A FINGERPRINT BASED STUDENTS ATTENDANCE MANAGEMENT SYSTEM FOR OLABISI ONABANJO UNIVERSITY
DOI:
https://doi.org/10.33003/fjs-2022-0601-896Keywords:
Fingerprint, Attendance, Software Development Life Cycle (SDLC)Abstract
The development of attendance was motivated by the necessity to keep track of who was there in a certain location at any given moment for future reference. Attendance is defined as the awareness of persons present at a specific location at a specific time for a previously scheduled event. Keeping and managing attendance records efficiently is critical for student evaluation. All formal institutions of learning place a high value on class attendance, which is so important that students who do not reach the class attendance threshold are not allowed to appear for exams. Traditional attendance marking techniques are prone to human error and time demanding for both students and lecturers during class. The old attendance system has various drawbacks, including lost attendance sheets, impersonation, time waste, insecurity, and lack of precision. As a result, by utilizing the unique qualities of fingerprint technology, a smart solution to the challenges connected with the traditional attendance system is required. As a result, the article devised, designed, and deployed a fingerprint-based attendance management system for students. The system's development model was the Software Development Life Cycle (SDLC). To record and verify students' fingerprints, a digital persona fingerprint scanner was utilized, and the Graphical User Interface (GUI) was created using the window forms application of the Visual Studio Integrated Development Environment (IDE). The back-end design was created using the C# programming language and the Structure Query Language (SQL) server. The system's logic was implemented in C#, and the SQL server was utilized as the
References
Ako, B., & Olorunfemi, M. (1989). Geoelectric Survey of Groundwater in The Newer Basalt of Jos, Plateau State. Journal of Mining and Geology 25 , 247-250.
Aller, L., Lehr, J., & Petty, R. (1987). DRASTIC: A Standardised System To Evaluate Groundwater Pollution Potential Using Hydrogeological Settings. U.S: US EPA Report 600/2-87-035, U.S. Enviromental Protection.
Chowdhury, A., Jha, M., Chowdary, V., & MAL, B. (2009). Integrated remote sensing and GIS-based approach for assessing groundwater potential in West Medinipur district,West Bengal, India. . Int. Jour. Remote Sensing, v.30 , 231-250.
Clark, L. (1985). Groundwater Abstraction From the Basement Complex Areas of Africa. Quarterly Journal for Engineering Geology, London, Vol 18 , 25-34.
Clark, L. (1985). Groundwater Abstraction From the Basement Complex Areas of Africa. Quarterly Journal for Engineering Geology, London, Vol 18 , 25-34.
Dearmaun, W., Dayness, F., & Irfar, T. (1978). Engineering Grading of Weathered Granite. Engineering Geology Granite. Engineering Geology No. 12 , 345-374.
Eduvie, M. (1998). Groundwater Assesment and Borehole Characteristics: Case Study of Kaduna Metropolis. Paper Presented at a Workshop Organized by Kaduna State Water Board. Nigeria Teachers Institute . Kaduna, Kaduna, Nigeria.
Gupta, M., & Srivastava, P. (2010). Integrating GIS and remote sensing for identification of groundwater potential zones in the hilly terrain of Pavagarh, Gujarat, India. Water Int., v.35 , 233-245..
IWMI. (2001). The Strategic Plan for IWMI 2000–2005. Colombo, Sri Lanka: International Water Management Institute.
McCurry, P. (1976). The Geology of The Precambrian to Lower Paleozoic Rocks pf Northern Nigeria:. In C. (. Kogbe, Geology of Nigeria (pp. 15-38). Ibadan: Elisabeth Publication Company, Ibadan, Nigeria.
Musa, I. (2011). Looming Water Scacity: The Challenges and Prospects of Integrated Water Resources Management in Nigeria. Paper Presented at the 7th Annual Lecture of the School of Engineering and Engineering Technology, (p. 54). Federal University of Technology, Akure, Ondo State.
Nag, S., & Anindita, L. (2011). Integrated approach using Remote Sensing and GIS techniques for Delineating Groundwater Potential Zones in Dwarakeswar Watershed Bankura District, West Bengal. International Journal for Geomatics and Geosciences. Vol 2, No 2 , 430-442.
Nigerian Geological Survey Agency (2008). Geologic Map of Kaduna. Abuja: Authority of The Federal Republic of Nigeria.
Olayinka, A., & Olorunfemi, M. (1992). Determination of Geoelectric Characteristics in Okene Area and Implication of Borehole Sitting. Journal of Mining and Geology 28 , 403-412.
Olorunfemi, M., & Fasuyi, S. (1993). Aquifer Type and The Geoelectric Hydrogeologic Characteristics of Part of The Central Basement Terrain Nigeria (Niger State). Journal of Africa Earth Sciences 16 , 309-317.
Olorunniwo, M., & Olorunfemi, M. (1987). Geophysical Investigation of Groundwater in Precambrian Terrains: A Case History of Ikare, South-western Nigeria. Journal of African Earth Sciences 6 , 787-796.
Oteze, G. (1989). The Hydrogeology ofthe North-Western Nigeria Basin. Kogbe C.A. Rockview (Nig) Ltd, Jos -Nigeria , 455=472.
Todd, D., & Mays, L. (2005). Groundwater Hydrology. 3rd ed. Hoboken: John Wiley & Sons.
The Geological Society of America (2009). Geologic Time Scale. USA: Cambrige University Press.
Udoh, E., & Etim, N. (2007). Analysis for Domestic Water Consumption by Farming Households in Itu, Akwa Ibom State, Nigeria. European Journal for Social Sciences , 76-82.
Wisler, C., & Brater, B. (1959). Hydrology. New York: Willey
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