It's just that Duke no longer cares about all these business operations in the future, this kind of thing is not what he is good at, just leave it to Cai Siqiang to handle, there is no need to intervene again.

Now there are still many R&D tasks in front of him, the core part of the miniaturization work of the lotus pile has been basically completed, and the rest of the things are left to Professor Zhu's team to do, and Duke only needs to check the progress and R&D direction from time to time to see if there are any problems.

But Mr. Liu's second problem is not so lucky, a lot of things have to start from scratch, Duke only has to discuss and track progress with the project team often, if it weren't for Kerry's very strong simulation ability, can give what is important and what is not important, which makes the research and development has not been a big deviation, without these guidelines, the whole project team does not know how many detours to take in the middle to touch the right path.

It is not easy to obtain a variety of key parameters that affect the operation of high-speed objects through various monitoring instruments, not only need to improve the method, but also need to update or purchase new monitoring equipment for the detection of some parameters.

Fortunately, the direction is now clear, and the progress of the project team is still quite satisfactory after the expansion of many sub-projects.

After several months of continuous improvement, after improving the monitoring parameters and monitoring accuracy, Duke's improved model now has a prediction deviation of several meters for high-speed moving objects such as missiles with fixed trajectories, which is much more regular than human-controlled objects such as airplanes.

After Duque used the military's data from the measured data of a variety of missiles and the actual operation of various major missile trajectories in the world provided by the military, the new model derived by Kerry simulation suddenly improved the prediction accuracy to the point of practicality, and the error between the missile trajectory predicted in real time and the actual trajectory was only a few meters.

If applied to the antimissile system, the success rate of interception by using a single-launch anti-missile in simulated applications is almost 70 percent, and the success rate of interception with two to three antimissiles can almost reach a high probability of more than 99 percent.

The progress of this achievement alone was extremely gratifying to Mr. Liu, who received the news, because when this achievement was transformed into an actual system, the combat effectiveness of the military's missile system immediately soared by a large margin.

It can predict the trajectory of the opponent's missile, predict the range of its landing point when the opponent's missile hits, assess its danger, and then judge whether it needs to be intercepted according to the danger, whether it is a single interception or multiple interceptions, and the number of missiles in the antimissile system is limited.

More importantly, Duke made public the mathematical modeling process and algorithms he derived from simulations, so that military researchers can continuously improve the prediction accuracy of the prediction model in the future with more data on the actual trajectory of the missile and related parameters.

When this algorithm was announced, it took a long time for the military's mathematicians, who are highly accomplished in mathematics, to figure it out, because if this modeling process and algorithm were published, it would be a world-class new achievement in the field of mathematics.

Of course, this is now one of the most core secrets of the military, and no one will try to publish it as a paper in a false name. Therefore, this achievement is destined to be unknown for a long time. Due to the massive computing performance support required for simulation operations, Duke developed a distributed computing application to run the new simulation algorithm by using the Nuwa 1.0 system, the first truly independent operating system in China, to run this new simulation algorithm, with the cooperation of four 4 16-core CPU boards, and the response time of the entire prediction system was increased to less than one second after various parameters were inputted.

This astonishing reaction speed means that even if a short-range attack missile is launched from an aircraft, the system has the ability to quickly locate and predict its trajectory, so that it can guide its own anti-missile to intercept.

At the same time, this fast response speed shows that the system also has the ability to track more targets at the same time, according to Duke's design, as long as the monitoring system is powerful and provides more target parameters, a single system tracking 16 to 32 high-speed targets is not a big problem.

For moving targets such as airplanes and tanks controlled by people, it is not possible to predict the long-term trajectory like missiles, but only to predict a small trajectory in a short-term range where the moving object has to run by inertia. That is, there are often only traces in a few seconds.

For an ordinary weapon response system, nothing can be done in such a short time, but if it is a missile attack system with a high-speed response, a few seconds and more than ten seconds are enough to destroy the opponent.

It would be nice if this system was used for auxiliary attacks in the fire control system.

Duke, who returned to the front line of R&D, immediately burst out with unimaginable light, leading the project team to make new progress one after another. While most of these things are breakthroughs in analog applications and are still a long way from being truly practical, it is only a matter of time before they are turned into practical systems.

After getting these key things done, Duke was relieved, although there was still a lot of work left, but it was basically a lot of grinding work, and the project team was enough to complete the rest of the work.

That way, Duke can get back to his work.

Because, after many activities, the Titan II supercomputer system that Duke sought to buy, finally came the good news, if the installation and use place is in Luxembourg or the Maldives, Cray can successfully obtain the export approval of Uncle Sam.

With such a result, Duke of course chose the Maldives as its second base, and now that Duke International has taken root there, Dong Feng and the politicians of the Maldivian authorities who tend to take the pragmatic line are now fighting hotly, and the factory that produces the key parts of the Lotus Reactor nuclear power plant has begun to enter the test stage and will soon be able to put into production.

At that time, Duche International will have an annual production capacity of 5 to 8 core components of commercial Lotus reactor nuclear power plants in the Maldives, because it is only a part of the production of nuclear power plant accessories, and has not triggered the domestic policy of denuclearization of the Maldives, plus these things Dooche International will be worth hundreds of millions of dollars for exports, bringing considerable tax revenue to the Maldives authorities, plus other infrastructure investment has also been in place, so Duche International has played a pivotal role in the Maldives.

The location of Duke's supercomputing center here is, of course, good news for the Maldivian authorities.