FR2859807A1 - Object e.g. banknote, classifying device for blind person, has measuring and transformation units measuring parameter of object such that object is in uniform contact with electrical conductor units to measure objects dimension - Google Patents

Abstract

The device has electrical conductor units distributed on a surface of a support connected to a power supply (5). A measuring unit (6) and a transformation unit (7) measure a determined parameter of an object, after placing the object on the support and folding back a cover on the support, such that the object is in uniform contact with the conductor units to measure the dimension of the object. An independent claim is also included for a method of classifying objects.

Description

DEVICE AND METHOD FOR CLASSIFYING OBJECTS

  The present invention relates to a device and a method for classification of objects which find their application particularly, but not only, in the field of the recognition of banknotes by possibly portable devices and intended in particular for the blind or visually impaired.

  More specifically, the blind or visually impaired are people dependent in their daily lives with regard to the handling of money and in particular bank notes. The problem of security in their payment and greater ease in the handling of the banknote is particularly sensitive because it limits their independence in their daily lives.

  The specific materials existing in the state of the art do not provide a real practical solution to this problem: inaccuracy, difficulty of implementation, size, ...

  Various equipment has already been proposed for the recognition of the value of banknotes, and are generally divided into two major categories: industrial equipment for large-volume processing, and individual equipment for equipping individuals, particularly non-disabled persons gaudy.

  It is easy to understand that industrial-type equipment, whatever the technique used to recognize the value of the banknotes, does not meet the same needs as the individual-type equipment, and is totally unsuitable for application to individual devices intended to to be worn by a user and therefore must be particularly compact and of moderate weight.

  With regard to the individual type devices, these can generally be divided into three categories according to the technique used to recognize the value of the banknotes.

  The most classic type and the simplest is the type called template. This type of device is generally bulky because it must provide the location of all types of notes that we want to recognize. The principle of use of this type of device is to position the ticket to be recognized in one of the slots provided and to repeat the operation until the housing corresponding perfectly to the ticket is found. It is easy to understand that this type of device has a relatively low reliability. Indeed, it is sometimes difficult for the user to quickly and easily determine which is the housing that is best, especially when different types of tickets have dimensions very close to one another.

  Another type of device relies on the use of photoelectric sensors to detect the edges of the banknote and thus to measure the dimensions. This type of device has several disadvantages. The use of photoelectric sensors requires a strong power supply, thus reducing the autonomy of a portable device. On the other hand, the reliability of the device is based on the use of stops against which the ticket is positioned, which has the same drawbacks as those mentioned for devices type template. The technical solutions to avoid the use of the stops when the measurement is made by photoelectric sensors, are complex and therefore expensive.

  In addition, measurements made by such a device are often too sensitive to ambient lighting.

  Finally, a third type of device relies on the use of colorimetric techniques to determine the value of banknotes. The principle consists in measuring the quantity of colors in all or part of the ticket to be recognized. This information is supposed to be characteristic of the ticket. It is then compared to a library of values stored in the device and each associated with a banknote value. Such devices are very expensive because the determination of the amount of color (colorimetric signature) is more difficult to implement than all other techniques. In addition, such devices have a high sensitivity to light.

  The invention therefore aims to overcome the aforementioned drawbacks by providing an optionally portable device for classifying objects, including but not only its application in the field of recognition of the value of a bank note.

  The device according to the invention makes it possible to classify objects by measuring at least one determined parameter in relation to at least one given dimension of the object to be classified, said dimension being characteristic of said object, and the device being characterized in that it comprises a support on the surface of which are arranged first electrical conductor elements powered by a power supply means, a cover, means for measuring at least one electrical parameter characteristic of all of said first electrical conductor elements , and means for transforming the measurement of this electrical parameter in measurement of the determined parameter. The measurement is made after placing the object to be classified on the support, and after folding the cover on the support so that the object to be classified is uniformly in contact with said first electrical conductor elements.

  In a preferred embodiment of the device of the invention, the first electrical conducting elements are distributed on the surface of the support in at least one direction, so that the dimension of the object to be classified that will be measured is that which is oriented in this direction when the object is placed on the surface of the support.

  More specifically, in a preferred embodiment of the device of the invention, the object to be classified being electrically conductive, the determined parameter measured is the recovery rate of the first electrical conductor elements by the object.

  In another preferred embodiment of the device of the invention, the object to be classified being electrically non-conductive (for example a banknote), the determined parameter measured is the rate of non-overlap of the first electrical conductor elements by the object.

  The subject of the invention is also a method of classifying objects by measuring at least one determined parameter in relation to at least one given dimension of the object to be classified, said dimension being characteristic of said object, the method being characterized in that it consists in placing the object to be classified on a set of electrically powered electrical conducting elements, in measuring the characteristic electrical parameter of all of said electrical conducting elements, and in transforming the measurement of said electrical parameter into a measurement of determined parameter.

  In a preferred variant of the method according to the invention, the object to be classified being electrically conductive, the determined parameter measured is the recovery rate of said electrical conductor elements.

  In another preferred variant of the method according to the invention, the object to be classified being electrically non-conductive, the determined parameter measured is the non-overlapping rate of said electrical conductor elements.

  The features and advantages of the invention will appear more clearly and in a more complete manner, on reading the following description of the preferred embodiments, which 2859807 are given by way of non-limiting example and with reference to the appended drawings.

  FIG. 1a: diagrammatic representation of a first variant embodiment in the case of an object to be classified as a planar and non-conductive electric sheet, FIG. 1b: schematic representation of a first variant embodiment in the case of a object to be classified as a plane sheet and an electrical conductor, FIG. 2a: schematic representation of a second variant embodiment in the case of an object to be classified as a flat plane and an electrically non-conductive type, FIG. 2b: schematic representation of a second variant embodiment in the case of an object to be classified as a plane circle and electrical conductor, FIG. 3a: schematic representation of a third variant embodiment in the case of an object to be classified as a non-planar sheet and non-electrical conductor, - Figure 3b: schematic representation of a third embodiment in the case of an object to classify n-sheet planar and electrical conductor, - Figure 4: schematic functional representation of an alternative embodiment of the device according to the invention.

  In Figures la, lb, 2a, 2c, the object to be classified, identified by the number (11) and shown to be transparent to simplify. 10

  In Figures 3a and 3b, the device is shown in front section, lid folded.

  Referring to Figure la, according to a first embodiment of the invention is schematically shown the cover (3) non-electrically connected by the connection (8) to the support (1). The connection (8) is not essential, but allows to ensure the correct positioning of the lid (3) on the support (1) after folding the lid. A set of first electrical conducting elements (2) is arranged on the surface of the support (1). The electrically conductive elements (2) are divided into two zones, possibly but not necessarily disjoint, each being oriented parallel to the same direction (D). Each of these two zones is further subdivided into two sub-zones, deleting their respective central parts, so that the support (1) is covered with first electrical conducting elements (2) divided into four sub-zones. These four sub-areas are possibly but not necessarily disjoint. At each of the areas parallel to the direction (D) corresponds a second electrically conductive element (4) disposed on the inner surface of the cover (3). Two first electrical conducting elements (2 ') and two push buttons (9) are also shown on the surface of the support (1). Each electrically conductive element (2) is connected to an electrical resistance not shown in the figure.

  In the example of FIG. 1a, the object (11) to be classified is of the electric non-conductive flat sheet type and is characterized by its length. The object (11) is thus disposed by orienting the axis of its length in the direction D. The entire device is powered by a feed means not shown in the figure. When the lid (3) is folded onto the object (11) thus disposed on the support (1), and by exerting sufficient pressure on the lid (3), the push buttons (9) are actuated, which triggers the measurement. The second electrically conductive elements (4) are brought to a certain potential transmitted by the first electrical conducting elements (2 '). They are also in contact with all the first electrical conducting elements (2) not covered by the object (11). These electrically conductive elements (4) therefore short-circuit the resistors connected to the first electrical conducting elements (2) not covered by the object (11). In doing so, the equivalent resistance of each of the networks constituted by each of the sub-zones of first electrical conducting elements (2) is modified. This voltage is almost proportional to the number of uncovered pads. Each of these four voltages is measured by a measurement means not shown in FIG. 1a, transformed by transformation means, also not shown in FIG. 1a, into the characteristic dimension of the object to be classified. This dimension is then returned to the user by a restitution means not shown in FIG.

  Thus, each of the four sets of first electrical conductor elements (2) provides a voltage proportional to the rate of recovery by the bill of the first electrical conductor elements (2) of each of the sub-areas. By closing the cover, the first electrical conductor elements (2 ') carry the second electrical conductor elements (4) at a given potential which will be transmitted by contact to the electrical conductor elements (2) not covered by the bill. The resistor network corresponding to a sub-area of appropriately sized first electrical conducting elements (2) makes it possible to transform the length (the number of electrically conductive elements (2) brought to the potential of the second electrical conducting element (4)) into voltage whose amplitude is significant of the length to be measured. If the pressure on the cover during the measurement is not evenly distributed, the push buttons (9) are not actuated and the measurement is not triggered. On the other hand, in this configuration, the double measurement of the same dimension avoids the use of a lateral stop. . In fact, if the two measurements of the same length differ from a value greater than a predefined threshold, then this means that the characteristic dimension to be measured of the object to be classified has not been disposed correctly along the axis of the direction D. The measure will therefore be rejected. In the case where the reproduction of the characteristic information to the user is done by audio, the rejection of the measurement may result in a predetermined message or a sound signal for example. Finally, the distribution of the first electrical conducting elements (2) of each of the zones over the entire length avoids the use of a longitudinal stop, since the object (11) can be positioned at any level in the direction ( D), without disturbing the measurement.

  In this variant embodiment, the flexibility of the material constituting the second electrical conducting elements (4) fitted to the cover is preferably such that, with a slight pressure exerted by the user on the cover, the electrical conducting element (4) can marry the shape of the object to be classified with minimal error, or a constant error. Therefore, in a preferred embodiment, the material chosen is an electrically conductive elastomer.

  A preferred example of application of the device consists in the recognition of the value of a banknote, characterized by its length or its width. With two strips of electrically conductive elastomer (4) and four sets of electrically conductive elements (2), two measurements of length or width (according to two perpendicular positions of the note) are made per ticket. If the long axis of the note for a measurement of length, or the minor axis of the note for a measurement of width, is parallel to the direction (D), these two measurements must be identical, which means that one knows the orientation of the ticket without resorting to any longitudinal or lateral stop, and therefore we can validate or reject the measurement. The number of electrical conductor elements (2) per measurement zone and their distribution pitch, condition the flexibility of positioning of the notes.

  It will be readily understood that such a device, given the electrical components it uses, is a low power consumer. We can also reduce power consumption by taking very high resistance values for each network.

  Figure 1b schematically shows the device according to the invention for classifying an electric conductive flat sheet type object. This device differs from that shown in FIG. 1a in that the second electrical conducting elements (4) of FIG. 1a are no longer necessary, and are replaced in their function by one or more electrical conductor elements (2 ") arranged on the surface of the support (1) The object (11) being electrically conductive, it is itself brought to a certain potential by this first electrical conducting element (2 "). When the lid (3) is folded down on the support (1), thus exerting a pressure on the push buttons (9) sufficient to actuate the latter and trigger the measurement, the object (11) is therefore brought to a certain potential that it transmits to the first electrical conducting elements (2) of each of the measurement zones or sub-zones that it covers. Thus, the equivalent voltage produced by each of the resistor networks connected to the electrical conducting elements (2) of each of the measurement sub-zones, is this time in relation with the recovery rate of the electrical conducting elements (2), while that it was in the example of Figure la in relation to the non-recovery rate of the electrical conductive elements (2). As in the example of FIG. 1a, the cover (3) is connected to the support (1) only to ensure the correct positioning during the measurement, and the uniform pressure on the object to be measured and the support .

  The measurement principle as explained in the example of Figure la remains valid in the example of Figure 1 b.

  In Figures 2a and 3a, the principle is identical to that of Figure la since it is to classify a non-conductive electrical object. In FIGS. 2b and 3b, the principle is the same as in the example of FIG. 1b since it is a matter of classifying an electrical conducting object.

  In FIG. 2a, it is more specifically an exemplary embodiment in which the diameter of a non-conductive plane circle is measured. A double measurement of the diameter is carried out in any two directions D1 and D2. If the two measurements differ by more than a predefined threshold, then the measurement is rejected and a message informs the user to correctly reposition the object to be classified.

  In the exemplary embodiment shown in FIG. 2b, the plane circle being electrically conductive, the cover (3) is no longer provided with electrically conductive elements (4), and the measurement is carried out according to the principle explained in the case of Figure lb. In Figure 3a is shown schematically an alternative embodiment in which a dimension (length or width for example) of a non-planar and non-conductive sheet is measured. The principle remains of course identical to that described in the context of Figure la. On the other hand, the non-planar shape of the object to be classified (11) imposes that the surface (1 ') of the support (1) consists of a material that is sufficiently flexible to allow it to conform to the shape of the object to be classified. classify, when sufficient pressure is exerted on the lid (3). In addition, the cover (3) must also be made of a sufficiently flexible material for the inner surface (3 ') to conform to the shape of the object to be classified when sufficient pressure is exerted on the cover (3) and so that the pressure exerted on the surface (3 ") is uniformly distributed.

  In Figure 3b, the object to be classified is a non-planar and electrically conductive sheet. The cover (3) and the support (1) of the device in this example therefore have the same flexibility characteristics as in the case of Figure 3a, and the measuring principle is identical to that described in Figures 1b and 2b.

  FIG. 4 depicts a functional representation of a preferred embodiment of the device according to the invention. In this figure, the portion (12) schematically represents the set of measurement zones, four in number in this example. Each of these measurement zones is earthed and powered by a power supply at commissioning. In the case of a portable device, this power supply can be of the battery type. To optimize the autonomy of such a portable device, the device optionally has an automatic shutdown mechanism after prolonged non-use while it is maintained in service (thus under tension). This mechanism is based on a possibly adjustable delay. A delay of between about 10 and about 60 seconds is particularly appropriate.

  Each of the measurement zones of the portion (12) produces an analog voltage sent to a computing unit (13). This computing unit is possibly but not necessarily a microprocessor known per se and suitably programmed. The computing unit is of course also electrically powered. The respective voltages are measured by means of the measurement means (6) and then transformed by the transformation means (7) into a recovery rate or non-recovery rate, according to whether the object to be classified is electrically conductive or electrically nonconducting. This recovery or non-recovery rate is related, possibly, but not necessarily proportionally, to the characteristic of the object to be classified.

  The information is then returned to the user. In particular, audio playback is appropriate, for example but not necessarily, through a speech synthesizer and a speaker (10). The apparatus is provided with a conventional audio output thus making it possible to connect any type of audio reproduction means other than a loudspeaker. In particular, headphones or headphones can be connected to this audio output. The audio reproduction can advantageously also be used to inform the user, for example by a voice message or a beep, when the charge level of the battery is too low. The audio reproduction means is associated with means for adjusting the sound volume of the audio reproduction. This volume setting means may also be used for commissioning the device.

  The description of these different embodiments is given merely by way of example and is not limiting. In particular, the choice of an electrically conductive elastomeric element disposed on the inner surface of the cover, in the case of the classification of an electrically non-conductive object, is not limiting.

  Any other material with sufficient characteristics of flexibility and electrical conductivity may be used.

  The use of push buttons as means of verification that the lid is sufficiently folded on the support is also presented by way of non-limiting example. Any other means for sensing the pressure exerted by the cover on the support to trigger the measurement when this pressure is sufficient, such as pressure sensors for example, can be considered.

  Likewise, the use of a microprocessor to measure and transform it into a characteristic value of the object to be classified is not limiting. Any other means of calculation may be suitable.

  The restitution of the information by means of a voice synthesizer and a loudspeaker is also not limiting, even if it is particularly suitable for blind users. In particular, for visually impaired users who still have a sufficient visual perception, it is possible to envisage a means of visual restitution.

  Moreover, the choice of directions (D) described in each of the examples above is not limiting. It depends on the geometric characteristics of the object to be classified. As a result, the distribution of the measurement zones of the first electrical conducting elements located on the surface of the support, and, in the case of an object to be classified as electrically non-conductive, the arrangement of the second electrical conducting elements on the inner surface of the cover. , given in each of the examples above, is not limiting either. Any other arrangement may be chosen according to the geometric characteristics of the object to be classified, the number of measurements that will be made for the same dimension, and also the number of different dimensions needed to characterize the object to be classified. .

  Finally, the geometric characteristics of the objects to be classified in the examples above have been chosen to illustrate the device and the method according to the invention, in particular in the case of the application to the recognition of the value of a bank note. , and are therefore in no way limiting.

Claims (1)

  Apparatus for classifying objects by measuring at least one determined parameter in relation to at least one given dimension of the object to be classified, said dimension being characteristic of said object, characterized in that it comprises: support (1) on the surface of which are arranged first electrical conducting elements (2) - a cover (3) - electrical supply means (5) of the first electrical conducting elements (2), - measuring means (6) ) at least one electrical parameter characteristic of the set of first electrical conducting elements (2), - transformation means (7) of the measurement of this electrical parameter in measurement of the determined parameter, and in that: the measurement of the determined parameter is carried out by the measuring means (6) and processing (7) after placing the object to be classified on the support (1) and after folding the cover (3) on the support (1) so at this the object to be classified is uniformly in contact with the electrically conductive elements which it covers among the first electrical conducting elements (2).   2. Device according to claim 1, characterized in that the set of first electrically conductive elements (2) is distributed on the surface of the support (1) in at least one direction (D).   3. Device according to any one of claims 1 and 2, characterized in that, the object to be classified being electrically conductive: at least one of the first electrical conductive elements (2 ") can carry the object to classify at an electric potential, the determined parameter measured is the recovery rate of the first electrical conducting elements (2) by the object to be classified.   4. Device according to any one of claims 1 and 2, characterized in that the object to be classified being electrically non-conductive: - at least a second electrically conductive element (4) is disposed on the inner surface of the lid (3). ) - at least one of the first electrical conducting elements (2 ') makes it possible to carry the second electrical conducting element (4) to an electric potential - the determined parameter measured is the non-overlapping rate of the first electrical conducting elements (2) by the object to be classified and in that the measurement of the determined parameter is carried out by the measuring (6) and transforming (7) means after having placed the object to be classified on the support (1) and after having folded the lid ( 3) on the support (1) so that the second electrically conductive element (4) extends in the direction of the characteristic dimension of the object to be classified and is in contact with the elements electrical conductors not covered by the object to be classified among the first electrical conducting elements (2).   5. Device according to any one of claims 1 to 4, characterized in that all of the first electrically conductive elements (2) is distributed on the surface of the support (1) 2859807 16 in several directions (Di).   6. Device according to any one of claims 1 to 5, characterized in that it measures at least one parameter determined by directions (Di) distribution of the first electrical conductor elements (2).   7. Device according to claim 6, characterized in that the distribution of the first electrical conductor elements (2) in at least one of the directions (Di) is doubled by a second distribution parallel to the first in the same direction (Di), so as to make two measurements of the same dimension extending in the direction (Di) for the object to be classified.   8. Device according to claim 6, characterized in that the distribution of the first electrical conductor elements (2) in at least one direction (Di) is doubled by a second distribution perpendicular to the first, so as to perform two measurements of two dimensions of the object to be classified perpendicular to each other.   9. Device according to any one of claims 7 and 8, characterized in that the classification of the object is validated only if the relative distance between the two measurements is less than a predefined value.   10. Device according to any one of claims 1 to 9, characterized in that: - the object to be classified is of planar type, - the support (1) is a flat support, - the lid (3) is a lid plan.   13. Device according to claim 10, characterized in that the object to be classified is of the flat sheet type, including a bank note, and in that one or more dimensions of the bank note are measured.   14. Device according to any one of claims 1 to 11, characterized in that: the support (1) is provided with means (9) for sensing the pressure, the measurement is triggered only when a sufficient pressure is exerted on said means (9).   13. Device according to claim 12, characterized in that said means (9) for sensing the pressure consists of at least one push button.   14. Device according to claim 12, characterized in that the lid (3) exerts pressure on said means (9) when it is folded over the object to be classified disposed on the support (1), thereby triggering the measurement.   15. Device according to any one of claims 1 to 14, characterized in that it is portable and electrically autonomous.   16. Device according to claim 15, characterized in that the electric autonomy comes from an electric battery.   17. Device according to any one of claims 1 to 16, characterized in that it comprises means (10) of audio reproduction of the classification information of the object to the user.   18. Device according to claim 17, characterized in that said means (10) for audio reproduction of the classification information of the object to the user is associated with a sound volume adjustment means for restitution of said information.   19. Device according to claim 18, characterized in that said means for adjusting the sound volume also makes it possible to put the assembly into operation or out of service.   20. Device according to any one of claims 17 to 19, characterized in that it comprises a speaker.   21. Device according to any one of claims 17 to 20, characterized in that it comprises an audio output jack.   22. Device according to any one of claims 17 to 21, characterized in that the means (10) of information retrieval by audio informs the user when the measurement is not validated or when the measurement can not be done. performed, or when the charge level of the battery is too low.   23. Device according to any one of claims 1 to 22, characterized in that it comprises means for detecting the prolonged inoperability beyond a predetermined time after powering on, and in that the device is turned off. voltage when such non-use is detected 24. A method of classifying objects by measuring at least one determined parameter in relation to at least one given dimension of the object to be classified, said dimension being characteristic of said object, characterized in what it consists of: placing the object to be classified on a set of electrically powered electrical conducting elements, measuring an electrical parameter characteristic of all of said electrical conducting elements, transforming the measurement of said electrical parameter into a measurement of determined parameter.   25. The method of claim 24, characterized in that, the object to be classified being electrically conductive, the determined parameter measured is the recovery rate of said electrical conductor elements.   26. The method of claim 24, characterized in that, the object to be classified being electrically nonconducting, the determined parameter measured is the non-overlap rate of said electrical conductor elements.