Abstract: A circular dielectric polarizer can have a cylindrical shape and include a dielectric slab, a dielectric core, and at least one air cutouts portions of the dielectric core. The dielectric slab can include a first dielectric material and have a thickness centered about an axis of the cylindrical shape. The dielectric core can include a second dielectric material. Portions of the dielectric core can be located on different sides of the dielectric slab. The dielectric core and the dielectric slab can form the cylindrical shape. The dielectric constant of the first dielectric material can be higher than a dielectric constant of the second dielectric material. Parameters of the circular dielectric polarizer, the dielectric slab, the dielectric core, and the at least one air cutout are selected to obtain approximately a 90 degree difference in phase in a signal passing through the circular dielectric polarizer at a target frequency.

Abstract: A circular dielectric polarizer can have a cylindrical shape and include a dielectric slab, a dielectric core, and at least one air cutouts portions of the dielectric core. The dielectric slab can include a first dielectric material and have a thickness centered about an axis of the cylindrical shape. The dielectric core can include a second dielectric material. Portions of the dielectric core can be located on different sides of the dielectric slab. The dielectric core and the dielectric slab can form the cylindrical shape. The dielectric constant of the first dielectric material can be higher than a dielectric constant of the second dielectric material. Parameters of the circular dielectric polarizer, the dielectric slab, the dielectric core, and the at least one air cutout are selected to obtain approximately a 90 degree difference in phase in a signal passing through the circular dielectric polarizer at a target frequency.

Abstract: Antenna elements operable to radiate different patterns are provided. A particular apparatus includes a first antenna element having a plurality of radiating elements. Each of the radiating elements includes a first member having a first end and a second end. The first end is coupled to an antenna interface and the second end extends a length of the first member from the first end. Each of the radiating elements further includes a second member having a third end and a fourth end. The third end is electrically coupled to the first member at a point partway along the length of the first member. The fourth end extends away from the first member. When a first radiating element is radiating in the presence of a second radiating element, a null is generated in a radiation pattern of the first radiating element.

Abstract: A bandgap surface for use in a waveguide transition module. The surface may be constructed with a ground plane; a capacitive layer including a plurality of capacitive elements arranged in a polar configuration within a common plane, and spaced apart from said ground plane; and a plurality of electrically conductive vias formed within a dielectric layer of material that conductively couple said ground plane to each of said capacitive elements.

Abstract: A bandgap surface for use in a waveguide transition module. The surface may be constructed with a ground plane; a capacitive layer including a plurality of capacitive elements arranged in a polar configuration within a common plane, and spaced apart from said ground plane; and a plurality of electrically conductive vias formed within a dielectric layer of material that conductively couple said ground plane to each of said capacitive elements.

Abstract: A method and structure for producing an angled RF connection between a first element and a second element using a flexible substrate is provided. The method includes laminating a flexible substrate onto the first element; bending the flexible substrate such that a bonding pad on the flexible substrate is in a similar plane as a bonding pad on the second element; and creating the angled RF connection by wire bonding the bonding pad on the flexible substrate and the bonding pad on the second element. The structure includes a flexible substrate that is laminated onto a first element as an outer layer, flexible substrate having at least one bonding pad, and the flexible substrate able to bend in an angle that places the bonding pad in a same plane as a bonding pad on a second element.

Abstract: A method and structure for producing an angled RF connection between a first element and a second element using a flexible substrate is provided. The method includes laminating a flexible substrate onto the first element; bending the flexible substrate such that a bonding pad on the flexible substrate is in a similar plane as a bonding pad on the second element; and creating the angled RF connection by wire bonding the bonding pad on the flexible substrate and the bonding pad on the second element. The structure includes a flexible substrate that is laminated onto a first element as an outer layer, flexible substrate having at least one bonding pad, and the flexible substrate able to bend in an angle that places the bonding pad in a same plane as a bonding pad on a second element.

Abstract: Various techniques are disclosed to suppress undesired signal components introduced by non-linear amplifiers of phased array antenna systems to accommodate bandwidths greater than one octave. For example, in accordance with one embodiment, a phased array antenna system includes first and second antenna elements adapted to provide first and second received signals in response to a radio signal. The second antenna element is rotated approximately 180 degrees in relation to the first antenna element. Amplifiers may amplify the received signals to provide amplified signals having a bandwidth greater than one octave. Undesired components of the amplified signals introduced by the amplifiers may be suppressed through appropriate phase shifts performed by associated phase shifters and/or power combiners.