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It's started: Robot Uprising Begins as China Turns to Machines to Fill in Gaps in the Workforce

University unveils agile, low-cost robot gripper
2018-12-12 13:12:46

(ECNS) - A new low-cost robotic gripper, developed by the University of Science and Technology of China, is capable of handling a broad range of tasks demanding agility and precision.

The flexible device can hold items of various sizes and shapes — including apples, blocks of tofu, thin paper, and slippery bottles — then accurately transport them to a designated location.

Chen Xiaoping, the director of the university’s Robot Lab, said grippers are a key component of robotics used in services and intelligent manufacturing.

Similar products made abroad cost as much as one million yuan and their performance has been substandard, but the lab’s creation costs under 1,000 yuan ($145) after mass production, he said.

The lab is cooperating with a manufacturer — the name of which Chen did not disclose — to develop a robot used for elderly care that would apply the technology behind Kejia, an intelligent service robot designed by the university.

The new product is expected to hit the market in three years, Chen added.

The university’s research team began studies of smart robots in 1998 and has won 12 world firsts at the RoboCup.

 
China Focus: Exoskeleton robots closer to being easily accessed
Source: Xinhua| 2019-01-03 20:47:41|Editor: Liangyu


SHENZHEN, Jan. 3 (Xinhua) -- Zhao Yeyun suffers from lower-body paralysis and has been living with the help of wearable exoskeleton robots, although he cannot afford them.

A car accident damaged his spinal cord nine years ago. A year after his hospitalization, he was able to stand with the help of the first model of a wearable exoskeleton robot developed by Wu Xinyu and his research team in the Center for Intelligent and Biomimetic Systems under the Shenzhen Institute of Advanced Technology of the Chinese Academy of Sciences.

Since then, he has become a volunteer for testing the exoskeleton robots developed by the team based in the southern China city of Shenzhen.

Wu, the executive director of the center, has led the team to develop four types of exoskeleton robots with six different models, which have 38 national patents.

"The algorithm of the robot system controls sensors to read the wearer's movement intentions and send commands to the drive system. The bionic shape design of lower limb prosthesis is in accordance with the characteristics of the wearer's skeleton and joints," said Xu.

Volunteers like Zhao provide details on the effects of the robots.

With the assistance of an exoskeleton robot, Zhao can stand, walk and sit down on his own.

Zhao said the first time he tried on the robotic legs, they did not work. "The robotic legs are so heavy that I could not straighten up or lift my feet high enough," Zhao said.

Based on feedback from volunteers, the research team improved and updated the exoskeleton robot's physical design and control algorithm over and over again.

"In order to decrease the robot's weight, we use alloy and carbon fiber as a substitute material for steel," said Wu.

The weight of the robot models has declined from 25kg to 14kg.

He said that apart from being used in rehabilitation and medical treatment, exoskeleton robots can provide increased strength, security and working efficiency for workers in heavy machinery industries.

The team has developed a light flexible exoskeleton robot weighing 4 kg to enhance physical strength of wearers, and signed a letter of cooperative intent with the Commercial Aircraft Corp. of China Ltd. and the Hong Kong International Airport. "The exoskeleton robots help workers save energy and avoid muscle fatigue. In the future, we plan to develop wearable robots that can assist human beings in climbing, hiking and other activities," said Wu.

Zhao, from southwest China's Guangxi Zhuang Autonomous Region, said he could not afford such a robot priced at about 200,000 yuan (29,000 U.S. dollars) or more.

"I hope this technology can be industrialized as soon as possible, as mass production can make the robots more affordable," he said.

As one of the world's largest emerging markets of robotics, China has launched a development plan for the robot industry from 2016 to 2020, which encourages the mass production and application of service robots in rehabilitation, clinic treatment and other fields.

According to the International Federation of Robotics, China installed around 138,000 industrial robots last year, accounting for one-third of the global market and representing a 58-percent growth rate year on year. Robot sales are expected to reach 150,000 units in 2018.

Wu said a number of the world's most prestigious universities and institutions have applied to put their advancing robotics research into practice in China. The global market for exoskeleton robotics is estimated to exceed 1.8 billion U.S. dollars by 2020.
 
why dont china put president as robot military chiefs police as robots

I think the robots should not take over human job because humans are far better superior than these scraps who dont judge anything but work on given path
 
ubtech is getting better. two-legged robot walking without falling down is very hard to make. i always wonder how honda able to make asimo walking and running so fluidly many many years ago... they are so way ahead of everyone :D
 
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Two-legged robot developed by Chinese researchers can walk like a human
New China TV
Published on Jan 9, 2019

It's no easy job to teach a robot to walk in a human-like way. Chinese researchers have managed to do it. Check out this walking two-legged robot nicknamed "Xiao Bei."
 


A self-driving sweeper car is put into service at Inner Mongolia Normal University in Hohhot, north China's Inner Mongolia Autonomous Region, Jan. 9, 2019. (Xinhua/Ding Genhou)



A self-driving sweeper car is put into service at Inner Mongolia Normal University in Hohhot, north China's Inner Mongolia Autonomous Region, Jan. 9, 2019. (Xinhua/Ding Genhou)



A self-driving sweeper car is put into service at Inner Mongolia Normal University in Hohhot, north China's Inner Mongolia Autonomous Region, Jan. 9, 2019. (Xinhua/Ding Genhou)

http://www.china.org.cn/photos/2019-01/10/content_74358417_3.htm
 
New version of “Jueying” robot dog released | ZJU NEWSROOM
2018-12-19

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A new version of the four-legged “Jueying” robot was released on Dec. 4. The new “Jueying” robot, a small-sized quadruped robot that can handle 20 kg objects, is capable of running and climbing stairs.

The new “Jueying” robot is marked by a better ability to strike a balance while running and a greater capability of adapting to more complicated terrains, said one of the developers.

“Jueying” can issue an order every 0.5 millisecond, adapt quickly to the environment, give an order while it is on the verge of losing its balance and make adjustments with a series of fast-paced mobility.

At present, it has grasped a myriad of skills. It can run, jump, climb stairs, walk on gravel paths, and squat and stand up. Even supposing it falls down, it can automatically adjust its body position and rise to its feet again. It can fulfill multiple tasks and is thereby expected to be a powerful assistant in daily life. It can be used for security check and logistics. It can also replace human labor in various capricious environments. For instance, it can be used to detect life signals in earthquake-hit areas. In the exploration of space, barriers may well get in the way of a wheeled robot, but a quadruped robot can climb over it with great ease.

link to another video
 
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MIT-Silk-Actuators-01_0.jpg
The experimental setup used to study the behavior of spider dragline silk. The cylindrical chamber at center allowed for precise control of humidity while testing the contraction and twisting of the fiber.
Photo courtesy of the researchers


Spider silk could be used as robotic muscle
Unusual property of the ultrastrong material could be harnessed for twisting or pulling motions.

David L. Chandler | MIT News Office
March 1, 2019

Spider silk, already known as one of the strongest materials for its weight, turns out to have another unusual property that might lead to new kinds of artificial muscles or robotic actuators, researchers have found.

The resilient fibers, the team discovered, respond very strongly to changes in humidity. Above a certain level of relative humidity in the air, they suddenly contract and twist, exerting enough force to potentially be competitive with other materials being explored as actuators — devices that move to perform some activity such as controlling a valve.

The findings are being reported today in the journal Science Advances, in a paper by MIT Professor Markus Buehler, head of the Department of Civil and Environmental Engineering, along with former postdoc Anna Tarakanova and undergraduate student Claire Hsu at MIT; Dabiao Liu, an associate professor at Huazhong University of Science and Technology in Wuhan, China; and six others.

Researchers recently discovered a property of spider silk called supercontraction, in which the slender fibers can suddenly shrink in response to changes in moisture. The new finding is that not only do the threads contract, they also twist at the same time, providing a strong torsional force. “It’s a new phenomenon,” Buehler says.

“We found this by accident initially,” Liu says. “My colleagues and I wanted to study the influence of humidity on spider dragline silk.” To do so, they suspended a weight from the silk to make a kind of pendulum, and enclosed it in a chamber where they could control the relative humidity inside. “When we increased the humidity, the pendulum started to rotate. It was out of our expectation. It really shocked me.”

spider-silk.gif
The researchers were able to decode the molecular structure of the two main proteins, shown here, that make up spider dragline silk. One of these, MaSp2, contains proline, which interacts with water molecules to produce the newly discovered twisting motion.

The team tested a number of other materials, including human hair, but found no such twisting motions in the others they tried. But Liu said he started thinking right away that this phenomenon “might be used for artificial muscles.”

“This could be very interesting for the robotics community,” Buehler says, as a novel way of controlling certain kinds of sensors or control devices. “It’s very precise in how you can control these motions by controlling the humidity.”

“This is a fantastic discovery because the torsion measured in spider dragline silk is huge, a full circle every millimeter or so of length,” says Pupa Gilbert, a professor of physics, chemistry, and materials science at the University of Wisconsin at Madison, who was not involved in this work. Gilbert adds, “This is like a rope that twists and untwists itself depending on air humidity. The molecular mechanism leading to this outstanding performance can be harnessed to build humidity-driven soft robots or smart fabrics.”

Spider silk is already known for its exceptional strength-to-weight ratio, its flexibility, and its toughness, or resilience. A number of teams around the world are working to replicate these properties in a synthetic version of the protein-based fiber.

While the purpose of this twisting force, from the spider’s point of view, is unknown, researchers think the supercontraction in response to moisture may be a way to make sure a web is pulled tight in response to morning dew, perhaps protecting it from damage and maximizing its responsiveness to vibration for the spider to sense its prey.

“We haven’t found any biological significance” for the twisting motion, Buehler says. But through a combination of lab experiments and molecular modeling by computer, they have been able to determine how the twisting mechanism works. It turns out to be based on the folding of a particular kind of protein building block, called proline.

Investigating that underlying mechanism required detailed molecular modeling, which was carried out by Tarakanova and Hsu. “We tried to find a molecular mechanism for what our collaborators were finding in the lab,” Hsu explains. “And we actually found a potential mechanism,” based on the proline. They showed that with this particular proline structure in place, the twisting always occurred in the simulations, but without it there was no twisting.

“Spider dragline silk is a protein fiber,” Liu explains. “It’s made of two main proteins, called MaSp1 and MaSp2.” The proline, crucial to the twisting reaction, is found within MaSp2, and when water molecules interact with it they disrupt its hydrogen bonds in an asymmetrical way that causes the rotation. The rotation only goes in one direction, and it takes place at a threshold of about 70 percent relative humidity.

“The protein has a rotational symmetry built in,” Buehler says. And through its torsional force, it makes possible “a whole new class of materials.” Now that this property has been found, he suggests, maybe it can be replicated in a synthetic material. “Maybe we can make a new polymer material that would replicate this behavior,” Buehler says.

“Silk’s unique propensity to undergo supercontraction and exhibit a torsional behavior in response to external triggers such as humidity can be exploited to design responsive silk-based materials that can be precisely tuned at the nanoscale,” says Tarakanova, who is now an assistant professor at the University of Connecticut. “Potential applications are diverse: from humidity-driven soft robots and sensors, to smart textiles and green energy generators.”

It may also turn out that other natural materials exhibit this property, but if so this hasn’t been noticed. “This kind of twisting motion might be found in other materials that we haven’t looked at yet,” Buehler says. In addition to possible artificial muscles, the finding could also lead to precise sensors for humidity.

These researchers “have used silk’s known high sensitivity to humidity and demonstrated that it can also be used in an interesting way to create very precise torsional actuators,” says Yonggang Huang, a professor of civil and environmental engineering and mechanical engineering at Northwestern University, who was not involved in this work. “Using silk as a torsional actuator is a novel concept that could find applications in a variety of fields from electronics to biomedicine, for example, hygroscopic artificial muscles and humidity sensors,” he says.

Huang adds, “What is particularly noteworthy about this work is that it combines molecular modeling, experimental validation, and a deep understanding by which elementary changes in chemical bonding scale up into the macroscopic phenomena. This is very significant from a fundamental science point of view, and also exciting for applications.”

The work included collaborators at Huazhong University of Science and Technology and Hubei University, both in Wuhan, China, and Queen Mary University of London. It was supported by the National Natural Science Foundation of China, the National Science Foundation of Hubei Province, the Young Elite Scientist Sponsorship Program by CAST, the National Institutes of Health, the MIT Undergraduate Research Opportunities Program, and the Office of Naval Research.



Spider silk could be used as robotic muscle | MIT News

Dabiao Liu, Anna Tarakanova, Claire C. Hsu, Miao Yu, Shimin Zheng, Longteng Yu, Jie Liu, Yuming He, D. J. Dunstan and Markus J. Buehler. Spider dragline silk as torsional actuator driven by humidity. Science Advances (2019). DOI: 10.1126/sciadv.aau9183
 
Beijing tests ‘watchman’ robot
By Xu Keyue Source:Global Times Published: 2019/3/21 21:48:40

High-tech patrol uses facial recognition, thermal imagery
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Liu Gangjun, the project director at Beijing Aerospace Automatic Control Institute,controls the high-tech robot, named Meibao, in Beijing's Meiyuan residential community. Photo: Xu Keyue/GT

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Liu Gangjun, the project director at Beijing Aerospace Automatic Control Institute,controls the high-tech robot, named Meibao, in Beijing's Meiyuan residential community. Photo: Xu Keyue/GT


Imagine a robot moving around in neighborhoods to protect residents from safety risks in the dead of night.

The Meiyuan residential community in Beijing has adopted a robot that integrates facial recognition, man-machine communication and infrared thermal imagery for the first time to help protect the neighborhood.

Beijing Aerospace Automatic Control Institute (BAACI) developed the high-tech robot, named Meibao, to replace the human night patrol, with the support of the China Academy of Launch Vehicle Technology, an institute in China's space industry, Liu Gangjun, the project director at BAACI, told the Global Times on Thursday. Liu said the robot is being tested from December 2018 to April 2019.

Meibao stands 1.7 meters, with cameras as eyes and a big screen showing images on its chest, the Global Times reporter spotted Thursday.

The technology is a combination of biological recognition, big data analysis, inertial navigation system and other technologies, which can accurately process the information of pedestrians, according to information provided by BAACI.

Liu said the institute monitors and records neighborhood conditions.

If any suspects show up in the community, Meibao or similar high-tech door locks would recognize them and the alarm in the department would sound off, Liu said.

"I would be truly at peace with Meibao's presence," said a resident who seems surprised to have such an intelligent watchman.

Meibao not only monitors illegal activities but also provides useful information to residents. For example, it can provide weather forecasts and interesting stories, and even play music, which often attracts many children to talk with it, said Liu.

The institute has launched a project called "intelligent home" involving the robot, facial recognition door locks, digital annunciator board and smart watches designed to record senior citizens' health condition, Liu added.

The project has been welcomed by watchmen.

"I feel good that Meibao takes a part of the load off me," a watchman in the community told the Global Times on Thursday.

He also noted that human watchmen's security work was heavy, having to take turns patrolling the community the whole day.

In recent years, some districts in Beijing have adopted smart digital safeguards and convenient services for residents.
 
中国科研人员开发出“蚁群”微型机器人 :-)

Reconfigurable magnetic microrobot swarm


Paper Link:http://robotics.sciencemag.org/content/4/28/eaav8006

2019-03-23 15:20:31字号:A- A A+来源:新华社

新华社3月22日消息,中国科研人员日前开发出一种磁性微游动机器人,可像“蚁群”一样成千上万地组队协同作业,有望为高效靶向给药和体内成像提供解决方案。

发表在新一期美国《科学·机器人学》杂志上的这一研究显示,这种呈花生状的磁性机器人长3微米,直径2微米,只有头发丝直径的约四十分之一。由大量这种机器人组成的群体可在旋转磁场的调控下变为长链,在狭长的模拟毛细血管中穿行。

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多模转换和集体操作 图《科学·机器人学》

论文作者之一、哈尔滨工业大学机器人技术与系统国家重点实验室谢晖教授在接受新华社记者采访时说,这些机器人之间通过非常小的作用力交流,形成一个动态系统,就像蚁群用触觉或气味交流一样。

谢晖说,大自然中,群体协作可解决个体无法胜任的复杂问题,如蚁群可搬运超重猎物、鲱鱼群可捕获非常警觉的桡足类动物,研究人员受其启发,构建了微游动机器人群体,使其具备快速的环境应变能力和多任务机动功能。

研究显示,这些机器人能够模拟自然界的蚁群和鲱鱼捕食阵列,完成大负载可控输送与大面积同步集群操作。

谢晖说,这种机器人将来可用于医疗方面,比如通过体内导航控制,成千上万个装载药物的微游动机器人组成的群体可直达病灶部位,识别并攻击病变细胞,还有望留存在体内监控健康状况,从而为疾病的早期诊断与治疗提供新方法。
 
This Robotics Startup Wants to Be the Boston Dynamics of China
By Erico Guizzo
Posted 16 Oct 2017 | 21:15 GMT

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Photo: Unitree Robotics

Of all the legged robots built in labs all over the world, few inspire more awe and reverence than Boston Dynamics’ quadrupeds.

Chinese roboticist Xing Wang has long been a fan of BigDog, AlphaDog, Spot, SpotMini, and other robots that Boston Dynamics has famously introduced over the years. “Marc Raibert … is my idol,” Wang once told us about the founder and president of Boston Dynamics.

Now Wang, with funding from a Chinese angel investor, has founded his own robotics company, called Unitree Robotics and based in Hangzhou, outside Shanghai. Wang says his plan is making legged robots as popular and affordable as smartphones and drones.

Unitree’s first robot is a four-legged robodog called Laikago, which the company is announcing this week. (The name comes from Laika, the Soviet space dog, which Wang admires as a symbol of “human exploration of the unknown.”)

Laikago is designed as a research platform for scientists and roboticists, but Wang hopes science museums and robot enthusiasts may also want one. With further improvements, the robot could also be used in applications like package delivery, he says.

As a grad student at Shanghai University, Wang and his adviser, Jia Wenchuan, built a quadruped with 3-degrees-of-freedom legs that could walk forward, backward, and sideways, and also over rough terrain.

Boston Dynamics’ machines served as inspiration, but Wang wanted to “make quadruped robots simpler and smaller, so that they can help ordinary people with things like carrying objects or as companions,” he told us.

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Photo: Unitree Robotics
Xing Wang tests his robot’s ability to stabilize itself by kicking it, a tradition started by Boston Dynamics engineers.

For now Laikago can’t do much on its own. The robot is currently not autonomous and needs to be remotely operated, using a Wi-Fi-enabled controller. It doesn’t carry stereo cameras or lidar sensors, though users can easily integrate additonal modules, Wang says.

Unitree created the robot’s mechanical structure, control system, and motion control algorithms from scratch. It also designed custom motors, drivers, and force sensors for the robot.

Laikago will sell initially for between US $20,000 and $30,000, but Wang hopes to bring the price down with further refinements and higher volume.

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Photo: Unitree Robotics

Laikago is designed as a research platform but could also be used as a robot pet.
Of all “tricks” Laikago can do, Wang’s favorite is the robot’s ability to remain stable in uneven surfaces, or when kicked. He was surprised by some of the motions the robot did to stabilize itself, including motions he did not explicitly program the robot to do.

“The actual performance is surprisingly good,” Wang says of the robot’s control algorithms. “Math is wonderful.”



This Robotics Startup Wants to Be the Boston Dynamics of China - IEEE Spectrum
 
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