The advantages of integrating rugged edge computer systems with existing information technology systems are abundantly clear, but in order to bring these capabilities to the market, a specialized rugged computer is needed to bring rugged edge computer technologies to new frontiers in dangerous work environments. The first step towards this integration is to develop new information systems, which have the necessary redundancy and durability to withstand harsh environments such as those found in the mining, construction, food processing and health care industries. The second step is to integrate these systems with existing information technology systems. The third step is to make these systems readily available to military and civilian users.
Mining and construction are two of the most hazardous environments in which rugged edge computers are required. It is important for these systems to be able to withstand harsh chemical agents and extreme temperatures to ensure the protection of personnel from exposure to dangerous materials during construction or mining operations. In these environments, it is also vital that these computers are able to run on alternate power sources, in order to provide an extra level of safety to the user in the event that the main power source fails. Likewise, it is essential that these computers are rugged enough to withstand long periods of exposure to extremely cold temperature and high humidity.
Another environment in which rugged edge computers are becoming essential is the automotive powertrain industry. In the past, automobile powertrain components were manufactured by highly regulated, specialized facilities within specialized plant lines. These components often had to be designed and tested under stringent firewalls and other stringent requirements. However, as the automotive powertrain has evolved, these manufacturing requirements have become less strict, leading to shorter lead times and higher reliability of these components.
With the ongoing challenges in serviceability and reliability of rugged edge computer systems, manufacturers of these specialized processors and mainframe processors have been developing products that are not only designed to increase reliability and extend shelf life, but that have also been optimized for extended and more frequent use. Today's most popular and versatile processors are those that have been designed to handle continual and routine deployment in a wide range of service environments. These deployment environments include military and civilian emergency situations, routine tactical and disaster recovery operations, and highly demanding commercial and defense applications. For example, the most popular processors used by the US military for its MRAP, MSA, Blackwater, and Fire Force Recon units all incorporate a software system with extended reliability and support for a wide array of deployment conditions.
One type of rugged edge computer that is making waves in the worldwide arena is the karbon processor. Originally developed as a hardware for use by the Japanese Red Army, the karbon was eventually adapted for use in radar systems and surface to air missiles. The long term impact of this remarkable new processor is the ability to process radar signals even when the temperature is extreme on the surface of the missile or aircraft. For example, with a temperature range of minus 100 degrees Fahrenheit, a kcarbon with an integrated temperature sensor can continuously process radar signals to determine the speed and direction of the missile, allowing a pilot to maintain flight and retain overall accuracy while on high altitude. Check out the Premio edge PCs here.
For many years, a mainstay of rugged edge computer systems has been a single-board computer system optimized for extreme weather environments. However, new advances in solid-state architecture have recently provided the means to implement two- or even three-boards. With the addition of a third independent board, the single-board system can now support weather and temperature range independent operation for airborne, land, and water applications. As new environments become more challenging and the reliability requirements of these systems grow, these innovative systems will become increasingly popular with both government and civilian applications. The future of computing is here and it is time to start thinking small. With a rugged, reliable, and energy-efficient processor, the power user will get the most out of their computing experience.
Click for more info at this link - https://en.wikipedia.org/wiki/Rugged_computer