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WiMAX versus 3G and Wi-Fi


WiMAX versus 3G and Wi-Fi
How does WiMAX compare with the existing and emerging capabilities of 3G and Wi-Fi? The
throughput capabilities of WiMAX depend on the channel bandwidth used. Unlike 3G systems,
which have a fixed channel bandwidth, WiMAX defines a selectable channel bandwidth from
1.25MHz to 20MHz, which allows for a very flexible deployment. When deployed using the
more likely 10MHz TDD (time division duplexing) channel, assuming a 3:1 downlink-to-uplink
split and 2 × 2 MIMO, WiMAX offers 46Mbps peak downlink throughput and 7Mbps uplink.
The reliance of Wi-Fi and WiMAX on OFDM modulation, as opposed to CDMA as in 3G,
allows them to support very high peak rates. The need for spreading makes very high data rates
more difficult in CDMA systems.
More important than peak data rate offered over an individual link is the average throughput
and overall system capacity when deployed in a multicellular environment. From a capacity
standpoint, the more pertinent measure of system performance is spectral efficiency. In Chapter
12, we provide a detailed analysis of WiMAX system capacity and show that WiMAX can
achieve spectral efficiencies higher than what is typically achieved in 3G systems. The fact that
WiMAX specifications accommodated multiple antennas right from the start gives it a boost in
spectral efficiency. In 3G systems, on the other hand, multiple-antenna support is being added in
the form of revisions. Further, the OFDM physical layer used by WiMAX is more amenable to
MIMO implementations than are CDMA systems from the standpoint of the required complexity
for comparable gain. OFDM also makes it easier to exploit frequency diversity and multiuser
diversity to improve capacity. Therefore, when compared to 3G, WiMAX offers higher peak
data rates, greater flexibility, and higher average throughput and system capacity.
Another advantage of WiMAX is its ability to efficiently support more symmetric links—
useful for fixed applications, such as T1 replacement—and support for flexible and dynamic
adjustment of the downlink-to-uplink data rate ratios. Typically, 3G systems have a fixed asymmetric
data rate ratio between downlink and uplink.
What about in terms of supporting advanced IP applications, such as voice, video, and multimedia?
How do the technologies compare in terms of prioritizing traffic and controlling quality?
The WiMAX media access control layer is built from the ground up to support a variety of
traffic mixes, including real-time and non-real-time constant bit rate and variable bit rate traffic,

prioritized data, and best-effort data. Such 3G solutions as HSDPA and 1x EV-DO were also
designed for a variety of QoS levels.
Perhaps the most important advantage for WiMAX may be the potential for lower cost
owing to its lightweight IP architecture. Using an IP architecture simplifies the core network—
3G has a complex and separate core network for voice and data—and reduces the capital and
operating expenses. IP also puts WiMAX on a performance/price curve that is more in line with
general-purpose processors (Moore’s Law), thereby providing greater capital and operational
efficiencies. IP also allows for easier integration with third-party application developers and
makes convergence with other networks and applications easier.
In terms of supporting roaming and high-speed vehicular mobility, WiMAX capabilities are
somewhat unproven when compared to those of 3G. In 3G, mobility was an integral part of the
design; WiMAX was designed as a fixed system, with mobility capabilities developed as an addon
feature.
In summary, WiMAX occupies a somewhat middle ground between Wi-Fi and 3G technologies
when compared in the key dimensions of data rate, coverage, QoS, mobility, and price.
Table 1.2 provides a summary comparison of WiMAX with 3G and Wi-Fi technologies.