bookbashuk Chapter 400 Primary AI System
Chapter 400 Primary AI System
In Li Yang's memory, the origin of AI intelligence can be traced back to the "Dartmouth Conference" in the 20s.
At that conference, several computer scientists proposed the concept of "artificial intelligence" and discussed how to make computers simulate human thinking processes.
Although AI at that time could only handle some simple logical problems, it laid the foundation for the subsequent development of artificial intelligence.
Li Yang combined the knowledge in his memory with the current level of technology and conceived an AI development framework suitable for the current situation.
He decided to start with the most basic logical reasoning and simple decision-making systems, and gradually expand the capabilities of AI.
First, he needs to design a simple neural network structure for the AI system, which will be the basis of AI intelligence.
Li Yang's eyes gradually became focused. He knew that the design of a neural network was the first step in the development of artificial intelligence.
Although the concept of neural networks was still unknown in this era, Li Yang already had a clear understanding of this structure thanks to his future memories.
He opened a set of software specifically used to simulate neural networks on his computer. This is a tool software he wrote himself that can simulate the operation of neural networks to a certain extent.
Li Yang's fingers tapped quickly on the keyboard, and nodes and connections began to appear on the screen. These nodes simulated the functions of neurons, while the connections were the "synapses" of the neural network.
"The initial AI intelligence does not need to be too complex," Li Yang whispered to himself, "As long as it can handle basic logical problems and has simple learning capabilities, it can play a role in combat."
As the program was continuously optimized, Li Yang gradually added more functions to this primary AI system. He designed a simple environment simulation program to allow the AI to conduct "battle" drills in a virtual environment. The AI needs to make decisions based on the battlefield situation and gradually adjust its strategy.
"Begin the test." Li Yang hit the Enter key, and the AI intelligent system began to operate in the virtual battlefield. The graphics on the screen kept changing, showing the decision-making process of the AI system.
The AI system reacts very quickly and can analyze battlefield situations and make corresponding tactical adjustments in a very short time. Li Yang saw that the AI system successfully avoided the enemy's attack and hit the target through complex maneuvers.
"Yes, the initial functions of AI are already available." Li Yang showed a satisfied smile on his face. Although this was just a simple simulation, he knew that as long as it continued to be optimized, this AI system would play a huge role in future actual combat.
After the initial success of the AI system development, Li Yang began to integrate it with other systems of the fighter. The intelligent combat system is not just a separate application of AI intelligence, it needs to be closely integrated with the flight control system, weapon system, and electronic system to form a complete combat system.
Li Yang designed a complex data exchange protocol that allows the AI system to receive data from various sensors in real time and adjust the fighter's flight attitude and weapon configuration based on this data. At the same time, the AI system also needs to cooperate with the electronic system to ensure that it can maintain stable communication and navigation capabilities under enemy electronic interference.
"All modules have been connected and are ready for system testing." Li Yang gave instructions to team members via radio.
In the laboratory, engineers quickly took action and various instruments and equipment began to operate. Li Yang stood in front of the console, staring at the data flow on the screen. The intelligent combat system began to start, and the AI system began to receive data from sensors and adjust the fighter's posture through the flight control system.
"The aiming system is normal and the target is locked," an engineer reported.
"The weapon system is ready and the laser weapon is fully charged." Another engineer reported immediately.
"Start attacking the simulated target." Li Yang gave the order.
The laser beam instantly shot out from the fighter's launcher and hit the simulated target in the distance. At the same time, the AI system quickly calculated the best attack angle and adjusted the attack route in a very short time. The target was accurately hit and instantly destroyed by the laser beam.
"The intelligent combat system is running normally, and the attack accuracy and reaction speed have reached the expected goals." Li Yang showed a satisfied smile on his face. He knew that the success of this system meant that the aerospace fighter was not only an aircraft, but also an intelligent combat machine.
Next, Li Yang turned his attention to the fighter's survival system.
As a fighter jet capable of performing missions in space, the design of a survival system is crucial. It not only ensures the safety of the pilot's life in space, but also provides the necessary energy, oxygen and temperature regulation for the fighter jet.
The first thing Li Yang considered was the oxygen supply system. He decided to equip the fighter with a small oxygen generator, which could provide fresh oxygen to the cabin during flight by electrolyzing water. Li Yang marked the location of the oxygen generator and the pipeline layout in detail on the design drawing.
Next is the temperature control system. The environment in space is extremely complex, and the temperature changes dramatically. The temperature inside the fighter must be kept stable. Li Yang decided to install a layer of special thermal insulation material on the surface of the fighter's fuselage. This material can effectively reflect the radiant heat in space and reduce the heat loss inside the fighter.
Li Yang outlined the coverage of the thermal insulation material on the drawing and designed a complex temperature regulation system, which can automatically adjust the temperature in the cabin through a heat exchanger to ensure that the pilots can maintain the best condition in various environments.
"The oxygen supply system and temperature control system have been designed. The next step is the integration of the energy system." Li Yang said to himself.
As an aerospace fighter, the design of the energy system is crucial. Li Yang decided to equip the fighter with a small energy reactor based on nuclear fusion technology, which can not only provide sufficient energy for the weapon system, but also provide a stable energy supply for the survival system.
Li Yang marked in detail the connection between the energy reactor and the survival system on the drawing, and designed a complex energy regulation system. This system can automatically adjust the energy distribution according to the flight status of the fighter, ensuring that each system can obtain sufficient energy when needed.
"All components have been installed and we are ready to test the survival system." Li Yang gave instructions to the team members via radio.
In the laboratory, the staff began to conduct various tests in an intense and orderly manner. The oxygen generator began to operate, and the oxygen concentration in the cabin gradually increased. The temperature control system started, and the temperature in the cabin was kept within a stable range.
"The oxygen supply system is normal and the oxygen concentration meets the standard." an engineer reported.
"The temperature control system is normal and the temperature in the cabin is stable." Another engineer reported shortly afterwards.
Li Yang felt relieved. The smooth operation of the survival system meant that this aerospace fighter had the ability to carry out long-term missions in space.
Although the intelligent combat system has achieved initial success, Li Yang knows that this is far from enough. He decided to further optimize the AI system to enable it to have higher autonomous learning ability and tactical decision-making ability.
Li Yang stood in the center of the laboratory with a determined look. He knew that the development of AI intelligence was not only a technological breakthrough, but also a challenge to human wisdom. In order to enable the AI system to have a higher level of autonomous decision-making ability, Li Yang decided to introduce reinforcement learning algorithms.
Reinforcement learning is a learning method based on trial and error. By constantly trying in the environment, the AI system can gradually optimize its strategy and eventually reach the optimal solution. Li Yang opened the reinforcement learning algorithm program on the computer and began to train the AI system.
"We need to design a more complex training environment for the AI system," Li Yang said to his assistants.
In the laboratory, staff began to build a simulated battlefield, which is more complex than the previous training environment and contains a variety of terrains, obstacles and enemy targets. The AI system will conduct autonomous learning in this environment and gradually optimize its own tactics.
"Start training." Li Yang hit the enter key.
The AI system began to operate in the simulated battlefield, and the screen showed the decision-making process of the AI system. The AI system first tried some simple tactics, but soon found that these tactics did not work in a complex environment. So the AI system began to adjust its strategy and try different ways of attack and defense.
Li Yang saw that as the training progressed, the AI system's tactics gradually became more flexible and complex. The system began to use the terrain for cover, used obstacles to avoid enemy attacks, and quickly approached the target through complex maneuvers.
"The AI system learns very quickly and is already able to make effective tactical decisions in complex environments," an engineer said excitedly.
A satisfied smile appeared on Li Yang's face. He knew that the reinforcement learning ability of the AI system would enable aerospace fighters to have higher autonomous combat capabilities on future battlefields.
While the optimization of the AI system has made progress, Li Yang decided to integrate the electronic countermeasure system with the intelligent combat system. The electronic countermeasure system is an important guarantee for the survival of fighters on the battlefield. It can maintain stable communication and navigation capabilities under the enemy's strong electromagnetic interference, and can also interfere with the enemy's radar and missile guidance system.
Li Yang designed a complex electronic countermeasure system on the blueprint. This system includes a high-performance electronic countermeasure processor that can analyze the enemy's electromagnetic signals in real time and select the best interference method based on the signal characteristics. Li Yang also designed a multi-band interference transmission system that can transmit interference signals in a wide frequency range.
"The design of the electronic countermeasure system has been completed and we are ready for system integration," Li Yang said to his assistants.
Inside the lab, staff began integrating the electronic countermeasures system with the intelligent combat system. Li Yang personally supervised each wiring point to ensure that all connections were secure and reliable. Finally, the system integration was complete and Li Yang was ready for the first test.
"Activate the electronic countermeasure system." Li Yang gave the order.