Audio-Based Emotion Recognition Using Self-Supervised Learning on an Engineered Feature Space

AI Pub Date : 2024-01-17 DOI:10.3390/ai5010011
Peranut Nimitsurachat, Peter Washington
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Abstract

Emotion recognition models using audio input data can enable the development of interactive systems with applications in mental healthcare, marketing, gaming, and social media analysis. While the field of affective computing using audio data is rich, a major barrier to achieve consistently high-performance models is the paucity of available training labels. Self-supervised learning (SSL) is a family of methods which can learn despite a scarcity of supervised labels by predicting properties of the data itself. To understand the utility of self-supervised learning for audio-based emotion recognition, we have applied self-supervised learning pre-training to the classification of emotions from the CMU Multimodal Opinion Sentiment and Emotion Intensity (CMU- MOSEI)’s acoustic data. Unlike prior papers that have experimented with raw acoustic data, our technique has been applied to encoded acoustic data with 74 parameters of distinctive audio features at discrete timesteps. Our model is first pre-trained to uncover the randomly masked timestamps of the acoustic data. The pre-trained model is then fine-tuned using a small sample of annotated data. The performance of the final model is then evaluated via overall mean absolute error (MAE), mean absolute error (MAE) per emotion, overall four-class accuracy, and four-class accuracy per emotion. These metrics are compared against a baseline deep learning model with an identical backbone architecture. We find that self-supervised learning consistently improves the performance of the model across all metrics, especially when the number of annotated data points in the fine-tuning step is small. Furthermore, we quantify the behaviors of the self-supervised model and its convergence as the amount of annotated data increases. This work characterizes the utility of self-supervised learning for affective computing, demonstrating that self-supervised learning is most useful when the number of training examples is small and that the effect is most pronounced for emotions which are easier to classify such as happy, sad, and angry. This work further demonstrates that self-supervised learning still improves performance when applied to the embedded feature representations rather than the traditional approach of pre-training on the raw input space.
利用工程特征空间上的自监督学习进行基于音频的情感识别
使用音频输入数据的情感识别模型可以开发互动系统,应用于心理保健、市场营销、游戏和社交媒体分析等领域。虽然使用音频数据进行情感计算的领域非常丰富,但要实现始终如一的高性能模型,一个主要障碍就是可用的训练标签太少。自监督学习(SSL)是一系列通过预测数据本身的属性,在缺乏监督标签的情况下仍能进行学习的方法。为了了解自监督学习在基于音频的情感识别中的实用性,我们将自监督学习预训练应用于 CMU 多模态意见情感和情感强度(CMU- MOSEI)声学数据的情感分类。与之前使用原始声学数据进行实验的论文不同,我们的技术应用于在离散时间步上具有 74 个独特音频特征参数的编码声学数据。我们的模型首先经过预训练,以发现声学数据中随机屏蔽的时间戳。然后,使用小样本的注释数据对预训练模型进行微调。然后通过总体平均绝对误差 (MAE)、每种情感的平均绝对误差 (MAE)、总体四类准确率和每种情感的四类准确率来评估最终模型的性能。这些指标与具有相同骨干架构的基线深度学习模型进行了比较。我们发现,自监督学习能持续提高模型在所有指标上的性能,尤其是当微调步骤中注释数据点的数量较少时。此外,随着注释数据量的增加,我们还量化了自监督模型的行为及其收敛性。这项工作描述了自监督学习在情感计算中的实用性,证明了当训练示例数量较少时,自监督学习最为有用,而且对于快乐、悲伤和愤怒等较易分类的情感,自监督学习的效果最为明显。这项研究还进一步证明,如果将自我监督学习应用于嵌入式特征表征,而不是采用在原始输入空间进行预训练的传统方法,那么自我监督学习仍能提高性能。
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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