WO2002023481A1 - Optical watermark - Google Patents

Optical watermark Download PDF

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Publication number
WO2002023481A1
WO2002023481A1 PCT/SG2000/000147 SG0000147W WO0223481A1 WO 2002023481 A1 WO2002023481 A1 WO 2002023481A1 SG 0000147 W SG0000147 W SG 0000147W WO 0223481 A1 WO0223481 A1 WO 0223481A1
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WO
WIPO (PCT)
Prior art keywords
watermark
latent image
layers
layer
dot
Prior art date
Application number
PCT/SG2000/000147
Other languages
French (fr)
Inventor
Sheng Huang
Jian Kang Wu
Original Assignee
Trustcopy Pte Ltd.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Trustcopy Pte Ltd. filed Critical Trustcopy Pte Ltd.
Priority to AT00964869T priority Critical patent/ATE289437T1/en
Priority to AU75690/00A priority patent/AU785178B2/en
Priority to DE60018222T priority patent/DE60018222T2/en
Priority to JP2001549269A priority patent/JP4373045B2/en
Priority to CNB008020361A priority patent/CN1170254C/en
Priority to EP00964869A priority patent/EP1317734B1/en
Priority to PCT/SG2000/000147 priority patent/WO2002023481A1/en
Priority to US09/810,971 priority patent/US7366301B2/en
Publication of WO2002023481A1 publication Critical patent/WO2002023481A1/en

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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T1/00General purpose image data processing
    • G06T1/0021Image watermarking
    • G06T1/005Robust watermarking, e.g. average attack or collusion attack resistant
    • G06T1/0071Robust watermarking, e.g. average attack or collusion attack resistant using multiple or alternating watermarks
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2201/00General purpose image data processing
    • G06T2201/005Image watermarking
    • G06T2201/0051Embedding of the watermark in the spatial domain

Definitions

  • This invention generally relates to a method and apparatus for producing optical watermarks on printed and electronic documents.
  • carrier dot pattern The structure of a watermark, referred to as carrier dot pattern, is a repetitive pattern with the simplest and most basic as a two- dimensional ("2-D") dot array.
  • the complexity of the dot pattern structure determines the security level.
  • Embedding a latent image object into a watermark is implemented by the modulation on the dot pattern with the latent image object.
  • Observing the latent image using a decoder is a process of demodulation.
  • the decoder is also a structured pattern, which corresponds to a particular dot pattern. It is implemented as an optical instrument, such as gratings, lenses, Ronchi Rulings, special films, or even a photocopier.
  • US 5,915,027 relates to digital watermarking of data, including image, video and audio data, which is performed by repeatedly inserting the watermark into subregions or subimages of the data. Similarly, the watermark is repeatedly extracted from the subregions of the data. This method is in a single layer and is not suitable to a text-based document or a document printed on paper.
  • US 4,921 ,278 has an identification system using a computer generated Moire, and is based on a computer generated random pattern of broken lines. The overlap of the object grid and the reference grid will induce the moire effect. This method is in a single layer, is rather simple, and does not provide enough protection, such as counterfeit indication.
  • US 5,734,752 is a method for generating watermarks in a digitally reproducible document which are substantially invisible when viewed. It uses stochastic screen patterns suitable for reproducing a gray image on a document, and another stochastic screen to correlate the first in order to view the content. This is quite similar to US 4,921,278, except that it uses stochastic screen patterns to represent the gray images.
  • It is the principal object of the present invention is to address this problem and to provide a watermark which, in general, will not normally allow all necessary information to be revealed.
  • the present invention provides a method and apparatus to protect documents from counterfeit and forgery. It embeds multiple latent image objects into layers of repetitive structures to generate a watermark. The watermark is then incorporated into a document as for example, a seal, logo or background. This may be referred to as an optical watermark.
  • An optical watermark has one or several watermark layers.
  • One or two latent image objects are embedded into each watermark layer.
  • Each watermark layer has different structure, as well as a corresponding decoder to observe the latent image object embedded in it.
  • the latent image object embedded in a watermark layer can not be observed by the unaided human eye unless a decoder corresponding to that watermark layer's structure is overlapped onto the watermark.
  • a decoder for one watermark layer will not reveal latent image objects in other watermark layers due to the difference in their structure.
  • decoders can be considered as keys to the secrets, and the secrets are the latent image objects embedded in the watermark.
  • Layers in the optical watermark protect each other. Without knowing all the secrets (including latent image objects and parameters of the dot patterns) of the optical watermark, it's almost impossible to forge the watermark or change the latent image objects in watermark layers without being noticed.
  • an optical watermark may appear as the logo of a company on a document issued by that company.
  • the first layer may be a cancellation word, such as "COPY”, and the verification device is the photocopier.
  • the cancellation word "COPY” appears if the printed original document is photocopied.
  • the latent image object in the second layer may be a logo of the company, and the verification device is a specially designed lens with gratings defined by periodical functions.
  • the lens can be given to the related organisations to verify the originality of the document.
  • the third layer may be embedded with a logo of a trusted third party.
  • the verification device is also a lens, but the structure is random dot pattern, which is more secure than the other layers.
  • Figure 1 shows a layered structure of an optical watermark
  • Figure 2 is an illustration of embedding latent image objects into a basic watermark layer
  • Figure 3 is a demodulation result of letters "T" and "C";
  • Figure 4 shows the structure of the optical watermark
  • Figure 5 shows a watermark with a random dot pattern
  • Figure 6 shows a counterfeit-proof watermark layer with a letter "P" embedded
  • Figure 7 is an electronic application
  • Figure 8 is an electronic service model.
  • the optical watermark in this invention has a multiple layered structure as shown in Figure 1. Watermark layers are superposed on each other to provide multiple layers and categories of protection. This superposition of several layers means that it is very difficult, if not impossible, to derive the parameters of the structure and the hidden information from the optical watermark alone.
  • Each watermark layer is a repetitive structured array of dots.
  • Latent image objects are embedded into the watermark layer by modulation. This may include, for example, phase modulation.
  • the structure and orientation of the different watermark layers in an optical watermark must be different from each other. Only the decoder corresponding to a particular watermark layer can be used to view the latent image object embedded in that particular watermark layer.
  • the basic watermark layer is a 2-D dot array, varying in two orthogonal directions.
  • phase modulation can be applied to both directions. As shown in Figure 2, part 205 is the phase modulation in the horizontal direction to embed a letter "T”, while part 206 shows the phase modulation in the vertical direction to embed a letter "C”.
  • the phase modulation changes the distances between a pair of dots at the edge of the latent images in the direction of the phase modulation. According to the characteristics of the human visual system, such changes of distances will make the edge of the latent image become either lighter or darker than the overall grey level of the dot array. Such effect will reveal the shape of the latent images.
  • a "smoothing" process may be applied to the regions with an abrupt phase shift. For example, in Figure 2, along regions indicated as 201 and 202, the distance between a pair of dots was greater than the spatial repetitive period of the dot array. Therefore, a dot is added, together with distance adjustment, to make the edge a little darker. Patterns 201 and 202 are the results after compensation.
  • Patterns 203 and 204 are the result of this type of adjustment.
  • the decoder should have a grating structure with the same spatial frequency as the dot arrays.
  • the orientation of the decoder should be aligned in the same direction.
  • Figure 3(01) and Figure 3(02) show the demodulation result of Figure 2. The detailed mathematical analysis is in accordance with a Fourier Series Expansion.
  • dot arrays are selected as the carrier dot patterns to embed latent image objects. Because dot arrays can be considered as 2-D signals, which vary in two orthogonal directions, two latent image objects can be modulated to one dot pattern in two directions with phase modulation. For the sake of simplicity, the dot arrays discussed here have the same spatial repetitive frequency in both directions. In an actual optical watermark, the frequencies in the two directions may be different.
  • a Fourier series expansion is employed to analyse the modulation f e TO 11 and demodulation.
  • the superposition of line gratings can be represented with the product of functions. This multiplicative model enables analysis with a Fourier series expansion.
  • the phase-shifted dot array can be represented as/ j f ⁇ j ) and f 2 ( ⁇ ,y) , each corresponding to a modulation direction.
  • f 0 (x,y) l- ⁇ (x-nT) ⁇ (y-nT) (1)
  • the decoders can be represented as
  • the angle ⁇ is the angle between the orientation of f d (x,y) and the direction of y-axis.
  • f 0 (x,y) l ⁇ cos(2 ⁇ )][ ⁇ s(2 ⁇ y)] (7)
  • f ⁇ (x,y) 1 - [- + - ⁇ cos(n ⁇ ) COS(2 ⁇ - x)] [- + - ⁇ cos(2 - y)] (8)
  • the mathematical derivation shows that with phase modulation two latent image objects can be modulated to the basic dot pattern. Because of the relatively high frequency of the dot array and the compensation methods applied on the edge, the latent image objects will not be observed by unaided eyes. In order to view the latent image objects, the frequency of the decoder should be the same as the frequency of the basic carrier dot pattern along that direction, and the orientation of the decoder should be aligned to the same direction in which the latent image object is modulated.
  • the human visual system has the highest contrast sensitivity in the mid spatial frequency range, around 2-6 c/deg.
  • the sensitivity has a sharp drop at high spatial frequencies.
  • the human eye is sensitive to relative phase, which is the shift or displacement between spatial signals at same frequency.
  • the threshold phase is represented by the displacement of about 0.85' arc.
  • the threshold of relative phase is about 5° .
  • a human observer will not be able to observe the relative phase, which is less than this threshold. So for high frequency signals, the displacement will not be easily observed by unaided eyes.
  • the latent image object in each watermark layer is encoded with relatively high repetitive frequency dot patterns with phase modulation.
  • the displacement is not significant to the human visual system because the relative phase difference is lower than, or similar to, the threshold at that relative high frequency, which is selected for the optical watermark. So the latent image objects will not be observed without proper decoders.
  • the frequencies of dot arrays along two directions can be different, and the dot arrays may take any orientation.
  • the watermark layer is denoted as L(f u ,f v , ⁇ ,g u ,g v ) , where f u and f v are the frequencies of dot array in two directions u and v , respectively, and ⁇ is the angle between u and x (horizontal axis)
  • the functions g ⁇ and g v whose value can only be 1 or 0, represent the latent image objects in this layer.
  • the function representing a watermark layer is:
  • each latent image object in this type of watermark layer There are two parameters for each latent image object in this type of watermark layer: one is the modulation frequency and the other is the modulation orientation.
  • the parameters for the latent image g u are f u and u . While the parameters for the latent image g v are f v and v . Only a decoder with the corresponding frequency can make a particular latent image visible when it's rotated to the corresponding direction. So the keys to the secrets in this type of watermark layer are the modulation frequency and the modulation orientation.
  • Figure 401 shows the coordinates of one watermark layer, with reference to a x-y co-ordinate.
  • Figure 402, 403 and 404 are three watermark layers, and Figure 405 is their superposition result.
  • the optical watermark is the superposition of several watermark layers. Such superposition can be represented as
  • the orientation difference A ⁇ y should be large enough, for example A ⁇ y ⁇ 60° , or in some cases A ⁇ y ⁇ 45° .
  • a ⁇ ⁇ should be less than 60° , for example A ⁇ y ⁇ 60° .
  • Figure 4(05) shows an sample of the optical watermark, which is the superposition of Figure 4(02), Figure 4(03) and Figure 4(04).
  • the frequency and the orientation of the decoder are the keys to decode the latent image objects. Only when the frequency of the decoder matches the modulation frequency and orientation of a particular latent image object, will the latent image object appear in the superposition.
  • this multiple-layer structure is that all the watermark layers protect each other. Without knowing the details (parameters and latent image objects) of all the watermark layers, it's very difficult, and almost impossible, to change the information in one of the watermark layers. If one of the watermark layers is changed, all other watermark layers will also be affected by this change. Therefore, this change, even it may be authorized by one party, will invalidate the authenticity of the document, in a scenario of a multiple party application, where each party is holding a "key" to a latent image object. Coordinate mapping to generate complex watermark layer
  • basic 2-D dot arrays can be generalized to any 2-D pattern, by coordinate mapping and superposition.
  • the parameters of a latent image object are the modulation frequency of the latent image object in the (u,v) coordinate space, the modulation orientation of the latent image object in the (u,v) coordinate space, and the mapping functions m x (u,v) and m y (u,v) .
  • mapping of coordinate system can be represented as:
  • the original decoder In order to demodulate the latent image object embedded in the watermark layer with coordinate system mapping, the original decoder should also be mapped from the (u,v) coordinate system to the (x,y) coordinate system:
  • the corresponding decoder is d'(x,y) in eq. (28) but not d Q (x,y) in eq.
  • Figure 501, 502 and 503 are simple watermark layers with/without phase modulation. It is relatively simple to derive parameters from them.
  • Figure 504,505 and 506 are watermark layers with random dot patterns. It is very complex, and virtually impossible, to recover latent image object information without decoders.
  • the key space of the decoder used to view the embedded latent image object is an indication of the security a watermark method or apparatus may have. The key space is very small for the prior art patents listed earlier. It is possible to find the key space with careful analysis or brute force attack from an expert in the area.
  • Figure 501, 502 and 503 show regular patterns with andwithout phase modulation. From the view point of cryptography, the problem of these watermark layers is that the space of the keys is too small. It is obvious that one can easily derive the key parametter by observing the watermark.
  • the key space can be expanded by two factors.
  • the watermark layer can be further generalised as a random pattern in a 2-D space.
  • the amount of information of the latent image object can reach its maximum when it is randomly distributed.
  • the randomly distributed information is divided into two parts: the watermark layer is generated based on one part, while the decoder is generated based on the other part.
  • both of the watermark layer and the decoder hold the information about the latent image object.
  • the latent image is recoverable only when both the watermark layer and the decoder are presented.
  • Two functions g w (x,y) and g d (x,y) can be generated based on the latent image object g(x,y) and a random function r(x,y) , which will return either 0 or 1 at random.
  • the function g w (x,y) is then encoded into the girds of the watermark layer with phase modulation, while the function g d (x,y) is also encoded into the line gratings of the decoder with phase modulation. Note that the value of g w (x,y) , g d (x,y) and g(x,y) can only be either 1 or 0.
  • g w ( ⁇ ,y) g( ⁇ ,y>( ⁇ ,y) + - g( ⁇ ,yW -r( ⁇ ,y)] (29)
  • No information about the latent image object can be found from investigating the function either g d (x,y) or g w (x,y) ⁇ There is a relationship between the function g d (x, y) and g w (x, y) . If the value of g(x,y) is 1, the function g d (x,y) equals to g w (x,y) ⁇ While if the value of g(x,y) is 0, the function g w (x,y) equals to l- g d (x,y) .
  • the watermark layer can be represented as:
  • x,y) g x > y)[n- ⁇ (x-nT x ) ⁇ (y-nT y )] +
  • d(x,y) g d (x,y) ⁇ l- ⁇ (x-nT x ) ⁇ [u(y-nT y )-u(y-nT y -T y )] ⁇ +
  • Figures 504, 505 and 506 are examples of the random pattern watermark layers corresponding to Figure 501, Figure 502 and Figure 503.
  • a random pattern watermark layer needs accurate alignment to reveal the latent image object.
  • the dot pattern of a watermark layer can be the result of a set of operations on one, or a set of basic, and other types of dot patterns.
  • the counterfeit-proof layer is an example.
  • the counterfeit-proof layer is a special watermark layer where a photocopier is the decoder to the latent image object.
  • the dot pattern in the counterfeit-proof watermark layer is based on the superposition of the basic dot arrays.
  • the latent image object in this layer which can be some cancelation words such as "COPY”, can be represented as a function g c (x,y) .
  • the value of this function can only be 0 or 1.
  • this layer can be represented as a function w c (x,y) .
  • w c (x, j>) [i - go ( ⁇ , y)]f a ⁇ X y)f a ( ⁇ +A,y+A)+ g c r ( ⁇ , y) iff b f ( ⁇ , y)f b ( ⁇ +- T ⁇ »-,y+- T > s) (33)
  • the functions f a (x,y) and f b (x,y) represent two sets of basic dot arrays.
  • the repetitive period T a of f a (x,y) is slightly larger then the period T b of f b (x,y) .
  • the ⁇ in eq. (33) represents a small displacement.
  • Figure 601 is a sample of such a counterfeit-proof layer.
  • Figure 602 is a enlarged view of the overlapped dot arrays which are represented by f a ( x > y)f a ( x + ,y + A) .
  • Each dot in the dot array f a (x,y) will adjoin to a dot in the other dot array f a (x + A,y + A) because ⁇ is a small enough displacement.
  • Figure 603 is an enlarged view of the overlapped dot arrays which are represented with
  • dot array f b (x,y) will adjoin to a dot in the other dot array
  • the dot size in this counterfeit-proof layer should be carefully chosen. It should be smaller than the size of the dot that a photocopier can sample.
  • a preferred dot size is inches, because the optical resolution of
  • T a T b to exceed the resolution limit of the human visual system.
  • the detailed structure of the counterfeit-proof layer will not be observable by unaided eyes.
  • the regions where the value of g c (x,y) is 0 will look lighter in the grey scale than the regions where the value of g c (x, y) is
  • Superposition of counterfeit-proof layer with other watermark layers is also operated according to eq. (18).
  • the only necessary postprocessing is for the region outside the latent image object.
  • Figure 6 of relevance here with Figures 602 and 603 representing typical dot patterns in object regions and non-object regions.
  • Figure 604 illustrates the post-processing for superposition of a counterfeit- proof layer with other watermark layers.
  • Figure 605 is the superposition result and
  • Figure 606 is the photocopying result of Figure 605.As shown in Figure 604, when a dot 613 of the watermark layer is superposed onto the counterfeit-proof layer, all other dots with a area indicated by the dash line box should be removed.
  • optical watermark in document delivery, ardival and authentication.
  • the optical watermark can be applied to an electronic document.
  • the optical watermark added to the document can be viewed as a seal to provide authenticity to the document.
  • the visual apperance of the optical watermark can be disigned as a logo or seal of the authority to provide immediate trust.
  • the embedded information can be the name, signature and logo of the authority, or some number or words related to the document content.
  • application scenario 1 is an authority such as, for example, an immigration department of a government, which issues passports to citizens.
  • the optical watermark is attached to a page of the passport, either as the background or as a seal of the immigration department.
  • a photograph of the passport holder is embedded into one layer, and the name and birth date is on the other layers.
  • a special symbol is embedded into a random pattern watermark layer.
  • Key lenses are distributed to various parties who need to verify the validity of the passport. The random key can be retained by the immigration department for final verification.
  • the passport is issued by the immigration department, and the holder may need to be checked by other parties such as passport controller of other countries.
  • Figure 8 is a service model.
  • a service provider provides delivery and authentication services to customers.
  • a customer for example, a shipping company, issues a bill of lading through the service provider to a shipper or consignee.
  • An optical watermark having a shape of the carrier's logo, is placed on all non-negotiable bills of lading as background.
  • Verification keys are distributed to banks and carrier agents for authentication purposes when the shipper and consignee use the bill of lading to claim the money and cargo.
  • the key lenses can be replaced periodically, for example, every 6 months, by the service provider for security reasons.
  • optical watermark described above can be readily applied to a document using more than one colour such as, for example, but not limited to, having different watermark layers into different colour channels in various colour spaces. Examples are CMYK and RGB.

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Abstract

A multiple layered watermark is generated to be placed on document, to protect against counterfeiting and forgery. Hidden information embedded into each of the watermark's layers is only detectable by using a corresponding decoder. Because of the multiple-layered structure, it is difficult to reverse engineer the optical watermark. The generalized watermark structure significantly increases the 'key space' of the decoder.

Description

OPTICAL WATERMARK
Field of the Invention
This invention generally relates to a method and apparatus for producing optical watermarks on printed and electronic documents.
Definition
Throughout this specification or reference to a document is to be taken as including a printed document and/ or an electronic document and/ or a copy (printed or electronic) of a printed document and/ or a copy (printed or electronic) of an electronic document and will include such a document with text, image, graphics, video, photographs, and other multimedia appearing thereon or therein.
Background to the Invention
The structure of a watermark, referred to as carrier dot pattern, is a repetitive pattern with the simplest and most basic as a two- dimensional ("2-D") dot array. The complexity of the dot pattern structure determines the security level. Embedding a latent image object into a watermark is implemented by the modulation on the dot pattern with the latent image object. Observing the latent image using a decoder is a process of demodulation. The decoder is also a structured pattern, which corresponds to a particular dot pattern. It is implemented as an optical instrument, such as gratings, lenses, Ronchi Rulings, special films, or even a photocopier.
Consideration of the Prior Art
US 5,915,027 relates to digital watermarking of data, including image, video and audio data, which is performed by repeatedly inserting the watermark into subregions or subimages of the data. Similarly, the watermark is repeatedly extracted from the subregions of the data. This method is in a single layer and is not suitable to a text-based document or a document printed on paper.
US 4,921 ,278 has an identification system using a computer generated Moire, and is based on a computer generated random pattern of broken lines. The overlap of the object grid and the reference grid will induce the moire effect. This method is in a single layer, is rather simple, and does not provide enough protection, such as counterfeit indication.
US 5,734,752 is a method for generating watermarks in a digitally reproducible document which are substantially invisible when viewed. It uses stochastic screen patterns suitable for reproducing a gray image on a document, and another stochastic screen to correlate the first in order to view the content. This is quite similar to US 4,921,278, except that it uses stochastic screen patterns to represent the gray images.
Other patents similar these include: US 5,708,717 which combines a source image with a latent image so that the scrambled latent image is visible only when viewed through a special decoder lens; US 5,790,703 produces a first screen pattern suitable for reproducing a gray image on a document, and deriving at least one conjugate screen description that is related to the first pattern, so that overlapping them can reveal the content of the document; and US 6,000,728 uses different sizes of dot screens for anti-counterfeiting. As can be seen from these US patents, there is only one layer of hidden information. The structure is exposed to attackers. Carefully observation of the structure with a microscope or similar instrument will reveal all information required to forge the image or document.
It is the principal object of the present invention is to address this problem and to provide a watermark which, in general, will not normally allow all necessary information to be revealed.
Summary of the Invention
The present invention provides a method and apparatus to protect documents from counterfeit and forgery. It embeds multiple latent image objects into layers of repetitive structures to generate a watermark. The watermark is then incorporated into a document as for example, a seal, logo or background. This may be referred to as an optical watermark.
An optical watermark has one or several watermark layers. One or two latent image objects are embedded into each watermark layer. Each watermark layer has different structure, as well as a corresponding decoder to observe the latent image object embedded in it. The latent image object embedded in a watermark layer can not be observed by the unaided human eye unless a decoder corresponding to that watermark layer's structure is overlapped onto the watermark. On the other hand, a decoder for one watermark layer will not reveal latent image objects in other watermark layers due to the difference in their structure. As such, decoders can be considered as keys to the secrets, and the secrets are the latent image objects embedded in the watermark. Layers in the optical watermark protect each other. Without knowing all the secrets (including latent image objects and parameters of the dot patterns) of the optical watermark, it's almost impossible to forge the watermark or change the latent image objects in watermark layers without being noticed.
The combination of layers of various security levels provides solutions for various applications needs. For example, an optical watermark may appear as the logo of a company on a document issued by that company. There can be, for example, three watermark layers. The first layer may be a cancellation word, such as "COPY", and the verification device is the photocopier. The cancellation word "COPY" appears if the printed original document is photocopied. The latent image object in the second layer may be a logo of the company, and the verification device is a specially designed lens with gratings defined by periodical functions. The lens can be given to the related organisations to verify the originality of the document. The third layer may be embedded with a logo of a trusted third party. The verification device is also a lens, but the structure is random dot pattern, which is more secure than the other layers.
Because the superposition of multiple layers is a non-inversable process, the complicity of the optical watermark increases and it is very difficult, if not impossible, to reverse engineer to derive the parameters and hidden information from the watermark. Because there are multiple layers, different verification methods, including counterfeit indication, can be combined to form a much more secure application. These verifications can be done off-line with very simple devices. Above all, the invented method and aparatus can achieve very high security without using special ink or special paper. Brief Description of Drawings
In order that the invention may be clearly understood and readily put into practical effect, there shall be described by way of non- limitative example only preferred embodiments of the present invention, the description being with reference to the accompanying illustrative drawings in which:
Figure 1 shows a layered structure of an optical watermark;
Figure 2 is an illustration of embedding latent image objects into a basic watermark layer;
Figure 3 is a demodulation result of letters "T" and "C";
Figure 4 shows the structure of the optical watermark;
Figure 5 shows a watermark with a random dot pattern;
Figure 6 shows a counterfeit-proof watermark layer with a letter "P" embedded;
Figure 7 is an electronic application; and
Figure 8 is an electronic service model.
Detailed Description of the Preferred Embodiment
The optical watermark in this invention has a multiple layered structure as shown in Figure 1. Watermark layers are superposed on each other to provide multiple layers and categories of protection. This superposition of several layers means that it is very difficult, if not impossible, to derive the parameters of the structure and the hidden information from the optical watermark alone.
Each watermark layer is a repetitive structured array of dots. Latent image objects are embedded into the watermark layer by modulation. This may include, for example, phase modulation. The structure and orientation of the different watermark layers in an optical watermark must be different from each other. Only the decoder corresponding to a particular watermark layer can be used to view the latent image object embedded in that particular watermark layer.
Basic watermark layer - 2-D dot arrays
The basic watermark layer is a 2-D dot array, varying in two orthogonal directions. To embed latent images, phase modulation can be applied to both directions. As shown in Figure 2, part 205 is the phase modulation in the horizontal direction to embed a letter "T", while part 206 shows the phase modulation in the vertical direction to embed a letter "C".
The phase modulation changes the distances between a pair of dots at the edge of the latent images in the direction of the phase modulation. According to the characteristics of the human visual system, such changes of distances will make the edge of the latent image become either lighter or darker than the overall grey level of the dot array. Such effect will reveal the shape of the latent images. In order to compensate for this effect, a "smoothing" process may be applied to the regions with an abrupt phase shift. For example, in Figure 2, along regions indicated as 201 and 202, the distance between a pair of dots was greater than the spatial repetitive period of the dot array. Therefore, a dot is added, together with distance adjustment, to make the edge a little darker. Patterns 201 and 202 are the results after compensation. On other hand, when the distance between two dots is much smaller than the repetitive period of the dot array, distance adjustment may also be necessary to make the edge a little lighter. Patterns 203 and 204 are the result of this type of adjustment. To view the latent image objects in the modulated dot arrays, the decoder should have a grating structure with the same spatial frequency as the dot arrays. In order to demodulate the latent image modulated in a particular direction, the orientation of the decoder should be aligned in the same direction. Figure 3(01) and Figure 3(02) show the demodulation result of Figure 2. The detailed mathematical analysis is in accordance with a Fourier Series Expansion.
Mathematical Analysis of Phase Modulation for Embedding a Latent Image into a Basic Watermark Layer
In the optical watermark, dot arrays are selected as the carrier dot patterns to embed latent image objects. Because dot arrays can be considered as 2-D signals, which vary in two orthogonal directions, two latent image objects can be modulated to one dot pattern in two directions with phase modulation. For the sake of simplicity, the dot arrays discussed here have the same spatial repetitive frequency in both directions. In an actual optical watermark, the frequencies in the two directions may be different.
A Fourier series expansion is employed to analyse the modulation f e TO 11 and demodulation. Let us denote basic dot pattern as J fa χπ-y) > where and the value 0 represents black, and 1 represents white. The superposition of line gratings can be represented with the product of functions. This multiplicative model enables analysis with a Fourier series expansion.
The phase-shifted dot array can be represented as/j føj ) and f2 (χ,y) , each corresponding to a modulation direction. f0(x,y) = l-∑δ(x-nT)∑δ(y-nT) (1)
f.(x,y) = \- δ(x-nT--) δ(y-nT) (2)
f2(x,y) = l-∑δ(x-nT)∑δ(y-nT- -) (3)
Two latent image objects to be modulated can be represented as j (x, y) and g2 (x, y) . Their valid values can only be either 0 or 1. So the watermarked dot array can be represented as w(x, y) = g. (x, y)g2 (x, y)f0 (x, y) +
[1 - gx (x, y)]f. (x, y) + [l- g2 (x, y)]f2 (x, y)
The decoders can be represented as
fd(x,y) = l- δ(xcosθ-ysmθ-nT) (5)
In eq. (A.5) the angle θ is the angle between the orientation of fd(x,y) and the direction of y-axis. The superposition of the watermarked dot array and the decoder can be represented as d(x,y) = w(x,y)fd(x,y) (6)
All these functions can then be expanded into Fourier series as following.
f0(x,y) = l^→^∑cos(2π→)][→^∑∞s(2π^y)] (7) fι (x,y) = 1 - [- + - ∑ cos(nπ) COS(2ΛΓ - x)] [- + -∑ cos(2 - y)] (8)
1 1 „=1 J i i „_ι 1
/2 (x, y) = 1 - [- + - ∑ cos(2;r - *)] [- + -∑ cos(n^r) cos(2 r - y)] (9) i 1 „=ι i „=ι
Λ ( ^) = (l --) --∑cos[2^-( cos^ - ^sin^)] (10)
The superposition can be analysed based on above expansions. There will be many components in the expansion of eq. (A.6). In order to make the analysis as clear as possible, all high frequency components can be ignored. Only the components, which probably have lower frequencies will be referred to in this analysis. Such components in d(x,.y) are analysed as following equations.
∑ cos(2 — x)∑ cos[2 — (x cos θ - y sin θ)] = — ∑ cx (m, ή) + c, (m,—ri) n=l J- »=1 J- 2 „,=ι „=1
(11)
2π cx (m, ) = cos — [(m + n cos θ)x - ny sin θ] (12)
∑cos(2π- y)∑cos[2π-(xcosθ - ysmθ)] = -∑∑c2(m,n) + c2(m,-n) (13) n=l •* n=l J- ,„=1 n=1
c2(m,ή) = cos — [røccosø + Cm - røsinø); ] (14)
When the value of θ is very close to 0° , only the frequency of the component ^(1,-1) will be much lower than the frequency of the carrier dot pattern. While the value of θ is slightly above or below 90° , only the component c2 (1,1) will have lower frequency. So for these two cases only cλ(l,-\) or c2(l,l) will be significant in superposition. 2π cλ (1,- 1) = cos — [(1 - cos θ)x + y sin θ] (15)
2π c2 (1,1) = cos — [x cos θ + (1 - sin θ)y] (16)
In case when ^(l.-l) is most significant, the significant components in eq. (6) will be the following three. Then only one latent image gλ(x,y) can be clearly observed because of the relative phase.
1 ) ffi (x, y)g <X y) cos — [(1 - cos θ)x + y sin θ]
2π T
2) [1 - gt (x, y)] cos — [(1 - cos θ)x + y sin θ ± — ]
3) [1 - g2 (x, y)] cos — [(1 - cos θ)x + y sin θ]
In case when c2 (1,1) is most significant, the significant components in eq. (6) will be the following three. Then only one latent image g2(x,y) can be clearly observed because of the relative phase.
i )
Figure imgf000011_0001
2) [l - g1 (x,^)]cos— -[xcos^ + Cl - sin^) ;]
2π T
3) [1 - g2 (x, y)] cos — [x cos θ + (l - sin θ)y ± — ]
1 2
The mathematical derivation shows that with phase modulation two latent image objects can be modulated to the basic dot pattern. Because of the relatively high frequency of the dot array and the compensation methods applied on the edge, the latent image objects will not be observed by unaided eyes. In order to view the latent image objects, the frequency of the decoder should be the same as the frequency of the basic carrier dot pattern along that direction, and the orientation of the decoder should be aligned to the same direction in which the latent image object is modulated.
Here there are used two characteristics of the human visual system. First, the human visual system has the highest contrast sensitivity in the mid spatial frequency range, around 2-6 c/deg. The sensitivity has a sharp drop at high spatial frequencies. Second, the human eye is sensitive to relative phase, which is the shift or displacement between spatial signals at same frequency. For frequencies higher than 3 c/deg, the threshold phase is represented by the displacement of about 0.85' arc. For frequencies less than 3 c/deg, the threshold of relative phase is about 5° . A human observer will not be able to observe the relative phase, which is less than this threshold. So for high frequency signals, the displacement will not be easily observed by unaided eyes.
The latent image object in each watermark layer is encoded with relatively high repetitive frequency dot patterns with phase modulation. The displacement is not significant to the human visual system because the relative phase difference is lower than, or similar to, the threshold at that relative high frequency, which is selected for the optical watermark. So the latent image objects will not be observed without proper decoders.
To generalise from the 2-D dot array watermark layer, the frequencies of dot arrays along two directions can be different, and the dot arrays may take any orientation. If the watermark layer is denoted as L(fu ,fv,θ,gu ,gv) , where fu and fv are the frequencies of dot array in two directions u and v , respectively, and θ is the angle between u and x (horizontal axis), the functions gυ and gv , whose value can only be 1 or 0, represent the latent image objects in this layer. The function representing a watermark layer is:
L[f„,f„θ, g„ (x,y),gv(x,y)] -- gu(x,y)gv(x,y)[l- ∑ δ(x∞sθ + ysmθ ~) δ(ycosθ-xs θ ~)]+ g,Xx,y)\J- g„ (x,y)]ϋ-~ __ δ(xcosθ + ysmθ~ -—) γι δ(ycosθ- xsmθ-~)] +
n « n \ g (x> )V--gv(x>yW- ∑ δ(x∞sθ + ysmθ-~) ∑ δ(ycosθ -xsmθ - — -—-)] + n=-x> j ιι=-∞ Jv Jv
[1- g„(χ, )π[n- g„(x, W- __ δ(xcosθ + ysinθ—2r——) j δ(ycosθ-xsmθ-~r-—-)] ιι=-∞ Ju 1Ja „__„ Jv ljv
(17)
There are two parameters for each latent image object in this type of watermark layer: one is the modulation frequency and the other is the modulation orientation. The parameters for the latent image gu are fu and u . While the parameters for the latent image gv are fv and v . Only a decoder with the corresponding frequency can make a particular latent image visible when it's rotated to the corresponding direction. So the keys to the secrets in this type of watermark layer are the modulation frequency and the modulation orientation.
Multiple Layers Structure
Reference is now made to Figure 4 where Figure 401 shows the coordinates of one watermark layer, with reference to a x-y co-ordinate. Figure 402, 403 and 404 are three watermark layers, and Figure 405 is their superposition result.
The optical watermark is the superposition of several watermark layers. Such superposition can be represented as
W = Ϋ[Ln(fu,n V,n ,gu,n,gv,„) (18)
M=l According to the above analysis, there would be some low frequency components in this superposition of multiple repetitive structures. Such low frequency components could probably bring unwanted visual effects, or even reveal the latent images without decoders. This problem can be avoided if the following requirements can be met for any two layers, E, and L} , in the optical watermark:
1. If fUj ^ fUtj or fVJ = fV , the orientation difference Aθy should be large enough, for example Aθy ≥ 60° , or in some cases Aθy ≥ 45° .
2. If fu ι = fV J , Aθυ should be less than 60° , for example Aθy < 60° .
(where Aθy = aιccos(|cos(0, - 0, )|) , and 0' ≤ Δθy < 90°)
The above two requirements mean that no component will have a frequency much lower than the frequency of any carrier dot arrays in the superposition. Figure 4(05) shows an sample of the optical watermark, which is the superposition of Figure 4(02), Figure 4(03) and Figure 4(04).
When the decoder, which is represented with the fuction d(x,y) , are superposed onto the optical watermark, the result of the decoding can be respresented as
D -^ d(x,y) - W = d(x,y) - f[LMι,n v,,Λ,gu,n,gv,)ι) (19)
d(x,y) = 1 - ∑ δ(xcosθd + ysinθd -—) (20) n=-∞ J d
From the analysis in Appendix A, the following results can be obtained: 1. When fd equals fu ι and \θd is very small, the latent image Su x>y will De visible in the superposition.
2. When fd equals fv ι and
Figure imgf000015_0001
is almost 90° , the latent image gv ,(x >y) will be visible in the superposition.
The frequency and the orientation of the decoder are the keys to decode the latent image objects. Only when the frequency of the decoder matches the modulation frequency and orientation of a particular latent image object, will the latent image object appear in the superposition.
Hence, in the mutilple-layer stucture, all latent image objects can be decoded seperately from the watermark layers. Every watermark layer carries its own latent image objects, and from the knowledge of one particular watermark layer it is very difficult, and almost impossible, to derive the latent images or the parameters of the other watermark layers.
The other advantage of this multiple-layer structure is that all the watermark layers protect each other. Without knowing the details (parameters and latent image objects) of all the watermark layers, it's very difficult, and almost impossible, to change the information in one of the watermark layers. If one of the watermark layers is changed, all other watermark layers will also be affected by this change. Therefore, this change, even it may be authorized by one party, will invalidate the authenticity of the document, in a scenario of a multiple party application, where each party is holding a "key" to a latent image object. Coordinate mapping to generate complex watermark layer
In a basic watermark layer, the key space to the hidden information is the frequency of the decoder, which is relatively small. Generally, basic 2-D dot arrays can be generalized to any 2-D pattern, by coordinate mapping and superposition.
In the case of coordinate mapping, linear or non-linear coordinate mapping functions are applied to the basic watermark layer. These mapping functions can be represented as x = mx (u,v) (21)
y = my(u,v) (22)
Functions mx(u,v) and my(u,v) map the coordinate space from (u,v) to (x,y) . In (u,v) coordinate space, the modulation and demodulation of the watermark layer are the same as the basic watermark layer. But the demodulation with a decoder is done in the (x,^) coordinate space. Hence, the decoder in the (x,y) coordinate space should be mapped from the corresponding decoder in the (u,v) coordinate space. So in coordinate mapping the watermark layer, the parameters of a latent image object are the modulation frequency of the latent image object in the (u,v) coordinate space, the modulation orientation of the latent image object in the (u,v) coordinate space, and the mapping functions mx(u,v) and my(u,v) .
For example, the sine function as the mapping function. The mapping of coordinate system can be represented as:
2π x = si — v + u (23) y = v (24)
While the dot array in the (u,v) coordinate space is represented as:
/(tt,v) = l- ∑ δ(u ~) ∑ δ(y-- -) (25) n=-co Ju n=-∞ Jv
With coordinate mapping, the corresponding fuction in the (x,y) coordinate space can be derived as:
f'(x,y) = l - ∑ δ(x -Sm y - r) ∑ δ(y - ) (126) n=-∞ J u «=-∞ J v
In order to demodulate the latent image object embedded in the watermark layer with coordinate system mapping, the original decoder should also be mapped from the (u,v) coordinate system to the (x,y) coordinate system:
d(u,v) = l - ∑ δ(u -~) (27) n=-∞ J u
Figure imgf000017_0001
For the latent image in the mapped watermark layer f(x,y) , the corresponding decoder is d'(x,y) in eq. (28) but not dQ(x,y) in eq.
(27). As can be seen from equation (28), that the key space is expanded by two factors: one is the sine function, and the other is the period of the sine function.
Random pattern watermark Layer
To refer to Figure 5, Figure 501, 502 and 503 are simple watermark layers with/without phase modulation. It is relatively simple to derive parameters from them. Figure 504,505 and 506 are watermark layers with random dot patterns. It is very complex, and virtually impossible, to recover latent image object information without decoders. The key space of the decoder used to view the embedded latent image object is an indication of the security a watermark method or apparatus may have. The key space is very small for the prior art patents listed earlier. It is possible to find the key space with careful analysis or brute force attack from an expert in the area. As a few examples, Figure 501, 502 and 503 show regular patterns with andwithout phase modulation. From the view point of cryptography, the problem of these watermark layers is that the space of the keys is too small. It is obvious that one can easily derive the key parametter by observing the watermark.
By linear and non-linear mapping of the basic watermark layer, the key space can be expanded by two factors. To further expand the key space to increase the security of the hidden information, the watermark layer can be further generalised as a random pattern in a 2-D space.
According to information theory, the amount of information of the latent image object can reach its maximum when it is randomly distributed. In a random pattern watermark layer, the randomly distributed information is divided into two parts: the watermark layer is generated based on one part, while the decoder is generated based on the other part. Hence, both of the watermark layer and the decoder hold the information about the latent image object. The latent image is recoverable only when both the watermark layer and the decoder are presented.
Two functions gw(x,y) and gd(x,y) can be generated based on the latent image object g(x,y) and a random function r(x,y) , which will return either 0 or 1 at random. The function gw(x,y) is then encoded into the girds of the watermark layer with phase modulation, while the function gd(x,y) is also encoded into the line gratings of the decoder with phase modulation. Note that the value of gw(x,y) , gd(x,y) and g(x,y) can only be either 1 or 0.
gw(χ,y) = g(χ,y>(χ,y) + - g(χ,yW -r(χ,y)] (29)
Figure imgf000019_0001
No information about the latent image object can be found from investigating the function either gd (x,y) or gw(x,y) ■ There is a relationship between the function gd (x, y) and gw (x, y) . If the value of g(x,y) is 1, the function gd(x,y) equals to gw(x,y) ■ While if the value of g(x,y) is 0, the function gw(x,y) equals to l- gd (x,y) .
The watermark layer can be represented as:
x,y) = g x >y)[n- ∑δ(x-nTx)∑δ(y-nTy)] +
(31) -g x,yW- ∑δ(x-nTx --Tx) ∑δ(y-nTy)]
And the decoder as:
d(x,y) = gd(x,y){l- ∑δ(x-nTx)∑[u(y-nTy)-u(y-nTy -Ty)]} +
(32)
^-gΛ^yW- ∑δ{x-nTx --Tx)∑[u y-nTy)-u(y-nTy -Ty)]}
From above equations, it can be seen that when the value of g(x,y) is 0, there is a relatve phase difference between the watermark layer and the decoder, and that when the value of g(x,y) is 1, there is no relatve phase difference between the watermark layer and the decoder. This implies that the latent image will appear because of the demodulation of the relative phase difference when the watermark layer and decoder are correctly overlapped.
Figures 504, 505 and 506 are examples of the random pattern watermark layers corresponding to Figure 501, Figure 502 and Figure 503.
Since the amount of information in a random pattern watermark layer is 2 to the power of the dimension of the latent image object, the security level will be very high. Since both the watermark layer and the decoder carry part of the latent image object, from either the watermark layer or the decoder alone it is virtually impossible to derive the other. On other hand, a random pattern watermark layer needs accurate alignment to reveal the latent image object.
Counterfeit-proof Layer
The dot pattern of a watermark layer can be the result of a set of operations on one, or a set of basic, and other types of dot patterns. Here, the counterfeit-proof layer is an example.
The counterfeit-proof layer is a special watermark layer where a photocopier is the decoder to the latent image object. The dot pattern in the counterfeit-proof watermark layer is based on the superposition of the basic dot arrays. The latent image object in this layer, which can be some cancelation words such as "COPY", can be represented as a function gc(x,y) . The value of this function can only be 0 or 1. Then this layer can be represented as a function wc(x,y) . wc (x, j>) = [i - go (χ, y)]fa <X y)fa (χ+A,y+A)+ gc r (χ, y) iffb f (χ, y)fb (χ+- T±»-,y+- T> s) (33)
Z L
fa(x,y) = l - ∑δ(x - nTa) ∑δ(y - nTa) (34)
H=-co H=-co
Figure imgf000021_0001
n=-∞ »=-co
The functions fa(x,y) and fb (x,y) represent two sets of basic dot arrays. The repetitive period Ta of fa(x,y) is slightly larger then the period Tb of fb(x,y) . And the Δ in eq. (33) represents a small displacement.
Figure 601 is a sample of such a counterfeit-proof layer. Figure 602 is a enlarged view of the overlapped dot arrays which are represented by fa(x >y)fa(x + ,y + A) . Each dot in the dot array fa(x,y) will adjoin to a dot in the other dot array fa(x + A,y + A) because Δ is a small enough displacement. While Figure 603 is an enlarged view of the overlapped dot arrays which are represented with
T T T fb (x,y)fb (χ + — ,y + —) . Because of the displacement — , no dot in the
dot array fb (x,y) will adjoin to a dot in the other dot array
Figure imgf000021_0002
In order to let the latent image object appear after photocopying, the dot size in this counterfeit-proof layer should be carefully chosen. It should be smaller than the size of the dot that a photocopier can sample.
A preferred dot size is inches, because the optical resolution of
most photocopiers is less than 6001pi. Such dots will disappear after photocopying because they are too small to be recognized by the photocopier. As such, the regions where the value of gc (x, y) is 1 , will fade after photocopying because all dots in these regions are isolated and cannot be sampled by the photocopier. On other hand, the regions where the value of gc(x,y) is 0, will still remain because adjacent dot pairs are viewed as having a relatively large size, and can be sampled by the photocopier. Hence the latent image object will be able to appear after photocopying.
Note both frequences, — and — , in eq. (33) should be high enough
Ta Tb to exceed the resolution limit of the human visual system. According to the characteristics of the human visual system, the detailed structure of the counterfeit-proof layer will not be observable by unaided eyes. The regions where the value of gc(x,y) is 0 will look lighter in the grey scale than the regions where the value of gc (x, y) is
1.
Superposition of the counterfeit-proof layer with other watermark layers proctects the counterfeit-proof layer. Because of the simple structure of the counterfeit-proof layer, it is relatively easy to analyse the layer and reproduce it.
Superposition of counterfeit-proof layer with other watermark layers is also operated according to eq. (18). The only necessary postprocessing is for the region outside the latent image object. Figure 6 of relevance here with Figures 602 and 603 representing typical dot patterns in object regions and non-object regions. Figure 604 illustrates the post-processing for superposition of a counterfeit- proof layer with other watermark layers. Figure 605 is the superposition result and Figure 606 is the photocopying result of Figure 605.As shown in Figure 604, when a dot 613 of the watermark layer is superposed onto the counterfeit-proof layer, all other dots with a area indicated by the dash line box should be removed. The principle is that the superposition should not change the grey level of the regions where the value of gc(x,y) is 1. As the result of superposition, both the inside and the outside of the latent image object have the same grey level. Because the structure in the counterfeit-proof layer has a frequency exceeding the resolution of the human visual system, it looks like a patch of countious grey tone to unaided eyes. Figure 605 is a enlarged view of the superposition, Figure 606 shows the result after photocopying. The latent image object "P" appears clearly.
Optical watermark in document delivery, ardival and authentication. The optical watermark can be applied to an electronic document. The optical watermark added to the document can be viewed as a seal to provide authenticity to the document. The visual apperance of the optical watermark can be disigned as a logo or seal of the authority to provide immediate trust. The embedded information can be the name, signature and logo of the authority, or some number or words related to the document content.
As show in the Figure 7, application scenario 1 is an authority such as, for example, an immigration department of a government, which issues passports to citizens. Here, the optical watermark is attached to a page of the passport, either as the background or as a seal of the immigration department. A photograph of the passport holder is embedded into one layer, and the name and birth date is on the other layers. Finally, a special symbol is embedded into a random pattern watermark layer. Key lenses are distributed to various parties who need to verify the validity of the passport. The random key can be retained by the immigration department for final verification. Here, the passport is issued by the immigration department, and the holder may need to be checked by other parties such as passport controller of other countries.
Another type of application is illustrated in Figure 8, which is a service model. A service provider provides delivery and authentication services to customers. A customer, for example, a shipping company, issues a bill of lading through the service provider to a shipper or consignee. An optical watermark, having a shape of the carrier's logo, is placed on all non-negotiable bills of lading as background. Verification keys are distributed to banks and carrier agents for authentication purposes when the shipper and consignee use the bill of lading to claim the money and cargo. The key lenses can be replaced periodically, for example, every 6 months, by the service provider for security reasons.
The optical watermark described above can be readily applied to a document using more than one colour such as, for example, but not limited to, having different watermark layers into different colour channels in various colour spaces. Examples are CMYK and RGB.
Whilst there has been described in the foregoing description a preferred embodiment of the present invention, it will be understood by those skilled in the technology that may variations or modifications may be made without departing from the present invention.

Claims

The Claims
1. A method for producing a watermark on a document, the method including the step of: a) determining a required plural number of watermark layers and a dot patterns for each of the plurality of watermark layers; b) selecting at least one latent image object for each of the plural number of watermark layers and embedding each latent image object into its respective watermark layer; c) superposing the watermark layers to form the watermark; d) defining and generating a decoder for each of the number of watermark layers; and e) applying the watermark to the document.
2. The method of claim 1, wherein the dot pattern for each of the number of watermark layers is a pattern defined on a two dimensional digital image plane.
3. The method of claim 2, wherein the dot pattern is a basic two- dimensional dot array.
4. The method of claim 2, wherein the dot pattern is a linear coordinate mapping of a basic two-dimensional dot array.
5. The method of claim 2, wherin the dot pattern also includes a non-linear coordinate mapping of a basic two-dimensional dot array.
6. The method of claim 2, wherein the dot pattern is a random distributed dot array
7. The method of claim 2, wherein the dot pattern is a result of a set of operations on a set of basic and other types of two- dimensional dot arrays.
8. The method of claim 1, wherein the latent image objects contain information which is critical to the application.
9. The method of claim 8, wherein the information is from the group consisting of: copy, void, a critical name, and a number from the document.
10. The method of claim 1, wherein the latent image object is embedded into each watermark layer by a modulation method.
11. The method of claim 10, wherein the modulation method is phase modulation.
12. The method of claim 11, wherein the phase modulation includes a post-processing to smooth any abrupt phase changes along the edges of the latent image object.
13. The method of claim 1, wherein the decoder has a decoder structure related to a dot pattern structure of a carrier dot pattern of the watermark layer and in the direction where the latent image object is embedded.
14. The method of claim 13, wherein the relationship is selected from the group consisting of: the same, and conjunct.
15. The method of claim 10, wherein after modulation the watermark layer and its decoder each carries part of the information of the latent image object which is generated based on the latent image object and a random function.
16. The method of claim 1, wherein the watermark layers are different to each other and are of sufficient difference to avoid interference between them as a result of them being superposed.
17. The method of claim 13, wherin one of the watermark layers is a counterfeit-proof layer, the decoder for which is a photocopier.
18. The method of claim 17, wherein after the superposition of the watermark layers with the counterfeit-proof layer there is included a post-processing step to remove dots which are too close to adjacent dots in a non-object area.
19. The method of claim 1 when included in a method for printing a document for protection and authentication including the steps of: a) verifying the authenticity and copyright of the document before printing; b) generating the watermark according to the method of claim 1 ; c) controlling the printing process to protect the document and the watermark from attack; and d) generating the decoder device and distributing the decoder device to enable verification of the authenticity of the document.
20. The method of claim 1, wherein the watermark is extended to colour documents.
21. The method of claim 20, wherein the watermark layers are in different colour channels in various colour spaces.
22. The method of claim 21, wherein colour spaces CMY/CMYK, HIS, XYA, Yuv and RGB are used.
23. A watermark for use on a document, the watermark having: a) a required plural number of watermark layers, each of the plural number of watermark layers each being a dot pattern; b) at least one latent image object embedded into each watermark layer; and c) the watermark layers being superposed to form the watermark
24. The watermark of claim 23, wherein the dot pattern for each of the number of watermark layers is a dot pattern defined on a two dimensional digital image plane.
25. The watermark of claim 24, wherein the dot pattern is a basic two-dimensional dot array.
26. The watermark of claim 24, wherein said dot pattern for the watermark is a linear coordinate mapping of a basic two- dimensional dot array.
27. The watermark of claim 26, wherin the dot pattern also includes a non-linear coordinate mapping of a basic two- dimensional dot array.
28. The watermark of claim 24, wherein the dot pattern is a random distributed dot array
29. The watermark of claim 24, wherein the dot pattern is a result of a set of operations on a set of basic and other types of two- dimensional dot arrays.
30. The watermark of claim 23, wherein the latent image objects contain information which is critical to the application.
31. The watermark of claim 30, wherein the information is from the group consisting of: copy, void, a critical name, and a number from the document.
32. The watermark of claim 23, wherein the latent image object is embedded into each watermark layer by modulation.
33. The watermark of claim 24, wherein the modulation is phase modulation.
34. The watermark of claim 33, wherein any abrupt phase changes along the edges of the latent image object are smoothed.
35. The watermark of claim 33, wherein there is included a decoder for each watermark layer which has a decoder structure related to a dot pattern structure of a carrier dot pattern of the relevant watermark layer and in the direction where the latent image object is embedded.
36. The watermark of claim 35, wherein the relationship is selected from the group consisting of: the same, and conjunct.
37. The watermark of claim 35, wherein after modulation the watermark layer and its decoder each carries part of the information of the latent image object which is generated based on the latent image object and a random function.
38. The watermark of claim 23, wherein the watermark layers are different to each other and are of sufficient difference to avoid interference between them as a result of them being superposed.
39. The watermark of claim 35, wherein one of the watermark layers is a counterfeit-proof layer, the decoder for which is a photocopier.
40. The watermark of claim 39, wherein after superposition of the watermark layers with the counterfeit-proof layer dots which are too close to adjacent dots in a non-object area are removed.
41. The watermark of claim 23 included on or in a document for protection and authentication.
42. The watermark of claim 41, wherein the watermark is included on or in the document as a device selected from the group consisting of: background, seal, logo, graphic device, trade mark and a word.
43. The watermark of claim 23, wherein the watermark is coloured.
44. The watermark as claimed in claim 43, wherein the watermark layers are in different colour channels in various colour spaces.
45. The watermark as claimed in claim 44, wherein colour spaces CMY/CMYK, HIS, XYZ, Yuv and RGB are used.
PCT/SG2000/000147 2000-09-15 2000-09-15 Optical watermark WO2002023481A1 (en)

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AT00964869T ATE289437T1 (en) 2000-09-15 2000-09-15 OPTICAL WATERMARK
AU75690/00A AU785178B2 (en) 2000-09-15 2000-09-15 Optical watermark
DE60018222T DE60018222T2 (en) 2000-09-15 2000-09-15 Optical watermark
JP2001549269A JP4373045B2 (en) 2000-09-15 2000-09-15 Optical watermark
CNB008020361A CN1170254C (en) 2000-09-15 2000-09-15 Optical watermark
EP00964869A EP1317734B1 (en) 2000-09-15 2000-09-15 Optical watermark
PCT/SG2000/000147 WO2002023481A1 (en) 2000-09-15 2000-09-15 Optical watermark
US09/810,971 US7366301B2 (en) 2000-09-15 2001-03-16 Optical watermark

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Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2004109599A1 (en) * 2003-06-04 2004-12-16 Commonwealth Scientific And Industrial Research Organisation Method of encoding a latent image
EP1547805A1 (en) * 2003-12-23 2005-06-29 Elca Informatique S.A. Method for generating and validating tickets printable at home
US7213757B2 (en) 2001-08-31 2007-05-08 Digimarc Corporation Emerging security features for identification documents
EP1787240A2 (en) * 2004-08-09 2007-05-23 Graphic Security Systems Corporation Systems and methods for authenticating objects using multiple-level image encoding and decoding
WO2007065224A1 (en) 2005-12-05 2007-06-14 Commonwealth Scientific And Industrial Research Organisation A method of forming a securitized image
EP2100403A2 (en) * 2006-12-13 2009-09-16 Graphic Security Systems Corporation Object authentication using encoded images digitally stored on the object
US7916343B2 (en) 2003-07-07 2011-03-29 Commonwealth Scientific And Industrial Research Organisation Method of encoding a latent image and article produced
WO2012164361A1 (en) * 2011-05-27 2012-12-06 Nds Limited Frequency-modulated watermarking
US9117268B2 (en) 2008-12-17 2015-08-25 Digimarc Corporation Out of phase digital watermarking in two chrominance directions
US9179033B2 (en) 2000-04-19 2015-11-03 Digimarc Corporation Digital watermarking in data representing color channels
US9245308B2 (en) 2008-12-17 2016-01-26 Digimarc Corporation Encoding in two chrominance directions
CN109040761A (en) * 2018-09-17 2018-12-18 俞群爱 A kind of monitoring on-wall system with encrypted watermark
US11210495B2 (en) 2011-03-17 2021-12-28 New York University Systems, methods and computer-accessible mediums for authentication and verification of physical objects

Families Citing this family (65)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6449377B1 (en) 1995-05-08 2002-09-10 Digimarc Corporation Methods and systems for watermark processing of line art images
US6763122B1 (en) 1999-11-05 2004-07-13 Tony Rodriguez Watermarking an image in color plane separations and detecting such watermarks
US20030056103A1 (en) * 2000-12-18 2003-03-20 Levy Kenneth L. Audio/video commerce application architectural framework
US6993149B2 (en) * 2001-09-25 2006-01-31 Digimarc Corporation Embedding digital watermarks in spot colors
US7162035B1 (en) 2000-05-24 2007-01-09 Tracer Detection Technology Corp. Authentication method and system
WO2002039714A2 (en) * 2000-11-08 2002-05-16 Digimarc Corporation Content authentication and recovery using digital watermarks
US7072487B2 (en) * 2001-01-26 2006-07-04 Digimarc Corporation Watermark detection using adaptive color projections
US7039215B2 (en) * 2001-07-18 2006-05-02 Oki Electric Industry Co., Ltd. Watermark information embedment device and watermark information detection device
JP2003174556A (en) * 2001-09-26 2003-06-20 Canon Inc Image processing apparatus and image processing method
US7321667B2 (en) * 2002-01-18 2008-01-22 Digimarc Corporation Data hiding through arrangement of objects
US8171567B1 (en) 2002-09-04 2012-05-01 Tracer Detection Technology Corp. Authentication method and system
US20040179713A1 (en) * 2003-03-11 2004-09-16 Kenji Tani Image processing method, image processing apparatus, and information processing apparatus
US7245740B2 (en) * 2003-07-01 2007-07-17 Oki Electric Industry Co., Ltd. Electronic watermark embedding device, electronic watermark detection device, electronic watermark embedding method, and electronic watermark detection method
US20050021970A1 (en) * 2003-07-21 2005-01-27 Curtis Reese Embedded data layers
US20050030588A1 (en) * 2003-08-06 2005-02-10 Curtis Reese Methods and apparatus utilizing embedded data layers
US6980654B2 (en) * 2003-09-05 2005-12-27 Graphic Security Systems Corporation System and method for authenticating an article
JP2005150815A (en) * 2003-11-11 2005-06-09 Oki Electric Ind Co Ltd Watermark information embedding apparatus and method, watermark information detecting apparatus and method, and printed matter
US8181884B2 (en) 2003-11-17 2012-05-22 Digimarc Corporation Machine-readable features for objects
US7114074B2 (en) * 2003-12-22 2006-09-26 Graphic Security Systems Corporation Method and system for controlling encoded image production using image signatures
US7512249B2 (en) * 2004-04-26 2009-03-31 Graphic Security Systems Corporation System and method for decoding digital encoded images
CA2567250A1 (en) * 2004-05-18 2005-11-24 Silverbrook Research Pty Ltd Authentication of an object using a signature encoded in a number of data portions
EP1765601B1 (en) * 2004-06-11 2008-11-05 Ahlstrom Kauttua OY Layered security material and method of manufacturing such
WO2006023577A2 (en) * 2004-08-19 2006-03-02 United States Postal Service Printed postage container having integrated security features
ATE437760T1 (en) * 2004-09-09 2009-08-15 Alcan Tech & Man Ltd ITEM WITH ANTI-COUNTERFEIT PRINTING
US8144558B1 (en) * 2004-09-14 2012-03-27 Doug Carson & Associates, Inc. Hidden patterns on a data storage medium
US20100297027A1 (en) * 2004-12-20 2010-11-25 Nanolnk, Inc. Overt authentication features for compositions and objects and methods of fabrication and verification thereof
JP4660212B2 (en) * 2005-01-24 2011-03-30 株式会社東芝 Image processing apparatus and image processing method
JP2008538047A (en) * 2005-04-13 2008-10-02 コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ Encoding with watermarking prior to phase modulation
US8243325B2 (en) * 2005-07-08 2012-08-14 Xerox Corporation Method for prepress-time color match verification and correction
US7487915B2 (en) * 2005-09-09 2009-02-10 Graphic Security Systems Corporation Reflective decoders for use in decoding optically encoded images
WO2007049184A1 (en) * 2005-10-26 2007-05-03 Koninklijke Philips Electronics N.V. A method of embedding data in an information signal
US7706025B2 (en) * 2005-10-31 2010-04-27 Xerox Corporation Moiré-based auto-stereoscopic watermarks
CN100364326C (en) 2005-12-01 2008-01-23 北京北大方正电子有限公司 Method and apparatus for embedding and detecting digital watermark in text file
US9327538B2 (en) * 2006-01-05 2016-05-03 Ppg Industries Ohio, Inc. Bragg diffracting security markers
JP4719717B2 (en) 2006-06-27 2011-07-06 株式会社リコー Image processing apparatus, image processing method, and image processing program
EP2127195A2 (en) * 2007-01-22 2009-12-02 Global Crypto Systems Methods and systems for digital authentication using digitally signed images
US20090004231A1 (en) * 2007-06-30 2009-01-01 Popp Shane M Pharmaceutical dosage forms fabricated with nanomaterials for quality monitoring
DE102008012419A1 (en) 2007-10-31 2009-05-07 Bundesdruckerei Gmbh Polymer composite layer for security and/or valuable documents comprises at least two interlocking polymer layers joined together with a surface printed with a printed layer absorbing in the visible region in and/or on the composite
JP5264311B2 (en) * 2008-06-18 2013-08-14 キヤノン株式会社 Image processing apparatus, control method, and program
EP2335935A4 (en) * 2008-09-16 2015-11-04 Nat Printing Bureau Incorporated Administrative Ag Forgery preventive printed matter, method for producing same, and recording medium in which dot data creation software is stored
US20110135888A1 (en) * 2009-12-04 2011-06-09 Ppg Industries Ohio, Inc. Crystalline colloidal array of particles bearing reactive surfactant
US8382002B2 (en) * 2010-01-26 2013-02-26 Nanoink, Inc. Moiré pattern generated by angular illumination of surfaces
US8582194B2 (en) 2010-04-29 2013-11-12 Ppg Industries Ohio, Inc. Thermally responsive crystalline colloidal arrays
US8792674B2 (en) 2010-10-11 2014-07-29 Graphic Security Systems Corporation Method for encoding and simultaneously decoding images having multiple color components
US9092872B2 (en) 2010-10-11 2015-07-28 Graphic Security Systems Corporation System and method for creating an animation from a plurality of latent images encoded into a visible image
SG189354A1 (en) 2010-10-11 2013-05-31 Graphic Security Systems Corp Method for constructing a composite image incorporating a hidden authentication image
WO2012057459A1 (en) * 2010-10-26 2012-05-03 Park Kwang-Don Random-type multilayer identification, and system using same
US8490546B2 (en) * 2010-11-01 2013-07-23 Ppg Industries Ohio, Inc. Method of imaging in crystalline colloidal arrays
US9022648B2 (en) 2010-11-11 2015-05-05 Prc-Desoto International, Inc. Temperature sensitive composite for photonic crystals
CN102122384B (en) * 2011-01-25 2012-08-15 机密科技公司 Method for manufacturing hidden pattern during plate making for presswork
WO2012118912A2 (en) * 2011-03-01 2012-09-07 Graphic Security Systems Corporation A method for encoding and simultaneously decoding images having multiple color components
US20130077169A1 (en) 2011-09-23 2013-03-28 Ppg Industries Ohio, Inc. Hollow particle crystalline colloidal arrays
US8641933B2 (en) 2011-09-23 2014-02-04 Ppg Industries Ohio, Inc Composite crystal colloidal array with photochromic member
CN103448402B (en) * 2012-05-28 2016-06-22 广州市人民印刷厂股份有限公司 Unlocking anti-fake method
WO2013179249A1 (en) * 2012-05-30 2013-12-05 Label Tech International Trims Limited Authentication apparatus and methods
CN103065101A (en) * 2012-12-14 2013-04-24 北京思特奇信息技术股份有限公司 Anti-counterfeiting method for documents
CN104228380B (en) * 2013-06-21 2016-12-28 广州市人民印刷厂股份有限公司 Invisible open locking-type method for anti-counterfeit
US9374497B2 (en) 2014-10-20 2016-06-21 Caterpillar Inc. Component and watermark formed by additive manufacturing
US10826900B1 (en) * 2014-12-31 2020-11-03 Morphotrust Usa, Llc Machine-readable verification of digital identifications
US9937656B2 (en) 2016-07-07 2018-04-10 Caterpillar Inc. Method for printing component with anti-counterfeit features
EP3686027B1 (en) 2019-01-27 2021-07-14 U-NICA Systems AG Method of printing authentication indicators with an amplitude-modulated half tone
CN111476703B (en) * 2020-04-09 2024-04-26 北京印实科技有限公司 Method for manufacturing optical watermark
CN113630606B (en) * 2020-05-07 2024-04-19 百度在线网络技术(北京)有限公司 Video watermark processing method, video watermark processing device, electronic equipment and storage medium
JP2023003627A (en) * 2021-06-24 2023-01-17 シヤチハタ株式会社 Computer device, method, and computer program
CN115330583A (en) * 2022-09-19 2022-11-11 景德镇陶瓷大学 Watermark model training method and device based on CMYK image

Family Cites Families (22)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN85100700A (en) * 1985-04-01 1987-01-31 陆伯祥 Computing machine Moire fringe certificate and recognition system thereof
US4838644A (en) * 1987-09-15 1989-06-13 The United States Of America As Represented By The United States Department Of Energy Position, rotation, and intensity invariant recognizing method
US5396559A (en) * 1990-08-24 1995-03-07 Mcgrew; Stephen P. Anticounterfeiting method and device utilizing holograms and pseudorandom dot patterns
US6000728A (en) * 1991-07-12 1999-12-14 The Standard Register Company Security document
US6345104B1 (en) * 1994-03-17 2002-02-05 Digimarc Corporation Digital watermarks and methods for security documents
US5659613A (en) * 1994-06-29 1997-08-19 Macrovision Corporation Method and apparatus for copy protection for various recording media using a video finger print
US6577746B1 (en) * 1999-12-28 2003-06-10 Digimarc Corporation Watermark-based object linking and embedding
US5767889A (en) * 1995-08-23 1998-06-16 Intermec Corporation Bar shaving of the resident fonts in an on-demand barcode printer
US5995638A (en) * 1995-08-28 1999-11-30 Ecole Polytechnique Federale De Lausanne Methods and apparatus for authentication of documents by using the intensity profile of moire patterns
US5708717A (en) * 1995-11-29 1998-01-13 Alasia; Alfred Digital anti-counterfeiting software method and apparatus
US5734752A (en) * 1996-09-24 1998-03-31 Xerox Corporation Digital watermarking using stochastic screen patterns
US5915027A (en) * 1996-11-05 1999-06-22 Nec Research Institute Digital watermarking
US5790703A (en) * 1997-01-21 1998-08-04 Xerox Corporation Digital watermarking using conjugate halftone screens
US5951055A (en) * 1997-06-11 1999-09-14 The Standard Register Company Security document containing encoded data block
EP0921675B1 (en) * 1997-12-03 2006-07-05 Kabushiki Kaisha Toshiba Method of processing image information and method of preventing forgery of certificates or the like
US6104812A (en) * 1998-01-12 2000-08-15 Juratrade, Limited Anti-counterfeiting method and apparatus using digital screening
US6145081A (en) * 1998-02-02 2000-11-07 Verance Corporation Method and apparatus for preventing removal of embedded information in cover signals
US6252971B1 (en) * 1998-04-29 2001-06-26 Xerox Corporation Digital watermarking using phase-shifted stoclustic screens
GB2364513B (en) * 1998-12-23 2003-04-09 Kent Ridge Digital Labs Method and apparatus for protecting the legitimacy of an article
US6456726B1 (en) * 1999-10-26 2002-09-24 Matsushita Electric Industrial Co., Ltd. Methods and apparatus for multi-layer data hiding
US6636616B1 (en) * 1999-11-30 2003-10-21 Xerox Corporation Method and apparatus for digital watermarking using error diffusion
US6879652B1 (en) * 2000-07-14 2005-04-12 Nielsen Media Research, Inc. Method for encoding an input signal

Non-Patent Citations (3)

* Cited by examiner, † Cited by third party
Title
PIVA A ET AL: "EXPLOITING THE CROSS-CORRELATING OF RGB-CHANNELS FOR ROBUST WATERMARKING OF COLOR IMAGES", KOBE, JAPAN, OCT. 24 - 28, 1999,LOS ALAMITOS, CA: IEEE,US, October 1999 (1999-10-01), pages 306 - 310, XP000937723, ISBN: 0-7803-5468-0 *
SAYROL E ET AL: "OPTIMUM WATERMARK DETECTION IN COLOR IMAGES", KOBE, JAPAN, OCT. 24 - 28, 1999,LOS ALAMITOS, CA: IEEE,US, October 1999 (1999-10-01), pages 231 - 235, XP000939228, ISBN: 0-7803-5468-0 *
WOLFGANG R B ET AL: "A WATERMARK FOR DIGITAL IMAGES", LAUSANNE, SEPT. 16 - 19, 1996,NEW YORK, IEEE,US, September 1996 (1996-09-01), pages 219 - 222, XP000668961, ISBN: 0-7803-3259-8 *

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9940685B2 (en) 2000-04-19 2018-04-10 Digimarc Corporation Digital watermarking in data representing color channels
US9179033B2 (en) 2000-04-19 2015-11-03 Digimarc Corporation Digital watermarking in data representing color channels
US7213757B2 (en) 2001-08-31 2007-05-08 Digimarc Corporation Emerging security features for identification documents
WO2004109599A1 (en) * 2003-06-04 2004-12-16 Commonwealth Scientific And Industrial Research Organisation Method of encoding a latent image
US7916343B2 (en) 2003-07-07 2011-03-29 Commonwealth Scientific And Industrial Research Organisation Method of encoding a latent image and article produced
EP1547805A1 (en) * 2003-12-23 2005-06-29 Elca Informatique S.A. Method for generating and validating tickets printable at home
EP1787240A4 (en) * 2004-08-09 2011-04-13 Graphic Security Systems Corp Systems and methods for authenticating objects using multiple-level image encoding and decoding
EP1787240A2 (en) * 2004-08-09 2007-05-23 Graphic Security Systems Corporation Systems and methods for authenticating objects using multiple-level image encoding and decoding
WO2007065224A1 (en) 2005-12-05 2007-06-14 Commonwealth Scientific And Industrial Research Organisation A method of forming a securitized image
EP2100403A4 (en) * 2006-12-13 2011-04-13 Graphic Security Systems Corp Object authentication using encoded images digitally stored on the object
EP2100403A2 (en) * 2006-12-13 2009-09-16 Graphic Security Systems Corporation Object authentication using encoded images digitally stored on the object
US9117268B2 (en) 2008-12-17 2015-08-25 Digimarc Corporation Out of phase digital watermarking in two chrominance directions
US9245308B2 (en) 2008-12-17 2016-01-26 Digimarc Corporation Encoding in two chrominance directions
US9582844B2 (en) 2008-12-17 2017-02-28 Digimarc Corporation Detection from two chrominance directions
US11210495B2 (en) 2011-03-17 2021-12-28 New York University Systems, methods and computer-accessible mediums for authentication and verification of physical objects
WO2012164361A1 (en) * 2011-05-27 2012-12-06 Nds Limited Frequency-modulated watermarking
US9111340B2 (en) 2011-05-27 2015-08-18 Cisco Technology Inc. Frequency-modulated watermarking
CN109040761A (en) * 2018-09-17 2018-12-18 俞群爱 A kind of monitoring on-wall system with encrypted watermark

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DE60018222D1 (en) 2005-03-24
US20020054680A1 (en) 2002-05-09
JP4373045B2 (en) 2009-11-25
DE60018222T2 (en) 2006-01-12
EP1317734B1 (en) 2005-02-16
JP2003530737A (en) 2003-10-14
ATE289437T1 (en) 2005-03-15
AU785178B2 (en) 2006-10-12
CN1170254C (en) 2004-10-06
AU7569000A (en) 2002-03-26
US7366301B2 (en) 2008-04-29
CN1372677A (en) 2002-10-02

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