Ah, yeah, that’s a great point. Although I think act-based agents is a pretty bad name, since those agents may often carry out a whole bunch of acts in a row—in fact, I think that’s what made me overlook the fact that it’s pointing at the right concept. So not sure if I’m comfortable using it going forward, but thanks for point that out.
Thanks for sharing!
Most model-based RL algorithms I’ve seen assume they can evaluate the reward functions in arbitrary states.
Hmm. AlphaZero can evaluate the true reward function in arbitrary states. MuZero can’t—it tries to learn the reward function by supervised learning from observations of past rewards (if I understand correctly). I googled “model-based RL Atari” and the first hit was this which likewise tries to learn the reward function by supervised learning from observations of past rewards (if I understand correctly). I’m not intimately familiar with the deep RL literature, I wouldn’t know what’s typical and I’ll take your word for it, but it does seem that both possibilities are out there.
Anyway, I don’t think the neocortex can evaluate the true reward function in arbitrary states, because it’s not a neat mathematical function, it involves messy things like the outputs of millions of pain receptors, hormones sloshing around, the input-output relationships of entire brain subsystems containing tens of millions of neurons, etc. So I presume that the neocortex tries to learn the reward function by supervised learning from observations of past rewards—and that’s the whole thing with TD learning and dopamine.
I added a new sub-bullet at the top to clarify that it’s hard to explain by RL unless you assume the planner can query the ground-truth reward function in arbitrary hypothetical states. And then I also added a new paragraph to the “other possible explanations” section at the bottom saying what I said in the paragraph just above. Thank you.
I don’t see how you solve this problem in general in a sample-efficient manner otherwise.
Well, the rats are trying to do the rewarding thing after zero samples, so I don’t think “sample-efficiency” is quite the right framing.
In ML today, the reward function is typically a function of states and actions, not “thoughts”. In a brain, the reward can depend directly on what you’re imagining doing or planning to do, or even just what you’re thinking about. That’s my proposal here.
Well, I guess you could say that this is still a “normal MDP”, but where “having thoughts” and “having ideas” etc. are part of the state / action space. But anyway, I think that’s a bit different than how most ML people would normally think about things.
After rereading the chapter in Superintelligence, it seems to me that “genie” captures something akin to act-based agents. Do you think that’s the main way to use this concept in the current state of the field, or do you have other applications in mind?
I used your idea of “a” vs. “an” as the basis of a GPT-3 experiment to show that GPT-3 indeed probably does do lookahead. Details are at https://www.reddit.com/r/GPT3/comments/k0mvf3/experiment_that_shows_that_gpt3_can_probably_plan/
Ah, looks like I missed this question for quite a while!
I agree that it’s not quite one or the other. I think that like wireheading, we can split delusion box into “the easy problem” and “the hard problem”. The easy delusion box is solved by making a reward/utility which is model-based, and so, knows that the delusion box isn’t real. Then, much like observation-utility functions, the agent won’t think entering into the delusion box is a good idea when it’s planning—and also, won’t get any reward even if it enters into the delusion box accidentally (so long as it knows this has happened).
But the hard problem of delusion box would be: we can’t make a perfect model of the real world in order to have model-based avoidance of the delusion box. So how to we guarantee that an agent avoids “generalized delusion boxes”?
This is clarifying, thanks.
WRT the last paragraph, I’m thinking in terms of convergent vs divergent processes. So , fixed points I guess.
The problem of figuring out preference without wireheading seems very similar to the problem of maintaining factual knowledge about the world without suffering from appeals to consequences. In both cases a specialized part of agent design (model of preference or model of a fact in the world) has a purpose (accurate modeling of its referent) whose pursuit might be at odds with consequentialist decision making of the agent as a whole. The desired outcome seems to involve maintaining integrity of the specialized part, resisting corruption of consequentialist reasoning.
With this analogy, it might be possible to transfer lessons from the more familiar problem of learning facts about the world, to the harder problem of protecting preference.
Perhaps the lesson is that terminology that is acceptable in one field (in this case philosophy) might not be suitable in another (in this case machine learning).
Is that from Superintelligence? I googled it, and that was the most convincing result.
Oracle-genie-sovereign is a really useful distinction that I think I (and probably many others) have avoided using mainly because “genie” sounds unprofessional/unacademic. This is a real shame, and a good lesson for future terminology.
Oh, actually, you’re right (that you were wrong). I think I made the same mistake in my previous comment. Good catch.
Well now I’m less sure that it’s incorrect. I was originally imagining that like in Solomonoff induction, the TMs basically directly controlled AIXI’s actions, but that’s not right: there’s an expectimax. And if the TMs reinforce actions by shaping the rewards, in the AIXI formalism you learn that immediately and throw out those TMs.
Wait, really? I thought it made sense (although I’d contend that most people don’t think about AIXI in terms of those TMs reinforcing hypotheses, which is the point I’m making). What’s incorrect about it?
Also, presumably many of the component Turing machines have reusable parameters and reinforce behaviour, altho this is hidden by the formalism.
Actually I think this is total nonsense produced by me forgetting the difference between AIXI and Solomonoff induction.
Thanks for the clarification! I agree if the planner does not have access to the reward function then it will not be able to solve it. Though, as you say, it could explore more given the uncertainty.
Most model-based RL algorithms I’ve seen assume they can evaluate the reward functions in arbitrary states. Moreover, it seems to me like this is the key thing that lets rats solve the problem. I don’t see how you solve this problem in general in a sample-efficient manner otherwise.One class of model-based RL approaches is based on [model-predictive control](https://en.wikipedia.org/wiki/Model_predictive_control): sample random actions, “rollout” the trajectories in the model, pick the trajectory that had the highest return and then take the first action from that trajectory, then replan. That said, assumptions vary. [iLQR](https://en.wikipedia.org/wiki/Linear%E2%80%93quadratic_regulator) makes the stronger assumption that reward is quadratic and differentiable.
I think methods based on [Monte Carlo tree search](https://en.wikipedia.org/wiki/Monte_Carlo_tree_search) might exhibit something like the problem you discuss. Since they sample actions from a policy trained to maximize reward, they might end up not exploring enough in this novel state if the policy is very confident it should not drink the salt water. That said, they typically include explicit methods for exploration like [UCB](https://en.wikipedia.org/wiki/Thompson_sampling#Upper-Confidence-Bound_(UCB)_algorithms) which should mitigate this.
Oh, OK, I see what you mean. Possibly related: my comment here.
Yes we do: training is our evolutionary history, deployment is an individual lifetime. And our genomes are our reusable parameters.
Unfortunately I haven’t yet written any papers/posts really laying out this analogy, but it’s pretty central to the way I think about AI, and I’m working on a bunch of related stuff as part of my PhD, so hopefully I’ll have a more complete explanation soon.
I kind of think the lack of episodes makes it more realistic for many problems, but admittedly not for simulated games. Also, presumably many of the component Turing machines have reusable parameters and reinforce behaviour, altho this is hidden by the formalism. [EDIT: I retract the second sentence]
Thanks for the good work!
I especially like the choice set paper.