Machine learning-based infant crying interpretation

M. Hammoud, Melaku N. Getahun, Anna Baldycheva, Andrey Somov
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Abstract

Crying is an inevitable character trait that occurs throughout the growth of infants, under conditions where the caregiver may have difficulty interpreting the underlying cause of the cry. Crying can be treated as an audio signal that carries a message about the infant's state, such as discomfort, hunger, and sickness. The primary infant caregiver requires traditional ways of understanding these feelings. Failing to understand them correctly can cause severe problems. Several methods attempt to solve this problem; however, proper audio feature representation and classifiers are necessary for better results. This study uses time-, frequency-, and time-frequency-domain feature representations to gain in-depth information from the data. The time-domain features include zero-crossing rate (ZCR) and root mean square (RMS), the frequency-domain feature includes the Mel-spectrogram, and the time-frequency-domain feature includes Mel-frequency cepstral coefficients (MFCCs). Moreover, time-series imaging algorithms are applied to transform 20 MFCC features into images using different algorithms: Gramian angular difference fields, Gramian angular summation fields, Markov transition fields, recurrence plots, and RGB GAF. Then, these features are provided to different machine learning classifiers, such as decision tree, random forest, K nearest neighbors, and bagging. The use of MFCCs, ZCR, and RMS as features achieved high performance, outperforming state of the art (SOTA). Optimal parameters are found via the grid search method using 10-fold cross-validation. Our MFCC-based random forest (RF) classifier approach achieved an accuracy of 96.39%, outperforming SOTA, the scalogram-based shuffleNet classifier, which had an accuracy of 95.17%.
基于机器学习的婴儿哭声解读
哭泣是婴儿在成长过程中不可避免的性格特征,在这种情况下,看护人可能难以理解哭泣的根本原因。啼哭可被视为一种声音信号,传递着婴儿的状态信息,如不舒服、饥饿和生病等。婴儿的主要照顾者需要用传统的方法来理解这些感受。如果不能正确理解,就会造成严重的问题。有几种方法试图解决这一问题,但要取得更好的效果,必须要有适当的音频特征表示和分类器。本研究使用时域、频域和时频域特征表示法从数据中获取深度信息。时域特征包括零交叉率(ZCR)和均方根(RMS),频域特征包括梅尔频谱图(Mel-spectrogram),时频域特征包括梅尔频率倒频谱系数(MFCC)。此外,时间序列成像算法可将 20 个 MFCC 特征转化为图像,并使用不同的算法:格拉米安角差场、格拉米安角和场、马尔可夫转换场、递归图和 RGB GAF。然后,将这些特征提供给不同的机器学习分类器,如决策树、随机森林、K 最近邻和袋式分类。使用 MFCCs、ZCR 和 RMS 作为特征实现了较高的性能,优于最新技术(SOTA)。通过使用 10 倍交叉验证的网格搜索法找到了最佳参数。我们基于 MFCC 的随机森林 (RF) 分类器的准确率达到了 96.39%,超过了 SOTA 和基于 scalogram 的 shuffleNet 分类器,后者的准确率为 95.17%。
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