After Spark Technology built the nuclear power plant, new materials were provided to the project team, prompting them to develop new technologies.

At the Neutrino Communications Laboratory, Zhao looks at the materials sent from the nuclear power plant.

He instructed, "Now start processing neutrino capture modulators with new materials."

The researchers began to look at the drawings, and the processed neutrino capture modulator was only the size of a soybean, which was too far from the previous large ball with a diameter of 5 meters.

The researcher in the laboratory asked Zhao Zhao worriedly: "Director Zhao, I learned that the company now manufactures a material called high-density materials.

Will this material be a high-density material, if it is a high-density material, it should be able to compress a multi-ton device to the size of a soybean.

But its quality has not changed, and if it is really made of high-density materials, such a device simply cannot be used by individuals.

It still cannot be popularized quickly, and it basically has no effect on the development of neutrino communication networks. ”

Zhao Zhao nodded with a smile and said, "You are right, if it is a high-density material, it really cannot be applied to our technology."

However, this material is not a high-density material, it is a new type of material developed by the degenerate state laboratory, the volume and mass are not large, but the nuclear force generated by the material is used to bind the ubiquitous neutrinos in space. ”

Neutrino Lab researchers were also shocked, they couldn't imagine that the technology could span so much.

Directly put a very large neutrino capture debugger, made so small.

This is not a compressed volume of several times or dozens of times, but a volume of neutrino capture modulators that is compressed by tens of thousands of times.

This is the promotion of existing technologies after breakthroughs in high-end materials and theoretical technologies.

Neutrino Capture Debugger, which previously relied on the strong weak interaction forces of heavy particles to capture neutrinos.

Now that the four fundamental forces are unified into a nuclear force, it is possible to capture neutrinos by nuclear force, which has become more efficient and consumes less energy.

Researchers quickly let intelligent industrial robots process neutrino capture modulators the size of soybeans and install them inside newly designed star glasses.

After Zhao Zhao used it, he said with emotion: "This is the real neutrino communication hardware, and we can finally improve the neutrino communication code to make it faster and more accurate to transmit complex information."

Smart devices are connected to neutrino communication satellites and can transmit data efficiently.

Without neutrino communication satellites, smart devices can capture and modulate small amounts of neutrinos on their own, and it can also relay emergency information to its surroundings.

Neutrino communication only needs to leave communication satellites in the sky, and there is no longer a need for servers on the ground for information processing.

As long as the power is sufficient, any smart device can be transformed into a small base station of a neutrino communication network. ”

After the success of this technology, Zhao Zhao immediately applied it to neutrino communication satellites, small neutrino capture modulators, which can make neutrino communication satellites smaller, carry more energy, and develop some important auxiliary functions.

The Neutrino Lab seized the time to test the satellites, and they needed to get the neutrino communications satellites ready before the mass projectors were put into service.

In the human-computer intelligent interaction laboratory, Lu Qinling, the laboratory director, is looking at a new material, which is high-density potassium chloride.

Feng Yunde, director of the Materials Research Institute, handed him the information that stated that this material can convert electrical signals into bioelectric signals that can be quickly recognized by nerves.

It can also quickly convert the bioelectrical signals of nerve endings into normal electrical signals.

Lu Qinling soon instructed researchers to study this high-density potassium chloride material.

Feng Yunde used ear bones to do experiments, he believed that the ears are closer to the brain, the pain nerves are not dense, and there is a sensitive nervous system.

Lv Qinling thought more about it, and needed to fully verify the properties of this material.

He not only did experiments on the ear bones, but also on the forehead, cervical vertebrae, arms, eye sockets and other sensitive places on the body.

At first, experiments were conducted on animals, and after ensuring the safety of the experiments, volunteers were recruited to conduct human experiments.

The artificial organs made by the genetic laboratory can ensure the safety of volunteers, but the process of the experiment is a little painful.

After meticulous experiments, Lu Qinling learned about the characteristics of high-density potassium chloride.

This material can indeed transform bioelectrical signals as long as it is plugged into nerve endings.

The nerve endings must be directly connected to the brain, and if they pass through the spine, the properties of this material will hardly work.

This requires that it be placed on the head. Combining all parts of the head, it is still the ear cartilage that is the most convenient.

Lv Qinling has developed a bioelectric signal transduction device, which is shaped like an ear stud.

The device directly penetrates the ear bone, and the high-density potassium chloride material inside will automatically connect with the nerve endings under the control of the smart device.

The potassium chloride material is only 50 microns thick and three millimeters long, the total mass of the equipment is only 100 grams, and most of the other modules of the equipment are power supply and communication modules.

Lv Qinling buckled himself with an earring-type bioelectric signal transduction device and tried to operate the intelligent robot.

He closed his eyes and focused on giving the robot a command to walk.

As a result, the intelligent robot did not move at all, and did not carry out the instructions given by Lu Qinling at all.

The researcher next to him had been observing the data, and when he saw that the device was outputting a set of garbled characters, he asked in surprise: "Director Lu, what's going on, other people's simple orders can be recognized, and if you give an order, why can't the device recognize it."

Is there a problem with the biopotential signaling device?

Fortunately, this problem has been discovered, and a potential hidden danger can be solved. ”

Lu Qinling waved his hand and said: "There is nothing wrong with the equipment, it still converts the bioelectric signals transmitted by the nerves into electrical signals that can be recognized by the instruments and equipment.

The reason why this kind of intelligent robot that gives commands but can't recognize it is that my brain has not yet established a new neural channel to pass accurate commands through the device. ”

The brain and bioelectrical signaling devices build new neural pathways, not from scratch to build a new neural network.

Instead, it uses the original neural network to transmit complex signals.

Human tissues and organs are highly adaptable to the environment.

When a person's blood vessel is blocked, several branches grow from the side and connect directly to the blood vessel in front of it.

Blood vessels are all like this, more complex brain nerves, more adaptable.

The brain's neural network is completely useless.

A person with an injured arm muscle does not always use his own hands until the injury is not healed.

Even if you use the advanced therapy of Spark Technology to heal your hand and not use it for a long time, you need complex rehabilitation training to restore the function of your arm.

A person who has been blind for a long time must have more sensitive ears than a normal person. This is the principle of using in and out.

The nerve pathway is still the original nerve near the ear bone, but it used to be a very simple signal to transmit and receive.

The bioelectric signals received now are very complex, and the brain has not yet adapted to this neural channel, and even if it actively gives a command, it will not transmit signals through this neural channel.

It is for these combined reasons that everyone has a different time to adapt to this technology.

After many experiments, Lu Qinling can make the intelligent robot start to walk right.

Officially developed advanced human-computer intelligent interaction technology, which can convey the commands of the human brain to intelligent devices in real time.