5 science fiction technologies today 2030 reality - Over the last few decades the world has evolved dramatically. The lifestyle and amenities you have today would have been unthinkable only fifty years ago.
One of the most relevant factors in the changes we have experienced has been technology. The development of new devices, and the ability to access them easily, has greatly simplified our life.
There are some very obvious examples, such as the internet. Not so long ago phones and letters were the most common means of being able to talk to someone who was far away.
And if we wanted to get information, we had to turn to the printed sources that you had at your fingertips. This undoubtedly greatly limited the possibilities of Investigation.
Today, thanks to the internet you can talk instantly with people who are at the other end of the world. And it's relatively easy to access almost all the information and knowledge you need.
That's just one example of how technology can move a lot forward in a very short time, changing in the process the way of life and the possibilities that are at your fingertips.
Of course, advances in technology never stop. At all times, there are people working on improving products and creating new inventions that facilitate our day to day in various ways.
As in the last decade, technology has advanced a lot, it is expected that in the coming years there will also be great advances, and let's see how products come to market that until not so much sounded like science fiction.
5 science fiction technologies today 2030 reality
There are already professionals working on such projects, and thanks to this, in a few years how what is now simple theory will end up becoming something without what would be strange to live.
If you want to know what awaits us in terms of technological advances, in this article you will discover some of the technologies that in 2030 will be part of our daily reality.
- Prostheses controlled by the brain
Due to accidents or various diseases, people are born without any of their limbs, or have lost them throughout their lives. To make their life a little easier, many use prostheses of various types.
But often prostheses are not very functional, since until recently they were simply rigid limbs that do not provide any mobility, or that articulate only with external influence (for example, using the hands to move the prosthesis).
Fortunately, in recent years, prostheses have come a long way. Companies like Open Bionics have developed robotic forearm prostheses that detect the user's muscle movements and articulate the wrist and hand based on it.
In itself it is a considerable advance, as it allows to create smart prostheses, with a more natural and intuitive mobility. But there is a step beyond prosthetics connected to the nervous system.
Having a direct connection to the brain, moving and articulating these prostheses is as simple as thinking about the movement you want to make. Although of course, creating something like this is not so simple.
To make these prostheses work, they must be connected by electrodes and other similar systems to the brain, the nervous system, and even the bones. These electrodes detect the signals of the body itself and send them to the prosthesis, making it perform the movements thought by the user.
To top it off, the signals can go both ways. And if the prostheses include sensors, this makes users artificially have a sense of touch on their prosthesis.
There has already been some small-scale testing with prototypes, and they seem to show that this type of technology is viable. Considering this, it is expected that by the year 2030 most prostheses will be controlled with the brain and allow to perceive different sensations.
- Flying wind turbines
Generating renewable energy is something that has been in the minds of many scientists for a long time. And the worse the problems caused by climate change, the more urgent is the search for viable energy solutions.
Of course, renewable energy technologies already exist. Some of the most common are solar panels and wind turbines, very common throughout the peninsula.
But under certain conditions, these devices may not be particularly efficient. The location where they are installed influences, of course, but when it comes to wind turbines height is one of the most relevant factors. "As you have seen many times, wind turbines are installed on very high towers to make the most of the force of the wind. And is that the higher the height, the higher the wind speed, so it allows to produce more energy.
However, with ordinary solar turbines there are limitations. For the structure to be stable and safe, the towers on which they are installed cannot exceed a certain height, and this of course affects the efficiency of the turbine.
To solve this problem, the possibility has been raised of creating wind turbines that remain in the air, thus allowing them to be placed at higher altitudes and thus generate more energy.
Oddly enough the idea of flying wind turbines sounds, some prototypes have shown very promising results. Therefore, we can expect that by 2030, this type of turbines will be launched on the market.
If you don't know how they would work, there are different systems that can keep them in the air. Some have helium inside, others have a system of wings as a glider, others have kites installed... that is, there are different options.
In addition, although there is no tower under this type of turbines, they always have a connection to the ground. Usually it is some type of high-strength cable, which also allows the transmission of energy obtained by the turbine.
- Smart clothing and fabrics
Smart devices have become part of the norm in recent years. You use smartphones, smart wristbands, and also various devices at home that make your life much easier.
And it is increasingly common for more ordinary devices to have technology implemented that goes beyond their usual functions. Having even the fridge and food processor connected to the internet is becoming more common every day.
Something a lot of resources have been devoted to is developing smart devices that you can carry around. Of course, phones are a clear example of this, but in the future it is expected that this technology will be applied to other very different objects.
During the next decade it will be possible to enjoy the incorporation of technology into something without what you never leave home: clothing. Several companies have been working on smart fabrics for a long time, and it doesn't seem to take too long for it to become a reality.
Smart textile products can have a wide variety of uses, which would allow them to be applied in areas beyond everyday life. For example, clothing could be developed to collect data about the body, such as heart rate or blood oxygen or sugar levels.
This could be particularly useful in hospital patients, and in people suffering from chronic diseases or requiring medical supervision of some kind. It could also help athletes, as they would have information at all times about their fitness.
Smart fabrics are also being developed with other applications. For example, there are some dedicated to protection (able to react to external stimuli and change their structure according to needs), or fabrics able to adapt and change based on temperature.
Other simpler smart fabrics, which have in fact been on the market for some time (though not affordably) are textiles that change color or light up.
In general the possibilities are endless, and it is expected that in the next ten years fabrics with technological applications included will be much more common, becoming another device that we use daily.
- Technology implanted in our body
Continuing with the theme of bringing technology always on top, there are other types of products that, based on what some companies are doing today, are likely to be available around the year 2030: technological implants.
Something that has profiled a lot in recent years is the reduction in the size of technological devices. Of course, when there are built-in screens are usually larger. But that is something that is done out of user preference, not out of necessity.
Storage devices are the most obvious case. An external hard drive that fits in the palm of our hand can easily store several terabytes of data. And Micro SD cards, which are barely the size of the bud of a finger, are already able to store around 1TB.
The same applies to any device you use on a daily basis. Smartphones, cameras, televisions, computers ... everything is much more powerful and functional than years ago, despite the fact that the size of its components has been significantly reduced.
With this in mind, it is not surprising that some companies have imagined the possibility of creating tiny devices that we can implant under our skin, thus eliminating the need to carry a product on top.
Some experts predict that over the next decade you will witness how different smart devices implantable in the body come to market. And these predictions are not based solely on your imagination; there have already been several such implants.
On several occasions small chips have been implanted in the brain that can be controlled from any smartphone and allow to control brain activity and certain motor functions.
And some companies have developed technological implants that have practical use in everyday life. For example, in I am ROBOT have created NFC implants that are inserted under the skin of the hands.
These small chips fulfill all the functions that current NFC devices have. For example, they can transmit small amounts of information, make payments, or even open doors with locks suitable for this.
Since it is already possible to have an NFC chip implanted in hand, it is assumed that in the coming years other devices will follow the same path. So it is very feasible that the predictions of experts come true.
- 3D printing of organic material
Another big change has been seen in recent years, in terms of product manufacturing, has been the implementation of 3D printers. they are able to create from the simplest objects to very complex products.
Originally 3D printers were quite limited. Most used different plastic compounds for printing, took a lot of hours to complete a process, and were not particularly good with more detailed projects.
But as with everything in the world of technology, they have improved rapidly, allowing them to be implemented in very diverse fields, and gradually becoming much more affordable.
However, 3D printers have not even remotely reached the limit of their potential. There is an idea that takes time on the table, and that is slowly becoming reality: organic tissue printing, better known as bio-printing.
The applications of this type of technology are mainly focused on the field of medicine, since 3D printing could allow printing organs and various tissues intended for research, surgical procedures and even transplants.
In fact, as you already knew a few months ago in this report, various laboratories and research centers have already managed to bio-print various organs and parts of the body successfully.
These organs are not yet functional, and very little has yet been experimented with them. But its advantages are obvious, so we can expect great advances in the next decade, and perhaps great changes in medicine as a result.
For example, those who need a transplant would not have to spend months, or even years, waiting until there is a compatible organ for them. A printer could create any organ in a matter of hours, which would not only improve the quality of life of many people, but even save lives.
However, the applications of bioimpression are not limited to the field of Medicine. The food industry could benefit greatly from bio-printing, as it would make it possible to obtain certain products ethically.
The main use that has been given in relation to food is the bioimpression of meat products. Livestock is one of the most polluting human activities, and in the face of growing concerns about climate change and animal welfare, some companies have developed alternatives focused on 3D printing.
The option they propose is to print meat directly, without the need to spend large amounts of resources on livestock, and also avoiding the slaughter of animals in the process.
Some companies use animal cells for their meat bioimpression. The cells can be obtained from a live animal, and grown to multiply, thus generating the raw material needed for bioimpression.
But others, such as the Spanish company NOVAMEAT, use vegetable proteins to print vegetable meat. It may not come from an animal, but thanks to the amount of research they have done, the end result has the same taste, texture and appearance as a piece of real meat.
In both cases, the benefits go beyond helping to combat climate change and prevent animal deaths. Being artificially created, the printed meat could be altered to remove substances that cause health problems, such as cholesterol, and add other beneficial to us, such as Omega 3.
5 science fiction technologies today 2030 reality