Definitions

• the present invention relates generally to Sagnac interferometers or more particularly to gyros, which employ optical waveguides, formed on or in the surface of a substrate such crystaline Lithium Niobate or silica glass.
• Optical rotation sensors such as RLGS (ring laser gyroscopes) FOGS (fiber optic gyroscopes), IFOGS (interferometric fiber optic gyroscopes), RFOGS (resonant fiber optic gyroscopes) and integrated optic gyros are based on the well-known non- reciprocal optical effect known as the Sagnac effect.
• a FOG has a fiber optic coil formed on a coil form. Light from a common source is launched into each end of the coil to form CW (clockwise waves) and CCW (counter-clockwise waves). When the FOG is at rest in inertial space, the CW and CCW waves have the same transit time through the coil. When the two waves are coupled out of the coil and superimposed on a detector, they exhibit a near zero phase difference. When the FOG is rotated around its axis of symmetry, however, the two waves no longer have identical transit times, and will exhibit a phase difference that appears as an interference pattern on the detector, that increases with the rate input to the gyro.
• the phase difference, and hence, the output intensity that results, is proportional to the rotation rate, as well as to the area enclosed by the fiber optic coil.
• Analysis of the output intensity generated by the combined light waves at the photodetector typically by means input signal modulation and output signal demodulation, provides a precise indication of rate and direction of rotation. Winding lengths of low-loss optical fiber into a relatively small coil creates a large effective area, making it possible for a compact sensor to resolve very small rotation rates.
• the manufacturing cost of the fiber optic coil component for a FOG gyro is considerable and can the cost can exclude their use from some applications.
• output bias stability problems due to varying thermal gradients throughout a coil wound on a bobbin or coil form can limit the FOG's performance.
• This invention provides an IOG, (integrated optic gyro) and reduces the cost of the waveguide coil for an IOG, further adapting the FOG to mass-production, and provides better thermal control of the coil for enhanced performance.
• the invention increases the scale factor of an IOG by using at least two substrates, each containing a spiral shaped waveguide. The area enclosed by the turns within the coil limits the scale factor of an IOG.
• Integrated optic gyros that use waveguides that are formed on, or in, the surface of a substrate have a sensitivity that is limited by the total area enclosed by the turns of the spiraling waveguide. The area is doubled by the use of a second substrate, and, in addition, a novel method is taught for forming the turns on the substrate.
• the spiral coils, formed on the top and bottom substrates, are positioned to be co-axially aligned.
• the coils are coupled together using one or more optical fiber pigtail connections.
• the structure of dual substrate coil mounted on opposing sides of a thermally conductive mounting plate is believed to improve the thermal control of the coil over the prior art.
• Fig. la is a schematic perspective view of the integrated optic gyro using a first and second coupler, PZT modulator and a laser diode as a system;
• Fig. lb is a schematic perspective view of the integrated optic gyro using a first and second coupler, a modulator having electrodes astride a waveguide segment;
• Fig. 2a is a schematic perspective view of the integrated optic gyro using a single coupler, an MIOC and a stabilized fiber light source as a system;
• Fig. 2b is a schematic plan view of the top substrate top surface and a bottom substrate bottom surface each having a spiral waveguide formed thereon, the waveguides being coupled to each other and to and to the MIOC;
• Fig. 3 is a sectional view of the multi-level optical coil taken on line 3-3 in Fig. la that schematically shows the thermally conductive mounting plate, and the top and bottom substrates;
• Fig. 4 is a schematic partial plan view of a portion of the outer edge of the top substrate showing a pair of parallel modulator electrodes straddling a segment of waveguide;
• Figs. 5a - 5f show the steps in one alternative method of making a spiral wave guide.
• FIGS la, lb, 2a and 2b are schematic perspective views showing alternative embodiments of the integrated optic gyro 10 as having a multi-level optical coil 12.
• Figure 3 a schematic sectional view of Figures 1 taken on section line 3-3, more clearly depicts the construction of the multi-level optical coil 12.
• the multi-level optical coil 12 is shown having a mounting plate 14.
• the mounting plate 14 has a top surface 16 and a bottom surface 18.
• Top substrate 22 and bottom substrate 23 are also shown.
• the top substrate 22 has a top surface 24 and a bottom surface 26.
• the top substrate's bottom surface 26 is bonded by an adhesive layer 28 to the mounting plate's top surface 16.
• Bottom substrate 23 has a top surface 32 and a bottom surface 34.
• the bottom substrate's top surface 32 is bonded by adhesive layer 33 to the mounting plate's bottom surface 18.
• the mounting plate 14 provides both mechanical and thermal stability to the top and bottom substrate and thereby also to the top waveguide coil 36 and the bottom waveguide coil 40.
• Preferred materials for the mounting plate include those with low coefficients of thermal expansion and high thermal conductivity such as alumna and metal filled ceramics.
• the mounting plate 14 is manufactured by casting, machining, sintering or other conventional methods.
• Suitable adhesives include those having a low thermal expansion and low shrinkage, such as glass filled epoxies. Chockfast Orange from ITW Philadelphia Resins, 130 Commerce Drive, Montgomeryville, PA 18936, USA is an example of such an adhesive.
• the top waveguide coil 36 is shown formed in the top substrate top surface 24.
• the bottom waveguide coil 40 is shown formed in the second substrate bottom surface 34.
• the coils are shown with their respective turns evenly spaced.
• the sensitive axis of the gyro 41 is shown.
• the sensitive axis 41 is shown in Figure 3 as being substantially normal to the plane of the top substrate top surface 24.
• phantom box 42 represents a coupler that typically comprises a first and a second 2X2 fused bi-conical coupler connected as shown.
• a single 2X2 coupler 42a is used in applications in which an MIOC 78 (Multifunction Integrated Optics Chip) is used, as is shown in Figures 2a and 2b.
• MIOC 78 Multifunction Integrated Optics Chip
• Coupler 42 can be regarded as a single 2X2 coupler that has an input port 44, a first output port 46, a second output port 48 and a third output port 52.
• a combination of first and second fused biconical tapered couplers shown in Figures la and lb is preferred in high accuracy applications absent an MIOC.
• fused bi-conical tapered fiber optic couplers such as 42a are formed from two fibers that are twisted together and fused over a region. As such, the two fibers have four ends with ports 44, 46 and 48 and 52.
• third port 48 is rendered non-functional, because it is not used. It is made non-functional by coating its end with a high refractive index adhesive or by crushing it or by angle polishing it so that light striking its surface is not reflected back into the fiber.
• Figure 2b shows a first optical fiber 54 coupling the top waveguide coil 36 to the bottom waveguide coil 40. Light passing through the two coils is coupled by the first optical fiber 54 so as to have a common rotational sense.
• the first optical fiber 54 By way of example, if light enters the top waveguide coil 36 from the MIOC 78 first output port 96 via second optical fiber 56, the light wave can be seen to travel in a CCWO (counterclockwise outward) direction from the top of the gyro looking down.
• Figure 2b shows the first optical fiber 54 connecting the outer port of top waveguide coil 36 to the outer port of the second optical fiber 40.
• Figure la provides no information on how the bottom waveguide coil 40 is wound. It might be wound on the bottom surface 34 of the bottom substrate 23 as a CWO (clockwise outward) spiral or as a CCWO (counter-clockwise outward) spiral.
• the top waveguide coil 36 is wound as a CCWO spiral on the top substrate top surface
• the bottom waveguide coil 40 is also wound as a CCWO spiral on the bottom substrate bottom surface
• connecting the outer ports of the top waveguide coil and bottom waveguide coil 40, as shown will obtain a common rotational sense, and also minimize the effect of time-varying thermal gradients across the coil, commonly known as the Shupe effect.
• the first optical fiber 54 is shown making this connection.
• Figures la and lb show the third optical fiber 58 connecting the coupler's second output port 48 to the bottom waveguide coil 40.
• Figure 2a and 2b show the second and third optical fibers 56, 58 delivering CCW and CW waves 59, 60 from the first and second output ports of the MIOC to the inner ports of the top waveguide coil and the bottom waveguide coils respectively.
• a light source represented by box 61, and phantom box 61a, is coupled to provide a light wave represented by phantom line 62 to the coupler's input port 44.
• the light source 61 is typically a low coherence source selected from the class of light sources comprising solid state ELEDs (Edge emitting Light Emitting Diodes) and SLDs (Super Luminescent Diodes), and sources such as the BFS (Broad Band Fiber Sources) shown in Figure 2a within phantom box 61a.
• ELEDs Electronicdge emitting Light Emitting Diodes
• SLDs Super Luminescent Diodes
• BFS Broad Band Fiber Sources
• the coupler 42 splits light wave 62 into substantially equal first and second (CCW, CW) output waves 59, 60. Coupler 42 combines the two beams coherently to produce an output beam 42, 64 from its third port 52 to.
• the top waveguide coil 36 of Figure la as depicted establishes that the first rotational sense is CCW when viewed from above.
• the coupler outputs the second output wave 60 from its second output port 48 to form to form a wave with a second rotational sense, i.e., CW, in the bottom and top waveguides 40 and 36 respectively that has a rotation rate-dependent intensity.
• the combination of a single coupler 42 and a MIOC 78, as shown in Figure 2a duplicates the function of coupler 42 in Figures la and lb of splitting the input light wave 62 into two substantially equal parts and recombining the beams from the coils.
• Coupler 42 outputs a first output beam 59 from its first output port 46 to form a beam with a first rotational sense, i.e., CCW, in the top and bottom waveguides 36 and 40, respectively
• a piezostrictive cylinder of lead zirconate titanate PZT, 68 is shown wrapped with coils from optical fiber 58.
• the cylinder 68 represents a first alternative embodiment of an optical phase modulator means when driven by a signal from a phase modulator drive electronics circuit 70a via signals 72a, 72b via signal lines 74a, 74b.
• the PZT can be connected, as a design choice, in the branch of the second optical fiber 56 or in the branch of the third optical fiber 58 to thereby induce a phase shift in light passing through the second or third optical fibers 56, 58.
• the diameter of the PZT cylinder changes slightly when a voltage is applied to its terminals.
• the change in diameter results in a strain on the tightly wound portion of the third optical fiber 58.
• the strain in the fiber results in a change in the optical path length of the third optical fiber 58, thereby changing the relative phase of the light passing through it.
• Proper timing of signals 72a, 72b depend on the optical path length of the integrated optic waveguides and the fibers between outputs 46 and 48 ensures application for a non-reciprocal phase shift between the CW and CCW waves for signal processing.
• Figure 4 is a schematic broken-away section of Figure lb that shows a second alternative embodiment of a modulator means.
• Conductive electrodes 76a, and 76b are formed on the top surface 24 of the top substrate 22 creating a nearly parallel plate capacitor across wave guide 36. The same conductive electrodes are depicted on Figure lb. These conductive electrodes also provide a modulator means for modulating the phase of the first output wave and the second output wave. The conductive electrodes straddle a straight portion of the top optical coil 36. In the alternative, (not shown) a pair of conductive electrodes formed on the bottom substrate 23 closely straddle a straight portion of the bottom waveguide coil 40. The conductive electrodes are electrically driven by phase control signals on signal lines 74a, 74b.
• Signal lines 74a, 74b are either connected to the PZT 68 or to the conductive electrodes 76a, 76b in an application, but not to both.
• the embodiment of Figure 2a and 2b shows the use of an MIOC (multifunction integrated optics chip) 78 which is formed from a wafer of crystaline Lithium Niobate and processed to have a Y-shaped waveguide junction.
• the waveguide is formed using a proton exchange method or titanium indiffusion.
• the Y- shaped junction has an input segment 80, a CW (clock-wise) segment 82 and CCW (counter clockwise) segment 84 straddled by modulator electrodes 88, 90, and 92.
• the waveguide could also be formed on a silicon wafer by the deposition of germanium doped silica using photo-lithographic methods.
• the top and bottom waveguide coils 36 and 40 might also be formed using polymer waveguide structures on silica as an alternative to proton exchange or titanium in diffusion on LiNbO3 waveguides.
• Polymer waveguides are also suitable and are described in U.S. Patent 5,352,556 and 5,136.682.
• Polymer waveguides are described in connection with a phase modulator in WP 0 402 803 A2.
• ARROW waveguide structures on silicon are also suitable, and are described in U.S. Patent 5,367,58. The contents of these patents are incorporated herein by reference in their entirety.
• the MIOC 78 shown in Figure 2a and 2b is a third alternative modulator means for modulating the phase of the wave with a first rotational sense and the wave with a second rotational sense.
• the "Y" junction has an input port 94 , and a first and a second output port 96, 98. At least region of the waveguide between the Y junction input port 94 and output ports 96 and 98 must linearly polarize light.
• the second optical fiber 56 couples the MIOC first output port 96 to the top waveguide coil 36.
• the third optical fiber 58 couples the MIOC second output port 98 to the bottom waveguide coil 40.
• the optical coupler first output port 46 of coupler 42a is coupled the MIOC input port 94.
• the optical coupler second output port 78 is unused and is treated to eliminate reflections into the gyro.
• the waveguide 92 are electrically driven by a phase modulation signal (not shown) from the modulator drive electronics 70b to induce a phase shift in light passing through the second or third optical fibers 56, 58 or both, at any given instant in time.
• the waveguide is configured to support only the optical polarization state allowed or transmitted by the polarizing portion of the waveguide.
• the waveguides on the top and bottom substrates can also be formed as spiral waveguides using the steps of Figures 5a - 5f.
• other geometric forms may work as well, or better, to accommodate other form factors.
• an ellipse of comparable area might be preferable to a pure circular spiral for an application requiring a narrow package.
• top waveguide coil 36 and the bottom waveguide coil 40 are each formed separately by first forming a the waveguide core 108 shown in cross-section in Figures 5e and 5f, within an optical substrate 110.
• the method begins by providing a blank optical disc 112, typically of silica glass, as shown in Figure 5a.
• the optical blank disk has a top and bottom surface 114, 116.
• the process of forming waveguide core 108 begins with rotating the optical blank disk 112 about an axis 113, between respective top and bottom laser waves 118 and 120.
• the laser waves are adjusted in power, aperture and focus.
• the laser source is guided by a digital program.
• Digital control is used to control the movement of the laser along a radial of the rotating substrate.
• the movement is from the outer edge to the center coincident with axis 113, or from the center to the outer edge at a speed adjusted to define opposing paths shown in Figure 5b as channels 122a, 122b, 122c on the top surface 114 and as 124a, 124b on the bottom surface 116.
• the waves are focused or masked to cut groves that form the boundaries for the core regions that when coated a material for cladding, will provide a predetermined optical coil waveguide.
• the optical coils are joined by a continuous web region, shown in section on the top as 122a, 122b, 122c and on the bottom as 124a, 124b.
• the web regions have a top and bottom surface shown as surfaces 126 and 128 and a depth on the order of 1 - 10 ⁇ m.
• the top and bottom of the resulting structure of optical webbing is then masked with a coat of photoresist material 130 as shown in Figure 5c.
• the photoresist adjacent to the web material is removed leaving the core regions 108 exposed as shown in Figure 5d.
• a laser could be used to clear a spiral through the mask. The cleared area is centered on the core areas.
• the exposed web regions are then doped with a material selected to raise the index of refraction of the region that will be the core region.
• the protected web region will have a lower index of refraction than that of the core regions 108.
• the remaining photoresist aterial is then removed leaving the structure characterized by Figure 5e. This preceding step defines the margins 122a, 124a or boundaries of optical cores 108 that in combination with the web regions 122a, 124a define the waveguides.
• Germanium Dioxide could be used as a doping for the web areas to change the index of refraction of silica glass.
• Figure 5e shows the result of chemically removing the mask.
• the resulting structure should be strong enough to permit handling.
• the core regions 108 are hatched with dots.
• Step 5f shows the result of the final step of cladding the top and bottom surfaces of the guide of optical cores 108 with an optical material having substantially the same index of refraction as that of the web regions 122a, 124a.
• the result is the formation of the optical substrate 110 containing the waveguide coils 36 therein.
• Two optical substrates 110 are then bonded to a thermally conductive ceramic substrate 14 or onto a thermally conductive substrate having a thermal coefficient of expansion selected to closely match that of the optical substrates 110.
• a pigtail connection is made from the outer ends of the top waveguide coil 36 and the outer edge of the bottom waveguide coil 40 to make a reciprocal unit.
• the remaining inner ends of the optical waveguide are connected to the first and second optical fibers 56 and 58.
• the bottom substrate 23 of Figures la, lb and 2a , the bottom waveguide coil 40 and the first optical fiber 54 are eliminated.
• the top waveguide coil is 36 having a core 108 has a first and second port.
• the second optical fiber 56 connects the first output port of coupler 42 to the top waveguide coil 36 first port within optical substrate 110.
• the third optical fiber 58 connects the coupler's second output port to the top waveguide coil 36 second port.
• the top waveguide coil 36 is formed using the method steps characterized above relating to Figures 5a though 5f. Moving the lasers along a radial track at constant velocity will produce a coil with a spiral character and with equal distance between coils.
• the gyro comprises a multi-level optical coil having a top substrate 22, and a bottom substrate 23.
• the mounting plate 14 is omitted.
• the first and second substrates are bonded directly to each other. All remaining features of the integrated optic gyro are thereafter, the same, as explained above.
• the method or process for making the integrated optic gyro of Figure la, lb, 2a or 2b comprises the steps of: Forming a multi-level optical coil having a mounting plate 14 having a top and bottom surface, a top substrate 22, and a bottom substrate 23. Each substrate has a top and bottom surface. A top spiral waveguide coil is formed in the top substrate and a bottom spiral waveguide coil is formed in the bottom substrate. The top substrate bottom surface is bonded to the mounting plate top surface. The bottom substrate top surface is bonded to the mounting plate bottom surface.
• a coupler 42 is provided.
• the coupler has an input port and first, second and third output port.
• a first optical fiber is used to couple the top waveguide coil to the bottom waveguide coil.
• the coils are coupled so as to have a common rotational sense with respect to the gyro's sensitive axis, which is typically normal to the plane of the top substrate.
• a second optical fiber is then used to connect the coupler's first output port to the top waveguide coil.
• a third optical fiber is then used to connect the coupler's second output port to the bottom waveguide coil.
• a light source 61, 61a, 61b is then coupled to provide a light wave 62 to the coupler's input port 44.
• the coupler 42 splits the light wave 62 into substantially equal first and second output waves 59 60
• the MIOC 78 linearly polarized light splits the light wave 62 into substantially equal first and second output waves 59, 60.
• the first output wave 59 is output from the coupler's first output port 46 to form a wave with a first rotational sense in the top and bottom waveguides 36, 40.
• the second output wave 60 is output from the coupler's second output port 48 to form a wave with a second rotational sense in the bottom and top waveguides.
• a modulator means such as PZT 68, electrodes 76a and 76b on substrate 24 or MIOC 78 is coupled to modulate the phase of the wave with a first rotational sense and the wave with a second rotational sense.
• a detector means 66 is coupled to receive light from the coupler's third output port 52 and to provide a detected electrical signal.
• phantom box 66 represents a detector means.
• the detector means typically comprises a photodetector 130 and preamplifier 132 combination 130.
• the output signal from the coupler's third output port 52 is directed toward the detector, 66.
• the detector 130 outputs a detected signal to preamplifier 132, which amplifies and buffers the detected signal.
• the preamplifier outputs the buffered signal to a low-pass filter 134.
• the low-pass filter 134 outputs the filtered detected signal to a synchronous demodulator 136.
• the synchronous demodulator is driven by a reference signal from the phase modulator output 72c to provide a detected output signal.
• Reference to Figure 2b sampling electronics 138 samples the value of the detected signal and periodically transfers the signal to a digital computer 140 via buss 142.
• the computer 140 outputs the processed detected signal as rate information on buss 144 and provides a continuously corrected phase modulation signal to the phase modulation drive electronics 70b on buss 146.
• Block 61b represents the preferred embodiment, utilizing a broadband superfluorescent fiber source.
• Block 150 represents a pump source control.
• the output of the pump source control drives a pump diode 152.
• the pump diode outputs pump light via a WDM 154 (wavelength division multiplexer) to an erbium-doped fiber 156.
• the erbium-doped fiber provides broadband light over a predetermined band to the WDM 154 which directs the light from the doped fiber to the input port 44 of coupler 42.
• an SFS superfluorescent source
• the operation of a superfluorescent source is discussed at length in U.S Patent 5,136,600 to B.
• Coupling of the first second and third fibers to the waveguides is made possible by trenching, i.e., machining a slot or landing into which contact with polished waveguide port or end is accomplished.
• Vertical coupling from the surface can also be used, and is discussed in U.S. patent 5,276,748 for a "VERTICALLY- COUPLED ARROW MODULATORS OR SWITCHES ON SILICON to G.A. Magel and assigned to Texas Instruments Incorporated the contents of which are incorporated herein in their entirety by reference.

Landscapes

• Gyroscopes (AREA)

Applications Claiming Priority (3)

Publications (1)

Family

ID=24917236

Family Applications (1)

Country Status (4)

Families Citing this family (3)

• 2001
  • 2001-05-24 IL IL15415401A patent/IL154154A0/xx not_active IP Right Cessation
  • 2001-05-24 CA CA002417113A patent/CA2417113A1/en not_active Abandoned
  • 2001-05-24 EP EP01995833A patent/EP1337805A1/de not_active Withdrawn
  • 2001-05-24 AU AU2002226872A patent/AU2002226872A1/en not_active Abandoned

Non-Patent Citations (1)

Also Published As

Similar Documents

Legal Events