The present disclosure relates to controlling optical signals using couple resonators. In particular, it relates to methods and system for delaying optical waves.
Optical delay lines and buffers are key components for optical networks and information processing systems. Delay lines based on conventional optical waveguides can be very long. The length can be greatly reduced if the group velocity of light is significantly reduced. “Slow light” can be achieved in engineered structures which bounce light back and forth as it propagates. Such structures can include grating structures as described in more details in references [1], [2], photonic crystal waveguides as described in reference [3], and coupled-resonator optical waveguide (CROW) as described in reference [4]. A major problem in designing delay lines based on such waveguides is the higher-order dispersion, which can cause a distortion of signal. Although the second-order dispersion of grating structures and CROW is zero at the band center, the group velocity can approach zero at frequencies close to the band edges (see references [1], [2], [4].
Two mechanisms have been proposed and used in the past for optical waveguiding. The most widely used is waveguiding by total internal reflection. Another mechanism is the Bragg waveguiding, in which waveguiding is achieved through Bragg reflection from a periodic structure, has also been demonstrated.
According to a first aspect, a method for providing an optical signal with a substantially constant delay along a frequency spectrum while maintaining a substantially constant amplitude of the optical signal is described, the method comprising: providing coupled resonator optical waveguides (CROW) comprising a plurality of resonators; setting a coupling distance between each resonator of the CROW; and propagating the optical signal through the CROW by inputting the optical signal to an input waveguide of the CROW and outputting the optical signal from an output waveguide of the CROW, wherein the input waveguide is the same as the output waveguide.
According to a second aspect, a method for providing an optical signal with a substantially constant delay along a frequency spectrum while maintaining a substantially constant amplitude of the optical signal is described, the method comprising: providing a first optical signal path, the first optical signal path comprising an input portion and an output portion; providing a second optical signal path, the second optical signal path being across coupled resonator optical waveguides (CROW), the CROW comprising a plurality of resonators; optically coupling the first optical signal path with a first resonator of the CROW, the optically coupling being a function of a coupling distance between the first optical signal path and the first resonator; providing an optical signal at the input portion of the first optical signal path; and sequentially propagating the optical signal through the input portion of the first optical signal path, through the second optical signal path, and through the output portion of the first optical signal path.
According to a third aspect, a system for delaying an optical signal is described, the system comprising: a first optical signal path, the first optical signal path being both an input portion for the optical signal and an output portion for the optical signal; and a second optical signal path, the second optical signal path being coupled resonator optical waveguides (CROW), the CROW comprising a plurality of resonators, wherein each resonator of the plurality of resonators is optically coupled with one or more adjacent resonators at a set coupling distance, and wherein the first optical signal path is optically coupled with a first resonator of the plurality of resonators at a set coupling distance, wherein the set coupling distance changes a group velocity of the optical signal in the second optical signal path and the output portion of the first optical signal path.
According to a fourth aspect, a system comprising a plurality of the system according to the third aspect is described, wherein the plurality of the system according to the third aspect is arranged in series such that the delayed optical signal outputted from a first system is adapted to be inputted into a second system.
The accompanying drawings, which are incorporated into and constitute a part of this specification, illustrate one or more embodiments of the present disclosure and, together with the description of example embodiments, serve to explain the principles and implementations of the disclosure.
In some optical systems, it may be desired to control the speed of an optical signal traveling through a waveguide in order to, for example, synchronize optical signals in an optical buffer network. Since the speed of light is extremely fast, a long waveguide can be used for such slowing down (delaying), or a coupled-resonator optical waveguide (CROW) as described in reference [4] can be utilized. A CROW can comprise a chain or an array of coupled resonators where light propagates along the chain or array of resonators by virtue of inter-resonator coupling. Thus, by slowing down the optical signal, the group velocity of the wave that comprises the optical signal can be delayed. The group velocity of a wave is defined herein as the velocity in which the overall modulation (envelope) shape of the wave propagates through space.
According to an embodiment of the present disclosure, a reflecting type CROW is described. In the example reflecting type CROW shown in
The concept of CROW as shown in
According to another embodiment of the present disclosure, the group velocity of the optical signal can be precisely controlled by adjusting the coupling distance between the chain or array of CROW resonators.
In the transmission mode, the transfer function T is a function of s, where s=i(ω−ω0) is the frequency detuning from the resonant frequency. Each resonator can be considered as a feedback loop which contributes a pole to the transfer function. An N-resonator CROW can be thought of as an all-pole filter of order N whose transfer function is given by T(s)=k/p(s), where p(s) is a polynomial in s. Filter designs can then be applied to derive the coupling coefficients which determine the transfer function of the CROW to achieve desired filter responses (references [5], [6], [7]). For example, Butterworth CROW exhibits a flat transmission and a Bessel CROW exhibits a group delay. However, it can be difficult to achieve a constant amplitude and group delay by any one of these filters simultaneously, since the amplitude and the phase of all-pole functions are related to each other.
According to an embodiment, an “ideal” optical delay line comprising a constant group delay and a constant amplitude transmission over a prescribed bandwidth can be achieved. It is based on the reflection of a CROW, whose inter-resonator coupling coefficients are tailored to realize an all-pass Bessel filter. The design of all-pass Bessel filters have been explored using microwave equivalent circuit methods [5]. A method for deriving the time-domain coupling coefficients and interpreting the physics behind the idea is described.
An all-pass filter function can be written as [p(s)]*/p(s) to preserves the phase of T(s) and achieve a constant (e.g. maximally flat) group delay output amplitude of 1. Thus, an all-pass Bessel filter whose p(s) is a Bessel polynomial possessing constant amplitude and maximally flat group delay over a prescribed bandwidth, as shown in
Reflecting CROWs can be realized using various kinds of resonators.
In order to realize ideal delay lines, according to an embodiment of the present disclosure, the coupling coefficients need to be derived. The formalism is based on coupled-mode theory. Consider the CROW as shown in
The tri-diagonal coupling matrix, denoted as A, consists of the frequency detuning s in the main diagonal and the time-domain coupling coefficients iκi in the upper and lower diagonals. The coupling to the input waveguide is modeled by an external loss of the first resonator, 1/τe1, and an input coupling −iμ1sin at the right-hand side of equation (1). It can be shown that μ1=√{square root over (2/τe1)} using conservation of energy.
The reflected amplitude, sr, is given by sr=sin−iμ1a1, where a1 is obtained from equation (1) as a1=[A−1]1,1(−iμ1sin). The transfer function of reflection can be written as:
where pk for k=1,2, . . . , N is defined as the determinant of the bottom-right k×k submatrix of A and is a polynomial in s with a leading term sk. The polynomials p1 through pN satisfy the recursive formulas [6]:
As an example we consider an all-pass Bessel filter of order N=6, whose transfer function is given by R(s)=[p(s)]*/p(s), where p(s) is a Bessel polynomial, p(s)=s6+4.495s5+9.622s4+12.358s3+9.92s2+4.672s+1. The group delay of R(s) is maximally flat between Δω=−1 and 1. Since the coefficients of p(s) are real, [p(s)]*=p(−s). Comparing R(s) with equation (2), we obtain p6=p(s) and μ12p5=p(s)−p(−s). Since the leading coefficient of every polynomial pk is 1, μ12=8.990 and p5=s5+2.749s3+1.039s. With p6 and p5, all the coupling coefficients can be extracted step by step, using Equation (3). The extracted coefficients are (1/τe1, κ1, κ2, κ3, κ4, κ5)=(4.495, 2.622, 1.207, 0.824, 0.632, 0.463), which decrease monotonically from the input. Finally, the coefficients can be multiplied by a bandwidth parameter B to choose the bandwidth, which leads to maximally flat delay between Δω=−B and B. The group delay is inversely proportional to B. The spectra of reflection and group delay are shown in
The physics behind reflecting Bessel CROWs can be explained by plotting the CROW propagation band as a function of distance. CROWs with uniform coupling coefficient κ form a constant-height band between ω0−2κ and ω0+2κ. Frequencies within the CROW band propagate freely while those outside evanesce exponentially with distance. CROWs with tailored coupling coefficients correspond to a distance-dependent CROW band wherein the thickness is 4κ(z), where κ(z) is the local coupling coefficient.
To realize reflecting Bessel CROWs in ring resonators, time-domain coupling coefficients can be converted to field coupling coefficients in the coupling regions. By way of example and not of limitation, silicon ring resonators can be considered. The mode index and group index of the silicon waveguides are respectively 2.4 and 4. The radii of the rings are selected as 20 μm so that one resonant wavelength is 1570.8 nm and the free spectral range fFSR is 597 GHz. The relation between the field coefficient η and the coupling coefficient κ is given by η=sin(κ/fFSR) for inter-resonator coupling and ηi=√{square root over (2 sin(1/τe1fFSR)/[1+sin(1/τe1fFSR)])}{square root over (2 sin(1/τe1fFSR)/[1+sin(1/τe1fFSR)])} at the input. By way of example and not of limitation, B=ωFSR·0.003 and B=ωFSR·0.03, which lead to field coupling coefficients of (0.395, 0.0494, 0.0228, 0.0155, 0.0119, 0.0087) and (0.926, 0.474, 0.226, 0.155, 0.119, 0.087), respectively. The spectra of reflection and group delay are shown in
Although lossless resonators were considered up to this point, lossy resonators with contact loss rates can also be considered. In such case with lossy resonators, the total loss is proportional to the group delay. Since the group delay is flat, the loss is also flat within the bandwidth, and the definition of ideal delay lines is still satisfied.
One important parameter of optical delay lines is the delay-bandwidth product (DBP), Δf·τ, which represents the maximum number of bits that can be stored. The DBP of reflecting Bessel CROWs is approximately 0.5 per resonator, as can be evaluated in
Although the delay capability of reflecting CROWs is larger, reflecting CROWs are more sensitive to fabrication disorder of coupling coefficients and resonant frequencies. Any imperfection in a reflecting CROW scatters light twice as it takes a round trip. The cavity between the imperfection and the end of the CROW causes Fabry-Perot-type oscillations, as shown in
According to another embodiment, in addition to achieving a constant group delay, the reflecting CROW can be further configured to yield different delay characteristics, by way of example and not of limitation, a group delay that is a linear function of frequency. Such linear delay can be used as a compact dispersion compensator for fiber optics communication systems.
Furthermore, an optical gain can be electrically or optically pumped into the reflecting CROW in order to amplify the light signal while maintaining the “ideal” delay/filter characteristics, as shown in
The examples set forth above are provided to give those of ordinary skill in the art a complete disclosure and description of how to make and use the embodiments of the present disclosure, and are not intended to limit the scope of what the inventors regard as their disclosure. Modifications of the above-described modes for carrying out the disclosure may be used by persons of skill in the art, and are intended to be within the scope of the following claims. All patents and publications mentioned in the specification may be indicative of the levels of skill of those skilled in the art to which the disclosure pertains. All references cited in this disclosure are incorporated by reference to the same extent as if each reference had been incorporated by reference in its entirety individually.
It is to be understood that the disclosure is not limited to particular methods or systems, which can, of course, vary. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting. As used in this specification and the appended claims, the singular forms “a”, “an”, and “the” include plural referents unless the content clearly dictates otherwise. The term “plurality” includes two or more referents unless the content clearly dictates otherwise. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the disclosure pertains.
A number of embodiments of the disclosure have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the present disclosure. Accordingly, other embodiments are within the scope of the following claims.
The present application is a Divisional of U.S. application Ser. No. 13/460,638 filed on Apr. 30, 2012 which, in turn, claims priority to U.S. Provisional Application No. 61/481,614, filed on May 2, 2011 all of which are incorporated herein by reference in their entirety.
This invention was made with government support under Grant No. 0925389 awarded by the National Science Foundation, and Grant No. W911NF-10-1-0103 awarded by the Army Research Office. The government has certain rights in the invention.
Number | Date | Country | |
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61481614 | May 2011 | US |
Number | Date | Country | |
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Parent | 13460638 | Apr 2012 | US |
Child | 14856419 | US |