Application of Radio-Over-Fiber ROF in mobile communicationReza Abdolee, Razali Ngah, Vida Vakilian and Tharek A.Rahman Wireless Communication Centre Faculty of Electrical Engineering U
Trang 1Application of Radio-Over-Fiber (ROF) in mobile communication
Reza Abdolee, Razali Ngah, Vida Vakilian and Tharek A.Rahman
Wireless Communication Centre Faculty of Electrical Engineering Universiti Teknologi Malaysia
81310 UTM Skudai Johor reza.ab@ieee.org, razalin@fke.utm.my, v.vakilian@gmail.com, and tharek@fke.utm.my
Abstract - Future generation of mobile
communication system must be capable of serving
high quality and broadband services even in highly
dense populated area The radio-over-fibre is one of
the promising systems which can be used along the
emerging wireless technologies such as smart
antenna or multiple input multiple output (MIMO)
systems to meet these requirements In this paper,
the role of ROF technology in next generation of
mobile communication system is presented, and
then the concept is clearly interpreted Then, base
on previous research and finding, a probable ROF
architecture for present and future wireless mobile
communication is portrayed Along this,
challenges and development issues of ROF
technology are presented as well
Keywords: ROF technology, CBS, RBS, WDM, DWDM
1 Introduction
Base on cellular concept to increase the
capacity of mobile cellular system cell optimization
can be used to take advantage of frequency reuse
scheme As a result of this scheme, the number of
base station increases in the area Increasing
number of base stations with current RF technology
especially in millimetre-wave band is very costly
And technically, using millimetre-wave band signal
is inevitable because the current RF spectrum is
limited Base on these facts, radio-over-fibre (ROF)
technology is a best choice to apply in cellular
system for cell optimization process since it can
easily be used in millimetre wave band and in
addition it can reduce the system overall cost [1]
ROF technology gives a lot of advantages such
as; The complicated signal processing is localized
at the central base station (CBS) therefore the
overall system is cost effective, remote base station
(RBS) is very simple, passive and compact
therefore it is transparent to air and its maintenance
is easy The system is very cost-effective because
of localization of signal processing in CBS and also
simple base station, the reliability of the system is high due to simple and passive structure of the RBS This system can easily serve high dense populated area such as shopping mall and airports, dead-zone area and highways can be covered efficiently and economically, the system can support multiple wireless standards [2] Because of high bandwidth nature of optical fiber, Broadband services are more feasible using this technology The centralized CBS can decrease the number of handover within the cells [2] Radiated power from antenna is very low due to Pico and Micro cells structure Low radiated power of antenna make the system more immune for human body and also reduces the power consumption of mobile battery The co-channel interference can greatly be reduced due to low radiation power In pico and micro cell structure, Propagation loss is less because of small cell radius These are some of the advantages of this system which make it attractive for future mobile communication system
The remained material of paper describes the ROF technology in 4G, probable future ROF architecture, ROF structure, ROF future trend and challenges, and at the end paper concludes
2 Role of ROF Technology In 4G The minimum bit rate that 4G would provide for broadband services is 20 Mb/s for indoor and 2 Mb/s for outdoor application even with high relative mobility Figure 1 shows the trend of mobile communication system [3] As candidate technologies for future systems, 4G-cellular and Intelligent Transport System (ITSs), have been attracting much interest in the mobile communication field [4] Both of these technologies take advantage of ROF technique The concept in 4G cellular system is cell optimization
In ITS system, the key technology in road vehicle communication system is again ROF, in which many base stations are equipped along the trunk road in order to communicate with vehicles, and several control base stations manage these base
1-4244-1435-0/07/$25.00©2007 IEEE
Trang 2Figure 1: Trend of mobile communication
system
3 An Overview on ROF Mobile Technology
At Architecture Level
By using ROF technology, any type of radio
and millimetre wave signals can be transmitted
through optical fibres The structure of ROF system
in indoor and outdoor application is slightly
different Therefore, it should be explained in two
different sections
3.1 ROF Technology Structure in Indoor
Mobile Communication
In indoor communication and for frequency
below mm-wave, firstly, optical wave from a laser
diode (LD) is modulated directly by the radio
signal at the CBS and transmitted through the
optical fiber In remote base station (RBS), RF
modulated optical signal detected by photodiode is
transmitted into the wireless link by RBS antenna
However in indoor application three possible
structures can be considered to implement In the
first structure, RF signal usually in the range of 800 -
2200MHz is transmitted over single mode fibre,
second structure IF signal is transmitted over
multimode optical link and third structure the
signal is firstly digitized at CBS and then
transmitted over optical link This has the
advantages of digital transmission means that no
impairments due to noise and distortion but at the
expense of further complexity [5]
The most common of these architectures is the
first, RF over single mode fiber, because it is the
simplest to design and the lowest in cost
Consequently it put most stringent requirement on
the optical component It means that the system
needs the optical and electrical component which has a low noise and distortion in RF frequency The most dominant source of noise and distortion in ROF link is laser source Therefore by finding the suitable laser source which has right balance between cost and performance, the indoor ROF technology simply can be implemented
3.2 ROF Technology Structure for Outdoor Mobile Communication
In outdoor mobile communication, the frequency band which is considered for future mobile communication is in the range of 60 GHz known as mm-wave band frequency Direct modulation just functions for below mm-wave frequency [6], therefore for generating mm-wave frequency, external modulation or heterodyning techniques must be used In external modulation
RF signal and optical carrier are optical modulated using a Mach-zehnder modulator or an electro-absorption modulator The drawback of this system
is chromatic dispersion due to double-sideband transmission Therefore, the most popular technique can be heterodyning technique There are different structures for heterodyning modulation
In the first technique, two optical sources (DFB laser) in the operating range of 1550 nm as a master slave arrangement to produce RF signal are used in CBS This RF signal is modulated with the data The modulating RF signal can be detected by photodiode then it is transmitted by RBS antenna without any electrical mixer [7] The main drawback of this method is that it is not amendable
to all modulation format or modulation bandwidth and also chromatic dispersion is created in the signal because of mixing optical carriers with RF signal at the CBS
In the second structure, the RF carrier using two master slaves DFB is generated similar to first method However, in this technique data is not mixed with the RF signal and upconversion with the data is taken place in the RBS using conventional electrical mixer or in simpler arrangement using optoelectronic mixer Therefore, separate pair of laser source and photodiode is needed to transmit the data and carriers [6] Third technique is exactly the same as technique number two The only difference is in signal detection in the RBS where instead of photodiode an Electro Absorption Modulator (EAM) is used [6] This device can operate as a modulator in return path Therefore, the laser source in the RBS can be eliminated
Trang 33.3 Perspective of ROF Mobile
Communication
Integrated structure of indoor and outdoor ROF
mobile technology might have the structure which
portrayed in Figure-2 This system may use in the
future with some modification in topology For
example, RBS can be connected to central RBS
using BUS topology By applying this topology,
system cost is reduced by saving in applied optical
cable in the system As it can be seen from the
Figure-2 by using ROF repeater which is proposed
in [9] more than 300 base stations in cellular
system can be multiplexed by DWDM and
transmitted over SMF (Single Mode Fiber) to the
CBS In this structure, every base station uses one
single wavelength to connect to the CBS WDM or
DWDM is the core of this system In Every RBS,
single set of antennas can be used to receive
various RF signal in ITS communication [2] By
using ROF repeater, pre-existing FTTH fiber optic
can be used for 3G applications, even without any
change in EVM (Error Vector Magnitude) [9] One
of the components in Figure-2 is distributed
antenna system (DAS) which is used for indoor
communication and proposed in [3] DAS takes
advantage of optical switches which has a lot of
advantages in compared with RF switches High
level of isolation and very low cross talk are the
significant advantages
3.4 Remote Base Stations antenna (RBS)
Figure-3 shows the available Equipments in
RBS which can be listed as: one EAM
(Eletroabsorbtion modulator), one remote antenna,
diplexer, high power amplifier, low noise amplifier
and Power supply However, the trend of ROF
system is simplifying the RBS and changing it to
passive unit
Figure 3: The block diagram of remote base
station (RBS)
4 Future Trend of ROF Mobile Technology
Several issues for future ROF mobile
communication have to be addressed The first
issue is to simplify the RBS as much as possible The research direction aims to design passive RBS which is needed no maintenance and no service Compactness is another issue for RBS which is important in indoor mobile communication
To simplify the RBS a lot of researches have been done One solution is powerless RBS which is proposed in [9] Since this system can operate without electric power supply, it can be used in various situations In some researches the elimination of the optical source in the RBS using EAM [11], [6] is suggested In this method EAM act as a photodiode in downlink and operate as a modulator for the uplink Optical carrier which is need for the uplink is fed to the RBS from CBS remotely One of the proposed ideas in order to centralize the signal processing is predistortion in downlink and postdistortion in uplink to compensate the effect of laser and fiber nonlinearity [12]
One of the drawbacks of ROF system is costly CBS due to signal processing in RF frequency because of costly RF devices Therefore some researches are going on to substitute the electrical processing with optical one PDC (photonic down conversion) is the solution to eliminate the use of electrical RF component in the CBS [13] Using this technique the problem of chromatic dispersion
in the fiber also can be resolved [11],[13]
Another research direction in order to reduce the cost of ROF system is usage of Multi-Mode Fiber (MMF) instead of SMF Some researches have been done to use of pre-existing graded index fiber in the old urban area to reduce the cost [14] Also FFTH can be used by applying WDM In this structure proposed in [16] the use of OEO (Optical-Electrical-Optical) repeater and WDM for multiplexing different signal coming from different base station has been suggested In contrast, in new urban area which there is no communication infrastructure the system cost can be reduced by sharing the optical fiber from the RBS’s to CBS using Dense Wave Length Division Multiplexing (DWDM) over single mode fiber [15] By this technique 300 base stations can be connected to one CBS In indoor application to flexibility support the user and giving various services to the user the software controlled optical switch such as 3MEM has been proposed [3]
5 Some Challenges of ROF Technology
In order to design the ROF system with high transmission rate and high capacity to pervade in future mobile communication, there are a lot of technical problem which need to be resolved Some
of theses challenges are summarized in Table 2
Trang 4Table-2: ROF challenges for mobile communication system
Challenges Some proposed solutions
Modulation technique, Direct modulation is exist just for below mm-wave frequency External
modulation, optical heterodyne technique and EAM modulator can be solutions
Chromatic dispersion Single Sideband Modulation (SSB) modulation, photonic downconversion
Phase distortion[1] 1.Phase noise cancellation method 2.Side band injection locking 3.error
correcting coding 4.Optical Phase Locked Loop (OPLL)
laser and optical fibre nonlinearity Pre-distortion and post-distortion technique [6]
Noise Characterization and
Cancellation for combination of
Optical and wireless noise
Characterize the optical-wireless noise by making relation between optical link property and optical devices with wireless noise
multi-user detection in Non linear
optical-wireless Estimation
Optical wireless detection using correlation property of PN code
RBS compactness and cost Centralizing the signal processing at CBS , elimination of laser source and
electrical mixer in RBS, Elimination of power supply in RBS,
High data rate wireless link as a
complimentary part of ROF
Using MIMO-OFDM-CDMA and smart antenna system
Expensive and complex uplink Using photonic down conversion, electrical signal processing can be done in IF
frequency(reduce the cost)
Non availability of Opto-electrical
interfaces
The researches are going on to provide a small size and low cost opto-electrical interfaces
Optical switch design 3DMEM technology with low price and all optical switches for ultra fast
switching
Figure 2: Perspective of ROF technology in mobile communication
Trang 56 Conclusion
In this paper, the application of ROF technology in
mobile communication is explained Recent finding
and issues in ROF mobile communication are
discussed The feature of future ROF technology in
mobile communication is presented Some of the
challenges are listed down Also the ROF
technology architecture for future mobile
communication system is portrayed
References
[1] Braun, R.P.; Grosskopf, G.; Rohde, D.”Optical
millimeter-wave generation and transmission
technologies for mobile communications, an
overview”Microwave Systems Conference, 1995
Conference Proceedings., IEEE NTC '95 17-19
May 1995 Page(s):239 – 242
[2] Tang, P.K.; Ong, L.C.; Luo, B.; Alphones, A.;
Fujise, M.; “Transmission of multiple wireless
standards over a radio-over-fiber network”
Microwave Symposium Digest, 2004 IEEE MTT-S
International Volume 3, 6-11 June 2004
Page(s):2051 - 2054 Vol.3
[3] M Fujise, K Sato and H Harada, “New
Road-Vehicle Communication Systems Based on Radio
on Fiber Technologies for Future Intelligent
Transport Systems (ITS),”Proc 1st Int’l Symp
Wireless Pers Multimedia Commun.,
Nov 1998, pp 139–44
[4]Shingo Ohmori, Yasushi Yamao and Nobuo
Nakajima,”The Future Generations of Mobile
Communications Based on Broadband Access
Technologies” IEEE Communications Magazine •
December 2000
[5] Wake, D.; Webster, M.; Wimpenny, G.;
Beacham, K.; Crawford, L.; “Radio over fiber for
mobile communications” Microwave Photonics,
2004 MWP'04 2004 IEEE International Topical
Meeting on 4-6 Oct 2004 Page(s):157 – 160
[6] Noel, L.; Wake, D.; Moodie, D.G.; Marcenac,
D.D.; Westbrook, L.D.; Nesset, D.;Novel
techniques for high-capacity 60-GHz fiber-radio
transmission systems Microwave Theory and
Techniques, IEEE Transactions on
Volume 45, Issue 8, Part 2, Aug 1997
Page(s):1416 – 1423
[7] L No¨el, D D Marcenac, and D Wake,
“Optical millimeter-wave generation technique
with high efficiency, purity and stability,” Electron Lett., vol 32, pp 1997–1998, 1996
[8] Nakajima, N.”ROF Technologies Applied for Cellular and Wireless Systems” Microwave Photonics, 2005 MWP 2005 International Topical Meeting on 12-14 Oct 2005 Page(s):, IEEE 2005,Conference Proceeding
[9] Stephen Z Pinter and Xavier N Fernando, Toronto, ON “Fiber Wireless Solution for Broadband Multimedia Access” IEEE Canadian Review - Summer 2005
[10] Kuri, T.; Kitayama, K.;”Novel photonic downconversion technique with optical frequency shift for millimeter-wave-band radio-on-fiber systems”Photonics Technology Letters, IEEE Volume 14, Issue 8, Aug 2002 Page(s):1163 –
1165
[11]X N Fernando and A B Sesay, “Higher Order Adaptive Filter Characterization of Microwave Fiber Optic Link Nonlinearity,” in Proceedings of SPIE - The International Society for Optical Engineering,vol 3927-06, January 2000,
pp 39-49
[12] N Takahashi, Y Ozeki, H Yokoyama, T Taguchi, M Kishi, and M Tsuchiya, “60 GHz-band fiber optic mm-wave uplink with chirp-inverted photonic downconversion scheme,” (in Japanese), , IEICE Tech Rep MWP2000-3, Oct
2000
[13] Kuri, T.; Toda, H.; Kitayama, K.;”Dense wavelength-division multiplexing millimeter-wave- band radio-on-fiber signal transmission with photonic downconversion” Volume 21, Issue 6, June 2003 Page(s):1510 – 1517,IEEE JNL [14] Kaoru Imai, Yukio Horiuchi and Noboru Edagawa” Radio-over-Fiber Distribution System with OEO Repeater for 3G Cellular Systems” Optical Society of America , OCIS codes: (060.2330) Fiber optics communications, 2005 [15] G L Stuber, J R Barry, S W Mclaughlin,
Y Li, M A Ingram, and T G Pratt, “Broadband MIMO-OFDM wireless communications,” Proceedings of IEEE, vol 92, no 2, pp 271-294, Feb 2004
[16] G J Foschini, G D Golden, P W Wolnianshy and R A Valenzuela, “ Simplified processing for high spectral efficiency wireless communication employing multi-element arrays,” IEEE Journal of Selected Areas in Communications, vol 17, no 11, pp 1841-1852, Nov 1999