Network capacity and performance

 IT managers are under increasing pressure to boost network capacity and performance to cope with the data deluge. Networking systems are under a similar form of stress with their performance degrading as new capabilities are added in software. The solution to both needs is next-generation System-on-Chip (SoC) communications processors that combine multiple cores with multiple hardware acceleration engines.

The data deluge, with its massive growth in both mobile and enterprise network traffic, is driving substantial changes in the architectures of base stations, routers, gateways, and other networking systems. To maintain high performance as traffic volume and velocity continue to grow, next-generation communications processors combine multicore processors with specialized hardware acceleration engines in SoC ICs.

refer:http://embedded-computing.com/articles/next-generation-architectures-tomorrows-communications-networks/

About Real-time and general-purpose operating issue

 Virtualization for embedded systems has many implementations in which two or more operating systems coexist to gain the benefits of each. One approach puts Microsoft Windows and a Real-Time Operating System (RTOS) together.

 

Much is being said about virtualization these days in the softwareworld. Simply stated, virtualization is about getting multiple OSs to run on the same computing platform at the same time. Virtualization has been cited as a key technology for getting the most performance out of the newest multicore processors. But just as not all computing applications are the same, not all virtualization approaches are appropriate for all applications.
Embedded systems have a key requirement that doesn’t normally apply to office and server computers: the need for deterministic response to real-time events. To support the requirement for determinism, embedded applications typically use RTOSs. Embedded applications also employ general-purpose OSs to handle operator interfaces, databases, and general-purpose computing tasks.
In the past, because OSs couldn’t successfully co-reside on computing platforms, system developers employed multiple processing platforms using one or more to support real-time functions and others to handle general-purpose processing. System designers that can combine both types of processing on the same platform can save costs by eliminating redundant computing hardware. The advent of multicore processors supports this premise because it is possible to dedicate processor cores to different computing environments; however, the software issues posed by consolidating such environments require special consideration. Combining real-time and general-purpose operating environments on the same platform (Figure 1) places some stringent requirements on how virtualization is implemented.
1.Paravirtualization
2.Server virtualization
3.Hardware-aided embedded virtualization     
4.Leveraging Intel Architecture
5.Embedded virtualization saves costs

refer: http://embedded-computing.com/articles/real-time-general-purpose-unite-via-virtualization/

Communication strategie in embedded technology

 

Although embedded devices destined for industrial applications have a wide range of design requirements due to the diverse environments in which they are deployed, almost all systems need some form of wired or wireless communications capabilities. Stand-alone industrial embedded devices are relatively rare, as users now demand remote access for data collection, management, maintenance, troubleshooting, software updates, and system security. For example, businesses need to monitor and collect real-time operational or throughput statistics from individual devices to evaluate the performance of manufacturing systems and methods.
Complex embedded systems can automatically run maintenance and diagnostic routines to evaluate reductions in performance and remotely schedule hardware updates. Many remote systems also require some type of security or surveillance features to detect and possibly prevent physical or virtual attacks. The challenge for embedded designers is to find the right communications technologythat delivers reliable, high-performance connectivity in an industrial environment with possible noise, extended temperatures, shock/vibration, and interference.
In this issue of Industrial Embedded Systems, we asked contributors to take a look at the principal issues and trends affecting contemporary embedded design for industrial applications and found that connectivity was a major topic in most of the articles and interviews. For example, in the Computing section, Mike Holt of Semitech Semiconductor illustrates techniques to optimize power line communications for Machine-to-Machine (M2M) applications such as automatic meter reading or control and management of streetlights, vending machines, or solar panels. In the same section, Lantronix VP of engineering Daryl Miller offers suggestions for making smart grids smarter by integrating M2M communications features into legacy equipment to enable remote access, control, and troubleshooting capabilities. Andreas Johannsen of Vincotech describes another important design requirement for industrial equipment, especially systems that operate 24 hours a day: power efficiency. Andreas shows how electronic commutated motor drives contained in an integrated power module can be up to 90 percent more efficient than conventional motor drives in industrial applications.
In the Networking/Sensing section, connectivity is a central theme in discussions on applications ranging from building automation to smart parking technology. In a Q&A session, HomePlug Powerline Alliance President Rob Ranck explains the current state of broadband networking over existing AC wiring within the home and outlines new standards that support smart gridapplications, electric vehicle charging stations, and HD streaming for movies or gaming. In a technical article targeting Building Automation Systems (BAS), Louis-Nicolas Hamer, VP at SCL Elements, describes the industry’s slow progress due to poor interoperability among multiple automation protocols and highlights a new all-in-one embedded gateway controller that can solve this BAS divergence. Citing unprecedented grown in the M2M industry, Mike Ueland, VP and general manager at Telit Wireless Solutions North America, shows how companies are deploying remote monitoring to increase efficiency and cut costs in managing industrial assets and systems. And finally, in a completely different connectivity application, Alicia Asín of Libelium offers a unique solution for automobile parking management that could potentially eliminate billions of hours of lost productivity along with billions of gallons of wasted fuel due to motorists cruising around searching for parking spaces.
REFER:
http://industrial-embedded.com/articles/communication-reshape-embedded-technology/