Meta platforms technologies, llc (20240162623). TRANSPARENT ANTENNA ON LENS WITH METALIZED EDGE simplified abstract

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TRANSPARENT ANTENNA ON LENS WITH METALIZED EDGE

Organization Name

meta platforms technologies, llc

Inventor(s)

Wei Huang of San Diego CA (US)

Yasuo Morimoto of Cupertino CA (US)

Boon Shiu of Palo Alto CA (US)

Geng Ye of Union City CA (US)

Umar Azad of San Jose CA (US)

Eswarappa Channabasappa of Milpitas CA (US)

Tao Zhou of San Jose CA (US)

Peter Eli Renner of San Jose CA (US)

Jiang Zhu of Cupertino CA (US)

TRANSPARENT ANTENNA ON LENS WITH METALIZED EDGE - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240162623 titled 'TRANSPARENT ANTENNA ON LENS WITH METALIZED EDGE

Simplified Explanation

The disclosed apparatus includes an antenna radiating structure with an active transparent mesh portion and a non-transparent antenna radiator portion, resulting in improved radiation efficiency. When overlaid on a transparent lens, the antenna structure maintains optical transparency due to the placement of the non-transparent metallic film.

  • The apparatus combines transparent metal mesh and non-transparent metallic film to enhance radiation efficiency.
  • When placed on a transparent lens, such as augmented reality glasses, the antenna structure maintains optical transparency.
  • Various other implementations of the apparatus are also disclosed.

Potential Applications

The technology could be applied in the development of transparent antennas for use in augmented reality devices, smart glasses, and other transparent electronic devices.

Problems Solved

The technology solves the problem of maintaining optical transparency while integrating antennas into transparent devices, improving radiation efficiency without compromising visibility.

Benefits

The benefits of this technology include improved radiation efficiency, seamless integration into transparent devices, and enhanced performance of transparent electronic systems.

Potential Commercial Applications

Potential commercial applications of this technology include transparent antennas for augmented reality devices, smart glasses, transparent displays, and other transparent electronic devices.

Possible Prior Art

One possible prior art could be the development of transparent antennas using traditional metallic structures that may compromise optical transparency.

Unanswered Questions

How does the antenna structure impact the overall design and functionality of augmented reality glasses?

The article does not delve into the specific design implications and functional enhancements that the antenna structure may bring to augmented reality glasses.

What are the potential challenges in mass-producing devices with integrated transparent antennas?

The article does not address the potential manufacturing challenges or scalability issues that may arise when mass-producing devices with integrated transparent antennas.


Original Abstract Submitted

the disclosed apparatus may include an antenna radiating structure that includes an active transparent mesh portion as well as a non-transparent antenna radiator portion. by combining transparent metal mesh and non-transparent metallic film into the antenna radiating structure, the disclosed apparatus results in improved radiation efficiency. moreover, when overlaid on a transparent lens (such as with a pair of augmented reality glasses), the antenna radiating structure leaves the optical transparency of the lens largely unaffected due to the placement of the non-transparent metallic film. various other implementations are also disclosed.