Hubbry Logo
Freedom of Mobile Multimedia AccessFreedom of Mobile Multimedia AccessMain
Open search
Freedom of Mobile Multimedia Access
Community hub
Freedom of Mobile Multimedia Access
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Contribute something
Freedom of Mobile Multimedia Access
Freedom of Mobile Multimedia Access
Freedom of Mobile Multimedia Access
View on Wikipedia
from Wikipedia

Freedom of Mobile Multimedia Access (FOMA) is the brand name of the W-CDMA-based 3G telecommunications services being offered by the Japanese telecommunications service provider NTT DoCoMo. It is an implementation of the Universal Mobile Telecommunications System (UMTS) and was the world's first 3G mobile data service to commence commercial operations.

A typical FOMA phone

NTT DoCoMo also offers HSPA services branded FOMA High-Speed (FOMAハイスピード), which offers downlink speeds up to 7.2 Mbit/s and uplink speeds up to 5.7 Mbit/s.[1]

History

[edit]

The W-CDMA air interface was accepted by the ITU as one of several air interfaces for the IMT-2000telecom initiative and by the ETSI as one of three air interfaces for the UMTS cellular network standard.

NTT DoCoMo originally planned to launch the world's first 3G services, initially branded Frontier of Mobile Multimedia Access (FOMA), in May 2001.[2] However, by May 2001, NTT DoCoMo had postponed the full-scale launch until October 2001, claiming they had not completed testing of their entire infrastructure, and would only launch an introductory trial to 4,000 subscribers.[3] In doing so, they also renamed the service to Freedom of Mobile multimedia Access.[3] In June 2001 trial subscribers complained the mobile phones had insufficient battery life and crashed frequently, that there was inadequate network coverage, and that there were security issues within the handset itself.[3] As a result, DoCoMo recalled 1,500 handsets by the end of June 2001. FOMA successfully launched in October 2001, providing mobile telecommunications coverage to Tokyo and Yokohama.[3]

Initially - as the first full-scale 3G service in the world[4] - The first FOMA handsets were of an experimental nature, targeting early adopters, were larger than previous handsets, had poor battery life, while the initial network only covered the center of Japan's largest towns and cities. For the first 1–2 years, FOMA was essentially an experimental service for early adopters - mainly centered around communication industry professionals.

As NTT DoCoMo did not wait for the completion and finalization of the 3G Release 99 network specification, their 3G W-CDMA network was initially incompatible with the internationally deployed UMTS standard.[5] However, in 2004 NTT DoCoMo performed wide-scale upgrades on its network, bringing it into compliance with the specification and enabling 100% compatibility with UMTS handsets, including incoming and outgoing roaming.

Around March 2004, the FOMA network achieved mass adoption, and handset sales soared. As of September 29, 2007, FOMA had over 40 million subscribers.[6]

Terminals

[edit]

NTT DoCoMo offers a wide range of FOMA branded handsets, which are made specifically for the Japanese market. FOMA handsets differ from Western UMTS handsets in several aspects, for example:

  • A standardized menu structure and chargers.
  • Japan-specific features such as i-mode or Osaifu-Keitai (electronic wallet).
  • Multiband-support, which includes band VI at 800 MHz for FOMA Plus-Area (newer models).
  • No support for dual-mode operation with GSM/EDGE (except some models branded by DoCoMo as World Wing).

Frequency allocations

[edit]

In metropolitan areas, FOMA uses the UMTS band I around 2100 MHz, which has been originally assigned to IMT-2000 services worldwide, except in the Americas.[7] In order to improve coverage in rural and mountainous areas, NTT DoCoMo also offers FOMA services in the 800 MHz band originally assigned to the 2G PDC mova service, which corresponds to UMTS band VI and is similar to band V used in the United States.[7] These extended service areas are branded FOMA Plus-Area (FOMAプラスエリア) and require multiband terminals.

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Freedom of Mobile Multimedia Access

View on Grokipedia
from Grokipedia
Freedom of Mobile Multimedia Access (FOMA) is the brand name for NTT DoCoMo's third-generation () mobile telecommunications service, which utilizes Wideband Code Division Multiple Access (W-CDMA) technology to deliver high-speed wireless connectivity for voice, data, and multimedia applications. Launched on October 1, 2001, in select areas of , FOMA represented one of the earliest commercial implementations of networks worldwide, enabling users to access mobile internet, video telephony, and other multimedia services at downlink speeds of up to 384 kbps and uplink speeds of 64 kbps. The development of FOMA stemmed from NTT DoCoMo's efforts to advance beyond second-generation (2G) services like its popular i-mode platform, with the brand name officially announced in December 2000 to signify "freedom" in mobile multimedia access through interactive and high-capacity networks. Initially rolled out in and , the service required substantial infrastructure investment—approximately $8.5 billion between 2001 and 2004—to expand coverage and capacity, focusing on W-CDMA as a "frontier" technology for flexible data transmission. Early handsets, such as the N2001, supported features like color displays and basic video calling, but adoption was slower than anticipated, with fewer than 40,000 subscribers by early 2002 due to high device costs ($500–$600) and monthly fees around $130. Over time, FOMA evolved to include enhancements like High-Speed Downlink Packet Access (HSDPA), branded as FOMA High-Speed, which initially boosted downlink speeds to 3.6 Mbit/s starting in 2006 and later reached 7.2 Mbit/s in 2007, facilitating richer experiences such as streaming video and advanced mobile . This progression helped maintain leadership in Japan's mobile market and influenced global standards, demonstrating the viability of packet-switched data services in mobile environments despite initial challenges like limited content availability and network coverage. By the late , FOMA had become integral to Japan's landscape, serving millions and paving the way for subsequent transitions, though the service is scheduled to end on , 2026.

Overview

Definition and Branding

Freedom of Mobile Multimedia Access (FOMA) is the branded name for a third-generation () mobile telecommunications service developed by , where the acronym emphasizes unrestricted access to content and services liberated from traditional wired connections. This branding highlights the service's intent to deliver seamless mobility, allowing users to engage with diverse media on the go without the limitations of fixed-line infrastructure. NTT DoCoMo positioned FOMA as Japan's pioneering commercial offering, utilizing the W-CDMA standard to enable advanced wireless capabilities within the country's competitive mobile landscape. The service was designed to expand beyond basic voice telephony, integrating high-speed data transmission to support a range of applications directly on portable devices. At its core, FOMA aimed to provide Japanese consumers with high-speed mobile access to voice communications, data services, video content, and functionalities, transforming handheld devices into versatile tools for everyday use. It targeted users eager for PC-like experiences on mobiles, including exchange, web browsing, and video calling, to meet the growing demand for integrated digital lifestyles in .

Launch and Initial Scope

NTT DoCoMo launched its Freedom of Mobile Multimedia Access (FOMA) service on October 1, 2001, in , marking the world's first commercial deployment of a W-CDMA-based network. As 's flagship 3G initiative, FOMA aimed to deliver enhanced capabilities over previous generations of mobile services. The rollout began with a low-key introduction amid cautious market expectations, focusing on voice, video calling, and packet data transmission. Initial coverage was confined to urban centers, including 's 23 wards and parts of and Kawasaki, supported by approximately 530 base stations in the Tokyo metropolitan area. By December 2001, the service expanded to additional major cities such as and , broadening access to about 50% of Japan's populated areas. FOMA quickly gained traction, reaching 100,000 subscribers by April 15, 2002, less than seven months after launch. This milestone occurred despite the high cost of early handsets, which ranged from 20,000 to 60,000 yen depending on the model and , and limited availability of only three initial devices from manufacturers and . The initial phase faced challenges, including short battery life—requiring recharges after just one day in standby mode—and variable data speeds that did not always achieve the maximum downlink of 384 kbps due to nascent network optimization. These issues contributed to slower in the early months, though they were gradually addressed through hardware improvements and network expansions.

Historical Development

Pre-Launch Research and Standardization

NTT DoCoMo initiated research and development on wideband code division multiple access (W-CDMA) technology in the early 1990s, with intensified efforts in the late 1990s to prepare for third-generation (3G) mobile services. By 1999, the company had selected multiple vendors, including Ericsson and Fujitsu, to develop W-CDMA prototypes for base stations, mobile terminals, and core network equipment. These collaborations resulted in the delivery of prototypes by early 2000, enabling initial interoperability testing and system validation ahead of commercial deployment. NTT DoCoMo actively participated in the 3rd Generation Partnership Project (3GPP), contributing to the standardization of Universal Mobile Telecommunications System (UMTS) specifications. FOMA was designed as an early implementation of the UMTS Release 99 standards, which defined the core framework for W-CDMA-based 3G networks, including support for circuit-switched voice and packet data services. Although Release 99 was not fully frozen until March 2000, NTT DoCoMo proceeded with pre-release elements to accelerate its timeline, ensuring compatibility with global UMTS evolution. Field trials began in late 1999 and continued into 2000 across urban and suburban areas in to verify system performance. These tests successfully demonstrated video telephony capabilities, enabling real-time two-way video calls at 64 kbps, as well as packet data transmission rates ranging from 64 kbps uplink to 384 kbps downlink under various mobility conditions. The trials confirmed reliable between cells and service delivery, paving the way for service optimization. Regulatory progress culminated in June 2000 when Japan's Ministry of Internal Affairs and Communications (MIC) allocated 2×15 MHz of spectrum in the 2 GHz band to for operations, fulfilling ITU IMT-2000 requirements and enabling nationwide deployment planning. This allocation, part of a broader beauty contest process, granted exclusive use of the frequencies to support W-CDMA services without auctions.

Commercial Rollout in Japan

Following its initial launch in in October 2001, rapidly expanded the FOMA service across to achieve nationwide coverage. By the end of March 2003, FOMA reached approximately 91% of Japan's population, increasing to 98% by the end of December 2003 and 99% by the end of March 2004 through targeted infrastructure deployments in urban and rural areas. This expansion was driven by subscriber demand, with FOMA users surpassing 3 million by March 31, 2004, exceeding the company's fiscal 2003 target of 2.4 million. Growth continued, reaching over 5 million subscribers by mid-2004 as nationwide coverage reached 99% by the end of March 2004, with 99.9% in the Kanto-Koshinetsu region. To support this rollout, invested heavily in network infrastructure, deploying thousands of base stations nationwide during the early to mid-2000s. By the end of June 2003, the company had installed around 7,000 base stations, increasing to approximately 10,700 by the end of December 2003, with further expansions including indoor systems to enhance urban and subway coverage, reaching about 2,000 indoor stations by mid-2004. These investments, part of a broader strategy to improve service reliability and capacity, positioned FOMA as Japan's leading network amid rising multimedia usage. Subscriber growth reflected this operational evolution, with FOMA accounting for a growing share of 's total base as services phased out. Service upgrades further bolstered the rollout, including the introduction of High-Speed Downlink Packet Access (HSDPA) on August 31, 2006, which increased downlink speeds to up to 3.6 Mbps for enhanced data services like video streaming. This upgrade addressed initial limitations in the W-CDMA network and supported the service's evolution toward higher multimedia capabilities. In the competitive landscape, FOMA's expansion responded to rivals such as KDDI's 1x launch in April 2002, which offered 144 kbps data speeds, and K.K.'s W-CDMA service debut in December 2002. These efforts helped maintain market leadership in Japan's sector during the mid-2000s.

Technical Specifications

W-CDMA Technology

Wideband (W-CDMA) forms the foundational for Freedom of Mobile Multimedia Access (FOMA), NTT DoCoMo's pioneering service in . It utilizes direct-sequence (DS-CDMA) for both the downlink and uplink directions, spreading user data across a nominal 5 MHz channel bandwidth to achieve high and robustness against interference. This approach, standardized in Release 99, enables multiple users to share the same frequency band simultaneously through unique orthogonal spreading codes, facilitating the delivery of multimedia content over mobile networks. Central to W-CDMA's operation are its key parameters, including a fixed chip rate of 3.84 million chips per second (Mcps), which determines the spreading resolution and supports variable data rates via adjustable spreading factors. The system operates with a frequency reuse factor of 1, allowing the same to be employed in all cells without partitioning, which maximizes capacity but necessitates precise interference through fast . Additionally, W-CDMA incorporates soft capabilities, where maintains simultaneous connections to multiple base stations on the same , combining signals via maximal ratio combining to improve link quality during cell transitions. Modulation schemes in W-CDMA are tailored to service types, with quadrature phase-shift keying (QPSK) employed for voice and low-rate on the downlink to ensure reliable transmission in noisy environments. Release 99 primarily relies on fixed QPSK modulation, with adaptive modulation and higher-order schemes introduced in later evolutions such as HSDPA in Release 5. correction is provided by convolutional coding with rates of 1/3 and 1/2 for voice, signaling, and low-data-rate channels, while turbo coding—using parallel concatenated convolutional codes with rates around 1/3—is applied to transport channels supporting rates above approximately 32 kbps, offering superior performance for applications. Performance metrics for W-CDMA in FOMA highlight its suitability for mobile environments, with theoretical maximum user data speeds of 384 kbps achieved in Release 99 under ideal conditions, enabling early multimedia services like video calling. In multipath fading channels, such as Rayleigh or ITU vehicular models, the system targets block error rates (BLER) of 10^{-1} to 10^{-2} for data channels and bit error rates (BER) below 10^{-3} for voice, leveraging rake receivers to capture multipath energy and closed-loop power control to mitigate signal fluctuations. These metrics ensure acceptable quality for multimedia access while operating at vehicular speeds up to 120 km/h.

Network Infrastructure

The core network of Freedom of Mobile Multimedia Access (FOMA) follows the architecture, incorporating the Mobile Switching Center (MSC) within the Mobile Multimedia Switching System (MMS) to handle circuit-switched services such as voice calls, integrated with the Visitor Location Register (VLR) for subscriber location management. For packet-switched data services, FOMA employs the Serving GPRS Support Node (SGSN) and Gateway GPRS Support Node (GGSN), which are combined into xGSN nodes to optimize processing and connectivity to external IP networks via the interface. These xGSN components separate control-plane and user-plane functions using advanced telecom computing architecture (aTCA) blades, enabling efficient handling of high packet traffic volumes while supporting (QoS) through . The in FOMA comprises base stations, which manage radio transmission and reception to connect , and Radio Network Controllers (RNCs) that oversee radio , mobility control, and domain-specific access restrictions for circuit-switched and packet-switched domains. RNCs independently set access ratios based on load from the MSC/VLR and SGSN, notifying terminals via system information blocks to balance network traffic. This structure utilizes W-CDMA as the underlying radio access technology for the UMTS Terrestrial Radio Access Network (UTRAN). FOMA enables interworking with networks through support for inter-system handovers and international , facilitated by Mobile Application Part () protocols for signaling and position registration. Handover procedures from to follow specifications, ensuring seamless connection transfer during mobility events. For , xGSN nodes use GTP tunneling over global roaming exchange (GRX) carriers and for compatibility with core elements. Security in the FOMA network is ensured through the Authentication and Key Agreement (AKA) protocol, which provides between the and the network using 128-bit secret keys derived via the . The AKA process generates authentication vectors including challenge (RAND), response (RES/XRES), and session keys (CK/IK) for confidentiality and integrity protection over the radio interface. This mechanism integrates with the Home Location Register/ Center (HLR/AuC) to securely manage subscriber access across the core and radio domains.

Devices and Terminals

Handset Evolution

The initial FOMA handsets, launched by in October 2001, marked the debut of commercial mobile devices in , with models such as the N2001 and P2101V leading the way. The N2001, a standard flip-style phone, featured a 2.2-inch full-color passive-matrix display with a resolution of 120 × 160 pixels, supporting basic services and circuit-switched data rates of 64 kbps for voice and low-speed connections. The P2101V added a built-in camera for videophone capabilities, enabling real-time video calls over the W-CDMA network, though early data speeds were limited to 384 kbps downlink and 64 kbps uplink for packet communications. These devices prioritized voice quality comparable to fixed-line phones and initial multimedia access, but faced challenges with battery life and coverage in their nascent rollout. Handset evolution progressed rapidly to enhance user experience and compatibility. By 2003, models like the Sony Ericsson SO505i introduced color TFT screens with 262,144 colors and 2.2-inch displays, alongside 1.3-megapixel cameras capable of 16x digital zoom and video clips at 5 frames per second, significantly improving photo and video quality for multimedia applications. Dual-mode capabilities for domestic networks became available in subsequent years, with chips supporting both W-CDMA for 3G and PDC for 2G fallback, as seen in the NEC N2701 (2003); international GSM compatibility for roaming was introduced later, such as in the NEC N900iG (2004). The NEC N900iL (2004) added dual-mode support for W-CDMA and IEEE 802.11b WiFi, facilitating seamless switching for corporate VoIP use. Battery capacities also advanced, starting from approximately 600-800 mAh in early models like the N2001—offering 60-90 minutes of talk time—and reaching over 1,000 mAh by the mid-2000s, extending standby times to 300-400 hours in devices such as the Panasonic P700i (2005). NTT DoCoMo collaborated primarily with Japanese manufacturers including , , and Sharp to produce FOMA-compatible handsets, ensuring optimized integration with the network. handled the N-series (e.g., N2001, N900i), the P-series (e.g., P2101V, P700i), and Sharp the SH-series (e.g., SH901i in 2004), focusing on compact designs and hardware innovations. A key milestone came with the 901i series in late 2004, which integrated contactless IC technology developed by , enabling secure mobile payments and authentication via the phone's built-in chip, thus expanding beyond voice and data to everyday transactions. These developments laid the groundwork for enhanced features like video emailing and i-appli applications, with later models in the 900i series (2006 onward) incorporating HSDPA for faster data rates up to 3.6 Mbit/s. FOMA handset production ceased in the early 2010s as focus shifted to LTE, with service support ending by March 2026.

Key Features and Capabilities

FOMA devices introduced video telephony as a capability, enabling real-time video calls at 64 kbps with QCIF (176x144 pixel) resolution, marking the first commercial deployment of such technology in October 2001 upon the service's launch. This feature utilized W-CDMA to support simultaneous voice and low-resolution video transmission, allowing users to see each other during calls for enhanced personal communication, though limited by the era's bandwidth constraints to basic facial views. Integration with the platform extended FOMA's by combining enhanced via c—a compact subset of optimized for small screens—with -based i-appli applications for dynamic, interactive content such as games and utilities. Launched in early 2001, this synergy allowed seamless browsing of web-like services and downloading of lightweight apps directly on handsets, fostering early mobile multimedia ecosystems without requiring full PC connectivity. i-appli's sandboxed environment ensured secure execution, enabling developers to create tailored applications that leveraged FOMA's higher data rates for richer experiences compared to predecessors. Location services via GPS were incorporated into FOMA handsets starting in 2005 with models like the Sharp SA700iS, supporting applications for route guidance and integration with alert systems for notifications. These capabilities combined satellite positioning with network-assisted A-GPS to improve accuracy in urban environments, allowing users to access real-time mapping and location-based alerts through compatible services. Early FOMA handsets faced usability challenges, including limited battery performance with talk times around 2 hours due to high power demands of operations, but iterative improvements by 2004 extended this to over 4 hours through optimized and larger batteries in subsequent models. Such enhancements, exemplified in handsets like those from the 900i series, significantly boosted everyday practicality while maintaining compact designs.

Services and Applications

Multimedia Offerings

FOMA's multimedia offerings emphasized video, audio, and interactive content delivered over its high-speed packet-switched network, enabling users to access entertainment services directly on compatible handsets. A key feature was the i-motion service, launched in 2001, which provided including short news clips, mini music videos, and sports highlights from content providers. This service supported clip distribution and streaming at effective rates suitable for mobile playback, with users able to download or view content via integration. Mobile karaoke services were also available, allowing downloads of tracks and visuals for on-device use. Music and ringtone downloads were facilitated through over-the-air delivery via sites, where users could preview snippets before purchasing full tracks or ringtones. Services such as Chaku-Uta enabled the acquisition of popular song clips as ringtones, while Uta-hodai allowed unlimited full-song downloads for a flat monthly fee starting in , building on earlier FOMA capabilities for audio content. These offerings supported playback on handsets with built-in music players, enhancing mobile entertainment without requiring external devices. Gaming on FOMA utilized downloadable Java-based i-appli applications, which supported richer online experiences including multiplayer modes over packet data connections. Users could access game portals via to download titles ranging from puzzles to action games, with features like motion controls in later models enabling intuitive play. Multiplayer functionality relied on FOMA's always-on packet network, allowing real-time interactions in supported titles. Camera phone integration began in 2002 with the introduction of built-in cameras on FOMA handsets, enabling photo and short followed by sharing via or early multimedia messaging services (MMS). The i-shot service permitted transmission of still images to any email-capable device, while i-motion mail supported video clips up to 15 seconds in length. MMS rollout expanded these capabilities for richer media exchange among FOMA users.

Data and Voice Services

FOMA's voice services relied on circuit-switched connections using the Adaptive Multi-Rate (AMR) standardized by , operating at a primary bitrate of 12.2 kbps to deliver speech quality approaching that of wireline while optimizing in W-CDMA networks. This supported variable rates down to 4.75 kbps for robustness in noisy environments, but the 12.2 kbps mode was the default for FOMA calls, enabling clear audio transmission over the 3G infrastructure. A key feature was the support for simultaneous voice and data operations, where users could conduct a voice call while transmitting or receiving packet data, such as browsing or sending messages, without interruption—this multi-access capability was demonstrated in early FOMA handsets like the F2402 launched in 2003. Packet data services in FOMA were handled through the packet-switched domain of the UMTS core network, providing IP-based connectivity with initial downlink speeds up to 384 kbps and uplink up to 64 kbps, marking a significant upgrade from limitations. For , FOMA devices incorporated fallback mechanisms to GPRS (up to 114 kbps) and EDGE (up to 384 kbps) when in coverage areas, ensuring uninterrupted service during network transitions or in non-3G zones. This always-on IP connectivity was achieved via persistent Packet Data Protocol (PDP) contexts, allowing devices to maintain an active data session without manual reconnection, which facilitated seamless applications like and basic web access. Email and web services were enhanced through the evolution of NTT DoCoMo's platform on FOMA, which optimized packet headers to 40 bytes—leveraging the fixed-size header structure—for reduced overhead and faster loading times compared to IPv4 implementations in i-mode. This improvement enabled quicker rendering of compact pages and push-based email delivery, with i-mode mail supporting attachments up to 100 KB and integration with SMS-like messaging, making it a cornerstone for non-multimedia on mobile devices. International roaming for FOMA voice and data services began in 2003 through agreements with partners including Hutchison 3G (now part of ), allowing Japanese subscribers to access networks abroad using their domestic SIM cards and maintaining service continuity for calls and basic data. Initial supported voice at AMR rates and packet data up to available local speeds, primarily with W-CDMA operators in the UK, , , and other European markets, with GPRS fallback for reliability, paving the way for global 3G interoperability under IMT-2000 standards. These partnerships extended to by 2004, with roaming zones covering key markets and focusing on network compatibility.

Frequency Allocations

Allocated Spectrum Bands

The primary spectrum bands allocated for Freedom of Mobile Multimedia Access (FOMA) operations in consist of the 2.1 GHz frequency range, specifically the uplink band from 1920 to 1980 MHz paired with the downlink band from 2110 to 2170 MHz. These bands support 5 MHz carriers, enabling the deployment of wideband code division multiple access (W-CDMA) technology for high-speed data and multimedia services. To extend coverage in rural and mountainous areas, received additional allocation in the 800 MHz band post-2005, with services commencing under the FOMA Plus Area initiative in June 2005. This band utilizes uplink frequencies from 830 to 840 MHz and downlink frequencies from 875 to 885 MHz, also structured in 5 MHz carriers, leveraging lower-frequency for improved penetration and wider area coverage. To address capacity in urban high-traffic areas, received allocation in the 1.7/1.8 GHz band ( Band IX) in 2005, with services commencing in June 2006. This band utilizes uplink frequencies from 1749.9 to 1784.9 MHz paired with downlink frequencies from 1844.9 to 1879.9 MHz, supporting 5 MHz carriers for W-CDMA to handle increased demand in densely populated regions. Channel arrangements in both bands follow the W-CDMA standard with a 200 kHz raster for carrier centers, facilitating paired frequency division duplex (FDD) operations within the allocated spectrum. These allocations align with the global IMT-2000 standards for third-generation mobile systems, as specified by the International Telecommunication Union, ensuring compatibility with international 3G frameworks while tailored to Japan's regulatory spectrum assignments.

Regulatory Framework

The regulatory framework for Freedom of Mobile Multimedia Access (FOMA), Japan's pioneering 3G mobile service launched by NTT DoCoMo in 2001, was established under the oversight of the Ministry of Internal Affairs and Communications (MIC), then known as the Ministry of Posts and Telecommunications (MPT). The MPT initiated the process for third-generation (3G) mobile licenses in the late 1990s to enable advanced multimedia services, with draft guidelines released in July 1998 and final policies approved in March 2000. Applications were accepted from April to May 2000, culminating in the granting of three licenses in June 2000 to the incumbent operators: NTT DoCoMo, KDDI, and J-Phone Communications. Japan employed a "beauty contest" licensing model, a comparative selection process that prioritized operators' proposed , technical capabilities, and deployment plans over financial bids, rather than a traditional . This approach aimed to ensure robust network rollout and innovation in mobile multimedia, with no upfront fees required—only annual radio usage fees estimated at approximately USD 5 per subscriber. NTT DoCoMo's application, emphasizing its W-CDMA and nationwide ambitions, secured the first , positioning it as the lead deployer of FOMA services. Licensees faced strict compliance requirements to promote reliable service delivery, including a mandate to achieve at least 50% coverage within five years (by 2005), focusing on urban and populated areas to support multimedia access. was enforced through adherence to standardized technologies, ensuring seamless integration with existing networks and compatibility among operators, though mandatory agreements were left to commercial negotiations. These conditions were governed by the Radio Law and the Telecommunications Business Law, with MIC monitoring progress to enforce accountability. The framework was heavily influenced by international standards to foster global harmony in services, aligning Japan's allocations—primarily in the 2 GHz band—with the International Telecommunication Union's (ITU) IMT-2000 framework. This ensured FOMA's W-CDMA system met ITU specifications for worldwide and , facilitating cross-border applications without proprietary barriers.

Impact and Legacy

Market Adoption and Competition

The adoption of FOMA began slowly following its commercial launch in October 2001, with subscriber numbers reaching approximately 150,000 by the end of 2002 amid challenges with availability and high costs. Growth accelerated in subsequent years as network coverage expanded and device improvements enhanced , culminating in over 40 million FOMA subscribers by September 2008, which accounted for the majority of NTT DoCoMo's total customer base of 53 million and contributed to the company's approximately 50% share of Japan's 104 million mobile subscribers at the time. FOMA's user base was predominantly composed of urban professionals and younger demographics, who valued its advanced features such as video calling and mobile for and . These groups, often well-educated and higher-income individuals in densely populated areas like , drove demand by integrating FOMA into daily routines for content consumption and social connectivity, reflecting broader trends in Japan's mobile-savvy society. In the competitive landscape, FOMA contended with KDDI's service, which utilized 1x technology offering lower speeds of up to 144 kbps, and SoftBank's delayed W-CDMA rollout starting in 2002, which initially struggled with . NTT DoCoMo's FOMA maintained a position through its pioneering W-CDMA implementation, providing superior initial data rates of 384 kbps and earlier nationwide availability, allowing it to capture the lion's share of subscribers in during the mid-2000s. Economic factors significantly influenced FOMA's uptake, with initial monthly tariffs exceeding $100—such as comprehensive plans approaching $130 including voice and data—posing barriers to mass adoption in the service's early years. To stimulate growth, progressively lowered prices, introducing more affordable flat-rate options and subsidies by the mid-2000s, which broadened accessibility and aligned with intensifying competition from rivals offering cheaper alternatives.

Transition to Subsequent Generations

As began deploying its LTE service under the Xi brand in December 2010, the transition from FOMA to networks commenced, marking the gradual phase-out of infrastructure. This migration effort focused on reallocating and encouraging subscriber upgrades, with FOMA services maintained to support legacy users during the overlap period. As of November 2025, has partially decommissioned FOMA infrastructure, including the 2.1 GHz band, while the full sunset remains scheduled for March 31, 2026, after which all operations will shift to and beyond, allowing to repurpose bands for enhanced LTE coverage. To ensure a smooth handover without service disruptions, implemented backward compatibility through dual-mode capabilities in LTE devices, enabling automatic fallback to the FOMA network for circuit-switched voice calls via the Circuit-Switched (CS) Fallback mechanism while utilizing Xi for packet-switched data. This approach, standardized under specifications, allowed early Xi handsets to operate seamlessly across generations, supporting voice over even as data traffic migrated to LTE, thereby minimizing the need for immediate device replacements. Globally, FOMA's pioneering role as the world's first commercial W-CDMA network in 2001 significantly influenced deployments in and , accelerating 3GPP's evolution of standards and inspiring operators like in the UK and Hutchison in to launch compatible services by 2004. Its early demonstration of wideband CDMA viability significantly influenced the global adoption of W-CDMA/, which became the dominant technology by the late 2000s, serving the majority of subscribers worldwide. This set precedents for regulatory spectrum allocations and network architectures worldwide. FOMA's innovations in mobile , including the 2004 introduction of for contactless payments using embedded chips and native video , laid foundational technologies that evolved into 5G's advanced , such as enhanced NFC-based wallets and immersive video streaming. These features, integrated into FOMA handsets from the outset, influenced subsequent enhancements for secure mobile transactions and , paving the way for applications in and real-time content delivery.

References

  1. https://www.gartner.com/en/information-technology/glossary/foma-freedom-of-mobile-multimedia-access
  2. https://digitalstrategies.tuck.dartmouth.edu/wp-content/uploads/2016/10/6-0010.pdf
  3. https://www.rcrwireless.com/20001204/archived-articles/docomo-makes-foma-its-3g-brand-name
  4. https://www.zdnet.com/article/first-3g-phones-on-the-way/
  5. https://www.rcrwireless.com/20060904/archived-articles/docomo-flips-the-switch-on-hsdpa
  6. https://www.docomo.ne.jp/english/info/media_center/pr/2008/001425.html
  7. https://www.researchgate.net/publication/298230559_FOMA_makes_mobile_multimedia_come_true
  8. https://asahi-net.jp/en/service/mobile/foma/
  9. https://www.pcmag.com/encyclopedia/term/foma
  10. https://spectrum.ieee.org/nifty-new-cellular-phone-systems-race-to-capture-japans-consumers
  11. https://www.devx.com/terms/freedom-of-mobile-multimedia-access/
  12. https://phys.org/news/2004-08-ntt-docomo-motorola-3g-foma.amp
  13. https://www.docomo.ne.jp/english/corporate/about/outline/history/
  14. http://news.bbc.co.uk/2/hi/business/1572372.stm
  15. https://www.rcrwireless.com/20011101/archived-articles/foma-launches-with-mixed-evaluation
  16. https://www.docomo.ne.jp/english/corporate/ir/binary/pdf/library/earnings/fy2001_4q_e.pdf
  17. https://www.docomo.ne.jp/english/info/media_center/pr/2003/001107.html
  18. https://www.rcrwireless.com/20010928/archived-articles/docomo-to-begin-foma-handset-sales
  19. https://www.japantimes.co.jp/news/2001/08/17/business/docomos-3g-service-disappoints-users-in-trial/
  20. https://www.docomo.ne.jp/english/corporate/technology/rd/tech/
  21. https://news.cision.com/ericsson/r/ericsson-selected-by-ntt-docomo-to-deliver-world-s-first-commerical-wcdma%2Cc8603
  22. https://www.fujitsu.com/global/documents/about/resources/publications/fstj/archives/vol38-2/paper13.pdf
  23. https://www.rcrwireless.com/19991001/archived-articles/japan-gears-up-for-3g-launch-in-2001
  24. https://www.scribd.com/document/550700759/3rd-Generation-System-and-Field-trials-other-trial-system
  25. https://omdia.tech.informa.com/om138323/japan-country-regulation-overview--2025
  26. https://www.docomo.ne.jp/english/info/media_center/pr/2003/000935.html
  27. https://www.docomo.ne.jp/english/info/media_center/pr/2003/001124.html
  28. https://www.docomo.ne.jp/english/info/media_center/pr/2004/001162.html
  29. https://www.geekzone.co.nz/content.asp?contentid=2581
  30. https://www.docomo.ne.jp/english/info/media_center/pr/2004/001151.html
  31. https://www.rcrwireless.com/20040730/archived-articles/docomo-sees-13-percent-drop-in-net-profit
  32. https://www.rcrwireless.com/20030616/archived-articles/ntt-docomo-plans-foma-expansion
  33. https://www.docomo.ne.jp/english/info/media_center/pr/2004/001195.html
  34. https://www.docomo.ne.jp/english/info/media_center/pr/2006/001284.html
  35. https://www.rcrwireless.com/20020402/archived-articles/kddi-launches-cdma2000-1x-service
  36. https://www.softbank.jp/en/-/media/sb/sjp/en/corp/set/data/group/sbm/news/press/vodafone/pdf/20060407e.pdf
  37. https://www.3gpp.org/ftp/tsg_ran/wg1_rl1/tsgr1_07/Docs/Pdfs/R1-99d97.pdf
  38. https://www.etsi.org/deliver/etsi_ts/125100_125199/125101/05.11.00_60/ts_125101v051100p.pdf
  39. https://www.3gpp.org/ftp/TSG_RAN/TSG_RAN/TSGR_05/Docs/Pdfs/rp-99544.pdf
  40. https://sites.cs.ucsb.edu/~almeroth/classes/W03.595N/papers/wcdma-concepts.pdf
  41. https://www.3gpp.org/ftp/tsg_ran/wg2_rl2/TSGR2_06/Docs/Pdfs/r2-99907.pdf
  42. https://www.3gpp.org/ftp/tsg_Ran/WG1_RL1/TSGR1_02/Docs/pdfs/R1-99071.pdf
  43. https://www.3gpp.org/ftp/tsg_ran/wg1_rl1/tsgr1_09/docs/pdfs/R1-99i58.pdf
  44. https://www.3gpp.org/ftp/tsg_ran/tsg_ran/TSGR_03/Docs/Pdfs/RP-99239.pdf
  45. https://www.docomo.ne.jp/english/corporate/ir/binary/pdf/library/sec/backnumber/fy2002_e.pdf
  46. https://www.arib.or.jp/english/html/overview/doc/STD-T63v9_10/5_Appendix/Rel9/25/25104-970.pdf
  47. https://hpwiki.mcguirescientificservices.com/_media/application_notes:an-1356.pdf
  48. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol6_3/vol6_3_033en.pdf
  49. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol8_4/vol8_4_041en.pdf
  50. https://www.etsi.org/deliver/etsi_ts/123000_123099/123009/10.00.00_60/ts_123009v100000p.pdf
  51. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol6_4/vol6_4_029en.pdf
  52. https://www.etsi.org/deliver/etsi_ts/133100_133199/133102/04.01.00_60/ts_133102v040100p.pdf
  53. https://www.shmj.or.jp/english/pdf/dis/exhibi343E.pdf
  54. https://www.phonescoop.com/articles/article.php?a=6&p=1659
  55. https://www.docomo.ne.jp/english/info/media_center/pr/2003/000969.html
  56. https://www.docomo.ne.jp/english/info/media_center/pr/2004/001192.html
  57. https://www.docomo.ne.jp/english/info/media_center/pr/2004/001193.html
  58. https://www.techwalls.com/the-evolution-smartphone-models-brief-history/
  59. https://www.docomo.ne.jp/english/info/media_center/pr/2004/001220.html
  60. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol7_1/vol7_1_019en.pdf
  61. https://www.docomo.ne.jp/english/binary/pdf/support/trouble/manual/download/m702ig/M702iG_E_04.pdf
  62. https://research-api.cbs.dk/ws/portalfiles/portal/58936586/6514.pdf
  63. https://www.netlab.tkk.fi/opetus/s38042/k03/Readings/i-mode.pdf
  64. https://static.wikitide.net/keitaiwikiwiki/3/30/DevGuide_en.pdf
  65. https://www.docomo.ne.jp/english/info/media_center/pr/2005/000680.html
  66. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol7_4/vol7_4_013en.pdf
  67. https://www.neowin.net/news/ntt-docomo-to-launch-video-service-for-3g-phones/
  68. https://www.theguardian.com/lifeandstyle/2003/apr/17/shopping.digitalmedia
  69. https://www.docomo.ne.jp/english/info/media_center/pr/2007/001335.html
  70. https://www.cnn.com/2002/TECH/ptech/05/23/camera.phone.idg/index.html
  71. https://www.mitsubishielectric.com/advance-magazine/earlierissues/pdf/vol102.pdf
  72. https://datatracker.ietf.org/doc/html/rfc4867
  73. https://www.docomo.ne.jp/english/info/media_center/pr/2003/001103.html
  74. https://datatracker.ietf.org/doc/html/rfc3481
  75. https://www.bloomberg.com/news/articles/2002-09-30/docomos-3g-service-marks-subdued-milestone-as-europe-prepares
  76. https://www.itu.int/itunews/issue/2001/08/licensing3g.html
  77. https://www.docomo.ne.jp/english/info/media_center/pr/2003/
  78. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol8_2/vol8_2_031en.pdf
  79. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol10_2/vol10_2_047en.pdf
  80. https://www.umtsworld.com/industry/subscribers.htm
  81. https://www.telecomasia.net/content/ntt-docomos-3g-foma-subscribers-breach-40m-mark-1/
  82. https://www.docomo.ne.jp/english/info/media_center/pr/2008/001412.html
  83. https://info.publicintelligence.net/OSC-JapanMobilePhones.pdf
  84. https://www.sciencedirect.com/science/article/abs/pii/S0378720605000340
  85. https://dl.acm.org/doi/abs/10.5555/1140882.1709393
  86. https://www.scmp.com/article/406535/japanese-rivals-shed-light-competing-3g-strategies
  87. https://www.sciencedirect.com/science/article/abs/pii/S073658531000016X
  88. https://www.economist.com/unknown/2001/09/03/japan-rolls-out-3g-phones
  89. https://www.docomo.ne.jp/english/info/media_center/pr/2010/001494.html
  90. https://www.docomo.ne.jp/english/corporate/ir/library/presentation/191101_qa/
  91. https://www.iplook.com/info/asias-3g-shutdowns-gather-pace-i00388i1.html
  92. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol11_3/vol11_3_013en.pdf
  93. https://www.3gpp.org/ftp/pcg/pcg_15/docs/pdf/PCG15_22.pdf
  94. https://www.docomo.ne.jp/english/binary/pdf/corporate/technology/rd/technical_journal/bn/vol23_2/vol23_2_007en.pdf
  95. https://atadistance.net/2019/07/01/ntt-docomo-celebrates-osaifu-keitai-15th-anniversary/
Add your contribution
Related Hubs
Contribute something
User Avatar
No comments yet.