A coordinated satellite and terrestrial microwave backhaul for cellular mobile in remote and regional Australia
Large distances and low population densities continue to make the delivery of telecommunications services to much of remote and regional Australia both challenging and costlyi. Thus in many cases government subsidies play an essential role in the provision and operation of services.
In regard to cellular mobile services, a policy commitment of $100m for regional and remote cellular mobile black spot funding made shortly prior to the recent Federal elections by the then Coalition Opposition is significant (Coalition Mobile Blackspots. 2013), (Coalition NBN 2013). With the subsequent change of government it brings a change from prior Federal policy that left mobile coverage expansion to private network operators and state and territory governments, allowing regional and remote area coverage growth to slow significantly. ThusAustralians without mobile service in many remote and regional locations, having waited for more than six years for such a Federal Government programme, now have a commitment for action, albeit one that will require more funding over the longer term.
The new policy aligns with a recommendation for regional and remote mobile service expansion made by the 2011/12 Regional Telecommunications Review (DBCDE. 2012). It likewise responds to numerous other calls for urgent actionii. Also it complements recent state and territory levelinitiatives, including the Regional Mobile Communications Project for remote communities and highways in WA, jointly funded by the Western Australian Government and Telstra (Delimiter. 2012) and the joint Northern Territory Government - Telstra agreement to provide mobile coverage in eight remote communities (Giles A. 2013).
Whilst supporting all of these initiatives, we believe there are a number of implementation and technological and/or cost savings opportunities that ought to be considered in the rollout of the new funding programme. In this context, we propose that the program should commence with, or be preceded by, a comprehensive technical and financial assessment of all potential implementation options. This assessment should be undertaken with full government, industry and end-user group representation. It should consider:
A coordinated approach to backhaul, employing modern satellite and terrestrial microwave systems, the physical infrastructure of the existing Telstra High Capacity Radio Concentrator (HCRC) network, and other backhaul systems including those for the NBN fixed wireless broadband services.
The implementation of small-cell mobile base station types.
Satellite mobile services might arguably be included in this assessment as an alternative to expanding terrestrial cellular mobile coverage. However, the high tariffs associated with satellite mobile, particularly for calls terminating on the mobile device, limit their application largely to high value commercial and emergency operations.
It is beyond the scope of this paper to suggest any specific policies for allocating the available funding across the various regions of the country, or for increasing the funding by extending the Universal Service Obligation (USO) to embrace mobile services; e.g. see (ACCAN RTR. 2011), (Corner S. 2012). Our purpose is rather to highlight technical and provisioning opportunities to make the available dollars go further.
We make no reference to optical fibre backhaul, which is the preferred transmission medium for very high capacity long distance main routes passing through regional and remote areas and for numerous shorter high capacity spur routesiii. New optical fibre systems and questions of employing add-drop multiplexers or possible dark fibre in existing fibre routes will be addressed as a matter of course by any expert group tasked with undertaking the proposed assessment. Furthermore, the majority of localities most in need (of cellular mobile coverage) necessitate backhaul route distances appreciably greater than those for which optical fibre would be cost competitiveiv.
Our recommendations are discussed in greater detail in the body of the paper below. Although the Australian telecommunications industry is well versed in the particular systems referred to, the authors have not encountered any public proposals by others calling for them to be considered in the way put forward here.Complementary Backhaul System and Base Station Possibilities Satellite Backhaul
We propose that satellite backhaul be considered in the study for the following reasons: -
The technology?s distance-independence and ease of remote installation can make it the best type for high priority or temporary services. It can also be the most viable option for difficult locations such as islands, or very long routes in remote areas.
Satellite systems utilising modern flexible operational control features in conjunction with low cost VSAT ground terminals and micro-cell mobile base stations are uniquely suited for isolated locations with small populations.
The scheduled introduction in 2015 of two very high capacity Ka-band multi-beam satellites for Australian NBN fixed services may offer a window of opportunity to meet new mobile backhaul requirements.
Communications satellites have been employed for mobile backhaul for some decades. However for much of that time various limiting factors, including high satellite launch costs and inherently inflexible traditional transmission and call-routing systems, have confined applications to overseas countries with large population centres and inadequate terrestrial trunking infrastructure. In recent years many technical advances have made this form of backhaul much more attractive to network operators. These advantages are listed in Appendix II and include flexible dynamic transponder capacity assignment, local call routing, very high capacity multi-beam Ka-band satellites and various power saving features.
Furthermore, the parallel emergence of smaller ?Micro-cell? cellular mobile base station types, discussed further below, has contributed markedly to the practicality of servicing small remote communitiesv (Anderson T. & Mavrakis D. 2009), (Bright, J. & Mavrakis, D. 2012), (Chambers D. 2012), (Informa 2012). Remote cellular mobile networks with satellite backhaul are now being extensively employed in many overseas countries including Africa, S.E. Asia and South America (Milano Teleport, 2011), (Holmes M. 2012), (Gilat 2013), (Intelsat 2010), (Cox J. 2011).
The technology has begun to be employed in Australia, albeit on a very limited basis. For example Optus provides mobile services via satellite backhaul both to Birdsville (Venkatramani V. 2010)and to the Kimberley Diamond Company remote site (Optus 2011). Also Telstra and Ericsson provide 3G mobile services via satellite backhaul, again to Birdsville (Telstra 2011), (Venkatramani V. 2010).
These Australian installations are of recent origin. Furthermore, although Birdsville is a small outback township, its annual race meeting has an iconic national reputation: at race time the population expands many times with an influx of thousands of visitors. With such an elevated national profile it is logical that network operators would endeavor to establish their presence there. Thus the existence of satellite backhaul at Birdsville is not a reliable indicator that network operators are likely to establish such facilities in other similarly small outback townships.
In regard to the Kimberley Diamond Company site, we understand that the provision of cellular mobile facilities there is not unusual. Such remote mining sites are frequently staffed by well remunerated work forces relying on good phone communications to their far distant homes, particularly during their on-site leisure hours. Hence sites of this type should offer network operators good returns on investment, an attraction not generally shared by small non-mining remote Australian townships, communities, roadhouses and homesteads.
Having promoted consideration of satellite backhaul links, we are conscious they introduce or exacerbate a number of transmission impairments such as latency, jitter and packet loss. The high levels of compression typically used on these links also contribute. Although industry specialists have been addressing these issues for many years, the advent of broadband services has required new innovations for maintaining quality of service (QoS) e.g. see (LingSun Tan et. al. 2011), (iDirect. 2009) & (O3b & Sofrecom). The new Australian NBN Satellites are doubtless being designed with advanced measures to guarantee satisfactory QoS for their intended fixed broadband applications. However if our recommendation for them to also be considered for cellular mobile backhaul is adopted, additional mitigation features may be required. Thus addressing these factors would form an important and timely part of the proposed study.Terrestrial Microwave Radio Backhaul
Terrestrial microwave radio systems will often offer the most economical means of providing the medium capacity backhaul function required for many remote and regional locations. These systems are being employed extensively both overseas and in Australiavi and various advances have yielded increased benefits for network operators (Knoll Y. 2009), (Croy P. 2011), (Aravantinos E. 2011). A number of the advances listed for satellite systems in Appendix II also apply to modern terrestrial systems. In addition, the ability to integrate modern power-efficient transceivers with their antennas makes it possible for all transmission equipment to be mast-mounted. This eliminates or at least reduces the cost of security fenced ground enclosures and it also appreciably lowers transceiver-to-antenna signal loss, reducing transceiver transmit power and with it attendant site powering requirements.Potential for Upgrading HCRC Terrestrial Network for Mobile Backhaul
Many localities in remote Australia receive telephony and low-speed data services via the High Capacity Radio Concentrator (HCRC) network, which came into being when its predecessor, the Digital Radio Concentrator System (DRCS) was upgraded with improved transceivers and associated equipment. Although this terrestrial microwave network has been replaced in some locations by other transmission facilities, much of it continues to fulfil the Universal Service Obligation (USO) for Standard Telephone Services (STS) and Public Payphone services.
With so many transceiver sites distributed throughout remote areas, powering and equipment problems have from time to time affected the operation of this network; e.g. see (Featherstone D. 2011), (Hutchinson J. 2012). However it is understood that the physical infrastructure (towers etc.), is well maintained. In fact the Hutchinson article describes Telstra?s 2009 plans to ?..... replace the decade-old HCRC networks with phone services based on a connection to the Next G mobile network or with copper services underpinned by microwave backhaul? (ibid.). This project reportedly covered 200 HCRC networks servicing a total of 9000 remote residents, which indicates its large proposed scale. Although these modernisation plans were eventually halted, their existence suggests the feasibility of upgrading the existing HCRC physical infrastructure with modern microwave backhaul equipment. The prospect therefore exists for reducing the cost of introducing cellular mobile through the shared use of existing HCRC tower/physical infrastructure.Flexible Mobile Base Station Sizes - Use of Small Cells
Traditional ?macro-cell? mobile base stations, now installed throughout the more populated areas of practically all countries, provide large cell coverage and commensurate service capacities. However, their relatively high cost and power consumption usually makes them unattractive for serving small isolated populations.
In comparison, the smaller micro-cell, pico-cell and femto-cell base station types, which were originally developed for boosting network capacities and alleviating shadowed black spot coverage problems within existing macro-cell footprints (Radio-Electronics.com) have been proposed for small isolated user populations. It is the reduced cost (including the cost of powering them) that is making the smaller cell types well suited to these latter applications (Talbot D. 2010), (RADWIN Ltd 2009), (Aravantinos E. 2011), (Anderson T. & Mavrakis D. 2009), (Bright, J. & Mavrakis, D. 2012).Complementarity of Satellite and Terrestrial Microwave Backhaul
The complementary nature of satellite and terrestrial microwave backhaul systems derives from their different characteristics and associated costs. In this section we discuss this complementarity conceptually, assuming that the various expenditure items are as outlined in Appendix III.
Satellite backhaul systems require low incremental (i.e. per end-customer) capital expenditure, especially for Very Small Aperture Terminal (VSAT) ground stations. Their operating costs are nevertheless high because leasing satellite transponder capacity is relatively expensivevii. In comparison, terrestrial microwave systems generally require significantly higher capital outlays, especially when the backhaul distances and/or terrain requires several line-of-sight paths or hops. However terrestrial system operating costs almost invariably fall well below those for satellite systems of comparable capacity. The features of the respective systems are qualitatively summarised in Table 1viii.
Table 1. Summary of satellite and terrestrial microwave system relative costs
Leased satellite transmission capacity
Low (distance independent)
Re-locatable at low cost
New Terrestrial Microwave
Medium for short distances Increases to High with increasing number of system hops
Low for short distances
Increases to Medium with increasing number of system hops
Medium-to-High cost to upgrade or re-locate (depends on number of system hops)
Upgrade to existing Terrestrial Microwave system
Low for short distancesP>
Increases to Medium with increasing number of system hops
Low for short distances
Increases to Medium with increasing number of system hops
Medium-to-High cost to re-locate (depends on number of system hops)
The capital and operating expenditure relativities set out in the first two rows of Table 1 demonstrate an important complementarity between the two system types. The satellite systems are ideal for rapid deployments into new locations, or for sites where the need is temporary, such as at remote mines. In comparison, the terrestrial microwave systems become practical over the longer term due to their lower operating costs (Anderson T. & Mavrakis D. 2009), (Milano Teleport, 2011), (Holmes M. 2012).
The capital expenditure to upgrade an existing terrestrial system, for example by replacing older transceivers and antennas with modern higher capacity equivalents, will be much less than that required for a completely new system. The final row of Table 1 covers this situation.
A graphical representation of the complementary nature of these systems is given in Figure 1, which shows the notional accumulation of capital-plus-operational expenditure with time. Note that the Satellite system incorporates adaptive capacity assignment, as listed in Appendix II. This reduces transponder leasing costs (and hence operational expenditure growth) for the period from initial start-up until the point of service-demand maturity is reached.
Figure 1. Notional Comparisons of Aggregated Capital + Operational Expenditure for Satellite and Terrestrial Microwave Backhaul Systems of the same maximum transmission capacity. (Satellite system costs assume a capacity-dependent lease component growing from initial start-up until maturity)
The relative costs in Table 1 and the trends depicted in Figure 1 are both conceptual and approximate. As Appendix A-III indicates, the comparisons assume terrestrial microwave systems of the basic point-to-point type. Furthermore, the respective core-network portions of the total backhaul costs are not included. So our basic purpose here is to outline the potential complementary nature of the two forms of backhaul.
The proposed study would undertake more accurate assessments. These would account for all actual factors, such as the servicing of locations with small or very small populations, or those distributed along the course of a terrestrial route and the potential for employing point-to-multi-point terrestrial systems.Coordinated deployment
A coordinated approach employing the appropriate mix of satellite and terrestrial backhaul types would require a major financial and technical pre-study, as outlined above. Following this, the deployment program should include the following stages:
Select candidate remote locations for new cellular mobile facilities, taking both population centres and transport movements into account. Identify the backhaul system type initially most suitable for each location e.g. satellite for locations without prospects for timely connection via terrestrial backhaul, or say upgraded HCRC terrestrial microwave for locations with short link distances.
Deploy cellular base stations at identified locations and connect via relevant backhaul type.
For locations initially connected via satellite, consider progressively extending terrestrial facilities. When these become available, transfer backhaul from satellite to terrestrial. At that stage the relevant satellite facilities could then either be moved to service new locations or remain in place to provide back-up route diversity.
This coordinated approach would deliver a cost effective sequence of backhaul solutions.
An initiative of this type would ensure participation by the industry. In particular, it would cause satellite backhaul for cellular mobile to be considered by the Communications Alliance (CA) Satellite Services Working Group (SSWG) set up in 2012.ix Examination by this major influential industry body would offer the best means of ensuring any technical issues specific to cellular mobile backhaul via satellites would be taken into account. This is timely, considering that the prelaunch design and construction phase of the new Ka-Band Australian Satellites is currently taking place. Furthermore it would ensure the consideration of other potential satellites, such as the new Medium Earth Orbit (MEO) types recently launched by O3b (O3b Networks. 2011).
The cost advantages afforded by modern technological innovations make it likely that service coverage could be extended to many localities without unduly high government subsidisation. It is possible the Commonwealth Government could recover some costs by leasing out temporarily unused capacity when the new NBN Ka-Band satellites first come into service.Conclusions
The $100M joint initiative planned by the newly elected Australian Government to address regional and remote cellular mobile service black spots is important. The allocated funding should serve for a substantial first stage, though subsequent further funding will be required.
To maximise cost benefits the joint program should commence with a comprehensive financial and technical investigation of backhaul and base station technology options to identify the most cost effective approaches. The scope of the study should include the provisioning of satellite and terrestrial systems in a complementary coordinated manner, shared use of existing or planned infrastructure such as the NBN and HCRC networks, and small-cell mobile base stations.
We are grateful for various helpful comments and suggestions from:
Prof. Reg Coutts of Coutts Communications,
Tony Bundrock of Activ8me,
Ray Heffernan of the Remote Area Planning and Development Board (RAPAD),
Apolline Kohen of Ninti One, and
Alan Howard of the Australian Communications Consumer Action Network (ACCAN).
We also wish to acknowledge the encouragement of Mike Crowe and John Huigen of Desert Knowledge Australia during the preparation of this paper. We have also had helpful discussions with the Northern Territory Chief Minister, Adam Giles on telecommunications requirements in outback Australia and with John Stanton of Communications Alliance. In addition a number of beneficial suggestions on content and style have been made by two reviewers and Professor Peter Gerrand, Managing Editor, Australian Journal of Telecommunications and the Digital Economy.References
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ACCAN Australian Communications Consumer Action Network
B4B Broadband for the Bush
B4BA Broadband for the Bush Alliance
DCDBE Department of Communications, Broadband and the Digital Economy
DRCS Digital Radio Concentrator System
HCRC High Capacity Radio Concentrator
MEO Medium Earth Orbit
NBN National Broadband Network
NT Northern Territory
QoS Quality of Service
RAPAD Central Western Queensland Remote Area Planning and Development Board
STS Standard Telephone Service
USO Universal Service Obligation
VSAT Very Small Aperture Terminal
WA Western AustraliaAppendix I - Delineation of Australian Remoteness Areas
Figure AI-1. Remoteness Areas of Australia (Australian Bureau of Statistics)Appendix II - Advances in Modern Communications Satellite Technology
Table AII-1. Advances of Modern Communications Satellite Technologies
TDMA transmission (as opposed to traditional Single Channel Per Carrier)
Facilitates implementation of flexible dynamic space-segment capacity assignment on demand, i.e. backhaul clients only pay for actual used capacity.
Enhances viability of backhaul from numerous small cellular mobile base stations generating low individual revenue streams.
Saves local and satellite power consumption.
Enables remote control of some system O&M functions such as adding additional channels for higher maximum capacity.
Particularly suited ease of integration and operation with the growing IP based networks such as IP/Ethernet.
Transponder circuit board miniaturisation, Gallium nitride power amplification
Reduced launch costs
Greater transponder power efficiencies
Increased satellite maximum capacity.
Local (i.e. terrestrial) call routing at remote Cellular Mobile Base Stations
Reduces space-segment traffic.
Saves local and satellite power consumption.
Removes double satellite-path latency from local calls.
Adaptive fade margin control
Saves local and satellite power consumption.
Enhances space-segment spectral efficiency when each satellite beam serves numerous remote sites distributed across the ground service area.
Optimised voice and data compression
Promotes greater space-segment transmission efficiency.
Ka - Band Satellites
Much higher capacities due to the combined effect of greater available bandwidths & the practicality of employing significantly increased numbers of spot-beams.
Because the introduction of these new satellite types has begun quite recently they are designed and built to include the latest innovations for providing improved transmission efficiencies.
Medium Earth Orbit (MEO) satellites
Lower launch costs leading to lower cost capacity leasing
Much reduced transmission latency
For the purposes of discussing comparative costings of satellite and terrestrial microwave backhaul systems we make the following assumptions: -
Satellite system transponder capacity is leased. Thus the high space segment development and launch costs and the main earth station development and construction and its ongoing operational costs are all amortised by the leasing, which is therefore accounted as OpEx by the backhaul Network Operators.
Installation of satellite system remote earth terminals is undertaken by the backhaul Network operator and accounted as CapEx. Ongoing remote earth terminal operational costs are accounted as OpEx.
The remote location served is typical of a remote township or community, say with a population of the order of one to two hundred.
The terrestrial microwave systems are of the basic point-to-point type running via a number of successive hops from the core network boundary to the remote location.
New terrestrial microwave systems are installed and operated by the backhaul Network Operator. So all construction, equipment and installation costs are CapEx and all ongoing operational costs are OpEx.
For an upgraded existing terrestrial microwave system it is assumed that all costs incurred in replacing older infrastructure components and equipment with new counterparts, changes such as tower strengthening or alternate guying and new system start-up costs are accounted as CapEx. OpEx costs are assumed to be the same as those for a comparable new terrestrial microwave system covering the same terrain and total route distance.
i Within Australia somewhat variable interpretations have come to apply to the terms ?regional? and ?remote?. In the present context and to be more definitive, the areas most likely to be without cellular mobile services will generally be in parts of the ?Outer Regional?, the ?Remote? and the ?Very Remote? categories defined in the detailed Australian Bureau of Statistics map shown in Appendix I.
ii ACCAN (ACCAN. 2013) the 2012 Broadband for the Bush forum and the Broadband for the Bush Alliance (B4BA. 2013) are examples of bodies that have recently voiced calls for regional and remote cellular mobile coverage to be addressed. Somewhat earlier calls have been made by the NSW Farmers? Association (Gibson A. 2011) and Engineers Australia (Engineers Australia. 2010).
iii Some examples of optical fibre routes in remote and regional Australia are shown in the telecommunications infrastructure map appended to the Central Western Queensland Remote Area Planning and Development Board (RAPAD) response to the 2009 Australian Government Backhaul Blackspots initiative (RAPAD. 2009).
iv We are unaware of any definitive public domain source covering backhaul media cost comparisons. However approximate indications can be deduced by examining material from various sources. For example helpful CapEx estimates for various optical fibre and terrestrial microwave system types traversing farmland or desert terrain, with tower costs for the latter systems included, are provided in the CSIRO submission by Guo (Guo J. 2009). Furthermore, the modeled total annualized cost estimates provided by Mavrakis, White and Banlamlih for a typical Tier-1 UK Mobile Operator (Mavrakis D. White C. and Benlamlih F. 2010.) and the less detailed CapEx comparisons given in slides 30 to 32 of the set produced by Pigg (Pigg J.M. 2010) while not being directly relevant to rural Australia, nevertheless point to appreciable cost advantages of terrestrial microwave over optical fibre systems generally.
v In certain cases the installation of a Macro-cell base station may still be warranted. For example if a small remote community is near a significant highway, then the additional coverage range may justify the larger and more powerful installation.
vi One good example showing terrestrial microwave systems in a part of regional and remote Australia is provided by the map included in the Central Western Queensland Remote Area Planning and Development Board (RAPAD) response to the 2009 Australian Government Backhaul Blackspots initiative (RAPAD. 2009). The map shows various existing terrestrial microwave backhaul links feeding out from optical fibre main routes. It also shows HCRC and DRCS system routes in the Central Western Queensland area.
vii Satellite transponder capacity is almost invariably leased by Network Operators from specialist companies or in some cases government entities that bear the high development, construction and launch costs.
viiiAlthough the comparisons provided by Table 1 are of a qualitative rather than a quantitative nature, they are founded on numerous reports including some of those referenced here. There is some natural variability of emphasis across all of this material. However practically all other accounts sighted by the authors support the results provided here and none have been contradicting. Therefore these present comparisons are considered to provide adequate justification for undertaking the further in-depth investigations advocated.
ix Currently the issues being addressed by the SSWG include:
1. Advocacy on behalf of the satellite sector, including via input to State and Federal Government policy development and Inquiries, and through representation of satellite sector interests on the ACMA?s Radiocommunications Consultative Committee (RCC)
2. Participation on the ACMA Australian Radiocommunications Study Group 4, Satellite services (ARSG 4)
3. Contributing to the ACMA spectrum management planning work program, including their Five-year Spectrum Outlook 2012-2016
4. General promotion of the role and importance of satellite services for Australia through the Satellite Industry Promotion Campaign
5. Liaison with NBN Co on operational and commercial issues relating to the satellite-based components of the National Broadband Network
6. Expert input into the creation or revision of Communications Alliance Codes, Guidelines and Standards that have implications for satellite-based services
7. Collaborative activities to foster the development and growth of the satellite sector in Australia and to resolve technical or commercial issues of common interest
8. Monitoring of international standards work relevant to the Australian satellite sector.