Patent Application
20080151310
With the general availability of high quality color reproduction, distinguishing an original from a copy and verifying, for example, a signature, on the original has become more difficult. More specifically, digital printers, scanners, and image editing software have made it possible for copies of legitimate documents to be made that are difficult to distinguish from the original.
One conventional approach to authenticating documents is the use of machine readable encoded data which is rendered onto a document or other physical media along with other information.
For example, authenticating information can be encoded into thousands of tiny, individual glyph elements. Each element consists of a small 45 degree diagonal line, as short as 1/100th of an inch or less, depending on the resolution of the printing and scanning that is used. Each glyph represents either binary 0 or binary 1, depending on whether the glyph slopes to the left or right. Sequences of glyphs can be used to encode numeric, textual, or other information. The glyphs are grouped together on the page, where the glyphs form unobtrusive, evenly textured gray areas, similar to a half-toned picture.
Another conventional approach to the problem of verifying document authenticity is the use of authenticating information embedded in a print, for example, a seal or a date and time. The embedded authenticating information catches the light when the print is tilted and can be seen as an additional and separate image. Moreover, watermarks, conventionally, have also been used to authenticate a document.
These various conventional methods of verifying a document share the feature that it is very difficult to reproduce the authenticating feature of the original on a conventional copier or scanner. Therefore, a copy of the original can be distinguished from the original.
However, the conventional methods of verifying a document have drawbacks. For example, glyphs need a device to decode the authenticating information. Moreover, conventional watermarks need a proper source of light to discern the authenticating information. In these various conventional methods, outside intervention; e.g., from either a machine (optical reader) or a light source; is needed to detect or discern the authenticating information.
Therefore, it is desirable to provide a method that enables authentication of an original document without the utilization of outside intervention; e.g. from either a machine (optical reader) or a light source. Moreover, it is desirable to provide a method that enables authentication of an original document through tactile perception. Furthermore, it is desirable to provide a method that enables authentication of an original document through tactile perception while preventing the authenticating information of the original document from being reproduced using conventional scanners and printers.
The drawings are only for purposes of illustrating an embodiment and are not to be construed as limiting, wherein:
For a general understanding, reference is made to the drawings. In the drawings, like references have been used throughout to designate identical or equivalent elements. It is also noted that the drawings may not have been drawn to scale and that certain regions may have been purposely drawn disproportionately so that the features and concepts could be properly illustrated.
As noted above, it is desirable to provide a method that enables authentication of an original document without the utilization of outside intervention; e.g. from either a machine (optical reader) or a light source. Moreover, it is desirable to provide a method that enables authentication of an original document through tactile perception. Furthermore, it is desirable to provide a method that enables authentication of an original document through tactile perception while preventing the authenticating information of the original document from being reproduced using conventional scanners and printers.
Tactile perception is based upon the physical sense of touch and thus tactile perception can be realized without utilizing a source of light or optical reader. In contrast, the various conventional methods of authenticating an original document required visual perception.
A flowchart of a method of authenticating a printed medium is shown in
It is noted that a predetermined mark should be used so that the authenticator of the printed medium will be apprised of the authentication criteria.
As noted above, the predetermined mark is transferred to the medium. One example of the transfer of the predetermined mark is using solid ink jetted onto an imaging drum. The imaging drum is used to transfer the image to the medium. It is noted that multiple transfer passes may be needed to attain a tactilely perceptible ink pile height.
The authenticator of the printed medium uses the sense of touch to determine if the authentication mark is present. If the mark is not present, the medium is not authenticated. It is noted that the authenticating mark may be present visually, but the mark is still not authenticated unless it can be detected tactilely. The medium with the tactilely perceptible authenticating mark may be duplicated using a conventional scanner or copier. However, the duplicate, although it may have a visually perceptible authenticating mark, will not have the tactilely perceptible authenticating mark.
It is noted that the authenticating mark may be selected using hardware or software connected to a printer through a conventional computer network.
Although the above examples discuss using solid inkjet printing, xerography (toner) can also be readily utilized. As in solid inkjet printing, xerographic printing can render a document where all or a portion of the printed image can be tactilely perceived.
It is noted that the portion of the image to be tactilely perceived will be the identifying signature or mark used for authentication. The identifying mark could be a letterhead, an image of a personal signature, or a tactilely perceptible code.
It is noted that multiple printing passes may be used to cause the identifying mark to have a marking material pile height that is tactilely perceptible. For example, a marking material pile height of at least 31 microns is perceptible through the sense of touch, whereas conventional solid ink printing or xerography produces a marking material pile height of no more that 10 microns which is not tactilely perceptible.
In summary, an authentication mark is created on a recording medium by depositing marking material on a recording medium in an image area to create a tactilely non-perceptible image and in an authentication image area to create a tactilely non-perceptible marking material authentication image; depositing a predetermined amount of additional marking material upon the recording medium in the authentication image area to increase an amount of marking material associated with the marking material authentication image; and fixing the marking material upon the recording medium such that the fixed marking material associated with the authentication image area is a tactilely perceptible authentication mark.
It will be appreciated that various of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
