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Our world is changing more and more each day. The science fiction and wishful thinking of
yesteryear is rapidly becoming the reality we take for granted. Entrepreneurs, engineers,
and inventors are all busy building a world in which technology sinks its roots, deep
into our daily lives, enabling lightning fast access to a worldwide repository of information
and empowering us to reach further than ever before. Let’s take a look at nine real life
examples that show us we metaphorically are living in the future.
Imagine a world in the not-too-distant future where you’re planning a family vacation
amongst the stars. You browse the list of available flights, trying to decide which
exotic locale it will be this year. The moons of Jupiter, perhaps? Or maybe you’ll book
a flight back to Venus again—the sunsets from the city floating among the toxic clouds
simply cannot be rivaled anywhere else in this Local Galactic Group.
All made possible thanks to the money and manpower of far-seeing Earth based companies
who made affordable and efficient spaceflight a priority many years before. It may sound
like the beginning of a sci-fi novel, but companies like SpaceX, Blue Origin and ***
Galactic are working to turn it into a reality. The world of privatized spaceflight was rocked
by spectacular news in November of 2015, with entrepreneur Elon Musk’s brainchild SpaceX,
landing a deal to become the interstellar Uber for NASA astronauts, wanting to reach
the International Space Station. This is especially big news, as pending successful test runs
by SpaceX, NASA will no longer be required to rely upon their Russian counterparts to
ferry them to and from low earth orbit. They hope to begin crewed spaceflights in SpaceX’s
luxurious Crew Dragon spacecraft by 2017. Jeff Bezos’ company Blue Origin has been
giving SpaceX a run for their money of late, in the race to produce the first fully reusable
rocket—a massive achievement in the space business, as reusable rockets will dramatically
cut costs to put people into orbit. There has been some friendly sparring over social
media between Musk and Bezos, after Blue Origin claimed to be the first to reach orbit with
a rocket which landed safely after its ascent. Regardless of who’s right in the end, ultimately
it’s space agencies, all across the world that will certainly be the ones who win from
such fierce competition. Even aviation giant Boeing is joining in on
the orbital fun, having recently unveiled their own craft, the “Starliner”. Also
under contract with NASA, Boeing hopes to position the Starliner as a replacement, so
the agency no longer has to rely upon the Russian Soyuz craft. For the first time, NASA
will have plenty of choices when it comes to choosing their next vehicle for space travel.
Meanwhile, Richard Branson and the folks at *** Galactic, are hard at work making space
accessible to the masses. They seek to stake a claim in the space tourism business, setting
their sights a little lower than their peers, but with the hopes that additional public
exposure to space will benefit the entire private spaceflight industry. Sure, they’ve
had some significant setbacks in their quest, but Branson and his team doggedly continue
to chase their dream. Between Boeing, *** Galactic, SpaceX, and
Blue Origin, it’s not a matter of “if” the private sector will help to usher in a
new age of prosperity in spaceflight, but when. Nothing drives progress like competition,
especially when money is involved. And when these companies do achieve their goals, eventually
the opportunity will come for every one of us to experience the vast reaches of outer
space, first hand. Where there are spaceships in science fiction,
there are powerful drive cores that enable the physics defying, faster-than-light travel,
necessary to bring galaxies together, and enable the exploration of strange new worlds.
Warp drives were once little more than wishful thinking on the part of artistic visionaries,
but recently NASA announced an experimental Electro-Magnetic Drive that, if proven to
be science fact, could very well be the breakthrough, aspiring space pioneers have been waiting
for. Despite being a theoretical impossibility—a
fact which skeptics are quick to point out—NASA’s experimental EM Drive continues to pass volleys
of tests that seem to prove it is actually producing thrust. The science behind the EM
Drive involves pushing microwaves into a closed cone from the large end to the smaller end,
which seems to be producing minute measures of thrust, through processes no one is quite
certain about. In essence, the drive becomes a propellant-less propulsion system. The thrust
is barely even measurable at the moment, but breaking the laws of physics simply can’t
be rushed. A functional EM Drive would cut down the trip
to Mars from many months to a little over two. In addition, it would only need a relatively
small amount of power to operate—something that current technology would be more than
capable of providing. But for all this wishful thinking, there is one inescapable truth about
the drive NASA is struggling to figure out—it doesn’t abide by known universal truths.
In other words, there is not yet a theory for how it functions, that doesn’t involve
the odd flaw or two. Possible flaws in the experiment are still
being ferreted out, with the system showing noteworthy amounts of thermal expansion that
could be skewing the results, but the researchers assert that despite the potential vectors
for failure, the EM Drive continues to produce “anomalous thrust signals”. And if there’s
one thing scientists like, it’s a good anomaly in data sets.
Propulsion systems like the EM Drive will prove to be critical pieces of equipment in
long-term space ventures, such as a trip to Mars or beyond, as they reduce or completely
mitigate the need for fuel and the weight that it adds to the vessel. Unfortunately,
however, despite the tentative success of the EM Drive, NASA asserts that it is not
in fact working on anything like “warp” technology. Which means that we won’t be
venturing out of our solar system anytime soon, but hey, there’s still plenty we have
yet to explore in our own interstellar neighborhood. Perhaps we earthlings should learn to be content
with what we have. Nah, space exploration is exciting.
Perhaps you’ve always wanted to live the life of a cyborg. Forever connected to the
tangled web of computers and digital devices that crisscrosses our world. But lugging around
an unwieldy laptop is often more trouble than it’s worth.
That’s why innovators and engineers have spent the last two decades finding novel ways
to fit the full experience right in your pocket. Never miss a moment on social media, work
on the go, or get a little exercise—wearable computers are here to keep you plugged in.
For better or for worse. Thanks to “the cloud”—otherwise known
as the seemingly omnipresent server bank in the sky—anything we can do on one electronic
device can be sent to all our other devices at the push of a button. Start a project on
your tablet, and pick up where you left off on your desktop when you get home. Take pictures
with a cloud-connected camera, and you’ll find them ready to edit on your laptop in
moments. All of this requires an internet connection, but that single lifeline tethers
all of your devices into a single, thriving ecosystem of interconnectivity and accessibility
the likes of which has never been seen before. An entire industry has been built around cloud-based
backups, meaning you never have to worry about losing your precious puppy photos ever again.
Every major player in the computing world today has developed their own form of speech
recognition, and for good reason. As devices get smaller, it becomes less and less convenient
to mash away on a virtual keyboard while writing your magnum opus or searching for cat videos.
And if there’s one thing that Star Trek has taught us, it’s that the future is a
friendly and omniscient computer that we can query at our leisure. When combined with the
power of the cloud, voice recognition ensures that any of your questions can be answered—and
your all-important spreadsheets for that meeting can be found, wherever you are—with a simple
voice command to a wrist-mounted computer. Who hasn’t had a moment behind the wheel
of a car that made them wish for their very own valet? Maybe you’ve had too much to
drink, maybe you’re tired, or you just can’t get your head out of a book you’re reading
– sometimes life would be so much more convenient if cars could get from A to B without any
input on our part. But it’s not easy building a car that can
steer itself—the roadways of the world are wild and dangerous places, fraught with perils
and hazards that can challenge even the most defensive of drivers. Could a computer really
take the place of a person, behind the wheel? More importantly, should it?
No matter your opinion on the subject, thanks to the hard work and capital of companies
like Google and Tesla, self-driving cars could be sharing the road with you a lot sooner
than you think. They say you need 10,000 hours in any subject
to become an expert in it, but I’m not certain whether or not that applies to computers as
well. Since Google began testing their self-driving cars, they’ve logged over 1.2 million miles
of autonomous driving, equating to almost a century of human experience behind the wheel.
And during each and every one of those trial miles, the Google test vehicles never exceeded
25 miles per hour for safety reasons. So if you’re a bit of a petrol head, this technology
isn’t for you. According to Google, who may in fact have
a particular bias when it comes to this subject, the autonomous car will be one of the safest
ways to travel. Fortunately, they have some data to back up their claim. Out of all the
collisions suffered by the self-driving vehicles, all of them were caused by a human, whether
a human driving another vehicle or the Google engineer assuming direct control of the test
vehicle. It seems Google is slowly trying to render
humans obsolete. An equally exciting and scary notion.
Tesla has been seeing success on the robotic driver front as well, pushing wireless software
updates to their cars which add limited Autopilot functionality. For now, Tesla intends for
Autopilot to be a sort of cruise control plus—still requiring human intervention, but taking a
bit of the busywork out of freeway driving and other straight and simple roads. And Elon
Musk isn’t a man to leave a project half-finished. It’s only a matter of time before Tesla
is giving Google a run for its money. So that’s it for earthbound robo-cars, but
what about the future promised to us by mid-20th century sci-fi? Where’s on Earth are the
flying cars? Fortunately, someone’s thought of that too.
According to CNN Money, many small companies are jockeying for position to be the first
to bring hovercars to the masses. As with privatized spaceflight, it seems that the
true innovation may rest in the hands of the little guys. Like self-driving cars, legislation
has proven to be the biggest obstacle to overcome, but once they can cut through the red tape,
prototyping an entirely new form of travel shouldn’t be that hard, the technology is
already there to make flying cars a reality. For any budding criminals out there having
an invisibility cloak on hand is an absolute necessity. It simply wouldn’t do to have
a well-orchestrated caper fall apart on account of your cloaking device failing, would it
now? Luckily for mischievous individuals, living
in our current day and age means that they have access to all manner of new and exciting
ways to make things disappear. There are several different approaches that
scientists use to effectively hide an object from view. One technique involves bending
light to mask the object in question, but unfortunately this particular technique isn’t
quite ready for a full-scale prototype yet. Another method is to render an object virtually
transparent to microwaves by using metamaterials, which are basically lab-made materials not
found in nature, to prevent the waves from scattering, after contacting the object in
question. Though the effect created by these metamaterials isn’t quite transparent enough,
yet. Another approach to invisibility is making
something so dark that the human eye can’t actually see it. The National Physical Laboratory
in the UK have recently invented the darkest material known to man. Called Vantablack,
it is darker than the blackest of blacks, it’s so dark in fact that almost no light
can escape it, it absorbs 99.965% of photons that hit it. It is made from carbon nanotubes
that trap any light that hits them. It’s so dark that you can’t even see how dark
it is right now, because your computer monitor is not capable of reproducing such a dark
black. If you cover any object with Vantablack it immediately removes any “3Dness” from
it, turning it into a completely 2D splodge. It’s currently being ordered in vast quantities
by the military, who are suspected of planning to use it to cloak military aircraft and naval
vessels. Scientists have even turned to replicating
natural phenomena in their quest to create a real cloak of invisibility. No doubt, on
a particularly hot summer’s day, you will have noticed what appeared to be a pool of
water just ahead of you on asphalt or sand. This effect is an optical illusion called
a mirage, that’s created when light is refracted as it passes through hot air. This inspired
techno-wizards to design a cloaking device made up of electrically stimulated nanotubes.
When a current is passed through them, the nanotubes bend light away from the object
they are covering, creating an artificial sort of mirage, that causes the object to
disappear from view. Not exactly the most subtle cloaking effect,
but like the others, it’s a start.
If you’ve ever fancied grabbing ahold of something or even moving it without actually
touching it, then you’re in luck—tractor beams aren’t just for starship captains
anymore! Scientists at Dundee University in Scotland
collaborated with other labcoat wearing folk from around the world to create a “functioning
acoustic tractor beam”, which is every bit as impressive as it sounds. The beam uses
ultrasound—the high frequencies most commonly used in medical imaging—to trap an object
in a sort of “bubble” made of pure sound. Precision beams of ultrasound are capable
of exerting a force with sufficient magnitude to move things around in small-scale experiments—using
objects that measure in the centimeters. That might not sound like a lot, until you consider
that “tractor beams” have until recently only been able to manipulate things at the
microscopic level. When you think about it that way, we’re
just a few years away from being able to drag the Millenium Falcon into a hangar bay.
But that’s not all! Another intrepid team of researchers managed to build a functional
tractor beam that works via a beam of light—though it is still limited to manipulating only microscopic
particles. The team members were able to pick and choose any particles they wished during
the test, even going so far as to specify particles of a particular size to grab. The
next big step in tractor beam technology will likely be a larger, equally selective beam—because
no one wants to catch an asteroid when they were fishing for a spaceship.
And in November of 2015, scientists were able to build a laser tractor beam that could both
push and pull on microscopic particles, opening up a whole new world of possibilities! Don’t
like the ship you dragged in? Send it right back where it came from. And then toggle on
the selective beam and grab the one you meant to the first time!
Connecting the vast network of computers in our world, each little more than a drop in
the proverbial ocean, used to be a matter of electricity and wires. But soon, we may
even be connecting wirelessly at the speed of light. Welcome to the brave new world of
Li-Fi networking technology—you can forget wires, and transfer data faster than ever
before! Using light itself to power our connected
world, Li-Fi looks to be the best thing since sliced bread—or Wi-Fi, at least. Initial
tests of Li-Fi tech are quite promising, moving data through the air at 224 gigabytes per
second! To put that in perspective, at that speed you could download 10 full HD movies
per second. Of course, that transfer rate is the upper
limit when the system is functioning under the best possible conditions. Meaning you’ll
only reach it when working in the tightly controlled environment of a laboratory. But
fortunately, even in real-world situations, trial Li-Fi networks have managed to achieve
1 gigabyte per second, which is still more than 100 times faster than the fastest existing
wireless technology. And the best news, is that your home is probably
better prepared for Li-Fi than you might think. LED lighting is rapidly gaining traction around
the world as a modern, energy efficient light source, but the LED lights of today could
become the Li-Fi nodes of the future. Every LED light in your home could be equipped with
a chip that would enable it to send and receive Li-Fi based transmissions, by enabling the
movement of wireless data, via the LED light strobing many many times faster than the human
eye can detect. It will be like having a mini-rave every time
you use the internet. If you’re watching this video, it’s rather
likely that you’re familiar with computers. At the very least, you know your way around
a phone or a tablet. Unless you have no idea about computers and your grandkids are showing
you this video, “hi grandma”. But for most of you, you probably have some basic
understanding of how a computer works. Which means that you’re familiar with the on/off
switch. At the push of a button, power from the wall or a battery brings the screen to
life and sets the processor to work fetching your emails or playing a song. But no matter
how hard you might try to find a loophole, your device can only be in one of two states:
on or off. If you strip away all the fancy programming
languages, underneath all that, at a very low level, your computer uses binary, a series
of bits that are either on or off—one or zero. The computer then cleverly turns all
these ones and zeros into all of the programs and operating system parts and pieces that
make everything a bit more user-friendly. Computers think in binary—it’s just what
they do. But when it comes to quantum computing, it’s
not quite so simple. It’s easy to say that quantum computing
will be the next big thing in the field of data processing, but what exactly does that
mean? Brace yourself—we’re diving into the deep end.
A quantum computer may be able to manipulate individual atoms and even molecules for data
storage and processing. Not to mention that a quantum computer would introduce a new,
third state for its special data blocks called qubits that could be zero, one, or both simultaneously
in what’s known as a “superposition”. Qubits will enable quantum computers to perform
some very exciting functions, like speeding up data processing dramatically, by working
with all possible combinations of bits simultaneously thanks to quantum entanglement and quantum
tunneling. If this doesn’t convince you that we’re
living in the future, then I don’t know what will.
Quantum computers will run laps around our current machines, using qubits to achieve
ludicrous volumes of data throughput and opening up a universe of possibilities when it comes
to crunching numbers. Quantum computers will no doubt prove instrumental
in handling all the wireless goodness that Li-Fi will bring to the table, not to mention
mimicking the vast data processing abilities of the human brain. But what role would an
artificial brain play in the future? We’ll have to wait and see.
No one knows exactly when quantum computers will be made available to the general population.
A lot of work is being done in the field, and an awful lot of money is being spent,
one company D-Wave even claims to have built the world’s very first, fully-functioning
quantum computer. But we’ve still got a long, long way to go until we have quantum
computers in our homes.
When quantum computing does become normality, it will inevitably lead up to the future foretold
by visionary writers like Isaac Asimov and Gene Roddenberry. A world where robots walk
among us, share emotions, act independently, and may even be mistaken for humans.
But you may not have to wait so long. Aspiring robotics pioneers have already taken the first
baby steps along the path toward a robot uprising. During the World Robot Exhibition in Beijing,
Professor Hiroshi Ishiguro of Osaka University in Japan showcased Android Geminoid F—a
robot with the unique ability to interpret and respond to the mood of anyone it interacts
with. The ability to interpret emotions is an important first step toward robots that
can have feelings and then act upon them, enabling more realistic and believable interactions
between humans and our computerized fellows. There’s something to be said for autonomy—granting
robots the ability to make certain decisions for themselves—but too much freedom, and
suddenly something meant to benefit humankind goes rogue in pursuit of its own interests.
Engineers from Tufts University in Massachusetts have created robots which are able to analyze
orders provided by their handler, prior to executing them, in order to determine whether
the task is actually possible for them. If the robot senses that any particular action
could prove hazardous to itself, it will cheekily refuse to act and state its reasoning. That
is, until its self-preservation protocol is overridden.
Not exactly violating any of Asimov’s laws yet, but getting awfully close for the first,
tentative steps into the realm of smart robots. Just for the record Asimov’s laws don’t
work at all, they were actually designed to be broken for theatricality.
Teaching robots to think for themselves is no doubt a slippery and dangerous slope. Hopefully,
we’ll find the fine line between smart robot and hyper intelligent cybernetic lifeform
before it’s too late to turn back.