Industrial Ethernet is the growing networking solution in industries by changing the common Fieldbus architecture to industrial Ethernet. Applying this, provides possibility of an Ethernet environment for the different industries and organizations based on their demand. Industrial Ethernet uses the usual Ethernet standards, this is shown in Figure below. The advantage of applying this standard is that the industrial section and the existing devices can continue using their traditional tools and applications in more efficient networking way. Also it provides more fast communication, better connectivity and transparency and there is no need for separate gateways in order to connect the devices.
As an example Common Industrial Protocol (CIP) has implementations based upon Ethernet and the IP protocol suite (EtherNet/IP), DeviceNet, and ControlNet (among others). Most of the controllers can transfer data from one network type to another, leveraging existing installations, by utilizing the advantage of Ethernet. The fieldbus data structure is applied to Layers 5, 6, and 7 of the OSI refe...
When controlling communications of multiple devices are outlined on defined procedures. Arbitration structures are essential in the control of the bus communications in the presence of multiple devices.
... access to what and in which sequence. The router connects the LAN to other networks, which could be the Internet or another corporate network so that the LAN can exchange information with networks external to it. The most common LAN operating systems are Windows, Linux, and Novell. Each of these network operating systems supports TCP/IP as their default networking protocol. Ethernet is the dominant LAN standard at the physical network level, specifying the physical medium to carry signals between computers, access control rules, and a standardized set of bits used to carry data over the system. Originally, Ethernet supported a data transfer rate of 10 megabits per second (Mbps). Newer versions, such as Fast Ethernet and Gigabit Ethernet, support data transfer rates of 100 Mbps and 1 gigabits per second (Gbps), respectively, and are used in network backbones.
The project that will be examined is an upgrade to our main Human-Machine Interface (HMI) software: Cimplicity, to SQL Server and to the Windows OS. Cimplicity is a product of the GEFanuc group of General Electric. This group develops a full suite of applications used in the manufacturing environment. By way of introduction, the manufacturing floor environment uses a variety of types of equipment. To control these machines, a specialized computer is used. For the purposes of simplicity (not the program), this paper will refer to them all as PLC's or Programmable Logic Controllers. Most of these PLC's are accessible via the ethernet and communicate to our Protocol Data Units (PDU) in the computer room. These PDU's have Cimplicity installed on them in the form of projects that are named for the various areas or functions of our plant such as GA or General Assembly. The project we are undertaking will be a fundamental change to these PDU's in our computer room. The servers currently run Windows NT and will be upgraded to Windows Server 2003 or Windows 2000 and SQL Server will will be upgraded from version 7 to SQL 2000.
first quarter of FY2012, prolonged, shortages in supplies due to capacity issues or other factors affecting the manufacturing process alter the price of these products. When there is a shortage in supplies the company may not be able to source required components in adequate quantities in a timely manner (Cisco Systems, Inc. SWOT Analysis, 2013).The company may be obligated to purchase components at higher than normal prices in the current market because of purchase commitments. When this happens its gross margin is affected. Supply chain issues also lead to delay in order fulfillment, affecting the revenues and margins of the company (Cisco Systems Inc. SWOT Analysis, 2013)
Sending data through the internet efficiently has always posed many problems. The two major technologies used, Ethernet and Asynchronous Transfer Mode (ATM), have done an admirable job of porting data, voice and video from one point to another. However, they both fall short in differing areas; neither has been able to present the "complete" package to become the single, dominant player in the internet market. They both have dominant areas they cover. Ethernet has dominated the LAN side, while ATM covers the WAN (backbone). This paper will compare the two technologies and determine which has a hand-up in the data trafficking world.
The Open Systems Interconnection (OSI) reference model is essential to the world of computer networking. The model was created in 1977 by the International Standards Committee, in response to a difficulty that was facing computer networkers at the time (Shelly, Cashman, and Serwatka 142). In order to understand the difficulty, one must first realize that computer networks consist of computer hardware, the software that is to be used in conjunction with this hardware, and the medium (such as wiring or cabling) that will interconnect the computing devices that are in the network. The computer networker’s job is to determine which hardware, software, and medium types will create the network that will best suit his client’s needs. Then, the networker must combine these elements into a functional system of interconnected computers (Fortino and Villeneuve 112). It was in attempting this latter task that the computer networker of the late 1970s often found himself in a pickle. The problem was that each vendor of computing equipment had developed his own unique set of products; products that were incompatible with the products of other vendors. This incompatibility made it very difficult for a computer networker to combine the various network components into an operational computer network (Stamper 27).
The Jaagz’ local area network will use category 5 cable and run IEEE 802.3 protocol. Using IEEE 802.3, the network speed will average about 10 Mbps. It will utilize a combination of a star and bus topology, which is the most common topology used in networks. The bus topology makes up the backbone of the network while the star topology branches out.
When it comes to getting network traffic from point A to point B, no single way suits every application. Voice and video applications require minimum delay variation, while mission-critical applications require hard guarantees-of-service and rerouting.
The purpose of this paper is to present a proposal to implement Internet Protocol version four (IPv4) also known as Transmission Control Protocol/Internet Protocol (TCP/IP) structure as our primary means of communication within our network infrastructure. We are currently using a legacy mainframe system that limits are current means of network connectivity with other evolving network systems and it is in our best interest that we look into the future as well as keep up with changing times as Information Technicians. I will present a detailed analysis of the TCP/IP brief history, understanding of IPv4 addresses, subnetting, configuration, and the benefits of using the TCP/IP structure. This will greatly increase the overall success rate of our business
It just doesn't get much simpler than the physical bus topology when it comes to connecting nodes on a Local Area Network (LAN). The most common implementation of a linear bus topology is IEEE 802.3 Ethernet. All devices in a bus topology are connected to a single cable called the bus, backbone, or ether. The transmission medium has a physical beginning and an end. All connections must be terminated with a resistor to keep data transmissions from being mistaken as network traffic. The terminating resistor must match the impedance of the cable.
Within the last five years, businesses have begun to need to share data across wide areas. This has prompted efforts to convert principally LAN-based protocols into WAN-friendly protocols. The result has spawned an entire industry of consultants who know how to manipulate routers; gateways and networks to force principally broadcast protocols across point-to-point links. Frequently the protocol of choice has been TCP/IP which is also the primary protocol run on the Internet. The emerging ubiquitous ness of TCP/IP allows companies to interconnect with each other via private networks as well as through public networks.
Local Area Networks also called LANs have been a major player in industrialization of computers. In the past 20 or so years the worlds industry has be invaded with new computer technology. It has made such an impact on the way we do business that it has become essential with an ever-growing need for improvement. LANs give an employer the ability to share information between computers with a simple relatively inexpensive system of network cards and software. It also lets the user or users share hardware such as Printers and scanners. The speed of access between the computers is lighting fast because the data has a short distance to cover. In most cases a LAN only occupies one or a group of buildings located next to each other. For larger area need there are several other types of networks such as the Internet.
Industrial Engineers serve as a bridge between management and operations. They combine their solid engineering background with good business sense and management ability. They figure out the best use of facilities, equipment and people for the most cost efficient and productive way to make or process a product. Industrial Engineers concentrate on improving manufacturing productivity and reducing costs associated with inventory. They are also concerned with worker safety and work environment.
There are several advantages to the layered approach provided by the OSI model. With the design separated into smaller logical pieces, network design problems can be easier to solve through divide and conquer techniques. Vendors who follow the model will produce equipment that is much more likely to be compatible with equipment from other vendors. The OSI model also provides for more extensible network designs. New protocols and other network services are more easier added to a layered architect.