PRODUCTION OF SOFTWARE TO DETERMINE PRODUCTIVE PERFORMANCE INDEXES AND NUTRITIONAL BIOENERGY OF AQUATIC ORGANISMS
DOI:
https://doi.org/10.47820/recinter21.v2i2.18Keywords:
productive indexes, nutritional bioenergy, mathematical models, softwareAbstract
Aquaculture is a way to ensure a viable and inexpensive source of high-quality protein for human nutrition. The state of global fisheries production shows critical levels of growth in fish production, as well as an increase in aquaculture to feed, nourish and employ millions of people. This practice requires a lot of production control, linked to water quality and the quality of the food supplied, in order to have better productive results. Growth can be influenced endogenously by inheritance and the action of hormones, and exogenously by a complex of environmental factors, the most important of which is probably the quantity and quality of food. Mathematical models of growth, using growth curves for weight, can lead to a greater understanding of the empirical nature of animal evolution. These curves are related to weight and age, and are constructed using measurements of body mass and time, which describe changes in weight over the lifespan. The production results are monitored by performing biometrics, recording weight, length and width data, and then analyzing the productive performance of the organisms by applying mathematical models. However, the manual use of mathematical models to determine the productive indices and nutritional bioenergy has been a time-consuming process that requires a lot of concentration from the technician, in addition to there being a risk of failure. In order to find solutions, an innovative software was developed that contains all the mathematical models applied for these purposes and data entry intervals to facilitate data processing and obtain results quickly and without risk of errors in operations.
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