2nd German-West African Conference on Sustainable, Renewable Energy Systems SusRes – Kara 2021 

Poster Contributions  

https://doi.org/10.52825/thwildauensp.v1i.21 

© Authors. This work is licensed under a Creative Commons Attribution 4.0 International License 

Published: 15 June 2021 

Education 4.0: An remote approach for training of 
intelligent automation and robotic during COVID19 

H. Smajic 1[https://orcid.org/0000-0002-0669-1979], T. Duspara 1[https://orcid.org/0000-0002-6985-5950] 
1 Technische Hochschule Köln 

Abstract. The COVID-19 pandemic confronts universities with great challenges to maintain 
research and teaching activities with as little contact as possible. Lecturers currently have to 
migrate to Internet teaching. In most cases, e-learning and digital tools are used to continue 
online courses to replace classroom teaching. But current online approaches are limited to 
just lectures and theoretical mathematical exercises. In this paper it will be shown how 
practical exercises can be carried out remotely via internet in a real technical environment. 
Experimental laboratory equipment for automation technology and mechatronics is always 
associated with high costs. The reason for the high investments are the costs for different 
intelligent devices within an automation solution and the costs for extensive engineering. 
Beyond the costs, the number of workstations usually does not correspond to the required 
number of students to be trained. In this case, the same exercises have to be repeated 
several times, which also leads to in-creased personnel costs.  

Remote laboratories are a very cost-effective solution for these problems. This paper 
describes how this goal can be achieved by implementing a WBT server (WBT - Web-Based 
Training Server) and a Java-based client-server architecture. The idea behind a remote 
controlled laboratory is to use web technologies and the Internet as communication 
infrastructure to perform an experimental part of the training with programmable automation 
devices. First of all, a detailed requirement profile for the laboratory was developed. Primarily 
technical, didactical and organizational requirements are concerned. In addition, the 
laboratory is to improve the education of the students by interactive, problem-oriented 
learning on real industrial automation components. The aim of the training is to learn suitable 
working methods for the design (engineering) of complete automation solutions starting from 
simple to medium complex machines and plants. 
Keywords: Education 4.0, Remote Lab, IIoT, COVID-19 

Introduction 

The use of online automation engineering in general has thus far not found any sweeping 
acceptance on the operating side. The engineering capable of being performed via world-
wide data paths and by means of multi-media tools are thus far advances of innovative 
manufacturers of capital goods who, in this way, ensure themselves new unique selling 
points compared with their competitors. 

This type of manufacturer-driven approach neglects important customer interests 
through the proprietary design and the differing manners of communication of the systems. 
The reasons for this trend lie in the fact that many manufacturers have initially striven for 
support by their own service personnel, especially during the commissioning phase. The 
finding phase of the suppliers with respect to online engineering that is still continuing makes 
the path towards a uniform communications standard for use in the industrial environment 
more difficult. The latter has been prevented in particular through the rapid changes in the 
field of various information and communication technologies [1].  

265

https://creativecommons.org/licenses/by/4.0/


Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

Some concepts for the provision of diverse machine-related services via remote control 
of these machines by humans with information technology tools have already been 
developed. These constitute comprehensive solutions for IT-assisted service scenarios with 
the involvement of the organizational structures of manufacturer and operating company that 
above all make clear the complete host of services that can be reproduced on the basis of 
modern-day information and communication technologies [2]. The use of the 
communications infrastructure of the Internet itself is becoming increasingly established in 
this field and, as a result, will develop far-reaching potential for the future online engineering. 

Nevertheless, the introduction of online engineering brings with it major challenges for 
the companies. Many of these companies are placing their faith in differing suppliers in the 
field of machines and machine control, with the result that the large number of 
heterogeneous components and online service solutions offered, prevents any efficient 
organization of remote access that represents a further precondition for a comprehensive, 
inter-compatible and future-oriented introduction of online service in the field of remote 
control access. Operating companies of Online supportable, production systems are 
consequently faced with high infrastructure and organizational costs as they constantly have 
to administer the large number of different systems in order to keep them available for 
possible use. 

In this respect, the world-wide operating, major manufacturers of online engineering 
systems offer comprehensive services that have already been taken into consideration in the 
planning of the installations, however, the well-known problems of the proprietary solutions 
and the difficulty with integration into company infrastructures continue to exist. In detail the 
following weaknesses of current remote. In detail the following weaknesses can be shown: 
• Users are confronted with different online service solutions. 
• Insufficient compatibility to allow in-house usage of proprietary systems.  
• High requirements for safety of operator and machine. 
• High requirements for security of system access and network. 
• Version conflicts due to different software updates. 
• Current complexity allows operation by experts only. 

Available automation concepts 

In process and manufacturing automation, the demands for increasing productivity and 
flexibility while maintaining consistently high quality standards are constantly growing in the 
face of intensifying competition. This development leads to increasingly complex 
requirements for control concepts and implies a further increase in the complexity of 
automation tasks. In order to meet these continuously changing requirements, decentralized 
control concepts are subject to constant change towards distributed systems with open 
interfaces. This change is also favored significantly by the daily growing performance 
potential of microelectronics and information technology [3, 4]. As a result, numerous 
centralized and decentralized control concepts have emerged in automation technology, 
which can be classified primarily according to their topological, functional and communication 
aspects (Figure 1). 

266



Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

 

For the control tasks of simple machines, which predominantly require binary signal 
processing in the form of logic or sequence control, central programmable logic controllers 
are still used. In complex machines and plants, a decentralized and modular network of 
individual controllers is increasingly replacing centralized structures. These are usually small 
and medium-sized control systems or intelligent sensors and drives directly on the machine 
or plant, which are networked with each other via appropriate field buses. In order to protect 
employees and the environment, safety-oriented control components and safety-oriented 
communication systems are used in complex plants and in the field of infrastructure 
applications. A continuous process is guaranteed by the use of redundant and highly 
available systems (HSBY).  

A new generation of decentralized control systems is significantly influenced by the 
spread of industrial Ethernet and web technologies. By consistently integrating these 
technologies, various problems of existing fieldbuses, such as openness and manufacturer 
independence, can be solved. These protocols have been successfully introduced right down 
to the control level. It is undisputed that this trend towards further integration will continue 
right into the field level. The introduction of Ethernet and the shifting of control functionalities 
to the field devices and drives requires further functional changes to the controllers and 
control systems when they are integrated into the higher automation structures, which 
consequently also affects the engineering and thus their software tools. The specification of 
different device descriptions (FDT, GDS, EDS, etc.), which are made available to the user by 
corresponding user organizations, is particularly helpful for the integration of these 
technologies.  

The design of an automation solution depends of machine size and market segment, 
where automated equipment can be applied. The main criteria for building of automation 
architecture are: number of digital and analogue Inputs/Outputs, intelligent channels, type of 
fieldbus, remote access, high availability and safety. 

Figure 1. Available automation concepts for machine and plants 

267



Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

Training in real and virtual environment 

The currently most widespread model for knowledge transfer at European universities is still 
characterized by passive lectures and exercises. However, such knowledge transfer through 
theoretical input in engineering courses always suffers from a low recall rate. At the Faculty 
of Vehicle Systems and Production, application-oriented teaching is provided with the 
support of practical exercises and group work. Although the recall rate with this approach is 
as high as 32% after three months, the number of dropouts is still too high. One of the main 
reasons for this dropout rate is an excessively high level of abstraction in the transfer of 
knowledge in mechatronic modules. This problem makes it increasingly difficult to find 
candidates who can carry out internal project work in the form of individual projects, 
interdisciplinary projects and master projects. The current shortage of skilled workers in 
Germany is also intensify-ing the competition between universities and industry, since even 
the few existing candidates with specialist knowledge prefer to write their theses in industry. 
 

 

 
The main focus of this project is the development of teaching content with a high practical 
relevance for areas of automation technology. The previous rather passive and theoretical 
learning should be supplemented by the experience in the practical environment and would 
lead to essentially better and more efficient learning results.  

For this purpose, technical workstations have been developed which enable active 
experience and experimentation. Such an approach can make the level of abstraction of 
complex programming tasks much more comprehensible through personal experience with 
all sensory organs and through cooperation and communication with others. It can even 
increase the above-mentioned recall rate to 65% and thus lead to significantly better learning 
outcomes. 

Design of an automation solution for practical education 

With the aim of providing students with a modern education in the field of automation 
technology, the Cologne University of Applied Sciences and Schneider Electric GmbH have 
designed a range of equipment to meet the needs of the students. Care was taken to ensure 
that as many and innovative automation technologies as possible were taken into account. 
Because of the investment security, the selected components should not be on the market 

Figure 2. Various training opportunities in higher education 

268



Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

for longer than two years. A classification of these technologies, which had to be considered, 
is shown in Figure 3. 
 
 

 
 

 
Inductive and capacitive sensors, optical encoders and data carriers for radio frequency 
identification (RFID) are provided for the acquisition of binary and analogue process signals 
and are connected to the programmable logic controller (PLC). A modern mid-range PLC 
with numerous external modules was selected for processing the process signals. For the 
tasks "operating and monitoring", sophisticated HMI touch panels with colour display are 
used. Each station is equipped with modern electronic drive components. A frequency 
converter is used to practice clockwise and counter-clockwise rotation and commands for 
constant speeds and constant torque. A linear axis with servo motor and servo controller can 
be used to perform various tasks with positioning control. All components are networked via 
CANOpen fieldbus. Profibus DP is also available as an option. In this way, students can 
configure field buses and learn about their communication protocols. All stations are 
connected to each other via Industrial Ethernet, so that access to web servers of individual 
components and technologies of web-based automation can be explained.  

The Cologne University of Applied Sciences is one of the first universities in Germany 
that would like to sensitize its students to the efficient use of electrical energy as part of their 
university education. For this purpose, appropriate measuring devices were installed at each 
station, with which all energy data of three consumers are continuously recorded and stored. 
Subsequently, these data are to be evaluated and analysed by the students. After the 
analysis, proposals for measures to be introduced to save energy will be developed. For 
training of automation engineering skills we designed a suitable working stations, which 
consider those commonly technologies. One workstation contains following equipment: 
 
• Sensors, detectors, encoders and RFID switches for data detection 
• Programmable logic control (PLC) for data processing 
• Human Machine Interface 
• Velocity speed driver and Motion driver 
• Smart meter for energy efficiency 
• Ethernet Network and CANOpen as machine bus 
• Programming and SCADA software 
 

Figure 3. Education Engineering 

269



Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

In order to increase the motivation of the students for the education in the field of automation 
technology even more, technologies were also procured with which young people can 
identify more easily today. This makes it possible for students to complete certain parts of the 
exercises from their own smartphones using Java Apps. An overview of this is shown in 
Figure 3. For example following exercises can be performed:  
• Command for motor via Bluetooth 

 Left turn and Right turn 
 Change velocity 

• Commands vie GSM Modem 
 Email sending from process 
 Alarm per SMS receive and email 

In addition to the hardware, appropriate site licenses were provided for the complete 
engineering (programming, visualization with SCADA, simulation, etc.). The entire apparatus 
equipment of the Laboratory for Automation Technology at the Cologne University of Applied 
Sciences comprises 20 modern workstations of identical design. A large number of practical 
exercises can be carried out in the teaching environment. The training of students in the 
areas of control, drive and communication technology is thus decisively improved and made 
much more clearly understandable. 

IIoT architecture for remote education 

The concept presented above was built identically at 20 workstations in the laboratory. At 
each station, two students work in a team, so the capacity for training is 40 participants. In 
order to use the potential of the equipment also outside, the approach of IoT was 
implemented. At each workstation 10 global IP addresses were implemented. A WBT server 
manages an Ethernet network of more than 200 addresses. The Internet-based architecture 
allows remote access to the automation technology modules for exercises and practical 
training. The resources of the laboratory can be used as "Distance Learning" for location-
independent training. This technology offers an enormous advantage, especially in the global 
pandemic period due to COVID-19. Students do not have to be present at the university, but 
are able to carry out their automation tasks (programming, visualization, parameterization 
etc.) online via re-mote access. The equipment is also available to our external partners from 
industry and other universities.  

In the middle of the remote architecture is a server that manages the entire information 
content of the individual stations. The server controls remote access and routing to individual 
workstations as well as authentication (user name and password) of the users. Various SQL 
databases for archiving access protocols are implemented on the server. Remote access 
from the global network is established via a VPN connection. In this step the external 
computer becomes part of the laboratory network and is assigned an IP address via the 
DHCP server. 
 
 

270



Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

 

 
In the next step, a connection to a virtual computer from the computer pool is created by 
establishing a remote desktop connection according to previously defined rules. This 
computer provides a working environment with all software components required for 
programming. After a "user name and password" query, access is gained to all programming 
software for PLC, HMI and drives. The user can observe the downloading and testing of the 
programs written on the automation components via a standard webcam. 

Once a student has logged on to a remote computer, he can use all of Toll's soft-ware to 
program the platforms. In figure 4 on the left side is the software for configuring and 
programming the PLC. Five different languages (LD, FBD, SFC, IL, ST) according to IEC 
61131-3 are available for programming the tasks. When the tasks have been programmed, 
the participant can test and validate his solutions in a de-bugging process before the project 
is remotely transferred to the hardware. Tools for diagnostics and online services are then 
also available. Following a similar pattern, students also use the software to create the 
screens on the HMI device. Objects are defined in a graphic editor and linked to control 
variables. 

HMI software uses Ethernet TCP/IP connectivity and is therefore able to support 
decentralized WEB gate access as well as the exchange of application data between 
terminals, the transfer of recipes and protocols for variables and much more.  
For the developed application, a simulation of the PLC variables (I/O, internal bits and words) 
and the graphical application can be performed with a RunTimer, before downloading the 
application to the device. This creates a condition window (top right) where all the exercise 
programs are validated. A webcam (bottom left) shows all activities on the unit. 
 
 

Figure 4. IoT architecture for practical exercises 

271



Smajic et al. | TH Wildau Eng. Nat. Sci. Proc.1 (2021) “SusRES 2021” 
 

 

 

Conclusion and future challenge 

The first experiences have shown that the interest and motivation of students for the tasks of 
automation engineering has increased significantly. Varied exercises reduce the degree of 
abstraction in programming tasks significantly and lead to a significant improvement of the 
examination results.  

The developed internet-based architecture with its WEB server provides a good basis for 
location-independent access to all resources of the laboratory. The challenges of digitization 
in teaching is another focus of current research at the faculty. Re-search projects include, for 
example, the development of innovative assistance systems for evaluating learning progress 
based on artificial intelligence approaches and the introduction of an automatized booking 
service (Scheduler Tools). The resources of the laboratory are currently also being used by 
partners from industry and partners from universities as "Distance Learning". 

References 

[1] Restivo M, Mendes J, Lopes A, Silva C, Chouzal F. A Remote Laboratory in Engineering 
Measurement. IEEE Transactions on Industrial Electronics. 2009 Dec;56(12):4836-4843. 
https://doi.org/10.1109/tie.2008.2011479 
[2] Niedersteiner S, Lang J, Pohlt C, Schlegl T. Klassifikation des Arbeitsfortschritts. atp 
magazin. 2017 Nov 17;59(11):58-66. https://doi.org/10.17560/atp.v59i11.1911 
[3] Osinde NO, Byiringiro JB, Gichane MM, Smajic H. Process Modelling of Geothermal 
Drilling System Using Digital Twin for Real-Time Monitoring and Control. Designs. 2019 08 
17;3(3):45. https://doi.org/10.3390/designs3030045 
[4] Smajic H, Bosco J. SIMULATION TOOLS FOR VIRTUAL PLC-TESTING IN EXTRUSION 
PROCESS. University of Banja Luka. DEMI 2019; Bosnia and Hercegovina. 2019 May. 
[5] Falkman P, Helander E, Andersson M. Automatic generation: A way of ensuring PLC and 
HMI standards. ETFA2011. Factory Automation (ETFA 2011). 2011 09. 
https://doi.org/10.1109/etfa.2011.6059201 

Figure 5. Software tools, testing and validation of programs remotly 

272

https://doi.org/10.1109/tie.2008.2011479
https://doi.org/10.17560/atp.v59i11.1911
https://doi.org/10.3390/designs3030045
https://doi.org/10.1109/etfa.2011.6059201

	30_21-Smajic-etal_Conference paper-42-1-6-20210510
	Introduction
	Available automation concepts
	Training in real and virtual environment
	Design of an automation solution for practical education
	IIoT architecture for remote education
	Conclusion and future challenge
	References