Abstract
Near-infrared (NIR) spectroscopy models for fresh fruit quality prediction often fail when used on a new batch or scenario having new variability which was absent in the primary calibration. To handle the new variability often model updating is required. In this study, to solve the challenge of updating NIR models related to fresh fruit quality properties, the use of a semi-supervised parameter-free calibration enhancement (PFCE) approach was proposed. Model updating with PFCE was shown in two ways: first where the model on the primary batch was updated individually for each new fruit batch, and second where the model was sequentially updated for the next batches. Furthermore, for the first time, a case of updating an instrument transferred model was also presented. The PFCE approach was shown in two real cases related to moisture and total soluble solids prediction in pear and kiwi fruit. In the case of pear, the model was later updated for 3 new measurement batches, while, for kiwi, a commercial model was updated to incorporate the variability of a new experiment carried out with a new instrument in the laboratory environment. For each modelling demonstration, the performance was benchmarked with the partial least-square (PLS) regression analysis on the primary batch. The results showed that the models updated with a semi-supervised approach kept a high predictive performance on new measurement batches, without any extra parameter optimization. An instrument transferred model was also updated to maintain its performance on different batches. Further, the sequential updating approach was found to be performing better than the update for individual batches, as the models were able to learn from multiple batches. Model updating with a semi-supervised approach can allow the NIR spectroscopy of fresh fruit to be scalable, where models can be shared between scientific or application community.
Highlights
Near-infrared (NIR) spectroscopy has proved itself as one of the main tools for rapid and non-destructive analysis of fresh fruit in the post-harvest domain [1,2]
This study aims to present a recently developed semisupervised parameter-free framework for calibration enhancement (PFCE) approach utilising a correlation constraint to update NIR models related to fresh fruit
This study found that the PLS model made on one batch lacked robustness to precisely predict moisture content (MC) and total soluble solids (TSS) in the new batches of pear fruit
Summary
Near-infrared (NIR) spectroscopy has proved itself as one of the main tools for rapid and non-destructive analysis of fresh fruit in the post-harvest domain [1,2]. In the case of fresh fruit analysis, the implementation of NIR is not as straightforward and very often the NIR calibration does not precisely predict the property of interest when the models are used on a new batch of fruit [1,2,5,9]. The examples of the new variability can be related to a new cultivar or a harvest season, and variability not related to the property of interest may be a different measurement temperature. To make it more complex, sometimes the new variability and the variability due to external influences are mixed such as for a batch where a new cultivar of fruit was measured at a different temperature and with a new light source. To achieve NIR models that work well on a new batch, it is important to both incorporate the new variability and remove/ reduce the influences of external factors from the data wherever possible [12e14]
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