Computers are the back office in multiple operations.

Computers are the back office in multiple operations. But they are also black boxes for many people who don't understand their capacity. The most powerful computers guarantee that the systems handle missions independently. The same programs, algorithms, and protocols that operate drone swarms can also operate nanomachine swarms inside the human body. 

But those nano-size systems require powerful, nano-size processors that can make those robots independently operate tools that can run control codes in their computers. If that kinds of systems are possible theoretically those small-size submarines can use similar control codes as full-size quadcopters or other-shaped drones. 

The back office of successful missions in technology is computers. The highly complicated systems and mission requires ultra-powerful computers that can operate many things and handle many variables in the mission. Space and aerospace missions are the most high-profile systems in the world. 

And the computers follow their entire missions and record every second of the aircraft and rocket's life cycle. The computers can make simulations about cases where something went wrong, and then the creators of the systems can fix that problem. The complicated AI-based software also runs on powerful computers. 

But things like multipolar calculation protocols where multiple small computers connect their forces make it possible. Those cloud-based solutions make it possible to interconnect multiple workstations into one entirety. Things like drone swarms can operate quite independently. But the ECM-jammer systems can disturb the cloud-based computing that those drone swarms require. 

"The centerpiece of the NASA Center for Climate Simulation (NCCS) is the over 127,232-core “Discover” supercomputing cluster, an assembly of multiple Linux scalable units built upon commodity components capable of nearly 8.1 petaflops, or 8,100 trillion floating-point operations per second. Credit: NASA’s Goddard Space Flight Center Conceptual Image Lab" (ScitechDaily.com/Behind the Scenes at NASA: Supercomputers Empower NASA Mission Success)

"This air flow visualization shows the vortex wake for NASA’s six-passenger tiltwing concept Advanced Air Mobility vehicle in cruise or “airplane-mode.” This image reveals the complexity of the flow for a tiltwing multi-rotor configuration, where many rotors interact with each other, the wing, and the fuselage. Credit: NASA/Patricia Ventura Diazfesta"(ScitechDaily.com/Behind the Scenes at NASA: Supercomputers Empower NASA Mission Success)

"The golden parts of the device depicted in the above graphic are transformable, an ability that is “not realizable with the current materials used in industry,” says Ian Sequeira, a Ph.D. student who worked to develop the technology in the laboratory of Javiar Sanchez-Yamahgishi, UCI assistant professor of physics & astronomy. Credit: Yuhui Yang / UCI" (ScitechDaily.com/Tiny Transformers: Physicists Unveil Shape-Shifting Nano-Scale Electronic Devices)

"Houston Methodist Research Institute nanomedicine researchers used an implantable nanofluidic device smaller than a grain of rice to deliver immunotherapy directly into a pancreatic tumor. Credit: Houston Methodist" (ScitechDaily.com/Smaller Than a Grain of Rice – Scientists Use Tiny Implantable Device To Tame Pancreatic Cancer)

“Excitons” are responsible for light emission of semiconductor materials and are key to developing a next-generation light-emitting element with less heat generation and a light source for quantum information technology due to the free conversion between light and material in their electrically neutral states. There are two types of excitons in a semiconductor heterobilayer, which is a stack of two different semiconductor monolayers: the intralayer excitons with horizontal direction and the interlayer excitons with vertical direction".(ScitechDaily/Processing Data at the Speed of Light – “Nano-Excitonic Transistor”)

"Optical signals emitted by the two excitons have different lights, durations, and coherence times. This means that selective control of the two optical signals could enable the development of a two-bit exciton transistor. However, it was challenging to control intra- and interlayer excitons in nano-scale spaces due to the non-homogeneity of semiconductor heterostructures and low luminous efficiency of interlayer excitons in addition to the diffraction limit of light". (ScitechDaily/Processing Data at the Speed of Light – “Nano-Excitonic Transistor”)

"Frenkel exciton, bound electron-hole pair where the hole is localized at a position in the crystal represented by black dots" (Wikipedia/Exciton)

Biotechnology with miniature, nano-size microchips are the most powerful tools in miniature robotics. 

The new nano-excitonic transistors and next-generation microchips are required for the control devices of the most powerful nanotechnology ever created. New nanotechnology allows to create the miniature submarines that are smaller than rice. Those nano-size submarines can create next-generation canvases and other things. The nano-submarines can create artificial DNA molecules and then turn them into nanotechnology canvas. 

The highly accurate nanotechnology also can make a chemical copy of its program code. And that thing could be useful in interstellar flights. The system puts its data into the artificial DNA. That is stored in bacteria. And then those bacteria transmit that data to the microchips in the form of electric impulses. 

In those systems, small-size submarines operate in water or some other liquid. But if they get energy those robots can operate as all other drone swarms. The living neurons are problematic because they are vulnerable to poisons and radiation as well as other neurons. So in high radiation levels, the drone swarms must use some other than organoid-intelligence-based solutions. 

The new robots that are smaller than rice can also benefit from the same systems that are operating drone swarms. Those miniature robots are created to input cytostatic treatment to the tumors. But the same systems also can use small cutters. And they can operate as miniature surgeon tools. That operates inside the human body. That kind of robot might remove plaque from the Altzheimer patient's nervous system. Genetic engineering makes it possible that some carrier cells. 

"Researchers from UT Health San Antonio discovered that certain immune cells, called invariant killer T (iNKT) cells, possess a unique homing property that directs them to the skin at birth, providing crucial protection and lifelong immunity. These skin-homing iNKT cells also promote hair follicle development and cooperate with commensal bacteria to maintain skin health and prevent pathogenic bacterial overgrowth". 

Those kinds of cells can use to transport those small submarines to the right point. Even if those cells are moving to the skin other cells are traveling in other places. There is the possibility that a small submarine carries stem cells to the right point sometime in the future. 

That small submarine can simply carry the DNA of the stem cell. And then that system can just suck the non-wanted DNA out from the cell's nucleus. Then it can inject the stem-cell DNA into that nucleus. But the problem is how that submarine finds the right point in the human body. 

https://scitechdaily.com/behind-the-scenes-at-nasa-supercomputers-empower-nasa-mission-success/

https://scitechdaily.com/processing-data-at-the-speed-of-light-nano-excitonic-transistor

https://scitechdaily.com/scientists-discover-new-property-of-immune-cells-like-guided-missiles/

https://scitechdaily.com/smaller-than-a-grain-of-rice-scientists-use-tiny-implantable-device-to-tame-pancreatic-cancer/

https://scitechdaily.com/tiny-transformers-physicists-unveil-shape-shifting-nano-scale-electronic-devices/

https://en.wikipedia.org/wiki/Exciton