Category: Gadgets

About Mobile Computer

Mobile computers such as smartphones, tablets, laptops, and notebooks have operating systems that are capable of performing basic functions similar to that of a personal or desktop computer. Mobile computing devices offer location-based services and e-commerce applications when connected to the Internet. Yet, the ability of a mobile computing device to perform different functions depends primarily on its processor speed and memory capacity. Devices such as smartphones and tablets provide the extended function of browsing the Internet on the go, in addition to other computing features.

Global mobile computer market to grow at a CAGR of 4.13% during the period 2016-2020.

Covered in this report

The report covers the present scenario and the growth prospects of the global mobile computer market for 2016-2020. To calculate the market size in terms of both revenue and shipments, the following devices have been considered:

• Smartphones
• Tablets
• Laptops
• Notebooks

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Global Mobile Computer Market 2016-2020, has been prepared based on an in-depth market analysis with inputs from industry experts. The report covers the market landscape and its growth prospects over the coming years. The report also includes a discussion of the key vendors operating in this market.

Key vendors
• Samsung
• Apple
• HP
• Dell
• Xiaomi
• Lenovo

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Other prominent vendors
• Sony
• Acer
• Asus
• Blackberry
• HTC
• Huawei
• LG
• Microsoft
• Toshiba
• Xiaomi

Market driver
• Rising demand for mobile computers from enterprises
• For a full, detailed list, view our report

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Market challenge
• Intense competition among vendors and segments
• For a full, detailed list, view our report

Market trend
• High acceptance of bring your own device (BYOD) and corporate owned, personally enabled (COPE) strategies
• For a full, detailed list, view our report

This tiny wearable allows wearers to benefit from glucose monitoring and AR tech at the same time.

A team of researchers at the University of South Australia have now created the prototype for a piece of wearable technology in the form of a contact lens that sounds more like science fiction than actual reality.

At the same time that smart glasses haven’t seen the hoped-for adoption, this eyewear offers a unique experience.

The contact lenses have been created to be a wearable technology that is electrically conductive and that could potentially host tiny displays. The tech would make it possible for a wearer to receive health feedback, such as blood sugar levels, and would be able to take advantage of certain augmented reality displays that would be shown as an overlay on top of the actual visible environment around them.

This type of wearable technology has been the pursuit of a few different teams around the world.

That said, the University of South Australia researchers from the Future Industries Institute (FFI) have been making some astounding advancements in the area of ultra-thin film tech sensors and displays. Previously, the same team of researchers have managed to come up with a type of thin reflective film coating that would improve the efficiency of vehicles. This same material could be used for the creation of smart windows on a building, so the amount of sunlight entering a room could be controlled.

That said, the most recent focus of the team has changed directions to a more medical pursuit. According to Drew Evans, an FII associate professor from the research team, “We have always known that our film coating technologies had potential for many applications and now we have taken that a step further by proving that we can make biocompatible, conducting polymers at the nanoscale and grow them directly on a contact lens.”

The wearable technology prototype was designed by using a layer of hydrated hydrogel substrates on the lens, which made it possible for a PEDOT polymer to be added to the lens surface. That polymer was engineered to be highly conductive at the same time that it is bio-compatible. Moreover, the team treated the hydrogel with plasma ahead of the application in order to ensure improved adhesion.