CN103106427A - Single parameter multiple-encryption anti-counterfeiting information storage trademark - Google Patents

Abstract

A single parameter multiple-encryption anti-counterfeiting information storage trademark can enable binary anti-counterfeiting information to be generated into binary modulation signals through multiple-encryption and channel coding, and enable the anti-counterfeiting information to be embedded into a whole trademark page through ordered changing of conductivity of amplitude modulation dots in a circulation table look-up method mode. The anti-counterfeiting information can be identified from any fragment during trademark identification, and the single parameter multiple-encryption anti-counterfeiting information storage trademark can be applied to all kinds of anti-counterfeiting trademarks.

Description

The polynary encryption anti-counterfeiting information storage of one-parameter trade mark

affiliated technical field:

The present invention relates to a kind of anti-false trademark, the polynary encryption anti-counterfeiting information of a kind of one-parameter storage trade mark particularly, this trade mark can be kept at binary add tight defense fake information on the trade mark page and realize the false proof of trade mark, and what this trade mark can be for extensive stock is false proof.

background technology:

Anti-false trademark, claim again antifalsification label, anti-counterfeiting mark, anti-false sign, anti-fake label, is a kind of proof label of discerning the false from the genuine, preventing personation, be in the commodity process of circulation people for distinguishing true and false, the sign of distinguishing the commercial quality quality of merchandise resources.Trademark anti-counterfeit is related to businessman, client and market safety, is related to protection businessman and client's interests.The trade mark of China has carried out innovation audaciously; adopted laser anti-counterfeit, the core micropore is false proof, invisible graph is false proof, magnetic ink is false proof, microfilm of characters is false proof, indicia distribution is false proof, light carving is false proof etc.; but the false proof struggle with fraud is high-tech trial of strength; advanced anti-counterfeiting technology has certain ageing again; so; must constantly promote trade mark anti-fake technique; could false proof with fake in forever maintain the leading position, this is also that protection businessman and client's interests are maintained the commodity safe basic assurance that circulates.

summary of the invention:

For reliability and the security that improves trademark anti-counterfeit, the deficiency that the present invention is directed to existing trademark anti-counterfeit existence is improved existing trade mark anti-fake technique, a kind of anti-counterfeiting information storage trade mark has been proposed, this trade mark is by the change to amplitude electric conductivity in brand printing, encryption anti-counterfeiting information is embedded on the whole trade mark page with scale-of-two coded signal form, can identify encryption anti-counterfeiting information when brand recognition from any one fragment, therefore there is very strong disguise and crush resistance.

The technical solution adopted for the present invention to solve the technical problems is:

Anti-counterfeiting information storage trade mark, by trade mark page paper, be printed on amplitude on trade mark page paper, be printed on the horizontal scanning line on trade mark page paper, the column scan line be printed on trade mark page paper forms, image and word on trade mark page paper consist of amplitude,

Binary add tight defense fake information according to storage, a part of amplitude on trade mark page paper is printed and is formed by electrically conductive ink, another part amplitude on trade mark page paper is printed and is formed by dielectric ink, and the horizontal scanning line on trade mark page paper and column scan line are printed and formed by electrically conducting transparent printing ink

The horizontal scanning line be printed on trade mark page paper has the N bar, the column scan line be printed on trade mark page paper has the M bar, the amplitude be printed on trade mark page paper is divided into the capable M row of N on the trade mark paper, amplitude neatly is matrix and arranges on trade mark page paper paper, allow i get 1 to N, allow j get 1 to M, j bar column scan line on trade mark page paper is electrically connected to the basal surface of each amplitude of the row of the j on trade mark page paper, the upper surface of each amplitude that the i bar horizontal scanning line on trade mark page paper is capable with i on trade mark page paper is electrically connected to

In the time the binary message of trade mark page stores need to being read, be set to successively high level to N bar horizontal scanning line by the 1st on trade mark page paper,

When the 1st horizontal scanning line on trade mark page paper is set to high level, the binary message of the 1st row storage on trade mark page paper is exported from the 1st column scan line to M bar column scan line with 0,1 code form, the 1st row on trade mark page paper is printed the amplitude output binary message 1 formed by electrically conductive ink, the 1st row on trade mark page paper is printed the amplitude output binary message 0 formed by dielectric ink, can repeat above-mentioned readout to other row on trade mark page paper

In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right

carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit, by non-obvious the extractible anti-counterfeiting information that embeds in the trade mark page, can provide valid certificates for true trade mark, there is stronger anti-forgery ability simultaneously.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right

carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit, by non-obvious the extractible anti-counterfeiting information that embeds in the trade mark page, can provide valid certificates for true trade mark, there is stronger anti-forgery ability simultaneously.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right

carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit, by non-obvious the extractible anti-counterfeiting information that embeds in the trade mark page, can provide valid certificates for true trade mark, there is stronger anti-forgery ability simultaneously.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right

carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit, by non-obvious the extractible anti-counterfeiting information that embeds in the trade mark page, can provide valid certificates for true trade mark, there is stronger anti-forgery ability simultaneously.

For solving above-mentioned technical matters, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, generate the scale-of-two anti-counterfeiting information table of 8 group, each 8 one group of scale-of-two anti-counterfeiting information in scale-of-two anti-counterfeiting information table are expanded to 32 one group of scale-of-two anti-counterfeiting information, generating high 24 is 0 32 one group scale-of-two anti-counterfeiting information table entirely, each 32 scale-of-two anti-counterfeiting information in 32 one group scale-of-two anti-counterfeiting information table are carried out to polynary cryptographic calculation, generate the binary add tight defense fake information table of 32 group, utilize 32 binary add tight defense fake informations process chnnel codings in binary add tight defense fake information table, generation has the binary modulated signal of 32 group of error detecting and error correcting function, chnnel coding can adopt loop coding, convolutional encoding or Turbo coding various ways, trade mark page original continuous is changed the line map, and image signal is processed (RIP) through rasterizing and hybrid screening is exported shadow tone hybrid screening picture signal, comprising amplitude and FM screened image signal, utilize 32 one group of binary modulated signals that generate to adopt the electric conductivity of amplitude in circulation look-up table modulation system modulation hybrid screening picture signal, the electric conductivity that makes amplitude is according to the dielectric ink amplitude and the electrically conductive ink amplitude is regular changes, make adjacent 32 amplitudes in the hybrid screening picture signal carry 32 scale-of-two anti-counterfeiting information by the change of electric conductivity, thereby be created on the hybrid screening picture signal that embeds anti-counterfeiting information in whole trade mark page site, realize the false proof of trade mark.

When extracting anti-counterfeiting information, at first gather trade mark page site electric conductivity signal, identification through the electric conductivity to amplitude, differentiate the electric conductivity of amplitude, extract the electric conductivity information of amplitude, the electric conductivity information of demodulation trade mark page amplitude, export the binary modulated signal of 32 group, the binary modulated signal of 32 one group to demodulation output carries out channel-decoding, generate scale-of-two deciphering anti-counterfeiting information table after channel-decoding, 32 binary messages of i group that scale-of-two is deciphered in the anti-counterfeiting information table are denoted as M _i.

Binary system is deciphered to 32 binary message M in the anti-counterfeiting information table _iThe initial value design of Position Control variable i be i=1, the initial value when initial value of setting encryption parameter C is encryption, the initial value when initial value of setting encryption variables q is encryption, the initial value design of binary operator control variables k is k=0, known by polynary ciphering process, during binary operator control variables k=0, decrypt operation is M _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, decrypt operation is M _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, decrypt operation is M _i=

C

C

C C

, k=2 wherein, during binary operator control variables k=3, decrypt operation is M _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, decrypt operation is M _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, decrypt operation is M _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, decrypt operation is M _i=

C

C

C

C

, k=6 wherein, during binary operator control variables k=7, decrypt operation is M _i=

C

C

C

C

, wherein k=7, decipher first M the anti-counterfeiting information table from binary system ₁Start, to each 32 the binary message M in binary system deciphering anti-counterfeiting information table _iCarry out corresponding decrypt operation, solve the binary system anti-counterfeiting information

, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, removes highly 24, recovers to generate the binary system anti-counterfeiting information table of 8 group, recovers anti-counterfeiting signal and also exports anti-counterfeiting information.Binary system is deciphered to 32 binary message M in the anti-counterfeiting information table _iThe initial value design of Position Control variable i be i=1, the initial value when initial value of setting encryption parameter C is encryption, the initial value when initial value of setting encryption variables q is encryption, the initial value design of binary operator control variables k is k=0, known by polynary ciphering process, during binary operator control variables k=0, decrypt operation is M _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, decrypt operation is M _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, decrypt operation is M _i=

C

C

C C

, k=2 wherein, during binary operator control variables k=3, decrypt operation is M _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, decrypt operation is M _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, decrypt operation is M _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, decrypt operation is M _i=

C

C

C

C

, k=6 wherein, during binary operator control variables k=7, decrypt operation is M _i=

C

C

C

C

, wherein k=7, decipher first M the anti-counterfeiting information table from binary system ₁Start, to each 32 the binary message M in binary system deciphering anti-counterfeiting information table _iCarry out corresponding decrypt operation, solve the binary system anti-counterfeiting information

, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, removes highly 24, recovers to generate the binary system anti-counterfeiting information table of 8 group, recovers anti-counterfeiting signal and also exports anti-counterfeiting information.

The accompanying drawing explanation

Below in conjunction with accompanying drawing, the present invention is further described.

Fig. 1 is one-piece construction figure of the present invention.

Fig. 2 is A of the present invention-A cut-open view.

Fig. 3 loads the anti-counterfeiting information process flow diagram.

Fig. 4 extracts the anti-counterfeiting information process flow diagram.

Embodiment

In Fig. 1 and Fig. 2, encryption anti-counterfeiting information storage trade mark, by trade mark page paper 7-1, be printed on amplitude 6-1 on trade mark page paper 7-1 to 6-150, be printed on horizontal scanning line 1-1 on trade mark page paper 7-1 and form to 2-10 to 1-15, the column scan line 2-1 that is printed on trade mark page paper 7-1, image and word on trade mark page paper 7-1 consist of to 6-150 amplitude 6-1

According to storage binary add tight defense fake information, a part of amplitude on trade mark page paper 7-1 is printed and is formed by electrically conductive ink, another part amplitude on trade mark page paper 7-1 is printed and is formed by dielectric ink, horizontal scanning line 1-1 on trade mark page paper 7-1 is printed and is formed by electrically conducting transparent printing ink to 2-10 to 1-15 and column scan line 2-1

In Fig. 1, the dark amplitude on trade mark page paper 7-1 is printed and is formed by electrically conductive ink, and the light amplitude on trade mark page paper 7-1 is printed and formed by dielectric ink,

The amplitude be printed on trade mark page paper 7-1 is divided into 15 row 10 row on the trade mark paper, amplitude 6-1 neatly is matrix and arranges on trade mark page paper 7-1 to 6-150, allow i get 1 to 15, allow j get 1 to 10, j bar column scan line on trade mark page paper 7-1 is electrically connected to the basal surface of each amplitude of j on trade mark page paper 7-1 row, the upper surface of each amplitude that the i bar horizontal scanning line on trade mark page paper 7-1 is capable with i on trade mark page paper 7-1 is electrically connected to

In the time the binary add tight defense fake information of trade mark page stores need to being read, 15 horizontal scanning lines of the 1st horizontal scanning line to the on trade mark page paper 7-1 are set to high level successively,

When the 1st horizontal scanning line 1-1 on trade mark page paper 7-1 is set to high level, the binary add tight defense fake information of the 1st row storage on trade mark page paper 7-1 is with 0, 1 code form is from 10 column scan line outputs of the 1st column scan line to the, the 1st row on trade mark page paper 7-1 is printed and is formed amplitude output binary message 1 by electrically conductive ink, the 1st row on trade mark page paper 7-1 is printed and is formed amplitude output binary message 0 by dielectric ink, therefore the binary add tight defense fake information 1100001000 that the 1st row is read, can repeat above-mentioned readout to other row on trade mark page paper 7-1.

In loading anti-counterfeiting information process flow diagram 3, original anti-counterfeiting information (image, word) is through digitized processing, generate the scale-of-two anti-counterfeiting information table of 8 group, 8 one group of binary messages in scale-of-two anti-counterfeiting information table are expanded to 32 one group of binary messages, generating high 24 is 0 32 one group scale-of-two anti-counterfeiting information table entirely, and 32 binary messages of i group in 32 one group scale-of-two anti-counterfeiting information table are denoted as

, i is greater than 0 positive integer, 32 binary add tight defense fake informations of first from 32 one group scale-of-two anti-counterfeiting information table start, to each 32 the scale-of-two anti-counterfeiting information in 32 one group scale-of-two anti-counterfeiting information table

carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that scale-of-two anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize the trademark anti-counterfeit printing, by non-obvious the extractible anti-counterfeiting information that embeds in the trade mark page, realize trademark anti-counterfeit.

In extracting anti-counterfeiting information process flow diagram 4, when extracting anti-counterfeiting information, at first gather the electric conductivity signal of trade mark page halftone dot image, through the identification of the electric conductivity to amplitude, differentiate the electric conductivity of amplitude, extract the electric conductivity information of amplitude, the electric conductivity information of demodulation trade mark page amplitude, export the binary modulated signal of 32 group, the binary modulated signal of 32 one group to demodulation output carries out channel-decoding, generates scale-of-two deciphering anti-counterfeiting information table after channel-decoding.

By 32 binary message M in the scale-of-two deciphering anti-counterfeiting information table generated after decoding _ithe initial value design of position control variable i be i=1, the initial value when initial value of setting encryption parameter C is encryption, the initial value when initial value of setting encryption variables q is encryption, the initial value design of binary operator control variable k is k=0, first M from the scale-of-two deciphering anti-counterfeiting information table generated ₁start, to each 32 the binary message M in scale-of-two deciphering anti-counterfeiting information table _ibe decrypted computing, solve the scale-of-two anti-counterfeiting information

, generating high 24 is 0 32 one group scale-of-two anti-counterfeiting information table entirely, removes highly 24, recovers to generate the scale-of-two anti-counterfeiting information table of 8 group, recovers anti-counterfeiting signal and also exports anti-counterfeiting information.

Claims (1)

1. one kind generates the binary modulated signal by anti-counterfeiting information by cryptographic calculation and chnnel coding, and by the circulation modulation system of tabling look-up, anti-counterfeiting information is embedded in to the polynary encryption anti-counterfeiting information storage of the one-parameter trade mark in full page, it is characterized in that:anti-counterfeiting information storage trade mark, by trade mark page paper, be printed on amplitude on trade mark page paper, be printed on the horizontal scanning line on trade mark page paper, the column scan line be printed on trade mark page paper forms, binary add tight defense fake information according to storage, a part of amplitude on trade mark page paper is printed and is formed by electrically conductive ink, another part amplitude on trade mark page paper is printed and is formed by dielectric ink, horizontal scanning line on trade mark page paper and column scan line are printed and are formed by electrically conducting transparent printing ink

In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i= C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i= C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i= C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i= C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit.In order to realize the encryption storage of trademark anti-counterfeit information, at first image false-proof information and character anti-counterfeiting information are carried out to digitized processing, utilize the binary system anti-counterfeiting information table of 8 one group of image false-proof information and character anti-counterfeiting Information generation, for preventing from ciphering process producing information spillover, each 8 one group of binary system anti-counterfeiting information in binary system anti-counterfeiting information table are expanded to 32 one group of binary system anti-counterfeiting information, generating high 24 is 0 32 one group binary system anti-counterfeiting information table entirely, 32 binary system anti-counterfeiting information of i in 32 one group binary system anti-counterfeiting information table group are denoted as

, 32 binary add tight defense fake informations of the group of the i in 32 one group binary add tight defense fake information table are denoted as to H _ii is greater than 0 positive integer, the eight-digit binary number encryption parameter is denoted as C, the binary system positive integer that encryption parameter C is 0<=C<=256, the eight-digit binary number encryption variables is denoted as q, the binary system positive integer that encryption variables q is 0<=q<=256, and the binary operator control variables is denoted as k, the binary system positive integer that binary operator control variables k is 0<=k<=7, operator

adopt+,-, *, four kinds of operators, during binary operator control variables k=0

be defined as respectively-,+, * ,+, * ,-, * ,+, during binary operator control variables k=1

be defined as respectively+, * ,+,+,-, * ,+, *, during binary operator control variables k=2

be defined as respectively-, * ,+,+, * ,-,+,-, during binary operator control variables k=3

be defined as respectively-, * ,+,-, * ,-,+, *, during binary operator control variables k=4

be defined as respectively+, * ,-, * ,+,-,+, *, during binary operator control variables k=5

be defined as respectively * ,+, * ,-,+,+,-, *, during binary operator control variables k=6

be defined as respectively * ,+,+,-, * ,+,+, *, during binary operator control variables k=7

be defined as respectively+, *, * ,-,+,-,-, *, during binary operator control variables k=0, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=0 wherein, during binary operator control variables k=1, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=1 wherein, during binary operator control variables k=2, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=2 wherein, during binary operator control variables k=3, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=3 wherein, during binary operator control variables k=4, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=4 wherein, during binary operator control variables k=5, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=5 wherein, during binary operator control variables k=6, polynary cryptographic calculation is defined as H _i= C

C

C

C

, k=6 wherein, during binary operator control variables k=7, polynary cryptographic calculation is defined as H _i=

C

C

C

C

, k=7 wherein, set the initial value of encryption parameter C, sets the initial value of encryption variables q, and the initial value of setting binary operator control variables k is k=0, sets 32 binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

Position Control variable i=1, set 32 binary add tight defense fake information H in 32 one group binary add tight defense fake information table _iPosition Control variable i=1, right

carry out H ₁=

C

C

C

C

polynary cryptographic calculation (wherein k=0), generate first binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₁, right carry out H ₁=

C

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₂=

C _?

C

C

C

(wherein k=1), generate second binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₂, right

carry out H ₂=

C _?

C

C

C

carry out i+1, q+1 and k+1 computing in the time of polynary cryptographic calculation, make next polynary cryptographic calculation point to H ₃=

C

C

C

C

(wherein k=2), generate the 3rd binary add tight defense fake information H in the binary add tight defense fake information table of 32 group ₃, this polynary cryptographic calculation goes on always until 32 binary system anti-counterfeiting information of last in binary system anti-counterfeiting information table, by each 32 the binary system anti-counterfeiting information in 32 one group binary system anti-counterfeiting information table

carry out polynary cryptographic calculation, generate and 32 one group 32 the one group binary add tight defense fake information table that binary system anti-counterfeiting information table is corresponding, amplitude in label printing is carried out to digitized processing, amplitude is set to two kinds, wherein by dielectric ink, print the amplitude formed and be defined as numeral 0, print by electrically conductive ink the amplitude formed and be defined as numeral 1, in the label printing process, utilize the binary add tight defense fake information of 32 group generated by the printing process of the amplitude on the circulation look-up table modulation trade mark page, by selecting dielectric ink and electrically conductive ink to print amplitude, the regular electric conductivity according to above-mentioned two kinds of amplitudes of amplitude on the trade mark page is changed, on the rear trade mark page of modulation, adjacent 32 amplitudes form one group of 32 binary message, make on the trade mark page and carry anti-counterfeiting information by the variation of amplitude electric conductivity, and this anti-counterfeiting information is embedded in whole trade mark page site, realize trademark anti-counterfeit.

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