1. Field of the Invention
The present invention relates to optical communication equipment and, more specifically, to optical amplifiers, attenuators, and/or wavelength converters.
2. Description of the Related Art
Optical communication systems employ optical parametric devices (OPDs), e.g., to compensate for optical-signal attenuation in transmission fibers and/or regenerate optical signals. An OPD usually has a nonlinear fiber (NLF) or nonlinear planar optical waveguide (NPOW) that enables various four-wave mixing (FWM) processes to occur and be used to amplify, attenuate, frequency-convert, phase-conjugate, regenerate, and/or sample optical communication signals.
According to one embodiment, a method of operating an OPD adapted to generate a desired output signal has the step of applying first and second polarized pumps to a birefringent optical medium adapted to perform FWM, wherein each of the first and second pumps is polarized at about 45 degrees with respect to a birefringence axis of the optical medium. The method also has the steps of applying an input signal S to the optical medium and generating, in the optical medium, the desired output signal via an FWM process that couples the first and second pumps and the signal S.
According to another embodiment, an OPD for generating a desired output signal comprises a birefringent optical medium adapted to perform FWM and one or more couplers adapted to apply first and second polarized pumps and an input signal S to the optical medium. Each of the first and second pumps is polarized at about 45 degrees with respect to a birefringence axis of the optical medium. The optical medium is adapted to generate the desired output signal via an FWM process that couples the first and second pumps and the signal S.
Other aspects, features, and benefits of the present invention will become more fully apparent from the following detailed description, the appended claims, and the accompanying drawings in which:
NLFs and NPOWs often exhibit some degree of birefringence, either by design or due to inherent limitations and/or imperfections of the corresponding fiber-fabrication processes. Fiber birefringence causes many FWM processes to depend sensitively on signal polarization. At the same time, transmission fibers used in optical communication systems do not normally preserve signal polarization. As a result, polarization of an optical signal applied to an OPD by the optical communication system might vary over time, thereby causing undesirable fluctuations in the power and other important characteristics of the output signal produced by the OPD.
Various embodiments of a two-pump optical parametric device (OPD) having a nonlinear birefringent fiber, in which various four-wave mixing (FWM) processes can occur, address various problems recognized herein. The OPD applies, to the nonlinear birefringent fiber, (i) two pump waves, each polarized at about 45 degrees with respect to a birefringence axis of the fiber, and (ii) a polarized input signal. A relevant FWM process couples the pump waves and the signal to cause the nonlinear birefringent fiber to generate a desired output signal. In one configuration of the OPD, the relevant FWM process is inverse modulational interaction, which causes the desired output signal to be generated through amplification or attenuation of the input signal. In another configuration of the OPD, the relevant FWM process is phase conjugation, which causes the desired output signal to be generated through amplification of the input signal. In yet another configuration of the OPD, the relevant FWM process is Bragg scattering, which causes the desired output signal to be generated as a corresponding idler signal. Advantageously, the OPD enables the power of the output signal to be substantially independent of the polarization of the input signal.
As used in this specification and the appended claims the term “phase sensitive” refers to an optical process that converts an optical input signal into an optical output signal in such a way that the power of the output signal depends on the phase of the input signal, wherein said phase is measured with respect to the phase of the corresponding pump light wave(s). If the power of the output signal does not depend on the phase of the input signal, then the corresponding optical process is termed “phase insensitive.” Examples of phase-sensitive optical parametric processes include frequency doubling, sum- and difference-frequency generation, parametric amplification and oscillation, four-wave mixing, etc.
The term “phase sensitive” is a term of art that should not be confused with the term “phase matching.” The latter term essentially means that a proper phase relationship (that minimizes or nulls the quantity called the “phase mismatch”) between the interacting waves is maintained. A phase-matching attribute of a nonlinear optical process is different from its phase-sensitivity or phase-insensitivity because phase matching generally applies to both phase-sensitive and phase-insensitive processes.
A phase-sensitive optical process is characterized by a property called a “squeezing transformation,” which couples, in a particular manner, the output light signal and pump light. A representative squeezing transformation is described in the above-cited U.S. Patent Application Publication No. 2006/0285197 in reference to contained-therein Eqs. (9a)-(9c). Phase-sensitive optical processes described in this specification may be similarly characterized by squeezing transformations.
2ωP=ωs+ωi (1)
where ωp, ωs, and ωi are the frequencies of the pump, signal, and idler photons, respectively. The nonlinear optical medium, in which the FWM process occurs, is characterized by a nonlinearity coefficient (γ) and a set dispersion coefficients, each of which is frequency dependent. The frequency or wavelength at which the second-order dispersion coefficient equals zero is referred to as the zero-dispersion frequency (ZDF, ω0) or wavelength (λ0). The regions in which the second-order dispersion coefficient is positive and negative are referred to as the normal dispersion region and the anomalous dispersion region, respectively.
The degenerate FWM process of
The following describes the FWM processes that lead to the frequency structure shown in
2ω1=ω1−+ω1+ (2)
A Bragg scattering (BS) process may produce a second idler sideband at frequency ω2− according to Eq. (3):
ω1−+ω2=ω1+ω2− (3)
A phase-conjugation (PC) process may produce a third idler sideband at frequency ω2+ according to Eq. (4):
ω1+ω2=ω1−+ω2+ (4)
In addition, each of the three idler sidebands may couple to the other two idler sidebands by an appropriate FWM process, i.e., MI, BS, or PC, that can be expressed by an equation analogous to one of Eqs. (2), (3), or (4).
In addition to the sidebands illustrated in
One skilled in the art will appreciate that the designation of the various optical waves in
The optical communication signal interacts with the pump light waves in NLF or NPOW 308, e.g., as described in the subsequent sections, and is amplified, attenuated, and/or frequency converted due to this interaction. A filter 310 placed at the end of NLF or NPOW 308 separates a desired optical output signal from the other optical signals present in the NLF or NPOW for further transmission in the communication system via section 302′. Note that all relevant light waves (e.g., the optical communication signal, the two pump light waves, and their different polarization components) propagate in NLF or NPOW 308 along the same (common) longitudinal direction, i.e., from optical coupler 304b toward optical filter 310.
In one embodiment, OPD 300 has an optional optical phase shifter (PS) 303 inserted into section 302 before optical coupler 304b. Optical phase shifter 303 is adapted to controllably change the phase of the optical communication signal to enable OPD 300 to take advantage of the phase sensitivity of certain FWM processes occurring in NLF or NPOW 308. For example, optical phase shifter 303 can be tuned to adjust the phase of the optical communication signal so as to change (as desirable) the amount of amplification or attenuation imparted onto that signal in NLF or NPOW 308.
In one embodiment, NLF or NPOW 308 is a birefringent optical medium. The anisotropy of NLF or NPOW 308 that results in birefringence can be created, e.g., by shaping the optical fiber core so that it has an elliptical cross-section. For an optical-wave polarization that is parallel to either the short axis or the long axis of the ellipse, NLF or NPOW 308 behaves as if it had a single effective refractive index. However, for other polarizations, propagation of the corresponding optical wave and its interaction with the fiber material can be described as if the optical wave consisted of two polarization components, each experiencing a different corresponding refractive index. The component that experiences the higher effective refractive index is referred to as the slow wave, and the component that experiences the lower effective refractive index is referred to as the fast wave.
In various embodiments, optical birefringence can be created in many different ways, such as: (1) fabricating the optical-waveguide or fiber core from an appropriate anisotropic material; (2) shaping the optical-waveguide or fiber core to have an arbitrary non-circular cross-section; (3) stressing or straining the optical-waveguide or fiber core in a transverse direction; and/or (4) applying an electric or magnetic field to the optical-waveguide or fiber core. One skilled in the art will appreciate that the mathematical formalism for describing optical birefringence remains substantially the same regardless of the specific physical cause of birefringence. For example, the optical-waveguide or fiber core can be characterized by two mutually orthogonal, transverse axes corresponding to the polarizations of the fast and slow light waves, respectively. Hereafter, these axes are referred to as the “birefringence axes.” For NLF or NPOW 308 having an elliptical cross-section, the birefringence axes are (1) the axis that is parallel to the short axis of the ellipse and (2) the axis that is parallel to the long axis of the ellipse. In the description that follows, if not explicitly stated otherwise, the polarization angles of various optical waves are given with respect to the birefringence axes of NFL or NPOW 308.
Optical-wave propagation in a birefringent optical waveguide or fiber, such as NLF or NPOW 308 (
∂zX=iβx(i∂τ)X+i(γs|X|2+γc|Y|2)X (5a)
∂zY=iβy(i∂τ)Y+i(γc|X|2+γs|Y|2)Y (5b)
where z is the distance along the longitudinal axis of the fiber; ∂z≡∂/∂z; X and Y are the amplitudes of the x and y polarization components, respectively; βx and βy are the corresponding dispersion functions of the fiber; γs=γK is the self-nonlinearity coefficient, where γK is the Kerr coefficient; and γc=2γK/3 is the cross-nonlinearity coefficient. In the frequency domain,
where ωc is the carrier frequency of the wave and ω is the difference between the actual and carrier frequencies. To convert from the frequency domain to the time domain, one replaces ω by i∂τ, where τ≡t−βaz is the retarded time and βa=[β1x(ωc)+β1y(ωc)]/2 is the average of the group slownesses (wherein the group slowness is the inverse group velocity).
Let us suppose that the frequencies of all relevant optical waves are close to (e.g., within about 1 THz from) the ZDF. Then, the effects of the second- and higher-order dispersion are relatively small and can be neglected. As a result, the CSEs (5a-b) reduce to the coupled-component equations (CCEs) (6a-b):
(∂z+βd∂t)X=i(γs|X|2+γc|Y|2)X (6a)
(∂z−βd∂t)Y=i(γc|X|2+γs|Y|2)Y (6b)
where βd=[β1x(ωc)−β1y(ωc)]/2 is the walk-off parameter defined as the difference between the group slownesses. It follows from CCEs (6a-b) that:
(∂z+βd∂t)Px=0 (7a)
(∂z−βd∂t)Py=0 (7b)
where Px=|X|2 and Py=|Y|2. This means that the power of each component is constant in a frame moving with the group velocity of that component and no power is exchanged between the components.
After defining the retarded times τx=τ−βdz and τy=τ+βdz, one can solve Eqs. (7a-b), using the method of characteristics, to find that:
Note that Eq. (8b) can be deduced from Eq. (8a) by interchanging the subscripts x and y and changing the sign of the walk-off parameter βd. For multiple-frequency inputs, the self- and cross-nonlinearities in Eqs. (8a-b) have time-independent parts, which produce self-phase modulation (SPM) and cross-phase modulation (CPM), respectively, and time-dependent parts, which produce scalar and vector FWM. The SPM and scalar FWM involve X and Px, or Y and Py, whereas the CPM and vector FWM involve X and Py, or Y and Px. The effects of SPM and scalar FWM accumulate with distance, as do the effects of CPM. However, the effects of vector FWM, which depend on an integral of a periodic function, are bounded and therefore can be neglected at relatively large propagation distances. Apart from the CPM, which produces only time-independent phase shifts, the polarization components can evolve nearly independently.
Of interest to this section is a case of inverse MI, in which there are (i) two relatively strong pump waves (denoted as modes number −1 and 1, respectively) that are linearly polarized at 45 degrees and (ii) a relatively weak input signal (denoted as mode number 0) that is linearly polarized at an arbitrary angle. Note that the polarizations of the pump waves can be parallel or anti-parallel with respect to each other. The pump waves may have substantially equal power. The signal frequency is the average of the pump frequencies, i.e., ω0=(ω1+ω−1)/2 (see also Eq. (2)). These input conditions can be expressed by Eq. (9):
X(τ,0)=ρexp(iφ−1)+ρ0xexp(iφ0)+ρexp(iφ1) (9)
where ρ is an x-axis projection of the pump-wave amplitude; ρ0x is an x-axis projection of the signal amplitude; and φ−1, φ0, and φ1 are the input phases of the first pump wave, signal, and second pump wave, respectively. Eq. (9) can also be rewritten as follows:
X(τ,0)=ρexp(iωdτx)+ρ0xexp(φ0)+ρexp(−ωdτx) (10)
where ωd=(ω1−ω−1)/2 is the frequency difference between the frequency-cascade orders (see also
With three input frequencies, different FWM processes can produce a cascade of frequencies in addition to the three initial frequencies. One such cascade is described in the above-cited U.S. Pat. No. 7,164,526. Likewise, for the initial conditions expressed by Eqs. (9)-(10), a cascade of frequencies mutually coupled by different FWM processes may be generated. Adjacent frequencies in the cascade are separated by ωd and, as a result, different frequencies in the cascade can be referred to as “harmonics.” It is convenient to refer to each of these harmonics as a mode assigned a corresponding order number. As already indicated above, the two initial pump waves are modes number −1 and 1, and the input signal is mode number 0.
A more-general description of the cascade(s) generated with the three input waves described by Eqs. (9) and (10) is given by Eq. (11) (which describes the x-polarization component) and an analogous equation (which is not explicitly given below) for the y-polarization component:
where n is the mode number; ψx is a time-independent phase expressed by Eq. (12):
ψx=2(γs+γc)ρ2z+(γsρ0x2+γcρ0y2)z (12)
and harmonics Xn of the cascade are given by Eq. (13):
where ζ=2ρ2z; εx=2(ρ0x/ρ)cos φ0; J′l(y)=dJl(y)/dy; and Jl is the Bessel function of the first kind, of order l.
Eq. (11) and its Y analog show that the output harmonics may depend on the polarization of the input signal in two ways: First, because γs≠γc, the polarization components experience different phase shifts. Second, the polarization components depend nonlinearly on εj(ρ0j). However, in a linear regime corresponding to εjζ<<1, the signal-induced phase shifts are typically negligible, the odd harmonics do not depend on ρ0j, and the even harmonics may be all proportional to ρ0j.
In the linear regime, for even n, the exact solution given by Eq. (13) can be approximated by Eq. (14):
Xn(ζ)≈in/2ρ0x{Jn/2(ζ)[exp(iφ0)+2iζ cos φ0]+J′n/2(ζ)2ζ cos φ0] (14)
Eq. (14) indicates that every contribution to Xn is proportional to ρ0x, which also means that every contribution to Yn is proportional to ρ0y. Both x and y polarization components have the same dependence on φ0. Hence, the output-signal and idler powers may depend on the input-signal phase, but not on the input-signal polarization, meaning that, in the linear regime, polarization-independent phase-sensitive amplification is possible.
For the signal mode (n=0), Eq. (14) can be written in the input-output form as follows:
X0(ζ)≈ρ0[μ(ζ)exp(iφ0)+ν(ζ)exp(−iφ0)] (15)
where μ(ζ)=J0(ζ)+ζJ′0(ζ)+iζJ0(ζ) and ν(ζ)=ζJ′0(ζ)+iζJ0(ζ) are transfer functions. The signal power attains its extreme values when 2φm=tan−1[(μrνi−μiνr)/(μrνr+μiνi)], where the subscripts r and i denote the real and imaginary parts, respectively, of the corresponding transfer function. The first-quadrant value of 2φm corresponds to a maximum gain of (|μ|2+|ν|2), whereas the third-quadrant value of 2φm corresponds to a minimum gain of (|μ|−|ν|)2. Using the aforementioned expressions for the transfer functions, one further finds that:
To confirm the above-described theoretical predictions, scalar (one-polarization) and vector (two-polarization) numerical simulations were performed based directly on CSEs (5a-b), for β3=0.03 ps3/Km, β4=−0.0003 ps4/Km, γs=10/Km-W, the pump powers Px=Py=0.5 W, and the signal powers Psx=0.08 mW and Psy=0.02 mW (which correspond to the pump and signal amplitudes of
Thus, for inverse modulation interaction (a degenerate FWM process) in a birefringent fiber with optical-wave frequencies near the zero-dispersion frequency (ZDF) of the fiber, the birefringence may decouple the evolution of the x and y components of the optical waves, where x and y denote the birefringence axes of the optical fiber or optical waveguide. If the two pump light waves are linearly polarized at about 45 degrees to the birefringence axes, then the phase-sensitive amplification (or attenuation) experienced by a linearly-polarized signal may be substantially independent of the signal-polarization angle. Because the effects of dispersion may be relatively weak in the vicinity of the ZDF, secondary FWM processes may produce a cascade of relatively strong secondary pumps and idlers that need to be filtered out at the output of the OPD.
If the optical-wave frequencies are not all close to the ZDF and/or each other, then the effects of dispersion may become significant and non-negligible. As a result, separate equations for each polarization and frequency component ought to be considered to describe the wave interaction. In this section, index j=1, 2, 3, 4 is used to denote different optical waves coupled by an FWM process. By substituting the ansätze given by Eqs. (17)-(18):
into the CSEs (5a-b) and collecting the terms of like frequency, one finds that:
The first term on the right side of Eq. (19) represents a linear phase shift caused by dispersion, whereas the second and fifth terms represent nonlinear phase shifts caused by SPM and CPM. The third and fourth terms represent scalar FWM processes in which 2π2x π3x+π1x and π2x+π3x π4x+π1x, respectively, where πjk denotes a photon with frequency ωj that is polarized parallel to the k axis. The seventh term represents a vector FWM process in which π2xπ2y π3y+π1x, and the eighth term represents a vector FWM process in which π2y+π3xπ4y+π1x and π2y+π3x π4y+π1x. The sixth term represents a process in which π1x+π2y π1y+π2x, and similar processes that involve waves 3 and 4. Analyses show that the latter processes are cross-polarization rotations (CPRs). Similar statements apply to the various terms of Eq. (20).
Note that Eqs. (19)-(20) have been derived for a special case of ω2−ω1=ω3−ω2=ω4−ω3. Similar equations may apply to a case, with more general frequencies. The equations for Y1 and Y2 can be deduced from Eqs. (19)-(20), respectively, by interchanging Xj and Yj. The equations for A3 and A4 (where A is X or Y) can be deduced from the equations for A1 and A2 by interchanging indices 1 and 4 and interchanging indices 2 and 3, respectively. Collectively, all these equations are referred to as the coupled-mode equations (CMEs).
Let us define the total x- and y-polarized powers
respectively. Phase shifts do not change Px and Py. Scalar FWM processes exchange energy between different x-polarized components or different y-polarized components. The photon-exchange equations show that, in each CPR and vector-FWM process, x- and y-polarized photons may be destroyed and other x- and y-polarized photons may be created. Hence, the CMEs conserve Px and Py, as do CCEs (6a-b).
For parameters that may be typical of operating conditions in OPD 300,
where ω is the frequency of any optical wave (measured relative to a reference frequency, such as the ZDF). Let Xj(z)=
where the dispersion functions
contain only second- and higher-order dispersion terms, and the bars are omitted for simplicity.
As stated above, the total powers Px and Py are conserved. Let Xj(z)={circumflex over (X)}j(z)exp[i(2γsPx+γcPy)z] and Yj(z)=Ŷj(z)exp[i(γcPx+2γsPy)z]. For each polarization, every frequency component has about the same phase shift. By making the corresponding substitutions in Eqs. (21) and (22), one can remove the terms that produce this common shift, and obtains reduced Eqs. (23) and (24):
ζzX1≈iβx(ω1)X1−iγs|X1|2X1+iγsX*3X22+i2γsX*4X2X3 (23)
ζzX2≈iβx(ω2)X2−iγs|X2|2X2+i2γsX*2X3X1+iγsX*4X32+i2γsX*3X4X1 (24)
where the carets are omitted for simplicity. Eqs. (23) and (24) describe scalar FWM processes in which 2π2x π3x+π1x, π2x+π3x π4x+π1x, and 2π3xπ4x+π2x. Similar equations should apply to the y-components of waves 1 and 2, and the x- and y-components of waves 3 and 4. These reduced CMEs imply that the x- and y-components of the waves evolve independently. Similar (reduced) CMEs can be derived for larger collections of waves (e.g., harmonics).
Eqs. (23) and (24) do not describe the vector FWM process associated with the seventh term on the right side of Eq. (19) and the eighth term on the right side of Eq. (20). In these processes, which are often called the CPM instability, a pump polarized at 45 degrees to the birefringence axes drives an x-polarized sideband and a y-polarized sideband. Let ω denote the frequency difference between the x-polarized sideband and the pump. Then, the dispersive contribution to the wavenumber mismatch is (β1x−β1y)ω+(β2x+β2y)ω2/2. Phase matching only occurs for large frequency differences, for which the first two terms in the dispersion functions have the same magnitude. We have omitted such frequencies from our analysis.
It is instructive to analyze the initial evolution of the FWM processes described by Eqs. (23) and (24).
First, consider the MI 2π2→π3+π1, in which two photons from a strong pump (j=2) are destroyed and two sideband, or signal and idler, photons (j=3 and 1) are created (πj is an abbreviation for πjx). By linearizing Eqs. (23) and (24), one obtains input-output Eqs. (25)-(26):
X
1(z)=μ(z)X1(0)+ν(z)X*3(0) (25)
X*
3(z)=ν*(z)X1(0)+μ*(z)X*3(0) (26)
in which the transfer functions are expressed as follows:
μ(z)=cos(kz)+i(δ/k)sin(kz) (27)
ν(z)=i(
where the wavenumber-mismatch parameter δ=[β(ω3)+β(ω1)−2β(ω2)]/2+γsP2, the coupling parameter
Second, consider the inverse MI π3+π1→2π2, in which photons from two relatively strong pumps (j=3 and 1) are destroyed and two signal photons (j=2) are created. The inverse MI is characterized by the input-output Eq. (29):
X
2(z)=μ(z)X2(0)+ν(z)X*2(0) (29)
where the transfer functions are given by Eqs. (27) and (28), δ=[2β2(ω2)+β(ω3)−β(ω1)]/2+γs(P1+P3)/2, and
Third, consider a PC process π2+π3→π4+π1, in which photons from two relatively strong pumps (j=2 and 3) are destroyed, and signal and idler photons (j=4 and 1) are created. The PC process may be characterized by input-output Eqs. (30) and (31):
X
1(z)=μ(z)X1(0)+ν(z)X*4(0) (30)
X*
4(z)=ν*(z)X1(0)+μ*(z)X*4(0) (31)
where the transfer functions were defined in Eqs. (27) and (28), δ=[β(ω4)+β(ω1)−β2(ω2)−β(ω3)]/2+γs(P2+P3)/2, and
Fourth, consider a BS process π2+π3→π4+π1, in which photons from a relatively strong pump (j=3) and a relatively weak signal (j=2) are destroyed, and pump (j=1) and idler (j=4) photons are created. Then, the photon-exchange equations for BS and PC typically have the same form, but the identities of the pumps and sidebands are different. The BS process may be characterized by input-output Eqs. (32) and (33):
X
2(z)=μ(z)X2(0)+ν(z)X4(0) (32)
X
4(z)=ν*(z)X2(0)+μ*(z)X4(0) (33)
where the transfer functions were defined in Eqs. (27) and (28), δ=[β(ω2)+β(ω3)−β4(ω2)−β(ω1)]/2+γs(P1−P3)/2,
It was shown in the preceding section that the inverse MI with pumps whose frequencies are near the ZDF may provide polarization-independent phase-sensitive amplification. However, because dispersion is typically weak near the ZDF, secondary FWM processes may produce secondary pumps and idlers, which might consume bandwidth and deplete the primary pumps. One can suppress the generation of secondary signals by using primary pumps whose frequencies are far from the ZDF. Eqs. (27)-(29) have been used to model the inverse MI for the following examples of fiber parameters: β3=0.03 ps3/Km, β4=−0.0003 ps4/Km, γ=10/Km-W, and fiber length l=0.46 Km. The pump powers are P1=P3=0.25 W. The slowness parameter β1 typically has no substantial effect on the inverse MI when the waves are co-polarized.
The foregoing description primarily focused on inverse MI, which provides phase-sensitive amplification. The remaining portion of this section contains a discussion of PC [as described by Eqs. (30) and (31)] and BS [as described by Eqs. (32) and (33)]. Recall that a PC process may provide phase-insensitive amplification, whereas a BS process may provide phase-insensitive frequency conversion (provided that there are no input idlers). It was previously shown that strong birefringence can suppress vector PC, which involves x- and y-polarized pumps, and x- and y-polarized sidebands. This result implies that scalar x-polarized PC and y-polarized PC are independent processes. It was also shown that birefringence can inhibit vector BS, which involves x-polarized pumps and y-polarized sidebands, or x- and y-polarized pumps, and x- and y-polarized sidebands. This result implies that scalar x-polarized BS and y-polarized BS may be independent processes.
The theoretical predictions of
A separate numerical simulation was conducted for a case in which both pumps were polarized at 45 degrees to the birefringence axes of NLF or NPOW 308. The spectra obtained for different polarization components were almost identical to the spectrum of
In summary, when most of the wave frequencies are far from the ZDF, the effects of dispersion are typically important and typically cannot be neglected. For a typical MI, PC, or BS configuration of OPD 300, the effects of dispersion may reduce, but do not typically eliminate completely, the cascade of secondary waves produced by various FWM processes. When the pump frequencies are far from the ZDF, but the signal frequency is near the ZDF, the presence of a weak cascade does not typically affect the signal evolution significantly. If the pump waves are linearly polarized at 45 degrees to the birefringence axes, then the inverse MI may produce substantially polarization-independent, phase-sensitive amplification. When the pump and signal frequencies are all far from the ZDF, but close to each other, the signal may evolve in a phase-sensitive manner, but the presence of a moderate cascade may limit the magnitude of signal amplification.
Two additional FWM processes, i.e., phase conjugation (PC) and Bragg scattering (BS), were also considered. In PC, the sum of the sideband frequencies equals the sum of the pump frequencies. In BS, the difference between the sideband frequencies equals the difference between the pump frequencies. PC may provide phase-insensitive amplification, whereas BS may provide phase-insensitive frequency conversion. Dispersion in NLF or NPOW 308 may affect both processes. If the pump waves are polarized at 45 degrees to the birefringence axes, then the signals in the PC and BS configurations may experience polarization-independent amplification and frequency conversion, respectively. The weak cascades of frequencies that are generated in NLF or NPOW 308 may not significantly degrade the relevant properties of PC and BS. However, the bandwidths of these polarization-independent processes might be limited by the presence of a (usually small) difference between the zero-dispersion frequencies corresponding to the two birefringence axes.
At step 1402 of method 1400, first and second linearly polarized pump light waves are applied to a birefringent optical medium of the OPD. For example, see
At step 1404 of method 1400, an input signal S is applied to the optical medium. For example, see
At step 1406 of method 1400, a corresponding FWM process that couples the first and second pumps and input signal S generates, in the optical medium, a desired output signal. For example, the FWM process might include inverse modulational interaction, phase conjugation, and/or Bragg scattering.
At step 1408 of method 1400, the desired output signal is separated from one or more other optical signals present in the optical medium. For example, see
Throughout this specification, the units of [/Km-W] and [Tr/s] stand for per kilometer-watt and teraradians per second, respectively.
In various embodiments of the invention, the difference (δn) between the effective refractive indices corresponding to the fast and slow waves can be, e.g., between about 10−7 and about 10−3. The lower values of δn correspond to relatively weak birefringence, and the higher values of δn correspond to relatively strong birefringence. For typical pump-wave powers amplification, attenuation, or wavelength-conversion results may be obtained for values of δn ranging from about 10−5 to about 10−3.
While this invention has been described with reference to illustrative embodiments, this description is not intended to be construed in a limiting sense. For example, the desired polarizations can be produced in either lasers 306 or optical couplers 304, or by the combined effect of both. Various modifications of the described embodiments, as well as other embodiments of the invention, which are apparent to persons skilled in the art to which the invention pertains are deemed to lie within the principle and scope of the invention as expressed in the following claims.
Unless explicitly stated otherwise, each numerical value and range should be interpreted as being approximate as if the word “about” or “approximately” preceded the value of the value or range.
It will be further understood that various changes in the details, materials, and arrangements of the parts which have been described and illustrated in order to explain the nature of this invention may be made by those skilled in the art without departing from the scope of the invention as expressed in the following claims.
Although the elements in the following method claims, if any, are recited in a particular sequence with corresponding labeling, unless the claim recitations otherwise imply a particular sequence for implementing some or all of those elements, those elements are not necessarily intended to be limited to being implemented in that particular sequence.
Reference herein to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments necessarily mutually exclusive of other embodiments. The same applies to the term “implementation.”
Also for purposes of this description, the terms “couple,” “coupling,” “coupled,” “connect,” “connecting,” or “connected” refer to any manner known in the art or later developed in which energy is allowed to be transferred between two or more elements, and the interposition of one or more additional elements is contemplated, although not required. Conversely, the terms “directly coupled,” “directly connected,” etc., imply the absence of such additional elements.
The subject matter of this application is related to that of U.S. Pat. No. 7,164,526 and U.S. Patent Application Publication Nos. 2006/0285197 and 2007/0216994, all of which are incorporated herein by reference in their entirety.