Electronics themselves work by understanding integration.
It's full circle. But with Lisp and Lambda Calculus even an Elementary school kid could understand integration, as you are literally describing the process as if they were Lego blocks.
Albeit in Forth would be far easier.
It's almost telling the computer that multiplying it's iterated addition, and dividing, iterated substraction.
Floating numbers are done with specially memory 'blocks', and you can 'teach' the computer to multiply numbers bigger than 65536 in the exact same way humans do with pen and paper.
Heck, you can set float numbers by yourself by telling Forth how to do the float numbers by following the standard and setting up the f, f+, f/... and outputting rules by hand.
Slower than a Forth done in assembly? Maybe, for sure;
but natively, in old 80's computers, Forth was 10x faster than Basic.
From that to calculus, it's just telling the computer new rules*.
And you don't need an LLM for that.
It's full circle. But with Lisp and Lambda Calculus even an Elementary school kid could understand integration, as you are literally describing the process as if they were Lego blocks.
Albeit in Forth would be far easier. It's almost telling the computer that multiplying it's iterated addition, and dividing, iterated substraction.
Floating numbers are done with specially memory 'blocks', and you can 'teach' the computer to multiply numbers bigger than 65536 in the exact same way humans do with pen and paper.
Heck, you can set float numbers by yourself by telling Forth how to do the float numbers by following the standard and setting up the f, f+, f/... and outputting rules by hand. Slower than a Forth done in assembly? Maybe, for sure; but natively, in old 80's computers, Forth was 10x faster than Basic.
From that to calculus, it's just telling the computer new rules*. And you don't need an LLM for that.