2014年4月28日 星期一

Make Acrosser’s All-in-One Gaming Board AMB-A55EG1 Your Cost-effective Gaming Solution.

Gaming Solution

Built-in AMD® low power G-Series™ T56N Dual Core CPU with A55E Fusion Control Hub Chipset, Acrosser AMB-A55EG1 brings you a cost-effective All-in-One gaming solution among the industry. Take a look at Acrosser’s AMB-A55EG1 product film and see the various gaming features of AMB-A55EG1, including: Gaming I/O, Intrusion Detection, cc-Talk and Battery back-up SRAM. All of these allow game designers to customize their peripherals in order to maximize the utility of this AMD® Embedded G-Series™  gaming board.

Moreover, the integration of AMD® Radeon™ HD 6320 graphic controller guarantees satisfactory visual effects in an economic way. From 3D graphics performance to dynamic visual interactivity, AMB-A55EG1 has its own niche market both for casino gaming and arcade gaming manufacturers.

Finally, as a ready-to-go gaming solution, AMB-A55EG1’s covers all the gaming requirements that designers look for. By integrating this gaming board into the system, designers can concentrate on game development without the worries of time-to-market. And as always, it is Acrosser’s professional industry experience and expertise that makes all your embedded idea a reality!

Product Information:

2014年4月21日 星期一

AMD Brings Immersive Graphics to Embedded Applications with the New AMD Embedded Radeon? E8860 GPU

Graphics Core Next based GPU delivers double the performance of its predecessor with industry-best seven year longevity to drive a new era of visual and GPGPU embedded systems

, Germany. — 2014 – Feb. 25, 2014  AMD today announced the AMD Embedded Radeon™E8860 GPU (codenamed “Adelaar”), the industry’s first discrete graphics card based on Graphics Core Next (GCN) architecture designed specifically to advance the visual growth and parallel processing capabilities of embedded applications. With more than double the performance in the same power envelope as its predecessor1, the AMD E8860 GPU delivers 3D and 4K graphics to embedded gaming machines, digital signage, medical imaging, commercial aerospace and conventional military, and other embedded applications. A 33 percent higher single precision floating point2 over the previous generation at 768 GFLOPS enables the AMD E8860 GPU to also blast through the most complex parallel applications like terrain and weather mapping, facial and gesture recognition and biometric and DNA analysis.
“The demand for rich, vibrant graphics and enhanced parallel compute capabilities in embedded systems is greater than ever before, and is expected to continue to grow as we enter the Surround Computing era,” said Scott Aylor, corporate vice president and general manager, AMD Embedded Solutions. “Legacy graphics no longer meet the needs of embedded solutions for today and tomorrow. With unprecedented performance-per-watt, the AMD E8860 GPU addresses the need to drive multi-displays, 3D and 4K content and GPGPU compute across small form factors, harsh environments and mission critical applications.”
The AMD E8860 GPU, designed in multi-chip module packaging, comes with an industry leading seven year longevity supply guarantee3 and is available as a mobile PCI Express module (MXM) and PCI Express add-in-board. The AMD E8860 GPU drives multiple independent displays with support for AMD
Eyefinity Technology4, and supports DirectX 11.1, OpenGL 4.2, and OpenCL™ 1.2 with support for Microsoft Windows 7, Windows Embedded 7 Standard, Windows 8/8.1, Windows Embedded 8 Standard,  and real-time and safety-critical operating systems supported by CoreAVI’s suite of embedded softwaredrivers. Additional features include:

“Embedded GPUs like the AMD E8860 will persevere to accommodate increasingly stringent OEM preferences as demands for HD, 3D and even 4K display capability continue to grow across a seemingly endless array of screen types and sizes,” said Chris Rommel, Executive Vice President of  Embedded Technology, VDC Research. “The proliferation of GPGPU computing will expand the applicability of GPUs beyond visual applications into medical, conventional military and commercial aerospace applications where massive parallel compute is a necessity.”

AMD E8860 GPU-based solutions for digital signage, conventional military and commercial aerospace, medical imaging and embedded gaming machines will be available from Curtiss-Wright
Defense Solutions, Quixant, SAPPHIRE, Tech Source Inc., TUL, WOLF Industrial Systems Inc., and other leading board manufacturers and solution providers beginning in Q1 2014.

About AMD

AMD (NYSE: AMD) designs and integrates technology that powers millions of intelligent devices, including personal computers, tablets, game consoles and servers that define the new era of surround computing. AMD solutions enable people everywhere to realize the full potential of their favorite devices and applications to push the boundaries of what is possible. For more information, visit www.amd.com.
—30— AMD, the AMD Arrow logo, Radeon and combinations thereof are trademarks of Advanced Micro Devices, Inc. Other names are for informational purposes only and may be trademarks of their respective owners.
1. AMD Radeon™ E8860 scored 2689 and AMD Radeon E6760 scored 1327 when running 3DMark® 11P benchmark paired with AMD R-464L APU. The E6760’s thermal design power (TDP) is 35W and the E8860’s TDP is 37W. The E8860 and AMD Radeon E6760 used an AMD DB-FS1r2 motherboard with 8GB DDR3 memory, a 64GB Crucial M4 hard disk drive, and AMD R-464L. The system ran Windows® 7 Ultimate EMB-79
2. AMD Radeon™ E8860's single-precision floating point is 768 GFLOPS; AMD Radeon E6760's single-precision floating point is 576 GFLOPS. EMB-80
3. Part availability is planned for seven years from date of announcement, subject to change without notice. Further support available under contract
4. AMD Eyefinity technology supports up to five DisplayPort monitors on an enabled graphics card. Supported display quantity, type and resolution vary by model and board design; confirm specifications with manufacturer before purchase. To enable more than two displays, or multiple displays from a single output, additional hardware such as DisplayPort-ready monitors or DisplayPort 1.2 MST-enabled hubs may be required. A maximum of two active adapters is recommended for consumer systems. See www.amd.com/eyefinityfaq for full detail
5. AMD Radeon™ E8860 scored 2689, AMD Radeon E6760 scored 1327, NVIDIA GeForce GT630 (Kepler) scored 1784, and NVIDIA GeForce GT640 (GDDR5) scored 2209 when running 3DMark® 11P benchmark paired with AMD R-464L. The performance-per-watt data was calculated by dividing the 3DMark 11P score by the GPU's thermal design power. The performance delta was calculated based on the E8860's 3DMark 11 score of 2689 and the GeForce GT640 (GDDR5)'s 3DMark 11 score of 2209. The performance-per-watt delta was calculated based on the E8860's performance-per-watt score of 72.7 and the GeForce GT640 (GDDR5)'s performance-per-watt score of 45.1. AMD Radeon E8860, AMD Radeon E6760, NVIDIA GeForce GT630 (Kepler), and NVIDIA GeForce GT640 (GDDR5) used an AMD DB-FS1r2 motherboard with 8GB DDR3 memory, a 64GB Crucial M4 hard disk drive, and AMD R-464L. The system ran Windows® 7 Ultimate. EMB-83
6. AMD Radeon™ E8860 scored 2689, AMD Radeon E6760 scored 1327, NVIDIA GeForce GT630 (Kepler) scored 1784, and NVIDIA GeForce GT640 (GDDR5) scored 2209 when running 3DMark® 11P benchmark paired with AMD R-464L. The performance-per-watt data was calculated by dividing the 3DMark 11P score by the GPU's thermal design power. The graphics performance delta was calculated based on the E8860's 3DMark 11 score of 2689 and the GeForce GT640 (GDDR5)'s 3DMark 11 score of 2209. The
performance-per-watt delta was calculated based on the E8860's performance-per-watt score of 72.7 and the GeForce GT640 (GDDR5)'s performance-per-watt score of 45.1. AMD Radeon E8860, AMD Radeon E6760, NVIDIA GeForce GT630 (Kepler), and NVIDIA GeForce GT640 (GDDR5) used an AMD DB-FS1r2 motherboard with 8GB DDR3 memory, a 64GB Crucial M4 hard disk drive, and AMD R-464L. The system ran Windows® 7 Ultimate. EMB-82

7. AMD Radeon™ E8860 scored 2689 and AMD Radeon E6760 scored 1327 when running 3DMark® 11P benchmark paired with AMD R-464L APU. The performance-per-watt data was calculated by dividing the 3DMark 11P score by the GPU's thermal design power. The performance-per-watt delta was calculated based on the E8860's performance-per-watt score of 72.7 and the E6760's performance-per-watt score of 37.9. The E8860 and AMD Radeon E6760 used an AMD DB-FS1r2 motherboard with 8GB DDR3 memory, a 64GB Crucial M4 hard disk drive, and AMD R-464L. The system ran Windows® 7 Ultimate. EMB-81
refer to:
http://embedded-computing.com/news/amd-radeontm-e8860-gpu/

2014年4月14日 星期一

Acrosser’s Fanless 3.5 Inch Embedded SBC AMB-N280S1 is the most inquired-about embedded board of all time!



Since 2013, there has been one embedded board that has caught global attention. It was so popular that Acrosser had to make a product film just to let everyone get a closer look at it. Acrosser believes that its No. 1 embedded SBC, AMB-N280S1, is worth introducing worldwide. The AMB-N280S1 single board computer comes with an Intel Atom N2800 processor 1.86GHz and NM10 PCH chipset. There are three main features that explain why AMB-N280S1 stood out among other products.
Space-saving design with uncompromising graphic performanceThe debate over power consumption versus performance has been going on for a while, but Acrosser strikes a fine balance on AMB-N280S1. The adoption of an Intel Atom Processor allows for better graphic performance without consuming more power. Secondly, the large heatsink provides great thermal conductivity in the board for the most efficient heat dissipation. In addition, AMB-N280S1’s small form factor (dimensions: 146mm x 102mm) makes it a great mini embedded solution.
Rich I/O connector for diverse application
Given limited space, AMB-N280S1 takes full advantage of its 3.5” surface. The board offers one VGA port, one LVDS header and one HDMI port each for video output, with an uncompromised 1920 x 1200 (LVDS 1366 x 768) resolution that supports dual displays. We placed one Mini PCIe on both the top and bottom sides of the board, which adds versatility to the board’s application. Not only that, but 6 COM headers and 4 USB also allow for diverse peripheral connection and use.
Variety of usage for industrial application
Thanks to its small form factor, AMB-N280S1 has triggered vast business interest in the following applications: medical deviceskiosk, and automated vending machines. AMB-N280S1’s steady thermal structure has also won the hearts of lab researchers planning to integrate the board into environmental monitoring systems for analysis use.
With Intel reassuring customers of the longevity of its CPU supply, the product life of AMB-N280S1 can last at least another 5 years, making the board an economic option for system integration. Please do not hesitate to send us inquiries if you need more information about the board. No wonder Acrosser’s AMB-N280S1 is the most inquired-about embedded board of all time!


Here’s our AMB-N280S1 Product Film:

2014年4月7日 星期一

IVI system sandboxing: The next frontier for in-vehicle upgrades

With the rapid advancement of mobile, cloud, and embedded technologies, it may surprise most that In-Vehicle Infotainment (IVI) systems are typically developed four to five years before the vehicles are release to the market. In fact, most 2014 models are running IVI systems from 2009. By most modern industry standards, a five-year development lifecycle is unacceptable. So how is it that one of our most valued commodities - the automobile - is subjected to such a technological lag?

Primarily, the bloated IVI development lifecycle can be linked to two factors: driver safety and vehicle longevity. Although most people associate IVI systems with just navigation and entertainment, these systems also interact with many critical vehicle safety components such as driver assistance, engine control, and vehicle sensors. This means that all IVI systems must go through significant testing, evaluation, security, and certification processes. In addition, vehicle manufacturers need to ensure that an IVI system will remain operational for the duration of a vehicle’s 10-15 year lifespan.
Unfortunately, even the sleekest of vehicles on the market today are equipped with IVI systems that contain old software and unattractive user interfaces. Furthermore, consumers do not currently have the option to upgrade their IVI systems through new software rollouts or third-party applications. And while some people do trade in their vehicles every two-to-three years, for most of us purchasing a car is a long-term investment. According to automobile information analysis firm R.L. Polk & Co., the average age of automobiles in the U.S. is rising. Assuming this trend continues, many consumers will be stuck with an outdated IVI system for the next nine-to-ten years.
Customizing the car
What if IVI systems could be customized and continuously upgraded like smartphones or tablets? What if drivers could listen to music through their Pandora account, share their location via Facebook, or take a call on Skype? What if online marketplaces like iTunes and Google Play started offering IVI-specific apps? With the rising demand for consumer device customization, it’s just a matter of time before these rhetorical scenarios become the new standard.
The Android platform is especially ripe for IVI customization efforts, as it is an open source wonderland for developers. Whereas iOS remains a proprietary Apple technology, Google has opened Android up to a wide variety of uses, which is why it is currently dominating in the mobile space.
However, Android does have some major drawbacks that must be addressed before it can be utilized for IVI applications. For example, from an automotive perspective, Android has a slow boot time and does not meet the industry’s strict security and stability standards. The average boot time on an Android-based device is 40 seconds. While this is an acceptable length of time for a mobile device that rarely gets shut off, it becomes a bigger problem in a vehicle. Since most people immediately begin driving after turning on the car, a long IVI system boot time would result in drivers pulling up a map or a play list while the vehicle is in motion – further adding to distractions while driving.
Furthermore, drivers cannot simply restart their vehicles if the IVI system crashes. An unstable Operating System (OS) is inconvenient in a mobile device, but it’s downright dangerous in a vehicle. And if a driver downloads a third-party IVI app whose settings override those of the vehicle’s operational components, it could seriously compromise the vehicle’s security and functionality, from altering diagnostics and  parameters to disabling emergency services.
While slow boot times and operating speeds can generally be resolved by modifying the Android OS distribution for an “automotive-grade” platform, the real challenge lies in balancing the innovation of Android with the stringent safety and reliability requirements of the automotive industry. How can a single system be flexible and modular for consumer customization while at the same time ensuring uncompromised security and reliability?
 sandboxing splits safety-critical from software-upgradeable
The unfortunate truth is that there is no way to combine these two conflicting demands – nor should we try. Instead of managing one complex and potentially flawed OS, the goal should be to run two completely functional and sandboxed systems. By leveraging an open source, “bare metal” Xen hypervisor, developers could simultaneously run two different OSs on a single System-on-Chip (SoC) to provide:
  1. Highly reliable automotive-grade Linux or (RTOSs) like Autosar and QNX for mission-critical vehicle software
  2. Highly customizable Android for infotainment software
A hybrid architecture that is based on a Type-1 hypervisor would allow developers to create an Android-based IVI system without compromising the functionality, security, or reliability of the vehicle’s operational software. Critical components such as vehicle sensors, diagnostics, and emergency services would never be impacted by third-party apps, as they would be completely enclosed within their own respective OSs (Figure 1). Sandboxed Linux and Android operating systems give developers the freedom to create truly customizable infotainment software without negatively impacting a vehicle’s security or reliability.




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Figure 1: A hypervisor approach can effectively separate infotainment apps from critical automobile systems into a single hybrid software architecture.

(Click graphic to zoom by 1.9x)


Although still a relatively untapped field, it’s only a matter of time before IVI systems become just as customizable as any other mobile device. While Android still has some issues around reliability, security, and speed to address before it can become truly “automotive grade,” it is an ideal OS for IVI customization. By modifying Android to accelerate operating and boot time speeds, and by leveraging a hybrid architecture to separate a vehicle’s mission-critical and infotainment components, developers can begin shaping a new and industry-changing market for automotive software.
refer to: http://embedded-computing.com/articles/ivi-sandboxing-next-frontier-in-vehicle-upgrades/