Indonesia is an archipelago, which three of its five main island consists mainly, or dense tropical rainforest. This rainforest is main breeding ground for malaria disease that mostly affect regions near said forest. In an effort to treat malaria disease, a diagnostic process is performed to correctly identify the disease. Several image pattern recognition technique been developed and have potential to be utilized as malaria diagnostic tool. In this research, a method is described on designing neural network to detect a blood cell parasitized by malaria. The method consists of utilizing a dense network, and a convolutional neural network, to be trained using publicly available training dataset. Both models’ performance is then compared and analyzed. Before the data is used, a process of padding is performed to resize the input image into 200 x 200 pixels. The resized input data is then used to train both models. From the training and testing, it is found that the dense network achiever 64.78% accuracy. On the other hand, model based on convolutional neural network achiever 94.32%. From analysis, it is found that the size of the model being used is not big enough to achieve better performance. Hence, it is suggested for future research to increase the model size in terms of network width and depth.

Bias, S., Reni, S., & Kale, I. (2018). Mobile Hardware Based Implementation of a Novel, Efficient, Fuzzy Bias, S., Reni, S., & Kale, I. (2018). Mobile Hardware Based Implementation of a Novel, Efficient, Fuzzy Logic Inspired Edge Detection Technique for Analysis of Malaria Infected Microscopic Thin Blood Images . The 8th International Conference on Current and Future Trends of Information and Communication Technologies in Healthcare (ICTH 2018) (pp. 374-381). Elsevier.

Bottou, L. (2018). Online Algorithms and Stochastic Approximations. Red Bank: AT&T Labs-Research.

Centers for Disease Control and Prevention. (2020, February 19). Malaria Diagnosis - Microscopy. Retrieved from Centers for Disease Control and Prevention: https://www.cdc.gov/malaria/diagnosis_treatment/diagnostic_tools.html

He, K., Zhang, X., Ren, S., & Sun, J. (2016). Deep Residual Learning for Image Recognition. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (pp. 770-778). IEEE.

Jaeger, S. (2019, May 28). National Library of Medicine. Retrieved from LHNCBC: lhncbc.nlm.nih.gov/LHC-publications/pubs/Malaria-Datasets.html

LeCun, Y., Bottou, L., Bengio, Y., & Haffner, P. (1998). Gradient-Based Learning Applied to Document Recognition. Proceedings of the IEEE (pp. 1-46). IEEE.

Pattanaik, P., Mittal, M., Khan, M., & Panda, S. (2020, July 7). Malaria detection using deep residual networks with mobile microscopy. Journal of King Saud University, pp. 1-6.

Poostchi, M., Silamut, K., Maude, R., Jaeger, S., & Thoma, G. (2018, April). Image analysis and machine learning for detecting malaria. Translational Research, pp. 36-55.

Primadi, O. (2017, April 3). Kenali Malaria Sebelum Lakukan Perjalanan ke Kawasan Timur Indonesia. Retrieved from Sehat Negeriku: https://sehatnegeriku.kemkes.go.id/baca/rilis-media/20170331/2720325/kenali-malaria-lakukan-perjalanan-kawasan-timur-indonesia/

Rajendran, S., Balasubramanian, D., & Rajinikanth, V. (2020). Automated detection of plasmodium species using Machine-Learning technique. Diagnostics and Molecular Technology, pp. 192-193.

Rosenblatt, F. (1958). The Perceptron: A Probabilistic Model for Information Storage and Organization in the Brain. Psychological Review, 386-408.

Sharma, A., Vans, E., Shigemizu, D., Boroevich, K., & Tsunoda, T. (2019). DeepInsight: A methodology to transform a non-image data to an image for convolutional neural network architecture. Scientific Reports.

Shorten, C., & Khoshgoftaar, T. (2019). A survey on Image Data Augmentation for Deep Learning. Journal of Big Data.

Zou, W., Wang, X., Sun, M., & Lin, Y. (2013). Generic Object Detection with Dense Neural Patterns and Regionlets. NEC Laboroties America.