Order Code RS20993
Updated August 12, 2008
Wireless Technology and Spectrum Demand:
Advanced Wireless Services
Linda K. Moore
Analyst in Telecommunications and Technology Policy
Resources, Science, and Industry Division
Summary
Advances in wireless telecommunications technology are converging with Internet
technology to foster new generations of applications and services. Presently, the United
States and other countries are moving to third-generation (3G) and fourth-generation
(4G) mobile telephony. A related trend is the growth in use of Wi-Fi (wireless fidelity)
and WiMAX (an industry designation for a type of broadband standard). Wi-Fi uses
local wireless networks for high-speed (broadband) mobile access to the Internet.
WiMAX uses broadband wireless to link fixed points and also supports mobile devices.
From the perspective of spectrum management, a significant difference in the
technologies is that 3G, 4G, and WiMAX services operate on designated, licensed
frequencies, while Wi-Fi shares unlicenced spectrum with other uses. Policy issues
before Congress include the competitive impact on commercial wireless carriers when
municipalities offer wireless broadband services, promoting the development of
broadband wireless access, and assuring the availability of appropriate spectrum for both
licensed and unlicensed applications..
Legislation providing terms for the release of spectrum for unlicensed or licensed
use in TV “white space” includes S. 234 (Kerry) and its companion bill H.R. 1597
(Inslee); S. 337 (Sununu); and H.R. 1320 (Rush). S. 1853 ( Lautenberg), the
Community Broadband Act, would assure the right of communities to offer advanced
telecommunications services. H.R. 5682 (Allen), the Rural America Communication
Expansion for the Future Act of 2008, would provide incentives to encourage broadband
use in rural areas, including a grants program for local governments “to establish
publicly-available networks of broadband service.” The Wireless Internet Nationwide
for Families Act of 2008, H.R. 5846 (Eshoo) would require the FCC to auction two
national licenses for unpaired spectrum that would be used to provide free broadband
services to consumers and public safety. A similar bill, the Open Wireless Internet Act,
S. 3420 (Wyden), would require study of possible interference between transmissions
from the spectrum band of the new licenses and adjacent bands previously licensed.

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Wireless Technology: Development and Demand
In order to deploy advanced wireless technologies, telecommunications carriers,
broadcasters, cable companies, content providers and others are seeking effective
strategies to move to new standards, upgrade infrastructure, and develop new services and
content. This migration path includes decisions about acquiring and using spectrum.
Spectrum is managed by the Federal Communications Commission (FCC) for commercial
and other non-federal uses and by the National Telecommunications and Information
Administration (NTIA) for federal government use. International use is facilitated by
numerous bilateral and multilateral agreements covering many aspects of usage, including
mobile telephony.1 Spectrum is segmented into bands of radio frequencies and typically
measured in cycles per second, or hertz.2
Commercial wireless communications typically rely on bandwidth below 3 GHz
because of limitations in current technology. Although developments in technology
increase the efficiency of spectrum and expand its usable range, there is persistent demand
for spectrum to carry new services as other technologies reach the market. New
developments in wireless technology support many services for business and consumer
markets, such as enhanced Internet links, digital television and radio broadcast reception,
high-quality streaming video, and mobile commerce (m-commerce) — including the
ability to make payments.
Mobile Telephony. Mobile communications became generally available to
businesses and consumers in the 1980s. The “first generation” was built on analog
technologies. Second generation (2G) wireless devices are characterized by digitized
delivery systems. Third generation (3G) mobile technology represents significant
advances services in cell phone technology. 3G and 4G networks provide capacity for
broadband applications that include video and mobile (transportable) television.3 These
leading-edge technologies can easily support multi-function devices, such as the
BlackBerry and the iPhone. Business and consumer demand for mobile services is
considered by many to be an important engine for future growth in American and global
economies. The United States had over 250 million mobile phone subscribers in
December 2007.4
1 The International Telecommunication Union (ITU), part of the United Nations, is the primary
organization for coordinating global telecommunications and spectrum management.
2 Radio waves are usually identified by frequency. Standard abbreviations for measuring
frequencies include kHz — kilohertz or thousands of hertz; MHz — megahertz, or millions of
hertz; and GHz — gigahertz, or billions of hertz.
3 Broadband refers to the capacity of the radio frequency channel. A broadband channel can
transmit live video, complex graphics, and other data-rich information as well as voice and text
messages, whereas a narrowband channel might be limited to handling voice, text, and some
graphics. For an in-depth study of wireless broadband, see Connected on the Go: Broadband
Goes Wireless,
Wireless Broadband Access Task Force, Federal Communications Commission,
February 2005 at [http://hraunfoss.fcc.gov/edocs_public/attachmatch/DOC-257247A1.pdf].
4 Statistic updated regularly at [http://www.ctia.org/].

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Wi-Fi and WiMAX. In 1999, what is now known as the Wi-Fi Alliance formed to
develop and promote a worldwide standard for localized, high-speed wireless
networking.5 Today, most new laptop computers come equipped with the technology that
allows wireless access to the Internet using Wi-Fi technology. Wireless Local Area
Networks (WLANs) operate on unlicenced spectrum, using radio frequencies in the free
2.4 GHz and 5.4/5.7GHz spectrum bands. A group of standards for frequency use in these
bands is known as the 802.11 family, or legacy. The 802.11a/n standards are commonly
referred to as Wi-Fi, for wireless fidelity. Wi-Fi provides high-speed Internet access for
personal computers and handheld devices and is also used by businesses to link computer-
based communications within a local area. Links are connected to a high-speed wireline
(landline) either at a business location or through hotspots. Hotspots are typically located
in homes or convenient public locations, including many airports and café environments
such as Starbucks. Another standard for wireless Internet is Bluetooth, which has a
shorter range than Wi-Fi but works well in cell phones. Bluetooth handles both voice and
data; Wi-Fi is mostly data but also supports Voice over Internet protocol (VoIP) calls,
sometimes known as VoWiFi.
WiMAX (Worldwide Interoperability for Microwave Access) refers to both a
technology and an industry standard, the work of an industry coalition of network and
equipment suppliers6 that have agreed to develop interoperable broadband wireless based
on a common standard (IEEE 802.16) for point-to-point transmissions. WiMAX
technology can transmit data over distances of up to 30 miles and is used in the United
States as a “last mile” technology, that is, a means to provide fixed wireless service to
locations that are not connected to networks by cable or high-speed wires. Mobile
WiMAX is still in the early stages of development.7 WiMAX uses multiple frequencies
around the world in ranges from 700 MHz to 66 GHz. In the United States, frequencies
where WiMAX is being tested or used include 700 MHz, 1.9 GHz, 2.3 GHz, 2.5 GHz and
2.7 GHz.
Future technologies for wireless broadband include WiMAX and Long Term
Evolution (LTE) networks. LTE is the projected development of existing 3G networks
built on Universal Mobile Telephone System (UMTS) standards.
Broadband Wireless Access to the Internet
As demand for Internet services grows, policymakers at all levels of government are
seeking ways to make access — especially high-speed, or broadband, access — to the
Internet available to all. As wireless technologies have improved, they have become a
popular option for deploying municipal broadband, especially to disadvantaged sectors
of a community. Successive Congresses have seen the introduction of bills supporting
5 Website at [http://www.wi-fi.org].
6 Founding members of the WiMAX Forum include Airspan, Alvarion, Analog Devices, Aperto
Networks, Ensemble Communications, Fujitsu, Intel, Nokia, Proxim, and Wi-LAN. For
additional information, see [http://www.wimaxforum.org/].
7 A global standard for mobile WiMAX, 802.16e has been established by the IEEE 802.16
Working Group; documentation is at [http://www.wimaxforum.org/technology/documents/].
Viewed October 23, 2007. WiMax has been accepted as a 3G standard by the International
Telecommunications Union.

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programs to bridge what is often called the digital divide, the inequality of access to the
Internet because of technical or economic constraints.8
Municipal Deployment of Broadband. The two main broadband technologies
that are particularly attractive to communities, in part because they support existing
community services such as Internet access for schools and communications for public
safety, are fiber-optic cable networks and wireless access — WiFi today, possibly
WiMAX in the future. The spread of wireless services such as access to the Internet and
anticipated advances in wireless technology are modifying the business case for choosing
a broadband technology. Networks that depend on a fiber-optic cable backbone are
capital-intensive and usually more profitable in high-density urban areas. A number of
rural communities have used their resources to install fiber-optic broadband services in
part because they were too small a market to interest for-profit companies. Increasingly,
communities are looking at wireless technologies to support their networks.
Several states have passed laws prohibiting or limiting local governments’ ability
to provide telecommunications services. An effort to challenge such a law in Missouri
by municipalities offering local communications services in the state was heard before the
U.S. Supreme Court in 2004.9 In the Telecommunications Act of 1996, Congress barred
states from “prohibiting the ability of any entity to provide any interstate or intrastate
telecommunications service.”10 The Court ruled that “entity” was not specific enough to
include state political divisions; if Congress wished specifically to protect both public and
private entities, they could do so by amending the language of the law. This Court
decision and the steady improvement in broadband communications technologies that
municipalities wish to have available in their communities have provided fuel for a policy
debate about access to broadband services. The central debate is whether municipal
broadband services are part of essential infrastructure with many public benefits,
including stimulus to the local economy, or whether they provide unfair competition that
distorts the marketplace and discourages commercial companies from investing in
broadband technologies. In particular, the fact that urban areas are creating Wi-Fi
networks and providing, among other services, free wireless links to the Internet is viewed
as a threat to commercial companies and a form of unfair competition.
Municipalities installing free Wi-Fi zones often contend that generally available
access to the Internet through wireless connections has become an urban amenity,
arguably a necessity in sustaining and developing the local economy. Municipal Wi-Fi
also provides the opportunity to improve social services and Internet access in
disadvantaged communities that often are not served by fiber optic networks.11
8 For further information, see CRS Report RL30719, Broadband Internet Access and the Digital
Divide: Federal Assistance Programs
, by Lennard G. Kruger and Angele A. Gilroy.
9 U.S. Supreme Court, Docket Number 02-1238.
10 47 U.S.C. 253 (a).
11 The Federal Trade Commissions’ Internet Access Task Force has published a report discussing
many aspects of municipal broadband implementation and related issues, at
[http://www.ftc.gov/opa/2006/10/muniwireless.htm].

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National Deployment of Free Broadband. During 2007, M2Z and several
other companies petitioned the FCC to release 20 MHz of spectrum licenses at 2155-2175
MHz for a national broadband network. M2Z offered to provide basic service for free to
consumers and public safety and offer content filtering for family-friendly access. In
return for the grant of the license, which would be assigned without auction, M2Z offered
to pay a percentage of gross revenues to the U.S Treasury. In September 2007, the FCC
issued a Notice of Proposed Rulemaking to establish service rules for the auction of a
license or licenses at 2155-2175 MHz.12 Proposed provisions include obligations to
offer free broadband service similar to that proposed by M2Z and family-friendly access.
Neither M2Z nor the FCC explained how the filtering technology would work. The
proposed spectrum band is adjacent to bands recently auctioned in the Advanced Wireless
Service (AWS) auction that concluded in 2006. The FCC’s rulemaking has prompted a
storm of comments. There are many allegations that the proposed network would cause
harmful interference to users on the AWS frequencies. There are also concerns that the
filtering would be applied in such a way as to constitute censoring. The concept of a
lifeline broadband service has significant support from many policy makers.
White Space. Unlicensed spectrum is not sold to the highest bidder and used for
the services chosen by the license-holder but is instead accessible to anyone using
wireless equipment certified by the FCC for those frequencies. New technologies that can
use unlicensed spectrum without causing interference are proposed for vacant spectrum
designated to provide space between the broadcasting signals of digital television, known
as white space. On September 11, 2006, the FCC announced a timetable for allowing
access to the spectrum so that devices could be developed and ready for retail sales by
February 2009.13 One of the potential uses for white space is wireless broadband access
to the Internet.14 These unlicensed applications could be used as an extension of the
licensed applications that will be possible on the 700 MHz band once it is cleared of
analog broadcasts. The National Association of Broadcasters (NAB), and others, are
protesting the use of white space for consumer devices on the grounds that they could
interfere with digital broadcasting. Companies such as Microsoft, Dell, and Motorola,
however, have stated that they believe solutions can be found to prevent interference.
NAB has asked the FCC to complete the rule-making process by banning unlicensed
devices from white spaces. Other interests, including consumer groups, argue that the
potential for new services, especially the possibility of wireless access to the Internet in
under-served areas, merits that the FCC continue to evaluate technologies. There are also
proposals to license some of the frequencies in white space and auction the licenses.
Bills in the 110th Congress
Bills to increase the availability of unlicensed spectrum for community broadband
are H.R. 1597, S. 234 and S. 337. The Wireless Innovation Act of 2007 (S. 234, Senator
Kerry) would require the FCC to complete Docket 04-186 and issue a final order, among
12 FCC, Notice of Proposed Rulemaking, WT Docket No. 07-195, released September 19, 2007.
13 FCC, First Report and Order and Further Notice of Proposed Rule Making, ET Docket No.
04-186, released October 18, 2006.
14 “Tech Firms Push to Use TV Airwaves for Internet,” by Charles Babington, The Washington
Post
, March 13, 2007.

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other requirements, within 180 days of the bill becoming law. H.R. 1597 (Representative
Inslee) is a companion bill. The White Spaces Act (S. 337, Senator Sununu) would
provide terms for the release of white space spectrum for unlicensed or licensed use,
prohibit the FCC from banning the marketing of technologies that work on the white
space, and address uncertainty stemming from legal proceedings regarding authority over
the use of the spectrum, among other uses. The Interference Protection for Existing
Television Band Devices Act (H.R. 1320, Representative Rush) would prohibit the use
of unlicensed devices of any kind in white space in rural areas until after February 17,
2009, and of mobile devices until at least three years later. In particular, unlicensed
devices would not be allowed to operate on channels already in use by low-power
auxiliary television broadcast devices and the FCC would be required to seek additional
way to protect these broadcasts from interference by unlicensed devices.
The Community Broadband Act of 2007 (S. 1853, Senator Lautenberg) would
specifically assure the rights of communities to offer broadband services. Other
provisions of the bill, would prohibit discrimination against competing service providers,
and would require full disclosure of the intended project to the community. Public-private
partnerships are encouraged in the bill’s language. S. 1853 was unanimously reported out
of the Committee on Commerce, Science, and Transportation on October 30, 2007.
The Rural America Communication Expansion for the Future Act of 2008 (H.R.
5682, Representative Allen) would provide incentives to encourage broadband use in
rural areas. The bill includes a section that would create a grants program for local
governments “to establish publicly-available networks of broadband service.” The bill
would authorize $15 million for each of fiscal years 2009 through 2013. The grants
program would be administered through the NTIA for the benefit of rural and underserved
areas.
The Wireless Internet Nationwide for Families Act of 2008 (H.R. 5846,
Representative Eshoo) would require the FCC to auction two national licenses for
unpaired spectrum that would be used to provide free broadband services to consumers
and public safety users. Both licenses would be for 20 MHz of spectrum; one of the
licenses would be in the 2155-2180 MHz range. H.R. 5846 would direct the FCC to
issue auction rules that would require free access, high-speed service, national coverage,
open access to devices, and build-out schedules, among other provisions. Similar rules
would apply to the second national license for 20 MHz that the FCC would be required
to identify and auction. Other provisions would require the FCC to work with the NTIA
in reporting to Congress on such matters as broadband competitiveness and affordability,
spectrum efficiency, technological advances, and more effective allocation and
assignment of spectrum resources.
The Open Wireless Internet Act (S. 3420, Senator Wyden) would similarly require
an auction of two licenses for broadband service that include a free data channel. Two
key differences in the Senate bill are (1) requirements that the FCC provide standards
governing interference between the 2155-2189 MHz range and adjacent bands previously
licensed and prepare a study of possible interference that would include parameters
established in the bill; and (2) offer the free service “with an option available to the user
at the time of initial connection or configuration of a connected device, to have that
service filtered by means of a technology protection measure or measures that prevent
underage users from accessing obscene or indecent material through such service.”