Human Machine Interface Industry
Due to growing industrial IoT and industry 4.0 technological needs, smart factory automation is increasingly in use in all the industries and hence the demand or need for smart Human Machine Interface (HMI) is also increasing. HMI market for discrete applications is growing at a higher rate as compared to process applications owing to growth of automotive, metal & mining, packaging and aviation industries. The other key factors driving the HMI market include demand for enhanced efficiency, high growth of software services suitable for each applications and increasing need for data security and reliable hardware.
Due to growing technological needs, factory automation is increasingly in use in all the industries and hence the demand or need for HMI is also increasing. HMI market for discrete applications is growing at a higher rate as compared to process applications owing to growth of automotive, metal & mining, packaging and aviation industries. The other key factors driving the HMI market include demand for enhanced efficiency, high growth of software services suitable for each applications and increasing need for data security and reliable hardware.
The overall HMI market is estimated to be worth $2.50 billion in 2012 and expected to reach $4.05 billion in 2017 at a CAGR of 10.13% from 2012 to 2017. Currently Americas commands the largest share in the global HMI market followed by Europe and APAC. It is observed that APAC is growing at a higher CAGR and is expected to have the largest market share i.e. 28% of the total HMI market by 2017. The higher CAGR of APAC is primarily due to its fast growing economy and increased significance for automation industries. Human Machine Interface (HMI), as the name describes, is an interface between operator and a machine. The level of interaction with the machines has increased exponentially.
The emerging Internet of Things (IoT) will offer value across multiple industrial sectors and applications. Cisco expands on this, using the term, "Internet of Everything" (IoE) to describe its vision of bringing people, process, and data together via the Internet of Things. The company predicts that the IoE could enable manufacturers to generate $3.88 trillion of value through a combination of increased revenues and lower costs over the next ten years.
Innovative, forward-thinking manufacturers are realigning their technology and business imperatives to capture this value by leveraging Internet Protocol (IP) technology. Pivoting the business to take advantage of this paradigm shift is not trivial. It requires a sound incremental strategy built around business use cases applied throughout the manufacturing and business value chain.
Today, IP-enabled microprocessors – the brains inside many digital devices – can seamlessly connect conventional automation equipment, such as I/O modules and variable frequency drives. But the explosive growth of other IP-enabled devices – many adopted from other disciplines – is transforming the industrial landscape.
- Automation: Today's manufacturing companies must become more responsive to changing market and operational conditions without sacrificing automation efficiency. This has created urgency for manufacturers to converge and connect the multitude of isolated production systems and processes throughout their value chain.
- Security and Compliance: By implementing Industrial IP across the entire enterprise, organizations can increase network security through a common architecture that decreases inconsistencies in network protocols, security practices and training.
- Mobility: Manufacturing and industrial users recognize the risks and rewards of proliferating mobile devices in production environments. The desire for context-based information – available on whatever device the user chooses – requires a converged communication fabric that supports both industrial and commercial technologies.
- Video: Video technology has historically been underutilized in manufacturing and production, largely because it required its own network infrastructure. Building digital communications fabrics based on Industrial IP allows video to be used to its fullest potential.
- Industrial Compute: Migrating from monolithic servers and databases with isolated islands of processing to virtualize computing and cloud resources creates new opportunities for manufacturers. Internet Protocol provides an appropriate environment for building tomorrow's cloud-based information architectures.
- Remote Assets and Services: Diverse manufacturing environments and shrinking in-house engineering staffs mean it's much more difficult to have direct line-of-sight to all machines and processes. Connecting these assets to an Industrial IP communications fabric greatly improves the ability to monitor and respond to changing conditions and more effectively leverage intellectual capital.
- Energy Management: Energy is one of the most volatile and fastest- growing costs of production, but until recently, energy data was locked away inside automation systems. By leveraging Industrial IP across the enterprise, manufacturers can use the same networking platform as their enterprise network to access energy data at the load and device levels, and up through the enterprise.
The Internet of Things (IoT) and Machine-to-Machine communication describes how the Internet will get bigger as sensors and intelligence are connected to physical things like physical assets or consumer devices and these things are connected to the Internet. The vision and model have existed for years but there has been acceleration in the number and types of things that are being connected and in the technologies for collecting, processing, and sharing. It also explores some of the key applications for IoT & M2M Communication, including retail, transportation, energy & power, telecom & IT, Industrial & commercial buildings, and mobile location-based services.
The IoT infrastructure allows combinations of smart things/objects, sensor network technologies. People using diverse and interoperable communication protocols realizes that a dynamic heterogeneous/multimodal network can be deployed in remote or unreachable spaces (such as, mines, oil platforms, forests, pipes, and tunnels) or in cases of emergencies such as earthquakes, floods, fire, radiation areas, etc. In IoT infrastructure, these “things or objects” will realize and explore each other and learn to take advantage of each other’s data by sharing resources and dramatically enhancing scope and dependability of the resulting services.
M2M communication will be focused more on the terminals and data centers (e.g. cloud computing and home data centers) than the nodes as in current networks. Expansion of storage capacity at lower costs will result in the local accessibility of most information required by people or things/objects. This can be coupled with improved processing capabilities and always-on connectivity; will make terminals increase its main role in communications.
IoT & M2M communication will bring physical business benefits like high-resolution management of resources and products, better collaboration between enterprises, and improved life-cycle management; many of these benefits are achieved via exclusive identification for individual things/objects together enabling each to cooperate independently, by building up an individual life history by cooperation and activities over time. Among the industry verticals, public safety and security, and retail accounts with maximum share, followed by consumer and residential, and IT & telecom.
OEMs/ODMs and end users are challenged more than ever with achieving the highest degree of manufacturing effectiveness, overall equipment effectiveness (OEE) and operational efficiency while maximizing productivity and throughput. Sustainability issues, pressure for device convergence, security, operations that increasingly transcend borders, regulatory complexity and the emergence of new markets can be addressed with AIS design for manufacturability services and capabilities, and superior open, PC-based HMI solutions combined with Windows Embedded 8 operating systems.
New information technologies such as cloud computing, mobility, Internet of Things (IoT), Machine-to-Machine communications (M2M), big data analytics and 3D visualization, are changing the world and having a huge impact on commercial and industrial plants and facilities. OEMs/ODMs and end-users are typically slower to adopt new leading edge technologies and historically conservative to invest in new technology areas. They will need to make substantial investments to stay competitive or be put at risk of a disruptive technology displacing their business model or competitive foothold. AIS helps these companies address technological demands by delivering prudent designs, engineering, manufacturing and superior open PC-based HMI solutions coupled with Windows embedded 8 operating software. AIS open platform strategy provides an affordable migration path to embracing new information technologies on the manufacturing floor, warehouse and logistics and at the enterprise level.
AIS open-based visualization operator interface panels and Windows Embedded provide a platform that can be utilized to build sustainable, converged intelligent systems. Solutions can be highly customized in manufacturing environments to fit the needs of OEMs and their customers, but offer high degrees of security, reduced costs, and faster time-to- market. Windows Embedded connects diverse technologies throughout manufacturing environments while increasing revenue generating opportunities. The combined solution of AIS HMIs and Windows Embedded 8 helps companies extend their operational intelligence, using their existing IT infrastructure and industry devices that securely exchange data with back-end systems.
The new IEC 62368-1 hazard-based standard that will replace both IEC 60065 (Safety of AV Equipment) and IEC 60950-1 (Safety of Information & Communication Technology Equipment). The IEC 62368-1 Second Edition CB Certificates and Standards represent a major change or shift in focus in how the standards are being developed. The traditional prescriptive standards focuses on establishing a set of written rules to be followed, whereas the new hazards-based standard is focused on identifying safety hazards in the early product development phase and designing the product to eliminate them – and providing more performance options to demonstrate compliance to the standards. These new hazards-based testing methods require a more comprehensive and holistic approach to Design for Manufacturability, in which AIS already has tremendous expertise, in-house capabilities and services for over the past decade.
In the next five years, the predominant approach to safety engineering will significant shift from prescriptive rules to a new hazard-based concept, with more performance-based options. The new hazards-based standard is expected to be advantageous for AIS who designs, engineers and manufacturers highly advanced, reliable and safe open-based platform PC-based HMIs for their customers. Their Design for Manufacturability Services (DMS) and capabilities for open platform HMIs are focused on hazard-based principles, which are more performance-based requirements (vs. prescriptive) and their ability to better consider and incorporate innovative HMI and visualization systems design and construction.
The IEC 61010 code which specifies general safety requirements for electrical equipment intended for professional, industrial process, and educational use; any of which may incorporate computing devices, when used under the normal and extended environmental conditions. AIS Design for Manufacturability Services test and certify open Industrial PCs and HMI solutions to perform within the following equipment:
- Electrical Test and Measurement Equipment: This is equipment which by electromagnetic means tests, measures, indicates or records one or more electrical or physical quantities, also non-measuring equipment such as signal generators, measurement standards, power supplies for laboratory use, transducers, transmitters, etc. This standard also applies to test equipment integrated into manufacturing processes and intended for testing manufactured devices.
- Electrical Control Equipment: This is equipment which controls one or more output quantities to speci?c values, with each value determined by manual setting, by local or remote programming, or by one or more input variables.
- Electrical Laboratory Equipment: This is equipment which measures, indicates monitors or analyzes substances; or is used to prepare materials, and includes in vitro diagnostic (IVD) equipment. This equipment may also be used in areas other than laboratories, for example self-test IVD equipment may be used in the home and inspection equipment to be used to check people or material during transportation.
AIS next generation HMI Touch Panel Series are engineered to meet the increasingly complex processes, demanding visualization and control tasks of machines and automation systems while simplifying operation and programming. Using flexible and standardized interfaces for embedded computing allows for easy and efficient integration for almost any machine, application or environment.
AIS Premium HMI Panel PCs are equipped with: NEMA 4X/IP66-compliant stainless steel front bezels featuring a corrosion and chemical resistant surface, integrated with Intel® Core™ i7-4650U Processor (4M Cache, up to 3.30 GHz), DDR3L-1600 memory up to 16 GB, RAID high availability storage, PCIe expansion slot, and 12-24 VDC power supply. They come standard with Windows Embedded Standard 7/8 and an X86 PC-based platform. The Premium series is modular, field-replaceable, easy to service, maintenance-free, rugged and fan-less. It is able to withstand high electromagnetic environments, as well as shock and vibration. Available in both single touch and multi-touch screen, wide screen options ranging from 15” to 24”, the new HMI family offers an extremely wide selection of interfaces and gesture-based touch panel solutions to serve its various requirements. Moreover, the Premium Series come with UL listing, CE Marking & CB Scheme – making them the most advanced, powerful, and no compromise modular HMI series with superior high speed processing capabilities that meet any HMI, SCADA, MES, ERP, networking or OEM applications. Learn more »
AIS Standard HMI Panel PCs are equipped with: NEMA 4X/IP66-compliant stainless steel front bezels featuring a corrosion and chemical resistant surface and utilize an Intel® Atom™ Processor E3845 (2M Cache, 1.91 GHz), DDR3L-1333 memory up to 8 GB, removable 2.5" SATA hard drive bay and 12-24 VDC power supply. They come with Windows Embedded Standard 7/8 and X 86 PC-based platforms and are modular, field-replaceable, easy to service, maintenance-free, rugged, fan-less, shock and vibration resistant and able to withstand high electromagnetic environments. The Standard series is available in both single and multi-touch screen models. Single touch models are available in 12.1”, 15”, 17”, 19”, 21.5” and 24” touch screen sizes. Multi-touch models include: 15.6”, 18.5”” and 21.5” display sizes. Moreover, the Standard Series come with UL listing and CB scheme certificate, offering functionality and affordability in a modular compact package covering the greatest range of industry requirements from medium-to-high-end HMI, SCADA, MES and OEM applications. Learn more »
AIS Compact HMI Panel PCs are equipped with NEMA 4/IP65-compliant aluminum front bezel, corrosion resistant surface. Integrated with an Intel® Celeron® Processor N2930, on-board non-volatile DDR3L-1333 memory and a standard SD card slot, the new series of touch panels deliver a great combination of performance, features and functionality at an affordable price. The Compact line of HMIs come standard with Windows Embedded Compact 7, Embedded 7 or 8 (32/64-bit) operating systems and are available in a variety of screen sizes (7” to 21.5”) in both single and multi-touch. These systems offer real-time performance, compact and lightweight aluminum die-cast housing and are: easy to service, maintenance-free, space-saving, fan-less, able to withstand high electromagnetic environments and are resistant to shock and vibration. Moreover these come with UL listing and CB scheme certificate and are: simpler, smarter, and more cost-effective all-in-one solutions. AIS offers the greatest value, feature set and capabilities for use 24/7 at machine level HMI, operator control and visualization applications. Learn more »
AIS has an extensive set of tools for HMI panels & displays design, simulation, and testing. We offer a wide range of electrical, software, mechanical, health, safety, and the environmental design capabilities. AIS designs to meet: automotive, industrial, commercial, hazardous, military, marine, ISO, IEC, UL, CE, MIL, DNV, ATEX, SAE and/or customer specific applications.
AIS implements the latest quality control practices and techniques (APQP, FMEA, Gage R&R, PV&V, SPC CAR/CAPA) to meet the demands of international regulations and standards (ISO 9001:2008 and ISO/TS16949).
Design Technology Capabilities
Designing Break-Through Technologies with People, the Environment & Profitability in Mind
AIS aspires for total excellence in everything we do. Creative and technical problem solvers who respond critically and resourcefully to the demands of technology innovation…a company who appreciates the importance of technology designed for life, company and the environment…and a resource committed to sustainability, profitability and efficiency. This sums up the spirit and approach of the AIS design technology team when solving complex engineering challenges and dilemmas.
The design cycle is a tool used to develop technologies to solve a problem. Knowing how to apply their immense technical expertise and hands-on experience, gained through years of solving real world problems, is what differentiates AIS from the rest.
AIS adheres to a four-stage process for in-house development of new product designs and technologies – a time proven methodology that has helped create numerous ground breaking technologies and solutions for their customers. The design cycle is a model intended to be the central tool to help AIS create and evaluate products/solutions. The AIS design cycle consists of four major stages as they relate to the objectives of the new product development.
AIS Design Cycle System for New Product Development:
- Inquire & Analyze Stage: AIS identifies and analyzes the problems to be solved and objectives of the overall project and then summarizes findings with action plans
- Ideation Stage: In this creative process stage, product design ideas and concepts are generated. Once the appropriate design concept and strategy is selected, AIS plans the entire design through execution phase of product development
- Creation Stage: Demonstrating their technical skills, AIS uses state-of-the-art equipment, tools and techniques to produce the new product/solution and make any necessary justified design changes if required
- Assess Stage: AIS evaluates the final product/solution and testing methods. If necessary revisions or upgrades for further refinement are made then proceed to final production
Innovating Electrical Designs while Meeting the Necessary Specifications and Standards
AIS has an extensive set of tools for electrical circuit design, simulation, and testing. Offering a wide range of electrical design and engineering capabilities, AIS provides custom integrated electronics system design and development, including evaluation and analysis to several standards. Some of the key standards that AIS’s designs meet include: automotive, military, marine, ISO, UL, CE, MIL, and/or customer specific applications. The combination of talented and highly trained design engineers and state of the art equipment and tools, allows AIS to deliver a design optimized for functionality and manufacturability.
- Electronic Circuit Design: Analog circuits, digital circuits, mixed-signal circuits
- Printed Circuit Board Design: Single-sided, double-sided, and multi-layer boards
- Embedded Logic and Signal Processing Board Design: RISC microprocessors or controllers, ARMs, DSPs, and FPGAs
- Industrial Embedded Board Solutions: Single board computers, computer on modules & extension single board computers with integrated high-performance embedded processors. Some of the microcontroller/processors manufacturers used by AIS are: Intel, AMD, TI, Freescale, and Samsung
- Electronic Circuit Simulation and Analysis: Analog or digital electronic circuit simulators, and mixed-signal electronic circuit simulators
Embedded Software Solutions from Conceptualization through Implementation
There are many aspects to consider in the design of an embedded software solution. The importance of each aspect should reflect the goals the software is designed to achieve. With this in mind, AIS offers complete software design, coding, testing, and documentation services using a software development process in a controlled environment.
The AIS software design team has worked on developing a variety software products for diverse categories, applications and market uses with visualization, control and monitoring equipment. From complex, military qualified, real time software design, to easy-to-use graphical user interfaces, AIS is your total embedded product software solution.
- System Drivers: BSP for a variety of hardware boards, including development/porting of the device drivers for various peripherals such as serial and Ethernet communication, graphics display, touch screen and Keyboard controller, PCI/USB/ATA bus-architectures, audio and video drivers, etc.
- System BIOS: BIOS flash is a tool that allows customers to update and backup the BIOS on AIS hardware platforms
- Operating System: Windows Embedded 8/7/XP/CE , embedded Linux, and QNX embedded solutions are total BSP to help customers speed up their project development
- Embedded Firmware: A wide range of embedded firmware solutions, no-OS environment, straight code-to-hardware, hardware architectures: 8-bit, custom (optimized) 32bit processors
- Real Time Operating System (RTOS): Real time Linux and Windows CE
- Application Programming Interface: A set of routines, protocols, and tools to build software applications
- Bootloader: A custom u-boot with specific configurations
A Thorough and Comprehensive Process for Embedded Software Lifecycle Management Success
Embedded software is a key driver in the success of today’s industrial equipment and products. AIS embedded software solutions enable the innovation and flexibility customers require achieving success in increasingly competitive markets. In light of this need, AIS’s approach to embedded software lifecycle management goes well beyond conventional thinking, techniques and tactics. They employ a comprehensive process to managing the entire lifecycle of an embedded software solution. The AIS lifecycle management process includes: project planning and scoping, architecture design, coding and integration, system design testing and debugging and support through entire life of the solution.
Turning Complex Engineering Ideas into Mechanically Viable Products and Solutions
Pulling together the combined resources and expertise of AIS’s cross-discipline design team allows them to efficiently develop and execute mechanical designs that are right for the project. Their flexibility enables them to adapt throughout the mechanical design process and deliver the proper solution for their customers.
AIS selects or designs product enclosures to satisfy the customer’s unique application and environment. Fabrication techniques include machined, cast, metal, and molded. In addition, AIS always considers requirements for EMI, fluid sealing, thermal transfer, ease of assembly, and cost when designing a mechanical solution. Our mechanical and system design expertise includes:
- Design-to-manufacturing methods
- Detailed drawings and documentation
- 3D CAM/CAM/CAE
- PCB Design & Simulation Software
- In-House Prototyping
Optimal Viewing from Every Angle, No Matter the Environment or Condition
AIS integrated leading-edge TFT-LCD panels ensure superior performance and excellent color quality and imaging in a broad range of indoor and outdoor operating environments. From measuring instruments, automatic teller machines (ATMs), retail point of sale terminals (POS), to factory automation equipment (FA) and touch screen kiosk, AIS integrated TFT-LCD panels have all the earmarks of superior performing panels and monitors. AIS TFT-LCDs deliver:
- High Reliability: AIS integrated LCD panels feature wide operating temperature range, forward compatibility, RoHS compliance, low EMI technology & long life lamp.
- Optimal Visibility: With excellent display characteristics even when viewed from extreme angles, AIS integrated LCD panels also offer ideal visibility and viewing in less than optimum conditions
- Outdoor Use Technology: Low reflection, high brightness and Transflective LCD modules and other features ensure AIS integrated LCD panels are ideal for continuous outdoor use.
Brilliant Color Conversion and Reproducing True-to-Life Images
Leveraging the very latest in color optimization and image reproduction technologies, meeting industry design standards and offering the ideal product mix for industrial and critical military applications, AIS high reliability imaging and vision processing devices support all your specific requirements. With a typical display the reproduction of images is visibly different from the original source because of display device characteristics and design. AIS integrated LCD panels with original Natural Color Matrix optimization technology separates color data and luminance components, while controlling individual display colors (red, green, blue, cyan, magenta, yellow) for optimized performance. Natural Color Matrix optimization delivers balanced color conversion without the loss of panel color properties to ensure color quality is extremely close to the original image.
AIS is fully dedicated to continuously monitor product line improvements and embraces the latest technologies in designing and manufacturing LCD displays that achieve realistic and true-to-life image reproduction. In line with these goals, AIS performs many base line tests to guarantee the best monitor performance, viewing and image quality achieved.
• Dark Black Level
• Perfect Pixel Tracking/Phase
• High Video Bandwidth Index
• Smooth Grey Scale with 256 Intensity
• Accurate Gamma
• RGB High Frequency Balance
• Wide Viewing Angle
• High Quality Scaling
• Few Motion Artifacts
• Screen Uniformity
• High Peak Brightness
• No White Saturation
• High Contrast
• No Bad Pixels
• No Ringing and Overshoot
• Weak Reflections
• Weak Streaking
• White-Point Color Temperature,
• Brightness and Contrast Controls
Visualizing Advanced Embedded Video & Vision Solutions
Embedded video and vision has emerged as one of the fast growing technologies for industrial and commercial applications. Its powerful functionality and advanced visual capabilities has completely changed the user interaction experience in a variety of applications in industrial, automotive, military and aerospace. AIS TFT LCD modules are designed for high reliability, optimal visibility, and enhanced view-ability. They add powerful imaging, video and vision processing capabilities to industrial embedded system applications. With expert integration experience and knowledge, AIS’s market-leading TFT LCD modules, applications processors and system-on-chip solutions offer the perfect combination of programmability, performance and power for both mobile devices and industrial systems. Moreover, AIS’s video and vision design capabilities help their customers realize success in the embedded vision market for areas such as automotive vision systems, industrial machine vision and more. Some key application opportunities include:
Video & Vision Applications Overview
- Machine Vision: Machine vision refers to applications where operational guidance is provided to equipment for the execution of functions based on the capture and processing of images. Providing the "sight" or "vision" to the equipment greatly enhances its capabilities, resulting in improved product quality, increased productivity and decreased costs.
- Driver Assistance Systems: With keen focus on improving safety, automotive vision control systems process digital information from sources digital cameras or other sensors to perform tasks such as lane departure warning, drowsiness sensors, or parking assistance. The processed information can be displayed on screens or announced via acoustical warning signals.
- Radar/Electronic Warfare: Integrated GPS guidance, image processing for target recognition, and real-time flight path guidance computations are all enabled by high performance processors. AIS integrated multicore processors meet the demanding requirements of mission critical functions in a variety of military and aerospace applications.
Taking Industrial Design Ideas into Sophisticated, High Performance Industrial Embedded Systems
Industrial embedded systems, ranging from operator interface terminals and mobile devices to process control equipment, become increasingly sophisticated and run on an ever diverse set of hardware and software platforms. This presents increasingly complex issues and requirements for manufacturers to continually create new applications and maintain existing ones.
Recognizing these challenges for their customers, AIS provides complete engineering solutions and services to help them create winning embedded industrial solutions. This comprises hardware and software services to create complete industrial systems, including integration of microcontrollers and processors, LCD displays, touch screen interfaces, video and audio subsystems, connectivity stacks and device layer integration and optimizations. Based on open architectures platforms such as Texas® Instruments (TI) ARM, Freescale™ Semiconductor, Inc. i.MX 6 and Intel® Atom microcontrollers and processors, AIS Embedded Systems designs offer the ultimate in flexibility and migration.
Many years of embedded hardware and software design has afforded us a unique understanding and insight optimizing solutions for our customers. Our software integration strengthens the performance of the hardware and reaps maximum processing power. Regardless of specification and/or system requirements, AIS has the total in-house resources, industry knowledge and expertise to design specific hardware and software that is cost-effective, reliable, efficient and superior in performance.
System Design Capabilities Overview:
- Complete in-house embedded system design capabilities for operator interfaces, mobile devices and control equipment
- Help customers address current requirements and stay ahead of new ones
- Delivering synergistic, integrated embedded hardware and software solutions
- Open architecture platform system design for the ultimate in flexibility
- Total in-house design resources and expertise for cost-effective and powerful solutions
Designing for Reliable Performance in Extreme Environments and Conditions
In some applications equipment failure is not an option. Designing and building visualization, control and monitoring equipment that can withstand and perform reliably in extreme environments and conditions is something AIS has amassed extensive experience in. AIS designs, tests, and qualifies products that are exposed to severe environmental and EMI conditions in military, automotive, and industrial applications. Testing is conducted using in-house resources or their network of independent testing labs. As standard operating procedure, AIS routinely tests its designs for compliance to severe military (UL Class/Division, MIL-STD-810, MIL-STD-461, and MIL-STD-1275), various SAE automotive and UL/CSA/CE/TUV/ATEX /DNV safety requirements or customer specifications.
- Military Standard MIL-STD-810: Tested to the MIL-STD-810 standard methodology for a range of extreme conditions including drops, shock, vibration, humidity, altitude, rain, dust and sand-resistance, temperature extremes and thermal shock
- Military Standard MIL-STD-461: Tested to the MIL-STD-461 standard methodology for EMI and EMC
- Maritime Environment Standard: Tested to the DNV standard methodology for a range of extreme conditions including temperature, humidity, vibration, EMC compatibility and enclosures
- ANSI/ISA-12.12.01-2013: Nonincendive electrical equipment for use in class I and II, division 2 and class III, divisions 1 and 2 hazardous (classified) locations
- ATEX 95 Equipment Directive 94/9/EC: Equipment and protective systems intended for use in potentially explosive atmospheres
- IEC 60079: Standard and general requirements for explosive atmospheres equipment
- EN 50155: Railway applications - EN standard for electronic equipment used on rolling stock
- EN 60721-3-2 : Railway applications - EN standard for classification of environmental conditions
- EN 1672-2 Hygiene: This standard specifies common hygiene requirements processing machines for machinery used in preparing and processing food for humans, and where relevant, animal consumption to eliminate or minimize the risk of contagion, infection, illness or injury arising from this food
- Highly Accelerated Life Test (HALT): AIS engineers using HALT stress testing methodology to accelerate product reliability testing during the engineering development process; cold step/hot step/rapid temperature cycling/stepped vibration (random)/combined environment stress (temperature cycling and random vibration plus power switching and power margining)
Systems comprised of electrical and/or electronic elements had been used for many years to perform safety functions in most application sectors. Functional safety is an integral part of the overall safety of AIS embedded system and HMI display, including the safe management of likely hardware failures and environmental changes. AIS computer-based systems and displays are being used in all application sectors to perform safety functions.
AIS functional safety design engineering is fundamental to enabling complex technology used for safety-related systems. It provides the assurance that safety-related systems will offer the necessary risk reduction required to achieve safety for the equipment.
Machinery Safety Legislation
- European Machinery Directive 2006/42/EC
- ISO EN 14121: Safety of machinery -- Principles of risk assessment
- ISO EN 12100: Safety of machinery - Basic concepts, general principles for design
- EN 60204: Safety of machinery - Electrical equipment of machines -- General requirements
- EN 13850: Safety of machinery - Emergency stop -- Principles for design
AIS Functional Safety Standards
- ISO EN DIN 13849: Safety of machinery -- Safety-related parts of control systems
- IEC EN 61508: Functional safety of Electrical/Electronic/Programmable Electronic Safety -- Related Systems (E/E/PE, or E/E/PES)
- IEC EN 62061: Functional safety of electrical, electronic and programmable electronic control systems
- IEC EN 61511: Functional safety -- Safety instrumented systems for the process industry sector
- ISO 26262: Road vehicles -- Functional safety
- EN 50126/IEC 62278: Railway applications -- The specification and demonstration of reliability, availability, maintainability and safety (RAMS) -- Basic requirements and generic process
- EN 50128: Railway applications - Communication, signalling and processing systems -- Software for railway control and protection systems
- EN 50129: Railway applications -- Communication, signalling and processing systems -- Safety related electronic systems for signalling
- ISO 25119: Tractors and machinery for agriculture and forestry -- Safety-related parts of control systems
- ISO 15998: Earth-moving machinery -- Machine-control systems (MCS) using electronic components -- Performance criteria and tests for functional safety
Integrated Quality Measures & Analysis for the Lowest Possible Final Costs & Waste
Quality leadership is something AIS strives for on a daily basis. AIS implements the latest quality control practices and techniques to meet the demands of international regulations and standards. Stringent and comprehensive quality control measures every step of the way assures total customer satisfaction from beginning to end. From quality policies and planning, to product lifecycle management and document control, AIS quality initiatives will result in a product that meets or exceeds even the most demanding standards, specifications and customer expectations. AIS quality programs include a complete list and menu of services and capabilities.
- Quality Policy, System And Manual: AIS operates quality management systems which comply with specific requirements of ISO 9001:2008 for manufacture and distribution of industrial grade displays and panel PCs
- Advanced Product Quality Planning (APQP): The AIS APQP quality system is a structured method of defining and establishing the necessary steps to ensure that a product satisfies the customer. This system provides complete tracking of all the information required for process documentation, and features direct links to FMEAs, control plans, inventory items, and customer information.
- Failure Mode and Effects Analysis (FMEA): AIS reliability, safety and quality engineers implement FMEA as a design tool used to systematically analyze postulated component failures and identify the resultant effects on system operations including functional design, and processing FMEA.
- Statistical Process Control (SPC): AIS SPC quality system enables real-time tracking of product and process quality to facilitate continuous improvement efforts.
- Gage Repeatability and Reproducibility (R&R): The gage R&R feature in AIS quality system provides the user with the necessary tools to conduct measurement system analysis to assess the accuracy of gages and operators in measuring parameters.
- Product Verification and Validation (PV&V): The AIS PV&V quality system ensures that a product, service, or system meets the needs of the customer. The PV&V system evaluates whether or not a product, service, or system complies with a regulation, requirement, specification, or an imposed condition.
- Corrective Action Request (CAR/CAPA): The CAR quality system enables AIS to document, manage, schedule, assign, and track their corrective action activities and provide instant communication to dependent departments such as customer service.
- Engineering Change Order (ECO): The AIS ECO quality system provides a centralized location to control item revisions, bill of material changes, and more. E-mail notifications are sent through a web-based approval process to the individuals responsible for each step, requiring review and/or approval, and facilitating the exchange of ideas.
- Product Lifecycle Management (PLM): The AIS PLM quality system provides a complete audit trail of a product's lifecycle from the design and quoting process through manufacture and maintenance, to the end of life of the product.
- Document Control: The AIS document control quality system manages workflow and external documents, providing complete control and visibility over the entire life cycle of documents.
- Cost of Quality: The AIS cost of quality system helps drive tighter cost control by allowing the quality management team to identify and eliminate poor quality and high production costs in areas such as rejects, unscheduled machine downtime, and returns or reworking.
Efficiently Managing the Flow of Goods & Materials for Timely Delivery of Solutions
Supply chain management is the systematic, strategic coordination of functions and tactics for the purpose of improving long-term performance of the individual companies and the supply chain as a whole. AIS supply chain activities cover everything from product development, sourcing, production, and logistics, as well as the information systems needed to coordinate these activities.
Managing the flow of raw materials in its supply chain network with expert precision, AIS is committed to meeting the on-going delivery needs and sustainability requirements of their customers. Moreover, their ability to move products and information to, from and between members of its supply chain is critical to achieving total customer satisfaction. The AIS supply chain provides framework for the businesses and their support to jointly deliver goods, services, and information efficiently, effectively and relevantly to customers. AIS provides the business processes and strategic solutions to its clients to achieve integrated, superior logistical management.
From Beginning to End, Total Product Lifecycle Management with an Improved Bottom Line
Product lifecycle management presents complex engineering challenges and considerations for companies when developing new products. AIS’s considerable PLM experience and capabilities allows them to easily comprehend the issues and see through all the pitfalls of product development. Managing the entire lifecycle of products from inception, through engineering design and manufacture, to service and disposal of manufactured products, AIS demonstrates their value-add as a true partner and resource for their customers. In reliability engineering, AIS has the knowledge, tools and equipment to help customers along the widely known product “bathtub” curve of life from a products’ infancy, through useful life and onto final wear out. This valuable reliability engineering expertise and practice greatly enhances product reliability, significant cost savings and bottom line results.
- New Product Design
- Reliability Prediction Analysis
- Functional Test Development
- Environmental Stress Testing
- Compliance and Sample Testing for Reliability
- Field Failure Analysis
- On-going Cost Reduction
- EOL Management