The leading FTTH technology is PON or Passive Optical Network
technology. This approach differs from most of the telecommunications
networks in place today by featuring "passive" operation. Active networks
like DSL, VDSL and cable have active components in the network backbone
equipment, in the central office, in the neighborhood network
infrastructure, and in the customer premise equipment. PONs have only
passive light transmission components in the neighborhood infrastructure
with active components only in the central office and the customer premise
equipment.
The elimination of active components means that the access network
consists of one bi-directional light source and a number of passive
splitters that divide the data stream into the individual links to each
customer. At the central office, the termination point is in PON optical
line terminal (OLT) equipment. At the customer premise, the termination
point is in optical network terminals or ONTs also called optical network
units or ONUs. These are in the customer premise equipment, or CPE.
Between the OLT and the ONT/ONUs is the passive optical network comprising
fiber links and passive splitters and couplers.
What's in a Name?
The FTTH market has a plethora of acronyms. Some are meaningful and
some are redundant, but here are some of the key ones:
FTTH - Fiber to the Home
A description of the PON-based broadband access network technology that
uses fiber optics running all the way from the Internet backbone to the
home or premise. Some times other acronyms, FTTx, FTTP, or FTTB are used,
but these are essentially interchangeable. FTTH is becoming the catch-all
descriptor for all fiber to the home, premise, business and "x"
technologies.
PON - Passive Optical Network
The fiber based network infrastructure between central office and the
home.
OLT, ONU, ONT - Optical Line Terminal, Optical Network Unit, Optical Network Terminal
The fiber link is terminated in the central office at a Optical Line
Terminal or OLT. OLT devices are the semiconductors that perform that
function. They interface to the fiber link connecting the central office
equipment to the customer premise equipment or CPE. In the CPE, the fiber
link is terminated by an Optical Network Unit, or ONU, or by an Optical
Network Terminal, or ONT. These terms have the same meaning, but ONU is
IEEE terminology and ONT is ITU-T terminology.
APON, BPON, GPON, EPON, and GE-PON Explained
These represent three flavors of PON technology. APON and BPON are the
same specification which is commonly referred to as BPON. BPON is the
oldest PON standard, defined in the mid-1990s and while there is an
installed base of BPON, most of the new market deployment focus is now on
EPON/GE-PON. GE-PON and EPON are different names for the same
specification, that is defined by the IEEE 802.3ah Ethernet in the First
Mile standard ratified in June 2004. This is the current standardized
high-volume solution for gigabit PON technologies. GPON is now being
standardized as the ITU-T G.984 recommendation and is receiving interest
in North America and elsewhere, but with no final standard. GPON devices
have just been announced, and there is no volume deployment as yet.
Differences Between BPON, GPON and GE-PON
One important distinction between the standards is operational speed.
BPON is relatively low speed with 155 Mbps upstream/622 Mbps downstream
operation. GE-PON/EPON supports 1.0 Gbps symmetrical operation. GPON
promises 2.5/1.25 Gbps asymmetrical operation.
Another key distinction is the protocol support for transport of data
packets between access network equipment. BPON is based on ATM, GE-PON
uses native Ethernet and GPON supports ATM, Ethernet and WDM using a
superset multi-protocol layer.
BPON suffers from the very aggressive optical timing of ATM and the
high complexity of the ATM transport layer. ATM-based FTTH solutions face
the problems posed by the provisioning (requires ATM-based central office
equipment), complexity (in timing requirements and protocol complexity)
and subsequent cost of components. This cost is exacerbated by the
relatively small market for traditional ATM equipment used in the backbone
telecommunications network.
GPON is still evolving; the final specification of GPON is still being
discussed by the ITU-T and FSAN bodies. But by definition, it requires the
complexity of supporting a multiple protocols through translation to the
native Generic Encapsulation Method (GEM) transport layer that through
emulation provides support for ATM, Ethernet and WDM protocols. This added
complexity and lack of standard low-cost 2.5/1.25 Gbps optical components
has delayed industry development of low-cost, high-volume GPON devices.
GE-PON or Ethernet in the First Mile has been ratified as the IEEE
802.3ah EFM standard and is already widely deployed in Asia. It uses
Ethernet as its native protocol and simplifies timing and lowers costs by
using symmetrical 1 Gbps data streams using standard 1Gbps Ethernet
optical components. Like other Ethernet equipment found in the extended
network, Ethernet-based FTTH equipment is much lower-cost relative to
ATM-based equipment and the streamlined protocol support for an extended
Ethernet protocol simplifies development. Specific to PMC-Sierra, the
GigaPASS architecture that is designed for gigabit throughput for GE-PON
devices is adaptable for use with GPON devices as well.
| |
TECHNOLOGY |
| |
BPON (APON) |
GE-PON (EPON) |
GPON |
| ATTRIBUTES |
|
| Speed - Upstream/Downstream |
155/622 Mbps |
1.0/1.0 Gbps |
1.25/2.5 Gbps |
| Native Protocol |
ATM |
Ethernet |
GEM |
| Complexity |
High |
Low |
High |
| Cost |
High |
Low |
Undetermined |
| Standards Body |
ITU-T |
IEEE |
ITU-T |
| Standard Complete |
Yes, 1995 |
Yes, 2004 |
No |
| Volume Deployment |
Yes, in 100,000s |
Yes, in 1,000,000s |
No |
| Primary Deployment Area |
North America |
Asia |
Not applicable |