Nikola Tesla and robotics

The paper analyzes some of Tesla's works and his most remarkable views concerning the problem of formulating theoretical bases of automatic control. As a tribute to Tesla's work on remote control of automated systems, as well to his (at the time) far-seeing visions, special attention is paid to solving complex problem of control and feedback application. A more detailed discussion of the way and origin of formulating theoretical bases of automatic control are given. Besides, in more detail are presented the related pioneering works of Professor Nicholas Bernstein, great Russian physiologist who formulated the basic rules of the self-regulating movements of the man. Bernstein has achievements of highest scientific significance that has been in a direct function of identifying and proving the priority of his pioneering contributions in the domain of feedback, i.e. control and principles of cybernetics

A software system for teaching and commanding the industrial robots

Design features of a software system for programming industrial robots with dynamic control are described. The software is intended for implementation an a microprocessor-based system and should enable the user to control a robot via specialized programming language RL. The paper contains description of the RL language and description of the system structure. Main characteristics and advantages of the system as well as questions concerning its realization on existing microprocessors are also discussed

General-purpose controller for industrial manipulators

The general-purpose controller for industrial robots of arbitrary type is described. It enables control of robots powered by DC electromotors or hydraulic actuators. The controller includes programs for communication with operators, robot program language, program for on-line robot kinematics, and program for direct digital servosystems for tracking trajectories including on-line dynamics of the robot. The controller is implemented on two microcomputers based on INTEL 8086 microprocessors. All parts of the controller hardware and software are briefly described. Implementation of on-line kinematics and on-line dynamics and the choice of the control law are considered in more details

Concept of multiprocessor robot control system

U radu je prikazan koncept novog upravljačkog sistema razvijenog u Institutu "Mihailo Pupin", namenjenog za upravljanje manipulacionim robotima opšte namene. Upravljački sistem sastoji se iz 3 procesora u paralelnom radu. Prvi procesor namenjen je za komunikaciju sa korisnikom i sinhronizaciju rada sistema sa okolinom (komunikacioni procesor), drugi (kinematički procesor) prevodi spoljašnje koordinate u unutrašnje, a treći (dinamički procesor) obezbeđuje praćenje zadatih trajektorija. Procesorske ploče su realizovane na bazi mikroprocesora Intel 8086 i koprocesora 8087 sa taktom od 8 MHz.This paper presents a concept of a new robot controller developed in "Mihailo Pupin" Institute. The controller consists of 3 parallel processor units. The first unit is intended for comunication with a user and synchronization of the system operation with its environment (communication processor). The second unit (kinematic processor) transforms world coordinates into joint angles, and the third (dynamic processor) enables quality tracking of imposed trajectories. The processor boards are based on Intel 8086 microprocessors and 8087 coprocessors running at 8 MHz clock

Optimal manoeuver trajectory synthesis for autonomous space and aerial vehicles and robots

© Springer Nature Switzerland AG 2019. In this paper the problem of the synthesis of optimal manoeuver trajectories for autonomous space vehicles and robots is revisited. It is shown that it is entirely feasible to construct optimal manoeuver trajectories from considerations of only the rigid body kinematics rather than the complete dynamics of the space vehicle or robot under consideration. Such an approach lends itself to several simplifications which allow the optimal angular velocity and translational velocity profiles to be constructed, purely from considerations of the body kinematic relations. In this paper the body kinematics is formulated, in general, in terms of the quaternion representation attitude and the angular velocities are considered to be the steering inputs. The optimal inputs for a typical attitude manoeuver is synthesized by solving for the states and co-states defined by a two point boundary value problem. A typical example of a space vehicle pointing problem is considered and the optimal torque inputs for the synthesis of a reference attitude trajectory and the reference trajectories are obtained

Virtual Constraints and Hybrid Zero Dynamics for Realizing Underactuated Bipedal Locomotion

Underactuation is ubiquitous in human locomotion and should be ubiquitous in bipedal robotic locomotion as well. This chapter presents a coherent theory for the design of feedback controllers that achieve stable walking gaits in underactuated bipedal robots. Two fundamental tools are introduced, virtual constraints and hybrid zero dynamics. Virtual constraints are relations on the state variables of a mechanical model that are imposed through a time-invariant feedback controller. One of their roles is to synchronize the robot's joints to an internal gait phasing variable. A second role is to induce a low dimensional system, the zero dynamics, that captures the underactuated aspects of a robot's model, without any approximations. To enhance intuition, the relation between physical constraints and virtual constraints is first established. From here, the hybrid zero dynamics of an underactuated bipedal model is developed, and its fundamental role in the design of asymptotically stable walking motions is established. The chapter includes numerous references to robots on which the highlighted techniques have been implemented.Comment: 17 pages, 4 figures, bookchapte

11000-Belgrade, Serbia and Montenegro

This paper is devoted to the permanence of the concept of Zero-Moment Point, widelyknown by the acronym ZMP. Thirty-five years have elapsed since its implicit presentation (actually before being named ZMP) to the scientific community and thirty-three years since it was explicitly introduced and clearly elaborated, initially in the leading journals published in English. Its first practical demonstration took place in Japan in 1984, at Waseda University, Laboratory of Ichiro Kato, in the first dynamically balanced robot WL-10RD of the robotic family WABOT. The paper gives an in-depth discussion of source results concerning ZMP, paying particular attention to some delicate issues that may lead to confusion if this method is applied in a mechanistic manner onto irregular cases of artificial gait, i.e. in the case of loss of dynamic balance of a humanoid robot. After a short survey of the history of the origin of ZMP a very detailed elaboration of ZMP notion is given, with a special review concerning “boundary cases ” when the ZMP is close to the edge of the support polygon and “fictious cases ” when the ZMP should be outside the support polygon. In addition, the difference between ZMP and the center of pressure is pointed out. Finally, some unresolved or insufficiently treated phenomena that may yield a significant improvement in robot performance are considered