Classification of crispness of food materials by deep neural networks

IF 2.8 3区农林科学 Q2 FOOD SCIENCE & TECHNOLOGY

Journal of texture studies Pub Date : 2023-08-01 DOI:10.1111/jtxs.12792

Rafael Z. Lopes, Gustavo C. Dacanal

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引用次数: 0

Abstract

Crispness is a textural characteristic that influences consumer choices, requiring a comprehensive understanding for product customization. Previous studies employing neural networks focused on acquiring audio through mechanical crushing of crispy samples. This research investigates the representation of crispy sound in time intervals and frequency domains, identifying key parameters to distinguish different foods. Two machine learning architectures, multi-layer perceptron (MLP) and residual neural network (ResNet), were used to analyze mel frequency cepstral coefficients (MFCC) and discrete Fourier transform (DFT) data, respectively. The models achieved over 95% accuracy “in-sample” successfully classifying fried chicken, potato chips, and toast using randomly extracted audio from ASMR videos. The MLP (MFCC) model demonstrated superior robustness compared to ResNet and predicted external inputs, such as freshly toasted bread acquired by a microphone or ASMR audio of toast in milk. In contrast, the ResNet model proved to be more responsive to variations in DFT spectrum and unable to predict the similarity of external audio sources, making it useful for classifying pretrained “in-samples”. These findings are useful for classifying crispness among individual food sources. Additionally, the study explores the promising utilization of ASMR audio from Internet platforms to pretrain artificial neural network models, expanding the dataset for investigating the texture of crispy foods.

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基于深度神经网络的食品材料脆度分类。

脆度是一种影响消费者选择的质地特征，需要对产品定制有全面的了解。以往使用神经网络的研究主要集中在通过机械破碎脆脆的样品来获取音频。本研究探讨脆脆声在时间间隔和频域的表征，找出区分不同食物的关键参数。采用多层感知器(MLP)和残差神经网络(ResNet)两种机器学习架构，分别对mel倒频系数(MFCC)和离散傅立叶变换(DFT)数据进行分析。该模型使用从ASMR视频中随机提取的音频，成功地对炸鸡、薯片和吐司进行了“样本内”分类，准确率超过95%。与ResNet相比，MLP (MFCC)模型表现出优越的鲁棒性，并预测了外部输入，例如通过麦克风或ASMR音频获取的新鲜烤面包。相比之下，ResNet模型被证明对DFT频谱的变化更敏感，并且无法预测外部音频源的相似性，这使得它对预训练的“样本内”分类很有用。这些发现有助于对不同食物来源的脆度进行分类。此外，本研究还探索了利用互联网平台的ASMR音频预训练人工神经网络模型的前景，扩大了研究脆皮食物质地的数据集。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of texture studies 工程技术-食品科技

CiteScore

6.30

自引率

9.40%

发文量

审稿时长

>24 weeks

期刊介绍： The Journal of Texture Studies is a fully peer-reviewed international journal specialized in the physics, physiology, and psychology of food oral processing, with an emphasis on the food texture and structure, sensory perception and mouth-feel, food oral behaviour, food liking and preference. The journal was first published in 1969 and has been the primary source for disseminating advances in knowledge on all of the sciences that relate to food texture. In recent years, Journal of Texture Studies has expanded its coverage to a much broader range of texture research and continues to publish high quality original and innovative experimental-based (including numerical analysis and simulation) research concerned with all aspects of eating and food preference. Journal of Texture Studies welcomes research articles, research notes, reviews, discussion papers, and communications from contributors of all relevant disciplines. Some key coverage areas/topics include (but not limited to): • Physical, mechanical, and micro-structural principles of food texture • Oral physiology • Psychology and brain responses of eating and food sensory • Food texture design and modification for specific consumers • In vitro and in vivo studies of eating and swallowing • Novel technologies and methodologies for the assessment of sensory properties • Simulation and numerical analysis of eating and swallowing