JPH0518120B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a speech synthesis method capable of synthesizing a given phoneme sequence with good naturalness through simple processing.

[Technical background of the invention and its problems]

When converting a sentence containing kanji and kana characters created using a word processor or the like into speech, it has conventionally been generally done as follows. That is, first, the character string consisting of the above-mentioned kanji-kana mixed sentence is converted into a phoneme sequence, and from this phoneme sequence, a speech segment expressed by parameters characterizing the spectral envelope of speech is obtained. Then, these speech segments are combined to generate a series of parameters, and a synthesizer is used to obtain synthesized speech according to this series of parameters. Various methods of speech synthesis using this synthesizer have been studied in the past, and in this case, speech segments play a very important role. Therefore, in the past, so-called (VCV) type segments have been often used to express phoneme sequences by combining segments in vowel intervals that are spectrally stable. This (VCV) type elemental piece is introduced in detail in Japanese Patent Publication No. 49-49241, etc., where (V) indicates a vowel and (C) indicates a consonant.

However, when synthesizing speech using only such (VCV) type fragments, there is no guarantee that highly natural synthesized speech will be obtained, and there is a problem that the processing becomes considerably complicated. . For example, when trying to synthesize the word ``Hatsushin'', there is no element in the conventional (VCV) type phoneme that indicates the consonant that corresponds to ``tsu'' in the word. , this is generally treated as a silent section. However, when a consonant is followed by a fricative consonant such as the "S" sound, as in the word "hatsushin" mentioned above, in natural speech a change occurs in the consonant interval due to articulatory combination. Despite this, in the processing using the above-mentioned "VCV" type segment, it was not possible to express the influence of such articulatory combination, and the naturalness of the synthesized speech was impaired.

[Purpose of the invention]

The present invention has been made in consideration of these circumstances, and its purpose is to be able to efficiently generate highly natural speech synthesis even for phoneme sequences affected by articulatory combination. The objective is to provide a highly practical speech synthesis method.

[Summary of the invention]

The present invention uses V as a vowel and C as a consonant (VCV).
Prepare a first segment parameter that indicates the basic chain of phonemes of the type, and a second segment parameter that indicates the format of a continuous phoneme (VQQC〓V) in which QQ is a consonant interval and C〓 is a fricative consonant. When the input phoneme sequence is tested and the continuous phoneme is detected, the second element parameter is selected for the continuous phoneme, and the first element parameter is selected for phonemes other than the continuous phoneme. Select segment parameters, combine these selected segment parameters in the vowel interval,
Speech synthesis is performed according to the combined segment parameters.

〔Effect of the invention〕

Thus, according to the present invention, by giving a segment parameter of the type (VQQC〓V) to a phonetic sequence in which the consonant interval is changed by articulatory combination, for example, when a consonant is followed by a fricative consonant, , it is possible to obtain a segment parameter sequence that well reflects the characteristics of continuous phonemes that have undergone articulatory combination,
This has great practical effects, such as making it possible to obtain highly natural synthesized speech.

[Embodiments of the invention]

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a schematic diagram of a speech synthesis device constructed by applying an embodiment method. This device processes a character string consisting of a sentence containing kanji and kana characters inputted to an input circuit 1, and obtains a speech synthesis output thereof. That is, the input circuit 1 divides the input character string into phrases according to changes in the character type of the input sentence containing kanji and kana, such as a change from hiragana to kanji. The input circuit 1 inputs a character string divided into phrases into a dictionary collation circuit 2, where the character string is checked against a word dictionary pre-registered in a word dictionary storage device 3 in order from the first character of the phrase. Through this verification, the clause is divided into words. still,
The word dictionary storage device 3 registers word information and prosodic information, which are attached information, together with the above-mentioned word information. It is now being read out.

Information on the word strings that constitute the input character string collated by the word collation circuit 2 is input to the graphophonemic conversion circuit 4, and is derived from the phonological information read out from the storage device 3 for each of the collated words. It is converted into a phonological sequence. According to this phoneme sequence, a segment parameter sequence is generated to obtain a synthesized speech. This conversion process into a unit parameter sequence is first performed by the phoneme sequence verification circuit 5. This phoneme sequence testing circuit 5 inputs the phoneme sequence generated as described above, and tests and extracts continuous phonemes including phonemes affected by articulatory combination and continuous phonemes with a high frequency of appearance in this phoneme sequence. It is something. Continuous phonemes that include phonemes affected by the above-mentioned articulatory combination are represented by the word ``hatsushin,'' for example, where a consonant ``tsu'' is followed by a consonant, resulting in a consonant combination due to the influence of a fricative consonant. It is as if there was a change in the consonant interval. Continuous phonemes that appear frequently include, for example, the conjugated ending “ru”.
It is like a Japanese verb or auxiliary verb that ends in .

According to such test results, the elemental piece selection circuit 6
reads the segment parameters registered in the segment file storage devices 7 and 8, respectively, for the phonetic sequence of each word. The segment parameters registered in the storage devices 7 and 8 include short segment parameters indicated as (VCV) type segments, and (VQQC〓V) type or (VCVC ⁺ V ⁺ ) type segments. The short segment parameters are classified and registered in the storage device 7, and the long segment parameters are classified and registered in the storage device 8.

To explain the (VCV) type short segment parameters here, the phonological sequence of a word is captured as a chain of vowel (V) - consonant (C) - vowel (V), and this is the basic data unit, which becomes (VCV). A parameter sequence representing the phonetic sequence of the word is generated by combining the segments at spectrally stable vowel parts. Therefore, in general, it can be said that the phonetic sequence of all words can be expressed by a combination of short segment parameters. However, as mentioned above, this (CVC)
It is not possible to clearly express the characteristics of the phonological sequence of a word, which includes consonants and the like, which have changed due to articulatory combinations, using only the short segment parameters of the pattern. In this case, a long segment parameter such as (VQQC〓V) is used. (QQ) in this long segment parameter
indicates a consonant interval with a duration of 1 mora,
(C〓) indicates a fricative consonant like the phoneme (S). That is, for the continuous phoneme of a word in which a consonant is followed by a fricative consonant, a (VQQC〓V)-type long segment parameter indicating its characteristics is prepared separately from the (VCV)-type long segment parameter. Furthermore, in the case of Japanese, it is well known that verbs ending in ``ru'' occur frequently. Therefore,
Regarding such frequently occurring continuous phonemes,
Prepare long segment parameters (VCVC ⁺ V ⁺ ). The above (C ⁺ ) (V ⁺ ) is the conjugated ending of the verb “ru:
RU”, and (C ⁺ ) corresponds to (R),
Moreover, (V ⁺ ) corresponds to (U), respectively. That is,
Continuous phonemes that appear frequently are conventionally processed as a combination of short segment parameters in the form (VCV + VCV), but this has been prepared in advance as long segment parameters in the form (VCVC ⁺ V ⁺ ) with the above combination. It is something to keep.

The segment selection circuit 6 uses the short segment parameters and long segment parameters registered in this way to convert the phoneme sequence into segment parameters according to the test result by the testing circuit 5. That is, for continuous phonemes that have undergone articulatory combination and continuous phonemes that appear frequently, the long segment parameters are selected, and for the others, the short segment parameters are selected. Then, these selected segment parameters are sequentially combined in the spectrally stable vowel section in the segment combination circuit 9 to obtain a parameter series. This parameter series is guided to a speech synthesizer 10 composed of a group of filters.

On the other hand, the prosodic information regarding the word obtained by the dictionary collation circuit 2 is stored in the prosodic information verification circuit 11.
is input. In this prosodic information verification circuit 11,
For the matched words according to prosodic information,
We test the number of moras and relationships between words, and investigate accents, pause lengths, and phonetic durations.
Based on these various pieces of information, the prosodic parameter generation circuit 12 generates prosodic parameters for speech synthesis. The speech synthesizer 10 performs speech synthesis processing on the segment parameter series according to the prosodic parameters, and outputs synthesized speech.

Thus, according to the speech synthesis device configured using this method, for continuous phonemes affected by articulatory combination, long segment parameters indicating the characteristics are given, and a segment parameter sequence is generated. Therefore, it is possible to easily obtain synthetic speech with naturalness. In other words, as shown in Figure 2, "Start"
For the phoneme of the word , we express the segment parameter indicating the continuous phoneme formed by a consonant followed by a fricative consonant as (VQQC〓V), so that the characteristics of the consonant changed by articulatory combination can be well reflected. Make it. In contrast, the conventional “VCV”
In the type-only method, the consonant sections were not prepared as segments and were processed as silent sections, so the consonant sections did not necessarily have a high degree of naturalness. In this way, according to this method,
Speech synthesis using only (VCV) type fragments has produced effects that could not be expected, and its advantages are enormous.

Note that the present invention is not limited to the above embodiments. For example, the present invention is not limited to continuous phonemes resulting from the combination of consonants and fricative consonants, but can be applied to all continuous phonemes, including phonemes that are strongly influenced by articulatory combinations. Furthermore, for continuous phonemes that include syllables with high frequency of appearance, long segment parameters may be prepared, not only for verbs, and various modifications can be made without departing from the gist.

[Brief explanation of the drawing]

FIG. 1 is a schematic block diagram of a speech synthesis apparatus employing an embodiment of the present invention, and FIG. 2 is a diagram showing the relationship between continuous phonemes and segment parameters. 1... Kanji/kana mixed sentence input circuit, 2... Dictionary collation circuit, 3... Word dictionary storage device, 4... Letter-to-phoneme conversion circuit, 5... Phoneme sequence testing circuit, 6... Fragment selection circuit, 7...Short segment file storage device, 8
. . . long segment file storage device, 9 . . . segment combination circuit, 10 . . . speech synthesizer, 11 . . . prosodic information verification circuit, 12 .

Claims (1)

[Claims] 1. The first segment parameter showing the basic chain of phonemes of the type (VCV) where V is a vowel and C is a consonant, and continuous phoneme (VQQC〓V) where QQ is a consonant interval and C〓 is a fricative consonant. When the input phoneme sequence is tested and the continuous phoneme is detected, the second phoneme parameter is selected for this continuous phoneme, and Selecting the first segment parameters for phonemes other than continuous phonemes, combining these selected segment parameters in a vowel interval, and synthesizing speech according to the combined segment parameters. A speech synthesis method featuring the following.