In a fiber optic gyroscope, polarization errors result from interference between the primary lightwaves and spurious lightwaves, as well as interference among spurious lightwaves. The weak spurious lightwaves come from polarization cross-couplings at non-ideal fiber splices, in birefringent coil fiber, at junctions between integrated optical circuit (IOC) waveguides and its pigtail fibers, and inside optical components. These spurious lightwaves reaching the photodetector carry erroneous Sagnac phase information because they traveled nonreciprocal paths in the sensing loop. Methods of using Lyot-type fiber depolarizers and tailoring of the depolarizer polarization maintaining (PM) fiber lengths have been suggested to mitigate polarization errors. In prior art polarization error models, the polarization errors are evaluated in the time domain by keeping track of time and phase delays of spurious lightwaves originating from cross-couplings in the optical circuit. Wavelength dependent properties of the optical component, such as polarization dependent loss (PDL), polarization mode dispersion (PMD), etc., are often completely or partially ignored in the model. Specifically, for a depolarized gyroscope using a non-polarization maintaining single-mode (SM) fiber coil, the impact of the SM coil birefringence on the polarization error is empirically taken into account by assuming a broadened light source coherence function. Such simplifications lead to inaccuracies (up to one order of magnitude of deviation) in evaluation of polarization errors. More accurate modeling methods are needed to find optimal design parameters of interferometric fiber optic gyroscopes with reduced polarization error and bias instability.
In one embodiment, an optical circuit for a fiber optic gyroscope having a broadband light source and a single mode optical fiber loop comprises: a polarization maintaining (PM) delay management fiber of length v, having a first end and a second end, wherein the first end of the polarization maintaining delay management fiber is coupled a directional coupler that receives light from the broadband light source; an integrated optical circuit (IOC) having the integrated optical circuit coupled to the second end of the polarization maintaining delay management fiber via a first polarization maintaining fiber pigtail of length d1; the integrated optical circuit coupled to a second polarization maintaining fiber pigtail with length of d2; and the integrated optical circuit coupled to a third polarization maintaining fiber pigtail with length of d3; wherein the integrated optic circuit (IOC) comprises a polarization maintaining waveguide device having waveguide length of LIOC and comprise a polarizing element so that the total effective polarization extinction ratio (PER) of the integrated optic circuit is ε. The circuit further comprises a splitter that splits light received from the first polarization maintaining fiber pigtail into a first beam directed to the second polarization maintaining fiber pigtail and a second beam directed to the third polarization maintaining fiber pigtail; and a depolarizer circuit coupled to said fiber loop, said depolarizer region including a first optical fiber section of length x, a second optical fiber section of length z, a third optical fiber section of length w and a fourth optical fiber section of length y, each comprising polarization maintaining fibers having a beat length of LB; wherein the second optical fiber section is coupled to the first optical fiber section via a first splice, the first optical fiber section is coupled to a first end of the single mode optical fiber loop via a second splice, the fourth optical fiber section is coupled to the third optical fiber section via a third splice, and the third optical fiber section is coupled to a second end of the single mode optical fiber loop via a fourth splice; and wherein x+z is substantially equal to w+y; wherein the lengths of v, x, y, d1 and d3 are proportioned to avoid regions of high bias instability defined by the expressions v=x−(LIOC+y+d1+d3), v=2x−(LIOC+y+d1+d3), v=3x−(LIOC+y+d1+d3), and v=4x+y−(LIOC+y+d1+d3).
Preferred and alternative embodiments of the present invention are described in detail below with reference to the following drawings.
a and 3b illustrate two coil coherence functions and their associated wavelength dependent differential group delays (DGDs) in accordance with an embodiment of the present invention;
a and 9b illustrate a first example of contour plots of relative bias fluctuation amplitude as a function of PM fiber lengths, x and v;
a and 10b illustrate a second example of contour plots of relative bias fluctuation amplitude as a function of fiber lengths, x and w; and
Embodiments of the invention are operational with numerous other general-purpose or special-purpose computing-system environments or configurations. Examples of well-known computing systems, environments, and/or configurations that may be suitable for use with embodiments of the invention include, but are not limited to, personal computers, server computers, hand-held or laptop devices, multiprocessor systems, microprocessor-based systems, set-top boxes, programmable consumer electronics, network PCs, minicomputers, mainframe computers, distributed-computing environments that include any of the above systems or devices, and the like.
Embodiments of the invention may be described in the general context of computer-executable instructions, such as program modules, executed by a computer. Generally, program modules include routines, programs, objects, components, data structures, and the like that perform particular tasks or implement particular abstract data types. Embodiments of the invention may also be practiced in distributed-computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed-computing environment, program modules may be located in both local- and remote-computer storage media including memory storage devices.
The operating environment illustrated in
With reference to
Depending on the exact configuration and type of computing device, memory 104 may be volatile (such as random-access memory (RAM)), non-volatile (such as read-only memory (ROM), flash memory, etc.) or some combination of the two. This most basic configuration is illustrated in
Additionally, device 100 may have additional features/functionality. For example, device 100 may also include additional storage (removable and/or non-removable) including, but not limited to, magnetic or optical disks or tape. Such additional storage is illustrated in
Device 100 may also contain communications connection(s) 112 that allow the device to communicate with other devices. Communications connection(s) 112 is an example of communication media. Communication media typically embodies computer-readable instructions, data structures, program modules or other data in a modulated data signal such as a carrier wave or other transport mechanism and includes any information delivery media. The term “modulated data signal” means a signal that has one or more of its characteristics set or changed in such a manner as to encode information in the signal. By way of example, and not limitation, communication media includes wired media such as a wired network or direct-wired connection, and wireless media such as acoustic, radio-frequency (RF), infrared and other wireless media. The term computer-readable media as used herein includes both storage media and communication media.
Device 100 may also have input device(s) 114 such as keyboard, mouse, pen, voice-input device, touch-input device, etc. Output device(s) 116 such as a display, speakers, printer, etc. may also be included.
An embodiment of the present invention pertains to interferometric fiber optic gyroscopes (IFOGs), and particularly to depolarized IFOGs using non-polarization-maintaining SM fiber in the sensing coil. More particularly, an embodiment of the present invention pertains to the reduction of bias instability originated from polarization errors. Embodiments include both analytical/computational and empirical methods of testing and designing such gyroscopes.
The optical circuit 1 of a depolarized gyroscope is shown in
A strict theoretical description of a broadband light source may require taking into account all the wavelength components and polarization states. However, for simplicity of the following discussion and without loss of generality, it may be assumed that the light source only contains two orthogonal polarization states for each wavelength component arriving at splice 30 in
Here we may assume the PDL experienced by the light source before point 30 is along the Y axis (i.e., the polarization state that experiences more loss is along the axis orthogonal to the plane of paper in
The light fields reaching the photodetector 14 can be modeled using a Jones-matrix description of the gyro optical circuit 1. Element 12 can be any kind of directional coupler. Here, a 2×2 coupler is used as an example, which may include polarization maintaining (PM) fiber leads. There is normally a rotation angle α between the input light PDL axis and the PM fiber pass axis. The Jones matrix of such an angle rotation at splice 30 can be expressed as
If light emitted by the light source 11 experiences wavelength dependent PDL, the rotation angle α(λ) may be a function of wavelength λ. For simplicity, we implicitly assume the wavelength dependence of every parameter and omit the λ in the following expressions.
The propagation of light through the directional coupler 12, including its fiber leads, can be described by a Jones matrix Hin. This matrix takes into account the polarization dependent splitting ratio, PDL, cross-couplings and phase delays incurred by the coupler 12 as light propagates from splice 30 to splice 31.
Element 15 may be a piece of PM fiber that connects the coupler 12 and an integrated optical circuit (IOC) 16. Element 15 has a Jones matrix of
where d15 is the relative phase delay of the slow axis with respect to the fast axis of the PM fiber 15. The IOC pigtails 33, 36 and 38 may be PM fibers. They can similarly be described by delay matrices
The splices, 31 and 32, between PM fibers, and the connection points, 34, 35 and 37, between IOC pigtail fibers and the IOC waveguides, are not perfect. They introduce small polarization cross-couplings, which can be described by Jones matrices
For light propagation from splice 30 to splice 34, the total Jones matrix G is
The electric field at the input point 34 of the IOC waveguide is therefore
Next, a Jones matrix
is used to represent the transmission of light through the sensing loop 10 in the clockwise direction, without taking into account the IOC phase modulation and its polarization extinction ratio ε. For the depolarized gyroscope shown in
Here, D40 and D41 are delay matrices for the IOC waveguide 40 and 41. Delay matrices D21, D23, D26, D28 are for segments of PM fibers that constitute the depolarizer 200, which contains an upper section 210 and a lower section 220. The imperfect splices 20 and 25 with small angle misalignments are represented by matrices K20 and K25. The two 45° angle splices 22 and 27 between the two pair of depolarizer PM fiber segments 21, 23 and 26, 28 are represented by matrices R22 and R27. Once can also include rotation matrices R24 and R29 for the splices 24 and 29 between the depolarizer sections 210, 220 and the fiber leads 101, 102 of the single-mode sensing coil 10.
The Jones matrix for propagation of light in the counter-clockwise direction is the transpose of the clockwise counterpart, i.e.
Again, the IOC phase modulation and polarization property are not taken into account in this matrix.
The integrated optical circuit (IOC) 16 may be composed of a polarizing element 18 (alternatively, the polarizing element itself could be a waveguide), a beam splitter/combiner 17 and two or more electrodes 19 for phase-modulation of the light beams passing through the IOC waveguides 40 and 41. This phase modulation function of IOC is used for gyro bias modulation, which typically changes the phase of light polarized along the pass axis (the horizontal x-axis is assumed here) with a period equal to loop transit time τ. If a clockwise propagating lightwave experiences a modulation phase φU(t) at the upper waveguide, it experiences a different modulation phase φU(t+τ) at the lower waveguide. During the same time, the counter-clockwise wave can experience a modulation phase of φL(t) at the lower waveguide and φL(t+τ) at the upper waveguide. For the situation of push-pull square-wave modulation, one can simply assume φU(t)=φL(t+τ)=φB and φL(t)=φU(t+τ)=−φB without loss of generality. In this case, the matrix that takes into account the IOC bias modulation and polarization extinction ratio for clockwise light propagation is
and that for the counter clockwise propagation is
The combined electric fields of CW and CCW light at IOC output 34 are therefore determined by the following equation:
Taking into account the Sagnac phase 2φR induced by the rotation sensing and expanding the above equation, yields:
To obtain the electric field at the photodetector 14, matrix F is used to describe the optic path from point 34 to the photodetector 14. It is:
Here K32T, K33T, K34T are the transposes of matrices K32, K33, K34 respectively Hout is the coupler matrix for light transmission from splice 31 to photodetector 14. Matrix
takes into account the mismatch angle of the PM fiber axis with respect to the axis of photodetector polarization-dependent responsivity, which is accounted for by matrix
With the matrix F, the electric field at the photodetector 14 can be expressed as
The power of the horizontally polarized light at the photodetector 14 is
Substituting (12) and (13) into (18) yields:
In equation 19, φM-N, φM-L, φN-L, φL-J and φAx-Ay express the phase differences of the complex numbers M and N; M and L; N and L; L and J; Ax and Ay. Similarly, term φF11-12 represents the phase differences of complex numbers F11 and F12.
Demodulation of the above push-pull square-wave bias modulated signal is accomplished by calculating the differences of the light intensity in the neighboring time slots of loop transit time τ. Since the φB flips the sign in the neighboring period, τ, the demodulated signal is calculated by
For the primary signal (i.e., the first term in Eq. (19)), the demodulated signal is
Demodulation of other terms in (19) yields two major types of polarization errors. One type is called amplitude type error, which is proportional to IOC polarization extinction ratio ε. The other type is called intensity type error, which is proportional to ε2. Higher order terms are extremely small, and therefore are neglected for purposes of simplicity in the following discussion. Performing demodulation calculation similar to those in Equations (20) and (21), the amplitude-type polarization error light intensity along the x-axis is:
The intensity-type polarization error light intensity along the x-axis is
In a similar manner, we can obtain the demodulated main signal along the y-axis
The amplitude-type polarization error intensity along the y-axis is
The intensity-type polarization error along the y-axis is
The electric fields, Ax and Ay, in expressions from (21) to (26) can be replaced by the incoming broadband light source fields, E0x and E0y. After applying Eq. (7), the intensity |Ax|2, |Ay|2 and AxA*y can be expanded into the following form:
In the above equations, the terms that have phase difference of E0x and E0y components can be ignored because they are uncorrelated and average to zero over time.
Summing the intensities along both x- and y-axes, and using equations, E0x(λ)=√{square root over (S(λ))}, E0y(λ)=t11y√{square root over (S(λ))} implied in Eq. (1) for light with intensity S(λ) at wavelength λ, the main signal light intensity becomes
The total main signal intensity is obtained through wavelength integration over the entire light source spectrum. From (30), the scale factor to convert light intensity to rate in unit of deg/hr is obtained,
where Lcoil and Dcoil are the sensing coil 10 fiber length and average coil diameter, and
The total amplitude type error, taking into account both x- and y-axes, is
The total intensity-type error is
The total error rate originated from both amplitude- and intensity-type polarization errors may thus be:
Integration over wavelength from λ1 to λ2 covers the broadband light source wavelength range. Data characterizing the total error rate and/or other error information may be displayed to output device 116.
The approach described above predicts a bias offset when there are polarization errors. Since the polarization errors are the result of interference of waves propagating along different respective optical paths, relative changes of optical paths will cause the corresponding polarization error to fluctuate. The said “optical path” depends on the polarization state of the light. For a PM fiber, there are two polarization modes. One mode is polarized along the so-called “slow polarization axis” in the fiber cross-section. It acquires more phase delays than the other polarization mode which is polarized along the orthogonal “fast polarization axis”. The slow mode effectively travels along a longer optical path than the fast mode. To quantify the phase difference associated with the fast and slow modes in a PM fiber, it is advantageous to express the lengths of fiber in terms of “beat length” (LB), such that LB=λ/Δn, where λ is the light wavelength, and Δn is the difference in effective mode refractive index between the fast and the slow polarization modes. Typically, LB ranges from 1 mm to 4 mm. The phase difference between slow and fast light after propagating over fiber length of LB is 2π. Typically, the fiber beat length LB increases slightly when temperature increases (i.e., the temperature is ramped). Changing the PM fiber temperature is equivalent to changing the phase difference of the slow and fast light waves, and is one of the effective ways to excite polarization error induced bias fluctuations. For example, if the PM fiber 15 is assumed to have a length of v=10000 LB, and the beat length LB of the PM fiber has a temperature sensitivity of 500 ppm/° C., the relative phase change of the fast and slow light will undergo five cycles per ° C., i.e. 10π/° C.
In the calculation method developed above, the wavelength dependent Jones matrix of the single mode non-polarization-maintaining fiber coil is used. The matrix can actually be measured directly using a polarization-mode-dispersion (PMD) characterization instrument. The coil matrix can also be modeled by treating the coil as a concatenation of many random birefringent elements. With the availability of the coil Jones matrix, the coherence function and the wavelength dependent differential group delay (DGD) of the coil can be determined.
The coupler 12 in the optical circuit also plays an important role in controlling polarization errors. As mentioned earlier, the Jones matrix of the coupler shall take into account the polarization dependent splitting ratio (PDSR) and PDL. For light propagating from point 30 to point 31, the x- and y-polarized light have different amplitude transmission coefficient sx and sy. There are also cross-couplings between x- and y-polarized light that can be quantified by parameter k12. After taking into account the phase delays, d121, d122 of the input and output pigtails 121 and 122 of the coupler, the Jones matrix of the coupler 12 can be written as
In the above equation LPDSR is the polarization splitting ratio difference in decibel units. Other PDL are omitted for simplification. Since the common loss and phase experienced by both x- and y-polarized light are not important in the final result of the polarization error calculation, the factor of sx in the expression of (35) may be omitted in the last step. Similarly, for propagation of light from point 31 to photodetector splice 13, the coupler matrix can be written as
where d123 is the phase delay caused by the coupler pigtail 123. Although small PDSR has been assumed in the approximations of expressions, it is not intended to limit the application of the method to use more general forms of Hin and Hout matrices. As illustrated in
Most of the spurious light producing polarization errors originates from cross-couplings at fiber splices or in optical components. It is therefore advantageous to reduce these cross-couplings as much as possible.
In the calculation of polarization error, one can observe that the amplitude-type polarization error is proportional to the IOC polarization extinction ratio (PER), ε, and the intensity type error is proportional to ε2. As an example,
Design of depolarizer 200 and the PM fiber 15 are effective ways to reduce gyro bias error according to an embodiment. As illustrated in the example of
In an embodiment, the length, w, is selected to be approximately twice that of length, x (i.e., w=2x). In addition, the physical lengths of the depolarizer section 210 and 220 are kept approximately the same (i.e., z=x+y). Sections 210, 220 may be winded onto the coil 10 with the symmetrical points, i.e. points with equal optical length measured from splitting point 17 in IOC, located close to each other to avoid the temperature-fluctuation-induced non-reciprocal phase noise (i.e., the so-called Shupe effect induced noise). To minimize the overall depolarizer length, the length, y, and IOC pigtail lengths, 33, 36 and 37 may be selected to be as short as possible. In such an embodiment of the model, the optimal lengths of x and v are determined once the IOC, coupler and coil properties are known.
As an example of showing the method to optimize the depolarizer and PM fiber 15 design, the calculated relative bias fluctuation amplitude under temperature ramp is plotted as functions of x and v in the contour plots illustrated in
Still referring to
where d32-27=LIOC+y+d33+d38 is the relative phase delay of the fast and slow light of the optical path between 32 and 27, which includes the IOC waveguide 41, pigtails 33 and 38, and the depolarizer PM fiber 26. These regions of high bias instability are associated with amplitude type polarization errors originating from the interference of the IOC-passed (x-polarized) waves and the IOC-rejected (y-polarized) waves traveling through the sensing loop 10. A preferable choice of design is often situated in the region A because of its larger low error region providing greater margins against coil uncertainties. However, designs in region A may require longer lengths of depolarizer and PM fibers 15, which may be of concern for gyro packaging and control of Shupe effect. Regions B, C, D and E are therefore of interest in design choices for reducing the PM fiber lengths.
However, the depolarizer x length cannot be lowered below a certain value. The broader vertically oriented regions on the left sides of
As another illustration of an embodiment of a depolarized gyroscope, one can optimize the lengths x and w as separate parameters, rather than observing the relation w=2x. In such an embodiment, the length y can be set to a fixed value, and w+y is set equal to the sum of x and z (i.e., z=y+w−x). As such, the depolarizer sections 210 and 220 have the same length. Next, the PM fiber 15 may be first set to a large value. As discussed elsewhere herein, it is known that v-insensitive error can be minimized by setting the length v, to a very large value. The design may now be reduced to the determination of the optimal lengths of x and w. Once optimal x and w is found to minimize the v insensitive polarization error, the PM fiber 15 length v can then be determined to reduce the v sensitive polarization errors. One will see below that w=2x used in an earlier-discussed embodiment is indeed one of the optimal selections of the w-x relationship for better bias stability.
a and
An embodiment includes using a temperature-ramping approach, for example, to select optimized values of depolarizer fiber section length w and x substantially in the regions of F, G, H and J shown in
The relative bias amplitude in these regions can be clearly seen by referring back to
While preferred embodiments of the invention have been illustrated and described, as noted above, many changes can be made without departing from the spirit and scope of the invention. Accordingly, the scope of the invention is not limited by the disclosure of the preferred embodiment. Instead, the invention should be determined entirely by reference to the claims that follow.
The present application is a continuation of, and claims priority to, U.S. patent application Ser. No. 12/187,932 (hereafter “the '932 Application”), entitled “BIAS-INSTABILITY REDUCTION IN FIBER OPTIC GYROSCOPES” filed on Aug. 7, 2008.
The U.S. Government may have certain rights in the present invention as provided for by the terms of a Government Contract No. N00030-08-C-0010 with the U.S. Navy.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 12187932 | Aug 2008 | US |
Child | 12848592 | US |