Vol.3, No 11, 2001 pp.285-294
UDC 517.93+519.713:007.52(045)
MATHEMATICAL MODELING AND CONTROL
OF REDUNDANT ROBOTIC MANIPULATORS
USING BIOLOGICAL ANALOG
Mihailo P. Lazarević
Faculty of Mechanical Engineering, University of Belgrade, 27 Marta
80, 11000 Belgrade, Yugoslavia, Fax: (381-11) 3370-364 Tel: (381-11) 3370
-760/ loc. 338
E-mail: lazarem@alfa.mas.bg.ac.yu
Abstract. In this paper it is considered
problem of realization new mathematical models of redundant systems as
well as control using suitable biological analog. The idea was to try to
imitate human behavior and this is specially convenient for tasks which
are similar to those characteristic for humans (e.g., assembling in industry,
different jobs at home and in health service). If we consider speed, accuracy
and stability of motion then the overall performance (taking into account
all three of parameters) with machines is still far behind human reaching
and grasping. Human arm movements are considered to be stable, fast and
accurate due to properties of muscles, musculo-skeletal structures and
hierarchical control. It was observed in the execution of functional motions
that certain trajectories are preferred from the infinite number of options.
Such behavior of organisms can be only explained by the existence of inherent
optimization laws in self-organized systems governing the acquisition of
motor skills. Existence of invariant features in the execution of functional
motions points out that central nervous system (CNS) uses synergy [Bernstein,1967](i.e
rule(s) that can be developed by the CNS based on some principles). The
control of arm movement in humans relies very much on distributed usage
of different joints, and inherent optimization of muscles which are active.
Analysis of multijoint coordination in humans is an important source of
information for synthesis of dynamic patterns in machines. In that way,
model of redundant system is obtained using biomechanical principle - synergy
i.e. introducing linear or nonlinear relations between independent parameters
or their first derivatives which uniquely define redundant system. Moreover,
one can introduced hypothetical control using joint actuator synergy approach
as suggested [Bernstein, 1967] which imposes a specific constraint(s) on
the control variables. Also, it can be applied biological concept called
distributed positioning (DP) which is based on the inertial properties
and actuation capabilities of joints of redundant system. The redundancy
and DP concept [Potkonjak 1990] could be used for solving the trajectory
that has problems with increased dynamic requirements. The concept of DP
allows us to separate the smooth and accelerated components of required
motions applying appropriate smoothing technique. The inverse kinematics
of redundant robot has been solved at the coordination level via (DP) concept.
Moreover, it is here proposed using other biological principles such as:
principle of minimum interaction which takes a main role in hierarchical
structure of control and self-adjusting principle, which allows efficiently
realization of control based on iterative natural learning. Motor control
is organized as a multilevel structure, is generally accepted. In assistive
system involves man as the decision maker, a hierarchical control structure
can be proposed with three levels from the left to right: -voluntary level,
coordination level, actuator level. This imposes the system is decomposed
into several sybsystems with strong coupling between subsystems. Explanation
of previous can be understood using the principle of maximum autonomy or
minimum information exchange [Tomović, Bellman, 1970]. According to this
principle, the optimal solution is to delegate the execution of functional
motions to the coordination level and local regulators once the task and
the task parameters have been selected. Learning control for controlling
dynamics systems, a class of tracking systems is applied where it is required
to repeat a given task todesired precision. The common observation that
human beings can learn perfect skills trough repeated trials motivations
the idea of iterative learning control for systems performing repetitive
tasks. Therefore, iterative learning control requires less a priori knowledge
about the controlled system in the controller design phase and also less
computational effort than many other kinds of control. For improving the
properties of tracking is proposed appling biological analog - principle
of self-adaptibility, [Grujuć,1989 ] which introduce local negative feedback
on control with great amplifing.
MATEMATIČKO
MODELIRANJE I UPRAVLJANJE REDUDOITNIM ROBOTIMA-MANIPULATORIMA KORIŠĆENJEM
BIOLOŠKIH ANALOGA
U ovom radu razmatran je problem realizacije novih matematičkih modela
redudantnih sistema kao i upravljanja korišćenjem pogodnih bioloških analogona.
Ideja je bila u tome da se imitira ljudsko ponašanje i to je posebno značajno
za zadatke koji su slični onim zadacima karakterističnim za ljude. Prvo,
može se primeniti biološki koncept distribuiranog pozicioniranja (DP) koji
je zasnovan na inercijalnim osobinama i aktuatorskim mogućnostima zglobova
redudantnih sistema. Drugo, predloženo je korišćenje biološkog analogona
- sinergije koja je posledica postojanja invarijantnih osobina u izvršavanju
funkcionalnih kretanja. Na kraju predloženo je korišćenje drugih bioloških
principa kao što su: princip minimuma interakcije koji ima važnu ulogu
u hijerarhijskoj strukturi upravljanja i principa samopodešavanja, koji
dozvoljava efikasnu realizaciju upravljanja koje je zasnovano na iterativnom
prirodnom učenju.
