Chapter 44. ADSL - Asymmetrical Digital Subscriber Line
Asymmetrical Digital Subscriber Line (ADSL) uses the existing analog local loop lines for digital data transfer (to and from the home). It is asymmetrical because the upstream transfer rate is slower than the downstream data rate. This means that the data transfer from the premise (home) to the CO is a different rate than the data transfer from the CO to the home.
The data transfer is rate adaptive. This means that, depending on the condition of the local loop lines, ADSL will automatically compensate (i.e. find the fastest transfer rate possible). The range for upstream data transfer is from 64 kbps to 768 kbps. The range for downstream data transfers is from 1.5 Mbps to 8 Mbps. The reasoning for the asymmetrical transfer rate is that most users will be surfing the Internet; upstream requests tend to be small web page addresses. The downstream data consists of downloads of large graphic intensive web pages. Small upstream requests, larger downstream response.
The data transfer rate depends on the distance from the central office, the quality of the line, and the wire gauge. If the distance from the central office is 15,000 to 18,000 ft, then the maximum transfer rate is 1.5 Mbps. If the distance is 9,000 ft or less, the maximum transfer rate is 8 Mbps.
ADSL Standards
At the time of this writing, there are 3 competing standards for ADSL (shown below):
Carrierless Phase Modulation ADSL
Splitterless ADSL
Discrete Multitone ADSL
Carrierless Phase Modulation (CAP) ADSL is a modulation technique similar to Quadrature Amplitude Modulation. It provides Echo Cancellation, and overlaps upstream and downstream signals.
Splitterless ADSL (also called ADSL Lite, G.Lite, PnP ADSL, Universal ADSL) has a lower transmitting rate, and is easier to implement.
DMT - Discrete Multitone is an ANSI T1.413 standard that uses a broadband modem (covering the 4 kHz to 2.2 MHz range). It has 256 channels of 4 kHz: each channel is assigned 15 bits of data to transfer. In addition, each channel is checked for signal quality, and bits are assigned accordingly. A poor responding channel may have less bits assigned, or none at all. DMT adjusts for the local loop line conditions, and attempts to make the fastest transfer rate possible.
ADSL OSI Model
ADSL is a Physical layer protocol that covers the transmission of data and cabling requirements.
ADSL Premise Equipment
ADSL Premise Equipment
ADSL shares the bandwidth of the local loop with the existing phone system. It does not require modification to the central office switch. Instead, a splitter combines the ADSL information with the POTS switch's analog information. At the central office end, the ADSL signal is sent to the Digital Subscriber Line Access Module (DSLAM), and then to a communication server.
At the premise end, another splitter separates the ADSL information from the analog information. An ADSL modem, called an ATU-R device, decodes the ADSL information, and sends it to the Service Module (SM). The Service Module translates it to Ethernet. In plain network terms, ADSL comes in and an Ethernet signal goes out for connection (to a network interface card).
ADSL Advantages
No expensive modification is required to CO switch
Simple splitter splits ADSL signal from the existing analog line
High bandwidth is available.
The POTS works regardless of ADS.
ADSL has competitive pricing versus other technologies.
ADSL Disadvantages
The transfer rate depends on distance from the central office.
The presence of bridged taps and load coils on the local loop affect the transfer rate.
ADSL must be installed to test if it will work.
25% of existing local loops will not work with ADSL
There is an 18,000 ft distance limit from the central office.
There can be a bottleneck at the communication server (at the central office).
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