https://doi.org/10.31449/inf.v45i2.3555 Informatica 45 (2021) 613–620 613 
 
Regional Network Education Information Collection Platform for 
Smart Classrooms based on Big Data Technology 
Yuyao Li 
Xi‘an Jiaotong University, School of Marxism Studies, Shaanxi Xi‘an, 710049, China 
E-mail: yuyaoli234@outlook.com 
 
Ashutosh Sharma 
Institute of Computer Technology and Information Security, Southern Federal University, Russia 
E-mail: ashutosh@sfedu.ru  
 
Keywords: big data technology, smart classroom concept, network education, web servers, hadoop clusters, teaching 
mode 
 
Received: May 20, 2021 
Big data technology plays an important role in optimizing the education intelligence by enhancing the 
learning experience through novel assessment strategies and predictive teaching. This work aims at 
improving the learning efficiency of users and increase the effective learning quality of the smart 
classroom concept using the big data technology. A regional network education information collection 
platform based on big data technology has been developed, which can collect student learning data for 
subsequent analysis and processing. The software architecture of this platform is mainly divided into 
basic layer, platform layer and access layer. The physical structure mainly includes web servers and 
Hadoop clusters. The big data acquisition platform of this education has excellent acquisition 
performance, and the data acquisition of different data item field length is larger than the expected 
index. The outcomes obtained reveals that the data item field is less than 20 and the acquisition amount 
is 145% of the expected result. When the data item field is between 20 and 40, the acquisition amount is 
137% of the expected result. The collection is 116% of the expected result, when the data item field is 
between 40 and 50. When the data item field is between 50 and 60, the collection is 103% of the 
expected result. The comparison of the regular teaching method with the smart classroom based concept 
revealed that the big data platform is 87% better than the normal regular teaching methods in terms of 
study material as well as meaningful teacher-student interaction. The research on education big data 
can provide better education services for educational activities, drive the reform of teaching mode and 
optimize the teaching methods of education enabling the smart classroom concept. 
Povzetek: Predstavljena je regionalna platforma za upravljanje pametne učilnice na osnovi 
tehnologije  velikih podatkov. 
 
1 Introduction 
With the increasing popularity of the concept of big data, 
big data has gradually evolved into a social culture, that 
is, a culture where everyone produces data, everyone 
manages data, everyone shares data, and everyone loves 
data [1]. This is a culture that is invisible. Affect the 
culture of all walks of life. Even if the education field is 
still "conservative" all the year round, under the impact 
of this big data trend, people have begun to actively 
"embrace" big data [2]. In this context, new big data 
technologies are produced every year to acquire data, 
store data, analyze data and data visualization. With the 
support of these new technologies, the massive data 
generated in real time can be processed and stored, 
calculated and further mined and analyzed. At the data 
storage level of big data, there are well-known 
technologies such as HDFS and Hbase that use 
distributed file systems to store data [3]. At the level of 
big data mining and analysis, there are techniques such 
as pattern recognition, machine learning, deep learning, 
and visualization analysis. With the development of big 
data technology, it will become a part of modern social 
infrastructure in the near future. The significance of big 
data is not only reflected in the huge amount of data, but 
also in the infinite value contained in it.  
Big data technology is an effective tool to conquer 
massive data and mine data value. In connection with the 
various challenges facing the country's current 
modernization, if we try to solve them through the 
innovative method of big data technology, it will greatly 
promote the development of many industries. Among 
them, industries that are closely related to people's 
livelihood, such as education, transportation, and medical 
care, have benefited most. 
The digital revolution has resulted in the innovative 
technologies like smart classrooms, smart devices, 
pervasive computing in order to shape the mode and 
accessibility of teaching and learning [4-6]. All these 
factors lead to the transformation in the education system 
blended with the smart learning environment including 

614 Informatica 45 (2021) 613–620 Y. Li et al. 
 
various learning management platforms like E-learning, 
online courses, intelligent tutoring systems, etc. [7,8]. 
The real time practices have enabled the automatic 
gathering of data, its processing, storage and analysis for 
satisfying the big data attributes [9,10]. The different 
attributes of big data are described in Figure 1. 
Big data involves the process of combining 
enormous volume of data and analyzing it using the 
complex algorithms [11-13]. The big data analytic deals 
with the usage of advanced techniques on a vast dataset 
for discovering the relevant pattern and information [14-
16]. These analytics are actually helpful in increasing the 
efficiency for providing better insight and improve the 
awareness regarding the education services as well as 
institution requirements [17]. Various methods involved 
in big data analytics application for education are data 
mining, web dashboard and data analytics, etc. These 
technologies enable the data collection and interpretation 
using the evidence based learning concept for automated 
instruction assessment [18]. They facilitate in the better 
insight of big data technology for increasing the 
productivity and profitability of the smart education 
system.  
This work contributes in providing a regional 
network education information collection platform based 
on big data technology to collect student learning data for 
subsequent analysis and processing. The proposed 
platform is able to collect the student information based 
on their learning behavior, learning content, learning 
preferences and other data and then a relevant data 
mining approach is used for facilitating the smart 
classroom concept. The platform’s software architecture 
is divided into three major layers: the basic layer, 
platform layer and the access layer. The physical layer of 
the platform comprises of web servers and Hadoop 
clusters. This big data acquisition platform for education 
enabling smart classrooms provides exceptional 
acquisition performance. The acquired data for different 
data item field lengths is much higher than the expected 
indexing. This research work implementing the big data 
scenario for educational activities can reform the 
teaching mode by optimizing the teaching methods for 
enabling the smart classroom concept.  
The rest of this article is arranged as: section 2 
provides the literature review of the current state of the 
art techniques in the smart classroom domain of big data 
analytics. Section 3 discusses the platform designing for 
the implementation. Results and analysis of platform 
function tests are depicted in section 4 followed by the 
concluding remarks of the study in section 5. 
2 Literature review 
In the Internet age, the data generated by education-
related activities is called education big data. It is a data 
set collected according to the educational needs of the 
entire education activity. It can be used for the 
development of education and create huge potential 
value. Because of the particularity of the education field, 
education big data also has its unique characteristics. In 
the field of online education, data is diversified and there 
are multiple associations between data, so the collection 
and analysis of educational data has certain complexity. 
In October 2012, the U.S. Department of Education 
published "Promoting Teaching and Learning through 
Educational Data Mining and Learning Analysis ", 
pointing out that the mining and analysis of educational 
big data plays an important role in promoting the 
innovation construction of colleges and universities and 
teachers' teaching reform. The education big data 
emphasized here focuses on comprehensive and full-
scale in-depth mining, scientific analysis and effective 
use of diversified education data, rather than being 
limited to the superficial large capacity. In August 2015, 
the State Council issued the "Outline of Action to 
Promote the Development of Big Data". The outline 
pointed out that big data resources play a fundamental 
role and have a strategic position in the development 
process of the country and the government. It is in the 
launch of the "Public Service Big Data Project". China 
emphasizes that the construction of education big data is 
urgent. It can be seen that the importance of big data in 
education has been raised to the national strategic level, 
and the government should attach great importance to the 
research on the application value of big data in 
education. In September 2015, my country established 
the first "China Education Big Data Research Institute". 
In 2016 and 2018, my country released two basic 
education big data blue books, and the content gradually 
changed from education big data to my country's 
education industry. The research on the macro-leading 
role has turned to the research on the specific issues of 
the current situation of education in my country. It can be 
seen from this that education big data has opened a new 
model for our government to play a decision-making role 
in the education field. In recent years, researchers at 
home and abroad have conducted many studies on 
education big data. To solve the problems of low data 
recall, poor data mining accuracy and poor interference 
ability of redundant data. Zhang proposed an adaptive 
big data mining recommendation algorithm based on 
Hadoop platform. The big data similarity mathematical 
model is constructed by statistical regression analysis. 
Using autocorrelation matching detection method to 
extract the relevant features of big data, using Bcklund 
transformation to decompose the time-frequency change 
features of big data, the adaptive recommendation model 
 
Figure 1: Attributes of Big Data Technology. 

Regional Network Education Information Collection Platform ... Informatica 45 (2021) 613–620 615 
 
of big data mining based on Hadoop platform is 
designed. Optimize the performance of big data mining 
on Hadoop platform. the accuracy of data mining 
increases with the number of iterations. Strong redundant 
interference capability [19]. Xia, et al. proposed a 
parallel adaptive Canopy-K-means method. Based on 
statistical method, the algorithm can adaptively 
determine the distance threshold parameter T2. In cloud 
computing framework, by using the parallelism of Map-
Reduce computing models. A parallel Canopy-K-means 
algorithm is optimized by adaptive parameter estimation, 
solve the problem that the parameters depend on manual 
experience selection in the Canopy process. After 
introducing the theory and derivation of the algorithm. 
Based on the Spark framework, the cloud computing 
experimental platform is constructed. Using Stanford 
Large Network Data Set (SNAP) data set and self-built 
Dimension Networks data set, a comparative experiment 
is carried out [20]. Hu, et al., in order to solve the 
problem of high cost of traditional data computing and 
storage and difficult to write parallel programs, 
summarized the core technologies of Hadoop, and used 
Hadoop distributed processing technology and 
virtualization technology to design and construct cloud 
computing storage platform. Experiments show that the 
platform has higher performance and higher resource 
utilization than the traditional single machine computing 
method and physical machine cluster computing method 
[21]. 
Songsangyos & Nilsook, stated that the 
characteristics of big data can be used to get the insight 
of reality by using the abundant amount of data for 
analysis [22]. The knowledge management can also be 
used for successful and rapid information generation. 
Hariri et al. [23] presented a big data approach that 
require high velocity reliable data for confirming the 
accurate information related to the results predicted by 
the data analysis. The predictive analytics was used by 
Altaye & Nixon in order to use the data mining technique 
for analyzing the student behavior for providing the 
interactive learning management [24]. Behavior 
detection can be described from the student’s facial 
expressions, his participating activities, model 
knowledge and understanding. Kumar and Singh reveal 
that the Hadoop platform was developed for recording, 
organizing and analyzing the data effectively by 
separating it from big data [25].   
With the continuous improvement of people's living 
standards, the demand for education and other public 
services is expanding, and the desire to solve the problem 
of imbalance and insufficiency of educational resources 
in various regions is more urgent [26]. The deep 
integration of the Internet and education provides new 
ideas and new ways to meet people's needs and solve 
various problems. The research on big data of online 
education can provide better education services for 
educational activities, drive the reform of teaching mode 
and optimize the teaching methods of education [27,28]. 
Therefore, this article has developed a regional network 
education information collection platform based on big 
data technology. This platform can collect students' usual 
learning behavior, learning content, learning preferences 
and other data, so that the subsequent data mining 
technology can be used to analyze and process the data to 
achieve personality. Recommendations are optimized to 
achieve the goal of optimizing information push services, 
so as to improve user learning efficiency and increase 
effective learning quality. 
3 Platform design 
The platform designing of software and physical 
architectural design is discussed in this section. The 
section also describes the function realization of the big 
data technology-based education information collection 
platform.  
3.1 Platform software architecture design 
The platform software architecture design describes the 
logical results and design methods of the entire system, 
and reflects the role of logical abstraction of the network 
education big data collection platform [29]. In the usual 
software architecture design work process, the software 
architecture diagram will explain the layers of the 
software architecture structure, and at the same time, it is 
also necessary to explain the relationship between each 
layer structure. This online education big data collection 
platform is divided into basic layer, platform layer and 
access layer according to the different services provided. 
The overall software architecture is shown in Figure 2. 
(1) Basic layer: Based on server, storage, network 
and virtualization system. By integrating infrastructure 
resources and improving the utilization rate of resources, 
it provides an extensible, safe and stable basic support 
for the educational big data analysis system [30]. In this 
paper, the Hadoop platform and its surrounding open-
source components are used to build the basic layer 
service and store the educational data set. 
(2) Platform layer: Based on the data analysis and 
acquisition platform, according to the data is collected, 
cleaned, converted, collected, regulated and monitored 
according to the data standard specification, and the 
buffer library is established. Through the meta-database 
to standardize the data integration, management and 
service process, establish a central library. Through the 
data mart, data warehouse and other forms of external 
data retrieval, data analysis, data reports, access 
interfaces, data comparison and other services. For 
 
Figure 2: Platform software architecture. 

616 Informatica 45 (2021) 613–620 Y. Li et al. 
 
network education big data application system, data 
analysis applications to provide data support. 
3) Access layer: Provide access channels for all users 
who visit the platform. Students or teachers can access 
the application platform by means of a browser, or access 
through platforms such as WeChat. 
3.2 Platform physical architecture design 
For the smooth realization of the platform's expected 
functions and facing the user community, we must design 
on the physical architecture [31-33]. Among them, Web 
server provides online information browsing service, and 
Hadoop cluster provides data storage service. 
(1) Web server 
The entry that students and teachers use to enter the 
system with the main function is the Web client. In the 
target system, Web browser is the main application 
software of the client, and the core function of the system 
is realized on the Web server. Web browser performs 
data interaction through TCP/IP network protocol. 
Students and teachers log in to the user interaction 
interface through Web browser to realize the functions of 
personal information management, knowledge inquiry, 
knowledge evaluation, and knowledge collection. The 
Web server presents an operable interface to the user to 
accept user input. The system administrator also uses this 
user interface to manage the system and make settings. 
All user input is transmitted to the Web server through 
the HTTP protocol, and the server performs processing 
and calculation according to the established business 
logic. And store the results, and finally send the 
processing results back to the operator in an easy-to-
understand manner. 
(2) Hadoop cluster 
In order to meet the real-time distributed storage 
network education big data, and be good at log analysis, 
it can further analyze the user behavior data generated 
during the learning process of students and teachers [34-
36]. Hadoop is a distributed system infrastructure 
developed by the Apache Foundation. It enables users to 
develop distributed programs when the underlying details 
of the distribution are unclear, and make full use of the 
powerful functions of the cluster to achieve high-speed 
computing and storage. 
3.3 Platform function realization 
In the field of online education big data, one big data 
type is student data. The content of student data covers a 
wide range, and the basic information of students, 
academic study information, daily study habits and other 
information can be summarized in it. As an online 
education big data analysis platform, it is necessary to 
gather the above information first, so as to understand the 
various learning dynamics of students in different 
directions to promote the good and healthy development 
of students [37]. Assuming that it is now necessary to 
collect data on the information on a campus website, the 
page crawling process during collection is shown in 
Figure 3. 
First, the page crawler sends a request according to 
the set URL link to obtain the requested page 
information. After receiving the response, the entire page 
structure is parsed. During the analysis, the 
corresponding content is captured according to the preset 
filtering rules, and then the page is captured. The 
program then persistently stores the captured data in the 
database. The data collection function of the entire page 
is mainly implemented by Iuntanitem, LtSpider, and 
Dbpipe. The Iuntanitem class is an entity class, LtSpider 
is a business logic processing class, and Dbpipe is a data 
manipulation class. Good scalability and maintainability. 
The class diagram is shown in Figure 4. 
The Iuntanitem class defines the data items captured 
by the page. The captured content is the author, title, 
class content and reply in the page. In the Iuntanitem 
class, four data fields, zuozhe, biaoti, leirong and 
huifushu, are defined with the Field () method. The data 
obtained by data collection will be encapsulated in this 
class and stored persistently. The LtSpider class is 
responsible for performing page crawling. The name 
attribute in this class can set a name as the identifier of 
the page crawler. This identifier will be unique: the 
start_urls attribute of this class, used to store the URL 
list, and the crawler uses the address in the list Page 
crawling for the starting target; pagelink instantiates a 
Link Extractor object; rule defines a rule parser. Dbpipe 
defines three methods, _init_() for initialization 
operations, such as initializing a database connection, 
process_item () for data persistence operations, and 
close_spider () to close the link. Page crawling is 
completed by the crawler class LtSpider, link extractor 
class Link Extractor instance pagelink, rule parser rule, 
item class and pipeline class Dbpipe. First, the crawler 
LtSpider requests the page according to the initial URL 
and obtains the content of the page. According to the 
 
Figure 3: Page crawl flow chart. 
 
Figure 4: Page crawler diagram. 

Regional Network Education Information Collection Platform ... Informatica 45 (2021) 613–620 617 
 
page content link extractor pagelink, the links in the page 
are extracted according to the set extraction rules. 
Analyze the specific page content associated with each 
link one by one, that is, the rule parser rule calls the 
callback function parse_item () and passes in the page 
content. The callback function parses the page content 
according to the specified parsing rules, and parses and 
extracts the data according to the preset field. The parsed 
data is submitted to the item class as a list type for 
encapsulation. Finally, the encapsulated item is passed as 
a parameter to the pipeline class Dbpipe for data 
persistent storage. 
4 Results and analysis of platform 
function tests 
According to the life cycle of software engineering, after 
the initial software requirements analysis, overall system 
architecture design, detailed system design, and coding 
implementation, the software system must be tested 
before it is officially launched. In this link, it is necessary 
to simulate the actual operating environment to test the 
system before the target system is officially put into 
operation, so as to achieve the effect of timely 
discovering system loopholes and eliminating system 
failures. In order to ensure that the system has a certain 
degree of stability and robustness in the actual 
environment after it is online, it is necessary to use some 
open-source test tools on the market to simulate the 
overloaded operating environment, test the performance 
level of the system in this environment and whether there 
is fatal performance defect. Due to the large amount of 
information in online education data, there are also 
certain requirements for the efficiency of data extraction. 
The online education big data platform is a big data 
experimental platform open to all online learners, with a 
large user base and a large number of people. The 
amount of daily collected and submitted data is very 
huge, so verifying the platform's data collection 
performance is a reference standard for evaluating 
whether the platform can operate stably under the 
condition of large amounts of data. The data set used in 
the test comes from posts, blogs, news forums and so on. 
There are 29462 data records. Data acquisition 
performance test cases and results are shown in Table 1. 
Table 1 shows that the data acquisition of different 
data item field length in this educational big data 
acquisition platform is larger than the expected index, in 
which the data item field is less than 20, and the 
acquisition amount is 145% of the expected result. When 
the data item field is between 20 and 40, the acquisition 
amount is 137% of the expected result. When the data 
item field is between 40 and 50, the collection is 116% of 
the expected result. When the data item field is between 
50 and 60, the collection is 103% of the expected result. 
This education big data acquisition platform collection 
performance is excellent. 
In order to access the usefulness of big data 
technological concept for enabling smart classroom 
approach, a questionnaire was conducted for the students 
to rate it from 1 (never) to 5 (always). The questions 
included in the questionnaire are: 
(1) Was I totally engaged while participating in the 
classroom activities? 
(2) Meaningful connection is made between the 
instructor and the students in the class activity. 
(3) The descriptive statistics for the questionnaire 
conducted are depicted in Figure 5 explaining the 
different opinions of the students grading their level 
of engagement.  
This comparison reveals that the classroom 
engagement of students is 57% using the smart big data-
based platform and the meaningful connection between 
the students and the instructor is 52%. The questionnaire 
was filled by the students themselves and further they 
were also asked to compare the big data smart classroom-
based approach with the normal teaching method. The 
questions asked during the survey are: 
(1) Compare the normal teaching with the smart 
classroom-based approach. (rate it on the scale of 
1(Regular teaching is better) to 5 (Smart classroom 
Serial 
number 
Test 
description 
Test 
expected 
results 
Actual 
results 
1 Data item 
field is less 
than 20 
Collect 
3000 
records per 
second 
Meet the 
expected 
result 
2 The data 
item field is 
between 20 
and 40 
Collect 
2500 
records per 
second 
Meet the 
expected 
result 
3 The data 
item field is 
between 40 
and 50 
Collect 
2300 
records per 
second 
Meet the 
expected 
result 
4 The data 
item field is 
between 50 
and 60 
Collect 
2000 
records per 
second 
Meet the 
expected 
result 
Table 1: Data collection performance test cases and test results. 
 
Figure 5: Level of students’ engagement in the smart classroom 
activities. 
3%
5%
15%
57%
20%
4%
9%
10%
52%
25%
0%
10%
20%
30%
40%
50%
60%
Never (1) Rare (2) Often (3) Very Often
(4)
Always (5)
Percentage (%)
Classroom Engagement

618 Informatica 45 (2021) 613–620 Y. Li et al. 
 
is much better)) 
(2) Compare the smart classroom-based approach to 
have the same material as normal teaching. (rate it 
on the scale of 1(Regular teaching is better) to 5 
(Smart classroom is much better)) 
This comparison done in Figure 6 reveals the 
usefulness of the smart classroom-based approach in 
respect to the regular teaching method. The majority of 
student with 82% population agreed that the smart 
classroom-based approach is better than the regular 
teaching method and 87% of them says that also the 
study material provided through this big data-based 
methodology is creative and better as compared to the 
regular teaching. 
The survey conducted on the basis of student’s 
learning is done in the experimental class of usage of big 
data-based teaching platform for enabling smart 
classrooms. The outcomes of the survey are presented in 
Table 2. 
The survey depicted in Table 2 is purely based on the 
classroom observations and recording of students' 
attitude and behavior by experimental teachers in the 
whole process of classroom interaction. 
5 Conclusions 
Based on the knowledge and application of big data 
technology, this paper designs and implements an 
educational big data collection platform in accordance 
with the actual needs of social users. The main tasks as 
follows: 
(1) The software structure design and physical structure 
design of this platform are introduced. The software 
structure of this platform is mainly divided into 
basic layer, platform layer and access layer. The 
physical structure mainly includes web servers and 
Hadoop clusters. 
(2) The implementation of data collection and storage 
on this platform is introduced. 
(3) The data collection efficiency of this platform was 
tested. The test found that the education big data 
collection platform has excellent collection 
performance, and the data collection of different 
data item field lengths is greater than the expected 
index. When the data item field is less than 20, the 
collection volume is the expected result. When the 
data item field is between 20 and 40, the collection 
volume is 137% of the expected result. When the 
data item field is between 40 and 50, the collection 
volume is 116% of the expected result. The data 
item field is introduced between 50 and 60, the 
collection volume is 103% of the expected result. 
A comparison is done of the regular teaching 
method with the smart classroom-based concept and it 
was revealed from the outcomes that the big data 
platform is 87% better than the normal regular teaching 
methods in terms of study material as well as 
meaningful interaction between the students and the 
instructor. 
6 Acknowledgements 
(1) National Social Science Fund Key Project: 
Research on the Governance of Officials’ Inaction 
Based on the Theory of Planned 
Behavior(17AZZ014); 
(2) Major Project of Shaanxi Provincial Social Science 
Foundation: Research on Establishing A Query and 
Traceable Feedback Mechanism for Power 
Operation to Effectively Broaden Supervision 
Channels (2020ZDWT02). 
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Figure 6: Comparison of normal teaching with the smart 
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Student’s  
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