Suprasegmental representations for the modeling of fundamental frequency in statistical parametric speech synthesis
Date
02/07/2018Author
Fonseca De Sam Bento Ribeiro, Manuel
Metadata
Abstract
Statistical parametric speech synthesis (SPSS) has seen improvements over
recent years, especially in terms of intelligibility. Synthetic speech is often clear
and understandable, but it can also be bland and monotonous. Proper generation
of natural speech prosody is still a largely unsolved problem. This is relevant
especially in the context of expressive audiobook speech synthesis, where speech
is expected to be fluid and captivating.
In general, prosody can be seen as a layer that is superimposed on the segmental
(phone) sequence. Listeners can perceive the same melody or rhythm
in different utterances, and the same segmental sequence can be uttered with a
different prosodic layer to convey a different message. For this reason, prosody
is commonly accepted to be inherently suprasegmental. It is governed by longer
units within the utterance (e.g. syllables, words, phrases) and beyond the utterance
(e.g. discourse). However, common techniques for the modeling of speech
prosody - and speech in general - operate mainly on very short intervals, either at
the state or frame level, in both hidden Markov model (HMM) and deep neural
network (DNN) based speech synthesis.
This thesis presents contributions supporting the claim that stronger representations
of suprasegmental variation are essential for the natural generation of
fundamental frequency for statistical parametric speech synthesis. We conceptualize
the problem by dividing it into three sub-problems: (1) representations of
acoustic signals, (2) representations of linguistic contexts, and (3) the mapping
of one representation to another. The contributions of this thesis provide novel
methods and insights relating to these three sub-problems.
In terms of sub-problem 1, we propose a multi-level representation of f0 using
the continuous wavelet transform and the discrete cosine transform, as well
as a wavelet-based decomposition strategy that is linguistically and perceptually
motivated. In terms of sub-problem 2, we investigate additional linguistic
features such as text-derived word embeddings and syllable bag-of-phones and
we propose a novel method for learning word vector representations based on
acoustic counts. Finally, considering sub-problem 3, insights are given regarding
hierarchical models such as parallel and cascaded deep neural networks.