After an introduction video, Wu Hao, who took a sip of water and rested for a while, continued: "What I introduced earlier is mainly the application of this hexagonal honeycomb compound lens in civilian digital products. In fact, it has a wide range of applications.

For example, our common astronomical telescopes, especially optical imaging telescopes, are limited by the size of the lens, and it is difficult for us to continue to expand them.

Now, with this technology, we can assemble countless hexahedral lenses into a larger lens according to the honeycomb structure, so as to obtain better imaging quality astronomical images, which is very helpful for us to study deep space.

Secondly, this hexagonal honeycomb compound lens can also be applied to the field of onlookers, so as to obtain a clearer microscopic image. ”

"This is just a routine application, and we can also implement synthetic hexagonal honeycomb compound lenses with a variety of imaging functions.

For example, we add infrared, thermal imaging and other functions to the hexagonal honeycomb compound lens to apply it to some complex and special fields.

In addition, compound lenses have a natural advantage in that they have a strong depth-of-field effect.

This means that it can be used in more areas of discovery, such as optical sensors on robots, which are our eyes.

And this super depth of field effect can also be used for the shooting of 3D film and television dramas, and the 3D stereoscopic effect presented is no worse than the current 3D camera.

In the future, we will continue to strengthen the in-depth research on this hexagonal honeycomb compound lens technology, and I believe that there will be more surprising results gradually displayed in front of you, let us look forward to it. ”

Speaking of this, Wu Hao breathed a long sigh of relief, and then smiled again and said: "This is our hexagonal honeycomb compound lens technology, thank you!" ”

After a burst of electronically synthesized applause, the scene began to change. This time, the space is white, a huge white space with a futuristic sense of technology.

Wu Hao reappeared at the scene, still sitting on the red chair.

As we all know, in the field of medical technology, our company has invested a lot of resources and obtained a number of fruitful technological achievements.

We are well known for our intelligent bionic electronic prosthetics, and through this technological achievement, we have enabled thousands of people with disabilities to return to normal lives.

I'm very proud of that, and it's something that my colleagues in the company have always been proud of.

We are really happy to see the bright smiles on the faces of so many people with disabilities who have returned to normal life, and this kind of harvest cannot be exchanged for no amount of money.

That's why we've increased our investment in medical technology. Despite the tremendous investment in this area, we are trying to persevere.

God rewards hard work, we are lucky, not long ago, we have another technical achievement, here is a little eager to share with you.

This technology is called a miniature multi-tentacle medical surgical robot.

Wu Hao's words fell, and he saw a floating octopus appear in the white space. The white octopus began to swim in the air, and then slowly levitated in front of Wu Hao, and turned into a mechanical octopus.

After we developed the intelligent robotic arm, we conducted in-depth research on this technology, hoping to make a breakthrough in this technology, apply it to more fields, and help more people.

This miniature multi-tentacle medical surgical robot is the latest type of medical surgical robot developed by borrowing the posture characteristics of the octopus in the technology of the intelligent robotic arm.

We all know that the trauma of surgery is generally very large, and for this reason, we invented minimally invasive surgery, but in fact, minimally invasive surgery is also very traumatic, and it generally takes three windows to achieve minimally invasive surgery.

And there are some surgeries that are not minimally invasive and require surgery. This is because minimally invasive surgery is limited by instruments and there are many conditions that cannot be adapted.

Therefore, after in-depth discussions and research with many surgical experts, our scientific research team decided to develop a miniature multi-tentacle medical surgical robot that can replace the current minimally invasive instruments.

In order to develop such a miniature multi-tentacle medical surgical robot, many problems must be solved.

The first one is small, the volume of this miniature multi-tentacle medical surgical robot must be small enough, only small can leave the smallest wound to the patient as much as possible during the operation, which is conducive to later recovery, and the pain brought to the patient is also minimal, and it is not easy to leave scars.

Therefore, we need to reduce the size of this miniature multi-tentacle medical surgical robot as much as possible. After repeated research, we felt that the octopus's body structure was the most suitable, so we conducted relevant observations and research, and assisted in the biomimetic design.

Octopus tentacles are very flexible, and our robots need to be as flexible as possible during surgery to accommodate different complex conditions.

So we had to re-equip the robotic arm, not just to make it smaller, but also flexible enough.

It may seem like a simple matter of scaling it down, but it's actually very difficult. The original structure was difficult to shrink, which required a new design, which also brought many challenges.

IN THE END, WE SUCCEEDED IN SHRINKING THE INTELLIGENT ROBOTIC ARM TO 43 MM AND 3.5 MM IN DIAMETER. On such a miniature intelligent robotic arm, we have set up a total of five joints, which is very flexible.

THEN, WE INSTALLED THESE TINY TENTACLES ON A 17MM DIAMETER TERMINAL, WHICH IS CALLED THE 'HEAD OF AN OCTOPUS'.

And on this 'octopus head', we equipped a total of four pairs of eight tentacles, and truly became an octopus.

ON THE TERMINAL END, IT IS CONNECTED TO THIS 15MM PIPELINE.

Through this pipeline, it can be connected to our control equipment.

As for the control equipment, it is also very simple, we use our intelligent VR system, which can get a very clear view through the micro high-definition camera in the middle of the tentacle.

Then, with the smart sensor gloves, we can control these mechanical tentacles very flexibly and perform related surgeries.

And with our intelligent voice assistant, a single doctor can control all the tentacles and then perform a complex surgical operation.

In addition, these four pairs of eight tentacles can also be controlled by four people separately to facilitate some very complex surgeries.

And with our intelligent voice assistant, a single doctor can control all the tentacles and then perform a complex surgical operation.

In addition, these four pairs of eight tentacles can also be controlled by four people separately to facilitate some very complex surgeries.

vertex