Wednesday, 31 August 2011

LG Thrill 4G


The first announced 3D phone was the European LG Optimus 3D, but here in the US, it’s actually the HTC EVO 3D that’s spreading the word regarding the novel feature into the minds of consumers, as it hit Sprint's shelves a couple of months ago. Very soon though, AT&T’s variant of the Optimus 3D - the LG Thrill 4G - will follow the same path, but unlike its rival, its allure is found elsewhere outside its 3D capabilities. Instead, it’s aiming to win over the hearts and minds of people by simply tantalizing them with its superior on-contract price of $99.99. Regardless of that, will it be enough to lure people in and wholeheartedly accept the novel 3D features?
Not surprisingly, the LG Thrill 4G is an almost exact facsimile to its European counterpart with the exception of its obvious AT&T branding in the rear. Nowadays, its industrial design is undeniably commonplace at this point, but despite that, it’s still one solidly constructed handset. By today’s standards though, its overall size makes it feel unwieldy at times and doesn’t quite come off as compelling to some of the razor thin designs incorporated by the heavy hitters in the big leagues.

Samsung I9103 Galaxy R


The Galaxy S lineup is no stranger to versioning - the original Galaxy S relied on half a dozen different editions to achieve its market success. Its successor will obviously take a similar path as we just got its first body double in the face of the Samsung I9103 Galaxy R. With Tegra 2 stepping in for the Exynos chipset and SC-LCD taking the place of the new generation SuperAMOLED Plus, the Galaxy Z should be covering for the cases when the Galaxy S II is just slightly out of budget, while at the same time saving on the precious AMOLED panels.
Shortly after this preview was published we were contacted by Samsung, who clarified that the handset will be available in most markets as Samsung I9103 Galaxy R. We've fixed the preview accordingly.


Samsung I9103 Galaxy R at a glance:
General: GSM 850/900/1800/1900 MHz, 3G with HSPA
Form factor: Touchscreen bar phone
Dimensions: 125 x 66.1 x 9.5 mm, 135g
Display: 4.2" 16M-color SC-LCD capacitive touchscreen, 480 x 800 pixels
CPU: Dual-core 1GHz ARM Cortex-A9 processor, GeForce GPU, Tegra 2 chipset
Memory: 1GB RAM, 2GB ROM, 8GB storage, microSD card slot
OS: Android OS, v2.3.3 Gingerbread with TouchWiz 4.0
Camera: 5 megapixel auto-focus camera with LED flash; face detection, geo-tagging; 1.3MP front-facing camera
Video recording: 720p video recording
Connectivity: Wi-Fi b/g/n, Bluetooth 2.1 with A2DP, standard microUSB port, GPS receiver with A-GPS, 3.5mm audio jack, FM radio
Battery: 1650mAh
Misc: Built-in accelerometer, multi-touch input, proximity sensor, Swype text input, Office document viewer/editor

Tuesday, 30 August 2011

Sony Ericsson Active

The Sony Ericsson Active is a tough Android Smartphone, designed for an active life. Built to last, the Xperia Active is water and dust-resistant and designed to handle whatever comes your way thanks to a responsive touchreen that even works with wet fingers. Running Android 2.3 (Gingerbread) with a 1GHz processor on board, the Active is perfect for keeping on top of your social networks, running multiple applications and staying in touch with the people that matter through email and instant messaging. Also included is a 5.0 Megapixel camera, Bluetooth, Wi-Fi and a built in multimedia player.

Sony Ericsson Txt

The Sony Ericsson Txt is a cute and compact phone that lets you textin the fast lane. With a full QWERTY keyboard with tactile, well-spaced keys, the Txt handles SMS, Email and Instant Messaging with ease. Read your messages clearly on the vivid 2.6 inch display and add photos to your messages captured with the onboard 3.15 Megapixel camera. Also included is a built in FM Radio, Bluetooth and an MP3 player with expandable memory helping you to get the most out of your phone.

Acer Liquid Metal

The Acer Liquid Metal is a stylish Android smartphone with a slender, curved design and vivid 3.6 inch touchscreen. Running Android 2.2, the Liquid Metal is powered by a Qualcomm 800MHz processor which allows for lightning quick navigation and multi-tasking. Android 2.2 supports free voice guided SatNav, Flash support in the web browser and has access to thousands of apps in the Android Market. The Acer Liquid Metal also features a 5 Megapixel camera with HD video, Wi-Fi, built in GPS and a full glass display supporting multi-touch for a fluid touchscreen experience.

BlackBerry Torch 450

BlackBerry's touchscreen operated Torch phone is great for social networking. It also offers the amazing instant messaging and email experience for which BlackBerry phones are renowned and an excellent QWERTY keyboard - all in a compact slide phone form factor.
BlackBerry phones are famed for their excellent physical QWERTY keyboards that make it fast and easy to enter text and mark them out as superb for emailing while you're on the go. The brilliant Torch is no exception. However, unlike earlier BlackBerrys, the Torch's slider form factor means that you can hide the keyboard away when it's not in use and use the touchscreen for accessing all the other great functions onboard.
And believe you me, you'll want to. Not least because the Torch doubles as a great social networking device. Live updates are seamlessly integrated, so that you can keep up to date with what's going on with your friends and family. Plus you can update your own profiles directly from your handset too.
Also onboard is Research in Motion's (RIM) highly regarded BlackBerry Maps mapping software. This combines with A-GPS support to give you peerless turn by turn directions and turn the Torch into a satellite navigation device that's easily the equal of dedicated sat navs.


To keep you entertained, a media player and web browser are installed, with high speed HSDPA support making for a smooth and satisfying mobile internet experience, as well as allowing you to access fresh content quickly.
Other features of the Torch include an attachment editor that allows you to work on documents created in all key Microsoft Office packages, a five megapixel camera with autofocus and LED flash and support for microSD cards that enables the handset's storage to be boosted by up to 32GB.

Nokia 700 Zeta


Some reports have claimed that a new Finnish-made Nokia handset named as “Zeta” will be hitting the store shelves soon. Although there are still no official words about its pricing and availability, most of the device’s specifications have already been leaked out — including a large tough screen display, a black frame with red back casing, and a 5-megapixel camera with 2592×1944 pixels resolution and LED flash.

The Nokia 700 Zeta will be powered by a Symbian “Belle”, a brand-new version of Symbian Operating system, and is aiming to become the world’s slimmest smartphone. It comes with a 1 GHz processor, a 3.2 inch AMOLED touch screen, and a built-in NFC chip which gives the device the ability to utilize some smart cards for various wireless transactions.
In terms of connectivity, the Zeta is still a winner as it has better support for 3G, GPRS, EDGE, WLAN, Bluetooth and USB. It also features a secondary camera, which could be used for video calling.

Nokia N9


The N9 is said to be the first Nokia smartphone to run on a Linux-based MeeGo operating system. It is made up of polycarbonate materials, which gives the device a competitive hardware and notable technical specifications.

The anticipated handset features a 3.9-inch AMOLED display with a resolution of 854 x 480. It has a protective glass that is made from Corning’s Gorilla Glass, and is powered by a TI OMAP3630 1GHz processor. One of the outstanding specs of the N9 is its 8-megapixel auto focus camera with a dual-LED flash that comes with Carl Zeiss optics and a 28mm lens, which could support 720p HD video (@ 30fps) recording. Aside from that, the smartphone is jam-packed with a 1GB RAM and new browsing capabilities.
Nokia N9 is also confirmed to be offering some cool applications, including the Ovi Store, Skype, Facebook and Twitter, Angry Magic Birds, Accuweather, Wi-Fi Hotspots, Foursquare and AP Mobile.

Sony Ericsson 715 mini


Ultra-compact smartphones may not be as popular as their large-screened counterparts, but that doesn't mean there isn't a nice, cosy place in the market for them, be it a bit smaller. At least, that's what Sony Ericsson tries to convince us in, by unleashing the successor of its last year super-mini, the Xperia X10 mini. The new model is identically named, except for the dropped “X10” part.

But how has the Sony Ericsson Xperia mini changed, in order to cater to this year's user requirements? Well, we guess the manufacturer has made the right moves by upping the screen size a bit, to 3”, as well as installing a faster, 1GHz processor. Is this enough to make the Xperia mini a worthy challenger in the mid-range Android space? Let us explore that!

In the box you'll find:

·                      Sony Ericsson Xperia mini
·                            Wall charger with detachable microUSB cable
·                            MH410 GreenHeart handsfree
·                            2GB microSD card
·                            Additional back cover in different color
·                            Lots of papers

Wednesday, 17 August 2011

Mobile 3rd Generation


 3rd Generation
3G or 3rd generation mobile telecommunications is a generation of standards for mobile phones and mobile telecommunication services fulfilling the International Mobile Telecommunications-2000 (IMT-2000) specifications by the International Telecommunication Union. Application services include wide-area wireless voice telephone, mobile Internet access, video calls and mobile TV, all in a mobile environment. To meet the IMT-2000 standards, a system is required to provide peak data rates of at least 200 kbit/s. Recent 3G releases, often denoted 3.5G and 3.75G, also provide mobile broadband access of several Mbit/s to smartphones and mobile modems in laptop computers.
The following standards are typically branded 3G:
§                    the UMTS system, first offered in 2001, standardized by 3GPP, used primarily in Europe, Japan, China (however with a different radio interface) and other regions predominated by GSM 2G system infrastructure. The cell phones are typically UMTS and GSM hybrids. Several radio interfaces are offered, sharing the same infrastructure:
§                                The original and most widespread radio interface is called W-CDMA.
§                                The TD-SCDMA radio interface was commercialised in 2009 and is only offered in China.
§                                The latest UMTS release, HSPA+, can provide peak data rates up to 56 Mbit/s in the downlink in theory (28 Mbit/s in existing services) and 22 Mbit/s in the uplink.
§                    the CDMA2000 system, first offered in 2002, standardized by 3GPP2, used especially in North America and South Korea, sharing infrastructure with the IS-95 2G standard. The cell phones are typically CDMA2000 and IS-95 hybrids. The latest release EVDO Rev B offers peak rates of 14.7 Mbit/s downstream.
The above systems and radio interfaces are based on kindred spread spectrum radio transmission technology. While the GSM EDGEstandard ("2.9G"), DECT cordless phones and Mobile WiMAX standards formally also fulfill the IMT-2000 requirements and are approved as 3G standards by ITU, these are typically not branded 3G, and are based on completely different technologies.
A new generation of cellular standards has appeared approximately every tenth year since 1G systems were introduced in 1981/1982. Each generation is characterized by new frequency bands, higher data rates and non backwards compatible transmission technology. The first release of the 3GPP Long Term Evolution (LTE) standard does not completely fulfill the ITU 4G requirements called IMT-Advanced. First release LTE is not backwards compatible with 3G, but is a pre-4G or 3.9G technology, however sometimes branded "4G" by the service providers. Its evolution LTE Advanced is a 4G technology. WiMAX is another technology verging on or marketed as 4G.

Mobile 2nd Generation


 2nd Generation
2G (or 2-G) is short for second-generation wireless telephone technology. Second generation 2G cellular telecom networks were commercially launched on the GSM standard in Finland by Radiolinja (now part of Elisa Oyj) in 1991. Three primary benefits of 2G networks over their predecessors were that phone conversations were digitally encrypted; 2G systems were significantly more efficient on the spectrum allowing for far greater mobile phone penetration levels; and 2G introduced data services for mobile, starting with SMS text messages.
After 2G was launched, the previous mobile telephone systems were retrospectively dubbed 1G. While radio signals on 1G networks are analog, radio signals on 2G networks are digital. Both systems use digital signaling to connect the radio towers (which listen to the handsets) to the rest of the telephone system.
2G has been superseded by newer technologies such as 2.5G, 2.75G, 3G, and 4G; however, 2G networks are still used in many parts of the world

Capacity

Using digital signals between the handsets and the towers increases system capacity in two key ways:
§                    Digital voice data can be compressed and multiplexed much more effectively than analog voice encodings through the use of variouscodecs, allowing more calls to be packed into the same amount of radio bandwidth.
§                    The digital systems were designed to emit less radio power from the handsets. This meant that cells could be smaller, so more cells could be placed in the same amount of space. This was also made possible by cell towers and related equipment getting less expensive.

Advantages

§                    The lower power emissions helped address health concerns.
§                    Going all-digital allowed for the introduction of digital data services, such as SMS and email.
§                    Greatly reduced fraud. With analog systems it was possible to have two or more "cloned" handsets that had the same phone number.
§                    Enhanced privacy. A key digital advantage not often mentioned is that digital cellular calls are much harder to eavesdrop on by use ofradio scanners. While the security algorithms used have proved not to be as secure as initially advertised, 2G phones are immensely more private than 1G phones, which have no protection against eavesdropping.

Disadvantages

§                    In less populous areas, the weaker digital signal may not be sufficient to reach a cell tower. This tends to be a particular problem on 2G systems deployed on higher frequencies, but is mostly not a problem on 2G systems deployed on lower frequencies. National regulations differ greatly among countries which dictate where 2G can be deployed.
§                    Analog has a smooth decay curve, digital a jagged steppy one. This can be both an advantage and a disadvantage. Under good conditions, digital will sound better. Under slightly worse conditions, analog will experience static, while digital has occasional dropouts. As conditions worsen, though, digital will start to completely fail, by dropping calls or being unintelligible, while analog slowly gets worse, generally holding a call longer and allowing at least a few words to get through.
§                    While digital calls tend to be free of static and background noise, the lossy compression used by the codecs takes a toll; the range of sound that they convey is reduced. You will hear less of the tonality of someone's voice talking on a digital cellphone, but you will hear it more clearly.

Mobile 1st Generation


1st Generation
The technological development that distinguished the First Generation of mobile phones from the previous generation was the use of multiple cell sites, and the ability to transfer calls from one site to the next as the user travelled between cells during a conversation. The first commercially automated cellular network (the 1G generation) was launched in Japan by NTT in 1979. The initial launch network covered the full metropolitan area of Tokyo's over 20 million inhabitants with a cellular network of 23 base stations. Within five years, the NTT network had been expanded to cover the whole population of Japan and became the first nation-wide 1G network.
The next 1G network to launch was the Nordic Mobile Telephone (NMT) system in Denmark, Finland, Norway and Sweden in 1981. NMT was the first mobile phone network to feature international roaming. The Swedish electrical engineer Östen Mäkitalo started work on this vision in 1966, and is considered to be the father of the NMT system, and by some the father of the cellular phone itself. The NMT installations were based on the Ericsson AXE digital exchange nodes.
Several other countries also launched 1G networks in the early 1980s including the UK, Mexico and Canada. A two year trial started in 1981 in Baltimore and Washington DC with 150 users and 300 Motorola DynaTAC pre-production phones. This took place on a seven tower cellular network that covered the area. The DC area trial turned into a commercial services in about 1983 with fixed cellular car phones also built by Motorola. They later added the 8000X to their Cellular offerings. A similar trial and commercial launch also took place in Chicago by Ameritech in 1983 using the famous first hand-held mobile phone Motorola DynaTAC.
AT&T's 1971 proposal for Advanced Mobile Phone System (AMPS) was approved by the FCC in 1982 and frequencies were allocated in the 824–894 MHz band. Analog AMPS was superseded by Digital AMPS in 1990.
In 1984, Bell Labs developed modern commercial cellular technology (based, to a large extent, on the Gladden, Parelman Patent), which employed multiple, centrally controlled base stations (cell sites), each providing service to a small cell area. The sites were set up so that cells partially overlapped and different base stations operated using the same frequencies with little or no interference.
Vodafone made the UK's first mobile call at a few minutes past midnight on 1 January 1985.
The technology in these early networks was pushed to the limit to accommodate increasing usage. The base stations and the mobile phones utilised variable transmission power, which allowed range and cell size to vary. As the system expanded and neared capacity, the ability to reduce transmission power allowed new cells to be added, resulting in more, smaller cells and thus more capacity. The evidence of this growth can still be seen in the many older, tall cell site towers with no antennae on the upper parts of their towers. These sites originally created large cells, and so had their antennae mounted atop high towers; the towers were designed so that as the system expanded—and cell sizes shrank—the antennae could be lowered on their original masts to reduce range.

Display Device

Virtually all mobile phones have an integrated display device, some with touch screen function. The main measurements for screen size varies greatly by model.
Manufacturers use different methods to specify display size, usually width and height in pixels or the diagonal measured in inches.
In 2011, a 3G Android Smart phone was launched with dual 3.5 inch screens. Furthermore, the screens can be combined into a single 4.7 inch which turns it into a Tablet computer. It uses a single Snapdragon processor.
A display device is an output device for presentation of information in visual or tactile form (the latter used for example in tactile electronic displays for blind people). When the input information is supplied as an electrical signal, the display is called an electronic display.
Some displays can show only digits or alphanumeric characters. They are called segment displays, because they are composed of several segments that switch on and off to give appearance of desired glyph. The segments are usually single LEDsor liquid crystals. They are mostly used in digital watches and pocket calculators. There are several types:

Smart Phones


A smartphone is a high-end mobile phone. A smartphone combines the functions of apersonal digital assistant (PDA) and a mobile phone. Today's models typically also serve asportable media players and camera phones with high-resolution touch screens, web browsers that can access and properly display standard web pages rather than only mobile-optimized sites,GPS navigation, Wifi and mobile broadband access. The term smartphone is usually used to describe phones with more advanced computing ability and connectivity than a contemporaryfeature phone, although the distinction can be vague and there is no official definition for what constitutes the difference between a smartphone and a feature phone.
A smartphone runs a mobile operating system. Widespread examples are Apple iOS, Google Android, Microsoft Windows Phone 7, Nokia Symbian, Research In Motion BlackBerry OS, andembedded Linux distributions such as Maemo and MeeGo. Such systems can be installed on many different phone models. They can run third-party applications, using an application programming interface (API).
According to an Olswang report in early 2011, the rate of smartphone adoption is accelerating: as of March 2011 22% of UK consumers had a smartphone, with this percentage rising to 31% amongst 24–35 year olds.
Growth in demand for advanced mobile devices boasting powerful processors and graphics processing units, abundant memory (FLASH memory), high-resolution screens with multi-touch capability, and open operating systems has outpaced the rest of the mobile phone market for several years. According to an early 2010 study by ComScore, over 45.5 million people in the United States owned smartphones out of 234 million total subscribers. Despite the large increase in smartphone sales in the last few years, smartphone shipments only make up 20% of total handset shipments, as of the first half of 2010. In March 2011 Berg Insight reported data that showed global smartphone shipments increased 74% from 2009 to 2010