Read The Singularity Is Near: When Humans Transcend Biology Online

Authors: Ray Kurzweil

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The Singularity Is Near: When Humans Transcend Biology (78 page)

As these technologies develop, our need for aggregating people in large buildings and cities will diminish, and people will spread out, living where they want and gathering together in virtual reality.

Civil Liberties in an Age of Asymmetric Warfare
. The nature of terrorist attacks and the philosophies of the organizations behind them highlight how civil liberties can be at odds with legitimate state interests in surveillance and control. Our law-enforcement system—and indeed, much of our thinking about security—is based on the assumption that people are motivated to preserve their own lives and well-being. That logic underlies all our strategies, from protection at the local level to mutual assured destruction on the world stage. But a foe that values the destruction of both its enemy and itself is not amenable to this line of reasoning.

The implications of dealing with an enemy that does not value its own survival are deeply troublesome and have led to controversy that will only intensify as the stakes continue to escalate. For example, when the FBI identifies a likely terrorist cell, it will arrest the participants, even though there may be insufficient evidence to convict them of a crime and they may not yet even have committed a crime. Under the rules of engagement in our war on terrorism, the government continues to hold these individuals.

In a lead editorial, the
New York Times
objected to this policy, which it described as a “troubling provision.”
47
The paper argued that the government should release these detainees because they have not yet committed a crime and should rearrest them only after they have done so. Of course by that time suspected terrorists might well be dead along with a large number of their victims. How can the authorities possibly break up a vast network of decentralized cells of suicide terrorists if they have to wait for each one to commit a crime?

On the other hand this very logic has been routinely used by tyrannical regimes to justify the waiving of the judicial protections we have come to
cherish. It is likewise fair to argue that curtailing civil liberties in this way is exactly the aim of the terrorists, who despise our notions of freedoms and pluralism. However, I do not see the prospect of any technology “magic bullet” that would essentially change this dilemma.

The encryption trapdoor may be considered a technical innovation that the government has been proposing in an attempt to balance legitimate individual needs for privacy with the government’s need for surveillance. Along with this type of technology we also need the requisite political innovation to provide for effective oversight, by both the judicial and legislative branches, of the executive branch’s use of these trapdoors, to avoid the potential for abuse of power. The secretive nature of our opponents and their lack of respect for human life including their own will deeply test the foundations of our democratic traditions.

A Program for GNR Defense

 

We come from goldfish, essentially, but that [doesn’t] mean we turned around and killed all the goldfish. Maybe [the AIs] will feed us once a week. . . . If you had a machine with a 10 to the 18th power IQ over humans, wouldn’t you want it to govern, or at least control your economy?

                   —S
ETH
S
HOSTAK

 

How can we secure the profound benefits of GNR while ameliorating its perils? Here’s a review of a suggested program for containing the GNR risks:

The most urgent recommendation is to
greatly increase our investment in defensive technologies
. Since we are already in the G era,
the bulk of this investment today should be in (biological) antiviral medications and treatments
. We have new tools that are well suited to this task. RNA interference, for example, can be used to block gene expression. Virtually all infections (as well as cancer) rely on gene expression at some point during their life cycles.

Efforts to anticipate the defensive technologies needed to safely guide N and R should also be supported, and these should be substantially increased as we get closer to the feasibility of molecular manufacturing and strong AI, respectively. A significant side benefit would be to accelerate effective treatments for infectious disease and cancer. I’ve testified before Congress on this issue, advocating the investment of tens of billions of dollars per year (less than 1 percent of the GDP) to address this new and underrecognized existential threat to humanity.
48

 
  • We need
    to streamline the regulatory process for genetic and medical technologies. The regulations do not impede the malevolent use of technology but significantly delay the needed defenses. As mentioned, we need to better balance the risks of new technology (for example, new medications) against the known harm of delay.
  • A global program of confidential, random serum monitoring for unknown or evolving biological pathogens should be funded. Diagnostic tools exist to rapidly identify the existence of unknown protein or nucleic acid sequences. Intelligence is key to defense, and such a program could provide invaluable early warning of an impending epidemic. Such a “pathogen sentinel” program has been proposed for many years by public health authorities but has never received adequate funding.
  • Well-defined and targeted temporary moratoriums, such as the one that occurred in the genetics field in 1975, may be needed from time to time. But such moratoriums are unlikely to be necessary with nanotechnology. Broad efforts at relinquishing major areas of technology serve only to continue vast human suffering by delaying the beneficial aspects of new technologies, and actually make the dangers worse.
  • Efforts to define safety and ethical guidelines for nanotechnology should continue. Such guidelines will inevitably become more detailed and refined as we get closer to molecular manufacturing.
  • To create the political support to fund the efforts suggested above, it is necessary to
    raise public awareness of these dangers
    . Because, of course, there exists the downside of raising alarm and generating uninformed backing for broad antitechnology mandates, we also need to create a public understanding of the profound benefits of continuing advances in technology.
  • These risks cut across international boundaries—which is, of course, nothing new; biological viruses, software viruses, and missiles already cross such boundaries with impunity.
    International cooperation
    was vital to containing the SARS virus and will become increasingly vital in confronting future challenges. Worldwide organizations such as the World Health Organization, which helped coordinate the SARS response, need to be strengthened.
  • A contentious contemporary political issue is the need for preemptive action to combat threats, such as terrorists with access to weapons of mass destruction or rogue nations that support such terrorists. Such measures will always be controversial, but the potential need for them is clear. A nuclear explosion can destroy a city in seconds. A self-replicating pathogen,
    whether biological or nanotechnology based, could destroy our civilization in a matter of days or weeks. We cannot always afford to wait for the massing of armies or other overt indications of ill intent before taking protective action.
  • Intelligence agencies and policing authorities will have a vital role in forestalling the vast majority of potentially dangerous incidents. Their efforts need to involve the most powerful technologies available. For example, before this decade is over, devices the size of dust particles will be able to carry out reconnaissance missions. When we reach the 2020s and have software running in our bodies and brains, government authorities will have a legitimate need on occasion to monitor these software streams. The potential for abuse of such powers is obvious. We will need to achieve a middle road of preventing catastrophic events while preserving our privacy and liberty.
  • The above approaches will be inadequate to deal with the danger from pathological R (strong AI). Our primary strategy in this area should be to optimize the likelihood that future nonbiological intelligence will reflect our values of liberty, tolerance, and respect for knowledge and diversity. The best way to accomplish this is to foster those values in our society today and going forward. If this sounds vague, it is. But there is no purely technical strategy that is workable in this area, because greater intelligence will always find a way to circumvent measures that are the product of a lesser intelligence. The nonbiological intelligence we are creating is and will be embedded in our societies and will reflect our values. The trans-biological phase will involve nonbiological intelligence deeply integrated with biological intelligence. This will amplify our abilities, and our application of these greater intellectual powers will be governed by the values of its creators. The transbiological era will ultimately give way to the post-biological era, but it is to be hoped that our values will remain influential. This strategy is certainly not foolproof, but it is the primary means we have today to influence the future course of strong AI.

Technology will remain a double-edged sword. It represents vast power to be used for all humankind’s purposes. GNR will provide the means to overcome age-old problems such as illness and poverty, but it will also empower destructive ideologies. We have no choice but to strengthen our defenses while we apply these quickening technologies to advance our human values, despite an apparent lack of consensus on what those values should be.

M
OLLY 2004:
Okay, now run that stealthy scenario by me again—you know, the one where the bad nanobots spread quietly through the biomass to get themselves into position but don’t actually expand to noticeably destroy anything until they’re spread around the globe
.

R
AY:
Well, the nanobots would spread at very low concentrations, say one carbon atom per 10
15
in the biomass, so they would be seeded throughout the biomass. Thus, the speed of physical spread of the destructive nanobots would not be a limiting factor when they subsequently replicate in place. If they skipped the stealth phase and expanded instead from a single point, the spreading nanodisease would be noticed, and the spread around the world would be relatively slow
.

M
OLLY 2004:
So how are we going to protect ourselves from that? By the time they start phase two, we’ve got only about ninety minutes, or much less if you want to avoid enormous damage
.

R
AY:
Because of the nature of exponential growth, the bulk of the damage gets done in the last few minutes, but your point is well taken. Under any scenario, we won’t have a chance without a nanotechnology immune system. Obviously, we can’t wait until the beginning of a ninety-minute cycle of destruction to begin thinking about creating one. Such a system would be very comparable to our human immune system. How long would a biological human circa 2004 last without one
?

M
OLLY 2004:
Not long, I suppose. How does this nano-immune system pick up these bad nanobots if they’re only one in a thousand trillion
?

R
AY:
We have the same issue with our biological immune system. Detection of even a single foreign protein triggers rapid action by biological antibody factories, so the immune system is there in force by the time a pathogen achieves a near critical level. We’ll need a similar capability for the nano-immune system
.

C
HARLES
D
ARWIN:
Now tell me, do the immune-system nanobots have the ability to replicate
?

R
AY:
They would need to be able to do this; otherwise they would not be able to keep pace with the replicating pathogenic nanobots. There have been proposals to seed the biomass with protective immune-system nanobots at a particular concentration, but as soon as the bad nanobots significantly exceeded this fixed concentration the immune system would lose. Robert Freitas proposes nonreplicating nanofactories able to turn out additional protective nanorobots when needed. I think this is likely to deal with threats for a while, but ultimately the defensive system will need the ability to replicate its immune capabilities in place to keep pace with emerging threats
.

C
HARLES:
So aren’t the immune-system nanobots entirely equivalent to the phase one malevolent nanobots? I mean seeding the biomass is the first phase of the stealth scenario
.

R
AY:
But the immune-system nanobots are programmed to protect us, not destroy us
.

C
HARLES:
I understand that software can be modified
.

R
AY:
Hacked, you mean
?

C
HARLES:
Yes, exactly. So if the immune-system software is modified by a hacker to simply turn on its self-replication ability without end

R
AY:
—yes, well, we’ll have to be careful about that, won’t we
?

M
OLLY 2004:
I’ll say
.

R
AY:
We have the same problem with our biological immune system. Our immune system is comparably powerful, and if it turns on us that’s an autoimmune disease, which can be insidious. But there’s still no alternative to having an immune system
.

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