1. Field of the Invention
The present invention is directed to a chromatic diffractive optical element (DOE) corrector. More particularly, the present invention is directed to a DOE corrector formed on two surfaces for use with multiple wavelengths.
2. Description of Related Art
Numerous applications require a single objective lens to be used for multiple wavelengths. In many such cases, there are three wavelengths for which the lens is to be used. For example, in blue laser based digital video disc (DVD) systems, it is desirable that these systems remain backwards compatible with red laser DVD systems and compact disc (CD) systems, which use infrared (IR) lasers. Each different color may require different focal lengths and/or different numerical apertures.
One conventional solution includes using one surface having a first phase function providing a high first order efficiency for red and a second phase function providing a high first order efficiency for IR, while providing high zeroth order efficiency for blue. In order to achieve this, a thick DOE needs to be used. For example, to make phase levels that are multiples of 2π for the blue wavelength, the phase delay for a transmission DOE is given by:
2π(n−1)d/λ (1)
where n is the index of refraction of the DOE for blue light, d is the thickness of the DOE and lambda is the wavelength of the blue light. The 2′ thickness D for each wavelength and corresponding refractive index is given by:
D=λ/(n−1) (2)
Thus, for example, if a DOE is designed to transmit 407 nm (blue light), impart the first phase function on 650 nm (red light) and impart the second phase function on 785 nm (IR), since 785 nm is nearly twice 407 nm, levels which effect 785 nm but would not effect 407 nm need to be determined. The phase levels would be determined from integer multiples M of D that do not effect the blue light. For most materials this results in very thick elements with relatively low efficiency, especially in the IR, e.g., less than 50%.
In this current solution using one surface to diffract two of the three wavelengths, phase levels for a first phase function at a first wavelength, e.g., 650 nm, are selected that correspond to a zero phase delay (modulo 2π) or about zero phase delay for the other two wavelengths, e.g., 407 nm and 785 nm. For a second phase function at a second wavelength, e.g., 785 nm, phase levels are chosen to correspond to zero for the other two wavelengths, e.g., 407nm and 650 nm. Assume the phase levels are provided in a material having no dispersion and a refractive index of 1.46. For simplification, consider only solutions MD for blue light. In designing the second phase function and restricting the multiple of D to M≦40, and then looking for values of M within this range where the phase angle for the red light is less than ±20°, then there are five values for M which satisfy this condition. However, these phase levels also need to provide phase angles close to 0°, 90°, 180° and 270° for a four phase level diffractive for the IR light. Only three of the five values are within ±20° of these target values. A diffractive other than a binary diffractive would thus need to be made with more than a thickness of M=40 at 407 nm, i.e., more than 35 microns thick.
The actual is problem is even more severe than in this simplified case, since the refractive index of fused silica actually decreases as wavelength increases, i.e., positive dispersion. Thus, the refractive index of fused silica is actually 1.470 at 405 nm, 1.457 at 650 nm, and 1.453 (at 785 nm). This dispersion results in the blue and IR light becoming even more closely harmonic, as can be seen with reference to the following phase delay ratio of Equation (3):
Without dispersion, i.e., when nB=nIR, this phase delay ratio is 1.93, while in fused silica, it becomes 2.01. With these refractive indices, when M is selected to be an integer for the blue light, then phase values for the IR light will all be within ±10° of either 0° or 180° for all values of M<75, resulting in a DOE having a thickness of at least 65 microns to realize even a four level DOE.
Thus, when using fused silica, the conventional approach is limited to a binary DOE for IR light, unless a very thick diffractive structure, e.g., much thicker than 65 microns, is used. Such a binary DOE has very low efficiency, roughly 40%, compared with roughly 80% for a four-level DOE. Thicker DOEs are a problem, as they are more difficult to fabricate, and generally don't perform as well due to shadowing. Shadowing is due to the relative aspect ratios of the etch depth and the period. For manufacturability, this aspect ratio should be less than about two, and the etch depth should less than about 35 microns. Materials other than fused silica, such as plastic, have been used, as these materials have a larger dispersion than for fused silica, allowing the phase delay ratio to exceed 2.0 and move further from the harmonic. However, in these higher dispersion materials, the proper operation of the first phase function for the red light becomes a problem, especially while achieving proper operation of the second phase function.
The present invention is therefore directed to a DOE corrector, which substantially overcomes one or more of the problems due to the limitations and disadvantages of the related art.
It is a feature of the present invention to provide a DOE corrector on two surfaces.
It is another feature of the present invention having a high efficiency in a first order for two wavelengths and a high efficiency in the zero order for a third wavelength.
It is yet another feature of the present invention to provide a thinner DOE corrector.
It is still another feature of the present invention to provide a DOE corrector having multiple levels.
At least one of the above and other features and advantages of the present invention may be realized by providing a diffractive optical element (DOE) corrector for use with three different wavelengths, a first diffractive element on a first surface of a first material, the first diffractive element diffracting a first wavelength of the three wavelengths, while directing a majority of light of second and third wavelengths of the three wavelengths into a zero-th order, and a second diffractive element on a second surface of a second material, the second material being different from the first material, the second surface being different from and in an optical path of the first surface, the second diffractive element diffracting the second wavelength, while directing a majority of light of the first and third wavelengths into a zero-th order.
Each of the first and second diffractive elements may include a difference between phase levels of more than 2π for at least one of the three different wavelengths. The second and third wavelengths may have a substantially harmonic relationship, the second and third wavelengths being more harmonic in the first material and less harmonic in the second material. A phase delay ratio between the second and third wavelengths in the second material may be less than about 1.95 or greater than about 2.05. A phase delay ratio between the second and third wavelengths in the first material may be between about 1.95 and about 2.05. The second material may be provided directly on the first material. The second material may be secured to the first material. The second material may be more dispersive than the first material.
At least one of the above and other features and advantages of the present invention may be realized by providing an optical system, including a refractive optical element, and a diffractive optical element (DOE) corrector for use with three different wavelengths and aligned with the refractive optical element, the DOE corrector including a first diffractive element on a first surface of a first material, the first diffractive element diffracting a first wavelength of the three wavelengths, while directing a majority of light of second and third wavelengths of the three wavelengths into a zero-th order, and a second diffractive element on a second surface of a second material, the second material being different from the first material, the second surface being different from and in an optical path of the first surface, the second diffractive element diffracting the second wavelength, while directing a majority of light of the first and third wavelengths into a zero-th order.
Each of the first and second diffractive elements may include a difference between phase levels of more than 2π for at least one of the three different wavelengths. The refractive optical element may be received in a hole in a substrate. At least one of the first material, the second material and the substrate are secured together. The first material and the second material may be secured together. The second material may be more dispersive than the first material. The second and third wavelengths may have a substantially harmonic relationship, the second and third wavelengths being more harmonic in the first material and less harmonic in the second material.
At least one of the above and other features and advantages of the present invention may be realized by providing a method of creating a diffractive optical element (DOE) corrector for use with three different wavelengths, including forming a first diffractive element on a first surface of a first material, the first diffractive element diffracting a first wavelength of the three wavelengths, while directing a majority of light of second and third wavelengths of the three wavelengths into a zero-th order, and forming a second diffractive element on a second surface of a second material, the second material being different from the first material, the second surface being different from and in an optical path of the first surface, the second diffractive element diffracting the second wavelength, while directing a majority of light of the first and third wavelengths into a zero-th order.
The first material may be selected to have a harmonic phase delay ratio and the second material may be selected to have a non-harmonic phase delay ratio. The first material may be selected to have a first chromatic dispersion and the second material may be selected to have a second chromatic dispersion, the second chromatic dispersion being greater than the first chromatic dispersion. Two of the three wavelengths may be substantially harmonics of one another when there is no dispersion. The first and second materials may be secured to one another.
At least one of the above and other features and advantages of the present invention may be realized by providing a plurality of integrated micro-optical system, including a first wafer having a plurality of holes therein, an approximately spherical lens inserted each hole, a second wafer including a plurality of diffractive optical elements, each diffractive optical element aligned with each approximately spherical lens, the first and second wafers being secured together, each micro-optical system including an approximately spherical lens in a hole and a diffractive optical element.
A single integrated micro-optical system may be separated from the plurality of micro-optical systems. The diffractive optical element may correct for chromatic dispersion of the micro-optical element.
The above and other features and advantages of the present invention will become readily apparent to those of skill in the art by describing in detail embodiments thereof with reference to the attached drawings, in which
U.S. Provisional Application No. 60/608,375 filed on Sep. 13, 2004 and entitled: “Chromatic Diffractive Optical Element Corrector,” is hereby is incorporated by reference herein in its entirety for all purposes.
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. The invention may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the invention to those skilled in the art. In the drawings, the thickness of layers and regions are exaggerated for clarity. It will also be understood that when a layer is referred to as being “on” another layer or substrate, it may be directly on the other layer or substrate, or intervening layers may also be present. Further, it will be understood that when a layer is referred to as being “under” another layer, it may be directly under, or one or more intervening layers may also be present. In addition, it will also be understood that when a layer is referred to as being “between” two layers, it may be the only layer between the two layers, or one or more intervening layers may also be present. Like numbers refer to like elements throughout.
As noted above, the use of fused silica for DOE correctors does not work well for beams at 405 nm and 785 nm, since the phase delay ratio of these wavelengths in fused silica if very close to 1:2, making the only manufacturable harmonic structure practical a binary lens, which is very inefficient. Therefore, a solution that can provide a phase delay ratio between two wavelengths of interest that is not so close to a harmonic, while allowing proper diffracting of a third wavelength, is needed.
In order to address the problems of harmonic influence, a DOE corrector 5 in accordance with an embodiment of the present invention is shown in
Conventionally, when designing a diffractive which is to provide a high efficiency zero-th order beam for a particular wavelength, the etch depths in the diffractive are set to be 2π multiples for that wavelength, so the diffractive structure essentially does not effect light at that wavelength, i.e., the phase delay will be negligible. In accordance with the present invention, in designing the first diffractive 12 for use with the red light, the diffractive etch depths are limited to be 2π multiples of the IR light, rather than the blue light, since the IR light is practically a harmonic of the blue light. In other words, the diffractive etch depths are limited to be 4π multiples of the blue light. After determining thickness values that are close to those multiples of 4π, those that also have phase values at or near fractional phase values of 2′ for the red light are chosen. For example, if a sixteen phase level structure is to be provided in fused silica, then the target (modulo 2π) phase values for the red light are given by:
2π*i/16 (4)
where i varies from 0 to 15.
On the non-harmonic phase delay side, the second diffractive element is designed to provide a high efficiency first order for the IR light. The second diffractive element is designed by selecting a maximum phase error for each wavelength not to be effected by the second diffractive element, here the blue and red light. Then, all levels that are equal to integer multiples of 2π, within the maximum phase error, are determined for the blue light. The maximum phase error for each wavelength may be the same. Then those levels that are not also within a maximum phase error of 2π for the red light are eliminated. Finally, the remaining levels are then selected in accordance with equation (1) for the IR light. The non-harmonic phase delay material may be TiO2, SU-8, ultra-violet (UV) curable polymers, or thermally curable polymers having an appropriate dispersion.
Numerous levels satisfying the above conditions are available for creating both diffractive elements, allowing efficient DOE corrector to be created. For example, if using fused silica and only diffracting 660 nm into the first order, while 407 nm and 785 nm are substantially directed into the zero-th order, i.e., the etch depths are at 2π multiples of 785 nm, within a 20 degree error and restricting M to less than twenty, four levels satisfy these requirement, i.e., M=0, M=2, M=14 and M=16 for 407 nm. Better performance may be realized in practice by also considering etch depths that are not exact 2π multiples of blue light, e.g., within a 20 degree error as for the IR. Using this method, if the maximum etch depth of the fused silica material is nine microns, a practical diffractive optical element may be formed in the fused silica having between four and twelve levels. If the maximum etch depth of the thin film, e.g., a UV curable polymer noted above, is fifteen microns, a diffractive optical element formed therein may have between four and eight levels. Again, the limitations on the etch depth is due to shadowing and vector diffraction effects due to the aspect ratio.
A specific example of a structure for the first diffractive element is shown in
Thus, in accordance with the present invention, a DOE corrector for use with three wavelengths may be formed by providing a first diffractive element in a harmonic phase delay material and a second diffractive element in a non-harmonic phase delay material. For example, assuming the harmonic relationships between the wavelengths is two, the phase delay ratio may be less than 1.95 or greater than 2.05 in the non-harmonic phase delay material, and within these bounds for the harmonic phase delay material. The DOE corrector 5 may face either direction. While the DOE corrector 5 shown in
Embodiments of the present invention have been disclosed. herein and, although specific terms are employed, they are used and are to be interpreted in a generic and descriptive sense only and not for purpose of limitation. For example, while a spherical lens has been illustrated, other shapes, using different alignment mechanisms, may be used. Accordingly, it will be understood by those of ordinary skill in the art that various changes in form and details may be made without departing from the spirit and scope of the present invention as set forth in the following claims.
This is a divisional application based on pending application Ser. No. 10/949,802, filed Sep. 27, 2004, the entire contents of which is hereby incorporated by reference.
Number | Date | Country | |
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Parent | 10949802 | Sep 2004 | US |
Child | 11647399 | Dec 2006 | US |