ELEKTROTEHNIŠKI VESTNIK 79(3): 117-122, 2012 
ENGLISH EDITION 
 
 
NG-PON1: technology presentation, implementation in 
practice and coexistence with the GPON system 
Vesna Eržen, Boštjan Batagelj  
 
University of  Ljubljana, Faculty of Electrical Engineering, Tržaška 25, 1000 Ljubljana, Slovenia 
E-mail: erzenvesna@gmail.com, bostjan.batagelj@fe.uni-lj.si 
 
Abstract The paper presents technology of the ten-gigabit-capable Passive Optical Network – XG-PON which 
in two phases of its development (XG-PON1 and XG-PON2) takes the first step towards the Next-generation 
Passive Optical Network 1 – NG-PON1. Results of researches and analyses of the development of the fixed 
broadband optical network are summarized. The focus is on describing the migration process of the Gigabit-
capable Passive Optical Network – GPON to NG-PON1. The migration to the new technology is sensible only if 
related to technological improvements that enable enhanced services and if the investments needed for migration 
are cost-efficient. Arrival of a new technology is always characterized by a certain range of changes in the 
existing system, therefore, the purpose of the paper is to answer the questions what is the scope of changes 
needed in the existing passive and active elements and which new elements need to be added. In relation to this, 
special attention is given to coexistence of GPON and NG-PON1. It is shown that for coexistence of the GPON 
and NG-PON1 systems using wavelength blocking filters – WBF based on the Thin Film Filter – TFF and 
Wavelength Division Multiplexing – WDM splitters is a cost-efficient and technologically adequate solution.  
 
Keywords: Next-generation Passive Optical Network, optical access network, Gigabit-capable Passive Optical 
Network, coexistence 
 
 
 
1 INTRODUCTION  
By the Nielsen's law, the required bandwidth in 
different access network is constantly increasing by 
approx. 50% every year [1]. Lately, the increase is 
mainly due to cloud computing and IPTV [2]. As the 
optical fiber is a broadband medium, which in theory 
and practice achieves very high transmission speeds, 
more and more service providers decide to use it in 
building a new or upgrading the existing optical access 
network.  
 When the fiber runs from the central office to the 
home of the end user, the technology is called Fiber to 
the Home – FTTH. When building FTTH, two basic 
architectures of the network are possible:  Point-to-point 
– P2P [3] or Point-to-multipoint – P2MP.  
 The Gigabit-capable Passive Optical Network – 
GPON is based on the architecture of P2MP and was 
selected by the majority of providers of 
telecommunication services in Europe and the USA. 
GPON is standardized by the ITU-T (International 
Telecommunication Union – Telecommunications) 
series of recommendations G.984 [4]. In accordance 
with the standard, it provides various combinations of 
transmission speeds. In practice, the most commonly 
realized asymmetric speed of data transfer is at the 
downstream speed of 2.4 Gbit/s and the upstream speed 
of 1.2 Gbit/s. The other possibility is symmetric 
transmission speed of 2.4 Gbit/s. As the optical fiber is 
able to transport much higher bit rates, the Next-
generations PON – NG-PON systems promise much 
higher transmission speeds. 
 In 2010, the ITU-T G.987 standard [5] was approved. 
It defines the first phase in the development of the Ten-
gigabit-capable PON – XG-PON1 system. X in the 
abbreviation XG-PON stands for the Roman numeral 10 
to denote 10 Gbit/s of the system transmission speed. 
This is true for the downstream transmission. The 
upstream transmission speed of XG-PON1 is 2.5 Gbit/s. 
The standard above contains also trends which refer to 
the 2nd phase in the development of the ten-gigabit 
PON system (XG-PON2) which anticipate the 
symmetric transmission speed of 10 Gbit/s in the 
downstream and upstream of data. 
 The paper defines general characteristics and 
physical level of the GPON, XG-PON1 and XG-PON2 
systems. The emphasis is on the recently standardized 
XG-PON1 technology. The technology definitions are 
based upon standards formed or still being formed in the 
working group FSAN – Full Service Access Network of 
the international association ITU-T. In its Chapter 3, a 
chronological overview of the development of 
technologies is given and demands to be fulfilled are 
identified enabling achievement of the simplest possible 
and spontaneous migration to the Next-generation PON. 
 
Received August 22, 2012 
Accepted October 11, 2012 
118  ERŽEN, BATAGELJ 
 
Two possible ways or scenarios of migrating from 
GPON to XG-PON1 and demands for their coexistence 
are described. Chapter 4 deals with the question which 
network devices are adequate to use to achieve 
compatibility of the NG-PON1 and GPON systems. In 
Chapter 5 the most important conclusions are drawn. 
 
2 TECHNOLOGY DESCRIPTION 
2.1 GPON 
Compliably with ITU-T G.984, the GPON’s Optical 
Distribution Network – ODN connects the Optical Line 
Terminal – OLT with the Optical Network Terminal – 
ONT or Optical Network Unit – ONU via a passive 
optical splitter. The basic components of the PON 
network are shown in Fig. 1. ONT is intended for one 
end user. ONU is able to have more end users connected 
to it, with different types of connections (optics, copper 
pairs, wireless connection).  
 
Figure 1. GPON network consists of OLT in the central office, passive 
optical splitter and ONT/ONU units 
 
 The ODN network is entirely passive, meaning that it 
contains no elements needing electric power supply for 
its operation. 
 Its downstream transmission is different from its 
upstream transmission. In the downstream, there is a 
continuous data stream, where the communication 
among OLT and individual ONTs runs via Time 
Division Multiplexing – TDM. ONT/ONU receive all 
frames and discard those that are not intended for them. 
In the upstream, there is an interrupted series of data 
bursts where separate ONT/ONU units communicate 
with OLT in the central unit via a multiple access on the 
basis of Time Division Multiple Access – TDMA [6].  
 OLT in the central office can support various split 
ratios (1:16, 1:32 or 1:64 or more), depending on the 
desired reach. A higher ratio means a lower reach and 
vice versa because there is a limited power budget in the 
network. To increase the power budget in the network, 
compliably with the ITU-T G.984.6 recommendation 
[7], the active components of the Reach Extenders – RE 
can be used.  
 The downstream transmission in a single-fiber 
system operates at the wavelength of 1490 nm and the 
upstream transmission at the wavelength of 1310 nm. At 
the wavelength of 1550 nm, a video signal is 
transmitted.  
 
2.2 XG-PON1 
The downstream transmission of XG-PON1 is 10 Gbit/s 
and the upstream transmission is 2.5 Gbit/s. Because of 
specific demands of the optical-transceiver market and 
industry, the FSAN/ITU-T group selected the 
bandwidth between 1575 nm and 1580 nm for the 
downstream and 1260 nm to 1280 nm for the upstream 
transmission (Fig. 2). Choosing the adequate band was 
not easy mainly because of the need for the guard band 
which prevents interference among signals of the near 
wavelengths.   
 
Figure 2. GPON and XG-PON wavelength allocation  
 
 The main components of the XG-PON1 network 
architecture are OLT in the central office, ODN and 
ONU/ONT units at the user end. The standard defines a 
simple and complex ODN as shown in Fig. 3. The 
simple ODN consists of a single passive Optical 
Distribution Segment – ODS and the complex ODN 
consists of a group of passive ODSs interconnected with 
reach extenders [8].  
 
 
Figure 3. Example of simple and complex networks united in a single 
PON. 
 
 The reach extender – RE, which increases the optical 
link budget, consists of technologies, such as optical 
amplifiers and regenerators on the basis of optical-
electrical-optical conversion. RE is anticipated to have 
an important role in the NG-PON system [9], [10]. The 
reach extenders are used to increase the power budget 
thus increasing the reach and split ratio and also 
merging more ODS.  
NG-PON1: TECHNOLOGY PRESENTATION, IMPLEMENTATION IN PRACTICE AND COEXISTENCE WITH THE GPON… 119 
 On higher network levels (transmission convergence 
– TC layer) management and encapsulation (framing) in 
the XG-PON1 system takes place, as is the case with 
GPON [11]. This is important from the coexistence 
point of view.  
 The downstream window is only 5 nm wide. To 
operate normally, such a narrow band uses cooled laser 
sources to stabilize the wavelength. Such special 
sources are in the first place related to higher costs [12].  
 The upstream window being 20 nm wide, uncooled 
laser sources can be used and the ONU optics costs 
decreased. 
2.3 XG-PON2 
The FSAN/ITU-T group has still not achieved 
consensus and clear cues regarding the next stage of the 
NG-PON1 system, marked as the XG-PON2 system. 
The XG-PON2 system refers to the increase in the 
upstream transmission speed from 2.5 Gbit/s to 10 
Gbit/s, enabling the symmetrical transmission speed in 
the upstream and downstream direction.  
 Some experts see the possibility of spontaneous 
migration from the GPON to the XG-PON1 technology 
and later to the XG-PON2 technology with some 
adjustments on the transmission convergence layer 
made. It is planned to retain the downstream wavelength 
of the XG-PON1 system and extend the framing 
structures for the TC layer. That would support a higher 
upstream transmission speed (10 Gbit/s) and 
compatibility of XG-PON1, XG-PON2 and GPON.   
 Solutions related to the coexistence of the XG-PON1, 
XG-PON2 and GPON are facing some technological 
shortcomings. Firstly, it is not clear if fragmentation 
should be supported in the upstream at higher 
transmission speeds and what would be the impacts on 
the Dynamic Bandwidth Allocation – DBA. Also, a 
separate receiver at OLT will be needed to prepare for 
the reception of data at different transmission speeds in 
the upstream. Difficulties because of the nature of the 
upstream burst occur at approximately 5 Gbit/s. The key 
problem is principally in the receiver designed so as to 
enable a precise detection of the change in the high-and 
low-signal levels and at the same time prompt 
adjustment of and appropriate time for signal recovery 
[10]. 
  
3 OUTLINE OF THE MIGRATION PROCESS 
The PON systems are well established in practice and 
are regarded as a very prospective access technology. 
After 2000, the GPON technology has become widely 
recognized. The ten-gigabit PON systems mark the next 
stage of development. These are the XG-PON1 and XG-
PON2 systems which are in technical literature marked 
under the umbrella term NG-PON1. The Conceptual 
definition of NG-PON1 goes back to 2008. In 2010, 
XG-PON1 was standardized. Due to the ever increasing 
needs for a higher bandwidth, it is expected that this 
technology will reach the market until the end of year 
2013. 
 
3.1 Migration to the new technology scenario 
The G.987.1 recommendation for the XG-PON1 
technology purposes two scenarios enabling migration 
from the GPON to the XG-PON1 technology. When 
service providers want to change the copper connection 
with the optical one, they can build the XG-PON1 
system. This migration scenario is called the PON 
green-field migration scenario. The other way of 
migrating to the XG-PON1 system operation is 
upgrading the existing GPON system where upgrading 
or replacement of the ONU/ONT units is needed. This 
can be done either one after one other in a longer time 
period or all at once. The period of coexistence of the 
GPON and XG-PON1 system in a single ODN depends 
on this decision. This migration scenario is called the 
PON brown-field migration scenario. 
 When we talking about the NG-PON1 systems, the 
concept of consolidation of the network should not be 
ignored. The idea is to combine and reduce the number 
of central offices in an extended and long-reach access, 
which is possible due to the large power budget in the 
NG-PON1 systems. 
 The main goal of introducing NG-PON1 is the 
increase in the data-transfer speed, which can be 
achieved at a minimal cost [9]. This can be done by 
minor interventions on the physical level of the 
network. To protect investments made by the service 
providers for GPON, the FSAN/ITU-T group in its 
recommendations defined demands enabling 
coexistence of the NG-PON1 and the GPON system. 
The demands [13] related to the process of 
migration to NG-PON1 and having to be considered 
when designing standards are: 
– optimization of the new equipment costs; 
– enabling coexistence of the new PON systems with 
the currently used ones to protect the operator 
investments; 
– optimal exploitation of the existing resources 
(bandwidth) by using a dynamic bandwidth 
allocation to users; 
– preserving and reusing the optical infrastructure; 
– minimization of network interference when 
migrating to the new technology by precise prior 
planning. 
 
 For achieving coexistence, when migrating to the 
XG-PON1 technology, it is important, the existing both 
the colorless ONT units and the ODN network can be 
used as they are. Advantages of the XG-PON1 over the 
GPON technology are higher profits per user, simple 
network expansion and efficient network management 
and planning [14]. 
120  ERŽEN, BATAGELJ 
 
3.2 Coexistence of the NG-PON1 with the GPON 
system  
The G.987 standard anticipates coexistence of XG-
PON1 with GPON and transmission of video signals 
into the same ODN system. If common ODN is 
intended for XG-PON1, GPON and transmission of 
video, it is required for differentiation of the data traffic 
to use special wavelength blocking filters – WBF. 
The most important condition to the met for the 
NG-PON1 and GPON system coexistence is operation 
in the existing optical distribution network. Because of 
the differences in the wavelength bands the two systems 
operate in, some updating ensuring simultaneous 
transmission of different wavelength signals should be 
made.  
 The wavelength band for the upstream transmission 
in GPON extends from 1260 nm to 1360 nm and for the 
downstream transmission from 1480 nm to 1500 nm. 
The function of the neighboring bands is to assure 
safety by separating the GPON bands the bands of the 
XG-PON1 system. In this way, interference among the 
signals of the nearby wavelengths is prevented. G.984.5 
recommends installation of low price bracket WBFs to 
ensure isolation outside the guard band and to reduce in 
this way the cost of migrating from GPON to XG-
PON1.  
 Fig. 4 shows the basic elements enabling coexistence 
between the GPON and XG-PON1 system. In the 
downstream transmission, the signal runs from the 
central office where two separate OLT units for GPON 
and XG-PON1 transmit. To allow for coexistence, a 
splitter (made on the basis of Wavelength Division 
Multiplexig – WDM) is used for its combining signals 
of different wavelengths (GPON, XG-PON1, video) in 
the downstream transmission to the common optical 
fiber and for splitting these signals in a reverse route. 
The WDM splitter can be placed in the central office 
[8].  
 
 
Figure 4. Basic network architecture enabling coexistence of the 
GPON and XG-PON1 system.  
 
 For the signal to operate and be processed properly in 
a separate ONT unit (for GPON and XG-PON1), it is 
preliminary passed through WBFs to assure isolation 
outside the guard bands as required. This makes the 
wider band of the wavelength to remain at our disposal 
for the next generation of the PON systems [14]. 
 When extending the reach or increasing the power 
budget in the network by migrating to XG-PON1, the 
G.987.1 standard foresees two possible architectures. 
One proposes installation of RE containing technologies 
for simultaneous amplification of the GPON and XG-
PON1 signals (Fig. 5). The other uses RE only for 
strengthening XG-PON1 (Fig. 6). The existing PON 
elements (OLT, ONT) despite being retained, 
coexistence is achieved and, at the same time, the power 
budget in the network is increased to the extent defined 
by the standard. 
 
Figure 5. Combined RE reinforces the GPON and XG-PON1 signals 
simultaneously 
 
 
Figure 6. By using XG-PON1 RE, a sufficient power budget in ODN 
is ensured. 
 
4 NEW DEVICES OF THE XG-PON1 SYSTEM 
Implementation of NG-PON1 into practice is designed 
in the way optimally protecting investments of operators 
in the existing system. It is for this purpose that XG-
PON1 operates in the same ODN as GPON. Despite that 
when migrating to a new technology there are still some 
investments that cannot be avoided. 
 As shown in Table 1, when migrating to the NG-
PON1 system, there are some elements that should be 
changed, some that can be used in their unchanged form 
and some that need to be upgraded. The unmarked cells 
in Table 1 are devices needing to be substituted, added 
or upgraded when migration to the new technology. 
 
Table 1. Adequacy of the network elements in different examples of 
the PON systems. 
Devices GPON XG-PON1 XG-PON2 
OLT 
   
ONU 
   
SPLITTERS 
   
CABLES 
   
FILTERS 
   
WDM SPLITTERS 
   
 
NG-PON1: TECHNOLOGY PRESENTATION, IMPLEMENTATION IN PRACTICE AND COEXISTENCE WITH THE GPON… 121 
 As already mentioned, to allow for coexistence, 
wavelengths of different signals transmitted via the 
common fiber need to be separated. This can be done by 
using special adjustable lasers or WBFs.  
 Speaking in terms of cost efficiency, using the 
WBFs, manufactured on the basis of the Thin Film 
Filter – TFF technology, is more appropriate than using 
adjustable expensive lasers. Besides WBFs have longer 
been present on the market and are a more developed 
technology. Development of adjustable lasers is still in 
progress and their use is to some extent technologically 
limited. An example of such a limitation is a system for 
laser temperature stabilization. Its implementation being 
quite demanding, the cost of the final product is high.  
 Besides the WBFs and adjustable lasers there are 
some other devices that can be used for wavelengths 
selection, but the majority of them are still being in their 
development and testing phase. One such example are 
devices based on nanowire technology. Currently, this 
technology is still in its early development stage and in 
many points of view it is not yet suitable for practical 
applications in the NG-PON1 systems; however, 
technological improvements are anticipated [15]. 
 
4.1 WDM splitters 
 The WDM splitter is an optical device required at 
central office under NG-PON1 deployment. It combines 
and splits signals of different wavelengths [15]. The 
WDM splitter increases the system performance without 
changing the distribution network. It provides signals of 
different wavelengths in the downstream transmission to 
merge to a common optical fiber. In the upstream 
transmission, it classifies signals from the common fiber 
in to the corresponding optical fiber. 
 The basic characteristics of the WDM splitters are 
defined in the appendix of the ITU-T G.984.5 
recommendation [16]. There are different reference 
options of the version of the WDM splitters listed, 
depending on specific demands of individual systems. 
Fig. 7 shows a scheme of the WDM splitter which 
enables merging of the XG-PON1 and GPON system 
and transmission of video signals. 
 
Figure 7. WDM splitter for coexistence of XG-PON1, GPON and 
video signals. 
  
 From the technological point of view, the fiber and 
the planar type of the WDM splitters are available. The 
first one is based on the TFF technology or on Fiber 
Bragg grating and usually consists of different (discrete) 
components for a particular wavelength. The second 
type is based on the use of Planar Lightwave Circuits – 
PLC which are mainly made on the basis of the 
Photonic Integrated Circuits – PIC technology. These 
WDM splitters in most cases contain arrayed waveguide 
gratings – AWG structure. Such multiplexers can 
manage a great number of channels and enable parallel 
processing. The advantage of these devices is possible 
integration with other passive or active components of 
the network. 
 In the past decade, PLC components fundamentally 
influenced the improvement of performance of the core 
network. As expected, such trend should continue in 
next generations of access networks. 
    
4.2 Structure of WBF  
As already mentioned above, TFF can be used in 
manufacture of low-cost WBF which is based on simple 
operations of filtration. The advantage of such WBFs is 
in its independence from the ONT unit. Usually it is 
formed by a sequence of very thin layers with low-
absorption of light. Their thickness can be compared to 
the wavelength of light. The layers are usually made of 
a sequence of materials of a high and low refractive 
index [14]. 
 Interference of the light entering into the multilayer 
structure constructed by certain number of altering thin 
layers has a spectrally-dependent response which is the 
characteristics of the filter (transmittance or reflectance 
of optical signals). Parameters, such as the number of 
layers, their thickness and consistence as well as optical 
features crucially affect the TFF permeability. This 
permits the TFF filter to be adjusted to certain needs or 
various applications. In other words, the filter can be 
designed so as to meet the required spectral 
transmittance or reflectance. 
 According to the FSAN/ITU-T recommendation 
G.984.2, the WBF insertion loss should minimally be 32 
dB outside the required passband width and maximally 
5 dB within the required passband width. It should 
qualitatively be the highest possible contrast factor 
(dB/nm). 
   
5 SUMMARY 
Further generations of the PON systems increase the 
network capacity mostly by increasing the bit rate 
transmission, split ratio and reach. The NG-PON1s 
already used the standardized XG-PON1 system but not 
yet the standardized XG-PON2 system. Compared to 
the well-established GPON system, they increase the bit 
rate to 10 Gbit/s, the split ratio from 1:64 to 1:128 and 
the reach from 20 km to 60 km. Despite these 
undisputable obvious advantages, implementation of the 
next generation PON systems into practice should in the 
first place be cost-effective.  
 In Slovenia, the question of the PON systems 
remains open. A couple of years ago, when the PON 
systems were not yet as firmly established as they are 
122  ERŽEN, BATAGELJ 
 
today, two operators, offering services via the optical 
link, decided to choose the point-to-point (P2P) 
architecture. Building a network based on the P2P 
architecture is compared to the PON systems often 
associated with higher costs resulting from higher 
consumption of the fiber, energy, active equipment, etc. 
The question still left open is what will be the interest of 
these providers in modernizing and transforming the 
existing optical architectures in accordance with the 
NG-PON technology and how it will be achieved.  
 Constructing a new PON network as well as 
optimizing the existing one is a most demanding task. It 
is important that migrating to the new technology is 
made in the simplest possible way preventing users 
from experiencing any difficulties. To achieve this, the 
standard regulating the new technology has to anticipate 
coexistence with the prior technology. 
 Preparation of the NG-PON2 standard is in progress. 
It should be based on a combination of the technology 
of time and wavelength division multiplexing – TWDM, 
to protect the interest of operators wishing to minimize 
their investing in upgrading the network. This is 
contrary to previous predictions that NG-PON2 will not 
coexist with the existing PON systems (GPON, NG-
PON1). 
 To achieve the GPON and NG-PON1 system to be 
compatible, the best solution seems to be the use of 
WBFs on the basis of the TFF technology at users and 
the WDM device to split signals of different sources in 
the central office [14]. To reach coexistence on the 
physical level it is important that operation is in the 
same ODN, and that management and encapsulation on 
transmission convergence layer are in NG-PON1 similar 
to that in GPON.  
REFERENCES 
[1] Nielsen, "Nielsen's Law of Internet Bandwidth". 
http://www.useit.com/alertbox/980405.html, Retrieved 2008-02-
27 
[2] VOLK, Mojca, GUNA, Jože, KOS, Andrej, BEŠTER, Janez. 
Quality-assured provisioning of IPTV services within the NGN 
environment. IEEE commun. mag., May 2008, vol. 46, no. 5, pp. 
118-126, 
[3] B. Batagelj, “Implementation concepts of an optical access 
network by point–to–point architecture,” Electrotechnical 
Review, Ljubljana, Slovenija,  pp. 259–266, 2010. 
[4] ITU-T Rec. G.984 series: “Gigabit-capable passive optical 
networks (G-PON)”. 
[5] ITU-T Rec. G.987 series: “10-Gibabit-capable passive optical 
networks (XG-PON)”. 
[6] B. Batagelj, “Pasivno optično dostopovno omrežje s časovnim 
razvrščanjem”, FE in FRI, Ljubljana, 2011.  
[7] ITU-T Recommendation G.984.6, »Gigabit-capable Passive 
Optical Networks (GPON): Reach extension«, 2008 
[8] ITU-T Recommendation. G.987.1: “10-Gibabit-capable passive 
optical networks (XG-PON)”. 
[9] J.-I. Kani, F. Bourgart, A. Cui, A. Rafel, M. Campbell, R. Davey, 
and S. Rodrigues, “Next-generation PON part I—Technology 
roadmap and general requirements,” IEEE Commun. Mag., vol. 
47, no. 11, pp. 43–49, Nov. 2009. 
 
[10] F. J. Effenberger, H. Mukai, S. Park, and T. Pfeiffer, “Next-
generation PON part II—Candidate systems for next generation 
PON,” IEEE Commun. Mag., vol. 47, no. 11, pp. 50–57, Nov. 
2009. 
[11] Frank J. Effenberger, “The XG-PON System: Cost Effective 10 
Gbit/s Access”, Journal of Lightwave Technology, Vol. 29, Issue 
4, pp. 403-409, 2011. 
[12] F. J. Effenberger, H. Mukai, J.-I. Kani, and M. Rasztovits-
Wiech, “Next-generation PON part III—System specifications 
for XG-PON,” IEEE Commun. Mag., vol. 47, no. 11, pp. 58–64, 
Nov. 2009. 
[13] M.D. Andrade, G. Kramer, L. Wosinska, Jiajia Chen, S. Sallent, 
B. Mukherjee, “Evaluating strategies for evolution of passive 
optical networks”, IEEE Communications Magazine, V. 49, I. 7, 
2011. 
[14] J. Mullerova and D. Korcek, “Super-separation thin film filtering 
for coexistence-type colorless WDM-PON networks,” 13th 
International Conference on Transparent Optical Networks 
(ICTON), pp. 1-4, 26-30 June 2011. 
[15] L. Wosinski, Ning Zhu, Zhechao Wang, “Wavelength selective 
devices for WDM communication systems”, 2009 IEEE 3rd 
International Symposium on Advanced Networks and 
Telecommunication Systems (ANTS), New Delhi, 14-16 Dec. 
2009. 
[16] ITU-T Rec. G.984.5, Amendment 1; “Gigabit-capable passive 
optical networks (G-PON): Enhancement band” , Oct. 2009. 
 
 
Boštjan Batagelj received his Ph.D. from the University of 
Ljubljana for work on optical-fiber nonlinearity measurements 
in 2003. Currently, he is an assistant professor at the Faculty 
of electrical engenering. His current research interests are in 
areas of next-generation optical access networks and optical-
technology-based timing systems. He has authored or co-
authored over 150 technical and scientific publications and is 
named as an inventor on four patents.  
 
 
Vesna Eržen obtained her B.Sc. degree in Electrical 
Engineering in 2012 at the University of Ljubljana, Slovenia. 
Her current research work is orientated towards extending the 
reach of communication link and increasing the number of 
users in a passive optical access network.