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Show HN: Does Information Density Cause Time Dilation?

10 points·by Jonghwa_Lee·7 months ago·16 comments

Is gravitational time dilation a form of computational latency?

zenodo.org
2 points·by Jonghwa_Lee·7 months ago·2 comments

comments

Jonghwa_Lee
·7 months ago·discuss
Really appreciate the pointers. I'll definitely look into them and use them as references.
Jonghwa_Lee
·7 months ago·discuss
Fair point on the semantics. But I'm not talking about subjective 'knowledge.' I'm talking about the thermodynamic cost to maintain a state.

Landauer showed that information processing is physical (heat). I’m just extending that logic: if the universe has to process too much state data in one spot, the cost isn't just heat—it's lag (Time Dilation).

It doesn't matter if we observe the mess; the system still has to render it.
Jonghwa_Lee
·7 months ago·discuss
Landauer demonstrated that erasing a bit releases heat. If information is fiction, implies that energy is fiction too?
Jonghwa_Lee
·7 months ago·discuss
Fair question.

English isn’t my first language, and I’m an independent researcher. I supplied the core intuition and overall architecture, and used an LLM as a research assistant for formal derivations and calculations.

Think of it as a human architect using modern tools to draft blueprints.
Jonghwa_Lee
·7 months ago·discuss
Valid point. I'm reaching out to academia too. I posted here because my theory treats spacetime as a computational substrate, and HN has the best mix of physicists and engineers to critique that specific angle.
Jonghwa_Lee
·7 months ago·discuss
Spot on. An Event Horizon indeed represents the theoretical limit of information density (the Bekenstein bound).

Since I can't create one in the lab, I'm betting on GHZ states to generate a steep enough local information gradient to yield a measurable effect. It's a scale-down, but unlike a black hole, we can test it today.
Jonghwa_Lee
·7 months ago·discuss
Thanks for the sharp question. You hit the core challenge. I am targeting a sensitivity of 10^{-18} seconds, which is within the range of modern Sr-87 optical lattice clocks (current stability \approx 10^{-19}). While the effect of information density (\Delta S_{info}) is expected to be extremely subtle compared to mass (G), the differential measurement (Entangled vs. Non-entangled) allows me to filter out common-mode noise. Even if I get a null result, establishing an upper bound on the coupling constant \alpha would be a significant contribution. I'm putting my bet on the high complexity of the GHZ state.
Jonghwa_Lee
·7 months ago·discuss
https://zenodo.org/records/18027729
Jonghwa_Lee
·7 months ago·discuss
I've been exploring a speculative idea: what if some of the "strange" phenomena in physics—like gravitational time dilation—aren't fundamental forces, but emergent effects of a universe with finite computational resources?

In this preprint, I model the universe as a Universal Computing System (UCS). The core hypothesis is what I call Information-Induced Time Dilation (ITD): regions with high information density may experience a local "processing lag," which we observe physically as time dilation.

Rather than replacing General Relativity, the idea is to extend it by adding an information entropy term to the stress-energy tensor. Importantly, the paper also outlines a concrete experimental test using Sr-87 optical lattice clocks that could, in principle, distinguish this effect from standard GR predictions.

I'd really appreciate feedback from people in systems, distributed computing, and physics: Does it make sense to think of spacetime as having computational bottlenecks, latency, or throughput limits?