CN106427286A - Single-parameter single-variable unitary layered encryption type binary anti-counterfeit printing method for Ren Min Bi - Google Patents
Single-parameter single-variable unitary layered encryption type binary anti-counterfeit printing method for Ren Min Bi Download PDFInfo
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- CN106427286A CN106427286A CN201610851102.3A CN201610851102A CN106427286A CN 106427286 A CN106427286 A CN 106427286A CN 201610851102 A CN201610851102 A CN 201610851102A CN 106427286 A CN106427286 A CN 106427286A
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
- B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
- B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
- B42D25/30—Identification or security features, e.g. for preventing forgery
- B42D25/305—Associated digital information
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Abstract
The invention discloses a single-parameter single-variable unitary layered encryption type binary anti-counterfeit printing method for the Ren Min Bi. According to the method, binary anti-counterfeit information can generate binary modulating signals through unitary layered encrypting and channel coding and are orderly changed and implanted into the whole surface of the Ren Min Bi in the shape of amplitude modulation dots and through the modulation mode of the cyclic table lookup method, and anti-counterfeit information can be recognized from any fragment in the recognition process of the Ren Min Bi. The method can be used in anti-counterfeit printing of the Ren Min Bi.
Description
Technical field:
The present invention relates to a kind of RMB anti-counterfeiting printing technology, particularly a kind of one-parameter univariate unitary layered encryption binary system
RMB anti-counterfeiting printing process, in the anti-counterfeit printing of RMB that this RMB anti-counterfeiting printing technology can be used for various face amounts.
Background technology:
Currency security is related to a national financial security, starts struggle that is false proof and faking from currency generation and does not just stop
Breath, the RMB of China is audaciously innovated, and employs watermark anti-counterfeiting technology, safety line anti-counterfeiting technology, carved intaglio print
Brush and gravure wiring anti-counterfeiting technology, red blue color fiber and colorless fluorescent fiber anti-counterfeiting technology, stealthy denomination digital anti-counterfeiting technology,
Photochromatic printing ink printing denomination digital anti-counterfeiting technology, yin yang complementarity are to being patterned anti-counterfeiting technology, number convex print anti-counterfeiting technology, miniature literary composition
Word anti-counterfeiting technology, colorless fluorescent pattern anti-counterfeiting technology, colored fluorescent pattern anti-fake technology and docking coincide etc. multinomial anti-counterfeiting technology,
But struggle that is false proof and faking is high-tech trial of strength, more advanced anti-counterfeiting technology have certain ageing, therefore it is necessary to not
So as to forever be in the leading position of anti-counterfeiting technology, this is also to maintain financial security of the country to disconnected lifting RMB anti-counterfeiting technology
Basic assurance.
Content of the invention:
In order to improve reliability and the safety of RMB anti-counterfeiting, the present invention is directed to the deficiency of existing RMB anti-counterfeiting presence to existing
RMB anti-counterfeiting technology is had to carry out improving it is proposed that the RMB that a kind of binary system coded signal modulates amplitude shape is prevented
Pseudo- technology, this RMB anti-counterfeiting technology, by the change of amplitude shape during RMB is printed, anti-counterfeiting information is entered with two
Coded signal form processed is embedded in the whole RMB page, can identify false proof from any one fragment when RMB identifies
Information, therefore has very disguised by force and crush resistance.
The technical solution adopted for the present invention to solve the technical problems is:First line number is entered to image and character anti-counterfeiting information
Wordization is processed, and generates 8 one group of binary system anti-counterfeiting information table using image and character anti-counterfeiting information, for preventing in ciphering process
Produce information spillover, 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 16 one group of binary systems
Anti-counterfeiting information, generates the 16 one group binary system anti-counterfeiting information table that most-significant byte is all 0, by 16 one group binary system anti-counterfeiting information table
In i-th group of 16 binary system anti-counterfeiting information be denoted as Ni, i is the positive integer more than 0, and eight-digit binary number encryption parameter is denoted as C, plus
Close parameter C is the bigit of 0 C 255, and binary operator control variable is denoted as k, and binary operator control variable k is 0
The bigit of k 7, binary system control variable is denoted as j, and control variable j is the integer of 0 j 7, operatorUsing+,-, ×, tetra- kinds of operators of ÷, binary operator control variable k=0
WhenBe defined as+, during binary operator control variable k=1Be respectively defined as+, ÷, binary operator control variable
During k=2Be respectively defined as-, ÷ ,+, during binary operator control variable k=3Fixed respectively
Justice for+, × ,+, ÷, during binary operator control variable k=4Be respectively defined as+, × ,+,
÷ ,-, during binary operator control variable k=5Be respectively defined as+, × ,+, ÷ ,-,
÷, during binary operator control variable k=6Be respectively defined as+, × ,+, ÷ ,-,
÷ ,+, during binary operator control variable k=7Be respectively defined as+, × ,+,
÷ ,-, ÷ ,+, ×, by i-th group of 16 binary system encryption anti-fake information in 16 one group binary system encryption anti-fake information table
It is denoted as Ni, during binary operator control variable k=0, unitary layered encryption operational formula is defined as, binary system calculation
During symbol control variable k=1, unitary layered encryption operational formula is defined as, binary operator control
During variable k=2, unitary layered encryption operational formula is defined as, binary operator control
During variable k=3 processed, unitary layered encryption operational formula is defined as, two
During system operator control variable k=4, unitary layered encryption operational formula is defined as , during binary operator control variable k=5, unitary layered encryption operational formula is defined as , during binary operator control variable k=6, unitary is layered and adds
Close operational formula is defined as,
During binary operator control variable k=7, unitary layered encryption operational formula is defined as , set the initial value of encryption parameter C, set the initial value k=0 of j and k
And j=0, set 16 binary system anti-counterfeiting information N in 16 one group binary system anti-counterfeiting information tableiPosition control variable i=1, from
First group 16 binary system anti-counterfeiting information N in 16 one group binary system anti-counterfeiting information table1Start, circulation adopts above-mentioned eight kinds of differences
Cryptographic calculation formula computing is encrypted to 16 binary system anti-counterfeiting information in 16 one group binary system anti-counterfeiting information table, and
Carry out i+1, j+1 and k+1 computing while cryptographic calculation each time, with the value change of i, k and j, by 16
Each group of 16 binary system anti-counterfeiting information in one group of binary system anti-counterfeiting information table are encrypted computing, generate and 16 one group two
The corresponding 16 one group binary system encryption anti-fake information table of system anti-counterfeiting information table, the shape to amplitude in RMB printing
It is digitized processing, amplitude is shaped toWithTwo kinds, whereinBe defined as numeral 0,Definition
For numeral 1, tabled look-up by circulation using the binary system encryption anti-fake information of 16 group generating in RMB printing process
Method modulates the amplitude on the RMB page, makes the amplitude on the RMB page regular according to above two amplitude modulation
The shape of site is changed, and on the RMB page after modulation, adjacent 16 amplitudes constitute the false proof letter of one group of 16 binary system
Breath is so that carry anti-counterfeiting information by the change of amplitude shape on the RMB page, and it is whole so that this anti-counterfeiting information is embedded in
In individual RMB page site, realize RMB anti-counterfeiting.By in the RMB page non-obvious embed extractible false proof
Information, can provide valid certificates for real Renminbi, have stronger anti-forgery ability simultaneously, and do not increase extra false proof one-tenth
This.
For solving above-mentioned technical problem, anti-counterfeiting information is digitized processing first, generates 8 one group of binary system
Anti-counterfeiting information table, anti-counterfeiting information can be image information and Word message information, by 8 one group in binary system anti-counterfeiting information table
Binary system anti-counterfeiting information expands to 16 one group of binary system anti-counterfeiting information, and 16 one group of binary systems that generation most-significant byte is all 0 are false proof
16 binary system anti-counterfeiting information of each of 16 one group binary system anti-counterfeiting information table are carried out layered encryption fortune by information table
Calculate, generate 16 one group of binary system encryption anti-fake information table, using 16 binary systems in binary system encryption anti-fake information table
Encryption anti-fake information, through chnnel coding, generates the binary modulated signal of 16 group with error detecting and error correcting function, letter
RMB page original continuous can be changed the line map picture by road coding using loop coding, convolutional encoding or Turbo coding various ways
Signal is processed through rasterizing(RIP)Export halftoning hybrid screening picture signal with hybrid screening, including amplitude
With FM screened image signal, modulated using circulation look-up table modulation system using the 16 one group of binary modulated signals generating
The shape of amplitude in halftoning hybrid screening picture signal, make the shape of amplitude according toWithRegular
Raw change, makes adjacent 16 amplitudes in halftoning hybrid screening picture signal carry 16 binary systems by the change of shape
Encryption anti-fake information, thus generate the halftoning hybrid screening image letter of embedded anti-counterfeiting information in whole RMB page site
Number, realize the anti-counterfeit printing of RMB.
When extracting anti-counterfeiting information, gather RMB page halftone dot image signal first, through the shape to amplitude
Fuzzy diagnosis, differentiate the shape of amplitude, extract the edge signal of amplitude and shape information, demodulate the RMB page
The shape information of amplitude, the binary modulated signal of 16 one group of output, the binary system to 16 group of demodulation output
Modulated signal carries out channel decoding, recovers to generate binary system deciphering anti-counterfeiting information table after channel decoding.
Binary system is deciphered 16 binary informations in anti-counterfeiting information table and is denoted as Hi, by ciphering process, extensive
In the binary system deciphering anti-counterfeiting information table of repetitive generation, unitary layering deciphering computing during binary operator control variable k=0 is, during binary operator control variable k=1 unitary layering deciphering computing be,
During binary operator control variable k=2 unitary layering deciphering computing be, binary system calculation
Symbol control variable k=3 when unitary layering deciphering computing be, binary system calculation
Symbol control variable k=4 when unitary layering deciphering computing be, two
During system operator control variable k=5 unitary layering deciphering computing be , during binary operator control variable k=6 unitary layering deciphering computing be , unitary layering during binary operator control variable k=7
Deciphering computing is,
By 16 binary informations H in the binary system deciphering anti-counterfeiting information table recovering after decoding to generateiPosition control initial guess set
It is set to i=1, binary operator control variable initial value design is k=0, the from the binary system deciphering anti-counterfeiting information table recovering to generate
One group of H1Start, each group of 16 binary informations in anti-counterfeiting information table are deciphered to the binary system recovering to generate and carries out accordingly
Unitary layering deciphering computing, solves binary system anti-counterfeiting information Ni, generate 16 one group of binary system anti-counterfeiting information that most-significant byte is all 0
Table, removes most-significant byte, recovers to generate 8 one group of binary system anti-counterfeiting information table, recovers anti-counterfeiting signal and export anti-counterfeiting information.
Brief description
The present invention is further described below in conjunction with the accompanying drawings.
Fig. 1 loads anti-counterfeiting information flow chart.
Fig. 2 extracts anti-counterfeiting information flow chart.
Specific embodiment
In loading anti-counterfeiting information flow process Fig. 1, original anti-counterfeiting information(Image, word)Encrypted, generate the two of 8 one group
System anti-counterfeiting information table, 8 one group of binary informations in binary system anti-counterfeiting information table are expanded to 16 one group of binary system letters
Breath, generates the 16 one group binary system anti-counterfeiting information table that most-significant byte is all 0, i-th group in 16 one group binary system anti-counterfeiting information table
16 binary informations are denoted as Ni, i is the positive integer more than 0, and eight-digit binary number encryption parameter is denoted as C, and encryption parameter C is 0 C
255 bigit, binary operator control variable is denoted as k, and binary operator control variable k is the two of 0 k 7 to enter
Integer processed, binary system control variable is denoted as j, and control variable j is the integer of 0 j 7, operatorUsing+,-, ×, tetra- kinds of operators of ÷, binary operator control variable k=0
WhenBe defined as+, during binary operator control variable k=1Be respectively defined as+, ÷, binary operator control variable
During k=2Be respectively defined as-, ÷ ,+, during binary operator control variable k=3Respectively
Be defined as+, × ,+, ÷, during binary operator control variable k=4Be respectively defined as+, × ,+,
÷ ,-, during binary operator control variable k=5Be respectively defined as+, × ,+, ÷ ,-,
÷, during binary operator control variable k=6Be respectively defined as+, × ,+, ÷ ,-,
÷ ,+, during binary operator control variable k=7Be respectively defined as+, × ,+,
÷ ,-, ÷ ,+, ×, during binary operator control variable k=0, unitary layered encryption operational formula is defined as,
During binary operator control variable k=1, unitary layered encryption operational formula is defined as, binary system calculation
During symbol control variable k=2, unitary layered encryption operational formula is defined as, binary system calculation
During symbol control variable k=3, unitary layered encryption operational formula is defined as,
During binary operator control variable k=4, unitary layered encryption operational formula is defined as , during binary operator control variable k=5, unitary layered encryption operational formula is defined as , unitary layered encryption during binary operator control variable k=6
Operational formula is defined as, binary system
During operator control variable k=7, unitary layered encryption operational formula is defined as , set the initial value of encryption parameter C, set the initial value k=of j and k
0 and j=0, set 16 binary system anti-counterfeiting information N in 16 one group binary system anti-counterfeiting information tableiPosition control variable i=1, from
First group of 16 binary information N in 16 one group binary system anti-counterfeiting information table1Start, circulation is using above-mentioned eight kinds different adding
Close operational formula is encrypted computing to 16 binary system anti-counterfeiting information in 16 one group binary system anti-counterfeiting information table, and every
Carry out i+1, j+1 and k+1 computing, with the value change of i, k and j, by 16 one group while cryptographic calculation
16 binary system anti-counterfeiting information of in binary system anti-counterfeiting information table each group are encrypted computing, generate and 16 one group of binary systems
The corresponding 16 one group binary system encryption anti-fake information table of anti-counterfeiting information table, is carried out to the shape of amplitude in RMB printing
Digitized processing, amplitude is shaped toWithTwo kinds, whereinBe defined as numeral 0,It is defined as counting
Word 1, passes through to circulate look-up table tune using the binary system encryption anti-fake information of 16 group generating in RMB printing process
Amplitude on the RMB page processed, makes the amplitude on the RMB page regular according to above two amplitude
Shape be changed, on the RMB page after modulation, adjacent 16 amplitudes constitute one group of 16 binary system anti-counterfeiting information,
Make to carry anti-counterfeiting information by the change of amplitude shape on the RMB page, and make this anti-counterfeiting information be embedded in whole people
In people's coin page site, realize RMB anti-counterfeiting printing.
In extracting anti-counterfeiting information flow process Fig. 2, when extracting anti-counterfeiting information, collection RMB page halftone dot image letter first
Number, through the fuzzy diagnosis to the shape of amplitude, differentiate the shape of amplitude, extract amplitude edge signal and
Shape information, the shape information of demodulation RMB page amplitude, the binary modulated signal of 16 one group of output, to demodulation
The binary modulated signal of 16 group of output carries out channel decoding, recovers generation binary system deciphering false proof after channel decoding
Information table.
Binary system is deciphered 16 binary informations in anti-counterfeiting information table and is denoted as Hi, by ciphering process, extensive
In the binary system deciphering anti-counterfeiting information table of repetitive generation, unitary layering deciphering computing during binary operator control variable k=0 is, during binary operator control variable k=1 unitary layering deciphering computing be,
During binary operator control variable k=2 unitary layering deciphering computing be, binary system
During operator control variable k=3 unitary layering deciphering computing be, binary system
During operator control variable k=4 unitary layering deciphering computing be
, during binary operator control variable k=5 unitary layering deciphering computing be , during binary operator control variable k=6 unitary layering deciphering computing be , unitary during binary operator control variable k=7
Computing is deciphered in layering
, by 16 binary informations H in the binary system deciphering anti-counterfeiting information table recovering after decoding to generateiPosition control initial guess set
It is set to i=1, binary operator control variable initial value design is k=0, the from the binary system deciphering anti-counterfeiting information table recovering to generate
One group of H1Start, corresponding one is carried out to each group of 16 binary informations in the binary system group anti-counterfeiting information table recovering generation
Unit's layering deciphering computing, solves binary system anti-counterfeiting information Ni, generate the 16 one group binary system anti-counterfeiting information table that most-significant byte is all 0,
Remove most-significant byte, recover to generate 8 one group of binary system anti-counterfeiting information table, recover anti-counterfeiting signal and export anti-counterfeiting information.
Claims (1)
1. anti-counterfeiting information is passed through cryptographic calculation and chnnel coding and generates binary modulated signal by one kind, and is tabled look-up tune by circulation
Anti-counterfeiting information is embedded in the one-parameter univariate unitary layered encryption binary system RMB anti-counterfeiting print in full page by mode processed
Brush method, is characterized in that:Anti-counterfeiting information is digitized, generates 8 one group of binary system anti-counterfeiting information table, anti-counterfeiting information is
Image information and Word message, for preventing from producing information spillover in ciphering process, by 8 one group in binary system anti-counterfeiting information table
Binary system anti-counterfeiting information expands to 16 one group of binary system anti-counterfeiting information, and 16 one group of binary systems that generation most-significant byte is all 0 are false proof
Information table, i-th group of 16 binary system anti-counterfeiting information in 16 one group binary system anti-counterfeiting information table are denoted as Ni, i is more than 0
Positive integer, eight-digit binary number encryption parameter is denoted as C, and encryption parameter C is the bigit of 0 C 255, binary operator control
Variable processed is denoted as k, and binary operator control variable k is the bigit of 0 k 7, and binary system control variable is denoted as j, controls
Variable j is the integer of 0 j 7, operatorUsing+,-, ×, tetra- kinds of ÷ calculation
Symbol, during binary operator control variable k=0Be defined as+, during binary operator control variable k=1It is respectively defined as
+, ÷, during binary operator control variable k=2Be respectively defined as-, ÷ ,+, binary operator control variable k
When=3Be respectively defined as+, × ,+, ÷, during binary operator control variable k=4Be respectively defined as+, × ,+, ÷ ,-, during binary operator control variable k=5Be respectively defined as+, × ,+, ÷ ,-, ÷, during binary operator control variable k=6Be respectively defined as+, × ,+, ÷ ,-, ÷ ,+, binary operator control variable k=7
WhenBe respectively defined as+, × ,+, ÷ ,-, ÷ ,+, ×, by 16 one group
I-th group of 16 binary system encryption anti-fake information in binary system encryption anti-fake information table are denoted as Ni, binary operator control variable k
When=0, unitary layered encryption operational formula is defined as, unitary layered encryption during binary operator control variable k=1
Operational formula is defined as, unitary layered encryption operational formula during binary operator control variable k=2
It is defined as, unitary layered encryption operational formula during binary operator control variable k=3
It is defined as, unitary layered encryption fortune during binary operator control variable k=4
Calculate formula to be defined as, binary operator control variable k=5
Shi Yiyuan layered encryption operational formula is defined as,
During binary operator control variable k=6, unitary layered encryption operational formula is defined as , during binary operator control variable k=7, the computing of unitary layered encryption is public
Formula is defined as
, set the initial value of encryption parameter C, set initial value k=0 and j=0 of j and k, set 16 in 16 one group binary system anti-counterfeiting information table
Position binary system anti-counterfeiting information NiPosition control variable i=1, first group 16 two from 16 one group binary system anti-counterfeiting information table
System anti-counterfeiting information N1Start, circulation is using above-mentioned eight kinds different cryptographic calculation formula to 16 one group of binary system anti-counterfeiting information
In table, 16 binary system anti-counterfeiting information are encrypted computing, and carry out i+1, j+1 and k+ while cryptographic calculation each time
1 computing, with the value change of i, k and j, by entering to each group 16 two in 16 one group binary system anti-counterfeiting information table
Anti-counterfeiting information processed is encrypted computing, generates 16 one group binary systems corresponding with 16 one group binary system anti-counterfeiting information table and encrypts
Anti-counterfeiting information table, is digitized processing to the shape of amplitude in RMB printing, amplitude is shaped toWithTwo kinds, whereinBe defined as numeral 0,It is defined as numeral 1, using 16 generating in RMB printing process
The binary system encryption anti-fake information of one group of position is passed through to circulate the amplitude that look-up table is modulated on the RMB page, makes RMB page
The regular shape according to above two amplitude of amplitude on face is changed, phase on the RMB page after modulation
Adjacent 16 amplitudes constitute one group of 16 binary system anti-counterfeiting information so that passing through the change of amplitude shape on the RMB page
Change and carry anti-counterfeiting information, and so that this anti-counterfeiting information is embedded in whole RMB page site, realize RMB anti-counterfeiting.
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Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN101777134A (en) * | 2010-03-01 | 2010-07-14 | 北京印刷学院 | Presswork encryption security printing technology based on multi-system quadrature amplitude modulation |
CN102402696A (en) * | 2011-04-25 | 2012-04-04 | 北京印刷学院 | Multi-dimensional encryption anti-counterfeiting printing technology based on binary signals |
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Publication number | Priority date | Publication date | Assignee | Title |
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CN101777134A (en) * | 2010-03-01 | 2010-07-14 | 北京印刷学院 | Presswork encryption security printing technology based on multi-system quadrature amplitude modulation |
CN102402696A (en) * | 2011-04-25 | 2012-04-04 | 北京印刷学院 | Multi-dimensional encryption anti-counterfeiting printing technology based on binary signals |
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