WIRELESS COMMUNICATION TECHNOLOGY, APPARATUSES, AND METHODS

Organization Name

Intel Corporation

Inventor(s)

Erkan Alpman of Portland OR (US)

Arnaud Lucres Amadjikpe of Beaverton OR (US)

Omer Asaf of Oranit (IL)

Kameran Azadet of San Ramon CA (US)

Rotem Banin of Even Yehuda (IL)

Miroslav Baryakh of Petach Tikva (IL)

Anat Bazov of Petach Tikva (IL)

Stefano Brenna of Hillsboro OR (US)

Bryan K. Casper of Portland OR (US)

Anandaroop Chakrabarti of Beaverton OR (US)

Gregory Chance of Chandler AZ (US)

Debabani Choudhury of Thousand Oaks CA (US)

Emanuel Cohen of Zichron Yaacov (IL)

Claudio Da Silva of Portland OR (US)

Sidharth Dalmia of Fair Oaks CA (US)

Saeid Daneshgar Asl of Portland OR (US)

Kaushik Dasgupta of Hillsboro OR (US)

Kunal Datta of Los Angeles CA (US)

Ofir Degani of Haifa (IL)

Amr M. Fahim of Portland OR (US)

Amit Freiman of Haifa (IL)

Michael Genossar of Modiin (IL)

Eran Gerson of Pardes Hana (IL)

Eyal Goldberger of Moshav Beherotaim (IL)

Eshel Gordon of Aloney Aba (IL)

Meir Gordon of Holon (IL)

Josef Hagn of Neubiberg (DE)

Shinwon Kang of San Francisco CA (US)

Te Yu Kao of San Jose CA (US)

Noam Kogan of Tel Aviv (IL)

Mikko S. Komulainen of Oulu (FI)

Igal Yehuda Kushnir of Hod Hasharon (IL)

Saku Lahti of Tampere (FI)

Mikko M. Lampinen of Nokia (FI)

Naftali Landsberg of Ramat Gan (IL)

Wook Bong Lee of San Jose CA (US)

Run Levinger of Tel Aviv (IL)

Albert Molina of Alcobenda (ES)

Resti Montoya Moreno of Helsinki (FI)

Tawfiq Musah of Hillsboro OR (US)

Nathan G. Narevsky of Portland OR (US)

Hosein Nikopour of San Jose CA (US)

Oner Orhan of San Jose CA (US)

Georgios Palaskas of Portland OR (US)

Stefano Pellerano of Beaverton OR (US)

Ron Pongratz of Tel Aviv (IL)

Ashoke Ravi of Portland OR (US)

Shmuel Ravid of Haifa (IL)

Peter Andrew Sagazio of Portland OR (US)

Eren Sasoglu of Mountain View CA (US)

Lior Shakedd of Kfar Bilu (IL)

Gadi Shor of Tel Aviv (IL)

Baljit Singh of San Jose CA (US)

Menashe Soffer of Katzir (IL)

Ra'anan Sover of Haifa (IL)

Shilpa Talwar of Cupertino CA (US)

Nebil Tanzi of Hoffman Estates IL (US)

Moshe Teplitsky of Tel-Aviv (IL)

Chintan S. Thakkar of Portland OR (US)

Jayprakash Thakur of BANGALORE (IN)

Avi Tsarfati of Rishon Le Zion (IL)

Marian Verhelst of Portland OR (US)

Yossi Tsfati of Rishon Le Zion (IL)

Nir Weisman of Hod Hasharon (IL)

Shuhei Yamada of Hillsboro OR (US)

Ana M. Yepes of Portland OR (US)

Duncan Kitchin of Beaverton OR (US)

WIRELESS COMMUNICATION TECHNOLOGY, APPARATUSES, AND METHODS - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240243477 titled 'WIRELESS COMMUNICATION TECHNOLOGY, APPARATUSES, AND METHODS

Simplified Explanation: The patent application describes various aspects of millimeter wave (mmwave) technology, including transceivers, receivers, and antenna structures for wireless communications.

Key Features and Innovation:

• Co-located millimeter wave (mmwave) and near-field communication (NFC) antennas
• Scalable phased array radio transceiver architecture (SPARTA)
• Phased array distributed communication system with MIMO support and phase noise synchronization over a single coax cable
• Communicating RF signals over cable (RFOC) in a distributed phased array communication system
• Clock noise leakage reduction
• IF-to-RF companion chip for backwards and forwards compatibility and modularity
• On-package matching networks
• 5G scalable receiver (RX) architecture

Potential Applications: The technology can be applied in various wireless communication systems, including 5G networks, IoT devices, and smart city infrastructure.

Problems Solved: The technology addresses issues related to signal interference, phase noise synchronization, and compatibility between different communication systems.

Benefits: The technology offers improved signal quality, increased data transfer speeds, and enhanced scalability for future wireless communication networks.

Commercial Applications: Potential commercial applications include telecommunications equipment, network infrastructure, and consumer electronics that require high-speed wireless connectivity.

Questions about millimeter wave technology: 1. How does millimeter wave technology improve wireless communication systems? 2. What are the key challenges in implementing millimeter wave technology in real-world applications?

Frequently Updated Research: Researchers are continuously exploring new ways to optimize millimeter wave technology for better performance and efficiency in wireless communication systems.

Original Abstract Submitted

millimeter wave (mmwave) technology, apparatuses, and methods that relate to transceivers, receivers, and antenna structures for wireless communications are described. the various aspects include co-located millimeter wave (mmwave) and near-field communication (nfc) antennas, scalable phased array radio transceiver architecture (sparta), phased array distributed communication system with mimo support and phase noise synchronization over a single coax cable, communicating rf signals over cable (rfoc) in a distributed phased array communication system, clock noise leakage reduction, if-to-rf companion chip for backwards and forwards compatibility and modularity, on-package matching networks, 5g scalable receiver (rx) architecture, among others.