Advanced technologies for 4G: Mobile broadband multimedia
Transcription
Advanced technologies for 4G: Mobile broadband multimedia
Advanced technologies for 4G: Mobile broadband multimedia everywhere by Vish Nandlall, Ed Sich, Wen Tong, and Peiying Zhu Nortel’s Wireless Technology Lab (WTL) is working on numerous innovations that will fundamentally rewrite the economic equation for wireless access infrastructures and pave the way for ubiquitous deployment of networks that support true broadband. From the industry’s most compact 4G base station, to new antenna designs, sophisticated scheduling algorithms, advanced beamforming, and mobile multi-hop relay, the WTL continues to pioneer breakthroughs that will dramatically lower the cost per bit of over-the-air transmission, while improving spectral efficiency and boosting data rates, capacity, coverage, reach, and throughput. For operators of all kinds – whether traditional 3G and 2G operators, or new entrants – these technologies form the underlying pillars for evolving to and rolling out high-performance, multimedia 4G wireless networks and, ultimately, for supporting an affordable true broadband experience anywhere. ven though the fourth-generation (4G) wireless story has not yet been written in stone – 4G is still being defined – the industry is clearly moving aggressively to a 4G world. Both the pace of 4G adoption and the rate of standards development are by 4 Nortel Technical Journal, Issue 6 far faster than all previous generations of wireless. Whereas it took nearly 10 years for 3G to roll out and become standardized, 4G activities are proceeding on an accelerated three-year cycle. For instance, the first instantiation of 4G – the rollout of Worldwide Interoperability for Microwave Access (WiMAX) systems – is already well under way in the networks of many wireless operators, and several new entrants are planning nationwide and even continent-wide WiMAX networks. At the same time, standardization and technology initiatives for other 4G technologies are proceeding rapidly. The 4G evolution of the UMTS standard, called the Long Term Evolution (LTE) project, is now being standardized within the 3rd Generation Partnership Project (3GPP). And the 3GPP2 has standardized Ultra Mobile Broadband (UMB) to improve CDMA for 4G applications and requirements. As this pace continues, many in the industry consider the year 2010 to be the inflection point for 4G mobile broadband – the point at which 4G will replace 2G and 3G infrastructures. Some analyst reports put the size of the 4G market at about $60 billion by 2015. Changing the wireless experience The drive to 4G is being fueled by the promise of target peak data rates of approximately 1 Gigabit per second (Gbit/s) for low mobility (such as nomadic/local wireless access) and approximately 100 Megabits per second (Mbit/s) for high mobility (such as vehicular mobility). These data rates are part of the International Telecommunication Union (ITU) long-term vision (2010-2015) for 4G, as outlined in the ITU’s IMT-Advanced requirements. (IMT stands for International Mobile Telecommunications.) At these speeds, downloading a 600-MByte full-length movie would take about 45 seconds, compared to more than 20 minutes in a 3G network. Fourth-generation wireless is not solely about data rates, and it is certainly not just “faster 3G.” Today’s cellular 2G and 3G networks offer excellent quality for mobile voice and narrowband data in the form of text messaging and emails, and even rudimentary web browsing and video transmission. By contrast, 4G networks will change the game entirely. This next wireless generation – the first to be based on an all-IP network and support all types of traffic on a single converged infrastructure – will substantially alter the definition and experience of mobile communications. The 4G user experience will be characterized by seamless, high-bandwidth network connectivity, with access to any application regardless of device and location. High-quality and reliable delivery of unified communications sessions, virtual-reality experiences, real-time video streaming, high-speed data, multimedia messaging, and high-definition mobile television will all become commonplace and affordable for wireless subscribers. The transition to 4G will also be critical for supporting what is fast becoming a hyperconnected communications environment. More and more devices and machines, many of them mobile, are becoming IP-enabled and connected to the network, far exceeding the number of humans using the network. As this trend continues, we will see an exponential growth in the number and types of users, applications, and services, and a greater drive toward much richer experiences and more extensive mobile lifestyles. The plethora of new, rich mobile applications and services that can be made possible with 4G is, not surprisingly, attracting many players – both existing and new. Traditional wireless carriers are being joined by new entrants that are acquiring non-traditional spectrum and moving into the broadband wireless space, including operators such as cable and satellite providers that are extending their infrastructures into the wireless world. A recent example is Rogers Communications and Bell Canada, which are pooling their broadband resources to build a new national wireless network, called Inukshuk, in Canada. This network aims to deliver access to voice, video streaming, and Internet data via mobile devices to customers in some 40 urban centers, as well as in 50 rural and remote communities. At the same time, non-traditional Internet and IT companies like Google, Yahoo, Microsoft, and Apple are coming to the wireless arena with entirely new business models. 2G operators also are keenly interested in accelerating the transition to 4G and evolving to true broadband using technology that allows them to leapfrog the incremental step to 3G without having to rip out their 2G equipment. 4G technology challenges All of these existing players and new entrants have their eyes on opportunities brought on by the transition to 4G, with its unprecedented jump in bandwidth, capacity, and multimedia capability. (The table on page 19 shows a comparison of wireless and wireline performance metrics.) As 4G technologies and standards mature, the industry will take a giant step closer to realizing the long-held vision of a single, converged, packet-based “fat pipe” that will carry all wireless multimedia services with high quality and reliability, will scale easily to accommodate subscriber growth, and will provide users with whatever bandwidth they need, wherever they need it, simply and cost-effectively. Most importantly, 4G promises a “true” broadband experience, where mobile services will be delivered with enough capacity and transparency that users will be unaware of the underlying network. This next era in the wireless industry is an exciting one from a technology perspective. The capabilities of 4G will not be achieved through a series of incremental improvements in capacity, spectral efficiency, and throughput. Rather, the disruptive shift to a 4G architecture affords the opportunity to rethink and revamp nearly every function in the wireless access network, from the radio and antennas to the point of backhaul and every stop in between. Put simply, this next wireless network will be designed differently. Interestingly, there are as many different schools of thought on 4G as there are providers. For some, 4G means highcapacity metro hot spots. For others, 4G is about enabling cheaper voice service, or achieving a better experience when viewing or uploading YouTube clips. Still others are looking to 4G for mobile video, broadband for the extended enterprise or home, or as a digital subscriber line (DSL) replacement. Nortel believes that if technology is built to solve only one of these scenarios, 4G will not be successful in the long term. Rather, 4G is about enabling all of these scenarios, by developing a common technology base to support all future 4G configurations, standards, and deployment strategies. Nortel’s commitment and approach to developing fundamental enabling technologies was demonstrated with its pioneering efforts with OFDM and MIMO (orthogonal frequency division multiplexing, and multiple-input multiple-output antenna processing Nortel Technical Journal, Issue 6 5 technology), which have become the foundation for all 4G technologies. Beginning some eight years ago, Nortel researchers achieved many industry firsts in OFDM-MIMO. (For more on Nortel’s OFDM-MIMO leadership, see page 26 in Issue 2 of the Nortel Technical Journal.) As well, almost a year ago, Nortel became the first in the industry to complete live calls using MIMO advanced antenna technology to deliver high-bandwidth multimedia over all of the major 4G technologies – WiMAX, LTE, and UMB. Now, researchers in Nortel’s Wireless Technology Lab (WTL) are building a set of fundamental technologies that will establish a flexible base upon which not only to achieve the promise of mobile multimedia and high bandwidth, speed, and capacity across all 4G technologies, but also to significantly alter the economic paradigm for mobility solutions. In these efforts, the WTL team is ensuring that all innovations meet a common set of requirements. Specifically, the team is developing disruptive technologies that deliver a number of important benefits. Provide dramatically lower OpEx and CapEx: A top priority for operators is to provide subscribers with mobile broadband multimedia services that are both affordable and ubiquitous. Operators are faced with rising consumer pressure for mobile services delivered at the same prices that they pay for similar services in the wireline domain. Consumers are increasingly pushing the market, expecting to be able to do much more with their mobile devices than ever before, but with no increase in service price. For instance, consumers have come to expect a growing richness of functionality from the network and their devices, so that they can upload photos and movies, surf the Internet, engage in social networking by interacting with friends and colleagues via instant messaging, and so on – and they expect the price of these services to fall over time. Increasingly, they also expect to be able to access these services everywhere they roam. 6 Nortel Technical Journal, Issue 6 Jim MacFie, advisor, standards management and tools, inresearcher, Nortel’s Harpreet Panesar, radio frequency hardware technology Strategic Standards group, power addresses a Global examines a high-efficiency amplifier (PA)Standards prototypeCollaboration developed for (GSC) meeting in France. future base station PA systems. This requirement leads to an interesting technology challenge: how to provide a significant leap in capability and performance, while at the same time driving down cost and complexity to keep network capital and operating costs equal to, or preferably lower than, those of today’s 3G networks. Certainly, OFDM-MIMO brings a significant improvement in spectral efficiency. Nortel is also leveraging new silicon technologies (taking advantage of the ongoing progression of Moore’s Law) and advances in materials technologies, which will be important from the standpoint of lowering overall cost of ownership. Support a wide variety of spectrum bands: Spectrum is a key challenge for 4G systems, because of both the differing bandwidth requirements and the spectrum bands available globally. Whereas previous wireless generations – 1G, 2G, and 3G – all globally operate roughly in two major bands [the 800 to 900 Megahertz (MHz) band and the 1.7 Gigahertz (GHz) to 2.1 GHz range allocated for Personal Communications Services (PCS)], new spectrum is spread across several additional bands – specifically, in parts of the 400 to 700 MHz range and in the 2.3, 2.5, 3.5, and 4.4 GHz bands. Unlike previous generations of wireless, 4G systems therefore will not lend themselves to a single product in a globally coordinated frequency band. As a result, 4G products must be deployable in different markets and adjustable to a wide range of different frequency bands. Moreover, these new frequencies have completely different over-the-air transmission characteristics compared to traditional bands, raising new challenges in ensuring a high quality of service. Develop cost-effective high-performance cell-site solutions: 4G will demand extremely high levels of performance and capability from the cell-site equipment. Multi-branch antennas, for instance, will be required at the cell site to provide the greater coverage and range needed to support the growth in both subscribers and capacity. Adding of their starting points – whether 2G, 2.5G, or 3G – operators will be seeking a migration path to 4G that is costeffective and does not require a “rip and replace” of existing equipment. 4G solutions, therefore, need to co-exist with today’s infrastructures to enable operators to preserve their spectrum and extend their existing investments. Enabling 4G technologies Art Fuller, digital signal processing hardware technology researcher, evaluates digital-to-analog converter technology for use in future wireless systems for 4G and beyond. antennas, however, raises significant issues with cabling from the base station to support those antennas. In conventional systems, such additions would place an impractical burden on the cell tower itself. There is an opportunity, therefore, to devise new cell-site architectures and technologies that integrate the base station with the antenna for placement at the tower top, thereby reducing and even eliminating the need for extra cabling. Enable higher capacity for hot-spot deployment: In a 4G-enabled wireless environment, the amount of highbandwidth, high-speed data traffic is expected to soar, especially for the high concentrations of users in dense urban environments and in-building office scenarios. This will require the development of technologies that provide higher throughput to users in these areas and ensure high quality of service at lower costs. Support VoIP applications: Voice, which has been the raison d’être of cel- lular and wireless communications since the beginning of the industry, is also undergoing a transformation. With 4G, voice transmission will, for the first time, be carried over the same infrastructure as all other traffic. No longer will separate parallel circuit-switched and packetswitched networks be required for voice and data. Instead, all traffic will be carried on a single all-IP wireless network. Even more, 4G air interfaces, such as LTE or UMB, can deliver VoIP capacity that is three times greater than that of 3G interfaces. To reach these capacity levels, however, and to meet and even exceed the quality and reliability that users have come to expect in the 2G and 3G worlds, several difficult technical challenges need to be met to accommodate the different traffic behaviors and to deliver real-time voice and video. Here, innovations are required in the area of digital signal processing and scheduling algorithms. Provide a cost-effective 4G migration path from 2G and 3G: Regardless These requirements form the backdrop for Nortel’s 4G research efforts, where teams are focusing on developing the core technologies that will ultimately allow operators to come at 4G from many different angles while delivering a “true” broadband experience. In particular, Nortel is developing: • new base station and terminal radio technologies; • advanced antenna designs, integration strategies, and configurations; • sophisticated digital signal processing techniques; and • solutions for mobile multi-hop relay. Base station technologies The focus on new base station technologies is a major research effort, primarily because the base station represents the majority (upwards of 70 percent) of the costs – both CapEx and OpEx – of the entire wireless infrastructure. Industry’s most compact 4G platform: In the area of base stations, researchers are focusing on several innovations – including a simpler, more cost-effective base station architecture, use of advanced silicon technology, a new network timing and synchronization solution, and more efficient power amplifiers. These innovations have culminated in the first 4G technology platform, and the industry’s most compact and efficient base station solution for WiMAX. Nortel’s new Base Transceiver Station (BTS) 5000 represents a major departure from traditional base station design, offering a dramatically smaller footprint that gives operators more flexible continued on page 10... Nortel Technical Journal, Issue 6 7 Technology innovations behind Nortel’s WiMAX base station: The industry’s most compact and efficient 4G platform by Steve Beaudin, David Choi, Brian Lehman, and Brad Morris “Where’s the rest of it?” is becoming an increasingly common reaction to Nortel’s new WiMAX Base Transceiver Station (BTS). Compared to the “fridge-sized” base stations that have been the norm for some time, the BTS 5000 is the most compact the industry has seen yet – supporting three sectors per cell site with two transmit and two receive paths per sector, packaged in just 6 rack units (Us) of a standard 19-inch rack. [One U is 1.75 inches (44.45 mm) high.] The WiMAX BTS 5000 is the industry’s first 4G platform – a three-sector, full-power, fully multiple-input multipleoutput (MIMO)-compatible unit that offers operators a dramatically smaller footprint, significantly lower CapEx and OpEx, and a radically higher fivefold increase in data capacity. The BTS design represents a new architectural approach, one that takes advantage of not only technology and materials-packaging advances, but also the generational jump from 3G to 4G technology – a once-in-a-decade opportunity to rethink the way products are designed and technology is used. Specifically, the evolution from code division multiple access (CDMA) to orthogonal frequency division multiple access (OFDMA) has enabled a fundamental shift in the architecture of base stations by changing the capacity growth strategy. In the CDMA world, because the signal characteristics over the air are fixed, capacity growth is achieved by adding radios (increasing bandwidth by increasing the number of carriers) and adding modems (to boost data rates). By contrast, with OFDMA, capacity growth is achieved by changing the modulation parameters to increase the bandwidth of a single carrier – a strategy that requires a single radio with flexible bandwidth. 8 Nortel Technical Journal, Issue 6 Embracing this architectural challenge, Nortel researchers focused on innovations in the following key areas: • architecture and packaging; • MIMO algorithms and antennas; • channelization; • network timing and synchronization; and • power amplifier memory-correction. Architecture and packaging Analytical design resulted in an evolution from a base station system with five or more modules to a simpler 4G WiMAX base station with just two key modules: a MIMO radio module and an integrated digital module. As shown in Diagram A, the current CDMA macro-cell BTS requires five basic elements: radio, timing, core, control, and modem modules. This architecture follows a hierarchical approach of multiple radios and modems, and expansion is achieved by plugging additional radios and modems into the core. The core provides a switching function, directing data transmissions between the radios and modems. The core then connects to a control module, which in turn connects to the network. By contrast, as shown in Diagram B, Nortel’s WiMAX BTS embraces a different approach, providing a direct one-to-one mapping of radio to modem. Through several key innovations, the team integrated the core, timing, and control modules into a single integrated digital module. This integration dramatically shrinks the size of Diagram A. Basic architecture of a CDMA BTS Modem Timing module Radio Modem Core Radio . . . Modem . . . Control module Radio Network Diagram B. Basic architecture of a WiMAX BTS Network Integrated digital module MIMO radio a base station, and facilitates a simple fiber interconnect, which eliminates the need for backplane infrastructure. MIMO algorithm and antenna MIMO is a spatial diversity technique that increases coverage or data capacity by either transmitting the same data on different antennas (Matrix A) or different data on different antennas (Matrix B). Nortel implements a two-antenna MIMO BTS with two transmitters and two receivers per sector on the radio frequency (RF) module. All digital processing functions to generate MIMO Matrix A/B and OFDM waveforms are implemented in the single-board modem, which can support up to 30 Megabits per second (Mbit/s). The knowledge and patented technology developed by the WTL for its MIMO testbed were transferred directly to the WiMAX product, including several thousand lines of prototype code that captured Nortel’s key innovations in OFDM uplink-receive MIMO maximum-likelihood detection decoding and channel estimation. The code was supported with detailed link-simulation suites, and the transfer was accelerated through the selection of compatible processor components in both the testbed and product. MIMO relies on sophisticated antennas, and Nortel’s world-class competency in antenna design and propagation modeling was applied to early MIMO proof-of-concept trials, channel models, system linkbudget simulations, and antenna selection. Channelization technology The evolution to OFDM places new demands on the radio channelization function. One key challenge is the need to costeffectively support, in a single configurable device, the wide array of band classes that are specified in the WiMAX (IEEE 802.16e) profiles. Channelization enables the radio to find and extract a specific channel from the radio spectrum, while filtering out adjacent channels or interferers, and includes supporting functions for power measurement, quadrature error correction, diversity, and transport formatting for data exchange with the modem. In older systems, analog filters were able to extract one channel. As technology evolved, digital filters were introduced and eventually were able to extract several channels. WiMAX, however, calls for a dramatic increase in flexibility. Building on the patented common-rate channelization technology developed to support the two dominant implementations of CDMA (IS-2000 and UMTS), designers utilized advanced multi-rate signal processing concepts, and implemented a unified, efficient field programmable gate array (FPGA) device that enables a single WiMAX radio to support 12 defined bandwidths. In this way, a single radio deployment can be configured to simultaneously meet the initial and future growth requirements of customers, including those in emerging global markets with disparate spectrum allocations. Network timing and synchronization OFDM technology can increase the on-air data rate by delivering improved resistance to many of the impairments in the wireless channel, including multi-path fading. This benefit, however, requires more stringent timing and frequency accuracies, compared to earlier technologies. Synchronization is obtained with a Global Positioning System (GPS) satellite constellation, and precision timing is typically delivered with a crystal oscillator, which must continue to operate in “holdover mode” if satellite visibility is temporarily lost. Because crystals age and are affected by changes in temperature (causing frequency variations, or drifting), they are normally subjected to a costly manufactur- ing process that prematurely ages them. This process improves the crystal’s initial insensitivity to temperature changes and thus produces extremely low frequency variations. In operation, one or more tiny heated enclosures (called ovens) inside the crystal package are used to moderate environmental temperature variations. Researchers decided to try solving the problems of crystal drift, inaccuracy, aging, and residual temperature variation with an intelligent algorithm. The resulting control system, which earned researchers several patents, successfully disciplined the crystal to produce highly accurate timing and synchronization performance. In the end, the control system was powerful enough to enable the selection of a much-lower-cost crystal and a smaller, simpler thermal package with only a single oven. This technology delivered a dramatic reduction in the size of the network timing and synchronization subsystem, collapsing a separate timing module the size of a bread box into a subsystem the size of a deck of cards. This subsystem, built onboard the WiMAX integrated digital module, delivers a dramatic cost reduction of some 80 percent compared to a previousgeneration timing module. Power amplifier memory-correction Even with today’s significant advances in pre-distortion techniques and increased transistor efficiencies, RF power amplifiers (PAs) still consume significant cost, volume, and energy, and require considerable manufacturing expertise. The move to multiple transmitters in a single radio to support MIMO has heightened the need to reduce transmitter size. The most expedient approach to reducing transmitter size is to increase power efficiency, which reduces not only the circuit size but also the attracted power supply and cooling requirements. Nortel Technical Journal, Issue 6 9 Nortel’s WiMAX base station continued Building smaller, more compact, more efficient power amplifiers, however, tends to force design trade-offs – specifically with respect to memory effects, which is an undesirable but inherent phenomenon of PAs. Briefly, the behavior of a PA is based on the signal history it has received. How long the PA remembers this history can pose a problem in the form of signal distortion or interference. Certainly, one ideal in designing PAs is to achieve close to zero memory, but reaching this goal requires the use of various complex techniques and expensive hardware. To counteract this memory phenomenon with signal processing techniques, designers integrated into the WiMAX radio module an innovative memory-correction technology, initially developed and patented by Nortel for an envelope-tracking power amplifier. This memory-correction algorithm enabled the power transistors to be “pushed harder,” or driven further into saturation, increasing efficiency while still achieving the required linearity. Designers combined the new memory-correction technology with a proven technology called baseband pre-distortion, developed by Nortel’s wireless business unit. Together, these two technologies minimize the impact of memory, allowing Nortel to push the transmitters to the compression point, while maintaining excellent emissions performance. Critically, Nortel’s WiMAX radios meet U.S. FCC emissions specifications with no guard band. For example, a 10-MHz carrier can be inserted into a 10-MHz frequency block and meet the emissions specifications at the corners of the frequency block. This key performance capability maximizes spectrum usage and eases deployment. The power amplifier technology, along with all of the BTS innovations, was designed-in upfront to achieve best-in-class manufacturability, compliance testing, and 10 Nortel Technical Journal, Issue 6 time to market. For example, researchers worked closely with the manufacturing-testset and test-development teams to transfer the designer test environments and tools from the early system integration efforts, in order to seed the factory testset, speed the transition from design to product, and shorten time to market. Flexible 4G technology enablers Far from incremental improvements, these innovations constitute a significant technology disruption in the wireless arena. While these innovations are targeted initially for WiMAX deployments, they are also applicable to all emerging 4G technologies, whether Long Term Evolution (LTE), Ultra Mobile Broadband (UMB), or beyond. The fact that all 4G technologies are based on OFDMA enables both these and tomorrow’s innovations to be highly flexible technology enablers – ones that will help ensure that 4G systems deliver the high capacity and the OpEx and CapEx reductions that operators need in order to offer broadband multimedia wireless everywhere. Steve Beaudin is Manager of WiMAX RF System Development, in Nortel’s Carrier Networks organization. David Choi is Leader of WiMAX Systems Development, in Nortel’s Carrier Networks organization. Brian Lehman is Manager of Wireless DSP Algorithms and Technology, in the CTO Office. Brad Morris is Advisor, Signal Processing Hardware Technology, in the CTO Office. deployment options, along with a significant reduction in cell-site operations costs. As well, the BTS 5000 can already operate in 12 different frequency bands (more bands by far than any other base station in the industry) giving it unparalleled flexibility for deployment in different markets and for various carriers. The BTS 5000, in fact, is well-positioned to set a new benchmark for performance and size and to become the standard against which all future base station technologies will be measured. These innovations are detailed on page 8. Miniature band reject filters: Nortel is developing miniature band reject filter (MBRF) technology, which is a key enabler in mobile terminals for allowing operators and new entrants with non-traditional spectrum, such as that used for satellite transmission, to deploy WiMAX. Where satellite signals and terrestrial signals are adjacent spectrally, there is a high likelihood that the more powerful near signal (i.e., terrestrial) can easily interfere with the far signal (satellite), by “leaking” unwanted transmit signals into the adjacent band. Preventing this effect requires filters that can separate the adjacent bands effectively. Researchers are meeting this need by designing a very small device, about the size of a fingernail, that can provide the steep transition band required to give WiMAX terminals the filtering capability they need for use in the satellite spectrum. The MBRF will allow WiMAX terminal vendors to build terminals that meet the stringent out-of-band requirements in certain frequency allocations, such as in the 1.5-GHz band that is adjacent to the Global Positioning System (GPS) satellite band, and the 2.3-GHz band that is adjacent to the Satellite Digital Audio Radio Service. Innovations in antenna design 4G systems are fundamentally based on a multiple antenna technology called multiple-input multiple-output (MIMO). MIMO allows the creation of multiple parallel data streams between High-performance Hex-MIMO antenna technology for cost-effective 4G by David Adams and Andy Jeffries In recent years, there have been many advances in the development of advanced spatial division multiple access (SDMA) and multiple-input multipleoutput (MIMO) algorithms for broadband wireless access. While these techniques offer the potential for substantial improvements in capacity and coverage, they also require increased signal processing capability in the base transceiver station (BTS) and, equally important, add complexity to the radio frequency (RF) and antenna systems at the cell site – issues that have the potential to significantly impact deployment, operating, and hardware costs. Researchers in Nortel’s Wireless Technology Lab (WTL) are investigating a wide range of antenna configurations based on various combinations of SDMA and MIMO. One configuration that is receiving considerable attention for its ability to overcome these practical overheads, while still delivering valuable capacity and coverage gains over conventional 2G and 3G systems, is an advanced antenna concept called Hex-MIMO. As shown in the diagram, a HexMIMO configuration essentially partitions each sector of a conventional trisector antenna area into two, achieving six-sector (or hex-sector) coverage around the cell site. Hex-MIMO employs two carefully shaped fixed dual-polar beams within a sector, each of which carries two-branch MIMO. Depending on the scenario, Hex-MIMO can offer both downlink and uplink capacities in excess of 2.5 times those of a conventional deployment. Nortel’s Hex-MIMO solution is based on several innovations, specifically: • a unique combination of SDMA and MIMO that leverages the performance gains of both techniques, while deliver- ing a solution that is sufficiently low-cost, easy to implement, and cost-effective to operate for widespread deployment; • the integration of the antenna and beamformer, which reduces the number of RF feeder cables and needs only three antennas (instead of the usual six) per cell site; and • the use of new low-cost lightweight materials and technologies to make the antenna simple, compact, and costeffective to manufacture and deploy. Unique SDMA-MIMO combination Hex-MIMO is based on a carefully designed combination of both SDMA and MIMO techniques. • SDMA partitions each sector using narrow beams achieved through spatial beamforming. In this way, spectrum resources can be reused for each sector. A two-part division would therefore, in principle, double the capacity. • Adding MIMO transmission to each sector further increases capacity and coverage. MIMO techniques are now being introduced into the marketplace as part of Nortel’s WiMAX product portfolio. Initial implementations will be in the form of two-branch MIMO, which employs antennas with two orthogonal polarizations (± 45 degrees) in a single-column sector antenna. In using SDMA, researchers chose to disregard the common industry perception that SDMA should be used only for higher-order antenna designs (creating three, four, or even more divisions in each sector) where high concentrations of users, such as in dense urban areas or military uses, warrant the cost of the added complexity and larger antennas. These more advanced forms of SDMA include options to steer adaptive beams toward multiple users and/or null out interference. Instead, the team worked to determine the optimum trade-offs – in antenna size and system complexity relative to performance – that would be key to the effective use of SDMA tech- Hex-MIMO antenna configuration Two-beam dual-polar MIMO per sector Nortel Technical Journal, Issue 6 11 Hex-MIMO continued niques for sub-1-GHz spectrum, for example. In doing so, they overcame several difficult challenges, including the design of the antenna array. Array antennas are required to support SDMA and these antennas typically require half-wavelengthspaced columns to provide good control of radiation patterns. The larger the number of antenna columns within the array, the greater the performance improvements, but at the cost of increased antenna width. So, while eight columns, for example, may be an ideal SDMA antenna from a performance perspective, it Shown above is a prototype of Nortel’s low-cost lightweight (LCLW) modular antenna design for use in a Hex-MIMO solution. Each pair of dual-polar elements (the smaller unit at bottom) is an antenna building block that provides flexibility in antenna configuration. A single column of elements would form the core of a dual-polarized sector antenna suitable for two-way MIMO, while an array of directly adjacent columns forms an array antenna suitable for SDMA-MIMO. This design uses a combination of flat-plate antenna technology, slot antenna designs, and plated plastics to reduce weight and costs. Such antenna designs are important enablers for the widespread deployment of cost-effective 4G antenna solutions, such as Hex-MIMO. 12 Nortel Technical Journal, Issue 6 is less than ideal from the point of view of deployment, since the antenna width, and therefore area, often has a direct bearing on the site leasing costs, as well as the wind loading stresses the antenna will experience. These issues become increasingly difficult to solve as the RF carrier frequency drops and the antenna size increases. To address these issues, the team combined SDMA and MIMO techniques and shaped the beams in a way that reaches a compromise between these various considerations. The resulting solution, which limits the width of the resulting aperture to only 50 percent of the width of conventional full-sector antennas, is being actively pursued by the research team for a variety of potential 4G (WiMAX and LTE) applications. Antenna-beamformer integration The use of fixed beams allows a low-loss passive RF beamformer to be integrated into the antenna and avoids the need for any phase-calibrated cabling. For configurations where the active elements of the radios are located remotely from the antenna, this beamforming approach offers the advantage of reducing the number of RF feeder cables required at the cell site to a single pair per beam rather than a pair per array column. For active mastheads, the cables can be short or, alternatively, can be avoided altogether and replaced by optical fiber through integration of the electronics and antenna. The antenna-beamformer combination can also be configured to provide coverage equivalent to that of a conventional tri-sectored deployment, able to support both existing 2G/3G and SDMA-MIMO 4G systems from a single antenna aperture. This coverage gives 2G/3G operators the opportunity to consolidate their masthead hardware and future-proof their services by deploying the Hex-MIMO antenna now, ready for 4G SDMA-MIMO when required. Low-cost lightweight antenna technologies As SDMA systems become increasingly common, the need for antenna technologies tuned to the requirements of these systems will become ever greater. Because antennas to support SDMA are inevitably larger and more complex than conventional designs, controlling and ideally reducing their weight and cost becomes increasingly important. Larger SDMA antenna configurations and higher operating frequencies also require increasing levels of masthead integration, where the conventional boundaries between antenna and active RF systems can be questioned and new concepts explored. For instance, the research team has been exploring a number of new low-cost lightweight (LCLW) antenna technologies that can be used for both passive standalone antennas and integrated active ones. Using a combination of Nortel’s flatplate antenna technology, slot antenna designs, and plated plastics to reduce weight and costs, the WTL team has developed a modular antenna design that employs a half-wavelength-wide dualpolar element capable of meeting both narrow- and wide-spaced array antennas. This modular design is suited to both active and passive sector and array solutions. The basic element is a cavity-backed slot that is excited by probes fed from an integral feed network. Two of these elements make up a pair of orthogonally polarized slot-cavity combinations. These dual-polar elements are fabricated in pairs (or more) to create an antenna building block that is small enough to both keep manufacturing costs down and provide flexibility in the configuration of the resulting antenna. A single column of such elements would then be the core of a dual-polarized sector antenna suitable for two-way MIMO, while an array of directly adjacent columns then forms an array antenna suitable for SDMA-MIMO (see photo, page 12). This antenna technology and others like it currently under development at Nortel are important enablers to the widespread deployment of SDMAMIMO technologies and are key to the deployment of affordable and ubiquitous 4G wireless broadband multimedia services. David Adams is Advisor, Advanced Antenna Technology, in Nortel’s Wireless Technology Lab. Andy Jeffries is Senior Manager, Advanced Antenna Technology, in Nortel’s Wireless Technology Lab. One technology focus at Nortel is the design of miniature band reject filters (MBRFs) using proprietary surface acoustic wave (SAW) technology. MBRFs will be key enablers in mobile terminals and handsets for allowing operators and new entrants with non-traditional spectrum to deploy WiMAX. multiple transmit and receive antennas. By exploiting the multi-path phenomenon to differentiate among the multiple parallel signal paths between MIMO antennas, MIMO technology achieves a multifold user throughput gain and multiple aggregated capacity increase compared to current 3G macro-cellular networks. Nortel has long held a leadership position in MIMO-based techniques, and MIMO has essentially become the de facto standard for antenna operation in 4G systems. The adoption of multiple antenna technology means that 4G systems will require new antenna designs that enable a range of deployment scenarios depending on operators’ needs. For instance, incumbent operators with many existing cell sites would most likely be interested in antenna deployments that increase the capacity at each site. By contrast, new entrants deploying new cell sites would be looking to maximize capital investments by building as few sites as possible, but equipping them with antennas that increase range. As well, because of the typically high costs involved with leasing cell sites, all players are de- manding antennas that are compact and require a smaller footprint than previous generations. To meet this range of needs, researchers are building on their experience and leadership in MIMO technology to develop several advanced technologies and configurations, as well as researching the use of advanced lightweight materials for more flexible, compact, and robust products. Adaptive antenna technology: One of the technologies Nortel is developing enables antennas to be directed at each user and ensures that the transmission and reception of every packet is optimized for that user. This technology involves adaptive beamforming techniques based on spatial division multiple access (SDMA). It also requires the development of sophisticated algorithms that steer a beam toward the target user, effectively optimizing the transmission of each packet delivered to each user. As well, the team is devising sophisticated schedulers for assigning users and determining priorities for transmission. Earlier research by Nortel demonstrated that OFDM-MIMO with multi-beam continued on page 16... Nortel Technical Journal, Issue 6 13 Closed-loop MIMO beamforming: Taking MIMO transmission the “extra mile” by Caroline Chan and Wen Tong Nortel researchers are developing a 4G solution that will extend the capabilities of multiple-input multiple-output (MIMO) transmission and cost-effectively deliver even higher data rates to mobile users in highly cluttered propagation environments, such as dense urban and indoor areas, as well as increase MIMO signal strength for greater reach in rural areas. Called closed-loop MIMO beamforming, this solution enables intrinsic integration of MIMO transmission with an advanced beamforming technique based on Eigenvectors. (An Eigenvector forms the complex mathematical equations that deal with transforming the shape and orientation of objects. In the wireless world, it is antenna beams that are transformed to enable them to direct radio signals around obstacles, such as buildings, that would normally block the signal path.) In this way, MIMO signals can be concentrated into narrow, and therefore more powerful, virtual beams that can, in turn, be focused on an individual user and optimized for each user’s reception conditions. “Closed loop” refers to the feedback loop created by the continuous communication of channel information between the mobile and base station, thus enabling the base station to direct the virtual beam to a particular user. This contrasts with an “open loop,” whereby signal transmissions are spread more broadly. Nortel is a strong proponent of closedloop MIMO beamforming because of its potential to achieve higher performance, while supporting a wide range of antenna configurations for field deployments and providing operators with greater flexibility and significantly reduced costs. According to both Nortel studies and analysis conducted within the WiMAX Forum, incumbent operators that are considering deployment of a cell-site overlay could potentially realize a 65-percent user throughput gain at 95-percent tile coverage, and a 40-percent aggregated sector capacity gain. For greenfield operators, this technology could provide a 30-percent cellcount reduction and a link budget gain of 5 dB in the downlink. Importantly, this technology complements and can be deployed in the company of other advanced 4G techniques, such as mobile multi-hop relay (see page 16) to further enhance reach and throughput. Conceptual view Nortel is developing a number of key technologies, including specialized algorithms and schedulers, to give 4G base stations Closed-loop MIMO beamforming: Architectural view (downlink transmission) OFDMA transmit Mobile terminal MIMO channel OFDMA receive OFDMA transmit Packet OFDMA receive OFDMA transmit Codebook and search OFDMA transmit Codebook Codebook index feedback via uplink 14 Nortel Technical Journal, Issue 6 Pre-coder Pre-coder Base station Packet the ability to dynamically track the continuously changing locations and directions of mobile terminals, and to enable the cell-site antennas to create narrow beams with the focus they need to target signals at individual user devices. These capabilities are performed by three key elements: a pre-coder, a codebook database, and orthogonal frequency division multiple access (OFDMA) transmitters/receivers. All three elements are housed both in the 4G base station and in the 4G-capable device (such as a WiMAX terminal). The job of the pre-coder is to apply a mathematical “weight” to each packet, and then feed the differently weighted packets to each OFDMA receiver or transmitter, which uses this information to form a narrow beam. The pre-coded beamforming weights are stored in a codebook – a database that contains the information required to translate channel information sent by the different devices into standard “terminology” understood by all network elements. The accompanying diagram presents a conceptual architectural view of these elements, and highlights the steps involved in downlink transmission – from the base station to the terminal. The first step begins on the device side (far right of diagram). Before the network transmits any packets, the device must instruct the base station on where to focus the virtual beam. To do this, the device searches its codebook for the appropriate codeword (or pre-coded beamforming weight) and then sends this value – called a codebook index – to the base station via closed-loop feedback signaling (on a separate channel from that used for user data). These pre-coded weights are then stored in the base station’s codebook. When the network transmits the packet, the packet is fed into the base station’s precoder, which retrieves the codebook index and applies the pre-generated weights to each packet. These weights are calculated specifically to ensure that the MIMO signal energy that is about to be emitted from the four-branch antenna can be best “added up” on the user device side for each packet over the scattering MIMO channel environment, hence delivering MIMO signal quality that will form the optimum targeted beam. Since the MIMO channel changes over time (as the mobile user changes position), the pre-coder weights must be adjusted as the channel changes, and as often as the user changes position, in order to ensure the best-quality transmission for every packet. The weighted packet is then mapped onto the four-branch OFDMA transmitters, which perform Inverse Fast Fourier Transform (IFFT) to generate OFDM signals. The packet is then fed into the antenna element, which sends the formed beam over the air to the targeted terminal. Beamforming for a MIMO signal requires MIMO channel information, which is carried through the MIMO pilot signal at the base station. The device receiver extracts the MIMO pilot signal and derives the beamforming weights that were applied at the base station. In a rich-scattering, non-line-of-sight environment, Eigen-based beams – virtual beams in the signal space that can navigate around obstacles (represented by the white “kidney” shapes in diagram) – constitute the best beamforming solution. The virtual beams are generated on both the transmit and receive sides. The weights of the beams can be computed by using the Eigen-decomposition technique based on the MIMO channel matrix. Another advantage of this technique is that it minimizes the level of overhead (the codebook index feedback) over the air interface. On the device side, the antennas collect the beamformed MIMO signals and feed them into the OFDMA receivers, which demodulate the OFDM signal using FFT. The device pre-coder then applies the codeword to form the best receive beam. Deployment considerations With respect to cost, footprint, and ease of deployment, the ideal base station configuration is one that provides closedloop MIMO beamforming while keeping the user device simple and low-cost. This challenge can be met with an advanced remote radio head cell-site architecture that provides four-branch transmit antennas and supports 4x2 downlink closed-loop MIMO, with two receive antennas on the user device side. The ideal antenna structure is two spatially separated cross-polarized antennas with 3 to 18 RF signal wavelength separation. Another attractive antenna configuration is a single, compact, two-column crosspolarized antenna with 0.7 RF signal wavelength separation. Nortel researchers are meeting this need with several innovations, including development of a compact remote radio head solution and low-cost lightweight antennas that leverage Nortel’s flatplate antenna technology, slot antenna designs, and plated plastics to reduce weight and costs (see page 12). While practical deployments of closed-loop MIMO beamforming are expected in the 2009/2010 timeframe, Nortel is working aggressively within the various standards bodies to help drive industry direction and standardization. In fact, Nortel is a leading technology contributor in this area within the WiMAX Forum and other standards development organizations. Caroline Chan is Leader, WiMAX Network Product Line Management, Carrier Networks. Wen Tong is Leader of Nortel’s Wireless Technology Lab. Nortel Technical Journal, Issue 6 15 technology can provide 10 times higher capacity on the downlink than current 3G baseline system deployments – and at one-tenth the cost. The team is now working with developers in the Nortel wireless business unit to deploy this technology into future products. Hex-MIMO: Another technology being actively pursued by our research teams for a variety of 4G applications is a concept called Hex-MIMO, a configuration that uses compact, lightweight antenna arrays to provide six sectors per cell site versus the typical three, delivering valuable capacity and coverage gains in urban hot-spot deployments. This concept, described on page 11, is based on both MIMO and SDMA techniques. Depending on the scenario, a Hex-MIMO solution can offer downlink and uplink capacities in excess of 2.5 times that of conventional deployments. Closed-loop MIMO beamforming: For dense urban indoor and rural environments, researchers are working on antenna solutions that utilize fourbranch receive and closed-loop MIMO transmission, also called closed-loop Eigen beamforming (see page 14). Essentially, Eigen beamforming concentrates radio signals and aims them at the targeted user in the complex propagation clutter environment, enabling high-quality signals to be delivered to users who are located in areas of weak or poor radio reception, such as indoors. Here, designers are developing a new algorithm and scheduler that can determine the optimum mode of transmission for each user’s reception conditions. Researchers are also working within the WiMAX Forum to bring this technology into the WiMAX Forum profile and allow interoperability among all types of mobile devices. Cable reduction technology: The WTL has developed innovative cable reduction technology that allows multiple antenna signals to travel between the top and bottom of the tower along a single RF cable. For traditional cellular systems, this technology enables a single 16 Nortel Technical Journal, Issue 6 The many advantages of mobile multi-hop relay technology by Hang Zhang and Peiying Zhu Nortel’s Wireless Technology Lab (WTL) is researching and developing key technologies and architectures that will enable mobile multi-hop relay (MMR), which is set to become a crucial capability in 4G networks for extending service coverage, enhancing throughput, reducing the need for and cost of additional base stations, and lowering overall CapEx and OpEx costs for operators. The MMR concept centers on a new network node called a relay station (RS). An RS (or several of them) is positioned between the base station and the mobile device (e.g., cell phone, personal computer, or laptop) and acts as a “hop” for wireless signals as they travel between the base station and the mobile. The diagram highlights the advantages of MMR technology across different cell-site deployments – from indoor office buildings, to dense urban areas with high concentrations of mobile users, to less-concentrated rural and suburban areas. As well, relay stations can be configured with various levels of functionality – from the simplest RS that physically relays data between the base station and terminal (under the control of the base station), to a highly configurable RS with the added intelligence necessary for performing such functions as resource management, scheduling, and security, effectively acting as a “mini” base station. With this flexibility, the RS can be deployed in many different scenarios, some of which follow. To enhance capacity: As shown in scenario A in the diagram, an RS can be used to enhance cell capacity and increase throughput. Today, in large cells that cover suburban areas, wireless signals can lose strength as they propagate to the edges of the cell, leading to weak transmission and therefore lower data rates and throughput for users positioned at these edges. An RS can be positioned at the edges of each cell to boost the strength of the wireless signal and provide ubiquitous and uniform highspeed access. To extend the network: Relay stations can also be used to extend network coverage (scenario B) and provide service to mobile users who are out of range of a cell site. Rather than deploy additional costly base stations, antennas, and RF feeder cables, a series of lowercost relays can be used to reach beyond the cell-site coverage area, with signals hopping from relay to relay. To eliminate coverage holes: Often in cellular and wireless networks, “holes” in coverage exist among two or more adjacent cell sites (scenario C). These coverage holes are especially pronounced within buildings and in dense urban environments, where signals may be blocked by physical obstacles such as buildings, or may be degraded while traveling around corners. Positioning relay stations at these points of blockage would allow signals to reach mobiles that otherwise would receive either poor or no service in these spots. To boost uplink throughput for mobiles: Wireless networks have always experienced link-budget imbalances for transmission on the downlink and uplink paths. Downlink transmission – which is the direct data path from the base station to the mobile station (MS) or mobile device – is generally of a higher power than that of the uplink – the reverse path from the terminal to the base station – because of the MS limitations in maximum transmission power. As a result, the uplink presents the more difficult challenge with respect to throughput, particularly Mobile multi-hop relay scenarios A. To enhance capacity BS B. To extend the network RS BS C. To eliminate coverage holes RS RS D. To boost uplink throughput for mobiles BS Up k lin wn Do k lin Radio RS k lin RS BS BS BS Up E. To simplify handover operation to a group of mobiles BS BS RS BS Base station RS Relay station Nortel Technical Journal, Issue 6 17 Mobile multi-hop relay continued when user devices are farther away from the base station. To help boost the uplink throughput for the MS, relay stations can be positioned between the MS and the base station to shorten the distance for the uplink traffic and boost throughput (scenario D). To simplify handover operation to a group of mobiles: In this particularly exciting application (scenario E), which is attracting much early interest in the wireless community, the RS can be deployed as an agent for a group of mobile devices. For instance, a small RS could be mounted in a vehicle – a car, bus, or train – that is carrying several wireless subscribers who are using their handsets, laptops, or BlackBerry devices. Today, those devices would each have to communicate directly with the base station, with each individual mobile device exchanging requests for handover and receiving assignments as the vehicle moves across the cell boundary. This individual handover process consumes a significant amount of bandwidth and results in less bandwidth available for MS data. Instead, an onboard RS would move with the mobiles, thereby keeping the relative location of the RS to MS unchanged, and the mobiles would communicate directly with the RS. The RS, then, would initiate and manage handover when the vehicle crosses a cell boundary, performing the procedure only once and making handover transparent to the mobile devices. This procedure is especially beneficial for fast-moving vehicles, where handover is performed more frequently. To enable these benefits across all types of scenarios, WTL researchers are developing several new enabling technologies. These technologies are currently being driven into key standards-setting 18 Nortel Technical Journal, Issue 6 bodies, and discussions regarding precise implementation schemes are under way. Notably, Nortel is the leading contributor to the IEEE 802.16j standard for WiMAX implementations, with more than 100 contributions submitted. IEEE 802.16j is currently in the final stages of standardization. Nortel is also actively participating in the WiMAX Forum, which is specifying MMR for the WiMAX profile. Across all of these efforts, the WTL continues to embrace a design approach that will ensure the technology innovations under way are applicable not just for a single 4G standard, such as WiMAX, but also for all current and future 4G technologies. With MMR, Nortel researchers are ensuring that the associated technologies are flexible enough to be easily extended to other 4G air interfaces, such as Long Term Evolution (LTE) and Ultra Mobile Broadband (UMB). Hang Zhang is Advisor, MAC Layer, Advanced Wireless Access Systems, in Nortel’s Wireless Technology Lab. Peiying Zhu is Leader of Advanced Wireless Access Systems, in the Wireless Technology Lab. RF cable to carry transmit, receive-main, receive-diversity, and control and synchronizing signals, as well as DC power, bringing cost reductions and greater deployment flexibility. This signal combining (or multiplexing) technique can be done in the time, frequency, phase, or code domains. For a MIMO-based system, this technology innovation is key to enabling multiple transmit and receive signals to travel on a single RF cable, providing cost-effective connectivity between the base station and antenna. Remote radio head: Another critical requirement in the antenna domain is ease of deployment. Because there is typically little spare room on the cell-site towers to accommodate additional large antennas and their associated RF cables, next-generation antennas must be much more compact, while still offering higher capacity and throughput. Our team is designing a solution that integrates the antenna with the necessary electronics for deployment on the tower top. This solution – a remote radio head – essentially puts a small, lightweight, highly reliable carrier-grade base station on top of the tower. The small size of the remote radio head brings new levels of flexibility for operators deploying 4G networks. Signal processing Digital signal processing (DSP) software – in the form of sophisticated scheduling algorithms – controls and optimizes the transmit and receive signals to and from the user’s mobile device. This optimization is a difficult challenge in over-the-air environments, where channel quality cannot be guaranteed and is much more vulnerable to undesirable channel fading, delay, and jitter than traffic in wireline environments. To date, signal processing in the wireless access portion of the network has focused on meeting the individual traffic characteristics of separate circuit-switched and packet-switched cellular voice and data networks. A 4G wireless access system that supports all types of traffic (voice, data, video) on a single converged IP Comparison of wireless and wireline access technologies Wireless technologies Wireline technologies 2G 3G 4G ADSL Cable EDGE 1xEV-DO HSPA Rev. A (Rel.6) WiMAX UMB LTE ADSL2+ DOCSIS 3.0 Commercial availability Now Now 2008 2007/beyond 2009 2009/10 Now Now Channel bandwidth (MHz) 0.200 1.25 5 1.25, 2.5, 5, 10, 20, 3.75, 7, 8.75 1.25 to 20 1.4, 1.6, 3, 5, 10, 15, 20 – – FDD/TDD FDD FDD FDD TDD (2:1) FDD FDD – – DL 0.384 3.1 10.8 31.68 37.25 29.4 28 171.25 UL 0.384 1.8 5.76 5.13 19.5 10.55 3.5 122.88 Aggregate per carrier-sector throughput (Mbit/s) DL 0.16 0.95 2.6 7.88 8.1 7.95 – – UL 0.16 0.45 1.5 3.03 4.0 3.75 – – Spectral efficiency (bits/sec/Hz/ carrier-sector) DL 0.1 0.76 0.52 1.28 1.62 1.59 – – UL 0.1 0.36 0.3 0.79 0.8 0.75 – – Performance metric Peak data rate (Mbit/s) This table compares the capabilities and several key performance metrics for the different generations of wireless access and the two dominant wired access technologies. The metrics for both the 3G and 4G technologies are based on the following assumptions. Frequency division duplex (FDD) assumes a 5-MHz bandwidth in the downlink (DL), and 5 MHz in the uplink (UL). Time division duplex (TDD) is based on a total network and directs this multimedia traffic through a single interface brings new DSP-related challenges. Not only must the software overcome the inherent over-the-air transmission characteristics, but it must also meet the different traffic behaviors and requirements of new types of services and a variety of user devices. For example, to ensure that users are provided with optimal transmission and reception for a particular service – whether real-time voice, realtime high-bandwidth streaming video, or lower-priority data, for instance – the scheduler must now determine priority for multiple types of traffic, change the coding modulation depending on the channel conditions, and change the 10-MHz bandwidth. For 4G, the peak data rate in the downlink is based on 64 quadrature amplitude modulation (QAM), and in the uplink, 16 QAM. For 3G, the downlink is 16 QAM and the uplink is based on quadrature phase-shift keying (QPSK). Spectrum reuse for both 3G and 4G is equal to 1, and signaling overheads are included. MIMO transmission modes according to both the robustness and throughput needed for each service and user type. To meet these challenges, Nortel is working to develop a new scheduling algorithm, along with new adaptive coding modulation schemes and radio resource management software. These elements are critical enablers for supporting Voice over IP and delivering a high quality of service. Mobile multi-hop relay Mobile multi-hop relay is another technology that Nortel is promoting, both in the industry and in the key standards bodies. This technology will enhance coverage and capacity (primarily in urban environments) for 4G deployments, such as WiMAX. In a multi-hop relay architecture, communication between the base stations and mobile terminals can be extended and improved through a number of intermediate relay stations. These relays enable signals to “hop” between them, without having to communicate back to the base station. In this way, relays can be used in a variety of deployments to provide many advantages. For instance, relays can help extend the network, allowing operators to effectively reduce the number of cell sites needed for coverage – a solution that is especially attractive to new entrants. Relays can also be deployed to fill “holes” Nortel Technical Journal, Issue 6 19 or shadowing caused by environmental obstacles (such as buildings, or corners within buildings), which can lead to weak signal reception and thus lower data rates. (For more information on the many advantages of mobile multi-hop relay, see page 16.) To realize the benefits of multi-hop relay technology, researchers have developed several innovative technologies, and have brought these into the IEEE 802.16j standard, which is currently in the final stages of standardization. In fact, Nortel holds numerous patents in this area and was a key contributor to the 802.16j standard. The advanced wireless technologies that Nortel is pursuing – including the base station, antenna, digital signal processing, and mobile multi-hop relay innovations discussed in this article – will serve to significantly raise the bar for overall wireless network throughput, performance, and cost, surpassing those of even a baseline 4G implementation. In fact, the wireless infrastructure that our teams are making possible is expected to enable operators to achieve up to three times higher throughput, with a corresponding reduction in CapEx and OpEx. Together, these technology enhancements will help operators create the more powerful and cost-effective infrastructures they will need not only to meet the intensifying subscriber demand for affordable “true” broadband services, but also to deliver a simpler and much richer user experience, with the ability to move seamlessly across the traditional IT, wired, and wireless worlds. Technology roadmap Beyond these innovations, Nortel’s longterm technology roadmap represents a continuation of this steep performance trajectory, with progression on all infrastructure fronts. Indeed, while the different 4G air interfaces, notably WiMAX and LTE, meet different market needs and are proceeding down separate evolution paths, Nortel’s vision is ultimately to deliver a single converged platform that will support both of these 20 Nortel Technical Journal, Issue 6 technologies. This convergence is made possible by the fact that all 4G technologies are built upon the same foundations – OFDM and MIMO. Nortel has long embraced the philosophy of developing common architectures, technologies, and platforms that will underpin and support all flavors of 4G and easily adapt to support other 4G technologies that appear in the future. With WiMAX and LTE following different evolution paths, a similar evolution of technologies to support them is expected over the next five years. For instance, we expect to see the evolution of duplexing schemes, such as time division duplex (TDD) and frequency division duplex (FDD). We also expect the development of new hot-spot technologies and new network elements, including nodes that support relay technology and femto cells. All are the focus of various research projects within the WTL. In addition, Nortel is continuing its leading role in major wireless standards activities. (For more on Nortel’s standards activities, see page 60.) For instance, Nortel was the early promoter of the OFDM-MIMO air interface as the 4G technology of choice. Nortel has been one of the key contributors in the LTE area, in both the study phase and the standards development phase. Here, researchers are applying their years of experience in OFDMMIMO technology to ensure that LTE will deliver best-in-class performance levels. Nortel is also working within the 3GPP, 3GPP2, and WiMAX Forum to ensure internetworking and seamless operation across LTE and all existing wireless technologies. With respect to LTE, standards work is scheduled to be completed by the end of 2008, with a complete set of specifications developed by the Technical Specification Group-Radio Access Network (TSG-RAN), TSG-SA (Services and System Aspects), and TSG-CT (Core Network and Terminals). These specifications will cover the end-to-end LTE system – from the air interface to network evolution. Already, Nortel has launched LTE design initiatives and is working with lead customers to conduct early trials. Another exciting technology revolution in the 4G landscape is occurring in the end-user mobile terminal and handset industry. Many vendors in the consumer electronics mass market are recognizing the tremendous potential of 4G connectivity and are quickly developing open devices, open source software, and open applications, which will give subscribers easy access to the richness of broadband multimedia services and facilitate a true broadband experience. As technology innovations such as those being spearheaded by the WTL progress and standards mature, the 1-Gbit/s (low mobility) and 100-Mbit/s (high mobility) access speeds envisioned by the ITU will become a reality. Soon, it will be second nature to expect that the same advanced broadband multimedia and communications-enabled capabilities offered in the wireline environment will also be available and affordable in the wireless world, providing users with a ubiquitous true broadband experience. Vish Nandlall is Chief Architect in Nortel’s Carrier Networks organization. Ed Sich is Leader of RF Technology in Nortel’s Wireless Technology Lab. Wen Tong is Leader of Nortel’s Wireless Technology Lab. He was also recently awarded the title of Nortel Technical Fellow. Peiying Zhu is Leader of Advanced Wireless Access Systems in Nortel’s Wireless Technology Lab.