Industrial PC Solution

As we near the end of 2013, acrosser would like to send you our warmest New Year’s wishes! We wish you and your family health, comfort, and prosperity this holiday season.

We also thank you for keeping up with our latest products, sending us inquiries, and choosing our products for your integrated solution! In 2014, we hope you will continue to choose Acrosser. We look forward to assisting you and your company in becoming the leader in your vertical market, and building a win-win relationship together.

And don’t forget about our star product, AES-HM76Z1FL, and its upcoming Product Testing Event in January! Remember to mark your calendar, since Acrosser is lending the product for free only to selected participants! Please stay tuned for more event information in early January!

With your continuous dedication and our commitment to quality, Acrosser is always motivated to make your embedded idea a reality!

Product Information:
http://www.acrosser.com/Products/Embedded-Computer/Fanless-Embedded-Systems/AES-HM76Z1FL/Intel-Core-i3／i7-AES-HM76Z1FL.html

Contact us：
http://www.acrosser.com/inquiry.html

December 5, 2013 – The Chinese market for industrial Ethernet & Fieldbus Technologies grew by 18 million nodes in 2012. More than 3 million nodes used Ethernet and the remainder used Fieldbus technology.

Although Fieldbus has a large base of new connected nodes in China, the usage of Fieldbus is not as common as in developed countries such as Germany or the United States. This is mainly because Chinese customers are encountering networking technology much later than those developing countries.

However, the growing speed of Ethernet is quite considerable in China and we think it is a great opportunity for Chinese customers to upgrade their automation system under current market condition. Customers will just jump from old Fieldbus Technologies direct to Ethernet now and actually many of them are doing right now. The Chinese market is currently engaged in extensive upgrading and new infrastructure construction, and that will require a great deal of Ethernet applications.

refer to:http://www.automation.com/portals/industrial-networks-field-buses/industrial-ethernet-growing-in-china

Service Dynamics

The primary objective of a service company should be to focus on the development a system solution that is uniquely suited to the idiosyncrasies of the client’s business without being tethered by particular product solution offerings. A big part of this is the ability to deploy technologies from appropriate sources using integration and engineering skills to achieve a superior result for the client. Service businesses need to have effective and refined project, personnel, and quality management systems. The growth and effectiveness of these businesses is directly related to adding and managing smart people and this is a unique business proficiency mastered by successful service organizations. Pure service businesses have an advantage of successfully maintaining alliances with a range of product vendors that cannot be logically achieved by product vendors who provide services. This separation positions a pure service business to use best of breed and get the most out of vendors. For comparison, consider you are a smartphone user and the only place to get apps was your phone hardware vendor.

Inherent Conflict

The dynamics of a service business and innovative product business are dramatically different. Established product companies tend to emphasize the practices and culture they know best when they move into services. The tendency is to find synergies based on their products that become the recommended solutions for customers. Additionally, it can be more difficult for a product company who provides services to be the champion for the customer when there is a problem with the product being implemented.

Ideal Product Company Focus

I believe that product companies should always be striving to eliminate implementation and operations labor with improved and innovative automation technology. There is an inherent conflict by having a company that provides services and products.

refer to:http://www.automation.com/portals/factory-discrete-automation/can-automation-vendors-serve-two-masters-products-services

acrosser Technology Co. Ltd, a world-leading industrial and embedded computer designer and manufacturer, announces the new AES-HM76Z1FL embedded system. AES-HM76Z1FL, Acrosser’s latest industrial endeavor, is surely a FIT under multiple circumstances. Innovation can be seen in the new ultra slim fanless design, and its Intel core i CPU can surely cater for those seeking for high performance. Therefore, these 3 stunning elements can be condensed as “F.I.T. Technology.” (Fanless, Intel core i, ultra Thin)

The heat sink from the fanless design provides AES-HM76Z1FL with great thermal performance, as well as increases the efficiency of usable space. The fanless design provides dustproof protection, and saving the product itself from fan malfunction. AES-HM76Z1FL has thin client dimensions, with a height of only 20 millimeters (272 mm x183 mm x 20 mm). This differs from most embedded appliances, which have a height of more than 50 millimeters.

The AES-HM76Z1FL embedded system uses the latest technology in scalable Intel Celeron and 3rd generation Core i7/i3 processors with a HM76 chipset. It features graphics via VGA and HDMI, DDR3 SO-DIMM support, complete I/O such as 4 x COM ports, 3 x USB3.0 ports, 8 x GPI and 8 x GPO, and storage via SATA III and Compact Flash. The AES-HM76Z1FL also supports communication by 2 x RJ-45 gigabit Ethernet ports, 1 x SIM slot, and 1 x MinPCIe expansion socket for a 3.5G or WiFi module.

Different from most industrial products that focus on application in one specific industry, the AES-HM76Z1FL provides solutions for various applications through the complete I/O interfaces. Applications of the AES-HM76Z1FL include: embedded system solutions, control systems, digital signage, POS, Kiosk, ATM, banking, home automation, and so on. It can support industrial automation and commercial bases under multiple circumstances.

Key features:
‧Fanless and ultra slim design
‧Support Intel Ivy Bridge CPU with HM76 chipset
‧2 x DDR3 SO-DIMM, up to 16GB
‧Support SATA III and CF storage
‧HDMI/VGA/USB/Audio/GPIO output interface
‧Serial ports by RS-232 and RS-422/485
‧2 x GbE, 1 x SIM, and 1 x MiniPCIe(for3G/WiFi)

Product Information:
http://www.acrosser.com/Products/Embedded-Computer/Fanless-Embedded-Systems/AES-HM76Z1FL/Intel-Core-i3／i7-AES-HM76Z1FL.html

Contact us：
http://www.acrosser.com/inquiry.html

industrial automation systems are performing more tasks and doing so more quickly, more accurately, and in harsher environments than ever before. They are becoming connected tools with substantially more computing and communication capabilities, allowing them to interoperate with other devices. As they evolve and proliferate, these systems put new demands on their computing technology. Rugged COM Express modules not only meet the computing needs of today’s rapidly changing industrial landscape, but also protect the investment to meet tomorrow’s performance needs.

At the dawn of the “Industrial Internet,” the ante is being upped for modular Embedded Systems. More and more machines are being connected, many in remote and challenging environments such as oil and gas, locomotives, transportation, and ship-propulsion systems. To meet the demand for more data in less time, these systems must work faster and longer. Accelerating with the demand for data is the evolution of computer processors. But businesses can’t afford the downtime required to replace processors, or the expense of replacing the carrier board when upgrading the processor. According to a 2006 Department of Energy study, idle industrial machinery can cost as much as $800 per minute.

What’s needed is a modular embedded computing architecture that addresses these cost and downtime issues. Perhaps the most compelling of the modular architectures available today is COM Express. COM Express provides the requisite computing power for today’s increasingly connected world while also extending the lifespan of the underlying system. As chip technology evolves, users can switch out the module without adverse effect on the underlying hardware and assets – saving time and money. The modularity, simplicity, and reliability of COM Express technology help businesses remain competitive, profitable, and flexible.

refer to:http://industrial-embedded.com/articles/rugged-increasingly-connected-world/

The impact of the new standards to UAV developers using model-based design is especially significant. Before describing this, an introduction to model-based design is appropriate.
Introduction to model-based design

With model-based design, UAV engineers develop and simulate system models comprised of hardware and software using block diagrams and state charts, as shown in Figures 1 and 2. They then automatically generate, deploy, and verify code on their Embedded Systems. With textual computation languages and block diagram model tools, one can generate code in C, C++, Verilog, and VHDL languages, enabling implementation on MCU, DSP[], FPGA[], and ASIC hardware. This lets system, software, and hardware engineers collaborate using the same tools and environment to develop, implement, and verify systems. Given their auto-nomous nature, UAV systems heavily employ closed-loop controls, making system modeling and closed-loop simulation, as shown in Figures 1 and 2, a natural fit.
Testing actual UAV systems via ground-controlled flight tests is expensive. A better way is to test early in the design process using desktop simulation and lab test benches. With model-based design, verification starts as soon as models are created and simulated for the first time. Tests cases based on high-level requirements formalize simulation testing. A common verification workflow is to reuse the simulation tests throughout model-based design as the model transitions from system model to software model to source code to executable object code using code generators and cross-compilers.

An in-the-loop testing strategy is often used as itemized below and summarized in Table 2:

1. Simulation test cases are derived and run on the model using Model-In-the-Loop (MIL) testing.

2. Source code is verified by compiling and executing it on a host computer using Software-In-the-Loop (SIL) testing.

3. Executable object code is verified by cross-compiling and executing it on the embedded processor or an instruction set simulator using Processor-In-the-Loop (PIL) testing.

4. Hardware implementation is verified by synthesizing HDL and executing it on an FPGA using FPGA-In-the-Loop (FIL) testing.

5. The embedded system is verified and validated using the original plant model using Hardware-In-the-Loop (HIL) testing.
A requirements-based test approach with test reuse for models and code is explicitly described in ARP4754A, DO-178C, and DO-331, the model-based design supplement to DO-178C.

Transitioning to new standards using model-based design

ARP4754A addresses the complete aircraft development cycle from requirements to integration through verification for three levels of abstraction: aircraft, systems, and item. An item is defined as a hardware or software element having bounded and well defined interfaces. According to the standard, aircraft requirements are allocated to system requirements, which are then allocated to item requirements.

The fact that ARP4754A addresses allocation of system requirements to hardware and software components is significant to UAV developers, especially suppliers. Some suppliers might have claimed that UAV subsystem development was beyond the scope of the original ARP4754, even for complex subsystems containing hardware and software, but not anymore. ARP4754A also more clearly refers to DO-178 and DO-254 for item design. In fact, the introductory notes for ARP4754A acknowledge that its working groups coordinated with RTCA special committees to ensure that the terminology and approach being used are consistent with those being developed for the DO-178B update [DO-178C].

Given the high coupling among systems, hardware, and software for UAVs, it is helpful that the governing standards now clarify relationships between systems and hardware/software subsystems.

ARP4754A recommends the use of modeling and simulation for several process-integral activities involving requirements capture and requirements validation.

ARP4754A Table 6 recommends (R) analysis, modeling and simulation (tests) for validating requirements at the highest Development Assurance Levels (A and B). For Level C, modeling is listed as one of several recommendations. While ARP4754 made similar recommendations, ARP4754A provides more insight and states that a representative environment model, such as the plant model shown in Figure 1, is an essential part of a system model.

Also noted in ARP4754A is that a graphical representation or model can be used to capture system requirements. The standard now notes that a model can be reused for software and hardware design.

If engineers use models to capture requirements, ARP4754A recommends engineers consider the following:

1. Identify the use of models/modeling

2. Identify the intended tools and their usage during development

3. Define modeling standards and libraries

When using model-based design with ARP4754A and DO-178C, additional verification capabilities are often needed beyond in-the-loop testing described in Table 2. These including requirement tracing, model standard checking, model-to-code structural equivalence checking, and robustness analysis using formal methods. For UAVs, rigorous verification that includes multiple verification technologies is paramount given their autonomous nature and system complexity.

DO-178C

Not surprisingly, one of the first changes new in DO-178C is an explicit mention of ARP4754A in Section 2: System life-cycle processes can be found in other industry documents (for example, SAE ARP4754A).

Clarification updates aside, such as the one noted earlier, DO-178C does not differ significantly from DO-178B, at least at first glance. In fact, a casual reader might miss an item mentioned in Section 1.4: How to Use this Document: One or more supplements to this document exist and extend the guidance in this document to a specific technique… if a supplement exists for a specific technique, the supplement should be used …

In other words, the standard’s big changes are captured in the supplemental documents, such as RTCA DO-331, Model-Based Development and Verification Supplement to DO-178C and DO-278A.

Pertinent to this discussion, a long-standing issue with DO-178B for practitioners of model-based design is the uncertainty in mapping DO-178B objectives to model-based design artifacts. Addressing this mapping was a main goal of the DO-178C Sub-Group (SG-4) focused on model-based design. No single mapping sufficed, so several mappings are provided in DO-331. Some include the concept of a Specification model, which is a model separate from that of the one used for design and code generation. The other concept is a Design model, which serves as the detailed requirements used to generate code.

The essence of a Design model is the following:

1. A model can be used for design (system and/or software) and should be developed using requirements external to the model (for example, a textual document or requirements database).

2. Source code can be generated directly from the design model (by hand or automatically).

Of course, with 125 pages, DO-331 has a lot more to offer than described here. One approach noted in the standard is that a model used initially for system design can be elaborated on and reused for software design and code generation. This ties ARP 4754A and DO-178C together quite nicely for UAV system and software developers using model-based design.

For example, the controller shown as a component in the system model in Figure 1 and by itself as a software model in Figure 2 is:

Used during system design
Reused as an entry point for software design
Elaborated on during detailed software design (for example, by discretizing continuous time blocks and changing double-precision data to single-precision or fixed-point)
Used as input for embedded code generation
The test cases for system requirement validation likewise are reused on the model, source code, and executable object code to perform functional testing and collect coverage metrics.

While not advocating for any particular mapping, the use and reuse of models for systems and software design along with code generation have long provided UAV system developers using MathWorks products of Simulink and Embedded Coder with streamlined processes. It is nice to see that this same approach is now clearly acknowledged as an acceptable means to certification by the governing standards. MathWorks provides verification tool qualification kits and workflow guidance regarding the use of model-based design for DO-178.

refer to:
http://mil-embedded.com/articles/transitioning-do-178c-arp4754a-uav-using-model-based-design/

One of the key areas of opportunity is the power industry, where the booming consumer and industrial power markets in developing economies such as China and India have created rocketing demand. In China the per capita energy use is still a long way behind most of Western Europe, meaning the potential for growth is still huge. Without question, Asia represents a perfect storm of opportunities for European automation suppliers.

In order to help businesses better understand how to take advantage of the current climate and increase their industrial automation sales in Asia, particularly China, the CC-Link Partner Association (CLPA) is hosting a seminar entitled ‘Gateway to China’. The event will take place on 24th September at the Mitsubishi Electric Europe Tokyo Conference Suite in Hatfield.

For more information on the speakers and to book tickets for the event, visit the CLPA’s EventBrite page gateway-to-china.eventbrite.co.uk/.

In light of the sensitive current economic climate, many Asian companies are taking a more careful approach to investment – they are becoming more demanding towards their suppliers and making more enquiries before purchasing. Furthermore, according to IHS’ research, several Chinese manufacturers are currently developing products which are in direct competition with the ones provided by Western suppliers of industrial automation solutions. These are only a few of the obstacles facing European vendors who want to penetrate the Asian market to change the way they do business.

Flexibility and the ability to respond to very specific demands are becoming essential factors when dealing with the Asian market. Being able to offer technologies and products which are compatible with the needs of Asian clients is no longer an option, it’s a must.

– See more at: http://www.connectingindustry.com/automation/asia-claims-almost-half-of-automation-sales.aspx#sthash.4z4uCkA2.dpuf

refer to:http://www.connectingindustry.com/automation/asia-claims-almost-half-of-automation-sales.aspx

Salary facts

The largest percentage of respondents (23.6%) reported a salary in the $100,000–$124,999 pay range. The second largest percentage (13.7%) was in a pay range of $125,000–$149,999. The average salary in the U.S. is now up to $106,772—that is an increase of $2,862 (or 2.8%) from last year. Two other regions of the world reported a higher average salary. Canadian respondents reported an average salary of $118,483, while Australia and New Zealand respondents reported a whopping $131,483. It is interesting to note that the dollar exchange rate in both of these regions is fairly close to a 1:1 ratio. However, the cost of living is typically higher in both regions, and the average salaries reflect those higher living expenses.

Within the U.S., the highest paid region is the west south central (south), with an average salary of $120,750, which is a $4,180 increase over last year. The lowest paid region is the east north central (midwest), with an average salary of $96,041, a $6,871 increase over last year. (Regions are defined on Wikipedia.)

The average salary of the largest percentage of respondents by job function (28.2%, automation/control engineering) was $105,650, which is a $1,610 increase over last year. The top five highest paid job functions are listed below.

Engineering management: $137,761 (6.6% of respondents), a $5,041 increase
Safety systems engineering: $129,285 (1.1% of respondents), a $7,255 increase
Consulting engineering: $127,398 (3.8% of respondents), a $3,108 increase
Sales (outside): $121,848 (4.5% of respondents), a $4,828 increase
Project management: $120,543 (3.5% of respondents), a $9,323 increase
Of respondents, 69.2% possessed a college degree or higher. The average salary of college graduates (without an advanced degree) is $109,029. The results show that those who attended at least some graduate school (but did not finish) were able to increase their annual salary by $5,647. Those respondents who actually completed an advanced degree reported an average salary of $123,004—that is a $13,975 increase (virtually unchanged from last year) over college graduates.A degree of higher learning

The largest percentage of respondents (33.1%) received a bachelor’s degree in electrical engineering, pulling in an average salary of $117,416, an increase of $4,666 over last year. The top five average salaries by degree are:

Chemical engineering: $123,789 (12.5% of respondents)
Physics: $123,125 (1.2% of respondents)
Other science: $122,222 (2.1% of respondents)
Liberal arts: $116,402 (1.9% of respondents)
Computer science: $112,459 (2.9% of respondents)
Participants in our survey work in 40 different industry segments. The largest number of responses came from the engineering services segment (12.3%), where the average salary is $123,444. It is interesting to note which industries are the biggest payers. The top five highest salaries are paid to professionals in these industry segments:

Petroleum refining and related industries: $125,805 (5.7% of respondents)
Oil and gas extraction: $125,326 (4.4% of respondents)
Instrument and control apparatus sales and solution: $115,105 (3.6%)
Utilities combination (nuclear/fossil fuel, etc.): $114,698 (2.2%)
Chemicals: $113,020 (6.4%)
Stating the obvious…

Again this year, we compared the salary of those with a professional engineering license to those without a license. It is no surprise that those with the license (16.1%) earn an average of $21,118 more each year, or an average salary of $124,857 versus $103,739 for those without the license.

refer to:http://www.automation.com/factors-that-affect-your-salary-what-you-need-to-know