Human Resources Monitoring System using Sensors GPS on Android Smartphone
DOI:
10.33395/sinkron.v7i2.11400Keywords:
Human Resources, Monitoring, Android, Flutter, SmartphoneAbstract
Smartphone technology is currently developing rapidly. In an effort to improve and empower companies, smart is used as a tool for anything in office work and in projects. For example, smartphones are currently used for meetings or coordination with leaders and employees. In the project, smartphones can be used to monitor employees. One of the problems with work on projects is that employees often leave project work for several reasons. The position of employees is often unknown to other employees or leaders. So the idea arose to find out the whereabouts of the employee. Monitoring employees on the project is very important, where the presence of these employees is needed to coordinate. If the employee is at risk of a work accident, the management quickly knows the position of the employee. The idea of making employee monitoring in the project by creating an application system for employee positions in the project. In addition to monitoring, employees do not need to attend the office, from the employee's home directly to the project site and do asben from the project site. The data will record the name of the employee, the position of the employee in the project, the time of absence, see the tasks that will be carried out per day. The results of the task are carried out by taking selfies as a report to superiors. The purpose of this research is to solve the problem of the existence of employees or the position of employees in the project, to be absent at the project site, to take selfies on the progress of daily work, and to hold meetings with the application. This application is built using technology based on the Android system using Flutter.
Downloads
References
Arjo, T. R., & Anbeni, R. (2018). Pengenalan Aktivitas Berkendara Berbasis Sensor Accelerometer Pada Smartphone Dengan Fitur Auto Feedback Menggunakan Algoritma k- Nearest Neighbour. Journal of Applied Informatics and Computing (JAIC), 2(1), 1–6.
Google.com. (2018). Flutter open source by Google. https://flutter.dev/
Gunawan, A. A. S., Stevanus, V., Farley, A., Ngarianto, H., Budiharto, W., Tolle, H., & Attamimi, M. (2019). Development of smart trolley system based on android smartphone sensors. Procedia Computer Science, 157, 629–637. https://doi.org/10.1016/j.procs.2019.08.225
Hashmi, M. F., Shukla, R. J., & Keskar, A. G. (2015). Real time copyright protection and implementation of image and video processing on android and embedded platforms. Procedia Computer Science, 46(Icict 2014), 1626–1634. https://doi.org/10.1016/j.procs.2015.02.096
Hernández-Álvarez, L., de Fuentes, J. M., González-Manzano, L., & Hernández Encinas, L. (2021). SmartCAMPP - Smartphone-based continuous authentication leveraging motion sensors with privacy preservation. Pattern Recognition Letters, 147, 189–196. https://doi.org/10.1016/j.patrec.2021.04.013
Kundra, L., & Ekler, P. (2014). Bias Compensation of Gyroscopes in Mobiles with Optical Flow. AASRI Procedia, 9(Csp), 152–157. https://doi.org/10.1016/j.aasri.2014.09.024
Lissa, D., Srinivasu, V. K. D., Prasad, D. S. V. V. D., & Niranjan, K. (2020). Ionospheric response to the 26 August 2018 geomagnetic storm using GPS-TEC observations along 80° E and 120° E longitudes in the Asian sector. Advances in Space Research, 66(6), 1427–1440. https://doi.org/10.1016/j.asr.2020.05.025
Maulana, S. H., & Setiawan, E. B. (2019). Pemanfaatan Sensor Pada Smartphone Android Untuk Rekomendasi Pembibitan Tanaman. Ultimatics, 10(2), 85–92. https://doi.org/10.31937/ti.v10i2.957
Mazuera-Rozo, A., Escobar-Velásquez, C., Espitia-Acero, J., Vega-Guzmán, D., Trubiani, C., Linares-Vásquez, M., & Bavota, G. (2022). Taxonomy of security weaknesses in Java and Kotlin Android apps. Journal of Systems and Software, 187, 111233. https://doi.org/10.1016/j.jss.2022.111233
Neforawati, I., Adani, D., Rahmawati, E., & Fitriana, A. (2016). Penggunaan Notifikasi Berbasis Android untuk Memantau Perawatan pada Sistem Otomasi Akuaponik Menggunakan Mikrokontroller ATmega 2560. Multinetics, 2(2), 24. https://doi.org/10.32722/vol2.no2.2016.pp24-29
Reddybattula, K. D., & Panda, S. K. (2019). Performance analysis of quiet and disturbed time ionospheric TEC responses from GPS-based observations, IGS-GIM, IRI-2016 and SPIM/IRI-Plas 2017 models over the low latitude Indian region. Advances in Space Research, 64(10), 2026–2045. https://doi.org/10.1016/j.asr.2019.03.034
Riantana, R. (2015). Aplikasi Sensor Accelerometer pada Handphone Android sebagai Pencatat Getaran Gempabumi secara Online. Jurnal Fisika Dan Aplikasinya, 11(3), 114. https://doi.org/10.12962/j24604682.v11i3.1071
Sadiq, S., Umer, M., Ullah, S., Mirjalili, S., Rupapara, V., & Nappi, M. (2021). Discrepancy detection between actual user reviews and numeric ratings of Google App store using deep learning. Expert Systems with Applications, 181, 115111. https://doi.org/10.1016/j.eswa.2021.115111
Weiss, P. (2021). The Global Positioning System (GPS): Creating Satellite Beacons in Space, Engineers Transformed Daily Life on Earth. Engineering, 7(3), 290–303. https://doi.org/10.1016/j.eng.2021.02.001
Yerima, S. Y., Loughlin, M., Sezer, S., Moriarty, J., McCann, M., McAneney, H., O’Hara, L., Tully, M. A., Ell, P. S., Miller, R., & Macdonald, G. (2018). MobiQ: A modular Android application for collecting social interaction, repeated survey, GPS and photographic data. SoftwareX, 7, 143–149. https://doi.org/10.1016/j.softx.2018.04.006
Downloads
|
How to Cite
Issue
Section
License
Copyright (c) 2022 Daniel Karjadi
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Muhammad Khoiruddin harahap
Google Scholar 
Moraref
PKP Index
Garuda Kemdikbud
Indonesia OneSearch
OCLC Worldcat
Dimensions
Index Copernicus
Scilit
