Pursuant to 35 U.S.C. §119 and the Paris Convention Treaty, this application claims the benefit of Chinese Patent Application No. 201310320167.1 filed Jul. 26, 2013, the contents of which are incorporated herein by reference. Inquiries from the public to applicants or assignees concerning this document or the related applications should be directed to: Matthias Scholl P.C., Attn.: Dr. Matthias Scholl Esq., 245 First Street, 18th Floor, Cambridge, Mass. 02142.
1. Field of the Invention
The invention generally relates to the field of composite waveplates, and more particularly to an alignment method for optical axes of a composite waveplate. The method of the invention is suitable for accurate alignment and calibration of optical axes of a composite waveplate consisting of two or more single crystal plates.
2. Description of the Related Art
A waveplate (also known as optical phase retardation plate) is an optical device commonly used in the fields of optical instrument design and optical measurement, and it can introduce a phase shift (also called phase retardation) between two orthogonal components of a polarized light and can be used to modulate or detect polarization states of the polarized light. A waveplate is also a crystal plate since it is generally produced from uniaxial or biaxial crystals (i.e. birefringent materials) such as quartz, mica, magnesium fluoride, gypsum, sapphire, and so on. A waveplate composed of one crystal plate is called a single plate, and a waveplate composed of two or more crystal plates is called a composite waveplate.
The composite waveplate is a combination of multiple crystal plates, and optical axes of the crystal plates are aligned to form certain angles (normally 90 or 0 degree). A biplate is the simplest and most commonly used composite waveplate composed of two crystal plates produced from identical or different materials and having optical axes perpendicular or parallel to each other. The biplate composed of two crystal plates produced from the same material features a retardance effect identical to a single plate produced from the same material when the optical axes of the biplate are perpendicular to each other, and the difference of the thicknesses of the two crystal plates is an equivalent optical path of the biplate, which make it possible to solve the problem of the single plate that it is too thin to manufacture and, thus, improves the accuracy of the waveplate. The biplate composed of two crystal plates produced from different materials is referred to as an achromatic composite waveplate since it is capable of eliminating the chromatic aberration of the waveplate. It is impossible for a single crystal plate to achieve the functions of the composite waveplate in improving accuracy and eliminating the chromatic aberration. Therefore, the composite waveplate is widely used in optical instrument design and optical measurement. In practice, to implement achromatic effect of retardance in a comparatively wide wavelength range, normally a more complex achromatic composite waveplate composed of multiple plates produced from the same or different materials is designed and produced, and angles between the optical axes of the crystal plates have optimally designed values.
In practical applications, to ensure overall retardance accuracy and measurement accuracy of the composite waveplate, alignment and calibration of the optical axes of the different crystal plates forming the composite waveplate are carried out with care.
Conventionally, alignment of the composite waveplate is conducted manually. In the manual method, one crystal plate is fixed firstly, and then the other crystal plate is manually rotated while the actual retardance of the composite waveplate is visually compared with a designed retardance. When a difference between the actual retardance of the composite waveplate and the designed retardance is acceptable, alignment thereof is completed. Although operation of the manual alignment method is comparatively simple, alignment accuracy thereof cannot be guaranteed, which makes it difficult to meet requirement for high measurement accuracy. Another alignment method for the waveplate is a light extinction method, in which the waveplate is disposed between two polarizers perpendicular to each other, and alignment of the optical axes of the waveplate is conducted according to the light extinction of the emitted light from one polarizer disposed after the waveplate in a direction of light propagation. However, the light extinction method has one problem because light extinction often occurs at one specific wavelength, and it is difficult to determine whether the optical axes of the waveplate is accurately aligned according to light extinction of the single specific wavelength. To solve this problem, laser light sources with different wavelengths need to be used, and correspondingly optical paths need to be adjusted in accordance with the different wavelengths, which results in complex operation and low alignment accuracy.
R. W. Collins et al. at University of Pennsylvania disposed a composite waveplate to be aligned on a high-accuracy rotating table, placed the high-accuracy rotating table on a sample stage of a rotating-analyzer ellipsometer, and set a polarization generation arm and a polarization detection arm of the rotating-analyzer ellipsometer in a straight-through mode to measure the amplitude ratio of the polarized light passing through the composite waveplate. During alignment, the high-accuracy rotating table controlled the rotation of the crystal plates, and the alignment of the composite waveplate was carried out by adjusting the high-frequency oscillations of the amplitude ratio of the polarized light passing through the composite waveplate and measured by the ellipsometer (see, Journal of the Optical Society of America A, Vol. 18, page 1980-1985, 2001). Although the accuracy of this alignment method is higher than that of the conventional manual alignment method, final alignment accuracy is largely dependent on the experience of the operator due to the complexity of this alignment process. At present, there is another method for guiding the alignment of the composite waveplate by detecting and controlling the fluctuation amplitude in the spectral curve of retardance of the composite waveplate. This method is theoretically capable of aligning the composite waveplate with high accuracy. However, since fluctuation in the spectral curve of retardance of the composite waveplate is not sensitive to an alignment error between composite waveplates, alignment accuracy thereof cannot be ensured when the accuracy of a device for detecting retardance is not high enough.
In view of the above-mentioned problems, it is one objective of the invention to provide an accurate alignment method for the optical axes of a composite waveplate by detecting and eliminating fluctuation in spectral parameters of the composite waveplate.
In accordance with an exemplary embodiment of the invention, provided is an alignment method for achieving accurate alignment of the optical axes of the multiple single plates in the composite waveplate. For any two adjacent waveplates, the alignment method comprises steps of:
In a class of this embodiment, the spectral parameters of the composite waveplate comprise an equivalent rotary angle spectrum Pe(λ), an equivalent axis azimuth spectrum θe(λ), and an equivalent retardance spectrum δe(λ) that are calculated according to the following equations:
where mij represents four elements of a matrix obtained by multiplying M(δ1, θ1) by M(δ2, θ2); M(δ1, θ1) and M(δ2, θ2) are characteristic matrices of the two waveplates to be aligned; rij represents four elements of a matrix obtained by multiplying matrices
together, in which i=1 or 2, and j=1 or 2; δ1 and δ2 are retardances of the fixed waveplate and the rotatable waveplate; θ1 is an angle formed by the optical axis of the fixed waveplate vertically disposed and a horizontal direction; and θ2 is an angle formed by an optical axis of the rotatable waveplate vertically disposed and a horizontal direction.
In a class of this embodiment, the spectral parameters of the composite waveplate are detected via an ellipsometer, and advantageously via a dual rotating-compensator Mueller matrix ellipsometer.
In a class of this embodiment, the waveplates are disposed on a sample stage between a polarization generation arm and a polarization detection arm of the ellipsometer. Light beam emitted from the polarization generation arm is vertically projected on the composite waveplate, then passes through the polarization detection arm, and is finally detected so that the spectral parameters are obtained.
In a class of this embodiment, the rotatable waveplate is disposed on a high-accuracy rotating table fixed on the sample stage, and is capable of being rotated about the central axis by the high-accuracy rotating table.
In a class of this embodiment, when the composite waveplate comprises three or more single plates, the fixed waveplate is a fixed composite waveplate composed of multiple single plates having aligned axes.
Generally, people only care about a retardance of a waveplate, and normally a detection device can only determine the value of the retardance. Because the fluctuation amplitude of a retardance curve is insensitive to an alignment error of the composite waveplate and because the accuracy of the detection device is limited, alignment accuracy of the composite waveplate in methods of using the retardance curve cannot be ensured. The method of the invention can simultaneously detect fluctuation in spectral curves of an equivalent retardance spectrum, an equivalent axis azimuth spectrum, and an equivalent rotary angle spectrum of the composite waveplate. Since the fluctuation in the spectral curves of the equivalent axis azimuth spectrum and the equivalent rotary angle spectrum is highly sensitive to the alignment error of the composite waveplate, the method of the invention achieves accurate alignment of the composite waveplate even when the detection accuracy of the detection device for the spectral parameters is limited.
In the invention, one single plate of the composite waveplate to be aligned is fixed in the optical path and referred to as the fixed waveplate. The other single plate is connected to the rotating device and referred to as a rotatable waveplate. The rotatable waveplate is parallel to the fixed waveplate and is capable of continuously be driven by the rotating device to rotate with respect to the fixed waveplate. The polarized light is vertically projected on the fixed waveplate, and is emitted from the rotatable waveplate after passing through the fixed waveplate and the rotatable waveplate. The detector is used for detecting and analyzing the light intensity signal of the light emitted from the rotatable waveplate in order to obtain the spectral parameters (Pe(λ), θe(λ), and δe(λ)) of the composite waveplate composed of the fixed waveplate and the rotatable waveplate.
In the invention, if the differences ΔPe(λ), Δθe(λ), and Δδe(λ) are greater than preset values (the preset values are the maximum values of the differences ΔPe(λ), Δθe(λ), and Δδe(λ) allowed in accordance with the required alignment accuracy and can be determined based on actual requirement for the accuracy), the rotatable waveplate is rotated and fluctuation amplitudes of the differences ΔPe(λ), Δ↓e(λ), and Δδe(λ) are detected. The rotatable waveplate is rotated in the same direction as the previous one if the fluctuation amplitudes decrease, and is rotated in a reverse direction if the fluctuation amplitudes increase until the fluctuation of the differences ΔPe(λ), Δθe(λ), and Δδe(λ) are smaller than the preset values; and then the alignment of the composite waveplate is completed.
In the invention, if the composite waveplate comprises multiple single plates, two single plates are chosen and aligned with respect to each other according to the above-mentioned steps, and are then fixed. Next, the fixed waveplates as a whole are treated as a single plate, and the above-mentioned steps are repeated until all single plates are aligned to each other so that the alignment of the composite waveplate is completed.
Compared to a conventional alignment method for optical axes of a composite waveplate, the alignment method of the invention detects and controls the fluctuation amplitudes of the three equivalent spectral parameters, including the equivalent retardance spectrum, the equivalent axis azimuth spectrum, and the equivalent rotary angle spectrum of the composite waveplate, via an optical detection and analyzing system according to the equivalent model of the composite waveplate, whereby achieving high accuracy alignment of the optical axes of the composite waveplate. The invention features simple operation, controllable alignment accuracy, and wide application prospect in optical instrument design and optical measurement.
For clear understanding of the objectives, features, and advantages of the invention, detailed description of the invention will be given below in conjunction with accompanying drawings and specific embodiments. It should be noted that the embodiments are only meant to explain the invention, and not to limit the scope of the invention.
To clearly illustrate an alignment method for optical axes of a composite waveplate of the invention, a dual rotating-compensator Mueller matrix ellipsometer is illustratively and advantageously used for detection of spectral parameters of the waveplate.
As shown in
where i represents the imaginary unit, and δ is formulated as the following equation (2):
where λ represents a wavelength; dn represents a birefringence of the materials forming the waveplate at a wavelength of λ; and d represents a thickness of the waveplate.
A biplate with an arbitrary angle α between the optical axes of the two component waveplates can be expressed by an equivalent model of the following equation (3):
where δe, θe, and Pe respectively represent an equivalent retardance, an equivalent angle between the fast axis and the x axis, and a possible equivalent rotary angle of the composite waveplate.
As shown in
where δ1 and δ2 are retardances of a first waveplate and a second waveplate of the biplate along the propagation direction of light; θ1 is an angle formed by an optical axis F1 of the first waveplate along the propagation direction of the light and the x axis; θ2 is an angle formed by an optical axis F2 of the second waveplate along the propagation direction of the light and the x axis; an angle formed by the two optical axes F1 and F2 is α=|θ2−θ1|; mij (i=1, 2; and j=1, 2) represents four elements of a matrix obtained by multiplying a matrix M(δ1, θ1) by M(δ2, θ2); and M(δ1, θ1) and M(δ2, θ2) are characteristic matrices of the two waveplates obtained from the above equation (1).
By simultaneously solving equations (3) and (4), expressions of δe, θe and Pe can be obtained, in which Pe and θe are firstly solved as the following equations (5) and (6):
By substituting equation (3) into equations (4)-(6), equation (7) is obtained:
then δe is solved as follows:
where rij (i=1, 2; j=1, 2) represents four elements in a matrix obtained by multiplying a
as shown in equation (7).
When the optical axes of the two waveplates are perpendicular to each other, namely α=|θ2−θ1|=90°, it can be deduced from equations (5)-(8) that Pe=0, θe=θ1, and δe=δ1−δ2. Therefore, when the optical axes of the biplate is perfectly aligned, namely the angle between optical axes of the two single plates forming the biplate is 90°, the equivalent spectral parameters Pe(λ), θe(λ), and δe(λ) of the composite waveplate are determined by the performance of the two single plates. If there is an alignment error ε between the optical axes of the two single plates forming the biplate, namely α=|θ2−θ1|=90°+ε, the differences ΔPe(λ), Δθe(λ), and Δδe(λ) between the equivalent spectral parameters Pe(λ), θe(λ), and δe(λ) of the composite waveplate and the ideal values Pe0(λ), θe0(λ), and δe0(λ) corresponding thereto may have certain fluctuation, and amplitudes of the fluctuation are dependent on the alignment error ε.
As shown in
As shown in
The method of the invention will be described below in details using a dual rotating-compensator Mueller matrix ellipsometer as an example:
(1) adjusting the dual rotating-compensator Mueller matrix ellipsometer to a straight-through (transmission) measurement mode; as shown in
(2) fixing a single plate of a composite waveplate to be aligned on a sample stage 5 so that this single plate functions as a fixed waveplate 7, and vertically projecting the light beam emitted from the polarization generation arm 2 on the fixed waveplate 7;
(3) connecting another single plate of the composite waveplate to be aligned to a high-accuracy rotating table 9 so that this single plate functions as a rotatable waveplate 8, disposing the high-accuracy rotating table 9 on the sample stage 5, and arranging the rotatable waveplate 8 in parallel to the fixed waveplate 7. Both of the rotatable waveplate 8 and the fixed waveplate 7 are perpendicular to the light beam. The high-accuracy rotating table 9 is hollow so that the light beam emitted from the composite waveplate to be aligned can enter the polarization detection arm 3. The high-accuracy rotating table 9 is connected to a step motor 10, and a step motor controller 11 is capable of controlling the step motor 10 to drive the high-accuracy rotating table 9 to rotate with high accuracy and definition. In this way, the rotatable waveplate 8 rotates with respect to the fixed waveplate 7;
(4) measuring the composite waveplate to be aligned via the dual rotating-compensator Mueller matrix ellipsometer, namely analyzing the light intensity signal detected by using the detector 4 and the computer 6, and obtaining spectral parameters Pe(λ), θe(λ), and δe(λ) of the composite waveplate according to an equivalent model of the composite waveplate built in equations (3) to (8);
(5) comparing the spectral parameters Pe(λ), θe(λ), and δe(λ) of the composite waveplate with the ideal spectral parameters Pe0(λ), θe0(λ), and δe0(λ), whereby obtaining differences ΔPe(λ), Δθe(λ), and Δδe(λ) therebetween;
(6) controlling the step motor 10 via the step motor controller 11 so that the high-accuracy rotating table 9 drives the rotatable waveplate 8 to rotate with respect to the fixed waveplate 7 at a certain angle, repeating steps (4) and (5), observing whether amplitudes of the differences ΔPe(λ), Δθe(λ), and Δδe(λ) increase or decrease, rotating the rotatable waveplate 8 in the same direction as described above if the amplitudes decrease, and rotating the rotatable waveplate 8 in a reverse direction if the amplitudes increase; and
(7) repeating step (6) until fluctuation of the differences ΔPe(λ), Δθe(λ), and Δδe(λ) disappears or the fluctuation amplitudes thereof are smaller than preset values, so that the alignment of the composite waveplate is completed.
It should be noted that the above description is illustratively based on a composite waveplate formed by two single plates. If the composite waveplate comprises more than two single plates, two single plates are chosen and aligned to each other according to the above-mentioned steps (1) to (7), and then fixed. Next the fixed waveplates as a whole are aligned to the next single plate, and steps (1) to (7) are repeated until all single-plates are aligned to each other, and at the time alignment of the composite waveplate is completed.
While particular embodiments of the invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention.
Number | Date | Country | Kind |
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2013 1 0320167 | Jul 2013 | CN | national |
Number | Name | Date | Kind |
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20050068529 | Montarou et al. | Mar 2005 | A1 |
Number | Date | Country | |
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20150029507 A1 | Jan 2015 | US |