EP2777292A1 - Method of evaluating at least one defect of quality in a data signal, associated device and computer program - Google Patents

Abstract

Method of evaluating at least one defect of quality in a data signal, associated device and computer program. The invention relates to a method of evaluating at least one defect of quality of a carrier signal bearing data intended to be restored to a recipient, said signal comprising at least one video component and one audio component. Such a method comprises the following steps, implemented on at least one sample of said signal: - detection of at least one defect in the video component of the sample and calculation of a duration associated with said at least one defect; - assigning of a class of defect to said at least one defect detected at least as a function of its associated duration; - according to the class of defect assigned, obtaining of a result of searching for at least one defect in the audio component at the instants corresponding to the sample; - decision to confirm the detection of a defect of quality in the sequence at least as a function of the result of the search for a defect in the audio component.

Description

 A method of evaluating at least one quality defect in a data signal, device and associated computer program.

1. Field of the invention

 The field of the invention is that of quality evaluation of audiovisual data signals comprising at least one video component and one audio component.

 The invention applies in particular to audio-visual data signals that have been degraded during transmission over telecommunication networks or during transcoding operations.

Today, audiovisual content is transmitted via video-on-demand services, catch-up video, and so on. These services have well-defined production and distribution channels with which errors can appear and accumulate on the different links of these two chains.

 Depending on the capture, contribution, encoding, transmission, reception, and audio-visual terminals used, errors may result in artefacts appearing on audio and video components. The appearance of these impairments may occur simultaneously on these two components.

 The defects of the video component often materialize by saccades or frosts of images. The defects on the audio component are manifested by a loss of sound. The duration of these two degradations fluctuates from a few milliseconds to a few hours. The frequency of occurrence of this type of event may also vary over time. The defects may as well have a low occurrence as sustained on a time scale.

 These degradations are a source of discomfort for the end users, which sometimes leads them to reject the service, if the inconvenience becomes too great.

Currently, the deployed equipment ensuring the automatic control of the audio-visual quality make measurements on the audio and video components of signals at the output of the terminal or samples at the decoder level without taking into account the reference signal, since these are rendered inaccessible. technically or legally. They use models classified as "without reference" and produce fluctuating notes on a quality scale. The conclusions of the expertise of the "no reference" prediction devices have shown that the performances must be greatly improved with respect to the human feeling.

 Document WO2006 / 103327 discloses a method for evaluating a quality degradation of an audiovisual signal based on a model for predicting the impact of the discontinuity of the fluidity of the images on the subjective quality. In relation to Figure 1, a schematic diagram of the evaluation method in question is presented. Discontinuity measurements are conducted in parallel on the video and audio components of the signal to be evaluated. Different audio and video metrics are used to qualify different types of defects (for example, image freezes, the presence of blurs or blocks in the images for the video component, sound losses for the audio component). A video decision module takes into account the results of the evaluations performed using the different metrics and assigns an overall quality score to the video component, using a video interaction model. An audio decision module does the same for the audio component and assigns an overall quality score to the audio component based on an audio interaction model. An audio / video weighting module takes into account both the overall video quality score and the overall audio quality score to assign an overall quality score to the audiovisual signal. It is a so-called cognitive approach because the model reproduces the mechanism of human judgment by producing notes on a quality scale.

2. Disadvantages of the prior art

The prior art calculates the degradation of the perceived quality caused by each break in fluidity, and noise cutoff. The calculations are done in a disjointed way on the audio and video components and without interaction a priori or a posteriori of the results obtained. This approach fails in the face of artificially created discontinuities and when they are not considered perceptible by human judgment. In these cases, interpretation errors appear and generate false alarms.

3. Presentation of the invention

The invention improves the situation by means of a method for evaluating at least one quality defect of a signal carrying data intended to be returned to a recipient, said signal comprising at least one video component and a component audio.

 Such a method comprises the following steps, implemented on at least one sample of said signal:

 detecting at least one defect on the video component of the sample and calculating a duration associated with said at least one defect;

 assigning a fault class to at least one detected fault at least according to its associated duration;

 - According to the assigned fault class, obtaining a search result of at least one defect on the audio component at times corresponding to the sample;

- decision to confirm the detection of a quality defect on the sequence at least according to the result of the fault search on the audio component.

With the invention, when a fault is detected on the video component, a fault class is assigned to it. According to the assigned fault class, the method according to the invention obtains or not the results of a search for defects on the audio component, with a view to confirming or invalidating the detected fault on the video component.

Thus, the method according to the invention makes it possible to improve the evaluation of the quality of a degraded video signal by resorting to a fault detection on the audio component, which enables it to remove an indeterminacy on the video degradation detection.

 Rather than taking a decision for the video component and a decision for the audio component in parallel as is the case in the prior art, the method according to the invention therefore enriches the video quality evaluation model directly to the video component. help degrade detection results on the audio component.

 The invention thus proposes an entirely new and inventive approach to the evaluation of the impairments undergone by a signal, which is based on the enrichment of the video model used to evaluate the video component of this signal using the results. of the evaluation of the audio component.

According to one aspect of the invention, the detection step comprises, following the detection of a defect on the video component, a sub-step of rejecting the detected fault if its duration associated is less than a first predetermined perceptual detection threshold.

 Thus, only defects of sufficient duration to be potentially perceptible by the user are retained for the subsequent steps of the method. According to another aspect of the invention, the decision step comprises a sub-step of cumulation of the durations associated with the image defects of the same class detected, a substep of rejection of said defects of the same class, if their cumulative duration is less than a second predetermined perceptual detection threshold. In this way, only the image defects of a particular class that are actually perceived by the user are retained for evaluating the quality of the audiovisual signal.

According to another aspect of the invention, the detection step is intended to detect image-free image defects, in that it comprises a step of calculating a value of similarity between images of the sample. and a step of comparing the calculated similarity value with a predetermined threshold.

Among the defects that can be detected on a video component, there are defects of the image freeze type. According to this embodiment of the invention, the detection of defects on the video component relates to image-free defects. An image freeze is detected when several images of the sequence are sufficiently similar to each other.

In another aspect, the detected image freeze class belongs to a group comprising at least:

a micro-gel;

 - a classic gel;

 - a postproduction effect;

- a macro-gel. At a detected image freeze is assigned a gel class from a set of predetermined gel-like defect classes.

According to another aspect of the invention, the step of obtaining a search result of a defect in the audio component is implemented for an image-free defect of which the class belongs to the group comprising less:

 - micro-gel;

 - classic gel:

 - post-production effect.

For the listed image defect classes, there is an indeterminacy about the result of the detection that justifies the use of the analysis of the audio component.

According to another aspect of the invention, the step of obtaining a result of searching for a defect in the audio component is not implemented for a defect of the image freeze type whose class belongs to the group comprising at least:

 - macro-gel.

For this class of freeze image, the result of the detection on the video component is considered reliable enough so that it is not necessary to resort to the search for damage on the audio component.

According to another aspect of the invention, the detection step is intended to detect block effect type defects, and it comprises a step of calculating a block rate value per image of the sample and a step comparing the calculated value to a predetermined threshold.

Block effects are another type of defects that are likely to be detected on a video component. According to this embodiment of the invention, a blockiness type defect is detected when several images of the sequence have a sufficiently high block rate. The invention also relates to a device for evaluating a quality defect of a signal, able to implement the method just described.

 Such a device can be integrated with an audiovisual signal receiver or with any other equipment node of a telecommunications network, such as an audiovisual contribution or transcoding system. The invention therefore also relates to a receiver of a video signal transmitted in a telecommunications network, said signal comprising at least one video component and one audio component. According to the invention, such a receiver 1 comprises a device for evaluating quality defects according to the invention.

 It also relates to a node equipment of a telecommunications network comprising a quality evaluation device according to the invention.

 The invention also relates to a system for distributing an audiovisual signal to at least one user terminal, said system comprising a plurality of node equipment connected to at least one telecommunications network, a node equipment being able to receive said signal and retransmit it to a neighbor node equipment. According to the invention, at least one of the group comprising the plurality of node equipment and the receiver equipment comprises the quality defect evaluation device that has just been presented.

The invention also relates to a computer program comprising instructions for the implementation of a quality evaluation method of an audiovisual signal as described above, when this program is executed by a processor. Such a program can use any programming language. It can be downloaded from a communication network and / or saved on a computer-readable medium.

 Finally, the invention relates to a storage medium, readable by a processor, storing a computer program implementing the evaluation method of at least one quality defect that has just been described.

4. List of figures

Other advantages and features of the invention will appear more clearly in the reading of the following description of a particular embodiment of the invention, given as a simple illustrative and non-limiting example, and the appended drawings, among which: FIG. 1 illustrates the evaluation scheme of a degradation of quality of an audiovisual signal according to the prior art;

 FIG. 2 schematically shows an example of a distribution system of an audiovisual signal according to the invention;

 FIG. 3 schematically shows the structure of a device for evaluating quality defects of an audiovisual signal according to the invention.

 FIG. 4 schematically shows the method for evaluating a quality defect of an audiovisual signal according to the invention;

 FIG. 5 schematically shows the steps of the method for evaluating quality defects of an audiovisual signal according to one embodiment of the invention, according to which image-gel defects are evaluated;

 FIG. 6 schematically shows a graphical representation of an image of the video component of an audiovisual signal to be evaluated;

 Figure 7 schematically illustrates an example of sound loss in an audio component of an audiovisual stream;

 FIG. 8 schematically shows classes of image-free-image defects taken into account in one embodiment of the invention;

 Figure 9 shows schematically the profile of a micro-gel type defect; and Figure 10 schematically shows a variation curve of a similarity rate measure for an image gel belonging to the postproduction effects class.

5. Description of a particular embodiment of the invention

The general principle of the invention relies on the use of the result of the analysis of the audio signal in case of indeterminacy on the detection of at least one image defect in the audio component. 5.1 Audiovisual signal distribution system In the remainder of the description, an audiovisual signal S comprising at least one video component Cv and at least one audio component Ca is considered. Such a signal S can be intercepted at any stage of an audiovisual transmission chain, between transmitter equipment, telecommunication network node equipment or customer receiving equipment.

 In relation with FIG. 2, a distribution system of an audiovisual signal S according to the invention is considered. Such a system comprises an audiovisual distribution server S Serv. Such a server may be for example a video on demand server or a live audiovisual content broadcasting server. The signal S is transmitted via a telecommunications network 1, which comprises a plurality of equipment nodes EN1, EN2. The nodes equipment EN1, EN2 are able to receive the signal S from a neighboring node and to retransmit it to another node of the network 1. The signal S is finally received by at least one destination equipment, for example the receiving equipment E , which can be a client terminal of the mobile terminal type or TV decoder for example.

 The invention can be implemented in any of these equipment Serv, EN1, EN2, ER which form the distribution chain of the audiovisual signal S.

5.2 Example structure of a quality defect evaluation device

With reference to FIG. 3, the simplified structure of a quality evaluation device 100 for an audiovisual signal embodying the invention is presented.

 For example, the device comprises a memory 110 comprising a buffer memory M, a processing unit 120, equipped for example with a processor P, and driven by a computer program Pg 130, implementing the evaluation method of quality according to the invention.

At initialization, the code instructions of the computer program 130 are for example loaded into a RAM memory before being executed by the processor of the processing unit 120. The processing unit 120 receives as input at least a sample of an audiovisual signal to be evaluated. The processor of the processing unit 120 implements the steps of the quality evaluation method described above, according to the instructions of the For this purpose, the device comprises, in addition to the memory 110, means for obtaining a detection of at least one quality defect on the video component of the sample, means for allocating a defect class audit at least one detected defect at least according to its associated duration, means for obtaining a search result of at least one defect on the audio component at the instants corresponding to the sample according to the assigned fault class and decision means to confirm the detection of a quality defect on the sequence at least according to the result of the fault search on the audio component. These means are controlled by the processor of the processing unit 120.

 Advantageously, such a device 100 may be integrated with at least one of the equipment Serv, EN1, EN2 and E of the distribution system of an audiovisual signal according to the invention.

5.3 Method for evaluating a quality defect according to the invention

 In relation with FIG. 4, the steps of the evaluation method of a quality defect undergone by the audiovisual signal S according to the invention are presented. Such a method is advantageously implemented by the device 100 which has just been described.

We consider a signal S cut into I samples e ,, with I nonzero integer, each of a duration T _{éCh paramétrable} , whose value is generally 5 to 10 ms.

The method according to the invention applies to such a sample e, of the signal.

 A sample ei of the video component Cv includes Nbl images, with non-zero integer Nbl.

During a step E _{1 (} at least one image defect Dv _j is detected on a sample e, of the video component Cv of the signal S. In the following, we consider J defects Dvl to DvJ detected in the sample ei, with a nonzero integer J Obviously, if no fault is detected, it is not necessary to implement the method according to the invention.

 Advantageously, the aforementioned detection is obtained by analysis of the video component on the sample e ,. An example of an analysis method will be detailed later.

During this step E _{1 (} a duration d _j of the fault Dvj is calculated, for each defect Dvj detected, and is associated with it.

The detected fault Dvj is then identified during a step E ₂ , at least according to the _j calculated duration. It is to assign an image defect class among several predetermined fault classes Cil to CIK, with K nonzero integer.

According to the image defect class identified, a step E ₃ of obtaining an analysis result of the audio component Ca on a sample eai corresponding to the sample evi, is triggered or not. It will be understood that for certain classes of image defect, the analysis of the video component alone is not in itself considered sufficient to allow reliable identification of the detected defect.

 The analysis of the audio component, which has been, for example, carried out in parallel with that of the video component, can lead to the detection of possible audio defects Dal to DaL, with L nonzero integer, on the component S signal audio. An example of an audio component analysis method will be presented later.

We now consider the result of audio analysis Da, obtained. Whether it is positive (at least one defect Dal of the detected audio gel type) or negative (no image-free defect detected on the audio sample ea,), it is taken into account, during a step E4 of decision. During this decision step, we consider at least the image defects Dvj belonging to Clk classes, k integer between 1 and K, for which the use of the result of the analysis of the audio component is considered necessary. These defects are subject to a substep E _{4 1} of confirmation, intended to confirm or deny the defect Dvj as a defect to take into account for the quality of the signal perceived by the user. According to the class Clk considered, it is either to verify that an audio defect was detected at the same instants as the current fault Dvj, or on the contrary to verify that there is no audio defect corresponding to the defect Dvj to to confirm. Depending on the result of this verification, the defect in question is therefore retained or rejected.

According to one embodiment of the invention, the decision step E ₄ comprises a sub-step E ₄ , ₂ of cumulation of the durations associated with image defects of the same class and of comparisons of the cumulative duration obtained at a given time. threshold. Only the defects of sufficient cumulative duration are retained and participate in the evaluation of the quality of the signal perceived by the user. 5.4 Evaluation of image freeze defects In relation with FIG. 5, the implementation of the method according to the invention for the detection of image-free defects is now considered as an illustrative and nonlimiting example. The video component Cv of an audiovisual signal S is cut into samples evi, i integer ranging from 0 to I, each of duration for example between 5 and 10 ms. The method according to the invention is implemented for at least one evi sample. Advantageously, it is iterated for each sample of the video component Cv.

 In a step ΕΊ, image freeze defects are detected on an evi sample.

 A method for detecting image-free image defects in an evi sample of a video component Cv of an audiovisual signal S will now be presented.

5.4.1 Video detection

We consider a sample ev, of a video component Cv of an audiovisual signal S, represented in any color space. In the following, we will limit ourselves to a colorimetric representation in luminance and chrominance containing Nbl images, with Nbl strictly positive integer, and whose image size is Vheight * Vwidth. Vheight and Vwidth are strictly positive integers. In relation to FIG. 6, we denote Pk (i, j), the pixel of the k ' ^th image on line i and on column j, and we write Pprec (i, j) the pixel of a previous image. of the ^fourth picture of the video in analysis.

ke [1, Nbl-1], ie [0, Vheight] and I [0, Vwidth].

An image-free defect is characterized by a break in fluidity between the image k and the neighboring image P _prec of the video sequence.

 A break in fluidity is evaluated by calculating the luminance and chrominance derivative as follows:

 We denote Yk (i, j), Uk (i, j), Vk (i, j) and Yprec (i, j), Uprec (i, j) and Vprec (i, j) respectively the components Y, U and V of Pk (i, j) and Pprec (i, j).

Y represents the luminance of the pixel, U the component unlike the blue and V the component unlike the red pixel. Let AP {k, ref) (i, j) be the function such that refe [0, Nbl-2], Vke [1, Nbl-1], V ie [0, Vheight] and V je [0, Vwidth] if :

(I Yk (U) - Ypred (i, j) I><^ Max) II (I _Uk (U) - U _prec (', j) I≥ to JMax) II (I _Vk (i, j) - V _{pre c} (i, j) I><¾ / Max)

is then true AP (k, vprec (i, j) = 1 (pixel (i, j) different), otherwise AP (k, prec) (i, j) = 0 (pixel (i, j) identical).

ÔYMax, ÔUMax and ôVMax are integer and positive parameters allowing to adjust the level of similarity between Pk (i, j) and Pprec (i, j). · ÔYMax e [0, 220]

 • ôUMax e [0, 220]

 • OVMax e [0, 220]

We consider that there is video freeze at the k ' ^th image between the images of indices ref and k, prece [0, Nbl-2] and ke [1, Nbl-1] if and only if Vie [0, Vheight] and Vje [0, Vwidth], the following equation is satisfied:

Vheight Vwidht

Σ Σ Δ P 0 ^' , j) ≤ Δ _Max P

 i = 0 = 0

 APMax is a positive integer that represents the number of max differences accepted to consider that two consecutive images of a video are identical.

 There is thus freezing on a sequence of X consecutive images of a video if and only if: refe [0, Nbl-X-1] and Vke [prec + 1, ref + X-2]

Vheight Vwidht

Σ Σ Δ P _(k , _prec) (i, j) ≤ AP _Max (1)

 i = 0 = 0

A similarity rate is now defined between the index image k and the precursor index image. It is denoted x (k, ref) and is obtained as follows: VheightVwidht

Σ Σ & P ( _{kt prec} ) (i, j)

 i = 0; = 0

 Vheight x Vwidth

Calculation of duration; following the detection of an image gel Dvj, a calculation of the duration dj (in ms) of this gel is carried out.

The duration of an image freeze is calculated as follows. For a sequence of x consecutive images of the sample ev, of the video component, consider the preceding image precf such that prece [0, Nbl-x -1], images k, such that ke [prec +1, prec + x], X the number of images of the gel sequence and FPS the display frequency of the video. The duration of the image freeze corresponds to: t ^gel FPS

The results of this detection are obtained during a step ΕΊ. 5.4.2 Perceptual thresholding

Advantageously, during a step E ' _{1 2} , the duration of the detected image gel can be compared to a first perceptual threshold τ _ρ1 , typically of the order of 40 ms, and rejected according to the following decision criterion. :

If the duration of freezing t _ge | is greater than 40 ms then the gel is considered potentially perceptible. If this condition is not satisfied, the rupture of fluidity is not taken into account.

An example of a method for detecting a defect of the audio gel type will now be described in more detail.

5.4.3 Classification of frost-like defects

During a step E ' ₂ , a defect class of gel type is assigned to each defect detected, at least according to its duration, among a group of classes comprising the following defects:

- Micro gel, Post-production effect;

 Classical gel;

 Macro gel.

 In relation to FIG. 7, it is considered, by way of illustration, classes of image gels that can be detected in a sample of an audio component. They are positioned on the time axis according to their typical duration. In order of increasing duration, there is the micro gel, the postproduction effect, the conventional image freeze and the macro gel.

In the context of the invention, they are defined as follows: The micro gel:

 In relation to FIG. 9, consider a micro gel of duration tgel, horn being pseudo periodic of period Τμ.

There is micro gel freeze time if and only if: a. There is no audio mute on the audio component (s) associated with the video component (it is detected using the audio signal) for the duration

 b. tgel ^ [imin 'Îmax] ^ tgel- & Τμ σ is a real in the interval [0, 1], it represents the cyclic ratio of the pseudo period of a gel below which the gel is considered as micro gel.

 Τμ is the pseudo period of the micro-gel or the time between two starts of freezing. tgel represents the duration of the video freeze as defined previously,

 ΐιτιϊημ represents the minimum duration of the micro gel (~ 76ms),

 represents the maximum duration of the micro gel (~ 350ms),

With the invention, when a micro gel is identified at E ' ₂ using the above definition, an analysis of the audio component is triggered, to verify that there is no associated audio loss.

Post production effect A video freeze of time t _fre e _Z e is considered as a post-production effect of the "interpub" type and therefore as not inconvenient by the observer, if and only if: c. A sound loss is associated with freezing of image and the duration of the sound loss satisfies the following relation: T ≥ X * † _r

 ί mute freeze

T Mute is the duration of the mute detected, a is a percentage generally greater than or equal to 80% (it allows to take into account the audio / video shift), _tjrgeze G [T _MinF ^ T _MaxFF l ^J ^ ~ 200ms and T _MaxFF ~ ls;

d. xrnoy <x _M axi, the average rate of similarity between the different frozen images does not exceed the threshold T _{MaX | P.}

In connection with FIG. 10, there is shown an example of an image freeze having video similarity rates considered representative of a post-production effect.

 xrnoy is the arithmetic mean of the similarity rates of the analyzed gel images.

It is understood that for the class "post-production effect" to be assigned to an image freeze, several conditions must be met:

 Conditions on the freeze-like defect itself (similarity rate below a threshold)

 - The conjunction of a sound loss type audio defect and a condition relating to the duration of the sound loss with respect to the duration of the image freeze.

The freeze of classic image ("freeze", in English)

It is considered that there is actually freeze of a duration tpp if and only if: a. This gel is not a "post-production effect";

b. The audio analysis led to the detection of an associated sound loss whose duration verifies the relation T ≥ X * f,. Where C _e T _M is the length of mute detected, a is a

 mute the freeze

percentage generally greater than or equal to 80% (it allows to take into account the audio / video shift); vs. The duration of the freeze tp [tminF, tminM F], where tminF represents the minimum duration of a freeze and tminMF represents the maximum duration of a gel-like defect. Macro Gel

An image freeze will be directly considered perceptible by itself if the freezing time exceeds the duration t _{min M} F- In this case, we are dealing with a macro freeze and only the video component is considered to make a decision . We do not use an analysis of the audio component.

As a result, in step E ' ₂ , the identification of an image-free defect class among the predetermined plurality of classes is made at least from the calculated duration and possibly from functions. other measures.

 For example, for the micro-gel, it relies on the measurement of a pseudo period of the detected gel and the fact that the calculated duration of the gel is much lower than this pseudo period (duty cycle low).

 With regard to a defect of the post-production effect type, it relies on a similarity rate measurement which must remain below a predetermined threshold (the images are not always exactly identical to each other).

 The conventional gel is identified by its duration which must be greater than a predetermined threshold.

 The macro gel is also identified using its duration which must be greater than a predetermined threshold.

5.4.4 Audio detection

During a step E ' ₃ , an audio error detection result is obtained. According to this embodiment, a loss-of-sound type audio defect is detected when the audio signal is attenuated with an energy level of the audio signal below a certain energy threshold over a given period of time. Each detected fault is therefore associated with a level of energy and a duration.

In connection with FIG. 8, an exemplary energy profile of an audio signal presenting an audio gel or sound loss ("mute") is considered. In this example, we consider a sound loss detection method based on a two-step approach. The first step is to measure an energy loss of the audio signal over time. The second step is to verify that for times when a power loss has been measured, the energy of the audio signal does not exceed a certain energy threshold.

 Consequently, it is considered that a sound loss is manifest when the energy loss is sufficient to maintain the energy of the audio signal below a certain energy threshold over a given period of time.

 The measurement is used on all the audio channels of a chain to be analyzed.

The first step is to find out if there is a falling edge.

The falling edge at time n is taken into account if and only if E "≤ and E _n -i> δ '· with In energy of the audio signal at time n, δ a threshold of energy max and δ' a threshold of energy min.

 The duration of the sound loss is then calculated as follows:

It is considered that the signal has a sound loss for a duration t _PS if and only if this state begins with a falling edge of mute and that the energy level remains lower than δ during the duration of the Mute state. s = N _Ech x- - (4)

 ^ Ech

N _Ech is the number of samples meeting the above conditions.

F _Ech is the sampling frequency of the audio signal.

The results of this audio detection will be taken into consideration during a decision step E ' ₄ , depending on the class of the fault considered.

5.4.5 Decision Module

The decision step E ' ₄ will now be described in more detail for this particular embodiment. At the end of the steps of detecting at least one image gel on a sample ei and analyzing the audio component, this step E ' ₄ ensures the production of the results on a Nbl analysis time window corresponding to the sample ei. It is first for each defect Dvj identified confirm or deny the class that has been assigned.

According to the class of the defect examined, such confirmation sub-step E ' ₁ uses the results of the detection of audio defects:

 For a micro-gel, the absence of sound loss on the sample makes it possible to confirm that the defect Dvj is a micro-gel;

 For a defect Dvj identified as a production effect, the class will be confirmed if a sound loss has been identified and if it has a duration that satisfies the condition previously exposed (slightly lower);

 For a defect of the classic gel type, the class is confirmed if a sound loss has been identified and if it has a duration that satisfies the condition previously exposed (slightly lower);

 For a macro-free fault, the class has been confirmed since step E'2 and the result of the audio analysis is not used.

Then, during another substep E'4,2, the decision module then determines for each sample ei of an audiovisual stream if the defects confirmed by E'4,1 are annoying or not for the user. For each confirmed image defect, we first consider its class. If it is a post-production effect, it is rejected because it is considered as non-annoying for the user.

 Otherwise, for the other classes:

We consider the group of M _C ik faults belonging to the same class Clk and perform a cumulation T _cumU | the durations of the defects of this group, which we compare with a second perceptual threshold τ _ρ2 .

cumulative / m 2

 m = 0

Where M _C i _k is the number of confirmed defects for class Cl _k .

It is considered that below this threshold, whose value is of the order of 500ms, defects of this class of defects are not a nuisance for the user. All the defects of the same class Clk can therefore be rejected if their cumulative duration is not sufficient according to this perceptual criterion.

 The decision module according to the invention therefore provides at the output a reduced number of image defects compared to the number of candidates from step E'1, corresponding to those who have passed the tests of substeps E'41 and E'42.

5.5 Evaluation of block effect type faults

 The field of application of the invention is not limited to the evaluation of image-like image defects, but concerns any other type of image defect introduced by the transmission of an audiovisual stream on a In fact, an alteration of the multiplexed stream has an impact on the audio and video components at the same time instants.

According to another embodiment of the invention, image defects of the block effect type are considered. In a manner similar to the detection of image gels, the detection of block effects ("blockiness effects") can be associated with the results of an evaluation of sound losses on the audio component associated with the video component.

 Indeed, in the same way as for freeze-like defects, the block-type effects may have different characteristics: in particular, the block effect times may vary between 20 ms to a few seconds. On the other hand, a block effect can be limited to a small area of the image or conversely relate to the entire image.

 In the case where the block effects are obvious, the detection does not pose any particular difficulty and does not require the use of the method according to the invention.

On the other hand, when the spatial zones concerned by the detected block effect are small and / or when the duration associated with this block effect is too small, the use of detection of sound losses on the sample concerned can make it possible to confirm or to negate the presence of troublesome block effects in the sample.

It is understood that in a manner similar to that presented for the gel-like image defects, it is possible to establish predetermined classes of block effects, which differ at least in their duration and / or spatial extent. Thus, the method according to the invention can be applied to defects of the block effect type. According to one variant, a previous detection of gel-type defects over a common analysis period can be validly exploited by the method according to the invention to confirm or invalidate the presence of troublesome block-effect type defects in an audiovisual stream.

The invention that has just been presented can be applied to any audiovisual signal at any stage of its distribution chain. It makes it possible to more effectively evaluate the quality defects caused by its transmission or transcoding step, according to perceptual criteria.

Claims

A method for evaluating at least one quality defect of a data carrier signal for delivery to a recipient, said signal comprising at least a video component and an audio component, said method being characterized in that it comprises the following steps, implemented on at least one sample of said signal:

detecting at least one defect on the video component of the sample and calculating a duration associated with said at least one defect;

 assigning a fault class to at least one detected fault at least according to its associated duration;

 according to the assigned fault class, obtaining a search result of at least one fault on the audio component at the moments corresponding to the sample;

 - decision to confirm the detection of a quality defect on the sequence at least according to the result of the fault search on the audio component.

2. A method for evaluating at least one quality defect according to claim 1, characterized in that the detection step comprises, following the detection of a defect on the video component, a sub-step of rejection of the detected fault if its associated duration is less than a first predetermined perceptual detection threshold.

3. Method for evaluating at least one quality defect according to claim 1, characterized in that the decision step comprises a substep of cumulation of the durations associated with the detected image defects of the same class, a sub-step step of rejecting said defects of the same class, if their cumulative duration is less than a second predetermined perceptual detection threshold.

4. Method for evaluating at least one quality defect according to claim 1, characterized in that the detection step is intended to detect image-free image defects, in that it comprises a step of calculating a similarity value between images of the sample and a step of comparing the calculated similarity value with a predetermined threshold.

A method for evaluating at least one quality defect according to claim 4, characterized in that the detected image gel class belongs to a group comprising at least:

 a micro-gel;

 - a classic gel;

 - a postproduction effect;

 - a macro-gel.

6. A method for evaluating at least one quality defect according to claim 5, characterized in that the step of obtaining a search result of a defect in the audio component is implemented for a defect. an image freeze type whose class belongs to the group comprising at least:

 - micro-gel;

 - classic gel:

 - post-production effect.

7. A method of detecting a quality degradation according to claim 5, characterized in that the step of obtaining a search result of a defect in the audio component is not implemented for a defect. an image freeze type whose class belongs to the group comprising at least:

 - macro-gel.

8. Process for evaluating at least one quality defect according to claim 1, characterized in that the detection step is intended to detect block-type defects, in that it comprises a step of calculating a block rate value between images of the sample and a step of comparing the calculated value with a predetermined threshold.

9. Device for evaluating at least one quality defect of a signal carrying data intended to be returned to a recipient, said signal comprising at least one video component and one audio component, said device being characterized in that it comprises the following means, implemented on at least one sample of a sequence of images of said signal:

 detecting at least one defect on the video component of the image sequence and calculating a duration associated with said at least one defect;

 assigning a fault class to audit at least one detected fault based on its associated duration;

 - According to the assigned fault class, obtaining a search result of at least one defect on the audio component at times corresponding to the sample;

 - Decision to confirm the detection of said at least one image defect on the sample at least according to the result of the search for a fault on the audio component obtained.

Receiver of a video signal transmitted in a telecommunications network, said signal comprising at least one video component and an audio component, characterized in that it comprises a quality defect evaluation device according to claim 9.

 11. System for distributing an audiovisual signal to at least one user terminal, said system comprising a plurality of node devices connected to at least one telecommunications network, a node equipment being able to receive said signal and to retransmit it to a neighboring node equipment, said system being characterized in that at least one of the group comprising the plurality of node equipment and the receiving equipment comprises the quality defect evaluation device according to claim 9.

12. Computer program characterized in that it comprises instructions for the implementation of a method for assessing quality defects of an audiovisual signal according to one of claims 1 to 8, when this program is executed by a processor.

13. A processor-readable recording medium on which is recorded a program comprising instructions for performing the method of evaluating a quality defect according to one of claims 1 to 8.