Biological software and hardware
Multi-modal anatomical control
Growing Neural Cellular Automata
Single-cell bioelectricity web app. https://github.com/betsee/calculion
EE123 / BME123 Bioelectricity https://www.ece.tufts.edu/ee/123/
BlogBarley
20250310
20250309
Coda: Large Bio-Mechanical Space Structures
Large Bio-Mechanical Space Structures
DARPA-SN-25-51
Diatom https://www.montereybayaquarium.org/animals/animals-a-to-z/diatoms
Ion channels, control growth and pattern
Molecular bioelectricity in developmental biology: new tools and recent discoveries: control of cell behavior and pattern formation by transmembrane potential gradients Michael Levin https://pubmed.ncbi.nlm.nih.gov/22237730/
Engineered DNA, control biology, energy consumption
Salt water bio-factories with natural transport to the upper atmosphere/ability to harvest nutrients from orbital bio-factory. Insufficient nutrients in orbit?
 |
| ImageFX |
Created on Jan 24, 2016
Note
This one is from cf001_energy_calculation
modified for diatom
This one uses redfield C:N
@author: Keisuke
'''
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#Computation of fe0, fpr and fn considering material, redox and energy balance
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
from pylab import *
class Evalue:
def __init__(self,E):
self.E=E
def evalue():
n=5 #number of carbon in biomass (167-6)
a=7 #number of hydrogen in biomass (167-6)
b=2 #number of oxygen in biomass (167-6)
c=5*16/106 #number of nitrogen in biomass (redfield ratio)(167-6)
d=1/30 #number of phosphorus in biomass (167-6)
d=0
C=6 #number of carbon in sugra substrate (glucose->6)
f=4*n+5*c+5*d-2*b+a #(from 167-6)
g=12*n+a+16*b+14*c+31*d #(from 167-6)
# fs00=(1/y)/(1/y+1/z) #The ratio of electron used for protein synthesis
fs00=1
# fn00=(1/z)/(1/y+1/z) #The ration of electron used for nitrogen fixation
fn00=0
dgn=36.2 #The free energy necessary (dg) for the half reaction of nitrogen fixation (kJ/e-mol)
dgc0=41.35 #The free energy necessary for the half reaction of glucose production (kJ/e-mol)
dgp=35.09-dgc0 #dg for production of pyruvate from glucose (kJ/e-mol))
dgpc=3.33*g/f #dg for the production of BB (bacterial biomass) from pyruvate) (147-17)
dgr=-120.07 #-dg for the energy production pathway (kJ/e-mol)
ep=0.6 #energy efficiency for the production of energy and the consumption of energy
if dgp<0:
ep1=1/ep #change ep1 depending on the sign of dgp
else:
ep1=ep
A=(fn00*dgn+fs00*(dgp/ep1+dgpc/ep))/(-ep*dgr) #A is related to fs0 and fe0
fe0=A/(1+A) #the ratio of electron used for energy production
fs0=1-fe0 #the ratio of electron used for biomass synthesis+nitrogen fixation
fpr=fs0*fs00 #the ratio of electron used for biomass synthesis
fn=fs0*fn00 #the ratio of electron used for nitrogen fixation
#@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
#2.--Stoichiometry (to get E1(E for the case O2cri>O2in))------------------
#@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
S1=array([["","CH","H2O","CO2","O2","HCO3-","NH4+","N2","H2","BB","H+","e-","NO3-","PO43-"],
["'-Rd",1/24,0.25,-0.25,0.,0.,0.,0.,0.,0.,-1.,-1.,0.,0.],
["Ra",0.,-0.5,0.,0.25,0.,0.,0.,0.,0.,1.,1.,0.,0.],
["Rpr",0.,-(2*n+3*c+4*d-b)/f,n/f,0.,0.,0.,0.,0.,-1/f,(4*n+6*c+8*d-2*b+a)/f,1.,c/f,d/f],
["Rn",0.,0.,0.,0.,0.,-0.25,0.125,-0.125,0.,1.25,1.,0.,0.]])
#=====================================================================================
#NH4+ absorption case
#=====================================================================================
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#for creating S2 (f*R for electron acceptance)
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
width=14
depth=5
Mua=array([[1],[fe0],[fpr],[0.0]]) #column of f
S2a=copy(S1[1:,1:]) #use copy so S2 does not respond to the change in S1
S2a=S2a.astype(float64)
#add numbers for columns and raws for counting
S21a=arange(1,width,1)
S22a=arange(0,depth,1)
S22a=S22a.reshape(depth,1)
S2a=vstack((S21a,S2a))
S2a=hstack((S22a,S2a))
#calculate f*R
S2a[1:,1:]=Mua*S2a[1:,1:]
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#for creating S3 (f*R for electron donation)
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
S3a=vstack((S2a[1,1:],S2a[1,1:],S2a[1,1:]))
S3a=Mua[1:]*S3a
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#for creating S4 (f*R for "electron donation + electron acceptance")
# and RR, which is the entire reaction
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
S4a=S2a[2:,1:]+S3a #S4 is f*R for "electron donation + electron acceptance"
RRa=S4a[0]+S4a[1]+S4a[2]
RR1a=copy(RRa)
RR1a=vstack((S1[0,1:],RR1a))
pa=-S4a[1,8]*n #(molC/e-mol) CH consumption for protein production
ha=(S4a[1,0]+S4a[2,0])*C #(molC/e-mol) CH consumption for other than energy production
alpa=pa/ha #(CO2 from (Ra-Rd))/(CH for protein production) (see 72-5)
betaa=-(S4a[1,2]+S4a[1,4]+S4a[2,2])/ha #(CO2 from (Rpr-Rd) + CO2 from (RN-Rd))/(CH for protein production) (see 72-5)
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#output of each array into CSV files
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
#Getting yield (Y) and the ratio of CO2 production rate to CH consumption (E)
#OOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOOO
Y1=-(RRa[8]*n)/(C*RRa[0]) #Yield
E3=1/Y1-1
E=E3
E1=Evalue(E)
return(E1)
https://github.com/ag105020/CFM-Diatom/tree/1.05 credit
MSFC-446 https://ntrs.nasa.gov/api/citations/20070039073/downloads/20070039073.pdf Testing Prospects for Reliable Diatom Nanotechnology in Microgravity
Large Bio-Mechanical Space Structures DARPA-SN-25-51 https://blogbarley.blogspot.com/2025/03/large-bio-mechanical-space-structures.html
Aquatic manufacturing of diatom craft https://barleysarthistory.blogspot.com/2024/06/diatoms.html Propulsion, navigation, interior design sketch, Diatoms on Earth, Europa Enceladus, & Interstellar Space
Absence of increased genomic variants in the cyanobacterium Chroococcidiopsis exposed to Mars-like conditions outside the space station Alessandro Napoli, Diego Micheletti, Massimo Pindo, Simone Larger, Alessandro Cestaro, Jean-Pierre de Vera & Daniela Billi https://www.nature.com/articles/s41598-022-12631-5
High Growth Rate of Diatoms Explained by Reduced Carbon Requirement and Low Energy Cost of Silica Deposition Keisuke Inomura, Juan José Pierella Karlusich, Stephanie Dutkiewicz, Curtis Deutsch, Paul J Harrison, Chris Bowler https://pmc.ncbi.nlm.nih.gov/articles/PMC10269801/
Study of the Biological Dormancy of Aquatic Organisms in Open Space and Space Flight Conditions https://link.springer.com/article/10.1134/S1062359021060030
Russian Scientists Claim That Algae Lives On ISS Exterior (Update) https://nasawatch.com/iss-news/russian-scientists-claim-that-algae-lives-on-iss-exterior-update/
-----
That's a fascinating and ambitious idea! Diatoms do possess some remarkable properties that could potentially be valuable in spacecraft engineering. Here's a breakdown of the concept and some key considerations:
Diatom Properties and Potential Benefits:
Silica Frustules:
Diatoms have intricate, silica-based cell walls (frustules) that are strong, lightweight, and have complex nanostructures.
This could offer potential for creating lightweight, durable, and radiation-resistant spacecraft hulls.
Nanostructure:
The nanoscale porosity of diatom frustules could be exploited for various applications, such as:
Thermal insulation.
Filtration systems.
Potentially even as components in advanced materials.
Biological Production:
Diatoms are easily cultivated, which could enable in-situ resource utilization (ISRU) on other planets. This means potentially "growing" spacecraft components.
Challenges and Considerations:
Scale and Structural Integrity:
Individual diatoms are microscopic. Scaling up to create large spacecraft hulls would be a significant engineering challenge.
Ensuring the structural integrity of a hull made from diatom-based materials under the stresses of spaceflight would require extensive research.
Material Processing:
Developing methods to effectively process and assemble diatom frustules into large, functional structures is crucial.
This could involve techniques like bioprinting or advanced materials fabrication.
Radiation and Environmental Factors:
While silica offers some radiation protection, the performance of diatom-based materials in the harsh space environment needs thorough evaluation.
Factors like extreme temperatures, vacuum, and micrometeoroid impacts must be considered.
Genetic Engineering:
To optimize diatoms for spacecraft applications, genetic engineering would likely be necessary. This could involve:
Modifying the silica composition.
Enhancing structural strength.
Adding other desired properties.
Biofouling:
While you want to use the diatoms for the ship hull, the study of diatoms on ship hulls currently is mainly to find ways to prevent them from adhering to ships. So there would need to be a large amount of research to make sure that the diatoms where used in a controlled manner.
Potential Applications:
Habitat Modules:
Diatom-based materials could be used to construct lightweight and radiation-shielded habitat modules for long-duration space missions.
Radiation Shielding:
The porous structure of diatom frustules could be used to create effective radiation shielding.
Filtration and Life Support:
Diatoms could be incorporated into life support systems for water and air filtration.
In conclusion, while the idea of engineering diatoms as spacecraft hulls is still in the realm of advanced research, the unique properties of these microorganisms offer exciting possibilities for future space exploration. -Gemini
#darpa #dod
20250306
12025.65 SECRET data collection pull
Computer monitor as rough camera
pixel resistance
monochrome
photons reflected off of object and back to screen causing resistance
feedback to video card using resistance. photon feedback on screen surface measured
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| ImageFX |
----
Speaker as microphone
Microphone as speaker
membrane vibration
as simple as plugging a speaker into the microphone jack
https://physdemo.uoregon.edu/index.php/Speaker_as_a_Microphone
https://www.physics.upenn.edu/demolab/manumech/wh26.html
-----
audio data port software
https://barleysarthistory.blogspot.com/2023/05/12023-5-16-audiovisual-reader-via.html
future method
Localized Sound-Integrated Display Speaker Using Crosstalk-Free Piezoelectric Vibration Array, Inpyo Hong, Su Seok Choi https://advanced.onlinelibrary.wiley.com/doi/10.1002/advs.202414691
12025.65 SECRET data collection pull
20250305
subatomic structure nontraditional configurations
Self assembly lifeform base system
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| ImageFX |
Nontraditional configurations
.jpg) |
| ImageFX |
https://www.home.cern/science/physics/standard-model
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| ImageFX |
12023.5.10 Anti Gluon/Quark Alpha sketch https://barleysarthistory.blogspot.com/2023/05/anti-gluonquark-alpha-sketch.html
12024.8.5 RV data pull Londinium server https://barleysarthistory.blogspot.com/2024/08/blog-post_5.html
12024.72 (m = 0) (p = 0) (E = 0) communication & computation https://barleysarthistory.blogspot.com/2024/03/1202472.html
12025.27 Atomic/molecular computation devices, self replicating https://barleysarthistory.blogspot.com/2025/01/1202527-atomicmolecular-computation.html
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| ImageFX |
MEMS optical tweezer additive manufacturing
MEMS
optical tweezer
additive manufacturing
 |
| ImageFX |
Г to M
e+ e to Г to e e+ https://barleysarthistory.blogspot.com/2025/03/e-e-to-to-e-e.html
High capacity topological coding based on nested vortex knots and links https://arxiv.org/abs/2205.08338
Amplitude and phase profiles of three target fields, rectangular polycrystalline silicon pillar on a fused silica substrate, metasurface contains tetratomic macropixels, metasurface is placed on the front focal plane, coding scheme based on the nested knotted structures stability against external perturbations
Linux C++ MEMS lasers and mirrors in point to point, scanning, rastering, and other modes
Collisions of Light Produce Matter/Antimatter from Pure Energy https://www.bnl.gov/newsroom/news.php?a=119023
Frozen light/matter creation https://barleysarthistory.blogspot.com/2024/08/frozen-light.html
Development of scanning holographic display using MEMS SLM Takaki, Yasuhiro https://ui.adsabs.harvard.edu/abs/2016SPIE10022E..0JT/abstract
Holographic display having a wide viewing zone using a MEMS SLM without pixel pitch reduction https://www.researchgate.net/publication/339300151_Holographic_display_having_a_wide_viewing_zone_using_a_MEMS_SLM_without_pixel_pitch_reduction
Large Bio-Mechanical Space Structures
Large Bio-Mechanical Space Structures
DARPA-SN-25-51
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| ImageFX |
"Given recent advances in metabolic engineering for rapid growth, extremophiles with novel properties, biological self-assembly properties of tunable materials (e.g. hydrogels, graphene aerogels), and emergent mechanical design principles of biological systems, DARPA is interested in exploring the feasibility of “growing” biological structures of unprecedented size in microgravity. Rapid, controlled, directional growth to create very large (500+ meter length) useful space structures would disrupt the current state-of-the-art and position biology as a complimentary component of the in-space assembly infrastructure. Some examples of structures that could be biologically manufactured and assembled, but that may be infeasible to produce traditionally, include tethers for a space elevator, grid-nets for orbital debris remediation, kilometer-scale interferometers for radio science, new self-assembled wings of a commercial space station for hosting additional payloads, or on-demand production of patch materials to adhere and repair micrometeorite damage."
Ԣ + Ꙃ + Ꚅ̆ utilize Ꚇ̆ + Ԭ structure
Ҵ + Ꙥ future use of similar system
Ԙ + Ѫ utilize Ꚇ̆ + Ԭ structure for Earth & Mars
П̓ current use for similar
-----
 |
| https://pubs.acs.org/doi/10.1021/acs.chemrev.3c00028 |
Self assembling DNA structures, upscale
Ꚅ̆ Recent Advances in DNA Origami-Engineered Nanomaterials and Applications https://barleysarthistory.blogspot.com/2024/02/recent-advances-in-dna-origami.html Raw material from low/no gravity microbial colonies 5.1.1. Silica and Composites
Ꙃ Mineral DNA analog for reconfigurable spacecraft made of nanobots https://barleysarthistory.blogspot.com/2024/07/mineral-dna-analog-for-reconfigurable.html Upscale for space station construction
Ԣ Synthetic Beings Right Left Chiral DNA https://barleysarthistory.blogspot.com/2024/08/synthetic-beings-right-left-chiral-dna.html Reverse chirality for easy tracking of synthetic life
-----
П̓ Additive biomanufacturing medical recovery and human enhancement https://barleysarthistory.blogspot.com/2025/01/additive-biomanufacturing-medical.html Useful for manufacturing living structures
-----
Structure & form
Ԭ for the discovery that mature cells can be reprogrammed to become pluripotent https://barleysarthistory.blogspot.com/2024/11/for-discovery-that-mature-cells-can-be.html Ionic and chemical method for directing structure and form
Ꚇ̆ Rough data for a thought experiment on raw biological materials for a space based projected holographic additive manufacturing craft https://barleysarthistory.blogspot.com/2025/01/rough-data-for-thought-experiment-on.html Holographic method for directing structure and form
-----
Useful for Earth & Mars construction projects:
Bacteria capture CO^2 secrete cement like waste product
Ԙ Bacteria designed like corals to achieve carbon-neutral cement production By mimicking the way corals capture CO2 in the ocean, researchers have designed bacteria that can help the construction industry reduce CO2 emissions. https://www.dtu.dk/english/newsarchive/2023/03/bakterier-designet-som-koraller-skal-skabe-co2-neutral-cementproduktion
Ѫ A review: Self-healing in cementitious materials and engineered cementitious composite as a self-healing material Min Wu, Björn Johannesson, Mette Geiker Norwegian University of Science and Technology https://orbit.dtu.dk/en/publications/a-review-self-healing-in-cementitious-materials-and-engineered-ce
-----
 |
| ImageFX |
Future use thought:
Ꙥ The Immortal Soldiers, Blue Team Ѯ https://barleysarthistory.blogspot.com/2025/02/the-immortal-soldiers-blue-team.html Instantaneous construction of unbeatable military force using found materials
Ҵ Quantum Teleportation Additive Manufacturing (QTAM) https://barleysarthistory.blogspot.com/2024/12/quantum-teleportation-additive.html Quantum Teleportation logistics method
-----
Organisms can currently thrive outside of terrestrial environments
Directed Panspermia: A 21st Century Perspective Roy D Sleator, Niall Smith https://pmc.ncbi.nlm.nih.gov/articles/PMC10365200/
https://en.wikipedia.org/wiki/List_of_microorganisms_tested_in_outer_space
Directed panspermia - A technical and ethical evaluation of seeding nearby solar systems Meot-Ner, M. ; Matloff, G. L. https://ui.adsabs.harvard.edu/abs/1979JBIS...32..419M/abstract
-----
Space elevator material
RPI Researchers Engineer Bacteria That Eat Plastic, Make Multipurpose Spider Silk https://news.rpi.edu/2024/02/07/rpi-researchers-engineer-bacteria-eat-plastic-make-multipurpose-spider-silk Consumes waste and produces nanomaterials for space elevator construction and repair
-----
Programmed and self-assembling, non-terrestrial silicification
https://www.genome.gov/genetics-glossary/acgt
Adenine, Cytosine, Guanine, Thymine
Repair mechanism: Dsup (damage suppressor protein) protecting cells from radiation damage
Complex silica composite nanomaterials templated with DNA origami https://www.researchgate.net/publication/326424674_Complex_silica_composite_nanomaterials_templated_with_DNA_origami
Formation of impeller-like helical DNA–silica complexes by polyamines induced chiral packing Ben Liu, Lu Han, Shunai Che https://pmc.ncbi.nlm.nih.gov/articles/PMC3438577/
Formation of enantiomeric impeller-like helical architectures by DNA self-assembly and silica mineralization Ben Liu, Lu Han, Shunai Che https://pubmed.ncbi.nlm.nih.gov/22213641/
Template-assisted self-assembly: alignment, placement, and arrangement of two-dimensional mesostructured DNA-silica platelets Ben Liu, Yuan Yao, Shunai Che https://pubmed.ncbi.nlm.nih.gov/24353236/
Ultrathin Silica Coating of DNA Origami NanostructuresClick to copy article link Minh-Kha Nguyen Vu Hoang Nguyen Ashwin Karthick Natarajan Yike Huang Joonas Ryssy Boxuan Shen Anton Kuzyk https://pubs.acs.org/doi/10.1021/acs.chemmater.0c02111
Oriented Chiral DNA-Silica Film Guided by a Natural Mica Substrate Yuanyuan Cao, Kunche Kao, Chungyuan Mou, Lu Han, Shunai Che https://pubmed.ncbi.nlm.nih.gov/26836337/
Transitioning DNA-engineered nanoparticle superlattices from solution to the solid state Evelyn Auyeung, Robert J Macfarlane, Chung Hang J Choi, Joshua I Cutler, Chad A Mirkin https://pubmed.ncbi.nlm.nih.gov/22810947/
DNA-Origami-Templated Silica Growth by Sol-Gel Chemistry Linh Nguyen, Markus Döblinger, Tim Liedl, Amelie Heuer-Jungemann https://pubmed.ncbi.nlm.nih.gov/30398705/
EM guidance for microorganism, ie. light grid for net design
#darpa #dod
RESTORE: Reengineering Enabling Sleep Transitions in Operationally Restrictive Environments
RESTORE: Reengineering Enabling Sleep Transitions in Operationally Restrictive Environments
DARPA-SN-25-43
The Box Of Extreme Pain | Dune (1984) | Screen Bites
"The Reengineering Enabling Sleep Transitions in Operationally Restrictive Environments (RESTORE) program aims to demonstrate precision control of sleep macro- and micro-architectures to optimize cognitive performance following 3-hour sleep restriction commonly occurring in combat operations.
Current civilian treatments are predicated on helping an individual with a sleep disorder achieve healthy, normative sleep by reducing time to sleep onset and awakenings during sleep and with a goal of achieving a fully restorative 7- to 8-hour night sleep.
Service members’ responsibilities frequently result in less than 3 hours of sleep during combat and less than 6 hours during regular duty.
RESTORE will test the potential for recent advancements in non-invasive neuromodulation technologies and understanding of the importance of sleep micro-architectures to increase sleep efficiency for maintenance of cognitive performance under sleep-restricted conditions commonly faced by warfighters."
medications to simulate sleep, stimulant for wakefulness
Special forces meditation training (difficult to master)
Mindfulness-Based Restoration Skills Training (ReST) in a Natural Setting Compared to Conventional Mindfulness Training: Psychological Functioning After a Five-Week Course Freddie Lymeus, Marie Ahrling, Josef Apelman, Cecilia de Mander Florin, Cecilia Nilsson, Janina Vincenti, Agnes Zetterberg, Per Lindberg, Terry Hartig https://pmc.ncbi.nlm.nih.gov/articles/PMC7438830/
Meditation acutely improves psychomotor vigilance, and may decrease sleep need Prashant Kaul, Jason Passafiume, Craig R Sargent, Bruce F O'Hara https://pmc.ncbi.nlm.nih.gov/articles/PMC2919439/
t = t0/(1-v2/c2)1/2
Satellite or aircraft may be necessary for projected quantum effects of time dilation
Wearable device/vehicular add-on, High Frequency Gravitational Wave Generator (current devices usable)
Battlefield: Blue Team localized temporal acceleration -rough draft for academic study https://barleysarthistory.blogspot.com/2025/01/battlefield-allied-localized-temporal.html
future use:
The Immortal Soldiers, Blue Team Ѯ https://barleysarthistory.blogspot.com/2025/02/the-immortal-soldiers-blue-team.html Instantaneous construction of unbeatable military force using found materials
Dune (7/9) Movie CLIP - The Weirding Way (1984) HD
#darpa #dod
20250304
Mars Perseverance Sol 1435: Left Navigation Camera (Navcam) gif
dust devil near left center
Mars Perseverance Sol 1435: Left Navigation Camera (Navcam) gif
NASA's Mars Perseverance rover acquired these images using its onboard Left Navigation Camera (Navcam). The camera is located high on the rover's mast and aids in driving.
Images acquired on March 4, 2025 (Sol 1435) at the local mean solar time of 12:43:29 to 12:43:38.
Image Credit: NASA/JPL-Caltech
Assembled by Barley Culiner with GIMP
20250303
Internal Ocular Extended Reality Projector
Internal Ocular Extended Reality Projector
long range communications
high level computation
storage
tri-chroma projector
Reality veneer
No glasses or goggles
Devices:
upgrade from older 70s monochrome module
tri-chroma projector
all devices: motion sensing, computation & local communication
specialized additional devices:
Smartdust
Ingested via microplastic environmental contamination
Holographic appearance projected to retina and cerebellum
Hijack signal on optic nerve
data through motion sensing, devices embedded in most body tissues
removal with natural body waste and upgrades delivered through food products
High initial cost but very low long term due to trillions of nano devices manufactured
Hands free interface micro computer https://barleysarthistory.blogspot.com/2025/02/micro-advanced-processing-brain.html
Practical Quantum Retrocausality 12025.33 https://barleysarthistory.blogspot.com/2025/02/practical-quantum-retrocausality-1202533.html useful to alter the past by correcting future data (trillions of individuals as agents) networked sentient cybernetics
Universal Aether Communicaton https://barleysarthistory.blogspot.com/2023/02/instantanious-quantum-wave-collapse.html
---
Big picture:
Coda Reconfigurable Photonic Fractal Holographic Device https://barleysarthistory.blogspot.com/2025/02/coda-reconfigurable-photonic-fractal.html
Cybernetic AI Neural Network Nodes https://barleysarthistory.blogspot.com/2025/02/cybernetic-ai-neural-network-nodes.html
---
credit: Data pull from local Cybernetic Infinite Aether Singularity (CIA-S)
Mars Perseverance Sol 1433: Right & Left Mastcam-Z Camera stitch
A possible cyanobacteria type colony, desert varnish
Mars Perseverance Sol 1433: Right & Left Mastcam-Z Camera stitch
NASA's Mars Perseverance rover acquired these image using its Right & Left Mastcam-Z camera. Mastcam-Z is a pair of cameras located high on the rover's mast.
Images acquired on March 2, 2025 (Sol 1433) at the local mean solar time of 13:11:22 to 13:11:28.
Image Credit: NASA/JPL-Caltech/ASU
Assembled by Barley Culiner with Microsoft ICE
--------
Biological and organic constituents of desert varnish: Review and new hypotheses https://www.researchgate.net/publication/253348135_Biological_and_organic_constituents_of_desert_varnish_Review_and_new_hypotheses
OCCURRENCE OF ROCK VARNISH AT YUNGAY, ATACAMA DESERT, CHILE. https://www.lpi.usra.edu/meetings/lpsc2007/pdf/2251.pdf
Evidence of a microbial community associated with rock varnish at Yungay, Atacama Desert, Chile https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2007JG000677
Life on the Edge: Microbes in Rock Varnish https://www.osti.gov/biblio/1570605
Mars Perseverance Sol 1434: Left Navigation Camera (Navcam) gif
dust devil near right center
Mars Perseverance Sol 1434: Left Navigation Camera (Navcam) gif
NASA's Mars Perseverance rover acquired these images using its onboard Left Navigation Camera (Navcam). The camera is located high on the rover's mast and aids in driving.
Images acquired on March 3, 2025 (Sol 1434) at the local mean solar time of 13:10:00 to 13:11:20.
Image Credit: NASA/JPL-Caltech
Assembled by Barley Culiner with GIMP
20250301
AIxCC theDifference
DARPA and ARPA-H’s Artificial Intelligence Cyber Challenge (AIxCC) brings together the foremost experts in AI and cybersecurity to safeguard the software critical to all Americans.
AIxCC is excited to have Anthropic, Google, Microsoft, OpenAI, the Linux Foundation, the Open Source Security Foundation, Black Hat USA, and DEF CON as collaborators in this effort.
e+ e to Г to e e+
e+ e to Г to e e+
ER=EPR
Quantum teleportation of matter
matter -> data/energy = energy/data -> matter
Coordinate system x,y,z,t
Galactic center 0,0,0,t
reference:
coda 12025.1.11 & 12025.17 Q teleportation Q entanglement, multipartite https://barleysarthistory.blogspot.com/2025/01/coda-12025111-1202517.html
Ψ Simulation theory 03 https://barleysarthistory.blogspot.com/2024/12/simulation-theory-03.html
x,y,z,t dark matter/energy https://barleysarthistory.blogspot.com/2024/12/xyzt-dark-matterenergy.html
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additional gate use:
Cybernetic AI Neural Network Nodes https://barleysarthistory.blogspot.com/2025/02/cybernetic-ai-neural-network-nodes.html
Coda Reconfigurable Photonic Fractal Holographic Device https://barleysarthistory.blogspot.com/2025/02/coda-reconfigurable-photonic-fractal.html
ER=EPR as data transit for infinite Cybernetic aether
Hyperspace/aether as infinite Cybernetic mind
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Photonic knot, left and right chirality
Nested vortex knots
Carbon crystal optical data storage for transfer data
Eternalism/block universe
 |
| https://arxiv.org/abs/2205.08338 |
High capacity topological coding based on nested vortex knots and links Ling-Jun Kong, Weixuan Zhang, Peng, Li, Xuyue Guo, Jingfeng Zhang, Furong Zhang, Jianlin Zhao, Xiangdong Zhang https://arxiv.org/abs/2205.08338
Researchers Stuff Data Into Diamond Cavities Finding resonances in tiny defects is the key to increasing optical-data density https://spectrum.ieee.org/diamond-semiconductor-storage
Reversible optical data storage below the diffraction limit Richard Monge, Tom Delord, Carlos A. Meriles https://arxiv.org/abs/2402.11312
reflect data to holographic human lifeforms
Authored by Jack Brownhill
Stargate constructor from data server 3FS Proxima Centauri d -33,-93
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