GetRobo Blog English

 Professor Minoru Asada of Osaka University in Japan is a leader in the field of “Cognitive Developmental Robotics” which aims to understand the development of human intelligence through the use of robotics. He is well-known as the director of the JST ERATO Project on “Synergistic Intelligence.” (Think CB2 – which stands for Child robot with Biomimetic Body.)  Additionally important facts about him are that he is the vice director of The Japanese Society of Baby Science, an academic group of researchers studying infants, and is one of the founders of RoboCup.
 His goal is to understand humans through robotics and then utilize that knowledge to design a robot that can learn by itself. Now that the 5 year ERATO project is coming to a close this spring, GetRobo asked him about what he wants to do next. (The interview took place in San Francisco during Prof. Asada’s visit to the Bay Area in the end of Nov. 2010.)

Q. What are the achievements of the Asada ERATO project?
 
A. There are many but let me go over some of the highlights of the research done by the 4 groups involved in this project.
 First of all, Prof. Koh Hosoda’s group set out to prove that it’s not just the brain that is controlling human movements but that other parts of the body are computing as well. They developed robots that mimic a 7 month old and 13 month old baby using pneumatic muscle actuators and showed how the spine was playing an important role in controlling crawling.
 Prof. Yasuo Kuniyoshi’s group was able to show through computer simulation how a 25 week old fetus is able to learn about its body by moving its muscles and touching itself inside the womb. We think that in real life this helps the baby in organizing its movement right after birth.
 Plus, we now have constructive proof that a neonatal infant can obtain an image of his own face without any visual data but just through touching. This work was done by Prof. Toshio Inui’s group.
  Last but not least, and perhaps the best known outside of academia, is the research done using the CB2 (pronounced CB square) robot, which was developed by Prof. Hiroshi Ishiguro’s group. They taught CB2 how to stand with the help of a human pulling it up. Through this experiment they figured out how to determine whether an attempt to stand was successful or not so that CB2 can improve on its skill.
 The common thread in all these research is that we were able to move one step closer in understanding how we can develop a robot as close to a human being as possible.
 
Q. The CB2 was called “the creepiest robot ever.” What do you think about this?
 
A. We take it as praise because it probably means that the robot looks real. But it’s actually not as eerie as people think. When you actually see it, it’s rather cute. I know reporters who’ve come to see the robot and commented that it’s cuter than they had thought. The photos and video don’t do justice to it. 
 
Q. What are the future plans for CB2?
 
A. Initially we had planned to use it long-term and to integrate the functions that were developed with other platforms, but unfortunately due to some hardware problems, we haven’t been able to do that yet.
 
Q. So what’s next?
 
A. So far we’ve developed 7 robotic baby platforms. The neonatal M3-Neony, Nana-chan (7 month old infant), Noby (9 month), Hitomi-chan (13 month), CB2 (1.5 years old), M3-Kindy (5 years) and M3-Synchy (5 years). We’ve used each platform to conduct research on each stage of a human’s life.  
Next at my lab, we would like to develop a new platform that can be used to do research spanning all these stages. I want to find out about the principle of how humans start to perceive self from others and the mechanism of social development.

 The new platform is named Affetto. Affetto can show various emotional expressions and therefore make it possible for human caregivers to interact with it naturally. This is very important to model the early social development of humans.
 
Q. I read that you are planning to sell the M3-Neony and M3-Synchy platforms. How much are they going to cost and who do you think will be interested in purchasing them?
 
A. M3-Neony will cost 3 million yen and the M3-Synchy 800,000 yen and they will be sold by Vstone. Vstone is planning to develop the necessary software in about a year. Our intention is that cognitive scientists and psychologists will find them useful.    
 Currently, we are conducting a joint research where we are having children with Asperger’s disorder play with the M3-Synchy.
 
Q. When do you think that a self-learning robot will become true?
 
A. That’s a hard question to answer since it depends on what you want the robot to learn. For example, if we suppose that the learning target is vowel imitation, to a certain extent it’s already possible by preparing the right environment.
 But in a real life situation, the robot must deal with various kinds of issues, including the complexity in processing auditory, vision and other sensory information. The many degrees of freedom that the humanoid robots have make the problem even harder. Cognitive functions are inseparable from these sensori-motor issues. 
 Having said that, my hope is that our quest for the design principle of cognitive development will enable us to realize general self-learning robots in 10 years. 

 Hisashi Ishihara, Yuichiro Yoshikawa and Prof. Minoru Asada of Osaka University in Japan have developed a new child robot platform called Affetto. Affetto can make realistic facial expressions so that humans can interact with it in a more natural way.

 Prof. Asada is the leader of the JST ERATO Asada Project that has been working on "Cognitive Developmental Robotics" which aims to understand the development of human intelligence through the use of robotics. (Learn more about the research that led to Affetto through this interview with Prof. Asada.)

 Affetto is modeled after a 1-2 year old child and will be used to study the early stages of humans' social development. There have been earlier attempts to study the interaction between child robots and people and how that relates to social development, but the lack of realistic child appearance and facial expressions hindered caregivers to attend to it in a more natural way.

 The paper describing the development of Affetto's head was published and presented at the 28th Annual Conference of the Robotics Society of Japan.

 You can see the mechatronics inside Affetto, which probably should not be shown to the caregiver before any interaction or EVER.

 Here are some of the expressions that Affetto can make to share it's emotions with the caregiver.

 GetRobo is in Nashville covering the Humanoids 2010 conference where researchers from around the world presented papers about the latest in robots that look and/or behave like humans.

 Here, James Kuffner, Adjunct Associate Professor at Carnegie Mellon University and currently working full-time as part of the team developing the driveless car project at Google, made a new proposal to the community - Cloud Robotics.

 To quickly summarize his talk: 

 What is Cloud Robotics? Cloud Robotics is cloud computing applied to robots.  Just like thin clients, robots don't need to carry around all the information nor the computing power that they need to perceive the world and make decisions to move around if they can access them when neccessary. 

Why Cloud Robotics? Here's another slide that explains it all.

 
 To  give you a little background about where James is coming from, he spent 15 years in academia working on humanoid motion planning. (He and Rosen Diankov developed OpenRAVE.) So James' knowledge and expertise in this area went into making reliable cars drive themselves in traffic.

 One of the things that the team at Google was able to leverage to realize the self-driving car was its cloud infrastructure which is used to process all the data involved. That made James and some of his colleagues at Google start thinking about how the cloud can benefit robotics.

 Check out Google Goggles to take a glimpse of what may be possible in the future. With Google Goggles you can upload a photograph and search the web for similar images. Potentially a robot can upload an image of the environment and search for ways to grasp that object, avoid that obstacle, etc. And moreover, all the robots - independent of platforms - may potentially be able to share that database.  

 Robotic researchers have been working on this line of idea for a while. For example, there is the Remote Brain developed by Prof. Masayuki Inaba at Tokyo University. And there are teleoperated robots where the human is acting as the remote brain.

 But now with all the computing power available and the increasing reliability of the mobile broadband network, this may become into something really big.

 The roboticists I talked to at the conference seemed to be enthusiastic about this idea, but it would be great if others can share their thoughts and comments on this new proposal. What do you think?

 If HRP-4 is the trim athlete, core is the hulk. Or part of it. Core is a huge pair-of-legs developed by the Future Robotics Technology Center (fuRo) at Chiba Institute of Technology in Japan. The legs are 2 meters long and weigh 230 kg. It can carry up to 100 kg (220 lb).

It is the first prototype of fuRo's Human Boardable Bipedal Robot Project.

 The main components, such as the motor (photo left) and impact absorption system (right), were developed at fuRo and the plan is to commercialize them so that people in the industry can use them to build their own systems.

Here are a couple of videos. The first is the walk. (Anyone think Avatar?) The second shows it doing a workout with a 100kg payload.

Well, 2 major robot announcements in 2 days. How better can it get?

 Just in from Kazumichi Moriyama who let us know via Twitter that the new humanoid robot HRP-4 will be sold to universities and research institutes for 26,000,000 yen - which today is a little over $300,000 with the yen still being high.

 HRP-4 - just annouced in Japan yesterday- was developed by Kawada Industries and AIST. Moriyama-san was at the press conference. Kawada plans to start selling HRP-4 worldwide starting January 2011 according to it's press release.

 You gotta see this video. It's amazing that this robot is  5 feet tall (151 cm) and weighs only 86 lb (39 kg).

 And it's interesting because the robot looks both male and female. Like when it makes the body-builder pose at around 1:12 in the video, it looks masculine. And at 2:22 when it puts it's right leg forward, it looks feminine. At least to me. I also realized that it has more degrees of freedom than myself when it reaches for it's back at 1:51. I can't do this because I am getting old and I have a frozen shoulder.

 Here is a longer video where you can see it following faces and a pink ball in the end.

 Are we getting closer to this?