OPTICALLY VARIABLE IMAGE DEVICE AND METHOD OF PREPARING THE SAME

Field of the Invention

The present invention relates to an optically variable image device assuming a form of a planar structure that is characterised by being based on the function of optical primitives arranged in accordance with a graphical phyllotactic model (the invention does not relate to a displaying device). Under prevalent conditions, such device having a fixed structure enables the observer to obtain a desired visual perception, an optically variable image perception being obtainable under changing conditions of observation or illumination. The desired visual perception comprises at least two different images, the first one corresponding to a respective characteristic phyllotactic pattern and the second one corresponding to a respective desired graphical pattern. Moreover, the present invention relates to a method of preparing such optically variable image device.

Background of the Invention

Phyllotaxy is the mode of arrangement of parts of plants (such as leaves along a plant stem, perianth leaves, cores in a flower head etc.). There are several known models describing such arrangements. An exemplary model was designed by VOGEL (VOGEL, H., A Better Way to Construct the Sunflower Head. Mathematical Biosciences 44: 179-189. (1979)). The basis of this model describing arrangement of cores in a flower head, including the basic spiral, is shown in Figure 1 (a). A model comprising an increased number of cores is shown in Figure 1 (b), wherein two sets of derived spirals are indicated (one set for each 21 ^st core and one set for each 34 ^th core) besides the basic cyclotron spiral. The mathematical description of this model is based on the relations defining the location of the core by means of polar coordinates (r, theta) and in dependence on the order k of the cores in a sorted array.

n = c . k (la) thetait = k . thetao (lb) Within the above relation, thetao is a rotational parameter and c is a scale parameter. The author VOGEL suggests choosing a constant relation thetao = 2 . pi / FT ² , wherein FI = ( sqrt ( 5 ) + l ) / 2, i.e. a constant rotational parameter assuming the value 137.5 degrees for achieving an azimuthally uniform arrangement.

A utilization of such a model for visual reference comparisons of the quality of exposures carried out by means of a recorder using an electron beam was published by MELUZI (MELUZIN, P. et al., Some Other Gratings: Benchmarks for Large-Area E-Beam Nanopatterning, NANOCON 2014, 6th International conference proceedings, Ostrava:

TANGER, 2014, ISBN 978-80-87294-55-0). The latter publication describes, among others, an image of a diffraction pattern of a phyllotactic model, said image being observable when the mesh comprising the elements of the phyllotactic model is sufficiently dense and extensive. Such pattern is peculiar to a given phyllotactic model, as shown in Figure 2. Figure 2 (a) shows the positions of the cores according to the above mentioned model, the number of the cores within this more extensive model being 10,000. A close observation makes it possible to recognize the fine strokes of the derived spirals (such spirals include particularly those appearing close to the edge of the circular area and comprising each 144 ^th and each 233 ^rd core, respectively). In this connection, Figure 2 (a) shows a pattern that is recognizable when observing this model, i.e. that shown in Figure 2 (a) at a very wide viewing angle.

However, the latter publication does not further deal with any possible method of utilizing a mesh of a phyllotactic model for creating a selected image for a particular device type, such as a DOVID (Diffractive Optically Variable Image Device).

Diffractive optically variable image devices make use of light diffraction on a regular structure, different parts of the obtained image being based on diffractive elements (such as grids) having specific parameters. When suitable parameters and locations of such elements are chosen, the image created by a DOVID device can invoke a diffractive visual perception that is typically variable when the observing conditions are changing, e.g. when the DOVID device is turned or tilted by the observer. Such devices are frequently used for creating protective elements of documents, tokens of value, identity cards, fee stamps or the like. A thorough overview of these elements is elaborated, for example, in the publication by

RENESSEE (RENESSEE, Rudolf L. van, Optical Document Security, 3rd edition, Artech House, Boston/London (2005), 386 pages, ISBN 1-58053-258-6), including references to tens of patents and hundreds of expert articles. Figure 3 shows various simplified configurations for observing a diffractive image; also shown are various directions in which the observer can see the image when a constant location of the light source and a constant location and orientation of the DOVID device, respectively, is selected. Further known variants of the DOVID device present structures, which are based on delineated contour lines of a three- dimensional object obtained by means of diffraction or refraction lines; actually, a simple Fresnel construction is concerned wherein the macro surface of the respective object is replaced with Fresnel zones or with diffractive Fresnel zones in the course of the implementation. An exemplary disclosure is contained in the patent application

WO2006013215A1.

The above list of known methods and processes is far from being exhaustive but it will be sufficient for a basic introduction into the particular topic. In the area of document security as well as in the area of the decorative usage of diffractive elements, there is an obvious unceasing effort to look for new methods which would enable to devise a device providing different perceptions when compared to the known, established methods. Moreover, the area of document security incessantly requires new approaches which would fulfil the basic demand more efficiently, namely the necessity of mitigating the contradiction between the desired simplicity of an authentication of documents on the one hand and the prevention of counterfeiting the same or, at least making such counterfeiting significantly more difficult, on the other hand.

Summary of the Invention

The above objective is fulfilled by providing an optically variable image device assuming the form of a planar optical structure, wherein the device comprises at least one planar primary area corresponding to a primary area of a final graphic template including a mesh of graphical elements, said mesh having been constructed by projecting a series of spatially deployed cores into the plane of a primary graphic template, wherein each of the cores is defined by

a) its basic order;

b) a triplet of initial spatial coordinates derived from a three-dimensional phyllotactic model;

c) a set of modifiable attributes having their initial values derived from a core model,

within said primary area of a primary graphic template comprising a mesh of graphical elements there is arranged in accordance with a graphic pattern at least one secondary subarea formed through a modification of the mesh of graphical elements in the respective secondary subarea, wherein the individual graphical elements of the primary area of the resulting graphic template are represented by micro and/or nano optical primitives or by sets thereof constituting said primary area of the planar optical structure, such that an impinging light by interacting with said planar optical structure creates a visual perception of one image corresponding to a characteristic pattern of the respective combination of said three- dimensional phyllotactic model and said core model and, simultaneously, a different visual perception of another image or images corresponding to said graphic pattern.

Advantageously, the observable image provided by the device according to the invention will at least partly maintain an approximate self-similarity of the image provided by the initial phyllotactic model.

It is also advantageous when the observable image provided by the above device can at least partly maintain a rotational invariance of the image provided by the initial phyllotactic model.

Advantageously, the mutual spacing of said graphical elements ranges from

approximately ten nanometres to approximately ten millimetres.

According to an advantageous embodiment the optically variable image device comprises at least one tertiary subarea within said primary area and the tertiary subarea includes at least one of the following optical elements: microtext, micrographics, computer generated hologram, micro-optical element, micro-lens, micro-mirror.

Preferably, the tertiary subarea comprises a graphical micro element such as micro graphics or a microtext, obtained by projecting a local orthogonal grid, in which such micro element has been prepared, into a local mesh comprising graphical elements, a recognizable modification of the shape of said micro element occurring in least one portion of said subarea, said modification being peculiar to said local mesh comprising graphical elements.

In another advantageous embodiment, another portion of said tertiary subarea contains a micro element arranged within the local orthogonal grid and pre-treated in a manner enabling said modification of the shape of said element and the rotational position of the same to be corrected.

It is also advantageous when the tertiary subarea includes a coded structure, such as a computer generated hologram, obtained by projecting a local orthogonal grid, in which such coded structure has been prepared, into a local mesh comprising graphical elements, a recognizable distortion of the Fourier image of said coded structure occurring in at least one portion of said subarea, said distortion being peculiar to the given local mesh comprising graphical elements. According to a further advantageous embodiment, another portion of said subarea contains said coded structure which has been prepared in the local orthogonal grid and calculated in a manner enabling said distortion of the Fourier image to be rectified.

According to still another advantageous embodiment, the tertiary subarea includes a combination of a microelement, such as a graphical micro element or a microtext, and a coded phase structure, such as a computer generated hologram, said combination enabling a cyclic freedom of a multiple wavelength to be used for distinguishing the positive portions of the micro element from the negative ones when performing a calculation of said coded phase structure.

According to yet another advantageous embodiment, the tertiary subarea, which has a macroscopic size, includes a microelement, such as a graphical micro element or a microtext, enabling a visually observable additional image or a coarse microscopically observable additional image to be obtained by selecting local positive and negative forms of said microelement.

In a particularly advantageous embodiment of the optically variable image device according to the invention, the device is formed using at least two different meshes, which are either entirely separated from each other or arranged in at least partial mutual abutment. Alternatively or additionally, the device is formed using at least two different meshes that at least partly overlap each other in at least one quaternary subarea.

The above mentioned mutual overlap of the meshes can be sharp, stepwise sharp and/or gradual in said quaternary subarea.

Said quaternary subarea is advantageously formed by at least two different meshes, the centres of the models of such meshes being coincident.

Advantageously, the quaternary subarea is formed by at least two meshes having different densities, at least one finer mesh defining an ordered series of graphical elements and, simultaneously, at least one coarser mesh being utilized for constructing at least one secondary and/or at least one tertiary subarea.

According to another advantageous embodiment, the quaternary subarea is formed by one coarse mesh within which the positions and numbers of the graphical elements form the midpoints for a set of fine meshes provided in a corresponding number.

The above objective is fulfilled by a method of preparing an optically variable image device, wherein the method comprises the following steps:

A) at least one plurality of cores arranged in an initial row is prepared by means of a three-dimensional phyllotactic model defining locations of said cores in an initial area and a core model defining properties of said cores, wherein each of said cores is defined by

a) its basic order;

b) a triplet of initial spatial coordinates derived from said three-dimensional phyllotactic model; c) a set of modifiable attributes having their initial values derived from said core model,

B) subsequently, the group of cores is projected into the plane of a primary graphic template to obtain a planar primary area, said primary area being filled with a mesh of primary graphical elements, which correspond to the initial cores,

C) further, at least one secondary subarea is selected within said primary area, which comprises the mesh of graphical elements, the selection being made using a graphical pattern, and then a secondary transformation of the mesh of graphical elements is performed in said secondary subarea to obtain a transformed mesh of graphical elements within the secondary subarea,

D) subsequently, the obtained row of graphical elements is converted into an

implementation sequence and the individual graphical elements are converted into micro and/or nano optical primitives or into sets of such primitives using a relief technique, such that an impinging light by interacting with said planar optical structure creates a visual perception of one image corresponding to a characteristic pattern of the respective combination of said three-dimensional phyllotactic model and said core model and, simultaneously, a different visual perception of another image or images corresponding to said graphic pattern.

Advantageous embodiments of the invention are defined in the dependent claims. Preferably, in step C) the initial series of graphical elements in said subarea is transformed for obtaining a secondary subarea, wherein the transformation, is a transformation of at least one of the following three types:

a) a change in the density of the mesh comprising graphical elements,

b) a transformation of the mesh of the graphical elements into a generally non-orthogonal and/or irregular web;

c) a change of attribute values of the graphical elements.

It is also advantageous, when in step D) the graphical elements of the primary area and/or the secondary subarea are transformed in micro- and/or nano optical primitives or their pluralities, forming a planar optical structure such, that they form at least partially a rotationally invariant optical perception, which corresponds to the initial phyllotactic model from step A).

According to another embodiment, the step C) additionally comprises a selection of at least one further subarea within said planar primary area and subsequently at least one of the following optical elements is created within said further subarea in order to obtain a tertiary subarea: microtext, micrographics, computer generated hologram, micro-optical element, micro-lens, micro-mirror.

Advantageously, said at least one further subarea contains an object, such as a microtext or micrographics, created by transforming the orthogonal grid of said object into a mesh comprising graphical elements within the given subarea to obtain a tertiary subarea, so that

a) in at least one portion of the tertiary subarea, the final shape of the microtext or micrographics is modified into a form that is characteristic for the mesh comprising graphical elements in the above mentioned subarea of the primary planar area, and/or b) in at least one portion of the tertiary subarea, the microtext or micrographics is modified before or after the transformation of its orthogonal grid into a mesh comprising graphical elements, said modification enabling a distortion of said microtext or micrographics to be compensated.

Advantageously, the tertiary subarea is obtained by creating combination of a microelement, such as a graphical micro element or a microtext, and a coded phase structure, such as a computer generated hologram, said combination enabling the cyclic freedom of a multiple wavelength to be used for distinguish the positive portion of the micro element from the negative ones when performing a calculation of said coded phase structure.

According to a particularly advantageous embodiment, the step A) comprises the preparation of at least two meshes for the three-dimensional phyllotactic model, followed by performing the steps B) to D) for at least one of said meshes and performing at least the step B) for the other of said meshes, the primary planar areas obtained in the step B) being arranged close to each other or with a mutual spacing.

According to another particularly advantageous embodiment, the step A) comprises the preparation of at least two meshes for the three-dimensional phyllotactic model, followed by performing the steps B) to D) for at least one of said meshes and performing at least the step B) for the other of said meshes, the primary planar areas obtained in the step B) being arranged with a partial mutual overlap, the individual portions of said overlap forming a quaternary subarea. Advantageously, the midpoints of the pair of the meshes of the three- dimensional phyllotactic model can be coincident.

The optically variable image device according to the present invention is based on the use of a homogeneous mesh of a phyllotactic model for creating an optically variable image within a defined area, said area further comprising several subareas, each of said subareas being implemented in a different manner which, nevertheless, enables the homogeneity of the initial arrangement of the phyllotactic model to be maintained.

The invention is described by means of three mutually related objects: a geometric or graphic template, a planar optical structure and an image that is recognizable for the observer. An array of such objects is referred to as an entity, such as a primary graphic template, a primary structure, a primary image etc. Simultaneously, a hierarchical arrangement of the elements, namely on a macro level, micro level and nano level, is used for descriptive purposes.

The initial arrangement is based on an ordered group oK of initial cores, said cores being orderly arranged along the basic spiral of the phyllotactic model, the origin of said spiral being referred to as the pole of the phyllotactic model. A three-dimensional phyllotactic model assigns a unique triplet of coordinates to each k-th, e.g. with the use of a Cartesian coordinate system {oxk oyk ozk}. Similarly, coordinate triplets based on other usual systems can be considered, e.g., on a cylindrical coordinate system (triplet {on othetak ozk}) or on a spherical coordinate system (triplets {ork othetak oflk})- Besides the coordinates derived from the phyllotactic model, each core has an initial set of attributes {oAk} assigned thereto and derived from a core model, such as attributes defining the shape and form of the respective core and the optical properties, e.g. translucency, of the same. The initial set of these attributes can be identical for the whole group oK of the initial cores or suitably parametrized in dependence on the order k of the given core. The core array of this model fills in a certain spatial area oVov a generally curved planar area oS in a quasi-homogeneous manner.

The arrangement of the cores of a simple phyllotactic model according to the equation (1) is characterized in that two nearest neighbouring cores exist for most of the cores of said phyllotactic model within the planar surrounding of the latter, the locations of the respective three cores forming vertices of a scalene triangle. The shape of said triangles undergoes a modification in the direction from the pole of the model towards the margin of the same (wherein the modification rate is higher in the vicinity of the pole and becomes significantly lower towards the margin), said modification taking place cyclically from one special triangle (isosceles triangle A) towards another special triangle (isosceles right-angled triangle B) and then back from the triangle B towards the triangle A. The lengths of the sides of the special triangles will be designated in the following manner: DELTAi (base side of the triangle A), DELTA ₂ (legs of the triangle A), DELTA 3 (legs of the triangle B), DELTA ₄ (hypotenuse of the triangle B). When related to the scale of the phyllotactic model c - and with the use of the invariable fm = ( FI + 1 / FI ) / 2, the above lengths can be expressed by means of the equations (2a) to (2d). The lengths of the sides of all remaining triangles (triangles C) lying between said extreme cases are expressed by the inequalities (2e) to (2g), the shortest length being DELTA _tr .c,i, the medium length being DELTAt,-.c,2 and the longest length being DELTAir.c,3. The numerical values of the above distances are as follows: DELTAi = 1.6763c; DELTA2 = 2.0530c; DELTA3 = 1.7725c; DELTA4 = 2.5066c. Thus, the distances between two planarly adjacent cores lie in the interval (1.6763c; 2.5066c).

DELTAi = sqrt ( pi 1 fm ) . c (2a)

DELTA 2 = sqrt ( ( 3 . pi ) / ( 2 . fm ) ) . c (2b)

DELTA 3 = sqrt ( pi ) . c (2c)

DELTA ₄ = sqrt ( 2 . pi ) . c (2d)

DELTAi < DELTAtr.c.i < DELTA3 (2e)

DELTA2 < DELTAtr.c < DELTA ₃ (2f)

DELTA 2 < DELTA _t r.c,3 < DELTA 4 (2g)

The altitudes of said triangles represent the periodicity of the mesh comprising the cores in the vicinity of the respective triangle and thereby also the local distance between the neighbouring derived spirals based on a selected oversampling rate of the order of the cores along the basic spiral. Said periodicity is significant with regard to the construction of the optical device because it constitutes the base for determining the deflection rate of the light beam impinging on a periodical structure (according to a grid equation). When a phyllotactic arrangement of the cores is concerned, the altitudes of the special triangles (LAMBDA], LAMBDA2, LAMBDAs, LAMBDA4), as corresponding to the sides (DELTAi, DELTA2, DELTA3, DELTAi) of the same, are given by the equations (3a) to (3d). The numerical values of the above periods are as follows: LAMBDA 1 = 1.8741c; LAMBDA 2 = 1.5303c;

LAMBDA3 = 1.7725c; LAMBDA4 = 1.2533c. The local maximum values of the periodicity of the phyllotactic mesh lie within the interval (1.7725c; 1.8741c).

LAMBDA, = sqrt ( pi . fm ) . c

LAMBDA2 = sqrt ( 2 . pi . fm / 3 ) .

LAMBDAs = sqrt ( pi ) . c

LAMBDA4 = sqrt ( pi / 2 ) . c

As far as the construction of the mesh is concerned, it is also important to know which of the cores lying on the basic spiral has the shortest distances to the neighbouring cores arranged along the given derived spiral. This order of the respective core can be expressed by means of the following relation (wherein Ff is the f-th member of a Fibbonacci sequence, said member constituting the basis for oversampling the basic spiral into a derived spiral). k _f = ( fm / ( 2 .pi ) ) . (4) Similarly to the above analysis of the spacing between the cores and the periodicity of the mesh, it is possible to perform an analysis of the azimuthal rotation of a local portion of that mesh with respect to a selected coordinate system. In this connection, it is useful to base the analysis on the angle included by the individual sides of triangles concerned, on the one hand, and the ray interconnecting the pole of the model with the core concerned, on the other hand. Said angle gradually increases along the derived spiral; the value of this angle is close to zero in the vicinity of the pole of the respective model; when the distance between the neighbouring cores corresponds the value DELTA 1 along the derived spiral, the value of the angle is 45 ° and -45 °, respectively (according to the rotational direction of the derived spiral) and gradually approaches the limit value, i.e. 90 ⁰ and -90 °, respectively.

The local variability of the arrangement of the cores within a phyllotactic model becomes more apparent when comparing the latter mesh with a fixed regular mesh formed by equilateral triangles wherein the distances between the respective planarly adjacent elements are constant, the same applying to the periodicity and the local rotational position of such a mesh. For such a mesh having a filling density, which is identical to that of the mesh of the phyllotactic model, the following relations for the space DELTAe between the elements and for the periodicity LAMBDAe can be derived, the numerical values of the related parameters being 1.9046c and 1.6495c, respectively.

DELTAe = sqrt ( 2 . pi / sqrt ( 3 ) ) . c (5a) LAMBDA ₆ = sqrt { (≠ 1 2 ) . sqrt ( 3 ) ) . c (5b) A local variability of the arrangement of the cores within the phyllotactic model is one of the characteristic features of said model. The knowledge of the parameters of the mesh comprising cores, particularly the knowledge of a suitably selected set of said periodicities and azimuths depending on the order of the core concerned in the respective sequence of cores, is important not only for the construction of the mesh but also for the analysis of the properties of the characteristic pattern when a particular arrangement of the mesh is selected. The above mentioned mutual dependencies can be advantageously utilized when simulating the behaviour of the optical phyllotactic image device, namely not only for configuring the basic illumination and observation but also, for example, for analysing the influence of the dimensions of the light source used on the shape of the characteristic pattern, for analysing possible modifications of the characteristic pattern with respect to the colour and motion parameters thereof. The shape of the basic spiral is in relation to the trajectory of an electron in a magnetic field. Thus, this type of spiral is also called cyclotron spiral. The shape of the individual segments of the framework inside the characteristic pattern can be likened to the trajectory of a ball lying in a scoop having a cross-sectional shape corresponding to that of the derived spiral, said trajectory being obtained during the rotation of said scoop around its attachment point, i.e. around the pole of the respective phyllotactic model.

An important property of the phyllotactic arrangement of the cores according to the equation (1) consists in that the area defined for each single core has a constant size. The size of such, let' say, elementary area, ao, can be derived using four different methods. The first method is based on the planar circular surroundings of each core and works with the scale parameter c— see equation (6a). According to the second method, the size of the elementary area is derived both from the space between the core concerned and the pole of the model R and from the width of the annulus DELTA R assigned to said core (this annulus can be represented by an orbit where just a single core can be located) - see the equation 6(b). The third method is derived from the size of the area of a circle sector containing a single core, the variable DELTA Jheta included in the equation (6c) representing both the angular value of said circle sector and the mean angular distance between each two most adjacent radius vectors of the cores (i.e. between the rays interconnecting the pole of the model and the respective core). Assuming a model where the number of the cores is kmax, the relation DELTAjheta = 2 . pi / k _max will apply. Finally, the fourth method defines the size of the elementary area to be equal to the twofold area of a triangle, the vertices of the latter being formed by the core concerned and by its nearest planar neighbours. In general, the size of the elementary area can be also derived from other triangles having one of their vertices within the core concerned and the other two vertices within the nearest cores arranged along the respective derived spirals. The equation (6d) relates to a specific kind of calculation, namely deriving of the size of an elementary area from the shortest side of the contemplated triangle dmin and from the corresponding longest altitude LAMBDAmax of the same. By means of the above expression methods and by means of various combinations of the same, it is possible to significantly facilitate the preparation of a core model as well as the construction and analysis of the objects within a mesh comprising the cores of the respective phyllotactic model.

ao = pi . c ² (6a) ao = 2 . pi . R . DELTA _R (6b) ao = ( R / 2 ) . DELTAjheta (6c) ao = dmin . LAMBDAmax (6d)

The filling density of the area containing cores, i.e. the number of cores per unit area, is directly defined by the phyllotactic model, particularly by the scale parameter c of the phyllotactic model concerned. The filling factor FF, i.e. the relation between the sum of the sizes of the cores within the concerned area and total size of this area depends on the respective core model and hence with the sizes and shapes of the cores. While a (simplified) biological model is based on the assumption that the cores fill in the entire area concerned, i.e. that the relation FF = 100 % applies to such model, a reduced filling factor will be more appropriate for the purpose of the implementation of the optical device according to the present invention. According to an advantageous embodiment, the value of such reduced filling factor will be 50 %. The relations (7a) and (7b) defining the filling factor FF _C for circular cores (with the radius ro _c ) and the filling factor FF _S for square cores (with a constant rotational positions with respect to the coordinate system and with the edge ro _s ) can be derived from the ratio between the surface area of a core having the given shape and the equivalent surface area of the same core as obtained with the use of the above equations. For other shapes of the cores, such as a general polygon or an ellipse, the procedure can be similar. The maximum sizes of the cores (under the assumption that the condition of non- overlapping cores is fulfilled) ro _c ,max and ro _s ,max are given by the equations (7b) and (7e), respectively, the highest possible filling factor for these maximum sizes of the cores being FFcmax and FF _s , _max - see the equations (7c) and (7f), respectively. The minimum space between the cores, namely the space DELTAi as used in the above equations, corresponds to the distance DELTAi according to the equation (2a). The corresponding substitution results in obtaining the value of 70.21 % for the maximum filling factor related to circular cores and merely 44.72 % for the maximum filling factor related to square cores. This means that circular cores make it possible to achieve an acceptable extent of flexibility with respect to a variable filling factor. In this regard, square-shaped cores having a constant rotational position with respect to the coordinate system are less advantageous. Nevertheless, a core model, which takes account of the location of the square-shaped core as well as the rotational positions of the individual cores derived from such a rotation, makes it possible to increase the threshold value of the filling factor to an acceptable level.

FFc = roc ² 1 c ² (7a) ro _c ,ma _X = DELTAi / 2 (7b)

FFcmax = ( DELTAi / ( 2 . c ) ) ² (7c)

FFs = ro? / ( pi . c ² ) (7d) ro _s , _llia , = DELTAi / sqrt ( 2 ) (7e)

FFs, _m ax = ( DELTAi I c† I ( 2 . pi ) (7f) Example of a three-dimensional phyllotactic model, wherein the cores are arranged around the surface of the lateral area of a rotational cone - see the equations (8a) to (8e), and a core model wherein each core is defined by three attributes: the shape of the core is a cylindrical cavity, the radius of the cylinder being rok and the depth of the cylinder being hk and the default values of the attributes rok and hk being assigned by means of the equations (8f) and (8g); the constant radius of the cylinder is based on the scale parameter c of the phyllotactic model and from the corresponding planar filling factor FF (e.g., for FF= 0.5, one half of the surface area of the planar optical structure arranged in the surroundings of the core concerned will contain the cavities related to said core and to the neighbouring cores thereof, while the other half of that area will be formed by the even surface of the planar optical structure); the depth ho of the cylinder is constant.

n = c . k ^Vq (8a) thetcik = k . thetao (8b)

Zk = -t'k (8c)

Xk = n■ cos thetcik (8d) yk = rk . sin thetcik (8e) rok = c . FF (8f)

hk = ho (8g)

In order to obtain a homogeneous filling factor, i.e. a constant density of the cores in the entire area, the member q = 2 should be selected in the equation (8a). This will correspond to the equation (la) and, simultaneously, to the case when the scale parameter c has a constant value in the entire area. When a different value of the parameter q is selected, a different variable level of filling density in the direction from the pole towards the margin of the model can be obtained; when q < 2, the basic spiral unfolds faster and the area filled with cores becomes sparser in the direction from its midpoint towards its margin; contrarily, when q > 2, the basic spiral unfolds more slowly and the area filled with cores becomes denser in the direction from its midpoint towards its margin. In such cases, the effective value of the parameter c is variable which must be taken into consideration when calculating and constructing the initial meshes comprising cores. Even though the above method of changing the filling density is quite simple, it does not provide any sufficient extent of flexibility when a specific pattern of the filling density in the direction from the pole of the model to the margin of the same is required. In such cases, it is more useful to consider a weighted sum of at least two members having different exponents in the above equation. Nevertheless, the effective value of the scale parameter c will remain variable and hence it is necessary to resolve the local variations of said value in the area considered before proceeding with the subsequent calculations.

The above mentioned initial arrangement of the cores can be transformed by meant of a defined mathematical prescription. The aim of this primary transformation may be

(1) to modify the initial sets of the attribute values {oAk} of the cores in a defined manner without affecting the coordinates of the same (e.g. {oxk oyk ozk}) and, hence, without affecting the filled area (OV OY oS); and/or

(2) to change the coordinates (e.g. {oxk o k ø¾}) of the cores in order to locally modify the (quasi) homogeneity of the initial arrangement without excluding a possible modification of the initial attribute values {oAk} but without affecting the filled area (oVor. oS); and/or

(3) to change the coordinates (e.g. {oxk oyk of the core in a manner causing a desired modification of the initial filled spatial area oV r a modification of the initial curved area oS to occur along with a necessary corresponding modification of the (quasi) homogeneity of the initial arrangement and with a possible modification of the initial sets of the attribute values {oAk} .

The initial spatial arrangement of the cores or a transformed spatial arrangement of the cores is projected into a generally selected primary plane of the graphic template where a group of graphical elements iK corresponding to the group of the initial cores oK will fill up the primary planar area iP. It is useful, but not necessary, to select a primary plane that is situated in a close vicinity to the initial plane ox-oy and or-otheta, respectively; however, the selected primary plane should not be identical to the latter one. In this primary area iP, each graphical element has a unique permanent basic order k, a derived pair of coordinates {ixk ly ] and a set of attributes {iAk}, the values of the latter being generally unequal. From a local point of view, a certain subgroup of planarly adjacent elements can be considered to be a local graphical mesh. The above mentioned process of transforming the initial cores and projecting the same into primary graphical elements can be described as follows.

iK≡oK (9a)

{oxk oyk ozkoA ] -> {ixk iyk i k} V k e (9b)

oV and oS - iP, respectively (9c)

The latter graphical planar arrangement of graphical elements is further implemented on the basis of a primary planar optical structure comprising a plurality of individual optical primitives, each single optical primitive being implemented in a location defined by the coordinates of the corresponding graphical element and in a manner based on the attributes of said graphical element.

When illuminated and observed in a usual manner, the above mentioned planar optical structure forms a primary optical image on the observer's retina, said image corresponding to a modified characteristic pattern obtained by means of the of the selected phyllotactic model and the selected core model. A characteristic feature of such primary image is posed by planar segments having a gradually changing level of colourfulness or intensity. One of the interesting properties of an optical structure derived from a simple model according to the equation (1) consists in the rotational invariance of the primary image; this means that the perception of the characteristic pattern remains unchanged when the respective optical structure is being rotated around a perpendicular intersecting the midpoint of the structure (i.e. the pole of the phyllotactic model) under given conditions of illumination and observation. In an advantageous embodiment, the rotational invariance of the image generated by the device according to the invention is based on a suitable selection of the way how the respective initial phyllotactic model is transformed and projected. Another property of the characteristic pattern consists in the rotational symmetry of the image under a 180 degrees rotation. Another significant property of the characteristic pattern consists in the partial self-similarity thereof; this means that the individual segments of the characteristic pattern have a similar shape and that size of said segments becomes smaller towards the midpoint of the pattern, the size of each subsequent segment being 2.6180 smaller than that of the preceding segment.

Furthermore, the above mentioned rotational symmetry means that the segments lying, for example, in the quadrants I and III have the same size after having been mutually rotated by 180 degrees. Then, the segments lying in the quadrants II and IV are similar to each other and their sizes are 1.6180 times greater or smaller when compared to the segments lying in the in the quadrants I and III, respectively. When the illumination of the optical structure is relatively sharp, each observer's eye receives light beams originating in a slightly different portion of the optical structure; this enables a stereoscopic image and a spatial impression of the perceived characteristic pattern to be obtained. When the optical structure is laterally tilted, the observer perceives a change to the rotational position of the characteristic pattern. When the optical structure is slightly and gradually tilted towards / away from the observer, the latter will perceive a characteristic pattern that is subject to morphing, i.e. a characteristic pattern comprising segments undergoing a gradual change in size and colourfulness. When the optical structure is tilted in an abrupt and distinct manner, a changeover between two different characteristic patterns is perceived. When the optical structure is illuminated by a monochromatic spot light source, the segments of the characteristic pattern are formed by thin short curves. When the optical structure is illuminated by a white spot light source, the aforesaid curves become longer, the marginal portions of each curve containing a colour corresponding to a shorter wavelength and the middle portion containing colours

corresponding to longer wavelengths. When being illuminated by a wide white light source, the segments of the characteristic pattern are extending perpendicularly to the respective curve.

A modification of the primary entities results in the formation of corresponding secondary entities. At least three different types of secondary subareas can be created inside the primary area iK: the first secondary subarea 2AK, the second secondary subarea 2BK and the third secondary subarea 2cK. Removing the secondary subareas from the primary area causes the primary subarea wK to emerge.

2BK ^ ,K (10b)

2CK C: IK (10c)

1NK = JK \ ( 2AK 2BK 2CK ) (lOd)

The first type of a secondary subarea (hereinafter referred to as the first secondary subarea) within the primary area is characterized by a changed density of the primary mesh comprising planarly adjacent graphical elements in this selected subarea. In this connection, the density can be changed in a rational (mathematical) manner. Thus, the modified first secondary mesh can be either denser or sparser than the primary one. A denser first secondary mesh means that such a mesh is formed by adding new graphical elements to the respective primary mesh; in this case, the original graphical elements of the primary mesh will be either entirely or partly retained. Contrarily, a sparser first secondary mesh means that only a certain number of the original graphical elements will be retained and, as the case may be, some new first secondary graphical elements will be added thereto. Within the framework of the first secondary transformation of the initial first secondary subarea 2AK, the elements k' will be retained and the elements k" will be removed; furthermore, the elements A:'" will be added. Thus, the resulting first secondary subarea will contain the elements k' and k'". The newly formed elements k'" will be linked to the retained initial ones k' and will have their coordinates {2 AW 2Ayk'"} and their attributes {2ΑΑ^"} derived from those of the retained initial elements {2AXk' 2Ayv 2AA } . 2AK→ 2A'K (11a) k k" e 2AK (l ib) k k'" e 2A'K (11c)

(l id)

{2AXk' 2Ayv AAW)≡ {lXk l)>k iAk} V k'

(l ie) {2AXk"' 2Ayk"' 2AAk"'} = fee ( { AXk' 2AyV 2AAk'} ) V k ¹

The mode of implementation of the first secondary optical structure is similar to that of the primary optical structure.

The character of the first secondary image is largely dependent on the size of at least one first secondary subarea and, simultaneously, on the rate of change in the density of the first secondary mesh. In an advantageous embodiment, a local change in colourfulness or reduction of the brightness of the primary image occurs in the first secondary subarea and the first secondary image is observable at the same azimuthal angle but with a different angular deviation from the direction of the reflection of the impinging light when compared to the primary image.

The second type of the secondary subarea (hereinafter second secondary subarea) within the primary subarea is characterized in that the coordinates of the respective graphical elements are modified. The number of graphical elements remains unchanged and the same applies to all the attribute values of these graphical elements. The location-based modification of each graphical element consists in relocating the respective element into a node of the second secondary web, the latter web being generally irregular and non-orthogonal and locally several times finer (denser) when compared to the original mesh of graphical elements in the vicinity of the respective primary graphical element. This causes a local disruption of the homogeneity of the primary mesh to occur, such disruption resulting in the formation of subharmonic components in the image of the spatial frequencies of the original primary mesh. The inherent properties of the web (irregularity and non-orthogonality) enable the kind and the extent of said local disruption of the homogeneity of the primary mesh to be defined.

{ixk lyk)→ {2BXk 2Byk) V k e 2BK (12a)

The mode of implementation of the second secondary optical structure is similar to that of the primary optical structure.

Although the character of the second secondary image depends on the local values of the parameters of the secondary web as related to the local values of the parameters of the respective primary mesh, the second secondary subarea is typically filled with a visible mosaic consisting of small scintillant and, in a considerable extent, achromatic points which are preferably observable when the angular deviation from the direction of the reflection of the impinging light is smaller than the corresponding distance obtained in the primary image. Simultaneously, a decrease in the intensity of the primary image occurs in the second secondary subarea.

The third type of the secondary subarea (hereinafter third secondary subarea) within the primary subarea is characterized in that the attribute values of the respective primary graphical elements are modified. According to an advantageous embodiment, the attribute values of the third secondary elements can be independently changed for each single primary element. In another advantageous embodiment, the attribute values of the individual graphical elements can be changed in relation to the attribute values of a defined conglomeration of the adjacent graphical elements, i.e. to the subset of those graphic elements which are arranged in the vicinity of the graphical element concerned. In addition to the previously mentioned attributes (relating to the shape and dimension of the given graphical element), the set of attributes can also include further attributes, namely both geometrical and physical ones, such as orientation, translucency or lustrelessness.

{lAk}→ {2cA _k } V k e 2cK (13a) {icxk 2cyk]≡ {ixk iyk) V i e 2cK (13b) The mode of implementation of the third secondary optical structure is similar to that of the primary optical structure.

According to an advantageous embodiment, the brightness of the primary image is locally decreased in the third local subarea, a third secondary image being typically observable at viewing angles which are very distant from the direction of the reflection of the impinging light. In another suitable arrangement, the implementation of the third secondary subarea may cause the translucency of said subarea to be different from that of the remaining subareas; for example, the entire primary area may be reflective and the third secondary subarea may be translucent.

Furthermore, a method of preparing an optical phyllotactic image device is presented. This method is characterized in that a phyllotactic mesh comprising graphical elements and derived from a single discrete variable k is used for preparing the optical image device.

This mesh comprising graphical elements is constructed on the basis of a phyllotactic model defining the locations of the cores and a core model defining the attributes of the cores, then the array consisting of said cores optionally undergoes a primary transformation followed by projecting the cores into a selected plane, whereby a planar primary area of a graphic template is obtained, said primary area being filled with an ordered series of graphical elements. Each of said elements has one basic order assigned thereto and defined by the respective phyllotactic model, two derived coordinates lying in the plane of the graphic template and a set of modifiable attributes, the initial values of the latter being also defined by the respective phyllotactic model. The method is further characterized in that at least one secondary subarea is defined within said primary area with the use of a graphic pattern, said secondary subarea being one of the types described below. The first of them (namely the first secondary subarea) is specific in that the density of the mesh comprising graphical elements undergoes a change within this subarea. The second secondary subarea is characterized by projecting the coordinates of the graphical elements into a generally non-orthogonal and irregular web. In the third secondary subarea, the above mentioned attributes of the graphical elements are modified in a suitably selected manner.

The above graphical patterns can have diverse characters, the number of alternatives and variants being noticeably higher when compared to a graphical pattern according to the usual concept. For example, such alternatives may include grid or vector graphics, mathematical or textual descriptions, freehand drawings etc. As far as the colour depth is concerned, a monochromatic pattern, a grayscale pattern or a reduced / full colour pattern can be used. Other possible variants include line graphics, planar graphics or relief graphics, an additional attribute being represented by the requirement for the imitation of various materials having characteristic optical properties or a specific surface finish. With regard to the variability of the image obtained by means of the optical image device, the partial graphic patterns representing images of animated sequences or, as the case may be, different images obtained under diversely defined illumination a/or observational conditions can be organized into coherent sets comprising said partial graphic patterns. The graphic patterns can be employed not only for preparing the secondary areas and the properties of the graphical elements contained therein but also for performing a primary transformation of an array of cores and for creating other types of areas, especially tertiary, quaternary and quinary ones. According to a further advantageous embodiment, it is possible to create graphic patterns for an optically variable image device in a manner that enables the device at least partly conforms to the patterns needed for subsequent large-scale operation, such as a controlled

demetallization, punching or application of a foil prepared from an initial template of an optical structure. The latter method is further characterized in that said mesh is transformed into micro- optical and/or nano optical primitives (or into groups of such primitives) forming a planar optical structure. Such transformation should be performed in a way that will enable said optical primitives to invoke (under usual condition of illumination and observation) a perception of at least two different image types: a primary image corresponding to the characteristic pattern based on the combination of the phyllotactic and core models as well as to at least one further pattern corresponding to the respective graphic pattern. When implementing the optical primitives, it is useful to change the initial sequence of the graphic elements corresponding to that of the cores within the respective phyllotactic model in a manner that will enable to gradually implement the optical primitives in mutually adjacent planes. While it may be useful to utilize the initial spiral in the close vicinity of the pole of the model, it will be more efficient to use a different sequence in the prevailing portion of the optical structure; according to an advantageous embodiment, implementation sequences extending along spirals, which have been derived from the basic spiral with the use of different oversampling rates selected in accordance with the location of the portion concerned, can be utilized. In the course of the graphic processing procedure as well as during the implementation itself, it is useful to provide a multilevel hierarchy of data structures, suitable approaches related to data compression / decompression and, when possible, parallel processing methods since otherwise the entire non-structured description of the optical structure could reach a prohibitive size and the duration of processing and implementation could become unacceptably long.

The method is further characterized in that the conversion of a graphical mesh into an optical structure is carried out using a relief or micro-relief technique, for example one of the following lithographic techniques and technologies or combinations thereof: a mechanical, physically chemical, chemical, ion, electron, optical, thermal, UV technique etc.

According to an advantageous embodiment, the present method is further extended by adding a method of providing tertiary subareas containing striking features / objects of various types, such as a microtext, micro graphics, nano graphics, coded structure, computer generated hologram based on the Fresnel or Fourier principle or the like. According to a particularly advantageous embodiment, the shape of the template used for such objects is modified into a mesh comprising derived spirals of the phyllotactic model.

According to another advantageous embodiment, the present method of preparing an optically variable image device is extended by adding a quaternary subarea formed by at least two different primary areas which at least partly overlap each other. According to a particularly advantageous embodiment, said mutually overlapping primary areas have a coincident pole, namely the location of the midpoint of the phyllotactic model. In a further advantageous embodiment, the mutually overlapping areas have a significantly different filling density given by the respective phyllotactic model and/or a significantly different filling factor given by the respective core model.

In another advantageous embodiment, the optical planar structure is extended by adding an area or areas constructed using a method that is not based on the use of phyllotactic and core models. This is particularly advantageous in either case: firstly, when it is desirable to emphasize the characteristic properties of the structure according to the phyllotactic arrangement in contrast to other types of structures and, secondly, when it is desirable to integrate an additional structure into the optical device, which integration would be unreasonably difficult or even impossible if a structure according the phyllotactic arrangement were concerned. In a further advantageous embodiment, the present method is extended by forming a quinary subarea which is characterized in that the microstructure of at least one portion of at least one primary area of at least partially mutually overlaps with a

microstructure of a different type within it.

Brief Description of the Drawings

Figure 1 shows prior art, namely the locations of the cores within a simple two-dimensional phyllotactic model as well as a basic spiral for a model comprising 30 cores (a) along with a basic spiral and derived spirals for a model comprising 400 cores (b).

Figure 2 shows prior art, namely a simple two-dimensional left-handed phyllotactic model comprising 10,000 cores (a) and a pattern that is recognizable when observing said model at a very wide viewing angle (b).

Figure 3 shows prior art, namely the mutual positional relationship of a light source, an optically variable image device and an observer; basic directions of propagation of the reflected and passing light within the device (a) and detailed directions of the propagation of the reflected light within the device (b).

Figure 4 shows a three-dimensional phyllotactic model (a), a primary transformation (b) of the same and a projection of such a model into a selected plane (c).

Figure 5 shows the execution of a local change in the density of the mesh by oversampling the latter at the ratio of 3:2 along the first selected series of spirals and at the ratio of 2:3 along the second selected series of spirals, the respective references used being as follows: initial state (a), auxiliary mesh (b), oversampled auxiliary mesh (c), final state (d). Figure 6 shows a local projection of the locations of the graphical elements into a second secondary web (a) and a detailed view of the respective embodiment (b).

Figure 7 shows a local modification of the attributes of the graphical elements (a) and a detailed view of the respective embodiment (b).

Figure 8 shows a mesh based on a microelement (a) along with a mesh based on a coded image, namely on a computer generated hologram (b).

Figure 9 shows, in a schematical view, the transformation of the initial arrangement into a planar optical structure; phyllotactic and core models (a), the initial state of a graphic template (b), the final state of the same graphic template (c), a planar optical structure (d), an image of a characteristic pattern (e) and an image corresponding to a graphic pattern (f).

Figure 10 shows an optical device providing the protection of documents.

Figure 11 shows an optical device used for decorative purposes.

Figure 12 shows, in the respective views, a simple two-dimensional phyllotactic model; a simple left-handed model (a), a combination of left-handed and right-handed models and two mutually overlapping primary areas representing a quaternary area (b).

Figure 13 shows a set of small fine phyllotactic models nested into one large coarse model, each core of the coarse phyllotactic model being filled with groups of elements ordered in accordance with the respective fine model. Exemplary Embodiments of the Invention

The method of converting an initial phyllotactic model into a primary mesh comprising graphical elements according to the present invention can be described with reference to Figure 4. This method consists of two steps. An axonometric view of an initial three-dimensional phyllotactic model 401 according to the system of equations (8) is shown in Figure 4 (a). According to an advantageous embodiment, an initial basic spiral 412 - similar to the basic spiral 160 shown in Figure 1 - twine around the surface of the lateral area of a cone. Along said spiral, the locations of the first thirty cores are indicated, the first two cores being marked as 411a and 411b. According to another advantageous embodiment, the spiral can lie on the surface of another geometric body, such as on the lateral area of a cylinder or pyramid, on the surface of a sphere or ellipsoid or the like. According to another advantageous embodiment, the spiral can pass through a spatial area delimited by a selected geometric body. The first step of the conversion of an initial phyllotactic model into a primary mesh comprising graphical elements according to the present invention comprises the

transformation of the order of the cores by means of a defined mathematical prescription.

The aim of this transformation may be:

(1) to modify the initial sets of the attribute values {oAk} of the cores in a defined manner without affecting the coordinates of the same (e.g. {oxk oyk ozk}) and, hence, without affecting the filled area (oVor oS); and/or

(2) to change the coordinates (e.g. {oxk oyk ozk}) of the cores in order to locally modify the (quasi) homogeneity of the initial arrangement without excluding a possible modification of the initial attribute values {oAk} but without affecting the filled area (oVor. oS); and/or

(3) to change the coordinates (e.g. {oxk oyk ozk}) of the core in a manner causing a desired modification of the initial filled spatial area oVor a modification of the initial curved area oS to occur along with a necessary corresponding modification of the (quasi) homogeneity of the initial arrangement and with a possible modification of the initial sets of the attribute values {oAk}.

According to the advantageous embodiment illustrated in Figure 4 (b), wherein the transformed model 402 is shown in an axonometric view, the displacement of the initial coordinates of the cores 411a, 411b distributed along the initial basic spiral 412 into the positions of the cores 421a, 421b distributed along the transformed basic spiral 422 is carried out in a manner which enables the desired modification of the initial area of the curved plane oS into the modified plane o'S to take place and, simultaneously, the corresponding transformation of the initial basic spiral 412 into the transformed basic spiral 422 to be performed. At the same time, the (quasi) homogeneity of the initial arrangement is also changed without affecting the initial set of the attribute values {oAk} . According to another advantageous embodiment, a change to the coordinates (e.g. {oxk oyk ozk}) the (quasi) homogeneity of the initial arrangement without affecting the initial filled area (oVand oS, respectively). According to a further advantageous embodiment, a modification of the initial sets of the attribute values {oAkjof the cores is performed, said attributes being, e.g., the sizes or rotational positions of the respective cores. If the attribute corresponding to the size of a core assumes zero value for the selected subgroup of cores, the area formed by that subgroup becoming a virtually masked. Thereby, the intended reduction of the modified area is achievable.

The second step of the conversion of an initial phyllotactic model into a primary mesh comprising graphical elements according to the present invention comprises the projection of the modified area o'S into a generally selected plane of the graphic template, as shown in Figure 4 (c). The cores of the initial model are converted into graphical elements. For the sake of clarity, the transformed basic spiral 422 has been omitted in the latter picture. While both the number of the initial cores 411a, 411b shown in Figure 4 (a) and the number of transformed cores 421a, 421b shown in Figure 4 (b) is 30, in Figure 4(c) the number of the graphical elements 431a, 431b corresponding to the transformed cores 421a, 421b is increased from 30 to 3,000. When being projected into a selected plane, the model delimits a planar area which has a size corresponding to that of the primary area of the graphic template 403.

The entire phyllotactic image device can be created using a single phyllotactic or several phyllotactic models. When the arrangement consists of more than one model, the areas corresponding to the individual models can be suitably combined, an example of such a combination being an arrangement enabling said areas to occupy adjacent positions within a selected plane into which the individual models are projected. Another possible arrangement enables said areas to partially or entirely overlap each other. Another advantageous arrangement makes it possible to combine various phyllotactic models at different hierarchical levels, as illustrated by the example shown in Figure 13.

This example shows two types of models having a distinctly different level of coarseness, said model being mutually embedded or nested. The illustrated arrangement refers to the coarse left-handed phyllotactic model 1302 having the pole 1300, consisting of 30 cores 1311a, 1311b, 1311c to 1311ad and having the scale parameter c _raw = 130 expressed by the equations (la) and (8a), respectively. The latter cores fill in the area delimited by the area boundary 1304 of a coarse model, each individual core filling in a corresponding subarea (e.g. the thirtieth core 1311ad fills in a subarea delimited by the boundary 1320adof the (thirtieth) core). Moreover, this figure shows 30 finer phyllotactic models of a similar type, the positions of the individual cores of the respective coarse model defining the poles (or midpoints) of the individual finer models; each finer model of this type contains 160 cores having the scale parameter cf _me = 8.

The aforementioned arrangement can be comprehended in two different ways.

According to one standpoint, the coarse model can be considered to be the basic phyllotactic model of the device concerned, each of the thirty groups of optical primitives, which belong to such model being formed by 160 primitives arranged within a fine phyllotactic model. According to the other standpoint, the fine model can be considered to be the basic

phyllotactic model of the device concerned, said model being combined with another 29 models of the same type, the resulting 30 models forming one coarser phyllotactic model. Similarly, an arrangement with more than two hierarchic nesting levels can be considered.

From a more general point of view, it is not necessary to use the phyllotactic model at all hierarchical levels; some levels or, as the case may be, portions thereof can be formed by simplified mathematical models, such as by those based on an orthogonal grid, a

mathematically defined curve / plane or a freehand graphical sketch.

In connection with the hierarchical arrangement of the entire optical phyllotactic image device it may be advantageous to use the hierarchical positioning mode for the implementation system wherein some hierarchies of the phyllotactic device being constructed may be partly or entirely related to the overall hierarchy of the implementation (exposure) system.

The first secondary subarea is characterized in that the construction of the first secondary mesh in the selected subarea is followed by the change in the density of the primary mesh comprising planarly adjacent graphical elements. Figure 5 (a) shows the primary area 501 of the graphic template (or a cut-out therefrom, to be more exact) where one graphical element 510x (or a selected reference graphical element, to be more exact) is marked, the location of this element being the initial one for the construction of the first secondary subarea. Figure 5 (b) shows the same cut-out from the primary area 501, said area encompassing the secondary subarea 502 comprising 13 x 13 = 169 planarly neighbouring graphical elements, one of said graphical elements being referenced as 510x. The primary subarea 503 is formed by the remaining portion of the primary area 501 that does not fall into the secondary subarea 502; for the sake of clarity, only a cut-out from the former subarea is shown.

In addition, two sets of thirteen auxiliary lines are arranged in the secondary subarea 502, namely one suitable set of derived spirals 521a, 521b to 521m and another suitable set of derived spirals 531a, 531b to 531m, the individual auxiliary lines intersecting the positions of the graphical elements within the selected secondary subarea and representing partial projection of suitably selected derived spirals belonging to the initial phyllotactic model, said suitably selected derived spirals being obtained from the basic spiral of the three-dimensional phyllotactic model, e.g., by oversampling the latter with the use of two consecutive members of a Fibbonacci sequence. The auxiliary lines only present an imaginary clarifying concept and they do not present real elements used for implementing the device.

Afterwards, an intended interpolation or oversampling of the auxiliary mesh is performed in the next step, as shown in Figure 5 (c). The oversampling process takes place in at least one direction, namely along auxiliary lines and by means of at least one coefficient, the latter being a rational number, i.e. a number that can be expressed as the fraction having both an integer numerator and an integer denominator. In this particular example, the density of the mesh is increased in the ratio of 3 : 2 in one direction, which means that one suitably selected set of 13 spirals (521a, 521b to 521m) lying in the primary area is converted into a suitable set of 19 derived spirals (541a, 541b to 541s) lying in the secondary subarea.

Simultaneously, the density of the mesh is decreased in the ratio of 2 : 3 in another direction, which means that another suitably selected set of 13 spirals (531a, 531b to 531m) lying in the primary area is converted into another suitable set of 9 derived spirals (551a, 551b to 551i) lying in the secondary subarea. The intersections of the derived spirals lying in the secondary subarea define the new positions of the graphical elements in the respective selected subarea, some graphical elements - including one graphical element 510x - remaining in the respective original positions, some other graphical elements being removed and some new graphical elements being added, the newly added graphical elements remaining linked to at least one graphical element retained in the initial arrangement. Thereby, the initial linear sequence is maintained, either in a reduced form or in a branched form.

The final form of the highlighted secondary subarea 502 is shown in Figure 5 (d). Now, this subarea comprises 9 19 = 171 graphical elements in total, compared to the original number of 169. According to the latter example, the first secondary subarea is identical to the corresponding subarea of the mesh constructed. According to a different arrangement, the first secondary subarea can form a subset within the corresponding subarea of the mesh constructed.

The above simplified clarifying example is based on an oversampled mesh where the change in the density of the mesh has been achieved independently in both auxiliary directions. In another advantageous embodiment, the change in density can be achieved in a more general manner consisting in that the auxiliary derived lines do not need to be quasi parallel to the derived spirals of the primary area.

The construction of a second secondary subarea can be explained with reference to the schematic sketch shown in Figure 6 (a). This figure shows a cut-out of the primary area 601 of the graphic template, said cut-out including a portion of the primary subarea 610 and a portion of the second secondary subarea 620. A detail of the interface 630 between these two subareas is drawn in Figure 6 (b). In the primary subarea 610, the positions of the graphical elements - e.g. 611x and 611y - are implemented in exact accordance with the phyllotactic model; in other words, the positional accuracy of said elements depends on the overall accuracy of the implementation system. This positional accuracy, i.e. the fineness of the primary web, should be by at least more then two orders higher when compared to the average spacing between planarly neighbouring cores, which spacing approximately correspond to the constant c (scale parameter) in the equations (la) and (8a), respectively. On the other hand, the positions of the graphical elements lying in the second secondary subarea - such as the elements 62 lx and 62 ly - are rounded in a manner enabling those positions to fall into the second secondary web 623, said web being intentionally coarser, i.e. by just approximately one order finer, when compared to the average spacing between planarly neighbouring cores. In this exemplary embodiment, the second secondary web 623 is formed by the grid of a polar coordinate system having its origin coincident with the pole of the phyllotactic model. A portion of this second secondary web 623 is indicated in an area of the Figure 6 (b) where several graphical elements have been omitted for the sake of clarity. One of the lines of the second secondary web having a constant radius, namely one line of the web extending along the second coordinate of the second secondary web, is referenced as 625y; one of the lines of the second secondary web having a constant azimuth, namely one line of the web extending along the first coordinate of the second secondary web, is referenced as 624x; the nodes (such as 626xy), i.e. the intersections of said lines, form a group of permitted coordinates of the positions of the graphical elements within the second secondary subarea, the given graphical element lying in said second secondary subarea being displaced from the initial position to the position of the respective nearest node 626xy. Using the above described method causes a distinct disruption of the regularity of the arrangement of graphical elements in the second secondary area.

Figure 7 shows the method of formation of a third secondary subarea. The primary area 710 shown in Figure 7 (a) has the boundary 720 of the primary area and is filled with graphical elements arranged in accordance with the respective phyllotactic model; moreover, two rectangular subareas, one third secondary subarea 740 and another third secondary subarea 750 are marked out within said primary area, in which subareas two different variant of the third secondary subarea will be implemented, the remaining portion of the primary area 710 (such as a circular one) representing the primary subarea 730. A detailed view of the primary area having a circular shape is shown in Figure 7 (b). The graphical elements, such as 731x and 73 ly, arranged in the primary subarea 730 have a square shape, the size and rotational position of the respective squares being constant. The third secondary subarea is characterized in that the attribute values of the graphical elements undergo a change therein, the numbers and position of such elements remaining unchanged. In one third secondary subarea 740, the following changes to the parameters of the graphical elements will be performed: the shape of the graphical elements - e.g. 74 lx a 741y - will be changed from a square to a quasi-rectangle, the orientation and size of the latter varying in dependence on the position of the planarly neighbouring graphical elements;

according to an advantageous embodiment, the longer side of said rectangle is virtually equal to the spacing between the position of the given element and the position of the neighbouring one along the derived spiral, the type of the spirals being the same for the entire secondary subarea 740; in this manner, the individual segments of the spirals are obtained - such as the line (742 ) formed by one series of graphical elements of one third secondary subarea and the line (742y) formed by another series of graphical elements of that third secondary subarea - as shown in Figure 7 (b).

Similarly, in another third secondary subarea 750, the following changes to the parameters of the graphical elements will be performed: the shape of the graphical elements of another third secondary subarea - e.g. 751x a 751y - will be changed from a square to a cross, the orientation the latter as well as the sizes of both portions thereof varying in dependence on the position of the planarly neighbouring graphical elements; according to an advantageous embodiment, the length of the first or second portion of said crosses is virtually equal to the spacing between the position of the given element and the position of the first or second neighbouring one along the derived spiral, the type of the first and second derived spiral being the same for the entire secondary subarea 750; in this manner, the individual segments of the set of spirals are obtained - such as the lines (753x, 753y) formed by one series of graphical elements of one third secondary subarea and intersecting the lines (754x, 754y_) formed by another series of graphical elements of that third secondary subarea - as shown in Figure 7 (b).

When the image device according to the present invention is used for security and authentication purposes, it is useful to supplement the device with specific marks (striking features), such as microtext or nanotext objects, micrographics, special rotationally symmetrical structures, coded structures, moire patterns, Fourier or Fresnel structures or the like. Such marks can be taken over from corresponding graphic templates and implemented by masking a mesh comprising optical primitives in a selected tertiary subarea, said subarea being defined by the respective reference coordinate, by the selected orientation and by the size of the template having a desired resolution. In the basic embodiment, it is possible to mask those optical primitives whose Cartesian coordinates related to a reference position correspond to the Cartesian coordinates of the given pixel within the graphical template of the respective mark. According to another embodiment, some properties of the phyllotactic model can be advantageously utilized.

For example, when a mark corresponding to a microtext object is implemented, it may be useful to project the graphical features of the specific mark into a tertiary area having its position defined by a selected reference core a being delimited by suitable spirals derived from the respective phyllotactic model; thus, the positions of the cores arranged within said subarea correspond to the positions of the pixels within the graphical template of the mark. This causes a slight or even perceptible distortion of the shape of the graphical template to occur, said distortion being characteristic for the selected modifies and projected phyllotactic model. The extent of the distortion is related to several factors, the most important ones being the real size of the specific mark and the distance of the same from the pole of the model. The above example of the implementation of a microtext is schematically shown in Figure 8 (a). The pattern of the mark, namely the pattern of the microtext 811 having the size of

83 x 50 pixels in the present particular example, is implemented in the position 830 of the tertiary subarea which corresponds to the coordinates of the selected graphical element. This implementation will be carried out within the tertiary subarea 823 embedded in the primary area 821 of the graphic template delimited by the auxiliary boundary 835 of the tertiary area, said boundary extending along selected spirals of the respective phyllotactic model. The implementation of variable pixel intensity of a monochromatic pattern can be based on the size of a circular graphical element (as illustrated herein) or a corresponding optical primitive: the white pixels of the pattern correspond to small circles - e.g., one (bright) graphical element 842y - while the black pixels of the template correspond to circles being larger in diameter - e.g., one (dark) graphical element 841x.

In a similar way, micrographics having a greater intensity depth (grayscale) can be implemented. The variable pixel intensity of the template may be obtained in different way, as described in connection with the explanation of the individual types of secondary areas.

According to one of possible advantageous embodiments, the variable pixel intensity of the template is obtained by means of different depths of the corresponding optical primitives. In this way, colourized micrographics can be obtained because various depths of the planarly neighbouring optical primitives belonging to a group make it possible to distinguish different colour tones of the reflected light when using a microscope for observing the respective tertiary subarea.

Another advantageous embodiment is based on the deployment of a more extensive microtext in a larger, visually observable subarea. In this case, it is possible to choose both the positive and the negative variant of the implementation of a microtext object in order enable the given subarea to carry additional graphical information.

In a similar way, other kinds of striking feature can also be achieved. Figure 8 (b) shows a schematical example of an implementation of a coded structure, such as a computer generated hologram, or a Fourier structure, the pattern of the respective coded image 861 having the size of 64 x 50 pixels. The structural pattern is implemented in the tertiary area 873 located inside the primary area 871, namely in the selected position corresponding to the tertiary subarea 880 (i.e., in the position corresponding to the selected reference graphical element). The tertiary subarea 873 is delimited by an auxiliary boundary 885 of the tertiary subarea, said boundary consisting of selected derived spirals. The individual pixels of the template, which represent a change in the phase or amplitude of the impinging light, are implemented by means of optical elements having different amplitude or phase modulation; at the level of the graphic template, the optical elements of a planar optical structure are represented by two graphical elements - one (dark) graphical element 891x and one (bright) graphical element 892y. In the present embodiment, the decoded image will intentionally undergo a slight distortion. According to another embodiment, it is possible to perform a compensation for said distortion, namely at the level of the implemented optical structure or at the level of the calculation of a coded image, a combination of both levels being also possible. According to a further embodiment, it is possible to modify the algorithm used for the calculation of the coded structure in order to enable the input image or decoded image of the calculated Fourier structure to be formed by the graphical cores of the respective phyllotactic model.

A schematical depiction of an exemplary transformation of the initial arrangement of a three-dimensional phyllotactic model 905 and a core model 906 using a graphic pattern 902 into a planar optical structure 950 according to the present invention is shown in the illustrative Figure 9. In accordance with the three-dimensional phyllotactic model 905, the cores 907a, 907b are initially arranged in a row along the initial basic spiral twining around the surface of the lateral area of a cone, the initial spatial coordinates of said cores being 908a, 908b. The initial attribute values 909aa, 909ab, 909ba, 908bb of the cores are defined by the core model 906; in this particular case, cylindrical objects having corresponding parameters are concerned, which means, for example, that the first cylinder has the depth hi and the diameter 2 . roi, the second cylinder has the depth hi and the diameter 2 . roi, and so on. The spatial arrangement of the cores is projected into the plane of the primary graphic template 901, wherein the graphical elements 911a, 911b corresponding to the cores 907a, 907b fill in the primary area 915 of said primary graphic template 901. After having been filled with the i graphical elements 911w, 911x, 911y_, 911z, the circular primary area 915 is subdivided into four complementary subareas by means of the graphic pattern 902. Three of the above four subareas are represented by one secondary subarea 920, another secondary subarea 930 and still another secondary subarea 940, all these subareas being of the third type (third secondary subareas) in the present example. The remaining portion of the primary area is the primary subarea 910. The secondary subareas enable at least one secondary transformation to be performed in order to transform the graphical elements 911 , 911y, 911z into the graphical elements 921 , 931y, 941z lying in the corresponding areas; in this particular example, the attributes of the respective graphical elements are changed, For the sake of simplicity, the fills of the individual subareas have different parameters of the graphical elements in the individual illustrations. It will be readily appreciated by those skilled in the art that other filling methods are possible, such as using a combination of one primary subarea, one first secondary subarea (where the numbers of graphical elements are different before and after the execution of the secondary transformation), one second secondary subarea and one third secondary subarea.

The primary subarea 910 is filled with graphical elements having the form of small circles, a typical example being the graphical element 911w. The depiction of the graphical elements in the secondary subareas is similar. One secondary subarea 920 is filled with cross- shaped elements, a typical example being the graphical element 921x. Another secondary subarea 930 is filled with graphical elements having the form of larger circles, a typical example being the graphical element 931y. Still another secondary subarea 940 is filled with graphical elements having the form of square contours, a typical example being the graphical element 941z.

The conversion of the final graphic template 900 into the planar optical structure 950 will be carried out in that, both within the primary subarea 960 of the planar optical structure (corresponding to the primary subarea 910 of the final graphic template) and within the secondary subareas 970, 980 and 990 of the planar optical structure (corresponding to the secondary subareas 920, 930 a 940 of the final graphic template), each individual graphical element (such as 911w, 921x, 931y and 941z) is implemented in the form of an optical primitive (such as 961w, 971x, 98 ly and 991z) or in the form of a set of optical primitives, the respective array of optical primitives forming a relief microstructure or an alternatively optically modulated microstructure. According to another advantageous embodiment, a suitably arranged set of several optical primitives is provided instead of a single optical primitive corresponding to a graphical element.

The light impinging on the planar optical structure 950 interacts with the latter, thus creating a simultaneous visual perception of at least two different images (based on the same planar optical structure), said perception being created either immediately or following a change to the conditions of observation or illumination. One image 903 corresponds to the characteristic pattern that is based on the combination of the three-dimensional phyllotactic model 905 and the core model 906. At least one another image 904 corresponds to the graphic pattern 902.

The above schematic example illustrates a further advantageous arrangement of the interface between the subareas extending along the derived spirals. Simultaneously, an advantageous possibility of utilizing a multiple quasi symmetrical arrangement of the phyllotactic model is illustrated. Both alternatives described above, namely either using an interface extending along derived spirals or using a quasi-symmetrical arrangement of the model, can be considered to represent advantageous embodiments of the optical phyllotactic image device according to the present invention. Although the utilization of the above mentioned possibilities is not necessary for the implementation of the given device, a certain level of conformity between the fine structure and the visually observable image can be achieved when such methods are at least partially used.

Industrial Applicability

The present invention relating to an optical phyllotactic image device is usable in numerous different applications. Furthermore, four exemplary areas are described without limiting the scope of applicability of the present invention by persons skilled in the art.

The reference to the comparison of Figure 2 (a) with Figures 2 (b) and 12 (a), respectively, makes it possible to demonstrate the difference between a simple two- dimensional left-handed phyllotactic model and an image of a phyllotactic model 1201

obtained in a low resolution. The image of the model is characterized in that the individual cores of the model are formed by thin lines having the same size and the same orientation. This image represents a simplified characteristic pattern of one primary area of the optical phyllotactic image device according to the present invention.

Figure 12 (b) shows the image of a pair of complementary phyllotactic models 1251; this arrangement is characterized in that it is composed of two models which are - except for the sign of the constant thetao in the equation 1(b) - identical. Thus, a combination of a left- handed phyllotactic model and a right-handed one is concerned. The aforesaid figure can be also considered to be an illustration of two mutually overlapping primary areas, the respective overlap forming a quaternary subarea; in the present case, said quaternary subarea

encompasses the entire surface of one or the other primary area, respectively.

The present invention relating to an optical phyllotactic image device can be used for imaging complex phyllotactic models of plants of the individual parts thereof having a size of, for example, several centimetres, the achievable level of resolution corresponding to individual plant cells.

One of the exemplary applications of the optical phyllotactic image device according to the present invention consists in using said device for securing documents, tokens of value and certificates against unauthorized duplication and counterfeiting. Similarly, such device can be used for protecting goods and brands as well as for verifying authenticity or genuineness of products.

A mass production based on known methods is also possible. In the first step, a recombination of the relief of the initial matrix of the image device is performed, e.g. using a galvanic punch. In the first step, a large-scale replication of the relief of the punch is performed, said replication consisting, e.g., in using a moulding, heat curing or ultraviolet irradiation technique for treating a thin film deposited on the surface of a foil substrate. Other possible steps can include depositing a thin metallic layer or another suitable layer on the surface of the relief, e.g. using a vapour or powder deposition technique, removing said layer using a selective etching technique, applying a foil on a substrate using a gluing or hot stamping technique etc.

The exemplary illustration shown in Figure 10 represents a schematical sketch of the token 1011 of value that is supplemented with the optical phyllotactic image device 1021 formed by a thin foil and applied, e.g. by hot stamping, on the carrying part of the token of value, said carrying part being preferably a paper or plastic substrate 1012. For example, the image device can assume the form of a strip, a ribbon or a medallion.

According to an advantageous embodiment, a token of value may be provided with a device having a form of a medallion a being applied on the token of value, said medallion being a diminished, true or modified replica of the graphical design of the respective token of value. Typically, such graphical design comprises text objects, numerical objects 1013 and image or graphical objects 1014. A further advantageous embodiment may consist in that the image device includes another miniature of its own, said miniature being arranged in that portion of the device which corresponds to the location of the device on the respective token of value.

Another advantageous embodiment may consist in that the graphical implementation of the token of value itself already comprises, either partially or to the full extent, a mesh of a phyllotactic model.

Another example of application of the present invention relating to an optical phyllotactic image device is depositing a foil comprising such device onto a wrapper of a product or article with the aim to enhance the attractiveness of such an item.

Figure 11 shows an article located in a box 1110 packed in a wrapper 1120 provided with a foil including one or more identical or different optical phyllotactic image devices 1130x, 1130v, said foil covering discrete portions of the surface or the whole surface of said wrapper.

Another exemplary application of the optical phyllotactic image device according to the present invention relates to collector' items, such as coins, cards, tokens, stamps or the like, provided with such device.

List of reference numerals

111a— 1 ^st core

111b— 2 ^nd core

11 1c— 3 ^rd core

11 lad— 30 ^th core (the last core in the respective figure)

11 lgr— 400 ^th core (the last core in the respective figure)

121 x— one of the 21 derived spirals formed by each 21 ^st core

121y— another one of the 21 derived spirals formed by each 21 ^st core

134x -— one of the 34 derived spirals formed by each 34 ^th core

134y— another one of the 34 derived spirals formed by each 34 ^th core

150— area comprising the cores of the phyllotactic model

160— basic spiral

250— circular area filled with the cores of the phyllotactic model (having a radius

r— c . sqrt ( le4 ) = 100 c, wherein c is a scale parameter)

299— pattern of the model 250, recognizable at a very wide viewing angle

301— arrangement (optical device on a underlying pad)

302— underlying pad

303— window / aperture / orifice 304— optically variable image device

305— light source

310— one impinging beam

311— reflected beam

320— another impinging beam

321— beam passed through

331— deflected beams, first order

341— deflected beams, higher harmonic orders

351— deflected beams, negative orders

361— deflected beams, subharmonic orders

371— deflected beams, high harmonic orders

391— observer's location (observing the reflected light, i.e. the beam 311)

392— observer's location (observing the light passing through)

393— observer's location (observing the beams 331)

394— observer's location (observing the beams 341)

395— observer's location (observing the beams 351)

396— observer's location (observing the beams 361)

397— observer's location (observing the beams 371)

401— axonometric view of the initial three-dimensional phyllotactic model (wherein the cores are arranged on a lateral area of a cone)

402— axonometric view of the transformed model

403— primary area of the graphic template (containing graphical elements coiTesponding to the cores of the transformed model projected into a selected plane)

411a— first core

411b— second core

412— initial basic spiral (on a lateral area of a cone)

421a— first core after transformation

421b— second core after transformation

422— transformed basic spiral

431a— first graphical element (corresponding to the first core after transformation and projection)

43 lb— second graphical element (corresponding to the second core after transformation and projection)

501— primary area (of the graphic template, cut-out) 502— secondary subarea

503— primary subareas (cut-out)

51 Ox— one graphical element (belonging to the primary mesh)

521a— first derived spiral (belonging to one suitable set of derived spirals of the phyllotactic model in the primary area)

521b— second derived spiral

521m ·— last (13 ^th ) derived spiral

531a— first derived spiral (belonging to another suitable set of derived spirals of the

phyllotactic model in the primary area)

53 lb— second derived spiral

531m— last (13 ^th ) derived spiral

541a— first derived spiral (belonging to one suitable set of derived spirals in the secondary area)

541b— second derived spiral

541m— last (19 ^th ) derived spiral

551a— first derived spiral (belonging to another suitable set of derived spirals in the

secondary area)

551b— second derived spiral

551m— last (9 ^th ) derived spiral

601— primary area of the graphic template (cut-out)

610— primary subarea (cut-out)

61 lx— one graphical element (of the primary area)

61 ly— another graphical element (of the primary area)

620— second secondary subarea (cut-out)

621x— one graphical element (belonging to a second secondary subarea)

62 ly— another graphical element (belonging to a second secondary subarea)

623— second secondary web (cut-out)

624x— one line of the web extending along the first coordinate of the second secondary web 625y— one line of the web extending along the second coordinate of the second secondary web

626xy— one node (of the second secondary web; crossing of one line of the web extending along the first coordinate and one line of the web extending along the second coordinate)

630— detailed view of an interface 710— primary area

720— boundary of the primary area

730— primary subarea

73 lx— one graphical element (belonging to the primary subarea)

73 ly— another graphical element (belonging to the primary subarea)

740— one third secondary subarea

74 lx— one graphical element (belonging to a third secondary subarea)

74 ly— another graphical element (belonging to a third secondary subarea)

742x— line formed by one series of graphical element in one third secondary subarea 742y— line formed by another series of graphical element in one third secondary subarea 750— another third secondary subarea

75 lx— one graphical element (belonging to another third secondary subarea)

75 lx— another graphical element (belonging to another third secondary subarea)

753x— line formed by one first series of graphical element in another third secondary subarea 753y— line formed by another first series of graphical element in another third secondary subarea

754x—line formed by one second series of graphical element in another third secondary subarea

754y— line formed by another second series of graphical element in another third secondary subarea

811— microtext (pattern)

821— primary area (cut-out)

823— tertiary subarea

830— location of the tertiary subarea

835— auxiliary boundary of the tertiary subarea

84 lx— one graphical element (within the tertiary subarea, dark)

842y— one graphical element (within the tertiary subarea, bright)

861— coded image (pattern)

871— primary area (cut-out)

873— tertiary subarea

880— location of the tertiary subarea

885— auxiliary boundary of the tertiary subarea

89 lx— one graphical element (within the tertiary subarea, dark)

892y— one graphical element (within the tertiary subarea, bright) 900— final graphic template

901— primary graphic template

902— graphic pattern

903— one image (of the characteristic pattern)

904— another image (corresponding to the graphic pattern)

905— three-dimensional phyllotactic model (axonometric view)

906— core model (axonometric view)

907a— core (first)

907b— core (second)

908a— initial spatial coordinates (of the first core)

908b— initial spatial coordinates (of the second core)

909aa— initial value (of the first attribute of the first core)

909ab— initial value (of the second attribute of the first core)

909ba— initial value (of the first attribute of the second core)

909bb— initial value (of the second attribute of the second core)

910— primary subarea (of the final graphic template)

911a— graphical element (in the primary area, corresponding to the first core)

911b— graphical element (in the primary area, corresponding to the first core)

91 1 w— another graphical element (in the primary area)

91 lx— another graphical element (in the primary area)

91 ly— another graphical element (in the primary area)

91 lz— another graphical element (in the primary area)

915— primary subarea (of both the primary graphic template and the final graphic template) 920— one secondary subarea

92 lx— one graphical element (belonging to one secondary subarea)

930— another secondary subarea

93 ly— one graphical element (belonging to a another secondary subarea)

940— still another secondary subarea

94 lz— one graphical element (belonging to a still another secondary subarea)

950— planar optical structure

951— primary area (of the planar optical structure)

960— primary subarea (of the planar optical structure)

96 lw— one optical primitive (in the primary subarea, coiTesponding to the graphical element 91 lw) 970— one secondary subarea

97 lx— one optical primitive (in one secondary subarea, corresponding to the graphical element 92 lx)

980— another secondary subarea

98 ly— one optical primitive (in another secondary subarea, corresponding to the graphical element 93 ly)

990— still another secondary subarea

99 lz— one optical primitive (in still another secondary subarea, corresponding to the

graphical element 94 lz)

1011— token of value

1012— substrate

1013— numerical object

1014— graphical object

1021— optical phyllotactic image device

1110— box

1120— shell

113 Ox— one optical phyllotactic image device

1130y— another optical phyllotactic image device

1201— view of a phyllotactic model

1251— view of a pair of complementary phyllotactic models

1300— pole of a coarse model

1302— coarse left-handed phyllotactic model

1304— area boundary of a coarse model

1311a— first core (of the coarse model)

131 lb— second core (of the coarse model)

1311c— third core (of the coarse model)

131 lad— last (thirtieth) core (of the coarse model)

1320ad— boundary of the thirtieth core of the coarse model