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Network Interface Device
Wiring termination

Two simple NIDs, carrying six lines each, on the outside of a building

The simplest NIDs are essentially just a specialized set of wiring terminals. These will typically take the form of a small, weather-proof box, mounted on the outside of the building. The telephone line from the telephone company will enter the NID and be connected to one side. The customer connects their wiring to the other side. A single NID enclosure may contain termination for a single line or multiple lines.

In its role as the demarcation point, the NID separates the telephone company’s equipment from the customer’s wiring and equipment. The telephone company owns the NID itself, and all wiring up to it. Anything past the NID is the customer’s responsibility. To facilitate this, there is typically a test jack inside the NID. Accessing the test jack disconnects the customer premises wiring from the network and allows the customer to plug a “known good” telephone into the jack to isolate trouble. If the telephone works at the test jack, the problem is the customer’s wiring, and the customer is responsible for repair. If the telephone does not work, the line is faulty, and the telephone company is responsible for repair.

Most NIDs also include “circuit protectors”, which are surge protectors for a telephone line. They protect customer wiring, equipment, and personnel from any transient energy on the line, such as from a lightning strike to a telephone pole.

Simple NIDs contain no “intelligence” or “logic”; they are “dumb” devices. They have no capabilities beyond wiring termination, circuit protection, and providing a place to connect test equipment.

Smartjack

Three smartjacks for T-1 circuits, in two shelves; a 66 block is on the left

Several types of NIDs provide more than just a terminal for the connection of wiring. Such NIDs are colloquially called “smartjacks” as an indication of their built-in “intelligence”, as opposed to a simple NID, which is just a wiring device. Smartjacks are typically used for more complicated types of telecommunications service, such as T1 lines. Plain old telephone service lines generally cannot be equipped with smartjacks.

Despite the name, most smartjacks are much more than a simple telephone jack. One common form for a smartjack is a circuit board with a face plate on one edge, mounted in an enclosure.

A smartjack may provide signal conversion, converting codes and protocols (e.g. framing types) to the type needed by the customer equipment. It may buffer and/or regenerate the signal, to compensate for signal degradation from line transmission, similar to what a repeater does.

Smartjacks also typically provide diagnostic capabilities. A very common capability provided by a smartjack is loopback, such that the signal from the telephone company is transmitted back to the telephone company. This allows the telephone company to test the line from the central office, without the need to have test equipment at the customer site. The telephone company usually has the ability to remotely activate loopback, without even needing personnel at the customer site. When looped back, the customer equipment is disconnected from the line.

Additional smartjack diagnostic capabilities include alarm indication signal, which reports trouble at one end of the line to the far end. This helps the telephone company know if trouble is present in the line, the smartjack, or customer equipment. Indicator lights to show configuration, status, and alarms are also common.

Smartjacks typically derive their operating power from the telephone line, rather than relying on premises electrical power, although this is not a universal rule.

Optical network terminals

An ONT mounted to the outside of a building, with the cover open

In fiber-to-the-premises systems, the signal is transmitted to the customer premises using fiber optic technologies. Unlike many conventional telephone technologies, this does not provide power for premises equipment, nor is it suitable for direct connection to customer equipment. An ONT (optical network terminal) is used to terminate the fiber optic line, demultiplex the signal into its component parts (voice telephone, television, and Internet), and provide power to customer telephones. As the ONT must derive its power from the customer premises electrical supply, many ONTs have the option for a battery backup, to maintain service in the event of a power outage.

Sources

“Network Interface Device”. Verizon Communications, Inc.. http://www22.verizon.com/wholesale/solutions/solution/NIDs.html. Retrieved 2009-06-03. 

“Network Interface Device (NID) V9.0″. Qwest Communications International. http://www.qwest.com/wholesale/pcat/nid.html. Retrieved 2009-06-03. 

“Functional Criteria for the DS1 Interface Connector” (PDF). BellSouth. June 1993. http://wholesale.att.com/reference_library/guides/tech_ref/TR-73569.pdf. Retrieved 2009-06-03. 

“network interface device”. Federal Standard 1037C. U.S. Department of Commerce and National Telecommunications and Information Administration. http://www.its.bldrdoc.gov/fs-1037/dir-024/_3522.htm. Retrieved 2009-06-03. 

“Testing, Repairing and Installing Home telephone Wiring – Network Interface Device”. Public Service Commission of Wisconsin. http://psc.wi.gov/utilityinfo/tele/teleConsumer/nid.htm. Retrieved 2009-06-03. 

“About your Optical Network Terminal (ONT)”. Verizon Communications, Inc.. http://www22.verizon.com/ResidentialHelp/FiOSInternet/General+Support/Getting+Started/QuestionsOne/121496.htm. Retrieved 2009-06-03. 

“Checking the service at the Optical Network Terminal (ONT)”. Verizon Communications, Inc.. https://www22.verizon.com/foryourhome/fttprepair/nr/common/SupportDetail.aspx?case=c29260. Retrieved 2009-06-03. 

See also

Demarcation point

Point of appearance

Customer premises wiring

Customer premises equipment

Local exchange carrier

CSU/DSU

Channel service unit

Data service unit

Main distribution frame

External links

“Network Interface Devices”. HomeTech Solutions. http://www.hometech.com/techwire/demarc.html. Retrieved 2009-06-03.  Photographs of several simple NIDs, including “inside” and “outside” views

Categories: Telecommunications terms | Local loop

Network interface controller

Network Interface Card (NIC)

A 1990s Ethernet network interface controller card which connects to the motherboard via the now-obsolete ISA bus. This combination card features both a (now obsolete) bayonet cap BNC connector (left) for use in coaxial-based 10base2 networks and an RJ-45 connector (right) for use in twisted pair-based 10baseT networks. (The ports could not be used simultaneously.)

Connects to

Motherboard via one of:

Integrated

PCI Connector

ISA Connector

PCI-E

FireWire

USB

Network via one of:

Fast Ethernet

Gigabit Ethernet

Optical fiber

Token ring

Speeds

10 Mbit/s

100 Mbit/s

1000 Mbit/s

up to 160 Gbit/s

Common manufacturers

Novell

Intel

Realtek

Others

A network interface card, network adapter, network interface controller (NIC), or LAN adapter is a computer hardware component designed to allow computers to communicate over a computer network.

It is both an OSI layer 1 (physical layer) and layer 2 (data link layer) device, as it provides physical access to a networking medium and provides a low-level addressing system through the use of MAC addresses. It allows users to connect to each other either by using cables or wirelessly.

Although other network technologies exist (e.g. Token Ring), Ethernet has achieved near-ubiquity since the mid-1990s. Every Ethernet network card has a unique 48-bit serial number called a MAC address, which is stored in ROM carried on the card.

Every computer on an Ethernet network must have a card with a unique MAC address. Normally it is safe to assume that no two network cards will share the same address, because card vendors purchase blocks of addresses from the Institute of Electrical and Electronics Engineers (IEEE) and assign a unique address to each card at the time of manufacture.

Madge 4/16Mbps TokenRing ISA NIC.

Ethernet 10Base-5/2 ISA NIC.

Whereas network cards used to be expansion cards that plug into a computer bus, the low cost and ubiquity of the Ethernet standard means that most newer computers have a network interface built into the motherboard. These either have Ethernet capabilities integrated into the motherboard chipset or implemented via a low cost dedicated Ethernet chip, connected through the PCI (or the newer PCI express) bus. A separate network card is not required unless multiple interfaces are needed or some other type of network is used. Newer motherboards may even have dual network (Ethernet) interfaces built-in.

The card implements the electronic circuitry required to communicate using a specific physical layer and data link layer standard such as Ethernet or token ring. This provides a base for a full network protocol stack, allowing communication among small groups of computers on the same LAN and large-scale network communications through routable protocols, such as IP.

There are four techniques used to transfer data, the NIC may use one or more of these techniques.

Polling is where the microprocessor examines the status of the peripheral under program control.

Programmed I/O is where the microprocessor alerts the designated peripheral by applying its address to the system’s address bus.

Interrupt-driven I/O is where the peripheral alerts the microprocessor that it’s ready to transfer data.

DMA is where an intelligent peripheral assumes control of the system bus to access memory directly. This removes load from the CPU but requires a separate processor on the card.

A network card typically has a RJ45, BNC, or AUI socket where the network cable is connected, and a few LEDs to inform the user of whether the network is active, and whether or not there is data being transmitted on it. Network cards are typically available in 10/100/1000 Mbit/s varieties. This means they can support a notional maximum transfer rate of 10, 100 or 1000 Megabits per second.

A network interface controller (NIC) is a hardware device that handles an interface to a computer network and allows a network-capable device to access that network. The NIC has a ROM chip that contains a unique number, the media access control (MAC) Address burned into it. The MAC address identifies the device uniquely on the LAN. The NIC exists on both the ‘Physical Layer’ (Layer 1) and the ‘Data Link Layer’ (Layer 2) of the OSI model.

Sometimes the words ‘controller’ and ‘card’ are used interchangeably when talking about networking because the most common NIC is the network interface card. Although ‘card’ is more commonly used, it is less encompassing. The ‘controller’ may take the form of a network card that is installed inside a computer, or it may refer to an embedded component as part of a computer motherboard, a router, expansion card, printer interface or a USB device.

A MAC address is a 48-bit network hardware identifier that is burned into a ROM chip on the NIC to identify that device on the network. The first 24-bit field is called the Organizationally Unique Identifier (OUI) and is largely manufacturer-specific. Each OUI allows for 16,777,216 Unique NIC Addresses. Smaller manufacturers that do not have a need for over 4096 unique NIC addresses may opt to purchase an Individual Address Block (IAB) instead. An IAB consists of the 24-bit OUI plus a 12-bit extension (taken from the ‘potential’ NIC portion of the MAC address.)

See also

MAC address

TCP Offload Engine (TOE)

Host bus adapter (HBA)

Wireless network interface card (WNIC)

Ethernet

Gigabit Ethernet

Router

IPMP

Adaptor

References

CCNA Exam Prep: Data Link Networking Concepts

IEEE Registration Authority – IEEE OUI and Company_id Assignments

Ieee Registration Authority – FAQ

Categories: Networking hardware