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www.etasr.com Zouari et al.: A Comparative Study of Computer-Aided Engineering Techniques for Robot Arm … 

 

A Comparative Study of Computer-Aided 

Engineering Techniques for Robot Arm Applications 
 

Lilia Zouari 

CES Laboratory 
Sfax University, Tunisia 
lilia.zouari@gmail.com 

Slim Chtourou 

College of Engineering, Electrical Department  
King Faisal University, Saudi Arabia 

slim.chtourou@ieee.org 

Mossaad Ben Ayed 

AlGhat College of Science and Humanities 

Al Majmaah University, Saudi Arabia and 

University of Sfax, Sfax Tunisia 
Tunisiamm.ayed@mu.edu.sa 

Shaya A. Alshaya 

Department of Computer Science  

Majmaah University 

Majmaah, Saudi Arabia 
shaya@mu.edu.sa 

 

 

Abstract-As systems become increasingly complex, their 

simulation techniques have to be more accurate and enhanced. 

Despite the wide use of robotic arms in industries, they still 
encompass a wide number of complexities. The control of a 

flexible robot arm driven by a Brushless DC Motor (BDCM) for 

tracking problems is a great challenge, not only for its complex 

algorithms but also for its verification process. Robotic systems 

are designed heterogeneously by combining continuous and event 

discrete models. Therefore, computer-aided engineering tools 
have to be enhanced in order to support the verification of the 

control algorithms. Ensuring definite and rapid simulations is a 

challenging task for robotic application systems. Although 

control strategies can be tested using the Matlab/Simulink 

environment to assess their performance, their verification at a 

low-level still remains a very difficult task. This paper studies 

different simulation techniques based on Model In the Loop 
(MIL), Hardware In the Loop (HIL), and Hardware Software In 

the Loop (HSIL) on a flexible robot arm driven by BDCM in 

order to overcome each method's limits, focusing on performance 

and cost and simulation time reduction. The HSIL achieves the 

highest accuracy and speed than MIL and HIL and provides 

reusability and portability of the control unit compared to the 

other techniques. 

Keywords- control; robot arm; brushless DC motor; model in 
the toop; hardware in the loop; hardware software in the loop 

I. INTRODUCTION  

Robots’ control driven by BDCM has achieved an 
interesting breakthrough recently [1-2]. The utilization of 
BDCMs is widely spread due to their independence of bearings 
and brushes, providing them a long survival time, robustness, 
energy efficiency, and implementation simplicity [3-7]. 
Authors in [8] utilized BDCM in robotics to benefit from its 
advantages, such as the execution time decrease of control 
algorithms. They showed that this was a great advantage, 
especially when looking for robot manipulators either in the 
industry performing repetitive tasks, or in service robots 

performing manipulation tasks. Nevertheless, despite the 
progress in this field, there is still an urgent need to minimize 
cost and time for certain robotic applications [9-13]. Robotic 
systems still require many improvements in design, accuracy, 
and real-time processing. On the other hand, computer-aided 
design methods have to be up to date in order to support the 
complexity and the needs of these systems. This challenge is 
the main subject of this paper, as it attempts to evaluate the 
control algorithm performance for a flexible robot arm with 
one freedom degree using Model In the Loop (MIL), Hardware 
In the Loop (HIL), and Hardware Software In the Loop (HSIL) 
[14] simulation techniques. 

The more complex is a control algorithm, the longer 
simulation time it requires. Hence, the design of accurate and 
rapid simulations is a great challenge for robotic systems, as 
the need for high performance and available real-time systems 
has increased their complexity. The design of these complex 
systems requires an efficient simulation tool for verification, 
ensuring high performance in less time. HIL appends the 
sincere device in the verification process. This may enhance the 
test capacity, diminish conceit time and predict the 
environment interaction. Despite its pertinence, compounding 
variant architecture conceits and protocols at the same time is a 
complex mission [15]. In [16], an environment to verify and 
test the hardware via HIL was presented and integrated in 
MATLAB/Simulink. The simulation model was synchronized 
via real-time communication, and logic control was performed 
by Simulink. Authors in [17] presented a technique to test real 
time embedded systems via HIL, benefiting from High-Level 
Architecture (HLA) for interoperability and synchronization of 
heterogeneous architectures. Their proposed test used Ptolemy 
to verify the patterns operating in hardware and their 
correspondent Ptolemy developed reference patterns in real-
time. This approach developed further performers in Ptolemy 
to integrate it in an HLA and to interface the software in the 
hardware under verification. As substantiation of concept, it 
was applied on a navigation algorithm for a mobile robot. 

Corresponding author: Mossaad Ben Ayed



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Every data collected by the sensors and the reactions were 
transmitted in real-time to Ptolemy performing the check in the 
face of a reference model. This allowed multiple computation 
models to be exploited as reference models, in order to 
checkout multiple hardware architectures synchronously based 
on HLA [17]. In [18], a distributed co-simulation environment 
to integrate virtual components was introduced. The co-
simulation used a modified HLA nominated as Distributed 
Cosimulation Backbone, which was the standard to exchange 
data, claiming specific appeals to run-time infrastructure 
functions. In general, the operation was similar to high-level 
architecture. Similarly, other works used HIL to test embedded 
systems, whereas they were restrained to a restricted set of 
models and devices, with specific architectures and 
computation models making the integration harder. In contrast, 
in [17] the co-simulation was performed for homogeneous 
models only. Unfortunately, these models lack any easy 
extensions for integration with heterogeneous systems, and 
their adaptation to diverse hardware platforms, synchronization 
and communication protocols require much effort. Authors in 
[19] attempted to support synchronization and heterogeneity by 
involving different computation patterns and integrating real-
time hardware devices in Ptolemy using high-level architecture. 
This was an improvement to the integration of several instances 
of Ptolemy to improve performance without HIL [20]. In [21], 
Ptolemy was integrated with hardware devices for testing 
excluding real-time constraints. However, test integration of 
embedded systems with HIL via Ptolemy and high-level 
architecture has not been found. 

Nowadays, designing complex systems requires tools and 
methods that allow verification and simulation in a practical 
and efficient way [22]. The use of different modeling and 
simulation tools during a unique design flow is a very common 
procedure. However, the integration of hybrid systems is not 
easy, as there is no guarantee that continuous and discrete 
systems that work smoothly when separated, will work well 
when combined [23]. This paper studies the development and 
evaluation of different verification techniques, based on high-
level architecture, for a flexible robot arm driven by BDCM. 
To reach this goal, a verification environment for the control of 
the robot system is necessary. Therefore, at first, the MIL 
simulation based on Matlab/Simulink was used. Then, its 
results were compared with the results of HIL and HSIL, in 
order to feature a high performance and short-time method for 
heterogeneous and complex embedded robot systems. This 
approach of co-simulation was expected to allow the 
synchronization between heterogeneous models, such as 
continuous and discrete models, integrating different 
simulators. 

II. PROBLEM FORMULATION AND CONTROL STRATEGY 

This section describes the control strategy associated to the 
BDCM and the flexible robot arm. 

A. BDCM Control 

The DC voltage ensuring power over the three arms in 
high- and low-level was conventionally provided by an AC-DC 
converter which was easily achievable through batteries. In line 
with [24], it was assumed that the Insulated-Gate Bipolar 

Transistors (IGBTs) and the diodes constituting the inverter 
were ideal switches, in order to simplify the brushless motor-
conventional inverter association formulation. The voltages of 
the BDCM's three phases, Van, Vbn, and Vcn were expressed as 
functions of S1-6 signals, characterizing the IGBTs of the three 
arms state. The BDCM phase voltages a, b, and c were 
determined considering the signals combinations S1-6. Each 
functioning sequence was divided into motor sub-sequence 
during which the power was transmitted from the battery to the 
motor stator phases through two IGBTs, and a generator sub-
sequence resulting in a power recovery that was returned to the 
battery through two diodes. The IGBTs conduction outbreak 
was ensured by the hysteresis current controllers. The principle 
of the hysteresis controller was to maintain the real current 
within a centered given width band around the reference 
current Iref . Figure 1 shows the flowchart of the BDCM 
control. 

 

 
Fig. 1.  Flowchart of BDCM control. 

B. Flexible Robot Arm Control 

The proposed design focused on a flexible robot arm with 
one degree of freedom. Most similar robots use an actuator 
brushless motor. The flexible robot arm based on BDCM 
provides fast, precise movements, and excellent dynamic 
response with a high dynamic and torque performance. The use 
of a transmission system is essential for the flexible robot arm. 
Figure 2 describes the flowchart of the flexible robot arm 
control. 

III. VERIFICATION TECHNIQUES 

The choice of the verification technique of the developed 
digital systems is a very important task. Any verification 
technique should be based on two essential requirements. At 
first, the existence of a software simulation tool is essential to 
monitor the performance and avoid potential risk scenarios in 
real tests. Additionally, the provision of a hardware simulation 
tool is imperative to verify its functionality and measure its 
performance under realistic conditions. The following section 



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presents the three verification techniques used for the control of 
the flexible robot arm driven by BDCM. 

 

 
Fig. 2.  Flowchart of flexible robot arm control. 

A. MIL Simulation Technique 

The simulation approach for dynamic systems analysis is a 
vital step in all robotics studies. For this reason, the scheme of 
the closed-loop robot manipulator control was modeled using 
Simulink as shown in Figure 3. 

 

 
Fig. 3.  Flexible robot arm control using MIL. 

Machine-converter associations were particularly involved 
in this, study since these systems are quite complex, nonlinear, 
presenting multiple time scales with very small time constants, 
and variables depending on the operating point. Within a 
perspective to implement the control algorithms for brushless 
motors driving the robot arm, special focus was given on 
studying and checking the dynamic performance of this robot 
in Matlab/Simulink environment. This model uses the electrical 
and mechanical equations and quantities already developed 
from the considered BDCM, and this section focuses on the 
implementation of the control strategy, adopting the dynamic 
model of the robot with the determined controller parameters. 

B. HIL Simulation Technique 

There is an increased interest in using electrical drives and 
power electronics in the control of a large variety of different 
applications, particularly in the robotic field. However, authors 
in [25, 26] recommended a serious consideration of the design 
and strict control of electrical drives and power electronics to 
validate their control strategies. Therefore, HIL and rapid 

prototyping methods are described as a deep layer of 
verification that is required after the software simulation. HIL 
simulators were essentially used for the verification of complex 
electromechanical systems such as industrial robots [27]. HIL 
simulations always performed the real-time simulation of the 
system including actuator and sensor models. Furthermore, 
theoretical considerations have been reported along with 
simulation results related to differences and the evaluation of 
approaches [28]. This technique has multiple advantages [27]: 

• During the initial design phases, the platform is not always 
available to perform real tests. 

• Cost and simulation time will be reduced. 

• In the presence of system uncertainties during the initial 
phases of the design, HIL is the safest simulation technique 
to avoid all scenarios risks and dangerous situations. 

• The verification flexibility can be automated and 
reproducible. 

Simulink/Matlab provides HIL by performing co-
simulation between the FPGA board and the Quartus II 
software design [27, 29-33]. HIL simulation is used to achieve 
the control strategy of the flexible robot arm, and ensures the 
verification of the effectiveness of controllers in a repeatable 
and cost-effective way [29, 31]. The steps required to perform 
the verification of the controller’s accuracy according to the 
HIL [30-33], are: 

• Step 1: Provide the model of the controllers based on the 
DSP builder blocks in the Simulink/Matlab environment. 

• Step 2: Compile the design based on the Signal Compiler. 
Compilation creates a compiled Quartus II project 
presented in Figure 4. The compilation procedure (Figure 5) 
comprises of four steps. The closed-loop flexible robot arm 
control driven by BDCM is described using the DSP 
builder tool to perform the HIL simulation based on the 
Altera DE2 board, as shown in Figure 6. 

• Step 3: Select the adequate configuration of the HIL 
interface and program the FPGA board, as shown in 
Figures 7 and 8. 

After finishing all these steps, the verification of the 
controllers' efficiency is performed through simulation with 
MATLAB/Simulink and an Altera FPGA board. However, 
despite the provided modeling language and the HIL multiple 
advantages, this verification technique is not suitable for 
hardware/software co-design. One of the contributions of this 
paper is to deal with HIL weaknesses by developing a new 
standard target based on the FPGA board [29, 33]. 
Shortcomings could be resumed as: 

• Only a few targets are supported. 

• Lack of reuse and portability: the model associated with the 
Control Unit (CU) target block set decreases reusability and 
portability.  

• Unchangeable HW: the HW is created based on the 
generated code that prevents the modification of HW 
architecture.  



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• Waste of time: When the model related to the CU changes, 
the HIL technique platform requires to be performed again. 

C. HSIL Co-Simulation Technique 

In line with [29], the control part was an embedded system 
defined by SW and HW components. Each part had to be 
aware of the other part's characteristics to obtain optimized 
components. The most adequate strategy was the co-design, 
since it was expected to develop HW/SW components 
concurrently. The main idea was to set the HSIL to overcome 
its limits, as it was recommended in [29, 32-33]. The described 
method could improve HIL, having the following advantages: 

• Expanding the HIL to attend the co-design strategy. 

• The S-function can be integrated into the Simulink block to 
perform specific communication with the FPGA board. 
This is a very powerful way to extend the capabilities of 
Simulink, guaranteeing reusability and portability. 

• Without modifying the architecture, the CU modification 
and verification is enabled. 

The main advantage of the proposed method is the 
synchronization mechanism that ensures the relationship 
between the Simulink/Matlab simulator and the HW 
architecture emulated on the FPGA board. The aim of the 
flexible robot manipulator control design was to verify the 
CUs. The model had a speed controller, a torque controller, and 
current controllers were considered as SW applications. Three 
steps were crucial for the implementation of the controller units 
[29-30,34]: 

• Target architecture: The verification needs several tools to 
satisfy continuous and discrete models. The discrete model 
was implemented on the ALTERA DE2-70 FPGA board, 
using the Quartus II, NIOSII IDEs. MATLAB was used for 
the continuous model. 

• Synchronization block integration: This block ensures 
communication and synchronization between the 
Matlab/Simulink simulator and the target architecture 
described in S-function block. The endpoints related to the 
synchronization interface represent the input signals of the 
continuous model. When an activation signal is triggered, 
the synchronization block ensures a context switch to the 
board by sending a data packet. Upon resuming execution, 
the data packet read by the interface synchronization 
defines the next activation time. 

• Simulation results: The signals' update events were not 
periodic, so the simulation was performed using the 
synchronization scheme. 

IV. EXPERIMENTS 

Figures 4 and 5 represent the design in the Matlab/Simulink 
environment associated to the MIL and HIL techniques 
respectively. Controllers were replaced with the HIL block, and 
the control algorithm was computed on the board. The HIL 
technique was performed using the DSP builder tool provided 
by Matlab/Simulink. Figure 6 shows the different 
characteristics mounted. A Cyclone version of FPGA was used, 
based on architecture done in Quartus II (BDCM DSPbuilder 

was the file architecture). As shown in Figure 6, the 
compilation passed through four steps: Analyze, Synthesis, 
Fitter, and Program. Figures 7 and 8 describe HIL technique's 
parameters.  

 

 
Fig. 4.  Flexible robot arm control using DSP Builder blocks. 

 
Fig. 5.  Flexible robot arm control using HIL. 

  
Fig. 6.  Compilation using  the DSP BUILDER. 

The simulation results for the three techniques, MIL using 
Simulink, HIL using DSP Builder tools and Altera FPGA 
board, and the HSIL using S-function and NIOSII were 
compared. The implementation steps of the HSIL techniques 
are described in [33]. Figures 9-11 show speed evolution, 
position, speed and position error, and the control law 
respectively using MIL, HIL, and HSIL techniques. However, 
as the curves in the MIL and HSIL are similar, only the curves 
using MIL are presented. As it can be observed, the flexible 
robot arm followed the desired trajectory with a tiny static error 
rate, confirming the robustness of the controllers orienting the 
flexible robot arm to the desired position respecting a definite 
speed. Moreover, when the desired final position is reached, the 



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electromagnetic torque is equal to the load torque. In addition, 
it would be worth noting that the controllers applied on a 
flexible robot arm driven by the BDCM yielded an acceptable 
performance using all techniques. Therefore, the desired speeds 
and accelerations were reached. 

 

 
Fig. 7.  Selection of the HIL configuration. 

 
Fig. 8.  The interface of the HIL program. 

Table I shows the simulation time for the hysteresis, PID, 
and torque controllers and all systems using MIL, HIL, and 
HSIL techniques. Table I shows that:  

• The output signals obtained using HIL have an error 
compared to the output signals using MIL and HSIL. At 
first, this error was not expected as the same control 
algorithm was used in both cases. After a deep research it 
was concluded that this error happened due to the 
insufficient memory of the FPGA board. This lack of 

memory led to data corruption which affected the 
computation results. 

• Satisfactory performance is obtained to achieve the desired 
speeds and positions at a lower cost. 

• The presence of a precision loss using HIL compared to 
simulation results using MIL, due to the high sampling 
time. This caused the failure to get all the points for more 
accuracy, while it allowed having a faster system. 

 

  

Fig. 9.  Speed and position. 

  

Fig. 10.  Speed error and position error. 

 

Fig. 11.  Control law. 

TABLE I.  SIMULATION TIME 

Parts 
Simulation 

with MIL (s) 

Simulation 

with HIL (s) 

Simulation 

with HSIL (s) 

Hysteresis 

controller 
48 12 6 

Torque 

controller 
16 4 2 

PID controller 24 6 3 

Flexible robot 

arm control 
8424 2107 1053.5 

 

After verifying the control algorithm of the flexible robot 
arm driven by a BDCM using MIL, the HIL verification results 



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were closer to the real case. This could enable a faster run of 
verification scenarios than with the software simulation. 
Following the previously described design methods, HIL 
simulation was much faster and more confident than software 
simulation. In addition, the refinement of the development and 
the rapidity of the control strategy were continued by the 
combination of the HSIL co-simulation, as it benefited from 
each technique's advantages. These results proved that HIL 
simulation was 4 times faster than software simulation. 
Furthermore, the HSIL simulation was twice faster than the 
HIL simulation, proving that HSIL is the best verification 
method. 

V. CONCLUSION 

This paper aimed to evaluate three Computer-Aided 
Engineering techniques in robotic systems, focusing on a 
BDCM control fitted to a flexible robot arm and simulating in 
Matlab/Simulink environment via verification methods. The 
model and the control of the BDCM-inverter flexible robot arm 
were presented. Then, different control strategies such as a 
speed controller, a torque controller and a hysteresis controller 
for controlling currents were described. MIL, HIL, and HSIL 
simulations were studied and analyzed, showing the HSIL's 
benefits. According to simulation results via the Simulink 
environment and the FPGA board, the HSIL achieves the 
highest accuracy and speed than MIL and HIL techniques. In 
addition, HSIL provides reusability and portability of the 
control unit compared to the other techniques.  

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