Moire magnification device

The invention claimed is: 1. A moiré magnification device comprising a transparent substrate carrying: i) a periodic array of micro-focusing elements on a first surface, the micro-focusing elements defining a focal plane; ii) a first array of microimages in an ink of a first color and located in a plane coincident with the focal plane of the micro-focusing elements; and iii) a second array of microimages, in an ink of a second color different from the first color, and located in a plane coincident with the focal plane of the micro-focusing elements, the second array of microimages being laterally offset from the first, wherein pitches of the micro-focusing elements and first and second arrays of microimages and their relative locations are such that the array of micro-focusing elements cooperates with each of the first and second arrays of microimages to generate respective magnified versions of the microimages of each array due to a moiré effect, and such that when viewing the arrays of microimages simultaneously, an interruption zone of non-zero width is perceived between the magnified version of the first microimage array and the magnified version of the second microimage array, the interruption zone exhibiting no magnified version of either microimage array, wherein the first array of microimages is laterally spaced from the second array of microimages by a boundary region of non-zero width which is free of microimages, thereby giving rise to the perceived interruption zone, and wherein the width of the microimage element-free boundary region is greater than a maximum pitch of either of the microimage element arrays. 2. The device according to claim 1 , wherein the microimage-free boundary region carries an interruption layer, the interruption layer taking a form of a uniform or patterned printing or coating. 3. The device according to claim 2 , wherein, in the microimage-free boundary region, the interruption layer is disposed between the substrate and at least one of the first and second arrays of microimages. 4. The device according to claim 1 , wherein the periodic array of micro-focusing elements comprises first and second periodic arrays of micro-focusing elements laterally spaced from one another by a boundary region of non-zero width which is free of functioning micro-focusing elements, the boundary region being aligned with a transition between the first array of microimages and the second, thereby giving rise to the interruption zone perceived. 5. The device according to claim 4 , wherein the width of the boundary region is greater than a largest dimension of individual micro-focusing elements. 6. The device according to claim 5 , wherein the width of the boundary region is greater than a maximum pitch of either of the micro-focusing element arrays. 7. The device according to claim 4 , wherein the boundary region comprises a layer of material formed on micro-focusing elements in that region, the material being of a same refractive index as that of the micro-focusing elements, such that the micro-focusing elements in the boundary region are non-functional. 8. The device according to claim 4 , wherein the boundary region comprises a region devoid of micro-focusing elements. 9. The device according to claim 1 , wherein the micro-focusing elements comprise microlenses. 10. The device according to claim 1 , wherein the microimages are printed on the substrate or are formed as grating structures, recesses or other relief patterns on the substrate. 11. A security device according to claim 1 . 12. The security device according to claim 11 , formed as a security thread, label or patch. 13. The security device according to claim 11 , the security device being provided in a transparent window of a security document. 14. An article provided with an optical device according to claim 1 , wherein the article comprises one of a banknote, a check, a passport, identity card, certificate of authenticity, fiscal stamp and other document of security value or personal identity. 15. A security document comprising a document substrate having at least two transparent or translucent windows spaced apart from one another, and a device comprising a transparent substrate carrying: i) a periodic array of micro-focusing elements on a first surface, the micro-focusing elements defining a focal plane; ii) a first array of microimages in an ink of a first color and located in a plane coincident with the focal plane of the micro-focusing elements; and iii) a second array of microimages, in an ink of a second color different from the first color, and located in a plane coincident with the focal plane of the micro-focusing elements, wherein the first array of microimagesn is laterally spaced from the second array of microimages by a microimage element-free boundary region of non-zero width which is free of microimages, wherein the width of the microimage element-free boundary region is greater than a maximum pitch of either of the microimage element arrays, and wherein pitches of the micro-focusing elements and first and second arrays of microimages and their relative locations are such that the array of micro-focusing elements cooperates with each of the first and second arrays of microimages to generate respective magnified versions of the microimages of each array due to a moiré effect, the device being incorporated into or applied on to the document substrate in alignment with the at least two windows, the device being registered to the document substrate such that, simultaneously, the magnified version of the first microimage array is visible through a first window of the two windows and the magnified version of the second microimage array is visible through a second window of the two windows, and such that the microimage element-free boundary region between the two microimage arrays is concealed by the document substrate between the two windows. 16. A moiré magnification device comprising a transparent substrate carrying: i) a periodic array of micro-focusing elements on a first surface, the micro-focusing elements defining a focal plane; ii) a first array of microimages in an ink of a first color and located in a plane coincident with the focal plane of the micro-focusing elements; and iii) a second array of microimages, in an ink of a second color different from the first color, and located in a plane coincident with the focal plane of the micro-focusing elements, the second array of microimages being laterally offset from the first, wherein pitches of the micro-focusing elements and first and second arrays of microimages and their relative locations are such that the array of micro-focusing elements cooperates with each of the first and second arrays of microimages to generate respective magnified versions of the microimages of each array due to a moiré effect, and such that when viewing the arrays of microimages simultaneously, an interruption zone of non-zero width is perceived between the magnified version of the first microimage array and the magnified version of the second microimage array, the interruption zone exhibiting no magnified version of either microimage array, wherein the periodic array of micro-focusing elements comprises first and second periodic arrays of micro-focusing elements laterally spaced from one another by a boundary region of non-zero width which is free of functioning micro-focusing elements, the boundary region being aligned with the transition between the first array of microimage elements and the second, thereby giving rise to the perceived interruption zone, and wher