Title of Invention

"OPTICALLY READABLE MEDIA"

Abstract The present invention discloses an optically readable media (10) having an information-encoding layer (16) and at least one color-forming layer (12) that embodies an optical readout-limiting mechanism. In a first embodiment the at least one color - forming layer contains an additive that does not interfere with the optical readability of the media for a duration of a readout period. The additive, upon exposure to a source of optical radiation that is suitable for reversing the color-forming layer from an optical radiation that is suitable for reversing the color-forming layer from an optical readout inhibiting state to an optical readout enabling state, undergoes a transformation that maintains the color-forming layer in the optical readout inhibiting state. More specifically, exposure to the source causes the color-forming layer to photobleach and the additive to oxidize, where the oxidation of the additive permanently inhibits the optical readability of the media. The additive may be a leuco dye. In one embodiment the color-forming layer is comprised of 3-[2,3-bis(4-diethylaminophenyl)vinyl]-6- dimethylaminophthalide and the additive is comprised of benzoyl leucomethylene blue. In a further embodiment the additive is placed into a protective layer (18) that overlies the color-forming layer.
Full Text OPTICALLY READABLE MEDIA
FIELD OF THE INVENTION;
This invention relates to optically readable information storage media and, more
particularly, to a technique for rendering a reading inhibit layer lightfast
BACKGROUND OF THE INVENTION:
It has become commonplace to distribute software or other information, such as music and
films, on optically readable media, such as CDs and DVDs. Successful readout of an
optical disk by current disk readers heavily relies on a number of parameters that
characterize the readout laser beam on its path from the laser to the reflective data layer
of the disk and back to the optical pickup system of the reader. The electromagnetic wave
structure of the readout beam is described by intensity, phase, polarization, and wave
vectors of the wave components that constitute the readout beam. The wave structure of
the beam determines geometrical and propagation parameters of the beam, such as beam
size, angle of incidence, and angle of convergence.
In addition to reading the data layer of a disk, the reader performs other functions, which
are as critical for playability as the data readout itself. These functions include auto-
focusing, auto-tracking and error correction. The first two functions allow the reader
device to actively control motion of the laser head and spindle motor in order to maintain
the required position of the beam relative to the disk. Therefore, maintaining the integrity
of the wave structure of the beam throughout its path inside the disk material is a key not
only to the successful detection and decoding of the information carried by the beam, but
also for the continuity of the readout process.
It is desirable in many applications to limit the duration of time during which the optical
disk can be read. For example, one could rent an optical disk containing a film or a
musical composition that, after some period of time, would become unreadable. In this
case there would be no need to return the optical disk to place where it was rented.
U.S. Patent No. 5,815,484 discloses an optical disk having a reflective metallic layer with
a plurality of data structures (provided in the form of pits and lands) and a compound that
reacts with oxygen that is superimposed over at least some of the data structures for
inhibiting reading of the information.
Commonly assigned U.S. Patent No. 6,011,772 discloses a read inhibit mechanism that
may also use a barrier layer. For example, the removal of a barrier layer enhances the
action of a reading-inhibit agent to prevent machine reading of information encoding
features on the optical disk. The reading-inhibit agent may also be activated by exposure
to optical radiation, or by rotation of the disk.
A disadvantage of some chemical moieties used in or proposed for use in a reading inhibit
layer is that they exhibit poor lightfastness, which could allow the limited play optical disk
to be photobleached and subsequently converted back, possiblypermanently, to areadable
optical disk.
OBJECTS OF THE INVENTION:
It is a first object and advantage of this invention to provide an improved system and
method for permanently limiting the readability of a media, such as an optically readable
media, examples of which include, but are not limited to, a laser disk, a compact disk
(CD), or a digital video disk (DVD).
It is a second object and advantage of this invention to provide an improved system and
method to render an optically readable media permanently unreadable, after having been
read at least once.
It is a further object and advantage of this invention to provide an optically readable media
having a read inhibit layer that is rendered lightfast by the addition of a chemical
compound.
It is a another object and advantage of this invention to provide an optically readable
media having a read inhibit layer that is resistant to being photobleached back to a
readable state.
It is one further object and advantage of this invention to provide an optically readable
media having a read inhibit layer and a protective layer. The protective layer may also
function as a barrier layer, and overlies the read inhibit layer. The protective layer includes
an additive that oxidizes and becomes optically absorbing at the readout wavelength(s) in
response to a source of light, such as UV light, that would also photobleach the read inhibit
layer back to an optically transmissive and, hence, optically readable state.
SUMMARY OF THE INVENTION
The foregoing and other problems are overcome and the objects and the advantages of the
invention are realized by methods and systems in accordance with embodiments of this
invention.
An optically readable media, such as a CD or a DVD, has an information-encoding layer
and at least one color-forming layer that embodies an optical readout-limiting mechanism.
In a first embodiment the at least one color-forming layer contains an additive that does
not interfere with the optical readability of the media for a duration of a readout period.
The additive, upon exposure to a source of optical radiation that is suitable for reversing
the color-forming layer from an optical readout inhibiting state to an optical readout
enabling state, undergoes a transformation that maintains the color-forming layer in the
optical readout inhibiting state. More specifically, exposure to the source causes the color-
forming layer to photobleach and the additive to oxidize, where the oxidation of the
additive permanently inhibits the optical readability of the media The additive may be a
leuco dye. In one embodiment the color-forming layer includes 3-[2,2-bis(4-
diemylanimophenyl)vinyl]-6-dimethylaminophthalide and the additive includes benzoyl
leucomethylene blue. In a further embodiment the additive is placed into a protective layer
that overlies the color-forming layer.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
The above set forth and other features of the invention are made more apparent in the
ensuing Detailed Description of the Invention when read in conjunction with the attached
Drawing, wherein:
Fig. 1 is a cross-sectional view of an optically readable media that includes a lightfast
readout inhibiting layer in accordance with this invention; and
Fig. 2 illustrates an equilibrium mechanism between a colorless lactone form and its
cationic colored quininoid form in the optical readout inhibiting layer of Fig. 1.
DETAILED DESCRIPTION OF THE INVENTION
Fig. 1 is a cross-sectional view of an optically readable media 10 that includes a lightfast
readout inhibiting layer 12 in accordance with this invention. It should be noted at the
outset that as employed herein an optically readable media is intended to encompass a
number of various devices wherein data (such as a computer program), audio (such as
music) and/or video (such as a film or television programming), collectively referred to
herein simply as information or content, is stored such that it can be readout when a
lightbeam (either visible light or invisible light) is applied to the medium. Such a medium
can include, but is not limited to laser disks, compact disks (CDs), CD-ROMs, digital
video or versatile disks and certain kinds of tapes.
The media 10 includes a substrate 14, a patterned, reflective surface 16 wherein the
information is encoded using conventional techniques, the readout inhibiting layer 12, and
optionally a top coat 18 or over coat that can function as a protective layer as well as a
barrier layer to at least partially inhibit or slow the evaporation or sublimation of a reactive
compound from the readout inhibiting layer 12. Reference in this regard can be made to
commonly assigned U.S. Patent Application No.: 09/690,405, filed on 10/17/00, as well
as to commonly assigned and allowed U.S. Patent Application No.: 09/338,959, filed on
06/24/99, both of which are incorporated by reference herein in their entireties.
In general, the media 10 of interest to this invention incorporates the readout inhibiting
mechanism or layer 12 that is capable of altering an optical property of the light, for
example, the wavefront, optical noise content, intensity and/or wave emission wavelength.
Also, the reflectance and/or transmission property of the media can be changed.
Limiting or inhibiting the readout of the media 10 can be effected by using a color forming
coating. Such a coating functions as the readout-limiting layer 12 by initially permitting,
when in a first state, an optically readable media to be read; after which the coating
changes to a second state in which the coating prevents the readable of the media 10. The
color forming coating changes color, or more precisely transitions from a substantially
transparent state (at the readout wavelength(s) of interest) to a substantially absorbing state
(again at the readout wavelength(s) of interest), thereby inhibiting readout of the media 10.
By rendering the media "unreadable" it should be understood that it is not necessary to
make the entire media 10 unreadable. For example, it may be necessary to make only a
relatively small portion of a boot record or a directory of contents unreadable such that the
entire media becomes unusable or unreadable, or such that some predetermined portion
of the media becomes unusable or unreadable. Making the media unreadable may also
imply adversely affecting a readout device optical feedback and tracking process.
Further, it is not necessary for the readout inhibiting layer 12 to become optically opaque,
as the media 10 may become unreadable or unplayable well before a state or condition of
optical opacity is reached. In general, the readout inhibiting layer 12 can be effective in
inhibiting the reading of desired information from the media 10 by causing a failure in any
of at least three readout light beam functions: data readout, auto-focusing, and auto-
tracking.
Referring to Fig. 2, in a presently preferred but not limiting embodiment the readout
inhibiting layer 12, which may also be referred to as the color forming coating, includes
at least three components: (1) a dye, such as a lactone type dye; (2) acidic sites; and (3) a
solvent, such as an amine or amide-based solvent. The acidic sites may be provided by
a polymer, a clay, or any other acidic substrate. When the components are combined, the
amine or amide-based solvent serves to stabilize the lactone dye to the colorless form.
When the amide or amine-based solvent evaporates, the lactone group reacts with the
acidic sites and undergoes a ring opening to generate a highly colored substance with a
strong absorption at a typical wavelength used to read DVD and CD disks (about 650 nm).
In greater detail, the colorless lactone shown in the reaction scheme shown in Fig. 2 is
protonated by an acid. Each nitrogen is shown with its free electron pair. The protonated
lactone undergoes a ring opening to produce the colored compound, in this case, a blue
quininoid form.
The functioning of this color changing system is based on a four component equilibrium
between the colorless lactone form, the colored quininoid form, and the number of acidic
and basic sites associated with the permanent and the volatile components of the color
changing system.
In various embodiments of this invention, the material that comprises the readout-
inhibiting layer 12 can include a lactone dye, such as crystal violet lactone, poly-p-
(hydroxystyrene), ethanol, N-methyl pyrrolidinone and ammonia and formaldehyde, or the
readout inhibiting layer 12 can comprise cellulose acetate butyrate, ethyl acetate, silica gel,
and benzyl alcohol, or the readout inhibiting layer 12 can comprise a salt of a volatile
amine, a non-volatile acid component and a lactone dye or a pH indicator dye, or the
readout inhibiting layer 12 can comprise a water damp polymer film containing a pH
indicator dye, wherein during storage the readout inhibiting layer 12 is exposed to an
atmosphere of a gas whose water solution is one of acidic or basic, and wherein upon
removal from storage a volatile gas evaporates from the water damp film, and the pH
changes causing a color change in the pH indicator dye.
In the preferred embodiments, the readout inhibiting layer 12 contains a dye, such as a
lactone dye, having a cation with strong light absorbance properties around 650 nm, a
currently preferred wavelength for the readout laser. A polymer material or some other
material can be used to provide an acidic environment for causing a controlled ring
opening of the lactone dye, and which can be cross-linked or otherwise modified to form
a relatively inert or inactive coating layer. Lactone dyes are generally colorless so long
as the lactone moiety remains intact. However, by modifying the environment, for
example by lowering the pH and/or by changing the micropolarity, the lactone ring is
cleaved and the intensely colored cationic form of the dye is obtained.
In general, the rate of color change is dependent on the type of solvent and its boiling
point. By selecting an appropriate solvent, complete color formation can occur within a
range of a few minutes to several hours to even longer times. Moreover, the final
maximum absorbance at the readout wavelength can be modified over a range of
absorbances by changing the lactone moiety to acidic site ratio.
In other embodiments of this invention, a polymer may provide a basic environment while
the evaporating solvent has an acidic nature. In this case the color change occurs when the
system transitions from acidic to basic due to evaporation.
The "undyed" state of the media 10 may be maintained by storing the media 10 in a
manner that prevents the solvent from evaporating. For example, the media 10 can be
stored in a sealed container, such as a foil or plastic bag, that may contain a source of the
volatile component of the readout inhibiting layer 12. In this manner the atmosphere
within the container becomes saturated with the volatile component, which in turn inhibits
the loss by evaporation (or sublimation in some embodiments) of the volatile component
form the readout inhibiting layer 12.
In any of the embodiments, the readout inhibiting layer 12 may be applied by a spin
coating procedure. As an example, for the amino-phthalide dye in the 4-vinylphenol
polymer embodiment a layer thickness equal to or less than about one micrometer was
found to be optimum, and DVD readability was found to be disabled when the absorbance
at 650 nm was equal to or greater than about 0.5.
However, if the colored quininoid form of the color forming compound does not have a
satisfactory lightfastness, exposing the limited-play system to ultraviolet (UV) light, such
as that found in sunlight, may induce a photochemical reaction and hence break down the
colored quininoid form into a mixture of colorless chemical compounds. As a
consequence, the unreadable media 10 might be made permanently optically readable by
exposing the media 10 to UV light, or to direct or indirect (i.e. behind window glass)
sunlight.
In accordance with the teachings of this invention, the problem of the media 10 reversal
back to readability can be solved by adding an additive either to the color forming coating
12 or to the top polymer protective coating 18. The additive preferably is colorless and
remains colorless under regular room light, as well as under normal media readout light
wavelengths. However, the additive oxidizes under sunlight or UV light into a colored
compound, and the oxidized form has an absorption spectrum that overlaps with the
absorption spectrum of the selected colored quininoid form. The additive thus adds a
superior lightfastness.
The quininoid photobleaching kinetics, the additive photooxidation kinetics and the optical
properties of the quininoid and additive components are preferably matched so that the
loss in absorbance of the quininoid form due to photobleaching is corrected by the
appearance of the colored photooxidized additive.
The additive can be co-mixed with color former in a polymer formulation that is used
when constructing the readout inhibiting layer 12 . The lightfastness-enhancing additive
need not interact with the performance of the readout inhibiting layer 12 or the protective
top polymer coating 18.
The additives may belong to different chemical classes depending on the selected color
former(s) of the readout inhibiting layer 12. One such chemical class comprises leuco
dyes.
As an example, an appropriate additive for the color former 3-[2,2-bis(4-
diethylaminophenyl)vinyl]-6-dimethylaminophthalide is benzoyl leucomethylene blue.
Exposure to UV light and sunlight transforms benzoyl leucomethylene blue into methylene
blue. Methylene blue is well known for its superior lightfastness, and its absorption
spectrum very closely matches the spectrum of the quininoid form of the color former in
the readout inhibiting layer 12. This additive can be incorporated into the formulation
described as Example 1 below and in the co-pending and commonly assigned U.S. Patent
Application No.: 09/690,405, filed on 10/17/00, the disclosure of which was incorporated
herein in its entirety.
Example 1:
A solution of 1 g poly(4-vinylphenol) (MW=8,000) in 10 ml ethanol, 2 ml N,N-dimethyl
formamide and 200 mg of 3-[2,2-bis(4-diethylaminophenyl)vinyl)-6-
dimethylaminophthalide was prepared. A surface of an optical disc was coated with this
formulation to produce a 500-700 nm thick layer that was substantially uncolored. The
coating was dried at 60-70°C for a few minutes, which caused the generation of an
intensely blue colored dye. This blue dye was transformed to a colorless state by exposure
to UV light.
The additive, benzoyl leucomethylene blue, is incorporated in the Example 2 formulation
as follows:
Example 2:
A solution was prepared of 1 g poly(4-vinylphenol) (MW=8,000) in 10 ml ethanol, 2 ml
N,N-dimethylformamide, 200 mg of 3-[2,2-bis(4-diethylaminophenyl)vinyl]-6-
dimethylaminophthalide and 200 mg of benzoyl leucomethylene blue. An optical disc was
coated with this formulation to produce a 500-700 nm thick layer that was substantially
uncolored. The coating was dried at 60-70°C for a few minutes, which caused the
generation of an intensely blue colored dye corresponding to a limited-play, unreadable
state of the disc. However, exposing the coating to sunlight or UV-light did not result in
a transformation back to the colorless state, and thus did not defeat the limited-play
mechanism.
While described in the context of a single readout wavelength, it is within the scope of
these teachings to render lightfast composite and multi-player (multi-wavelength) readout
inhibiting layer or layers 12. Such multi-wavelength layer(s) provide absorption maxima
at two or more wavelengths that coincide with possible readout light wavelengths, e.g.,
630 nm and 780 nm for CDs, 630 nm and 650 nm for DVDs, and may also accommodate
future higher density readout wavelengths at shorted wavelengths. The multi-wavelength
coating can also be used to absorb a specific wavelength and a range of wavelengths, such
as 635 nm and the range of 750 nm to 800 nm.
It can be appreciated that a number of embodiments of the teachings of this invention have
been described herein, and it should be further appreciated that the teachings of this
invention are not intended to be read in a limiting sense to encompass only these described
embodiments.
WE CLAIM:
1. An optically readable media 10 comprising :
an information-encoding layer 16 ;
at least one color-forming layer 12 that embodies an optical readout-limiting mechanism; said
color-forming layer prohibits, once activated, the readout of said information encoding layer 16 ; and
an additive 12 or 18, said additive undergoes a transformation upon exposure to a predefined
optical wavelength to prohibit the color-forming layer from reversing from a read prohibiting state to a
read enabling state and thereby preserving the color-forming layer in its read prohibiting state.
2. The media as claimed in claim 1, where said additive is comprised of a leuco dye.
3. The media as claimed in claim 1, where said color-forming layer is comprised of 3-[2,2-bis(4-
diethylaminophenyl)vinyl]-6-dimethylaminophthalide and where said additive is comprised of benzoyl
leucomethylene blue.
4. The media as claimed in claim 1, wherein when in said readout inhibiting state said color-
forming layer exhibits an optical wavelength absorption range that comprises an optical readout
wavelength of said media, thereby inhibiting optical readout of said media.
5. The media as claimed in claim 4, where exposure to said source of optical radiation causes said
additive to oxidize and to exhibit an optical wavelength absorption range that overlaps with said optical
wavelength absorption range of said color-forming layer, thereby permanently inhibiting the readability
of said media.
6. The media as claimed in claim 4, where exposure to said source causes said color-forming layer
to photobleach and said additive to oxidize, where the oxidation of said additive permanently inhibits
the optical readability of said media.
7. The media as claimed in claim 1, having a protective layer that overlies said at least one color-
forming layer, wherein said additive is a component of said protective layer.
The present invention discloses an optically readable media (10) having an
information-encoding layer (16) and at least one color-forming layer (12) that embodies
an optical readout-limiting mechanism. In a first embodiment the at least one color -
forming layer contains an additive that does not interfere with the optical readability of
the media for a duration of a readout period. The additive, upon exposure to a source of
optical radiation that is suitable for reversing the color-forming layer from an optical
radiation that is suitable for reversing the color-forming layer from an optical readout
inhibiting state to an optical readout enabling state, undergoes a transformation that
maintains the color-forming layer in the optical readout inhibiting state. More
specifically, exposure to the source causes the color-forming layer to photobleach and
the additive to oxidize, where the oxidation of the additive permanently inhibits the
optical readability of the media. The additive may be a leuco dye. In one embodiment
the color-forming layer is comprised of 3-[2,3-bis(4-diethylaminophenyl)vinyl]-6-
dimethylaminophthalide and the additive is comprised of benzoyl leucomethylene blue.
In a further embodiment the additive is placed into a protective layer (18) that overlies
the color-forming layer.

Documents:

755-kolnp-2003-granted-abstract.pdf

755-kolnp-2003-granted-assignment.pdf

755-kolnp-2003-granted-claims.pdf

755-kolnp-2003-granted-correspondence.pdf

755-kolnp-2003-granted-description (complete).pdf

755-kolnp-2003-granted-drawings.pdf

755-kolnp-2003-granted-examination report.pdf

755-kolnp-2003-granted-form 1.pdf

755-kolnp-2003-granted-form 18.pdf

755-kolnp-2003-granted-form 3.pdf

755-kolnp-2003-granted-form 5.pdf

755-kolnp-2003-granted-gpa.pdf

755-kolnp-2003-granted-reply to examination report.pdf

755-kolnp-2003-granted-specification.pdf

755-kolnp-2003-granted-translated copy of priority document.pdf


Patent Number 222739
Indian Patent Application Number 755/KOLNP/2003
PG Journal Number 34/2008
Publication Date 22-Aug-2008
Grant Date 21-Aug-2008
Date of Filing 10-Jun-2003
Name of Patentee FLEXPLAY TECHNOLOGIES, INC.
Applicant Address 274 MADISON AVENUE NEW YORK, NY
Inventors:
# Inventor's Name Inventor's Address
1 KREIG-KOWALD MARIANNE 1 FERRIER AVENUE BARRINGTON, RI 02806
PCT International Classification Number G11B
PCT International Application Number PCT/US01/48029
PCT International Filing date 2001-12-11
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 60/254,610 2000-12-11 U.S.A.