[0001] This invention relates to an apparatus for inspecting printed matters and, more particularly,
to an apparatus for discriminating a replica of a printed matter, for instance a false
or counterfeit bank note, from the original, i.e., the true or authentic bank note,
by an optical method.
[0002] Up to data, printing techniques and copying techniques have been advanced outstandingly,
and color copiers are available as commercial products. In these circumstances, it
is liable that valuable securities such as bank notes and checks are deftly copied
for improper use. Bank notes are manufactured by elaborate multi-color printing to
prevent manufacture of counterfeit paper money. However, there are already cases where-copies
of bank notes are produced using multi-color printing processes or color copies, which
copies cannot be discriminated from the originals by-a mere visual inspection.
[0003] An object of the invention is to provide a printed matter inspecting apparatus, which
can readily and accurately discriminate a copy of a printed matter from the original
even if it is difficult to discriminate the copy as such by a visual inspection.
[0004] According to the invention, the above object is attained by a printed matter inspecting
apparatus, which comprises means for inrradiating a printed matter having an ink capable
of reflecting or emitting electromagnetic waves of wavelengths outside the visible
range with electromagnetic radiation of a predetermined wavelength range, means for
forming an electric signal according to the energy distribution of electromagnetic
waves reflected or emitted by the printed matter, and means for effecting inspection
of the printed matter according to the electric signal.
[0005] The above and further objects, features and advantages of the invention will becomes
more apparent from the following description when the same is read with reference
to the accompanying drawings, in which:
Fig. 1 is a graph for explaining the relative luminosity of man;
Fig. 2 is a graph showing the spectral reflectivity characteristic of an organic ink
CF 5,150, a product of Toyo Ink Manufacturing Co., Ltd, in Japan, for example;
Fig. 3 is a graph showing the spectral reflectivity characteristc of an inorganic
ink;
Fig. 4 is a view showing a print pattern of a printed matter;
Fig. 5 is a graph showing the spectral energy characteristic of a light source of
a color copier;
Figs. 6 and 7 show an embodiment of the invention;
Figs. 8 and 9 show a different embodiment of the invention;
Fig. 10 is a graph showing the spectral energy characteristic of an ink which is excited
by visible light and emits near-infrared radiation;
Fig. 11 is a graph showing the spectral energy characteristic of an ink which is excited
by near-infrared radiation and emits near-infrared radiation;
Fig. 12 is a schematic showing of a further embodiment of the invention;
Fig. 13 is a graph showing the spectral energy characteristic of an ink, a fluorescent
ink SPD-3S, a product of Tokyo Shibaura Denki Kabushiki Kaisha, for example, which
is excited by ultraviolet radiation and emits visible light;
Fig. 14 is a graph showing the spectral energy characteristic of an ink, a fluorescent
ink SPD-120S, a product of Tokyo Shibaura Denki Kabushiki Kaisha, for example, which
is excited by ultraviolet radiation and emits near-infrared radiation;
Fig. 15 is a schematic showing of a further embodiment of the invention;
Fig. 16 is a graph showing the spectral reflectivity characteristic of a further different
ink;
Fig. 17 is a view showing a print pattern of a different printed matter;
Fig. 18 is a schematic showing of a further embodiment of the invention;
Fig. 19 is a graph showing the transmittance characteristic of an optical filter;
Fig. 20 is a graph showing the spectral reflectivity characteristic of a further different
ink; and
Fig. 21 is a block diagram showing a further embodiment of the invention.
[0006] Now, preferred embodiments of the invention will be described in detail with reference
to the accompanying drawings. Fig. 1 shows the relation between the relative luminosity
of the eye of man and the wavelength. As is seen from the Figure, the visible wavelength
range is approximately from 380 nm to 700 nm. That is, the electromagnetic waves of
the wavelengths in this range constitute visible light, which can be sensed by the
eye of man when it is reflected or radiated by the ink. An inorganic ink has a character
that it can reflect only light in the visible range as shown in Fig. 3. However, among
organic inks which are used for color copying machine, for instance, there is one
having a reflectivity characteristic covering an invisible range as shown in Fig.
2. In this characteristic, the reflectivity is high in the neighborhood of 520 nm
and in the infrared region above 700 nm while it is low for the rest of the wavelength
range.
[0007] The human eye, however, is hardly sensitive to wavelengths near infrared, so that
with an ink having the characteristic of Fig. 2 only wavelengths in the neighborhood
of 520 nm which correspond to green are seen. Now, a printed matter 4 as shown in
Fig. 4 will be considered, in which a portion labeled A has an impression of an organic
ink having a character as shown in Fig. 2 while a portion labeled B has an inpression
of the inorganic ink of the character shown in Fig. 3. In this case, of the light
reflected from the portion A components in a portion A' in Fig. 2 are seen, while
of the reflected light from the portion B components in a portion B' in Fig. 3 are
seen. The portions A and B are seen substantially as the same color. however, when
the printed matter of Fig. 4 is color-copied, a different color results for the portion
A though the same color is reproduced for the portion B. This results because the
light source which is used with a color copier has a spectral characteristic as shown
in Fig. 5, with the energy being higher for the near-infrared region rather than for
the visible region (i.e., 380 to 700 nm). The inorganic ink in the portion B has no
influence on a red-sensing section in the color copier, but the organic ink in the
portion B has an effect that this portion B were red. Further, all inorganic color
inks used with color copiers have high reflectivity in the infrared range, and substantially
no ink having high reflectivity in an infrared region above 700 nm is used for printing
purposes. In the case of organic ink, the reflectivity in an infrared region becomes
high. Thus, by making use of these facts, reliable judgement of a printed matter as
to whether it is true or false can be obtained.
[0008] Figs. 6 and 7 shows an embodiment of the invention applied to a judging apparatus,
which can make a decision as to whether a printed paper sheet as shown in Fig. 4,
e.g., a bank note, is authentic or counterfeit.
[0009] As shown in Fig. 6, a bank note 4, the printing of which is done in the manner as
shown in Fig. 4, is conveyed on a conveyor belt (not shown) in the direction of arrow
7. The bank note 4 is illuminated by light, which is projected from an illumination
lamp 8. The illumination light contains energy in the visible range and also in the
infrared range. Light reflected by the bank note 4 is coupled through a focusing lens
9, a near-infrared filter 10, which passes wavelengths of near-infrared region, and
an aperture unit 11 to a photoelectric converter 12. The aperture of the aperture
unit 11 serves to determine the resolution in the direction of transport of the bank
note, the resolution in the direction perpendicular to the direction of transport
of the bank note and a field of view. A light source 14 and a light receiver 15 are
provided on the opposite sides of the path of the bank note 4 respectively. The light
source 14 and light receiver 15 constitute a bank note passage detector, which serves
to determine the timing of reading of signal from the photoelectric converter 12.
The output signal of the bank note passage detector 14, 15 is fed to a sequence control
circuit 16 which will be described later in detail. The output signal of the photoelectric
converter 12 is amplified by an amplifier 13 to be fed to analog memories 17 and 17'
as shown in Fig. 7._ Of the output of the amplifier 13, data representing the quantities
of reflected light from the portions A and B of the bank note 4, for instance, are
stored in the analog memories 17 and 17' under the control of a signal produced from
the control circuit 16 in a timed relation to the passage of the bank note 4 through
the bank note passage detector 14, 15. The output of the analog memory 17 is fed to
a difference circuit 21 and also to a comparator 19. The output of the analog memory
17' is fed to the difference circuit 21 and also to a comparator 19'. An output signal
of reference level generator 18 is supplied to the comparators 19 and 19'. The output
of the difference circuit 21 and the outputs of the comparators 19 and 19' are fed
to a judgement circuit 20.
[0010] The operation of the construction of Figs. 6 and 7 as described above will now be
described. When the bank note 4 passes through the bank note passage detector 14,
15, the data representing the quantity of infrared radiation reflected from the portion
A of the bank note 4 is stored in the analog memory 17, while the data representing
the quantity of infrared radiation reflected from the portion B of the bank note 4
is stored in the analog memory 17'. When the writing of data in the analog memories
17 and 17' is completed, the difference between the outputs of the analog memories
17 and 17' is calculated in the difference circuit 21. If the bank note 4 is an authentic
one, in which the portion A has an impression of organic ink, a large quantity of
near-infrared radiation is reflected from the portion A, while substantially no near-infrared
radiation is reflected from the portion B. In this case, an output from the difference
circuit 21 calculating the output difference of the memories 17, 17' becomes "1".
If the bank note 4 is what is copied with a color copier, large quantities of infrared
radiation are reflected from both the portions A and B, and the difference circuit
21 produces a "0" output. If the bank note 4 is a counterfeit one obtained by printing,
substantially no infrared radiation or high infrared radiation is reflected from both
the portions A and B, and the difference circuit 21 again produces a "0" output. The
judging circuit 20 thus judges the detected bank note 4 to be an authentic one when
ane only when the output of the difference circuit 21 is "1".
[0011] The outputs of the analog memories 17 and 17' are fed to the respective comparators
19 and 19' for level comparison with respect to a reference level provided from the
reference level generator 18. In the comparator 19, the level of the infrared radiation
quantity from the portion A is checked as to whether it is within a level range U
in Fig. 2. If it is detected that the level is within the level range U, the bank
note 4 is judged to be an authentic one. In the case of, for instance, a counterfeit
bank note produced by printing using inorganic ink, less infrared radiation is reflected
so that the compared level is below the level range U. In this case, the counterfeit
bank note thus is judged to be as such. In the comparator 19', the level of the infrared
radiation quantity from the portion B is checked as to whether it is within the level
range L in Fig. 3. If it is detected that the level is within the level range L, the
bank note is judged to be an authentic one. In the case of, for instance, a counterfeit
bank note produced by copying with a color copier or that produced by organic ink
printing, more than proper quantity of infrared radiation is reflected from the portion
B, so that the compared level is above the level range L. In this case, the counterfeit
bank note thus is judged to be as such.
[0012] In the manner as described above, counterfeit bank notes such as those produced by
printing or by copying with a color copier can be reliably discriminated.
[0013] Figs. 8 and 9 show a different embodiment of the invention.
[0014] As shown in Fig. 8, a bank note 4, a print of which is again as shown in Fig. 4 with
its portion A having a green impression of an organic ink and its portion B having
a green impression of an inorganic ink, is conveyed on a conveyor belt (not shown)
in the direction of arrow 7. The bank note 4 is illuminated by light or electromagnetic
wave prcjected from an illumination lamp 8 and containing energy in the visible and
infrared ranges. Light reflected from the bank note 4 is coupled through a focusing
lens 9 to a blue dichroic mirror 36. The blue dichroic mirror 36 reflects only blue
light while allowing light of the other wavelengths to pass. Light transmitted through
the blue dichroic mirror 36 is coupled to a green dichroic mirror 37, which reflects
only green light. Light transmitted through the green dichroic mirror 37 is coupled
to a red dichroic mirror 38, which reflects only red light of 600 to 650 nm.
[0015] Light transmitted through the red dichroic mirror 38 is coupled through a near-infrared
filter 30, which transmits wavelengths of near-infrared region, and an aperture unit
31 to a photoelectric converter 32. Light reflected by the blue dichroic mirror 36
is coupled through a blue filter 39 and an aperture unit 40 to a photoelectric converter
41. Light reflected by the green dichroic mirror 37 is coupled through a green filter
43 and an aperture unit 44 to a photoelectric converter 45. Light reflected by the
red dichroic mirror 38 is coupled through a red filter 47, which transmits wavelengths
of 600 to 650 nm, and an aperture unit 48 to a photoelectric converter 50. The aperture
units 31, 40, 44 and 48 serve to determine the resolutions and field of view as in
the preceding embodiment. Further, like the preceding embodiment a light source 14
and a light receiving element 15 are provided to constitute a bank note passage detector
which serves to determine the timing of reading.
[0016] The outputs of the photoelectric converters 32, 41, 45 and 49 are amplified by respective
amplifiers 33, 42, 46 and 50 to detect reflected infrared, blue, green and red radiation
quantities respectively. These output signals of the amplifiers 32, 42, 46 and 50
are fed to analog memories 51 to 58 shown in Fig. 9. More particularly, data representing
the quantities of infrared radiation from the portions A and B are stored in the respective
analog memories 51 and 52, those of red radiation from the portions A and B are stored
in the analog memories 53 and 54, those of green radiation from the positions A and
B are stored in the analog memories 55 and 56, and those of blue radiation from the
portions A and B are stored in the analog memories 57 and 58.
[0017] After the writing of data in these analog memories 51 to 58 is completed, judgement
as to whether the bank note is authentic or counterfeit is done in the following way.
Difference circuits 61 to 64 compare the quantites of radiation reflected from the
A and B portions for the respective colors. For the infrared component of light, like
the preceding embodiment, the quantity of radiation from the portion A is large while
that from the portion B is small if the bank note is an authentic one. With an authentic
bank note the difference circuit 61 thus produces a "1" output, so that a judging
circuit 74 judges the bank note to be authentic. In case of a counterfeit bank note
obtained by copying with a color copier, large quantities of infrared radiations are
felected from both the portions A and B. Thus, the difference circuit 61 produces
this time a "0" output so that the judging circuit 74 judges the bank note to be a
counterfeit one. In case of a counterfeit bank note obtained by printing using inorganic
or organic ink, less or large quantities of infrared radiation are reflected from
both the portions A and B. Thus, the difference circuit 61 again produces this time
a "0" output so that the judging circuit 74 judges the bank note to be counterfeit.
[0018] The difference circuit 62 calcultes the difference between the quanties of the red
component of light reflected from the portions A and B. With an authentic bank note,
neither A nor B portion reflects any red component of light, where the inks used for
these portions are of the characteristics of Figs. 2 and 3, in both of which a spectral
reflectivity peak occurs in the green region. In this case, the difference circuit
62 thus produces a "0" output so that the judging circuit 74 judges the bank note
to be authentic. With a counterfeit bank note obtained by copying with a color copier
using an ink which has a spectral reflectivity peak in the red region, however, the
peak is shifted toward the red region for the portion A although the same red color
as in the original can be reproduced for the portion B. In this case, therefore, the
difference circuit 62 produces a "1" output.
[0019] The difference circuit 63 calculates the difference between the quantities of the
green component of light reflected from the portions A and B. With an authentic bank
note, there is not difference between the quantities of reflected green light from
the portions A and B, as is seen from Figs. 2 and 3. In this case, the difference
circuit 63 thus produces a "0" output. With a counterfeit bank note obtained by copying
with a color copier, the color of the portion A is rather reddish although the color
of the portion B is the same as in the original as is recognizable even by the visual
inspection. That is, the spectral reflectivity peak is shifted from the green region
toward red (i.e., toward the right side in Fig. 2). Consequently, a difference is
detected between the quantities of reflected green light from the A and B portions,
causing the difference circuit 63 to produce a "I" signal so that the judging circuit
74 judges the counterfeit bank note as such.
[0020] The difference circuit 64 detects a difference for the blue component of light. Again
with an authentic bank note, there is nod difference in the reflected red light between
the portions A and B. With a counterfeit bank note obtained by copying with a color
copier, in which case the spectral reflectivity peak is shifted toward red as mentioned
earlier, a difference in the reflected green light is detected, causing the difference
circuit 64 to produce a "1" output so that the judging circuit 74 judges the counterfeit
bank note as such.
[0021] A reference level generator 65 and comparators 66 and 67 respectively have the same
construction and function as the reference level generator 18 and comparators 19 and
19' in the preceding embodiment of Fig. 7, so these components are not described.
[0022] While the above embodiments have concerned with the case where a green organic ink
in which the reflectivity is high in the neighborhood of 520 nm and in the near-infrared
region, similar effects may of course of obtained in case of an organic ink of any
other color so long as the reflectivity is high in the infrared region.
[0023] Further, an organic ink having a reflectivity characteristic in which the reflectivity
is high in a certain color region and in the near-infrared region has been concerned,
this is by no means limitative. For example, in case of an ink, the reflectivity of
which is high for a certain color region and in the long wavelength region in the
visible region, short wavelength region, or the ultraviolet region, it is possible
to make judgement similar to the above embodiments. In case of using the ultraviolet
region, the judgement may be done by making the detection of the quantity of reflected
light in the neighborhood of 400 nm or by making use of the fact that a shift toward
violet results when color separation is done. In general, the effects according to
the invention can be obtained in case of any ink, the reflectivity of which is high
in the invisible regions or in a low luminosity region in the visible range.
[0024] In the preceding embodiment, the authenticity of a printed matter, for which two
different kinds of ink which have substantially the same spectral reflectivity characteristic
in the visible range but have different spectral reflectivity characteristics in the
invisible or low luminosity range, is judged by detecting the quantities of reflected
light from these two inks. Thus, a false or counterfeit paper sheet obtained by copying
with a color copier can be readily discriminated as such due to lack in the fidelity
of color reproduction. Further, color copies can be reliably judged as such because
of the high reflectivity in the infrared region. Further, a replica obtained by printing
can be reliably discriminated as such.
[0025] Further, not only the judgement of the authenticity but also the judgement of different
kinds of printed matter can be obtained by varying the place of presence of ink or
the color of ink.
[0026] Now, a difference embodiment for discriminating a counterfeit printed matter obtained
by a printing process will be described. Generally, light emitters which absorb light
energy of certain wavelengths and emit energy of the other wavelengths are known.
These light emitters include those, which are excited by visible light and emit near-infrared
radiation, and those, which are excited by near-infrared radiation of certain wavelengths
and emit near-infrared radiation of other wavelengths.
[0027] Fig. 10 shows a spectral characteristic of a light emitter ink, which is excited
by visible light and emits near-infrared radiation. Fig. 11 shows a spectral characteristic
of a light emitter ink, which is excited by near-infrared radiation of certain wavelengths
and emits near-infrared radiation of other wavelengths. With either of these light
emitters, the radiation is not sensitive to the human eye because it is in a near-infrared
wavelength range above the upper limit of the visible wavelength range. With a printed
matter, in which a mixture of either of such inks and an inorganic ink is used for
printing in the portion A while the inorganic ink having the characteristic of Fig.
3 is used for the portion B as in Fig. 4, both the portions A and B are seen to the
human eye that they are entirely of the same color. However, when the printed matter
is copied with a color copier, a different color results for the portion A though
the same color is reproduced for the portion B. This results from the ground as described
earlier. If the copy of the printed matter is a counterfeit paper money, it can thus
be discriminated as such by the human eye. Fig. 12 shows a further embodiment of the
invention applied to a counterfeit bank note discriminating apparatus for a bank note
using a blend ink containing a near-infrared emission ink in a pattern of Fig. 4 as
noted above.
[0028] As shown in Fig. 12, a bank note 4, which has a print pattern as shown in Fig. 4,
is conveyed on a conveying belt (not shown) in the direction of arrow 7. The bank
note is illuminated by light from an illumination light source 80. Where the near-infrared
emission ink has a character as shown in Fig. 10, the light source projects only visible
light of 520 nm peak. Where the near-infrared emission ink is of a character as shown
in Fig. 11, the light source projects only radiation in the infrared exciation wavelength
range of 800 nm to 900 nm. When the portion A of the bank note is illuminated by light
from the light source 80 shown in Fig. 10 or Fig. ll, it emits near-infrared radiation
of 700 to 900 nm or 700 to 800 nm. The near-infrared radiation from the bank note
4 is coupled through a focusing lens 81, a near-infrared filter 82, which allows only
the near-infrared components to pass, and an aperture unit 83 to a photoelectric converter
84. The aperture of the aperture unit 83 serves to determine the resolution in the
direction of transport of the bank note, the resolution in the direction perpendicular
to the direction of transport of the bank note and the field as mentioned earlier.
Further, a light source 14 and a light receiver 15 form a bank note passage detector
serving to determine the timing of reading data from the photoelectric converter 84.
The output signal from the bank note passage detector is fed to a control circuit
85 to be described later is detail. The output signal of the photoelectric converter
84 is amplified by an amplifier 86 to be fed to an analog memory 87. Of the output
of the amplifier 86, data representirg the quantity of near-infrared radiation from
the portion A of the bank note 4 is stored in the analog memory 87 in a timed relation
to the passage of the bank note 4 through the bank note passage detector 14, 15. The
output of the analog memory 87 is fed to a comparator 88. An output from reference
level generator 89 is supplied to the comparator 88, and the output thereof is fed
to a judging circuit 90.
[0029] The operation of the construction of Fig. 12 described above will now be described.
When the bank note 4 passes through the bank note passage detector 14, 15, the data
representing the quantity cf near-infrared radiation from the portion A of the bank
note is stored in the analog memory 87. The output of the analog memory 87 is compared
in the comparator 88 with the reference level provided from the reference level generator
89. More particularly, the comparator 88 makes a check as to whether the level of
the quantity of near-infrared radiation from the portion A is above a predetermined
level. If the compared level is above the predetermined level, the bank note is judged
to be an authentic one. With a counterfeit bank note obtained by printing, no near-infrared
radiation is detected so that the compared level is below the predetermined level.
In this case, the counterfeit bank note is thus judged as such. With a counterfeit
bank note obtained by copying with a color copier, the compared level of near-infrared
ray from the color toner is again below the level of the near-infrared ray radiated
by the excitation so that the bank note is judged to be counterfeit.
[0030] As has been shown, with the apparatus of the above. embodiment it is possible to
reliably detect a counterfeit bank note obtained by copying with a color copier or
that obtained by printing.
[0031] Among the light emitters, there are also those which, unlike those described in connection
with the preceding embodiment, are excited by ultraviolet radiation and emit visible
light or are excited by ultraviolet radiation and emit near-infrared radiation.
[0032] Fig. 13 shows a spectral characteristic of a light emitter ink, which is excited
by ultraviolet radiation of 300 to 400 nm and emits visible light of 450 to 550 nm.
Fig. 14 shows a spectral characteristic of a light emitter ink, which is excited by
ultraviolet radiation of 150 nm peak and emits near-infrared radiation of 680 to 900
nm. A printed matter, in which a mixture of either of these inks with an inorganic
ink having the characteristic of Fig. 3 is used for printing in the portion A in Fig.
4, will now be considered. When such a printed matter or bank note is printed using
an ultraviolet radiation source such as a commercially available mercury lamp, the
portion A emits visible light so that one can recognize that the printing ink for
the portion A contains a light emitter capable of emitting visible light. However,
one cannot recognize that this printing ink also contains a light emitter capable
of emitting near-infrared radiation. In other words, the visible light emitter is
incorporated for the purpose of camouflaging. Fig. 15 shows a further embodiment of
the invention applied to a counterfeit bank note discriminating apparatus for a bank
note using a blend ink as noted above.
[0033] As shown in Fig. 15, a bank note 4, which has a print pattern as shown in Fig. 4,
is conveyed on a conveyor belt (not shown) in the direction of arrow 7. The bank note
4 is illuminated by light from an illumination light source 91 (e.g., a low pressure
mercury lamp). When the bank note 4 is illuminated by light from the light source
91, the portion A emits visible light and near-infrared radiation. The visible light
and near-infrared radiation from the bank note are coupled through a focusing lens
92 to a dichroic mirror 93, which reflects only visible light. Visible light reflected
by the dichroic mirror 93, is coupled through an optical filter 94, which transmits
only visible light emitted by the light emitter as mentioned above, and an aperture
unit 95 to a photoelectric converter 96. Light transmitted through the dichroic mirror
93 is coupled through an optical filter 97, which transmits only near-infrared radiation,
and an aperture unit 98, to a photoelectric converter 99. The bank note passage detector
14, 15 has the same role as the one in the preceding embodiment of Fig. 12, and its
output signal is fed to a control circuit 100 to be described later in detail. The
outputs of the photoelectric converters 96 and 99 are amplified by respective amplifiers
?01 and 102 to be fed to respective analog memories 103 and 104. The outputs of the
amplifiers 101 and 102, data representing the quantities of visible light and near-infrared
radiation from the portion A of the bank note 4 are stored in the respective analog
memories 103 and 104 under the control of a signal provided from a control circuit
100 in timed relation to the passage of the bank note 4 through the bank note passage
detector 14, 15. The outputs of the analog memories 103 and 104 are fed to respective
comparators 105 and 106. An output of reference level generator 107 is fed to the
comparators 105 and 106, and the outputs thereof are fed to a judging circuit 108.
[0034] The operation of the construction of Fig. 15 described above will now be described.
When the bank note 4 passes through the bank note passage detector 14, 15, the quantities
of visible light and near-infrared radiation from the portion A of the bank note 4
are stored in the analog memories 103 and 104. The outputs of the analog memories
103 and 104 are compared in the comparators 105 and 106 with the reference level provided
from the reference level generator 107. More particularly, the comparator 105 compares
the level of the visible light quantity from the portion A with a certain fixed level,
while the comparator 106 compares the level of the near-infrared radiation from the
portion A with a certain fixed level. If both the compared levels are above the respective
fixed levels, the bank note is judged to be an authentic bank note. With a counterfeit
bank note in which neither visible light near-infrared radiation is emitted from the
portion A or, in the worst case, only visible light is emitted from the portion A,
the conditions mentioned above are note satisfied, so that the counterfeit bank note
is judged as such. Further, a counterfeit bank note obtained by copying with a color
copier is judged as such since neither visible light nor near-infrared radiation is
emitted from the portion A.
[0035] As has been shown, with the above embodiment it is possible to reliably detect a
counterfeit bank note obtained by printing or that obtained by copying with a color
copier.
[0036] While the above embodiment concerned with a printed matter where a light emitter
capable of emitting both visible light and near-infrared radiation wave used in the
form of a mixture with the ordinary ink, where the individual light emitters are solely
printed in different positions, the same effects may be obtained by altering the timing
of the sample pulse from the control circuit 100 such that the sample pulse corresponds
to the afore-mentioned positions. Further, where an ink capable of emitting near-infrared
radiation, only the component parts for the near-infrared radiation may be used.
[0037] Further, in addition to the inspection of bank note for the authenticity thereof,
discrimination of different kinds of bank notes may also be done by appropriately
arranging a suitable number of detecting sections such that the relevant different
kinds of ink are covered.
[0038] The preceding embodiment has concerned with a case where two different inks which
have different spectral reflectivity characteristics for the near-infrared region
though the visible range reflective characteristic is the same are used. Among the
light emitter inks, there is one, which has a spectral reflectivity characteristic
as shown in Fig. 16. Here, there is a reflectivity peak in a certain portion of the
visible wavelength region and also the reflectivity is increased on the long wavelength
side of the peak noted above and is high for near-infrared. (In this case, it is necessary
that the reflectivity h2 is increased on the long wavelength side of near 700 nm beyond
the visible region peak kl.) A printed matter, which has an impression of such ink
in a portion A of a sheet 4 as shown in Fig. 17, will now be considered. (The printed
matter also uses an inorganic ink having the characteristic of Fig. 3, with the reflectivity
being low for long wavelengths in the visible region and also in the nera-infrared
region.) When this printed matter is copied with a color copier, a color change results
for the portion A to a greater extent than that which may result in case of an inorganic
ink. This results because the light source used with the color copier provides higher
energy for the long wavelength side than for the short wavelength side so that the
red-sensitive section is affected to a greater extent by the ink in the portion A
than by the inorganic ink.
[0039] Fig. 18 shows a further embodiment of the invention applied to a counterfeit bank
note discriminating apparatus for a bank note such as that shown in Fig. 17.
[0040] As shown in Fig. 18, a bank note 4 which is like that shown in Fig. 17 is conveyed
on a conveyor belt (not shown) in the direction of arrow 7. The bank note 4 is illuminated
by light from an illuminatior lamp 109. The illumination light contains energy inthe
visible region and infrared region. Light reflected from the bank note 4 is coupled
through a focusing lens 110 to an optical filter lll. The optical filter 111 reflects
wavelengths longer than a wavelength in the neighborhood of a wavelength λ
3 in Fig. 16. Components of the incident light only in the neighborhood of the wavelength
λ
3, these being reflected by the optical filter 111, are coupled through a filter 112
and an aperture unit 113 to a photoelectric converter 114. Meanwhile, light transmitted
through the optical filter 111 is coupled to a second optical filter 115. The optical
filter 115 reflects wavelengths longer than X
2 in Fig. 16 to be coupled through a filter 116 and an aperture unit 117 to a photoelectric
converter 118. Light transmitted through the optical filter 115 is coupled through
a third optical filter 119, which transmits only wavelengths in the neighborhood of
λ
1 in Fig. 16, and an aperture unit 120 to a photoelectric converter 121. Fig. 19 shows
the transmittance characteristics X, Y and Z of the optical filters 112, 116 and 119.
The aperture units 113, 117 and 120 serve to determine the resolution in the direction
of transport of the bank note, the resolution in the direction perpendicular to the
direction of transport of the bank note. A light source 14 and a-light receiver 15
constitute a bank note passage detector having the same function as in the previous
embodiments. The output from the detector is-fed to a control circuit 128 to be described
later in detail. The output signals of the photoelectric converters 114, 118 and 121
are amplified by respective amplifiers 123, 124 and 125 to be fed to respective analog
memories 125, 126 and 127. The quantities of the λ
3, λ
2 and λ
1 wavelength components of light reflected from the portion A of the bank note 4 are
stored in the analog memories 125, 126 and 127 under tne control of a signal provided
from a control circuit 128 in a timed relation to the passage of the bank note 4 through
the bank note passage detector 14, 15. The output of the analog memory 125 is fed
to difference circuts 129 and 130 and also to a comparator 132. The output of the
analog memory 126 is fed to difference circuits 130 and 131 and also to a comparator
133. The output of the analog memory 127 is fed to difference circuits 129 and 131
and also to a comparator 134. An output signal of reference level generator 135 is
supplied to the comparators 132, 133 and 134. The outputs of the difference circuits
129 to 131 and the outputs of the comparators 132 to 134 are fed to a judging circuit
136.
[0041] The operation of the construction of Fig. 18 described above will now be described.
When the bank note 4 passes through the bank note passage detector 14, 15, the quantities
of the a3, λ
2 and λ
1 components of light reflected from the bank note 4 are stored in the analog memories
126 to 127. The difference circuit 129 calculates the difference between the outputs
of the analog memories 125 and 126. If the bank note is authentic, more À
3 component of light is reflected from the portion A than λ
1 component. In this case, the difference circuit 129 thus produces a "1" output. In
the case of an inorganic ink, more λ
1 component of light is reflected than x
3 component, so that the difference circuit 120 produces a "0" output. The judging
circuit 136 thus judges the bank note to be an authentic one when the output of the
difference circuit 129 is "1".
[0042] The difference circuit 131 calculates the difference between the outputs of the analog
memories 126 and 127. If the bank note is authentic, more λ
1 component of light is reflected than λ
1 component. In this case, the difference circuit 131 thus produces a "1" output. The
judging circuit 136 judges the bank note to be an authentic one when and only when
both the difference circuits 129 and 131 produce a "1" output. That is, the bank note
id judged to be authentic when and only when the quantity of the λ
1 component of light refelcts is greater than the quantity of the X
2 component and less than the λ
3 component.
[0043] As has been shown, with the above embodiment a counterfeit bank note can be reliably
detected.
[0044] The proceeding embodiment concerned with a method of detection with respect to a
single kind of ink. In case where a plurality of difference inks in which the wavelengths
λ
1, X
2 and X
3 shown in Fig. 16 are different, higher performance of detection can be realized with
an electronic circuit as shown in Fig. 18 by providing an increased number of photoelectric
converters in the optical system in correspondence to the number of wavelengths involved
for the wavelength analysis.
[0045] Now a further embodiment will be described with reference to Figs. 20 and 21. Among
light emitter inks, there is one having a spectral reflectivity characteristic as
shown in Fig. 20. If a printed matter, which uses such ink for a portion A as shown
in Fig. 4, is reproduced, by copying with a color copier or by printing, the reproduced
color will have a considerably different spectral reflectivity characteristic from
that of the original due to the photosensitive characteristics of the color copier
of characteristics of toner or depending upon the kinds of inks used for printing
although it may be more or less similar to the original color. In this embodiment,
a spectral reflectivity characteristic pattern for a certain portion or portions of
the wavelength range is previously obtained from the authentic bank note, and the
spectral reflectivity pattern read out from the bank note tested in compared with
the standard pattern. If the difference between the two patterns is within a certain
value, the bank note is judged to be an authentic one. Fig. 12 shows the circuit constructio
of this embodiment. The circuit includes photoelectric converters 151 to 158. Like
the embodiment of Fig. 8, near-infrared (NI), red (R), ornage (O), yellow (Y), green
(G), blue (B), magenta (M) and violet (V) components of reflected light, these components
being successively separated in the mentioned order through dichroic mirrors, are
coupled through filters and aperture units to the respective photoelectric converts
151 to 158. The outputs of the photoelectric converters 151 to 158 are amplified by
respective amplifiers 161 to 168 to be stored in an analog memory 170. If the bank
note is inspected for three different portions, data from these three portions are
successively stored in the analog memory 170. Like the previous embodiment of Fig.
8, the writing is done under the control of a timing signal produced from a control
circuit 171 according to a signal from bank note passage detector 14, 15.
[0046] When the writing of the spectral reflectivity characteristic data for the individual
inspection areas of the bank note in the analog memory 170 is completed, data of the
near-infrared component from the first inspection area is read out from the analog
memory 170 and fed to a difference circuit 172 under the control of a timing signal
from the control circuit 171. At this time, data for the near-infrared component from
the first inspection area, which has been obtained from the authentic bank note in
advance stored in a reference spectral reflectivity pattern memory 173, is read out
and supplied to the difference circuit 172 under the control of timing signal from
the control circuit 171. The difference circuit 172 calculates the difference between
the reference data and compared data and provides the absolute value of the difference
thus obtained. The output of the difference circuit 172 is set in an adder 174. Subsequently,
data of the red component from the first inspection area'is read out from the analog
memory 170 and fed to the difference circuit 172. At the same time, the red component
data for the first inspection area is read out from the reference spectral reflectivity
pattern memory 173 and supplied to the difference circuit 172. The difference circuit
172 again calculates the difference, and the absolute value thereof is added to the
difference data for the near-infrared component in the adder 174. Likewise, the differences
between the other components, i.e., orange, yellow, green, blue, magenta and violet
components, for the first inspection area and the corresponding data of the reference
spectral reflectivity pattern are also obtained, and their absolute values are accumulated
in the adder 174. When the above processing of the component data for the first inspection
area is completed, the data of the adder 174 is fed to a judging circuit 175. The
judging circuit 175 judges whether the total difference data from the adder 174 is
within a predetermined value.
[0047] When the judgement for the first inspection area is ended, similar operation of calculating
differences and adding together the absolute difference values thereof for the second
inspection area is caused to commence with the near-infrared component first. At this
time, the corresponding authentic bank note data for the second inspection point are
of course provided from the reference spectral reflectivity pattern memory 173. When
the processing of data for the second inspection area is completed, the total difference
data obtained in the adder 174 is fed to the judging circuit 175, whereby whether
it is within a predetermined value is judged. Likewise, for the third inspection area
the total difference data is obtained and fed to the judging circuit 175 for judgement
as to whether it is within a predetermined value.
[0048] When the judgement for all the inspection areas is completed, the judging circuit
175 executes a final judgement as to whether there are two or more insepec- tion areas,
for which th.
2 total difference data are above the respective predetermiend values. If there are
two or more such inspection areas, the judging circuit 175 judges the bank note to
a counterfeit one. The above judgement operation is effective for eliminating or at
least reducing the possibility of erroneously judging an authentic bank note to be
a counterfeit one in such a case as when the spectral reflectivity characteristic
is changed by contamination. For more stringent judgement, the number of inspection
spots may be increased, and the final judgement to be an authentic bank note may be
rendered when and only when the data for all the inspection spots are within respective
predetermined values. Further, where very stringent inspection is necessary such as
when a large number of counterfeit bank notes are circulated, the judgement level
of the judging circuit 175, i.e., the level to which the level of the output of the
adder 174 is compared (i.e., the predetermined values in the previous description)
may be made selectable to one of a plurality of different levels.
[0049] Further, discrimination of different kinds of bank notes can be simultaneously effected
by providing reference spectra reflectivity characteristic patterns for the individual
kinds of bank notes and by arranging such that the most similar reference pattern
may be selected from the comparison of the individual reference patterns with the
pattern obtained from each inspected bank note.
[0050] As has been shown, with the above embodiment reliable judgement can be obtained.
[0051] While some preferred embodiments of the invention have been described above, they
may be used either independently or in suitable combinations. In the latter case,
more reliable and accurate judgement can be obtained. Also, a variety of combinations
are possible for various purposes.
[0052] As has been described in detail in the foregoing, according to the invention a printed
matter, in which an ink fearuting a reflectivity characteristic or emittance characteristic
in a wavelength region outside the visible range is used, can be reliably inspected
for its authenticity by irradiating the printed matter with electromagnetic waves.
1. An apparatus for inspecting printed matters comprising means (8, 80) for irradiating
a printed matter (4) having an ink capable of reflecting or emitting electromagnetic
waves of wavelengths outside the visible range with electromagnetic radiation of a
predetermined wavelength range, means (12) for forming an electric signal according
to the energy distribution of electromagnetic waves reflected or emitted from said
printed matter, and means (20) for inspecting the printed matter (40) according to
said electric signal.
2. The apparatus for inspecting printed matters according to claim 1, characterized
in that said printed matter (4) includes a first print section (A) bearing an impression
of a first ink having at least one reflectivity peak in a visible region and high
reflectivity in the invisible region and a second print section (B) bearing an impression
of a second ink having at least one reflectivity peak in the visible region.
3. The apparatus according to claim 2, characterized in that said inspecting means
includes a memory area (17) for storing an output signal representing the level of
invisible light reflected from said first print section (A), a reference level generator
(18) for generating a signal of a reference level, a comparator (19) for comparing
the level of a component of the signal stored in said memory area (17) with the reference
level, and judging means (20) for judging the printed matter (14) by detecting whether
the level of an output from said comparator (19) exceeds the reference level.
4. The apparatus for inspecting printed matters according to claim 2, characterized
in that:
said inspecting means includes a memory area (17') for storing an output signal representing
the level of invisible light reflected from said second print section (B), a reference
level generator for generating (18) a signal of a reference level, a comparator (19')
for comparing the level of a component of the signal stored in the memory area (17')
with the reference level, and judging means (20) for inspecting the printed matter
(4) by detecting whether the level of an output from said comparator (19') exceeds
the reference level.
5. The apparatus for inspecting printed matters according to claim 2, characterized
in that:
said inspecting means includes a first memory area (17) for storing a first output
signal representing the level of invisible light reflected from said first print section
(A), a second memory area (17') for storing a second output signal representing the
level of invisible light reflected from said second print section (B), means (21)
for obtaining the difference between the levels of the components of the first and
second output signals stored in said first and second memory areas (17, 17') representing
the respective reflectivity, and a judging means (20) for effecting inspection of
the printed matter (4) according to the output of said difference obtaining means
(21).
6. The apparatus for inspecting printed matters according to claim 2, characterized
in that:
said inspecting means includes a first memory area (17)-for storing a first output
signal representing the level of invisible light reflected from said first print section
(A), a second memory area (17') for storing a second output signal representing the
level of invisible light reflected from said second print section (B), a reference
level generator (18) for generating reference level signals, first and second comparators
(19, 191) for comparing the levels of the components of the first and second signals stored
in the first and second memory areas (17, 17') with the reference level signals, respectively,
and judging means (20) for inspecting the printed matter (4) according to the outputs
of said first and second comparators (19, 19').
7. The apparatus for inspecting printed matters according to claim 2, characterized
in that:
said inspecting means includes a first memory area (17) for storing a first output
signal representing the level of invisible light reflected from said first print section
(A), a second memory area (17') for storing a second output signal representing the
level of invisible light reflected from said second print section (B), means (21)
for obtaining the difference between the levels of the components of the first and
second output signals stored in said first and second memory areas (17, 17'), a reference
level generator (18) for generating reference level signals, first and second comparators
(19, 19') for comparing the levels of the components of the first and second signals
with the reference level signals, respectively, and judging means (20) for inspecting
the printed matter (4) according to the outputs of said difference obtaining means
(21) and first and second comparators (19, 19').
8. The apparatus for inspecting printed matters according to claim 2, characterized
in that:
both said first and second inks are of chromatic or achromatic color;
said means for forming an electric signal includes a blue reflection mirror (36) to
which light reflected by said printed matter (4) is coupled, a first photoelectric
converter (41) for forming an electric signal representing blue light reflected by
said blue reflection mirror (36), a green reflection mirror (37) to which light transmitted
through said blue reflection mirror (36) is coupled, a second photoelectric converter
(45) for forming an electric signal representing to green light reflected from said
green reflection mirror (37), a red reflection mirror (38) to which light transmitted
through said green reflection mirror (37) is coupled, a third photoelectric converter
(49) for forming an electric signal representing red light reflected by said red reflection
mirror (38), a near-infrared filter (30) to which light transmitted through said red
reflection mirror (38) is coupled, and a fourth photoelectric converter (33) for forming
an electric signal representing near-infrared light transmitted through said near-infrared
filter (30); and
said inspecting means includes first to fourth memories (57, 55, 53, 51) in which
data in the output signals of said first to fourth photoelectric converters (41, 45,
49 and 32) for said first print section (A) are respectively stored, fifth to eighth
memories (58, 56, 54, 52) in which data in the output signals of said first to fourth
photoelectric converters for said second print section (B) are respectively stored,
first to fourth difference circuits (64, 63, 62, 61) for forming respective difference
signals between the outputs of said first and fifth memories, between the outputs
of said second and sixth memories, between the third and seventh memories and between
the fourth and eighth memories, a reference level signal generator (68) for generating
reference level signals, first and second comparators (56, 57) to which the outputs
of said respective fourth and eighth memories and the reference level signals are
supplied, and judging means (74) to which the outputs of said difference circuits
(64, 63, 62, 61) and the outputs of said comparators (56, 57) are supplied.
9. The apparatus for inspecting printed matters according to claim 1, characterized
in that said printed matter (4) includes a first print section (A) bearing an impression
of a first ink having at least one reflectivity peak in the visible region and at
least one reflectivity peak in the invisible region and a second pring section (B)
bearing an impression of a second ink having at least one reflectivity peak in the
visible region.
10. The apparatus for inspecting printed matters according to claim 9, characterized
in that:
said means for irradiating the printed matter with electromagnetic radiation is a
lamp (18) for producing electromagnetic radiation in a wavelength region corresponding
to the light emission characteristic of said first ink;
said means for forming an electric signal includes a near-infrared filter (82) to
which light reflected and light emitted by said printed matter (4) are coupled, and
a photoelectric converter (84) for generating an electric signal corresponding to
light from said filter (82); and
said inspecting means includes a memory (87) for storing the electric signal from
said photoelectric converter (84), a reference level generator (89) for generating
a reference level signal, a comparator (88) to which the output signal from said memory
(87) and said reference level signal are supplied, and judging means (90) to which
the output of said comparator (88) is supplied.
11. The apparatus for inspecting printed matters according to claim 1, characterized
in that said printed matter (4) includes a first print section (A) bearing an impression
of a first ink having a light emission characteristic having at least one peak in
the visible region and also at least one peak in the invisible region.
12. The apparatus for inspecting printed matters according to claim 11, characterized
in that:
said means for irradiating the printed matter with electromagnetic radiation is a
lamp (91) for emitting ultraviolet radiation in a wavelength region corresponding
to the light emission characteristic of said first ink;
said means for forming an electric signal includes a dichroic mirror (93) to which
light from said first print section (A) is coupled and which reflects only visible
light, a first photoelectric converter (96) for forming an electric signal corresponding
to visible light from said dischroic mirror (93), and a second photoelectric converter
(99) for forming an electric signal corresponding to near-infrared radiation transmitted
through said dichroic mirror (93); and
said inspecting means includes first and second memories (103, 104) for storing the
output signals from said respective photoelectric converters (96, 99), a reference
signal generator (107) for generating reference level signals, first and second comparators
(105, 106) to which the output signals of said respective first and second memories
(103, 104) and said reference level signals are supplied, and judging means (105)
to which the output signals of said first and second comparators (105, 106) are supplied.
13. The apparatus for inspecting printed matters according to claim 1, characterized
in that said printed matter (4) includes a print section (A) bearing an impression
of an ink having a reflectivity peak in a wavelength region (λ1) in the visible range, higher reflectivities than said reflectivity peak in a wavelength
region (X3) in the invisible range and lower reflectivities than said reflectivity peak in a
wavelength region (a2) between said two wavelength regions.
14. The apparatus for inspecting printed matters according to claim 13, characterized
in that:
said means for forming an electric signal includes first extracting means (111, 112)
for extracting a high reflectivity component of a first wavelength (X3) in said invisible region from the light reflected from said print section (A), a
first photoelectric converter (114) for obtaining an electric'signal corresponding
to said first wavelength (X3) component, second extracting means (115, 116) for extracting a component of a second
wavelength (X2) from said reflected light, a second photoelectric converter (118) for obtaining
an electric signal corresponding to said second wavelength (X2) component from said second extracting means (115, 116), third extracting means (115,
119) for extracting a component of a third wavelength (al) from said reflected light, and a third photoelectric converter (121) for forming
an electric signal corresponding to said third wavelength (Xl) component from said third extracting means (115, 119); and
said inspecting means includes first to third memories (125, 126, 127) for storing
the output signals of said respective first to third photoelectric converters (114,
118, 121), first to third difference obtaining means (129, 130, 131) for forming difference
signals between respective combinations of the output signals of said first to third
memories (125, 126, 127), a reference level generator (135) for generating reference
level signals, comparators (132, 133, 134) to which the output signals of said respective
first to third memories (125, 126, 127) and said reference level signals are supplied,
and judging means (136) to which the outputs of said difference circuits (129 to 131)
and the outputs of said comparators (132 to 134) are supplied.
15. The apparatus for inspecting printed matters according to claim 13, characterized
in that:
said means for forming an electric signal includes a plurality of photoelectric converters
(151 to 158) for forming electric signals representing respective spectral reflectivity
characteristics of the printed matter (4); and
said inspecting means includes a first memory (170) for storing the output signals
from said photoelectric converters (151 to 158), a second memory (173) in which data
representing a reference spectral reflectivity characteristic of said printed matter
(4) are stored, means (172) for obtaining a difference signal between two spectral
reflectivity data successively read out from said respective first and second memories
(170, 173), means (174) for accumulating the output of said difference obtaining means
(172), and judging means (175) to which the output of said accumulating means (174)
is supplied.