DE19649877A1 - Process for processing an interferometric signal to measure a force - Google Patents

Abstract

A force such as a vehicle wheel (4) moving over an optical fibre (2) causes a phase shift in one of two light waves in the fibre, the light waves having differing polarisation (Ev, Eh). This phase shift results in a series of extrema in the fringe pattern produced when the two light waves are recombined in an interferometer (Fig.2, not shown). The method of measurement comprises steps consisting in digitizing (30) the interferometer signal (S) so as to extract (33) a chronological succession of amplitude extrema in digital form, processing (34) the succession of extrema so as to obtain a corresponding chronological succession of first data items representative of variation in phase rotation over time, and using a physical model relating phase rotation to force for processing (35) the succession of first data items so as to obtain a corresponding chronological succession of second data items representative of variation in force over time.

Description

The invention relates to a method for Processing an interferometric signal for measurement a force with the help of birefringence, which is through force action is induced in a light guide.

The invention relates generally to the Ver traffic monitoring and especially on the weighing of moving vehicles Vehicles.

The principle of measuring a force with the aid of the birefringence induced by the action of force on an optical fiber or a mono-mode optical fiber is known. Fig. 1 shows very schematically the various elements of a piezo-optical measuring probe, which measures a force according to this principle. A light beam with polarization along a straight line egg, which is generated by a laser diode 1 , is injected into the optical fiber 2 via a polarization separator 3 , which separates this light beam into two waves, the polarizations of which are in quadrature, namely an Ev in the (vertical) direction in which the force to be measured acts on the optical fiber and the other direction in the direction perpendicular to it. Since the polarization is retained in the case of monomode propagation, both waves propagate independently and as a function of the optical index corresponding to the direction of polarization. The difference in the optical sections of the two waves therefore depends on the difference in the directional forces along the section. A change in the birefringence of the optical fiber due to a dynamic force such as. B. the tire 4 of a vehicle that drives over the optical fiber, thus causes a relative phase shift between the two waves (where this phase shift increases with the force, then settles at a certain level when the force is at its maximum in the vertical direction has, and finally decreases, the further the force decreases, ie when the tire leaves the optical fiber). In the construction of FIG. 1 is flexed, the incident light beam from a mirror 5 re, which is arranged at the end of the optical fiber, and then collected on the polarization 3 of a Erfas sung photo diode 6. The interferometric electrical signal S resulting from the additive recombination of the two waves at the level of the detection photodiode 6 has an instantaneous amplitude level, which changes as a function of the instantaneous relative phase shift between the two waves Ev and Eh.

Fig. 2 shows the general form of an interferometric signal S. This signal has an amplitude level which, over an interference period T, which corresponds to the influence of the force, has a sequence of maxima and minima which define polarimetric lines. One can see in this figure, starting from the origin of the time t, a first sequence of polarimetric lines, which corresponds to the angular increase in the phase shift, then a central polarimetric line, which corresponds to a maximum angle of the phase shift, then a second sequence of polarimetric lines , which corresponds to the angular decrease in the phase shift.

In the document EP-0 153 997 was already before struck, the number of polarimetric lines too tough len that are present in an interferometric signal to measure a force according to the principle given above. However, such a method has an accuracy that is necessary for the Measuring moving vehicles is not suitable. A one counting polarimetric lines by definition has namely only an accuracy limited to ± 0.5 lines, the uncertainty of precision being a few percent of the measuring force can represent.

The aim of the invention is to provide another method for  Propose processing of the interferometric signal, by a force, especially a dynamic load measure up.

For this purpose, the invention has a method for Processing an interferometric signal for measurement a force with the help of loading into a light line ter induced birefringence to the subject, which thereby is characterized by the following steps:

• - Digitization of the interferometric signal in order a chronological sequence of extreme amplitude values in di gital form,
• - Processing this sequence of extreme values in order to corresponding chronological sequence of first data on it consider that a temporal profile of a phase shift are representative,
• - Processing of this sequence of first data based on a physical model that is the phase shift in connection with the force, so that one corresponds appropriate chronological sequence of second data that are representative of a temporal profile of the force.

The invention takes advantage of the fact that the expression the phase shift Φ between the waves Ev and Eh, the from the application of a directed pressure load P via a length L of an optical fiber of a piezo-optical measuring probe arises that has the form:

(1) Φ = KP ^α L

where K and α are constants that depend on the properties of the depend on the piezo-optical measuring probe (geometry of the light guide fiber, elasticity of silicon oxide, wavelength of the laser source, etc.). These constants can be calibrated tion of the piezo-optical probe can be obtained with known weights is performed.

In addition, the current amplitude level has I (t) the form of the interferometric signal

(2) 1 (t) = A + BcosΦ (t)

where Φ the phase shift between the two waves Ev and Eh represents and A and B are constant (A and B become starting from the equations A = (Imax + Imin) / 2 and B = (Imax-Imin) / 2 calculated in which Imax and Imin the maximum Mit tel value or the minimum mean of the interferometric Signal over a period of interferential activity). This phase shift actually corresponds to a pha counterclockwise rotation while the load is on rises, and clockwise again as soon as the load decreases. By deriving expression (2) over time, one sees that the relative extreme values of the signal I (t) either exceeding an angle determination (Φ = kΠ) or an extreme value of the phase shift (dΦ / dt = o) chen.

One can see on the basis of equations (1) and (2) consequently, that a time profile of a dynamic force (defi nated by different values of P depending on the Time) from the time profile of a phase shift corresponding to the Phase shift Φ can be derived, this Time profile of the phase shift simply for the extreme values of the interferometric signal is determined.

According to a special feature of the Ver driving, the processing of the extreme values consists of alternating an extreme value at the beginning of the sequence of extreme values and an extreme value at the end of this sequence of extreme values to be taken into account by switching to Middle of this sequence of extreme values continues to the Follow the first data to get that for a time profile the phase rotation are representative.

This processing takes advantage of the fact that the time profile of the phase shift is based on a rest value and there after going through a corresponding measure ximal value returns, which is typically the extreme value of the middle in the simple case of a time profile in the form of a bell-shaped curve.  

With a more complex phase shift profile in The shape of a saddle corresponds to the maximum of the phase rotation not necessarily the central extreme of the sequence of Am extreme values of the interferometric signal, and one must consider every extreme value as exceeding a win kel determination or a maximum of the phase rotation correspond identify accordingly. However, this ambiguity can be a can be eliminated by determining that an over the angle determination exceeds an extreme value close to the Limits (A + B) or (A-B). Conversely ent generally speaks a maximum of phase rotation observed extreme, which is far outside of this limit te lies.

The invention is described below with reference to the drawings explained in more detail.

Fig. 1 shows schematically a piezo-optical Messson de.

Fig. 2 shows an example of an interferometric signal.

Fig. 3 is a flowchart illustrating the main steps of the inventive method.

Fig. 4 shows another example of an interferometric signal.

FIG. 5 shows in a curve the time profile of the phase rotation obtained for the signal of FIG. 4.

Fig. 6 is a detailed flow chart of the step of forming the time profile of the phase rotation.

According to the measurement method according to the invention a force, especially a dynamic force a time profile of this load based on a time pro fil of a phase shift that itself based on amplitude the extreme values of the interferometric signal becomes. Compared to a simple polarime counting tric lines you get to a much higher measurement accuracy on the order of 0.01 lines. As part of  the application to the weighing of moving vehicles also illuminates the time profile of the dynamic load, more precisely to infer the value of the static force, since a sol ches the dynamic effects of the suspension, the Acceleration etc. on shows, then for determination the static force can be taken into account.

Referring to FIG. 3, the inventive method begins processing an interferometric signal S with a step 30, the digitization of the signal.

Step 30 is preferably followed by a step of digital filtering 31 , which enables a reduction of the interference signals by smoothing the digital interferometric signal.

Step 31 is followed by step 32 of detection the beginning and end of the period of the interference activities interferometric signal in digital form. The Detection of the beginning and end of the interference activity can for example on a logic for monitoring the eyes visible level of the digital signal and on a ver equal to this current level with a medium one Levels of the digital interferometric signal are based on that measured in the absence of a force and after each interfe activity period is updated.

Step 32 is followed by step 33 of processing of samples used for interference activity peri ode of the digital signal were formed to those too record that correspond to extreme amplitude values.

Fig. 4 shows the time course of the amplitude level of an interferometric signal. The beginning and end of the interference period are marked with D and F respectively. The extreme amplitude values are with Ext (1),. . . , Ext (n), where Ext denotes a vector which is ordered according to the chronological sequence of extreme amplitude values. In this figure, the extreme value Ext (j) corresponds to a maximum of the phase rotation.

The chronological sequence of extreme values in the vector Ext is processed in step 34 to provide a corresponding one determine chronological sequence of data required for a Time profile of a phase shift are representative. It is note that step 34 also requires each ex tremwert its temporal position in the interference period assign to the time profiles of the phase shift and the Win load. For the sake of clearer description below the timing of the extreme values is not taken into account left calm.

Fig. 6 shows the processing which takes place in step 34. In this figure, PHI denotes the vector in which the chronological sequence of data is ordered, which is representative of the time profile of the phase shift. The vector PHI contains the different values of the corresponding phase shift corresponding to the extreme values of the vector Ext. The processing 34 simply consists of a loop with indices ig (which point to the beginning of the vector Ext) and id (which point to the end of the vector Ext), which are initialized to 1 or n in step 61 (where n indicates the number of extreme values in the vector Ext), alternating with an index extreme value ig of the vector Ext, in order to determine in step 62 a discrete value PHI [ig] which corresponds to the phase shift corresponds, and an extreme index value id of the vector Ext be taken into account in order to determine in step 63 another discrete value PHI [id] of the phase rotation. The indices id and ig move together in step 64 to the center of the vector Ext. If the index ig becomes greater than or equal to the index id, which is determined by comparison in step 65, the processing exits the loop and sets continues in step 66. The test id ig is preferred and not the test id = ig to exit the loop, even if the number n of detected extreme values happens to be even, although this number is normally odd.

In step 62, the rank ig is used Extreme value directly to determine the corresponding value the phase shift. The same applies to the index in step 63 id. At this stage of processing is only the maximum Phase rotation value not determined. It will be in step 66 based on the value of the phase shift without loading on the Based on the following relationship:

(3) PHI [id] = PHI [id-1] + arccos ((Ext [id] -A) / B) - Φo where Φo is the value of the phase shift without load. Of the Value Φo depends on the settings of the piezo-optical measuring probe and can be any. It is through an analysis of the average level Io of the interferometric signal without Stress is estimated based on the following relationship:

(4) Φo = Arccos (Io-A) / B

In step 65, id and ig correspond to index j in FIG. 4, ie they point to the extreme value in the middle of the sequence of extreme values.

FIG. 5 shows the shape of the time profile obtained for the interferometric signal of FIG. 4. It is a simple bell-shaped curve. One has PHI [1] = Π, PHI [2] = 2Π, PHI [3] = 3Π, PHI [n] = Π.

The processing represented by the flowchart of FIG. 6 can be refined in the case of a more complex time profile of the phase rotation. In this case, the value of the extreme value Ext [ig] or Ext [id] must be compared with the values A + B or AB in steps 62 and 63 (see FIG. 4). If this extreme value is close to AB or A + B, it is an extreme value that corresponds to an excess of the phase shift, and the rank ig or id of the extreme value is used to determine the value of the phase shift. In the opposite case, the data value PHI [ig] or PHI [id] is assigned a special value, for example 0, which can easily be obtained by analyzing the vector PHI. The vector PHI is then processed to replace these particular values with values calculated based on relationship (3).

After step 34 in FIG. 3, the vector PHI is processed in step 35 to obtain a final chronological sequence of data representative of the time profile of the load based on the following relationship:

(5) P [i] = (PHI [i] / KL) ^{1 / α}

where P denotes the vector that this last chronologi contains a sequence of data.

It should be noted that the value of the force or the dynamic load of the specification of the maximum value in the vector P ent speaks.

Claims (3)

1. A method for processing an interferometric signal (S) for measuring a force with the aid of the birefringence induced by the action of force on a light guide, characterized in that it has the following steps:

• - Digitization ( 30 ) of the interferometric signal in order to extract a chronological sequence of extreme amplitude values in digital form,
• - processing ( 34 ) this sequence of extreme values in order to obtain a corresponding chronological sequence of first data which are representative of a temporal profile of a phase shift,
• - Processing ( 35 ) of this sequence of first data based on a physical model that relates the phase rotation to the force, so that a corresponding chronological sequence of second data is obtained which is representative of a temporal profile of the force.

2. The method according to claim 1, characterized in that the processing of the extreme values consists in taking into account ( 62 ) an extreme value of the beginning of the sequence of extreme values and ( 63 ) an extreme value of this sequence of extreme values and with each change to To proceed in the middle of this sequence of extreme values in order to obtain the sequence of the first data (PHI), which are representative of a time profile of the phase shift. 3. The method according to claim 2, characterized in that the extreme value taken into account during processing as egg ner exceeding the angle determination of the phase rotation is identified accordingly, the rank of this Ex  trem values in the sequence of extreme values serves one to determine the value corresponding to the phase rotation.