Image Processing is image processing with a digital computer to produce new images according to the user's wishes. One implementation is to reconstruct the image. Through the extraction stages are able to get the characteristics of an image. The algorithm used is Adam Optimization, which is an extension of the stochastic gradient reduction that has just seen wider adoption for deep learning applications in computer vision and natural language processing. In this study using the autoencoder technique, which is one variant of artificial neural networks that are generally used to "encode" data. Autoencoder is trained to be able to produce the same output as the input. This image reconstruction aims to process an image whose quality is not very clear to be clear. This if possible can be used to detect someone's face from a distance of photos. In reconstructing this image through the encode and decode process by defining Conv2D and Maxpool, it is processed into training with epoch 100 times while for the prediction process using Keras library. Then the last one gets an accuracy of 0,022. The final result is the output of the reconstructed image and calculation graph.

W. N. Hidayat, A. T. Oktaviani, T. A. Sutikno, R. K. Sari, H. Elmunsyah, and T. A. Sandy, “Camlearn as Photography Mobile Learning Application and its Effects on Academic Achievement,” in 2019 International Conference on Electrical, Electronics and Information Engineering (ICEEIE), Oct. 2019, pp. 168–171. doi: 10.1109/ICEEIE-47180.¬2019.8981467.

A. Dolmatova, M. Chukalina, and D. Nikolaev, “Accelerated FBP for computed tomography image reconstruction,” in 2020 IEEE International Conference on Image Processing (ICIP), 2020, pp. 3030–3034.

M. G. Hu, J. F. Wang, and Y. Ge, “Super-resolution reconstruction of remote sensing images using multifractal analysis,” Sensors, vol. 9, no. 11, pp. 8669–8683, 2009.

Y. Zhang, W. Miao, Z. Lin, H. Gao, and S. Shi, “Millimeter-wave InSAR image reconstruction approach by total variation regularized matrix completion,” Remote Sens., vol. 10, no. 7, p. 1053, 2018.

J. H. Nam and A. Velten, “Super-resolution remote imaging using time encoded remote apertures,” Appl. Sci., vol. 10, no. 18, p. 6458, 2020.

M. Engelcke, O. P. Jones, and I. Posner, “Reconstruction bottlenecks in Object-Centric generative models,” in arXiv preprint arXiv:2007.06245, 2020.

O. Wiles, S. Ehrhardt, and A. Zisserman, “Co-attention for conditioned image matching,” in Proceedings of the IEEE/CVF conference on computer vision and pattern recognition, 2021, pp. 15920–15929.

D. Minnen and S. Singh, “Channel-wise autoregressive entropy models for learned image compression,” in 2020 IEEE International Conference on Image Processing (ICIP), 2020, pp. 3339–3343.

S. Indolia, A. K. Goswami, S. P. Mishra, and P. Asopa, “Conceptual understanding of convolutional neural network-a deep learning approach,” Procedia Comput. Sci., vol. 132, pp. 679–688, 2018.

T. Sun, W. Fang, W. Chen, Y. Yao, F. Bi, and B. Wu, “High-resolution image inpainting based on multi-scale neural network,” Electronics, vol. 8, no. 11, p. 1370, 2019.

N. Ailon, O. Leibovitch, and V. Nair, “Sparse linear networks with a fixed butterfly structure: theory and practice,” in Uncertainty in Artificial Intelligence, 2021, pp. 1174–1184.

J. Tang, C. Huang, J. Liu, and H. Zhu, “Image super-resolution based on CNN using multilabel gene expression programming,” Appl. Sci., vol. 10, no. 3, p. 854, 2020.

W. Lee, J. Lee, D. Kim, and B. Ham, “Learning with privileged information for efficient image super-resolution,” in Computer Vision–ECCV 2020: 16th European Conference, Glasgow, UK, August 23–28, 2020, Proceedings, Part XXIV 16, 2020, pp. 465–482.

W. N. Hidayat, T. A. Sutikno, H. Elmunsyah, A. Prasasti, L. F. Tumelisya, and W. M. Utomo, “User Experience Design of Augmented Reality-based Mobile Learning Media for English Subjects through User-Centered Design Approach,” in 2021 7th International Conference on Education and Technology (ICET), Sep. 2021, pp. 171–176. doi: 10.1109/ICET53279.2021.9575121.