Multi-ring switched parasitic array for improved antenna gain
First Claim
Patent Images
1. A parasitic antenna array, comprising:
- a substrate;
a ground plane, the ground plane being directly connected to a bottom surface of the substrate;
a monopole element, the monopole element being connected to the substrate, the monopole element configured for radiating electromagnetic energy in an omni-directional radiation pattern;
a first plurality of parasitic elements, the first plurality of parasitic elements being connected to the substrate, the first plurality of parasitic elements collectively forming a first ring, said first ring being formed around the monopole element;
a second plurality of parasitic elements, the second plurality of parasitic elements being connected to the substrate, the second plurality of parasitic elements collectively forming a second ring, said second ring being formed around the monopole element and being formed around the first ring; and
a plurality of variable impedance load circuits, each of the plurality of variable impedance load circuits including a plurality of diodes, each of the plurality of variable impedance load circuits being connected to a particular parasitic element, the plurality of variable impedance load circuits further being directly connected to the ground plane.
1 Assignment
0 Petitions
Accused Products
Abstract
The present disclosure is directed to a multi-ring switched parasitic array for improved antenna gain. The array includes multiple rings of parasitic elements configured around a central monopole element. Each parasitic element may be connected to a corresponding load circuit. Variable impedances may be applied to the parasitic elements via the variable impedance loads for causing the antenna array to produce a desired radiation pattern and/or for increasing gain of directional beams radiated by the parasitic antenna array.
11 Citations
19 Claims
-
1. A parasitic antenna array, comprising:
-
a substrate; a ground plane, the ground plane being directly connected to a bottom surface of the substrate; a monopole element, the monopole element being connected to the substrate, the monopole element configured for radiating electromagnetic energy in an omni-directional radiation pattern; a first plurality of parasitic elements, the first plurality of parasitic elements being connected to the substrate, the first plurality of parasitic elements collectively forming a first ring, said first ring being formed around the monopole element; a second plurality of parasitic elements, the second plurality of parasitic elements being connected to the substrate, the second plurality of parasitic elements collectively forming a second ring, said second ring being formed around the monopole element and being formed around the first ring; and a plurality of variable impedance load circuits, each of the plurality of variable impedance load circuits including a plurality of diodes, each of the plurality of variable impedance load circuits being connected to a particular parasitic element, the plurality of variable impedance load circuits further being directly connected to the ground plane. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
-
-
10. A method of operation of a parasitic antenna array, the parasitic array including a substrate, a ground plane, a plurality of variable impedance load circuits, a monopole element, and a plurality of parasitic elements collectively forming two or more rings around the monopole element, the method comprising:
selectively establishing a subset of the plurality of parasitic elements as on elements to form a steerable reflector of the parasitic antenna array, wherein the ground plane of the parasitic antenna array is directly connected to a bottom surface of the substrate and the plurality of variable impedance load circuits of the parasitic antenna array are directly connected to the ground plane, wherein each of the plurality of variable impedance load circuits includes at least two diodes, a capacitor connected to a first diode of the at least two diodes, and a resistor connected to a second diode of the at least two diodes, wherein selectively establishing the subset of the plurality of parasitic elements as the on elements to form the steerable reflector at least includes; transmitting a first current from a DC bias current source of a first variable impedance load circuit of the parasitic antenna array to a resistor of the first variable impedance load circuit; providing a second current from the resistor of the first variable impedance load circuit to a capacitor of the first load circuit, the second current being based upon the first current; transmitting a third current from the capacitor of the first variable impedance load circuit to a plurality of diodes of the first variable impedance load circuit, the third current being based upon the second current, the third current including a DC bias current; providing an impedance from the plurality of diodes of the first variable impedance load circuit to a first parasitic element of the parasitic antenna array, the impedance being based upon the DC bias current included in the third current; transmitting a fourth current, the fourth current being transmitted from a DC bias current source of a second variable impedance load circuit of the parasitic antenna array to a resistor of the second variable impedance load circuit; providing a fifth current from the resistor of the second variable impedance load circuit to a capacitor of the second variable impedance load circuit, the fifth current being based upon the fourth current; transmitting a sixth current from the capacitor of the second variable impedance load circuit to a plurality of diodes of the second variable impedance load circuit, the sixth current being based upon the fifth current, the sixth current including a DC bias current; and providing an impedance from the plurality of diodes of the second variable impedance load circuit to a second parasitic element of the parasitic antenna array, the impedance being based upon the DC bias current included in the sixth current. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18)
-
19. A parasitic antenna array, comprising:
-
a substrate; a ground plane, the ground plane being directly connected to a bottom surface of the substrate; a monopole element, the monopole element being connected to the substrate, the monopole element configured for radiating electromagnetic energy in an omni-directional radiation pattern; a first plurality of parasitic elements, the first plurality of parasitic elements being connected to the substrate, the first plurality of parasitic elements collectively forming a first ring, said first ring being formed around the monopole element; a second plurality of parasitic elements, the second plurality of parasitic elements being connected to the substrate, the second plurality of parasitic elements collectively forming a second ring, said second ring being formed around the monopole element and being formed around the first ring; and a plurality of variable impedance load circuits, each of the plurality of variable impedance load circuits including a plurality of diodes, the plurality of variable impedance load circuits being connected to the parasitic elements and the ground plane, wherein a first variable impedance load circuit included in the plurality of load circuits is connected to a base of a first parasitic element included in the parasitic elements, said variable impedance load circuit being configured for providing an adjustable impedance to the first parasitic element, wherein the first parasitic element is selectively configurable, based upon the adjustable impedance provided to the first parasitic element by the first variable impedance load circuit, for;
reflecting the electromagnetic energy radiated from the monopole element when a first impedance of the adjustable impedance is provided to the first parasitic element by the first variable impedance load circuit; and
allowing transmission through the first parasitic element of the electromagnetic energy radiated from the monopole element when a second impedance of the adjustable impedance is provided to the first parasitic element by the first variable impedance load circuit.
-
Specification