Бернард Марр

Business Trends in Practice


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rel="nofollow" href="#ulink_4e05505f-0641-53d3-aa7b-c21e58b34357">39. The diversity and inclusion revolution; Deloitte; https://www2.deloitte.com/content/dam/insights/us/articles/4209_Diversity-and-inclusion-revolution/DI_Diversity-and-inclusion-revolution.pdf

      40 40. Ibid.

      41 41. Ibid.

      42 42. 10 Mega Trends that are (re)shaping our world; Ipsos; https://www.ipsos.com/sites/default/files/10-Mega-Trends-That-are-Reshaping-The-World.pdf

      We are now entering the fourth industrial revolution. As with each industrial revolution before it – steam and waterpower, electricity, and computerization – this revolution represents a huge transformational shift that will forever alter how we do business, and even how we go about our everyday lives. Driven by data, artificial intelligence and the Internet of Things (IoT, the plethora of everyday devices that are now connected to the internet), the fourth industrial revolution is essentially turning the world around us into one huge information system, which is why I often refer to it as “the intelligence revolution.”

      What's interesting about the fourth industrial revolution is that the unprecedented digital transformation that we've seen in recent years is being accelerated by the interaction between all these different technologies. The enormous leaps in AI, for example, have been made possible by the explosion of data, which in turn is being accelerated by the plethora of smart devices constantly generating data. These trends are influencing each other, and will continue to do so. This means, rather than the big step changes of previous industrial revolutions, this latest revolution may usher in a period of exponential growth that just carries on and on. In other words, there may not be a fifth industrial revolution; we may instead experience a continual acceleration of the fourth industrial revolution.

      Imagine if the speed of cars developed at such a pace. Initially, the progress would seem fairly sensible, starting with 50mph then doubling two years later to 100mph. But after eight years our cars would be traveling faster than the speed of sound (767 mph). Within 50 years, we'd be driving faster than the speed of light (670 million mph). That's fast enough to take a round-trip from Earth to the Moon and back in about 2.5 seconds. Clearly, such pace of change isn't happening in the automotive industry, or other industries for that matter. And that's what makes the pace of digital change so startling. It's something we've never seen before, and it's almost impossible to imagine this pace continuing. But that's precisely what may happen. There's no limit to what these technologies can achieve.

      Digital technology is more readily available and more powerful than ever before. Let's take a quick look how we got here, to the point where computers are all around us, and see what's in store for the future of computing.

      Advances in computing power

      As processing power has increased and the size of computer microchips has shrunk, most of us have become used to computers and devices getting smaller, lighter, cheaper, and more powerful. Indeed, the average smartphone today is more powerful than the supercomputers of 10 years ago.

      Moore's Law states that the number of transistors on a microchip doubles every two years, thus doubling the speed and capability of computers every two years. This law has been in place for an astonishing 55 years. Now, however, we're reaching the limits of Moore's Law. After all, there's only so far you can take the shrinking of transistors and computer chips. But this doesn't mean the end of advances in computing power. It's just that, instead of relying on microchips getting smaller, it's likely future advances will come from innovations in software and algorithms (especially when the coding is done by AI), quantum computing, and even new forms of digital storage, such as DNA storage. In other words, even as Moore's Law falters, new advances on the horizon will continue to push the boundaries of computing power. These gains may be a bit more irregular and uneven than we've grown used to with Moore's Law, but they will come.

      Quantum computing

      A quantum computer, on the other hand, uses “quantumbits” or “qubits” to process data, and these qubits seem to be capable of existing in two states simultaneously, meaning they have some likelihood of being a 1 and some likelihood of being a 0 at the same time. Using these quantum methods, it's possible to build machines capable of operating far more quickly than the fastest computers available today – potentially hundreds of millions of times faster. While quantum computers won't replace traditional computers (using a quantum computer to write your memoir, for example, would be like using a rocket launcher to crack a walnut), they could be used to complete new, previously impossible tasks that traditional computers aren't capable of. In other words, they're ideally suited to solving problems that humanity (and computers) hasn't yet been able to solve, such as the climate crisis. Some quantum computers exist today, but their use is mostly confined to academia and highly theoretical work. However, companies such as IBM, Google, and Microsoft are investing heavily in developing large-scale quantum computers that could see quantum computing deliver more widespread practical applications.

      Storing and processing data

      Computers have had to get faster and more powerful, in part to keep up with the vast amounts of data we're