Simplified Access Technology for Gigabit Speeds Over Existing Infrastructure in Multi-Dwelling Units

For carriers seeking to expedite their broadband deployment in underserved areas, the prospect of an in-building fiber installation for high-speed broadband is a daunting challenge. Fortunately, Positronโ€™s G.hn Access Multiplexer (GAM) technology makes it possible to leverage a non-blocking CE 2.0 Carrier Ethernet Core to reliably deliver managed Gigabit services over existing infrastructure.

Using G.hn for Advanced Services

G.hn is an access technology for operators looking to simplify their access network and reduce their costs with an Ethernet-like technology. The ITU-T G.9960 G.hn Wave-2 standard leverages the existing telephone wiring (UTP, CAT-3 or CAT 5/5e) or RG-6/RG-59 coax cabling (each coax port serves up to 16 subscribers) to deliver a gigabit Internet access to each apartment inside Multi-Dwelling Unit (MDU) properties or Multi-Tenant Unit (MTU) properties.

Each G.hn subscriber port supports up to 1.7 Gbps of dynamically allocated bandwidth for near-symmetrical gigabit access. A G.hn Access Multiplexer (GAM) then connects to and extends multi-gigabit feeds from fiber terminating in the GAM via an ONT (Optical Network Terminal xPON) or fixed wireless access radios. It serves all residential gateways in multi-family properties with gigabit Ethernet router ports using G.hn, allowing operators to deliver advanced services, such as gigabit high-speed residential Internet and 4K Internet Protocol television (IPTV), over existing infrastructure without the high capital and operational expenses associated with a fiber internet retrofit.

Beyond Bandwidth Constraints

Unlike Data Over Cable Service Interface Specifications (DOCSIS), G.hn uses baseband spectrum from 5-200 MHz and dynamically allocates each tone to carry either upstream or downstream traffic to reflect the demand from the subscribers, achieving gigabit speeds in both directions over coaxial cable networks.

The base definition of DOCSIS 3.1 allocates the 5-42 MHz range to upstream traffic, resulting in โ€œup toโ€ 100 Mbps of shared bandwidth across all subscribers on a Cable Modem Termination System (CMTS) port. DOCSIS vendors have recently introduced solutions to provide more upstream bandwidth by extending the spectrum for the upstream bands by reducing the spectrum used for the downstream direction. Two split levels are defined as per Figure 1.

Figure 1. DOCSIS Spectrum allocation for Mid-Split and High-Split.

Figure 1. DOCSIS Spectrum allocation for Mid-Split and High-Split.

Figure 1 shows the Mid-Split approach extends the upstream spectrum to 5-85 MHz, resulting in about 500 Mbps. The High-Split approach extends the spectrum to 5-204 MHz for about 1.5 Gbps of throughput. A DOCSIS network is engineered to serve an average of 150 subscribers on the premises in which the peak bandwidth levels per subscriber is well below 5 Mbps downstream and below 350 Kbps (not Mbps) upstream. With the increase in bandwidth consumption for teleworking, remote learning, video streaming, online gaming and related services, this no longer reflects the real-time traffic demand patterns we experience today.

Bandwidth Capacity in MDUs

Looking at the G.hn spectrum, we see that the 5-200 MHz range handles upstream and downstream traffic using an Orthogonal Frequency-Division Multiplexing (OFDM) encoding. (See Figure 2.) (This is somewhat different than with DOCSIS where the upstream is encoded with OFDM and the downstream uses Orthogonal Frequency-Division Multiple Access (OFDMA)). The aggregate bandwidth of G.hn on coax is 1.7 Gbps (or 2 Gbps at the physical layer).
G.hn and CATV Spectrum Allocation

Figure 2. G.hn and CATV Spectrum Allocation

Before jumping to the conclusion that a High-Split approach offers more bandwidth than G.hn broadband protocol, it is important to remember that each coax port of a GAM can serve up to 16 subscribers (not several hundred as is the case with DOCSIS). This easily handles a peak average of 100 Mbps (dynamically split between upstream and downstream for each subscriber) and allows for peaks at 1 Gbps without problem.

A 24-port GAM device, like the Positron GAM, can deliver 40 Gbps of capacity inside an MDU, with the actual total bandwidth being constrained by the available fiber link. For instance, the GAM hardware would be able to handle the same bandwidth as four (4) 10GEPON or XGS-PON links. That means, the GAM will not be a limiting factor when a property owner or property manager decides to extend the fiber service over the coaxial infrastructure of a building.

CATV & G.hn Signals Over the Same Coax Cabling

When it comes to the question of bandwidth availability, unlike DOCSIS High-Split, G.hn avoids spectrum overlap with Community Antenna Television (CATV) channels.

With DOCSIS High-Split, the Community Antenna Television (CATV) channels are allocated from 258 MHz (channel 30), and the total downstream spectrum available and bandwidth achievable is a function of the number of channels offered to subscribers. The more channels, the less spectrum remains for the downstream traffic.

The very important difference and benefit of G.hn is that it does not use any spectrum that overlaps with the CATV content. Therefore, the total available bandwidth of G.hn is not impacted by the number of channels offered to the subscribers. For instance, 20 CATV channels, each using 6 MHz of spectrum, reduce the downstream bandwidth of DOCSIS by about 1 Gbps. Like the DOCSIS High-Split, G.hn allows CATV channels starting at 258 MHz.

When deploying a GAM in environments such as an MDU or a hotel, it is very easy to overlay the G.hn and CATV signals over the same coaxial cabling using standard splitters-combiners as shown in Figure 3.

Figure 1. DOCSIS Spectrum allocation for Mid-Split and High-Split.

Figure 3. Combining G.hn and CATV on the same coaxial cable.

Looking at Figure 3, we see that the CATV signal needs to be overlaid with G.hn for each port of a GAM device. This combined G.hn + CATV signal can then feed up to 16 subscribers per GAM port using standard splitter devices that are typically already in place. A single coaxial drop per apartment or guest room is then used to bring the G.hn signal to a G.hn endpoint (Ethernet bridge) and to a set-top-box or TV.

Pay-Per-View Services, Simplified

Although the specific channel(s) may vary depending on the Pay-per-View (PPV) solution in use, PPV services rely on return channels located below the 50 MHz range. To make room for such signals, a G.hn signal can be โ€œnotchedโ€ to begin at a higher frequency than the default 5 MHz defined by the G.hn standard (ITU-T G.9660), via a simple configuration setting in the GAM. While this reduces the available spectrum, it does not prevent G.hn from delivering peak bandwidth of 1 Gbps in any direction.

For example, a GAM can configure the G.hn signal to begin at 60 MHz. Looking at Figure 4, we clearly see that the Power Spectral Density (PSD) for the G.hn signal is from 60 MHz to 200 MHz on the G.hn port using the coaxial cable.

Figure 1. DOCSIS Spectrum allocation for Mid-Split and High-Split.

Figure 4. PSD of G.hn to make room for CATV and Pay-per-View.

Simple, 2-Step Migration to IPTV

G.hn permits a seamless migration to Internet Protocol television (IPTV) services, allowing subscribers to switch at their own pace, through a 2-step approach.

Step 1. Inject the IPTV feed via the uplink port of a GAM. The GAM provides full support for Internet Group Management Protocol (IGMP) Multicasting, allowing multiple subscribers to share the same IPTV feed, which is very convenient for serial TV. At the same time, the GAM supports unicast IPTV which allows for more advanced user experiences (pause, rewind) without additional complexity.

Step 2. Whenever a subscriber is ready to migrate to IPTV, use the second Gigabit Ethernet port of the G.hn endpoint and connect it to the set-top-box or smart TV. You can then disconnect the coax cable from that previously used for the CATV signal.

Once there are no remaining CATV subscribers on a coaxial segment, remove the spectrum notch (5-60 MHz in the example earlier) to reclaim the full G.hn spectrum to deliver the full 1.7 Gbps of aggregate bandwidth of G.hn.

Simplified & Cost-Effective MDU Gigabit Internet Access

For building owners or property managers who wish to provide gigabit coverage to multiple users in apartment buildings, condominiums, hotels and other MDUs without a costly fiber retrofit, G.hn offers an elegant solution. Through the use of existing infrastructure, G.hn achieves superior upstream and downstream bandwidth than DOCSIS, and it permits the easy integration of other advanced services, such as pay-per-view and IPTV.

See the Broadband Forum TR-419 document for more information about the concept of Fiber to the Extension point.

For more information, please email ptrudeau@positronaccess.com and visit https://www.positronaccess.com/. Follow us on Twitter at https://twitter.com/PositronAccess. Social media handles: #ghn #GAM #telecoms #fiberextension #MDU.

Pierre Trudeau

About Pierre Trudeau

President and CTO of Positron Access Solutions Corp, Pierre Trudeau revolutionized Wi-Fi in 2005 with Colubrisโ€™ Distributed Data Plane architecture. Today, he is the driving force behind Positronโ€™s carrier grade G.hn Access Multiplexer (GAM) technology. By extending fiber / FWA virtually symmetrical Gigabit services over the existing in-building wiring to all underserved subscribers in MDUs at a small fraction of the cost, this technology is set to have a huge impact on the global market, so it comes as no surprise that he was selected as part of the โ€œTop 50 Broadband Influencers, Innovators and Disrupters who are Connecting the Worldโ€ in 2021. (Informa Tech).








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    Extending Gigabit Fiber services to Every Door without installing fiber to the door

    Positronโ€™s G.hn Access Multiplexer (GAM) can extend your fiber services to every door of an MDU/MTU over the existing telephone pairs or coaxial cable to deliver Gigabit broadband. The Positron GAM delivers symmetrical Gigabit broadband without the need to install fiber to every door.

    By |2023-05-30T14:36:31-04:00April 12, 2022|GAM, Press Release|0 Comments

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