A Digital Subscriber Line Access Multiplexer (DSLAM) allows telephone lines to make faster connections to the Internet. It is a network device, usually located at a telephone company central office (CO), that connects multiple customer Digital Subscriber Line (DSL)s to a high-speed Internet backbone line using multiplexing techniques. The DSLAM creates a network similar to a LAN but not subject to Ethernet distance limits, thus providing an Internet connection for the subscribers.Path taken by data to DSLAM located in the CO
Residential/commercial source: DSL modem plugged into the customer's computer.
Local loop: the telephone company wires from a customer to the telephone company's central office, often called the "last mile".
Main Distribution Frame (MDF): a wiring rack that connects outside subscriber lines with internal lines. It is used to connect public or private lines coming into the building to internal networks. In a telco CO, the MDF is generally in proximity to the cable vault and not far from the telephone switch.
DSLAM: a CO device for DSL service. Sending on the customer or downstream side, it intermixes voice traffic and VDSL traffic onto the customer's DSL line. Receiving on that side, it accepts and separates outgoing phone and data signals from the customer. It directs the data signals upstream towards the appropriate carrier's network, and the phone signals towards the voice switch.
From the DSLAM the telephone wires, now cleansed of DSL signals, go through the MDF again to the voice switch so the customer will have dial tone phone service. Old-fashioned voice signals pass between voice switch and subscriber line through DSLAM, which does not disturb them but adds a higher frequency signal to carry data for Internet service.
Role of the DSLAM
The DSLAM at the CO collects the digital signals from its many modem ports and combines them into one signal, via multiplexing.
Depending on the product, DSLAM's connect DSL lines with some combination of Asynchronous Transfer Mode (ATM), frame relay or Internet Protocol networks.
In terms of the OSI 7 Layer Model, the DSLAM acts like a massive network switch, since its functionality is purely Layer 2.
The aggregated signal then loads onto backbone switching equipment, traveling through an access network (AN) — also known as a Network Service Provider (NSP) — at speeds of up to 10 Gbit/s and connecting to the Internet-backbone.
The DSLAM, functioning as a switch, collects the ADSL modem data (connected to it via twisted pair copper wire) and multiplexes this data via the gigabit link that physically plugs into the DSLAM itself, into the Telco's backbone.
DSLAM is not always located in the telco central office, but may also serve customers within a neighborhood Serving Area Interface (SAI), sometimes in association with a digital loop carrier. DSLAMs are also used by hotels, lodges, golfing estates, residential neighbourhoods and other corporations setting up their own private telephone exchange.
Besides being a data switch and multiplexer, DSLAM is also a large number of modems, each modem on the aggregation card communicating with a subscriber's DSL modem. This modem function being inside the DSLAM rather than separate hardware, and being wideband rather than voiceband, it isn't often called a modem. Like voiceband modems of standard v.32 and later, it has the ability to probe the line and train itself to compensate for echoes and other impairments, in order to move data at the maximum rate the line allows. This is also why twisted pair DSL services have a longer range than twisted pair (UTP) Ethernet.
Speed vs Distance
Balanced pair cable has higher attenuation at higher frequencies, hence the longer the wire between DSLAM and subscriber, the slower the maximum possible data rate. The following is a rough guide to the relation between wire distance and maximum data rate. Local conditions may vary, especially beyond 2 km, often necessitating a closer DSLAM to bring acceptable speeds:
· 25 Mbit/s at 1000 feet ~300 m
· 24 Mbit/s at 2000 feet ~600 m
· 23 Mbit/s at 3000 feet ~900 m
· 22 Mbit/s at 4000 feet ~1.2 km
· 21 Mbit/s at 5000 feet ~1.5 km
· 19 Mbit/s at 6000 feet ~1.8 km
· 16 Mbit/s at 7000 feet ~2.1 km
~
· 1.5 Mbit/s at 15,000 feet 4.5 km
· 800 kbit/s at 17,000 feet ~5.2 km
Additional Features
A DSLAM may offer the ability to tag VLAN traffic as it passes from the subscribers to upstream routers. Though not a full stateful firewall, some DSLAMs also offer packet filtering facilities like dropping inter-port traffic and dropping certain protocols.
The DSLAM also supports quality of service (QoS) features like contention, differentiated services ("DiffServ") and priority queues.
Hardware details
Customers connect to the DSLAM through ADSL modems or DSL routers, which are connected to the PSTN network via typical unshielded twisted pair telephone lines. Each DSLAM has multiple aggregation cards, and each such card can have multiple ports to which the customers lines are connected. Typically a single DSLAM aggregation card has 24 ports, but this number can vary with each manufacturer. The most common DSLAMs are housed in a telco-grade chassis, which is supplied with (nominal) 48 Volts DC. Hence a typical DSLAM setup may contain power converters, DSLAM chassis, aggregation cards, cabling, and upstream links. The most common upstream links in these DSLAMs use gigabit ethernet or multi-gigabit fiber optic links.
IP-DSLAM
IP-DSLAM stands for Internet Protocol based Digital Subscriber Line Access Multiplexer. User Traffic is mostly IP based.
Traditional DSLAM used ATM(Asynchronous Transfer Mode) technology to connect to upstream ATM routers/Switches. These devices then extract the IP traffic and pass it on to an IP network. IP-DSLAMs extract the IP traffic at the DSLAM itself. Thus it is all IP from there. Advantage of IP-DSLAM over a traditional ATM DSLAM is in terms of lower CAPEX/OPEX and a richer set of features and functionality. This is so as IP has a rich set of existing and ever growing protocol set that one gets access to as soon as one moves to IP.
