LAND AND WATER CARRYING CAPACITY ON INDUSTRY ALLOCATION IN KENDAL REGENCY

  • Casnan Casnan Program Studi Pendidikan Matematika, STKIP Muhammadiyah Kuningan
  • Hartrisari Hardjomidjojo Teknik Industri Pertanian, Institut Pertanian Bogor
Keywords: Carrying Capacity, Land, Water, Industry

Abstract

The purpose of this study is to provide information and also clear and accurate pictures of the carrying capacity of land and water in the industrial designation in the Kendal Regency. The method of analysis used is system dynamics approach. The projection of calculation for the next 10 years (2021 - 2031) is a prediction of water demand which is known continues to increase. The availability of water in the Kendal Regency is still sufficient for the population's living and industrial needs during this period. The management of agriculture and plantations have taken several steps to maintain the function of land according to conservation aspects and to prevent degradation in order to keep the conservation area as a reservoir of natural water. The industrial estate area in Kendal Regency is 1,265,323 hectares which is consists of land for industry and trade, mixed gardens, fields, meadows, coastal sand, settlements, rice fields, fishponds and dryland agriculture.

References

[1] M. Sukarja, “Pengaruh Alih Fungsi Lahan Pertanian Terhadap Ketahanan Pangan Kawasan Subang Jawa Barat,” Institut Pertaniasn Bogor, 2015.
[2] KIK, Dokumen Analisis Mengenai Dampak Lingkungan Kawasan Industri Tahap I. 2014.
[3] J. Zhou, Z. Erdal, P. Creanor, and F. Montalto, “Sustainability,” Water Environ. Res., vol. 82, no. 10, pp. 1376–1395, 2010.
[4] M. Salazar-Ordonez, M. Rodrıguez-Entrena, and S. Sayadi, “Agricultural Sustainability from a Societal View: An Analysis of Southern Spanish Citizens,” J. Agric. Environ. Ethics, vol. 26, no. 1, pp. 473–490, 2013.
[5] I. Firmansyah and T. Sukwika, “Penilaian kondisi degradasi tanah di SPK Sawangan kota Depok,” J. Tanah dan Sumberd. Lahan, vol. 7, no. 1, pp. 45–57, 2020.
[6] G. Luo, C. Yin, X. Chen, W. Xu, and L. Lu, “Combining System Dynamic Model and CLUE-S Model to Improve Land Use Scenario Analyses at Regional Scale: A Case Study of Sangong Watershed in Xinjiang, China,” Ecol. Complex., vol. 7, no. 1, pp. 198–207, 2010.
[7] A. Saysel, Y. Barlas, and O. Yenigun, “Environmental Sustainability in an Agricultural Development Project: a System Dynamics Approach,” Environ. Manage., vol. 64, no. 3, pp. 247–260, 2002.
[8] S. Sikdar, “Measuring Sustainability,” Clean Technol. Environ. Policy, vol. 14, no. 1, pp. 153–154, 2012.
[9] D. Sterman, Business Dynamic: System thinking and modelling for complex world. USA: The Mc Graw-Hill Companies, 2000.
[10] Muhammadi, E. Aminullah, and B. Susilo, Analisis Sistem Dinamis. Jakarta: UMJ Press, 2001.
[11] I. Firmansyah, “Model Pengendalian Konversi Lahan Sawah di Dalam DAS Citarum,” 2016.
[12] Widiatmaka, W. Ambarwulan, I. Firmansyah, K. Munibah, P. Santoso, and Sudarsono, “Land Suitability and Dynamic System Modelling To Define Priority Areas Of Soybean Plantation In Paddy Fields In Karawang, West Java.,” Agrivita, vol. 36, no. 3, pp. 235–248, 2014.
[13] BPS, Kabupaten Kendal Dalam Angka 2019. 2019.
[14] BPS, Kabupaten Kendal Dalam Angka 2016. 2016.
[15] BPS, Kabupaten Kendal Dalam Angka 2015. 2015.
[16] BPS, Kabupaten Kendal Dalam Angka 2018. 2018.
[17] BPS, Kabupaten Kendal Dalam Angka 2014. 2014.
[18] BPPP, Kajian Lingkungan Hidup Strategis Review RTRW Kabupaten Kendal. 2017.
[19] Q. Shen, Q. Chen, B. Tang, S. Yeung, Y. Hu, and G. Cheung, “A System Dynamics Model for The Sustainable Land Use Planning and Development.,” Habitat Int., vol. 33, no. 1, pp. 15–25, 2009.
[20] P. Yadav, M. Kapoor, and K. Sarma, “Land Use Land Cover Mapping, Change Detection and Conflict Analysis of Nagzira-Navegaon Corridor, Central India using geospatial technology,” Int. J. Remote Sens. GIS, vol. 1, no. 2, pp. 90–98, 2012.
Published
2020-06-30