LUMINAIRES AND OPTICAL ELEMENTS FOR USE THEREIN

Abstract

A luminaire including: at least one light source (2), and an optical system (10, 11, 12a, 12b) for directing and/or distributing the light (5) emitted by the source(s) (2) into a desired output light distribution pattern (7); wherein the optical system comprises one or more optical elements (10, 11, 12a, 12b), the or each said optical element (10, 11, 12a, 12b) comprising a thin foil or sheet substrate having at least one optically functional surface or surface layer thereon or on a portion thereof, and wherein: (i) at least a portion of the at least one optically functional surface or surface layer on the substrate of at least one of the one or more optical elements (10, 11, 12a, 12b) has an at least partially diffractive optical function, and/or (ii) at least a portion of the at least one of the one or more optical elements (10, 11, 12a, 12b) is shaped such that its substrate is configured so as to have a non-flat or non-planar shape in three dimensions.

Claims

1. A luminaire including: at least one light source, and an optical system for directing and/or distributing the light emitted by the source(s) into a desired output light distribution pattern; wherein the optical system comprises one or more optical elements, the or each said optical element comprising a foil or sheet substrate having at least one optically functional surface or surface layer thereon or on a portion thereof, and wherein: (i) at least a portion of the at least one optically functional surface or surface layer on the substrate of at least one of the one or more optical elements has an at least partially diffractive optical function, and/or (ii) at least a portion of the at least one of the one or more optical elements is shaped such that its substrate is configured so as to have a non-flat or non-planar shape in three dimensions.

2. A luminaire according to claim 1, wherein the features (i) and (ii) are both present together in any single one or more of the optical elements.

3. A luminaire according to claim 1, wherein the optical system comprises at least one, optionally a plurality of, optical elements, and the at least one optical element which is configured so as to have the non-flat or non-planar shape in three dimensions is the same one(s) of the optical element(s) whose substrate's optically functional surface(s) or surface layer(s) has/have the at least partially diffractive optical function.

4. A luminaire according to claim 1, wherein the optical system comprises at least one, optionally a plurality of, optical elements, and the at least one optical element which is configured so as to have the non-flat or non-planar shape in three dimensions is a different one(s) of the optical element(s) whose substrate's optically functional surface(s) or surface layer(s) has/have the at least partially diffractive optical function.

5. A luminaire according to claim 1, wherein the one or more optical elements present therein exclude any optical element which is other than the said one or more optical elements whose features are as defined in the respective preceding claim.

6. A luminaire according to claim 1, wherein the or each optically functional surface or surface layer (or portion thereof) on the substrate of the at least one optical element comprises a fully or partially diffractive optical function derived from, or created by, a diffractive optical relief structure or pattern formed on the said surface or surface layer, wherein: (i) the width and/or height of individual surface relief features of the relief structure/pattern is from 0.001 up to 100 μm, optionally from 0.001 up to 70 or 80 or 90 μm, further optionally from 0.001 up to 50 or 60 or 70 μm, or even further optionally from 0.001 or 0.005 or 0.01 up to 5 or 10 or 20 or 30 or 40 or 50 μm; and/or (ii) the individual surface relief features of the relief structure/pattern have depths of less than 15 μm, optionally less than 10 μm, further optionally less than 5 μm, even further optionally less than 3 μm; and/or (iii) the aspect ratio (i.e. the ratio of the relief profile depth to the relief feature size/width) of the individual surface relief features is less than 1; and/or (iv) the density of the placement of the surface relief features of the relief structure/pattern across the area of the or the respective surface or surface layer is, in one or any surface direction, from 50,000 or 20,000 up to 20 or 50 features per mm.

7. A luminaire according to claim 1, wherein the one or more optical elements, or at least a portion thereof, is/are each independently shaped such that its, or its substrate's, general non-flat or non-planar shape extends in three orthogonal dimensions, whereby its general shape is curved or arcuate in cross-section or profile, or follows a simple or complex mathematical function, or is defined as a free-form optical surface, in at least one, optionally in at least two, further optionally in three, directions or dimensions.

8. A luminaire according to claim 1, wherein the, or at least a portion of, the or at least one of the optically functional surfaces or surface layers on the substrate of the or at least one of the one or more optical element(s) has formed thereon or applied thereto one or more coating layers, the or each said coating layer being constructed or configured or formed of a material so as to modify, or further modify, the direction of light passing therethrough or to modify the light transmission and/or reflection properties of the at least one optically functional surface or surface layer on or to which the coating layer is formed or applied.

9. A luminaire according to claim 1, wherein: (i) the foil or sheet substrate of the or each optical element has a general overall thickness (or a maximum or minimum or average thickness if the height of any optical relief pattern on one or more surfaces thereof is taken into account in that calculation) of less than 1000 μm, optionally less than 500 μm, further optionally less than 250 μm or 125 μm, or even further optionally less than 50 μm; or (ii) the foil or sheet substrate of the or each optical element has a thickness (or a maximum or minimum or average thickness if the height of any optical relief pattern on one or more surfaces thereof is taken into account in that calculation) which is at least 10 times, optionally at least 20 times, further optionally at least 50 times less than its smaller lateral dimension; or (iii) both (i) and (ii) above are present or satisfied.

10. A luminaire according to claim 1, wherein the foil or sheet substrate of the or each optical element comprises or consists of an optically transparent plastics material or combination of plastics materials.

11. A luminaire according to claim 1, wherein the at least one optically functional surface or surface layer on the substrate (or portion thereof) of the or at least one of the one or more optical element(s) comprises an at least partially diffractive optical structure which operates at plural or multiple diffraction orders, optionally at plural or multiple diffraction orders lower than 10th or 15th or 20th; optionally wherein the at least partially diffractive optical function of the at least one optically functional surface or surface layer on the substrate (or portion thereof) of the or at least one of the one or more optical element(s) is such that it operates at at least two or at least three or at least four diffraction orders having diffraction efficiency maximized at at least two or at least three or at least four wavelengths respectively.

12. (canceled)

13. A luminaire according to claim 1, wherein the structure and/or configuration of the or at least one of the one or more optical element(s) is such that light emitted by the light source(s) of at least two different wavelengths which is incident on the said at least partially diffractive optical structure at the same angle of incidence is directed or distributed by the said optical structure into substantially overlapping directions with maximized diffraction efficiency, relative to the diffraction efficiency of light being directed or (re-)distributed into other directions).

14. A luminaire according to claim 1, wherein the at least partially diffractive optical function of the at least one optically functional surface or surface layer on the substrate (or portion thereof) of the or at least one of the one or more optical element(s) is such that plural or multiple wavelengths of light with maximized diffraction efficiency are distributed across at least 60% of the bandwidth of the light emitted by the light source(s).

15. A luminaire according to claim 1, wherein: (i) the optically functional surface or surface layer of the or at least one of the one or more optical element(s) comprises a substantially reflective surface or surface layer, optionally wherein the said reflective surface or surface layer comprises a metal film coating or layer, and further optionally wherein the said reflective surface or surface layer comprises one or more dielectric materials, and still further optionally wherein the optically functional surface or surface layer comprises a TIR (total internal reflection) surface or surface layer; or (ii) the optically functional surface or surface layer of the or the at least one optical element comprises a substantially optically transparent surface or surface layer.

16. A luminaire according to claim 1, wherein the at least one optically functional surface or surface layer on the substrate (or portion thereof) of the or at least one of the one or more optical element(s) comprises an at least partially diffractive optical structure which comprises: one or more structural features having a first density superimposed on one or more structural features with a second density, the first density being higher than the second density, wherein the relatively higher density structural features have a width and/or height which is at least two times, optionally at least five times, further optionally at least ten times, smaller than the corresponding size of the relatively lower density structural features.

17. A luminaire according to claim 1, wherein the or at least one of the one or more optical element(s) comprises a stack or superimposed or overlapping combination of a plurality of discrete substrate foils or sheets or surfaces or surfaces layers, optionally wherein, in the stack or combination of layers, each layer performs the overall optical function of the respective optical element only partially, and the entire stack or combination of layers performs the overall optical function of the respective optical element fully, and further optionally wherein any separation between the layers in the stack is such that the separation distance does not exceed the thickness of one or two of the layers in the stack, or a lateral shift between a beam incident on a given layer and the next one is such that the lateral shift does not exceed the separation distance between neighbouring layers in the stack.

18. A luminaire according to claim 1, wherein the optical system of the luminaire includes, in addition to the said at least one optical element having the at least one optically functional surface or surface layer thereon, one or more secondary optical elements, wherein the one or more secondary optical elements act(s) to further define or distribute or modify or redistribute the direction(s) of light from the light source(s) incident thereon and thereby to contribute to the formation of the output light distribution pattern at the exit of the luminaire, wherein said secondary optical element(s) is/are arranged either: (a) separately or discretely within the luminaire and spaced apart from, and/or oriented parallel or non-parallel to, the or the respective optical element having the at least one optically functional surface or surface layer thereon, or (b) superimposed on or overlapped with, or placed facially adjacent, the at least one optical element having the at least one optically functional surface or surface layer thereon.

19. An optical system for a luminaire as defined in claim 1, the optical system comprising: a plurality of optically-functional optical elements as defined within claim 1, wherein: (i) at least one of the said optically-functional optical elements is shaped so that its substrate is configured so as to have the non-flat or non-planar shape in three dimensions, optionally in three orthogonal dimensions, optionally wherein at least one other of said optically-functional optical elements is substantially flat or planar in its general shape; and (ii) at least one other of the said optically-functional optical elements comprises at least a portion of the at least one optically functional surface or surface layer on the substrate thereof having the at least partially diffractive optical function; optionally wherein the said at least one other diffractively-optically-functional optical element(s) (ii) comprise(s) a stack or paired combination of like diffractively-optically-functional optical element(s), optionally a pair thereof which are inversely mutually superimposed, such that the stack or paired combination acts to further tailor the distribution or modification of the output direction(s) of light redirected from the said at least one non-flat or non-planar three-dimensionally shaped optically-functional optical elements (i).

20. An optical system for a luminaire as defined in claim 1, the optical system comprising: at least one optically-functional optical element as defined within claim 1, and wherein the features of either group (A) or group (B) below are present or satisfied: (A)(i) the said at least one optically-functional optical element is both: shaped so that its substrate is configured so as to have the non-flat or non-planar shape in three dimensions, optionally in three orthogonal dimensions, and configured such that at least a portion of the at least one optically functional surface or surface layer on the substrate thereof has the at least partially diffractive optical function; optionally wherein the optical system further comprises at least one secondary optical element having a secondary optical function for further distributing or modifying the direction(s) of light redirected from the said plurality of optically-functional optical elements (A)(i); or (B)(i) at least one first portion or region of the said optically-functional optical element is shaped so that its substrate is configured so as to have the non-flat or non-planar shape in three dimensions, optionally in three orthogonal dimensions; and (ii) at least one second portion or region of the said optically-functional optical element comprises at least a portion of the at least one optically functional surface or surface layer on the substrate thereof having the at least partially diffractive optical function; optionally wherein the said first and second portions or regions of the said optically-functional optical element are formed by discrete and different ones of plural portions of the said optically-functional optical element, further optionally wherein the said first and second portions or regions of the said optically-functional optical element are formed with their respective substrates at least partially in common with, or unitary with, one another; optionally wherein the said at least one first portion or region being the non-flat or non-planar optically-functional optical element portion or region (B)(i) of the at least one optical element is configured such as to surround or enclose or circumscribe or peripherally contain the said at least one second portion or region being the diffractively-optically-functional optical element portion or region (B)(ii).

21-22. (canceled)

23. A method for producing an optical element, the optical element comprising: a foil or sheet substrate having at least one optically functional surface or surface layer thereon or on a portion thereof, and wherein: (i) at least a portion of the at least one optically functional surface or surface layer on the substrate has an at least partially diffractive optical function, and (ii) at least a portion of the optical element is shaped such that its substrate is configured so as to have a non-flat or non-planar shape in three dimensions; wherein the method comprises the steps of: (1) providing a foil or sheet substrate; (2) forming on or applying to at least one surface or surface layer of the substrate an at least partially diffractive optical relief pattern, whereby the said at least one surface or surface layer becomes the said at least one optically functional surface or surface layer with the said at least partially diffractive optical function; and (3) shaping the said substrate so that it assumes or is configured into the said non-flat or non-planar shape in three dimensions.

24. A method according to claim 23, wherein: (i) the shaping step (3) is carried out either before or after the optical functionalisation step (2); or (ii) the optical functionalisation step (2) is carried out either before or after the shaping step (3); or (iii) the optical functionalisation step (2) and the shaping step (3) are carried out together or substantially simultaneously.

25. A method according to claim 23, further including an additional step of: (4) forming on or applying to the at least one optically functional surface or surface layer one or more coating layers, the or each said coating layer being constructed or configured or formed of a material so as to modify the direction of light passing therethrough or to modify the light transmission and/or reflection properties of the at least one optically functional surface on or to which the coating layer is formed or applied; wherein: (i) the above step (4) is carried out either before or after the optical functionalisation step (2); and/or (ii) the above step (4) is carried out either before or after the shaping step (3).

26. (canceled)

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0127] Some embodiments of the invention in its various aspects, as well as various technical features underpin some of those embodiments, will now be described and explained in detail, by way of non-limiting example only, with reference to the accompanying drawings, in which:

[0128] FIG. 1(a) is a schematic cross-sectional view of a luminaire optical arrangement according to a first embodiment of the invention;

[0129] FIG. 1(b) is a schematic perspective view of the arrangement shown in FIG. 1(a);

[0130] FIG. 2 is a schematic cross-sectional view of a rotationally symmetrical luminaire optical arrangement according to a second embodiment of the invention;

[0131] FIG. 3 is a schematic cross-sectional view of a luminaire optical arrangement according to a third embodiment of the invention;

[0132] FIG. 4(a) is an explanatory graph illustrating the relationship between diffraction order and diffraction efficiency across the visible spectrum in relation to certain optical functions as may be employed in certain example embodiments of the invention, for aiding an understanding of, and to be read in conjunction with, the explanations hereinbelow concerning diffractive structures with multi-order (or plural-order) functionality(ies);

[0133] FIG. 4(b) is another explanatory graph, similar to FIG. 4(a), but illustrating the relationship between diffraction order and diffraction efficiency across the visible spectrum in relation to certain other optical functions as employed in certain other example embodiments of the invention, again for aiding an understanding thereof and to be read in conjunction with the explanations thereof hereinbelow;

[0134] FIG. 5(a) is a schematic cross-sectional illustration representing an example optical element for use in certain embodiments of the invention in which stacked or layered combinations of plural optically functional elements, layers or surfaces are employed, this FIG. illustrating the basic principle of replacing a single layer with a stack of layers;

[0135] FIG. 5(b) is another schematic cross-sectional illustration representing an example optical element based on stacked or layered combinations of plural optically functional elements, layers or surfaces, in which:

[0136] FIG. 5(b), top half, illustrates an optical function (deflection to higher angles) which cannot be performed by one prismatic structure of a given orientation, but can be performed by two stacked structures of the same type and orientation, each performing a portion of the deflection, and in total they perform the desired total deflection; and

[0137] FIG. 5(b), bottom half, illustrates an optical function (deflection to higher angles) which cannot be performed with high efficiency by one blazed diffraction grating of a given orientation, but can be performed efficiently by two stacked gratings of the same type and orientation, each performing a portion of the deflection, and in total they perform the desired total deflection;

[0138] FIG. 5(c) is another schematic cross-sectional illustration representing an example optical element based on stacked or layered combinations of plural optically functional elements, layers or surfaces, this FIG. 5(c) illustrating the idea of splitting the optical function of the layer structure between multiple layers only on a portion of the original structure;

[0139] FIG. 5(d) is another schematic cross-sectional illustration representing an example optical element based on stacked or layered combinations of plural optically functional elements, layers or surfaces, this FIG. 5(d) illustrating some examples of different orientations of the structures in the stack of layers;

[0140] FIG. 5(e) is another schematic cross-sectional illustration representing an example optical element based on stacked or layered combinations of plural optically functional elements, layers or surfaces, this FIG. 5(e) illustrating some examples of different types of separation between layers in the stack of layers.

DETAILED DESCRIPTION OF EMBODIMENTS

[0141] FIGS. 1(a) and 1(b) show a luminaire optical system comprising plural—in this case four —optically functional optical elements 10, 11, 12a, 12b, and a light source 2, for example an LED. Each optical element 10, 11, 12a, 12b is in the form of a thin layer, e.g. a plastics foil, of a respective substantially uniform thickness 3, typically below about 500 μm (which thickness 3 may be substantially the same or may be different for each respective element layer 10, 11, 12a, 12b). Three of the layer elements 10, 12a, 12b are flat, while one element layer 11 is curved in three dimensions so as to represent a free-form three-dimensional optical element.

[0142] Each of the two flat layer elements oriented horizontally, 12a, 12b, comprises two optical surfaces 40, 41, one on each side of the respective foil substrate layer. The optical surfaces 41 are partially diffractive, and may also be partially refractive, optical surfaces, while the optical surfaces (or surface portions) 40 are not, e.g. they may be merely refractive. Each of the other two optical element layers 10, 11 comprises only one optical surface 42, and one non-optical surface on the opposite side of the respective element layer—i.e. they are not designed or arranged to process incident light.

[0143] The surfaces 40 on one respective side/face of the two flat horizontal layer elements 12a, 12b are just plain index boundaries, i.e. a flat boundary between the layer element surface and the surrounding environment, whilst the surfaces 41 on the respective opposite sides/faces thereof are nano- or micro-structured diffractive and/or refractive surfaces. The inner surfaces 42 on each of the two optical element layers 10, 11 are coated with a reflective thin film coating.

[0144] The light source 2 emits radiation 5 which is incident on the various optical surfaces present—i.e. 42, 41, 40—and these surfaces redirect the incident radiation by a combination of reflection, refraction and diffraction. The redirected radiation 6 propagates further in a sequence to other ones of the optical surfaces—in particular 40 and 41—until it finally exits the optical system forming a specific light output distribution pattern 7.

[0145] Thus, in more detail, in the optical system as illustrated in FIGS. 1(a) and 1(b), the following features may be recognised: [0146] one or both sides of each layer optical element 10, 11, 12a, 12b comprises an optical surface; [0147] at least a portion of each optical surface (of each optical element) is configured to receive at least a portion of radiation from the at least one radiation (e.g. light) source 2, or at least a portion of radiation 6 reflected from or transmitted through any of the other optical surfaces or optical elements in the optical system; [0148] at least one of the optical surfaces of any of the layer optical elements 10, 11, 12a, 12b comprises: [0149] a diffractive nano- or micro-structure 41 with characteristic feature sizes e.g. below 100s of μm or even below 10 s of μm, or [0150] a thin film coating, or [0151] both of the above; [0152] the optical function of each optical surface is designed: [0153] to redirect at least a portion of the incident radiation into a specific radiation distribution pattern, which: [0154] propagates towards another optical surface or optical element 6, or [0155] contributes to the predefined radiation distribution pattern 7 at the output of the optical system, or [0156] both of the above; [0157] and/or to modify reflection or transmission properties of the corresponding layer; [0158] and/or to totally reflect at least a portion of the incident radiation; [0159] and/or to effect any combination of the aforementioned optical functions; [0160] all the optical elements in the optical system are designed and arranged to produce a predefined radiation (light) distribution pattern 7 at the output of the optical system.

[0161] FIG. 2 shows in cross-section a luminaire optical system comprising a LED light source 2 and a rotationally symmetrical thin layer diffractive optical element 13 (shown in two halves on each side of the drawing, given that it is showing it in cross-section) shaped into a free-form three-dimensional optical element which extends in three dimensions around the luminaire. The optical system also includes a classical volume lens element 1. The thin layer partially diffractive element 13 has optical surfaces on both its sides. One surface comprises a partially diffractive nano- or micro-structure 41, e.g. moulded into the layer during the layer shaping process, and the other surface 43 is a simple curved index boundary with a TIR function.

[0162] The inner surface 41 of the element 13 receives a portion of light 5 from the source 2. The nano- or micro-structure features on this surface 41 are configured such as that they redirect incident light by diffraction (and/or also by refraction) into a light pattern 6 which is further redirected by surface 43 by total internal reflection and send the light back to the surface 41, which then redirects the light towards the lens element 1 which processes that portion of light—as well as a portion of the light 5 coming directly from the source—so as to create a final light distribution pattern 7 at the exit of the optical system.

[0163] All the optical elements in this optical system and the interactions between them are designed and configured such that all the radiation from the source 2 is transformed into a quasi-collimated beam.

[0164] Thus, in more detail, in the optical system as illustrated in FIG. 2, the following features may be recognised: [0165] the element 13 is shaped into a free-form three-dimensional optical element comprising a nano- or micro-structured surface 41, especially one which is at least partially diffractive; [0166] that shaping may be done using a foil moulding process, e.g. comprising a transfer of a nano- or micro-structured relief pattern on the mould surface, or a portion thereof, to create a nano- or micro-structured surface on the layer element 13; [0167] during that shaping of the element 13 the nano- or micro-structured surface 41 is configured so that, in use, it receives at least a portion of radiation from the radiation source(s) 2 or a portion of radiation 6 reflected from or transmitted by any of other layer surfaces or optical elements in the optical system, [0168] that shaping of the element 13 is done so that the resulting optical function of the surface 41 is designed to redirect at least a portion of the incident radiation into a specific radiation (light) distribution pattern, which: [0169] propagates (e.g. as at 6) at least towards another optical surface or optical element of the system, and/or [0170] contributes to the predefined radiation distribution pattern 7 at the output of the optical system; [0171] all the optical elements in the optical system are designed and arranged to produce a predefined radiation (light) distribution pattern 7 at the output of the system.

[0172] FIG. 3 shows a modified embodiment of a luminaire optical system within the scope of the invention which has a multi-region (or plural-region) arrangement 8 based on a multi-functional surface of a unitary thin layer optical element 15.

[0173] In this case, however, the unitary thin layer element 15 is shaped overall into a rotationally symmetrical free-form three-dimensional optical element 15 (shown in two halves on each side of the drawing, given that it is showing it in cross-section). The outer curved or arcuate portions or regions 15a, 15b each comprise a reflective coating 52 which, together with the specifically designed shape of those element portions or regions 15a, 15b, collimate radiation from the source 2 emitted into higher angles. The central portion or region 61 of the element 15, located between the outer portions/regions 15a, 15b, comprises a zonal lens 61 which collimates the radiation from the source 2 emitted into smaller angles. The regions 64 between the reflecting and collimating regions represent plain index boundaries transmitting incident radiation without any substantial modification.

[0174] The specific configuration of this single layer multi-region element 15 transforms radiation from the source 2 into a collimated beam 7 at the output of the optical system.

[0175] Thus, in more detail, in the optical system as illustrated in FIG. 3, the following features may be recognised: [0176] single layer multi-region element 15 is curved or shaped into a free-form three-dimensional optical element using a foil molding process; [0177] as in the other illustrated embodiments discussed above, the thin substrate layer 15 is in the form of a plastics foil with a substantially uniform thickness 3 of about 500 μm or less; [0178] both sides of the each element portion 15a, 15b, 61 comprise an optical surface, in which: [0179] each surface is configured to receive at least a portion of radiation from the radiation (light) source(s) 2 or at least a portion of radiation 6 reflected from or transmitted through any of the other surfaces or optical element portions in the optical system; [0180] the optical function of each surface is designed to: [0181] redirect at least a portion of the incident radiation into a specific radiation distribution pattern, which: [0182] propagates towards another optical surface or element, [0183] or contributes to the predefined radiation distribution pattern 7 at the output of the optical system, [0184] or both of the above; [0185] and/or modify the reflection and/or transmission properties of the corresponding layer/elemnt; [0186] and/or totally (e.g. internally) reflect at least a portion of the incident radiation; [0187] and/or any combination of the above-listed optical functions; [0188] each optical surface of the element portions 15a, 15b, 61 comprises at least one of: [0189] a nano- or micro-structure with a diffractive optical function, [0190] a thin film coating, [0191] both of the above; [0192] all the optical elements in the optical system are designed and arranged to produce a predefined radiation (light) distribution pattern 7 at the output of the system.

[0193] There now follows a detailed description of “nano- and micro-structures”, which may provide the focus of many embodiments of the present invention, especially those which are based on diffractive structures, and further especially those which are based on diffractive structures with multi-order (or plural-order) functionality(ies).

[0194] During the process of modelling, simulating and experimenting with various types of nano- and micro-structures we came to a conclusion that production of nano- and/or micro-structures may be very efficiently accomplished in high volumes if these structures form an optical surface on thin plastic layers (e.g. foils) in the form of a relief structure, in particular if the relief features are relatively shallow (e.g. typically less than about 15 μm, especially less than about 10 μm, or perhaps less than about 5 μm, or even less than about 3 μm deep) and their aspect ratio (i.e. the ratio of the relief profile depth to the relief feature size/width) is preferably less than about 1. Such structures may be embossed into or UV casted onto very cheap plastic foils which may be used for example in security holography applications, which are very thin, typically less than about 50 μm and even as thin as about 15 μm. However, many other foils are readily available on the market and available in various thicknesses, typically less than about 500 μm, or 250 μm or 125 μm, and may be used in certain embodiments of this invention.

[0195] A particular useful type of nano- and/or micro-structure which fits the above description is, for example, a diffractive structure. They may be designed in very complex forms (e.g. high density of their nano- and/or micro-features, which may be arranged into very complex two- or three-dimensional patterns in the form of a surface and/or volume relief structure), which may enable them to generate complex light distribution patterns, whilst at the same time their high complexity does not make them more difficult to reproduce than less complex structures once the primary master structure (or mould) has been produced. This is often not the case with known “micro-prismatic” optics (i.e. optics with micro-structured surfaces in the form of an array or assembly of a plurality of micro-prismatic or other refractive features) which are more widely used in luminaires nowadays, and which operate primarily on refractive optical principles rather than diffraction principles. The size and height of such known micro-prismatic features is also often much larger and deeper (e.g. 10s to 100s of μm) than features of a diffractive structure, and therefore their high volume production may be less effective.

[0196] The diffractive structures used in the present invention, in spite of their effective replicability, have hitherto not been considered as a useful solution for luminaire optics or more generally for white-light illumination applications, since they are often perceived as structures producing too strong chromatic aberration, which is an unwanted effect observed either in light distribution patterns or illumination patterns that they produce. For this reason, diffractive structures may, on the basis of conventional wisdom, be rather seen as a suitable choice for monochromatic or quasi-monochromatic applications (e.g. to process light emitted by a monochromatic LED or a laser).

[0197] To be able to use diffractive structures in white-light illumination applications, the effect of chromatic aberration usually needs to be suppressed. There are several ways of doing this. For example, the incident light may be blurred at the entrance or exit of the diffractive structure by some type of an additional diffuser which acts to spatially mix incident light or light processed by the diffractive structure and therefore also mix the propagation directions of various wavelengths. The degree of mixing may be tied to the degree of “achromatization”. A drawback of this approach is, however, that the light distribution pattern also may become blurred (e.g. is widened and/or it loses its definition or sharp transitions). As a result, this approach may not allow (or it may suppress) realization of complex functions of the diffractive optics. Moreover it may require one or more additional or secondary optical element(s) (e.g. one or more diffusers), which unfortunately then adds cost to the overall optical system.

[0198] Another achromatization approach may be to use a technique of mixing the performance of a diffractive structure designed for several wavelengths (typically red, green and blue, in the case of white light) in such a way that the structure is divided into small portions (e.g. regions or pixels), and multiple sets of these regions—with each set being associated with a particular design wavelength—alternate (e.g. regularly, quasi-randomly or randomly) across the area of the diffractive structure. However, since the area of the diffractive structure may thus in effect practically split into three different structures, this may reduce the structure area's potential to realize more complex optical functions. Also, such an approach may be more suitable for applications using several distinct colours rather than a continuous spectrum typically produced for example by white light LEDs.

[0199] Following on from the foregoing discussion, we turn now to a more detailed explanation of the function of diffractive structures used in accordance with the present invention, especially those which are based on diffractive structures with multi-order (or plural-order) functionality(ies). However, it is to be understood that this explanation is for non-limiting explanatory purposes only for aiding an understanding of certain embodiments of the invention, so it should not be construed as limiting the scope of the invention to any particular theory or theoretical model or embodiment.

[0200] Yet another achromatization approach may be to operate diffractive elements simultaneously at multiple (or plural) diffraction orders. The use of such an approach is actually novel in the area of illumination applications, in particular if white light is involved. It is well-known that diffractive structures produce multiple orders (apart from zero order, and excluding cases when typical feature size of a diffractive structure is comparable or rather smaller than the wavelength of the incident light). There are applications of diffractive optics in which several of such orders generated by the diffractive structure perform a specific optical function. This may be the case in the use of diffractive elements called beam splitters. A diffraction structure of this kind may be designed such as to split an incident beam into three diffraction orders of the same diffraction efficiency and the proper proportions of the structure feature sizes ensure the efficiency is maximized. Such or similar diffractive beam splitters are usually designed for one wavelength, but the structure generates multiple diffraction orders which are intentionally and simultaneously used in a particular optical application. It is possible to say that such a structure “operates” simultaneously at multiple (or plural) diffraction orders. In many cases, the very same structure would produce more diffraction orders than “operational” ones. However, these orders are usually undesirable, since they often carry away (i.e. in non-useful directions) some portion of incident energy (i.e. decreasing the diffraction efficiency of the operational diffraction orders) and/or are perceived as optical noise, which may negatively interfere with the optical function of the system in which the diffractive beam-splitting element is used.

[0201] Another historically old type of diffractive element operating simultaneously at multiple (or plural) diffraction orders is an echelle grating used in spectroscopy applications. It is a relatively coarse grating (i.e. coarse with respect to wavelengths of the incident light) which can produce high numbers of diffraction orders, each of them generating a spectrum of wavelength (spatially separated) represented in the incident light and each of them having optimized (i.e. maximized) diffraction efficiency at one wavelength of the generated respective spectrum. If the incident light has the same angle of incidence for each wavelength these diffraction orders (i.e. diffraction spectra) overlap, which is an undesirable effect for spectroscopy purposes. Therefore, echelle gratings are usually combined with another optical element which pre-separates wavelengths into a range of angles of incidence, which helps to spatially separate spectra subsequently generated by multiple (or plural) diffraction orders of the echelle grating, which enables meaningful detection and/or spectral analysis.

[0202] The novel use of the simultaneous use of multiple diffraction orders (i.e. operational orders) in illumination applications can be demonstrated using the following example:

[0203] The basic function of the optics used in luminaires—which optics generally employ one or more optical elements—is to redirect light coming from one direction into one or more other directions. In general, different parts of the optical element deflect incoming light into different directions. In the case of diffractive structures, the deflection is realized typically by a periodic or quasi-periodic structure, of which the simplest representative structure is a diffraction grating, i.e. a structure with equi-distantly spaced linear features. For simplicity we will further consider a thin (“thin” meaning a theoretical construct in the field of diffractive optics) surface relief transmission grating with equi-distantly distributed linear features having a blazed (i.e. sawtooth-like) profile. The deflection angle on the diffraction grating is given by the grating equation:

sin θ.sub.dm=sin θ.sub.i+m(λ/Λ),

[0204] where θ.sub.dm is the angle of diffraction (i.e. deflection) of m-th order, λ is a wavelength in the spectral bandwith of the incident light, Λ is the grating period (i.e. spacing of grating lines) and θ.sub.i is the angle of incidence. Based on the principle of diffraction on a thin grating, the diffraction efficiency η.sub.m of the m-th order (i.e. the portion of incident light deflected into angle θ.sub.dm) is

η.sub.m=sinc [m−d(n−1)/λ].

[0205] If the grating operates at the first order, the angle of incidence is 0 and the grating depth is tuned to maximize efficiency at green wavelength λ.sub.g. The diffraction efficiency of green wavelength η.sub.1g will be equal to 1 (i.e. 100%), and all other wavelengths diffracted into 1.sup.st order will have efficiency less than 1.

[0206] However, if for example the grating period, grating depth and diffraction order are tripled, the grating will deflect green light into the 3.sup.rd order by the same angle (as in the previous case of the grating operating at first diffraction order), and also the other two wavelengths of a white spectrum (red λ.sub.r=3/2 λ.sub.g and blue λ.sub.b=4/3 λ.sub.g) will be deflected into the same angle although not at the same diffraction orders (i.e. red will be then operating at 2.sup.nd and blue at 4.sup.th diffraction orders). All three wavelengths will deflect with efficiency equal to 1 (i.e. with maximized efficiency).

[0207] It has to be stressed that the behaviour of diffractive structures is principally different from the behaviour of refractive structures. The simple blazed grating discussed above resembles an assembly of micro-prismatic structures. However, the grating can deflect the incident light in directions which are not the same as geometrical paths of light through the equivalent (i.e. the same triangular shape but on a different scale) prismatic feature, which follows the refractive principle. This is actually obvious, even from the grating equation (see above), which implies that incident light is deflected in multiple directions given by the structure of the diffraction orders. Moreover, the deflection into one of the directions of the diffraction orders, which may not be the same as the direction of the beam refracted through the refractive micro-prism of equivalent shape (i.e. a scaled up period of the blazed profile), can be significantly more efficient (or even maximized) than the deflection into the direction of refraction on the said refractive micro-prism (in this respect, see and compare the top and bottom examples in FIG. 5(b)). Therefore, the design of grating features cannot simply follow the rules of refraction. In other words, the diffraction grating (even a blazed grating with a profile in the shape of an assembly of micro-prismatic features) is not just a scaled down version of a refractive micro-prismatic (or other refractive) structure, if the efficiency of deflection into the direction of refraction should be maximized. Even in the case where both micro-prismatic and diffraction gratings have the same sizes of features, the behavior (i.e. the ability to deflect an incident beam into a certain direction) of a grating structure optimized on diffraction principles may be different from the behaviour of a micro-prismatic structure optimized on refractive principles.

[0208] There now follows an explanation of the relationship between operational diffraction orders and feature sizes, which again is to be understood as being for non-limiting explanatory purposes only for aiding an understanding of certain embodiments of the invention, so it should not be construed as limiting the scope of the invention to any particular theory or theoretical model or embodiment.

[0209] A different grating structure may be designed to operate at much higher diffraction orders, enabling more wavelengths to reach efficiency equal to 1. However, increasing the order of operation of the diffraction grating may result in an increase of the size of grating features, which will eventually turn the grating rather into a refractive micro-structure (i.e. refraction will “dominate” over the diffraction).

[0210] In order to keep grating features (i.e. their depth, in particular) reasonably small (i.e. less than about 15 μm, especially less than about 10 μm, optionally less than about 5 μm, or perhaps even less than about 3 μm) so that they may be moulded easily into the plastics foils we preferably utilize in embodiments of this invention, the present inventor(s) focused on a task to find the lowest operational diffraction order of the grating that would ensure sufficient suppression of colour effects. By using more rigorous methods of calculating diffraction efficiency (for example the RCWA method, which is often used by persons skilled in the art for this purpose) and by experimenting with prototype diffractive structures, we discovered that gratings and also more complex diffractive structures (e.g. which have designs based on grating-like structures) may produce sufficiently achromatic light distribution patterns if they operate at an average diffraction order as low as 3.sup.rd. For optimum results the structure did not typically have to operate at a higher average order than 6.sup.th—this is illustrated in FIG. 4(a) of the accompanying drawings. This FIG. 4(a) shows the diffraction efficiency of the visible spectrum at multiple (plural) diffraction orders for a blazed grating with a period of 10 μm and profile depth 3.5 μm (the profile representation is shown in FIG. 4(a) adjacent the top left corner thereof). As was mentioned above, only a few wavelengths reach optimum efficiency at a given diffraction order, and only these wavelengths are re-directed by the diffractive structure into the same direction. The other wavelengths are actually re-directed into somewhat different directions. Using the equations above, grating parameters and the bandwidth of the efficiency curves on the graph of FIG. 4(a), the light of wavelengths within a half-width of the peak may actually be re-directed into a small cone of diffraction angles only several degrees wide (e.g. actually less than 5 degrees wide). Since those spectral peaks represent red, green and blue portions of the visible spectrum and they overlap spatially, they may produce a well achromatized diffraction pattern.

[0211] The modelled efficiency of peak wavelengths (i.e. distributed across the multiple orders) may be about 70%. The remaining energy is distributed among other lower or higher orders (i.e. not all of them are displayed on the graph of FIG. 4(a)). This may usually be considered as an undesirable effect, due to a decrease in the efficiency of the main optical function (as discussed in relation to the beam-splitting diffractive structure described above). However, we have unexpectedly discovered that mixing of high and low efficiency orders may contribute further to achromatization of the light distribution pattern at the exit of the diffractive structure.

[0212] The achromatization effect has been analyzed and illustrated here only by way of one example of a specific grating. However, a similar and/or reversed approach may be used by a designer not only for analysis but also for design of diffraction gratings or more complex diffractive structures which redistribute incident light into multiple directions, keeping the resulting light distribution curve achromatized. In reality the design problem may be even more complex owing to deviations from idealized structures (such as ideal blaze gratings), which may be caused by limitations in diffractive structure origination or replication processes. These deviations may manifest themselves as, for example, rounding of the sharp profile features, reduced angle of the side wall, surface roughness, etc. These deviations may also have a significant effect on the distribution of the diffraction efficiency at different orders—which is illustrated in FIG. 4(b) of the accompanying drawings. Therefore, also these deviations may have to be considered during the diffractive structure design stage.

[0213] However, we unexpectedly found that these imperfections and their effect on diffraction efficiency may contribute rather positively to smoothing out residual colour effects and also to suppressing or removing any undesirable sharp transitions or localized peaks in the light distribution or illumination patterns, which are often responsible for unacceptable glare at certain observation angles and/or inhomogeneity in the illumination pattern. This may actually often be a problem of conventional micro-structures, which need to be combined with additional “smoothing” elements (such as diffusers), while diffractive structures used in embodiments of the present invention may operate with a certain level of “smoothing” functionality inherently therein.

[0214] In practising some embodiments within the scope of the present invention, it may be advantageous to add one or more “smoothing” features to the diffractive structure of the relevant optical element(s). In the case or relief types of diffractive structures, such “smoothing” feature(s) may represent deviation(s) (i.e. typically in height) from the profile shape of the original diffractive structure. The size of such “smoothing” feature(s) may usually be smaller (e.g. at least about 2 times smaller) than the features of the original diffractive structure. In some cases the additive “smoothing” feature(s) may be included in the optical design of the function and structure of the diffractive structure, whereas in other cases it may be more practical to determine “smoothing” feature(s)′ size and/or density and/or depth of modulation and/or type of distribution experimentally.

[0215] All the above-described discoveries have led us to a novel use of high-density nano- or micro-structures (i.e. nano- or micro-structures with typical feature sizes below 10 μm) for illumination applications in luminaires, which may be capable of operating at white light and multiple operational diffraction orders, typically higher than 1′ and lower than 10.sup.th or 15.sup.th or 20.sup.th, and which may perform complex functions due to their ability to concentrate high numbers and diversities of nano- and micro-features, these features being typically of a low aspect ratio, thereby making these structures easily manufacturable in large volumes using cheap and very light carriers (e.g. plastics foils), and which can provide an achromatic and smooth appearance of a luminaire as well as light distribution or illumination patterns either with or without the aid of additional “smoothing” features.

[0216] We turn now to a description and discussion of various optional features of some further example embodiments of the invention, which involve the use of stacked or layered combinations of plural optically functional elements, layers or surfaces.

[0217] In certain embodiments of the invention a nano- or micro-structured substrate or surface or surface layer thereof performing a certain optical function may be replaced by two or more layers (i.e. substrates or surfaces or surface layers thereof) forming a stack of layers, each layer performing the optical function only partially, and the entire stack of layers performing the overall optical function fully, as per the original nano- or micro-structured layer or its close equivalent.

[0218] Although using a stack of layers instead of one layer may seem counterproductive, for example from the optics efficiency standpoint (since each layer introduces new boundaries on which the incident light may reflect back towards the source(s), which may further get absorbed or attenuated or redirected into undesirable directions) and/or the cost standpoint (since the use of more layers and their need for physical assembly may be more expensive), there may actually be advantageous in some embodiments of the present invention, given their attractiveness from a production standpoint. They may also be advantageous in that they may enable an optical function to be designed and exploited which may not be possible or may be difficult to achieve by using a known type of nano- or micro-structure which relies on a single layer configuration. Further, they may also be advantageous in that they may enhance a given pre-existing optical function of an originally single layer. In the end these potential additional benefits may even prove the plural-layer, stacked approach to be a cheaper solution in comparison with potential other alternatives.

[0219] A structure performing deflection of light incident perpendicularly to the layer surface into a higher angle may be used as an example to illustrate certain advantages of replacing a single nano- or micro-structured layer with a stack of layers. One example of this is illustrated in FIG. 5(a) of the accompanying drawings.

[0220] As shown in FIG. 5(a) (left-hand side), the deflection of incident light into certain angles may be performed in a basic manner for example by a diffractive structure in the form of e.g. a blazed diffraction grating. Considering normal incidence onto the grating surface, a person skilled in the art may design the grating period, the blazed profile angle and the preferred diffraction order for a given wavelength such that the grating deflects the incident beam by angle α (see FIG. 5(a). However, the resulting efficiency of such a grating may be low, and even optimization of the shape of the grating profile may not be able to increase the efficiency to a desirable level. Moreover, regardless of the diffraction efficiency, the structure may be difficult to produce or reproduce, owing to the high structure depth and/or high aspect ratio of the grating profile (see FIG. 5(a), left-hand side). However, by replacing such a grating structure with a stack of two grating structures in such a way that each grating performs partial deflection, for example at angle α/2 (as shown in FIG. 5(a), right-hand side), they will be less dense and shallower than the original grating, and thus will be easier to produce and reproduce. In many cases the overall efficiency of the deflection by the stack will be higher than the efficiency of a single grating, in spite of additional reflections introduced by additional boundaries of the second grating. Also, since the production of the gratings in the stack is much easier, it may be even more cost-effective to produce and use two such layers with simpler grating structures, rather than using just one single layer with a grating structure that is more difficult to produce/reproduce.

[0221] In some embodiments the nano- or micro-structures in the stack of layers may be designed such that their structure is the same in all layers (although not necessarily the degree of their partial optical function), which may further reduce the cost of the mass production, including the production of the primary structure (i.e. the mould) as well as the multiplication (i.e. replication) process—especially since only one type of structure needs to be produced.

[0222] It may be at the designer's discretion to decide how the desired optical function may be split as between the multiple (i.e. plural) layers in the stack (i.e. how much of the optical function the structure of each layer performs), so that the entire stack performs the desired overall function as a whole.

[0223] In some embodiments the desired overall optical function may not be able to be produced by one layer only, but may be producible only by a stack of layers. An example of such an optical function which cannot be produced by a single layer configured in a certain way, but may be produced by a stack of the layers, is illustrated in FIG. 5(b), in which the top and bottom halves show two slightly different but closely related arrangements.

[0224] Referring to FIG. 5(b), top half: A micro-structure consisting of micro-prisms oriented away from the incident light can be used to deflect light (in a similar manner to a diffraction grating as shown in FIG. 5(a) (left-hand side). However, if one wishes to achieve large deflection angles (e.g. higher than ˜45°, for a refractive index of the micro-prisms of ˜1.5), the incident beam may get totally reflected from the prisms and would not exit the structure at the desired angle (see FIG. 5(b), top half, left-hand side). However, the prism structure may in principle be able to be configured to refract the incident beam into a higher angle, but such a beam may still get totally reflected on the opposite side of the layer, in which case this may not represent an optimum solution. In contrast, however, the stacked arrangement shown in FIG. 5(b), top half, right-hand side, does present a workable and useful solution.

[0225] In a similar arrangement, FIG. 5(b), bottom half, illustrates an optical function (i.e. deflection to higher angles) which, although it cannot be performed with high efficiency by one blazed diffraction grating only of a given orientation, can be performed efficiently by two stacked gratings of the same type and orientation, each performing a respective portion of the overall deflection, and in total they perform the desired total deflection, as FIG. 5(b), bottom half illustrates.

[0226] In other embodiments an optical function of only a portion of a nano- or micro-structure on one layer may be split into multiple nano- or micro-structures in a stack of layers. FIG. 5(c) shows an example of this—in which a collimating Fresnel lens is employed.

[0227] The zonal structure of such a lens becomes denser with increasing distance from the lens centre. The optical function of the denser areas of the lens is split between two lens structures on two layers. The central portion of the original lens is now part of the top layer only and the second layer does not contain any structure at the respective central area. The partial split of certain areas only, typically those which are difficult to produce, and the leaving of the less dense areas untouched, may be an advantageous approach, since it may reduce the total number of zones in the stack and therefore also a potential scatter which may typically be generated at the zone boundaries (i.e. at sharp transitions between the zones).

[0228] As already mentioned above, the optical function of the whole original layer or any of its portions may be split into two or more partial functions, each partial function being performed by a structure associated with a respective layer in the stack of layers replacing the original layer, with each such structure being designed to perform the partial function to a certain degree of the original function, and all partial functions being performed as per the original optical function or its close equivalent. In other words, the stack of layers redistributes the incident light into the same or similar light distribution pattern as would be produced by the structure of the original layer, unless the original structure alone cannot produce the desired light distribution pattern or cannot produce it with sufficient efficiency, and it can be produced per-partes by the structures associated with the layers in the stack.

[0229] In some embodiments, therefore, the optical functions associated with different portions of the original structure may be split into multiple layers in such a way that the respective portions of the structure in a given layer perform respective partial functions to different degrees for each portion, and in some instances this may be done differently for each layer in the stack.

[0230] Since the structures performing optical functions in the stack of layers may be physically separated, the redistribution of the incident light may somewhat differ from the redistribution performed by a structure based on a single layer. Therefore, the optical function of the structures in the stack of layers may somewhat differ from the optical function of a structure based on a single layer. To make sure these functions are almost the same, any separation between the structures in the layers may need to be minimal and preferably should not exceed the thickness of one or two of the layers. This principle is illustrated in FIG. 5(d), right-hand side. Also, the lateral shift between a beam incident on a particular layer and the next one preferably should not exceed the separation distance between neighbouring structures in the stack. In most cases this may be easily achieved, since the layers are in any event very thin.

[0231] In such stacked-layer embodiments the configuration of the plural layers replacing the original layer may not be limited to the configurations exemplified in FIGS. 5(a), 5(b) and 5(c), i.e. in which the structure of the replacing layers has the same orientation as the original structure (i.e. towards the incident beam) and an air gap is left between the replacing layers. Many other configurations may be used as well—and FIGS. 5(d) and 5(e) illustrate that by way of a collection of additional example stack arrangements.

[0232] Throughout the description and claims of this specification, the words “comprise” and “contain” and linguistic variations of those words, for example “comprising” and “comprises”, mean “including but not limited to”, and are not intended to (and do not) exclude other moieties, additives, components, elements, integers or steps.

[0233] Throughout the description and claims of this specification, the singular encompasses the plural unless expressly stated otherwise or the context otherwise requires. In particular, where the indefinite article is used, the specification is to be understood as contemplating plurality as well as singularity, unless expressly stated otherwise or the context requires otherwise.

[0234] Throughout the description and claims of this specification, features, components, elements, integers, characteristics, properties, compounds, chemical moieties or groups described in conjunction with a particular aspect, embodiment or example of the invention are to be understood to be applicable to any other aspect, embodiment or example described herein unless incompatible therewith or expressly stated otherwise.