RESONATING STRUCTURE FOR A DIELECTRIC FILTER COMPRISING A DIELECTRIC BODY INCLUDING OFFSET FIRST AND SECOND BLIND COUPLING HOLES WITH RESPECTIVE DEFECTED PORTIONS

Organization Name

telefonaktiebolaget lm ericsson (publ)

Inventor(s)

Peiguang Lu of Beijing (CN)

Haitao Liu of Beijing (CN)

Weidong Wang of Beijing (CN)

RESONATING STRUCTURE FOR A DIELECTRIC FILTER COMPRISING A DIELECTRIC BODY INCLUDING OFFSET FIRST AND SECOND BLIND COUPLING HOLES WITH RESPECTIVE DEFECTED PORTIONS - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240347887 titled 'RESONATING STRUCTURE FOR A DIELECTRIC FILTER COMPRISING A DIELECTRIC BODY INCLUDING OFFSET FIRST AND SECOND BLIND COUPLING HOLES WITH RESPECTIVE DEFECTED PORTIONS

The abstract describes a resonating structure and a dielectric filter, with the resonating structure consisting of a body, negative coupling holes, and a conductive material layer. The body is made of a solid dielectric material and contains at least two resonators, with negative coupling holes formed at the connection between adjacent resonators. Each set of negative coupling holes includes a first blind hole and a second blind hole on opposite surfaces of the body, offset from each other in a plane perpendicular to the direction in which they are dug. The conductive material layer covers the surfaces of the body, first blind hole, and second blind hole.

• The resonating structure includes a body made of a solid dielectric material with at least two resonators.
• Negative coupling holes are formed at the connection between adjacent resonators, with each set comprising a first and second blind hole on opposite surfaces of the body.
• The conductive material layer covers the surfaces of the body, first blind hole, and second blind hole.
• The first and second blind holes are offset from each other in a plane perpendicular to the direction in which they are dug.
• The resonating structure and dielectric filter provide enhanced filtering capabilities for various applications.

Potential Applications: - Wireless communication systems - Radar systems - Satellite communication systems

Problems Solved: - Improved filtering performance - Enhanced signal quality - Reduction of interference

Benefits: - Increased efficiency in communication systems - Enhanced signal clarity - Reduction of signal interference

Commercial Applications: Title: Enhanced Dielectric Filters for Communication Systems This technology can be used in the development of advanced communication systems for various industries, including telecommunications, aerospace, and defense. The improved filtering capabilities can enhance signal quality and reduce interference, making it a valuable asset in the design of high-performance communication networks.

Questions about the technology: 1. How does the resonating structure improve filtering performance in communication systems? The resonating structure enhances filtering performance by utilizing negative coupling holes and a conductive material layer to reduce interference and improve signal quality.

2. What are the potential commercial applications of this technology? The technology can be applied in various industries such as telecommunications, aerospace, and defense to enhance communication systems' performance and reliability.

Original Abstract Submitted

a resonating structure and a dielectric filter having the same are disclosed. the resonating structure comprises a body, at least one set of negative coupling holes, and a conductive material layer. the body is made of a solid dielectric material and comprises at least two resonators. the negative coupling holes are formed at a connection between two adjacent resonators. each set of negative coupling holes comprises a first blind hole and a second blind hole disposed on two opposite surfaces of the body respectively. the first blind hole and the second blind hole are offset from each other in a plane perpendicular to a direction along which the first or second blind hole is dug. the conductive material layer covers surfaces of the body and surfaces of the first blind hole and the second blind hole.