1. Introduction
Since 2019, in response to four years of COVID-19 outbreaks and frequent food safety concerns in China, spontaneous agricultural labor has quietly become an integral part of the daily lives of urban residents. At the same time, urban micro-renewal under the guidance of the 14th “Five-Year Plan” [
1] has gradually become a new trend of urban governance and development, with its advantages of “minor demolition and little repair” replacing large demolition and construction, providing fertile soil for the development of micro-urban agriculture in urban construction areas. Community gardens, as “multi-functional” urban micro-renewal space models of co-construction and co-governance, are regarded by numerous scholars as the hope of community rejuvenation [
2].
The earliest theoretical studies on CGs can be traced back to the emergence of British allotments. Influenced by the “enclosure movement” in Britain in the late 18th century, a large number of farmers lost the land which they depended on for survival. In order to avoid social unrest, the British government collected some land in the suburbs and leased it to the bottom residents as compensation [
3]. The residents began to grow vegetables and fruits for their families on the nearby land allocated by the government. It is this practical need for social development that has driven the development of theories related to CGs, and as a result, relevant theoretical studies of summarizing significance have begun to arise. The reason why the United States can gradually occupy the first place in this research field in the 21st century is that a large number of theoretical evaluations have further contributed to the formation of the local CG system. The Landscape Performance Survey (LPS) guidelines published by the Landscape Campus Foundation (LCF) in 2010 added four new indicators for evaluating the environmental, social, and economic indicators about CGs [
4], which further standardize the guidelines for the future construction of CGs. It can be seen that the formation of mature urban CG systems has benefited from the mutual promoting of practical application and theoretical research. This has greatly inspired the starting point of this study.
Throughout this global research progress, CGs, as a product of the contemporary era within national development planning systems, have been significantly influenced by the developmental stages of different countries and societal needs [
5]. Consequently, there is currently no universally accepted definition or description of CGs. In general, the CGs under the western political system have a certain scale of practice and social organization system [
6,
7,
8]. The main purpose of their construction is to alleviate the economic pressure of vulnerable groups and solve practical problems such as food and space balance [
9,
10,
11]. However, Chinese CGs are mostly located in empty zones of urban planning. Only Hong Kong and Taiwan have issued targeted policies and plans [
12,
13] on CGs. Some “hidden policies” put forward by Beijing, Shanghai, Chengdu, Guangzhou, and other places only play a guiding or supporting [
14,
15,
16,
17] role in the construction of CGs and cannot provide guiding opinions for future CGs. Therefore, under the framework of top-down urban planning, the construction of CGs still faces the awkward situation of no clear land ownership and no department of planning and management to claim. The bottom-up organization and management model faces difficulties in fund preparation, small-scale promotion, and the low participation of the community. Thus, advanced Western experiences cannot provide effective references and theoretical support for the construction of CGs in China. How to further achieve optimal development under China’s urban planning policy system urgently needs to be summed up from the experience and shortcomings of existing CG construction practices. Therefore, due to varying national development backgrounds and construction objectives, the practical experience of developed countries holds limited relevance for the establishment of CGs in China.
Most of the studies about site-based construction in China have been based on an excellent case study with limited dimensions such as functional effect and management mode [
18,
19,
20,
21], and they suggest various experiences and insights. In addition, innovative urban agriculture theories have been used to guide the planning and design of CGs in recent years [
22,
23,
24]. In summary, the guidance and direct effects regarding the “elitist analysis” of existing cases and innovative urban agriculture theories on the practice of CG construction is minimal, even disjointed. Some researchers have even argued that agriculture in built-up areas is still an activity that needs to be “defended” [
2]. Nowadays, urban micro-renewal policy provides a good opportunity for Chinese urban planners. Previously, most of the existing CGs were built by social organizations or individuals on their own effort, and the question of land ownership under centralized management was undoubtedly an obstacle to the construction and development of the CG system. The proposed policy of urban micro-renewal is an effective way for the government to enter into stock planning. As a new form of small-scale and micro-involvement in urban renewal, micro-renewal emphasizes more bottom-up mobilization and resident participation. In general, the proposal of urban micro-renewal policy provides a legalized way to reuse grey space and provide us with some samples for research. With the experience of “practice drives theoretical research” in developed countries, we can analyze the results from the evaluation of China’s existing CGs and summarize them into theoretical facts to guide practical application in a feasible way. Therefore, it is necessary to carry out systematic evaluation based on the existing CGs at this stage of development.
As part of urban green infrastructure, the most common evaluation system for urban CGs is the evaluation of ecosystem service (ES). It aims to explore the role and value of the green space to the whole ecosystem. The biggest difference between CGs and other non-edible green infrastructure is that their value to human welfare is overwhelming compared to other biodiversity and regulatory functions. This can even be a decisive factor in determining the sustainability of CGs. This is also confirmed by studies on single dimensions of CGs. For example, CAI Zhizheng et al. investigated urban residents’ preferences for community agricultural landscapes through a questionnaire that combined graphics and text [
25]; Wang Zhifang et al. investigated the landscape preference of residential communities in Beijing and then analyzed residents’ acceptance of CGs [
26]. These indicate that the ability to provide human well-being plays an important role in the optimization of CGs. By considering the perceptions of users or participants as value-oriented, it becomes possible to more efficiently identify key indicators for the sustainable development of CGs within the context of urban planning.
As an evaluation method based on users’ perception, the IPA method was presented in 1977 with its advantages of simplicity, intuition, and strong operability, and it has been widely used in a variety of scenarios and projects [
27]. In recent years, it has also been gradually applied to the fields of tourism, architecture, planning, and the landscape industry. The main research objects are concentrated on aspects of building monomers, scenic areas, city parks, community parks, cultural ecosystem services (CES), and so on [
28,
29,
30,
31,
32]. The users are mainly tourists and urban residents [
33,
34], including research on the needs of village residents and elderly groups [
27,
33]. However, there is no research on its application to the construction projects of CGs. Applying IPA to the existing CG programs and creating a complete evaluation system based on the value of users’ perceptions can effectively guide the construction and long-term development of CGs in future.
We have developed a comprehensive database of evaluation indices for CGs that are applicable to the current planning situation in China. This was achieved through network text analysis, literature analysis, and expert opinions. Using 20 CGs in Wuhan as study samples, the IPA method was used to perform statistical analysis on 245 questionnaires. Our aim is constructing a human’s perception value-oriented evaluation system and summarizing the optimization strategies according to the evaluation results, which can provide more systematic and targeted practical guidance for the construction of CGs in China.
2. Materials and Methods
At the stage of determining the IPA evaluation metrics, we mainly performed desk research. We used a combination of network text analysis and the literature analysis method to make preliminary determinations of the indicators, and we integrated expert opinions to further determine the scientific accuracy of the indicators. This is essential for the subsequent analysis of users’ perceptions based on metrics. At the stage of data acquisition, we selected Wuhan as the city for the empirical study of the indicator system and collected data while giving out questionnaires to target populations with activities similar to the 20 different types of sample CGs. After the IPA quadrant analysis, the “key transformation indicators” were extracted and applied to the optimization strategies of the current and future CGs (
Figure 1).
2.1. Construction of the Indicator System Based on Network Text Analysis, Literature Analysis, and Expert Opinions
As an important part of urban micro-regeneration, CGs occupy tiny areas and are widely respected by users because of their multifunctional value in construction zones. The identification of evaluation indicators for CGs should not be limited to the dimensions of interest of researchers and scholars. Therefore, expanding the sources of information is necessary for the determination of evaluation indicators for CGs in China. In this study, we combined the network text analysis method with the literature analysis method to determine the original indicator database of CGs.
Network text analysis is a research method for the objective, systematic, and quantitative description of text, images, and other information. Its free, open, and shared characteristics allow users’ feelings and perceptions to be fully expressed [
35]. It is widely used in various fields of social science research [
30]. We selected the most influential online platforms in China: Blogs, Sina Weibo, and WeChat as search engines, and we searched with the keyword “community gardens”. Then ROST Content Mining 6.0 software was used to classify and mine the selected network text content.
It is worth mentioning that the high-frequency vocabulary from the internet has lexical diversity and colloquial features that cannot be directly used for indicator characterization and needs to be further normalized and related to the results of the literature analysis. We combined the literature analysis method with high-frequency vocabulary to determine the initial indicators. In the literature analysis phase, “community agricultural garden *”, “community garden *”, “IPA analysis”, “evaluation”, “agricultural landscape of residential area”, “transformation and improvement”, and “construction design” were used as key words to search. Then, we determined the descriptive elements considered for practice or evaluation in each piece of literature by eliminating repetitive elements and integrating semantically unclear elements.
In order to summarize two results in a qualitative integration, we organized an indicator team of six people, including CG project staff, community managers, and users. They needed to conduct correspondence matching between descriptive elements and high-frequency vocabulary, and the two checked each other to form the original indicator database.
On the basis of the original indicator database, expert opinions from relevant fields were acquired through expert interviews to refine and adjust the indicators accordingly. The expert members included 5 scholars of landscape architecture, 3 managers of CG project organization, and 2 professional practitioners of urban farm projects. This step was mainly based on the experts’ theoretical academic level and practical experience to optimize the original indicators, facilitating better consideration of the accuracy and scientificity of the indicators from multiple perspectives.
2.2. Research Scope and Sample Delineation
In this study, the urban built-up area of Wuhan was used as the actual research area for the indicator system. We collected all information on all CGs constructed over the last seven years in Wuhan. By 23 March 2023, the distribution information of 60 CGs was obtained through a literature review, an internet search, and field research. Most of these CGs were transformed by original public green spaces, and some of the CGs were recreated and reused by building rooftops, impervious surfaces with planting potential, unused parking lots, and courtyards. Through the field research, planting facilities such as individual flower beds and boxes and vertical crop planting patterns were excluded due to their micro scale. According to different types of urban planning and corresponding user groups, Wuhan CGs were divided into Resi-CGs, Comm-CGs, Camp-CGs, and Comp-CGs (see
Table 1). This classification system has been proven to be effective and provide full-coverage by a number of scholars [
36,
37,
38]. The classification of the targeted optimization strategies makes the practical application of this study even more valuable.
See
Appendix A for a detailed summary of CG information. Based on the representativeness of the samples and the integrity of the study, 20 spatial sample points in this study were chosen according to the following rules (
Figure 2):
Ensure the diversity of sample types and the number of single types is not less than 15%;
The project management should be mature, the operation should be stable, and the project should have a certain scale and own some number of users;
The organization and management of the sample is easy to communicate and establish contacts, which is helpful for information acquisition, the conduct of interviews, and the distribution and collection of questionnaires.
2.3. Questionnaire Distribution and Data Processing
The questionnaire consists of two parts. The first part is a basic information survey of the participants, including gender, age, occupation, education level, frequency of agricultural activities, etc. We will use this portion of the data to characterize the participants from different types of CGs as one of the considerations for future CG construction optimization strategies. The second part is the “satisfaction-importance” evaluation of the CG, which is the main content of the questionnaire (see
Appendix B for details). We used the questionnaire approach to score the indicators as constructed in the previous section. A five-point Likert scale was used as a measure to assess CG evaluation metrics. Participants rated the two aspects of “satisfaction” and “importance” of the CG projects they participated in according to their own feelings and cognition. “1” means “extremely unsatisfied/important”; “2” means “unsatisfied/important”; “3” means “generally satisfied/important”; “4” means “satisfied/important”; and “5” means “extremely satisfied/important.” A total of 245 questionnaires were distributed, with 212 valid questionnaires. In order to test the reliability and efficiency of single indicator in the questionnaire and judge whether the resulting data were valuable for research, we used SPSS.27 software to calculate the alpha reliability coefficient Cronbach’s α, the KMO value, and the Bartlett spherical value for display. According to the statistics in
Table 2, the α of four types of CGs were all greater than 0.8, indicating high reliability. The KMO values ranged from 0.7 to 0.8, indicating the high efficiency of the questionnaire. The results show that 212 questionnaires passed the test, and the data were suitable for follow-up IPA evaluation.
3. Results
3.1. Indicator System of CGs
At the stage of network text analysis, we extracted 45 high-frequency vocabulary words from online records and accounts of CGs (
Table 3). The high-frequency vocabulary words are mainly nouns, adjectives, and verbs. The nouns mainly reflect the information of place, location, and organizational unit; the verbs mainly reflect the specific activities of the participants; and the adjectives mainly express the participants’ overall feelings about the main image of CGs and the types of activities. In addition, the high-frequency vocabulary words are mainly positive feedback, such as “leisure”, “health”, “nature”, etc., indicating the overall recognition and support attitude of urban residents towards the functions of CGs. Simultaneously, they also reflect the operational and managerial challenges faced by CGs during the ‘epidemic’ period, as well as concerns regarding their impact on the community environment. Following visualization, a prototype of a semantic network analysis diagram was created (
Figure 3).
During the literature analysis phase, we selected 27 pieces of strong correlation literature related to the descriptors of CG evaluation. Among them, there are 16 master’s and doctoral theses and 10 journal articles. After summarization, 22 relevant descriptive elements were extracted. Combining the high-frequency vocabulary of the Internet, we summarized the final indicators into four major types, forming the original indicator database with 24 indicators in total (
Table 4).
After summarizing the expert opinions, the original indicator database was modified as follows (
Table 5):
“Noise effect” has a negative bias, replaced with “Quiet level”;
There is a difference in understanding of “Environmental coordination degree”, replaced with “Farm style and characteristics”;
“Quantity of tools and facilities” is not comprehensive enough, replaced with” Quantity and type of tools and facilities”;
“Landscape quality” is too broad, replaced with “Aesthetics”;
With integration and adjustment, the two levels of indicators in
Table 3 are identified as part of the final indicator database of CG users’ evaluation system.
3.2. Characteristics and Needs of Users of Different CG Types
The main participants of Resi-CGs are the retired elderly, aged between 60 and 80 years old, followed by office workers and students. Participants generally claimed that the original intention of designing and building CGs was to improve the community environment, and that most of them hoped to strengthen their health through such convenient, quick, and easily available farming activities. Participants of Comm-CGs are mainly young and middle-aged people aged 18–29, followed by office workers. They often want to get up close and personal with nature and feel the growth of plants after a weekend of relaxation. Parents and children are the main force in the use of this type of CG. In this way, they can help children learn more about nature and provide a natural and healthy outdoor environment. Participants of Camp-CGs are mostly limited to students and a small number of teaching staff. Students generally said that they participated in the activities in CGs on the one hand to respond to the call of the School Volunteer Association and on the other hand due to the fact that farming has the effect of reducing pressure from schoolwork, while at the same time acquiring more knowledge about plants and cultivating a sense of teamwork. The main participants of the Comp-CGs are the employees and their families. Participants can not only obtain fresh vegetables and relax their muscles and bones, but also relieve stress and nurture their body and mind.
3.3. IPA Quadrant Analysis
By statistical analysis and calculation of the data through SPSS, the average satisfaction (
p-value), the average importance (I-value), and the mean difference (I-P) of various types of CGs in Wuhan can be obtained (see
Table 6). The higher values of I and
p values indicate the higher importance/satisfaction of the indicator as perceived by participants. From the statistical data, it can be seen that participants’ satisfaction with the CG is higher on the whole, and users are more satisfied with “Charge situation”, “Decompress experience”, “Accessibility”, and “Fitness and recreation experience”. In terms of importance, participants commonly believe that “Air quality”, “Mosquito impact”, and “Environmental cleaning” are the key points for the construction of CGs.
IPA analysis is a method to express users’ evaluations of different indicators in the form of different quadrants. The quadrant diagram is divided into four quadrants using the I-value as the
x-axis, the
p-value as the
y-axis, and the mean value of the indicator as the dividing line. Moreover, I and
p values of 24 indicators are marked on the quadrant diagram. It is found in
Figure 4 that the distribution of the various indicators in the diagram shows some commonalities. The indicators of “Accessibility”, “Planting skills learn”, and “Environmental cleaning” are located in the dominant areas, and they are both highly important and highly satisfying. In addition, there are differences in the “high importance-low satisfaction” coupling indicators of different types of CGs, which will lead to differentiated priorities for the construction of different types of CGs.
3.4. Key Transformation Indexes Analysis
The “key transformation” index is an influential index to put forward the optimization strategy for CGs. This kind of index falls in the fourth quadrant of the IPA quadrant analysis diagram. The I-P mean difference is positive (see
Table 5), which represents the statistical meaning of the difference between the degree of importance and satisfaction. Larger values mean that the index is more important in the construction of this type of CG and the current situation does not meet the high expectations of users; smaller values indicate that the index basically meets users’ expectations but still needs to be strengthened. Therefore, we use radar charts of mean difference values (
Figure 5) to more intuitively express the importance of the “key transformation” index of different types of CGs.
“Mosquito impact”, “Facility maintenance”, and “Social experience” are the indicators of greatest concern of residents and are easily ignored in the construction of Resi-CGs. “Air quality” and “Farm style and characteristics” also need to be optimized and improved. The users of Comm-CGs believe that “Mosquito impact” should be improved in the process of use. Moreover, they put forward higher requirements for the “Aesthetics”, “Farm style and characteristics”, and “Interactive diversity” of CGs. A more distinctive theme and distinctive design of the garden environment is what will make it commercially viable. Camp-CGs need to be optimized in relation to the two aspects of “Crop stewardship” and “Leisure facilities”. In addition, “Path design”, “Guide sign”, and “Crop diversity” also need to be improved so as to enhance students’ awareness of labor and farming practices. There is no significant trend in the key transformation indexes of the Comp-CGs, and the indexes of “Fitness and recreation experience”, “Crop diversity”, “Aesthetics”, “Leisure facilities”, and “Decompress experience” need to be improved. Relaxation of mind and body and the harvesting of different kinds of vegetables have become the chief purposes of cultivation for this group of people.
4. Application and Discussion
We combined the results of the radar charts (
Figure 5) and characteristics and needs of users (See
Section 3.2) to further explore the application of optimization strategies and pathways for different types of CGs.
- (1)
Optimization strategy of Resi-CGs
Based on the evaluation results of the key issues that need to be improved, such as “Mosquito impact”, “Social experience”, and “Facility maintenance”, we try to propose corresponding optimization strategies from three aspects of environment, site vitality, and operation mechanism: (a) In terms of the environment of CGs, rainwater collection, ecological composting, ecological paving, and other related ecological technologies are used to solve the harmful effects of mosquito infestation and undesirable odors, so as to improve the overall environmental quality of CGs in the form of low cost, easy maintenance, and environmental friendliness. (b) Improving the vitality of the space is the fundamental way to enhance the social experience of residents. Through functional weaving, cultural implantation, facility improvement, and plant design, we can activate inefficient spaces in communities, trigger regional links, and gradually promote the expansion of CGs in regions and cities. (c) Another strategy is to build a multi-governance participation platform and encourage the government, neighborhood committees, and additional parties to work together to build a long-term operating mechanism for the sustainable development of CGs. Second, we can tap into the talents of the community and play a leading role as a group of residents to promote the regeneration of the community with spontaneous force. In addition, professional design and construction teams are required. Finally, the positive interaction of “preliminary design—consultation—feedback—adjustment design” is formed by combining all forces (
Figure 6).
- (2)
Optimization strategy of Comm-CGs
Combined with the key improvement issues of “Mosquito impact”, “Farm style and characteristics”, and “Interactive diversity” in the evaluation results, we proposed an optimization strategy of Comm-CGs based on three aspects: planting technology, style positioning, and activity design: (a) Through the application of modern planting technology, such as soilless cultivation and hydroponics, the negative effects from mosquitoes can be reduced, and the user’s participation experience can be improved. (b) In terms of style positioning, it is necessary to explore the most appropriate design style of CGs based on various factors such as site conditions, population characteristics, history, and culture. First, we can use well-established malls and quality resources for designing style extensions. The other way is that we can rely on local characteristics and culture to create regional character, and the third is to survey and research the main audience groups and finally determine the final design style of CGs. (c) To improve the activity design, it is necessary to provide different services for diverse users. Planting can be taken as an opportunity to carry out activities such as “Farmland Adoption”, “Creative Workshops”, “Science Lectures”, and “Cultural Salon”. These can be combined with the current popular elements of the time to meet the complex needs of people of different ages (
Figure 6).
- (3)
Optimization strategy of Camp-CGs
Combined with the key improvement issues of “Crop diversity”, “Leisure facilities”, and “Crop stewardship” in the evaluation results, we propose three aspects: planting design, facility design, and construction of smart CGs: (a) We must provide a diversified participation experience for students through abundant planting design and make use of limited space and resources on campus to provide more natural education content. Examples include herb gardens, five-sensory gardens, edible gardens, aquatic gardens, and other diversified planting themed designs; diversified planting techniques are displayed using soilless cultivation, glass greenhouses, substrate planting frames, three-dimensional cultivation, advanced water, fertilizer circulation supply systems, and electric control systems. In addition, students can be motivated to participate in various educational and practical activities such as “Insect Class”, “Plant Encyclopedia”, and “Harvest Season”. (b) We should create a safe, pleasant, and approachable environment by optimizing the science signage facilities, recreation facilities, and landscape facilities of the CG. Scientific sign facilities should be combined with nature education content and presented in a lively, fascinating, and easy-to-understand manner; recreation facilities should follow ecological concepts in terms of shape, material, utilization, and natural elements, and they should allow students to gain an attachment and emotional connection to the place through direct perception and experience; landscape facilities are needed to make the CG a demonstration area for campus culture, thus facilitating the development of additional teaching and practice activities on campus. (c) To improve the crop management mechanism, professional and technical personnel can be equipped to take charge of the maintenance of daily crops and the management of facilities. The implantation of automatic planting systems can simplify the management and protection of CGs and reduce manual pressure. Secondly, the online and offline interactive communication platform can provide students with ways to observe the whole cycle growth of crops and build an all-around smart CG on the basis of ensuring the stable operation of the CG (
Figure 6).
- (4)
Optimization strategy of Comp-CGs
In combination with the evaluation results on the key improvement problems of “Fitness and recreation experience”, “Aesthetics”, and “Leisure facilities”, the optimization strategies were proposed from two aspects of multi-functional CGs and progressive design: (a) The one-sided emphasis on production leads to the single function of the CG, which makes it difficult to meet the needs of users. Therefore, it is extremely essential to build a multi-functional CG. With abundant facility design, landscape design, and planting design to create a harvest experience for employees, the CG should have both recreational and leisure functions to activate the space. (b) At present, the popularity of Comp-CGs is low, and scattered and disordered planting areas considerably affect the overall beauty of the CG. The potential space should be explored comprehensively in the overall planning and design of the CG, the construction of the CG should be carried out in stages by a small-scale and gradual method, and the linear green infrastructure should be integrated to complete the series of planting areas so as to improve the overall esthetic sense of the CG (
Figure 6).
Observing community gardening in the historical context of urban development, it seems to have become a mirror of different countries and different stages of urban economic development [
48,
49]. This has led to the fact that it is still impossible to give an accurate description of the intrinsic meaning and form of CGs. On the contrary, those who endeavor to define CGs tend to make their future research and development more narrow [
50]. Currently, 93.22% of all studies on CGs are from developed countries. Among them, the United States occupies the leading position [
51]. The rapid urbanization of non-high-income developing countries in the future will also provide a broader practical space for the development of CGs [
51], and it is necessary and meaningful to strengthen the site-based research in these countries. This would greatly compensate for the current depth of research on CGs around the world. Therefore, we believe that Chinese local CGs must be evaluated in order to provide a practical optimization guideline for the development of urban CGs. Currently, most of the site-based research in China focuses on qualitative topics such as review studies [
52,
53], theoretical summaries [
54,
55,
56], planning and design of single CGs [
57], and public participation [
58,
59], which are not able to intuitively and scientifically guide the development of CGs in China. These studies are unable to intuitively and scientifically guide the development of urban practices.
In the post-COVID-19 period, the multidimensional functional value of CGs has made them the first choice for urban micro-renewal space transformation in China. The construction of CGs has also been pushed to the climax of the current development stage in China. As part of urban green infrastructure, the ES of CGs has also become a hot topic of evaluation related to urban green space planning [
60]. These ES function types are very similar to the indicator database in this study. Most of the current research on the topic of ES only stops at the stage of interviewing users of CGs to determine their ES types. Unfortunately, ESs were identified using a free listing technique [
61]. This interview-based identification of indicators is very much limited by the selection bias of the samples, and it is highly likely that the results of the indicator selection will have a large error due to the insufficient coverage of the interviewed population [
62]. Secondly, due to the unique features of CGs, this approach to data collection suffers a potential methodological bias towards the appreciation of CES [
63,
64]. Therefore, we moved beyond the inherent scope of ES indicators and improved the methodology for the construction of the CG indicator database. The finalized 24 indicators were obtained based on the methodology of network text analysis and literature analysis. It is a scientific summary based on the whole scope of CG users and concerned people in China. In addition, we further invited relevant experts to optimize and adjust the indicators. This makes the indicator system more complete and more feasible for subsequent evaluation.
As for the overwhelming “CES function” and “social and cultural benefit value” of CGs [
65], we interpret them in relation to the fact that the existence and development of CGs must have a strong correlation with the provision of “human” happiness and well-being. This point is fundamental to differentiate CGs from other non-edible urban green infrastructures. Therefore, we have chosen to use IPA as a tool to link CGs in China to human well-being. What kind of CGs do the Chinese people want now? What is the main contradiction in the construction of CGs? The evaluation results of this study provide a good answer to these two questions.
We finish the discussion by acknowledging the limitation of this study. The importance and satisfaction reflected by the mean difference may only reflect the basic attitudes, feelings, and judgments of the users near CGs in Wuhan, which has certain regional limitations. Therefore, it is necessary to expand the sample size of Chinese cities at different development stages in order to make the results more scientific and instructive so as to match the highest level of urban development strategies and provide a systematic and comprehensive theoretical and practical reference for future CGs.
5. Conclusions
The arrival of the post-COVID-19 period and the implementation of urban micro-renewal policies have pushed Chinese urban community gardening into a golden age. However, there is still a lack of site-based research on the systematic evaluation of CGs. Providing more human well-being experiences is essential for the sustainable development of CGs. Therefore, in order to fill the current theoretical gap in the systematic evaluation of China’s existing CGs, we constructed a human’s perception value-oriented evaluation system and evaluated and analyzed 24 indicators of four different types of CGs through the IPA method. The main findings are as follows:
(1) “Mosquito impact”, “Facility maintenance”, and “Social experience” are the indicators of greatest concern for residents and are easily ignored in the construction of Resi-CGs, which need to be emphasized in the future design and construction process.
(2) “Mosquito impact” should be improved in the process of use. Moreover, they put forward higher requirements for the “Aesthetics”, “Farm style and characteristics”, and “Interactive diversity” of CGs. A more distinctive theme and distinctive design of the garden environment is what will make it commercially viable.
(3) Camp-CGs need to be optimized in the two aspects of “Crop stewardship” and “Leisure facilities” so as to enhance students’ awareness of labor and farming practices.
(4) There is no significant trend in the key transformation indexes of the Comp-CGs, and the indexes of “Fitness and recreation experience”, “Crop diversity”, “Aesthetics”, “Leisure facilities”, and “Decompress experience” need to be improved.
Based on the above conclusions, we further summarize the optimization strategies to give more practical guidance for the construction of CGs in China. In the future, if we have the support of the relevant government departments, we will optimize the construction method of the indicator system and use big data and artificial intelligence to carry out more scientific and systematic research on the evaluation of different cities.