FR2649480A1 - Method for measuring stability of the perforations on a product in strip form and device for implementing the method - Google Patents

Abstract

The invention relates to a method of checking the positioning of the perforations on a perforated strip, as well as a device for implementing the method. The invention consists in calculating, for a photodiode arranged on one of the edges of the perforation and receiving both a quantity of light transmitted through the film and a quantity directly transmitted through the perforation, the proportions of each of these quantities. Application to the checking of photographic films.

Description

METHOD FOR MEASURING STABILITY OF PERFORATIONS
ON A STRIP PRODUCT AND DEVICE
FOR IMPLEMENTING THE PROCESS
The invention relates to a method for checking the longitudinal and transverse positioning of the perforations on a perforated strip of the photographic film type, as well as its implementation device.
In general, a photographic film has at each of its longitudinal edges a row of perforations which are used during projection for driving the film by means of toothed wheels cooperating with said perforations. A bad arrangement of these perforations both in the transverse direction and in the longitudinal direction inevitably results in a poor stability of the image during projection. This instability, when it responds to certain frequencies, (frequencies at which the eye is particularly sensitive) is annoying for the viewer. Hence the interest in accurately measuring this positioning of the perforations in order to be able to eliminate the films whose perforations do not meet acceptable standards of stability.

 In the prior art, this control was carried out mainly by means of a direct inspection of the perforated strip by an operator. In reality during the standard projection of a photographic film, the perforated parts of the film are masked so that only the image part of the film is visible on the screen. During an inspection of the stability of the perforations, the entire width of the film is visualized, including the perforations. An image of one of the edges of the perforation is formed on a scale of graduations. One can thus observe in dynamics the differences in positioning of the perforations compared to an average position. This type of control has the disadvantage, in addition to being tedious for the operator, of not being very reliable and of not be able to be used to, in particular, determine the origin of the defect.

 It is therefore one of the objects of the present invention to provide a device and a method for controlling the positioning of the perforations on a photographic film making it possible to replace the tedious control carried out by an operator.

 Another object of the present invention is to provide precise control as to the positioning deviation of the perforations.

 It is yet another object to be able to allow processing of the information obtained during the control, such as for example frequency processing.

 Other objects of the present invention will appear during the description which follows.

The invention therefore relates to a method for verifying the positioning of the perforations on a perforated strip of the photographic film type in which the strip is driven in front of a lighting station by means of a suitable drive device cooperating with said perforations and in which is sequentially formed on an appropriate support an image of at least one perforation distant from those cooperating with the drive device, said method being characterized in that it comprises the following additional steps
a) measure the current 1M resulting from the light received
by a first DM photodiode placed on one of
edges (1) of the image of the perforation, part of
the light received being transmitted # directly to the
through the perforation, the rest being transmitted to the
through film
b) measure the current IW resulting from the light received
by a second DW photodiode arranged to be
illuminated directly through the perforation
c) measure the current IG resulting from the light received
by a third DG photodiode arranged to be
lit through the film
d) determine a coordinate of the perforation in
calculating, for the photodiode DM, the proportions
of light transmitted directly through the
perforation and respectively through the film.

The invention also relates to a method for measuring the positioning of a perforation, characterized in that it further comprises the following steps
1) measure the current IM, resulting from the light
received by a DM photodiode, located on one of
edges perpendicular to the edge (1) of the image of the
perforation, part of the light being transmitted
directly through the perforation, the rest
being transmitted through the film
2) determine another coordinate of the perforation in
calculating, for the photodiode DM ,, the proportions
of light transmitted directly through the
perforation and respectively through the film.

The invention also relates to a device making it possible to check the positioning of the perforations on a perforated strip of the photographic film type which is driven in front of a lighting station by means of an appropriate device, an image of at least one distant perforation. of those cooperating with the drive device being formed sequentially in an image area, said device being characterized in that it comprises
a) detection means positioned in the area of
image formation and including
i) at least one photodiode (DM; DM,) generating
a total current <1M; IM,) and arranged on
one of the edges of the image of the perforation, a
part of the light received by the photodiode
(DM ;;
being transmitted directly through the
perforation, the rest being transmitted through
from the film
ii) a photodiode (Dw) generating a current
and arranged so that it is directly lit
through the perforation
iii) a photodiode (DG) generating a current IG
and arranged to be lit through
from the film
b) electronics intended to calculate, for the
photodiode (DM ;; Dom,) the proportions of light
transmitted directly through the perforation
and respectively through the film, determining
thus at least one coordinate for said perforation
The following description will be made with reference to the drawings in which - FIG. 1 shows in simplified form the device
general implementation of the invention - FIG. 2 represents the shape of the signal generated by the
photodiodes used for the implementation of
the invention - FIG. 3 illustrates a possible arrangement of the
photodiodes forming the device according to this
invention - FIG. 4 represents a possible diagram of
the electronics used for signal processing
from photodiodes arranged according to this
invention.

 Fig. 1, to which reference is now made, shows in a simplified manner the general device for implementing the invention.

This device mainly comprises a projection device which has been shown in a simplified manner and mainly comprising: - an illumination device (40) intended to illuminate the
film (41), previously grayed out, in order to form a
picture. This device illuminates the film throughout
width including perforations.

- A shutter system (42) intended to mask
the illumination when moving the film to move to
the following image. The shutter frequency is
48 Hz.

- A device (43) for driving the film which can be
in the form of a toothed wheel and which cooperates with the
perforations (44) of the film. The training of the film is
actually does it step by step, producing in front of the area
of illumination a rate of 24 images per second. In
the embodiment shown in FIG. 1, the
drive device is placed upstream of the area
of illumination (40) so that the perforations
(44) of which the image is formed are distant from those
cooperating with the drive device (by
example, 20 offset perforations).

- An image area (45) where one forms, between each
passage of the shutter, an image of the perforations.

- A detection device (46) comprising an arrangement
photodiodes, which will be discussed in more detail by
which is placed at the level of the
image formation. These photodiodes receive a
light intensity and generate a current in response
electric. Fig. 2 represents the shape of the signal
generated by said photodiodes.

 Fig. 3, to which reference is now made, illustrates a possible arrangement of the photodiodes for implementing the method according to the invention.

The photodiodes are, in one embodiment, arranged on a plate which is placed at the level of the image formation zone. This arrangement of photodiodes comprises - a first photodiode DW generating a current IW and
arranged so that it is lit only
through the perforation (white light), said
photodiode giving a reference value for the
light transmitted through the perforation ;; - a second photodiode DG generating a current IG and
arranged so that it is lit only
through the film (gray light), said photodiode
giving a reference value for light
transmitted through the film - a third photodiode DM generating a current 1M
and arranged on one of the edges (1) of the image of the
perforation so that it is partly
lit through the gray part of the film and
part directly through the perforation. The
position variations of the perforation in the direction
longitudinal correspond to variations in
proportions of light transmitted directly through
of the perforation and respectively through the film.

In one possible embodiment, a coordinate of
the perforation is obtained by determining the length X
of the portion of the diode DM which is directly
illuminated through the perforation.

 The currents 1M c, r # are amplified and normalized so that, for the same light intensity received, the voltages from the amplification stages (30, 31, 32; fig. 4) are equal.

We have then
M = WX + (1 - X) G either
x = M # G
WG
X, as calculated here, actually corresponds to the percentage of the length of the diode DM which is illuminated directly through the perforation.

 Variations in X, we then deduce the variations in longitudinal positioning of the perforation.

 It is obvious that the length of the DN diode must be related to the amplitude of the deviations that we are supposed to observe. Indeed, this diode must be longer than the maximum amplitude of the deviations that one obtains, but for reasons of precision, it must not be too long. Thus in one embodiment, this diode DM has a length of the order of 10 cm, for a maximum deviation of the perforation of the order of 2 cm.

 It is also obvious that another Y coordinate can be obtained in a similar manner by using an additional diode DEY ,, arranged on one of the edges perpendicular to the edge (1). This coordinate will make it possible to visualize the transverse positioning deviations of the perforation.

Fig. 4, to which reference is now made, represents a possible diagram of the electronics used for processing the signals from the photodiodes arranged according to the invention, DN being one of the diodes arranged on one of the edges of the image of the perforation,
DG being the photodiode receiving the light transmitted through the film and DW being that receiving the light transmitted directly through the perforation. The currents IN IN XIW emanating from these diodes D
G 'WM'
DG 8 DW are amplified respectively in conventional current amplifiers 30, 31, 32. By playing on the gains of these amplifiers 30, 31, 32, - by means of variable resistances, we normalize the currents 1M> IN 'IN so that , for the same light intensity received, the voltages M, G, W coming from said amplification stages are equal. At the output of these amplifiers, the resulting voltages M, G, W are subtracted two by two in differential amplifiers 33, 34, at the output of which we obtain (M - G) and (W - G) respectively. Before going further in the description of the electronics used, it should be remembered that the light received by the photodiodes is pulsed light. In reality, there are 24 images per second and a shutter frequency twice as large, i.e. frequency of 48 Hz, which corresponds to the frequency of the light pulses received by the photodiodes. During the shutter periods, the three photodiodes are not directly lit and actually receive the same amount of ambient light. This implies that the terms
MG and WG are zero, hence the indeterminacy as to the relationship between these terms. To solve this problem, before dividing these terms, they are filtered using low-pass filters 35, 36 which are adjusted with a cut-off frequency of 24 hz. These terms are then divided between them by means of a divider 37. The output of the divider (MG) / (WG) is then amplified in an amplifier 38 whose output provides a coordinate of the perforation considered. In a possible embodiment, the components 30, 31, 32 are of the type BB3542 (BURR BROWN), the components 33, 34, 35, 36, 37, 38 are of the type TL 081 (TEXAS).

 Likewise when using a second on-board diode DM. in order to have at the same time a vertical coordinate and a horizontal coordinate, the principle of the electronics used remains the same, except that it has one more stage for this time calculate the term (M'-G ) / (WG). Such electronic stages are well known in the art and the invention is obviously not limited to the embodiment which has just been given.

 It should be noted that with the embodiment which has just been mentioned, the coordinate or coordinates which one obtains corresponds to the length of the portion of the diode DM and / or DM, which is illuminated directly through the perforation. But it is quite obvious, that with a similar calculation, one would obtain a coordinate corresponding to the length of the portion of diode lit through the film.

 The results obtained can then be viewed on a plotter and / or can be subject to additional processing such as frequency processing which can be used to more easily determine the origin of the positioning defect.

 The invention which has just been described is particularly advantageous in that the precision of the results obtained, as regards the positioning deviations of the perforations, is completely independent of the variations in density of the film or the variations in the intensity of illumination.

Claims (3)

1 - Device for checking the positioning of  perforations (44) on a perforated strip (41) of the type  photographic film, which is taken to a post  lighting (40) by means of a suitable device  (43), an image of at least one perforation, distant  of those cooperating with the drive device,  being formed sequentially into an image area (45),  said device being characterized in that it  understands  a) detection means (46) positioned at the level  of the image formation area and comprising:  i) at least one photodiode (DM; Dom,)  generating a total current <1M; I,) and  arranged on one of the edges of the image of the  perforation, part of the light received  by the photodiode (DM; DM.) being  transmitted directly through the  perforation, the rest being transmitted to the  through film  ii) a photodiode (DW) generating an IW current  and arranged to be lit  directly through the perforation  iii) a photodiode (DG) generating a current IG  and arranged so as to be illuminated at  through film  b) electronics intended to calculate, for the  photodiode (DM ;; DM1) the proportions of  light transmitted directly through the  perforation and respectively through the film,  thus determining at least one coordinate for  said perforation. 2 - Method for verifying the positioning of  perforations (44) on a perforated strip (41) of the type  photographic film in which the strip is driven in front of a lighting device (40) by means of a suitable driving device (43) cooperating with said perforations and in which an image is sequentially formed, on a suitable support (45) , at least one perforation, distant from those cooperating with the drive device (43), said method being characterized in that it comprises the following additional steps a) measuring the current 1M resulting from the light  received by a first photodiode DM arranged on  one of the edges (1) of the image of the perforation, a  part of the received light being transmitted  directly through the perforation, the rest  being transmitted through the film b) measuring the current IW resulting from the light  received by a second photodiode Dw arranged for  be illuminated directly through the  perforation c) measure the 1G current resulting from the light  received by a third DG photodiode arranged  to be illuminated through the film; d) determine a coordinate of the perforation in  calculating, for the photodiode DM, the  proportions of light transmitted directly to the  through the perforation and respectively at  through the film. Method for checking the positioning of the perforations, according to claim 2, characterized in that it further comprises the following steps 1) measuring the current IM, resulting from the light  received by a DM photodiode, located on one of  edges perpendicular to the edge (1) of the image of the  perforation, part of the light being  transmitted directly through the perforation,  the rest being transmitted through the film  2) calculate another coordinate of the perforation in  calculating, for the photodiode DM ,, the  proportions of light transmitted directly to the  through the perforation and respectively at  through the film.  4 - Method for checking the positioning of  perforations according to one of claims 2 or 3,  characterized in that the currents from said  photodiodes are normalized so that for  the same light intensity received, the voltages M, G,  W from the amplification stages (30, 31, 32)  are equal.