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Robotics

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Title: Robotics


1
Robotics
2
A robot is a reprogrammable, multifunctional
manipulator designed to move material, parts,
tools, or specialized devices through variable
programmed motions for the performance of a
variety of tasks. (Robot Institute of America)
Definition
Alternate definition
A robot is a one-armed, blind idiot with
limited memory and which cannot speak, see, or
hear.
3
Ideal Tasks
  • Tasks which are
  • Dangerous
  • Space exploration
  • chemical spill cleanup
  • disarming bombs
  • disaster cleanup
  • Boring and/or repetitive
  • Welding car frames
  • part pick and place
  • manufacturing parts.
  • High precision or high speed
  • Electronics testing
  • Surgery
  • precision machining.

4
Automation vs. robots
  • Automation Machinery designed to carry out a
    specific task
  • Bottling machine
  • Dishwasher
  • Paint sprayer
  • Robots machinery designed
  • to carry out a variety of tasks
  • Pick and place arms
  • Mobile robots
  • Computer Numerical Control
  • machines

5
Types of robots
  • Pick and place
  • Moves items between points
  • Continuous path control
  • Moves along a programmable path
  • Sensory
  • Employs sensors for feedback

6
Pick and Place
  • Moves items from one point to another
  • Does not need to follow a specific path between
    points
  • Uses include loading and unloading machines,
    placing components on circuit boards, and moving
    parts off conveyor belts.

7
Continuous path control
  • Moves along a specific path
  • Uses include welding, cutting, machining parts.

8
Sensory
  • Uses sensors for feedback.
  • Closed-loop robots use sensors in conjunction
    with actuators to gain higher accuracy servo
    motors.
  • Uses include mobile robotics, telepresence,
    search and rescue, pick and place with machine
    vision.

9
Measures of performance
  • Working volume
  • The space within which the robot operates.
  • Larger volume costs more but can increase the
    capabilities of a robot
  • Speed and acceleration
  • Faster speed often reduces resolution or
    increases cost
  • Varies depending on position, load.
  • Speed can be limited by the task the robot
    performs (welding, cutting)
  • Resolution
  • Often a speed tradeoff
  • The smallest step the robot can take

10
Performance (cont.)
  • Accuracy
  • The difference between the actual position of the
    robot and the programmed position
  • Repeatability
  • Will the robot always return to the same point
    under the same control conditions?
  • Increased cost
  • Varies depending on position, load

11
Control
  • Open loop, i.e., no feedback, deterministic
  • Closed loop, i.e., feedback, maybe a sense of
  • touch and/or vision

12
Kinematics and dynamics
  • Degrees of freedomnumber of independent motions
  • Translation--3 independent directions
  • Rotation-- 3 independent axes
  • 2D motion 3 degrees of freedom 2 translation,
    1 rotation
  • 3D motion 6 degrees of freedom 3
    translation, 3 rotation

13
Kinematics and dynamics (cont.)
  • Actions
  • Simple joints
  • prismaticsliding joint, e.g., square cylinder in
    square tube
  • revolutehinge joint
  • Compound joints
  • ball and socket 3 revolute joints
  • round cylinder in tube 1 prismatic, 1 revolute
  • Mobility
  • Wheels
  • multipedal (multi-legged with a sequence of
    actions)

14
Kinematics and dynamics (cont.)
  • Work areas
  • rectangular (x,y,z)
  • cylindrical (r,?,z)
  • spherical (r,?,?)
  •  
  • Coordinates
  • World coordinate frame
  • End effector frame
  • How to get from coordinate system x to x to x

15
Transformations
  • General coordinate transformation from x to x
    is x Bx p , where B is a rotation matrix and
    p is a translation vector
  • More conveniently, one can create an augmented
    matrix
  •   which allows the above equation to be
    expressed as x A x.
  • Coordinate transformations of multilink systems
    are represented as
  • x0 A01 A12A23. . .A(n-1)(n)xn

16
Dynamics
  • Velocity, acceleration of end actuator
  • power transmission
  • actuator
  • solenoid two positions , e.g., in, out
  • motorgears, belts, screws, leverscontinuum of
    positions
  • stepper motorrange of positions in discrete
    increments

17
A 2-D binary robot segment
  • Example of a 2D robotic link having three
    solenoids to determine geometry. All members are
    linked by pin joints members A,B,C have two
    statesin, outcontrolled by in-line solenoids.
    Note that the geometry of such a link can be
    represented in terms of three binary digits
    corresponding to the states of A,B,C, e.g., 010
    represents A,C in, B out. Links can be chained
    together and controlled by sets of three bit
    codes.

18
Problems
  • Joint play, compounded through N joints
  • Accelerating masses produce vibration, elastic
    deformations in links
  • Torques, stresses transmitted depending on end
    actuator loads

19
Control and programming
  • Position of end actuator
  • multiple solutions
  • Trajectory of end actuator how to get from
    point A to B
  • programming for coordinated motion of each link
  • problemsometimes no closed-form solution

20
Control and programming (cont.)
  • Example end actuator (tip) problem with no
    closed solution.
  • Two-segment arm with arm lengths L1 L2, and
    stepper -motor control of angles ?1 and ?2.
  • Problem control ?1 and ?2 such that arm tip
    traverses its range at constant height y, or with
    no more variation than ?y.
  • Geometry is easy position of arm tip
  • x L1 (cos ?1 cos ?2)
  • y L1 (sin ?1 sin ?2)

21
Control and programming (cont.)
  • Arm tip moves by changing ?1 and ?2 as a function
    of time.
  • Therefore
  • So, as ?1 and ?2 are changed, x and y are
    affected.
  • To satisfy y constant, we must have
  • . So the rates at which ?1 and ?2 are changed
    depend on the values of ?1 and ?2.

22
Control and programming (cont.)
  • There is no closed-form solution to this
    problem. One must use approximations, and accept
    some minor variations in y. Moving the arm tip
    through its maximum range of x might have to be
    accomplished through a sequence of program steps
    that define different rates of changing ?1 and
    ?2.
  • Possible approaches
  • Program the rates of change of ?1 and ?2 for y
    const. for initial values of ?1 and ?2 . When
    arm tip exceeds ?y, reprogram for new values of
    ?1 and ?2.
  • Program the rates of change of ?1 and ?2 at the
    initial point and at some other point for y
    const. Take the average of these two rates, and
    hope that ?y is not exceeded. If it is exceeded,
    reprogram for a shorter distance. Continue
    program segments until the arm tip has traversed
    its range.
  •  

23
Control and programming (cont.)
  • Program the rates of change of ?1 and ?2 at the
    initial point and at some other point for y
    const. Take the average of these two rates, and
    hope that ?y is not exceeded. If it is exceeded,
    reprogram for a shorter distance. Continue
    program segments until the arm tip has traversed
    its range.
  • The rate of change of ?1 and ?2 can be changed in
    a programming segment, i.e., the rates of change
    need not be uniform over time. This programming
    strategy incorporates approaches 1) and 2).
    Start with rates of change for the initial values
    of ?1 and ?2 , then add an acceleration component
    so that y const. will also be satisfied at a
    distant position.

24
Feedback control
  • Rotation encoders
  • Cameras
  • Pressure sensors
  • Temperature sensors
  • Limit switches
  • Optical sensors
  • Sonar

25
New directions
  • Haptics--tactile sensing
  • Other kinematic mechanisms,
  • e.g. snake motion
  • Robots that can learn
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