Exploration of the Technologies Application Experience of Landscape-Scale Green Infrastructure by the Conservation Fund
Abstract
:1. Introduction
- 1.
- What is the longitudinal trend in the CF’s Landscape-scale GI practices?
- 2.
- What are the patterns in the CF’s selection of GI technologies, and how do these choices correlate with the achievement of GI functions?
- 3.
- What is the impact of these experiences on the advancement of Landscape-scale GI?
2. Background
2.1. Disparities in the Promotion of GI
2.2. Landscape-Scale GI Practice Case Study Status
2.3. Landscape-Scale GI Practices by the Conservation Fund
3. Methods
3.1. Database Preparation
3.2. Data Analysis
3.2.1. Determination of “Standardized Classification System for Descriptive Information” and Coding
- 1.
- Standardized Project Information description. We mainly extracted Location/Scope, Cooperation Partner, and Land use/Land; these cover three aspects of Project Information, which may have constraints on the implementation of different projects. The Location/Scope classifications are consistent with the criteria used in the delineation of site boundaries, the Cooperation Partner is directly based on their own work characteristics, and the Land Use/Land Cover is described in further detail using the Land Use and Land Cover Classification System [44] as a baseline.
- 2.
- Standardized Purpose and GI Function description. Unlike Project Information, there are no directly usable classification criteria for Purpose and GI Function, so we used the conceptual function in ATLAS.ti (v23.3) [45] based on the preliminary coding result to extract concept words and count the frequency of occurrence. However, the extracted concept words do not directly reflect the specific purposes and functions, so we discussed and summarized the standardized Purposes and GI Function based on the lexical nature of the concept words, the frequency of their occurrence, and the context of the original descriptions in the projects (See Table A1 and Table A2).
- 3.
- Standardized Technology/Tool description. The official website discloses some of the main technologies the CF used in the GI projects [46], which are used as parts of the standardized description in this study. Other documented technologies also have been added using the same treatment as in “2”.
3.2.2. Coding and Characterization of Variables
3.2.3. Selection of Analytical Methods and Statistical Analysis
- 1.
- Descriptive Statistics: SPSS is used to perform descriptive statistical analysis on the collected data. This analysis provides insights into changes in Project Information, Purpose, GI Function, and Technology/Tool over time and can also summarize the overall characteristics.
- 2.
- Correlation Analysis: The correlation between various items within SCSDI is examined by using SPSS. The primary focus is on exploring the relationships between Technology/Tool and Project Information, Purpose, and GI Function.
- 3.
- Trend and Pattern Analysis: Based on the results of the aforementioned analyses, the overall trends in Landscape-scale GI practices by the CF and the characteristic patterns in technical applications are summarized.
4. Results
4.1. Descriptive Statistics
4.1.1. Project Information Descriptive Statistics
4.1.2. Purpose and GI Function Descriptive Statistics
4.1.3. Technology/Tool Descriptive Statistics
4.2. Correlation Test
4.2.1. Technology/Tool and Project Information Correlation
4.2.2. Technology/Tool and Purpose Correlation
- 1.
- Technology/Tool and View of Development Purpose (See Table 5). The six Technology/Tool as Ecosystem service valuation, GIS decision support tools and map services, Green infrastructure networks/landscape design, Implementation/acquisition targeting, Public Involvement and Cooperation Enhanced, and Regional conservation visions showed a statistically significant relationship between Technology/Tool and View of Development Purpose, but in terms of subcategory of these purposes, Raising Environmental Awareness had four Technology/Tool with relevance, Using Nature Resource for Tourism had three, and Stormwater/Flood Management had none. The remaining purposes all have 1–2 relevant Technology/Tool.
- 2.
- Technology/Tool and View of Protection Purpose (See Table 6). Seven of the Technology/Tool as Ecosystem service valuation, Green infrastructure networks/landscape design, Implementation/acquisition targeting, Public Involvement and Cooperation Enhanced, Regional conservation visions, Review of previous planning and conservation and Structured decision tools using the Logic Scoring of Preference method showed a statistical correlation with View of Protection Purpose. However, only two Technology/Tool: Ecosystem service valuation and Public Involvement and Cooperation Enhanced, showed relevance to the subcategory purposes, and Public Involvement and Cooperation Enhanced was the Technology/Tool with the highest number of correlations.
4.2.3. Technology/Tool and GI Function Correlation
- 1.
- Technology/Tool and Nature and Ecosystem Function (see Table 7). We found that there are as many as seven Technology/Tool that have relevance to Nature and Ecosystem Function, but only five subcategory functions (less than half) have relevance to one or two Technology/Tool. In terms of Technology/Tool, the most relevance to various Nature and Ecosystem Function are Public Involvement and Cooperation Enhanced and Regional conservation visions. In addition, Green infrastructure networks/landscape design is only relevant to one subcategory function, Implementation Quilt, Review of previous planning and conservation and Structured decision-making tools using the Logic Scoring of the Preference method are relevant for the whole category only.
- 2.
- Technology/Tool and People Society Activities Function (see Table 8). There are seven subcategory of People Society Activities Function that have at least two Technology/Tool with relevance; Support Economy Development has relevance with as many as four Technology/Tool, followed by Improve People Living Environment and Public Health with three. In terms of Technology/Tool, except Ecosystem service valuation, Optimization models for cost-effective decision-making, and Strategic conservation guidance, as many as 11 were associated with this category and only Green infrastructure networks/landscape design did not have a subcategory function associated with it while Implementation Quilt, Leadership Forum, Rapid open space assessment and Travel Planning in contrast did.
- 3.
- Technology/Tool and Planning and Implementation Function (see Table 9). Half of the Planning and Implementation Function subcategories had relevance to one or two Technology/Tool, with as many as four Technology/Tool having relevance to Guiding the Future. On the other hand, fewer than half of Technology/Tool had relevance to this category or subcategories, and none of them had more than two.
- 4.
- Technology/Tool and Water Resource Function (see Table 10). Although there are not many subcategories of Water Resource Function, each of them has one or two Technology/Tool associated with, which are Implementation/acquisition targeting, Public Involvement and Cooperation Enhanced and Review of previous planning and conservation.
5. Discussion
5.1. Selection and Expansion of Technology/Tool
5.2. Interaction between Technology/Tool and Project Information
5.3. Experience of the CF Technology/Tool Applications
- Situation (1): The Technology/Tool is correlated with a subcategory Purpose/GI Function but not with the general category it belongs to. This indicates that the CF prioritizes this Technology/Tool for achieving a particular Purpose/GI Function. However, it may not be applicable to another Purpose/GI Function within the same category.
- Situation (2): The Technology/Tool is correlated with a category of Purpose/GI Function but not with any subcategory. This situation is not uncommon, suggesting that while the Technology/Tool may have weaker specificity, it provides support across the entire category of Purpose/GI Function.
- Situation (3): The Technology/Tool is correlated with a subcategory Purpose/GI Function and also with the category it belongs to. This indicates that the Technology/Tool not only has a targeted effect on a particular Purpose/GI Function but also provides support for others within the same category.
5.3.1. According to Purpose
- In View of Development Purpose: There are six of Technology/Tool in Situation (1), none in Situation (2), and six in Situation (3). Moreover, nearly all nine subcategories of View of Development Purpose are associated with one or two related Technology/Tool.
- In View of Protection Purpose: There are no Technology/Tool in Situation (1), five in Situation (2), and two in Situation (3). Additionally, only four subcategories of View of Protection Purpose are associated with one or two related Technology/Tool.
5.3.2. According to GI Function
- In Natural and Ecosystem Function: There is one of Technology/Tool in Situation (1), three in Situation (2), and three in Situation (3). Only half of the subcategories have associated Technology/Tool.
- In People Society Activities Function: There are four of Technology/Tool in Situation (1), one in Situation (2), and six in Situation (3). Seven subcategories have at least two associated Technology/Tool.
- In Planning and Implementation Function: There is one of Technology/Tool in Situation (1), one in Situation (2), and five in Situation (3). Half of the subcategories have associated Technology/Tool.
- In Water Resource Function: There is one of Technology/Tool in Situation (1), none in Situation (2), and two in Situation (3). Each subcategory has at least one associated Technology/Tool.
5.3.3. Performance of the CF Technology/Tool Applications
- “Implementation/Acquisition Targeting”, as an officially endorsed method by the CF, characterized by clear target positioning, serves as a foundational tool for project implementation. It has been applied 12 times, highlighting its widespread use.
- “Green Infrastructure Networks/Landscape Design”, another officially recognized method, exhibits clear correlations with various types of projects, empirically validating the widely accepted theoretical connection between multifunctional GI at the Landscape-scale and interconnected spatial networks [51,52,53,54]. However, it is noteworthy that this technology was applied only nine times across 27 projects, indicating that while network form and landscape design are key mediators in achieving GI multifunctionality, other forms of Landscape-scale GI may also be viable.
- “Structured Decision Tools Using the LSP Method”, also publicly available from the CF, is a Multi-Criteria Evaluation (hereafter MCE) method designed for the assessment and comparison of complex systems [55]. It encompasses every measurable attribute relevant to Landscape-scale GI [56], with criteria tailored to the reasonable needs of different stakeholders [57]. This approach assists decision-makers in comprehensively considering various factors to make scientifically informed and optimal choices [58].
- “Public Involvement and Cooperation Enhanced”, as identified in this study through document analysis, has been similarly validated in GI practices in other regions, particularly within the European Union. Public involvement is widely recognized as a means to ensure that planning decisions reflect public interests, better understand local conditions, and foster a mutual understanding between stakeholders and designers regarding the design proposals, which contribute to the long-term, high-quality maintenance of GI spaces in turn [59]. However, the effectiveness of participation can vary depending on the project stage and the identity of the participants. While research indicates that the involvement of government, business, academia, and civil society is crucial and indispensable, issues such as incomplete coverage of participant identities and low participation rates still persist [60,61].
- “Review of Previous Planning and Conservation” aids participants in gaining a better understanding of the local context, identifying the strengths and weaknesses of past planning and conservation efforts, and making targeted improvements in new GI projects. Although related planning policies often reference GI concepts, they may differ in the depth of their considerations compared to actual GI projects. Drawing on experiences from GI practice, recommendations can be made to optimize planning policies, reducing restrictions on GI and maximizing the benefits for both planning and GI outcomes [62].
- “Regional Conservation Visions” go beyond simple ecological restoration by identifying and designating areas of conservation value, offering a more advanced approach to protection [63].
- “GIS Decision Support Tools and Map Services” is the most frequently employed computational aid in this identification process. Since the 1990s, GIS has proven to be a valuable tool for spatially presenting and analyzing information layers, offering decision-makers accessible and manageable data [64]. GIS-based decision support systems facilitate communication between researchers and decision-makers and provide a platform for multidisciplinary studies.
- “Ecosystem Service Valuation” and other tools like it are still being refined; they enable the calculation of the added value generated by GI investments, providing developers with a basis for assessment and helping to mitigate potential obstacles in GI project investments [65].
- “Implementation Quilt”, as summarized in reports, alongside tools designed for specific objectives such as Optimization Models for Cost-Effective Decision Making and Rapid Open Space Assessments, serve similar roles, offering targeted support for specialized goals.
5.4. Classification of Technology/Tool Used by the CF
- Implementation/Acquisition Targeting ensures that clear objectives are set before the project begins.
- Green Infrastructure Networks/Landscape Design control the spatial form of GI.
- GIS Decision Support Tools and Map Services provide an objective and comprehensive assessment of the overall environment.
- Ecosystem Service Valuation and Regional Conservation Visions deepen the focus of GI-specific practices.
- Public Involvement and Cooperation Enhanced ensure that projects are effectively implemented throughout their lifecycle.
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Appendix A
Objective Objects * | Interests * | Main Thrust of the Operation * | Practical Approach * | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Category ** | Concept | Freq. | Category ** | Concept | Freq. | Category ** | Concept | Freq. | Category ** | Concept | Freq. |
Biotype | wildlife | 9 | All | opportunity | 14 | Utilization | Development | 21 | Planning Type | plan/planning | 15/9 |
people | 5 | benefit | 11 | use | 9 | project | 9 | ||||
Natural and Ecological Resources | land | 34 | need | 8 | tourism | 6 | strategy | 8 | |||
water | 24 | quality | 6 | Conservation | conservation | 13 | program | 6 | |||
resource | 21 | additional | 5 | protection | 9 | vision | 6 | ||||
forest | 8 | impact | 5 | preservation | 5 | policy | 4 | ||||
ecosystem | 6 | change | 4 | support | 5 | framework | 3 | ||||
nature | 6 | effect | 4 | Operation | process | 8 | |||||
source | 6 | growth | 4 | management | 8 | ||||||
landscape | 5 | future | 3 | information | 5 | ||||||
stream | 4 | value | 3 | Acquisition | 4 | ||||||
tree | 4 | View of Nature | priority | 8 | assessment | 4 | |||||
river | 3 | forest preserves | 5 | decision | 4 | ||||||
Spatial Morphology | network | 22 | restoration | 5 | implementation | 4 | |||||
corridor | 8 | no loss | 4 | issue | 4 | ||||||
system | 6 | View of Human | health | 6 | Limitation | year | 8 | ||||
trail | 6 | recreation | 6 | ||||||||
greenway | 4 | enjoyment | 4 | ||||||||
Site | area | 21 | ecosystem service | 4 | |||||||
County | 18 | supply | 4 | ||||||||
Acre | 16 | economy | 3 | ||||||||
Region | 14 | food | 3 | ||||||||
community | 13 | ||||||||||
city | 11 | ||||||||||
state | 8 | ||||||||||
downtown | 6 | ||||||||||
Land type | park/parkland | 13/3 | |||||||||
habitat | 10 | ||||||||||
asset | 5 | ||||||||||
farm/farmland | 3/3 | ||||||||||
Disaster | flood | 5 | |||||||||
stormwater | 5 |
Objective Objects * | Interests * | Main Thrust of the Operation * | Practical Approach * | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Category ** | Concept | Freq. | Category ** | Concept | Freq. | Category ** | Concept | Freq. | Category ** | Concept | Freq. |
Natural and Ecological Resources | Land | 53 | All | Quality | 27 | Utilization | Development | 19 | Planning Type | Plan/Planning | 26/10 |
Ecosystem | 25 | Benefit | 19 | Use | 10 | Study | 13 | ||||
Air | 19 | Value | 19 | Conservation | Conservation | 30 | Strategy | 10 | |||
Specie | 17 | Opportunity | 18 | Protection | 14 | Program | 8 | ||||
Climate | 17 | Impact | 10 | Support | 11 | Vision | 6 | ||||
Soil | 16 | Change | 9 | Operation | Assessment | 17 | |||||
Resource | 16 | Future | 7 | Project | 17 | ||||||
Forest | 14 | Addition | 7 | Effort | 14 | ||||||
Plant | 13 | View of Nature | Restoration | 10 | Management | 10 | |||||
Carbon | 12 | Priority | 9 | Investment | 10 | ||||||
Vegetation | 9 | View of Human | Recreation | 19 | Process | 9 | |||||
life | 9 | Ecosystem service | 18 | Decision | 8 | ||||||
Bird | 7 | Cost | 17 | Limitation | Year | 15 | |||||
Tree | 7 | Health | 16 | Level | 10 | ||||||
Animal | 6 | Production | 11 | Term | 7 | ||||||
Water Resources and Water Management | Water | 49 | Food | 10 | |||||||
Wetland | 20 | Treatment | 8 | ||||||||
Flood/Flooding | 14/13 | Economy | 7 | ||||||||
Stormwater | 13 | Emission | 7 | ||||||||
River | 10 | Property | 7 | ||||||||
Lake | 9 | ||||||||||
Runoff | 8 | ||||||||||
Groundwater | 8 | ||||||||||
Watershed | 7 | ||||||||||
Stream | 7 | ||||||||||
Sediment | 7 | ||||||||||
Spatial Morphology | Space | 22 | |||||||||
System | 21 | ||||||||||
Network | 19 | ||||||||||
Trail | 13 | ||||||||||
Disaster | Greenway | 10 | |||||||||
Greenbelt | 8 | ||||||||||
Wild live Survival | Wildlife | 26 | |||||||||
Parcel | 10 | ||||||||||
Habitat | 20 | ||||||||||
Corridor | 15 | ||||||||||
People Society Activities | Resident | 15 | |||||||||
Activity | 10 | ||||||||||
People | 9 | ||||||||||
Visitor | 8 | ||||||||||
Business | 8 | ||||||||||
Agency | 7 | ||||||||||
Pollutant | 6 | ||||||||||
Site | Area | 41 | |||||||||
Community | 40 | ||||||||||
Park/Parkland | 30/7 | ||||||||||
County | 22 | ||||||||||
Acre | 21 | ||||||||||
Region | 20 | ||||||||||
State | 13 | ||||||||||
Site | 12 | ||||||||||
City | 8 |
Appendix B
Technology/Tool | Development | Protection | Other | Nature | Society | Planning | Water | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
S1 | S2 | S3 | S1 | S2 | S3 | S | S1 | S2 | S3 | S1 | S2 | S3 | S1 | S2 | S3 | S1 | S2 | S3 | |
Ecosystem Service Valuation | 1 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 |
GIS Decision Support Tools and Map Services | 1 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
Green Infrastructure Networks/Landscape Design | 1 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 1 | 0 | 1 | 0 | 1 | 0 | 0 | 0 | 0 | 0 |
Implementation/Acquisition Targeting | 1 | 0 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 0 | 1 | 0 | 1 | 0 | 0 |
Implementation Quilt | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 1 | 1 | 0 | 0 | 0 | 0 | 0 |
Leadership Forum | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 |
Optimization Models for Cost-effective Decision-making | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
Public Involvement and Cooperation Enhanced | 1 | 0 | 0 | 1 | 0 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 |
Rapid Open Space Assessments | 0 | 0 | 1 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 |
Regional Conservation Visions | 1 | 0 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
Review of Previous Planning and Conservation | 0 | 0 | 1 | 0 | 1 | 0 | 0 | 0 | 1 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 |
Strategic Conservation Guidance | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
Structured Decision Tools Using the Logic Scoring of Preference Method | 0 | 0 | 1 | 0 | 1 | 0 | 0 | 0 | 1 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 |
Travel Planning | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 |
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GI Definition in the Projects by the CF | Project Name |
---|---|
Green infrastructure is our natural life support system—an interconnected network of forests, wetlands, waterways, floodplains, and other natural areas; including parks, greenways, farms; and other open spaces that support native species, maintain natural ecological processes, sustain air and water resources that contribute to people’s health and quality of life. | Green Infrastructure Plan for Cecil County, MD |
Kent County, Delaware Rapid Assessment of Green Infrastructure | |
A Green Infrastructure Network is an interconnected system of natural areas and open space that conserves ecosystem values, helps sustain clean air and water, and provides benefits to people and wildlife. | Angelina County, Texas Green Infrastructure Plan |
Green Infrastructure Plan for Central Indiana-Greening the Crossroads | |
Green infrastructure is defined as a strategically planned and managed network of natural lands, working landscapes, and other open spaces that conserve ecosystem functions and values and provide associated benefits to human populations. | Houston-Galveston Green Infrastructure and Ecosystem Services Assessment |
Lake County Green Infrastructure Model and Strategy | |
Green infrastructure refers to the services provided by open spaces. Green infrastructure includes tree-lined streets, community gardens, parks, greenways, pocket parks, farmland, forestland, waterways, and bluffs. These places, great and small, when connected, make a stronger network. | “Nashville: Naturally” |
Green infrastructure—and an interconnected network of parks, rivers, and lands—to help reconnect people and wildlife to the county’s lands and waters. | The Emerald Necklace Forest to Ocean Expanded Vision plan for Los Angeles County |
Green infrastructure investments on a regional basis at all scales, landscape through site-specific, can provide cost-effective protection for valuable transportation, energy and water treatment infrastructure, shield homes and businesses from adverse impacts, and provide additional benefits, particularly for underserved and vulnerable populations. | Greater Baltimore Wilderness Coastal Resilience Project |
Green infrastructure, a complex system of land, streams, rivers, and lakes that provide and protect critical source waters. * | Upper Neuse Clean Water Initiative |
Interconnected natural areas make up the region’s green infrastructure network and provide important conservation landscapes for high-quality ecosystems. | Chicago Wilderness Vision |
No. | Project Name |
---|---|
01 | Green Infrastructure Plan for Louisiana Wildlife Management Areas |
02 | Strategic Conservation Plan for Nevada |
03 | Green Infrastructure Plan in West Virginia |
04 | Greenseams® |
05 | Ann Arbor Greenbelt Initiative |
06 | Strategic Conservation for the Loxahatchee River Watershed |
07 | Atlanta Green Space Assessment |
08 | Baltimore County Land Preservation Model |
09 | Texas Pineywoods Experience |
10 | Kent County, Delaware Rapid Assessment of Green Infrastructure |
11 | Spartanburg Rapid Parks Assessment |
12 | Green Infrastructure Plan for Cecil County, MD |
13 | Angelina County, Texas Green Infrastructure Plan |
14 | Strategic Conservation for Kona, Hawai’i |
15 | Green Infrastructure Plan for Central Indiana-Greening the Crossroads |
16 | Houston-Galveston Green Infrastructure and Ecosystem Services Assessment |
17 | “Nashville: Naturally” |
18 | The Emerald Necklace Forest to Ocean Expanded Vision Plan for Los Angeles County |
19 | Chicago Wilderness Vision |
20 | Conservation Priority Mapping in West Virginia |
21 | Greater Baltimore Wilderness Coastal Resilience Project |
22 | Lake County Green Infrastructure Model and Strategy |
23 | Upper Neuse Clean Water Initiative |
24 | Finding the Flint, Flint River, Georgia |
25 | Green Infrastructure Vision for Cameron County, Texas |
26 | Mississippi River Basin/Gulf Hypoxia Initiative (MRB/GHI) Conservation Blueprint 2.0 |
27 | Southeast Cook County Land Acquisition Plan |
Items | Category | Subcategory | |
---|---|---|---|
Project Information | Location/Scope | Census-designated place | Multiple |
City | State | ||
County | Watershed | ||
Cooperation Partners | Conservation Organization | Land Trust | |
Consulting Firms | NGO | ||
Foundation | Regional Committee | ||
Government Agency | Research Organization | ||
Land Use and Land Cover Description | Border Area | Lake/Pond | |
Coastal Area | Open Space | ||
Farmland | Park and Preserve | ||
Forest/Woodland | River/Stream | ||
Full Administrative Scope Area | Urban Developed Area | ||
Grassland | Water and Watershed | ||
Green Space | Wetland | ||
Purpose | View of Development | People–Nature Connection | Preservation and Addition of City Parks/Parkland |
Economy Development | Promote Sectoral Cooperation | ||
Farmland Protection and Support Food Supply | Raise Environmental Awareness | ||
Improve People Living Environment | Stormwater/Flood Management | ||
Land Acquisition and Management | Use Nature Resource for Tourism | ||
View of Protection | Addition of Protected Area | Curb the Negative Effects of Development and Urban Sprawl | |
Build Site Resilience | Nature and Resource Restoration | ||
Conservation of Wildlife Living Environment | Priority of Nature Environment and Resource Protection | ||
Construct of GI Network for Conservation | Protection and Supply of Ecosystem Service | ||
Others | Environment Assessment | ||
GI Function | Nature and Ecosystem | Build Site Resilience | Determine the Minimum Area to be Protected/Utilized |
Build GI Networks | Identification of Priority Areas for Protection | ||
Conservation of Nature Resources | Identification of Regional Capacities/Potentials | ||
Conservation of Species and Habitats | Keep Balance of Protection and Utilization in Land Use | ||
Conservation/Addition of Nature Land | Purification of Air | ||
Conservation/Support of Ecosystem Service | Restoration of Natural Environment | ||
Curb the Negative Effects of Development and Urban Sprawl | |||
People Society Activities | Build Parks and Connecting to Nature | Protection of Infrastructure | |
Develop Recreation by Natural Landscapes Finance of Funds | Raise Civic Awareness and Encouraging Public Participation | ||
Improve People Living Environment and Public Health | Resist Disasters and Reducing the Cost of Disaster Prevention | ||
Preservation of Cultural Heritage | Support Economy Development | ||
Protection of Agricultural | Support Stabilization of Food Supply | ||
Communities/Agricultural Landscapes | |||
Planning and Implementation | Assess Protection Ability | Provide Technical Support for the Future | |
Assistance in Program/Strategy/Development | Sensitive Land Acquisition | ||
Guide the Future | Systematic Integration of Conservation/Restoration/ Development | ||
Water Resource | Protection and Purification of Water Quantity/Quality | Stormwater Management | |
Protection of Waters Area | |||
Technology /Tool * | / | Ecosystem Service Valuation | Public Involvement and Cooperation Enhanced |
GIS Decision Support Tools and Map Services | Rapid Open Space Assessments | ||
Green Infrastructure Networks/Landscape Design | Regional Conservation Visions | ||
Implementation/Acquisition Targeting | Review of Previous Planning and Conservation | ||
Implementation Quilt | Strategic conservation guidance | ||
Leadership Forum | Structured Decision Tools Using the Logic Scoring of Preference Method | ||
Optimization Models for Cost-effective Decision-making | Travel Planning |
Technology/Tool | Cooperation Partners | Land Use and Land Cover Description | ||||||
---|---|---|---|---|---|---|---|---|
Consulting Firms | Land Trust | Full Administrative Scope | Urban Developed | Farmland | Open Space | Park and Preserve | Water and Watershed | |
Implementation Quilt | p = 0.030 | p = 0.028 | ||||||
Phi (φ) = 0.509 | Phi (φ) = 0.593 | |||||||
Optimization Models for Cost-effective Decision-making | p = 0.028 | |||||||
Phi (φ) = 0.593 | ||||||||
Public Involvement and Cooperation Enhanced | p = 0.012 | p = 0.009 | p = 0.012 | p = 0.042 | ||||
Phi (φ) = 0.598 | Phi (φ) = 0.588 | Phi (φ) = 0.598 | Phi (φ) = 0.467 | |||||
Review of Previous Planning and Conservation | p = 0.027 | |||||||
Phi (φ) = 0.463 | ||||||||
Travel Planning | p ≤ 0.001 | |||||||
Phi (φ) = 1.000 |
Technology/Tool | View of Development | |||||||||
---|---|---|---|---|---|---|---|---|---|---|
Category Total | Addition of People-Nature Connection | Economy Development | Farmland Protection and Support Food Supply | Improve People Living Environment | Land Acquisition and Management | Preservation and Addition of City Parks/ Parkland | Promoting Sectoral Cooperation | Raising Environmental Awareness | Using Nature Resource for Tourism | |
Ecosystem Service Valuation | p = 0.022 | p = 0.030 | ||||||||
Phi (φ) = 0.145 | Phi (φ) = 0.472 | |||||||||
GIS Decision Support Tools and Map Services | p ≤ 0.001 | p = 0.030 | ||||||||
Phi(φ) = −0.261 | Phi(φ) = −0.472 | |||||||||
Green Infrastructure Networks/Landscape Design | p ≤ 0.001 | p = 0.008 | p = 0.023 | |||||||
Phi (φ) = 0.223 | Phi (φ) = 0.567 | Phi (φ) = 0.478 | ||||||||
Implementation Quilt | p = 0.037 | p = 0.024 | ||||||||
Phi (φ) = 0.131 | Phi (φ) = 0.491 | |||||||||
Leadership Forum | p = 0.042 | |||||||||
Phi (φ) = 0.467 | ||||||||||
Optimization Models for Cost-effective Decision-making | p = 0.017 | |||||||||
Phi (φ) = 0.678 | ||||||||||
Public Involvement and Cooperation Enhanced | p ≤ 0.001 | p = 0.050 | p = 0.042 | p = 0.024 | p = 0.050 | |||||
Phi (φ) = 0.267 | Phi (φ) = 0.421 | Phi (φ) = 0.467 | Phi(φ) = 0.497 | Phi (φ) = 0.421 | ||||||
Rapid Open Space Assessments | p = 0.013 | |||||||||
Phi (φ) = 0.606 | ||||||||||
Regional Conservation Visions | p = 0.002 | p = 0.027 | ||||||||
Phi (φ) = 0.194 | Phi (φ) = 0.467 | |||||||||
Review of Previous Planning and Conservation | p = 0.043 | |||||||||
Phi (φ) = 0.529 | ||||||||||
Structured Decision Tools Using the Logic Scoring of Preference Method | p = 0.004 | |||||||||
Phi (φ) = 0.197 | ||||||||||
Travel Planning | p = 0.029 | p = 0.019 | ||||||||
Phi (φ) = 0.500 | Phi (φ) = 0.545 |
Technology/Tool | View of Protection | ||||
---|---|---|---|---|---|
Category Total | Construct of GI Network for Conservation | Curb the Negative Effects of Development and Urban Sprawl | Priority of Nature Environment and Resource Protection | Protection and Supply of Ecosystem Service | |
Ecosystem Service Valuation | p = 0.004 | p = 0.016 | p = 0.030 | ||
Phi (φ) = 0.207 | Phi (φ) = 0.495 | Phi (φ) = 0.509 | |||
Green Infrastructure Networks/Landscape Design | p = 0.008 | ||||
Phi (φ) = 0.187 | |||||
Implementation Quilt | p = 0.013 | ||||
Phi (φ) = 0.172 | |||||
Public Involvement and Cooperation Enhanced | p ≤ 0.001 | p = 0.023 | p = 0.009 | p = 0.033 | |
Phi (φ) = 0.349 | Phi (φ) = 0.478 | Phi (φ) = 0.588 | Phi (φ) = 0.445 | ||
Regional Conservation Visions | p = 0.017 | ||||
Phi (φ) = 0.171 | |||||
Review of Previous Planning and Conservation | p = 0.024 | ||||
Phi (φ) = 0.167 | |||||
Structured Decision Tools Using the Logic Scoring of Preference Method | p = 0.004 | ||||
Phi (φ) = 0.197 |
Technology/Tool | Nature and Ecosystem | |||||
---|---|---|---|---|---|---|
Category Total | Build Site Resilience | Building GI Networks | Conservation of Nature Resources | Conservation of Species and Habitats | Purification of Air | |
Green Infrastructure Networks/Landscape Design | p = 0.007 | |||||
Phi (φ) = 0.590 | ||||||
Implementation/Acquisition Targeting | p < 0.001 | p = 0.003 | ||||
Phi (φ) = 0.239 | Phi (φ) = 0.598 | |||||
Implementation Quilt | p = 0.031 | |||||
Phi (φ) = 0.121 | ||||||
Public Involvement and Cooperation Enhanced | p < 0.001 | p = 0.024 | p = 0.042 | p = 0.024 | ||
Phi (φ) = 0.198 | Phi (φ) = 0.497 | Phi (φ) = 0.467 | Phi (φ) = 0.497 | |||
Regional Conservation Visions | p < 0.001 | p = 0.011 | p = 0.008 | p = 0.044 | ||
Phi (φ) = 0.184 | Phi (φ) = 0.542 | Phi (φ) = 0.562 | Phi (φ) = 0.434 | |||
Review of Previous Planning and Conservation | p = 0.004 | |||||
Phi (φ) = 0.161 | ||||||
Structured Decision Tools Using the Logic Scoring of Preference Method | p = 0.047 | |||||
Phi (φ) = 0.111 |
Technology/Tool | People Society Activities | |||||||
---|---|---|---|---|---|---|---|---|
Category Total | Build Parks and Connecting to Nature | Develop Recreation by Natural Landscapes | Improve People Living Environment and Public Health | Raise Civic Awareness and Encouraging Public Participation | Resist Disasters and Reducing the Cost of Disaster Prevention | Support Economy Development | Support Stabilization of Food Supply | |
GIS Decision Support Tools and Map Services | p = 0.018 | p = 0.029 | ||||||
Phi (φ) = −0.141 | Phi (φ) = −0.500 | |||||||
Green Infrastructure Networks/Landscape Design | p = 0.007 | |||||||
Phi (φ) = 0.159 | ||||||||
Implementation/Acquisition Targeting | p < 0.001 | p = 0.024 | ||||||
Phi (φ) = 0.219 | Phi (φ) = 0.491 | |||||||
Implementation Quilt | p = 0.013 | |||||||
Phi (φ) = 0.606 | ||||||||
Leadership Forum | p = 0.042 | |||||||
Phi (φ) = 0.467 | ||||||||
Public Involvement and Cooperation Enhanced | p < 0.001 | p = 0.024 | p = 0.002 | p = 0.042 | p = 0.001 | p = 0.050 | p = 0.012 | |
Phi (φ) = 0.371 | Phi (φ) = 0.497 | Phi (φ) = 0.657 | Phi (φ) = 0.467 | Phi (φ) = 0.700 | Phi (φ) = 0.421 | Phi (φ) = 0.598 | ||
Rapid Open Space Assessments | p = 0.030 | |||||||
Phi (φ) = 0.472 | ||||||||
Regional Conservation Visions | p = 0.014 | p ≤ 0.001 | p = 0.011 | |||||
Phi (φ) = 0.146 | Phi (φ) = 0.746 | Phi (φ) = 0.542 | ||||||
Review of Previous Planning and Conservation | p < 0.001 | p = 0.008 | ||||||
Phi (φ) = 0.204 | Phi (φ) = 0.567 | |||||||
Structured Decision Tools Using the Logic Scoring of Preference Method | p = 0.010 | p = 0.027 | p = 0.027 | |||||
Phi (φ) = 0.152 | Phi (φ) = 0.463 | Phi (φ) = 0.463 | ||||||
Travel Planning | p = 0.029 | |||||||
Phi (φ) = 0.500 |
Technology/Tool | Planning and Implementation | |||
---|---|---|---|---|
Category Total | Guiding the Future | Providing Technical Support for the Future | Systematic Integration of Conservation/Restoration/ Development | |
Ecosystem Service Valuation | p = 0.006 | p = 0.017 | ||
Phi (φ) = 0.228 | Phi (φ) = 0.526 | |||
Green Infrastructure Networks/Landscape Design | p = 0.006 | p = 0.023 | ||
Phi (φ) = 0.223 | Phi (φ) = 0.478 | |||
Implementation/Acquisition Targeting | p = 0.024 | |||
Phi (φ) = 0.181 | ||||
Implementation Quilt | p = 0.001 | p = 0.017 | ||
Phi (φ) = 0.264 | Phi (φ) = 0.526 | |||
Leadership Forum | p = 0.042 | |||
Phi (φ) = 0.467 | ||||
Public Involvement and Cooperation Enhanced | p = 0.006 | p = 0.011 | p = 0.050 | |
Phi (φ) = 0.221 | Phi (φ) = 0.542 | Phi (φ) = 0.421 | ||
Structured Decision Tools Using the Logic Scoring of Preference Method | p = 0.004 | p = 0.033 | ||
Phi (φ) = 0.230 | Phi (φ) = 0.452 |
Technology/Tool | Water Resource | |||
---|---|---|---|---|
Category Total | Protection and Purification of Water Quantity/Quality | Protection of Waters Area | Stormwater Management | |
Implementation/Acquisition Targeting | p < 0.001 | p = 0.024 | ||
Phi (φ) = 0.384 | Phi (φ) = 0.491 | |||
Public Involvement and Cooperation Enhanced | p < 0.001 | p = 0.042 | p ≤ 0.001 | |
Phi (φ) = 0.470 | Phi (φ) = 0.467 | Phi (φ) = 0.727 | ||
Review of Previous Planning and Conservation | p = 0.044 | |||
Phi (φ) = 0.434 |
Technology/Tool | Adopted Times | Situation Type for Purpose Relevance * | Situation Type for GI Function Relevance ** | |||||
---|---|---|---|---|---|---|---|---|
VD | VP | O | NE | PSA | PI | WR | ||
Implementation/Acquisition Targeting | 12 | S(3) | S(2) | S(3) | S(3) | S(2) | S(3) | |
Public Involvement and Cooperation Enhanced | 7 | S(3) | S(3) | S(3) | S(3) | S(3) | S(3) | |
Green Infrastructure Networks/Landscape Design | 9 | S(3) | S(2) | S(1) | S(2) | S(3) | S(1) | |
Review of Previous Planning and Conservation | 6 | S(1) | S(2) | S(2) | S(3) | |||
Structured Decision Tools Using the Logic Scoring of Preference Method | 11 | S(1) | S(2) | S(2) | S(3) | S(3) | ||
Regional Conservation Visions | 8 | S(3) | S(2) | S(3) | S(3) | |||
Ecosystem Service Valuation | 5 | S(3) | S(3) | S(3) | ||||
GIS Decision Support Tools and Map Services | 18 | S(3) | S(3) | |||||
Implementation Quilt | 5 | S(2) | S(1) | S(3) | ||||
Travel Planning | 3 | S(1) | S(1) | |||||
Leadership Forum | 4 | S(1) | S(1) | |||||
Rapid Open Space Assessments | 5 | S(1) | S(1) | |||||
Optimization Models for Cost-effective -Decision-making | 2 | S(1) | ||||||
Strategic Conservation Guidance | 14 |
Classification | Technology/Tool | Adopted Times | |
---|---|---|---|
Core Technology/Tool | 12 | Strategic Conservation Guidance | 14 |
01 | Ecosystem Service Valuation | 5 | |
02 | GIS Decision Support Tools and Map Services | 18 | |
03 | Green Infrastructure Networks/Landscape Design | 9 | |
04 | Implementation/Acquisition Targeting | 12 | |
08 | Public Involvement and Cooperation Enhanced | 7 | |
10 | Regional Conservation Visions | 8 | |
05 | Implementation Quilt | 5 | |
Specialized Technology/Tool | 11 | Review of Previous Planning and Conservation | 6 |
13 | Structured Decision Tools using the Logic Scoring of Preference Method | 11 | |
06 | Leadership Forum | 4 | |
07 | Optimization Models for Cost-effective Decision-making | 2 | |
09 | Rapid Open Space Assessments | 5 | |
14 | Travel Planning | 3 |
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Yang, X.; Wang, Q.; Chen, Y.; Kinoshita, T. Exploration of the Technologies Application Experience of Landscape-Scale Green Infrastructure by the Conservation Fund. Land 2024, 13, 1648. https://doi.org/10.3390/land13101648
Yang X, Wang Q, Chen Y, Kinoshita T. Exploration of the Technologies Application Experience of Landscape-Scale Green Infrastructure by the Conservation Fund. Land. 2024; 13(10):1648. https://doi.org/10.3390/land13101648
Chicago/Turabian StyleYang, Xiaoqi, Qian Wang, Yifan Chen, and Takeshi Kinoshita. 2024. "Exploration of the Technologies Application Experience of Landscape-Scale Green Infrastructure by the Conservation Fund" Land 13, no. 10: 1648. https://doi.org/10.3390/land13101648
APA StyleYang, X., Wang, Q., Chen, Y., & Kinoshita, T. (2024). Exploration of the Technologies Application Experience of Landscape-Scale Green Infrastructure by the Conservation Fund. Land, 13(10), 1648. https://doi.org/10.3390/land13101648