'TD-SCDMA' (Time Division-Synchronous Code Division Multiple Access) is a
3G mobile telecommunications standard, being pursued in the
People's Republic of China by the
Chinese Academy of Telecommunications Technology (CATT),
Datang and
Siemens AG, in an attempt not to be "dependent on Western technology"
[1]. This is likely primarily for practical reasons, other
3G formats require the payment of patent fees to a large number of western patent holders
[2]. TD-SCDMA is based on spread spectrum technology which makes it unlikely that it will be able to escape completely the payment of license fees to western patent holders. The launch of an operational system was initially projected by
2005 but is now projected by
2007 [3].
Deployment and Usage
On January 20, 2006, Ministry of Information Industry of the
People's Republic of China formally announced that TD-SCDMA is the country's standard of 3G mobile telecommunication. On February 15th, 2006, a timeline for deployment of the network in China was announced, stating pre-commercial trials would take place starting after completion of a number of test networks in select cities. These trials are expected to run from March to June, 2006. TD-SCDMA enabled handsets are also set to start testing around the same time, and are expected to be available in Q2 or Q3 of 2006. TD-SCDMA 3G phones are expected to become available at the end of 2006 and other 3G networks will be delayed until TD-SCDMA is ready.
The standard has been adopted by
3GPP since Rel-4, known as "UTRA TDD 1.28Mcps Option". This, and TD-CDMA (an independently developed TDD CDMA system more closely related to
W-CDMA), are offered as air interfaces for the
UMTS-TDD system, a version of UMTS used largely to provide Internet access. The use of
TDD is more efficient than FDD at dynamically providing asymmetric data rates, which are typical in ordinary Internet use.
Technical highlights
TD-SCDMA uses
TDD, in contrast to the FDD scheme used by
W-CDMA. By dynamically adjusting the number of timeslots used for
downlink and
uplink, the system can more easily accommodate asymmetric traffic with different data rate requirements on downlink and uplink than FDD schemes. Since it does not require paired spectrum for downlink and uplink, spectrum allocation flexibility is also increased. Also, using the same carrier frequency for uplink and downlink means that the channel condition is the same on both directions, and the
base station can deduce the downlink channel information from uplink channel estimates, which is helpful to the application of
beamforming techniques.
TD-SCDMA also uses
TDMA in addition to the
CDMA used in WCDMA. This reduces the number of users in each timeslot, which reduces the implementation complexity of
multiuser detection and
beamforming schemes, but the non-continuous transmission also reduces
coverage (because of the higher peak power needed), mobility (because of lower
power control frequency) and complicates
radio resource management algorithms.
The "S" in TD-SCDMA stands for "synchronous", which means that uplink signals are synchronized at the base station receiver, achieved by continuous timing adjustments. This reduces the
interference between users of the same timeslot using different codes by improving the
orthogonality between the codes, therefore increasing system capacity, at the cost of some hardware complexity in achieving uplink synchronization.
References
1. [1]
2. ''3G Licensing introduces the W-CDMA Patent Licensing Programme at the "Low Cost 3G Devices" conference'', London, 13 March 2007
3. ''3G in China still held up'', EE Times Asia, Global Sources
See also
★
Dynamic TDMA
External links
★
TD-SCDMA Forum
★
TD-SCDMA Industry Alliance
★
China will not interfere in 3G standard selection
★
China will provide 3G Service in cities where Olympic Games 2008 are held
-
العربية
中国
Français
Deutsch
Ελληνική
हिन्दी
Italiano
日本語
Português
Русский
Español
