MIMO ANTENNA ARRAY DESIGN FOR ULTRA-RELIABLE LOW LATENCY COMMUNICATION IN 5G NETWORKS

Abstract

The proposed invention introduces a MIMO (Multiple Input, Multiple Output) antenna array designed specifically for ultra-reliable low-latency communication (URLLC) in 5G networks. Utilizing a compact, scalable architecture, the antenna array enables high data throughput and enhanced signal reliability in dense environments. The array structure incorporates microstrip patch antennas optimized for low latency and wideband operation, making it suitable for realtime applications like autonomous vehicles, industrial automation, and smart cities. The design balances compactness with high gain and efficient transmission across multiple frequency bands, ensuring robust performance for 5G deployments. Advanced photolithographic techniques and computational modeling are employed to optimize the antenna design, supporting the stringent requirements of URLLC in next-generation wireless networks.

Specification

THE FIELD OF INVENTION
The invention pertains to the field of wireless communications, focusing on the development of
MIMO antenna arrays for 50 networks. Specifically, it addresses antenna design challenges related
to ultra-reliable low-latency communication, which is critical for real-time data transfer in
applications such as autonomous systems, industrial automation, and the Internet of Things (loT).
BACKGROUND OF THE INVENTION
In 50 networks, ultra-reliable low-latency communication (URLLC) is a key enabler for missioncritical
applications that demand real-time responsiveness and high data reliability. Traditional
antennas and communication systems are insufficient to meet the low latency and high reliability
requirements of such applications. The need for antenna systems that offer higher data throughput,
improved signal propagation, and low latency has driven the development of MIMO-based antenna
arrays. These systems, when optimized for URLLC, can significantly enhance communication
reliability, even in high-density environments like smart cities, factories, and transportation systems.
SUMMARY OF THE INVENTION
This invention provides a MIMO antenna array specifically designed for ultra-reliable low-latency
communication in 50 networks. The array incorporates multiple microstrip patch antennas to
achieve high data rates and reliable communication. Each patch operates across multiple frequency
bands, ensuring compatibility with the broad spectrum required for 50 services. The design
leverages computational modeling for optimal impedance matching, low signal reflection, and high
. gain. The array structure is compact and scalable, allowing for integration into a variety of
communication devices, from small loT sensors to industrial equipment. Photolithographic
manufacturing techniques ensure precision in the design and consistency in performance across all
elements of the array
Specifications
� Substrate Material: Dielectric materials such as Rogers RT/duroid or FR-4,
providing minimal signal loss and optimized for 5G frequency bands.
� � Conductive Patch: Made of copper or gold thin films, with precise patterning
using photolithographic techniques for high-frequency operations.
� MIMO Configuration: Array includes multiple microstrip patches to enable
spatial multiplexing and enhance data throughput.
� Impedance Matching: Optimized to minimize signal reflection, ensunng
reliable data transmission with minimal latency.
&#65533; Wideband Operation: Capable of supporting 5G frequency bands (<::.g., sub-6
GHz and millimeter-wave bands), ensuring compatibility with various URLLC
applications.
&#65533; Scalability: Design is modular, allowing for integration into both l&#65533;rge-scale -Q) industrial systems and compact consumer devices.<
The MIMO antenna array IS a low-profile, high-performance solution designed for nextgeneration
5G networks. Each microstrip patch is optimized for high-gain, low-latency
communication, ensuring seamless performance in dense urban and industrial environments. The
antenna operates over a wide frequency range, supporting real-time applications that demand ultrareliable
low-latency. communication. The conductive patches are fabricated from high-quality
copper or gold thin films and are mounted on a dielectric substrate to ensure low loss and high
efficiency. Advanced computationill models are used to design the antenna's impedance matching
and radiation patterns, ensuring optimal performance in 5G environments.
The antenna is designed for integration into a variety of devices, ranging from mobile phones
and JoT sensors to industrial automation systems and autonomous vehicles. Its compact size and
scalable architecture make it ideal for high-density applications, where multiple antennas are
needed to provide reliable communication.
We Claim
I. A MIMO antenna array designed for ultra-reliable low-latency communication m SG
networks, comprising multiple conductive microstrip patch elements mounted on a dielectric
substrate.
2. The MIMO antenna array wherein each conductive patch is made from copper or gold,
optimized for operation across multiple 5G frequency bands.
3. The MIMO antenna array configured to enhance communication reliability and minimize
latency through optimized impedance matching and high-gain performance.
4. The MIMO antenna array designed for scalable integration into communication devices,
including loT systems, industrial equipment, and mobile devices.
5. The MIMO antenna array capable of supporting wideband operation, ensuring compatibility
with various SG URLLC applications.to o

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