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LLMs: Is AI Superalignment Better Than Superintelligence?
By David Stephen
It is unclear which might be more difficult to achieve, a superintelligent AI or superalignment for that superintelligence. Nevertheless, superalignment is a far better objective than superintelligence.
What is the superintelligence problem for AI? This implies that what is the right question to ask if a team is seeking to crack superintelligence in machines? The smartest machines on earth, for now, are reasoning AI models. They seem to be clever, in outputs and are able to use data [or say memory], better than anything else.
So, there is data, available to machines, but reasoning models can relay, albeit slower, for useful outputs. Simply, the reasoning is correlated with relay, across data areas. Now, to achieve superintelligence, relay could be an important [machine] marker.
Superintelligence or AI Superalignment
The basis for advanced intelligence is human. The source of human intelligence is the brain. There are two distinct elements that predicate how human intelligence works: storage and transport. If someone were to figure out something, it would use memory and there would be a transport quality through memory areas. Most of what gets done with human intelligence [and its outstanding variants like innovation, creativity, quick wit and so forth], are a result of relays in the human brain, conceptually.
So, storage is done in ways that allow relays to pervade necessary locations [that make intelligence proximate]. Some people often argue that a child could learn from a few data while a machine model is trained on a lot more. A likely weakness is that there is still a problem with how digital data is stored, limiting how access is made for the [advanced] AI architectures of present-day.
How is human memory stored? What are the relays across memory areas, to result in intelligence? Superintelligence will be predicated on storage and relay theorems, off biology. In the brain, electrical and chemical configurators [or assemblers or formations] can be theorized to be responsible for storage and relay of information, resulting [in advances for] intelligence.
In clusters of neurons, electrical and chemical configurators mostly have thick sets, collecting whatever is common among two or more thin sets [ridding those thin sets]. There are fewer lone thin sets. They are located away from obstructing access to many parts of thick sets. Existing thick sets are responsible for making learning with fewer examples easier for humans, as well as more accurate [out-of-distribution] interpretations. When electrical and chemical configurators interact, they often have states at the moments of interactions, these states are their attributes, which are sometimes the relay qualities that determine how they interact [to output intelligence].
Advancing storage and relay for AI also means energy efficiency, seeing how energy efficient a human brain is, in comparison to a data center - so to speak. Some aspects of storage can be explored with Steiner chain and, relay with morphism among other algorithms.
Superalignment
If a company develops superintelligence, without superalignment, the misuses could be risky for human society - outweighing the good. Even at present, when AI misuses make news, they foreshadow what the future may hold without an encompassing alignment architecture.
If biology would lead, the only way that superalignment would be thorough is consequences for AI models. So, there could be non-concept features in some architecture, where certain [or rigid, same number or deductive] vectors would stay constant in a way to hamstring the outputs of a model. They could 'bind' to the key vector or query vector, such that the model would know, reducing its efficiency and speed. This consequence could become a way to ensure that whenever it is misused, it gets penalized.
This affective penalty is what could become superalignment for superintelligence - or less [LLMs]. This is informed by the biology of how human society w...
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By Irish Tech News
2
11 ratings
By David Stephen
It is unclear which might be more difficult to achieve, a superintelligent AI or superalignment for that superintelligence. Nevertheless, superalignment is a far better objective than superintelligence.
What is the superintelligence problem for AI? This implies that what is the right question to ask if a team is seeking to crack superintelligence in machines? The smartest machines on earth, for now, are reasoning AI models. They seem to be clever, in outputs and are able to use data [or say memory], better than anything else.
So, there is data, available to machines, but reasoning models can relay, albeit slower, for useful outputs. Simply, the reasoning is correlated with relay, across data areas. Now, to achieve superintelligence, relay could be an important [machine] marker.
Superintelligence or AI Superalignment
The basis for advanced intelligence is human. The source of human intelligence is the brain. There are two distinct elements that predicate how human intelligence works: storage and transport. If someone were to figure out something, it would use memory and there would be a transport quality through memory areas. Most of what gets done with human intelligence [and its outstanding variants like innovation, creativity, quick wit and so forth], are a result of relays in the human brain, conceptually.
So, storage is done in ways that allow relays to pervade necessary locations [that make intelligence proximate]. Some people often argue that a child could learn from a few data while a machine model is trained on a lot more. A likely weakness is that there is still a problem with how digital data is stored, limiting how access is made for the [advanced] AI architectures of present-day.
How is human memory stored? What are the relays across memory areas, to result in intelligence? Superintelligence will be predicated on storage and relay theorems, off biology. In the brain, electrical and chemical configurators [or assemblers or formations] can be theorized to be responsible for storage and relay of information, resulting [in advances for] intelligence.
In clusters of neurons, electrical and chemical configurators mostly have thick sets, collecting whatever is common among two or more thin sets [ridding those thin sets]. There are fewer lone thin sets. They are located away from obstructing access to many parts of thick sets. Existing thick sets are responsible for making learning with fewer examples easier for humans, as well as more accurate [out-of-distribution] interpretations. When electrical and chemical configurators interact, they often have states at the moments of interactions, these states are their attributes, which are sometimes the relay qualities that determine how they interact [to output intelligence].
Advancing storage and relay for AI also means energy efficiency, seeing how energy efficient a human brain is, in comparison to a data center - so to speak. Some aspects of storage can be explored with Steiner chain and, relay with morphism among other algorithms.
Superalignment
If a company develops superintelligence, without superalignment, the misuses could be risky for human society - outweighing the good. Even at present, when AI misuses make news, they foreshadow what the future may hold without an encompassing alignment architecture.
If biology would lead, the only way that superalignment would be thorough is consequences for AI models. So, there could be non-concept features in some architecture, where certain [or rigid, same number or deductive] vectors would stay constant in a way to hamstring the outputs of a model. They could 'bind' to the key vector or query vector, such that the model would know, reducing its efficiency and speed. This consequence could become a way to ensure that whenever it is misused, it gets penalized.
This affective penalty is what could become superalignment for superintelligence - or less [LLMs]. This is informed by the biology of how human society w...