[Retracted] Preschool Education Based on Computer Information Technology Literacy and Big Data

Luo, Lan

doi:https://doi.org/10.1155/2022/4457811

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Abstract Introduction Related Works Discussion Conclusion Data Availability Conflicts of Interest References Copyright Related Articles

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Research Article | Open Access

Volume 2022 | Article ID 4457811 | https://doi.org/10.1155/2022/4457811

[Retracted] Preschool Education Based on Computer Information Technology Literacy and Big Data

Lan Luo¹

Academic Editor: Sweta Bhattacharya

Received05 Aug 2022

Revised24 Aug 2022

Accepted02 Sept 2022

Published12 Oct 2022

Abstract

In this practical framework, the preschool teacher is reinforced to utilize a more significant teaching model, like forming real-time-based contextual issues, to help participants to identify a deep learning-based learning model. Numerous studies have been released as a result of the popularity of the use of CIT in preschool education as a research subject. Due to the fact that it broadens teaching resources, provides learning time flexibility, and strengthens teacher-student relationships, this teaching method has received a lot of attention in academia. Teaching strategies in preschool classrooms combine elements of both direct instruction and free play. Among these, CIT stands out as a powerful tool for boosting students’ motivation and engagement in the classroom. Integrate new technology and science into the classroom setting, as well as implement pedagogical changes that make use of IT. Preschool education informatization is now deploying new technology in a variety of preschools, yet there are still flaws. In this paper, a theoretical and problematic-based classifier model, a deep learning-based methodology that was reinforced by utilising a Python-based model to create the comprehensive among preschool students and high-phase semantic parameters, and to enhance computer-based teaching through estimation and text design that can detect high-frequency-based knowledge samples, are used. In this practical model, teachers are insisted to utilize significant frameworks like contextual issues to provide skills to students. The results show that this integrated CIT teaching method is suitable for students and able to raise their aptitude and enthusiasm for studying. By offering new theoretical and practical results about preschool education, the study helps to reform preschool education.

1. Introduction

Internationalization is currently undergoing rapid development for English proficiency [1]. English classes make it difficult to ensure instructional effectiveness. The number of classrooms is rapidly increasing in tandem with the shift in educational paradigms. The teacher must teach numerous students throughout the real teaching process, and it is tough. Researchers discovered that when the static image target detection model is used, the results are unsatisfactory [2]. As a result, researchers integrate the video’s temporal and context information to conduct target detection [3]. The detection is first completed by a single frame of photos in the postprocessing stage.

However, because this method is usually multistage, the findings are influenced by the results, and correcting errors in the prior stage might be difficult. There are unresolved issues in the video caused by object motion [4]. To improve the identification accuracy, recently researchers employed Long Short-Term Memory (LSTM) to combine video time to maximize the features of fuzzy frames [5]. In addition, the feature propagation is achieved via optical flow-related technologies. In video target detection, recurrent neural networks (RNN) are interleaved with feature extractors [6]. There are numerous flaws in the current research’s accuracy when compared to prior studies [7]. Its performance will be affected by the detecting target and will have a certain gap. The complex situations and model design are all areas where it could be improved [8]. The SSD base network has been adequately replaced. To improve computational efficiency, the network’s characteristics are employed to tune the network parameters. The deep feature map’s data is blended upward improving the accuracy of tiny target calibration. Finally, experiments involving student behavior are examined. It shows that small target recognition accuracy may be enhanced without affecting the computation speed of standard algorithms. These are important for improving the efficiency of English classroom teaching since they assist teachers to understand the student’s learning status [9].

Language teaching professionals must adapt concepts and roles, as well as systematize the disorganized techniques of language training [10]. Teachers should be able to formulate the process of learning using network resources and manage every student’s capability. Artificial intelligence is used extensively in the development of intelligent computer-assisted education systems [11]. The final goal of the study is to assume relevant educational and teaching tasks, i.e., to equip the computer system for optimal instruction [12]. The significance of current system education broadens the preschool learning. Individuals are acquiring a growing number of network teaching platforms. Due to the network education environment’s increasing complexity and temporal and spatial isolation, management and teachers are having difficulty assembling dynamic learning [13]. This leads to a straightforward reproduction and a one-sided pursuit in current teaching [14]. With such a large number of online learners, determining a reliable method for collecting learning status has become crucial [15].

Time is a critical issue that must be addressed immediately with the advancement of multimedia and network technologies [16]. Individuals have been constantly exploring and attempting to apply new technology [17]. Simultaneously, we attempt to teach children according to their aptitudes and to provide individualized education based on pupils’ diverse learning foundations, skills, and other characteristics [18]. It is difficult to educate because of a lack of teacher resources and instructional efficiency standards. Modern education eliminates the geographical constraints associated with conventional schooling [19]. It is critical for optimizing the resource benefits of varied existing educational systems while maintaining an acceptable resource allocation. Additionally, it presents a workable solution to the problem [20].

To tackle the issues of the current network system, this study builds and creates a model of a network teaching system. Computer-assisted instruction is progressing toward intelligent instruction. It is a style of instruction that utilizes a computer to simulate the instructional thinking process of professionals, with the students at the center and the computer serving as the channel [21]. Intelligent teaching is founded on contemporary educational theory and utilizes the latest breakthroughs in artificial intelligence to enable students to acquire knowledge in order to accomplish the objective of truly personalized instruction [22]. The majority of the research effort has been directed to ad hoc research institutes, the majority of which are research and demonstration systems, and just a few have been thoroughly explored [23]. It will contribute positively to China’s education reform through computer-assisted systems.

In the past, theorists and researchers debated whether or not young children should use computers in school [24]. One viewpoint argues that technology is inappropriate for young children because they require concrete items to solidify their information. Additionally, excessive screen time can overwhelm a young child’s senses, resulting in concentration issues and difficulty focusing. Similarly, excessive use of technology may increase the risk of muscular-skeletal injuries in young children. Additional potential negative implications of early technology use include diminished reading abilities and a loss of imagination. The opposing perspective asserts that developmentally appropriate technology use can aid in the learning of young children, particularly in the area of emergent reading abilities. The usage of technology by younger children has been associated with greater motivation and student-centered learning practices [25].

The argument in early childhood settings has recently changed from whether or not to use technology to how to utilize it and how it affects children’s learning and development [26]. Determining the proper level of technology integration into pedagogical practice and curriculum design is a challenge for educators and policymakers in early childhood settings. Several scholars have suggested that practitioners take a deliberate approach to technology use, assessing the technology’s design to see if it supports creativity, curiosity, and play, encourages kid engagement, and provides an authentic learning experience. Researchers invented the phrase “developmentally appropriate technology use” to describe learning that is led by children and encourages collaborative problem-solving [27]. The goal of this research was to perform a thorough review of the literature to identify the impact of digital technology in education settings.

Researchers highlight a range of ways that children might be involved in global contexts when describing the textual landscape [28]. While there has been a rise in calls and an expansion of children’s experiences of this environment in their literacy teaching over the last decade, there are still differences over the function of new technologies in childhood settings. Others worry that young children will be exposed to unsuitable content, put their safety in danger through Internet contacts, or interpret data without critical thinking [29].

At the same time, examinations have revealed a backlog in efficiency and proficiency among new technologies, as seen in Figure 1. Following an examination of the role those new technologies appear to play in the practices under investigation, researchers [30] work to elicit technologies that might be influencing these practices, as well as how a shift in the researcher’s perspective might reveal other important aspects of children’s interactions with new technologies. It has been argued that some preschools expose children to academic pressure at an inappropriate age. In the context of educational initiatives, this is a particularly pressing issue. Frustration and a loss of interest in learning are the results of attempting to master reading, writing, and arithmetic before one is developmentally ready.

Hence in this paper, the research on preschool education based on computer information technology literacy and big data was described. The further part of this article is categorized as follows: part II provides the related works; part III explains the proposed method; part IV explains the results and discussion; part V explains the conclusion.

Language teachers in a networked environment must analyze existing communication channels from the practice end of the teaching, as well as modify ideas and roles [31]. By researching the teaching network using the UML framework language, Reference [32] offers a methodology and pattern design to swiftly produce reliable performance. The modern system-based teaching learns from the literature [33], including learning fillings, and each platform concentrates primarily on nurturing students’ capabilities of listening, speaking, reading, and writing. Traditional language-learning methods are combined literature. Teachers should be able to create the learning process using network resources and attain every capability of students to steer the system [34]. The student method is significantly at personalized education, according to the literature, and it is responsible for the systematic depiction of students’ knowledge level and other data [35]. The primary goal is of features and attitudes while also providing a framework for content creation and instructional tactics. Educational goals should encompass cognitive ability and emotion, with cognitive ability targets separated into six tiers based on the difficulty of intellectual activity [36].

The framework was designed following an extensive investigation. The student model is built on the interaction and response history of the students, and it is updated as the students’ learning changes. The technology can then personalize lessons based on the student model. This study creates a DL based on past research and the current state of the Chinese language network education system. It also categorizes students’ learning and offers various teaching tactics and materials depending on those characteristics. By developing a learning environment based on the characteristics of pupils in real time, the technique enables true customized teaching [37].

Deep learning is a crucial topic in education, despite the reality that the research themes are so different. This information has come from text and voice recognition, as well as certain specialist tournaments. Deep learning is an educational strategy that encourages pupils to think outside the box while also modifying their learning patterns in order to improve learning quality. Multimedia education has gained in popularity in schools during the 1990s, with a growing number of people considering problem-solving as an important part of the learning process. Teachers should emphasize the vital role of students’ learning and assist them through autonomous thinking, according to the study. CNKI published 7177 papers on the topic of “deep learning” between 2005 and 2019. There was just one result for “deep learning” and “teaching ideology and politics,” whereas deep learning is defined as the development of new ideas based on a deep understanding of the subject [38].

Students’ ability to critically examine, reflect on, and express what they have learned is emphasized in deep learning. I defined the properties of deep learning and said that higher-order thinking is the most essential part of deep learning in the study. They also mentioned that heuristic theory can assist students to improve their higher-order thinking abilities, which is an important part of deep learning [39].

Meanwhile, many academics distinguish between deep and shallow learning in various ways. Surface learning differs from deep learning. Similarly, the methodology examines the current status of deep learning research and, based on that assessment, offers some current research fields. Learning on a more in-depth level due to China’s late entry into deep learning research, research on the underlying theory of deep learning [40].

Researchers [41] look at how high school students might learn more deeply about philosophy by relating it to their personal lives and taking action. Students should be taught in a way that takes into account their long-term development guides students’ thinking through the use of a real-life problem situation and inspires them to study deeply [42]. In this way, students will be able to learn about philosophy and politics while simultaneously strengthening their core reading. In the political theory class, the strategy is built on a system that recommends what students enjoy and three machine learning models that can figure out what individuals like.

These algorithms are used by this platform. Machine learning and deep systems were used to investigate an online teaching system for ideological and political education. This was done in order to have a better understanding of how deep learning and machine learning are used in institutions [43]. Deep learning has recently sparked a lot of interest in education, and there is a rising corpus of literature on the topic each year. Although there is a handful, there are few studies that integrate deep learning research into the teaching of specific courses, such as high school philosophy and politics. The majority of the literature focuses on how to help students learn more profoundly from their passions, as well as teaching philosophies and methodology improvements [44]. The majority of it emphasizes the importance of “problems” in assisting students in learning more deeply, but there is almost no literature on how to design countermeasures.

3. Methodology

3.1. Data Collection

The main contexts for preschool instruction are, as already said, kindergartens and preprimary schools. We focused on Level 1 (K1; 3- to 4-year-olds), Level 2 (K2; 4- to 5-year-olds), and Level 3 when it comes to kindergarten (K3; 5- to 6-year-olds). Children between the ages of 3 and 6 may also enroll in kindergarten in a mixed-age setting. 13 kindergartens were randomly selected from Shanghai’s urban and suburban areas. All kids in the districts among the ages of 3 and 6 had access to these kindergartens. Data were gathered through the use of random sampling. The original sample of 710 participants included more than 700 children, aged 36 to 72 months, from 45 K2 and seven mixed-age classrooms. The sample size was reduced to 681 after children older than 71 months or less than 48 months were excluded. The control group (341 students) and a study group were separated into two groups (340 students). A study group is a group in which children’s education is combined with computer-based instruction, as opposed to a control group, which is a group in which children get a traditional education. 88% of courses had lead teachers, and 18% had assistant teachers. According to the survey, all observed teachers (98%) held an early childhood education (ECE) teaching certificate, 77% had an associate degree or above in ECE, and 75% had majored in ECE. In comparison to Guizhou, Shanghai’s classes had fewer students and better teacher-to-child ratios, which led to more qualified teachers. Urban classrooms in Shanghai and Guizhou frequently had longer preschool hours, better teacher-to-child ratios, and a larger percentage of teachers with an associate degree than schools in suburban or rural areas. Compared to children in Guizhou, children in Shanghai had a longer history of preschool attendance and came from families with higher levels of parental education and wealth [45]. Tables 1 and 2 provide the dataset description in detail.

3.2. Theoretical Basis of Intelligent Technology Literacy (ITL)

This method of utilizing deep learning (DL) framework for researching on preschool teaching is significantly obtained from the research on neural networks. A multilayer-based perceptron uses various hidden layers as a structure. It uses the mechanism of the human brain to intercept the data like sounds, images, and texts. DL-based models can produce various pattern-based methodologies. In view of certain research analysis, it primarily focuses on three different methods: convolution neural network, multilayer neuron-based self-encoding, and deep confidence network. This form of neural network has the capability of learning itself; the primary characteristics of training the data can be obtained, so it has a higher rate of fault tolerance and ability of memory association. Incorporating neural and ITL can significantly enhance the network’s intelligence, speed of response, and adaptability. ITL is a unique methodology that realizes the evolution of preschool mode, as it can entirely explore the behavior of participants and can guide students in forming their ability and intelligence. System based on expert analysis, student and teacher method, and machine-man interface are four vital parameters of typical ITL. The primary structure of ITL is depicted in Figure 2.

The key component of the activity is significant how to sort out the instructing content or how to educate. The intelligent point of interaction fills in as the framework’s and clients’ intuitive connection point, giving intelligent interactive media information input, and client data and conducting procurement and information yield for other modules. Regular language handling, information base upkeep, understudy model introduction, instructor model versatile change, and different capacities are all essential for the ITL. Understudy model is an information structure addressing students’ mental state, and it is the premise of ITL instruction. The dynamic design of the understudy model shows the development and association of the four parts of the ITL in the learning system, as well as their jobs in instructing choice. It tends to be seen that the understudy method is a significant function, which learns understudies’ learning exercises. By analyzing understudies’ learning ways of behaving, it records and changes the data depicting understudies’ customized characteristics, for example, their insight structure, learning capacity, furthermore, learning propensities, to draw new education methodologies.

In light of the possibility of savvy education, the design of a shrewd network showing framework is planned as a three-level B/S formation: client cooperation layer, showing application layer, what is more, dataset server layer. The client connection layer incorporates the connection points of interaction of understudies, instructors, and framework overseers and understands the association between the framework and clients through programs. The understudy association connection point is the modified showing content and learning interface given by the framework to various students.

3.3. Formation of Intelligent Technology Literacy

Understudies sign in to the framework first and afterward partake in the preevaluation test intentionally, with the goal that the framework can get a starter comprehension of understudies’ information level, mental capacity, learning style, most loved learning procedures, etc. In the subsequent review, the framework will choose the participants in the showing information base that are appropriate for understudies’ qualities and real level as per the understudies’ learning literature, cooperation with the framework, and execution in the framework indicative test; what is more, powerfully put together understudies’ learning by the educating systems in the instructing model. At the time of the process, the framework progressively creates the education system as indicated by the understudy model. Understudies can pick, judge, and manage a huge sum of information involving a canny thinking system in the canny showing collaborator framework, which shows the learning strategy designated and works on the learning impact. The groundwork of all improvement is framework investigation, which is a significant phase of computer programming. In the phase of framework investigation, an exact comprehension of the framework prerequisites and the inward working system of the framework is useful in precisely getting a handle on the framework prerequisites, with the goal that the particular substance of programming development can still up in the air, to see completely the clients’ prerequisites for the framework.

After learning an information point, understudies first consolidate their insight through relating works out and afterward survey their mental capacity using tests. The test inquiries of every information point incorporate three sorts: single-decision on participant’s questions, questions based on judgment, and survey questions. Each question can test no less than one of the over six mental capacities. The steps involved in the processing of text flow are depicted in Figure 3.

When you the test based on the preschool students, their answer is based on the cognitive capability of more parameters individually. After the preschool students finalize a certain type of question, they can estimate every capability of cognitive in this question type as below.

Most of them are desirable, ; here, is the total question of test of this ^th capability correctly responded in this type of test. is the total answer which is wrongly answered to the ability of the cognitive interface.

Suppose the type of question for every knowledge space consists of various choices, false or true answers. Based on equation (1), the capabilities of every question are estimated to formulate the evaluation ability of every question type. The proposed framework is illustrated below:

Based on them, illustrates the estimation range of the six abilities of single questions. illustrates the estimation range of six abilities of the survey questions. Knowledge range is a vital parameter of brilliant assistant-based teaching. The entire processing of a neural network is a measurable procedure for the participation of students in a system. The procedure segregates the participant degree into three various phases. The students’ participants in the department are identified as the output axis, which eventually finalizes the mapping from various space dimensional to another dimensional space.

The component of master choice-making component can be viewed as the surmising motor in the smart showing colleague framework. For the most part, it embraces the technique for consolidating two degrees of thinking, that is, thinking in light of semantic organization and thinking in view of creation rules. Among them, thinking in view of the semantic organization is utilized to decide the instructing content, while thinking in view of creation rules is utilized to determine the educating technique. Not quite the same as rule-based thinking, case-based thinking is viewed as thinking in light of past experience. Therefore, in some shrewd showing partner frameworks, case-based thinking is taken on.

The estimation to solve the quantitative estimation of problem and dimension of capability. Based to the various methods of estimation to estimate the student’s ability, describe the different weights of question types . The weight-based question is illustrated:

The weight of the question based on true or false is as follows:

The weight of questions based on fill in the blanks is as follows:

Based on them, are, individually, the estimation range of the answer on average of every question type of students after considered test. Utilizing equation (2) and weight to estimate the final calculation analysis of different abilities,

Estimate the cognitive capability of preschool students after learning this point of knowledge

4. Result and Discussion

The proposed cognitive-based methodology is a key element of the preschool. Individuals have been concentrating on the human mental process for a long time. Albeit some advancement has been made, in light of the fact that the human mental interaction is such a compound issue, laying out an ideal understudy mental methodology at this phase is just perfect. We should initially tackle the issue of how to address mental capacity to decide on understudies’ mental capacity. Understudies have an assortment of inclinations. Two inclinations are considered in this plan: information instructing and information show. The showing strategy for information alludes to the ropes understudies like to be taught, and the introduction of information alludes to the media wherein learning capability is introduced. We can utilize illustrations to exclusively address the information in the model. Figure 4 illustrates the comparative analysis of teaching score for the original and preschool teaching system.

The teaching methodology is utilized to manage the content of teaching based on the student’s model in the teaching methodology. This strategy function has developed three primary strategies. (1) Maintain the learning process using knowledge points. (2) Utilized prerequisite-based knowledge NN alters the association loads of the organization structure through versatile calculation, so the organization approaches the normal information yield relationship, can consequently change the boundaries as per the changes of info information, and can advance the framework to better mirror the learning attributes of understudies. The number of information level hubs is 5. The yield layer is planned as per the understudies’ learning state and attributes to be communicated. As of now, the set result incorporates the dominance of specific learning content, learning strategies, and learning propensities. The number of stowed away layers is set on a case-by-case basis. The model understands the communication between the clients and the framework, and it is the point of interaction of two-way exercises of educating and picking up, including understudy association interface, instructor communication connection point, and head interaction interface; simultaneously, it incorporates the plan of interfaces among the models. The model primarily utilizes web to express and convey the substance.

Preschoolers often make mistakes in their learning because they are not mature enough to understand the depths of the methods they are using. This particular system will iterate based on the student’s examination in the learning process. After a period of time, students get emotion, by which the network can enhance the learning process of the students by utilizing psychological parameters. Figure 5 illustrates the deviation in the target score with a total of repetitions. As of now, the set result incorporates the dominance of specific content on learning, learning strategies, and learning propensities. The total of stowed away sheets is set on a case-by-case basis. The model understands the cooperation between the clients and the framework, and it is the connection point of two-way exercises of instructing and getting the hang of, including the understudy collaboration interface, educator association point of interaction, and head interaction interface; simultaneously, it incorporates the plan of interfaces based on the framework. The model utilizes the web to infer and impart the substance.

Although some advancement has been made, in light of the fact that human mental interaction is like significant issue, laying out an ideal understudy mental stage model is just ideal. We should initially settle the issue of how to address mental capacity to decide understudies’ mental capacity. Understudies have an assortment of inclinations. Two inclinations are considered in this plan: information instructing and information presentation. The showing strategy for information alludes to the ropes understudies like to be taught, and the introduction of information alludes to the media wherein learning content is introduced. Figure 6 illustrates the variable score of ability based on preschool methodology.

5. Conclusion

The machine learning-based methodology of the unique course contents of the preschool teaching framework was formed utilizing Python language, using text-based validation, and training from the questionnaires; this proposed framework is utilized to learn the knowledge frequencies of the participants and interrelated details. This framework can be utilized to manage classroom learning of very basic science online and can enhance the significance and reliability of preschool learning. In this practical model, teachers are insisted to utilize significant frameworks like contextual issues to provide skills to students. Moreover, the results showed the original system teaching score and preschool teaching score, iteration times of the target value, and the preschool method-based line graph. The future enhancement of intelligent technology literacy is analyzed and is framed out that this area with an attractive methodology view is significant for future design and methodology. Future research needs to assess the effectiveness of information technology included in the model of learning with the model without technology.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The author declares that there are no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

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Copyright © 2022 Lan Luo. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Journal of Sensors

Advanced Machine Learning and Big Data Analytics with IoT Sensor Data

[Retracted] Preschool Education Based on Computer Information Technology Literacy and Big Data

Abstract

1. Introduction

2. Related Works

3. Methodology

3.1. Data Collection

3.2. Theoretical Basis of Intelligent Technology Literacy (ITL)

3.3. Formation of Intelligent Technology Literacy

4. Result and Discussion

5. Conclusion

Data Availability

Conflicts of Interest

References

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