.
In default mode (20 fps) the Basler blaze-101 camera operates at two different frequencies: 15 MHz and 100 Mhz. In fast camera mode (30 fps) the modulation frequency is 15 MHz for long range and 100 MHz for short range.

15. CAN I SET THE MODULATION FREQUENCY OF THE CAMERA MYSELF? IF I WANT TO MEASURE UP TO 15 M, CAN I SET 10 MHZ?

The camera performance is optimized for two modulation frequencies (15 MHz and 100 MHz) and factory-calibrated, so it is not possible to change it.

16. CAN I USE A TOF CAMERA FOR OUTDOOR APPLICATIONS AS WELL?

Ambient light does not help with distance measurement. In fact, it fills the sensor with photons from random directions not related to the distance which thus have to be considered as a noise source.
Basler’s blaze-101 camera works under sunlight conditions. Compared to a ToF camera working at 850 nm, a ToF camera working at 940 nm is more daylight robust as at this wavelength the sunlight is strongly absorbed by the atmosphere. Also, modern artificial light sources do not emit NIR light for efficiency reasons. Please check the user manual for details.

17. IS A TOF CAMERA WORKING AT 940NM (BASLER BLAZE) LESS SUITABLE FOR INDOOR USE THAN A TOF CAMERA WORKING AT 850 NM?

The quantum efficiency (QE) of a typical sensor at 850 nm is indeed higher than at 940 nm. However, the maximum permissible light exposure at 940 nm permits a 1.5X higher lighting output for cameras working at 940 nm. This compensates for the disadvantages of QE to a large extent. Furthermore, the properties of camera illumination, ambient light and other sensor properties such as dynamic range must also be considered. For indoor use of a ToF camera we recommend uniform DC lighting such as high-quality LEDs.

18. IS THE BASLER TOF CAMERA SUPPORTING THE GIGE VISION INTERFACE STANDARD?

Basler blaze-101 is compatible with GigE Vision standard. However, if you want to access all four streaming formats (point cloud, range map, intensity image, confidence map) and have usage of the full range of functions available, we highly recommend the Basler GenTL producer, provided with the Basler blaze SDK.

19. WHAT IS THE PROTECTION CLASS RATING FOR THE TOF CAMERA?

If you put a ToF camera into an external enclosure, you have to make sure that the cover protection glass does not interfere with the ToF measurement.
The Basler blaze-101 camera is already rated to protection class IP67; thus, it is completely dustproof and can withstand submersion in water down to 1m for 30 minutes.

20. CAN A TOF CAMERA SURVIVE VIBRATION AND SHOCKS?

Due to their design principle, ToF cameras are fundamentally more robust than structured light or stereo cameras, which must maintain a precise basic length.
The Basler blaze-101 camera is shock- and vibration-proof according to EN60068. The cameras were submitted to an independent mechanical testing laboratory and subjected to specific stress tests. After mechanical testing, the cameras exhibited no detectable physical damage and produced normal images during standard operational testing. Please check the user manual for test details.

21. I'D LIKE TO USE THE CAMERA IN AN OUTDOOR SETTING AND WANT TO PUT IT INTO A HOUSING. WHAT FACTORS REQUIRE SPECIAL CONSIDERATION? CAN I SIMPLY PUT THE TOF CAMERA INTO A STANDARD PROTECTION HOUSING?

Cooling is a primary consideration before mounting into a protective housing, as well as avoidance of stray light (no reflecting housing parts near the lens).
The protective glass must be translucent in the required wavelength, must be of high quality with no scratches and must not cause reflections. Ideally, the lens and the LEDs will have separate protective glasses.

22. I'D LIKE TO USE MULTIPLE TOF CAMERAS IN MY APPLICATION.

Operating multiple ToF cameras extends your field of view and allows you to capture objects from every angle. However, the light pulse of one ToF camera can disturb the sensor of a second camera, leading to false distance measurements.
In case of Basler’s blaze-101 camera, you have several options to minimize camera interference for reliable multi-camera operation:

• 1. Use the software trigger over Ethernet. You can synchronize the cameras such that two cameras never illuminate the scene at the same time. Trigger one camera after another.
• 2. Use the Precision Time Protocol (PTP) to synchronize the timing. Instead of issuing the trigger via software (1.), you can configure the cameras to trigger themselves based on a common clock. This clock is synchronized over the network automatically (PTP protocol) down to a microsecond precision which allows very tight timing in the trigger sequence.
• 3. Use the multi-camera feature of Basler blaze. For each camera, select a slightly different modulation frequency, which yields almost no interference.

You can also combine the methods. For example, you can configure PTP so that all cameras trigger at exactly the same time, but also use multi-camera feature to minimize the interference. This is the recommended method to capture objects in motion.

23. CAN I USE A 2D AND A 3D BASLER CAMERA WITHIN ONE SYSTEM?

Yes, you can install the blaze SDK and the pylon SDK on one computer. The blaze SDK comes with samples; one shows the use of a blaze-101 and an ace camera in combination.

24. I HAVE TO DOWNLOAD A GENTL PRODUCER COMPLIANT WITH THE GENICAM STANDARD TO OPERATE THE BASLER BLAZE CAMERA. WHAT EXACTLY IS THAT STANDARD AND WHY DOES BASLER USE THIS PROCESS?

GenTL is the third module of GenICam. While GenApi and SFNC are more oriented toward the camera's settings, GenTL regulates the transport of the image data. GenTL is the latest module.

25. WHERE DOES ALL THIS INTENSE PROCESSING HAPPEN? ON THE CAMERA OR THE HOST? WHAT KIND OF CPU/GPU COMBINATION WOULD YOU NEED?

It depends on the specific camera model you use. For example, stereo cameras often load the host processor with the depth calculation. The Basler blaze-101 camera has a very powerful NXP processor that does all the work, so the host requirements are relatively low.

26. DOES THE BASLER BLAZE SUPPORT ROS?

Yes, the blaze SDK comes with a driver and sample for ROS under Linux.

27. DOES USING POLARIZING FILTERS HELP WHEN WORKING WITH STRONG REFLECTIVE SURFACES?

For this setup you would need an especially strong, polarized light source. This is unusual for ToF cameras.

28. HOW DOES YOUR CAMERA MANAGE SCATTERED LIGHT?

Scattered light occurs due to unwanted reflections within the lens or behind it. Even for the most carefully engineered setup, scattered light cannot be completely eliminated. Bright surfaces located very close to the light source quickly scatter too much light into the lens. This can cause measurement errors (measured distance too short). In the intensity image, scattered light leads to a washed-out image with poor contrast. The Basler blaze-101 camera has an inbuilt lens that is optimized for Time-of-Flight cameras and reduces stray light effects as much as possible. You should also remove specular objects from the scene, if possible.

29. IS IT POSSIBLE TO INSTALL THE CAMERA BEHIND A PROTECTIVE GLASS?

It is possible, but you have to choose a protective glass as transparent to 940nm light as possible. The protective glass must not cause reflections. Please also consider that the latest model blaze-101 is rated to protection class IP67, so it is splash water and dust resistant.

30. DO YOU HAVE ANY PLAN TO SELL HIGH RESOLUTION VERSIONS OF THIS TOF SENSOR?

Currently VGA resolution is state-of-the-art for ToF cameras. But across the product life cycle, we closely observe innovations in the ToF sensor market, and newer sensor models will be taken into consideration for future camera models as they are released.