Impedance control devices for use in the transition regions of electromagnetic and optical circuitry and methods for using the same
First Claim
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1. A device for controlling impedance transition in millimeter wave circuitry, the device comprising:
- a substrate;
an electromagnetic waveguide disposed on the substrate having a first region defined by a first width, a second region extending from the first region and defined by a transitioning width and a third region extending from the second region and defined by a second width, wherein the second width is greater than the first width; and
a plurality of impedance control elements disposed on the substrate adjacent to the second region of the electromagnetic waveguide, the plurality of impedance control elements occupying more planar area on the substrate proximate the third region and decreasing in planar area occupancy as they approach the first region, wherein the plurality of impedance control elements serve to control the reflection of pulses impinging from the first region onto the third region.
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Abstract
Impedance control elements that are implemented in conjunction with the transition region of an electromagnetic waveguide to diminish the effect of reflective pulses on the signal transmission and to create linear impedance transition in the transition region are provided for. The device of the present invention provides the stated benefits in electromagnetic waveguides that are capable of high bandwidth signal transmission.
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Citations
35 Claims
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1. A device for controlling impedance transition in millimeter wave circuitry, the device comprising:
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a substrate;
an electromagnetic waveguide disposed on the substrate having a first region defined by a first width, a second region extending from the first region and defined by a transitioning width and a third region extending from the second region and defined by a second width, wherein the second width is greater than the first width; and
a plurality of impedance control elements disposed on the substrate adjacent to the second region of the electromagnetic waveguide, the plurality of impedance control elements occupying more planar area on the substrate proximate the third region and decreasing in planar area occupancy as they approach the first region, wherein the plurality of impedance control elements serve to control the reflection of pulses impinging from the first region onto the third region. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19)
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20. A device for controlling impedance transition in optical circuitry, the device comprising:
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a substrate;
an optical waveguide disposed on the substrate having a first region defined by a first width, a second region extending from the first region and defined by a transitioning width and a third region extending from the second region and defined by a second width, wherein the second width is greater than the first width; and
a plurality of impedance control elements disposed on the substrate adjacent to the second region, the plurality of impedance control elements occupying more planar area on the substrate proximate the third region and decreasing in planar area occupancy as they approach the first region, wherein the plurality of impedance control elements serve to control the reflection of pulses impinging from the first region onto the third region. - View Dependent Claims (21, 22, 23, 24, 25, 26)
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27. A device for controlling impedance transition in co-planar waveguides, the device comprising:
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a substrate;
a electromagnetic waveguide disposed on the substrate having a first region defined by a first width, a second region extending from the first region and defined by a transitioning width and a third region extending from the second region and defined by a second width, wherein the second width is greater than the first width;
first and second ground plane structures disposed co-planar to the circuit line and adjacent to opposite sides of the third region of the circuit line; and
a plurality of impedance control elements disposed on the substrate adjacent to the second region, the plurality of impedance control elements occupying more planar area on the substrate proximate the third region and decreasing in planar area occupancy as they approach the first region, wherein the plurality of impedance control elements serve to control the reflection of pulses impinging from the first region onto the third region. - View Dependent Claims (28, 29, 30, 31, 32, 33)
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34. A method for altering propagation velocity in an electromagnetic waveguide, the method comprising the steps of:
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providing for an electromagnetic waveguide having a first region of substantially constant propagation velocity, a second region extending from the first region having transitioning propagation velocity and a third region extending from the second region having generally constant propagation velocity;
providing for velocity control elements adjacent planar to the second region of the electromagnetic waveguide, the velocity control elements increasing in planar density from an area proximate the first region to an area proximate the third region;
creating an electromagnetic propagating wave signal in the electromagnetic waveguide;
causing interaction between the velocity control elements and the electromagnetic propagating wave signal; and
introducing delays in the electromagnetic propagating wave signal to alter the effective velocity in the second region of the waveguide.
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35. A method for altering impedance in an electromagnetic waveguide, the method comprising the steps of:
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providing for an electromagnetic waveguide having a first region of substantially constant impedance, a second region extending from the first region having transitioning propagate impedance and a third region extending from the second region having generally constant impedance;
providing for impedance control elements adjacent planar to the second region of the electromagnetic waveguide, the impedance control elements increasing in planar density from an area proximate the first region to an area proximate the third region;
creating an electromagnetic propagating wave signal in the electromagnetic waveguide;
causing interaction between the impedance control elements and the electromagnetic propagating wave signal; and
introducing phase shifts in the electromagnetic propagating wave signal to alter the effective impedance in the second region of the waveguide.
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Specification