DOI QR코드

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동적패널모형을 이용한 천해어류양식 생산에 영향을 미치는 요인 분석

Identifying Factors Influencing Fish Production of Shallow-sea Aquaculture Based on the Dynamic Panel Model

  • 심성현 (국립부경대학교 자원환경경제연구소) ;
  • 남종오 (국립부경대학교 인문사회과학대학 경제학부)
  • Sim, Seonghyun (Institute of Resources & Environmental Economics, Pukyong National University) ;
  • Nam, Jongoh (Division of Economics, College of Humanities & Social Sciences, Pukyong National University)
  • 투고 : 2019.02.07
  • 심사 : 2019.03.08
  • 발행 : 2019.03.30

초록

The purpose of this study is to identify factors influencing fish production of shallow-sea aquaculture in South Korea. This study employed the two-way fixed effect and random effect models based on the panel models and also the difference between GMM and system GMM models based on the dynamic panel models using the amount of fish farming production, the number of stocked fry, the number of cultured fish, the amount of inputted feed, the farming area, the number of workers, and the sales price data from 2010 to 2017. First, the two-way fixed effect model of the panel models was selected by panel characteristics, time characteristics and Hausman tests and also the model was statistically significant. As a result of the two-way fixed effect model, the number of stocked fry, the amount of inputted feed, and the number of workers were identified as factors that increase the fish production of shallow-sea aquaculture. However, the number of cultured fish and the sales price were analyzed as factors that reduce the fish production of shallow-sea aquaculture. Second, the system GMM model of the dynamic panel models was selected by Hansen test and Arellano-Bond test in order to identify whether or not the over-discrimination condition is appropriate. Based on the system GMM model, the number of stocked fry, the amount of inputted feed, the number of workers in this year and 1 year ago, the number of cultured fish 2 years ago, and the sale price 3 years ago were analyzed as factors that increase the fish production of shallow-sea aquaculture. However, the amount of fish farming production 1, 2, 3 years ago, the farming area in this year, and the number of cultured fish in this year and 1 year ago were identified as factors that reduce the fish production of shallow-sea aquaculture. In conclusion, this study suggests that it is desirable to control the amount of stocked fry rather than to expand the farming area for fish farming in shallow-sea aquaculture, so as to keep the sale price at a certain level by maintaining the appropriate amount of fish production.

키워드

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Fig. 1. Trends in fish production volume and value of shallow-sea aquaculture (2000−2017)

Table 1. Fish production volume and ratio by fishery type (2015−2017)

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Table 2. Fish production volume and ratio of shallow-sea aquaculture by province (2013−2017)

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Table 3. Fish production volume and ratio of fish species by aquaculture type (2017)

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Table 4. Factors of fish production in shallow-sea aquaculture (2013−2017)

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Table 5. Basic statistics of analysis data

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Table 6. Results of the Pearson correlation analysis

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Table 6. Results of the Variation Index Factor’s estimation

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Table 7. Results of the two-way fixed effect and random effect models

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Table 8. Results of the difference GMM and system GMM models

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