Lessons Learned
Robotic systems must be flexible, reliable and easy to program to survive in today’s marketplace.  Unfortunately, the more complex a robot becomes, i.e. more joints, the greater the control complexity.  This tends to decrease reliability and ease of use.  However, design complexity does not necessarily result in control complexity, based upon a control technique that couples a robot design having anatomical similarity to humans and a body movement simulator, worn by a person, which accurately monitors joint angles of the person’s fingers, arms and upper body.  The fundamental premise of this control technique is rooted in the principle of anatomical consistency that all humans generally share.  Human anatomical features such as finger, hand and arm lengths possess length ratios, such that similarity from one person to the next would allow the average person the ability to easily control an "anatomically averaged" Robot.  It is the coupling of anatomically similar robotic link dimensions with a human operator that distills complex computer control of some 58 robotic upper body joints into relatively simple human motor-skills.  This control technique leverages millennia of developed, complex human hand-eye coordination tasks, which today are generally taken for granted.  Motor skills such as tying shoe laces, writing and typing are easily acquired skills, yet programming a robot for such a task would be extremely difficult.  In developing my Personal Assistant, computer resources are used for robot /teleoperator joint position and finger tip sensing, not multi-joint kinematic solutions, therefore eliminating motion delays associated with real-time kinematic motion control of many joints.  Furthermore, special tooling to interface robot hands to the task are not emphasized, utilizing instead, common tools manufactured for use by the human hand.