Archive/IoT Monitoring Framework with Physics-Based Energy Loss Modeling for Smart Microgrids: Architecture and Benchmarks
IoT Monitoring Framework with Physics-Based Energy Loss Modeling for Smart Microgrids: Architecture and Benchmarks
Elton Boshnjaku, Galia Marinova, Edmond Hajrizi et al.
July 3, 2026
en

Abstract

Smart microgrids combining photovoltaic arrays, wind turbines, and battery storage generate telemetry that existing open-source monitoring tools cannot process with per-mechanism energy loss visibility in real time. This paper presents the design, implementation, and evaluation of an IoT monitoring framework. The framework incorporates a physics-based microgrid simulator, a hierarchical MQTT communication architecture, and a React-based web-based user interface that supports WebSocket-based real-time data visualization. The framework consists of ten containerized microservices that can be started with a single command: docker compose up -d. All stack performance testing was conducted using a simulated 1 h test case based on a 100 kWp PV system, 10 kW wind turbine, and 50 kWh battery-powered campus microgrid. Median P50 publisher-to-subscriber latency was 27.2 ms and 99th percentile (P99) latency was 48.3 ms, with 100% message delivery across 5840 test messages, with per-topic analysis revealing a 25 ms serialization-order effect in sequential MQTT publishing. Comparative analysis against nine existing platforms including OpenEMS, VOLTTRON, Eclipse Ditto, and pymgrid confirms that, among the platforms surveyed, none unifies physics-based loss telemetry, IoT communication, time-series storage, and real-time visualization in a single reproducible deployment.

IPC Classification

G06H04H01

Keywords

monitoringframeworkphysics-basedenergylossmodelingsmartmicrogridsarchitecturebenchmarkstelecomcombiningphotovoltaicarrayswindturbinesbatterystoragegeneratetelemetryexistingopen-sourcetoolscannot
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