Single-feed multi-cell metamaterial antenna devices
First Claim
Patent Images
1. A Composite Right-Left Handed (CRLH) metamaterial (MTM) antenna device, comprising:
- a substrate;
a plurality of MTM cells formed on the substrate, each MTM cell comprising a cell conductive patch formed on a first surface of the substrate and a cell conductive via formed in the substrate and conductively coupled to the cell conductive patch;
a conductive launch stub formed on the substrate to be adjacent to at least a portion of a lateral edge of the cell conductive patch of each of the MTM cells and electromagnetically coupled to each of the MTM cells; and
a ground electrode formed on the second surface of the substrate, the ground electrode entirely outside a footprint of the respective cell conductive patches projected from the first surface onto the second surface,wherein a first of the plurality of MTM cells comprises an L-shaped cell conductive patch and a second of the plurality of MTM cells comprises a rectangularly-shaped cell conductive patch having a linear recess in one side; and
wherein the cell conductive patch of each of the MTM cells is coupled to the ground electrode using at least one conductive line located on the second surface of the substrate, the at least one conductive line conductively coupled to the cell conductive via of each of the MTM cells.
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Abstract
Designs and techniques of Composite Right-Left Handed (CRLH) Metamaterial (MTM) antenna devices, including a CRLH MTM devices that include MTM cells formed on a substrate and a conductive launch stub formed on the substrate to be adjacent to each of the MTM cells and electromagnetically coupled to each of the MTM cells.
23 Citations
14 Claims
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1. A Composite Right-Left Handed (CRLH) metamaterial (MTM) antenna device, comprising:
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a substrate; a plurality of MTM cells formed on the substrate, each MTM cell comprising a cell conductive patch formed on a first surface of the substrate and a cell conductive via formed in the substrate and conductively coupled to the cell conductive patch; a conductive launch stub formed on the substrate to be adjacent to at least a portion of a lateral edge of the cell conductive patch of each of the MTM cells and electromagnetically coupled to each of the MTM cells; and a ground electrode formed on the second surface of the substrate, the ground electrode entirely outside a footprint of the respective cell conductive patches projected from the first surface onto the second surface, wherein a first of the plurality of MTM cells comprises an L-shaped cell conductive patch and a second of the plurality of MTM cells comprises a rectangularly-shaped cell conductive patch having a linear recess in one side; and wherein the cell conductive patch of each of the MTM cells is coupled to the ground electrode using at least one conductive line located on the second surface of the substrate, the at least one conductive line conductively coupled to the cell conductive via of each of the MTM cells. - View Dependent Claims (2, 3, 4, 5, 6, 12)
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7. A Composite Right-Left Handed (CRLH) Metamaterial (MTM) antenna device, comprising:
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a dielectric substrate having a first surface on a first side and a second surface on a second side opposing the first side; a first cell conductive patch formed on the first surface; a second cell conductive patch formed on the first surface and adjacent to the first cell conductive patch by an insulation gap; a shared conductive launch stub formed on the first surface adjacent to at least a portion of a lateral edge of both the first and second cell conductive patches and separated from each of the first and second cell conductive patches by an insulation gap to be electromagnetically coupled to each of the first and second cell conductive patches, the shared conductive launch stub comprising an extended strip line configured to direct a signal to the first and second cell conductive patches and configured to receive signals from the first and second cell conductive patches; a cell ground conductive electrode formed on the second surface and located entirely outside footprints projected by the first and second cell conductive patches onto the second surface; a first cell conductive via patch formed on the second surface and in a footprint projected by the first cell conductive patch onto the second surface; a first cell conductive via connector formed in the substrate to connect the first cell conductive patch to the first cell conductive via patch; a second cell conductive via patch formed on the second surface and in a footprint projected by the second cell conductive patch onto the second surface; a second cell conductive via connector formed in the substrate to connect the second cell conductive patch to the second cell conductive via patch; a first conductive strip line formed on the second surface to connect the first cell conductive via patch to the cell ground conductive electrode; and a second conductive strip line formed on the second surface to connect the second cell conductive via patch to the cell ground conductive electrode, wherein the first cell conductive patch comprises an L-shaped cell conductive patch and the second cell conductive patch comprises a rectangularly-shaped cell conductive patch having a linear recess in one side. - View Dependent Claims (8, 13)
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9. A Composite Right-Left Handed (CRLH) Metamaterial (MTM) antenna device, comprising:
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a dielectric substrate having a first surface on a first side and a second surface on a second side opposing the first side; a first cell conductive patch formed on the first surface; a second cell conductive patch formed on the first surface and separated from the first cell conductive patch; a conductive launch stub formed on the first surface adjacent to at least a portion of a lateral edge of both the first and second cell conductive patches and separated from each of the first and second cell conductive patches by an insulation gap to be electromagnetically coupled to each of the first and second cell conductive patches, the conductive launch stub comprising; a first conductive line to receive a signal from an external launch cable; a second conductive line extending from a first end of the conductive launch stub, the second conductive line guiding the signal to the first and second cell conductive patches; a meandering conductive line extending from the second end of the conductive launch stub to a location away from the first and second conductive patches; a cell ground conductive electrode formed on the second surface and located entirely outside footprints projected by the first and second cell conductive patches, and the conductive launch stub onto the second surface; a first cell conductive via patch formed on the second surface and in a footprint projected by the first cell conductive patch onto the second surface; a first cell conductive via connector formed in the substrate to connect the first cell conductive patch to the first cell conductive via patch; a second cell conductive via patch formed on the second surface and in a footprint projected by the second cell conductive patch onto the second surface; a second cell conductive via connector formed in the substrate to connect the second cell conductive patch to the second cell conductive via patch; a third conductive via patch formed on the second surface and in substantially a footprint projected by the meandering conductive line onto the second surface; a third conductive via connector formed in the substrate to connect the end of the meandering conductive line to the third conductive via patch; a first conductive strip line formed on the second surface to connect the first cell conductive via patch to the cell ground conductive electrode; and a second conductive strip line formed on the second surface to connect the second cell conductive via patch to the cell ground conductive electrode, wherein the first cell conductive patch comprises an L-shaped cell conductive patch and the second cell conductive patch comprises a rectangularly-shaped cell conductive patch having a linear recess in one side. - View Dependent Claims (10, 11)
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14. A Composite Right-Left Handed (CRLH) metamaterial (MTM) antenna device, comprising:
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a substrate; a plurality of MTM cells formed on the substrate, each MTM cell comprising a cell conductive patch formed on a first surface of the substrate and a cell conductive via formed in the substrate and conductively coupled to the cell conductive patch; a conductive launch stub formed on the substrate to be adjacent to at least a portion of a lateral edge of the cell conductive patch of each of the MTM cells and electromagnetically coupled to each of the MTM cells; and a ground electrode formed on the second surface of the substrate, the ground electrode entirely outside a footprint of the respective cell conductive patches projected from the first surface onto the second surface, wherein a first of the plurality of MTM cells comprises a rectangularly-shaped cell conductive patch having a linear recess in each of two sides of the rectangularly-shaped cell conductive patch and a second of the plurality of MTM cells comprises an L-shaped cell conductive patch; and wherein the cell conductive patch of each of the MTM cells is coupled to the ground electrode using at least one conductive line located on the second surface of the substrate, the at least one conductive line conductively coupled to the cell conductive via of each of the MTM cells.
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Specification
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Current AssigneeTyco Electronics Services GmbH (TE Connectivity Ltd. (United Kingdom))
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Original AssigneeTyco Electronics Services GmbH (TE Connectivity Ltd. (United Kingdom))
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InventorsXu, Nan, Lopez, Norberto, Pathak, Vaneet, Gummalla, Ajay
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Primary Examiner(s)SMITH, GRAHAM P
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Application NumberUS12/408,642Publication NumberTime in Patent Office2,433 DaysField of SearchNoneUS Class Current1/1CPC Class CodesH01Q 15/008 said selective devices havi...
