FR3071611A1 - METHOD AND DEVICE FOR NON-DESTRUCTIVE CONTROL OF AN AERONAUTICAL WORKPIECE - Google Patents

Abstract

Method and device for non-destructive inspection of an aeronautical part The method comprises: obtaining several images of the part at several moments of acquisition via an active infrared thermography system, each pixel of an image having an amplitude representing a characteristic of the part at a moment of acquisition at a point of the part; The estimation, from the images, of a derivative of a first function of this characteristic with respect to a second function of time; and - checking the part from the estimated derivative; the estimation comprising, for each estimated derivative: the selection (F10) of several instants of estimation of this derivative; The application (F20) of the first function to the amplitudes of the pixels; The application (F30) of the second function to the acquisition instants and to the estimation instants of the derivative, these being selected so as to have uniformly spaced converted evaluation instants; and estimating (F60) for each instant of converted estimate of the derivative from the converted amplitudes corresponding to the converted acquisition instants belonging to a determined estimation interval (F50) around the converted estimation instant .

Description

The invention relates to the general field of aeronautics.

It relates more particularly to non-destructive testing by active infrared thermography of aeronautical parts, such as parts with complex geometry fitted to aircraft engines such as for example fixed internal structures (or IFS for Inner Fixed Structures) or other composite sandwich structures. thrust reversers. No limitation is attached however to the type of aeronautical part considered nor to the material in which this part is made up, it can be either a composite material or not.

In known manner, a non-destructive test designates a set of methods which make it possible to characterize the state of integrity and / or the quality of structures or materials without degrading them. Non-destructive testing has a preferred but non-limiting application in the field of aeronautics, and more generally in any field in which the structures whose condition or quality is to be characterized are costly and / or their reliability of operation is critical. Non-destructive testing can advantageously be carried out on the structure or material considered both during production and during use or maintenance.

Active thermography, or active infrared thermography, is one of the known techniques used to carry out non-destructive checks in the field of aeronautics. It is based in the first place on a controlled excitation of the part considered. This excitation leads to a change in the thermal state of the room (for example to an instantaneous increase in the surface temperature of the room by several degrees in the case where the excitation source is a flash lamp). Then in a second step, we observe by means of an infrared camera, the evolution of the temperature on the surface of the part (for example the progressive decrease of the temperature on the surface of the part in the case of an excitation by flash lamp). The infrared camera provides a time sequence of digital thermal images representing the temperature at different times at different points on the surface of the room. For example, each digital image is a grayscale coded image on which each pixel associated with a point in the room has a gray level representative of an increasing function of the temperature at this point at the time of acquisition. of the digital image. The observation of the time sequence of digital thermal images provided by the infrared camera makes it possible to detect the presence of anomalies in the evolution of the temperature on the surface of the part which would be caused by defects inherent in the part (ex voids, inclusions, etc.) which would disturb the diffusion of heat from the surface to the interior of the room.

The document WO 2001/041421 describes a method called TSR (Thermography Signal Reconstruction) method, making it possible to use the information contained in the thermal images provided by the infrared camera to detect faults affecting a piece of material. This method is based on the observation that the thermal response at any point of a piece of material decreases as a function of time following its excitation until a state of equilibrium corresponding substantially to the thermal state of the piece before its excitation, and that, for a pulse excitation (flash), this decrease is such that the natural logarithm of the temperature perturbation (difference between the current surface temperature and the equilibrium temperature) varies linearly as a function of the natural logarithm of the time elapsed after the pulse excitation in the case of a homogeneous material of semi-infinite thickness. Based on this observation, the state of the art proposes a method making it possible to estimate the derivatives of order 1 and / or of order 2 of the natural logarithm of the temperature, and to use the derivatives thus estimated to determine the presence or not a defect in the piece of material considered.

To estimate the aforementioned derivatives, the state of the art first of all converts, by means of a natural logarithm function, the amplitude deviations of the pixels (relative to the equilibrium amplitude evaluated from the images digital images provided by the infrared camera as well as the instants at which these digital images were acquired, the origin of time being attributed to the instant of excitation. Then, for each pixel, it determines by a least squares regression performed on the set of digital images provided by the infrared camera, a polynomial of order n approximating the evolution of the logarithm of the amplitude difference of this pixel as a function of the logarithm of time. The polynomial thus determined is then derived to estimate the order 1 and / or order 2 derivatives sought.

Unfortunately, the method proposed in the state of the art is ill-suited in practice to non-destructive testing of large, often heterogeneous parts and / or with complex geometry as they commonly exist in aeronautics, such as for example the IFS structures mentioned. previously.

Complete non-destructive testing of a large room (several square meters typically for an IFS structure for example) indeed requires carrying out several “unitary” acquisitions of time sequences of thermal images to cover the entire surface of this, each unit acquisition relating to a so-called unit acquisition zone different from the part. The juxtaposition of unit acquisitions thus makes it possible to obtain a representation of the part as a whole, by taking into account a possible overlap zone between each unit acquisition. FIG. 1 illustrates by way of example an aeronautical part such as an IFS structure broken down into a plurality of rectangular unit acquisition zones, each being intended to be the subject of a unit acquisition.

Aeronautical parts can also be heterogeneous, in the sense that the thermal properties of the material of which they are composed can vary spatially, in particular with the presence of defects, and can have complex geometries, that is to say that:

- The thickness of the part can vary depending on the position considered on the surface of the part. In particular, the maximum thickness of a unit acquisition zone can vary from one unit acquisition zone to another; and / or - the surface of the part is not necessarily flat.

Several parameters for acquiring thermal images of such parts can thus vary, in particular from one unit acquisition zone to another when several unit acquisitions are necessary to cover a large part as a whole. These acquisition parameters that may vary include:

- the amplitude of the excitation (ie energy deposited) at the surface of the part, for example due to the non-uniformity of the excitation source, the non-uniformity of the surface appearance of the part, its complex geometry, or the variable distance between the excitation source and the zone of the part considered;

- the acquisition time of each time sequence of thermal images of the part and the sampling (temporal, and even spatial) applied (in particular the sampling step), which may vary depending on the thickness of the area considered during the acquisition.

Non-destructive testing of a large, heterogeneous and / or complex geometry part must therefore be based, to be relevant, on characteristics which are "reasonably" invariant with respect to the conditions of acquisition of thermal images on the room as a whole.

However, in the state of the art, the order 1 and order 2 derivatives used for non-destructive testing are estimated from a polynomial approximation determined over the entire temporal sequence of acquired thermal images. The polynomial model used is therefore shared by all the time samples acquired for a pixel. This results in an estimation bias which depends, by construction, on the conditions of acquisition of the sequence of images used and in particular on the duration of acquisition of the sequence of images. Thus, if the acquisition conditions are modified between two adjacent unit acquisition zones, which may prove necessary when these zones have different thicknesses, the state of the art can lead to distinct polynomials and incidentally to derivatives estimated to be distinct for the same material structure seen via two separate unit acquisitions.

This can lead to results that are difficult to interpret in terms of non-destructive testing (i.e. interpretation of the derivatives obtained). This difficulty in interpretation is all the more damaging when considering automating the interpretation of the derivatives obtained during the non-destructive testing of the part.

Subject and summary of the invention

The main object of the present invention is to overcome the aforementioned drawbacks and to propose a method which can be applied to any type of part, in particular aeronautical, including large aeronautical parts, heterogeneous and / or of complex geometry.

To this end, it offers a non-destructive testing process for an aeronautical part comprising:

A step of obtaining a plurality of digital images of the aeronautical part acquired at a plurality of acquisition instants defined over a determined period of time called the acquisition period by means of an active infrared thermography system , each pixel of a digital image acquired at an acquisition instant having an amplitude representing a characteristic of the aeronautical part at this acquisition instant at a point of the aeronautical part;

A step of estimating, from the digital images acquired, at least one derivative of a first function of said characteristic with respect to a second function of time; and a step of verifying the aeronautical part using said at least one estimated derivative.

This method is remarkable in that the estimation step comprises, for each estimated derivative:

A step of selecting a plurality of instants for estimating this derivative over said acquisition period;

A step of applying the first function to the amplitudes of the pixels of the digital images, said step of applying resulting in amplitudes of the converted pixels;

A step of applying the second function to the instants of acquisition of the digital images resulting in instants of converted acquisition and to the instants of estimation of the derivative resulting in instants of converted estimation, said instants of estimation being selected during the selection step so that the converted estimation times are uniformly spaced; and a step of estimating, for each instant of estimation converted, of said derivative from the amplitudes converted corresponding to the instants of acquisition converted belonging to an estimation interval determined around the instant of estimation converted.

Correlatively, the invention also proposes a non-destructive control system for an aeronautical part comprising:

- an active thermography system comprising an excitation device and an acquisition device configured to acquire at a plurality of acquisition instants defined over a determined period of time called the acquisition period, digital images of the aeronautical part , each pixel of a digital image acquired at an acquisition instant having an amplitude representing a characteristic of the aeronautical part at this acquisition instant at a point of the aeronautical part after excitation of the aeronautical part by the excitation device ;

- an estimation device, configured to estimate from the digital images acquired, at least one derivative of a first function of said characteristic with respect to a second function of time; and - a verification device configured to verify the aeronautical part using said at least one estimated derivative.

This system is remarkable in that the estimation device comprises a plurality of modules activated for each estimated derivative and comprising:

- a selection module, configured to select a plurality of instants for estimating this derivative over said acquisition period;

- a first application module, configured to apply the first function to the amplitudes of the pixels of the digital images, said first application module providing amplitudes of converted pixels;

A second application module, configured to apply the second function to the instants of acquisition of the digital images providing instants of converted acquisition and to apply the second function to the instants of estimation of the derivative providing instants of converted estimation , said estimation instants having been selected by the selection module so that the converted estimation instants are uniformly spaced; and - an estimation module, configured to estimate for each converted estimation instant, said derivative from the converted amplitudes corresponding to the converted acquisition instants belonging to an estimation interval determined around the converted estimation instant .

For a digital image coded in gray levels, each pixel is associated with a gray level whose amplitude represents the spectral luminance seen by the sensor of the acquisition device of the active thermography system and which is, in a manner known per se , an increasing function of the temperature of the aeronautical part at the point corresponding to the pixel considered of the aeronautical part.

Thus, the invention proposes a non-destructive control based on an estimate of time derivative (s) of the converted amplitudes of the signal acquired by robust active infrared thermography under the conditions of acquisition of thermal images of the aeronautical part. This robustness is ensured by a local estimate of the derivatives (as opposed to a global estimate of these over the whole of the acquired signal as in the state of the art), for different instants of estimation chosen judiciously beforehand and on estimation intervals determined around each estimation instant to locally estimate the derivatives. Each estimation interval associated with an estimation instant at which it is desired to estimate the derivative contains samples measured temporally close to this estimation instant. This estimation interval can vary from one estimation instant to another.

If we consider that the acquisition period is delimited by an initial instant and a final instant, we preferentially choose for each estimation interval determined around a converted estimation instant a size less than the difference between the converted final instant resulting from the application of the second function at the final instant and the converted initial instant resulting from the application of the second function at the initial instant. In other words, each estimation interval determined in accordance with the invention advantageously defines a limited neighborhood of samples around the estimation instant considered for locally calculating the derivatives.

Note that in accordance with the invention, the estimation instants are chosen so that the converted estimation instants are uniformly spaced. This makes it possible to adapt to the time base in which the derivatives are represented (in particular for the visual exploitation of these derivatives which can be implemented for example during the verification step). In addition, the instants of estimation can be chosen independently of the instants of acquisition (and therefore different from the instants of acquisition), and it is advantageously possible to choose a number of instants of estimation of the derivative lower (or even much lower) than the number of acquisition times defined over the acquisition period.

Indeed, to characterize the material structures considered, it is necessary to choose a sufficiently dense acquisition sampling (i.e. sufficiently close acquisition instants). This sampling is generally constant in the time domain and the transition to a converted time domain (ie via the application of the second function at the acquisition times) can generate, depending on the nature of the second function applied, oversampling in this space. of representation.

By considering a temporal sampling of estimation of derivatives less dense than the temporal sampling of acquisition and by distributing the instants of estimation as proposed in the invention, it is possible to control the redundancy of information produced, and thus the calculation time required and the amount of information to be stored.

In a case of application of the invention in which the verification step comprises the detection of indications of faults or heterogeneities in the structure of material considered, a plurality of images each representing a map on the aeronautical part d a derivative estimated at a given instant can be presented to an operator to detect whether or not the part includes one or more faults. If as mentioned previously the application of the second function induces an oversampling, it suffices to select a number of instants for estimating the relatively parsimonious derivative on the time support of interest contained in the acquisition period, this which amounts to showing the operator only a relatively small number of images to enable him to carry out a verification of the part. Typically, in the example of a second applied function of logarithm type of a difference (or a deviation), a sequence of more than a thousand images can be reduced to a hundred images while allowing a quality of equivalent analysis. It therefore suffices to estimate the derivative over a small number of estimation instants, which considerably reduces the computation times, the storage space of the calculated derivatives and the analysis time of these derivatives.

The implementation complexity of the invention linked to the local estimation of derivatives is thus limited while ensuring that there is a good representation of the estimated derivatives (it is possible to overcome this by making too many important of derivative estimates while keeping enough relevant information to effectively check the aeronautical part).

The local estimation of the derivatives proposed by the invention makes it possible to dispense with the existence of an estimation bias dependent on the conditions of acquisition of the sequence of thermal images. An estimation bias may remain with such a local estimate, but this is invariant to the acquisition conditions. In particular, if the same material structure is observed in different areas of a large part seen by different unit acquisitions and the unit acquisition conditions differ (for example in terms of acquisition time), then the derivatives estimated by the process described are identical with an estimation variance. The method according to the invention therefore provides information (derivative values) easily interpretable on the part in its entirety, facilitating the analysis of the part on the basis of this information by a human operator or automatically. In fact, thanks to the invention, derivatives are obtained which locally characterize the material structure of the aeronautical part in question and no longer the assembly made up of the material structure and the acquisition conditions.

The method proposed by the invention ensures better stability of the estimated derivatives. In addition, with identical detection performance, it allows a reduction in the acquisition time of the temporal samples necessary for the estimation of the derivatives compared to the state of the art (gain of around 30% observed by the inventors).

It should be noted that although the invention has a preferred application for aeronautical parts of large size, heterogeneous and / or of complex geometry, it nevertheless applies to any aeronautical part, including parts which require only a single acquisition. thermal images. The invention can also be applied advantageously to other industrial fields than the aeronautical field.

No limitation is attached to the order of the estimated derivatives. Thus, for example, said at least one derivative may comprise a derivative of order 1 and / or a derivative of order 2 of the first function of the characteristic. The method according to the invention however makes it possible to estimate derivatives of higher orders, such as for example of order 3.

Furthermore, in accordance with the invention, it is estimated from the digital images supplied by the active thermography system a derivative of a first function of the characteristic represented on the digital images with respect to a second function of time. The first and second functions can be diverse. They can be chosen according to different parameters, such as in particular the nature of the excitation used by the active thermography system, and / or the type of material making up the aeronautical part.

For example, in a particular embodiment in which:

- the characteristic reflected by the digital images is an increasing function of the surface temperature of the aeronautical part; and the active infrared thermography system uses a pulse excitation mode by reflection of the aeronautical part; and - the first function and the second function are logarithmic functions (eg natural logarithm) of a difference between a value and a determined reference value.

Indeed, in such a context, it is known from the laws of physics, that the derivative of order 1 of the natural logarithm of the difference between the characteristic acquired by the active thermography system after excitation (characteristic which is assimilated to a increasing linear function of the temperature) and the value of this characteristic at rest (ie before excitation) compared to the logarithm of time (if we take as reference time the instant at which the excitation takes place), is equal to the value -0.5 (for a material composing the homogeneous aeronautical part of semi-infinite thickness, and neglecting the phenomenon of convection). Based on this observation, the use in the process of the invention of first and second functions as mentioned above makes it possible to facilitate the detection of a fault in the aeronautical part. It should be noted that for other types of excitation applied to the aeronautical part, other functions than a logarithm of a difference between two values can be envisaged and more relevant.

The non-destructive testing method according to the invention therefore has great flexibility in configuration and can be configured at different levels, which allows it to be applied in many contexts: choice of first and second functions according to the acquisition conditions, choice of estimation instants, choice of the estimation interval of the derivative, etc.

As mentioned above, the interval for estimating derivatives is configurable in accordance with the invention. Its choice depends on several factors, such as typically the characteristics of the aeronautical part, acquisition conditions (including the mode of excitation of the part by the active thermography system), etc.

Thus, in particular, the inventors have found that the noise affecting the converted amplitudes of the pixels of the digital images used to estimate the derivatives can be impacted by the nature of the first function applied to convert the amplitudes of the signal acquired by the active thermography system. To reduce the estimation error resulting from this noise, it may be wise to consider estimation intervals of variable size as a function of time, that is to say containing a number of samples (ie of amplitudes acquired by the active thermography system) which varies over time.

In the above example of a first function and a second function equal to logarithmic functions of deviations, the fact of considering a time window (ie a time neighborhood) around each instant of constant estimation as a function of time (and therefore to use a constant number of acquired samples for the calculation of the derivative) typically leads to an increase in time of the variance of estimation of the derivative. To overcome this drawback, the inventors propose, in a particular embodiment of the invention, to select time windows comprising a variable number of samples in order to control the variance of estimation as a function of time.

Thus, in a particular embodiment, the estimation interval determined around each of the converted estimation instants can have the same size for all the converted estimation instants. If the second function is a logarithmic function, and therefore increasing in time, this is tantamount to having a time window of estimation (corresponding in the time domain to the estimation interval) which increases in time (but which is constant with respect to the logarithm of time, in other words in the reference frame of converted time). This gives an estimation error independent of the logarithm of time.

In a particular embodiment, the non-destructive testing method according to the invention comprises, prior to the step of estimating the derivative, a step of reducing the noise affecting the converted amplitudes.

Such a step makes it possible to reduce the noise affecting the amplitudes converted and thus to improve the quality of the derivatives estimated locally. The inventors have found that such a denoising step can typically lead to a division by 5 or even 10 of the estimation error affecting the calculation of the derivative.

In a particular embodiment, certain steps of the non-destructive testing method according to the invention are determined by instructions from computer programs. This is the case for example of the steps implemented during the step of determining the non-destructive testing method.

Consequently, the invention also relates to a computer program on an information or recording medium, this program being capable of being implemented in an estimation device or more generally in a computer, this program comprising instructions adapted to the implementation of the step of determining the non-destructive testing method as described above.

This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as in a partially compiled form, or in any other desirable form.

The invention also relates to an information or recording medium readable by a computer, and comprising instructions of a computer program as mentioned above.

The information medium can be any entity or device capable of storing the program. For example, the support may include a storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or else a magnetic recording means, for example a floppy disk or a disc. hard.

On the other hand, the information medium can be a transmissible medium such as an electrical or optical signal, which can be routed via an electrical or optical cable, by radio or by other means. The program according to the invention can in particular be downloaded from a network of the Internet type.

Alternatively, the information medium can be an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the process in question.

Brief description of the drawings

Other characteristics and advantages of the present invention will emerge from the description given below, with reference to the appended drawings which illustrate an embodiment thereof devoid of any limiting character. In the figures:

- Figure 1, already described, shows an aeronautical part such as an IFS structure on which are defined a plurality of unit acquisition zones to conduct a plurality of unit acquisitions by an active thermography system;

- Figure 2 shows a non-destructive control system according to the invention, in a particular embodiment;

- Figure 3 shows the hardware architecture of a device for estimating derivatives of the non-destructive control system of Figure 2 in a particular embodiment;

- Figure 4 illustrates the main steps of a non-destructive testing method according to the invention;

- Figure 5 shows several derivatives estimated according to the invention and can be used to perform a non-destructive test according to the invention; and - Figure 6 shows the main steps implemented by the estimation device of Figure 2 in accordance with the invention.

Detailed description of the invention

FIG. 2 represents, in its environment, a non-destructive control system 1 according to the invention, in a particular embodiment. In the example envisaged here, the system 1 makes it possible to carry out non-destructive testing of large aeronautical parts, heterogeneous and of complex geometry, such as for example a fixed internal structure (IFS) 2 of a thrust reverser equipping an aircraft.

However, no limitation is attached to the nature of the part on which non-destructive testing is applied. It can more generally be any type of part, preferably aeronautical, such as for example a part equipping an aircraft engine, etc., these parts being able to be of any size and geometry, heterogeneous or not, etc. The invention also applies also to other industrial fields than to the aeronautical field.

According to the invention, the non-destructive testing system 1 comprises:

- an active thermography system 3;

- an estimation device 4 in accordance with the invention; and - a verification device 5 configured to sanction (i.e. validate or reject) the aeronautical part 2 from the data estimated by the estimation device 4.

In the example envisaged in FIG. 2, the active thermography system 3 comprises one or more excitation sources 3A intended to excite in transmission and / or in reflection the aeronautical part 2 then positioned on a physical support provided for this purpose ( not shown in the figure), and an acquisition device 3B capable of measuring the response (thermal here) of all or part of the aeronautical part 2 to the excitations of the sources 4 over a determined period Tacq.

In the embodiment described here, the excitation sources 3A are here heat sources capable of causing a pulse excitation, of the flash type for example, of the aeronautical part 2. We are concerned here with excitation by reflection of aeronautical part 2.

In response to this impulse excitation, the temperature on the surface of the aeronautical part 2 increases instantaneously (for example by 10-15 degrees). Then, the diffusion of the heat flow in the aeronautical part 2 results in a decrease in temperature at the surface of the aeronautical part 2 until reaching or almost the initial temperature of the aeronautical part 2 before excitation (in other words, the temperature ambient).

The acquisition device 3B is an infrared thermal camera capable of capturing (by means of an appropriate sensor), over a period (duration) of so-called determined acquisition time, the thermal response at the surface of the aeronautical part 2 to 1 impulse excitation applied to it by the excitation source (s) 3A. The infrared thermal camera 3B is further capable of providing a temporal sequence of digital thermal images reflecting this response over the acquisition period. Each digital image IMj, j = l, ..., J supplied by the infrared camera corresponds to an acquisition instant tj defined over the acquisition period, J designating an integer greater than 1. The instants tj are for example spaced uniformly over the vesting period. It is considered here for the sake of simplification that the origin of time is the moment of excitation of the aeronautical part 2 by the infrared thermography system 3.

Each digital image IMj reflects the thermal response at the surface of the aeronautical part 2 to excitation by the source or sources 3A, or when it is a large aeronautical part, only part of this part. said unit acquisition area of the part. The thermal response over the entire aeronautical part 2 is obtained by carrying out a plurality of unit acquisitions, each unit acquisition potentially having a different acquisition period, and each unit acquisition being carried out on a dedicated unit acquisition area of aeronautical part 2. The size of the unit acquisition zones is preferably chosen taking into account the characteristics of the infrared thermal camera 3B and the requirements on the measurements carried out by the thermal camera (eg spatial resolution, temporal resolution, signal to noise) induced by the requirements on the precision of estimation of the derivatives. In addition, the unit acquisition zones are chosen so that their juxtaposition covers the entire aeronautical part 2 (for example as in FIG. 1 previously described) or at least a previously chosen part of this aeronautical part 2 on which one wishes to base more particularly non-destructive testing.

To carry out this plurality of unit acquisitions, the infrared camera 3B can be placed, for example, on an arm capable of moving around the aeronautical part 2 and of positioning the infrared camera 3B facing each acquisition zone. unit.

In the following description, we denote Zl, Z2, ..., ZN, N denoting an integer greater than or equal to 1, the unit acquisition zones considered during unit acquisitions (when N = l, a single zone d unit acquisition covering all or a selected part of aeronautical part 2 is considered), and IMj (Zn), j = l, ..., J (n) the thermal images provided by the infrared camera 3B of the area Zn, J (n) designating an integer greater than 1. Each unit acquisition corresponds to an acquisition period or duration Tacqn, n = l, ..., N.

As mentioned previously, each digital image IMj (Zn) of the aeronautical part 2 reflects the thermal response of the unit acquisition zone Zn of the aeronautical part 2 at the acquisition time tj, following the excitation (pulse here ) applied through the 3A excitation source (s). It comprises a plurality of pixels corresponding to a spatial sampling of the unit acquisition area Zn, in other words, each pixel is associated with a point of the unit acquisition area Zn. Each pixel is associated on the image IMj (Zn) with an amplitude representing a characteristic of the aeronautical part 2 at the instant of acquisition tj, this characteristic here being a determined increasing function of the surface temperature of the part.

In the embodiment described here, the digital thermal images supplied by the infrared camera 3B are two-dimensional images coded in gray levels: each pixel of an image therefore has an amplitude which is here a gray level reflecting the temperature surface or more precisely an increasing function of the surface temperature at the point of the aeronautical part 2 represented by the pixel. This increasing function results, in a known manner, from the combination of Planck's law in monochromatic and from the supposed linear response of the sensor of the infrared camera 3B: it translates the conversion into a gray level here of the spectral luminance picked up by the sensor of the infrared camera 3B at the point represented by the pixel, this spectral luminance reflecting the surface temperature of the aeronautical part at this point (ie the higher the temperature the higher the luminance).

According to the invention, the digital images acquired by the acquisition device 3 and in particular by the infrared camera 3B are supplied to the estimation device 4. In the embodiment described here, the estimation device 4 is configured to estimate from digital images supplied by the infrared camera 3B, at least one derivative of a first mathematical function f1 of the temperature with respect to a second mathematical function f2 of time.

In the example envisaged here of a pulse excitation of the aeronautical part 2 by the acquisition device 3, we consider for fl and f2 the same mathematical function, namely a natural logarithm function also called natural logarithm of a difference between a value and a determined reference value, ie fl (y) = f2 (y) = ln (y-yref), where y is a real number and yref the reference value considered.

For fl, the reference value here corresponds to the gray level amplitude of the pixel considered associated with a temperature at rest of the point of the aeronautical part 2 represented by this pixel.

For f2, the reference value corresponds to the moment of excitation of the aeronautical part 2 by the infrared thermography system. As mentioned previously, it is considered here that the acquisition instants originate from the moment of excitation of the aeronautical part 2 so that a zero reference value is applied here (ie it is already implicitly contained in the instants d 'acquisition).

However, these assumptions are not limiting in themselves. Other mathematical functions can be envisaged for fl and f2. The choice of functions fl and f2 can be guided by various parameters, such as in particular the nature of the excitation used by the active thermography system, etc.

In the embodiment described here, the estimation device 4 has the hardware architecture of a computer as shown diagrammatically in FIG. 3.

It includes, in particular, a processor 6, a random access memory 7, a read-only memory 8, a non-volatile flash memory 9 as well as communication means 10 allowing in particular the estimation device 4 to communicate with the verification device 5 to supply for example the derivative (s) estimated from the digital images of the aeronautical part 2 supplied by the infrared camera 3B. These communication means include for example a digital data bus or if the estimation device 4 and the verification device 5 are connected via a telecommunications network (local or other, wired or wireless, etc.), a network card or an interface allowing communication on this network.

In an alternative embodiment, the estimation device 4 and the verification device 5 can be located within the same equipment, for example a computer such as that shown in FIG.

3.

The ROM 8 of the estimation device 4 constitutes a recording medium according to the invention, readable by the processor 6 and on which a computer program PROG according to the invention is recorded.

The computer program PROG defines functional modules and software here, configured to implement an estimate of one or more derivatives as proposed by the invention from digital images of aeronautical part 2 supplied by the infrared camera 3B. These functional modules are based on and / or control the hardware elements 6-10 of the estimation device 4 mentioned above. They notably include here, as illustrated in FIG. 2, a plurality of modules activated for each estimated derivative and for each unit acquisition area Zn, n = l, ..., N considered, said modules comprising here:

A selection module 4A, configured to select a plurality K (n) of instants of estimation tek, k = l, ..., K (n) of this derivative over the acquisition period Tacqn of the digital images ( period of time determined within the meaning of the invention) for the unit acquisition indexed by n, n = l, ..., N, K (n) designating an integer greater than 1;

A first application module 4B, configured to apply the first function f1 to the amplitudes of the pixels of the digital images, this first application module providing amplitudes of so-called converted pixels;

A second application module 4C, configured to apply the second function f2 to the acquisition times tj, j = l, ..., J (n) of the digital images for the unit acquisition area Z (n) and at the instants of estimation tek, k = l, ..., K (n) of the derivative, this second application module 4C providing so-called converted acquisition instants denoted rj, j = l, ..., J (n) and in so-called converted estimation moments denoted -tek, k = l, ..., K (n);

- a 4D denoising module, configured to reduce the noise present in the amplitudes of the converted pixels;

- a 4E determination module, configured to determine for each converted estimation instant rck, an estimation interval (i.e. neighborhood) Wk around this converted estimation instant. If we consider that the acquisition period Tacqn for the unit acquisition carried out on the unit acquisition area Zn is delimited by an initial instant tjnit and a final instant t_fin, each estimation interval Wk determined by the determination module 4E around a converted estimation instant ick has a size less than (is included in) the converted acquisition period defined by the difference between the final converted instant resulting from the application of the second function f2 at the instant final t_fin and the initial instant converted resulting from the application of the second function f2 at the initial instant tjnit (we consider here the same convention as previously for the origin of the instants tjnit and t_fin); and - an estimation module 4F, configured to estimate for each instant of converted estimation -tek, the derivative from the converted amplitudes corresponding to the converted acquisition instants ij belonging to the estimation interval Wk determined by the module 4E determination for the converted estimation time.

The functions of these different modules are described in more detail later with reference to the step of estimating the non-destructive testing method according to the invention implemented by the device 4 for estimating the system 1 of non-destructive testing of the figure 2.

As mentioned above, the non-destructive testing system 1 also comprises a device 5 for checking the aeronautical part 2. This checking device 5 is configured to allow the integrity of the aeronautical part 2 to be checked (that is to say say to detect the presence of anomalies or indications of such anomalies in the aeronautical part 2) by analyzing the derivative or derivatives evaluated by the estimation device 4.

In the embodiment described here, the verification device 5 comprises a screen and a graphical interface making it possible to display images representing the derivative (s) produced by the estimation device 4. This allows an operator viewing this data to detect the possible anomaly on aeronautical part 2, if necessary position this anomaly on the surface of the part and possibly assess the depth of the defect. This verification device 5 is configured to give intelligible information to the operator to help him make a decision as to the integrity of the aeronautical part 2, as described in more detail later.

In another embodiment, the verification device 5 can comprise an automatic fault detection module on the aeronautical part 2 configured to use the derivative (s) provided by the estimation device 4 and to make a diagnosis as to the integrity aeronautical part 2 (eg detection or not of indications in the material structure suggesting a defect or anomaly), without requiring the intervention of an external operator proper.

FIG. 4 represents the different stages of the method implemented by the non-destructive testing system 1 illustrated in FIG. 2 to operate a non-destructive testing of the aeronautical part 2 in accordance with the invention.

According to the invention, the non-destructive testing of the aeronautical part 2 is based on an active infrared thermography process. This process, known per se and briefly recalled previously, is implemented by the active thermography system 3 (step E10). More particularly, the active thermography system 3 applies, by means of excitation sources 3A, a pulse excitation by reflection here on the aeronautical part 2 positioned on its support provided for this purpose.

The thermal response of the aeronautical part 2 to this impulse excitation is captured by the infrared camera 3B during a determined acquisition period, at a plurality of acquisition instants. In the example envisaged here, aeronautical part 2 being a large IFS structure, several (i.e. N, N denoting an integer greater than 1) unit acquisitions are successively carried out on aeronautical part 2 as mentioned previously. Each unit acquisition is carried out over a unit acquisition period equal to Tacqn, each unit acquisition targeting a separate unit acquisition zone Zn, n = l, ..., N, the N unit acquisition zones Zn juxtaposed allowing, as previously mentioned, to cover aeronautical part 2 in its entirety.

The infrared camera 3B generates, for each unit acquisition indexed by n, a plurality of digital images IMj, j = l, ..., J (n) of the aeronautical part 2 representing the response thus captured from the aeronautical part to the different acquisition times tj, j = l, ..., J (n) (step E20).

In the embodiment described here, it is assumed that the acquisition times tj, j = l, ..., J (n) defined over the time period Tacqn are spaced uniformly with a sufficiently small pitch to have a good representation of the thermal response of the unit acquisition area Zn of the aeronautical part 2 to the impulse excitation applied to the part, and an observation redundancy allowing a precise estimate in the presence of statistical observation noise.

The digital images IMj (Zn), j = l, ..., J, acquired on each of the unit acquisition zones Zn, n = l, ..., N considered represent the evolution of the temperature at the surface of the aeronautical part 2 following the impulse excitation which has been applied to it by means of the excitation source or sources 3A. More particularly, each pixel denoted PIXi, i = l, ..., I, of a digital image IMj (Zn) corresponds to a point of the unit acquisition area Zn resulting from a spatial sampling of the latter, I designating an integer greater than 1 corresponding to the number of pixels in each image IMj (Zn). Each pixel PIXi of the image IMj (Zn) has an amplitude denoted amp (PIXi) which represents an increasing function of the surface temperature of the aeronautical part 2 (characteristic of the aeronautical part within the meaning of the invention), at acquisition time tj, at the point of the unit acquisition area Zn corresponding to this pixel.

The digital images IMj (Zn), j = l, ..., J, n = l, ..., N acquired by the digital camera 3B are then supplied by the active thermography system 3 to the estimation device 4 ( step E30).

According to the invention, the estimation device 4 estimates, from the digital thermal images supplied to it, at least one derivative of order x (integer) denoted d ^(x) of a first function f1 of the temperature with respect to a second time function f2 (step E40). In the example considered here, as mentioned above, the functions fl and f2 are both taken equal to a natural logarithm (ie natural) function of a difference (ie of a difference) between a value and a reference value determined (ie of an amplitude difference for fl and a time difference for f2). These functions are particularly well suited to an excitation of the impulse type, in particular by reflection, as explained above.

No limitation is attached to the order x of the derivative estimated by the estimation device 4. This is for example a derivative of order 1 or of any order greater than 1. Furthermore, several derivatives of different orders can be estimated by the estimation device 4. For the sake of simplification, in the example described here, we limit ourselves to the estimation of a single derivative of order 1, in other words d ^(x) = d ^w .

According to the invention, the derivative d ^(x) estimated by the estimation device 4 is estimated locally for each pixel of each unit acquisition area Zn, in several instants of estimation tek, k = l, ... , K, on a temporal neighborhood around these moments of estimation. This temporal neighborhood is reduced compared to the acquisition period Tacqn, as described in more detail later. This gives a (local) estimate of the derivative d ^ix) sought robust under the conditions of acquisition of thermal images.

The estimation device 4 supplies the estimated derivative d ^(x) formed from the derivatives estimated locally at each of the estimation instants tek, k = l, ..., K (n) and in each pixel of each of the zones of unit acquisition Zn to the verification device 5 (step E50).

In the embodiment described here, the verification device 5 is configured to display on its screen, via a graphical interface provided for this purpose, the derivatives thus estimated locally. This display can be triggered under the action for example of an operator who, from the displayed derivatives, is able, via his own expertise, to carry out a diagnosis of the aeronautical part 2, that is to say to verify the integrity of the material structure with respect to an expected state and to determine whether or not the aeronautical part 2 has a defect (step E60).

An example of such a display is given in FIG. 5. In this figure, the different curves represented in broken lines correspond to the derivatives d ⁽¹⁾ of order 1 estimated in accordance with the invention for different pixels associated with distinct points d '' the same unit acquisition area. On the abscissa are represented the indices k of the different estimation instants, while on the ordinate are represented the amplitudes of the estimated derivatives. To account for the precision of the estimated derivatives, the true first derivatives (in other words “theoretical” or “expected”) are also represented in the figure for reference in solid lines.

The use of such information by an operator to carry out a diagnosis of the aeronautical part 2 (also called verification or “sanction” of the part) is known in itself. By examining the shape of the derivative d ⁽¹⁾ of order 1 of the natural logarithm of the deviation of a determined increasing function of the temperature compared to the natural logarithm of the time elapsed after the impulse excitation provided by the device d estimate 4, the operator can determine whether it has a shape that conforms to the expected material structure or if it has significant differences from it, suggesting the presence of heterogeneities or defects in the part aeronautics 2. By way of illustration, FIG. 5 represents the estimated derivatives d ⁽¹⁾ obtained for different pixels all having defects, during a check in reflection with excitation by flash lamp. It is noted that the earlier the defect appears in time, the closer it is to the surface of the aeronautical part 2 located on the side of the camera.

More particularly, in the case of application of the detection of indications by an operator, the sanction of the aeronautical part 2 may for example include the successive observation for each estimation instant, of so-called spatial images representing a spatial mapping derivatives estimated at this acquisition time. A defect such as an air gap deep in the structure of the material constitutes heterogeneity and results in a contrast between the zone presenting the defect and a healthy neighboring zone in at least one spatial image of derivatives. Thanks to the invention, we ensure the absence of gray level jumps between the juxtaposed images of two juxtaposed unit acquisition zones (in other words, the invention makes it possible to get rid of the existence of an estimation bias depending on the acquisition conditions, such as for example the unit acquisition period which can vary from one unit acquisition to another). We also ensure that the visual contrast between two neighboring zones, one healthy and the other failing, both of fixed material structure, is independent of the observation conditions of the unit acquisition zone containing this zone. healthy and this area failing.

As a variant, the vector of derivatives of each pixel of the aeronautical part 2 can be compared to reference vectors, previously learned and covering the variability of the "possible" expected for the material structure. This makes it possible to have a characteristic of the material structure at each point of the part and to assess the conformity of the inspected material structure. The invention makes it possible to reduce the size of the base of the reference vectors considered with respect to the state of the art, by guaranteeing an estimate of the derivatives independent of the acquisition conditions. Indeed, to establish the base of the reference vectors, it is necessary to take account only of the variability of the structures of material (and not of the variability of the structures of material coupled with the variability of the conditions of acquisition). In addition, the acquisition conditions can advantageously be modified after the base has been set up, which offers flexibility of use.

The document WO 2001/041421 gives other examples of exploitation of the derivative ^(s) d ^(x) estimated by the estimation device 4 to detect the presence of a fault in an aeronautical part.

These examples are of course only given by way of illustration, and depend in particular on the derivatives d ^(x) estimated by the estimation device 4 and on the structure of material inspected.

In another embodiment, the verification device 5 comprises an automatic fault detection module on the aeronautical part 2 configured to use the derivative ^(s) d ^(x) provided by the estimation device 4 and to make a diagnosis as to the integrity of the aeronautical part 2, without requiring the intervention of an external operator proper. The document EP 1 910 786 describes for example an automatic method making it possible to use information contained in derivatives d ^{(x) which} can be calculated by the estimation device

4. This example is, however, given only for illustration.

As mentioned previously, the invention differs mainly from the existing state of the art by the way in which it proposes to estimate, during step E40 of the non-destructive testing method described above, the derivative ^(s) d ^{( x)} used to carry out non-destructive testing of the aeronautical part 2. The invention indeed proposes an estimate of this or these derivatives which is both less biased and bias insensitive to the usual variations in the conditions of acquisition, such as the acquisition period. This estimation is carried out on a dedicated temporal sampling, possibly and advantageously different from the acquisition sampling considered by the acquisition device 3 to obtain the thermal images (ie the instants of estimation tek, k = l, ... , K can be different from the acquisition times tj, j = l, ..., J). In addition, the invention is based on a local estimate of the derivative ^(s) d ^(x) from samples measured in a temporal neighborhood of limited size with respect to the acquisition period Tacq of the thermal images, which guarantees, by construction, the invariance of the estimate obtained compared to the period of acquisition and to the unit acquisition area considered. We will now describe in more detail how the derivative ^(s) d ^(x) are estimated by the estimation device 4 of the non-destructive control system 1 during step E40, in accordance with the invention. We limit ourselves here for the sake of simplification to the calculation of a single derivative of order 1 (ie d ^(x) = d ⁽¹⁾ ).

FIG. 6 illustrates the main steps implemented during step E40 by the estimation device 4 to estimate the derivative d ^(x) from the images IMj (Zn), j = 1, ..., 3, n = l, ..., N supplied by the infrared camera 3B for each unit acquisition zone Zn.

In the embodiment described here, the estimation device 4, via its selection module 4A, first selects the plurality of estimation instants tek, k = l, ..., K (n) to which it will estimate the derivative d ^(x) in each pixel of each unit acquisition area over the acquisition period Tacqn (step F10). To this end, the selection module 4A uses here a predetermined selection rule, fixed beforehand by an operator.

According to the invention, this rule fixes times of estimation of the derivative uniformly spaced in the logarithmic graph resulting from the conversion of the time domain corresponding to the acquisition period Tacqn by the function f2. In other words, by taking up the notations introduced previously, if we consider that the unit acquisition period Tacqn is delimited by an initial instant tjnit and a final instant t_fin, the instants of estimated estimation are uniformly spaced (same difference in the instants d 'converted estimate) over the converted acquisition period defined by the difference between the converted final instant resulting from the application of the second function f2 at the final instant t_fin and the converted initial instant resulting from the application of the second function f2 at the initial time tjnit. In addition, according to the construction rule applied, the number of estimation instants selected K (n) for the unit acquisition area Zn is less than the number of acquisition instants tj, j = l, ... , J (n).

Such a selection rule applied by the selection module 4A is for example the following: “from an instant T0 defined on the acquisition period Tacq and for an integer parameter a positive, as long as tek <Tacq: tc ( k + l) = a.tck with tcl = T0 ”. The instant T0 and the parameter a are supplied by the operator. T0 can for example be chosen so as to coincide with the first acquisition instant tl of the acquisition period Tacqn.

Of course, this example is given only as an illustration and other selection rules or ways of determining the instants of estimation tek, k = l, ..., K over the acquisition period Tacq can be considered. For example, we can consider defining instants of estimation coinciding with certain acquisition instants tj (eg tcl = tl, tc2 = t3, tc3 = t5, etc.). Preferably, a number K (n) of estimation instants is chosen which is less than the number J (n) of acquisition instants over the time period Tacqn to limit the complexity of implementation of the invention and in particular the calculation time required.

Then, the estimation device 4 proceeds to format the data which it has and which are contained in the digital images which have been supplied to it by the infrared camera 3B (step F20).

More precisely, during this formatting, it firstly determines the acquisition instants tj, j = l, ..., J (n) of the digital images which are supplied to it for each unitary acquisition zone Zn, n = l, ..., N of the aeronautical part 2. It is assumed here that for this purpose, the acquisition parameters of these images have been supplied to it, namely in particular the instant t_init (Zn) at which the acquisition the thermal response of the aeronautical part 2 to the impulse excitation to which it was subjected has started (fixed here as mentioned previously at the moment of excitation of the aeronautical part 2), for each unit acquisition zone Zn considered, as well as the acquisition sampling step retained for each unit acquisition (ie duration between each acquired frame).

Then the estimation device 4, via its first application module 4B, converts, for each unit acquisition area Zn, n = l, ..., N, the amplitudes of the pixels PIXi of the digital images corresponding to this area unit acquisition, by applying the first function fl. It thus generates here amplitudes of pixels, denoted y (PIXi) said to be converted, for each pixel PIXi, i = 1, ..., 1 of each image IMj (Zn), j = l, ..., J (n ) of the unit acquisition area Zn, such that: y (PIXi) = fl (amp (PIXi)) = ln (amp (PIXi) -ampO) where ampO designates the gray level associated with the pixel PIXi at a temperature of aeronautical part 2 at rest (that is to say before excitation) (reference value within the meaning of the invention for the function fl). The reference value ampO can be easily determined and supplied to the estimation device 4. This makes it possible to take into account only the amplitude disturbance induced by the excitation.

Following this formatting, the estimation device 4 proceeds to a change of time variable (step F30), in order to adapt in particular to the type of excitation applied to the aeronautical part by the active thermography system 3.

More precisely, during this step, it applies, via its second application module 4C, the second function f2 to the acquisition instants tj, j = l, ..., J (n) previously determined for each zone d unit acquisition Zn and each digital image IMj (Zn), as well as at the instants of estimation tek, k = l, ..., K (n) of the derivative d ^(x) . It thus obtains so-called converted acquisition instants denoted xj, j = l, ..., J (n) and so-called converted estimation instants denoted xck, k = l, ..., K (n) such that :

xj = f2 (tj) = ln (tj), j = l, ..., J (n) xck = f2 (tck) = ln (tck), k = l, ..., K (n)

We note that the natural logarithm In here is applied directly to the instants of acquisition and estimation (ie zero reference value for the function f2), these having the same origin by hypothesis the excitation of the aeronautical part 2 ( in other words, the reference value is somehow already integrated into the value of the acquisition and estimation instants considered).

In the embodiment described here, the estimation device 4, via its denoising module 4D, then applies denoising processing (ie noise reduction) to all the amplitudes of converted pixels obtained at the end of step F20 (step F40). It is noted that step F40 can be carried out either before, after or even in parallel with the step of changing time variable F30. This step is optional.

The denoising step F40 (or also designated by the pre-restoration step) aims to reduce, prior to the estimation of the derivative d ^(x) , the noise affecting the amplitudes of the pixels converted by taking into account the redundancy properties of the useful signal and noise statistics. Such denoising can be carried out using numerous techniques known per se applied successively to the converted amplitudes y (PIXi) corresponding to each image IMj, j = l, ..., J (n) of the same acquisition area. unit Zn. Such techniques consist for example of a spatial filtering applied to each image, of a denoising by patches (also known under the English name of "non-local means"), in a technique called mathematical morphology, and or a regularized variational approach (Tikhonov, total variation, etc.), etc.

No limitation is attached to the denoising technique used. In the embodiment described here, it is assumed that the denoising module 4D implements an isotropic 2D Gaussian spatial filtering on the converted amplitudes of the pixels PIXi, image by image. The denoised converted amplitudes are designated in the following description by y '(PIXi). It is noted that the parameters of the filtering carried out (and in particular the number of pixels on which it is carried out) depend in particular on the dimension of the anomalies which one seeks on the part.

The estimation device 4 then estimates the derivative d ^(x) from the converted denoised amplitudes y ′ (PIXi) obtained for each image IMj and for each unit acquisition area Zn. As mentioned previously, in accordance with the invention, the derivative d ^(x) is estimated locally, on selected neighborhoods around each instant of estimation tek, or in an equivalent manner around each instant of estimation converted Tek, k = l , ..., K (n).

The estimation device 4, via its determination module 4E, therefore firstly determines, for each converted estimation instant Tek (and for each unitary acquisition zone Zn), an estimation interval Wk around this instant of converted estimate, this estimate interval having a duration less than the previously defined converted acquisition period (step F50). The same estimation intervals Wk can be selected for the different unit acquisition zones Zn, n = l, ..., N.

To determine the estimation intervals Wk, the determination module 4E here uses a predefined determination rule, fixed beforehand as a function of the characteristics of the aeronautical part 2 and / or of the conditions of acquisition of the digital thermal images (e.g. of the excitation method applied by the active infrared thermography system). In the example envisaged here, this determination rule consists in selecting an estimation interval Wk centered around the converted estimation instant xck and of size Δ greater than 0, identical for all the estimation instants converted xck, k = l, ..., K. This amounts to considering, in the example of the function f2, a temporal neighborhood around the instants of estimation tek (before change of temporal variable, ie before conversion) which increases in time, in a proportional manner. Such a choice leads, for an acquisition to a regular sampling over time (ie tj regularly spaced over the period Tacqn) and a white observation noise on the measured amplitudes, to a variance of estimation of the derivative d ^(x) practically independent of the converted acquisition instants ή, j = l, ..., J (n).

As a variant, other rules for determining the estimation intervals Wk can be envisaged. Typically, the estimation intervals Wk are not necessarily centered around the moments of converted estimation. They are also not necessarily identical for each of the instants of estimation converted.

Following the determination step F50, the estimation device 4 via its estimation module 4F, estimates for each pixel PIXî, i = 1, ..., 1 corresponding to the spatial sampling of each acquisition zone unit Zn, and for each instant of converted estimate xck, k = l, ..., K (n), the derivative denoted d ^(x) (n, i, k) at this instant from the corresponding denoised converted amplitudes at the converted acquisition times ή belonging to the estimation interval Wk (in other words from the noisy converted amplitudes extracted from the images IMj of the unit acquisition area Zn associated with the acquisition times tj corresponding to the acquisition times converted rj) (step F60). It proceeds in the same way for each unit acquisition zone Zn considered.

Different techniques can be used by the 4F estimation module to locally estimate the derivative d ^(x) (n, i, k) over the estimation interval Wk. Thus, for example, the estimation module 4F can estimate the derivative d ^w (n, i, k) by a technique of derivation of a temporal Gaussian filter having a constant standard deviation.

In known manner, such a derivation technique is based on the following principle. If we assume a function ^ (τ) (y, here is homogeneous to the converted amplitude of the pixel indexed by i) continuous with respect to a real variable 1 -H-} τ and a Gaussian function / ι _σ (τ) = ^ = ^ em of standard deviation σ, then the function ÿ (r) = y * / ι _σ (τ) (where “*” denotes a convolution product) is a smoothed version of y (r) on a scale defined by σ. Convolution by the Gaussian function effectively amounts to achieving a local average weighted by the Gaussian function giving more weight to the values of variable close to τ. We can for example set σ = 0.125 x sizeW where sizeW is the size of a neighborhood to take into account.

The n ^th derivative of the smoothed continuous function evaluated in τ is then given by:

DY? ⁿ⁾ (T) = ^ [y * h _a ] (r) = y ^ h _a (r).

In the embodiment described here, the estimation module 4F applies this principle (convolution by a Gaussian filter and derivation) by using Gaussian filters for each estimated derivative whose implementation must take into account on the one hand, the nature of the converted amplitudes of the pixels, and on the other hand of the non-uniform nature of the sampling of the estimation instants.

Alternatively, the 4F estimation module can perform local parametric regression on a family of differentiable functions (eg polynomials), then analytically derive the parameterized function resulting from the regression.

Of course, these examples are only given by way of illustration and other techniques for local estimation of the derivatives can be envisaged as a variant.

As previously mentioned, the derivatives thus estimated by a local approach are then supplied to the verification device 5 to allow their interpretation, either by an external operator, or by the verification device 5 itself when this interpretation is automated.

In the embodiment described here, we considered a pulse excitation by reflection, derivatives of order 1 or 2, and identical functions f 1 and f 2, equal to the natural logarithm of a difference between a value and a reference value . As mentioned, these hypotheses are not limiting in themselves, and the invention applies to any type of excitation, any order of derivative, and any type of functions f1 and f2. Taking into account other orders of derivatives and / or other functions f1 and f2 makes it possible to adapt to other excitation profiles, such as niche excitations by hot air flow or by halogen lamps.

Claims (8)

1. Method for non-destructive testing of an aeronautical part (2) comprising: A step of obtaining (E20) a plurality of digital images of the aeronautical part acquired at a plurality of acquisition instants defined over a determined period of time called the acquisition period by means of a system ( 3) active infrared thermography, each pixel of a digital image acquired at an acquisition time having an amplitude representing a characteristic of the aeronautical part at this acquisition time at a point of the aeronautical part; - an estimation step (E40), from the digital images acquired, of at least one derivative of a first function of said characteristic with respect to a second time function; and - a verification step (E60) of the aeronautical part using said at least one estimated derivative; said method being characterized in that the estimation step (E40) comprises, for each estimated derivative: A step of selecting (F10) a plurality of instants for estimating this derivative over said acquisition period; - a step of applying (F20) the first function to the amplitudes of the pixels of the digital images, said step of applying resulting in amplitudes of pixels converted; A step of applying (F30) the second function at the instants of acquisition of the digital images resulting in instants of converted acquisition, and at the instants of estimation of the derivative resulting in instants of estimated estimation, said instants estimation being selected during the selection step so that the converted estimation times are uniformly spaced; and - an estimation step (F60), for each converted estimation instant, of said derivative from the converted amplitudes corresponding to the converted acquisition instants belonging to a determined estimation interval (F50) around the instant of converted estimate. 2. Non-destructive testing method according to claim 1, in which the acquisition period is delimited by an initial said instant and a final said instant, and each estimation interval determined around an estimation instant converted to a size. less than the difference between the converted final instant resulting from the application of the second function at the final instant and the converted initial instant resulting from the application of the second function at the initial instant. 3. A non-destructive testing method according to claim 1 or 2 in which: - Said characteristic is an increasing function of the surface temperature of the aeronautical part; - the active infrared thermography system (3) uses a pulse excitation mode by reflection of the aeronautical part; and - the first function and the second function are logarithmic functions of a difference between a value and a determined reference value. 4. Method of non-destructive testing according to any one of claims 1 to 3 wherein said at least one derivative comprises a derivative of order 1 and / or a derivative of order 2 of the first function of said characteristic with respect to the second function of time. 5. The non-destructive testing method as claimed in claim 1, in which the estimation interval determined around each of the converted estimation instants has the same size for all the converted estimation instants. 6. Non-destructive testing method according to any one of claims 1 to 5 in which the number of instants for estimating the derivative is chosen during the selection step less than the number of acquisition instants on the acquisition period. 7. A non-destructive testing method according to any one of claims 1 to 6 further comprising, prior to the step of estimating the derivative, a step (F40) of reducing noise affecting the converted amplitudes. 8. System (1) for non-destructive testing of an aeronautical part comprising: - an active thermography system (3) comprising an excitation device (3A) and an acquisition device (3B) configured to acquire at a plurality of acquisition instants defined over a determined period of time called the period of acquisition, of digital images of the aeronautical part, each pixel of a digital image acquired at an acquisition time having an amplitude representing a characteristic of the aeronautical part at this acquisition time at a point of the aeronautical part after excitation of the aeronautical part by the excitation device; - an estimation device (4), configured to estimate from the digital images acquired, at least one derivative of a first function of said characteristic with respect to a second function of time; and - a verification device (5) configured to verify the aeronautical part using said at least one estimated derivative; said system being characterized in that the estimation device comprises a plurality of modules activated for each estimated derivative and comprising: - a selection module (4A), configured to select a plurality of instants for estimating this derivative over said acquisition period; - a first application module (4B), configured to apply the first function to the amplitudes of the pixels of the digital images, said first application module providing amplitudes of converted pixels; - a second application module (4C), configured to apply the second function to the instants of acquisition of the digital images supplying converted acquisition instants and to apply the second function to the instants of estimation of the derivative providing instants d converting estimate, said estimation instants having been selected by the selection module (4A) so that the converted estimation instants are uniformly spaced; An estimation module (4F), configured to estimate for each converted estimation instant, said derivative from converted amplitudes 5 corresponding to the converted acquisition instants belonging to an estimation interval determined around the instant d estimate converted.