Future phones will have borderless displays, which extend across the entire front surface, sides, and back of the device. They may even do away with physical buttons, since further integration of display and touch technologies will replace them. And if we want to get rid of physical buttons entirely, we’ll have to deal with capacitive touch technology.

Flexible displays

One day, smartphone displays may be able to stretch and flex to fit the shape of your fingers. The technology isn’t new, but it is still in its infancy. Samsung is the company that developed the first flexible AMOLED display. It had an 800×480 resolution and was 4.5 inches in size.

LG and Samsung have already shown off a flexible 6 inch prototype in June 2013 and a curved phone model after CES in 2014. They have also shown off a curved phone prototype, the G Flex, and released a prototype with a dual-edge display at SID 2015. In June 2015, LG showed off an 18-inch rollable display. It hopes to launch a 60-inch version by 2017.

On-Cell technology

The use of on-cell phone technology is not limited to just keeping your heart beating, though. In the future, it will likely be connected to various medical devices such as heart monitors and pacemakers. With these devices, you will be able to track your health data, like your blood pressure, heart rate, and activity levels. Moreover, your phone will be able to send you alerts about diseases detected.

The future of cell phone technology will be determined by current market trends by using home VoIP phone, consumer demand, and new innovations. For example, 5G was predicted to be the future of cell phones by 2020 and will likely continue to shape the future of smart phones in the years to come.

Microfluidics

Microfluidics are becoming increasingly common in diagnostic devices. This innovative technology has the potential to help identify infectious diseases and monitor their progression. It can detect bacterial, fungal, viral, and parasitic pathogens. Examples of such diagnostics include HIV detection, tuberculosis diagnosis, and malaria diagnosis.

Microfluidic devices rely on the strange properties of liquids at a small scale to achieve precision and speed. These devices are also more affordable and simpler to manufacture. They can process small amounts of liquid to achieve automation and multiplexing. For instance, using surface acoustic wave technology, scientists can analyze tiny quantities of fluids at high speeds. This process has the potential to extend beyond medical devices and into other fields, such as agriculture.

Graphene

Graphene power cells are an excellent way to improve battery life in smartphones. They can be thinner and lighter, and they can charge up faster than current quick-charge technologies. Furthermore, they can have much higher capacity than lithium-ion batteries. In addition, graphene batteries can be made to dissipate heat more efficiently, which means they can last longer.

Graphene is the future of battery technology, and scientists are currently working to make larger sheets of graphene. Recently, scientists in Australia managed to create a graphene sheet that was as large as a credit card.

Programmable SIMs

Programmable SIMs represent the next evolution of SIM card technology. This technology is a derivative of the Global System for Mobile Communications (GSM) standard, which was developed by a consortium of 13 European mobile operators in 1982. The group later became the Global Systems for Mobile Communications Association and owns the GSM trademark. It represents mobile operators around the world. Unlike the traditional SIM card, a programmable SIM has both hardware and software components.

Programmable SIMs can help smartphones become more convenient and slimmer. By removing the SIM tray, manufacturers are able to build phones with thinner bodies and larger batteries. The technology can also be used to create more powerful connected devices with more functionality, such as slimmer tablets and laptops. It may even be possible to create smaller and lighter smartwatches.

Holographic displays

With the recent success of Google Glass, it is possible to imagine holographic displays in mobile phones in the future. However, there are several limitations to these new holographic displays. The technology currently available is limited by the computational power of the device and the number of pixels it can control. It is also only good to see holographic images and videos when you are directly in front of the device. To overcome these limitations, a new technology has been developed. It uses a special backlight and holographic video processor to improve the viewing angle of 3D videos. The researchers at Samsung Advanced Institute of Technology believe this new technology will make holographic video displays easier to integrate into mobile devices.

Another use for holographic technology is in video conferencing. Google is currently working on holographic video conferencing technology, known as Project Starline. Holographic video calls would use high-resolution cameras to produce 3D models. They would then display these images on a high-definition 3D screen.