Research on the Innovative Path of Intelligent Technology-Enabled Curriculum Design in the Process of High-Quality Development of Higher Education

Education, science and technology, and human resources are the basic and strategic support for the comprehensive construction of a modern socialist country, which has put forward new requirements for the high-quality development of education. Promoting the digitalization of education and building a learning society and a learning country with lifelong learning for all people not only indicates that education has an irreplaceable and important position in the process of comprehensively building a socialist modernization in China, but also shows that the digital transformation of education has become an important path for China to build a strong education country at present. And one of the important features of education digitalization and informatization is the deep integration and mutual empowerment of artificial intelligence and education.

The process of high-quality development of higher education in the age of intelligence refers to the process of combining modern higher education theories with intelligent science and technology, so that the concept of higher education curriculum, curriculum content and curriculum design can reach the modern advanced level, and promote the continuous development and enhancement of the intelligence of higher education objects in order to cultivate advanced intelligent talents [1-2]. Higher education curriculum design is a complex work, using the outstanding advantages of intelligent science and technology to clarify the curriculum objectives, organize the curriculum content, promote the implementation of the curriculum, and carry out the curriculum evaluation, so as to innovate the higher education curriculum design [3]. Intelligent technology-enabled curriculum design is not only an intrinsic requirement for the modernization of higher education, but also an important path to enhance students’ intelligence and cultivate intelligent talents [4]. Through the construction of intelligent curriculum, we can continuously promote the modernization of higher education curriculum, rationally formulate the practical path of modernization of higher education curriculum, effectively improve the quality of higher education curriculum and teaching effect, and then promote the comprehensive development of students’ intelligence, and cultivate more intelligent talents for the construction of the country and the development of the society [5-7].

The arrival of the intelligent era makes the structure of society’s demand for talents change from professional knowledge to comprehensive and intelligent, and it is necessary to use intelligent science and technology as a means to promote the intelligent transformation of higher education curricula. Aljawarneh, S. A. demonstrated that web-pervasive learning tools can help students establish easy interactions between real and digital learning resources, and also provide them with personalized learning opportunities that effectively improve students’ contextual awareness and learning experience [8]. Subhash, S. et al. investigated the implementation of gamification and game-based learning systems in higher education, which through the integration of gamification elements fully provide the opportunity to develop the teaching-learning process and effectively improve student engagement, motivation and performance [9]. Rasul, T. et al. discussed the benefits and challenges of the generative AI model ChatGPT in higher education, arguing that faculty and students must ensure ethical, reliable, and effective use of ChatGPT in order to maximize the student learning experience in higher education by balancing potential benefits and challenges [10]. Murillo-Zamorano, L. R. et al. constructed a structural equation model to analyze the impact of a smart flipped classroom on students’ knowledge, skills, and engagement, and empirical research proved that this impact was positive and helped to enhance students’ employability in the digital age [11]. Aguilar, J. et al. describe how to invoke and use the components in a smart classroom to develop learning analytics tasks to adapt and respond to the teaching and learning needs of students, in addition to its ability to further improve the student learning process by defining a kind of feedback loop on knowledge [12]. Guri- Rosenblit, S. emphasizes that smart technologies in higher education environments should be used mainly for additional functions and not as a substitute for teaching and learning activities with the involvement of the teacher, this is due to the inability or unwillingness to learn autonomously without the guidance of a professional teacher for the construction of knowledge, based on which proposes some strategies for a more adequate use of technology in teaching and learning [13]. Tarus, J. K., et al. analyzed the important role of resource recommendation systems in the context of online learning, and e-learning recommendation systems can help learners find useful and relevant learning materials that meet their learning needs and effectively solve the problem of information overload [14]. Wijngaards-de Meij, L. et al. introduced a new approach to enhance course visibility, the Digital Course Map tool, which reproduces students’ learning trajectories in a course in terms of four themes: course development, visibility, assessment and learning enhancement [15].

In the era of intelligence, the evaluation of higher education courses shows a diversified trend, and intelligent evaluation systems can be developed with the help of intelligent science and technology to promote the modernization of the evaluation of higher education courses. Stough, T. et al. compared the results of the evaluation of courses by two methods, namely the credit transfer accumulation system and the self-assessment of supplemental course documents, and found that the two methods have validity problems in the evaluation of the real sustainability integration program. Validity issues, the use of intelligent tools for sustainability assessment in higher education deserves in-depth study [16]. McInnes, R. et al. examined online course quality assessment tools and analyzed the building of capacity resources to support these tools, and by summarizing the key attributes of course quality assessment tools, they proposed specific core criteria for measuring course quality, which provide educators with metrics for optimizing online course design [17]. Tsimaras, D. O. et al. noted that the pros and cons of online instructional tools can be systematically assessed using data analysis techniques, and so text analysis methods were used to quantitatively assess the positive or negative content of participants’ responses to online courses from answers to open-ended assessment questions, which facilitates improvement by educators [18]. Noaman, A. Y. et al. proposed a Higher Education Quality Assessment Model (HEQAM) to determine the weights of the indicators of the model through hierarchical analysis in order to assess the quality standards of higher education institutions, and the results of the study showed that the model provided important recommendations for the top management of the university to achieve the required high quality of services [19].

Through literature review and teaching experiment analysis, this paper systematically elaborates the impact of intelligent technology on curriculum design, proposes a curriculum design model empowered by intelligent technology, and analyzes its implementation effect. First, the importance of intelligent technology-enabled curriculum design and related applications is identified, based on which an innovative path for intelligent technology-enabled curriculum design is proposed. Then, a teaching control experiment is designed to analyze the effect of the curriculum design path proposed in this paper on students’ physical fitness and health level and physical activity attitudes by using independent samples t-test and paired samples t-test methods, respectively.

2

Innovative path design for smart technology-enabled curriculum design

2.1

Importance of Smart Technology Enabled Curriculum Design

In the process of high-quality development of higher education, intelligent technology-enabled curriculum design has the following important significance:

1)

Enhance the quality of teaching

Intelligent technology can accurately analyze students’ learning behavior and needs through big data analysis, artificial intelligence algorithms, and other means, providing a scientific basis for curriculum design. This helps teachers adjust the teaching content and methods according to the learning situation of students, and improves the quality of teaching.

2)

Promoting educational equity

The widespread application of intelligent technology, especially the construction of online education platforms, breaks the restrictions of geography and time, enabling the sharing of high-quality educational resources, which helps to narrow the education gap between urban and rural areas and regions, and promotes educational equity.

3)

Promoting Educational Innovation

Intelligent technology provides a wealth of tools and means for curriculum design, including virtual reality (VR), augmented reality (AR), and more. These technologies can create more vivid and intuitive teaching scenes, stimulate students’ interest in learning, and promote educational innovation.

2.2

Application of Intelligent Technology in Course Design

This paper takes the artificial intelligence branch of intelligent technology as the intrinsic driving force, and carries out construction and exploration after closely integrating it with higher education courses, and the driving process is in order: optimizing the course objectives, empowering course design and implementation, and perfecting course assessment and evaluation in three steps.

2.2.1

Artificial Intelligence Optimization Course Objectives

As the cohesive force of the whole classroom, the course objectives guide the development direction of the course on the one hand, and they must have clear and effective characteristics. With the support of artificial intelligence technology, through the data collection, cleaning, analysis, modeling and visualization of the teaching process, the objectives of knowledge, competence and quality adapted to the cultivation of high-quality talents in higher education can be extracted, which are progressive and mutually supportive, forming a stable dynamic structure.

On the other hand, the course objectives promote the improvement of teachers’ work efficiency and teaching skills. Teachers must deeply understand the course objectives formed under the artificial intelligence technology, enrich their own teaching behaviors, explore teaching resources, innovate teaching methods, and put them into practice in order to help students truly acquire knowledge, improve their abilities, and sublimate their qualities, and ultimately realize the high-quality development of higher education.

2.2.2

Artificial Intelligence Enabled Curriculum Design and Implementation

Driven by the curriculum objectives of knowledge, competence, and quality, AI technology has provided powerful momentum to the design and implementation of the curriculum. Given the inclusiveness and extensibility of artificial intelligence, it is easy to realize the cross-discipline. The specific steps of artificial intelligence to empower the process of curriculum design and implementation in colleges and universities are shown in Figure 1.

Step 1: Mining materials

First, use data mining algorithms and big data technology in the context of artificial intelligence, combined with the content of the course teaching and the mining of course materials.

Step 2: Building a library of materials

Under the premise of the first step, teachers play the role of “cleaning”, screen the materials for the first time under the guidance of the curriculum objectives, remove the content with negative guiding influence, unclear values, and contrary to the development trend of the content, and then use database technology to establish a course material library, and at the same time supplement the new teaching content with the latest research results and application technologies in the field of artificial intelligence.

Step 3: Classroom Integration

Give full play to the role of the material, integrate it into the classroom naturally and effectively, create a vivid and novel teaching environment with the assistance of relevant intelligent equipment, teachers organically arrange the chapter process, effectively control the classroom rhythm, the process always emphasizes the students’ understanding of the principles, methods, realization techniques, development trends and other aspects of the integration and implementation of the final.

Step 4: Updating materials

According to the classroom feedback and timely reflection on the teaching design, improve and update the teaching case again, through the feedback to constantly modify the data mining model, the formation of the teaching material library of self-adaptation, to improve its perception, and to explore more accurate material to stimulate the students’ desire to explore the knowledge.

2.2.3

Artificial Intelligence Improves Course Assessment and Evaluation

This subsection combines the design and implementation of the course, the artificial intelligence technology combined with computer vision, database and other technologies applied to the course of the various assessment links, echoing the trinity of the course objective pattern, making the evaluation links more vivid and relevant, rich and complete. In addition, artificial intelligence technology is more relevant to the actual teaching data while relieving the teachers’ work pressure, which helps to form a more perfect way of multiple evaluation of the course. The specific application process of artificial intelligence in course assessment is shown in Figure 2.

2.3

Innovative paths for smart technology-enabled curriculum design

In order to achieve the high-quality development of higher education, this paper optimizes the intelligent technology-enabled curriculum design and implementation environment, and proposes the innovative path shown below:

1)

Building an intelligent education platform

The sharing and optimization of educational resources can be achieved through the construction of an intelligent education platform. The platform must possess strong data processing and analysis capabilities, as well as the ability to gather students’ learning data to give teachers scientific teaching decision support. At the same time, the platform should also support the application of a variety of teaching tools, such as online courses, virtual laboratories, etc., to enrich the means of teaching.

2)

Integrate new technologies and update the content of teaching materials

Various majors in colleges and universities should carry out in-depth school-enterprise cooperation with enterprises, and integrate the new knowledge, new technologies and new standards required by enterprise positions into the curriculum and teaching in the aspects of curriculum development, curriculum standard development and teaching implementation, so as to enhance the degree of fit between talent cultivation and enterprise needs. At the same time, in order to help students adapt to future career needs, curriculum design should pay more attention to the integration of interdisciplinary content. Intelligent technology is utilized to assist teachers in integrating the knowledge points and teaching resources of different disciplines to form comprehensive teaching cases and situational problems, so as to improve students’ comprehensive quality and innovation ability.

3)

Strengthening teacher training

Teachers implement teaching activities, undertaking the depth and breadth of knowledge acquired by students through curriculum teaching. Teachers, as the main source of instruction, have a direct impact on the quality of teaching through their ability to use intelligent technology. Therefore, by relying on the education department and schools to emphasize teachers’ professional development ability, teachers are provided with relevant training to improve their technology application and innovative teaching ability. The training should include the basic knowledge of intelligent technology, the use of teaching tools, and innovative concepts of teaching design.

4)

Actively explore the human-machine cooperative teaching mode

Diversification of students’ learning methods in the era of artificial intelligence, human-computer collaborative learning through artificial intelligence technology represented by generative AI has become one of the main means of students’ daily learning, and students can quickly acquire knowledge through the use of generative AI. Teachers, on the other hand, can use VR, AR and other intelligent technologies to realize a virtual simulation teaching environment, so that students can carry out experimental operations, scene simulation, etc., in the virtual space, to enhance students’ practical ability and interest in learning, and to provide students with a safer and more convenient learning experience. Therefore, it is not only necessary to focus on the cultivation of students’ critical thinking in course teaching, but also to take multiple measures to incorporate many ethical and legal issues brought about by AI, such as privacy protection and algorithmic bias, into the course design, and to actively explore human-machine collaborative teaching modes in future education.

3

Model for evaluating the effectiveness of innovative pathways in curriculum design

This paper evaluates the effectiveness of the application of innovative pathways for smart technology- enabled curriculum design by designing a controlled experiment for teaching and learning, utilizing independent samples t-tests and paired samples t-tests.

3.1

Paired samples t-test

The t test, as the most basic of the statistical inference methods for continuous variables, is mainly used for normally distributed information with a small sample size (e.g., n < 30) and an unknown overall standard deviation σ [20].

t The test gives the following 2 possible hypotheses:

H₀: u = u₀ that the sample mean is not significantly different from the assumed overall mean, and that the difference that exists is due entirely to sampling error.

H₁: u ≠ u₀, The sample mean is significantly different from the assumed overall mean and the difference that exists does reflect this difference in addition to being caused by sampling error.

t The test utilizes the characteristics of the T-distribution and uses t as the test statistic to perform the test, with the specific statistical expression: (1) $t = \frac{\bar{X} - μ_{0}}{s_{\bar{X}}} = \frac{\bar{X} - μ_{0}}{s / \sqrt{N}}, Degree of freedom d f = N - 1$ $$t = {{\bar X - {\mu _0}} \over {{s_{\bar X}}}} = {{\bar X - {\mu _0}} \over {s/\sqrt N }},{\rm{Degree}}\,{\rm{of}}\,{\rm{freedom}}\,df = N - 1$$

t Tests include one-sample t tests, independent sample t tests, and paired-sample t tests. The one-sample t test is used to compare a sample’s data with the overall mean. The independent samples t test is used to compare the means of 2 groups of samples. The Paired Samples t test is used to compare the means of groups of data, where there are as many groups as there are pairs of data, and where there is some correlation between the pairs of data.

The Paired Samples t test is used to test whether paired samples come from a normal population with the same mean. The basic principle is to obtain the difference of each pair of data: if the treatment factor has no effect on each pair, the mean of the difference is equal to 0, and the mean of the samples drawn from the totals in which the paired samples are drawn should fluctuate around 0. Conversely, if the treatment factor has an effect on each pair of data, the mean of the difference is not equal to 0, and the sample mean drawn from the population in which the paired samples are located is farther away from 0 [21].

In the paired samples t-test, let x₁,x₂(x = 1,2,…n) be the paired samples respectively. Its sample difference d_i = x₁ − x₂, at which point the test statistic: (2) $t = \frac{\bar{d} - (μ_{1} - μ_{2})}{S / \sqrt{N}}$ where $\bar{d}$ is the mean of d_i, S is the standard deviation of d_i, and N is the sample size. When μ₁ − μ₂ = 0, the t-statistic obeys a t-distribution with N-1 degrees of freedom.

In fact, the paired-sample t-test is also the one-sample t-test for the difference. And the conditions for the applicability of the one-sample t-test, according to the central limit theorem, even if the original data do not obey a normal distribution, as long as the sample size is large enough, then the sampling distribution of the sample mean is still normal. So as long as the distribution of the data is not strongly skewed, the t-test is generally applicable.

3.2

Independent samples t-test

3.2.1

Principles and steps of independent samples t-tests

The basic steps of independent samples t-test are as follows:

Step 1: Establish the original hypothesis H₀: u = u₀.

Step 2: Determine the test statistics. The sample overall are consistent with the bell-shaped normal distribution curve, the variances $σ_{1}^{2}$ and $σ_{2}^{2}$ to determine the value of the two samples to estimate the sampling distribution, that is, $σ_{12}^{2}$ , can be expressed as: (3) $σ_{12}^{2} = \frac{σ_{1}^{2}}{n_{1}} + \frac{σ_{2}^{2}}{n_{2}}$ where $σ_{1}^{2}$ is the overall variance of the first sample, $σ_{2}^{2}$ is the overall variance of the second sample, and n₁ and n₂ represent the numbers in the sample data. Since it was previously determined that the samples conformed to a normal distribution. A determination of variance can be made using the Levine statistic derived from the Z-test. Because different t-tests are required for different cases of variance, before conducting the two independent samples t test, it should first be clarified whether the variances of the two are equal, in order to determine which test statistic should be used [22].

Step 3: Observe the Levene statistic F values as well as the detected two-tailed P values. Calculate the corresponding probability P values according to the distribution obeyed by the t statistic. Unlike the one-sample t test, the analysis result of the independent sample t test gives two t statistics to choose from, and the appropriate statistic needs to be selected according to the corresponding test result.

Step 4: Set the significance level α to compare with the probability P value and make a statistical decision.

3.2.2

Decision making for two independent samples t-tests

The decision for the two independent samples t test is made in two steps:

1) Examine the problem of two independent samples variance chi-square. The Levene statistic scale in the F-test determines whether the variances are equal, and the probability value P to see whether there is a significant difference between the two samples. If the Levene’s Statistical Scale in the test of detectability two-tailed P > 0.05, the two total variances are aligned. If probability P < 0.05, the two overall variances are determined to be unequal.

2) Determine whether there is a difference between the overall means of the two independent samples, the first step demonstrates the equality of variances provides the basis for selecting the appropriate t test, and then through the mode of the t test, to determine whether there is a significant difference between the two samples, the Levene’s test, which compares the P with the value of 0.05 to the difference in the conclusions drawn. Detectability two-tailed P > 0.05, there is no significant difference. Detectability two-tailed P < 0.05, there is a significant difference.

4

Analysis of the effect of pathway application

4.1

Experimental setup

In order to explore the effectiveness of the innovative path of intelligent technology-enabled curriculum design, this paper takes the design of public physical education courses in colleges and universities as the research object, and selects the students of public physical education courses in H colleges and universities as the experimental sample. Among the four classes totaling 240 students that can be studied, two classes with 120 students and 60 students in each class are randomly selected, one is the control group (32 female students and 28 male students), and the other is the experimental group (31 female students and 29 male students), and the experimental study of their teaching is carried out through 16 weeks of class time. The experimental group used the innovative approach of this paper for course content design, while the control group used the traditional approach for course design. The experimental measurement indexes include physical fitness level and attitude towards physical activity. Physical fitness levels are obtained through a physical fitness test, and physical activity attitudes are scored through a questionnaire.

Before and after the experiment, the students in the experimental group and the control group were tested for their corresponding physical health level, including lung capacity, 50m, standing long jump, seated forward bending, 800m/1000m, and pull-ups/sit-ups. In terms of questionnaire distribution, among them, the evaluation indexes of physical activity attitudes included behavioral attitudes, goal attitudes, behavioral cognition, behavioral habits, behavioral intentions, emotional experience, sense of behavioral control, and subjective standards. The Cronbach’s alpha coefficient of the questionnaire scale was 0.914>0.7, the KMO value was 0.895>0.8, the p-value of the Bartlett’s test of sphericity was 0.000<0.05, and the explained rate of the rotated cumulative variance was 85.79%>50%, which indicated that the scale had good reliability and validity.

4.2

Analysis of changes in physical fitness levels

Independent samples t-test was conducted on the physical fitness level of the experimental group and the control group before the experiment, and the results of the independent samples t-test on the physical fitness level before the experiment are shown in Table 1.

Table 1.

Independent sample t test results of physical health before the experiment

Test item	Experimental group(N=60)	Control group(N=60)	t	P
Test item	M±SD	M±SD	t	P
50m	75.46±8.973	76.37±7.817	-0.678	0.598
Sit-ups/Pull-up	52.38±31.527	48.64±30.821	1.284	0.273
Standing long jump	75.18±11.254	72.42±11.146	1.976	0.082
Vital capacity	83.15±7.584	82.87±7.935	0.425	0.864
Sit-and-reach	75.64±9.543	73.48±11.326	1.462	0.197
800/1000m	76.37±9.856	75.49±10.725	0.667	0.601

As can be seen from Table 1, the independent sample t-test P-value of the performance of the experimental group and the control group in the six test items of lung capacity, 50m, standing long jump, seated forward bending, 800m/1000m, and pull-ups/sit-ups before the experiment is greater than 0.05, which indicates that there is no significant difference between the experimental group and the control group in the physical fitness level before the experiment and they have chi-square sex.

The results of independent samples t-test of physical fitness level of experimental and control groups after the experiment are shown in Table 2.

Table 2.

Independent sample t test results of physical health before the experiment

Test item	Experimental group(N=60)	Control group(N=60)	t	P
Test item	M±SD	M±SD	t	P
50m	82.25±9.734	78.41±8.215	2.546	0.032
Sit-ups/Pull-up	66.51±28.413	52.48±25.761	2.758	0.006
Standing long jump	85.41±13.721	76.37±12.782	1.472	0.021
Vital capacity	92.43±6.454	86.37±8.046	1.215	0.046
Sit-and-reach	87.54±10.277	77.48±10.721	1.531	0.009
800/1000m	88.48±11.127	79.42±12.634	0.785	0.015

As can be seen from Table 2, the independent samples t-test P-values of the performance of the experimental group and the control group in the six test items of lung capacity, 50m, standing long jump, seated forward bending, 800m/1000m, and pull-ups/sit-ups after the experiment are 0.032, 0.006, 0.021, 0.046, 0.009, and 0.015, respectively, which are all less than 0.05, and there is a significant difference. It indicates that the course design based on an intelligent technology-enabled innovation pathway in this paper is significantly better than the traditional course design, and the teaching effect is better.

The results of the paired-samples t-test for the physical fitness level of the control group before and after the experiment are shown in Table 3. As can be seen from Table 3, there is no significant difference in the six dimensions of physical fitness level of the control group before and after the experiment (P>0.05), which indicates that there is no significant improvement in the physical fitness level of the control group before and after the experiment, i.e., the effect of the public physical education program designed according to the traditional method on the enhancement of the physical fitness level of students is not significant.

Table 3.

Match sample t test results of physical health of control group

Test item	Group	Number	Mean value	Standard deviation	t	P
50m	Before the experiment	60	76.37	7.817	-0.048	0.459
50m	After the experiment	60	78.41	8.215	-0.048	0.459
Sit-ups/Pull-up	Before the experiment	60	48.64	30.821	-1.647	0.125
Sit-ups/Pull-up	After the experiment	60	52.48	25.761	-1.647	0.125
Standing long jump	Before the experiment	60	72.42	11.146	-1.802	0.186
Standing long jump	After the experiment	60	76.37	12.782	-1.802	0.186
Vital capacity	Before the experiment	60	82.87	7.935	-1.324	0.214
Vital capacity	After the experiment	60	86.37	8.046	-1.324	0.214
Sit-and-reach	Before the experiment	60	73.48	11.326	-1.298	0.179
Sit-and-reach	After the experiment	60	77.48	10.721	-1.298	0.179
800/1000m	Before the experiment	60	75.49	10.725	-1.835	0.183
800/1000m	After the experiment	60	79.42	12.634	-1.835	0.183

The paired-sample t-test results of the physical fitness level of the experimental group before and after the experiment are shown in Table 4. As can be seen from Table 4, the P-value of the experimental group’s performance in each physical fitness level test item is less than 0.05, indicating that there is a significant difference in the physical fitness level of the experimental group before and after the experiment, which corroborates the validity of the path of course design in this paper.

Table 4.

Match sample t test results of physical health of experiment group

Test item	Group	Number	Mean value	Standard deviation	t	P
50m	Before the experiment	60	75.46	8.973	-1.852	0.045
50m	After the experiment	60	82.25	9.734	-1.852	0.045
Sit-ups/Pull-up	Before the experiment	60	52.38	31.527	-2.576	0.000
Sit-ups/Pull-up	After the experiment	60	66.51	28.413	-2.576	0.000
Standing long jump	Before the experiment	60	75.18	11.254	-2.914	0.007
Standing long jump	After the experiment	60	85.41	13.721	-2.914	0.007
Vital capacity	Before the experiment	60	83.15	7.584	-2.457	0.012
Vital capacity	After the experiment	60	92.43	6.454	-2.457	0.012
Sit-and-reach	Before the experiment	60	75.64	9.543	-2.596	0.024
Sit-and-reach	After the experiment	60	87.54	10.277	-2.596	0.024
800/1000m	Before the experiment	60	76.37	9.856	-2.741	0.001
800/1000m	After the experiment	60	88.48	11.127	-2.741	0.001

4.3

Analysis of changes in attitudes toward physical activity

The independent sample t-test of physical activity attitudes of the experimental group and the control group was conducted before the experiment, and the results of the independent sample t-test of physical activity attitudes before the experiment are shown in Table 5.

Table 5.

Test results of students’ exercise attitude before the experiment

Dimension	Group	Number	M±SD	t	P
Behavioral attitude	Experiment group	60	18.42±3.836	1.012	0.411
Behavioral attitude	Control group	60	17.38±3.245	1.012	0.411
Target attitude	Experiment group	60	29.64±2.467	-1.134	0.254
Target attitude	Control group	60	30.52±3.013	-1.134	0.254
Behavioral cognition	Experiment group	60	27.45±3.451	0.467	0.608
Behavioral cognition	Control group	60	27.24±3.257	0.467	0.608
Behavioral habits	Experiment group	60	29.33±3.842	-0.528	0.741
Behavioral habits	Control group	60	29.58±3.165	-0.528	0.741
Behavioral intention	Experiment group	60	26.06±4.524	1.513	0.109
Behavioral intention	Control group	60	25.21±4.652	1.513	0.109
Emotional experience	Experiment group	60	28.47±4.238	1.825	0.078
Emotional experience	Control group	60	26.94±4.357	1.825	0.078
Sense of behavioral control	Experiment group	60	25.26±3.424	1.713	0.105
Sense of behavioral control	Control group	60	23.98±2.955	1.713	0.105
Subjective criteria	Experiment group	60	21.31±2.563	0.986	0.265
Subjective criteria	Control group	60	20.67±2.924	0.986	0.265

As can be seen from Table 5, there is no significant difference between the experimental group and the control group before the experiment at the level of eight indicators: behavioral attitude, goal attitude, behavioral cognition, behavioral habits, behavioral intention, emotional experience, sense of behavioral control, and subjective standards (P>0.05), indicating that the physical activity attitudes of the experimental group and the control group before the experiment are more or less the same.

Immediately after the course, a physical activity attitude questionnaire was administered to both groups of students. Students in the control group were tested with the physical activity attitude questionnaire, and the data obtained from the two questionnaire distributions were analyzed using the paired samples t-test. The results of the paired samples on the experience of physical activity attitudes of the control group are shown in Table 6.

Table 6.

Match sample t test results of exercise attitude of control group

Test item	Group	Number	Mean value	Standard deviation	t	P
Behavioral attitude	Before the experiment	60	17.38	3.245	-4.934	0.012
Behavioral attitude	After the experiment	60	21.52	2.483	-4.934	0.012
Target attitude	Before the experiment	60	30.52	3.013	-0.313	0.805
Target attitude	After the experiment	60	30.85	3.157	-0.313	0.805
Behavioral cognition	Before the experiment	60	27.24	3.257	-1.725	0.072
Behavioral cognition	After the experiment	60	28.33	3.046	-1.725	0.072
Behavioral habits	Before the experiment	60	29.58	3.165	-3.936	0.017
Behavioral habits	After the experiment	60	32.44	3.316	-3.936	0.017
Behavioral intention	Before the experiment	60	25.21	4.652	-4.357	0.039
Behavioral intention	After the experiment	60	27.32	3.859	-4.357	0.039
Emotional experience	Before the experiment	60	26.94	4.357	-1.875	0.064
Emotional experience	After the experiment	60	28.67	3.763	-1.875	0.064
Sense of behavioral control	Before the experiment	60	23.98	2.955	-3.114	0.048
Sense of behavioral control	After the experiment	60	25.96	2.979	-3.114	0.048
Subjective criteria	Before the experiment	60	20.67	2.924	-1.558	0.103
Subjective criteria	After the experiment	60	21.23	3.765	-1.558	0.103

As shown in Table 6, after one semester of traditional teaching, among the eight indicators of physical activity attitude of the control group students, there are significant differences in the four indicators of behavioral attitude, behavioral habits, behavioral intention and behavioral sense of control (P<0.05), and there are no significant differences in the target attitude, behavioral cognition, affective experience and subjective criteria (P<0.05), but the comparison of scores before and after shows that all of them are slightly higher than the scores before teaching after teaching. .

Similarly, the paired-samples t-test results of the physical activity attitudes of the experimental group measured before and after the experiment are shown in Table 7.

Table 7.

Match sample t test results of exercise attitude of experiment group

Test item	Group	Number	Mean value	Standard deviation	t	P
Behavioral attitude	Before the experiment	60	18.42	3.836	-3.164	0.025
Behavioral attitude	After the experiment	60	24.53	4.012	-3.164	0.025
Target attitude	Before the experiment	60	29.64	2.467	-2.947	0.033
Target attitude	After the experiment	60	34.18	2.375	-2.947	0.033
Behavioral cognition	Before the experiment	60	27.45	3.451	-2.351	0.048
Behavioral cognition	After the experiment	60	30.59	3.852	-2.351	0.048
Behavioral habits	Before the experiment	60	29.33	3.842	-3.064	0.031
Behavioral habits	After the experiment	60	34.51	3.528	-3.064	0.031
Behavioral intention	Before the experiment	60	26.06	4.524	-4.245	0.007
Behavioral intention	After the experiment	60	32.78	4.913	-4.245	0.007
Emotional experience	Before the experiment	60	28.47	4.238	-4.053	0.011
Emotional experience	After the experiment	60	34.22	4.825	-4.053	0.011
Sense of behavioral control	Before the experiment	60	25.26	3.424	-2.359	0.029
Sense of behavioral control	After the experiment	60	29.75	4.417	-2.359	0.029
Subjective criteria	Before the experiment	60	21.31	2.563	-1.986	0.043
Subjective criteria	After the experiment	60	24.74	2.954	-1.986	0.043

As can be seen from Table 7, there is a significant difference between the eight dimensions of physical activity attitudes of the experimental group before and after the experiment (P<0.05), and when comparing their means, the mean value after the experiment is significantly higher than that before the experiment. This indicates that the physical education learning attitude of the experimental group was significantly improved before and after the experiment.

To further validate the experimental results, an independent t-test was conducted on the physical activity attitudes of the experimental and control groups after the experiment. The results of the independent sample t-test on physical activity attitude after the experiment are shown in Table 8.

Table 8.

Test results of students’ exercise attitude after the experiment

Dimension	Group	Number	M±SD	t	P
Behavioral attitude	Experiment group	60	24.53±4.012	2.786	0.024
Behavioral attitude	Control group	60	21.52±2.483	2.786	0.024
Target attitude	Experiment group	60	34.18±2.375	3.125	0.002
Target attitude	Control group	60	30.85±3.157	3.125	0.002
Behavioral cognition	Experiment group	60	30.59±3.852	2.014	0.041
Behavioral cognition	Control group	60	28.33±3.046	2.014	0.041
Behavioral habits	Experiment group	60	34.51±3.528	1.979	0.038
Behavioral habits	Control group	60	32.44±3.316	1.979	0.038
Behavioral intention	Experiment group	60	32.78±4.913	4.831	0.000
Behavioral intention	Control group	60	27.32±3.859	4.831	0.000
Emotional experience	Experiment group	60	34.22±4.825	4.916	0.000
Emotional experience	Control group	60	28.67±3.763	4.916	0.000
Sense of behavioral control	Experiment group	60	29.75±4.417	3.625	0.004
Sense of behavioral control	Control group	60	25.96±2.979	3.625	0.004
Subjective criteria	Experiment group	60	24.74±2.954	2.794	0.009
Subjective criteria	Control group	60	21.23±3.765	2.794	0.009

As can be seen from Table 8, the p-values of the experimental group and the control group in the eight physical activity attitude indicators of behavioral attitude, goal attitude, behavioral cognition, behavioral habits, behavioral intention, emotional experience, sense of behavioral control, and subjective standards after the experiment were 0.024, 0.002, 0.041, 0.038, 0.000, 0.000, 0.004, and 0.009, respectively, which were all less than 0.05, there is a significant difference. In summary, it can be seen that the intelligent technology-enabled curriculum design innovation path designed in this paper can effectively improve students’ attitudes toward physical exercise, thus promoting the enhancement of students’ physical fitness and health, and the effect is significantly better than the traditional curriculum design path.

5

Conclusion

This paper creatively proposes a course design pathway that is powered by intelligent technology and utilizes the T-test method to evaluate its implementation effectiveness.

This paper takes the public physical education course as an example and uses the control method to design a teaching experiment. The experimental group uses an innovative path empowered by intelligent technology for curriculum design, while the control group uses the conventional path for curriculum design. Before the experiment, the physical fitness levels and physical activity attitudes of students in the experimental and control groups were homogenous (t-test p-value greater than 0.05).

In terms of physical fitness level, the post-experimental scores of the experimental group and the control group in six test items, namely, lung capacity, 50m, standing long jump, seated forward bending, 800m/1000m, and pull-ups/sit-ups, were significantly different (P<0.05). And there was no significant difference in the 6 dimensions of physical fitness level before and after the experiment in the control group (P>0.05), while there was a significant difference in the 6 dimensions in the experimental group (P<0.05), which indicates that this paper’s curriculum design based on the intelligent technology-enabled innovation pathway is significantly better than the traditional curriculum design in enhancing the teaching effect of the empowerment of students’ physical fitness level.

In terms of physical exercise attitudes, there are significant differences in the four indicators of behavioral attitudes, behavioral habits, behavioral intentions and behavioral sense of control of the control group students before and after the experiment (P<0.05), and there are no significant differences in the target attitudes, behavioral perceptions, affective experiences and subjective standards (P<0.05), but the scores of the eight indicators after the experiment were slightly higher than those before the experiment. And there were significant differences (P<0.05) in the 8 dimensions of physical activity attitude in the experimental group before and after the experiment, and the scores were significantly higher after the experiment than before the experiment. At the same time, there is a significant difference (P<0.05) between the experimental group and the control group in all 8 indicators of physical activity attitude after the experiment. It indicates that the approach of this paper has a better effect on improving students’ attitude towards physical activity than the traditional approach.

In summary, it can be seen that the intelligent technology-enabled curriculum design innovation path designed in this paper can effectively improve students’ physical fitness and health level by improving students’ physical exercise attitude, and the effect is significantly better than the traditional curriculum design path.

Fund Project:

This article is one of the phased achievements of the 2024 Hunan Provincial Department of Education Scientific Research Project “Research on the Digital Path and Mechanism of Education in Hunan Private Universities under the Background of High Quality Development” (Project No. 24C0584).

Language:: English

Publication timeframe:: 1 times per year
Journal Subjects:: Life Sciences, Life Sciences, other, Mathematics, Applied Mathematics, General Mathematics, Physics, Physics, other

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Research on the Innovative Path of Intelligent Technology-Enabled Curriculum Design in the Process of High-Quality Development of Higher Education

Yan Chen

Zhiming Chen

Published Online: Mar 17, 2025

Received: Nov 14, 2024

Accepted: Feb 13, 2025

DOI: https://doi.org/10.2478/amns-2025-0287

KeywordsPaired samples t-test, Independent samples t-test, Intelligent technology, Curriculum design

© 2025 Yan Chen et al., published by Sciendo

This work is licensed under the Creative Commons Attribution 4.0 International License.

Keywords
Paired samples t-test, Independent samples t-test, Intelligent technology, Curriculum design