1. Field of the Invention
The present invention relates to an interferometer, and more particularly to a double pass interferometer which obtains displacement information of an object to be measured from lights which have been reflected twice on a reference mirror and a measurement mirror, respectively.
2. Description of the Related Art
Conventionally, as an apparatus which measures a displacement of an object, controls a stage, or performs a various kind of length measurements, a laser interferometer has been used because of the features of the high accuracy and high resolution. For example, Japanese Patent Laid-Open No. 2006-112974 discloses a position detecting apparatus which detects a position displacement of an object using an interference length measurement by non-contact.
On the other hand, the measurement light 120b is reflected on a measurement mirror 40b and passes through a previous optical path to enter the PBS 20 again. In this case, because a light beam of the measurement light 120b is transmitted through a ¼ λ plate 30b twice and an S wave is converted to a P wave, it is reflected on the PBS surface 20p to be a light beam 130b and, similarly to the reference light 130a, enter the reflective device 50.
After that, the reference light 130a is transmitted through the PBS 20 again to be reference light 140a, and the measurement light 130b is reflected on the PBS 20 again to be measurement light 140b. The reference light 140a and the measurement light 140b are transmitted through the ¼ λ plates 30a and 30b twice, respectively. The reference light 140a and the measurement light 140b entered the PBS 20 again are multiplexed to be multiplexed light 150. An interference signal having a period of ¼ λ in accordance with a displacement of the measurement mirror 40b can be obtained by receiving the multiplexed light 150 by a light receiving device 160.
As shown in
For example, when a reflectance of an AR coat (an antireflective coating film) on the interface 210b is 0.2%, the interference signal generated by the ghost light which has been reflected on the interface 210b has an interference intensity of no less than around 9%, compared wave-optically to the interference intensity of a primary signal. Even if an ultralow reflective AR coat having a reflectance of 0.01% is adopted, the interference intensity is 2.5%.
On the electric signal outputted from the light receiving device 160, a sine wave signal caused by all ghost lights is superimposed. Therefore, the interference signal obtained by the conventional interferometer has a waveform as shown in
Commonly, sub-nanometer resolution can be obtained by electrically dividing the sine wave periodic signal modulated in accordance with the displacement of the object to be measured. However, if a component caused by the ghost light is superimposed, as shown in
The present invention provides a high-accuracy interferometer which suppresses an effect of ghost light.
An interferometer as one aspect of the present invention includes a light splitting device configured to split light from a light source apparatus into reference light and measurement light, a reference mirror configured to reflect the reference light which has been split by the light splitting device and enters the reference mirror from a first direction, a measurement mirror configured to reflect the measurement light which has been split by the light splitting device and enters the measurement mirror from a second direction, an optical system configured so that reflected lights from the reference mirror and the measurement mirror enters the optical system via the light splitting device, a reflective device configured to reflect lights from the optical system in order to irradiate corresponding one of the reflected lights on corresponding one of the reference mirror and the measurement mirror again, respectively, and a light receiving device configured to receive lights which have been multiplexed after irradiating corresponding one of lights twice on corresponding one of the reference mirror and the measurement mirror, respectively. The reference mirror and the measurement mirror are in a conjugate relation with respect to the reflective device, and at least one of the reference mirror and the measurement mirror is tilted so that a normal direction of at least one of the reference mirror and the measurement mirror differs from the first and the second direction.
Further features and aspects of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Exemplary embodiments of the present invention will be described below with reference to the accompanied drawings. In each of the drawings, the same elements will be denoted by the same reference numerals and the duplicate descriptions thereof will be omitted.
An interferometer of the present embodiment detects displacement information of an object (an object to be measured) as phase information of light, and it obtains the displacement information of the object by converting the phase information of the light into an electric signal.
Reference numeral 1 denotes a light source (a light source apparatus). The light source 1 emits laser light 11 (collimated light beam) which has a wavelength of λ (λ=633 nm). The wavelength λ of the laser light 11 is not limited to this, but the light source may emit a laser light which has a different wavelength.
Reference numeral 2 denotes a PBS (a polarizing beam splitter). The PBS 2 is a light splitting device which splits a light beam into two beams in accordance with a polarization component of incident light. In the top view of
Reference numerals 4a and 4b denote a reference mirror and a measurement mirror, respectively. Partial light of the incident light from the light source 1 to the PBS 2 is reflected in a first direction on the PBS surface 2p, and enters the reference mirror 4a as a reference light 12a. The other partial light of the incident light to the PBS 2 is transmitted through the PBS surface 2p, and enters the measurement mirror 4b from a second direction as a measurement light 12b. As shown in
The reference mirror 4a is arranged with a tilt at an angle θ so that a normal direction of its mirror surface differs from an optical axis direction (a first direction) of the reference light 12a reflected on the PBS surface 2p. Similarly, the measurement mirror 4b is arranged with a tilt at an angle θ so that a normal direction of its mirror surface differs from an optical axis direction (a second direction) of the measurement light 12b transmitted through the PBS surface 2p. In the present embodiment, for example the angle θ is set to 0.5°. In the description of the present embodiment, when viewed from the elevation view of
Therefore, reference light 13a after reflected on the reference mirror 4a is a light beam with a tilt at an angle 2θ with respect to the reference light 12a before entering the reference mirror 4a. Similarly, measurement light 13b after reflected on the measurement mirror 4b is a light beam with a tilt at an angle 2θ with respect to the measurement light 12b before entering the measurement mirror 4b.
Reference numeral 6 denotes a lens system (an optical system). The reference light 13a reflected on the reference mirror 4a is reflected on the PBS surface 2p and enters the lens system 6 at an angle 2θ. Similarly, the measurement light 13b reflected on the reference mirror 4b is transmitted through the PBS surface 2p and enters the lens system 6 at an angle 2θ. Thus, the lens system 6 (the optical system) is configured so that the reflected light (the reference light 13a) from the reference mirror 4a and the reflected light (the measurement light 13b) from the measurement mirror 4b enter it via the PBS 2. As shown in the elevation view of
In the present embodiment, the lens system 6 is used as an optical system that the reference light 13a and the measurement light 13b enter, but the embodiment is not limited to this. Instead of the lens system 6, a reflective system can also be used.
In the embodiment, the reference mirror 4a and the measurement mirror 4b are positioned so that each passing position of the reflected lights in the lens system 6 is symmetric with respect to a central axis of the lens system 6. In other words, as shown in
The present embodiment is not to this, but the angle of the reference mirror 4a may be set to an angle differing from that of the measurement mirror 4b or these mirrors may be tilted in different directions from each other. In the embodiment, at least one of the reference mirror 4a and the measurement mirror 4b has only to be tilted. In this case, at least one of the normal directions of the reference mirror 4a and the measurement mirror 4b is tilted with respect to the first direction and the second direction.
Reference numeral 5 denotes a reflective device. The reference light 13a and the measurement light 13b which have entered the lens system 6 at an angle 2θ are, as shown in the elevation view of
The reflective device 5 is in a conjugate relation with the reference mirror 4a and the measurement mirror 4b. Therefore, in the elevation view of
Reference numeral 16 denotes a light receiving device (a photo detector). The light receiving device 16 receives a multiplexed light 15 which has been multiplexed by being irradiated twice on each of the reference mirror 4a and the measurement mirror 4b. The multiplexed light 15 enters the light receiving device 16 at the same angle as that of the laser light 11.
Thus, the multiplexed light 15 (a primary light beam in a double pass interferometer) enters the light receiving device 16 at the same angle as that of the laser light 11. Therefore, it becomes an interference signal having a period of ¼ λ at a maximum which repeats uniform blinking on the entire surface of the light receiving device 16.
Next, stray light (ghost light) which is generated by an interferometer of the present embodiment will be described.
In the present embodiment, the reference light 13a and the measurement light 13b that are light beams returned from the reflective device 5 will be considered. After the reference light 13a and the measurement light 13b enters the PBS 2, parts of the lights reflect on an AR coating surface (an antireflective coating surface) at each of interfaces 21aa and 21bb between the PBS 2(the prism) and the air. The ghost lights 15a and 15b reflected on the AR coating surface of the interfaces 21aa and 21bb, similarly to a principal light beam (the reference light and the measurement light), enter the light receiving device 16 to generate an interference signal.
However, in the elevation view of
In the present embodiment, as shown in
For example, it is considered that the interference pattern of the ghost light 15a reflected on the interface 21aa is generated by the intensity of around 9% compared to the interference pattern intensity of the principal light beam, as described in the conventional art. In this case, when a diameter φ of the light receiving area is 2 mm and the tilt angle θ of each of the reference mirror 4a and the measurement mirror 4b is 0.5°, the interference pattern generated caused by the ghost light is a stripe pattern with a pitch p of 36 μm. The rate of the signal having a period of ½ λ which is caused by the ghost light superimposed on an electric signal is only 0.16% of a main signal. Because this is a deterioration of only ±0.04 nm as linearity, the error can be reduced to the extent that there is no problem at all even if it is an ultra-high accurate length measurement of sub nanometer level. The same is true for the other interfaces 21b, 21bb, and 21a. Therefore, even if deterioration factors in all of these four interfaces are added, a periodic error of ±0.16 nm is only generated. Accordingly, the length measurement can be performed with extremely high accuracy.
In the present embodiment, when the light receiving area of the light receiving device 16 is a circle having a diameter D, the pitch p may be set so as to be shorter than the diameter D. On the other hand, since sin 2θ is equal to or less than 1, the pitch p is not shorter than a wavelength λ. Therefore, if the pitch p is set to the range represented by expression 2, an averaging effect can be improved in the present embodiment.
Furthermore, when a distance x between the reference mirror 4a and the PBS 2 is equal to a distance r between the measurement mirror 4b and the PBS 2, a wave optically equivalent optical path position of the reference light and the measurement light is obtained. Therefore, the optical path length of light passing through the glass optical path matches the optical path length of light passing through the air.
Therefore, a stable measurement can be performed in the long term without being influenced by the state change of the atmosphere relating to an air refractive index such as atmospheric pressure, temperature, or humidity.
When the amplitude is averaged in a state where the diameter D of the light receiving area is equal to or more than 0.5 mm, the wavelength of the light source is 850 nm, and the number of the patterns in the light receiving surface is equal to or more than 0.5, it is preferable that the tilt angle θ of each of the reference mirror 4a and the measurement mirror 4b in the present embodiment is set to be equal to or more than 0.1°. In a conventional interferometer which was made so as not to tilt a reference mirror or a measurement mirror, it is predicted that the error of the tilt angle is equal to or less than 0.1° and the effect of the present invention can not be obtained.
The light source apparatus (the light source 1) in the present embodiment is an apparatus which generates collimated light, but is not limited to this. For example, even when a divergent light source is used instead of the light source generating the collimated light, the same effect as that of the light source 1 can be obtained by using a lens system as a collimate unit which collimates a divergent light beam. In this case, the same effect as that of the light source 1 can be obtained with a simple configuration by integrating the lens system as the collimate unit and the lens system 6, i.e. by constituting the lens system 6 as a part of the light source apparatus. In this case, the light from the divergent light source is changed to collimated light by the lens system 6 and enters the PBS 2.
According to the interferometer of the present embodiment, the reference mirror and/or the measurement mirror is set so as to be always tilted. Therefore, the ghost lights which have been reflected once on the reference mirror and once on the measurement mirror are multiplexed at an angle different from that of the light beams which have been reflected twice on the reference mirror and twice on the measurement mirror. Therefore, a lot of interference patterns (interference stripes) appear and are averaged on the light receiving device, and the error amount is considerably improved. Furthermore, the primary light beams which have been reflected twice on the reference mirror and twice on the measurement mirror are multiplexed at the same angle each other. Therefore, a uniform interference state is formed and the maximum interference intensity can be obtained.
Therefore, according to the present embodiment, a high-accuracy interferometer which suppresses the influence of ghost light can be provided.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions. For example, a Michelson interferometer has been described in the present embodiment, but is not limited to this. The present embodiment is also applicable to other interferometers such as a Fizeau interferometer.
Number | Date | Country | Kind |
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2008-125655 | May 2008 | JP | national |
The present application is a continuation of U.S. patent application Ser. No. 12/437,770, filed May 8, 2009, entitled “DOUBLE PASS INTERFEROMETER WITH TILTED MIRRORS”, the content of which is expressly incorporated by reference herein in its entirety. Further, the present application claims the benefit of priority from Japanese Patent Application No. 2008-125655, filed on May 13, 2008, the contents of which are hereby incorporated by reference herein in its entirety.
Number | Date | Country | |
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Parent | 12437770 | May 2009 | US |
Child | 13608960 | US |