KING FAHD UNIVERSITY OF PETROLEUM & MINERALS

Computer Engineering Department

Robotics Laboratory

BILATERAL MASTER-SLAVE TELEROBOTIC SYSTEM

Professor Mayez Al-Mouhamed

 

Research Objectives

Research Strategy

 

 

                TASK 1: DESIGNING A LIGHT AND BACKDRIVABLE LINKAGE MECHANISM

  • Approach:
    • The aim is to design a light, tight, low-friction, motor-linkage transmission system
    • Transmit motor power to robot link using a small gear 
    • For simplicity a two-loop transmission mechanism is designed

     

  • The two-loop transmission
    • Gear loop (Motor shaft to gear wheel)
      • Motor power is transmitted to a large gear wheel using a timing belt to avoid slippage
      • Both motor shaft and gear wheel have timing teeth

       

    • Transmission loop (Gear wheel to linkage)
      • A flexible steel wire-based transmission
      • The wire is wrapped 1.5 times at each of  two terminal threaded wheels (60mm)
      • To avoid wire slippage the wire is retained using a jam screw in the threaded wheel
      • The wheel material is emptied to reduce weight whenever possible
      • Mechanism allows accessibility to jam screws of multiple gear wheels on a single shaft   

       

    • Testing
      • Mechanism is tested in lifting a payload of 3 Kgs without slippage
      • Ability to actuate the chain with moderate effort at both ends
      • Moderate backdrivability due to belt friction

 

           

               TASK 2: IMPROVED  BACKDRIVABILITY IN THE LINKAGE MECHANISM        

  • Improved approach through experimentation
    • The aim is improve quality of motion and force display fidelity
    • To improve backdrivability the timing belt transmission in the first loop is dropped
    • To improve maintainability multiple loop mechanism to promote localized fault
    • A wire-based transmission is adopted to transmit motor power to gear wheel 
    • Multiple loop transmission using steel wire from motor to linkage

     

  • Revision of the two-loop transmission
    • The gear loop (Motor shaft to gear wheel) (H-water-lifting-wire-disk-1D):
      • Motor power is transmitted to a large gear wheel using a tiff  wire drive system
      • A small threaded roller (14 turns) is attached to the motor shaft
      • The flexible wire is rolled 3 or 4 times on the motor roller (without retaining mechanism)
      • The gear wheel is threaded (3 threads) and the wire is rolled 1.5 times
      • In the middle wrap the wire enters an inclined hole and get retained using a jam screw
      • The wire returns to the thread using a second  inclined hole 
      • The ratio of diameters of  motor-roller and large gear wheel controls the transmission gear
      • For efficiency the large gear wheel is set closer to the driven link
      • Self-lubricated deep groove ball bearings are used for rotating elements
      • Light aluminum alloy is used
      • All unnecessary material is removed to reduce weight and inertia
    • Transmission loop (Gear wheel to linkage):
      • Unchanged

       

  • Testing
    • Mechanism is tested in lifting a payload of 3-10 Kgs at different speeds without slippage
    • Excellent backdrivability at both ends for a moderate gear ratios
    • Ability to smoothly actuating the chain with low effort at both ends

 

 

               TASK 3: DESIGNING THE MAN-MACHINE INTERFACE OF MASTER ARM

  • Research direction
    • Objectives
      • An effective man-machine interface between operator and master arm
      • An effective motion mapping  from operator hand to remote slave arm tool
      • Operator hand must be at the center of concurrency of last three DOFs
     
    • How to design the last 3 DOF of a  master arm so that the user can easily map his hand motion to a remote tool
      • Operator wearing a head-mounted display cannot see his hand nor the master arm he is holding
      • Operator needs a man-machine interface to logically maps his hand motion to slave arm tool
      • Operator thinks he is holding the tool through the master-slave system
      • A solution that failed (experiment-1)
        • Last 3 DOFs have concurrent rotation axes,
        • But operator hand center  is not the center of rotational concurrency
      • The operator hand center must be placed at the point of concurrency of last 3 DOFs
      • Operator hand center is also the origin of hand frame of reference

       

  • Study of a passive master arm (experimment-2)
    • Operator hand is placed at the center of rotational concurrency of last 3 DOFs
    • decoupling operator hand position from orientation
    •  Minimizing number of iterations to set up the arm in a given configuration
    • Improved mapping between operator hand position and orientation and slave arm tool 

 

 

      TASK 4: DESIGNING LIGHT AND BACKDRIVABLE ROBOT ARMS FOR TELEROBOTICS

  • Objectives
  • The aim is a Telerobotic System that allows an operator carrying out remote work through a computer network
  • To design a light, backdrivable master and slave robot arm while engineering the cost/performance ratio
  • To develop an effective real-time client (master arm) and  server (slave arm) software system 
  • To provide real-time stereo vision from the slave station to master station with head-mounted display
  • A wire-based transmission is adopted to transmit motor power to gear wheel 
  • Multiple loop transmission using steel wire from motor to linkage 
  • Common features to both Master and Slave Arms ():
    • A 6 DOF, serial, anthropomorphic slave arm
    • Wire-based transmission to lower friction and cost
    • Motor-to-link chain has a gear loop followed by a number of transmission loops (see above)
    • Improved backdrivability, each motor-to-link chain can be easily actuated at both ends
    • Multiple independent transmission loops to make it fault-localized 
    • Designed to ease accessibility and maintenance   
    • Light material and robust structure, mobile arm linkage weight only 3Kgs
    • Last 2 DOFs have concurrent rotational axes to simplify arm kinematics
    • All six motors are grounded, all wire transmission go to ground through link 1 (see demo)
  • Features of the Slave Arm
    • Last 2 DOFs controls a hub-gear (differential) motion of the gripper
    • Simple kinematics

     

  • Features of the Master Arm
    • Operator hand is placed at the center of rotational concurrency of last 3 DOFs
    • decoupling operator hand position from orientation
    •  Minimizing number of iterations to set up the arm in a given configuration
    • Improved mapping between operator hand position and orientation and slave arm tool 
    • Last 3 DOFs controls a hub-gear (differential) motion of the gripper

     

  • Testing
    • Tested in Bilateral Master-Slave mode in 2004 at the Robotics Lab and a US patent is pending for the master arm.

 

 

      TASK 5: A LIGHT (3 KGS), ANTHROPOMORPHIC BILATERAL MASTER-SLAVE TELEROBOTIC SYSTEM

             FROM WIRING, CONTROL ELECTRONICS, TO OPERABILITY

Development of the bilateral telerobot

  • Wiring of master and slave arms (master-mechanics) and slave arm (slave)
    • Maintainable structure based multiple-loops
    • Accessible wring through new wheel structure
    • Revolutionary wiring attachment and installation
    • Tightly tensioned wiring to avoid undesirable elesticity
  • Master arm mobility features (wired master) (Master-mobility)
    • Real anthropomorphic structure as it does not constrain human arm motion in any translation or orientation
    • Low impedance as whole arm weight 3 kgs,  low friction due to wire structure and fine mechanics 
    • Low gear (wire-based) linkage from grounded motors to joint and operator handle

     

  • Designing and implementing arm control and power drive system (master-electronics)
Operability of master-slave bilateral system at the joint level and sight of slave scene

          3D stereo vision in master-slave bilateral system at the joint level 

  • Operator holding master arm and wearing Head-Mounted-Display HMD (operator)
  • Operator does not sees has arm but the slave arm tip and object through the HMD
  • Operator is logically holding the remote object and moving his arm to properly move remote object

            Potential development

  • Design of an advanced computer aided teleoperation (CAT) to support pervasive quality remote work
  • Develop a pervasive client-server software with real-time streaming of force and video information
  • Experience the above Bilateral telerobot with its CAT on hard manual and automatic tasks
  • Evaluate different working scales and faster networks (1Gbps Ethernet) in preparation for Internet 2 technology.

              

 

 

      POTENTIAL RESEARCH DIRECTIONS:

Develop a KFUPM research product in the area of telerobotics to support KSA needs

  • Designing anthropomorphic master arms for robotic surgery, tight-safety and fire fitting, under water, and military.
  • Designing of an advanced pervasive network connectivity to enable high-quality remote work using telerobotics
  • Designing of stand alone, networked,  light, slave arm with force feedback with embedded computer and software
  • Design of an Educational Telerobotic system (arm and Experiments) to equip graduate laboratory in Robotics, Mechantronics, Sensor-Based Computer Systems, Context-Aware Mobile Computers, etc.    
  • Develop Software for real-time remote control and QOS through a computer network
  • Develop a pervasive, fast, and accurate Stereo-Vision system that relays stereo frames through the Internet with Augmented Reality capability to augment a telerobotic system.

LONG TERM PLANS

  • Transfer telerobotic design methodology and techniques
  • Provide necessary training and consulting whenever needed
  • Develop local skills to master the above technology whenever needed
  • Help develop new telerobotic product tailored to specific applications whenever needed

Contact:  Professor Mayez Al-Mouhamed, Computer Engineering Department, King Fahd University of Petroleum and Minerals, Dhahran 31261, KSA. Phone: 966-3-860-2934, Fax 966-3-860-3059, email: mayez@ccse.kfupm.edu.sa

              

 

 

 

        Please see the following papers for more details:

     Patents