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Los Angeles, United States
51-100 Employees
We take members from any major and any skill level - no prior experience required! Learn more and sign up here.
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Featured
USC AUV – USC's Autonomous Underwater Vehicle Design Team
... USC AUV – USC's Autonomous Underwater Vehicle Design ...
Seattle, United States
1-10 Employees
1983
SUNFISH was developed by Stone Aerospace in collaboration with NASA for future exploratory mission to the Jovian moon, Europa. The AUV is designed to operate in a wide variety of undersea environments, ranging from man-made (e.g.
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Featured
SUNFISH® AUV – Pushing the Boundaries of Exploration & Technology
... Meet SUNFISH, a user friendly and person-portable Autonomous Underwater Vehicle (AUV) with field proven Artificial Intelligence (AI) and Simultaneous Localization and Mapping (SLAM). ...
City of Edinburgh, United Kingdom
1-10 Employees
Our mission is clear: to empower businesses and the scientific community with seamless access to and understanding of seafloor data. Our Mission PicSea's pioneering technology has successfully reduced both the cost and complexity associated with creating autonomous underwater vehicles. Andrew and the dedicated PicSea team have successfully developed, maintained, and deployed autonomous ocean systems worldwide, ensuring clients receive the data and insights they seek. At PicSea, we are committed to mapping the remaining uncharted territories on our planet. Our mission is to shed light on the mysteries of the deep sea. Join PicSea on this remarkable journey to unveil the secrets of the seafloor and revolutionize underwater exploration. Choose PicSea: Experts in underwater robotics and autonomous ocean systems. PicSea is at the forefront of revolutionizing marine surveys using Autonomous Underwater Vehicles (AUVs).
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Featured
PicSea300E Autonomous Underwater Vehicle
... PicSea300E Autonomous Underwater Vehicle ...
Brandérion, France
11-50 Employees
SEABER is an innovative company that designs and manufactures highly reliable micro-AUVs navigating down to 300m depth with 8-10 hours autonomy, weighing 10kg and measuring 1m long. After years of experience and with a shared obsession for robotics and marine technologies, we decided to use our expertise and knowledge to develop the first micro-AUV that meets the specific needs of oceanographic researchers and navies. We believe that the future of ocean exploration belongs to fleets of numerous small, agile, and affordable AUVs. Come to booth 📍 F351, to meet the Seaber team and see in real our YUCO and MARVEL micro-AUV range…. This cost is a major obstacle, as it is hard to come up with….
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Featured
YUCO the first Autonomous Underwater Vehicle, used with confidence
... YUCO the first Autonomous Underwater Vehicle, used with ...
Kharagpur, India
11-50 Employees
2010
This competition provides an opportunity for teams and industries across the globe to showcase their capabilities in underwater robotics. As a technology and innovation driven team, we are determined to develop cutting-edge technology to overcome challenges and perform better.
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Featured
Home | Team AUV, IIT Kharagpur
... Autonomous Underwater Vehicle is a research group in IIT Kharagpur working on designing and building fully autonomous submarines. Our main goals are to build robots to compete in competitions such as RoboSub and do pioneering research work in the fields of Image Processing, Embedded Systems ...
Warminster, United Kingdom
11-50 Employees
2002
Autonomous Robotics is developing an autonomous underwater vehicle solution – Flying Nodes – to be deployed in swarms of up to 3,500 for assessing and measuring key data in depths of up to 3000 metres. This ground breaking technology will dramatically reduce the cost of obtaining accurate data in the key sectors of environmental, offshore energy and defence. The Flying Node technology will disrupt these markets by offering commercial advantages in cost, time and/or higher data quality compared to existing technologies. Autonomous Robotics Ltd is a wholly owned subsidiary of Thalassa Holdings Ltd which is a company listed on the UK and Luxembourg stock exchanges. Thalassa is an investment group of companies with a wide range of business interests.
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Featured
Autonomous Robotics | Autonomous underwater vehicle solution
... Autonomous Robotics | Autonomous underwater vehicle ...
Leuven, Belgium
11-50 Employees
2010
We are slam experts, developing, contributing and integrating proprietary and Open Source libraries (like Cartographer, ORBSlam,…) for Visual SLAM, laser-based SLAM, 2D and 3D based SLAM. Creating Robotics & Vision products is always a multidisciplinary team effort. We collaborate in our projects with hardware, frontend and usability teams to deliver the result our stakeholders expect ! By adopting the latest technologies and industry best practices, we are able to increase the speed of development without compromising on the reliability and robustness of the final product.
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Real-time system for autonomous underwater vehicle — Intermodalics
... Real-time system for autonomous underwater vehicle — ...
Bibra Lake, Australia
1-10 Employees
1999
Born as a small manufacturer of military equipment for the Royal Australia Navy and Royal New Zealand Navy, SITEP Australia is based in Perth and Sydney. This will allow SITEP to provide our client ’s with innovative and customised solutions. SITEP’s fully owned the patents of its products , we are increasing the transfer of know how in Australia tocontribute in enancing of the Commnwealth’s Sovereign Capability. The manufacturing department of SITEP Italia has the capability of manufacturing equipment.. The company can offer the following services to its clients both in Italy and abroad:. SITEP assures the Integrated Logistic Support (ILS) for all its products:.
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Autonomous Underwater Vehicle for Defence Application – Sitep Australia
... Autonomous Underwater Vehicle for Defence Application – Sitep ...
India
11-50 Employees
2015
Formed in 2014, Team Tiburon is an interdisciplinary team from The National Institute of Technology, Rourkela, that works towards designing and developing AUVs (Autonomous Underwater Vehicle) capable of performing a plethora of tasks, all without a human pilot. And we take pride in announcing that we have been actively developing bots capable enough to perform complex operations such as dropping, grabbing and torpedo shooting as deep as 10m, amongst others. Moreover, we take part in various Student AUV competitions at both National and International levels. VEHICLE SPECIFICATIONS Frame Dimensions: 94x50x45cm3 Weight: 20Kgf Buoyancy: 22Kgf Computing Unit: MSI H871AC Motherboard Supporting Controller: Arduino and Pololu Maestro Servo Controller Navigation Unit: VN-100 Degree of Freedom: 4 Approximate Cost of the Vehicle: INR 7,00,000. VEHICLE SPECIFICATIONS Frame Dimensions: 75x59x60cm3 Weight: 15.3Kgf Buoyancy: 16.1Kgf Computing Unit: MSI H871AC Motherboard Supporting Controller: Arduino and Pololu Maestro Servo Controller Navigation Unit: VN-100 Degree of Freedom: 4 Approximate Cost of the Vehicle:(Including reused parts) INR 7,00,000.
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Team Tiburon — The AUV Team Of NITR
... Autonomous Underwater vehicle ...
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Some interesting numbers and facts about the results you have just received for Autonomous Underwater Vehicle
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 36 |
| Amount of suitable service providers | 24 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1983 |
| Youngest suiting company | 2016 |
An Autonomous Underwater Vehicle (AUV) is a robot designed for underwater exploration and tasks without requiring real-time control by human operators. These sophisticated machines are equipped with sensors, cameras, and sometimes manipulative tools to collect data or perform specific functions beneath the ocean's surface. AUVs are propelled through the water by onboard propulsion systems, navigating using complex algorithms and guidance systems such as inertial navigation, sonar, and depth sensors. They play a pivotal role in various marine applications, including oceanographic research, underwater mapping, and the inspection of infrastructure such as pipelines and oil rigs. The data collected by AUVs contribute significantly to our understanding of marine environments, aiding in scientific research, environmental monitoring, and the exploration of natural resources. Additionally, these vehicles are instrumental in search and rescue operations, where the depth and dangers of the environment make human intervention risky. The development and deployment of AUVs have revolutionized how researchers and industries interact with the underwater world, offering a safer, more efficient means to access and study the depths of the oceans. Their ability to operate autonomously for extended periods significantly enhances our capacity to monitor and protect marine ecosystems, showcasing the profound impact of this technology within its field.
1. Enhanced Exploration Capabilities
Autonomous Underwater Vehicles (AUVs) can dive deeper and navigate more complex environments than human divers. This allows for the exploration of previously inaccessible areas of the ocean floor, offering valuable data for research and commercial purposes.
2. Cost Efficiency
AUVs eliminate the need for large support ships and crews required for manned underwater missions. This significant reduction in operational costs makes them an economically viable option for a wide range of underwater tasks, including environmental monitoring and resource exploration.
3. Increased Safety
By deploying AUVs, the risk to human life is markedly reduced. These vehicles can operate in hazardous environments, such as those with high pressure or toxic substances, without exposing humans to the inherent dangers of deep-sea exploration.
4. Operational Autonomy
AUVs are designed to perform tasks with minimal human intervention, thanks to their advanced programming and decision-making capabilities. This autonomy enables continuous operations over extended periods, even in challenging conditions, thus enhancing productivity and efficiency.
1. Technology and Innovation
Evaluate the supplier's commitment to technology and innovation. This includes their use of advanced sensors, propulsion systems, and autonomy software that can adapt to various underwater missions.
2. Customization Capabilities
Determine if the supplier offers customization options to meet specific mission requirements, such as payload capacity, energy sources, and navigational accuracy.
3. Operational Range and Endurance
Consider the AUV's operational range and endurance, crucial for long-duration missions. Assess the energy efficiency and battery life to ensure it meets your needs.
4. Reliability and Maintenance
Assess the reliability of the AUV in diverse conditions and the ease of maintenance. A robust support system for troubleshooting and repairs is essential.
5. Cost-effectiveness
While cost should not be the sole factor, evaluate the overall value proposition, including initial purchasing costs, operational and maintenance expenses, and potential for upgrades.
6. Regulatory Compliance
Ensure the supplier's AUVs comply with international maritime regulations and standards, minimizing legal and operational risks.
Autonomous Underwater Vehicles (AUVs) play a vital role in the oil and gas industry, primarily for deep-sea exploration and pipeline inspections. These unmanned vehicles can navigate challenging underwater terrains to identify potential oil reserves and monitor the integrity of subsea infrastructure, ensuring operational safety and environmental compliance. In the field of marine research, AUVs are indispensable tools for collecting data on oceanic conditions, marine life, and underwater geological formations. Researchers rely on these vehicles to conduct surveys in areas that are otherwise inaccessible, significantly expanding our understanding of marine ecosystems and biodiversity. The defense sector also benefits from the deployment of AUVs, utilizing them for surveillance, mine detection, and underwater reconnaissance missions. These vehicles enhance naval capabilities by providing critical information on potential threats and underwater obstacles, contributing to maritime security without risking human lives. Additionally, AUVs are becoming increasingly popular in the renewable energy industry, particularly for the inspection and maintenance of offshore wind farms. Their ability to operate autonomously and navigate around complex underwater structures makes them an efficient solution for ensuring the longevity and performance of wind turbines and underwater cables. These use cases underscore the versatility of AUVs across various industries, highlighting their importance in advancing underwater exploration, infrastructure maintenance, and environmental monitoring.
Autonomous Underwater Vehicles (AUVs) are currently positioned at a high Technology Readiness Level (TRL), typically ranging between 7 and 9, depending on their specific application and technological sophistication. This advanced TRL indicates that AUVs have undergone extensive validation in relevant environments, with some systems even proven through successful mission deployments in operational settings. The progression to this stage is largely attributable to significant advancements in several key technical areas. Firstly, improvements in sensor technology have greatly enhanced AUVs' capabilities for environmental monitoring, data collection, and navigation, enabling more precise and reliable operations. Furthermore, developments in battery and power systems have extended AUVs' endurance and range, allowing for longer missions and reduced operational constraints. Additionally, advancements in artificial intelligence and machine learning algorithms have improved AUVs' autonomy, decision-making abilities, and adaptability to dynamic underwater environments. Collectively, these technical achievements have propelled AUVs to their current high TRL by demonstrating their effectiveness, reliability, and practical utility across a variety of research, military, and commercial applications, underscoring their readiness for widespread adoption and use in operational environments.
In the short-term, advancements in autonomous underwater vehicles (AUVs) are expected to focus on enhancing battery life and improving navigational accuracy. Engineers are working on developing more efficient energy storage solutions to extend the operational range of AUVs. Simultaneously, investments in artificial intelligence (AI) and machine learning (ML) technologies are set to refine their capability to autonomously navigate complex underwater terrains with greater precision, reducing the reliance on human intervention for path planning. The mid-term developments will likely see the integration of advanced sensory technologies and high-speed data communication systems. This phase aims to equip AUVs with the ability to perform more sophisticated tasks such as detailed seabed mapping and real-time environmental monitoring. Enhanced sensory equipment will allow for better detection of obstacles and more accurate data collection, while improved communication technologies will facilitate quicker data transmission to surface operators, enabling more efficient analysis and decision-making processes. Looking into the long-term, the focus will shift towards fully autonomous robotic ecosystems underwater. AUVs will be designed to work in swarms, communicating and making decisions collectively to undertake complex tasks such as deep-sea exploration, underwater infrastructure maintenance, and environmental restoration projects. These advancements will be supported by breakthroughs in AI, enabling AUVs to learn from their environment and each other, thereby significantly expanding their operational capabilities and areas of application.
