But Duke no longer cared about all the business operations in the future. This kind of thing is not something he is good at. Just leave it to Cai Siqiang to handle it. There is no need to interfere again.

There are still many R&D tasks in front of him now. The core part of the miniaturization of the Lotus Duplex has been basically completed. Just leave the rest to Professor Zhu's team. Duke only needs to check whether there are any problems with the progress and R&D direction from time to time.

However, the second problem that Mr. Liu asked was not so lucky. Many things had to start from scratch. Duke could only discuss and track progress with the project team frequently. If Kerry had not had very strong simulation capabilities, he could give out what was important and what was not important. This has caused no major deviations in R&D. Without these guidance, the entire project team would not know how many detours they would take in the middle to find the correct path.

Even so, 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 does it require improvement in methods, but the detection of some parameters even requires updates or procurement of new monitoring equipment.

Fortunately, the direction is clear now. After the project team expanded many sub-projects, the progress was quite satisfactory.

After several months of continuous improvement, after improving monitoring parameters and monitoring accuracy, soon Duke's improved model predicted deviations for high-speed moving objects such as missiles with fixed trajectories have now reached a range of several meters. This thing has a much more regular trajectory change than those of objects such as takeoff aircraft and humans.

After Duke used the military to use the actual operation graphical image data of various missiles through various mainstream missiles in the world provided by the military, the new model derived by Kerry simulation suddenly increased the prediction accuracy to a practical level. The error between the missile trajectory predicted through real-time is only a few meters.

An error of several meters is nothing to a missile. If applied to anti-missile systems, the success rate of single-engine anti-missile interception in simulation applications is almost 70%, while the interception formed by two to three-engine anti-missiles can almost reach more than 99%.

The progress of this achievement alone made Mr. Liu, who received the news, very pleased, because when this result was transformed into a practical system, the combat effectiveness of the military's missile-generating system immediately soared significantly.

It can predict the trajectory of the opponent's missile. When the opponent's missile comes, it can predict its landing range and evaluate its danger. Then, based on the danger, determine whether it is an interception or multiple interception. The number of missiles in the anti-missile system is limited. If the random interception is ignored, it will cause the truly dangerous and huge attack to be missed due to insufficient anti-missile missiles.

More importantly, Duke disclosed his simulation and derivation mathematical modeling process and algorithms, so that military researchers can continuously improve the prediction accuracy of the prediction model when obtaining more actual missile operation trajectory data and related parameters.

After the algorithm was published, mathematicians with deep mathematical skills in the military studied it for a long time before they figured it out, because if the modeling process and algorithm were published, it would be a world-class new achievement in the mathematics community.

Of course, this is one of the most core secrets of the military now, and no one will use the virtual name to publish it as a paper. Therefore, this result is destined to be unknown for a long time. Since simulation operations require massive computing performance support, Duke used the latest research of China's first truly independent operating system, Nuwa 1.0 system, to develop a distributed computing application to run this new simulation algorithm. With the cooperation of 4 blocks and 4 16-core CPU boards, the entire prediction system's reaction time has been increased to within one second after inputting various parameters.

This amazing reaction speed, that is, even the short-range attack missiles launched on the aircraft, have the ability to quickly locate and predict its operating trajectory, so as to guide its anti-missiles to intercept.

At the same time, this fast reaction 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 more target parameters are provided, it is not a big problem for a single system to track 16 to 32 high-speed targets.

For mobile targets such as aircraft and tanks controlled by humans, long-term operation trajectory predictions cannot be predicted like missiles, but can only predict a small trajectory in which moving objects have to operate inertia within a short period of time. In other words, trajectories often only have a few seconds.

For general weapon reaction systems, basically nothing can be done in such a short time, but if a missile attack system with high-speed reaction is used, a few seconds or ten seconds is enough to destroy the opponent.

If this system is used for auxiliary attacks in the fire control system, it would be really good.

Duke, who returned to the front line of R&D, immediately burst out with unimaginable light and led the project team to make new progress one after another. Although most of these things are breakthroughs in simulation applications and are still a long way from a real practical system, with such results in advance, it is only a matter of time to transform these results into practical systems.

After finishing these key things, Duke was relieved. Although there was still a lot of work left, it was basically water grinding skills, and the project team was enough to complete the remaining work.

In this way, Duke can go back and do his job.

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

With such a result, Duke of course chose the Maldives as his second base. Now Dushi International has taken root there. Dong Feng and the Maldives who tend to take the pragmatism route are now fighting fiercely. The factory that produces key accessories for the Lotus Release Nuclear Power Plant has begun to enter the test run stage and will be able to start production soon.

By then, Dushi International will have the capacity to produce core accessories for 5 to 8 commercial lotus reactor nuclear power plants in the Maldives at an annual output. Since it is only part of the accessories for nuclear power plants, it will not trigger the domestic policy of denuclearization of the Maldives. In addition, Dushi International will be exported for hundreds of millions of US dollars, bringing considerable tax revenue to the Maldives authorities, and other infrastructure investments are in place, so Dushi International has already played an important role in the Maldives.

Duke's location of the supercomputing center here is of course another good news for the Maldives authorities.
Chapter completed!