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1 Introduction

For many years engineering researchers have been inter-
ested in exploring ways in which knowledge about biology
can contribute to engineering design. An early stimulus to
research efforts in that area came from the much-publicised
and innovative work of Norbert Wiener, including his intro-
duction of the word “cybernetics”, meaning the study of
control principles in man and machine. Later milestones
include the publication in the 1960s of the proceedings of an
AGARD conference [1] on the theme of “bionics”, which
included some fascinating contributions that showed just how
much biologically-inspired engineering research was under
way by then, both in Europe and in North America. More
recent examples where biology has provided important links
that have led to widely-used design tools, include evolution-
ary methods of optimisation (such as genetic algorithms and
genetic programming) and to artificial neural networks. In
both of these areas biological analogies and biological think-
ing have contributed to the tools as they are used at present,
but it is clear that the biological context of much of the origi-
nal research is now largely irrelevant to those who routinely
use the techniques in solving engineering problems. Also,
although biological thinking did contribute significantly to
their development, it is important to point out that the most
widely used forms of artificial neural networks have only some
features that reflect properties of networks of real biological
neurons. Similarly, in the evolutionary computing field, al-
though the algorithms are firmly based on the principles of
survival of the fittest, only some aspects of evolutionary biol-
ogy have been applied within the forms of genetic algorithm
that are in general use today.

In considering living systems from an engineering
perspective it is clear that there are some fundamental simi-
larities and differences between natural systems and human-
-engineered systems. Both types of system show behaviour
that is based on the same physical, chemical and thermo-
dynamic laws and principles. On the other hand, natural
systems sample a design space through the processes of
evolution and optimisation that involves small changes to an
existing system. They are also strongly integrated at a variety
of levels including the molecular, cellular, organ and eco-sys-

tem levels. Human-engineered sub-systems are never, at the
current level of our technology, integrated as closely as bio-
logical systems and these engineering sub-systems can often
function independently. Indeed structure and function are
related at all scales and levels in biological systems in a way
that is seldom approached in present-day man-made systems.

2 Biological control systems
Man-made control systems still lag far behind natural sys-

tems in terms of their performance. This is especially clear in
mobile robots where human performance in complex tasks,
such as tennis playing or riding a standard bicycle, goes be-
yond the capabilities of any present-day man-made system.
Present-day manipulator robots also show a level of perfor-
mance in terms of control system capabilities that is far below
that of the equivalent biological systems. A manipulator robot
has a dynamic response that is highly dependent on the load
being carried by the arm. Human arms on the other hand
show dynamic responses that are largely independent of the
loading conditions and have characteristics that strongly sug-
gest adaptive properties in the underlying control system.
The question arises of how these adaptive properties are pro-
vided from the basic elements of the neuromuscular system
and whether some of these properties could be translated into
equivalent characteristics in robots.

3 The neuromuscular control system
The biological system that controls posture and move-

ment in mammals is highly complex, with significantly
nonlinear and adaptive properties. Although the system pres-
ents a considerable challenge to biologists and to engineers, it
has for many years attracted much attention because of the
potential benefits in terms of the treatment of diseases that
can affect our ability to control posture and move effectively.

The neuromuscular system has also been taken into ac-
count in modelling the human operator for control tasks
where the human-in-the-loop has a critically important role,
such as in flying high-performance military aircraft. Much use
has been made of relatively simple neuromuscular system

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Acta Polytechnica Vol. 44  No. 2/2004

Biological Systems Thinking for Control
Engineering Design

D. J. Murray-Smith

Artificial neural networks and genetic algorithms are often quoted in discussions about the contribution of biological systems thinking to
engineering design. This paper reviews work on the neuromuscular system, a field in which biological systems thinking could make specific
contributions to the development and design of automatic control systems for mechatronics and robotics applications. The paper suggests
some specific areas in which a better understanding of this biological control system could be expected to contribute to control engineering
design methods in the future. Particular emphasis is given to the nonlinear nature of elements within the neuromuscular system and to
processes of neural signal processing, sensing and system adaptivity. Aspects of the biological system that are of particular significance for
engineering control systems include sensor fusion, sensor redundancy and parallelism, together with advanced forms of signal processing for
adaptive and learning control.

Keywords: biology, control systems, design, neuro-muscular system.



sub-models within pilot models used for aircraft handling
qualities and flight control systems studies.

Interest shown by engineers in the structure and function
of the neuromuscular system has also been very considerable
because they have recognised the potential benefits for engi-
neering design. A better understanding of the way in which
the central nervous system controls complex movements and
the role of reflex systems in the regulation of posture could
well lead to the design of better control systems for manipula-
tor robots or walking robots.

It is generally accepted that the neuromuscular control
system is organised in a hierarchical fashion. The muscular
and skeletal subsystems and the associated sensory elements
(neural receptors) lie at the lowest level and are directly in-
volved as elements in the feedback loops that provide reflex
actions through the spinal cord. These reflex actions are influ-
enced by a network of interneurones which is thought to
provide the coordination and pattern generation elements
for the system for control tasks involving more than one
muscle. The brain stem, cerebellum, motor cortex and other
similar areas of the central nervous system are involved in the
upper levels of this hierarchy. Neural communication path-
ways, both ascending and descending, interconnect elements
at the various different levels. Fig. 1 shows a simplified sche-
matic diagram of the system.

Most physiologists and engineers involved in neuro-
muscular system modelling and experimental investigations
have adopted a modular approach in which attempts are
made to understand the function and structure of the many
different elements of the system. The basic actuator is the
anatomical muscle. A single anatomical muscle may contain
hundreds of active contractile elements, known as motor
units, which are connected in parallel to a common tendon.
Each motor unit itself consists of a single motoneurone and
a group of about 250 muscle cells that can be activated simul-
taneously by the motoneurone. Each muscle fibre resembles
a form of active nonlinear spring in which the force devel-
oped is dependent upon both the external loading and the
neural input. At a microscopic level the fibres contain many
smaller elements known as fibrils, and each fibril is itself
packed with microfilaments which are of two types, thin
filaments of actin and thick filaments of myosin. The active
contractile properties of muscle are derived from the active
sliding of one type of filament over the other.

The signal transmission paths in the neuromuscular sys-
tem are nerve fibres. A typical nerve fibre has a cell body,
which contains the nucleus, and a number of so-called “pro-
cesses” that may be more than one metre in length. Most
nerve cells have several short processes, called dendrites,
and a thinner and longer process called the axon. Electrical
impulses are generated by a discharge at a receptor organ.

Activity at one point in a nerve fibre leads to activation of
adjacent parts of the fibre and at points where a nerve divides
the activity is carried into all branches. In electrical terms the
activity at a given point takes the form of voltage impulses or
“spikes”, known as action potentials, separated by periods of
inactivity. It is widely believed that neural information is
transmitted using a form of pulse-frequency modulation.

Since the transmission of an action potential is an active
process that depends upon ion transport across membranes
there are usually significant time delays. The velocity of prop-
agation of a neural impulse is directly related to the nerve
fibre diameter. The point of connection between one nerve
cell and another is known as a synapse. A single impulse in
one pre-synaptic fibre may not have sufficient effect to acti-
vate the post-synaptic cell and there is a resulting change in
the pattern of activity. In many ways a synaptic junction may
be regarded as analogous to an ideal summing junction with
additional attenuating properties. The pre-synaptic connec-
tions are classified as either facilitatory or inhibitory and are
equivalent to inputs with positive or negative signs, respec-
tively, at the summing element.

The sensory elements of the stretch reflex feedback system
are of two main types. These are the muscle spindle receptors
and the tendon organ receptors and they are known to
be very different, both anatomically and functionally. It is
believed that the muscle spindle receptors have a particularly
important role in the stretch reflex system and in the overall
control of the complete neuromuscular system. It has for long
been accepted that a more complete understanding of the
muscle spindle receptor would throw light on many unsolved
problems concerning neuromuscular control mechanisms.

The muscle spindle receptors are sense organs that lie in
parallel with the main load-bearing (extrafusal) muscle fibres.
Each spindle consists of a group of special-purpose muscle
fibres, known as intrafusal fibres, with a set of receptors
located in the central region of the spindle. Although the
complexity of the muscle spindle is considerable and some of

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Acta Polytechnica Vol. 44  No. 2/2004

Fig. 1: Diagram of pathways connecting the muscle spindle and its parent muscle to the spinal cord (adapted from diagram in [2])



its features are still not understood, there are some points
upon which there is general agreement. It is recognised that
intrafusal fibres vary in size and fall into two distinct catego-
ries in terms of visible microscopic features, these being
known as nuclear bag fibres and chain fibres. Nuclear bag
fibres consist of a central region which has few myofibrils and
is thought to have properties that are essentially elastic. This
central region is linked in series on either side to contractile
regions that have visco-elastic characteristics. Nuclear chain
fibres are more uniform in structure and therefore are not ex-
pected to show such markedly viscous responses. In most
mammals the muscle spindle consists of two or three bag
fibres and several chain fibres.

A typical anatomical muscle may have a large number
of muscle spindles, in some cases as many as eighty. The prop-
erties of the intrafusal fibres are similar to the properties of or-
dinary extrafusal muscle, except that the intrafusal fibres have
their own motor pathways through which the central nervous
system can influence the spindle quite independently of the
main extrafusal fibres. In the context of neuromuscular con-
trol, one of the most important points that has been estab-
lished about the muscle spindle receptor is that there are sev-
eral different types of efferent nerve fibre leading to intrafusal
fibres. In addition to the well-known gamma efferents, of
which there are two types, muscle spindles may also be
innervated by collaterals of the alpha motor nerve fibres
which supply the extrafusal fibres of the main muscle. These
collaterals are known as beta fibres.

The sensory regions of the muscle spindle can therefore
be affected both by mechanical changes in the main load-
-bearing muscle and by activity in the gamma and beta
pathways. Functionally, the muscle spindle receptors are
thought to be somewhat analogous to strain gauges and pro-
vide neural output signals in response to an applied extension
of the main muscle or in response to neural activation of the
intrafusal fibres of the spindle itself.

There are two types of sensory receptor in the mammalian
muscle spindle and these are known as primary and second-
ary endings. The significant difference between primary and
secondary endings is that while the primary endings are
found to display a high sensitivity to the velocity of applied
stretch, the secondary endings are not so velocity sensitive.
The primary output of the muscle spindle is usually transmit-
ted to the spinal cord by a single large axon that winds around
the nuclear bag. Mechanical deformation of the sensory end-
ings of this axon leads to the generation of neural impulses at
a frequency that is related to the velocity of applied stretch
as well as to the static deformation. This rate sensitivity is
thought to be of considerable significance in the study of the
neuromuscular control system. Secondary endings do not dis-
play any marked rate sensitivity.

Tendon organs lie in series with the main load-bearing
muscle and the neural ouput from this sensory receptor is
directly related to the overall muscle tension. The tendon
organ is known to have an inhibitory effect on the the moto-
neurones of its own load-bearing muscle, whereas the spindle
output has a facilitatory effect.

In the 1950’s a servomechamism hypothesis of neuro-
muscular control was formulated by Hammond, Merton et al
[3] in which it was suggested that some movements are pro-

duced not as a direct result of neural signals from higher cen-
tres acting on the alpha motoneurones, but indirectly through
the gamma pathway to cause contraction of the intrafusal
fibres of the muscle spindle. The spindle output signal is
transmitted to the motoneurone pool and thus stimulates the
motoneurone which causes contraction of the load-bearing
muscle. Although Hammond et al. [3] were the first to employ
the servomechanism analogy and carried out experimental
investigations that supported this theory, the existence of
closed-loop neuromuscular systems had been recognised for
many years before that.

The supposed advantage of the indirect route through the
gamma efferent pathways is that feedback through the muscle
spindle receptor facilitates the maintenance of the conditions
appropriate to the fusimotor input in the presence of external
disturbances. The system becomes largely independent of
changes in load and will be relatively insensitive to muscle
fatigue. Later work suggested that the action of the stretch re-
flex system must be more complicated than the description
given by Hammond et al.. It is known, for example, that
beta motoneurones innervate both extrafusal muscle and the
intrafusal fibres of the muscle spindle. A number of research-
ers pointed out that the controlled variable cannot be defined
in a simple way because of the complex dynamic interactions
in the muscle spindle that acts as the comparator within
the closed-loop system. Examination of the possible conse-
quences of either position or tension control suggests that
neither of these would be suited to the tasks performed by
skeletal muscle. More recently, the ideas of pre-calculated
feed-forward control have contributed to an understanding of
some aspects of the action of the cerebellum in controlling
rapid movements in the presence of delays in the feedback
pathways.

4 Computational models of the
neuromuscular system
A number of mathematical and computer-based models

have been proposed for describing control mechanisms in the
neuromuscular system and these models have been reviewed
recently [4]. A modular approach is generally favoured and
has been highly successful in studies of the dynamic proper-
ties of individual neural elements of this complex nonlinear
dynamic system and of interactions between them [2]. What
remains uncertain in this closed-loop system model is the
nature of the controlled variable and the origin of properties
that produce insensitivity to changes of external load and
smooth movements under a very wide range of experimental
conditions. These apparently adaptive features are of enor-
mous interest for robotics research. If these and other features
of the biological system could be more fully understood and
reproduced in the design of control systems for manipulator
robots there could be significant benefits.

It appears likely that the key element in providing insight
about the complex properties of this biological system is
the muscle spindle receptor. This appears to function as a
comparator and also as a combined sensor that provides a sig-
nal that depends primarily on muscle length and velocity but
has dynamic properties that are dependent on the gamma
efferent signal from the central nervous system. There is
substantial evidence [2, 5] that the fusimotor inputs to the

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Acta Polytechnica Vol. 44  No. 2/2004



muscle spindle are responsible for changes in the dynamic
response of this sensory element in the system. This gives a
strong clue about the possible source of some of the complex
self-adaptive properties observed in the intact closed-loop
system but it is still not known how the overall behaviour of
the control system is influenced by these changes at the spin-
dle. The difficulty in approaching this problem lies in the
inherent nonlinearities of the system, the complex nature of
the interactions at the spinal cord of the various sensory
feedback pathways together with spinal pattern generators
and local neural feedback pathways. There is also evidence
from experiments on intact human subjects that the neuro-
muscular system changes the loop gain with the load on the
system – a feature that is not replicated in many present-day
man-made control systems. This has been the subject of a fur-
ther servomechanism hypothesis by Marsden, Merton et al
[6], one of whom (Merton) was closely associated with the
earlier hypothesis of Hammond et al [3].

Within the control paths for a single muscle, the alpha
motoneurone provides the actuating input that causes the
extrafusal muscle fibres to contract. The alpha motoneurone
output is determined by a number of feedback loops as well as
the inputs from higher levels in the central nervous system.
These loops include the feedback from muscle spindle recep-
tors and Golgi tendon organs, feedback from joint receptors
and skin receptors and local neural feedback pathways at the
spinal cord, involving what are known as Renshaw cells which
provide recurrent inhibition. Also, while the activities of the
alpha and gamma motoneurones are essentially independ-
ent, the activity of the beta motoneurones causes contraction
of the intrafusal fibres as well as being related to the activity of
the alpha motoneurones, which leads to contraction of the
extrafusal fibres. The situation becomes even more complex
when the model attempts to represent the coordinated action
of a pair of muscles working together on a joint.

It is far from clear how the sensory feedback signals
and descending control signals interact. The effect of a sin-
gle feedback pathway on the overall system behaviour may
appear obvious but the complex nonlinear properties of
muscle and the threshold phenomena that are know to be
present in some of the feedback pathways make any meaning-
ful quantitative analysis or simulation very difficult. Detailed
models that attempt to incorporate the anatomical features
of the real biological system require knowledge of a large
number of parameter values, many of which are difficult, or
impossible at present, to estimate from experimental data.
Access to intermediate variables for model validation is also
extremely difficult in models of this type.

5 An alternative nonlinear model of
the neuromuscular system
One common assumption in models of the neuro-

muscular system is that the efferent signal that actuates the
load-bearing muscle is a pulse-frequency modulated signal of
strength proportional to the weighted sum of the relevant
afferent signals. There is, however, considerable well-estab-
lished experimental evidence that suggests that the force
developed by a muscle is controlled primarily by regulation of
the number of motor units that are active. As the required
force in the muscle increases, more and more units become
active. It is known that in a single unit the pulse frequency
increases with the overall load force until a saturation level
is reached beyond which no further increase occurs. If re-
cruitment of motor units is the most significant factor in the
development of tension in intact muscle this feature must be
incorporated into neuromuscular control system models. For
a muscle subjected to an imposed constant tension p(t), it is
reasonable to assume initially that the applied tension is
shared equally by the active units. If the number of active
units is n(t), the tension in each single unit of the load-bearing
musle must be p(t) / n(t). Traditional models of muscle, make
the implicit assumption that all the motor units are stimulated
in synchronous fashion, with the complete muscle acting as a
single unit. This is clearly incorrect, except in some rather
artificial experimental conditions, but it is reasonable to take
such a description as a model of a single active motor unit [6].
This provides a basis for quantitative assessment of the ideas
of a variable gain system that are implied by the hypothesis of
Marsden et al [7].

It is first of all assumed that, as in most previous models,
the outputs of the muscle spindle are proportional to the
overall length of the main muscle. It is also assumed that
some form of composite afferent signal from the muscle spin-
dles and other sensory receptors controls the number of
active motor units in the extrafusal load-bearing muscle. Pos-
sible models representing the stretch reflex under conditions
of controlled tension or controlled length would have the
forms shown in Figs. 2 and 3 respectively. If, in the model for
isotonic conditions, the fusimotor input is such that at a par-
ticular level of applied tension p1, the number of active units
is n1 and the muscle length is l1, then an increase of applied
tension will cause the length to increase and this will give rise
to an increase in the number of active units. Any increase in
the number of active units will tend to reduce the tension
within each active unit because of the action of the divider in
the forward path of the nonlinear feedback system. This

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Acta Polytechnica Vol. 44  No. 2/2004

Fig. 2: Block diagram showing stretch reflex model for conditions of controlled muscle tension



shows clearly that a form of negative feedback exists. In Fig. 3
no feedback path exists involving the active skeletal muscle.

It has already been noted that there is evidence that
suggests that the stretch reflex system is not a simple posi-
tion servomechanism. It is possible therefore that muscle
spindle receptors have a component of their output that is
proportional to muscle tension as well as the component pro-
portional to muscle length. An increase in either length or
tension would then tend to increase the number of active
units. The overall characteristics of the stretch reflex models
for isotonic conditions is altered very little by the introduction
of the tension path, but for isometric conditions the presence
of such a pathway completely changes the properties of the
model and introduces the possibility of an unstable condition
that would not otherwise exist. Such instabilities have been
observed experimentally under conditions of controlled mus-
cle length.

Tendon organ receptors have been included in this re-
cruitment model. The inclusion of tendon organs provides
an additional feedback pathway under isometric conditions.
A tendon organ discharge is known to have an inhibitory
effect on the motoneurones of its own muscle and must there-
fore act in opposition to the signals in the muscle spindle
pathway. The fusimotor input influences the spindle primary
discharge and thus may be expected to influence the number
of motor units that are active. For conditions of controlled
tension any increase of fusimotor activity will cause the mus-
cle to contract until a new equilibrium condition has been
reached. Conversely, any reduction of fusimotor activity will
cause the muscle to lengthen.

Although fusimotor inputs are known to play an impor-
tant part in the control of the neuromuscular system, it is also
known that active movements can occur in preparations in
which the feedback path from the muscle spindle receptors
has been opened. It follows that the system must incorporate
a second input that acts directly at the motoneurone pool.
This is the feed-forward input, referred to previously, that
appears to be used for the initiation of urgent movements for
which the time delays inherent in the gamma pathway would
introduce an unacceptable lag. Although the two inputs are
normally considered as being functionally distinct it is known
that they often work together and it has been suggested that
the relative amounts of activity in the two pathways may be
controlled by the central nervous system to suit the task being
performed.

It has been suggested that the feedback properties of the
neuromuscular system only apply for fusimotor inputs but
this is not necessarily true since in many forms of feedback
control input signals applied at different points in the loop
may have similar effects at the output. If, however, the con-
traction initiated by the direct pathway is so rapid that the
spindle discharge ceases, the system does become transiently
open-loop. This is one of the interesting effects of neural sig-
nal encoding through pulse frequency modulation. Large
negative effects at a sensory receptor may cause the neural
discharge to cease complete and the feedback signal to be
interrupted. This gives rise to a subtle form of nonlinearity in
a closed-loop system that may produce open-loop operation
on a transient basis.

The models of the muscle spindle currently available sug-
gest that there is a significant rate sensitivity component on
the spindle primary output but no similar rate sensitivity in
the secondary output. This could be regarded as a form of
rate feedback that would be beneficial in compensating for
the effects of pure time delays and other lags. There is a fur-
ther interesting observation that can be made here about the
pulse frequency modulated form of signal in neural pathways.
Since the signal strength is proportional to the inverse of the
time between adjacent spikes observed in the afferent nerve,
the primary discharge from the spindle could be said to show
a form of adaptive sampling. When the mechanical input is
changing rapidly the instantaneous frequency in the afferent
nerve will be high due to the rate sensitivity and the sampling
rate will be correspondingly high. This is clearly a desirable
situation in a control system.

The changes in the dynamic response of muscle spindles
observed when fusimotor inputs are applied suggests that, in
addition to producing changes of the equilibrium point, these
inputs may provide some form of adaptive compensation of
the stretch reflex through parametric changes at the muscle
spindles. It is possible, therefore that the static and dynamic
fusimotor pathways to the intrafusal fibres provide a means of
relatively independent control of the operating point and the
dynamic characteristics of the complete closed-loop system.

Discussion
One technological development that makes the study of

recruitment phenomena in muscle particularly interesting is
the recent development at a number of research centres,

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Acta Polytechnica Vol. 44  No. 2/2004

Fig. 3: Block diagram showing stretch reflex model for conditions of controlled muscle length



including SRI International at Menlo Park, California [8],
of actuators that expand and contract in response to electrical
stimuli. The development of a robotic actuator made up
of many strands of plastic artificial muscle fibre provides
interesting possibilities for a wide range of applications. The
inclusion of large numbers of sensors that can be embedded
in these artificial muscles, like muscle spindles and tendon
organs in real muscle, opens up the further possibility of
highly redundant control systems that resemble the structure
of the neuromuscular system and could begin to offer the
high levels of redundancy in terms of sensors, actuation units
and signal transmission pathways that seem to offer advan-
tages in the neuromuscular control system. Adaptive systems
that vary the gain and other system parameters with load
would become relatively easy to implement.

The pulse frequency modulation that is inherent in ner-
vous signal transmission has interesting consequences in
terms of control. As already pointed out, extreme conditions
can effectively cause feedback pathways to open transiently
and switch the control system from closed-loop to an open-
-loop mode. This form of nonlinearity could well be beneficial
in some circumstances and has already been introduced in
some forms of bang-bang control system, which effectively
operate in open–loop mode with maximum control effort ap-
plied except when the error becomes small and they change
to linear closed-loop operation. As has been noted above,
the pulse frequency modulation inherent in nervous signal
transmission can also be regarded as a form of adaptive
sampling and this has interesting implications in terms of
information transmission in man-made systems.

Conclusions
Any engineer must inevitably have respect for the excel-

lence of the design that can be seen in biological systems.
Unfortunately much of the fine detail is well beyond our
present understanding and cases where the results of these
natural design processes may appear to us to be imperfect or
puzzling may simply represent our failure to comprehend
fully the complexities of the situation.

One of the key elements of engineering design is that,
generally, we aim for simplicity and accept added complexity
only when we have convincing evidence that the gains exceed
the losses. Such losses may be associated with the inevitable
extra development or materials cost and the possible added
system life-time costs caused by a reduction in reliability and
additional maintenance demands. In contrast, complexity
does not appear to be expensive in nature, where prototype
testing is carried out on such a very large scale that an
enormous number of refinements can be tried [9]. While
biological systems appear to have a major advantage in terms
of the scope for innovative design by evolutionary optimisa-
tion, there are important limitations set by the kinds of
materials that can be used and the mechanisms that can be
employed.

Biological systems are also limited, if one accepts evolu-
tionary principles, in the sense that every new feature must
develop from an existing feature and there is no chance
of making the sudden giant developmental leaps that are

so common in the history of technology. Nevertheless it is
clear that the processes of evolution can tell us much that is
of value for specific engineering control systems that have
functions equivalent to easily identifiable biological systems.
The neuromuscular system is an excellent example because
of the obvious link to manipulator robots and other types
of robotic system. The subtle nonlinear and self-adaptive
features of the neuromuscular control system are beginning to
be understood and better knowledge of the biological control
system could well provide further ideas to explore in the de-
velopment of improved forms of man-made system. Im-
proved understanding of the normal operation of the
neuromuscular control system could also assist rehabilitation
engineers in developing ways of assisting , through controlled
functional electrical stimulation techniques, those who have
lost the functions of normal limb control.

References
[1] von Gierke H. E., Keidel W. D., Oestreicher H. L.

(Editors): Principles and Practice of Bionics. AGARD Con-
ference Proceedings No. 54. Slough (England): Techni-
vision Services, 1970.

[2] Rosenberg J. R., Murray-Smith D. J., Rigas A.: “An
introduction to the application of system identification
techniques to elements of the neuromuscular system.”
Trans. Institute Measurement and Control, (U.K.), Vol. 4
(1982), p. 187–201.

[3] Hammond P. H., Merton P. A., Sutton G. G.: “Nervous
gradation of muscular contraction.” Brit. Med. Bulletin,
Vol. 12 (1956), p. 214–218.

[4] He J., Maltenfort M. G., Wang Q., Hamm T. M.:
“Modelling neural control.” IEEE Control Systems Maga-
zine, Vol. 21 (2001), p 55-69.

[5] Halliday D., Murray-Smith D. J., Rosenberg J. R., Rigas
A.: “A frequency-domain identification approach to the
study of neuromuscular systems-a combined experimen-
tal and modelling study.” Trans. Institute Measurement
and Control, U.K., Vol. 14 (1992), p. 79–90.

[6] Murray-Smith D. J.: An Application of Modelling Techniques
to the Neuromuscular Control System. PhD Thesis, Univer-
sity of Glasgow, Chapter 6, 1970.

[7] Marsden C. D., Merton P. A., Morton H. B.: “Servo ac-
tion in human voluntary movement.” Nature, Vol. 238
(1972), p. 140–143.

[8] Anon: “Artificial muscles: Expansive thinking.” The
Economist, February 5th 2000.

[9] French M.: Invention and Evolution. 2th Edition. Cam-
bridge, Cambridge University Press, 1994.

David J. Murray-Smith

Centre for Systems and Control

Department of Electronics and Electrical Engineering
Rankine Building
The University of Glasgow
Glasgow G12 8LT, Scotland, U.K.

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Acta Polytechnica Vol. 44  No. 2/2004


	Table of Contents
	Biological Systems Thinking for Control Engineering Design 3
	D. J. Murray-Smith

	Computational Fluid Dynamic Simulation (CFD) and Experimental Study on Wing-external Store Aerodynamic Interference of a Subsonic Fighter Aircraft 9
	Tholudin Mat Lazim, Shabudin Mat, Huong Yu Saint

	Dynamics of Micro-Air-Vehicle with Flapping Wings 15
	K. Sibilski
	The Role of CAD in Enterprise Integration Process 22
	M. Ota, I. Jelínek


	Development of a Technique and Method of Testing Aircraft Models with Turboprop Engine Simulators in a Small-scale Wind Tunnel – Results of Tests 27
	A. V. Petrov, Y. G. Stepanov, M. V. Shmakov

	Developing a Conceptual Design Engineering Toolbox and its Tools 32
	R. W. Vroom, E. J. J. van Breemen, W. F. van der Vegte
	Knowledge Support of Simulation Model Reuse 39
	M. Valášek, P. Steinbauer, Z. Šika, Z. Zdráhal

	The Effect of Pedestrian Traffic on the Dynamic Behavior of Footbridges 47
	M. Studnièková


	Control of Systems of Reservoirs with the Use of Risk Analysis 52
	P. Fošumpaur, L. Satrapa

	A coding and On-Line Transmitting System 56
	V. Zagursky, I. Zarumba, A. Riekstinsh
	Speech Signal Recovery in Communication Networks 59
	V. Zagursky, A. Riekstinsh


	Simulation of Scoliosis Treatment Using a Brace 62
	J. Èulík

	Image Analysis of Eccentric Photorefraction 68
	J. Dušek, M. Dostálek

	A Novel Approach to Power Circuit Breaker Design for Replacement of SF6 72
	D. J. Telfer, J. W. Spencer, G. R. Jones, J. E. Humphries
	Numerical Analysis of the Temperature Field in Luminaires 77
	J. Murín, M. Kropáè, R. Fric

	Computer Aided Design of Transformer Station Grounding System Using CDEGS Software 83
	S. Nikolovski, T. Bariæ


	Recycling and Networking 90
	T. Bányai
	Response of a Light Aircraft Under Gust Loads 97
	P. Chudý

	Preliminary Determination of Propeller Aerodynamic Characteristics for Small Aeroplanes 103
	S. Slavík