Among the people summoned, in addition to programmers and computing system design experts, there were also sociologists, jurists, scholars from Chinese think tanks, and members of the security department.
However, except for a few people who know that they are designing a biological operating system core, the vast majority of people have no idea what they are doing.
This system, named "Nuwa Core", is designed and constructed through the virtual space of Nanke Dream World.
Huang Mingzhe also let ghosts participate in it, the purpose is to avoid someone playing tricks. Nuwa core will be used in cell chips, and cell chips may be used in humans.
The importance of Nuwa's core is related to the future of mankind, and it must not be taken advantage of.
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On the other hand, the Institute of Human Evolution has undergone an internal reorganization.
The previous route that focused on X-gene enhanced serum was rejected, and was changed to fully support Fang Ge's biological computers, bio-based armor, cell robots, etc.
Although Li Jiahang, the chief researcher of the X serum project, is very disappointed, the X gene-enhanced serum currently has a bleak future.
Since the X-gene enhanced serum route is difficult, and the biocomputer route has begun to appear, of course we must concentrate on winning the biocomputer.
With Li Jiahang and hundreds of other researchers joining the team, the biocomputer project has once again accelerated.
Wen Kehan and Jiang Tiansheng were responsible for setting up the Nuwa Kernel Laboratory, communicating with the system design and construction team of Nanke Mengjie, and jointly designing and building the Nuwa Kernel.
Regarding the Nuwa core, the R&D team decided on the core route and ideas of R&D after some discussions.
That is "security", "stability", "joint array", "compatibility", and "strong association".
Security and stability are indispensable. Sociologists have proposed that the humanized Nuwa core should be blank, that is, the artificial intelligence-type programs in the Nuwa core should be strictly restricted.
Because many people are worried that biological computers will give birth to real intelligence, and once biological computers give birth to intelligence, the consequences will be disastrous.
Imagine that a biological computer integrated with human beings suddenly gave birth to intelligence one day, and then personality. Can one body accommodate the existence of two consciousnesses?
Obviously it is impossible. The consequence is that the human consciousness is swallowed by the biological computer and becomes a "new human being".
No one can accept that as soon as they wake up, they become another person, and this "person" can seamlessly inherit everything from the original owner.
The best way is to blank out the core of Nuwa and, after implanting it into the human body, directly use the human consciousness itself as artificial intelligence, fundamentally preventing the birth of intelligence from biological computers.
It's like a farmland. If left unchecked, weeds may become overgrown. But if you build a greenhouse and plant crops, the weeds will lose their living space.
Therefore, the Nuwa core uses as many underlying rules as possible to fully integrate the human consciousness and the biological computer.
This is a fundamental design idea, and it is also the guiding idea for future Nuwa core upgrades. Human beings are here to strengthen themselves, not to become slaves of computers and biological batteries.
Kill artificial intelligence from the beginning to avoid endless troubles later.
With the guiding ideology and the efforts of a large number of professional programmers, experts and scholars, the progress of Nuwa kernel research and development has been rapid.
After all, we have now entered the era of brainwave input and virtual networks, and the work efficiency of Chinese programmers has increased by more than ten times.
After setting the strong correlation brain wave bands between the cell chips, the process of constructing the cell chip joint array begins.
The design idea of the cell-chip joint array draws on the neuron network of the human brain and adds the multi-threaded working mode of modern electronic computer systems.
By rationally allocating the computing power of the biological computer, multitasking can be achieved without conflict.
These are all plans that can be used for reference. Human beings have come up with so many imaginative ideas over the years, and there are countless ideas that they can learn from.
For example, in the human supercomputing model, connecting biological computers to the public network can form a human supercomputing array, integrating the computing power of everyone's biological computers.
However, this part of the technology is very controversial, and the R&D team has temporarily shelved the compilation of this program.
Let’s complete another important system first, which is the consciousness protection system (firewall).
For example, the brainwave traffic threshold is forced to be set to prevent someone from using the flood of information to attack the biological computer system; there is also a forced disconnection mechanism to protect the information used and life safety.
It is very important to protect the system consciously. If the biocomputer system is unsafe, the user will not only lose property, but may even endanger his or her life.
Once the system permissions of the biological computer are stolen by hackers, the consequence is that the hackers can control a person's body.
This phenomenon is very scary and may even cause humans to reject biological computers.
As the first-generation system designers, everyone has carefully considered the possible negative impacts of biological computers and tried to plug these existing loopholes as much as possible.
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Inside the laboratory.
Fang Ge, Lin Sha, Li Jiahang and others are studying Huang Mingzhe's particle control technology.
After a few days of understanding, everyone realized how powerful particle control technology was. With this technology, cell chips can control particles through specific conditions.
Of course, the technology seems very simple, but without the presence of X-gene serum, ordinary cells have no way to control particles, or they cannot actively control particles.
The cancer cells after the fusion of **gene serum now have strong vitality and strength, and can store energy. The energy stored per unit is equivalent to about 23.5 times that of ordinary cells.
Whether it is the macroscopic universe or microscopic particles, their movements are subject to the conservation of energy. There is no high-energy storage mechanism, and cell chips do not have the power to control particles.
The particles mentioned here refer to atoms, small molecules, and a small portion of polymers.
Li Jiahang was amazed: "I didn't expect Academician Huang to have such technology."
"Among the technologies we have screened out, there are only 7 types of particles that can be micro-controlled using cell chips, while some other particles need further improvement." Fang Singer posted a relevant test report.
The seven types of particles that can be micro-controlled by cell chips are: iron atoms, calcium atoms, zinc atoms, aluminum atoms, silicon atoms, carbon atoms, and phosphorus atoms.
It can be seen from here that metal-type atoms are the easiest to control, followed by semiconductor-type atoms, and the most difficult-to-control atoms are gas atoms.
As one of the basic elements of the human body, carbon atom has attracted the attention of many researchers.
However, semiconductor atoms are much more difficult to control than metal atoms.
Through the combination of X-gene serum and modified proteins, work began on the development of carbon atom controller protein components.
This kind of experiment is different from the general research and development of semiconductor chips or electronic components.
The research and development of cell components adopts the mutation screening method, which is to continuously induce mutation of cancer cells, then select excellent mutant varieties, and carry out induction, screening and cultivation from generation to generation.
This approach has advantages and disadvantages.
The advantage is that it is easier to induce mutations and the cost of experimental production is low; the disadvantage is that the randomness is too great and it is difficult to determine the progress of the research.