AUTOMATION

Embedded systems span all aspects of modern life and there are many examples of their use.

Telecommunications systems employ numerous embedded systems from telephone switches for the network to mobile phones at the end-user. Computer networking uses dedicated routers and network bridges to route data.

Consumer electronics include personal digital assistants (PDAs), mp3 players, mobile phones, videogame consoles, digital cameras, DVD players, GPS receivers, and printers. Many household appliances, such as microwave ovens, washing machines and dishwashers, are including embedded systems to provide flexibility, efficiency and features. Advanced HVAC systems use networked thermostats to more accurately and efficiently control temperature that can change by time of day and season. Home automation uses wired- and wireless-networking that can be used to control lights, climate, security, audio/visual, surveillance, etc., all of which use embedded devices for sensing and controlling.

Transportation systems from flight to automobiles increasingly use embedded systems. New airplanes contain advanced avionics such as inertial guidance systems and GPS receivers that also have considerable safety requirements. Various electric motors — brushless DC motors, induction motors and DC motors — are using electric/electronic motor controllers. Automobiles, electric vehicles, and hybrid vehicles are increasingly using embedded systems to maximize efficiency and reduce pollution. Other automotive safety systems such as anti-lock braking system (ABS), Electronic Stability Control (ESC/ESP), traction control (TCS) and automatic four-wheel drive.

Medical equipment is continuing to advance with more embedded systems for vital signs monitoring, electronic stethoscopes for amplifying sounds, and various medical imaging (PET, SPECT, CT, MRI) for non-invasive internal inspections.

In addition to commonly described embedded systems based on small computers, a new class of miniature wireless devices called motes are quickly gaining popularity as the field of wireless sensor networking rises. Wireless sensor networking, WSN, makes use of miniaturization made possible by advanced IC design to couple full wireless subsystems to sophisticated sensor, enabling people and companies to measure a myriad of things in the physical world and act on this information through IT monitoring and control systems. These motes are completely self contained, and will typically run off a battery source for many years before the batteries need to be changed or charged.

An embedded system is a computer system designed to perform one or a few dedicated functions,[1] often with real-time computing constraints. It is embedded as part of a complete device often including hardware and mechanical parts. In contrast, a general-purpose computer, such as a personal computer, is designed to be flexible and to meet a wide range of an end-user's needs. Embedded systems control many of the common devices in use today.

Since the embedded system is dedicated to specific tasks, design engineers can optimize it, reducing the size and cost of the product, or increasing the reliability and performance. Some embedded systems are mass-produced, benefiting from economies of scale.

Physically, embedded systems range from portable devices such as digital watches and MP3 players, to large stationary installations like traffic lights, factory controllers, or the systems controlling nuclear power plants. Complexity varies from low, with a single microcontroller chip, to very high with multiple units, peripherals and networks mounted inside a large chassis or enclosure.

In general, "embedded system" is not an exactly defined term, as many systems have some element of programmability. For example, Handheld computers share some elements with embedded systems — such as the operating systems and microprocessors which power them — but are not truly embedded systems, because they allow different applications to be loaded and peripherals to be connected.

In computer science and human-computer interaction, the user interface (of a computer program) refers to the graphical, textual and auditory information the program presents to the user, and the control sequences (such as keystrokes with the computer keyboard, movements of the computer mouse, and selections with the touchscreen) the user employs to control the program.

Types

Currently (as of 2009[update]) the following types of user interface are the most common:

* Graphical user interfaces (GUI) accept input via devices such as computer keyboard and mouse and provide articulated graphical output on the computer monitor. There are at least two different principles widely used in GUI design: Object-oriented user interfaces (OOUIs) and application oriented interfaces[verification needed].
* Web-based user interfaces or web user interfaces (WUI) accept input and provide output by generating web pages which are transmitted via the Internet and viewed by the user using a web browser program. Newer implementations utilize Java, AJAX, Adobe Flex, Microsoft .NET, or similar technologies to provide real-time control in a separate program, eliminating the need to refresh a traditional HTML based web browser. Administrative web interfaces for web-servers, servers and networked computers are often called Control panels.

User interfaces that are common in various fields outside desktop computing:

* Command line interfaces, where the user provides the input by typing a command string with the computer keyboard and the system provides output by printing text on the computer monitor. Used by programmers and system administrators, in engineering and scientific environments, and by technically advanced personal computer users.
* Tactile interfaces supplement or replace other forms of output with haptic feedback methods. Used in computerized simulators etc.
* Touch user interface are graphical user interfaces using a touchscreen display as a combined input and output device. Used in many types of point of sale, industrial processes and machines, self-service machines etc.

Other types of user interfaces:

* Attentive user interfaces manage the user attention deciding when to interrupt the user, the kind of warnings, and the level of detail of the messages presented to the user.
* Batch interfaces are non-interactive user interfaces, where the user specifies all the details of the batch job in advance to batch processing, and receives the output when all the processing is done. The computer does not prompt for further input after the processing has started.
* Conversational Interface Agents attempt to personify the computer interface in the form of an animated person, robot, or other character (such as Microsoft's Clippy the paperclip), and present interactions in a conversational form.
* Crossing-based interfaces are graphical user interfaces in which the primary task consists in crossing boundaries instead of pointing.
* Gesture interface are graphical user interfaces which accept input in a form of hand gestures, or mouse gestures sketched with a computer mouse or a stylus.
* Intelligent user interfaces are human-machine interfaces that aim to improve the efficiency, effectiveness, and naturalness of human-machine interaction by representing, reasoning, and acting on models of the user, domain, task, discourse, and media (e.g., graphics, natural language, gesture).
* Motion tracking interfaces monitor the user's body motions and translate them into commands, currently being developed by Apple[1]
* Multi-screen interfaces, employ multiple displays to provide a more flexible interaction. This is often employed in computer game interaction in both the commercial arcades and more recently the handheld markets.
* Noncommand user interfaces, which observe the user to infer his / her needs and intentions, without requiring that he / she formulate explicit commands.
* Object-oriented user interface (OOUI)
* Reflexive user interfaces where the users control and redefine the entire system via the user interface alone, for instance to change its command verbs. Typically this is only possible with very rich graphic user interfaces.
* Tangible user interfaces, which place a greater emphasis on touch and physical environment or its element.
* Text user interfaces are user interfaces which output text, but accept other form of input in addition to or in place of typed command strings.
* Voice user interfaces, which accept input and provide output by generating voice prompts. The user input is made by pressing keys or buttons, or responding verbally to the interface.
* Natural-Language interfaces - Used for search engines and on webpages. User types in a question and waits for a response.
* Zero-Input interfaces get inputs from a set of sensors instead of querying the user with input dialogs.
* Zooming user interfaces are graphical user interfaces in which information objects are represented at different levels of scale and detail, and where the user can change the scale of the viewed area in order to show more detail.

SCADA is an acronym that stands for Supervisory Control and Data Acquisition. SCADA refers to a system that collects data from various sensors at a factory, plant or in other remote locations and then sends this data to a central computer which then manages and controls the data

SCADA systems are used not only in industrial processes: e.g. steel making, power generation (conventional and nuclear) and distribution, chemistry, but also in some experimental facilities such as nuclear fusion. The size of such plants range from a few 1000 to several 10 thousands input/output (I/O) channels. However, SCADA systems evolve rapidly and are now penetrating the market of plants with a number of I/O channels of several 100 K: we know of two cases of near to 1 M I/O channels currently under development.

There are many parts of a working SCADA system. A SCADA system usually includes signal hardware (input and output), controllers, networks, user interface (HMI), communications equipment and software. All together, the term SCADA refers to the entire central system. The central system usually monitors data from various sensors that are either in close proximity or off site (sometimes miles away).

System Overview

The MicroLogix 1200/1762 system provides functionality between the MicroLogix 1000/1761 and MicroLogix 1500/1764 systems, using the proven MicroLogix and SLC family architecture. The 6K-word memory provides for a maximum program of 4K words and maximum data of 2K words with 100% data retention. An optional memory module provides program and data backup with program upload and download capability. The optional real-time clock enables time scheduling of control activities. The flash upgradeable operating system lets you upgrade system software without replacing hardware.

Benefits

• Small Footprint—The MicroLogix 1200 controller is designed to optimize panel space. Integrated packages just 90mm (3.54 in) high (110mm high including mounting tabs) and 110 or 160mm (4.33 or 6.30 in) wide include processor, embedded inputs and outputs, and power supply. Expansion I/O modules add only 40mm (1.57 in) each in width.
  
• Flexibility—A range of I/O and communication options let you configure a MicroLogix 1200 controller for a variety of applications:
  
  • 24 or 40 built-in I/O. The inputs are either 24V DC (sink or source) or 120V AC. Outputs are relay contact or FET.
    
  • Add up to 96 I/O in up to 6 digital and/or analog I/O modules (within the limits of power supply capacity, for a total of 136 I/O maximum).
    
• Wide range of communication options:
  
  • DF1 full- or half-duplex, DF1 Radio Modem, Modbus RTU slave and RTU master. Communication interface modules support DH-485, DeviceNet, and EtherNet/IP.
    
  • MicroLogix 1200R controllers also provide a Programming / HMI port with fixed communication parameters to provide an additional means to communicate to the controller.
    
• High Functionality—The MicroLogix 1200 / 1762 system provides powerful features that let you tackle tough applications:
  
  • 20k-Hz high-speed counter.
    
  • 20k-Hz PTO (Pulse Train Output) or PWM (Pulse Width Modulation).
    
  • 6K-word non-volatile memory (4K-word maximum program, 2K-word maximum data).
    
  • 4 interrupt inputs.
    
  • 4 latching inputs.
    
  • 2 built-in trim potentiometers.
    
  • optional memory, real-time clock, or memory/real-time clock module.
    
  • powerful instruction set with support for PID and ASCII.
    
  • uses RSLogix 500 programming software.
    
  • field-upgradeable flash operating system.
    
• Low Price—This compact but powerful control solution will fit well within your budget.

With online editing and a built-in 10/100 Mbps EtherNet/IP port for peer-to-peer messaging, the MicroLogix 1100 controller adds greater connectivity and application coverage to the MicroLogix family of Allen-Bradley controllers. This next generation controller's built-in LCD screen displays controller status, I/O status, and simple operator messages; enables bit and integer manipulation; offers digital trim pot functionality, and a means to make operating mode changes (Prog / Remote / Run).

With 10 digital inputs, 2 analog inputs and 6 digital outputs, the MicroLogix 1100 can handle a wide variety of tasks. The MicroLogix 1100 controllers also support expansion I/O. Up to four 1762 I/O modules (also used on the MicroLogix 1200 and 1400) may be added to the embedded I/O, providing application flexibility and support of up to 80 digital I/O.

Features

• Built-in 10/100 Mbps EtherNet/IP port for peer-to-peer messaging — offers users high speed connectivity between controllers, with the ability to access, monitor and program from anywhere an Ethernet connection is available
• Online editing functionality — modifications can be made to a program while it is running, making fine tuning of an operating control system possible, including PID loops. Not only does this reduce development time, but it aids in troubleshooting
• Embedded Web server — allows a user to custom configure data from the controller to be displayed as a web page
• Isolated RS-232/RS-485 combo port — provides a host of different point-to-point and network protocols
• Embedded LCD screen — allows user to monitor data within the controller, optionally modify that data, and interact with the control program. Displays status of embedded digital I/O and controller functions, and acts as a pair of digital trim pots to allow a user to tweak and tune a program

Communication Choices

Ethernet Connectivity for MicroLogix 1000 Controllers

The 1761-NET-ENI provides Ethernet connectivity for all SLC, MicroLogix, and CompactLogix controllers and other DF1 full-duplex devices. The ENI helps you easily connect these controllers onto new or existing Ethernet networks and upload/download programs, communicate between controllers, and generate email messages via SMTP (simple mail transport protocol).

As with other MicroLogix communication devices, the ENI can be powered via the RS-232 communications cable when attached to a MicroLogix controller, or externally with 24V dc when connected to other DF1 full duplex devices. It can be DIN-rail mounted, or panel mounted to meet your installation requirements.

NEW Series D Enhancements

The series D has been updated with a new Ethernet communications processor and several ease-of-use features. In addition to the features of previous versions, Series D provides:

• Added the capability for configuration via Ethernet, with a Configuration Security Mask provision.
• Ability to force Ethernet to 10 Mbps or 100 Mbps and half-duplex or full-duplex. (default is still Auto Negotiate).
• Added an optional Username and Password fields for Email authentication.
• Added a new Diagnostics web page that displays a list of current Ethernet connections.
• Updated the ENIW web pages to more closely conform to the style used on other RA web-enabled products (more like 1756-EWEB module pages).

Series B Enhancements

The 1761-NET-ENI, series B:

• Lets any device that can initiate a CIP data table read or write on an EtherNet/IP link through a 1761-NET-ENI/B (e.g., PanelView, ControlLogix, RSLinx) access a Logix processor data table. This eliminates the requirement of mapping PLC/SLC file numbers to Logix tag names.
• Provides more functional integration with CompactLogix processors by eliminating the need for an additional ENI in CompactLogix systems to communicate with RSLogix 5000 (1761-NET-ENI/A requires an additional ENI at the PC running the programming package for communication with RSLogix 5000).
• Incorporates several data handling improvements, such as additional buffering and increased message queues and provides more robust communications at increased throughput rates. In general, ENI series B users should expect upload/download times to be about 33% longer than transferring the same file over DF1.

ENI and ENIW series B and series C firmware can be upgraded in the field by downloading the Upgrade Utility.

The ENI series A firmware cannot be upgraded in the field. For information on upgrading your ENI series A unit to series B, please contact Rockwell Automation technical support.

Series C Enhancements

The 1761-NET-ENI, series C:

• Provides 10/100 Mbps EtherNet/IP capability, which results in significant upload/download performance improvements. Performance tests indicate that with a 100 Mbps EtherNet/IP connection and a 38.4 Kbaud serial connection, upload/download times are typically half as long as with Series B units.
• Due to RSLinx EtherNet /IP driver efficiency, Series C upload/download times are typically 15-30 percent faster than a direct 38.4 Kbaud serial connection.
• Provides improved performance access for Allen-Bradley SLC 500, MicroLogix, and CompactLogix controller platforms.
• Is included as an upgrade option in the Step Forward Program. This offer presents users of Series A or B units with a credit incentive when upgrading to a Series C product.

General Features

• Program upload/download - Upload or download user programs over Ethernet using the ENI. The only requirement is that you use RSLinx version 2.20 SP2 or newer.
• Peer-to-Peer communication - The ENI allows the attached controller to initiate or receive messages with other controllers. The controllers can be connected directly to Ethernet like the SLC 5/05, Ethernet PLC-5, or ControlLogix processors, or with other ENIs (MicroLogix, SLC 5/03, CompactLogix, etc.).
• Email communication - The ENI enables a controller to send an ASCII string to an Email address. Send production data, alarms, or other status information to any computer, cell phone, or pager capable of receiving an Email message. This feature requires a valid SMTP Email server (Simple Mail Transport Protocol). SMTP servers are readily available via Internet Service Providers (ISPs).
• EtherNet/IP compatibility - The ENI uses the open EtherNet/IP protocol. This industry standard open protocol provides inter device compatibility. The ENI can exchange information with other A-B Ethernet controllers (SLC, PLC, CompactLogix, FlexLogix and ControlLogix) in a peer-to-peer relationship, so you don't need any master type device.
• Easy to configure - The ENI can be configured via messages from the attached controller, or via the ENI utility, a free Windows-based configuration package.
• 10 base-T port with embedded LEDs - Use any standard RJ Ethernet cable to connect to your network. This minimizes connection problems and improves startup. Embedded LEDs provide easy to see link and transmit/receive status.
• Isolated mini-DIN RS-232 port - The RS-232 port provides isolation and will auto baud on power up to detect the communications port setting of the attached controller. Supported baud rates include 2400, 4800, 9600, 19.2k and 38.4k. This autobaud feature can also be disabled if desired.
• Small and compact - The ENI uses the same packaging as the AIC+ and DNI communication interfaces. This packaging is rugged and can be either panel or DIN rail mounted.