"The range covered by F-rays is large enough!"
"If the built-in energy intensity is higher, the coverage area will be larger, and low-orbit satellites will be within range."
"Now the accuracy is guaranteed..."
Liao Jianguo's voice was full of expectation.
Wang Hao nodded and affirmed the results of the F-ray team, but raised his own doubts about the 'satellite weapons' mentioned by Liao Jianguo, "The coverage is indeed very high, but when it comes to satellite weapons, if a satellite passes overhead, you
Are you sure it can be hit with F-rays?"
"this……"
Liao Jianguo suddenly felt a little embarrassed. He said, "It still requires the cooperation of a large radar base station. We will definitely not be able to target it alone."
"Now that radar technology is so high-end, the electronic system may not be able to keep up, right?"
"I think should not be……"
Liao Jianguo said a little depressed. Of course, he knew very well that the so-called "satellite weapons" could only be realized in theory.
There are still many problems, the most critical ones lie in radar and electronic systems.
The coverage range of F-rays exceeds 300 kilometers, but that does not mean that they can hit satellites at an altitude of 300 kilometers.
Being able to cover and being able to hit are two levels of concepts.
This is just like launching a missile. The warhead of a high-end missile is often equipped with an electronic system for tracking performance. However, the missile does not directly hit the target, but has a deviation range.
F-rays have much higher requirements than missiles.
The missile explosion covers a large range. As long as the deviation range is smaller than the explosion coverage, the missile can be said to be very accurate.
The target of F-ray is only one point, and even a slight deviation will have no effect. It is too difficult to hit satellites in the sky.
This is mainly because radar and electronic systems can't keep up.
The most advanced radar system in the country now is called phased array radar. It is a huge radar base station specially used to monitor satellites with an altitude of more than 100 kilometers. It can be used to track a large number of low-orbit satellites and improve the space monitoring system.
Phased array radar, public data can only detect satellites over 100 kilometers away. To understand it from another perspective, it is difficult to monitor satellites over 100 kilometers away.
In addition, monitoring is just monitoring.
From monitoring, tracking, calculating the trajectory, to reacting to the electronic system, and instantly emitting F-rays, even if there is a slight deviation in the entire process, it is impossible to directly hit the satellite.
This is mainly because the satellite's target is too small and its speed is too fast.
If a satellite wants to revolve around the earth, it must first break through the first cosmic speed. Conventional satellites can travel more than 8 kilometers per second.
Therefore, even if there is only a deviation of 0.01 seconds, the deviation distance can reach several hundred meters by the time it reaches space.
There is also missile technology that can hit satellites, but the entire operation system is very complicated. First, monitoring satellites in space are needed to track. Only by continuously tracking the target can the trajectory be accurately calculated.
In addition, the launched missiles must also have an electronic system to lock on to the target.
In other words, after the missile reaches space, it will turn on the electronic system and then run the power system to correct the trajectory to hit the target.
"It's really difficult to hit the satellite accurately." After the two talked about technology for a while, Liao Jianguo said with a sigh.
Wang Haodao, "Don't be discouraged, we have been researching new technologies."
"It is true that current radar technology cannot accurately track satellites in the sky from the ground, but the technology is constantly improving."
"First-order waves have stronger speed and penetration. If the first-order wave radar technology can be improved, radar technology will be greatly improved."
"At that time, coupled with the electronic system, F-rays can really be used as a 'satellite weapon'."
Liao Jianguo pursed his lips hard and sighed, "I hope so."
…
In terms of military technology, radar technology has been lagging behind.
Air-to-ship series aircraft are limited by the level of radar technology. After turning on the invisible shield, they can only guarantee the most basic communication functions.
F-rays, used as satellite weapons, are also limited by radar technology.
The same is true in other fields.
No matter how powerful a weapon is, it must be able to hit the target to be a deterrent, otherwise it will be useless.
Therefore, the research of Shen Huiming's team has received attention from many aspects.
The research of Shen Huiming's team went very smoothly. Using a large number of new materials provided by the annihilation force field experimental group, they quickly perfected the first-order wave receiving technology.
The release of this technology will definitely cause an international shock.
First-order waves are not something that can only be actively created. The astrophysical content of annihilation theory believes that there are a large number of higher-order waves in the universe.
For example, black holes and other stars with strong annihilation fields are constantly releasing high-order electromagnetic waves and cosmic rays.
The reason why humans have not discovered first-order waves is because they have not mastered the relevant technology. If we have this technology, we can build large-scale first-order wave receiving radars and continuously receive first-order wave signals from the universe. By then, astronomy will
In the physical direction, there may be a huge breakthrough, which will help mankind understand the universe more clearly, and also help the annihilation theory gain a firm foothold in astronomy and physics.
However, technologies involving military applications will certainly not be made public easily.
Wang Hao focuses on the creation of first-order waves. They have two manufacturing methods. One is excitation radiation, which is also the first method developed.
The other is to use the reflective properties of ‘brown gold’.
'Brown gold' has been studied since it was produced. At first, it was discovered that it reflects first-order light waves, and later it was discovered that reflecting first-order waves also has limitations.
For example, high-frequency waves and low-frequency waves cannot be reflected.
"This is most likely due to an energy issue."
"Reflected waves exist in frequency ranges. We have experimented many times. Whether it is a high-frequency wave or a low-frequency wave, most of the energy is directly absorbed, and the amount of reflection is very small. It is not a first-order wave."
This chapter is not finished yet, please click on the next page to continue reading the exciting content! "It may be related to the internal atomic characteristics."
Shen Huiming said, "However, we have done very little research on atoms and can only make simple speculations. Now we are using other methods to test whether brown gold can be used to create radio waves."
After hearing this, Wang Hao nodded and said, "It is also related to environmental factors. In a strong annihilation field environment, using ordinary first-order materials and conventional means can create first-order waves."
"Your research is in a normal environment, a normal environment, and what is naturally produced is a normal wave."
"It's just that the annihilation field environment is too limiting."
Shen Huiming shook his head and said, "We can only do research in a conventional environment. The next step is to conduct various experiments. We have many directions, but this research is a bit hit and miss."
"Yeah, try your luck!"
Wang Hao sighed as he spoke. He didn't like luck-based research.
Such research may not necessarily lead to results, but the current problem is that the research on one-section wave generation technology has no theoretical support and cannot even find the direction, so we can only continue to make experimental attempts.
He stayed in the experimental group for a few days and then returned to Xihai University.
Ding Zhiqiang is back.
Ding Zhiqiang has been responsible for the work of nuclear engineering projects. He represents the Antigravity Behavior Research Center and the Annihilation Force Field Experiment Group. He is responsible for docking dense material technology. He also leads a research team to study "the impact of strong annihilation force field thin layers on materials."
question".
This is very important content.
The thin layer of strong annihilation force field inside the nuclear fusion equipment always exists, and it exists inside the material, and it will definitely continue to affect the material.
So whether a thin layer of strong annihilation force field will affect the performance and life of the material is also a very important research content.
Ding Zhiqiang has done a good job.
They continued to conduct demonstrations and research from a theoretical and experimental perspective, and also improved the compression-resistant material technology. The general method is to add a layer of first-order a-iron alloy material inside the material. The specificity of a-iron will produce an anti-magnetization effect.
It will reduce the impact of strong annihilation force fields on compression-resistant materials.
After Wang Hao found Ding Zhiqiang, he listened to him give a work report alone, and then gave him affirmation and praise, "Well done!"
"You've been busy for a long time."
"Let's take a rest during this period..."
"Um!"
Ding Zhiqiang smiled and nodded vigorously.
His plan was also like this. After finally leaving the nuclear engineering project team and returning to Xihai University, he naturally wanted to take some more rest.
To be continued...