Asep K. Supriatna
Cited by
Cited by
A two-age-classes dengue transmission model
AK Supriatna, E Soewono, SA van Gils
Mathematical Biosciences 216 (1), 114-121, 2008
A two-dimensional model for the transmission of dengue fever disease
E Soewono, AK Supriatna
Bulletin of the Malaysian Mathematical Sciences Society 24 (1), 2001
Model Development of a synergistic sustainable marine ecotourism—a case study in Pangandaran region, west java province, Indonesia
A Nurhayati, I Aisah, AK Supriatna
Sustainability 11 (12), 3418, 2019
The effect of reinfection with the same serotype on dengue transmission dynamics
N Anggriani, H Tasman, MZ Ndii, AK Supriatna, E Soewono, E Siregar
Applied Mathematics and Computation 349, 62-80, 2019
Indonesia’s issues and challenges on teacher professional development
A Supriatna
CICE Series 4 (2), 29-42, 2011
Mathematical models for the spread of rumors: a review
MZ Ndii, E Carnia, AK Supriatna
Issues and trends in interdisciplinary behavior and social science, 65-73, 2018
Stochastic mathematical models in epidemiology
MZ Ndii, AK Supriatna
Information 20, 6185-6196, 2017
Application of fractional differential equation in economic growth model: A systematic review approach
MD Johansyah, AK Supriatna, E Rusyaman, J Saputra
Aims Math 6 (9), 10266-10280, 2021
Optimal harvesting for a predator–prey metapopulation
AK Supriatna, HP Possingham
Bulletin of Mathematical Biology 60 (1), 49-65, 1998
An analysis of Covid-19 transmission in Indonesia and Saudi Arabia
MZ Ndii, P Hadisoemarto, D Agustian, AK Supriatna
Communication in Biomathematical Sciences 3 (1), 19-27, 2020
Mathematical model of tuberculosis transmission with reccurent infection and vaccination
J Nainggolan, S Supian, AK Supriatna, N Anggriani
Journal of Physics: Conference Series 423 (1), 012059, 2013
Estimating the basic reproduction number of dengue transmission during 2002-2007 outbreaks in Bandung, Indonesia
AK Supriatna
WHO Regional Office for South-East Asia., 2009
Harvesting a two‐patch predator‐prey metapopulation
AK Supriatna, HP Possingham
Natural Resource Modeling 12 (4), 481-498, 1999
Rabies epidemic model with uncertainty in parameters: crisp and fuzzy approaches
MZ Ndii, Z Amarti, ED Wiraningsih, AK Supriatna
IOP conference series: materials science and Engineering 332, 012031, 2018
System dynamics model of Wolbachia infection in dengue transmission
AK Supriatna, N Anggriani
Procedia Engineering 50, 12-18, 2012
Application of differential transformation method for solving dengue transmission mathematical model
MZ Ndii, N Anggriani, AK Supriatna
AIP conference proceedings 1937 (1), 2018
Optimal control issues in plant disease with host demographic factor and botanical fungicides
N Anggriani, M Mardiyah, N Istifadah, AK Supriatna
IOP conference series: Materials Science and Engineering 332 (1), 012036, 2018
Lesson Study Pengembangan Profesi Guru
S Hendayana, D Suryadi, A Supriatna, H Imansyah
Bandung: Rizqi Press, 2009
Mathematical model of temephos resistance in Aedes aegypti mosquito population
D Aldila, N Nuraini, E Soewono, AK Supriatna
AIP Conference Proceedings 1589 (1), 460-463, 2014
Stability analysis and optimal control of plant fungal epidemic: An explicit model with curative factor
N Anggriani, LN Putri, AK Supriatna
Symposium on Biomathematics (SYMOMATH 2014) 1651 (1), 40-47, 2015
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