This application is a National Phase Application of International Application Number PCT/CN2009/000642, filed Jun. 10, 2009, and claims the benefit of priority of Chinese Patent App. Nos. 200810127037.5 and 200810116638.6 filed Jun. 18, 2008 and Jul. 14, 2008; respectively, the contents of all of which are incorporated herein by reference in their entirety.
The present invention relates to wavelength and frequency tuning of grating external-cavity semiconductor lasers, wherein quasi-synchronous tuning is achieved by selecting tuning rotation center of the grating or mirror.
In the use of external-cavity semiconductor laser (ECDL), there usually needs to tune the wavelength or frequency of generated laser and such tuning is realized by rotating grating to vary the incidence angle and diffraction angle of light on the grating, or by rotating mirror to vary the diffraction angle of light on the grating.
As shown in
In the grazing-incidence configuration shown in
In the Littrow configuration shown in
In order to illustrate the tuning principle of external-cavity semiconductor lasers, a Cartesian coordinate system xOy is introduced in the figures, wherein the point O represents the intersection point of a laser beam emitted from semiconductor laser diode LD and the diffraction surface of grating G in its original position; the x-axis runs through the point O and its direction is collinear with and opposite to that of the light emitted from LD; and the y-axis runs through the point O upward and is perpendicular to the x-axis.
The three planes of the equivalent LD rear facet, the diffraction surface of the grating G and the reflection surface of the mirror M are all perpendicular to the xOy coordination plane. The intersection line of the plane on which the diffraction surface of the grating lies and the xOy coordination plane is represented as SG, and the point O is on the intersection line; the intersection line of the plane on which the equivalent LD rear facet lies and the xOy coordination plane is represented as SL, which is separated from the point O at a distance l1; and the intersection line of the plane on which the reflection surface of the feedback mirror M lies and the xOy coordination plane is represented as SM, which is separated from the point O at a distance l2.
In the grazing-incidence configuration shown in
When rotating the grating G or the mirror M to perform tuning, the rotational axis is perpendicular to the xOy coordinate plane, and the intersecting point of the rotational axis and the xOy coordinate plane (i.e., a rotation center) is denoted as P(x,y) in
In grating external cavity semiconductor laser, there are two essential factors for laser wavelength or frequency determination:
1. frequency selection determined by the values of incidence angle and diffraction angle of the light on the grating and their variations;
2. frequency selection determined by the values of the cavity length of the equivalent F-P cavity formed by SL, SM and SG and their variations.
During the rotation of the grating or mirror around the rotation center P, both the frequency selection of the grating and the frequency selection of the F-P cavity change. In general, those changes are not synchronous, which will cause mode-hopping of the laser mode, thus will disrupt the continuous tuning of laser frequency, and hence, resulting in a very small continuous tuning range without mode-hopping, e.g., 1 to 2 GHz.
In order to achieve synchronous tuning of laser frequency or wavelength, i.e., achieve a large range of continuous frequency tuning without mode-hopping, the rotation center P of the grating G or the feedback mirror M needs to be selected purposefully.
Assuming the grating or the mirror was rotated by an angle α with respect to its original position, the phase shift W of laser beam after one round trip within the F-P cavity is:
Ψ=Ψ0+A(α)·[B·sin α+C·(1−cos α)] (1)
wherein, Ψ0 is the original one round trip phase shift of the beam before the rotation tuning, A(a) is a function of the tuning rotation angle α. Ψ0, B and C are functions that are irrelative to the angle α. Ψ0, A(α), B and C relate to the original parameters of the external-cavity semiconductor laser, including original angles (for example, original incidence angle θi, original diffraction angle θd etc.), original positions (for example, original cavity lengths l1 and l2, and original distances u, v and w), and grating constant d, and the like. When full synchronous tuning conditions are satisfied, the phase shift Ψ should be independent of the rotation angle α, and thus, both B and C in Eq.(1) should be zero.
Here, the distance parameters of the rotation center P0 fulfilling rigorous synchronous tuning should meet:
It is evident that the rotation center P0 satisfying synchronous tuning conditions should lie on the intersection line of the plane on which the grating diffraction surface lies and the xOy coordinate plane; meanwhile, the distance u0 from the rotation center P0 to the plane on which the reflection surface of the mirror lies and the distance w0 from P0 to the plane on which the equivalent LD rear facet lies have the same absolute values and the opposite signs.
For grazing-incidence and grazing-diffraction configuration, the coordinate of the rotation center satisfying synchronous tuning conditions is represented as P0(x0,y0), which meet:
Wherein, x0, y0 are abscissa and ordinate of the synchronous tuning rotation center P0 respectively, 1 is the equivalent cavity length of the F-P cavity at the original position, d is the grating constant, θi is the incidence angle of the light on the grating, and λ is the laser wavelength.
That is, the synchronous tuning center PO should at the intersecting point of the lines SG and SL.
Since θi=θd=θ and the actual optical cavity length is l1 in the Littrow configuration, when expressed by coordinate of P0(x0, y0), the distance parameter constraint conditions defined in Eq.(3) become:
It can be seen from the above description that, regardless of whether the coordination parameter or the distance parameter is used, the position of the synchronous tuning rotation center P0 needs to be defined by a equation group consisting of two equations, and the above two constraint conditions must be satisfied simultaneously, which means that there needs two adjustment mechanisms with the independent freedoms in the laser design. Despite for the grazing-incidence configuration, the grazing-diffraction configuration or the Littrow configuration, the position of the synchronous tuning rotation center PO can not leave from the SG plane on which the diffraction surface of the grating lies, which leads to disadvantages and difficulties in configuration design, adjustment and application of laser, while complicates the mechanical system and increases the instable factors.
In practice, a large continuous tuning range without mode-hopping may be affected by many other factors, for example, whether there is a AR(antireflection) coating applied on the LD surface and the quality of coating and the like. However, a continuous frequency tuning range of hundreds or even tens of GHz may be sufficient for many applications.
The technical problem to be solved by the present invention is to find a method for performing approximately synchronous tuning (quasi-synchronous tuning) of grating external-cavity semiconductor laser, which renders the resultant mode-hopping-free tuning range is almost the same as in rigorous synchronous tuning, while the adjustment mechanism is more stable, reliable and simple, without significantly degrading the quality of the laser. According to the present invention, the technical problem is solved by a method for tuning a grating external-cavity semiconductor laser, wherein a grating or a mirror of the semiconductor laser is rotated around a quasi-synchronous tuning point as rotation center, such that the distance between the plane on which the diffraction surface of the grating lies or the plane on which the reflection surface of the mirror lies and the quasi-synchronous tuning point holds during the rotation, whereby achieving the quasi-synchronous tuning of the frequency selections by the grating and resonance cavity, wherein the quasi-synchronous timing point is determined in the following manner:
According to the present invention, a corresponding external-cavity semiconductor laser is also provided, which comprises a quasi-synchronous tuning mechanism for implementing the abovementioned quasi-synchronous tuning method. The quasi-synchronous tuning mechanism rotates the grating or the mirror around the determined quasi-synchronous tuning rotation center to achieve the quasi-synchronous tuning of frequency selections by the grating and resonance cavity. The external-cavity semiconductor laser may in a Littman configuration or in a grazing-diffraction configuration, as well as a Littrow configuration. In the case of external-cavity semiconductor laser in Littrow configuration, the line from the quasi-synchronous tuning center to the synchronous tuning center is parallel to the direction of the light incident on the grating, since the difference between the incidence angle and the diffraction angle Δθ=0.
The present invention is based on the following finds:
In the tuning phase shift described in the above Eq.(1), the tuning rotation angle α, when represented in radian, is a small value approximating to zero and far less than 1. According to the Taylor series expansion theorem, it can be known that, the first item sin α in the square brackets of Eq.(1) is the odd high-order item beginning from the first-order item of the tuning rotation angle α, and the second item (1−cos α) is even high-order item beginning from the second-order item of the tuning rotation angle α, and so the second item (1−cos α) is a small value higher ordered than sin α and has far less contribution to the phase shift Ψ than sin α. Hence, by omitting the second-order and higher-order items in Eq.(1), the round trip phase shift Ψ can be approximately represented as:
Ψ=Ψ0+A(α)·B·sin α (6)
In this case, the coefficient B can be set to 0 in order to make the round trip phase shift q irrelevant to the tuning rotation angle α. That is,
B=0 (7)
Such approximation is called quasi-synchronous tuning approximation, under which the frequency tuning of the external-cavity semiconductor laser is a quasi-synchronous tuning, wherein the rotation center of the corresponding grating or mirror is called quasi-synchronous tuning rotation center Pq with coordination Pq(xq,yq). In the range of such approximation, the round trip phase shift caused by the rotation angle α can be omitted, i.e., Ψ≈Ψ0, which can be approximated as a constant irrelevant to the tuning rotation angle. In practice, almost all the parameters of external-cavity semiconductor laser and tuning range of rotation angle α meet such approximation condition.
By means of the solutions of the present invention, the number of synchronous tuning constraint conditions can be reduced, so that merely one adjustment freedom is required for the adjustment mechanism. The position of the rotation center is no longer limited to the intersection line SG of the plane on which the grating surface lies, thus resulting in more flexible and powerful synchronous tuning, facilitating realization of approximately synchronous rotational frequency or wavelength tuning of the laser.
yq−y0=−(xq−x0)·tan Δθ (10)
It can be seen from Eq.(8) and Eq.(10) that, when the diffraction angle θd equals to the incidence angle θi, namely, θd=θi=θ, Δθ=0, and quasi-synchronous tuning condition of a Littrow configuration can be obtained, that is:
yq=y0 (12)
Wherein y0 is the ordinate of the synchronous tuning rotation center P0 given by Eq.(5). On the xOy plane, the trace of quasi-synchronous rotation center coordinate Pq(xq, yq) satisfying the above condition is a line passing through the synchronous tuning rotation center P0(x0, y0) and parallel to the x-axis (see
wq·cos θ+vq=0 (13)
Here, the signs of the distance parameters uq, vq and wq are specified as positive if the light and quasi-synchronous tuning center Pq are on the same side of the corresponding intersection line of planes, and otherwise, negative.
Thus, from the perspective of actual physical space of laser, on the xOy plane, the rotation center Pq(xq, yq) satisfying the quasi-synchronous tuning condition can be considered as a section extending from the rotation center P0(x0, y0) under the conventional synchronous tuning condition to a line passing through P0(x0, y0) in the proximity of P0, the section can be on either side of P0. For external-cavity semiconductor laser in grazing-incidence configuration and grazing-diffraction configuration, in grating rotation tuning (
As shown in
The semiconductor diode LD, for example, utilizes temperature sensor and semiconductor cooler to realize temperature control by a heat sink 2. A specific implementation of the quasi-synchronous tuning mechanism will be described below: the collimating lens AL is adjusted and fixed by a lens holder 4, a diffraction grating G is fixed on an adjuster moving plate 6, the direction of the diffraction grating G can be adjusted by adjusting screws 8 and 9 on a adjuster fixed plate 7 and further finely adjusted by a piezoelectric ceramics 10 on the moving plate, and the mirror M is fixed on a base plate 13 by a fixing holder 11. Frequency selections by the external-cavity and the grating are realized by rotating the diffraction grating G around a quasi-synchronous rotation center Pq. For example, a coarse tuning can be made by varying the angle of diffraction grating G by means of adjusting screw 8, and/or a fine tuning can be made by applying a control voltage on the piezoelectric ceramics 10.
In the external-cavity semiconductor laser in Littman configuration shown in
The external-cavity semiconductor laser in grazing-diffraction configuration tuned by grating rotation shown in
Similarly,
In the quasi-synchronous tuning mechanisms shown in
In the external-cavity semiconductor laser in Littman configuration tuned by mirror rotation shown in
The external-cavity semiconductor laser in grazing-diffraction configuration quasi-synchronously tuned by mirror rotation shown in
It can be seen from
Those skilled in the art will appreciated that, the semiconductor diode in the above examples may have other wavelength or output power, the grating can be a blazed grating or a transmission grating, which may have other groove density, size or thickness, the collimating lens may have other focal length and numerical aperture as well.
1. Semiconductor Diode LD
2. Heat Sink
3. Collimating Lens AL
4. Lens Holder
5. Mirror M
6. Adjuster Moving Plate
7. Adjuster Fixed Plate
8. Adjusting Screw (for fine tuning)
9. Adjusting Screw
10. Piezoelectric Ceramics
11. Fixing Holder
12. Grating G
13. Base Plate
Number | Date | Country | Kind |
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2008 1 0127037 | Jun 2008 | CN | national |
2008 1 0116638 | Jul 2008 | CN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/CN2009/000642 | 6/10/2009 | WO | 00 | 12/13/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/152690 | 12/23/2009 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5058124 | Cameron et al. | Oct 1991 | A |
5255273 | Nilsson et al. | Oct 1993 | A |
5867512 | Sacher | Feb 1999 | A |
6018535 | Maeda | Jan 2000 | A |
6026100 | Maeda | Feb 2000 | A |
6324193 | Bourzeix et al. | Nov 2001 | B1 |
6778564 | Funakawa | Aug 2004 | B2 |
6850545 | Asami | Feb 2005 | B2 |
20070223554 | Hunter et al. | Sep 2007 | A1 |
Number | Date | Country |
---|---|---|
101582561 | Nov 2009 | CN |
296 06 494 | Jun 1997 | DE |
Entry |
---|
International Search Report from P.R. China in International Application PCT/CN2009/000642, mailed Sep. 3, 2009. |
McNicholl et al., “Synchronous cavity mode and feedback wavelength scanning in dye laser oscillators with gratings,” Applied Optics, vol. 24, No. 17, pp. 2757-2761 (Sep. 1, 1985). |
Number | Date | Country | |
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20110261843 A1 | Oct 2011 | US |