Title: International Federation
1- International Federation
- of Automatic Control
- EMERGING AREAS PROJECT
- Rotterdam August, 2003
- The goal of the on-going Emerging Areas project
is to identify recent significant trends that are
likely to continue within the automatic control
field. The 2003 outcome of the project was a
Panel Session. Presentations from that Session
follow, - Introduction to Emerging Areas Project
Slide 7 - Integrated / Embedded Control
Slide 17 - Distributed Control (over Communication
Networks) Slide 24 - Collaborative Control
Slide 30 - Hybrid/Discrete Event Systems/Networks
Slide 36 - Autonomous Systems
Slide 43 - Closing Comments Slide 48
2IFAC NEWSLETTER
- IFAC Technical Board Identifies Emerging Areas
-
- The goal of IFAC is to promote (in both theory
and applications) science and technology of
control in all systems, whether engineering,
physical, biological, social or economic. In
support of this goal, the IFAC Technical Board
maintains on-going efforts to identify trends and
forecast emerging areas within our field. The
Technical Boards most recent formal activity
regarding this thrust was a Workshop and Panel
Session held in Rotterdam, The Netherlands, in
conjunction with the IFAC Symposium on System
Identification (SYSID). -
- The goal of the 2003 Emerging Areas Workshop /
Panel was, -
- Identify emerging trends within the
control system and automation field - Forecast tomorrows most significant
applications which will achieve higher
performance, increased efficiency, lower cost, or
other benefits - Identify the likely control methodologies
and implementations that will enable such future
improvements. -
- WORKSHOP Participants in the Workshop portion
of the meeting were members of the IFAC Technical
Board and selected Invited Guests from Dutch
industries invited by the Dutch NMO. Each
participant was asked to suggest
trends/developments/needs within their respective
areas of competence. As a result, over 50
suggestions were presented and considered during
the afternoon Workshop. (A complete inventory of
all these suggestions is available at the IFAC
web-site as described below.) -
3 -
- After presentation and discussion of the various
suggestions by each participant, several of the
related suggestions were combined, and a final
list was then prioritized to identify the
following major trends believed to be especially
significant -
- Increased Development of Theoretical
Techniques and Practical Application of Hybrid /
Discrete Event Systems - Increased Development and use of
Distributed Control Techniques (Especially for
Applications using Wireless communication
Technology) - Continued Theoretical Development and
Applications for Nonlinear Control to Overcome
Limitations with Linear Representations / Models - Increased use and Development of
Innovative, Ubiquitous Sensors and Actuators
MEMS will Enable many New Sensors - More Effective Subsystems Operating at
Optimal levels will be Integrated and Embedded to
yield Improved Overall Systems - Interest in Learning Control Systems
will Intensify the Name Adaptive Control may
Not be Used, but the Concepts will Continue - Autonomous Robots and Autonomous Vehicle
Development will Continue as Enabling
Technologies Advance - Fault Detection / Isolation and
Predictive Maintenance Techniques will greatly
Improve operation of Highly Complex Systems - Collaborative Robots will assist and
collaborate with Humans in Complex and/or
Difficult Work Environments - Tools that Facilitate Collaborative
Human-to-Human Work and Activities (e.g. E-Work
and collaborative robotic systems) will Develop - New Hard and Soft Sensors will be
Developed for Biotechnology and Biomedical
Applications - Artificial Intelligence and Agent-Based
Models will become more Useful for Controlling
and Improving Economic Systems - Dramatic Automotive Control Advancements
will Continue to Improve Safety, Operation, and
Vehicle Efficiency - Autonomous Systems will Become Practical
for Complex Operating Environments - Control Technologies will enable
Realization and Deployment of next-generation
high-performance Nano and Micro Systems future
Controllers will benefit. -
4 -
- PANEL SESSION The above trends were further
reviewed and several were selected and refined
for presentation in an evening Panel Session,
attended by many of the SYSID Symposium attendees
and members of the Dutch NMO. The allowable time
for the Panel Session was of course limited, so
only five trends were selected for the Panel
Session. The highlights of these presentations
are, -
- Integrated / Embedded Control
- Significant developments over the last decade
within several different technologies now enable
practical implementation of new control
architectures. These advancements include
innovative sensors actuators (many based on
MEMS techniques), more powerful computers
Digital Signal Processors, and exciting
breakthroughs in communications network
technology. As a result, two distinct trends are
now gaining momentum within control. The first
trend is integration such that perception
(measurement, sensing) can now be embedded with
control (controller, actuator) so that these
previously separate functions are now
transparent in fact, single components may
someday sense, determine what to do, and then
carry out the desired actions. The second trend
is distributed control over wireless (and
conventional wire-based) communication networks
to connect embedded controllers into an overall
closed loop operation. Such integrated/embedded
controllers will enable improved medical
technologies, increase energy efficiency, advance
vehicle control, and enable many new consumer
products. -
- Distributed Control (Over Communication Networks)
- Recent developments within both control theory
and hardware tools now enable distributed
control to become a practical reality. Numerous
subsystems, each with their respective level of
autonomy (but not co-located), can be integrated
to control highly complex systems. As
distributed control has progressed, it is common
for large numbers of different types of
components to exchange information through
dispersed communication networks furthermore,
recent developments of wireless communication
offer yet another tool for this field. Although
control, information theory, and communications
are mature disciplines, theoretical issues in
information theory and its effect upon
performance of distributed control (conflict
resolution, resource allocation, avoidance of
deadlocks, etc.) are not well understood. Future
control theory will address the impact of
communication channel delays, quantization
errors, transmission noise, random loss of
information, as well as data handling and safety
reliability. Attention will also be given to
practical design of encoders, decoders,
estimators, filters, and other communication
elements to achieve improved performance,
efficiency, and decisions made by large numbers
of distributed controllers. -
5 -
-
- Collaborative Control
- Distributed systems are typically composed of
numerous lower-level sub-systems with their
individual control tasks and responsibilities.
Collaboration among such interrelated systems is
clearly essential in order to benefit from the
respective strengths of the several partners.
Fortunately, collaborative control trends are
apparent for all system types. Machine-Machine
Cooperation of smart robotic teams (including
micro- and nano- as well as routine robots)
will improve as new collaborative control
techniques are developed as faults, errors, and
interactions are better managed and as protocols
for fault-tolerant operation are developed.
Human-Machine Better understanding of how to
share tasks will improve operation and will
come from improved software, more incorporation
of human factors, continued adaptation (learning)
by the machine, better displays, new types of
feedback, and new sensors actuators better
tailored for human users. Human-Human Human
team performance will also improve as
enterprise software integrates and aids team
decisions, as new methods (e.g.
internet-conferencing) improve team coordination
(even when remotely located with different
databases, culture, or knowledge disciplines),
and as task optimization methods enable multiple
workers to share work and reduce local overloads.
-
- Hybrid / Discrete Event Systems / Networks
- Continuous (and discrete) Time systems and
Discrete Event systems have essentially been
developed independently of each other. However
both phenomena frequently appear in the same
process. Examples include manufacturing, process
control (start-up/shut-down), autonomous, and
distributed control systems. Radar processing
provides a specific example which requires
dynamic estimation of whether or not a target is
present, what type target, whether or not it is
maneuvering, forecasted track movements, etc.
Typical solutions are sequential which involves
detection, then classification, estimation, etc.
Such approaches are clearly sub-optimal.
Combined solutions for such Hybrid systems will
no doubt develop in the future. New controllers
will be driven by the need for higher performance
from such systems, as well as the need to make
better use of resources and an increased use of
embedded/integrated systems. Theoretical
developments are already being addressed and, as
proven performance improves and reliability
autonomy increase, the number of applications
will grow. Controllers for such systems will
probably be more complex than earlier solutions,
and development of such methods will require
merging of heretofore different fields and
different designer approaches (sometimes even
with different methods and solution languages). -
6 -
-
-
- Autonomous Systems
- Todays automotive industry offers numerous
innovations including driver assistance (ABS,
ESP, Distance Detection), suspension control
(passive), self-diagnostics, improved comfort
(climate control, lighting, seats,
entertainment), and more precise engine and
driveline control. Emerging developments include
drive-by-wire, brake-by-wire, parking assistance,
collision warning, pedestrian detection, active
suspension control, noise vibration control,
and a host of telematics (navigation, on-board
e-services, etc.). These developments will
improve vehicle safety and, when coupled with
infrastructure improvements, will yield
intelligent traffic control. These developments
will also leverage developments in autonomous
unmanned vehicles for situations such as
operation in hostile environments. Such vehicles
will plan their own operations, as well as
control the vehicle, to achieve these goals and
develop alternate strategies when failures or
unexpected hindrances are encountered. These
autonomous concepts will also be extended to
other applications such as unmanned factories and
processing plants. -
- Post Session Comments
- Various comments that have been submitted since
the Panel Session begin at Slide 48 in this file.
If you would like to add your comments, please
send them to m.masten_at_ieee.org -
- Mike Masten, Chair, Technical Board
7IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- INTRODUCTION TO PROJECT
- Presenter Mike Masten
8IFAC EMERGING AREAS PANEL DISCUSSION
-
- Introduction to IFAC
- Goals
- Activities
- Goals of IFAC Emerging Areas Project
- Emerging Areas Process
- Panel Session
- Panelists Presentations
- Industrial Guest Evaluation Feedback
- Audience Comments Questions
9INTERNATIONAL FEDERATION OF AUTOMATIC CONTROL
- Goal Promote science and technology of control
in the broadest sense in all systems, whether,
for example, engineering, physical, biological,
social or economic, in both theory and
application. Also concerned with the impact of
control technology on society. - Activities Organize technical meetings,
publications, and any other activities consistent
with IFAC constitution which enhances the
interchange and circulation of information on
automatic control activities.
10IFAC MEETINGS
- CONGRESS
- Major IFAC event, Held every Three (3) years
- Recent Forthcoming Congresses
- 2002 Barcelona 2005 Prague 2008
Seoul - SYMPOSIA
- Long Term Events on Master Plan, usually Held
Triennially - CONFERENCES
- Technical Events, not Necessarily Part of a
Series - WORKSHOPS
- Smaller Events, less Formal
11IFAC PUBLICATIONS
- IFAC NEWSLETTER
- Current IFAC News Information and Up-to-Date
Announcements of Forthcoming Events - AUTOMATICA
- Papers on Original Theoretical and Experimental
Research and Development, Involving all facets of
Control Theory and Applications - CONTROL ENGINEERING PRACTICE
- Papers which Illustrate Applications of Control
Theory and its Supporting Tools Emphasizes
Practical Results - ANNUAL REVIEWS IN CONTROL
- Best IFAC papers Presented at Meetings,
re-written, and Broadened (or Commissioned
Reviews in Emerging Research areas) - JOURNAL OF PROCESS CONTROL
- Papers Relating to all Aspects of Chemical
Process Control - ENGINEERING APPLICATIONS OF ARTIFICIAL
INTELLIGENCE - Papers Relating to Intelligent Real-Time
Automation - AFFILIATED JOURNALS
- Usually associated with a Technical Committee
List Available from IFAC Secretariat
12IFAC TECHNICAL AREAS
13IFAC EMERGING AREAS
- EMERGING AREAS PROJECT
- GOALS
-
- Identify the Major Emerging Trends within the
Control System and Automation Field - Forecast Tomorrows Most Significant Applications
which will Achieve Higher Performance, Increased
Efficiency, Lower Cost, or Other Benefits - Identify Likely Control Methodologies and
Implementations that will Enable Future
Improvements -
14IFAC EMERGING AREAS
- PROCESS
- Workshop
- Consideration Potential Significant
Trends/Forecasts - Selection Most Significant Trends/Forecasts
- Preparation Breakouts to Prepare for Panel
- Panel Session
- Presentation Workshop Conclusions
- Evaluation Industrial Guest Feedback
- Discussion Audience Questions Comments
15IFAC EMERGING AREAS
- PARTICIPANTS
- IFAC Technical Board Members
- Tohru Katayama Ruth Bars
Robert Babuska - Anibal Ollero Shimon Nof Denis Dochain
- Philipp Nenninger Keith Godfrey Talha
Dinibutun - Sirkka-Liisa Jamsa-Jounela
Alberto Isidori - Dongil Cho
- Industrial Guests
- Herman Van der Auweraer (Lueven Measurement
Systems) - Fred Abbink (National Aerospace Lab NLR)
- Ton Backx (IPCOS Technology)
- Hans Driessen (Thales)
- Alex van Delft (DSM)
16IFAC EMERGING AREAS
- SOME OF THE CONSIDERATIONS
- Adaptive Control MEMS Driving Assistance
Smart Drugs - Robotics Manufacturing Artificial
Intelligence Radar - Optimization Navigation Speaking
Animals Plants - Telepresence Distributed Systems
Wireless - Software Agents Switching Control
Learning Control - Ubiquitous Sensors Actuators
Perception Systems - Stochastic Agriculture and
Crops BioTechnology - Economics Business Airports/Aerospace
- Transportation Systems E-Work Hybrid
Systems - Bio-Informatics PDE
Systems - Water/Waste Management Computers Control
- Infinite Dimensional Systems
- Intelligent Systems Modeling Identification
17IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- TREND INTEGRATED / EMBEDDED CONTROL
- Presenter Anibal Ollero
18Panel Session PresentationEmbedded Control
- Ollero (Univ. Sevilla, Spain),
- R. Babuska (Delft University of Technology, The
Netherlands) and - H. Vander Auwerarer (IMS, Belgium)
19 EMBEDDED CONTROL
Embedded controllers
Control System
Embedded control separates control into
subsystems of the overall system, e.g. Hands,
Arms, Feet, Wheel
20 Enabling technologies
- Sensors and actuators with embedded
intelligence. - MEMS as supporting technology.
- Computer developments embedded systems with
increasing powers. - Communications/Networks.
21 Forecast/trends in control applications
- Medical technologies, health care surgical
devices, medical instruments. - Communication technologies network control,
wireless devices. - Advanced vehicle control.
- New cars, vehicles and transportation
technologies. - Technology for energy savings
- mixed energy sources, small scale energy
systems. - Consumer products, instruments, MEMS.
Performance, reliability, cost, easy to use and
maintain.
22 Most significant technological trends
- Two poles
- Integration
- Embedded control systems integrating perception
and control functions that can be used,
eventually, in a transparent way. - Reasons Technological developments (Hardware
integration, MEMS, ) and new applications
(vehicles, autonomous systems, consumer products,
biomedical systems, ) - Distribution
- Distributed control systems with wire and
wireless connections between components and
embedded controllers. - Reasons Communications technology and new
applications (Tele- applications, distributed
manufacturing, protection of people and
environment, home automation, .)
23 The single trend/forecast
- Integration of control and perception components
in embedded systems that could be networked using
wire or wireless technologies.
24IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- TREND DISTRIBUTED CONTROL (OVER COMMUNICATION
NETWORKS) - Presenter Philipp Nenninger
25Control of systems distributed over communication
networks
- R.Bars, A.Isidori, P. Nenninger, A.Ollero
26Motivation
- More and more systems are becoming distributed,
consisting of a large number of components of a
very different nature, which exchange information
through wire/wireless networks (Wireless
communications in the loop) - While control, information theory communication
are mature disciplines, little effort has been
put so far in understanding how issues in
information theory affects the performance of a
distributed control system
27Theoretical Challenges
- Design of
- Encoders
- Decoders
- Communication channels
- Controllers / estimators
- To achieve prescribed performances with minimum
loss, high efficiency and with decisions made by
a large number of users
28Theoretical Challenges
- Quantitative analysis of how the performance of
the system is affected by - Bandwidth
- Delays
- Quantization errors
- Transmission noise, loss of information
- Data handling / control of data flow
- Safety / reliability issues
- Conflict resolution / avoidance of deadlocks
- Resource allocation
29Emerging Application Areas
- Technologies for safety critical and hostile
environments - Remote control and coordination of unmanned
vehicles (UAV, UGV, AUVs) - Telepresence
- Remote laboratory
- Remote surgery
- Distributed manufacturing
- Home automation
- Ubiquitous sensors
30IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- TREND COLLABORATIVE CONTROL
- Presenter Shimon Nof
31Trends in Collaboration Presented by Shimon Y.
Nof Purdue University, USA and Stephen
Kahne Embry Riddle University, USA For the IFAC
Technical Board Meeting Rotterdam, Holland,
August 2003
32 Machine Machine
Overall Trend Smart robotic teams (normal,
micro, nano robots) will be able to interact even
better than human teams Trend 1. Collaborative
Coordination Control Theory Safety is
critical Enable unmanned manufacturing and
maintenance Trend 2. Control Methods to Manage
faults, errors, conflicts, and interactions
Save money Improve product uniformity Trend
3. Control Protocols for fault-tolerant,
time-out integration of information
signals Future collaborative machines will
depend on cheaper, redundant arrays/networks
(e.g., FTTP)
33 Human -- Human
Overall Trend Smart tools and collaboration will
enable significantly better complex system
performance Trend 1. Interoperability of
software for enterprise applications
Integration of team decision support, e.g. air
traffic control, ERP, supply networks Trend 2.
Coordination of team members interactions
Geographic remoteness of collaborating members
Members have different databases, culture,
knowledge Trend 3. Optimization of parallelism
among resources Two (or more) heads are
better than one Overcome overload of tasks
34 Human -- Machine
Overall Trend Better understanding of how to
share tasks Trend 1. Impedance matching
Software Human factors -- information
usability Process goals adjustment-adaptation
(learning) Trend 2. Performance monitoring
Better displays New forms of feedback Trend
3. New sensors and actuators Fly by
everything e.g. , by wire , light
Understand who is the human customer/partner/user
35- CONCLUSIONS
- Collaboration in distributed operational systems
is critical - Collaboration must be optimized to benefit from
respective strengths of the partners - Control theory and applications must be developed
and verified to enable this new control
environment trend
36IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- TREND HYBRID / DISCRETE EVENT SYSTEMS / NETWORKS
- Presenter Hans Driessen
37 IFAC Emerging Areas Panel Session
Presentation Hybrid/Discrete Event
Systems/Networks Hans Driessen Thales, The
Netherlands Pedro Albertos Universidad
Politecnica de Valencia, Spain
38Hybrid/Discrete Event Systems/Networks
Motivation Continuous (and discrete) time
systems at one hand and discrete event systems on
the other hand have been studied / developed
independently of each other, but often appear in
the same process. An incomplete list of
application areas isdistributed control
systems, autonomous systems, manufacturing,
process control (start-up/shut down), radar
processing management. 1. What is the
forecast? The forecast is that we will see a
combined treatment in the future.2. Why is this
forecast likely to happen? This is due to the
ever higher performance requirements, e.g. a
shorter dead-time. Also better use of the
resources, Embedded systems, and Integrated
control design.
39Hybrid/Discrete Event Systems/Networks
3. When is this forecast likely to
happen? Theoretical developments are taking
place right now.
- Theoretical Challenges
- Integrate the control design and its
implementation - Develop the joint theory for hybrid systems and
their control - Include the delays and randomness of the
communication networks
Applications will appear in coming years.
40Hybrid/Discrete Event Systems/Networks
4. What will be the impact when this
happens? Higher performance of systems. Broader
spectrum of applications. Increased reliability
and autonomy.5. Are there any adverse effects
of this development? Increased complexity of the
problem /solutions6. What must happen for this
forecast to come true? Combine different fields,
people, even language- Control and Real Time SW
expertise (difficult)- Continuous/discrete time
control and discrete event systems (easier to
combine)
41Hybrid/Discrete Event Systems/Networks
IllustrationsSome of these ideas can be
illustrated with a typical area of applications
namely, radar systems. In radar processing we
encounter dynamic estimation problems including
both discrete and continuous state variables. The
discrete variables amount to whether an object is
present or not, whether it is maneuvering or not,
what type of object it is from a known class of
possible objects. So infact there are
simultaneous, dynamic, stochasticdetection/estima
tion/classification problems. In radar
management we encounter both continuous and
discrete parameters to be selected on-line for
every transmission in order to maximize
performance. This involves calculations of
expected performance for hybrid systems and
control schemes for obtaining the maximum of
performance.
42Hybrid/Discrete Event Systems/Networks
Illustrations ContinuedUp to
now most of the simultaneous detection /
estimation / classification problems are treated
sequentially, more or less independent so we
first try to detect, then estimate, and then
classify. This is sub-optimal and leads to all
kind of smart and tricky algorithms. This is not
only sub-optimal, but also hard to reuse from
application-to- application. Significant
performance improvements can be obtained by
solving the problems simultaneously, but this
induces a computational problem that cannot be
solved with traditional techniques, or at least
very difficult. Particle filtering, or
Sequential Monte Carlo filtering, is a technique
that is very well-suited for solving problems
including discrete variables, nonlinearities,
constraints etc. These algorithms lead to
well-understood algorithmic solutions that are
easily re-used, saving considerable development
time and costs.
43IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- TREND AUTONOMOUS SYSTEMS
- Presenter Anibal Ollero
44Panel Session PresentationAutonomous Systems
- Ollero (Univ. Sevilla, Spain),
- R. Babuska (Delft University of Technology, The
Netherlands) and - H. Vander Auwerarer (IMS, Belgium)
45Industry Trend Advanced Vehicle Control
- Increasing role of vehicle electronics.
- Current functionality
- Engine control
- Driver assistance (ABS, ESP, distance detection)
- Suspension control (mainly semi-active)
- Diagnostics (ABS)
- Comfort (climate control, lighting, seats)
- Supported by standards such as CAN bus etc.
46Industry Trend Advanced Vehicle Control
Emerging functionality X-by-wire
drive-by-wire, brake-by-wire. Driver assistance
(parking assistance, speed control, dangerous
maneuvering) Active safety measures (collision
warning, pedestrian detection) Active suspension
control Active noise and vibration
control Telematics (on-board e-services,
navigation and beyond)
47 Autonomous systems
- Autonomous vehicles
- UAV, UGV, AUVs, multiple vehicles
- Autonomous functions in conventional vehicles
(cars, aircraft, vessels, ..) - Driver overrule (collision avoidance, lane
control, ..) - Intelligent Traffic Control
- Technologies for safety-critical and hostile
environments - space, disaster remediation, defense, ..
- Combination of autonomy and Teleoperation.
- Unmanned plants.
- Application of learning, uncertainty handling and
AI techniques. - Autonomous perception.
- Reactivity and planning techniques.
- Reliability is a main issue.
48IFAC TECHNICAL BOARD
- AUGUST, 2003
- IFAC EMERGING AREAS
- PROJECT
- CLOSING COMMENTS
49- Closing Comments
- The comments on the following slides were
received after the Workshop and Panel Discussion.
These comments do not necessarily represent the
collective opinions of the participants, but
rather the individuals who submitted them. These
comments are provided to stimulate further
discussion of this important subject. - If you would like to contribute additional
comments, please sent them to Mike Masten at
m.masten_at_ieee.org Comments regarding trends that
you believe will be highly significant within our
field are especially welcome. We will
periodically update this section of this
presentation if such comments are submitted.
50- I wrote down some remarks/items on which I will
be happy to contribute more. - The summary discussion highlighted some of the
developments (in theory, technology and
applications) that are linked to our field of
research. It appeared to me that the audience
liked the structured way in which Shimon Nof
presented the different trends M-M, H-H, H-M. It
was hard to find trends (in his and other
presentations) that did not imply 'more of the
same or make things better' (in terms of
reliability, working domain, robustness). - It should be stated that complexity is the enemy
of reliability. Hence, understanding complexity
and trying to cope with it are key issues in
theory and technology developments and in the
design of applications. Trends that host 'the
complexity virus' are the drive to increase
automation, implement intelligent (autonomous)
sensor- and actuator systems, link/teleconnect
systems that are different in nature (causing all
kinds of unexpected 'dynamics') and that are at a
far distance. - I personally disagree that the gap between
practical problems and research at the university
is so big. I think industry is not capable to
formulate their problems such that these can be
worked on by academia and serve as an educational
podium. Industry and academia have different
missions! - I hope these remarks are helpful for further
discussion. - _______________________
- Peter A. Wieringa Man-Machine Systems,
Mechanical Engineering - Faculty of Design Engineering, Delft
University of Technology TU Delft
51- I am uncomfortable with Peter Wieringa's
comments. He more or less reduces the sense
of urgency to close the gap between academia and
industrial practice (the well known time-delay),
whereas in the Panel Discussion we were quite in
agreement about the gap and the need to overcome
it. Remarks made at the end of the session about
the thoroughness of the meeting clearly suggested
that we should repeat these kind of sessions and
to devote more time to this challenge. - Anonymous Comment
- I agree the gap between practical problems and
university research is not that large, but we
should not try to identify who is responsible for
the gap. I believe we have to avoid a
formulation where it may appear that the problem
is in "the other camp". The most fruitful
approach, which was also the spirit of the panel
meeting, is "What we can learn from each other",
industry by (early) understanding the trends in
fundamental research (what is possible), academia
by understanding the (long-term) industrial needs
and applications (what is needed, where can this
be actually used). While the missions are indeed
different, in the long run, they touch. We both,
industry and academia, have to look beyond the
scope of our classical, daily, way of thinking,
and this requires efforts from both sides. The
result is a cross-fertilization of ideas, methods
and applications that does not follow a simple
linear model (such as industry needs -gt
university develops -gt industry uses). I am
convinced many good examples of such efforts
exist and I felt that the panel meeting was held
in this spirit. - Herman Van der Auweraer
52- I do not fully agree with the remark of Peter
Wieringa saying that industry is not capable to
formulate their problems such that these can be
worked on by academia ... etc. I accept it as a
personal remark and opinion, but we should
perhaps be a little careful that IFAC is not
identified with this (slightly arrogant) view. - Anonymous
53IFAC EMERGING AREAS
- THANK YOU
- To IFAC Technical Committee and Coordinating
Committee Chairs - Identification of Potential Forecasts/Trends
- Presentation of Forecasts/Trends for
Consideration - Participation in Workshop and Panel Session
- To Industrial Guests
- Identification Presentation of Potential
Forecasts/Trends - Participation in Workshop Panel Session
- Evaluation/Feedback at End of Panel Session