Math of distribution networks at 4D, like where to store things in an a
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All on Mon Oct 3 20:17:26 2022
At a computer network a super fast side channel (like 100 ghz or higher velocity, noting that test instruments function at 100 GHz or possibly even 1 GHz, I think from using analog ICs) that updates and communicates a quantity (or possibly data) could
take the place of kana at a human space computer, superimposed ultra high 100 ghz clock rate 2 out of three says it qualifies as a simultaneous update, Or detecting a prime number out of arbitrary n says it is a kana-esque motion update, so that way at
100 GHz (compared with 2019 four GHz) kana data integrity can be just a fraction of the 4ghz amount and contribute distribution and logistics value
Two out of three or detecting a prime number out of n saying there is a kana update teaches nonutilized areas of the chip to do things ahead of time, like at a multicore fill up with memory or program before the 4ghz asks, also think of a field effect or
binary transistor with a 100 GHz analog sensing nanodot on it, if there is a 100 GHz kana like update then the dot absorbs the charge, the charge effects the transistor, and the kanalike update has occured, while at only 2/3 data integrity from the
developmental reliability difference between an analog charge dot and a highly reliable 4ghz (2019) cpu, or a 1/7th kana activity update from a prime detected out of n update events, the kana update dot can be fast rather than precise, as a technology an
analog integrated circuit molecular and physical form dot that causes a kana update at the digital chip like a CPU, photonic internet data connection, or software directed solution to an equation or message passing algorithm like IP (internet protocol)
then uses the kana effect hypervelocity to optimize routing at the network (IP), advance one group of data carrying photons kana-above another at an optical network like the photonic parts of the internet, at memory a kana update could say move l2 catch
to l3 cache or l3 cache to ram, (notably if the 2 out of three or 1/7th kana update is misperceived then some proportion of data is moved to different velocity memory but the aggregate effect is more faster memory that is more available), at a server,
like an internet server, kana could defragment memory and preload most accessed material, although if memory is not as fast as CPU that may not matter
Kana at a CPU could decrease waiting at multicores prepopulating them, if kana carries some data sparsely, and with less accuracy, variables, some functions with a kind of sketch of program flow Possibly the same loops or tests unpopulated with variables,
or possibly just the variables (kanaed from memory), with the 4Ghz providing the functions, so that when all of it arrives the computation happens faster with fewer 4ghz memory calls; At memory, kana like motion at 100ghz could send variables and stored
data systemwide, and nonactive areas of the chip could share their kana impressions to 99% certainty
internet photonics could do kana with different materials
The computer has an extra 100ghz-1thz clock to make kana work
Central place theory and kana
Is there a kind of fiber optic that supports 3D light for greater distribution and logistics efficiency, things like water-wavish 3D solitons, and higher detectability, perhaps a light emitting shaped pile, or Fresnel like stacked laser diode makes a 3D
light shape, and rather than a total internal reflection fiber optic tube, a Fresnel surface textured, textured at a size less than a wavelength of light side of tube would transmit 3D light
Does a 3D dissipative soliton or a 2D dissipative soliton of the same energy travel further, what about a greenshift transverse time 4D soliton
Things that fill children's lives with happiness
Benefitting people with heightening the efficiency of powderizing minerals, perhaps ungrindables at one machine could be fractured to many vertices fragments at another machine, then reintroduced into machine to make more point contact stresses, causing
more grinding more rapidly, possibly with a preferred particle size distribution
Things that fill children with happiness, if minerals were 14 times cheaper to grind with machines then many things would be even more affordable and children would benefit
Ways to turn mineral to powder more efficiently would benefit humans, I read 2-3% of the earths energy use goes to powderizing rocks, bringing that to 1% provides the energy about 150 million people use annually, loading eentsy and medium chips together
then grinding might cause vertex pressure points to disintegrate faster causing preferred powder size distributions
Images of mineral grinders I have seen have grinding areas at the perimeter, perhaps acoustics, among them solitons, could be used to shake sort the middle to optimize the size of mineral chunks that meet the perimeter to optimize powder size math
distribution, also, could a central vertical mineral fragmenter stamp the middle area to make more rock fragments of the right size faster, that is kind of like 1/4 more minerals ground per machine
I may have read grinding minerals is 2-3% efficient, making explosives an order of magnitude more affordable might complement grinding to heighten efficiency, a machine that uses nitrogen from air and a carbon source like co2 could make a continuous
stream of trinitrotoluene, one possibility is a fractal reactor like a zeolite, a fractal catalyst coated or part of the molecule, cyclodextrin, or a comparatively higher volume gas centrifuge with catalysts at the membrane,
A reactor that makes trinitrotoluene superaffordably to complement or replace 2-3% efficient mineral grinding, as a technology, a catalytic, sparse at the medium semiconductor or conductor sponge with a predictable electron traversal path that although
bulk produced does not overlap much and is a kind of amorphous form, make a bunch of fractal 1-3 nanometer wide highly conductive semiconductors or conductors, at a sponge form, optimally react them to put catalytic atoms at their fractal tips, then coat
them with a solid nonconductive gas permeable coating like custom channel size PTFE or another polymer, then compress them into shapes, sinter them to mechanical durability, or just load a column with the catalytic atom tipped fractal, sparse enough to
omit being a direct conductor with PTFE or other gas permeable polymer material, the gas permeable polymer sinters to the other polymer coated fractals, and then when nitrogen and a carbon containing gases (possibly toluene vapor) are pumped through it,
the mostly non overlapping conductors or semiconductors provide charge at the fractal tips and the catalytic atoms like Rh or Co or a more affordable catalyst catalyze the nitrogen being attached to the carbon containing molecule, at cool temperatures
that minimize risk, the charge density at the fractal tips could be high enough to function similarly to the (diffetent) ammonia making process temperature, it is even possible discharge arcing, like carpet and doorknob plasma bolts, only nanometers big
could provide nanolocal temperature and charge sufficient to get the nitrogen gas to react with the carbon containing gas or vapor like toluene vapor, the nitrated carbon chemicals would then travel out of the column from pressure or vacuum as a
condensible vapor or fluid stream and the cool temperature on site trinitrotoluene producing reactor could then complement mineral grinders to powderize minerals more efficiently, benefitting people,
I read the energy the system uses to produce the explosives is at least some higher than the energy of the explosives themselves, I think I read vegetable oil actually has more kilojoules per mole than nitro explosives, it is just that the chemical
motion change at TNT is so rapid when it causes motion from expansion, that it can disintegrate other things, possibly at $2.00 per gallon at gasoline TNT could be $4-9 a gallon at 50-22% reactor efficiency or $19 a gallon at 9% efficiency, also it could
be more affordable than this as electricity, notably off-high-demand electricity, is more affordable than gasoline,
The use of fractal conductors or semiconductors with catalytic element tips provides other adjustable things that could benefit the reaction, input voltage and current and AC frequency, also skipping the hook-up wires, things like fractals tuned to
absorb electromagnetic energy, EM,, like wireless phone charging could electrically energize the fractals
If nitroalkanes are explosive that would be even more affordable than TNT to produce
Has anyone made nitroexplosives from silicone polymers or silicone molecules (Sitoluene?) as an explosive, it might be less sensitive while still having full nitrogen explosion energy
Vibration and acoustic stochastics might be tunable
If a 60 decibel mild gentle soliton meets your ear does it transmit almost no energy, and is much less audible, audio speakers could broadcast to hundreds of times further areas causing perceived loudness of a speaker to be the same over an acre which
could benefit concert sound systems
I read they use solitons now at internet fiber optic repeaters, could solitons or partial 30% solitons be used at WiFi to gain further distances
Longevity technology
Culturing the yeast and bacteria being screened for greater longevity being cultured at human body temperatures will make all the proteins function at the velocities they would at the human body
Use a flow cytometer on MEMS to find the most on specification ones
Things that fill children's lives with happiness
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