A Swarm of tiny drones can search for life from distant worlds.

Tiny swimming drones can search for life in the oceans of the distant worlds like oceans on the icy moons of Jupiter. The system that delivers those drones into the ocean might look like a virus. The system can make a hole in the ice by using lasers. 

Or some other electromagnetic radiation. Then the system delivers those drones to the ocean. The drone swarm can use cloud-based network architecture for handling information. And they must operate very independently. 

And those drones can send information to the surface module. The surface module will transmit that data to Earth.  

But there must be an alternative system. That ensures that data can send to Earth. In the cases that the surface unit fails. There is the possibility that when the surface unit makes a hole in the ice. That system will fall through the ice core. 

"In the Sensing With Independent Micro-Swimmers (SWIM) concept, illustrated here, dozens of small robots would descend through the icy shell of a distant moon via a cryobot – depicted at left – to the ocean below. The project has received funding from the NASA Innovative Advanced Concepts program. Credit: Jet Propulsion Laboratory" (Phys.org/Swarm of tiny swimming robots could look for life on distant worlds)

The drone swarms at another planet are interesting things. But also places like the South Pole on the Earth are places where those swimming drone swarms are suitable for mapping the lifeforms. Swimming nano-drones can also measure pollution and other kinds of things. 

But the drone swarms are also suitable for searching and observing things like submarines. The AI-controlled swimming drone swarm can slip to submarine bases and can search for secretive information. 

Those microrobots can carry by using miniature- robot submarines that are looking like torpedoes. But if those drone swarms have a suitable power source those drones can also swim to their target independently. The carbon-fiber materials and nuclear batteries make it possible that the quadcopters can operate underwater and in airborne conditions. The carbon fiber materials are making it possible. That those drones can swim very deep. 

The new radioisotope technology is making it possible to make very small-size interchangeable radio thermal generators. Those systems are like normal batteries. But their energy source is in a radioactive breakup.

Those nuclear batteries can install in regular drones. And they are easy to handle. So they can offer operational time that lasts for years for even regular small-size quadcopters. 

https://phys.org/news/2022-06-swarm-tiny-robots-life-distant.html

https://scitechdaily.com/nasa-swarm-of-tiny-swimming-robots-could-look-for-alien-life-on-distant-worlds/

Sky Cruise is one of the wildest aviation innovations ever seen.

Sky Cruise is an enormous, nuclear-powered drone. That concept allows flying luxury hotel service for 5000 passengers. In that concept, there are swimming pools and hotel rooms with restaurants inside that massive hyper jumbo-jet. The Sky Cruise can stay airborne even for years. And that thing is opening interesting scenarios also for things like interplanetary missions. 

The Sky Cruise concept can operate in atmospheres there is no oxygen. The plasma-jet engines make it possible that the giant flying laboratory can send to the Venus or even to the atmospheres of gas giants. This kind of nuclear-powered aircraft can also operate as a flying aircraft carrier. And it can also transport division with all its equipment across the ocean. 

The idea for Sky Cruise could be from the "Avengers" movie. In "Extreme tech" mentioned that DARPA wants to build the similar flying aircraft carrier that is in that movie. (ExtremeTech/DARPA wants to build an Avengers-like flying aircraft carrier, to make drones even more effective)

Image 2

The use of nuclear power in aircraft is not a new idea. The USAF made test flights by using NB-36 "Crusader" from 1955-1961. The NB-36H was the nuclear-powered version of the B-36 "Peacemaker". (Wikipedia, Convair NB-36H)

In fictional movie "Avengers", the heroes operate with a massive flying mothership. In some visions of the future. There are massive nuclear-powered quadcopters. Those quadcopters are operating as platforms for many types of missions. The fact is that nothing except the power source limits the size of the quadcopters. 

Boeing company introduced one of the most interesting visions of a flying aircraft carrier. There the giant Boeing-747 jumbo-jet carried small jet fighters. That giant Boeing 747 would launch those miniature fighter jets in the air. The Boeing 747 in question would be equipped with a service glove where those fighter jets would be re-equipped.

Things like F-117 "Nighthawk" attack aircraft, could be launched from C-5 Galaxy cargo planes. The brake chute will pull that aircraft out from the backdoor of the cargo plane. And there is the possibility that this kind of small jet fighter can fly in a cargo plane. 

And nuclear-powered quadcopters can be even larger than an aircraft carrier. But as you know nuclear-powered aircraft are possible to make. When we are thinking about things like flying aircraft carriers there are concepts where drones are dropped from the cargo planes. 

And the same cargo planes can offer to refuel and rearming for those drones. In some visions. There is a manipulator arm at the back of the C-130 cargo plane, and that system will pull the drone into the cargo plane for rearming. 

http://www.extremetech.com/extreme/193904-darpa-wants-to-build-an-avengers-like-flying-aircraft-carrier-to-make-drones-even-more-effective

https://www.sandboxx.us/blog/nb-36-crusader-americas-massive-nuclear-powered-bomber/

https://en.wikipedia.org/wiki/Convair_NB-36H

https://en.wikipedia.org/wiki/Lockheed_C-5_Galaxy

https://en.wikipedia.org/wiki/Lockheed_F-117_Nighthawk

Image 2)http://www.extremetech.com/extreme/193904-darpa-wants-to-build-an-avengers-like-flying-aircraft-carrier-to-make-drones-even-more-effective

Flying cars are back in the spotlight.

The flying cars or rather-saying cheap and flexible VTOL (Vertical Take-Off and Landing) aircraft that can travel on highways and by air are probably the next-generation systems for many purposes. Those flying cars are suitable tools for avoiding rushes. Flying cars can move people to remote areas. 

They can replace traditional ambulance helicopters or small-size police helicopters. The term flying car means a low-cost helicopter that can operate also as a car. One version is the quadcopter-based solution where those wheels are turned into propellers. 

If we think of the solution where propellers are in the tubes that makes the system less vulnerable. If VTOL-system uses traditional rotors where one contact with a wall can break the blade. 

Or they can fly to the roofs of the buildings. That low-noise vertically operating systems can carry servicemen and tools to roofs. But the fact is that those systems can also be equipped with machine guns and anti-tank missiles. And that makes them flexible tools for many things. 

Their drivers can drive them straight out from flying cargo planes. And then they can travel on the ground or by flying. New computerized stabilization systems and highly advanced AI makes those systems safe. And one important thing is that the flying cars that are using blowers can move through air faster than traditional helicopters. 

Those small aerial vehicles can move faster than sound. By using the electric jet engines. There is possible to make hybrid engines where propellers inside a tube give thrust when the vehicle moves slowly. And when the speed of the craft is rising. The propellers turn into straight plates. And the electric arc is made by using those propellers as electrodes allowing those systems to reach incredible speeds. The electric jet engines can be quite small and effective systems. 

The system can use remote electric load like some kind of maser system. This kind of thing can be a very powerful tool in the civil and military world. One of the weapon solutions for flying cars can be the flying car bomb. The weapon could fly to its target like an airbase as a missile. And then that missile would turn to drive on the ground against the armored doors of aircraft bunkers. 

https://www.designboom.com/technology/evtol-leo-coupe-jet-turbine-propelled-flying-car-06-28-2022/

https://interestingengineering.com/this-electric-jet-engine-could-lead-to-carbon-neutral-air-travel

Image 1) https://www.nationaldefensemagazine.org/articles/2020/7/6/air-force-aims-to-turn-science-fiction-into-science-fact

Image 2) Pinterest

The discoveries in genetics are making it possible to create cancer vaccines and artificial lifeforms and explore the origins of life.

Image 1) "Origin of Life” artist’s concept. (ScitechDaily/Incredible Virus Discovery Offers Clues About the Origins of Complex Life)

The new virus renews our understanding of the origin of life. 

This virus can be the key to solving questions when eukaryotic bacteria are born. The first bacteria that were born on Earth were prokaryotes. They had no nucleus. Then some kind of mutation made the nucleus in those cells. The nucleus protects the DNA against electromagnetic radiation. And that thing was a fundamental advantage. 

The order of born of life:

1) First-born organisms were prokaryotic cells. The very first cells got their energy from the volcanic heat. For being real cells. Those primitive cells required mitochondria and cell organelles that made the membrane for those cells. In history, mitochondria have been independent organisms. 

Today mitochondria live in symbiosis with all cells with an internal power source. The cell is delivering sugars to mitochondria that are giving energy to it. 

2) Then born viruses. The viruses might advance from the DNA bites of those prokaryotes. Some people think that viruses were unsuccessfully split bacteria. They had protein-membrane and DNA (or RNA) but no other cell organelles. 

3) The viruses connected their genome to the prokaryote. And that thing made it possible to make eukaryotes. Cells with a nucleus, cell organelles, and cell membrane. 

There is suspicion or hypothesis. That some viruses slip into the prokaryotic bacteria. Then that virus connected the DNA (or RNA) of that bacteria to itself. The eukaryote required two genomes. The first is how to make a cell membrane. And how to make a nucleus structure in the cell. The cell must also have cell organelles that are giving energy to it and make the protein membrane for the cell. That kind of ability is very interesting because it opens new roads in genetic engineering. 

Image 2A

Image 2B

Image 2C

Image 2A) Simplified structure of a mitochondrion (Wikipedia/Eukaryote)

Image 2B) The endomembrane system and its components ((Wikipedia/Eukaryote)

Image 2C) Diagram of a typical prokaryotic cell (Wikipedia/Prokaryote)

Cancer vaccines

Cancer vaccines are vaccines whose principle is the same as other vaccines. The idea is that the immune system detects cancer cells and destroys them. The customized cancer vaccines made separately for each individual are easy to make by using the person's tumor cells. Or if the person would not have a tumor the person's cells can turn into cancer cells by using radioactive stress. 

Then developers must kill those cells and separate the membrane proteins from the cells. And then those proteins will just inject into the person. That thing makes it possible to create a preventing cure for cancer. And that thing might save many lives and save lots of money. The cancer vaccines are the thing that can be very revolutionary. 

DNA-based mimicks of cytoskeletal filaments for reversible assembly and cargo transport.       Credit: University of Stuttgart and Max-Planck-Institute for Medical Research ( Phys.org/Another step toward synthetic cells)

Artificial cells can use to give genome therapy. 

Biotechnology allows to making of artificial cells. Those cells can use in bio or nanotechnology. If the artificial bacteria can change the genomes from the cells. That thing can use to give genome therapy. The idea is that the bacteria will destroy the genome of targeted cells. And then bacteria can inject another DNA into the cell. 

This is one version of how the new biotechnology can bring fundamental things to our life. If we are thinking about the controlled evolution there is the possibility that in the future. Researchers are transferring the genome that allows some mammals to live in the desert without water to humans. That thing makes it possible to make humans that must not drink so often.

https://www.cancer.gov/about-cancer/treatment/types/immunotherapy/cancer-treatment-vaccines

https://phys.org/news/2022-06-synthetic-cells.html 

https://scitechdaily.com/incredible-virus-discovery-offers-clues-about-the-origins-of-complex-life/

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

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

Image 1) https://scitechdaily.com/incredible-virus-discovery-offers-clues-about-the-origins-of-complex-life/

Image 2A) https://en.wikipedia.org/wiki/Eukaryote

Image 2B) https://en.wikipedia.org/wiki/Eukaryote

Image 2C https://en.wikipedia.org/wiki/Prokaryote

Image 3) https://phys.org/news/2022-06-synthetic-cells.html 

Researchers found genomes that control the advance of our senses.

Researchers found the genomes that are controlling our senses. Or they found the genetic origin of our senses. That thing gives information on how our sensory cells and neurons that control our senses are forming. And that thing can use to make organisms like bacteria that are following images even from the computer screens. 

That kind of research can help to find why some people turn blind. And why do some people have things like sensory hypersensitivity? There is suspicion that people who have sensory hypersensitivity. Have too many neurons for handling the senses that hypersensitive sensor sends. That means one sense turns too dominating. 

The things like genome tests are opening the road to a new type of diagnosis. Things like sensory hypersensitivity along with ADHD are the reason for genomes. That means those things can detect in genetic tests. And things like therapy can begin at an early age. And of course, if the sensory hypersensitivity is in an audition that kind of person can use earplugs. 

Those genomes are opening fascinating ideas for developing artificial species that have no certain senses. The ability to connect genomes between species is making it possible to create new species. The ability to connect genomes makes it possible to create the bacteria chains. That are following certain images. This thing makes it possible to create bacteria that can capture images from the computer screen in physical form. 

The idea is that the bacteria chain will put itself over certain images. And if it can see those things it can connect also virtual images to nutrients. Those bacteria can be fluorescence. And that means they can detect by stressing them with UV light. Or the small amoeba that detects the letters by using eyesight can drop fluorescence chemical to the point of letters that it sees on the computer screen. 

If we can create the bacteria line that follows the image. That thing makes it possible to capture images from computer screens in physical form. This thing requires that the bacteria can connect the image to the food. And that's why that bacteria chain can have the basil with cloned neuron as the locomotive. And then the basil makes the daughter calls that it drops at a certain point. 

https://scitechdaily.com/scientists-find-the-genetic-origin-of-our-senses/

The single-atom tractor beam is powering electromagnetic catalysis.

The tractor beams are here. They are effective only in atom-sized devices. In those systems, the photons are used to turn the atoms in the right position. So that they can form bonds more easily than without that position. And those kinds of things can be extreme tools. 

The system can turn things like enzyme molecules in the right position. It allows the system can adjust the enzyme's surface layer and their effect with very high accuracy. 

Those optical systems can use to make nanomachines and other kinds of systems like ultra-small microchips. The optical tractor beams are the next-generation tools in many areas. They can use to make complicated molecules or move single atoms on the layers. 

Optical tweezers are one of the solutions that can revolutionize technology. The idea of the tractor beams is not the new one. There are made pressure-wave-based tweezers that can use to move the miniature microchips and put them in the right position. The problem with microchips is that if somebody touches them with magnetic tools that thing can delete the program of that microchip. 

The pressure or optical tweezers are working in the same way. The wave motion will focus in the middle of the structure. And then those energy or pressure waves are anchoring the object to the right position so that the operator can move it to the right place. 

So that's why this kind of system is interesting. The tractor beams or the pressure tweezers can use also for rising things from the ground without touching them. This is why people like criminal investigators are interested in those systems. Things like quadcopters can equip with pressure-based tractor beam systems. And they can pick evidence up from the ground. 

But is it possible that the tractor ray from UFO cases will work in real life? The system could use simply light that turns atoms in our body in the right position. Then the system will pull the person to the craft. The idea is that the system turns water molecules in the same position. And benefit the polarity of those molecules. And then the magnets will pull the person or object to the craft. 

Simulations are making the R&D process cheaper.

Mixed reality is an excellent tool for making simulations. 

There are many versions of the virtual worlds. Some of them have no touch with the real world at all. Those virtual worlds are products of imagination. Some other virtual worlds can be so-called mixed reality worlds. 

Things like computer games can use to research and develop tactics. The gamers are playing things like war simulations. And then the AI selects the most successful ways how to make some things. The war simulations are a good example of how to use virtual worlds and virtual reality in R&D work. 

Those mixed-reality worlds can be spaces that are scanned by using lasers. The term "mixed reality" means that the real-world and virtual worlds are mixed. The mixed reality can use to control remote-controlled robots from long distances. The things that robots see and hear are transmitted to the controller's virtual reality set. 

The VR systems can also use to control hypersonic aircraft. The problem with those extremely fast aircraft is the pressure that impacts the aircraft's nose. If the nose of the aircraft can make by using the same material and form the same layer that makes the aircraft more sustainable. So the camera systems are transmitting data to the pilot or remote controller that uses the VR systems to get information about the environment. 

The mixed reality systems can contain many parameters. They can have the cell cultures in the laboratory or even in the nuclear reactor hall. Those cells can be packed in the boxes where the walls are made of the material that is used in protective suits. Then system observes how long those cells are living under radioactive radiation. And when an operator like a fireman operates in some harmless space the system tells when that person got too much radiation by using data that is collected from those cell cultures. 

But the thing is that also robots can wear VR sets. That thing makes it possible. That robot can practice how to operate in virtual areas. So the robot can operate in virtual space. The operators can make the labyrinth by using wires and paper. And the operator can see the scanned corridors. 

The use of virtual spaces makes research of robots cheaper. And those robots can practice operating in areas where it's hard to get access. The robot can get scanned images about things like nuclear power plants. So the robot can practice how to move in that place without being there physically. 

The fact is this in this type of mixed reality simulation where the robot is following the road that is marked by using wires and board elements that can move to different places are easy to build. And they are also easy to remove. That kind of mixed reality training site allows that robots must not take anywhere. So making the research is cheaper because the research team can be in their hall. And that thing makes R&D work easier. 

The artificial language of AI is interesting.

The operator can use a pocket interpreter to command computers and robots. That translator can translate the spoken language to a synthetic language like Esperanto or Volapük. 

Those languages can use to command robots. The problem is how the robot can separate commands that are meant for it from other speech. And synthetic languages can offer a solution to those kinds of problems. 

When the robot is operating in a noisy shopping center.  And it should follow the voice commands. The problem is that there is a lot of speech in that area. The robot should separate the commands meant for it from other discussions. And one version of how to make that thing is to use Esperanto or Volapük as command language. People are not using those synthetic languages for everyday communication. And that makes them perfect for commanding robots. 

The system would be easy to separate commands from other speech. If the operator gives commands to it using Esperanto. The operator can give commands by using a regular translation tool. In the pocket interpreting machine will just increase the Esperanto or Volapük. And the operator can use the pocket interpreter for commanding robots. 

And that is why researchers are interested in synthetic languages like Esperanto. Synthetic languages are easier to use for commanding things, like robots in public places than so-called natural languages. The computer is easier to separate commands that are meant to it from the other speech if they are given by using Esperanto or Volapük than using English or some other language. 

AI has developed a new spoken language. The new synthetic language is different than any other spoken language. This kind of language can use in the communication between robots. But when humans are interacting with humans. There is needed some kind of language that's easy for the speaker. The robot can speak English. But when the commander gives commands the robot must separate those commands from other speech. And one version is to use some synthetic languages.  

In history, there were two synthetic languages that language specialists developed seriously. Those languages were Esperanto and Volapük. Those famous languages were synthetic that had nothing to do with the cultural environment where natural languages are born. If the commands to computers are given using Esperanto it's easier to separate commands from other speech-like discussions of the workers. 

But why the synthetic languages needed in computing? The fact is that if we want to give commands to computers by using speech. The computer must separate the commands. That meant to it from other speech. And that's why synthetic languages are better than spoken languages. 

The fact is that programming languages are all synthetic. Famous programming languages C, C++, Java, and Python are also languages. They are used for making programs. Those languages are "quite easy" to write. But they are hard to speak because they involve symbols that are not letters or numerals. 

Those programming languages are fast and easy to write, but the problem is that they are different than spoken languages. Programmers must learn the new grammar and that thing takes time. The researchers make lots of work to create the programming and commanding languages that are easy to learn. 

When researchers are developing commanding languages for robots they must realize. That person who is giving commands might have bad argumentation. Or they might have some kind of speech defect. That kind of thing must be noticed when the voice commands are given to robots or computers. 

The thing is that the computers can calibrate the system and customize it for every single user separately. In that kind of technology, the person who gives commands to robots would first command virtual characters on the screen. When the character makes something it might ask, "was this OK"?  

If the character made the right things. The user must just accept the operation. And it will be driven to the robots. In that case, the robot will use macros to make things. That its controllers want. 

https://www.slashgear.com/902068/ai-develops-a-secret-language-that-researchers-dont-fully-understand-heres-what-it-means-for-the-future/

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

https://en.wikipedia.org/wiki/Volap%C3%BCk

The economics and environment.

Things like delivery robots are important for making something interesting. When marketing people offer products, their job is to make the product interesting. That people will click them or touch them. The image of the robot makes homepages interesting. People are always interested in high tech. 

And when some new services like home delivery are marketed to customers. The first challenge is to make people click the homepage. Homepages are making products that customers use interesting looking. But they are also making some marketing areas interesting. 

Economics is not an independent thing. The economic conditions are connected to the will to invest in the country. And when we are looking at things. That is looking good from the point of view of investments. Investors are afraid of things like dictatorship, corruption, and authoritarian governments. Also, areas that promise nothing cause investors are not interested in that kind of thing. 

When an investor gives money to some project, that person wants something for that money. Things like ethics in the production and value chains also mean very important. And in the time of the internet, the data is traveling very fast. And if there is some kind of problems with ethics in the production plants that causes problems in the markets. 

Bad economics causes a whirl that rises corruption makes authoritarian touch possible. Finally causes the nation falls into dictatorship. And when the nation turns to open dictatorial. That makes investors escape from that area. 

The image of the area means very much in modern marketing. If some products are made in areas. That is not good for the image. That means nobody buys them.

Marketing plays a big role in sales. If nobody buys the product. That thing means that the factory will bring losses. And sooner or later the investor must decide to close the factory. That means the investor takes the money away from that area. 

And the investors are bringing their money to the areas because they want to sell products to customers. If investment will not bring value and profit the investor will take money out from the area. If that investor is the central actor that can cause a chain reaction. And lots of investments can lose in a short moment. That causes inflation and destroys economics. 

The main effect of destroyed economics is that the society turns unstable. That accelerates things like brain leaks to more stable countries. And then the most innovative people are leaving the area. And that causes problems for new startups. 

But how to call investors? 

The key element is that we must sort, out what kind of jobs and economics we want to make? We can, of course, make a business environment where are a lot of low-tech companies like hamburger restaurants. But then we can think that there. Is some other way to make the business area interesting. 

If we want to call high-tech industry to some region, we must make that area addictive for that kind of companies. Things like universities that offer high education are good places. Where tomorrow's professionals can get there at least basic skills. 

But another thing is that education is a good moment to familiarize the environment where schools or educational faculties are. The thing is that higher technology and artificial intelligence are interesting things. 

If we want to make a sewing shop or garment factory. That thing might be very big news. But if we want to make a garment factory where robots are making the work, we might get also more positive publicity. 

The main problem in manned garment factories is the poor salary of those workers. The thing is that the robot factories are an elegant way to make ethical business. The problem is that in markets their highest quality-price relationship wins. But the problem with production costs is that the low production costs mean low salaries. 

A bad economic situation causes untrustworthy conditions. 

The problem is how to fit low production price and low selling price together with an image of the product? Low production prices mean poor salaries. And that thing is one of the biggest problems in markets. Even if we would transport our factory to some cheap land, we must realize that there is something that keeps salaries low. 

And that thing is bad economics. Bad economics is making society unstable and violent. That means there is a danger that a person will get physical injuries because of some robberies. And bad economics is the thing that causes low education. Low education makes people susceptible to populists that are offering a simple medicine for that kind of economic situation.

Those things are refusing to pay loans, hiring more people to the army, and finding outside enemies. Also, corruption makes investors afraid of that area. Corruption is the thing that makes investors fear things like arbitrariness. 

https://networkedinternet.blogspot.com/

How to make material that can place itself?

Have you seen the movie named Christie? There was a car in memory that sheet metals could fix the limited damages. The name of those materials is "memory metal". The easiest way to make material that can fix the limited damage like dents and small holes is to connect small nanomachines to the flexible wires. 

The system looks a little bit like a pearl necklace but the form of pearls looks like boxes. Those miniature boxes are connected by using the spring-shaped nano-wire. When something impacts the structure that spring will stretch. And when electricity is connected to that spring it would turn shorter. 

Those nanomachines could have small-size rods that can lock themselves to a certain form. When something impacts that kind of material, the flexible wire keeps those nano-structures together. And then the system will conduct electricity to that material. And it makes the spring-looking wire turn shorter and those crystals can connect and form the entirety. 

https://artificialintelligenceandindividuals.blogspot.com/

Why does traffic form the perfect environment for AI creators?

Image 1) Oldsmobile 442 (Illustration image) 

When researchers are creating algorithms and self-operating robots, they need an environment there are strict and certain rules. The traffic environment offers that kind of operational environment. The first AI algorithms used the chess game as the test platform. 

Chess offered a good, well-controlled but limited environment for the AI creators. But then the power of computers and things like decentralized computing along with AI-based solutions makes it possible to use a larger environment when ambition grows. The self-driving cars are engineers' dreams and that kind of system requires lots of complicated code. 

Making self-flying aircraft is easier than making a self-driving car. The flight altitude of the aircraft must adjust to higher than the highest mountain. And the aircraft will not impact that mountain. The self-driving car must avoid many things like surprisingly starting danger. 

Image 2) Delivery robots can use to collect information that researchers need for making self-driving cars. 

The self-driving cars require lots of code and many variables. That means the programmer must be accurate. And the code must be error-free. If there are problems with the program code. That means the car can cause a dangerous situation. 

So the things like delivery robots used in markets play a big role in this kind of development. Those robots can collect information on what kind of changes and bugs the control code of the systems has. The car pays over 1000 kg, and if it has problems with control algorithms that thing can cause a dangerous situation. 

But when we are talking about traffic as the platform for testing and operating the AI, we must understand one thing. The data mass and accuracy of data are the things that are making those systems suitable. If the AI can get information about the beginning and destiny of each vehicle. 

And information about predicted breaks, etc. that allows the system to operate as an entirety. The system can make holes in car rows in the motorways and adjust the driving speed. But there are always problems with privacy. 

Information plays a big role in the AI-controlled entireties. Drone swarms require information about the positions of their members. The algorithms that are controlling traffic are basing a similar hierarchy to the drone swarms. 

The hierarchy in the control protocol is simple. 

1) The system that operates the entirety interacts with

2) Individual systems. Those individual systems can be the systems that are operating cars. But they can be infrastructural systems. 

When some drawbridge rises the system stops traffic. And the operating system can also interact with the ships and fit its speed so that passing the bridge is comfortable. This kind of entirety where multi-level systems interact makes the traffic smooth and flexible. But there is lots of work with those systems. 

Image 1) Pinterest

Image 2) https://www.innovatorsmag.com/robots-to-deliver-products-on-the-streets-of-europe/

Use of the AI for speeding of computing. And AI-based computer-program code's error correction.

There is possible to make error-correction in the programming languages very easily by benefiting the AI and network-based technology. When the computer program will make contact with databases. It requires the paths where to find those databases. So there is possible that the programmer will set paths to the needed database in the programming editor before the programming starts. 

That programmer can make a macro by using the form that can call by giving a certain command. That macro can bring all databases in the form of a list to the screen. And there can be a description of what each database is doing. That the macro will put the paths of the databases in the wanted point. So the programmer can simply select the right database from the list and the program makes the paths. 

Another thing is that AI can make it possible to use descriptions. If a programmer forgets how to make input-output syntax by using the C- or some other programming language that person must simply write "take input and output syntax between interface and database 'x'". That means that the programmer's time would not go for finding paths or some commands. 

When we are thinking about network-based solutions for the program the modular program is the key to making the new and effective programs faster. On the server can be stored the modules where is a description of what those modules are doing. Then the programmer must just tell the computer what the program should do. And then the AI will collect certain elements in their entirety. After that, the programmer can make cosmetic changes in the code like replacing some images, or something like that. 

When the program is running the workstation can send the code that should drive to the server. And in this point server checks if the code is damaged. And do the bits and the length of the program match with the code in the hard disk. So the system compares two codes. And then it will check things like user permissions. 

The new technology is making it possible to drive computer programs faster than ever before. That cloud-based system makes it possible to share the program code between microprocessors and computers through the internet. The idea is taken from the animation programs from the early 21 st century. Those systems shared the code between multiple processors and made it possible to make complicated animations by using home computers. 

In that AI-based system, the computer program is cut into segments like in the TCP/IP protocol. Each segment has a serial number. The system observes how often the system needs hose segments or modules. And if the system doesn't use some segment for a while. It removes that segment from the RAM and stores it on the hard disk. 

(Segment 1)(Segment 2)(Segment 3) (Segment 4)... .

The AI-based operating systems make it possible. The program code can travel through the hard disks when the program is running. That means the system can remove unnecessary parts of the code from RAM. When they are not needed. In that model, the AI keeps a book on how often the system uses a certain part of the program. And if that part is not needed that thing can be written to a hard disk waiting for recall. 

In modern systems, the computer program can crush into small pieces. And then each processor will handle an individual part of that data. The idea is that every piece of code is equipped with code that helps to break it into pieces and then reconnect those pieces to one entirety. That kind of technology makes it possible to drive complicated AI code by using limited computing power. This kind of system is necessary for the things like drone swarms. 

https://scitechdaily.com/new-technique-dramatically-accelerates-computer-programs-without-fear-of-errors/

The new technology will allow to deletion of single atoms from molecules.

"A new technique offers a way to leapfrog the laborious process of building molecular structures, allowing scientists to quickly and easily produce new molecules of interest." (ScitechDaily/Speeding Up Molecule Design With a New Technique That Can Delete Single Atoms)

The ability to delete single atoms from molecules makes a fundamental advance for many types of chemical- and molecular research. The medical industry can use this thing in the system, where is made complicated molecules. 

If another molecule must connect with certain carbon or some certain point in another molecule. That technology makes it possible to connect some other atom or molecule to the contact point for mark and also for keeping that reaction bond free.

The same technology can use in nano-manipulators that are making molecular structures with a certain form. In that system, the molecule that will transfer can connect to a carbon chain that acts as a manipulator by using a glue atom. When that molecule is in the right position the system can delete that glue atom. 

The nano-drill can conduct an ultrasound to the right position. Or it can release the sub-machine in the cell. 

The nano-drill can be the tool that takes a certain atom group near the target. One version is the nano-drill is the tool that conducts resonance to the precise point. The ultrasound will conduct on that system and then it aims that sound to the right position. 

That thing can open blood vessels. But in more conventional versions, nano-drills will just be driven to the ion pump of the cell. And that thing will just hang in that ion pump keeping it open. Or that system releases submachine in the cell. In that case, there can be the hatch that must release in the right position. When the system deletes those atoms the submachine jumps in the cell. 

In nanotechnology, the form of an atom group or molecule is important. When we are thinking about things like nano-drills the molecule itself is neutral. But the vertex has a positive or negative electric load. If a nano-drill is used for medical operation the positive electricity drives that system to the ion pump that pulls positive ions or anions in the cell. The problem is how to activate that vertex at the right moment. 

One of the versions is that the nano-drill or its vertex is in the protective nano-chamber. And when that nano-drill is in the right position the system deletes the protective chamber. That activates the nano-drill. In the other version, the nanomachine can be like a spring in the fullerene chamber. When that thing is close enough to its target the system deletes the fullerene, and the nanomachine will jump against the cell. 

If that thing can activate by using enzymes or the cell membrane will activate that process that makes it possible to make the new type of medicals that are effective against the bacteria or cancer cells. In that case, the fullerene can operate like a nano-size virus. 

The fullerene involves the carbon chain. And when that thing will slip into the cell. Then that fullerene will be destroyed. This releases the carbon chain in the cell.

Similar technology can use to transfer new genomes into the cells. The fullerene core protects the DNA or RNA molecule. When that artificial virus is in the cell it releases the genome in that cell. At the front of that molecule can be the DNA cutter enzyme that destroys the DNA from the front of that new DNA. 

This thing makes it possible to make complete genome transfer to living species. The first cells can infect with the artificial DNA that makes them create the viruses which DNA (or RNA) is equipped with that enzyme. Then those viruses will replace genomes with new ones. The system can create a way that when the genomes in the cell group have been replaced the system just removes the part of the genome that creates viruses. That thing stabilizes the DNA and a new species is born. 

https://scitechdaily.com/from-microsaws-to-nanodrills-laser-pulses-act-as-industrial-grade-machining-tools/

https://scitechdaily.com/molecular-machines-bacteria-killing-drills-get-an-upgrade/

https://scitechdaily.com/speeding-up-molecule-design-with-a-new-technique-that-can-delete-single-atoms/

The ion engines are the next-generation tools for controlling nanomachines.

The ion pumps of the cells can use as miniature ion engines or miniature MHD (Magneto Hydrodynamic Drive)-drive. They can connect with the nanomachines by removing cell organelles. And then the nanomachine can slip into that empty cell. Or it can rip bites of the cell membrane. Then nanomachine can control those ion pumps by conducting electricity to that membrane. 

The ion-driven nanomachines can be next-generation power tools. The ion pumps of the cell core can use as small ion motors. The idea of this kind of system is simple. The organelles of the cells will be removed and then the cell's core will connect with the nanomachine. The nanomachine will just control the function of the ion pumps by connecting plus and minus electricity to the cell membrane that is "stolen" from living cells. 

That kind of thing makes it possible to control nanomachines inside the human body. When the polarity of the electricity is changing it opens the certain ion pump. And that ion pump can drive the electrolytic liquid through it. 

The nanorobot can fly by using a plasma ball. In that case, the nanomachine is in the artificial ball-lightning. And the heat of the plasma makes that small robot hover above the ground. 

In some wildest visions, the small-size robot called a mini- or nanomachine will just cover with a water drop that is pulled to the machine by using magnetism. Or there can be some network that helps to keep that droplet in form. Then there would be the creation of the plasma ball that makes the system hover and follow the magnetic power lines of the Earth. The purpose of the water droplet is to isolate the plasma from the core of the nanomachine. 

Then the ions will shoot to that plasma ball, and that causes asymmetry in the power of that plasma. In the same way, the magnet that has the same pole as the plasma will target that plasma ball that causes oscillation in that thing. So that oscillation can send pressure waves to air. And those pressure waves can make the machine travel in the direction where the controller wants. 

Natural nanotechnology

The water droplets are hovering above the leaf of the vegetables because of the small-size hair. That hair is making it possible that water droplets will not close the air channels of the leaves. And that makes it possible that the vegetables can change gasses. Also when it's a rainy day. 

But similar hair or small wires can use another way. Small silicon droplets can be covered by using that kind of hair. That makes it possible that those silicon droplets are hovering above the layer. The microchip-controlled silicon droplets can be the form of the next generation of soft-core miniature robots. Those robots can hover above the water layer by using that nano-hair. 

The polar property of water molecules can make it possible to hover nanomachines above the water layer in which molecules are turned to the same position. 

There is the possibility that the next-generation nanomachines are using one quantum property of the water. The water molecule is polar. And if the same poles of water molecules can turn against each other. That thing will push the small machine above the water layer.

Magnets can put water molecules in the same direction. If the plus poles of the molecules are up. The nanomachine can hover by turning puls poles to the water layer. And those extremely small robots can benefit Earth's magnetic field for movement. They can move by following the magnetic power lines of Earth. Like plasma ball moves. 

If there is a compass stylus type molecule that has plus and minus poles that molecule can use to make those nanomachines flow above the water molecules that are in the same direction. The opposite pole of the stylus will pull and the same pole will push the nanomachine in the wanted direction. 

One of the differences between sci-fi- and the real-life robot is that the robot's behavior depends on programming.

The robots like fictional R2D2 from Star Wars movies can act as the model for every home cleaner robot that has also an entertainment center. The system can clean house and also project things like movies to walls or it can have a hologram projector. That hologram system can use dust like smoke or steam as the medium where it can project that 3D film. 

The programming or mission modules of robots are skills that robot has. In the world of robots, every skill that a robot has is a certain module in the program code. The term "ghost protocol" means that there is a computer program in the robot's computer. That existence is not reported to the owners of the machine. 

A certain signal activates the ghost protocol. And that signal can be a certain crucifix that activates some hidden mode in the computer. That kind of signal can be useful if the robot is playing count Dracula. The Dracula robot can order people to open doors by using subliminal commands. 

The armed person can also be that kind of signal when the system sees the person who carries some kind of gun. It can activate the combat model. The fact is that the robots can learn things in seconds if they have an operational module that is ready to use. The thing is that the robot is the platform. 

The robot's skills are determining the skills of robots. The same robot can operate as a cleaner, mason, security officer, military man, surgeon, etc. And those operational modules can download to it in seconds through the internet. So the robot learns new skills in seconds. 

In Sci-fi movies, the robots can be captured by their enemies. And in the Star Wars movies, the robots are yelling in pain. When they are under extortion. The thing is that modern AI can make it possible that the robot can really "cry" if it is handled too roughly. 

This kind of robot can be equipped with an accelerometer, thermal,  and pressure sensor. If the value that those sensors are registering is at a certain level the robot can say "it hurts" or it can yell of pain. Those things are called pseudo emotions. 

And maybe the next-generation toys are equipped with this kind of system. If they face rough treatment, those robots can say. That they are hurt. Maybe, those futuristic intelligent toys are meant for teaching children how to communicate and handle other people. And maybe they are used to select people who are working with children. 

When we think about scenes where robots are raising their hands for surrender we must remember one thing. If that reaction is programmed in the computer's memory the robot will surrender to people. The thing is that the robot can be dangerous anyway. There could be some kind of GPS that detonates the robot in the enemy base. The thing is that the robot will not tell anything that it will not know. 

A thing like a certain gesture from a person like a police officer can make the robot raise its hands. But there is the possibility that robots have ghost protocols that are activated by using certain signals, as I wrote earlier in this text. 

In some other visions, the robot can have subliminal loudspeakers. The shadow protocol means that the robot can do everything that its masters can say. But it can transmit everything that it hears to the observers. 

https://www.space.com/star-wars-robots-sci-fi-versus-reality

Modular programming is like connecting boxes with skills together.

Machine learning and traffic. 

How to make computers come out of the box? The simplest way is to make new boxes for the robots and computers. In that model, every box is a new skill for the AI. 

The thing in machine learning and learning algorithms is that they are not far different from us what we maybe want to believe. If we are thinking about the AI algorithm that is controlling things like traffic we might say that the AI is limited. The reason for that is that the AI controls only things that are connected to the traffic. But then we must realize that the traffic controlling algorithm will not simply know anything else. But it knows how traffic is working. 

The thing is that when humans are learning new skills like driving. They go to driving school. That driving school gives us the skill to drive. So in that learning process, the driving school is making the marks in memory that involve all skills that we need for driving. 

The driving school creates the module that involves all movements that we need for driving. Learning is simply recording the movement series. And then, those movement series are connected to certain actions or signals. 

Then those movements must connect with the certain situation.  So we can think that modular programming is like a group of boxes. In every single box is a series of actions. 

And programmers can connect those boxes freely. So modular programming is like putting the domino buttons in a certain order. Each box or button involves certain series of movements. 

The traffic control algorithm doesn't have physical actions. Except when the system controls active screens and traffic lights. 

If all vehicles would be robots. The traffic control system could give the orders to driving computers. And the car's internal computer makes the decisions about driving those cars. The system is a two-layer neural network where the vehicles are communicating with each other. And the traffic control system operates above this base layer.

The system collects data from sensors about the driving speeds and positions of the vehicles on the road. The purpose of the algorithm is to make the traffic work flexible. 

And the mass of data that the system has determines how effective it is. If the algorithm knows the goal of every vehicle it can make individual tracks for those vehicles and even fit their speed to each other. And that thing makes it possible to make flexible and fast traffic. The AI can handle large entireties. 

But that algorithm is in the box. That means it can make things very fast. But those things must program into its memory. We can think of those boxes where the AI is as nodules. Each module is like a box that involves a new skill that the AI can use for expanding its skills. The thing that makes it possible to paint houses is that there is some kind of robot that makes it possible to make that thing. 

There is the possibility that the robot cars have robot men. Which mission is to carry luggage and as an example clean the vehicles. So if the traffic control computer takes orders that it should paint a house it can ask some robot worker to make that thing. The thing is that the AI can scale the mission all over the entirety. And if it will not know what painting means, it can simply ask that thing to all robots. 

But the only thing that the AI knows is how the traffic works. The system knows how to control traffic lights and adjust the speed limits. But if we want to give orders to that algorithm that it should paint a house the system will not know what to do, because it probably even knows the word "paint". That means that the AI is like in the box. And how the Ai can come out of the box?  AI cannot yet learn like humans. But there is a way to expand the operational sector of AI simply by making the new box where is a new skill. 

Research shows that robotic surgeon is safer and improves patient recovery time by 20%.

 

If AI-controlled robots are making surgeries or some other things they are very effective tools. The AI will not be tired and it has nothing else to do than just make things what they should. The AI that recognizes things like cancer cells from microscopic images will make more accurate work when they remove those cells than any human can do. 

The AI-controlled robot never lost its skills. It must not update things what it must do in some courses. Only the needed databases must download from the net. So the robot is a platform that can do everything that is programmed in there. 

This means that the robot that acts as a mason can turn medical doctor very easily. The operators must just download the necessary mission modules to that system. 

AI is the perfect tool for many things. It can collect information and be neutral all the time. The reason why robots and AI are developed and why they are perfect surgeons is that those systems are ever worried. They don't have families about whom they must worry. Most of the errors that human surgeons are made are human errors. 

The surgeon might be worried about something in their private life. They might argue with their families. Or there might be something else that borrows their mind. One of the things that can cause problems is the summer holiday. And that can cause the doctor can keep hurry in the last case. 

 Or they can just think the wrong thing at the wrong moment. And that can cause problems when they will pull stitches too tight when they think wrong things. This is one problem with humans. One critique against AI is that AI doesn't have feelings. But the problem is that the negative feelings can cause problems in every work. We are all humans. Sometimes there are cases where a doctor or ambulance crew will come to a place where the victim had fought with those people. And that thing can cause the medical staff will not make everything that they can. Crimes are always opportunity and motives. 

And we have feelings. One of the reasons why researchers are developing AI  is that it removes humanity from actions. The AI is the cold mechanical actor that makes everything and only things what they should. They don't start to think about things that will happen evening. 

https://scitechdaily.com/research-shows-that-robotic-surgery-is-safer-and-improves-patient-recovery-time-by-20/

Researchers from the University of Minnesota are making it possible to control prostheses by using EEG.

When combined with an artificial intelligence computer and the above robotic arm, the University of Minnesota researchers’ neural chip can read and interpret brain signals, allowing upper limb amputees to control the arm using only their thoughts. Credit: Neuroelectronics Lab, University of Minnesota (ScitechDaily/Making Mind Reading Possible: Invention Allows Amputees To Control a Robotic Arm With Their Mind)

Mind reading is possible. The new invention makes it possible that amputees can move their prostheses. The same technology that is making it possible to control prostheses can use to control remote-controlled robots.  And those robots can operate as external bodies for people who use this technology. 

The prostheses controlled by the EEG are also robots. So the same technology that is used in those prostheses can use in many other types of systems. The system can also read thoughts and project them to the computer screen. And that thing is making it possible that this kind of system is the next-generation police and security system. 

Machine intelligence is making it possible that the microchip can interact with the prostheses and communicate with computers that are hidden in that robot arm. The biggest challenge in those systems is to connect the robot arm control with a certain bite of the EEG. 

In the same way, similar systems can control mobile telephones and computers. So this kind of technology allows a person to interact with many types of computers and computer-based systems. The EEG can use to control things like aircraft. 

And that thing makes it possible to create jet fighters that can make very tight turns. Even if the pilot would be onboard that brain-controlled interface allows turning the aircraft with extremely strong G-forces. The pilot must not even move their hands if all systems can control by using the EEG. 

One way to make a system that uses the EEG for controlling the thing is to use the electric curves of certain brain areas. The thing is that. A certain group of neurons are controlling every single movement of the human body. So if the neuron group that controls for example finger movement is known the system can detect the activation of those neurons and transmit information about that activation to the decoder that controls the manipulators. 

https://scitechdaily.com/making-mind-reading-possible-invention-allows-amputees-to-control-a-robotic-arm-with-their-mind/

Cyborg worms, robot amoebas, and miniature air-cushion vehicles can go anywhere where a man cannot go.

The next-generation robot worms can look like medicinal leeches. They might have air cushions that allow them to operate at least on ice. And those systems can also dive into deeper water. The black color is suitable because the solar panels are black. And that allows the robot worm to use solar energy during the daytime. 

Nanotechnology allows making the of square millimeter-sized robot air cushion vehicles. Those small air cushion vehicles can have silicon bodies and they can be very flexible. The system can even change its form and that kind of robot could swim like some worms or polyps. They can have muscles that are solar operating. The cloned muscle cells can connect to the solar panels. That allows for making the cyborg worm where a non-organic body will use cloned muscle cells for moving. 

Those cyborg worms can look like a medicinal leech that can dive into polluted water. Those worms are microchip-controlled and the black color could be useful because those robot worms use solar panels as the power source. At night time they could use miniaturized fuel cells that can use methane as fuel. Methane is everywhere where is rotten biological garbage. So the robots that are operating at water treatment plants. 

And search pollution and things that should not throw into the sewer can get methane from their environment. Or the robot worms can use internal methane bacteria cultures for making fuel for their power cells. In some visions, those systems can use the cloned electricity cells of electric eels that are giving them electricity. 

And those light-activating muscles can use in robotics. But also non-organic robots can use living muscle cells for moving. The idea is that the living muscle cells are moving the silicon or plastic core. So cyborg worms can operate in the water and other places where humans cannot go. 

The extremely small air-cushion vehicles can be next-generation tools for many roles. They can observe pollution, calculate animals, etc. 

https://scitechdaily.com/light-activated-muscle-cells-may-advance-biorobotics/

Image: https://www.britannica.com/animal/medicinal-leech

How to make a stamp-size hovercraft that can travel up to a hill? 

If we want to make the nanotechnical gel that flows up the hill we must make material that rises over an air cushion. Then there must be the miniature propellers that are making the low-pressure area at the forward of the gel or soft nanomachine group. The same propellers can put the airflow under the cushion. 

Or there is the possibility to make the same thing without the moving parts. The air flows naturally from down to up because of the pressure difference. So through extremely lightweight nanomaterial plate will pull the "U"-shaped tubes. Because of the capillary effect, the air flows to the tube. The U-shaped curve acts like the sail and the air pulls the nanolayer forward when it hits the U-shaped point of the tube. 

The same way the air can conduct below that structure when it comes out from that tube. The thing is that this could be a practical way to make the small-size nanotechnical amoeba travel up to the hill at least when it's on the water layer. The thing is that this kind of structure can be useful in very small-size systems. 

This new robot got its inspiration from mythic Centaurs.

Image 1:

The new centaur robot can operate on the moon. But there is also the possibility that that robot's wheels would equip with propellers that are giving the centaur robot the ability to fly and operate underwater. These kinds of innovations are interesting because the same robots can use in many areas. The centaur robot can operate alone or with a team of humans or other robots. 

If the size of the robot is big enough it can carry four to ten service men or robots. The number of carried people depends on the size of the robot. And it can have the ability to get wounded people to get medical attention or simply carry equipment to the places like building sites.

Image 2:

The centaur robot can carry wounded people on its platform and the man-shaped part of it can give medical attention while the vehicle travels to the hospital. If that robot can fly it can travel straight in the hovering VTOL aircraft like V-22 "Osprey" or helicopter. The fact is that the robots are multi-use tools. The same system can carry equipment to the building site or they can evacuate wounded people. Those robots can also operate in radioactive areas. 

The man-shaped robots can have ultra-sound or x-ray sensors in their hands and they can also detect the EEG curves if those systems have necessary sensors. In the combat zone that robot can carry a large number of Javelin missiles and shoot them independently or by using a remote control. The limits of the robots are depending on imagination. 

https://interestingengineering.com/lunar-rover-cross-centaur-robot

https://en.wikipedia.org/wiki/Bell_Boeing_V-22_Osprey

Image 1:) https://interestingengineering.com/lunar-rover-cross-centaur-robot

Image 2:) https://en.wikipedia.org/wiki/Centaur

Photonic microprocessors can be the next generation revolution in AI.

New photonic microchips are the most powerful tools in the world. The quantum computer can make the thing where the regular computers use 9000 years in 36 nanoseconds. And that means the quantum computers would be the tools that are turning the mind-blowing fantasies true. 

The quantum computers will turn the AI to a new level. And that thing will make many new things that are thought impossible before. The quantum computers can communicate with the robots by using WLAN. But in the wildest visions, the drones or other robots of the future use the half-organic microchips. The half-organic microchips mean that over the microprocessor are the living neurons. 

Communication between non-organic and organic microchips requires. The system can turn neural electricity into the form that the microchip understands. And then the microchip must turn its internal data signals into the form so that the neurons understand what the non-organic part of the system "wants to say". 

And small LED lights can use the bioelectricity of the neurons to communicate with the computer. And when those neurons are receiving data from the computer they can use tiny silicon electric cells for chancing the light that the computer sends to electric signals that will conduct to the neurons. The interactive communication between organic and non-organic layers is important so that the system will work perfectly. 

********************************************************************

The biological photonic brains. 

The phonic brains can consist of neurons that have the retina cells in their synapses bladder. The neuron can use the bioluminescence light to transfer the information to another neuron. 

The retina cell will transform the flashes of light into the electric impulses that are traveling in the neural system. Researchers can make that kind of brain by using genetic engineering. 

*****************************************************************

Quantum computers are tools that can control things like robots through the internet. But the fact is that the photonic microchips are opening roads to the new type of hybrid systems where living neurons communicate with microchips. The photonic microchip uses photonic neurons for making the operations. 

In some wildest visions, in the future. There could be photonic microprocessors between animals' neural systems. Or even the human neural system can boost by using a photonic system. These kinds of futuristic systems are making it possible to boost the power of neural systems. The higher thinking would be in the living neurons. And the reflexes of the system could be at the non-organic part of the microchips. 

But there is the possibility that the small LED light or another photon source will connect to the living neuron. And that thing can make it possible to create a new type of half-biological quantum processor. There is also the possibility that the neurons would be genetically engineered by connecting the genome that makes them shine. 

And they can send bioluminescence light to the computer. The thing is that those neurons must adjust the level of the bioluminescence light so that they can communicate with the non-organic microchips. In the half-organic microchips, the system has two layers. Those layers are living neurons and regular (binary or quantum processors). In those systems, the reflexes of the computer would control by using the non-biological microchips. That thing makes those systems very powerful and fast. 

https://singularityhub.com/2022/06/07/a-photonic-quantum-device-took-microseconds-to-do-a-task-a-conventional-computer-would-spend-9000-years-on/

https://www.thetimes.co.uk/article/ministry-defence-develop-quantum-computer-battlefields-c2cjnfp95

Image: ) https://www.tomshardware.com/news/photonic-chip-images

https://miraclesofthequantumworld.blogspot.com/

 

The new cockroach-inspired robots can be the next-generation recon tool.

There are many types of robots. And the new cockroach-inspired robot looks like trash. This type of system can serve law enforcement and intelligence for many missions. The robot can slip into the house and eavesdrop and otherwise observe people who are inside it. The fact is that robots can benefit from the oscillation of the structures for recording and re-transfer speech. 

Those very flat and invisible robots can also come over microchips and observe the electricity in those systems. The fact is that this type of robot is the next version of the eavesdropping and reconnaissance tools. The mission of those reconnaissance tools is being unseen. And deliver information about their entirety.

Those small robots can also slip into the ammunition storage or at the roof of the tanks. And they can guide smart weapons to their targets. As I wrote before, imagination is the limit of the use of robots. The robot is a good servant but a bad master. And another thing is that they are revolutionizing the world. Robots can make many things that are been impossible before. 

When we are looking at robotics we should see their opportunities. Most of the missions that are planned to transfer to robots are not surgical operations. They are works like masonry or cleaning. So most of the robots are not operating in the military area. They are operating in the regular works like cleaners. And those cleaner robots are good for data security. 

They are not taking unauthorized pictures of startup companies' introductions and putting them on social media. And those robots are not going to bars after work to tell about things that they see in business parks. The problem with low-paid human workers is that they are easy to recruit for industrial espionage. 

So the robots are partially solving this type of problem. But there is always the possibility that somebody uses robots as the eavesdropping and intelligence platform. The cleaner robot can of course act as a spying tool as well as humans do. The thing is that the programming determines the role of the robots. 

But we must realize one thing. Robots are platforms. And the types of equipment and programs are the thing that is limiting their use. The thing is that the works where robots are planned to use are low-pay, and some people want to buy those services rather from robots than humans. 

https://www.sciencealert.com/engineers-built-a-cockroach-inspired-robot-that-can-t-be-squashed

The next-generation medicals can be tiny nano-drills.

The schematics show two variants of light-activated molecular machines developed at Rice University that drill into and destroy antibiotic-resistant bacteria. The machines could be useful to fight infectious skin diseases. Credit: Tour Research Group/Rice University (Scitechdaily/Molecular Machines: Bacteria-Killing Drills Get an Upgrade)

Molecular robots are tools that can use for many purposes. Molecular nano-drill can destroy bacteria mechanically. When nano-machines are used for medical treatment. The system can remove those systems from the body quite easily. There are two ways how to make that thing. 

The first way is by connecting some magnetic metal to those molecules. Then the magnetic field can use to pull those molecular machines out from the body. Another way is to use special enzymes that are destroying the molecule. The problem is that the nano-drill bases benzene molecules and those molecules cause cancer. 

And that makes it the next-generation antibiotics. The problem with antibiotics is that it turns immune against antibiotics. But there is no way, how the bacteria can resist nano-machines. 

Nano-drills can do many more things than acting just like a bacteria killer. They can remove the waste from the body. And in some visions, those nano-drills can remove plaque from the synapsis. And that thing can be the next-generation treatment for Alzheimer's. 

The nano-drills can also remove things from the blood vessels. And that thing can open closed blood veins in the case of an infarct. The benefit of those nano-drills is that they can go to places where regular scalpels cannot operate. They can also remove single cancer cells from the body. 

The molecular nano-drills can use also for drilling holes in the cancer cells' protein membrane. The aiming of those molecular machines to the right cells will happen by connecting certain enzymes or nutrients to those molecules. And then the own immune system will transport the nano drill to the right cells. 

The problem with nano-drills is how they can aim at the right cells and how to deny them to destroy other cells. If there is some special nutrient that the targeted cells are using the nano drill can benefit that thing. The nutrient can involve enzymes that are making the protein-membrane weaker. Then the nano-drills can use feely because the cells must be prepared so that the nano-drills can make the hole in the membrane. 

https://scitechdaily.com/molecular-machines-bacteria-killing-drills-get-an-upgrade/

Image:) https://scitechdaily.com/molecular-machines-bacteria-killing-drills-get-an-upgrade/

The SAR technology

SAR or Synthetic-aperture Radar is a tool that is giving extremely good images from the ground. In that technology radio or microwaves are put to jump from the ground. And that helps to create the 3D maps of ground areas. The SAR radar is basing the idea that the radar is put on an instantly moving platform.

And makes the system possible to detect small-size, 3D targets from the ground. The wavelength of the radar determines how big objects they can see. When radar radiation comes from different sides it can create a structure's 3D models. Modern commercial SAR systems can detect even single vehicles from the ground through clouds.  The SAR technology allows us to see what happens in the Ukraine war. 

Diagram of the SAR system. The thing is that this system can be in two different satellites. (Wikipedia/Synthetic-aperture Radar)

The virtualization of the SAR systems is making them very hard to destroy. The small-size satellites can operate as a swarm. And the laser systems can be used as the laser-SAR systems. But the laser rays can also use to create the radio waves. When lasers are giving the electromagnetic stress to air molecules they send electromagnetic radiation like radio waves. The laser ray can use to create the virtual antenna for the radar system. The system can use two laser rays. 

One is giving the EM stress to air molecules. And the second one measures the echoes from the environment. The next-generation quantum systems can make it possible to see even a single sand bite from the ground. The idea of those systems is the same as the scanning tunneling microscopes. They can hover things like electrons or protons at the front of the radar. 

One of the things that this system can use is the water molecule. In that case, the water molecule will anchor to the layer by using the molecule's polarity. The hydrogen atoms can be in the layer and the oxygen can be outside. Then the system gives electromagnetic stress to the molecule that acts as the antenna. That type of system might be the key to the radar technology of the future. 

https://en.wikipedia.org/wiki/Synthetic-aperture_radar