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DLD: An Optimized Chinese Speech Recognition Model Based on Deep Learning

Author

Listed:
  • Hong Lei
  • Yue Xiao
  • Yanchun Liang
  • Dalin Li
  • Heow Pueh Lee
  • Daniele Salvati

Abstract

Speech recognition technology has played an indispensable role in realizing human-computer intelligent interaction. However, most of the current Chinese speech recognition systems are provided online or offline models with low accuracy and poor performance. To improve the performance of offline Chinese speech recognition, we propose a hybrid acoustic model of deep convolutional neural network, long short-term memory, and deep neural network (DCNN-LSTM-DNN, DLD). This model utilizes DCNN to reduce frequency variation and adds a batch normalization (BN) layer after its convolutional layer to ensure the stability of data distribution, and then use LSTM to effectively solve the gradient vanishing problem. Finally, the fully connected structure of DNN is utilized to efficiently map the input features into a separable space, which is helpful for data classification. Therefore, leveraging the strengths of DCNN, LSTM, and DNN by combining them into a unified architecture can effectively improve speech recognition performance. Our model was tested on the open Chinese speech database THCHS-30 released by the Center for Speech and Language Technology (CSLT) of Tsinghua University, and it was concluded that the DLD model with 3 layers of LSTM and 3 layers of DNN had the best performance, reaching 13.49% of words error rate (WER).

Suggested Citation

  • Hong Lei & Yue Xiao & Yanchun Liang & Dalin Li & Heow Pueh Lee & Daniele Salvati, 2022. "DLD: An Optimized Chinese Speech Recognition Model Based on Deep Learning," Complexity, Hindawi, vol. 2022, pages 1-8, May.
    • Handle: RePEc:hin:complx:6927400
    DOI: 10.1155/2022/6927400
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