RU99112497A

RU99112497A - UNIVERSAL DEVICE FOR DETERMINING THE DIGNITY AND AUTHENTICITY OF BANKNOTES

Info

Publication number: RU99112497A
Application number: RU99112497/09A
Authority: RU
Inventors: Эдвард Л. ЛАСКОВСКИ
Original assignee: Интерболд
Priority date: 1996-11-15
Filing date: 1997-11-14
Publication date: 2001-05-27

Claims

1. A device for providing an indication of the type of banknote read by said device, comprising a radiation source on a first side of said banknote, wherein said radiation source directs radiation to a test point on said banknote, a first detector on a first side of said banknote, wherein said first detector outputs the first signal that responds to radiation reflected from the specified test point to the specified first detector, the second detector on the second opposite side of the specified bank you, in which the specified second detector outputs a second signal that is responsive to the radiation transmitted through the specified test point, to the specified second detector, a circuit, operatively connected to a data storage device, in which the specified circuit is configured to drive the specified radiation source and generate the values of the reflection and transmission coefficients when triggered by the specified first and second signals, respectively, in which the specified circuit is configured to calculate at least one value characterizing the level of correlation between the indicated values of the reflection and transmission coefficient and the stored values in the specified data device, corresponding to the transmission and reflection properties near the specified test point for each type from among the set of known banknote types.

2. The device according to claim 1, wherein said radiation source comprises a second plurality of radiation emitters, in which each of said emitters generates radiation at a different wavelength, and in which said circuit is configured to generate transmission and reflection coefficient values corresponding to said the first and second signals responsive to radiation generated by each emitter.

3. The device according to claim 2, wherein said control circuit is configured to actuate each emitter separately.

4. The device according to claim 2, in which these emitters are placed, in General, around the specified first detector.

5. The device according to claim 2, in which these emitters emit radiation, which, in General, includes a range of visible light.

6. The device according to claim 2, in which these emitters contain emitters that emit visible and invisible radiation.

7. The device according to claim 6, wherein said emitters comprise, in general, a red emitter, generally a blue emitter, generally a green emitter and, in general, an infrared emitter.

8. The device according to claim 1, in which the read set of values contains the specified values of the reflection and transmission coefficients, and in which the specified stored values are located in the stored sets of values, and in which the specified circuit is configured to calculate the specified level of correlation for the read set of values and each memorized set of values.

9. The device of claim 8, in which the specified radiation source contains many emitters of radiation, in which each of these emitters of radiation generates radiation, in General, at a different wavelength, and in which the specified circuit is configured to generate transmission values when triggered by these second signals generated when triggered by radiation from each emitter, and in which the transmission value corresponding to radiation from one emitter is contained in the first part of the read-out set of values, and sets transmission values corresponding to another emitter are contained in the second part of the read set of values, and in which these stored sets of values contain the first and second parts, and in which the level of correlation is calculated between the first parts of the read and stored sets of values and the second parts of the read and stored sets of values , respectively.

10. The device according to p. 8, in which the specified radiation source contains emitters of radiation, and in which each of these emitters of radiation generates radiation, in General, at a different wavelength, and in which the specified circuit is configured to generate reflectance values when triggered to said first signals generated when triggered by radiation from each emitter, and in which the value of the reflection coefficient corresponding to radiation from one emitter is contained in the first part of the read sets values, and the reflection coefficient value corresponding to another emitter is contained in the second part of the read set of values, and in which each of the stored sets of values contains the first and second parts, and in which the level of correlation is calculated using the circuit between the specified first parts of the read and stored sets of values and said second parts of said read and stored sets of values, respectively.

11. The device of claim 8, in which the specified radiation source contains many emitters of radiation, and in which each of these emitters generates radiation, in General, at a different wavelength, and in which the specified circuit is configured to generate reflectance and transmission values when triggered by the radiation generated by each emitter, and in which each of the indicated values of the reflection and transmission coefficient is contained in a read data set.

12. The device according to claim 11, in which said circuit is configured to actuate each emitter separately from the others, in which reflection and transmission values for each emitter are generated simultaneously.

13. The device according to claim 1, also containing means for moving the banknote, and in which the specified means of moving the banknote is made with the possibility of relative movement of the specified banknote and the specified first and second detectors, while as a result of the specified relative movement of the specified banknote contains a second set of discrete test points , and in which said circuit generates reflection and transmission coefficient values for each of said test points, and in which said stored values correspond to the properties of the transmission and reflection coefficient near each of these test points for each type from among the specified set of known types of banknotes.

14. The device of claim 13, wherein said radiation source comprises a third plurality of types of radiation emitter, wherein each type of emitter generates radiation generally at a different wavelength, and wherein said circuit is configured to drive each type of emitter separately and in the sequence near each point from the number of the specified second set of test points.

15. The device according to 14, in which the specified second set of transmission values corresponding to one first emitter is contained in the first part of the read data set, and in which the specified data storage device contains the fourth set of first stored sets of values, each of which has the first part corresponding to the transfer properties near each of these test points for each type from among the specified set of known types of banknotes, and in which the specified circuit is configured to to compute a value characterizing the level of correlation between said first part of said read set of values and the first parts of each set from said fourth set of stored value sets.

16. The device according to 14, in which the specified second set of values of the reflection coefficient corresponding to one first emitter is contained in the first part of the read data set, and in which the specified data storage device contains the fourth set of first stored sets of values, each of which has a first the part corresponding to the properties of the reflection coefficient near each of these test points for each type from among the specified set of known types of banknotes, and in which the specified schemes and configured to calculate a value characterizing the level of correlation between the first part of the specified read data set and the first parts of each set from the specified fourth set of stored value sets.

17. The device according to p. 15, in which the specified means of movement moves the specified banknote in the direction of the banknotes, and in which the first and second detectors and the third set of emitters contain a point reading unit, and in which the specified device contains a fifth set of point reading units, generally separated from each other transversely by intervals in the indicated direction of the banknote, and in which said first part of said read data set contains transmission values corresponding to said one the first emitter in one node from the specified fifth set of point reading nodes, and the specified transmission values correspond to the radiation transmitted through the specified banknote at each of the points tested near one node from the specified fifth set of point reading points during relative movement of the specified banknote by the indicated means moving banknotes.

18. The device according to p. 15, in which the specified means of moving banknotes moves the specified banknote in the direction of the banknote, and in which these first and second detectors and the specified third set of emitters contain a point reading unit, and in which the specified device also contains a fifth set of point nodes reading, in general, transversely separated from each other by intervals in the indicated direction of the banknote, and in which said first part of said read data set contains coefficient values from pressure corresponding to the specified one first emitter and one node from the specified fifth set of point reading nodes, the indicated reflection coefficient values corresponding to the radiation reflected from the specified banknote at each point from the number of points being checked near one node from the specified fifth set of point reading points in time of relative movement of said banknote by said means of moving banknote.

19. The device according to clause 15, in which the specified circuit is configured to generate stored sets of values, in which these stored sets of values contain data values from the specified data storage device, in which these stored sets of values contain transmission values for each type of the specified a plurality of known types of banknotes from each specified emitter adjacent to each point from the number of the specified second set of checked points.

20. The device according to clause 16, in which the specified circuit is configured to generate stored sets of values, in which these stored sets of values contain stored values from the specified data storage device, and in which these stored sets of values contain reflectance values for each type of the number of the specified set of known types of banknotes from each of the emitters near each point from the number of the specified second set of checked points.

21. The device according to claim 19, in which each point of the specified second set of test points is separated from the other, at equal intervals, and in which the specified data storage device contains data values corresponding to transmission values for each type from among the specified set of known types banknotes separated by each point from the number of specified points on the specified banknote, as a result of which it is not necessary to determine the location of the edge of the specified banknote to identify the specified type of banknote.

22. The device according to claim 20, in which the specified second set of test points, in General, separated from each other by equal intervals, and in which the specified data storage device contains data values corresponding to the values of the reflection coefficient for each type from among the specified set of known types banknotes separated by each point from the number of specified points on the specified banknote, as a result of which it is not necessary to determine the location of the edge of the specified banknote to identify the specified about the type of banknote.

23. The device according to p. 19, in which the specified means of moving banknotes moves the specified banknote relative to the specified detectors in the direction of the banknote, and in which the specified data storage device contains data values corresponding to transmission values for each type from among the specified set of known types of banknotes, offset from the specified banknote, at least one increment in the direction transverse to the specified direction of the banknote, as a result of which it is not necessary to center the decree hydrochloric banknote in said transverse movement means to identify said note type.

24. The device according to claim 20, in which the specified means of moving banknotes moves the specified banknote relative to the specified detectors in the direction of the banknote, and in which the specified data storage device contains data values corresponding to the values of the reflection coefficient for each type from among the specified set of known types of banknotes, offset from said banknote by at least one increment in a direction that is transverse to said banknote direction, whereby said banknote that is not needed to center the transverse displacement in said means for identifying said banknote note type.

25. The device according to p. 21, in which the specified means of moving banknotes moves the specified banknote relative to the specified detectors in the direction of the banknote, and in which the specified data storage device contains data values corresponding to transmission values for each type from among the specified set of known types of banknotes offset from the specified banknote, at least one increment in a direction that is transverse relative to the specified direction of the banknote, as a result of which the banknote is not required etsya centered in said means for identifying the movement types.

26. The device according to item 22, in which the specified means of moving banknotes moves the specified banknote relative to the specified detectors in the direction of the banknote, and in which the specified data storage device contains data values corresponding to the values of the reflection coefficient for each type from among the specified set of known types of banknotes, offset from the specified banknote by at least one increment in the direction transverse to the specified direction of the banknote, as a result of which the banknote does not require I centered in the said movement means to identify their types.

27. The apparatus of claim 2, wherein said first detector, second detector, and said second plurality of radiation emitters comprise a point sensing assembly, and wherein said device comprises banknote moving means, and wherein said banknote moving means moves said banknote relative to said node point reading in the direction of the banknote, and in which said device comprises a fifth plurality of point reading units, and in which said point reading units are separated other intervals in a direction transverse to said note direction.

28. The device according to item 27, in which the specified circuit actuates each of these emitters in each of the specified nodes of the point reading sixth set of times when moving the specified banknote near relative to the specified points of the point reading.

29. The device according to p, in which the specified circuit actuates the specified emitters in accordance with a specific time sequence.

30. The device according to clause 29, wherein said circuit drives said emitters to condition the generation of said transmission values and reflection coefficient for the radiation emitted by each emitter at each of the point reading nodes on the grid of checked points on said banknote.

31. The device according to clause 30, in which emitters of this type generate radiation, in General, at the same wavelength, and in which the specified values of the transmission and reflection coefficient corresponding to radiation from one type of emitter at each of these test points in this part of the specified grids, contain the first part of the read data set, and in which the specified data storage device contains stored values, in which the specified circuit generates a stored set of values, having the first part corresponding to corresponding to the specified values of the transmission or reflection coefficient at the indicated test points in the specified grid, corresponding to one type of emitter for each type from among the specified set of known types of banknotes.

32. The device according to p. 31, in which the indicated first part of the indicated read-out set of values contains values denoted as (x), and in which the indicated first part of the said stored sets of values contains the stored values denoted as (y), and in which the circuit is configured to calculate a value characterizing the level of correlation between said first part of said read set of values and said first part of said second sets of values in accordance with the following form hive:

where C _{x, y} is the correlation coefficient;
x _i is the read value from the data of the read set of values;
y _i is the corresponding value in the stored set of values;
μ _x is the average value in terms of the correlated read set of values;
μ _y is the average value in the corresponding part of the correlated stored set of values;
σ _x is the standard deviation of the read values in the part of the correlated read set of values;
σ _y is the standard deviation in the corresponding part of the stored set of values.

33. The device according to p, in which the specified circuit is configured to generate a read-through set of values, having a first part containing reflection coefficient values generated when each type of radiation is emitted from among the indicated types of emitter, and calculate a value characterizing the correlation level with the first part of each set of the seventh set of stored sets of values corresponding to the values of the reflection coefficient of each type from among the specified types of emitters.

34. The device according to p, in which the specified circuit is configured to generate a read-through set of values, having a first part containing transmission values generated when triggered by radiation from each of these types of emitter, and calculate a value characterizing the level of correlation with the first part every seventh set of the stored sets of values corresponding to transmission values from each of the indicated types of emitter.

35. The device according to p. 34, in which these stored sets of values contain reflectance or transmission values corresponding to each type from among the specified set of known types of banknotes shifted in the direction of the banknote from the specified banknote.

36. The device according to clause 34, in which these stored sets of values contain transmission values or reflection coefficients corresponding to each type from among the specified set of known types of banknotes offset in a direction transverse to the specified direction of the banknote from the specified banknote.

37. The device according to claim 1, in which the specified radiation source contains a second set of emitters of radiation, and these emitters contain a third set of types of emitters, in which each type of emitter generates radiation at a wavelength that is different from other types, and in which all of these emitters direct radiation to one test point on said banknote, and in which at least one of said first or second detectors is installed near said test point.

38. The device according to clause 37, in which the specified circuit is configured to generate a read multiple values containing the first part corresponding to both values of the transmission or reflection coefficient for one of these types of emitter, and in which the specified circuit is configured to generate stored sets of values containing said stored values, and in which each of said stored sets of values contains a first corresponding part, in which each said first corresponds the majority of the stored set of values corresponds to the specified values of the transmission or reflection coefficient for the specified one type of emitter and the known type of banknote, and in which the specified circuit is configured to calculate the specified value characterizing the level of correlation between the specified first part of the specified read set of values and the specified first corresponding part each memorized set of values.

39. The device according to p. 38, in which the specified circuit is configured to generate a read many values, containing the fourth set of parts, and each part corresponds to the values of the reflection or transmission coefficient from each type from the specified third set of types of emitters, and in which the specified scheme configured to generate stored sets of values, and each specified stored set of values contains the specified fourth set of corresponding parts that correspond there are specified transmission values and reflection coefficients for each of the indicated types of emitter and a known type of banknote, and in which said circuit calculates a specified value characterizing the level of correlation for each part of the read set of values and each corresponding part of each stored set of values.

40. The device according to claim 39, in which the control circuit is configured to calculate a specified value characterizing the level of correlation between the read set of values and each stored set of values by combining parts of the read set of values and each stored set of values.

41. The device according to § 39, wherein said circuit is configured to calculate a value characterizing a general level of correlation between a read set of values and a stored set of values by multiplying values characterizing a correlation level of reflection coefficient values in corresponding parts of the read set of values and the stored set of values to obtain the product of the reflection coefficient, which corresponds to the general level of correlation for the reflection coefficient between the read a set of values and a stored set of values in which the indicated circuit is configured to multiply values characterizing the correlation level of transmission values in the corresponding parts of the read set of values and the stored set of values to obtain a transmission product that corresponds to the general correlation level for transmission between the read set of values and the stored a set of values, and in which the specified control circuit is also configured to form a value, the nature total binder level of correlation between the sensed value set and the stored value set by multiplying the transmission product by the product of the reflection coefficient.

42. The device according to claim 1, in which said banknote has a certain position, and in which said stored values contain data characterizing stored value patterns corresponding to reflection and transmission coefficient values for each type from among a plurality of known banknote types in said banknote position and in provisions not in the indicated position of the banknote.

43. The device according to § 42, in which the specified banknote is located, in General, in the plane, and in which these patterns correspond to the specified known types of banknotes offset from the specified position of the banknote in the first direction in the specified plane.

44. The device according to item 43, in which these templates correspond to the specified known types of banknotes offset from the specified position of the banknote in a direction transverse to the specified first direction.

45. The device according to p, in which the specified circuit is configured to generate a signal corresponding to a stored set of values, providing a value that characterizes the highest level of correlation with the specified read set of values, as a result of which the specified signal indicates a specific type of banknote.

46. The device according to item 45, in which the specified circuit is configured to compare the specified value characterizing the specified highest level of correlation with the stored threshold value, and in which the specified circuit is configured to provide a second signal when the specified value characterizing the highest level of correlation does not exceed the specified stored threshold value.

47. The device according to claim 1, in which these stored values correspond to each type from among the specified set of types of banknotes in the second set of angular positions.

48. The device according to item 44, in which these stored sets of values correspond to each type from among the known types of banknotes offset from the specified position of the banknote in the second set of angular directions.

49. The device according to claim 1, in which said device comprises means for reading a skew angle of said banknote, and in which said circuit is configured to select said stored values used to calculate said value characterizing the level of correlation from said data storage device, skewed to the specified angle.

50. The device according to item 27, in which the specified control circuit is configured to determine the skew angle of the specified banknote when triggered by the specified point reading units, which are the first to read the transmission property or reflection coefficient of the specified banknote at different times, and in which these stored values used to calculate the specified value, characterizing the level of correlation, select the specified scheme, triggered by the specified angle of bias.

51. The device according to p. 50, in which the specified skew angle is calculated by the specified control circuit that is triggered by the transmission value or reflection coefficient from the first type of emitter in the first point reading unit upon reaching the threshold value, and the specified transmission value or reflection coefficient for the specified first type the emitter in the second point reading unit, separated by a transverse interval from the specified first point reading unit, reaches the specified threshold value some time after this about.

52. The device according to 51, in which the specified control circuit calculates the specified skew angle as a function of the specified time, the distance separating the specified first and second nodes of the point reading, or the speed at which the specified means of movement moves the specified banknote.

53. The device according to clause 47, in which the specified circuit is configured to generate stored sets of values, in which the specified value characterizing the level of correlation is calculated between the specified values of the reflection coefficient and transmission and the specified stored sets of values, and in which the specified circuit is made with the ability to selectively contain stored values from the specified data storage device in the specified stored sets of values when triggered at the specified skew angle.

54. The device according to p. 53, in which the specified storage device contains data characterizing at least one pattern corresponding to each one type from among the specified set of known types of banknotes, and in which the specified pattern contains values corresponding to the values of transfer and coefficient reflection for the specified corresponding type of banknotes at a generally zero skew angle, and in which the specified circuit generates the specified stored set of values from the specified template when triggered on specified first skew angle.

55. The device according to p. 54, in which the specified data storage device contains at least one specified pattern for each one type from among the specified set of known types of banknotes, in which the specified pattern contains stored values corresponding to the specified values of the reflection coefficient and transmission for the specified type of banknotes in the third set of transverse positions.

56. The device according to p. 55, in which the specified device also contains means of movement for the relative movement of the specified banknote in the direction of the banknote relative to the specified radiation source and these detectors, and in which the indicated relatively moving banknote contains a fourth set of test points, and in which each of of said test points is separated from each adjacent test point in the indicated direction of the banknote by the interval distance of the point, and in which each indicated pattern n contains stored values corresponding to the indicated values of the reflection and transmission coefficient for each one type from among the known types of banknotes in uniform increments that are less than the indicated interval distance of the point.

57. The device according to p. 56, in which these increments comprise, in General, one fourth of the specified interval distance of the point.

58. The device according to p. 56, in which the specified data storage device contains for each one type from among the specified set of types of banknotes the main template, and in which each specified main template contains the fifth set of subpatterns corresponding to one type of banknotes, and in which each of these basic patterns corresponds to the specified type of banknote at a zero skew angle, and in which each of these subpatterns in one of the main patterns corresponds to the values of transmission and reflection coefficient for one type of banknote located outside the adjacent subpattern in the direction transverse to the specified direction of the banknote, and in which the specified circuit is configured to contain values in the indicated stored sets of values for the specified one type of banknote from the number of specified subpatterns in one main template when triggered at the specified angle skew.

59. The device according to claim 1, wherein said circuit comprises a digital signal processor, and wherein said data storage device contains data characterizing at least one pattern corresponding to a known type of banknote and having said stored values corresponding to said type of banknote in a second plurality of banknote positions, and in which a selection of said stored values containing said template is performed by said digital processor of said circuit.

60. The device according to § 59, in which the specified circuit contains a third set of digital signal processors, and in which each of these digital signal processors selects the stored values in the patterns related to one specific digital signal processor.

61. The apparatus of claim 60, wherein said circuit is configured to calculate a correlation value corresponding to the highest level of correlation between said read values of reflection and transfer coefficient for said banknote and stored values in each one of said patterns.

62. The device according to 61, in which the indicated circuit is also configured to generate a signal characterizing the indicated highest level of the indicated correlation values from among all the indicated patterns, as a result of which the indicated signal indicates that the detected banknote has the highest correlation level with the stored values for specific type of banknote.

63. The apparatus of claim 61, wherein said correlation value is a function of transmission correlation value and reflection coefficient correlation value, in which said function is calculated by said circuit, and in which said transmission correlation value is calculated by said circuit and it indicates a correlation level between said read transmission values and stored values in the specified pattern corresponding to the transmission values, and in which the specified reflection coefficient correlation value is calculated hydrochloric circuit and which indicates the level of correlation between said sensed reflectance values and said stored values in said template corresponding to reflectance values.

64. The device of claim 63, wherein said radiation source comprises a fourth plurality of types of emitter, in which each type of emitter emits radiation at a wavelength different from other types of emitters, and in which said circuit is configured to calculate said value transmission correlations as a combination of calculated emitter-type correlation values characterizing the correlation levels between transmission values from the specified banknote for each one of the indicated emitter types, and the stored values in the indicated patterns correspond to each one of the indicated types of emitter.

65. The device according to item 63, in which the specified radiation source contains the fourth set of types of emitter, and in which the specified circuit is configured to calculate the specified value of the correlation of the reflection coefficient when triggered by the level of correlation between the specified values of the reflection coefficient from the specified banknote for each one of these types of emitter, and the stored values in these patterns correspond to each one of the indicated types of emitter.

66. The device according to item 64, in which the specified circuit is configured to generate reflection and transmission coefficients for a fifth set of generally linearly centered test points, whereby said test points pass along a line on said banknote, and in which banknote reflection and transfer coefficient values are calculated by the indicated circuit for all points tested on the indicated line for each one of the indicated emitter types by calculating the value characterizing the level of correlations with stored values in each of the indicated patterns, in accordance with the indicated line and type of emitter.

67. The device according to p, in which the specified circuit is configured to generate reflection and transmission values corresponding to the sixth set of lines of the tested points, and in which the specified transmission correlation and reflection coefficient are calculated by the specified circuit from the stored values in each specified pattern, corresponding to each indicated line of checked points and emitter type.

68. A method for determining the type of banknote, comprising the steps of illuminating a test point on a specified banknote using a radiation source, detecting with a first radiation detector reflected from said test point, and generating a first signal that is triggered by said reflected detectable radiation, detecting with a second detector radiation transmitted through the specified test point, and generating a second signal that is triggered on the specified transmitted detected radiation, calculating, using the circuit, a value characterizing the level of correlation between the indicated first and second signals and the stored values in the data storage device, corresponding to the transmission and reflection coefficient properties near the specified test point for many known types of banknotes.

69. The method according to p, in which these stored values are located in the stored sets of values, and each specified stored set of values corresponds to one of these known types of banknotes, and also containing the operation of generating a signal indicating a known type of banknote having the highest value, characterizing the level of correlation with the indicated first and second signals.

70. The method of claim 68, wherein said lighting operation comprises illuminating said test point in sequence with a second plurality of types of radiation emitters, each type of emitter emitting radiation at a wavelength that is generally different from the wavelength of other types of emitter.

71. The method of claim 70, wherein in said first detection operation, said second plurality of first signals are generated in such a way that each of them corresponds to one type of emitter, and in which in said calculation operation, the first correlation value is calculated as a value characterizing the correlation level between each of the indicated first signals for the specified banknote and the first stored values corresponding to the reflection coefficient from the indicated type of emitter for each type from among the specified set famous types of banknotes.

72. The method of claim 71, wherein in said second detection operation, said second plurality of second signals are generated in such a way that each of them corresponds to some type of emitter, and in which in said calculation operation, a second correlation value is calculated as characterizing the level of correlation between each from said second signals for said banknote and second stored values corresponding to transmission from said corresponding type of emitter through each type from among said set and is known note types.

73. The method of claim 72, wherein said calculation operation comprises calculating said first and second correlation values for said banknote and each type from among known banknote types, said value characterizing the level of correlation being calculated as a function of said first and second correlation values .

74. The method of claim 72, further comprising the step of performing said first and second detection steps near a third plurality of test points on said banknote, said test points being arranged in a grid and wherein said first and second stored values characterize transmission and coefficient properties reflection near each of these test points in the specified grid for each of these known types of banknotes, while these values are stored as data characterizing the template in the data storage device, and wherein said calculation operation comprises generating, using said circuit, a stored set of values containing values from each pattern, and computing said value characterizing the correlation level as a function of the values corresponding to said first and second signals for each of said test signals points on said banknote and said first and second values in each of said stored value sets.

75. The method of claim 68, wherein said lighting operation comprises illuminating a second set of test points on a grid on said banknote, wherein each test point is sequentially illuminated by a third set of types of radiation emitters, wherein each type of radiation emitter generates radiation at a wavelength that , in general, is different from the wavelength of other types of emitters, and in which the said first and second detection operations comprise generating the first and second signals at each point of the specified second the set of test points for each emitter from the specified third set of emitters, and in which the specified calculation operation includes generating, using the indicated scheme, reflection and transmission coefficients when each of the first signals and second signals are triggered, respectively, and in which the indicated values the reflection and transmission coefficients are placed in a set of values, and in which the specified calculation operation also includes generating using the specified circuit the set of values containing the stored values from the specified data storage device, and in which these stored sets of values correspond to the transmission and reflection coefficient for each type from among the specified set of known types of banknotes, and in which the specified set characterizing the level of correlation is calculated for the specified read a set of values and each of these stored sets of values.

76. The method according to claim 75, wherein prior to said lighting operation, the stored data is also carried out in said storage device for the stored values corresponding to said transmission and reflection coefficient values for each type of emitter near each point to be checked for each type of the known types of banknotes located in the fourth set of spatial positions.

77. The method according to p, in which prior to the specified calculation operation also perform the operation of determining the skew angle of the specified banknote from the specified first and second signals, and in which the specified calculation operation, said stored values are selected from the specified data storage device when triggered at the specified angle bias, and in which the specified value characterizing the level of correlation is calculated by the specified circuit using the specified selected values.