1. Field of the Invention
The present invention relates generally to lasers, and more particularly, to external cavity lasers.
2. Related Art
The use of an external laser cavity with a spectrally selective element has been used for several decades to create a laser with a narrower spectral linewidth than is available with the non-wavelength selective minors in the laser cavity of the typical laser. In addition, the tenability of the spectrally selective element may create a laser with an agile wavelength that may be both narrow in line width and cover a broad tuning range. The spectrally selective element in many non-integrated external cavity lasers may be a diffraction grating. These diffraction gratings may be designed to meet a broad range of laser cavity needs such as size, efficiency, and dispersion. The tuning of the wavelength of the laser may be achieved by adjusting the grating angle of the diffraction grating with respect to the laser beam.
Tuning such a laser by merely adjusting the grating angle may result in the laser occasionally “hopping” from one cavity mode to another cavity mode. A cavity mode (referred to hereafter as a “mode”) refers to the integral number of half wavelengths of light at the tuned wavelength that fit within the optical cavity of the laser. Further, these hops from one mode to another are referred to as mode hops. Mode hops may result in the instability of the laser output by the laser system. Thus, it is desirable to reduce the number of mode hops that exist across a tuning range of the laser system.
Accordingly, there is a need for laser systems with improved mode hop performance over the tuning range.
According to a first broad aspect of the present invention, there is provided a laser system comprising:
a light source which provides light;
a lens which collimates the light to provide a collimated coherent light beam;
a diffraction grating which reflects at least a portion of a wavelength of light of the collimated coherent light beam towards the light source; and
a pivot arm connected to the diffraction grating, wherein the pivot arm pivots the diffraction grating to thereby adjust the wavelength of light reflected by the diffraction grating towards the light source as well as adjusting an optical path length.
According to a second broad aspect of the invention, there is provided a method for generating a coherent light beam comprising the following steps:
(a) providing a collimated coherent light beam; and
(b) pivoting a pivot arm connected to a diffraction grating to adjust a position of the diffraction grating, thereby adjusting a wavelength of light of the collimated coherent light beam reflected by the diffraction grating as well as adjusting an optical path length.
According to a third broad aspect of the invention, there is provided a laser system for generating a coherent light beam comprising:
means for providing a collimated coherent light beam;
means for reflecting at least a portion of a wavelength of light of the collimated coherent light beam; and
means for adjusting a position of the reflecting means to thereby adjust a wavelength of light of the collimated coherent light beam reflected by the reflecting means as well as adjusting an optical path length for the laser system.
The invention will be described in conjunction with the accompanying drawings, in which:
It is advantageous to define several terms before describing the invention. It should be appreciated that the following definitions are used throughout this application.
Where the definition of terms departs from the commonly used meaning of the term, applicant intends to utilize the definitions provided below, unless specifically indicated.
For the purposes of the present invention, the term “light source” refers to a source of electromagnetic radiation having a single wavelength or multiple wavelengths. The light source may be from a laser, a laser diode, one or more light emitting diodes (LEDs), etc.
For the purposes of the present invention, the term “coherent light beam” refers to a beam of light including waves with a particular (e.g., constant) phase relationship, such as, for example, a laser beam.
For the purposes of the present invention, the term “processor” refers to a device capable of executing instructions and/or implementing logic. Exemplary processors may include application specific integrated circuits (ASIC), central processing units, microprocessors, such as, for example, microprocessors commercially available from Intel and AMD, etc.
For the purposes of the present invention, the term “reflective device” refers to a device capable of reflecting light. Exemplary reflective devices comprise mirrors, diffraction gratings, including, for example, tunable transmission diffraction gratings, etc.
For the purposes of the present invention, the term “diffraction grating” refers to a device whose optical properties are periodically modulated which results in the incoming light to exit the grating with an angle that is dependent on the wavelength. Exemplary diffraction gratings may include reflective or transmission gratings.
For the purposes of the present invention, the term “transmission grating” refers to a diffraction grating that is on a transparent substrate which permits the non-diffracted light to be transmitted through the substrate. Exemplary transmission gratings comprise devices capable of diffracting a portion of light at a particular wavelength that passes through the device back along the same path on which the incoming light traveled, for example, by adjusting an angle of the device.
For the purpose of the present invention, the term “tunable transmission grating” refers to a Transmission grating in which the particular wavelength of light reflected may be adjusted.
For the purposes of the present invention, the term “reflective grating” refers to a diffraction grating that is on a reflective substrate which permits the non-diffracted light to be reflected from the substrate.
For the purpose of the present invention, the term “collimated light beam” refers to a beam of light comprising surfaces of approximately constant phase that are approximately parallel and normal to the direction of propagation. For example, in embodiments, a collimated light beam may have surfaces of constant phase that are as close to parallel as possible and normal to the direction of propagation.
For the purpose of the present invention, the term “tune” refers to adjusting a device to a desired state. For example, in exemplary embodiments, a diffraction grating may be tuned by adjusting the particular wavelength reflected or transmitted by the diffraction grating to a desired wavelength.
For the purpose of the present invention, the term “optical cavity” refers to a space between two reflective devices. Exemplary optical cavities may comprise the space between reflective devices in a laser system, such as, for example, the space between a reflective coating on a facet of a laser diode and a transmission grating, diffraction grating, mirror, etc.
For the purpose of the present invention, the term “external cavity” refers to a portion of an optical cavity that is external to a component of a laser system that is the source of the photons and optical gain. Exemplary external cavities comprise the portion of an optical cavity of a laser system between a laser diode and a reflective device (e.g., a Transmission grating) external to the laser diode, and usually provide control over the longitudinal and/or transverse mode structure of the laser.
For the purpose of the present invention, the term “mode number” refers to the number of half wavelengths of a particular wavelength of light that fits within an optical cavity.
For the purpose of the present invention, the term “mode hop” refers to an integral change in the mode number that occurs during tuning of laser.
For the purpose of the present invention, the term “substrate” refers to a layer of material. Exemplary substrates may include, for example, transparent materials, such as, for example, glass, plastic, etc.
Collimating lens 104 may be a high quality collimating lens, such as those commercially available. Although not illustrated in this embodiment, an optional half wave plate (HWP), such as, for example, any type of commercially available HWP, may be located between lens 104 and transmission grating 108. Transmission grating 108 may be, for example, a transmission grating such as described in M. Merimaa, H. Talvitie, P. Laakkonen, M. Kuittinen, I. Tittonen, and E. Ikonen, “Compact External-Cavity Laser with a Novel Transmission Geometry,” Optics Communications 174:175-180 (Jan. 15, 2000). Further, in laser system 100 transmission grating 108 may have a reflectivity of, for example, from about 10 to about 50%. Although the present embodiments are described as using a transmission grating, in other embodiments other types of spectrum selective elements may be used, such as for example, other types of a diffraction gratings, such as, for example, a reflective grating.
Pivot arm 150 may be connected to transmission grating 108 so as to pivot about a pivot point 152 so that transmission grating 108 is pivoted (e.g., to rotated) to an angular position to tune laser system 100 to a desired wavelength. A further description of an exemplary transmission grating 108 is provided below, along with an explanation regarding tuning laser system 100 by pivoting transmission grating 108 to the desired angular position using pivot arm 150.
In operation, laser diode 102 may generate a coherent light beam 120 that may be achromatically collimated by collimating lens 104. Pivotable transmission grating 108 may then be used to tune laser system 100 to a desired wavelength of light by diffracting only a selected wavelength of coherent light beam 120 directly back towards laser diode 102. Wavelengths of light other than the desired wavelength (i.e., the wavelength to which laser system 100 is to be tuned) will be diffracted at other angles. Only the reflected light at the desired wavelength may then pass back through collimating lens 104 and laser diode 102 where it may then be reflected back by reflective coating 112. Since a laser amplifies the photon energy on each round trip through the total laser cavity 134, transmission grating 108 of the external cavity 132 of laser system 100 may be used to selectively allow only one (or a few) wavelengths to dominate (i.e., lase).
As noted above, transmission grating 108 may be able to diffract about 10% to about 50% of the light of the desired wavelength back to the light source, which is for example, a reflectivity of between about 10% and about 50% for the output coupler of the external cavity laser system described in the present embodiment of laser system 100. Thus, in operation, tunable transmission grating 108 may transmit almost all of the light incident upon it except for the diffraction of from about 10 to about 50% of light back into the laser cavity and any other light that is diffracted or reflected at other angles due to the design of the diffraction grating or reflective coatings. In addition, transmission grating 108 may allow the remaining light (i.e., from about 50 to about 90%) at the tuned wavelength (as well as all other wavelengths of light) to pass through the transmission grating 108 to form collimated output laser beam 122.
The following provides a more detailed description of an exemplary method for designing a laser system 100 using a pivotable transmission grating 108 for tuning. In the description below, laser diode 102 will be described with reference to a desired center wavelength, λcenter and a tuning range Δλtotal in terms of nanometers (nm). Further, for simplicity in the description below, the center wavelength will be set in the center of the turning range. Laser diode 102 may also have a minimum wavelength, λmin=λcenter−Δλhalf and a maximum wavelength, λmin=λcenter+Δλhalf, where Δλhalf=Δλtotal/2.
Transmission grating 108 may comprise a plurality of equally spaced and parallel gratings. The density of grating lines, G, in lines/nm, may be defined as G=2*sin(αλ)/λ0, where αλ is the Littrow angle. Thus, for example, for a Littrow angle, αλ=45 degree, G=√{square root over (2)}/λ0. Accordingly, in an exemplary system where λenter=405 nm and αλ=45 degrees, G=3492 lines/mm.
The following provides a description of an exemplary method for determining the placement of the pivot point 152 of transmission grating 108 and the length, P, of pivot arm 150. For simplicity, the first reflected order of diffraction for the transmission grating 108 will be assumed to be the order of interest in the below description, m=1 and therefore the R1 beam is the one that defines the external cavity laser optical path.
Referring back to
L=(Ldiode*ndiode)+(Lair*nair)+(Llens
where Ldiode=physical length of the laser diode along the central optical path, ndiode=the index of refraction at the center wavelength, λcanter, enter, of laser diode 102, Lair=physical length of the space along the central optical path that is air, nair=the index of refraction at λcenter of the air, Llens
As noted above, the Littrow angle, αλ for transmission grating 108 is defined as:
As noted above, transmission grating 108 may be pivoted to an angular position to tune laser system 100 over a desired tuning range. Laser system 100 may therefore, for example, be designed such that transmission grating 108 may pivoted to create angles Littrow angles ranging from αmin to αmax, where:
To reduce the number of mode hops in laser system 100 over the tuning range, laser system 100 may be designed so that the overall cavity length, L, changes proportionally with the change in the wavelength:
where
Lcenter=Cavity Length of the Laser at λcenter
Δλ=λ1−λcenter
ΔL=L1−Lcenter where LN=Cavity Length of the Laser at λN, and λmin≦λN≦λmax
That is, mode hop free tuning of laser system 100 may be achieved when the cavity length, L, for a new wavelength contains the same mode number as for the starting cavity length, L, for λcenter. The mode number, M, may be defined as the number of half wavelengths that fit into the cavity:
Therefore, mode hop free tuning may occur when M=Mλ for all λ in the tuning range (i.e., M is a constant for all λ in the tuning range). Although it may be difficult to have no change in mode number over the tuning range in a Littrow external cavity laser, embodiments of the present invention may be used minimize the number of mode hops by placing the center of rotation for transmission grating 108 at an optimal position.
As will be described in more detail below, the length, P, of pivot arm 150 may change the total number of mode hops experienced over the tuning range, Δλtotal. Thus, it may be advantageous to choose the length, P, to minimize the change in mode hops, M. For small angles of Δα≦3°, the pivot arm length, Pbest, that may result in the fewest number of mode hops, M, may be in the narrow range of Pmin<Pbest<Pmax, where
Thus, in an embodiment, Pmin and Pmax may be calculated and the pivot arm length, P, selected such that it is between Pmin and Pmax. For example, P may be selected such that P=(Pmin+Pmax)/2.
The following provides exemplary computations for calculating a pivot arm length, P, for a tunable laser over a tunable range of from about 400 to about 410 nm (Δλtotal=10 nm) with a grating with G=3492 lines/mm (0.003492 lines/nm), and where the center wavelength of tuning range, λcenter=405 nm. Thus, P, may be determined in this example as follows:
The cavity length, L=Lcenter, may then be determined as noted above, where L is a function of the central optical ray on a single pass through the cavity starting at the diode:
where li is the physical length of the object on the optic axis and ni is the index of refraction.
Typically,
L=(Ldiode*ndiode)+(Lair*nair)+(Llens
where Lair is the combination of the length traveled in air between laser diode 102 and lens 104 and the length traveled in air between lens 104 and transmission grating 108.
For exemplary purposes, in this example, the calculated cavity length, L, will be assumed to be L=20 mm. Thus,
Pmin=19.88 mm
Pmax=20.12 mm, and 19.88 mm=Pmin<Ps<Pmax=20.12 mm, where Ps is the selected pivot arm length.
In another example, the target for the placement of the pivot point 152 may not simply be at a point directly below the intercept point on transmission grating 108 with a length Pbest, but instead the pivot point 152 may be located on a line below the transmission grating 108 on which the pivot point 152 resides. Placing the pivot point 152 on such a line may be useful for tolerancing as well as permitting flexibility of the cavity design, such as, for example, if it is not desirable to place the pivot point 152 directly below the transmission grating 108 intercept point as shown in
In order to improve performance of the laser system, it may also be desirable to be able to adjust the alignment of the laser system's components, such as, for example laser diode 102 and lens 104. For example, in one embodiment, the position and alignment of the laser system's components may be adjusted and the resulting mode hop performance of the laser system measured over the tuning range by analyzing the laser system's output laser beam using, for example, a high resolution optical spectrum analyzer. Such an optical spectrum analyzer may have, for example, a resolution greater than the change in wavelength, Δλ, associated with a mode hop for a fixed cavity length, L, laser system at the center wavelength, λcenter. For example, as noted above,
which can be converted into frequency terms (e.g., hertz):
where c=λv=speed of light=299,792,458 m/sec. Thus, in this example, the high resolution optical spectrum analyzer may have, for example, a resolution (e.g., in terms of hertz) greater than or equal to Δv=7.5 GHz.
Laser system 700 may be initially tuned as follows: First, laser system 700 may be assembled such that pivot arm 750 has a pivot length, P, equal to the optimum length, Pbest, calculated using methods such as those discussed above and the pivot point 752 and transmission grating 708 are located such that the pivot point 752 is located directly beneath the expected intercept point 754 on the transmission grating 708. As noted above, rather than locating the pivot point 752 directly below the intercept point, in other embodiments, the pivot point may located at other locations along a line 782 that passes through pivot point 752 and is at an angle equal to the Littrow angle, αλ, for the center wavelength, λcenter, as discussed above with reference to
Next, laser system 700 may be turned on and the transmission grating 708 pivoted to tune (i.e., obtain lasing) over the tuning range for laser system 700. An optical spectrum analyzer may then be used to determine the number of mode hops over the tuning range by analyzing the output laser beam 722. Next, the position of moveable assembly 762 may be adjusted and the number of mode hops determined over the tuning range for laser system 700. For example, moveable assembly 762 may be moveable up or down and/or to the left or right. Moving moveable assembly 762 may have the effect of altering the cavity length, L. For example, moving moveable assembly 762 down may have the effect of reducing the cavity length, L, by moving the point of intercept of light 720 on transmission grating 708 down and to the left due to the angle of transmission grating 708 in this example. Similarly, moving moveable assembly up or to the left may have the effect of increasing the cavity length, L.
Moveable assembly 762 may then be adjusted and the number of mode hops measured via, for example, an iterative process until a location for moveable assembly 762 is determined that minimizes the number of mode hops over the tuning range of laser system 700. Moveable assembly 762 may then be fixed at this determined location by, for example, tightening screws that may help to fix moveable assembly at this location. This process of determining a position for moveable assembly 762 may be, for example, performed prior to shipment of laser system 700 to customers. Moveable assembly may then remain located at the determined position, for example, for the life of laser system 700 or, for example, this position may be adjusted in the event, for example, errors or problems are determined with laser system 700.
First axis 822 may be used to pivot transmission grating 808 to tune the laser system such as discussed above with reference to laser system 100 of
For example, the optimum position of rotation for the second axis 824 may be determined by iteratively adjusting the angular position of rotation and measuring the optical power of the output laser beam 122. These measurements may be taken, for example, with the first axes or rotation 822 located at its center position so that the laser system is tuned to its center wavelength. The optimum angular position of rotation of the second axis 824 may be determined where the output laser beam 122 is at its maximum power.
The optimum angular position of rotation for the third axis 826 may similarly be, for example, determined by iteratively adjusting the angular position of rotation and measuring the optical power of the output laser beam 122 over the tuning range of the laser system. The optimum angular position of rotation of the third axis 826 may be determined where the output laser beam 122 is at its maximum power across the entire tuning range of the laser system.
A laser system using a pivot arm such as pivot arm 800 may be initially tuned by, for example, first rotating the third axes 826 to align the grating lines of transmission grating 808 so that they are orthogonal to the first axes of rotation 822, as noted above. This may be initially done, for example, without transmission grating 808 being installed in pivot arm 800. Next, transmission grating 808 may be installed and aligned in pivot arm 800. The first axis 822 may then be rotated to tune the laser system at its center wavelength. Then, for example, the rotation for the second axis 824 may be determined such as described above, by using a power meter to measure the output of the output laser beam 122 and fixing the rotation at the position of maximum output power. The laser system may then be tuned across its tuning range and the output laser beam 122 analyzed to ensure optimum performance across the entire tuning range and the second and third axes 824 and 826 adjusted to ensure optimum performance of the laser system across the entire tuning range.
However, there are distinct advantages of using transmissive type gratings.
As shown in
All documents, patents, journal articles and other materials cited in the present application are hereby incorporated by reference.
Although the present invention has been fully described in conjunction with several embodiments thereof with reference to the accompanying drawings, it is to be understood that various changes and modifications may be apparent to those skilled in the art. Such changes and modifications are to be understood as included within the scope of the present invention as defined by the appended claims, unless they depart therefrom.
This application claims the priority date of co-pending U.S. patent application Ser. No. 14/53,529, filed Aug. 6, 2014 and titled “External Cavity Laser,” which claims priority to U.S. patent application Ser. No. 11/716,002, filed Mar. 9, 2007, titled “External Cavity Laser,” now abandoned, which claims priority to U.S. Patent Application 60/780,354, also entitled “External Cavity laser”, filed Mar. 9, 2006. The entire disclosures and contents of the above applications are incorporated herein by reference.
Number | Date | Country | |
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60780354 | Mar 2006 | US |
Number | Date | Country | |
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Parent | 11716002 | Mar 2007 | US |
Child | 14453529 | US |
Number | Date | Country | |
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Parent | 14453529 | Aug 2014 | US |
Child | 14816683 | US |