Abstract: A low profile phased array antenna that is configured to be manufactured using additive manufacturing techniques is provided. In one or more embodiments, the phased array can include a plurality of signal ears, ground ears, and clustered pillars that can be arranged in relation to a base plate such that each component of the antenna can be manufactured from a single piece of material, thereby allowing for the use of additive manufacturing techniques which can substantially reduce the cost and time of the manufacturing process. The phased array can include a signal ear that include one or more posts that interface with an airgap located within a base plate of the array, wherein the size of the airgap in relation to the size of the post is configured to achieve an optimal level of impedance matching.

Abstract: A low profile phased array antenna that is configured to be manufactured using additive manufacturing techniques is provided. In one or more embodiments, the phased array can include a plurality of signal ears, ground ears, and clustered pillars that can be arranged in relation to a base plate such that each component of the antenna can be manufactured from a single piece of material, thereby allowing for the use of additive manufacturing techniques which can substantially reduce the cost and time of the manufacturing process. The phased array can include a signal ear that include one or more posts that interface with an airgap located within a base plate of the array, wherein the size of the airgap in relation to the size of the post is configured to achieve an optimal level of impedance matching.

Abstract: A low profile phased array antenna that is configured to be manufactured using additive manufacturing techniques is provided. In one or more embodiments, the phased array can include a plurality of signal ears, ground ears, and clustered pillars that can be arranged in relation to a base plate such that each component of the antenna can be manufactured from a single piece of material, thereby allowing for the use of additive manufacturing techniques which can substantially reduce the cost and time of the manufacturing process. The phased array can include a signal ear that include one or more posts that interface with an airgap located within a base plate of the array, wherein the size of the airgap in relation to the size of the post is configured to achieve an optimal level of impedance matching.

Abstract: A low profile phased array antenna that is configured to be manufactured using additive manufacturing techniques is provided. In one or more embodiments, the phased array can include a plurality of signal ears, ground ears, and clustered pillars that can be arranged in relation to a base plate such that each component of the antenna can be manufactured from a single piece of material, thereby allowing for the use of additive manufacturing techniques which can substantially reduce the cost and time of the manufacturing process. The phased array can include a signal ear that include one or more posts that interface with an airgap located within a base plate of the array, wherein the size of the airgap in relation to the size of the post is configured to achieve an optimal level of impedance matching.

Abstract: A low profile phased array antenna that is configured to be manufactured using additive manufacturing techniques is provided. In one or more embodiments, the phased array can include a plurality of signal ears, ground ears, and clustered pillars that can be arranged in relation to a base plate such that each component of the antenna can be manufactured from a single piece of material, thereby allowing for the use of additive manufacturing techniques which can substantially reduce the cost and time of the manufacturing process. The phased array can include a signal ear that include one or more posts that interface with an airgap located within a base plate of the array, wherein the size of the airgap in relation to the size of the post is configured to achieve an optimal level of impedance matching.

Abstract: A metamaterial for receiving electromagnetic waves having any polarization is provided. The metamaterial allows for receipt and/or propagation of electromagnetic waves at a resonant frequency of the metamaterial.

Abstract: A metamaterial for receiving electromagnetic waves having any polarization is provided. The metamaterial allows for receipt and/or propagation of electromagnetic waves at a resonant frequency of the metamaterial.

Abstract: An adjustable and portable mounting system for a tablet computing device and solar based charging system is described. An example mounting system for a tablet computing device includes a tablet enclosure with a plurality of gripping portions adjustable to hold tablets with different sizes and shapes, and each gripping portion is configured to grip a corner of the tablet computing device. The mounting system further includes an adjustable solar panel support, which is pivotally attached to the tablet enclosure and where a solar panel placed within the support can be configured to provide trickle charging to the tablet and to orient 360 degrees about three axes of rotation. The mounting system also includes a table stand, which is mounted to the tablet enclosure and provides support of the tablet computing device on a flat surface with a wide range of viewing angles. The mounting system also includes a connector configured to couple to a tripod stand mount, or a similar device.

Abstract: An adjustable and portable mounting system for a tablet computing device and solar based charging system is described. An example mounting system for a tablet computing device includes a tablet enclosure with a plurality of gripping portions adjustable to hold tablets with different sizes and shapes, and each gripping portion is configured to grip a corner of the tablet computing device. The mounting system further includes an adjustable solar panel support, which is pivotally attached to the tablet enclosure and where a solar panel placed within the support can be configured to provide trickle charging to the tablet and to orient 360 degrees about three axes of rotation. The mounting system also includes a table stand, which is mounted to the tablet enclosure and provides support of the tablet computing device on a flat surface with a wide range of viewing angles. The mounting system also includes a connector configured to couple to a tripod stand mount, or a similar device.