Pirate c: Vacuum Energy and the Joules Hertz Constant

post by Pirate c · 2018-08-13T09:00:09.353Z · LW · GW · 4 comments

Contents

  3110^3/[(13413183.7/(d*1.076756663056355872e-10)]=amu/mhz
  The Joules Hertz Constant: 3110^3/(13413183.7/1.076756663056355872e-10)=2.41472046e-7
  1.076756663056355872e-10*c^2=9677406.27
  The Joules Hertz Constant divided by Vacuum energy hertz over c^3:
  (4.63887489e-7/5.1614444e-32)/c^3=0.333564096
  bRad bIll bUsch
None
4 comments

Just a Theory, Pirate c: (3110mhz)^3/[e/(m/v)]=cpu, s^3/ED=p, or

The processing limit to a single core circuit processor (dictated by electromigration and the speed of light) cubed, divided by the available energy density is equal to processing capacity in mhz (cpu speed in mega hertz).

(3110mhz^3/3100mhz)/c^2=1.07616626e-10

Assuming density relative to mhz:

Correction*

The processing limit to a single core circuit processor (dictated by electromigration and the speed of light) cubed, divided by the available energy density is equal to processing capacity in mhz (cpu speed in giga hertz).

1.07616626e-10/amu=6.48082551e+16amu

Into Unified atomic mass units (including electron masses):

(6.48082551e+16amu)+(3.555250784e+13amu) which is plus electrons.

6.48438076e+16/c^2,

What I was trying to show is that around a certain energy density, a simulated reality bubble can emerge, where the processing capacity of an environment can in fact simulate a give perspective of reality to be physically real: producing simulated events, which result in the un-illusion of the Mandela Effect, where probable events become physical reality locally, but not universally.

Random nonsense, or stuff no one is looking into..?

3110^3/c^2/2242.58697665=1.49241796e-10

1.49241796e-10Kg*c^2=13413183.7J

s^3/13413183.7/ED=2242.58697665mhz, ed=13413183.7/(1/1),

Properties of gold, DUH! Energy density, m/v not=1/1

3110^3/[(13413183.7/(d*1.076756663056355872e-10)]=amu/mhz

The Joules Hertz Constant: 3110^3/(13413183.7/1.076756663056355872e-10)=2.41472046e-7

1.076756663056355872e-10*c^2=9677406.27

3110^3/[(9677406.27/(d*1.49241796e-10)]

The Joules Hertz Constant 2.0: 3110^3/[(9677406.27/(1*1.49241796e-10)]=4.63887489e-7

Vacuum Energy: 3110^3/[(9677406.27/[(10e9/c^2)*1.49241796e-10]]=5.1614444e-32

3110^3/[(9677406.27/(1.11265006e-25*1.49241796e-10)]=5.1614444e-32

The Joules Hertz Constant divided by Vacuum energy hertz over c^3:

(4.63887489e-7/5.1614444e-32)/c^3=0.333564096

3110^3/(13413183.7/0.0000208029)=46.65231249khz for gold

3110^3/(13413183.7/8.47407494e-7)=1.900385khz for iron

The Earth: 13.3179077mhz

The Sun: 3110^3/(13413183.7/19.8591607459)=44535.895136mhz

Venus: 3110^3/[(13413183.7/(31725133.0181*1.076756663056355872e-10)]=7.66073278929mhz/amu

Assume: 3.11ghz=c^2

3110^3/[(13413183.7/(d*1.076756663056355872e-10)]=amu/mhz,

3110^3/3110/c^2/amu=0.721089009*c^2

[3110*(3110^3/3110/c^2/amu/c^2)]]=2242.58697665

[3110^3/c^2/[3110*(3110^3/3110/c^2/amu/c^2)]]*c^2=13413183.7J,

3110^3/[[3110^3/c^2/[3110*(3110^3/3110/c^2/amu/c^2)]]*c^2]/[d*(3110^3/3110)/c^2]=mhz/amu

s^3/[[s^3/c^2/[s*(s^3/s/c^2/amu/c^2)]]*c^2]/(d*s^3/s)/c^2=mhz/amu

3110^3/c^2/[3110*(3110^3/3110/c^2/amu/c^2)]]=c^2/amu

3110^3/3110)/c^2=1.076756663056355872e-10

bRad bIll bUsch

4 comments

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comment by wisnij · 2018-08-16T20:13:09.208Z · LW(p) · GW(p)

Testing. Where does this comment go?

Replies from: Raemon
comment by Raemon · 2018-08-16T22:35:27.122Z · LW(p) · GW(p)

This post has negative karma, so comments don't show up on the front page.

Replies from: wisnij
comment by wisnij · 2018-08-16T23:36:16.573Z · LW(p) · GW(p)

That's fine. I commented on this a few days ago but somehow it ended up getting posted to a different article, so I was trying to reproduce the issue.

Replies from: Raemon
comment by Raemon · 2018-08-17T01:16:41.968Z · LW(p) · GW(p)

Hrm. Yeah this has a particularly challenging bug. Apologies for it, will try looking into it next week.