FR3060159B1 - METHOD, PROGRAM, APPLICATION AND SIDE MEASURING MACHINE ON VITUAL DOCUMENT - Google Patents

Abstract

The invention relates to a method for measuring dimensions (L2) on a virtual document (P) displayed on a screen (E) of a machine (T). The invention is characterized in that - during a first step, points (31, 41) are moved on the document (P) in (R1, R2), a sensor measures a non-zero distance (D1) between the positions (R1, R2), we enter a dimension (L1) between the positions (R1, R2) or a value (SC) of scale, - then in a second step, we move the points (31, 41) on the document (P) at positions (R3, R4), the sensor measures a distance (D2) between the positions (R3, R4), a calculator calculates the dimension (L2) corrected by the dimension (L1), multiplied by the distance (D2) and divided by the distance (D1) or corrected by the distance (L2) multiplied by the scale value (SC), and the dimension (L2) is displayed on the screen (E).

Description

The invention relates to a plan dimension measuring tool, as well as a measurement method for measuring dimensions on a virtual document displayed on a screen of a machine, a computer program and a computer application implementing this process, as well as the machine for measuring dimensions on a virtual document.

One field of application of the invention relates to plans for the construction of houses or buildings.

Such plans are used in the field to build the house or building and are used by building professionals, such as architects, builders, design offices, contractors, craftsmen , building companies, but also real estate professionals, notaries, land surveyors, DPE agents, real estate and thermal diagnostic agencies and, more generally, all professionals making measurements on drawings or drawings (designers products, design offices in particular). The inventor realized that, regularly, errors in the field are due to the reading of the dimensions on the plans. In fact, very often, there are no quotations on the plan and the professionals on the site measure these quotations directly on the plan and apply the indicated scale. The object of the invention is to obtain a measurement tool, as well as a method for measuring dimensions on a plane, which solves this problem and makes it possible to measure on a virtual document such as, for example, a plane or other dimension. For this purpose, a first object of the invention is a measuring method for measuring dimensions (L2) on a virtual document (P) displayed on a screen (E) of a machine (T), characterized in that - during a first calibration step, first and second points (31, 41) on the document (P) are moved to first and second positions (R1, R2) chosen and distinct from each other; other, a distance sensor (56) of the machine measures a first non-zero distance (D1) on the document (P) between the first and second positions (R1, R2) where the first and second points (31, 41) are located. ), and on a keypad (71) of the machine (T) a first dimension (L1), represented by the first distance (D1) between the first and second positions (R1, R2), or during first calibration step is entered on the numeric keypad (71) of the machine (T) a value (SC) of scale, - then during one of second step of measuring a second dimension (L2) on the document (P), moving the first and second points (31, 41) on the document (P) to third and fourth positions (R3, R4) chosen respectively and separate from each other, the distance sensor (56) of the machine (T) measures a second distance (D2) on the document (P) between the third and fourth positions (R3, R4) where the first and second points (31, 41), a calculator (8) of the machine (T) calculates the second dimension (L2), represented by the second distance (D2) between the third and fourth positions (R3, R4), the second dimension (L2) being corrected by the first dimension (L1), multiplied by the second distance (D2) and divided by the first distance (D1) or corrected by the second distance (L2) multiplied by the value (SC) scale, and the second dimension (L2) is displayed on the screen (E).

Thanks to the invention, the machine displays the dimension measured on the document by automatically calculating for each document the correction multiplying factor. The virtual document can be for example a plan or others. The invention makes it possible to calculate all the dimensions of a plane displayed on the screen.

According to one embodiment of the invention, during the first step, at least one key (72, 73) is actuated to cause the first dimension (L1) to be recorded in a memory (9). entered or the scale value (SC) having been entered, then the calculator calculates a correction multiplying factor (FCL) for the dimensions of the plane, as being equal to the first corrective dimension (L1), divided by the first distance (D1) and stores the correction multiplying factor (FCL) in the memory (9), and in the second step the second dimension (L2) is calculated by the calculator (8) as being corrected by the second distance (L2) multiplied by the correction multiplying factor (FCL) or by the scale value (SC).

According to one embodiment of the invention, the machine (T) is one of a mobile phone, a telecommunications terminal, a digital tablet, a computer.

According to one embodiment of the invention, the virtual document is or comprises a virtual plan.

A second object of the invention is a computer program comprising code instructions for implementing the measurement method as described above, when executed on a processor of the machine.

A third subject of the invention is a mobile phone computer application, comprising code instructions for implementing the measurement method according to any one of the preceding claims, when the application is executed on a mobile phone processor. .

A fourth object of the invention is a machine comprising a screen (E) for displaying a virtual document (P), characterized in that it comprises - a man-machine interface (7) capable of moving the first and second points (31, 41) on the document (P) respectively in first and second positions (R1, R2) chosen and distinct from one another, a distance sensor (56) for measuring a first distance (D1) non-zero on the document (P) between the first and second points (31, 41), the man-machine interface (7) having a number pad (71) for entering a first dimension (L1), represented by the first distance (D1) between the first and second positions (R1, R2), or to enter a scale value (SC), - the man-machine interface (7) being able to move the first and second points (31, 41). ) on the document (P) respectively in the third and fourth positions (R3, R4) chosen and distinct one on the other hand, the distance sensor (56) of the machine (T) being able to measure a second distance (D2) on the document (P) between the third and fourth positions (R3, R4) where the first and second points (31, 41), the machine comprising a calculator (8) for calculating a second dimension (L2), represented by the second distance (D2) between the third and fourth positions (R3, R4), the second dimension (L2) being corrected by the first dimension (L1), multiplied by the second distance (D2) and divided by the first distance (D1) or corrected by the second distance (L2) multiplied by the scale value (SC), the computer (8) causing the display of the second dimension (L2) on the screen (E).

According to one embodiment of the invention, the interface (7) man-machine comprises at least one key (72, 73) to cause the recording, in a memory (9), of the first dimension (L1) having entered or the scaled value (SC) having been entered, the calculator being configured to calculate a correction multiplication factor (FCL) for the plan dimensions, equal to the first corrective rating (L1), divided by the first distance (D1) and for storing the correction multiplying factor (FCL) in the memory (9), the computer being configured to calculate the second dimension (L2) as being corrected by the second distance (L2) multiplied by the factor multiplicative (FCL) correction or scale (SC) value.

A fifth object of the invention and a measuring tool (1) for measuring dimensions of a plane (P), comprising a support (2), at least a first spout (3) fixed to the support (2) and comprising a first end (31) of application against the plane (P), at least a second nose (4) having a second end (41) of application against the plane (P) and able to be moved manually on the support ( 2) for varying a distance between the first end (31) of application and the second end (41) of application, at least one sensor (5) arranged to provide a measurement quantity (D) of the actual distance between the first application end (31) and the second application end (41), at least one display unit (6), able to display at least one plane dimension depending on at least the measurement quantity ( D) provided by the sensor (5), characterized in that the measuring tool (1) further comprises at least one interface ace (7) man-machine having • a keypad (71) for entering at least a first corrective dimension (L1) and / or at least a second scale value (SC), • a first key (72) allowing to store in a memory (9) the first corrective dimension (L1), which has been entered on the numeric keypad (71), and the distance measurement quantity (D1), called the first distance (D1) of nozzles, supplied by the sensor (5) and corresponding to a position of the second nose (41) relative to the support (2), having been chosen by the user, and / or a second key (73) for recording in the memory (9). the second scale value (SC), having been entered on the keypad (71), a calculator (8) provided for calculating and storing in the memory (9) a correction multiplying factor (FCL) for the odds, as being equal to the first corrective rating (L1), divided by the first distance (D1) of nozzles or as being equal to the second scale value (SC), the calculator (8) being able to calculate the dimension (L2) of the plane to be displayed on the display unit (6), as being corrected at least by the magnitude measuring distance (D) provided by the sensor (5), multiplied by the correction multiplying factor (FCL).

Thanks to the invention, the measurement tool displays the actual dimension measured by the tool on the plan by correcting the errors mentioned due to the photocopy (or due to the conversions of software formats) or the printing of the plan and by automatically calculating for each plane the multiplicative correction factor.

According to one embodiment of the invention, the display unit (6) comprises a first display area (61) intended to display the plane dimension (L2), which has been calculated by the computer (8), and a second display area (62) for displaying the correction multiplying factor (FCL).

According to one embodiment of the invention, the second spout (5) is movable in front of the first spout (4).

According to one embodiment of the invention, the measuring tool (1) is of the vernier caliper type.

According to one embodiment of the invention, the display unit (6) is integral with the first spout (3) or the support (2).

According to one embodiment of the invention, the display unit (6) is integral with the second spout (4).

According to one embodiment of the invention, the interface (7) man-machine is secured to the first spout (3) or the support (2).

According to one embodiment of the invention, the interface (7) man-machine is secured to the second spout (4).

According to one embodiment of the invention, the human-machine interface (7) and / or the display unit (6) and / or the computer (8) is included in a telecommunication terminal, which is remote a distance measuring unit in which the support (2), the first spout (3), the second spout (4) and the sensor (5) are connected to each other, the measuring unit and the terminal telecommunication device being able to communicate with each other via a wireless telecommunication link.

According to one embodiment of the invention, the sensor (5) is resistive.

According to one embodiment of the invention, the interface (7) man-machine further comprises a third key (74) for resetting the dimension (L) plane for another position of the second spout (5) on the carrier (2), having been selected by the user, and / or a fourth plane-level conversion key (L) (75) to a selectable length measurement unit from a plurality of different length measurement units prerecorded, and / or a fifth key (76) for setting the second scale value (SC).

A sixth object of the invention is a measuring method for measuring dimensions of a plane using the measuring tool as described above, characterized in that during a first step of calibration: - the second spout (4) is moved on the support (2) in a first selected position with respect to the first spout (3) and the first and second ends (31, 41) of application are applied in this first position against first marks (R1, R2) of the plane (P), a dimension (L1) delimited by the first marks (R1, R2) is to be measured and a first corrective note is entered on the keypad (71) ( L1), - then the first key (72) is actuated to cause the recording, in the memory (9), of the first corrective dimension (L1) that has been inputted and the measurement variable (D1) of distance, called first distance (D1) of nozzles, provided by the sensor (5) and corresponding to the first position c hoisie, - then the calculator calculates a correction multiplying factor (FCL) for the dimensions of the plane, as being equal to the first corrective dimension (L1), divided by the first distance (D1) of nozzles and stores the multiplicative factor (FCL ) of correction in the memory (9), - then during a second measurement step of a second dimension (L2) of plane, different from or identical to the first dimension (C1) and delimited by second marks ( R3, R4) of the plane (P), different from or identical to the first marks (R1, R2): - the second nose (5) is moved on the support (2) in a second selected position, different from or identical to the first position, relative to the first spout (3) and applying the first and second ends (31, 41) of application being in this second position against the second pins (R3, R4) of the plane (P), - the calculator calculates the second dimension (L2) of plane corresponding to the second pos ition chosen, as corrected at least by the measurement variable (D) provided by the sensor (5), multiplied by the correction multiplying factor (FCL) and the display unit (6) displaying the second dimension (L2 ) plan corresponding to the second position chosen.

A seventh object of the invention is a measuring method for measuring dimensions of a plane using the measuring tool as described above, characterized in that during a first step of calibration: - one seizes on the keypad (71) at least one scale value (SC), - then the first key (72) is actuated to cause the recording, in the memory (9), of the value of d scale (SC) having been entered, then during a second step of measuring a dimension (L3) of plane: - the second spout (4) is moved on the support (2) at a selected position relative to at the first nose (3) and applying the first and second ends (31, 41) of application being in this selected position against pins (R3, R4) of the plane (P), a dimension (L3) of the plane separating the marks (R3, R4) are to be measured, - the calculator calculates the dimension (L3) of the plane corresponding to the chosen position, as corrected at less by the measurement variable (D) provided by the sensor (5), multiplied by the scale value (SC) and the display unit (6) displays the dimension (L3) of the plane corresponding to the chosen position .

An eighth object of the invention is a computer program comprising code instructions for the implementation of one and / or the other of the measuring methods as described above, when executed. on a calculator (8). The invention will be better understood on reading the description which follows, with reference to the accompanying drawings, in which: - Figures 1 and 3 are schematic views from above of the measuring tool according to an embodiment of the invention. invention in different positions of its moving nose, - Figure 2 is a schematic view of an example of a plane on which can be used the measuring tool according to the invention, - Figure 4 is a block diagram of the measuring tool according to one embodiment of the invention, - Figures 5 to 8 are schematic top views of the measuring tool according to one embodiment of the invention during different possible stages of its use, FIG. 9 is a diagram of an example of a sensor that can be used in the measuring tool according to one embodiment of the invention; FIGS. 10 to 12 are schematic views from above of a measuring machine; of cost on a virtual document, according to an embodiment of the invention during different possible stages of its use.

In FIGS. 1, 3 and 5 to 8, the measuring tool 1 comprises a first spout 3 fixed to a support 2 and a second spout 4 that is manually movable on the support 2. The first spout 3 has a first end 31 of application against a plane P, while the second spout 4 has a second end 41 of application against the plane P. The displacement of the spout 4 on the support 2 makes it possible to vary the real distance between the first end 31 of application and the second end 41 of application. For example, the spout 4 is guided on the support 2 along a guide direction 21, to vary the distance between the ends 31 and 41 along this direction 21 of guidance. Of course, the invention is applicable to any other type of displacement of the spout 4 with respect to the spout 3.

The ends 31 and 41 may be applied against a document, physical or virtual, such as for example a plane P, which may be in particular a plane of a construction, as indicated above, and which may comprise drawings DES of a building or other, as is shown by way of example in Figure 2. The plane P is dimensioned, that is to say it comprises dimensions indicating lengths present between marks, for example the marks R1, R2, R3, R4, forming part of the plane P in the drawing DES. The document or plane P can also be virtual, in that it is displayed on a screen E of a machine T, as shown in FIGS. 10 to 12. In the following, the term plan can be replaced by document generally.

In FIGS. 1, 3 and 5 to 8, the support 2 may or may not comprise a graduated ruler 22 on which the second spout 4 is movable so that it can read visually in front of which of the graduations 23 of the ruler 22 is the second end 41 of the second spout 4. The first end 31 and the first spout 3 may for example be in front of a zero graduation of the rule 22.

The spouts 3 and 4 may be of the inner spout type as shown in the figures, that is to say that the two ends 31 and 41 of application thereof are opposite one another and delimit between them a free space. However, the spouts 3 and 4 could also be of the outer spout type, that is to say that the ends 31 and 41 are turned out of the distance separating them. Alternatively, one of the spouts 3 and 4 may be of the inner spout type and the other of the spouts 3 and 4 may be of the outer spout type. The end 31 and / or 41 of application can be shaped tip.

In the embodiment of Figures 10 to 12, the spouts 3 and 4 and ends 31, 41 may be replaced by a first virtual point 31 and a second virtual point 41, displayable and movable on the screen E on the document P. Spouts 3, 4, ends 31, 41 and virtual points 31, 41 are generally designated by first point 31 and second point 41, which may be physical or virtual.

The measuring tool 1 is firstly described below with reference to FIGS. 1 to 9. Of course, what is described below for the measuring tool 1 is also valid for the machine T of FIGS. The measuring tool 1 further comprises at least one sensor 5 or 56 capable of providing a quantity D for measuring the real distance between the first application end 31 or the first point 31 and the second application end 41. or second point 41. The measuring tool 1 further comprises at least one display unit 6 for displaying at least one plane L dimension and can be formed for example by a digital segment display (as shown in FIGS. Figures 1, 3, 5 to 8) or a display screen. The plane L dimension displayed by the unit 6 varies, for example in a monotonous manner, as a function of at least the measurement variable D supplied by the sensor 5. For example, in the position represented in FIG. 4, the display unit 6 displays a plane LO dimension of 60 mm, for a 1: 1 plane scale.

In the example of Figure 3, the spout 4 is against the spout 3 and the ends 31 and 41 are against each other, so that the distance between them is zero and the plan dimension displayed by the display unit 6 is 0.0 mm for a scale of plane equal to 1: 1.

Of course, the spout 4 and its end 41 may for example take any position between a minimum spacing and a maximum spacing, in a continuous or discrete manner, on the support 2, as indicated by the two arrows shown in FIG. 1.

According to the invention, the measuring tool 1 or the machine T comprises a man-machine interface 7 comprising a keypad 71. This keypad 71 comprises keys or buttons, for example ten keys for the digits 0, 1, 2 , 3, 4, 5, 6, 7, 8 and 9, a key 71a for a digital comma and a key 71b for deleting the input. The numeric keypad 71 makes it possible to enter numerical values. The keypad 71 allows the user to enter at least a first corrective dimension L1 and / or at least a second scale value SC.

In addition, the man-machine interface 7 comprises at least one key (72 or 73 described below) for causing the recording in a memory 9 of a multiplying factor FCL correction for dimensions.

According to a first embodiment of the measurement tool 1 and the measuring method according to the invention, the human-machine interface 7 comprises a first key 72 or the like (as indicated below) for recording. in the memory 9 a first corrective dimension L1, which has been entered by the user on the keypad 71. The pressing on the first key 72 makes it possible to record in the memory 9, with this first corrective dimension L1 the magnitude of measurement D1 distance (called first distance D1 spouts) provided by the sensor 5 and corresponding to a position of the second spout 41 on the support 2, having been chosen by the user.

Thus, for example, in order to carry out a measurement method using the measurement tool 1, the user, during a first calibration step, moves the second nozzle 4 in this first selected position relative to to the first spout 3 and applies their first and second ends 31, 41 of application being in this first position against first references of the plane P, for example the first references R1 and R2 of the plane P as shown in Figure 5.

Then, in Figure 6, the user enters on the keypad 71 the first corrective dimension L1 (as represented by the arrow F1) and actuates the first key 72 (as represented by the arrow F2). The measurement tool 1 further comprises a computer 8 programmed to calculate and store in the memory 9 the multiplying factor FCL of correction for the dimensions. The calculator 8 calculates the multiplying factor FCL correction equal to the first corrective dimension L1, having been recorded in the memory 9, divided by the first distance D1 of beaks, having been recorded in the memory 9 in association with the first corrective dimension L1 having been stored in the memory 9, i.e. FCL = L1 / D1.

Indeed, even having been able to enter beforehand the step of FIG. 6, the nominal scale indicated on the plane P (for example 1:20 in FIG. 2) by the second key 73, the dimension displayed by the unit 6 in FIG. 5 (for example 6000 mm) may differ from the dimension C1 (for example 590 cm in FIG. 2) indicated on the plane P and separating the marks R1 and R2 from the plane P, because of uncontrolled dimensional deformations. of the plan, due to its photocopy by a printer or its printing on a printer or its scanning by a scanner. The first key 72 makes it possible to correct this dimension L0 in the first corrective dimension L1, which will be equal in the example of FIGS. 2 and 6 to 5900 mm to be equal to the dimension C1 of 590 cm indicated on the plane P. The first The key 72 thus makes it possible to return to FIG. 6 a corrected scale value equal to this correction multiplying factor FCL in the memory 9, to take account of the dimensional deformations of the plane P with respect to the scale it indicates.

When the user wishes to measure any dimension L2 delimited by reference marks of the plane, such as for example another dimension C2 delimited by the marks R1 and R3 and whose value is indicated on the plane P, and / or another dimension C3 delimited by the marks R3 and R4 and whose nominal value is not indicated on the plane P, the user moves the second spout 5 on the support 2 in a second selected position, different from the first position or identical to the first position , relative to the first spout 3, and applies the first and second ends 31, 41 of application being in this second position against the second references of the plane delimiting this second dimension (R1, R3 or R3, R4 in the examples below). above).

The computer 8 is programmed to calculate the second dimension L2 of the plane corresponding to the second selected position. The second dimension L2 of the calculated plane is corrected by the measurement variable D supplied by the sensor 5, multiplied by the multiplying factor FCL of correction. Thus, the second dimension L2 of the calculated plane is equal to a constant near B to the measurement variable D supplied by the sensor 5, multiplied by the correction multiplying factor FCL, that is to say that L2 = D. FCL + B, where the constant B is determined and may be zero or non-zero and may be the opposite of a reference dimension with respect to which the other scores are measured.

According to one embodiment, the second dimension L2 of the calculated plane is equal to the measurement variable D supplied by the sensor 5, multiplied by the correction multiplying factor FCL, that is to say that L2 = D. FCL, which corresponds to the constant B equal to zero in the above.

The computer 8 then controls the display unit 6 to send it the second plane dimension L2 and make it display this second plane dimension L2 corresponding to the second selected position.

The first key 72 thus makes it possible to calculate the actual scale SC of the plane (for example 1: 19.67 in FIG. 6), which is different from the nominal scale indicated on the plane (for example, 1:20 in FIG. 2). because of the dimensional deformations of the plane. This corrected real scale (or multiplication factor FCL of correction) is memorized and is used to display all the dimensions of the plane P by displacement of the second spout 4.

In a second embodiment of the measuring tool 1 and the measuring method according to the invention, the man-machine interface 7 comprises a second key 73 whose actuation by the user causes the recording in the memory 9 of a second SC scale value, which was entered by the user on the keypad 71 during a first calibration step. For example, the user can enter the nominal scale of the plane P as the second scale SC value. Even having been able to enter beforehand the nominal scale indicated on the plane P (for example, 1:20 in FIG. 2) by the second key 73 and when the user positions the spouts 3 and 4 against the R1 and R2 landmarks of the plane, the dimension LO displayed by the unit 6 (for example 6000 mm in FIG. 5) may differ from the nominal dimension C1 (for example 590 cm in FIG. 2) indicated on the plane P and separating the marks R1 and R2 from the plane P, due to uncontrolled dimensional deformations of the plane, due to its photocopy by a printer or to its printing on a printer or its scanning by a scanner.

This second embodiment can provide that the user enters, during the first calibration step, on the keypad 71 as the second scale SC value, not the nominal scale indicated on the plane P (for example 1:20 in Figure 2), but a scaled SC value (for example 19.67 in Figure 8). The user may have previously calculated this second scale value SC different from the nominal scale indicated on the plane P, by calculating itself this second scale value SC (for example 19.67) as being equal to a dimension indicated on the plane P (for example the dimension C1 equal to 590 cm between the marks R1 and R2) divided by the real distance D1 (300 mm in FIG. 5) on the plane P between the two marks R1 and R2, which can be measured for example in FIG. 7 using the measurement tool 1 in which the second key 73 has recorded an initial SCO scale value equal to one (the second SC scale value being set by default to the value one). The second scale SC value, entered by the user on the keypad 71, is recorded by the computer 8 in the memory 9.

The calculator 8 and the measurement tool 1 are programmed to calculate the multiplying factor FCL correction equal to the second scale SC value stored in the memory 9, that is to say FCL = SC. The computer 8 stores the correction multiplying factor FCL in the memory 9.

Then, during a second measurement step of any L3 plane dimension, the user moves the second spout 4 on the support 2 at a position that is chosen relative to the first spout and applies the ends 31 and 41 in this selected position against marks of the plane P, whose L3 dimension separating these marks is to be measured (for example the dimension L3 delimited by the marks R3 and R4 on the plane P in FIG. nominal value is not indicated on the plane P).

The computer 8 is programmed to calculate the L3 dimension of the plane corresponding to this chosen position. The calculated plane dimension L3 is corrected by the measurement variable D supplied by the sensor 5 in the selected position, multiplied by the correction factor FCL stored in the memory 9.

Thus, the dimension L3 of the calculated plane is equal to a constant B close to the measurement variable D supplied by the sensor 5, multiplied by the correction multiplying factor FCL, that is to say that L3 = D. FCL + B or L3 = D. SC + B, where the constant B is determined and may be zero or non-zero and may be the opposite of a reference dimension with respect to which the other scores are measured.

According to one embodiment, the dimension L3 of the calculated plane is equal to the measurement variable D supplied by the sensor 5, multiplied by the correction multiplying factor FCL, that is to say that L3 = D. FCL or L3 = D. SC, which corresponds to the constant B equal to zero in the foregoing.

The computer 8 then controls the display unit 6 to send it the calculated planar dimension L3 and make it display this plane dimension L3 corresponding to the second selected position.

The second key 73 thus makes it possible to correct the scale of the plane P in a real scale SC making it possible to go directly from the distance measurement D1 of the sensor to the actual dimension delimited by reference marks of the plane. The second key 73 thus makes it possible to enter a corrected scale value equal to the correction multiplying factor FCL in the memory 9, to take account of the dimensional deformations of the plane P with respect to the nominal scale that it indicates. The display unit 6 may comprise a first display area 61 displaying the plane LO, L1, L3, having been calculated by the calculator 8, and a second display area 62 displaying the correction multiplying factor FCL. , having been saved in memory 9.

In the embodiments shown in the figures, the display unit 6 is fixed to the first spout 3 or the support 2. However, in other embodiments not shown, the display unit 6 can be attached to the second spout 4 mobile. Similarly, in the embodiments shown in the figures, the human-machine interface 7 is fixed to the first spout 3 or the support 2. In other embodiments not shown, the human-machine interface 7 and / or the display unit 6 and / or the computer 8 is deported in a remote telecommunication terminal. This telecommunications terminal can be for example a mobile phone, a watch, a tablet or a laptop or other.

For example, the man-machine interface 7 is included in the communication terminal, which is itself distant from a distance measuring unit in which the support 2, the first spout 3, the second spout 4, the sensor 5, the display unit 6 and the computer 8 are located.

In another example, the display unit 6 is included in the communication terminal, which is itself distant from a distance measuring unit in which the support 2, the first spout 3, the second spout 4, the sensor 5, the man-machine interface 7 and the computer 8 are located.

In another example, the computer 8 is included in the communication terminal, which is itself distant from a distance measuring unit in which the support 2, the first spout 3, the second spout 4, the sensor 5, the display unit 6 and the man-machine interface 7 are located. The distance measuring unit and the communication terminal are provided with communication means enabling them to communicate with one another via a wireless telecommunication link.

The sensor 5 can be resistive or other.

According to one embodiment, in the case of a resistive sensor, the measurement variable D supplied by the sensor 5 may for example be an electrical voltage or an electrical resistance, which varies in a monotonic manner as a function of the actual distance D between the ends 31 and 41.

For example, in the case of a resistive sensor, in FIG. 9, this sensor 5 comprises: a first conductor 51 extending from its first end 511 located on the side of the first fixed spout 3 along the direction 21 for guiding the support 2 to its second free end 512; a second conductor 52 extending from its third end 521 located on the side of the first fixed spout 3 along the guide direction 21 on the support 2 until at its fourth free end 522, a third transverse conductor 53 extending in a second direction secant with respect to the first guide direction and for example perpendicular to this guide direction.

The third transverse conductor is attached to the second movable spout 4 below it to be in contact with the two first and second conductors extending on the support 2. The electrical resistance seen by the first end 511 of the first conductor 51 and the third end 521 of the second conductor 52 varies according to the position of the second spout 4 movable along the guide direction 21, because the third transverse conductor 53 bypasses the first and second conductors 51, 52 of the support 2 in this position. This sensor 5 of the resistive type may comprise a source 54 of constant current connecting the first end 511 of the first conductor 51 to the third end 521 of the second conductor 52 and to a device 55 for measuring voltage or electrical resistance between these two ends 511 and 521 of the conductors 51, 52, the displacement of the second spout 4 on the support 2 in the guiding direction 21 varying in this case the voltage or the electrical resistance between these two ends 511 and 521 of the conductors 51, 52.

According to one embodiment, in FIG. 4, the man-machine interface 7 may furthermore comprise a third key 74 for causing the plane L-dimension to be reset for a certain other position of the second spout 4 on the support. 2, having been chosen by the user. This other reset position of the plane dimension L can correspond, for example, to a measurement variable D of a zero real distance between the first application end 31 and the second application end 41 of the nozzles 3 and 4. , as shown in FIG. 3, or at another position where the measurement variable D corresponds to a non-zero real distance between these ends 31 and 41. The calculation of the planar coordinates L by the computer 8 will then be done by subtracting of the measurement variable D of distance provided by the sensor 5, multiplied by the correction multiplying factor FCL, the reference reference LREF calculated in the said other reset position of the second nozzle 4, when the user has pressed the third reset key 74 (which may be in the above constant B = - LREF). The human-machine interface 7 may comprise a fourth key 75 causing the conversion of the plane dimension L to a measurement unit of length that can be selected from several measurement units of different lengths pre-stored in the memory 9, for example in millimeters, centimeters, meters or inches, feet, or others. The human-machine interface 7 may comprise a fifth key 76 causing the setting of one of the second SC scale value (SC = 1), as for example in FIG. 5. By default, that is in the absence of actuation of the second key 73 by the user and in the absence of actuation of the first key 72 by the user, the second scale SC value remains at the value one. For example, any entry on the keypad 71, not stored in the memory 9 within a certain time (for example five seconds or other) by pressing the button 72 or 73, is replaced by the actual value of the size D measuring distance before entering, that is to say by a displayed dimension L equal to a value calculated for the second scale SC value equal to one (in this case L = D). The measuring tool 1 may comprise a device for retaining the spout 4 movable on the support 2 in each position chosen by the user, in order to keep the movable spout 4 in this position on the support 2 below a certain threshold displacement force exerted on the spout 4 mobile. This makes it possible to apply the spouts 3 and 4 on pins of the plane P without these spouts moving relative to each other. Thus, the user must exert a displacement force greater than this threshold of retaining force, to move the spout 4 again with respect to the first spout 3. The measuring tool 1 for example may for example have a measurement range. actual distance D between the ends 31 and 41 of 0-150 mm, or 0-300 mm, or 0-500 mm or other. The tool 1 measurement may include a snap point. The support 2 may for example be plane.

The support 2 may comprise a limit stop 100 for the movable spout 4, away from the first spout 3. The measuring tool 1 may comprise an autonomous power supply, such as for example an electric battery or an electric battery, can be removable and rechargeable energy or non-rechargeable energy. The battery or battery can be recharged for example by a photovoltaic cell provided on the measuring tool 1, for example on the top of the support 2 or on the top of another element of the tool 1. The unit 6 d The display may include a backlight that can be turned on by pressing a sixth backlight key 77. In addition, the measuring tool 1 may comprise an outward illumination device, for example oriented towards the underside of the support 2 to illuminate the plane P, which can be actuated by the backlight key 77 or by another touch.

The backlight can be operated for a limited time, for example can be a minute or other. The display unit 6 can switch to a standby mode after a prescribed duration of display without modification of measurement or input, which can be for example three minutes or other. The measurement tool 1 may furthermore comprise a seventh key 78 for starting and stopping the measuring tool 1. The measuring tool 1 may also include a lighting device of the man-machine interface 7. The man-machine interface 7 and / or the keypad 71 and / or the aforementioned key (s) may be formed of buttons or be formed of tactile keys displayed on a screen, or more generally control ( s) manual (s).

The computer 8 may be programmed by a computer program (stored in the memory 9 or the like) having code instructions for performing the above-described steps of one and / or the other of the measurement methods.

With reference to FIGS. 10 to 12, a measuring method for measuring dimensions L2 on a virtual document P displayed on the screen E of the machine T, a computer program, a computer application and the machine is described below. T having a screen E for displaying a virtual document P.

The machine T can be a mobile phone, a telecommunications terminal, a digital tablet, a computer or others. The machine T may include as man-machine interface 7 a touch keyboard displayed on the screen E, whose keys are actuated by pressing on a finger of the user.

During a first calibration step, first and second virtual points 31, 41 are moved on the virtual document P displayed on the screen E respectively in the first and second positions R1, R2 selected and distinct from each other. the other (the positions R1, R2, R3, R4, which can be generally the marks as indicated above on the virtual document or virtual plane P). In the machine T, the man-machine interface 7 is able to move the first and second virtual points 31 and 41 on the document P to the screen E respectively in the first and second positions R1, R2 or R3, R4, or other selected and distinct from each other, so that the sensor 56 measures each time the distance D1 or D2. During the first step, the distance sensor 56 of the machine T measures a first non-zero distance D1 on the virtual document P between the first and second positions R1, R2 where the first and second points 31, 41 are located. distance sensor 56 is configured to measure the distance existing on the virtual document P between the first virtual point 31 and the second virtual point 41, with reference, for example, to a prescribed dimension reference of the document, which may be, for example, its width or length or others. This distance sensor 56 can be realized by any known program or computer function. It is entered on the keypad 71 of the machine T of the interface 7 (which may for example be a touchpad, displayed on the screen E or being a physical numeric keypad of the machine, separate from the screen E) a first L1, represented by the first distance D1 between the first and second positions R1, R2. Or during the first calibration step, it is entered on the keypad 71 of the machine T Sc scale value.

Then, during a second step of measuring a second dimension L2 on the virtual document P, the first and second points 31, 41 are moved on the document P on the screen E respectively in the third and fourth positions R3, R4 chosen and distinct from each other. The distance sensor 56 of the machine T measures a second distance D2 on the document P between the third and fourth positions R3 and R4, to which are the first and second virtual points 31 and 41. A calculator 8 of the machine T calculates the second dimension L2, represented by the second distance D2 between the third and fourth positions R3 and R4. The second dimension L2 is corrected by the first dimension L1, multiplied by the second distance D2 and divided by the first distance D1 or is corrected by the second distance L2 multiplied by the scale SC value. Then the second dimension L2 is displayed on the screen E or on the virtual document P. According to one embodiment, the second dimension L2 is displayed between the third and fourth positions R3 and R4 or close thereto. This display can be automatic and triggered by the positioning of the first and second points 31 and 41 in the third and fourth positions R3 and R4. The keypad 71 and / or the key 72 and / or 73 may not occur in the second step.

According to one embodiment, during the first step, at least the key 72 or 73 of the man-machine interface 7 is actuated to cause the recording, in the memory 9, of the first dimension L1 having been entered or Scale SC value has been entered. Then the calculator calculates the multiplying factor FCL of correction, as being equal to the first corrective dimension L1, divided by the first distance D1 and stores the correction multiplying factor FCL in the memory 9. During the second step, the second dimension L2 is calculated by the calculator 8 as being corrected by the second distance L2 multiplied by the correction multiplying factor FCL, or as being corrected by the second distance L2 multiplied by the scaling value SC.

The computer program of the machine or the computer application of the machine (in particular one of the machines indicated above) comprises code instructions for the implementation of the measuring method, when it is executed on a machine. processor of the machine T.

Claims (9)

1. Measuring method for measuring dimensions (L2) on a virtual document (P) displayed on a screen (E) of a machine (T), characterized in that - during a first calibration step. moving first and second points (31, 41) on the document (P) to first and second positions (R1, R2) selected and distinct from each other, a distance sensor (56), the machine measures a first non-zero distance (D1) on the document (P) between the first and second positions (R1, R2) where the first and second points (31, 41) are located, and is entered on a keypad ( 71) of the machine (T) a first dimension (L1), represented by the first distance (D1) between the first and second positions (R1, R2), or during the first calibration step is entered on the block numeral (71) of the machine (T) a scale value (SC), - then in a second step of measuring a second dimension (L2) on the document (P), the first and second points (31, 41) are moved on the document (P) respectively in the third and fourth positions (R3, R4) chosen and distinct from each other , the distance sensor (56) of the machine (T) measures a second distance (D2) on the document (P) between the third and fourth positions (R3, R4) where the first and second points (31, 41) are located. ), a calculator (8) of the machine (T) calculates the second dimension (L2), represented by the second distance (D2) between the third and fourth positions (R3, R4), the second dimension (L2) being corrected by the first dimension (L1), multiplied by the second distance (D2) and divided by the first distance (D1) or corrected by the second distance (L2) multiplied by the scale value (SC), and the second dimension ( L2) is displayed on the screen (E), the man-machine interface (7) further comprising a third reset key (74) ro of the second dimension (L) for some other position of the second virtual point (5) on the screen (E) on the document (P), having been chosen by the user. 2. Measuring method according to claim 1, characterized in that during the first step, at least one key (72, 73) is actuated to cause the first dimension to be recorded in a memory (9). (L1) having been entered or of the scaled value (SC) having been entered, then the calculator calculates a correction multiplying factor (FCL) for the dimensions of the plane, as being equal to the first corrective dimension (U), divided by the first distance (D1) and stores the correction multiplying factor (FCL) in the memory (9), and in the second step, the second dimension (L2) is calculated by the calculator (8) as being corrected by the second distance (L2) multiplied by te correction factor (FCL) or by the scale value (SC). 3. Measuring method according to claim 2, characterized in that when the user has pressed the third reset key (74), the calculator (8) calculates the second dimension (L) by subtracting from the second distance (D2) provided by the sensor (5), multiplied by the correction multiplying factor (FCL) or by the scale value (SC), the reference (LREF) dimension calculated in said other reset position. 4. Measuring method according to any one of the preceding claims, characterized in that the machine (T) is one of a mobile phone, a telecommunications terminal, a digital tablet, a computer. 5. Measuring method according to any one of the preceding claims, characterized in that the virtual document is or comprises a virtual plane. A computer program comprising code instructions for implementing the measurement method according to any one of the preceding claims, when executed on a processor of the machine. 7. A mobile phone computer application, comprising code instructions for implementing the measurement method according to any one of claims 1 to 5, when the application is executed on a mobile phone processor. 8. Machine comprising a screen (E) for displaying a virtual document (P), characterized in that it comprises - a human-machine interface (7) able to move the first and second points (31, 41) on the document (P) in respectively first and second positions (R1, R2) chosen and distinct from one another, a distance sensor (56) for measuring a first non-zero distance (D1) on the document (P ) between your first and second points (31, 41), the human-machine interface (7) having a keypad (71) for entering a first dimension (L1), represented by your first distance (D1) between your first and second second positions (R1, R2), or to enter a scale value (SC), - the man-machine interface (7) being able to move the first and second points (31, 41) on the document (P) in respectively third and fourth positions <R3, R4) selected and distinct from each other, the distance sensor (56) e of your machine (T) being able to measure a second distance (D2) on the document (P) between the third and fourth positions (R3, R4) where are the first and second points (31, 41), the machine including a calculator (8) to calculate a second dimension (L2), represented by your second distance (D2) between your third and fourth positions (R3, R4), your second dimension (L2) being corrected by your first dimension (L1_) multiplied by your second distance (D2) and divided by the first distance (D1) or corrected by the second distance (L2) multiplied by the scale value (SC), the calculator (8) causing the display of your second dimension (L2) on the screen (E), the man-machine interface (7) further comprising a third key (74) for resetting the second dimension (L) for some other position of the second virtual point ( 5) on the screen (E) on the document (P), having been chosen by the user. 9. Machine according to claim 8, characterized in that the interface (7) man-machine comprises at least one key (72, 73) to cause the recording in a memory (9), your first rating (L1 ) having been entered or the scaled value (SC) having been entered, the calculator being configured to calculate a correction multiplying factor (FCL) for the plan dimensions as being equal to the first corrective rating (L1), divided by the first distance (D1) and for storing the correction multiplying factor (FCL) in the memory (9), the calculator being configured to calculate the second dimension (L2) as being corrected by the second distance (L2) multiplied by the multiplying factor (FCL) of correction or by the value (SC) of scale.