Incomparable speed and agility
The Sparq2020 distributed gNB architecture is based on a DRAN unit connected through Ethernet over fiber or wireless front-haul to a set of Beam Forming RRH transceiver units, wirelessly connect with Smart Phones or IoT/MTC/URLLC/eMBB devices.
The Sparq-2020P is scalable peaking up to 64Gbps aggregate data rate per 100MHz channel BW for a coverage area with 64 beams created by the RRHs transceivers connected to the DRAN.
Sparq 2020P System Highlights
Plug &Play with “Zero touch” enabling capabilities, including Innovative AI algorithms and support of performance needs for the 5G services and use cases
Embedded Wireless AI techniques (e.g. in its un-comparable centralized Scheduler - which manages all the Users/Devices connected through all RRHs at the same transmitting receiving time) using small resources allocation such as Resource Block, solving the Quality of Experience (QoE) using Quality of Service (QoS) per packet prioritization, interference Management, Traffic Management, on the fly Self Organizing Network (SON) and Collaborative Multi Point (COMP), Load Balancing, etc. The AI/ML in the PHY engines also include the FEC (LDPC and Polar), MIMO and Beam Forming based on collected data.
The Scheduler in the MAC Layer (Layer-2) compiles many status parameters, uses a library of pertained cases, and finds the adequate setup for non-trained situations. The scheduler works in parallel to the beam set created by the RRH units connected to the DRAN. This innovative scheduler controls and manages more functions while enabling fast on the fly SON (Self Organizing Network) and CoMP (Coordinated Multi-Point) by its embedded learning algorithms (include Reinforcement Digital Learning algorithms) facilitating low cost (CAPEX), easy deployment, operation and maintenance (OPEX) at diversity of coverage area (in door, out door, from dense urban to Rural) public and/or private networks.
Ultra-Accurate Positioning made possible by the Sparq2020P platform PHY precision positioning (centimeter range) of the 5G user terminal or end device (UE), using advanced, patented, deep inspection algorithm, analyzing the received signals to enable new family of applications which require high precision, within fractional of nanoseconds, differential time interval measurements with thousands of devices at the same time.
5G RAN gNB PHY Distributed architecture first incorporated by RunEL with PHY Split that enables maximum virtualization of the BS creating a mini edge cloud that facilitates the advantages of centralized computing and keeps the Front-Haul connection with the edge using limited data overhead and delay (micro seconds). The Split point protects the data that runs over the Front-Haul by taking advantage of the 5G powerful LDPC embedded FEC. A similar PHY layer split is presented by O-RAN alliance.