Program Algorithm for Monitoring System Development

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Program Algorithm for Monitoring System Development

Maksym Moiseev 1, Svitlana Maksymova 1,

Vladyslav Yevsieiev 1, Ahmad Alkhalaileh 2

1 Department of Computer-Integrated Technologies, Automation and Robotics,

Kharkiv National University of Radio Electronics, Ukraine

2 Senior Developer Electronic Health Solution, Amman, Jordan

Abstract:

In our time, the development of a system for monitoring the parameters of the

production environment is of great relevance and importance in the current industrial
environment for several reasons. First of all, the measurement and analysis of the
parameters of the vibrational medium make it possible to ensure the safety of workers
and avoid possible accidents and unsafe situations. In other words, monitoring systems
allow you to optimize industrial processes by continuously monitoring parameters in
real time. This allows you to detect possible malfunctions or anomalies in the plant and
immediately respond to them, so as to avoid wasting time and resources. In this article
authors propose a program algorithm for parameters of industrial premises monitoring
system.

Key words:

Monitoring system, Industrial premise, Algorithm, Manufacturing

Innovation, Industrial Innovation.

Introduction

The development of industry 4.0 and the integration of digital technologies in

manufacturing creates a need for effective and intelligent monitoring systems that can
automate the processes of collecting, processing and analyzing data [1]-[12].

This helps companies increase productivity, reduce costs and improve product

Quality [13]-[27]. Various methods and approaches can be used here [28]-[33].

Monitoring of production process parameters is a system that provides constant

control over key parameters and conditions that affect the efficiency and safety of the
production process. Given the constant pressure to increase productivity and reduce
costs, monitoring the parameters of the production process becomes extremely relevant,
it allows manufacturers and employees to quickly respond to changes in the production
environment and ensure stable product quality.

A monitoring system usually consists of sensors that measure various parameters

such as temperature, pressure, humidity, resource level (such as electricity or fluids),

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material flow rate, vibration, noise level, etc. This data is usually collected in real time
and transmitted to a central system for analysis. The main purpose of monitoring the
parameters of the production process is to ensure the stability and efficiency of the
production environment. This includes identifying deviations from the norm, hazardous
conditions, malfunctions in equipment or processes, and optimizing the efficiency of
the production process.

In manufacturing, where automation plays a key role, parameter monitoring

becomes even more important. It allows automatic control systems to quickly respond
to any changes in the production process and avoid problems or emergency situations.
Modern monitoring systems use advanced technologies such as the Internet of Things,
artificial intelligence, real-time analytics, and cloud solutions. This allows for more
accurate and effective monitoring, and also increases the possibilities of forecasting and
optimization of the production process.

In today's production conditions, when the industry is rapidly developing and

becoming more and more automated, the integration of monitoring systems is becoming
more and more relevant. It allows automatic control systems to quickly respond to
changes in the production environment, optimize processes and ensure high product
quality. Integration between monitoring systems and automatic control systems
requires standardization of data exchange protocols, compatibility between hardware
and software, and reliable real-time data transmission and processing. The main task of
integration is to ensure the joint operation of monitoring and control systems to achieve
common production goals. This includes automatically responding to detected
deviations in parameters, optimizing the operation of equipment and processes,
ensuring safety and reducing costs. Integration may require the development of
specialized application programming interfaces to enable interoperability between
systems. It is also important to ensure protection against unauthorized access to data
and reliable transmission of information over the network. The integration of
monitoring and control systems makes it possible to increase the automation and
efficiency of production processes, reduce energy and resource costs, improve product
quality and ensure employee safety.

Related works

The development of monitoring systems is becoming increasingly relevant,

especially for those enterprises that want to move to the next level in accordance with

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the principles of Industry 4.0. And it is not surprising that many scientists write various
works on this topic. Let's look at a few recent works.

Marquès, J. M., and co-authors [34] propose a notification, recommendation and

monitoring system which is integrated into an automatic assessment tool with the aim
to enhance the learning process in virtual classrooms.

Group of authors in [35] notes that due to long process cycle time and arc-based

deposition, defect monitoring, process stability and control are critical for the wire arc
additive manufacturing technology system to be used in the industry. Although major
progress has been made in process development, path slicing and programming, and
material analysis, a comprehensive process monitoring, and control system are yet to
be developed. They analyze sensing and control design suitable for a wire arc additive
manufacturing system, including technologies developed for the generic Arc Welding
process, the Wire Arc Additive Manufacturing process and laser Additive
Manufacturing.

Researchers in [36] tell us that operational pollen monitoring networks have

developed across Europe, and the world more generally, in response to the increasing
prevalence of pollen allergy and asthma. his paper describes the rationale behind the
EUMETNET AutoPollen programme, which aims to develop a prototype automatic
pollen monitoring network across Europe.

The paper [37] addresses the issue of substantiating a methodological approach

to evaluating the efficiency of automated information and telecommunication systems
for vehicle traffic monitoring, which allows us to quantify the efficiency of their
application.

Guo, Y., & et al. [38] note that computer numerical control machine tools are the

core manufacturing equipment in discrete manufacturing enterprises, collecting and
monitoring the data is an important part of intelligent manufacturing workshops.

Scientists in [39] present the design and development of a framework for the

remote monitoring of refrigerator and cold storage systems based on the
implementation of a wireless sensor network for data acquisition, and intelligent
algorithms for Predictive Maintenance.

In the study [40], an industrial IoT algorithm with an associated hardware

prototype is proposed to monitor the condition of wind energy conversion system in the
real-time environment.

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So, we see how diverse monitoring systems can be. Further in this article we will

consider the algorithm of the program for a system for monitoring the climatic
parameters of industrial premises.

Development of the algorithm of the program of the monitoring system of

the parameters of industrial premises

The use of systems for monitoring the production premises parameters is

critically important for increasing the efficiency and safety of the production process.
These systems allow you to monitor production parameters in real time, detect
anomalies and warn of possible malfunctions, which helps prevent accidents and
product losses. By analyzing data, these systems help to optimize the use of resources,
reduce costs and improve product quality. Personnel training and regular maintenance
are important elements in the successful implementation and operation of monitoring
systems. Overall, these systems are an essential tool for modern manufacturing, helping
to maintain high levels of productivity, safety and competitiveness.

One of the important components of the production process monitoring system,

which is aimed at preventing potential problems and emergency situations by detecting
deviations from the norm or changes that may indicate malfunctions in the production
environment, is the detection of anomalies and warning of system malfunctions. Having
considered the detection of anomalies and warning of malfunctions in the monitoring
system of the parameters of the production process, it can be emphasized its importance
in preventing potential problems in the production environment. This aspect includes
real-time monitoring, data analysis to detect deviations, setting thresholds, alert systems
and automatic actions, as well as the ability to predict and prevent future problems. This
approach helps to ensure the safety, stability and efficiency of the production process.

The system for monitoring the parameters of production premises should provide

information in real time. Real-time display of data and their analysis are key elements
for effective management and control of the production process. This allows operators
and production managers to see the current status of the process without delays. This
allows them to quickly respond to any changes, identify problems and take the
necessary measures to solve them. Quick access to up-to-date data allows you to assess
performance in real time. This allows you to identify weak points in the production
process and quickly react to them to increase efficiency. Real-time data analysis also
allows you to identify opportunities to optimize production processes. By identifying

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and analyzing different execution options, you can find ways to increase productivity,
reduce costs, and improve product quality.

The development of the algorithm of the program for monitoring the parameters

of industrial premises is key to ensuring its efficiency and reliability. The algorithm
allows you to optimize the use of resources, such as electricity and network traffic,
ensuring the efficient operation of the system. It also determines how the system reacts
to events such as the detection of excessive temperature or humidity, allowing
appropriate measures to be taken to resolve them. A well-developed algorithm ensures
stable operation of the system even in difficult environmental conditions. It can also
include parameter monitoring and reporting functions, allowing operators and
administrators to respond to any problems or anomalies in a timely manner. In addition,
the algorithm may include security measures to help prevent unauthorized access and
protect data. A well-designed algorithm is also scalable and can be easily extended to
include new features or expand system functionality in the future. The general
algorithm of the program of the system for monitoring the parameters of production
premises is presented in Figure 1.

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Figure 1:

The general algorithm of the program for monitoring the parameters

of industrial premises

Start

initialization of

libraries

display connection

declaration of

constant strings

settings

parameters

Wi-Fi

connection?

no

Connecting to

the server

MQTT?

yes

no

yes

a

a

Temperature and

humidity readings

from the DHT

sensor

Temperature

display on the

OLED display

Transfer of

temperature and

humidity in

MQTT

9

1

2

3

4

5

6

7

8

Message about

an error

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Let us present a brief description of each block of the general algorithm of the

program for monitoring the parameters of industrial premises:

1 – this block of code is used to connect and initialize the various libraries

required for the application to run. For example, the initialization of the
ESP8266WiFi.h library allows you to connect to a Wi-Fi network, and the initialization of
PubSubClient.h allows you to interact with the MQTT server for data transfer;

2 – the display connection block in the algorithm is used to initialize and

configure the connection between the microcontroller and the display. This includes
setting communication parameters (such as interface type and display address),
preparing the display for operation (cleaning, setting text colors, etc.), and maintaining
communication between the microcontroller and the display while displaying data;

3 – the declaration block of constant lines in the algorithm is used to store values

that remain constant during the execution of the program. This may include
identification data such as Wi-Fi network names or MQTT server addresses, which
allows for convenient management of communication parameters and application
settings without the need to change the application code itself;

4 – this block of code is designed to configure the display parameters on the

OLED display. It sets the power mode of the display, the address of the display on the
I2C bus, performs the first initialization of the display, sets the size of the text, the color
of the text and other parameters affecting its display;

5 – a cycle of checking the connection to a local wireless network based on Wi-

Fi technologies;

6 – cycle of checking the connection to the MQTT server;
7 – this code block is designed to read temperature and humidity values from the

DHT sensor. It reads data from the sensor and stores it in the appropriate variables. If
the read data is incorrect, the program displays an error message;

8 – this block of code is responsible for displaying the temperature value on the

OLED display. It clears the display, sets the text size and color, and outputs the
temperature value to the display;

9 – this block in the algorithm is responsible for publishing temperature and

humidity values to the MQTT broker. It converts temperature and humidity values to
strings and uses the publish function to send these values to the appropriate MQTT
topics so they can be processed and visualized on the server.

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The developed algorithm of the program for monitoring the parameters of

industrial premises has several advantages. First, it provides reliable collection and
transmission of data from temperature, humidity, motion and gas level sensors to the
server using Wi-Fi and the MQTT protocol. This allows you to monitor the state of
parameters in the production room in real time. Secondly, thanks to the use of an OLED
display, local temperature visualization is possible on the spot without the need to
connect to a server. In addition, the implemented Wi-Fi and MQTT connection system
allows you to easily configure and control the system from any device that supports
these technologies. This approach makes the system quite flexible and easy to use for
production needs.

Conclusion

Developing a program algorithm for a monitoring system for industrial premises

brings significant benefits by improving comfort, safety, energy efficiency. This article
describes the purpose of the system for monitoring the parameters of industrial
premises. The basic requirements that such a system must satisfy are described.
Particular attention is paid to the need for a real-time monitoring process.

A generalized program algorithm has been developed for a system for monitoring

the parameters of production premises.

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