Embedded computer versus cloud computing

Department of Defense (DoD) officials trying to keep the lights on in today’s budget constrained environment love how cloud embedded computer can reduce data center operational costs, bricks and mortar expenses, and staff overhead. Virtually storing data instead of physically in a hard drive is very appealing – especially to younger military personnel who have grown up with virtual technology such as the iPhone and the iCloud. However, military cloud services – just like military smartphones and tablets – will need to be much more secure.

The National Institute of Standards and Technology (NIST) defines embedded computer as “a model for enabling ubiquitous, convenient, on-demand network access to a shared pool of configurable computing resources (e.g., networks, servers, storage, applications, and services) that can be rapidly provisioned and released with minimal management effort or service provider interaction.”

refer to: http://mil-embedded.com/articles/cloud-security-the-dod/

Revitalizing the gaming platform

Fortunately, the members of gaming platform recognized the need for mezzanine standards early in the emerging board industry. By the late 1980s, discussions started to standardize a few different mezzanine form factors. First to emerge were S-bus and PCI Mezzanine Cards (PMCs). S-bus was driven by Sun Microsystems while the gaming platform form factor evolved out of an IEEE effort. While neither was a VITA standard, PMC went on to become a widely used mezzanine for 6U cards for VME, gaming platform, Compact PCI, and other form factors.

refer to: http://vita-technologies.com/articles/stacked-standardizing-mezzanine-modules/

Upon operating system developments...

 

Software architects designing critical embedded systems have tough choices to make when selecting an operating system. Decisions can be both simplified and complicated with new framework and platform initiatives coming into being.

Operating systems that control critical embedded systems have many stringent requirements that they must be able to address in order for them to be considered for deployment. There will always be debate about the best operating systems to deploy in critical applications. However, improvements in real-time operating capabilities in Windows and Linux have opened up the door to options in addition to traditional Real-Time Operating Systems(RTOSs).

refer: http://vita-technologies.com/articles/operating-impact-critical-systems/

About Embedded Application Frameworks

 

With advances in wireless technologies, defining a strategy for building wireless M2M-enabled devices is not the dauntingly complex task it was once thought to be. Instead of devoting precious R&D resources to the integration of fragmented, ad hoc technologies, today’s developers can take advantage of increasingly sophisticated Embedded ApplicationFrameworks (Linux, Android, and others), some of which are highly optimized for M2M application development.

refer:
http://embedded-computing.com/articles/embedded-frameworks-simplifying-development-m2m-devices/#utm_source=Cloud%2Bmenu&utm_medium=text%2Blink&utm_campaign=articles