SCIENTIFIC CHALLENGES IN MODELING MASTICATION OF MEAT USING ENGINEERING TOOLS
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This paper gives an overview of scientific challenges that may occur while performing modelling meat (as a product) and simulating mastication by using engineering tools. To evaluate these challenges, Failure Mode and Effect Analysis method has been employed to assess six engineering tools often used in analyzing different perspectives of food oral processing. As a result, a risk priority number comprising of severity of the failure, occurrence probability of a failure and difficulty to detect the failure has been calculated. Results show that finite element method and emotion detection are two tools with highest levels of risks. The first method is a known engineering solution used for analyzing different types of materials, but when it comes to meat as a very complex and anisotropic material, risk of inadequate calculations is high. Emotion detection is not so much dependent on meat as a product consumed but on imperfections of software and risk of recognizing false emotions is high.... Findings indicate that more research is needed for a more sophisticated use of these engineering tools. Further studies should include other engineering models that simulate meat breakdown during mastication, the role of saliva and jaw movement with the aim to carry out full modelling of mastication of an average meat consumer. © 2022, Djekic.
Keywords:
FMEA / Meat characteristics / Meat engineering / Meat qualitySource:
Theory and Practice of Meat Processing, 2022, 7, 1, 16-21Collections
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Poljoprivredni fakultetTY - JOUR AU - Djekic, I.V. PY - 2022 UR - http://aspace.agrif.bg.ac.rs/handle/123456789/6175 AB - This paper gives an overview of scientific challenges that may occur while performing modelling meat (as a product) and simulating mastication by using engineering tools. To evaluate these challenges, Failure Mode and Effect Analysis method has been employed to assess six engineering tools often used in analyzing different perspectives of food oral processing. As a result, a risk priority number comprising of severity of the failure, occurrence probability of a failure and difficulty to detect the failure has been calculated. Results show that finite element method and emotion detection are two tools with highest levels of risks. The first method is a known engineering solution used for analyzing different types of materials, but when it comes to meat as a very complex and anisotropic material, risk of inadequate calculations is high. Emotion detection is not so much dependent on meat as a product consumed but on imperfections of software and risk of recognizing false emotions is high. Findings indicate that more research is needed for a more sophisticated use of these engineering tools. Further studies should include other engineering models that simulate meat breakdown during mastication, the role of saliva and jaw movement with the aim to carry out full modelling of mastication of an average meat consumer. © 2022, Djekic. T2 - Theory and Practice of Meat Processing T2 - Theory and Practice of Meat Processing T1 - SCIENTIFIC CHALLENGES IN MODELING MASTICATION OF MEAT USING ENGINEERING TOOLS EP - 21 IS - 1 SP - 16 VL - 7 DO - 10.21323/2414-438X-2022-7-1-16-21 ER -
@article{ author = "Djekic, I.V.", year = "2022", abstract = "This paper gives an overview of scientific challenges that may occur while performing modelling meat (as a product) and simulating mastication by using engineering tools. To evaluate these challenges, Failure Mode and Effect Analysis method has been employed to assess six engineering tools often used in analyzing different perspectives of food oral processing. As a result, a risk priority number comprising of severity of the failure, occurrence probability of a failure and difficulty to detect the failure has been calculated. Results show that finite element method and emotion detection are two tools with highest levels of risks. The first method is a known engineering solution used for analyzing different types of materials, but when it comes to meat as a very complex and anisotropic material, risk of inadequate calculations is high. Emotion detection is not so much dependent on meat as a product consumed but on imperfections of software and risk of recognizing false emotions is high. Findings indicate that more research is needed for a more sophisticated use of these engineering tools. Further studies should include other engineering models that simulate meat breakdown during mastication, the role of saliva and jaw movement with the aim to carry out full modelling of mastication of an average meat consumer. © 2022, Djekic.", journal = "Theory and Practice of Meat Processing, Theory and Practice of Meat Processing", title = "SCIENTIFIC CHALLENGES IN MODELING MASTICATION OF MEAT USING ENGINEERING TOOLS", pages = "21-16", number = "1", volume = "7", doi = "10.21323/2414-438X-2022-7-1-16-21" }
Djekic, I.V.. (2022). SCIENTIFIC CHALLENGES IN MODELING MASTICATION OF MEAT USING ENGINEERING TOOLS. in Theory and Practice of Meat Processing, 7(1), 16-21. https://doi.org/10.21323/2414-438X-2022-7-1-16-21
Djekic I. SCIENTIFIC CHALLENGES IN MODELING MASTICATION OF MEAT USING ENGINEERING TOOLS. in Theory and Practice of Meat Processing. 2022;7(1):16-21. doi:10.21323/2414-438X-2022-7-1-16-21 .
Djekic, I.V., "SCIENTIFIC CHALLENGES IN MODELING MASTICATION OF MEAT USING ENGINEERING TOOLS" in Theory and Practice of Meat Processing, 7, no. 1 (2022):16-21, https://doi.org/10.21323/2414-438X-2022-7-1-16-21 . .