Ethernet is the traditional technology for connecting devices in a wired local area network (LAN) or wide area network (WAN), enabling them to communicate with each other via a protocol -- a set of rules or common network language. Ethernet describes how network devices can format and transmit data so other devices on the same local or campus area network segment can recognize, receive and process the information. An Ethernet cable is the physical, encased wiring over which the data travels.
Connected devices accessing a geographically localized network with a cable -- that is, with a wired rather than wireless connection -- likely use Ethernet. From businesses to gamers, diverse end users depend on the benefits of Ethernet connectivity, which include reliability and security.
Compared to wireless LAN (WLAN) technology, Ethernet is typically less vulnerable to disruptions. It can also offer a greater degree of network security and control than wireless technology since devices must connect using physical cabling. This makes it difficult for outsiders to access network data or hijack bandwidth for unsanctioned devices.
Ethernet is used to connect devices in a network and is still a popular form of network connection. For local networks used by specific organizations -- such as company offices, school campuses and hospitals -- Ethernet is used for its high speed, security and reliability.
Ethernet initially grew popular due to its inexpensive price tag when compared to the competing technology of the time, such as IBM's Token Ring. As network technology advanced, Ethernet's ability to evolve and deliver higher levels of performance, while also maintaining backward compatibility, ensured its sustained popularity. Ethernet's original 10 megabits per second throughput increased tenfold to 100 Mbps in the mid-1990s, and the Institute of Electrical and Electronics Engineers Inc. (IEEE) continues to deliver increased performance with successive updates. Current versions of Ethernet can support operations up to 400 gigabits per second (Gbps).
Ethernet has many benefits for users, which is why it grew so popular. However, there are a few disadvantages as well.
Wi-Fi is the most popular type of network connection. Unlike wired connection types, such as Ethernet, it does not require a physical cable to be connected; data is transmitted through wireless signals.
Differences between Ethernet and Wi-Fi connections
IEEE specifies in the family of standards called IEEE 802.3 that the Ethernet protocol touches both Layer 1 (physical layer) and Layer 2 (data link layer) on the Open Systems Interconnection (OSI) network protocol model.
Ethernet defines two units of transmission: packet and frame. The frame includes not just the payload of data being transmitted, but also the following:
Each frame is wrapped in a packet that contains several bytes of information to establish the connection and mark where the frame starts.
Engineers at Xerox first developed Ethernet in the 1970s; Ethernet initially ran over coaxial cables. Today, a typical Ethernet LAN uses special grades of twisted-pair cables or fiber optic cabling. Early Ethernet connected multiple devices into network segments through hubs -- Layer 1 devices responsible for transporting network data -- using either a daisy chain or star topology.
However, if two devices that share a hub try to transmit data at the same time, the packets can collide and create connectivity problems. To alleviate these digital traffic jams, IEEE developed the Carrier Sense Multiple Access with Collision Detection (CSMA/CD) protocol, which enables devices to check whether a given line is in use before initiating new transmissions.
Later, Ethernet hubs largely gave way to network switches. Because a hub cannot discriminate between points on a network segment, it can't send data directly from point A to point B. Instead, whenever a network device sends a transmission via an input port, the hub copies the data and distributes it to all the available output ports.
In contrast, a switch intelligently sends any given port only the traffic intended for its devices rather than copies of any and all the transmissions on the network segment, thus improving security and efficiency.
Like with other network types, involved computers must include a network interface card (NIC) to connect to Ethernet.
The IEEE 802.3 working group approved the first Ethernet standard in 1983. Since then, the technology has continued to evolve and embrace new media, higher transmission speeds and changes in frame content:
Gigabit Ethernet boasts speeds of 1,000 Mbps -- 1 gigabit or 1 billion bits per second (bps) -- 10 GbE, up to 10 Gbps, and so on. Network engineers use 100BASE-T largely to connect end-user computers, printers and other devices; to manage servers and storage; and to achieve higher speeds for network backbone segments. Over time, the typical speed of each connection tends to increase.
Ethernet cables connect network devices to the appropriate routers or modems, with different cables working with different standards and speeds. For example, the Category 5 (Cat5) cable supports traditional and 100BASE-T Ethernet, the Category 5e (Cat5e) cable can handle GbE and Category 6 (Cat6) works with 10 GbE.
Ethernet crossover cables, which connect two devices of the same type, also exist, enabling two computers to be connected without a switch or router between them.
09 Mar 2020