An Overview of Robotics

1. An Overview of Robotics JinxiangChai

2. Reminder • 11/22: Final Report draft: You are to turn in an initial draft of your paper. Feedback will be given. If this draft is satisfactory, then you do not need to do a revision • We have graded all of the first eight short reports. You can check your grades on elearning. • Two more presentations: - An overview of Robotics (today) - Guest lecture from Schlumberger (This Thursday)

3. What is A Robot?

4. What is A Robot? • “A reprogrammable, multifunctional manipulator designed to move material, parts, tools, or specialized devices through various programmed motions for the performance of a variety of tasks.“ Robot Institute of America, 1979 • “A physical agent that generates “intelligent” connection between perception and action” • “Where AI (Artificial Intelligence) meet the real world.” • “An automatic device that performs functions normally ascribed to humans or a machine in the form of a human.” Webster’s Dictionary

5. History of Robotics • 1921: The first reference to the word robot is made in a play by Czech writer Karel Capek (1890 - 1938) - R.U.R (Rossum's Universal Robots). The word comes from the Czech “robota” which means serf or one in subservient labour. • In the play, the Czech • robot is defined as "a worker of forced labour". After this • play, electromechanical • automatons were • referred to as robots

6. History of Robotics • 1940: Westinghouse Electric Corp. creates two of the first robots that use the electric motor for entire body motion. Elektra could dance, count to ten and smoke, while his dog companion Sparko, could walk, stand on its hind legs and bark. • 1941: Isaac Asimov first uses the • term 'robotics' to describe the • technology of robots. He predicted • the rise of the robot industry.

7. History of Robotics • Dr. W. Grey Walter, one of the great pioneers in the field of robotics, develops the first autonomous tortoise-type robots, Elsie and Elmer (Electro MEchanical Robot, Light-Sensitive), designed with wheel motors controlled by very basic electronic circuitry and two vacuum tubes. • 1951: Raymond Goertz designs the first 'teleoperator' - a device allowing actions to be performed at a distance. Goertz's device was an articulated arm, used to handle radioactive material. • 1962: General Motors installs the first industrial robot on a production line. It is a Unimate robot and is used in a car factory run by General Motors in Trenton, New Jersey. The robot lifted hot pieces of metal from a die-casting machine and stacked them.

8. History of Robotics • 1968: SRI International, formerly known as the Stanford Research Institute, builds and tests the first mobile robot with vision capability. • Shakey was equipped with a television camera, a range finder and sensors. • Shakey was the first mobile robot that could think and respond to the world around it.

9. History of Robotics • 1968: The General Electric Walking Truck was the first manual controlled walking truck.

10. History of Robotics • 1969: Stanford University develop the first electrically powered computer controlled robotic arm. This becomes standard for research projects • 1974: Professor Sheinman, of Stanford Arm fame, forms Vicarm Inc. to market a version of the arm controlled by microcomputer for industrial applications. This robotic arm, known as the Silver Arm performs small-parts assembly using touch sensitive sensors.

11. What is in A Robot?

12. sensors environment ? agent effectors What is in A Robot? Robots  Physical sensors and effectors

13. What is in A Robot?

14. Sensors • Sensors that tell the robot position/change of joints: odometers, speedometers, etc. • Force sensing. Enables compliant motion--robot just maintains contact with object • Sonar. Send out sound waves and measure how long it takes for it to be reflected back. Good for obstacle avoidance. • Vision systems • Tactile touch sensors • Etc.

15. Actuators/Effectors • Converts software commands into physical motion • Actuators are like the "muscles" of a robot, the parts which convert stored energy into movement. - By far the most popular actuators are electric motors that spin a wheel or gear, and linear actuators that control industrial robots in factories. - But there are some recent advances in alternative types of actuators, powered by electricity, chemicals, or compressed air. • Two main types of effectors: • locomotion • manipulation

16. Locomotion • Legs! • traditional such as Honda Asimo • Still, wheeled or tread locomotion like Shakey is still most practical for typical environments • Other methods: reconfigurable robots, fish robots, snake-like robots, UAVs, etc

17. Manipulation • Manipulation of objects • Typical manipulators allow for: • Prismatic motion (linear movement) • Rotary motion (around a fixed hub) • Robot hands go from complex anthropomorphic models to simpler ones that are just graspers • (video: surgery on grape, Robotic heart surgery)

18. What Are Basic Robot Software Issues?

19. Perception • What to perceive: - Where am I? (Localization and Mapping, video) - Where are targets? (e.g., object recognition) - Who/what are you, where are you, what are you doing, etc.?... • Science fiction authors also typically assume that robots will eventually be capable of communicating with humans through speech, gestures, and facial expressions, rather than a command-line interface.

20. Motion Planning • Simplest task that a robot needs to accomplish • Goal: move robot from one configuration to another under certain constraints (e.g., without colliding an obstacle).

21. Control • How to design a controller for generating appropriate forces/torques to achieve particular tasks, e.g., move from one point to another? • How can a humanoid robot walk with particular speeds, step sizes or turn angles? How to ride a bicycle? • How to balance your body when some one is pushing you? • How to cooperate a group of robots to achieve a specific goal? • etc

22. Challenges

23. Uncertainty

24. Software For Robotics

25. Software For Robotics

26. BigDog

30. Statement of Robotics Applications • Moving from manufacturing, industrial manipulators to: – Entertainment robotics – Personal service robots – Medical robots – Industrial applications beyond factory (e.g., mining, agriculture) – Hazardous applications (e.g., military, toxic cleanup, space)

31. Some Current Robots

32. Need for Humanoid Robots • Industrial robots not flexible enough for unmodified environments • Separated from humans • New applications: Service, household helper, entertainment, ... • Interaction with people needed • Human-like body helps when acting in environments designed for humans • Intuitive multimodal communication • Programming by demonstration, imitation learning

33. Humanoid Robots

34. Humanoid Robots Honda Asimo Robots - youtube video (click here)

35. Other Humanoid Robots video

36. More Robots video

37. And Even More Robots video

38. Robots: Alternative Terms • UAV - Unmanned aerial vehicles • UGV (Rover) - Unmanned ground vehicles • UUV - Unmanned undersea vehicles

39. CSE Faculty in Robotics Prof. Nancy Amato Prof. Robin Murph Prof. Dylan Shell Prof. Dezhen Song - Motion planning - Rescue robotics • Distributed Sensing, • Networked Robots, • - Vision and Surveillance • Distributed AI, • Biologically-inspired multi-robot systems, • Coordinated system, analysis of multi-agent systems

40. CSE Courses in Robotics • CSCE 420: Artificial Intelligence • CSCE 452: Robotics and Spatial Intelligence • CSCE 489: Special Topics in Robotics