I blogged few months back about SMS for emergency services in USA now the same is being tried in UK.
Ofcom is trialling a new system to let deaf people access 999 services using text messaging.
The system lets users who can’t speak send a text message to emergency services. Their text is received by 999 assistants and read out to fire, police or other emergency service. A reply is also sent back via SMS.
The trial kicked off earlier this month, with Ofcom asking people to register to test the service. As the trial will use actual emergency messages, it needs enough people to register to get a good feel for how the system is working as most won’t actually have cause to use it.
To register, text “register” to 999; anyone not registered will not be able to use the service.
Ofcom noted that users shouldn’t assume their message has been received until they’ve received a reply, and that anyone sending hoax messages will be prosecuted.
If the trial goes well, the texting system could be in place as early as next year, Ofcom said. It’s being supported by the major telecoms companies, as well as emergency services and the Royal National Institute for Deaf People (RNID).
SMS to the emergency website here.
Tuesday, 22 September 2009
Monday, 21 September 2009
HSPA Functions and Benefits
Very interesting diagram summarising HSPA Functions and Benefits
Source: 3G Americas Whitepaper, HSPA to LTE-Advanced: 3GPP Broadband Evolution to IMT-Advanced (4G)
Labels:
HSPA,
Technical Details
Friday, 18 September 2009
Network Interfaces for Applications using Parlay and OneAPI
Here is an old posting on Parlay/OSA that might be useful to put things in context.
An important development related to service evolution is operators making interfaces available to external applications for information and control. Two widely deployed capabilities today include location queries and short message service. With location, mobile devices or external applications (e.g., applications operating on computers outside of the network) can query the location of a user, subject to privacy restrictions. This can significantly enhance many applications including navigation, supplying location of nearby destinations (e.g., restaurants, stores), location of friends for social networking, and worker dispatch. With SMS, external applications can send user requested content such as flight updates.
Until now, the interfaces for such functions have either been proprietary, or specific to that function. However, there are now interfaces that span multiple functions using a consistent set of programming methods. One set is the Parlay X Web Services, a set of functions specified through a joint project of the Parlay Group, the European Telecommunications Standards Institute (ETSI) and 3GPP. The Open Mobile Alliance (OMA) now manages the Parlay X specifications. Parlay X Web Services include support for location and SMS, as well as many other functions with which developers will be able to build innovative applications.
Table 4 (above) summarizes the available Parlay X specifications. Operators are beginning to selectively deploy these functions. The advantage of this approach is that developers can build applications that are compatible with multiple operator networks.
A related project is GSMA OneAPI, a GSM Association project to also define network interfaces, but that prioritizes implementation based on expected market demand. OneAPI defines a simplified Web service for most functions that is essentially a subset of the related Parlay X Web service. It also defines a REST (Representational State Transfer) interface for most functions as an alternative to using the Web service. RESTful interfaces are simpler for developers to work with and experiment with than Web services.
Regardless of whether operators deploy with Parlay X or OneAPI, these are mainstream interfaces that will open wireless networks to thousands of Internet programmers who will be able to build applications that leverage the latent information and capabilities of wireless networks.
Thursday, 17 September 2009
Wireless Subscribers Forecast 2014
Source: Informa Telecoms & Media, WCIS+, June 2009
Via: 3G Americas Whitepaper, HSPA to LTE-Advanced: 3GPP Broadband Evolution to IMT-Advanced (4G)
Wednesday, 16 September 2009
Opera Mini: Better and More Popular
Opera Mini has been downloaded more than 25 million times from the GetJar mobile application store, the companies said.
The mobile browser is one of the most popular in the world because it is available on a variety of devices including Java, Android, BlackBerry, Windows Mobile, and other handsets. It is also able to run on relatively low-end hardware because it uses server-side compression technology to minimize the processing and bandwidth requirements.
Opera is bringing multipage browsing to its popular Mini browser, with a beta rolling out today. Mini 5.0 also gets a slick visual makeover, and touch support on devices that accept touch input.
Underneath it's the familiar Opera 4 Mini engine with a few tweaks, and existing users will be relieved that key shortcuts have been retained. But the proliferating screens of settings, bookmarks etc are now accessible by a pulldown menu. The address bar and search bar are integrated into the page view, almost exactly in the manner of iPhone Safari. Usually the ideas in the browser flow the other way.
Opera Mini 5, out now in beta, features a sleek new design to give the browser a more intuitive look and feel, the firm said. Also included is tabbed browsing, enabling users to browse several sites simultaneously, and support for touch screen as well as keypad-based browsing.
A Password Manager function acts as a "virtual memory bank" to store all a user's passwords for email, social networking and other online accounts, according to Opera.
Finally, Opera Mini 5 features Speed Dial, providing users with pre-selected web sites on loading the browser to jump straight to the content they want.
"The idea of navigating the vastness of the web from such a small screen can be a daunting leap, which is why we have long committed to make the browsing experience you are familiar with from your PC, easy to do on your mobile phone," said Jon von Tetzchner, chief executive of Opera Software.
"With new sleek navigation buttons, tabbed browsing and Speed Dial bookmarks, you are never more than a click away from where you want to go on the web."
Monday, 14 September 2009
TD-SCDMA, TDD and FDD
After my posting on TD-SCDMA so many people asked me about what TD-SCDMA is. I am surprised that so many people are not aware of TD-SCDMA. So here is a quick posting on that.
Basically most of the UMTS networks in operation are Frequency Division Duplex (FDD) based. There is also another variant called the Time Division Duplex or TDD. In reality there is more than one variant of TDD, so the normal 5MHz bandwidth TDD is called Wideband TDD of WTDD. There is also another name for WTDD to confuse people, called the High Chip Rate TDD (HCR-TDD). There is another variant of TDD as would have guessed known as the Narrowband TDD (NTDD). NTDD is also known as Low Chip Rate TDD (LCR-TDD) and most popularly its known as TD-SCDMA or Time Division Synchronous CDMA.
"Synchronous" implies 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.
The normal bandwidth of FDD or TDD mode of operation is 5 MHz. This gives a chip rate of 3.84 Mcps (Mega chips per second). The corresponding figure for TD-SCDMA is 1.66 Mhz and 1.28 Mcps.
The advantage of TDD over FDD are:
By the way, in Release 7 a new TDD mode of operation with 10 MHz bandwidth (7.86 Mcps) has been added. Unfortunately I dont know much about it.
You can read more about TD-SCDMA in whitepaper 'TD-SCDMA: the Solution for TDD bands'
TDD and FDD Mode of Operation
Basically most of the UMTS networks in operation are Frequency Division Duplex (FDD) based. There is also another variant called the Time Division Duplex or TDD. In reality there is more than one variant of TDD, so the normal 5MHz bandwidth TDD is called Wideband TDD of WTDD. There is also another name for WTDD to confuse people, called the High Chip Rate TDD (HCR-TDD). There is another variant of TDD as would have guessed known as the Narrowband TDD (NTDD). NTDD is also known as Low Chip Rate TDD (LCR-TDD) and most popularly its known as TD-SCDMA or Time Division Synchronous CDMA.
"Synchronous" implies 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.
The normal bandwidth of FDD or TDD mode of operation is 5 MHz. This gives a chip rate of 3.84 Mcps (Mega chips per second). The corresponding figure for TD-SCDMA is 1.66 Mhz and 1.28 Mcps.
Assymetric operation in TDD mode
The advantage of TDD over FDD are:
- Does not require paired spectrum because FDD uses different frequencies for UL and DL whereas TDD uses the same frequency hence its more easy to deploy
- Channel charachteristics is the same in both directions due to same band
- You can dynamically change the UL and the DL bandwidth allocation depending on the traffic.
- Switching between transmission directions requires time, and the switching transients must be controlled. To avoid corrupted transmission, the uplink and downlink transmissions require a common means of agreeing on transmission direction and allowed time to transmit. Corruption of transmission is avoided by allocating a guard period which allows uncorrupted propagation to counter the propagation delay. Discontinuous transmission may also cause audible interference to audio equipment that does not comply with electromagnetic susceptibility requirements.
- Base stations need to be synchronised with respect to the uplink and downlink transmission times. If neighbouring base stations use different uplink and downlink assignments and share the same channel, then interference may occur between cells. This can increase the complexity of the system and the cost.
- Also it does not support soft/softer handovers
By the way, in Release 7 a new TDD mode of operation with 10 MHz bandwidth (7.86 Mcps) has been added. Unfortunately I dont know much about it.
You can read more about TD-SCDMA in whitepaper 'TD-SCDMA: the Solution for TDD bands'
You can find more information on TD-SCDMA at: http://www.td-forum.org/en/
Sunday, 13 September 2009
Scratch Input: Future Input for Mobile Phones
Very interesting...not being able to see past your fingers on smaller devices. That's where "scratch input" comes in. Harrison's prototype uses a digital stethoscope to pick up the sound of scratching on a table or wall. The device attached to the stethoscope, be it a phone, watch or a computer, is programmed to recognise the sounds of different scratch gestures. By tracing a spiral on his desk, Harrison can, for example, turn the volume down on his media player. Ultimately the microphone would be built into the device. Imagine a touch screen watchphone that can be controlled simply by scratching your arm.
You may be interested in reading this article Touch Screens at The Independent here.
Labels:
Concept Mobile,
Future Technologies,
Videos
Friday, 11 September 2009
Ericsson's Exciter: Conceptual mobile Personal Area Mediator (PAM)
Interesting Video:
If you find this interesting, there is a presentation you can look at here. Unfortunately its in swedish but you can get an idea about which direction things will be going in future.
If you find this interesting, there is a presentation you can look at here. Unfortunately its in swedish but you can get an idea about which direction things will be going in future.
Labels:
Ericsson,
Future Technologies,
Videos
Thursday, 10 September 2009
Huawei becomes a big player in LTE
[Shenzhen, China, 1 September 2009] Huawei, a leader in providing next-generation telecommunications network solutions for operators around the world, today announced that it has been granted 147 Long Term Evolution (LTE) patents by the European Telecommunications Standards Institute (ETSI), representing 12 percent of the total existing 1,272 LTE patents assigned by ETSI as of August 2009. The patents granted were across several key LTE sub-sectors, such as physical-layer air interface, radio resource management and connection management.
Huawei’s robust investment in LTE research and development has accelerated the commercialization of LTE technology. In June 2009, Huawei connected the world’s first LTE mobile broadband internet connection for Teliasonera in Oslo, Norway.
Huawei is an active participant in 91 standardization organizations, with over 100 committee leadership positions. In 2008, Huawei had filed a total of 35,773 patent applications globally.
Last year LG had claimed that it has upto 300 patents, not sure if that is still true.
Huawei’s robust investment in LTE research and development has accelerated the commercialization of LTE technology. In June 2009, Huawei connected the world’s first LTE mobile broadband internet connection for Teliasonera in Oslo, Norway.
Huawei is an active participant in 91 standardization organizations, with over 100 committee leadership positions. In 2008, Huawei had filed a total of 35,773 patent applications globally.
Last year LG had claimed that it has upto 300 patents, not sure if that is still true.
New report on Mobile Broadband Evolution from HSPA to LTE-Advanced
The white paper, HSPA to LTE-Advanced: 3GPP Broadband Evolution to IMT-Advanced (4G), discusses the 3GPP evolution of EDGE, HSPA and LTE, their capabilities and their positions relative to other primary competing technologies and how these technologies fit into the ITU roadmap that leads to IMT-Advanced.
The following are some of the important observations and conclusions of the report:
- HSPA Evolution (HSPA+) provides a strategic performance roadmap advantage for GSM-HSPA operators. Features such as dual-carrier operation, MIMO and higher-order modulation offer operators multiple options for improving their networks, and some of these features are simply network software upgrades.
- Persistent innovation in developing HSPA and HSPA+ is bringing UMTS to its full potential providing mobile broadband to the mass market; in current deployments, HSPA users regularly experience throughput rates well in excess of 1 Mbps under favorable conditions, on both downlinks and uplinks, with 4 Mbps downlink speed commonly being measured. Planned enhancements such as dual-carrier operation will double peak user-achievable throughput rates.
- LTE has become the next-generation platform of choice for GSM-HSPA and CDMA/EV-DO operators.
- The 3GPP OFDMA approach used in LTE matches or exceeds the capabilities of any other OFDMA system providing the most powerful wide area wireless technology ever developed. Peak theoretical downlink rates are 326 Mbps in a 20 MHz channel bandwidth.
- 3GPP has made significant progress investigating how to enhance LTE to meet the requirements of IMT-Advanced in a project called LTE-Advanced.
With a customer base of 4 billion connections today, the GSM family of technologies is available on nearly 800 networks in 219 countries worldwide. Building on this base, UMTS-HSPA – the world’s dominant mobile broadband technology today – has proven to be the most widely deployed and adopted 3G technology of all time, with more than 352 operators in various stages of deployment, including 277 commercial HSPA networks in 116 countries.
The white paper explains the tremendous opportunity afforded to GSM-HSPA operators via the 3GPP roadmap to HSPA+. While OFDMA systems such as LTE and WiMAX have attracted a great amount of attention, evolving HSPA to exploit available radio technologies can significantly enhance its performance capabilities and extend the life of sizable operator HSPA infrastructure investments. Techniques include advanced receivers, MIMO, Continuous Packet Connectivity, Higher-Order Modulation and One Tunnel Architecture, many of which are included in the standardization of 3GPP Release 7 and Release 8.Depending on the features implemented, HSPA+ can exceed the capabilities of IEEE 802.16e-2005 (Mobile WiMAX Release-1) in the same amount of spectrum. Beyond the peak data rate of 42 Mbps for HSPA+ in Release 8 (with 2X2 MIMO, DL 64 QAM and UL 16 QAM), Release 9 may specify 2X2 MIMO in combination with dual-carrier operation, which would further boost peak theoretical downlink network rates to 84 Mbps. In addition to the increased speeds, HSPA+ also will more than double HSPA capacity and has the potential of reducing latency to below 25 milliseconds.
HSPA and HSPA+ will continue to dominate mobile broadband subscriptions worldwide for the remainder of this decade and well into the next. However, announcements have already begun in support of the next 3GPP evolutionary step, LTE. Trials and deployments of LTE will begin in 2010 by leading operators including AT&T, China Mobile, China Telecom, NTT DoCoMo, Verizon and Vodafone. In fact, today there are more than 2 billion subscriptions represented by combining the total existing customer bases of the more than 100 operators, both GSM and CDMA operators, who have announced indications of their intention to deploy LTE networks.
The deployment of LTE and its coexistence with UMTS-HSPA will be analogous to the deployment of UMTS-HSPA and its coexistence with GSM-EDGE.
Whitepaper available to download here.
Accompanying slide presentation available here.
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