The present invention relates generally to communications systems and, in particular, to speech quality assessment.
Performance of a wireless communication system can be measured, among other things, in terms of speech quality. In the current art, there are two techniques of speech quality assessment. The first technique is a subjective technique (hereinafter referred to as “subjective speech quality assessment”). In subjective speech quality assessment, human listeners are used to rate the speech quality of processed speech, wherein processed speech is a transmitted speech signal which has been processed at the receiver. This technique is subjective because it is based on the perception of the individual human, and human assessment of speech quality typically takes into account phonetic contents, speaking styles or individual speaker differences. Subjective speech quality assessment can be expensive and time consuming.
The second technique is an objective technique (hereinafter referred to as “objective speech quality assessment”). Objective speech quality assessment is not based on the perception of the individual human. Most objective speech quality assessment techniques are based on known source speech or reconstructed source speech estimated from processed speech. However, these objective techniques do not account for phonetic contents, speaking styles or individual speaker differences.
Accordingly, there exists a need for assessing speech quality objectively which takes into account phonetic contents, speaking styles or individual speaker differences.
The present invention is a method for objective speech quality assessment that accounts for phonetic contents, speaking styles or individual speaker differences by distorting speech signals under speech quality assessment. By using a distorted version of a speech signal, it is possible to compensate for different phonetic contents, different individual speakers and different speaking styles when assessing speech quality. The amount of degradation in the objective speech quality assessment by distorting the speech signal is maintained similarly for different speech signals, especially when the amount of distortion of the distorted version of speech signal is severe. Objective speech quality assessment for the distorted speech signal and the original undistorted speech signal are compared to obtain a speech quality assessment compensated for utterance dependent articulation. In one embodiment, the comparison corresponds to a difference between the objective speech quality assessments for the distorted and undistorted speech signals.
The features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings where:
The present invention is a method for objective speech quality assessment that accounts for phonetic contents, speaking styles or individual speaker differences by distorting processed speech. Objective speech quality assessment tend to yield different values for different speech signals which have same subjective speech quality scores. The reason these values differ is because of different distributions of spectral contents in the modulation spectral domain. By using a distorted version of a processed speech signal, it is possible to compensate for different phonetic contents, different individual speakers and different speaking styles. The amount of degradation in the objective speech quality assessment by distorting the speech signal is maintained similarly for different speech signals, especially when the distortion is severe. Objective speech quality assessment for the distorted speech signal and the original undistorted speech signal are compared to obtain a speech quality assessment compensated for utterance dependent articulation.
In objective speech quality assessment modules 12, 14, speech signal s(t) and MNRU speech signal s'(t) are processed to obtain objective speech quality assessments SQ(s(t) and SQ(s'(t)). Objective speech quality assessment modules 12, 14 are essentially identical in terms of the type of processing performed to any input speech signals. That is, if both objective speech quality assessment modules 12, 14 receive the same input speech signal, the output signals of both modules 12, 14 would be approximately identical. Note that, in other embodiments, objective speech quality assessment modules 12, 14 may process speech signals s(t) and s'(t) in a manner different from each other. Objective speech quality assessment modules are well-known in the art. An example of such a module will be described later herein.
Objective speech quality assessments SQ(s(t) and SQ(s'(t)) are then compared to obtain speech quality assessment SQcompensated, which compensates for utterance dependent articulation. In one embodiment, speech quality assessment SQcompensated is determined using the difference between objective speech quality assessments SQ(s(t) and SQ(s'(t)). For example, SQcompensated is equal to SQ(s(t) minus SQ(s'(t)), or vice-versa. In another embodiment, speech quality assessment SQcompensated is determined based on a ratio between objective speech quality assessments SQ(s(t) and SQ(s'(t)). For example,
where μ is a small constant value.
As mentioned earlier, objective speech quality assessment modules 12, 14 are well known in the art.
The plurality of critical band signals si(t) is provided as input to envelope analysis module 24. In envelope analysis module 24, the plurality of critical band signals si(t) is processed to obtain a plurality of envelopes ai(t), wherein ai(t)=√{square root over (si2(t)+ŝi2(t))}{square root over (si2(t)+ŝi2(t))} and ŝi(t) is the Hilbert transform of si(t).
The plurality of envelopes ai(t) is then provided as input to articulatory analysis module 26. In articulatory analysis module 26, the plurality of envelopes ai(t) is processed to obtain a speech quality assessment for speech signal s(t). Specifically, articulatory analysis module 26 does a comparison of the power associated with signals generated from the human articulatory system (hereinafter referred to as “articulation power PA(m,i)”) with the power associated with signals not generated from the human articulatory system (hereinafter referred to as “non-articulation power PNA(m,i)”). Such comparison is then used to make a speech quality assessment.
In step 320, for each modulation spectrum Ai(m,f), articulatory analysis module 26 performs a comparison between articulation power PA(m,i) and non-articulation power PNA(m,i). In this embodiment of articulatory analysis module 26, the comparison between articulation power PA(m,i) and non-articulation power PNA(m,i) is an articulation-to-non-articulation ratio ANR(m,i). The ANR is defined by the following equation
where ε is some small constant value. Other comparisons between articulation power PA(m,i) and non-articulation power PNA(m,i) are possible. For example, the comparison may be the reciprocal of equation (1), or the comparison may be a difference between articulation power PA(m,i) and non-articulation power PNA(m,i). For ease of discussion, the embodiment of articulatory analysis module 26 depicted by flowchart 300 will be discussed with respect to the comparison using ANR(m,i) of equation (1). This should not, however, be construed to limit the present invention in any manner.
In step 330, ANR(m,i) is used to determine local speech quality LSQ(m) for frame m. Local speech quality LSQ(m) is determined using an aggregate of the articulation-to-non-articulation ratio ANR(m,i) across all channels i and a weighing factor R(m,i) based on the DC-component power PNo(m,i). Specifically, local speech quality LSQ(m) is determined using the following equation
and k is a frequency index.
In step 340, overall speech quality SQ for speech signal s(t) is determined using local speech quality LSQ(m) and a log power Ps(m) for frame m. Specifically, speech quality SQ is determined using the following equation
where
L is Lp-norm, T is the total number of frames in speech signal s(t), λ is any value, and Pth is a threshold for distinguishing between audible signals and silence. In one embodiment, λ is preferably an odd integer value.
The output of articulatory analysis module 26 is an assessment of speech quality SQ over all frames m. That is, speech quality SQ is a speech quality assessment for speech signal s(t).
Although the present invention has been described in considerable detail with reference to certain embodiments, other versions are possible. Therefore, the spirit and scope of the present invention should not be limited to the description of the embodiments contained herein.
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