FR2978572A1 - Method for analyzing compatibility of software application with digital transport network, involves calculating note representing efficiency of communication flow of software application as polynomial function having two variables - Google Patents

Abstract

The method involves recording a communication flow of a software application with a digital transport network, and calculating multiple primary technical communication flow with an acquittal threading rate and an average size of packets. A note representing the efficiency of the communication flow of the software application is calculated as a polynomial function having two variables, where the note reflects the compatibility of the software application with the digital transport network. An independent claim is also included for a physical computer network.

Description

COMPATIBILITY INDICATOR FOR COMPUTING APPLICATIONS TO TRANSPORT NETWORKS. The invention relates to the problems of compatibility of computer applications with digital transport over a network. More particularly, the invention relates to the analysis of the compatibility of a computer application to a computer transport network. The invention also relates to a method for managing the computer resources required for the installation of an application. The industry employs a wide variety of computer applications on a daily basis. These applications make it possible to automatically perform several tasks such as computer-aided design, numerical calculation, data management or office automation. Applications are based on software or a set of software. These applications can lead to the exchange of information within the same company or with third-party users. This exchange is done through networks that can be expanded in the case of people in different geographic locations; or a local area network type enterprise LAN for people on the same site of the company. The development of these computer applications is an investment in time and money. It requires first of all a work of developers to develop the code of an application software. Second, network specialists integrate the application into a network or network infrastructure. It is at this stage only that the application undergoes its first integration tests in the network infrastructure. These tests require high skills and a lot of work time. This work of development then integration extends over a significant period. It pushes back the moment when the application is functional compared to when a need is issued and a specification is defined. According to an industrial logic this delay is to be reduced. In fact we note that the applications are not always suitable for networks and cause malfunctions that affect the quality of the application, the client rendering is degraded. There are jerks in the image, slowdowns or errors. Applications then require improvements that further delay their availability date and generate new fees.

The program must be modified to become compatible, which requires a new investment and is not always feasible. In some industries it is found that a noticeable fraction of applications are classified as incompatible with standard digital transport solutions. The infrastructure must then be modified to improve user rendering. One can consider using an accelerator, a proxy server to improve the operation of the application. However, these modifications require specialized skills and involve complex technologies whose development and exploitation costs can be penalizing. Modifications can make the application work harder. The cost of the project then increases significantly. At the extreme, there is no solution, the project becomes a dry loss. It is therefore profitable to develop a technical solution that makes it possible to control the compatibility and the development of an upstream application. It is known to those skilled in the art to study applications through their primary data. As primary data of an application, mention may be made of the threading rate, the acknowledgment rate and the average size of the packets transmitted by an application. This isolated data has its own meaning and information on the capabilities of an application but does not provide a general indicator of the operation of an application in a network infrastructure.

The object of the invention is to propose a solution for evaluating the general compatibility of a computer application with a computer network. More particularly, the invention also aims to propose a solution for evaluating the compatibility with digital transport of an application from its development stage. The invention also aims to propose a method of managing the computer resources (hardware and / or software) necessary for the installation of an application. The subject of the invention is a method for analyzing the compatibility of a computer application with a digital transport network, comprising the following steps: a) Recording a communication flow of the application with the digital transport network ; b) Calculation of several primary technical characteristics of the communication flow including the acknowledgment rate A, the threading rate T and the average size P of the packets; remarkable by the following step: c) Calculation of a note representative of the efficiency of the communication flow of the application as a function of a polynomial R comprising as variables at least two of, preferably three, primary technical characteristics A , T and P of the communication stream, said note reflecting the compatibility of the application with the digital transport network. According to an advantageous embodiment of the invention, the method comprises a step d) comparing the note with at least one reference value. The subject of the invention is a method for managing the computer resources required for the installation of an application comprising the following steps: a) Recording of an application communication stream with a digital transport network; b) Calculation of several primary technical characteristics of the communication flow including the acknowledgment rate A, the threading rate T and the average size P of the packets; remarkable by the following step: c) Calculation of a note representative of the efficiency of the communication flow of the application as a function of a polynomial R comprising as variables at least two of, preferably three, primary technical characteristics IA , T and P of the communication stream, said note reflecting the compatibility of the application with the digital transport network; D) comparing the score with at least one reference value; e) If the score is consistent with the reference value, install the application on a computer or server; if the score does not conform to the reference value, modify the IT infrastructure or modify the application. The method of analyzing the compatibility of an application and / or the method of managing computer resources also have the following characteristics. According to another advantageous embodiment of the invention, the score is increasing or decreasing with respect to each of the at least two primary technical characteristics among 7, T and P of the communication flow. According to yet another advantageous embodiment of the invention, at least one of the primary technical characteristics A, T and P as a variable of the polynomial R is brought to a power of a positive real number; preferably, a power of a positive real number less than 1. According to yet another advantageous embodiment of the invention, at least one of the primary technical characteristics A, T and P as a variable of the polynomial R is assigned a multiplier ; preferentially positive. According to yet another advantageous embodiment of the invention, in step a) the durations of the execution threads TH and the durations of the blanks BL are recorded for a total duration DT, the threading rate T being calculated as follows: M.THT DT -; E; According to yet another advantageous embodiment of the invention, in step a), the stream is analyzed and the number of data packets transmitted by the application 25 operating on a transmitter station E and the number of acknowledgment packets are counted. sent in response by a receiver station R; the acknowledgment rate A being calculated as follows: A = n shadow of data packets According to yet another advantageous embodiment of the invention, the polynomial R comprises a product between at least two primary technical characteristics., T and P .

According to yet another advantageous embodiment of the invention, in step c), the calculation of the note N1 is of the form: I where a and y are real coefficients and R is the polynomial. According to yet another advantageous embodiment of the invention, in step c) the calculation of the note N1 is carried out as follows: 3 ± 0.0 15. * (T4 - 1) + + `: P- 100) t: 4 where P is expressed in bytes. According to yet another advantageous embodiment of the invention, in step c) the calculation of the note N2 is of the form: where δ etc. are real coefficients and R is the polynomial. According to still another advantageous embodiment of the invention, in step c) the calculation of the note N2 is carried out as follows: (P2 * * x -, where P is expressed in bytes, according to another advantageous embodiment application is installed on a server The invention also relates to a physical computer network comprising: o a plurality of computers and / or servers, o an extended or local computer network which connects the computers and / or servers, o an application computer installed on at least one of the computers and / or servers, o an application analysis software installed on one of the computers and / or servers, characterized in that: o the software is configured to execute a compatibility analysis method The invention makes it possible to quickly establish an indicator informing about the compatibility of a computer application with a computer network This indicator is based on a computer network application. Easily recoverable data. The indicator can be developed by a software developer without the need for particular network skills. The possession of this indicator makes it possible to anticipate during the development of an application the modifications to be made or the infrastructure fixes to be implemented. The calculation of the indicator is fast, its interpretation is easy. It can be automated and allows mass processing of applications.

Other features and advantages of the present invention will be better understood with the aid of the description and the drawings, among which: FIG. 1 represents a communication flow of an application as encountered in the invention. - Figure 2 shows a data exchange between a transmitting station and a receiving station. FIG. 3 represents a graphic illustration of the calculation of the note N1 according to the invention. FIG. 4 represents a graphic illustration of the calculation of the note N2 according to the invention. FIG. 5 represents the diagram of the method of analysis of compatibility of an application according to the invention.

The invention relates to a method for analyzing compatibility of an application. This analysis uses application capture software and application analysis known per se to those skilled in the art. These softwares make it possible to determine the primary technical characteristics used to calculate a note. The first type of software used is flow capture software. This software is active during the operation of an application and allows among others to: - Enter real-time packets of a network interface. - Open and save seized packages. - Open and examine seized packages. - Import and export information packets. - Filter packets according to several criteria. - Look for packages following certain criteria.

The information entered on the stream can be saved to a file. Via an export, for example, you can choose to transfer them to a spreadsheet. A spreadsheet will facilitate the exploitation of the data and allow the calculation of different values characterizing the flow. From the transmitted and received information, the primary technical characteristics of the application transport are determined. This operation is performed from an application analysis software. It allows to decode flows by performing easily exploitable calculations. These softwares make it possible to: - Carry out statistics on the characteristics of the packets. - Create a history. - Classify flows. - Mapping the exchanges. - Perform calculations from the raw data.

The application analysis makes it possible to determine about fifteen primary technical characteristics of the application transport. In the context of the invention we choose to retain three which are: - the acknowledgment rate A, - the threading rate T, - the average packet size P expressed in bytes. It would be conceivable to develop a solution that relies on more of primary technical characteristics. These three characteristics are precisely retained because they have a basic appearance, they are simple to observe and they are common to all applications.

Figure 1 shows a flow of threads also called TH threads. By extension the threading rate TH is also called TH thread rate. FIG. 1 is a temporal graph of the emissions of an application that the invention proposes to analyze. In the abscissa is the time, in ordinate the different threads of execution TH issued over several sessions SE. The broadcast begins at a moment TO and ends at a moment TF. The observation time extends over a DT interval.

In each session SE, different threads TH are issued. In Figure 1 is shown an example with 3 open sessions SE1, SE2 and SE3. TH execution threads contain a certain amount of information that varies their length and the duration of their transmission. It is assumed that the size of a thread TH is substantially proportional to the time required for its communication.

Between the various threads TH remain WH blanks where there is no TH thread flow. During BL whites the network is not operated. In the context of the invention, the T threading rate is used. This rate can be defined in several ways; it is here calculated using a detailed formula below. At first, we let an application work and we capture the flow.

This capture focuses on the recording of several data including: - TH thread durations. - the durations of the BL whites. - the total duration DT of the input. The threading rate T is then calculated as follows: In this calculation the durations TH, DT and BL are expressed with the same unit, by way of example we can retain the milliseconds. Concretely in the example of Figure 1 we obtain: ({H1 - T H2 T TH 3 T TH4. + .DTH5 TH6 - 3 3) DT-L1 # BL 25 The number of SE sessions that the application can open is large, the higher the threading rate T is because the number of threads TH issued simultaneously is important. The larger the size of the threads TH, the higher the rate of threading T increases. The lower the total transmission duration DT, the higher the T threading rate because transmissions are carried out in the shortest possible time. The larger the set of BL whites, the greater the T threading rate because the necessary transmission time is reduced and the use of the bandwidth resource is limited. The threading rate T includes the number of TCP sessions that an application can open at the same time, the transmission time, and the blanks between the broadcasts. The higher the T threading rate, the higher the communication density and the faster the application exchanges.

FIG. 2 is a representation of an exchange of data of an application between a transmitting station E and a receiving station R. On the transmitting station E is installed an application. Using the application capture software, the data items (D1, D2, D3, D4) originating from the sending station E are observed towards the receiving station R. The data items (D1, D2, D3, D4) are in the form of packets.

In return, the receiving station R transmits an acknowledgment message to signify that it has received one or more messages (D1, D2, D3, D4). The receiving station R therefore sends an acknowledgment message, also called acknowledge (Ack1, Ack2). Acknowledgment messages are also sent as packets. The acknowledgment message has an acknowledgment function.

The invention uses an acknowledgment rate A which is calculated as described below. From the data exchanges and acknowledgments, the number of data packets (D1, D2, D3, D4) and the number of acknowledgment packets (Ack1, Ack2) are counted. Using these numbers, the acknowledgment rate A can be calculated in the following manner: number of tweeting packets. In the context of the invention, the acknowledgment ratio A or its inverse A, which is just as simply calculated, is used.

In the example case of Figure 2 we have: Number of acknowledgment packets (Ack1, Ack2) = 2 A number of packets e do ae.

Number of data packets (D1, D2, D3, D4) = 4 Therefore z A = - = 055 4 By deduction the inverse of the acknowledgment rate 7 = 2.

The acknowledgment rate A has a direct impact on long-distance compatibility. The more an application can send packets before receiving an acknowledgment A, the lower its rate and the better its behavior on the network. Despite the long distances that packets must travel, the application does not have to wait for an answer before a new send. When an application can send only one packet before receiving an A acknowledgment, its rate increases. It is recalled that the travel time, and therefore the waiting time increases with the distance traveled by the information. The inverse of the acknowledgment rate is all the greater as the network behavior of the application is good, which is illustrated in FIG.

The invention uses a third technical characteristic of the application transport: the average size of the packets P. The average size of the packets P is determined from the measurements of the sizes of all the packets communicated except the packets of zero size. This average is calculated by averaging all the packets communicated. The smaller the average packet size P, the less it favors network transport because of the information that is contiguous to each packet. A small average packet size P will increase bandwidth resource requirements without increasing the amount of information exchanged. It should be noted that the three primary technical characteristics λ, τ and β take values that are all the higher as the quality of the application transport is good. There is a correlation between the increase in the value of the primary technical characteristics 1 A, T, P and the quality of the application transport.

These characteristics are chosen because they are easily deductible from the capture phase and are present at each transmission. They can be obtained without having advanced network skills. A developer will be in the process of developing the application itself perform this recovery of primary characteristics. The method of analyzing the compatibility of a computer application to a transport network comprises the following steps: a) Recording the communication flow of an application; b) Calculation of several primary technical characteristics of the application transport including the acknowledgment rate A, the threading rate T and the average size of the packets P; c) Calculation of a note (N1, N2) representative of the efficiency of the communication flow of the application as a function of a polynomial R comprising as variables at least two primary technical characteristics of the application transport. Preferably the calculation of the note (N1, N2) comprises the following three primary technical characteristics:., T and P. The note (N1, N2) carries out the operation of converting primary technical characteristics I, (T, P) whose size is related to the quality of the application transport, in a result that reflects the compatibility of the application to digital transport. During step a), an application is allowed to operate for a given time and the communication flow of an application is recorded. Communication flow means the information sent and received by an application.

The process starts with a technical step. In step b), various primary technical characteristics of the application transport are computed, among which are the acknowledgment rate A, the threading rate T and the average packet size P. t These primary technical characteristics (, T, P) are the variables of a mathematical function that includes a polynomial R. Some primary technical characteristics I (A, T, P) are the variables of the polynomial R. This function is calculated in step c).

The function of the note (N1, N2) is monotonic, and in the same sense, with respect to each of the primary technical characteristics of the application transport (To, T, P). The compatibility score (N1, N2) is strictly increasing or strictly decreasing according to each of the primary technical characteristics of the application transport including the inverse of the acknowledgment rate 7, the threading rate T and the average size of the packets P The note (N1, N2) must be either strictly increasing for each of the primary technical characteristics, or strictly decreasing. This particularity facilitates the interpretation of the note. Each of the 1 primary technical characteristics (A, T, P) provides information on the quality of the application transport. To create a coherent and readable note, it is logical that all the primary technical characteristics (A, T, P) are monotone and have the same monotony. The growth of each primary technical characteristic (, T, P) influences in the same direction the note (N1, N2) insofar as their intrinsic meaning is related to the quality of the communication. The polynomial R can comprise several products of primary technical characteristics. It may also include sums of primary technical characteristics assigned multiplying coefficients so that the orders of magnitude of the monomers constituting the polynomial R are of the same order of magnitude for current values of the primary technical characteristics. A multiplier can be applied to a product of primary technical characteristics. The polynomial R can comprise a constant.

As an example we can give: polynomial R = a * T + b * A, I Or again: polynomial 3 = c * P * T + d * + e, I Or again: polynomial 13 = f * P * T + g * A * P + h * T + i. Where a, b, c, d, e, f, g, h, i denote multiplying coefficients, which are real numbers. They may also designate primary technical characteristics of the communication flow other than (A, T, P). In the invention at least one of the primary technical characteristics (, T, P) of the polynomial R is brought to a power of a positive real number. Preferably, one of the primary technical characteristics (, T, P) is brought to a power of a positive real number less than 1. Optionally, one of the primary technical characteristics can be raised to a negative power. In the context of the invention, within the polynomial R, it is advantageous to bring the average size of the packets P to its square root. This particularity makes it possible to weight the importance of the variation of the size of the packets P with respect to the other coefficients. This action is necessary when the average variation of one I of the primary technical characteristics (., T, P) is important compared to the others. Its variation overwrites the variation brought by the other characteristics

primary techniques (., T, P) in the polynomial R. Concretely a power greater than 1 will be assigned to a primary technical characteristic (, T, P), the variation of which is small compared to the others, while one will adopt a power between 0 and 1 for a significant variation. The orders of magnitude of A, T and P are as follows: A is between 0 and 1, T is between 1 and 4; P is between 100 and 1500 bytes. These values are indicative, the corresponding intervals may be expanded depending on the case. The values may vary depending on the protocol used. The calculation of the note (N1, N2) includes a composite function. The compound function can be a fraction and / or an exponential comprising the polynomial R.

In a first method of calculating the note N1, we use a fraction F of the form: I + x If the variable x is positive, the denominator remains greater than the numerator and the fraction F (x) takes values between 0 and 1. If a polynomial R taking values greater than 1 is incorporated in the denominator of F (x), F ((3) takes values between 0 and 1. The function F ((3) decreases from 1 to 0. F ((3) tends to 0 when the polynomial [i goes to infinity More precisely, a first method of calculating the note N1 can take the form of: where a and y are real coefficients and [i a polynomial FIG. 3 is a graphical representation corresponding to the calculation of the note Ni. The function F1 plotted on the graph has the following formula:

3 where

In this particular case a = 0.01 and y = 1.

The values of x are on the x-axis and those of F1 on the y-axis. On the graph the variable takes values between 0 and 1200, the values of F1 are between 0 and 3. On the graph we delimit 7 characteristic zones of the curve. These areas are named by letters: A, B, C, D, E, F, G. - Zone A delimits the values in the interval [0; 0.25 [, - Zone B delimits values in the range [0.25; 0.75 [, - Area C delineates values in the range [0.75; 1.25 [, - Zone D delineates values in the range [1.25; 1.75 [, - Zone E delimits values in the range [1.75; 2.25 [, - Zone F delimits values in the range [2.25; 2.75 [, - Zone G delimits values in the range [2.75; 3 [. Zones can be used to interpret the note Ni. In area A the note N1 tends to 0. The function has a small variation and is relatively linear and forms an asymptote.

In zone B the note N1 is substantially linear and initiates a beginning of curvature. In zone C note N1 has a pronounced curvature between the low variation portion and the high variation portion. In the zones D, E, F and G, the note N1 is substantially linear and has a strong variation.

In a second method of calculating the note N2, we use the exponential function in the form: If the variable x is positive, the function E (x) takes values between 0 and 1. If a polynomial R taking positive values replace the variable x in the function E (x), the latter takes values between 0 and 1. More precisely, a second mode of calculation of the note N2 can have as structure: where 0 etc. are real coefficients and R a polynomial.

FIG. 4 is a graphical representation corresponding to the calculation of the note N2. The function plotted on this graph has the formula F2: = 3 * q_ ~. 3 In this particular case b = 0.05 etc =.

The values of x are on the abscissa axis and those of F2 on the ordinate. On the graph the variable x is varied between 0 and 50. F2 takes values between 0 and 3. In this figure are shown the same areas A, B, C, D, E, F and G as in FIG. .

In area A the note N2 tends to 0. The function has a small variation and forms an asymptote. In zone B note N2 has a curvature between the low variation portion and the high variation portion. In zones D, E and F the note N2 is substantially linear and has a sharp decrease. In zone G, note N2 has a curvature. Notes N1 or N2 included in zones A are particularly good. Notes N1 or N2 included in zone G are particularly bad. The calculation of the note (N1, N2) which includes the fraction F (x) or the exponential E (x) is multiplied by an integer. One chooses like whole number 3. Thus the notes N1 and N2 take values included between 0 and 3. The choice of this value makes it possible then to define 3 simple intervals of notes which give a general tendency. According to the invention, the rating of the note is even better than its rating is close to 0.

The following intervals can be selected: First interval 11:] 0; 1], Second interval 12:] 1; 2], Third interval 13:] 2, 3]. These intervals (11, 12, 13) are of equal size and have integers as terminals. These features of the invention make the result easily interpretable and appreciable. For more finesse, these intervals can be subdivided into several finer subintervals. Other intervals of different sizes can also be created that would overlap the intervals described above.

The F1 (x) function has a slow decay. It reaches the value 2 when x = 50. The value 1 is reached for x = 200. Then the function remains between 1 and 0.20 when x is between 200 and 1200. The intervals (11, 12, 13) of appreciations are crossed for different x variations: 11: 50; 12: 150 and 13: 1000. We can consider that the interpretation of the interval 11 can be very fine because a slight variation of x will cause a significant variation of F1. The function F2 (x) has a fast decrease. It reaches the value 2 when x is close to 11. The value 1 is reached for x close to 21. Then the function is between 1 and 0.05 when x is between 21 and 50. The decay is more marked at the beginning of the curve. . We can accurately detect that an application is bad. Alternatively, in the calculation of the note (N1, N2) one can multiply the fraction F (x) or the function E (x) by any other integer or real number. The centering of the results of the values between 0 and 3 and the creation of basic intervals facilitates the reading of the note (N1, N2) and makes it usable by a larger number of users who do not need to be specialists. In step c) the compatibility score (Ni, N2) is calculated according to one or both of the following formulas: ## EQU1 ## nenz.bre data packets T DT In We obtain the formula of the note N1 by replacing in the function Fl (x) the variable x by the following polynomial P1: Pl (A T. p) (T4 .- 1) -FS . s -1, + 3 sP -'1 3 10 We obtain the formula of the note N2 by replacing in the function F2 (x) the variable x by the following polynomial P2: P.Gt, p) It is emphasized that in the frame notes N1 and N2 are based on a function (F1, F2) and include a polynomial (P1, P2). Composite functions are performed. The two functions have different variations. One of the advantages of the invention is that the calculation of the note can be made at several times of an application: - at the time of login, - at the time of navigation, 20 at the time of sending data, .sTH . - at the time of data reception, - at the processor moment when data is processed. The different scores obtained according to the different moments make it possible to target the moments on which it will be necessary to act and possibly to foresee solutions. The invention and the sequence of these tasks is shown in FIG. 5. In the first step, the application is started and possibly installed on a computer or a server. In the second step, an application capture is performed. The incoming and outgoing information flow is collected in the application. This data is then saved. In the third step, the application analysis is started and a preliminary calculation is carried out. Here, the importance of the flow having transited between a transmitting station E and a receiving station R is checked. If the exchange is too weak for a given duration, it may have an inappropriate analysis base. In this step we will therefore check the following inequality: Number of bytes. Therefore, it is desired that the amount of bytes transmitted during a total observation period, also called the total time, be greater than a threshold value. If the amount of data transmitted in time is insufficient, no note calculation is performed. If the quantity is sufficient, go to the next step in the process of calculating the note. In the fourth step we continue the application analysis. Using dedicated software; we perform filtering and calculations on the data. The values of the primary technical characteristics of the application transport are thus calculated, of which: the average size of the packets P, 10 1, the inverse of the acknowledgment rate calculated using the following formula: 1. number: of pacques. ..of data = to. number, of packets, eacqutttment the rate of threading T deriving from the formula: In the fifth step one calculates the note (Ni, N2) using one of the following two formulas: 01 * IS * (T '4-1) ± 5 .. + 3s - Loo) = 1 3 Or: In the sixth and final stage we study the result of the note (N1, N2). If N1 and / or N2 1, the score is considered good. - If 1 <N1 and / or N2 2 the rating is considered average. - If 2 <N1 and / or N2 3 the rating is considered bad.

The interpretation of the notes can be nuanced according to their environment. The conditions of use of the application, the context can influence the actual operation, impact the quality of the flow and degrade the client rendering. In the case where a score is between 1 and 2, we can extend the analysis of the result and look at the context of use of the application. If for example the application is installed on a transmitter station E in an area of the globe with poor infrastructure, the interpretation will degrade the note and it will be considered bad. At the opposite, if the application is installed on a transmitter station E in a region rich in infrastructures such as for example a capital of a country rich in network infrastructures, the interpretation of the note will tend to appreciate it. The note may be considered good. The analysis can, for example, be based on the proximity of a hub. This environment analysis takes into account for example the number of users that the application will have to manage simultaneously.

The invention makes it possible to develop a reliable compatibility indicator that provides an insertion criteria for an application in a network architecture. The problems of network incompatibilities can be detected at the earliest, as soon as a prototype of the application is able to work on a computer. Thanks to this anticipation we can anticipate corrective measures, estimate the necessary means and their costs.

This anticipation also helps to feed the company's know-how and to anticipate future cases. The solution can be automated by installing application capture software and application analysis. Thus the time required and skills required are limited, which promotes the automation of the process.

The invention also proposes a method for managing the computer resources required for the installation of an application on a computer or server. Computer resources may include computer hardware and / or computer software. As part of the management method, if the note (N ,, N2) is insufficient compared to a reference value, one can modify the computer infrastructure or the application. If we modify the IT infrastructure we can plan to add an accelerator or a proxy server. The modification of the application may consist of modifying or replacing one of the programs that compose it.

Claims (10)

CLAIMS1- A method for analyzing the compatibility of a computer application with a digital transport network, comprising the following steps: a) Recording a communication flow of the application with the digital transport network; b) Calculation of several primary technical characteristics of the communication flow including the acknowledgment rate A, the threading rate T and the average size P of the packets; characterized by the following step: c) Calculation of a note (N1, N2) representative of the efficiency of the communication flow of the application as a function of a polynomial R comprising as variables at least two of the, preferably the three , primary technical characteristics IT and P of the communication flow, said note reflecting the compatibility of the application with the digital transport network. 20 2- Process according to claim 1, characterized in that the note (N1, N2) is increasing or decreasing with respect to each of the at least two primary technical characteristics among., T and P of the communication flow. 3- Process according to one of Claims 1 to 2, characterized in that at least one of the primary technical characteristics λ, τ and ρ as a variable of the polynomial 13 is brought to a power of a real number. positive; preferentially a power of a positive real number less than 1; and / or at least one of the primary technical characteristics A, T and P of the polynomial 13 is assigned a multiplying coefficient; preferentially positive. 4- Method according to one of claims 1 to 3, characterized in that in step a) the duration of the threads TH are recorded and the durations of the blanks BL for a total duration DT, the threading rate T being calculated as follows: ETH = T T - L and / or in step a) the flow is analyzed and the number of data packets transmitted by the application operating on a transmitter station E and the number of acknowledgment packets sent in response by a receiver station R; the acknowledgment rate A being calculated as follows: o7t`t> r "d: acknowledgment packets A = number of data packets20 5. Method according to one of claims 1 to 4, characterized in that the polynomial R comprises a product between at least two primary characteristics A, T and P. 6. Process according to one of claims 1 to 5, characterized in that in step c), the calculation of the note N1 is of the form: where a and y are real coefficients and R the polynomial. 7- The method of claim 6, characterized in that in step c) the calculation of the note N1 is performed as follows: 3 1 +,. ~ 5s -1) + S t q + rW - ion $ where P is expressed in bytes. 8- Method according to one of claims 1 to 5, characterized in that in step c) the calculation of the note N2 is of the form: where 0 etc. are real coefficients and 13 the polynomial. 9- A method according to claim 8, characterized in that in step c) the calculation of the note N2 is performed as follows: _ -3 * ~ 'G5 3 where P is expressed in bytes. 10-Physical computer network comprising: o several computers and / or servers, o a wide or local computer network that connects computers and / or servers, o a computer application installed on at least one of the computers and / or servers, o software application analysis system installed on one of the computers and / or servers, characterized in that: o the software is configured to execute a method of analyzing the compatibility of a computer application with a transport network as described in the Claims 1 to 9.