When you connect to the Internet, you might connect through a regular modem, through a local-area network connection in your office, or through a cable modem. A growing number of people, though, are reaching the Internet through a Digital Subscriber Line (DSL) connection -- a very high-speed connection using the same wires as a regular telephone line. We explain how a DSL connection manages to squeeze more information through a standard telephone line -- and lets you make regular telephone calls at the same time!
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Here are some advantages of DSL:
- You can leave your Internet connection open and still use the phone line for voice calls.
- The speed is much higher than a regular modem (1.5 Mps vs. 56 kps)
- DSL doesn't necessarily require new wiring; it can use the phone line you already have.
- LOCL .net offers a DSL modem as part of the installation
But there are disadvantages:
- A DSL connection works better when you are closer to the provider's central office.
- The connection is faster for receiving data than it is for sending data over the Internet.
- The service is not available everywhere.
The Skinny Voice and the Broad Band
A standard telephone installation in the U.S. consists of a pair of copper wires that the phone company installs in your home. The pair of copper wires have lots of room for carrying more than your phone conversations. The wires are capable of handling a much greater bandwidth, the range of frequencies, than that demanded for voice. DSL exploits this "extra capacity" to carry information on the wire without disturbing the line's ability to carry conversations. The entire plan is based on matching particular frequencies to specific tasks.
To understand DSL, you first need to know a couple of things about a normal telephone line -- the kind that telephone professionals call POTS, for Plain Old Telephone Service. One of the ways that POTS makes the most of the telephone company's wires and equipment is by limiting the frequencies that the switches, telephones and other equipment will carry. Human voices, speaking in normal conversational tones, can be carried in a frequency range of 0 to 3,400 hertz, or cycles per second. This range of frequencies is tiny. For example, compare this to the range of most stereo speakers, which cover from roughly 20 hertz to 20,000 hertz. And the wires themselves have the potential to handle frequencies up to several million hertz in most cases. The use of such a small portion of the wire's total bandwidth is historical -- remember that the telephone system has been in place, using a pair of copper wires to each home, for about a century. By limiting the frequencies carried over the lines, the telephone system can pack lots of wires into a very small space without worrying about interference from one line causing problems on another. Modern equipment that sends digital, rather than analog, data can safely use much more of the telephone line's capacity. DSL does just that.
Voice and Data
Most
home and small business users
are connected to an Asymmetrical
DSL (ADSL) line. ADSL divides
up the available frequencies in
a line on the assumption that
most Internet users look at, or
download, much more information
than they send, or upload. Under
this assumption, if the connection
speed from the Internet to the
user is 3-4 times faster than
the connection from the user back
to the Internet, then the user
will see the most benefit, most
of the time.
Precisely how much benefit you see will greatly depend on how far you are from the central office of the company providing the ADSL service. ADSL is a distance-sensitive technology: As the connection's length increases, the signal quality decreases, and the connection speed goes down. The limit for ADSL service is 18,000 feet (5,460 meters), though for speed and quality of service reasons many ADSL providers place a lower limit on the distances for the service. At the extremes of the distance limits, ADSL customers may see speeds far below the promised maximums, while customers nearer the central office have the potential for seeing very high speeds in the future. For example, ADSL technology can provide maximum downstream (Internet to customer) speeds of up to 8 megabits per second (Mbps) at a distance of about 6,000 feet (1,820 meters), and upstream speeds of up to 640 kilobits per second (kbps). In practice, the best speeds widely offered today are 1.5 Mbps downstream, with upstream speeds varying between 64-640 kbps.
You might wonder, if distance is a limitation for DSL, why it's not also a limitation for voice telephone calls. The answer lies in small amplifiers called loading coils that the telephone company uses to boost voice signals. Unfortunately, these loading coils are incompatible with ADSL signals, so a voice coil in the loop between your telephone and the telephone company's central office will disqualify you from receiving ADSL. Other factors that might disqualify you from receiving ADSL include:
- The presence of "bridge taps." These are extensions, between you and the central office, that extend service to other customers. While you wouldn't notice these bridge taps in normal phone service, they may take the total length of the circuit beyond the distance limits of the service provider.
- Fiber-optic cables. ADSL signals can't pass through the conversion from analog to digital and back to analog that occurs if a portion of your telephone circuit comes through fiber-optic cables.
- Distance. Even if you know where your central office is (don't be surprised if you don't -- the telephone companies don't advertise their locations), looking at a map is no indication of the distance a signal must travel between your house and the office.
Splitting the Signal
There are two competing and incompatible standards for ADSL.
The official ANSI standard for
ADSL is a system called Discrete MultiTone, or "DMT". According
to equipment manufacturers,
most of the ADSL equipment installed
today uses DMT. An earlier,
and more easily implemented,
standard was the Carrierless
Amplitude Phase or CAP,
system, which was used on many
of the early installations of
ADSL.
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CAP operates by dividing the signals on the telephone line into three distinct bands: Voice conversations are carried in the 0-4 khz (kilohertz) band, as they are in all POTS circuits. The upstream channel (from the user back to the server) is carried in a band between 25-160 khz. The downstream channel (from the server to the user) begins at 240 khz and goes up to a point that varies depending on a number of conditions (line length, line noise, number of users in a particular telephone company switch) but has a maximum of about 1.5 Mhz (megahertz). This system, with the three channels widely separated, minimizes the possibility of interference between the channels on one line, or between the signals on different lines.
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DMT also divides signals into separate channels, but doesn't use two fairly broad channels for upstream and downstream data. Instead, DMT divides the data into 247 separate channels, each 4 khz wide. One way to think about it is to imagine that the phone company divides your copper line into 247 different 4 khz lines and then attaches a modem to each one. You get the equivilent of 247 modems connected to your computer at once! Each channel is monitored and, if the quality is too impaired, the signal is shifted to another channel. This system constantly shifts signals between different channels, searching for the best channels for transmission and reception. In addition, some of the lower channels (those starting at about 8 khz, are used as bidirectional channels, for upstream and downstream information. Monitoring and sorting out the information on the bidirectional channels, and keeping up with the quality of all 247 channels, makes DMT more complex to implement than CAP, but gives it more flexibility on lines of differing quality.
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CAP and DMT are similar in one way that you can see as a DSL user. If you have ADSL installed, you were almost certainly given small filters to attach to the outlets that don't provide the signal to your ADSL modem. These filters are low-pass filters -- simple filters that block all signals above a certain frequency. Since all voice conversations take place below 4 khz, the low-pass filters are built to block everything above 4 khz, preventing the data signals from interfering with standard telephone calls.
DSL
Equipment
ADSL uses two pieces of equipment,
one on the customer end, and
one at the Internet Service
Provider, telephone company
or other provider of DSL services.
At the customer's location there
is a DSL transceiver, which
may also provide other services.
The DSL service provider has
a DSL Access Multiplexer, or
DSLAM to receive customer connections.
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DSL Transceiver
Most residential customers will
call their DSL transceiver a
"DSL modem." The engineers at
the telephone company or ISP
will call it an ATU-R. Regardless
of what it's called, it's the
point where data from the user's
computer or network is connected
to the DSL line. The transceiver
can connect to a customer's
equipment in several ways, though
most residential installation
uses USB or 10-baseT Ethernet
connections. While most of the
ADSL transceivers sold by ISPs
and telephone companies are
simply transceivers, the devices
used by businesses may combine
network routers, network switches
or other networking equipment
in the same platform.
DSLAM
The DSLAM at the access provider
is the equipment that really
allows DSL to happen. A DSLAM
takes connections from many
customers and aggregates them
onto a single, high-capacity
connection to the internet.
DSLAMs are generally flexible
and able to support multiple
types of DSL in a single central
office and different varieties
of protocol and modulation --
both CAP and DMT, for example
-- in the same type of DSL.
In addition, the DSLAM may provide
additional functions including
routing or dynamic IP address
assignment for the customers.
The DSLAM provides one of the main differences between user service through ADSL and through cable modems. Because cable modem users generally share a network loop that runs through a neighborhood, additional users mean lowered performance in many instances. ADSL provides a dedicated connection from each user back to the DSLAM, meaning that users won't see a performance decrease as new users are added--until the total number of users begin to saturate the single, high-speed connection to the Internet. At that point, an upgrade by the service provider can provide additional performance for all the users connected to the DSLAM.
Currently, ADSL is limited by U.S. Federal Communications Commission regulations to a maximum of 1.5 megabits per second. Current technology can provide a theoretical maximum of up to 7 megabits per second, and research promises even greater performance in the future with protocols like G.Lite and VDSL.