Estimating Residents’ Preferences of the Land Use Program Surrounding Forest Park, Taiwan
Abstract
:1. Introduction
2. The Research Framework of the Land Use Programs
2.1. Introduction to DFP and the Community Population
2.2. Choice of Experiment Design for the Land Use Preference
2.2.1. Agricultural Farming Type
2.2.2. Biodiversity
2.2.3. Water Provision
2.2.4. Land Use Type
2.2.5. Ecotourism Mode
2.2.6. Willingness to Pay
2.2.7. Willingness to Work
2.3. The Choice Experiment for the Questionnaire Design
2.4. Sample Design and Data
2.5. Theory of Preference Function and the Marginal Effect on Land Use Preference
2.5.1. Models
2.5.2. Welfare Measures for the Marginal Effects
2.5.3. Hypothetical Land-Use Management Scenarios
- Scenario I—Natural conservation: The wetland area increases in size and a restoration effort is carried out by the surface water. Surface water and biodiversity increase. Land-use is devoted to ethnobotany and wetland areas. As for the agricultural farming type and ecotourism mode, we maintain the status quo.
- Scenario II—Environmental-friendly agriculture: The organic farming area and surface water provision increase. The organic farming area, biodiversity, surface water, and ethnobotany area increase. The ecotourism mode retains the status quo.
- Scenario III—Ecotourism development: The ecotourism package is integrated and the healthy environment area increases. The organic farming area and biodiversity increase, and an ecotourism package is integrated. Land-use is devoted to the ethnobotany area, wetland area, and integrated ecotourism. Water provision retains the status quo.
3. Empirical Results
3.1. Estimating the Land Use Preference Function
3.2. Welfare Analysis
3.3. Heterogeneity Test of the LCM Results
3.4. Welfare Changes for Hypothetical Land Use Management Scenarios
4. Discussion
Supplementary Materials
Acknowledgments
Author Contributions
Conflicts of Interest
References
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Attributes | Levels | Variable Name * | |
---|---|---|---|
Agricultural Farming Type | a. Status quo (conventional farming) | FA± | |
b. Increase organic farming area | FA+ | ||
Biodiversity | a. Status quo (244 nationwide plant, animal, fish, and insect species) | BI± | |
b. Increase in populations of species | BI+ | ||
Water Provision | a. Status quo (tap water or groundwater abstraction) | WA± | |
b. Increase surface water provision | WA+ | ||
Land Use Type | a. Status quo (artificial and mixed forest) | LU± | |
b. Increase natural forestry area | LU1 | ||
c. Increase ethnobotany area | LU2 | ||
d. Increase wetland area | LU3 | ||
Ecotourism Mode | a. Status quo (individual tourism) | EC± | |
b. Integrated framework for the ecotourism | EC+ | ||
Welfare foundation | (A) Willingness to Pay | a. Status quo (no payment) | FUND |
b. $500 NTD/year/person | |||
c. $1000 NTD/year/person | |||
d. $1500 NTD/year/person | |||
e. $2000 NTD/year/person | |||
(B) Willingness to work | a. Status quo (no contribution) | TIME | |
b. 6 h/month/person | |||
c. 12 h/month/person | |||
d. 18 h/month/person | |||
e. 24 h/month/person |
Attributes and Levels | WTP | WTW | ||
---|---|---|---|---|
Coefficient | t Value | Coefficient | t Value | |
ASC | 0.674 | 4.27 *** | 0.407 | 2.67 *** |
FA+ | 0.268 | 3.22 *** | 0.155 | 1.87 * |
BI+ | −0.09 | −0.76 | −0.103 | −0.87 |
WA+ | 0.363 | 4.66 *** | 0.45 | 5.8 *** |
LU1 | −0.052 | −0.42 | 0.063 | 0.52 |
LU2 | 0.252 | 2.29 ** | 0.133 | 1.23 |
LU3 | 0.408 | 2.65 *** | 0.38 | 2.52 *** |
EC+ | 0.194 | 3.63 *** | 0.225 | 4.25 *** |
FUND | −0.00079 | −6.18 *** | - | - |
TIME | - | - | −0.07473 | −7.10 *** |
Log-likelihood | −1895.60 | −1928.60 |
Attributes and Levels | Farmer (n = 146) | Non-Farmer (n = 510) | ||||||
---|---|---|---|---|---|---|---|---|
WTP | WTW | WTP | WTW | |||||
Coefficient | t Value | Coefficient | t Value | Coefficient | t Value | Coefficient | t Value | |
ASC | −0.585 | −1.81 * | −1.139 | −3.59 *** | 1.07 | 5.79 *** | 0.843 | 4.71 *** |
FA+ | −0.089 | −0.48 | −0.176 | −0.92 | 0.379 | 4.03 *** | 0.255 | 2.73 *** |
BI+ | 0.472 | 1.77 * | 0.675 | 2.48 ** | −0.253 | −1.88 * | −0.299 | −2.24 ** |
WA+ | 0.581 | 3.37 *** | 0.825 | 4.62 *** | 0.304 | 3.46 *** | 0.366 | 4.19 *** |
LU1 | 0.047 | 0.17 | 0.282 | 0.99 | −0.077 | −0.55 | 0.022 | 0.16 |
LU2 | −0.111 | −0.44 | −0.449 | −1.78 * | 0.348 | 2.81 *** | 0.276 | 2.24 ** |
LU3 | −0.193 | −0.61 | −0.343 | −1.05 | 0.597 | 3.34 *** | 0.575 | 3.29 *** |
EC+ | 0.215 | 1.82 * | 0.427 | 3.66 *** | 0.203 | 3.33 *** | 0.202 | 3.34 *** |
FUND | −0.002 | −6.37 *** | - | - | −0.00049 | −3.39 *** | - | - |
TIME | - | - | −0.19 | −7.5 *** | - | - | −0.046 | −3.9 *** |
Log-likelihood | −409.5 | −401.2 | −1467.50 | −1491.80 |
Attributes and Levels | All Respondents (n = 656) | Farmer (n = 146) | Non-Farmer (n = 510) | |||
---|---|---|---|---|---|---|
MWTP (FUND) | MWTW (TIME) | MWTP (FUND) | MWTW (TIME) | MWTP (FUND) | MWTW (TIME) | |
FA+ | 339.2 | 2.07 | - | - | 773.5 | 5.54 |
BI+ | - | - | 236 | 3.55 | −516.3 | −6.5 |
WA+ | 459.5 | 6.02 | 290.5 | 4.34 | 620.4 | 7.96 |
LU2 | 319 | - | - | −2.36 | 710.2 | 6 |
LU3 | 516.5 | 5.08 | - | - | 1218.40 | 12.5 |
EC+ | 245.6 | 3.01 | 107.5 | 2.25 | 414.3 | 4.4 |
Total value | 1879.80 | 16.18 | 634 | 7.78 | 3220.50 | 29.9 |
Attributes and Levels | Class 1 | Class 2 | ||||
---|---|---|---|---|---|---|
Coefficient | t Value | MWTP | Coefficient | t Value | MWTP | |
Class 1 | ||||||
ASC | −0.44904 | −1.29 | - | 17.46 | 0.001 | - |
FA+ | 0.3147 | 1.83 * | 229.7 | −12.65 | −0.001 | - |
BI+ | 0.15644 | 0.57 | - | 21.54 | 0.001 | - |
WA+ | 0.55119 | 3.23 *** | 402.3 | 17.55 | −0.001 | - |
LU1 | −0.02796 | −0.09 | - | 3.13 | 0.001 | - |
LU2 | 0.41324 | 1.68 * | 301.6 | −15.65 | −0.001 | - |
LU3 | −0.23473 | −0.64 | - | −1.72 | −0.001 | - |
EC+ | 0.48088 | 4.01 *** | 351 | 1.22 | 0.001 | - |
FUND | −0.00137 | −5.02 *** | - | −0.02 | −0.06 | - |
Probability | 0.673 | 0.327 | ||||
Class membership parameters: Class 1 | ||||||
Constant | 0.047 | 0.13 | ||||
Monthly income more than $20,000 NTD | 1.085 | 4.13 *** | ||||
Lived at location more than 50 years | −0.231 | −1.39 | ||||
Joined the community group | 0.549 | 2.55 ** | ||||
Land owner | 0.993 | 4.98 *** | ||||
Farmer | −0.329 | −1.42 | ||||
Log-likelihood ratio | 648.8 *** | |||||
Chi Square | χ20.01(24) = 43.0 |
Attributes and Levels | Hypothetical Future Scenarios | ||
---|---|---|---|
Scenario I: Natural Conservation | Scenario II: Environmental-Friendly Agriculture | Scenario III: Ecotourism Development | |
Agricultural Farming Type | Stay the present | Increase organic farming area | Increase organic farming area |
Biodiversity | Increase | Increase | Increase |
Water Provision | Increase surface water | Increase surface water | Stay the present |
Land Use Type | Increase ethnobotany area | Increase ethnobotany area | Increase ethnobotany area |
Increase wetland area | Increase wetland area | ||
Ecotourism Mode | Maintain status quo | Maintain status quo | Integrated ecotourism package |
MWTP (FUND) | 1293.90 | 1116.40 | 1419.30 |
MWTW (TIME) | 11.11 | 8.1 | 10.18 |
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Lee, C.-H.; Wang, C.-H. Estimating Residents’ Preferences of the Land Use Program Surrounding Forest Park, Taiwan. Sustainability 2017, 9, 598. https://doi.org/10.3390/su9040598
Lee C-H, Wang C-H. Estimating Residents’ Preferences of the Land Use Program Surrounding Forest Park, Taiwan. Sustainability. 2017; 9(4):598. https://doi.org/10.3390/su9040598
Chicago/Turabian StyleLee, Chun-Hung, and Chiung-Hsin Wang. 2017. "Estimating Residents’ Preferences of the Land Use Program Surrounding Forest Park, Taiwan" Sustainability 9, no. 4: 598. https://doi.org/10.3390/su9040598
APA StyleLee, C. -H., & Wang, C. -H. (2017). Estimating Residents’ Preferences of the Land Use Program Surrounding Forest Park, Taiwan. Sustainability, 9(4), 598. https://doi.org/10.3390/su9040598