Our Final Invention: Artificial Intelligence and the End of the Human Era Hardcover (4 page)

BOOK: Our Final Invention: Artificial Intelligence and the End of the Human Era Hardcover
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I also think its popularity as entertainment has inoculated AI from serious consideration in the not-so-entertaining category of catastrophic risks. For decades, getting wiped out by artificial intelligence, usually in the form of humanoid robots, or in the most artful case a glowing red lens, has been a staple of popular movies, science-fiction novels, and video games. Imagine if the Centers for Disease Control issued a serious warning about vampires (unlike their recent tongue-in-cheek alert about zombies). Because vampires have provided so much fun, it’d take time for the guffawing to stop, and the wooden stakes to come out. Maybe we’re in that period right now with AI, and only an accident or a near-death experience will jar us awake.

Another reason AI and human extinction do not often receive serious consideration may be due to one of our psychological blind spots—a cognitive bias. Cognitive biases are open manholes on the avenues of our thinking. Israeli American psychologists Amos Tversky and Daniel Kahneman began developing the science of cognitive biases in 1972. Their basic idea is that we humans make decisions in irrational ways. That observation alone won’t earn you a Nobel Prize (Kahneman received one in 2002); the stunner is that we are irrational in scientifically verifiable patterns. In order to make the quick decisions useful during our evolution, we repeatedly take the same mental shortcuts, called heuristics. One is to draw broad inferences—too broad as it turns out—from our own experiences.

Say, for example, you’re visiting a friend and his house catches on fire. You escape, and the next day you take part in a poll ranking causes of accidental death. Who would blame you if you ranked “fire” as the first or second most common cause? In fact, in the United States, fire ranks well down the list, after falls, traffic accidents, and poisonings. But by choosing fire, you have demonstrated what’s called the “availability” bias: your recent experience impacts your decision, making it irrational. But don’t feel bad—it happens to everyone, and there are a dozen more biases in addition to availability.

Perhaps it’s the availability bias that keeps us from associating artificial intelligence with human annihilation. We haven’t experienced well-publicized accidents at the hands of AI, while we’ve come close with the other usual suspects. We know about superviruses like HIV, SARS, and the 1918 Spanish Flu. We’ve seen the effects of nuclear weapons on cities full of humans. We’ve been scared by geological evidence of ancient asteroids the size of Texas. And disasters at Three Mile Island (1979), Chernobyl (1986), and Fukushima (2011) show us we must learn even the most painful lessons again and again.

Artificial intelligence is not yet on our existential threat radar. Again, an accident would change that, just as 9/11 introduced the world to the concept that airplanes could be wielded as weapons. That attack revolutionized airline security and spawned a new forty-four-billion-dollar-a-year bureaucracy, the Department of Homeland Security. Must we have an AI disaster to learn a similarly excruciating lesson? Hopefully not, because there’s one big problem with AI disasters. They’re not like airplane disasters, nuclear disasters, or any other kind of technology disaster with the possible exception of nanotechnology. That’s because there’s a high probability we won’t recover from the first one.

And there’s another critical way in which runaway AI is different from other technological accidents. Nuclear plants and airplanes are one-shot affairs—when the disaster is over you clean it up. A true AI disaster involves smart software that improves itself and reproduces at high speeds. It’s self-perpetuating. How can we stop a disaster if it outmatches our strongest defense—our brains? And how can we clean up a disaster that, once it starts, may never stop?

Another reason for the curious absence of AI in discussions of existential threats is that the Singularity dominates AI dialogue.

“Singularity” has become a very popular word to throw around, even though it has several definitions that are often used interchangeably. Accomplished inventor, author, and Singularity pitchman Ray Kurzweil defines the Singularity as a “singular” period in time (beginning around the year 2045) after which the pace of technological change will irreversibly transform human life. Most intelligence will be computer-based, and trillions of times more powerful than today. The Singularity will jump-start a new era in mankind’s history in which most of our problems, such as hunger, disease, even mortality, will be solved.

Artificial intelligence is the star of the Singularity media spectacle, but nanotechnology plays an important supporting role. Many experts predict that artificial superintelligence will put nanotechnology on the fast track by finding solutions for seemingly intractable problems with nanotech’s development. Some think it would be better if ASI came first, because nanotechnology is too volatile a tool to trust to our puny brains. In fact, a lot of the benefits that are attributed to the Singularity are due to nanotechnology, not artificial intelligence. Engineering at an atomic scale may provide, among other things: immortality, by eliminating on the cellular level the effects of aging; immersive virtual reality, because it’ll come from nanobots that take over the body’s sensory inputs; and neural scanning and uploading of minds to computers.

However, say skeptics, out-of-control nano robots might endlessly reproduce themselves, turning the planet into a mass of “gray goo.” The “gray goo” problem is nanotechnology’s most well-known Frankenstein face. But almost no one describes an analogous problem with AI, such as the “intelligence explosion” in which the development of smarter-than-human machines sets in motion the extinction of the human race. That’s one of the many downsides of the Singularity spectacle, one of many we don’t hear enough about. That absence may be due to what I call the two-minute problem.

I’ve listened to dozens of scientists, inventors, and ethicists lecture about superintelligence. Most consider it inevitable, and celebrate the bounty the ASI genie will grant us. Then, often in the last two minutes of their talks, experts note that if AI’s not properly managed, it could extinguish humanity. Then their audiences nervously chuckle, eager to get back to the good news.

Authors approach the ongoing technological revolution in one of two ways. First there are books like Kurzweil’s
The Singularity Is Near.
Their goal is to lay the theoretical groundwork for a supremely positive future. If a bad thing happened there, you would never hear about it over optimism’s merry din. Jeff Stibel’s
Wired for Thought
represents the second tack. It looks at the technological future through the lens of business. Stibel persuasively argues that the Internet is an increasingly well-connected brain, and Web start-ups should take this into account. Books like Stibel’s try to teach entrepreneurs how to dip a net between Internet trends and consumers, and seine off buckets full of cash.

Most technology theorists and authors are missing the less rosy, third perspective, and this book aims to make up for it. The argument is that the endgame for first creating smart machines, then smarter-than-human machines, is not their integration into our lives, but their conquest of us. In the quest for AGI, researchers will create a kind of intelligence that is stronger than their own and that they cannot control or adequately understand.

We’ve learned what happens when technologically advanced beings run into less advanced ones: Christopher Columbus versus the Tiano, Pizzaro versus the Inca, Europeans versus Native Americans.

Get ready for the next one. Artificial superintelligence versus you and me.

*   *   *

Perhaps technology thinkers have considered AI’s downside, but believe it’s too unlikely to worry about. Or they get it, but think they can’t do anything to change it. Noted AI developer Ben Goertzel, whose road map to AGI we’ll explore in chapter 11, told me that we won’t know how to protect ourselves from advanced AI until we have had a lot more experience with it. Kurzweil, whose theories we’ll investigate in chapter 9, has long argued a similar point—our invention and integration with superintelligence will be gradual enough for us to learn as we go. Both argue that the
actual
dangers of AI cannot be seen from here. In other words, if you are living in the horse-and-buggy age, it’s impossible to anticipate how to steer an automobile over icy roads. So, relax, we’ll figure it out when we get there.

My problem with the gradualist view is that while superintelligent machines can certainly wipe out humankind, or make us irrelevant, I think there is also plenty to fear from the AIs we will encounter on the developmental path to superintelligence. That is, a mother grizzly may be highly disruptive to a picnic, but don’t discount a juvenile bear’s ability to shake things up, too. Moreover, gradualists think that from the platform of human-level intelligence, the jump to superintelligence may take years or decades longer. That would give us a grace period of coexistence with smart machines during which we could learn a lot about how to interact with them. Then their advanced descendants won’t catch us unawares.

But it ain’t necessarily so. The jump from human-level intelligence to superintelligence, through a positive feedback loop of self-improvement, could undergo what is called a “hard takeoff.” In this scenario, an AGI improves its intelligence so rapidly that it becomes superintelligent in weeks, days, or even hours, instead of months or years. Chapter 1 outlines a hard takeoff’s likely speed and impact. There may be nothing gradual about it.

It may be that Goertzel and Kurzweil are right—we’ll take a closer look at the gradualist argument later. But what I want to get across right now are some important, alarming ideas derived from the Busy Child scenario.

Computer scientists, especially those who work for defense and intelligence agencies, will feel compelled to speed up the development of AGI because to them the alternatives (such as the Chinese government developing it first) are more frightening than hastily developing their own AGI. Computer scientists may also feel compelled to speed up the development of AGI in order to better control other highly volatile technologies likely to emerge in this century, such as nanotechnology. They may not stop to consider checks to self-improvement. A self-improving artificial intelligence could jump quickly from AGI to ASI in a hard takeoff version of an “intelligence explosion.”

Because we cannot know what an intelligence smarter than our own will do, we can only imagine a fraction of the abilities it may use against us, such as duplicating itself to bring more superintelligent minds to bear on problems, simultaneously working on many strategic issues related to its escape and survival, and acting outside the rules of honesty or fairness. Finally, we’d be prudent to assume that the first ASI will not be friendly or unfriendly, but ambivalent about our happiness, health, and survival.

Can we calculate the potential risk from ASI? In his book
Technological Risk,
H. W. Lewis identifies categories of risk and ranks them by how easy they are to factor. Easiest are actions of high probability and high consequence, like driving a car from one city to another. There’s plenty of data to consult. Low probability, high consequence events, like earthquakes, are rarer, and therefore harder to anticipate. But their consequences are so severe that calculating their likelihood is worthwhile.

Then there are risks whose probability is low because they’ve never happened before, yet their consequences are, again, severe. Major climate change resulting from man-made pollution is one good example. Before the July 16, 1945, test at White Sands, New Mexico, the detonation of an atomic bomb was another. Technically, it is in this category that superintelligence resides. Experience doesn’t provide much guidance. You cannot calculate its probability using traditional statistical methods.

I believe, however, that given the current pace of AI development the invention of superintelligence belongs in the first category—a high probability and high-risk event. Furthermore, even if it were a low probability event, its risk factor should promote it to the front tier of our attention.

Put another way, I believe the Busy Child will come very soon.

The fear of being outsmarted by greater-than-human intelligence is an old one, but early in this century a sophisticated experiment about it came out of Silicon Valley, and instantly became the stuff of Internet legend.

The rumor went like this: a lone genius had engaged in a series of high-stakes bets in a scenario he called the AI-Box Experiment. In the experiment, the genius role-played the part of the AI. An assortment of dot-com millionaires each took a turn as the Gatekeeper—an AI maker confronted with the dilemma of guarding and containing smarter-than-human AI. The AI and Gatekeeper would communicate through an online chat room. Using only a keyboard, it was said, the man posing as the ASI escaped every time, and won each bet. More important, he proved his point. If he, a mere human, could talk his way out of the box, an ASI hundreds or thousands of times smarter could do it too, and do it much faster. This would lead to mankind’s likely annihilation.

The rumor said the genius had gone underground. He’d garnered so much notoriety for the AI-Box Experiment, and for authoring papers and essays on AI, that he had developed a fan base. Spending time with fans was less rewarding than the reason he’d started the AI-Box Experiment to begin with—to save mankind.

Therefore, he had made himself hard to find. But of course I wanted to talk to him.

 

Chapter Three

Looking into the Future

AGI is intrinsically very, very dangerous. And this problem is not terribly difficult to understand. You don’t need to be super smart or super well informed, or even super intellectually honest to understand this problem.

—Michael Vassar, president, Machine Intelligence Research Institute

“I definitely think that people should try to develop Artificial General Intelligence with all due care. In this case, all due care means much more scrupulous caution than would be necessary for dealing with Ebola or plutonium.”

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