Scalability Solved for Space
The growing demand for global connectivity across various sectors like logistics, agriculture, and infrastructure monitoring has highlighted a critical
challenge for satellite networks: how to scale efficiently without compromising performance or increasing system complexity. Traditional methods of managing radio frequency (RF) channels, which often involve intricate scheduling or collision detection, tend to reduce the usable capacity of the network or degrade significantly when a large number of devices attempt to connect. This issue is particularly acute for the exchange of data from mobile assets and Internet of Things (IoT) devices, where numerous units vie for limited RF channel access. The recently unveiled E-SSA waveform offers a completely novel approach to this problem. Through extensive offline testing utilizing a 4 MHz bandwidth, E-SSA has demonstrated an impressive capability to support 500 concurrent device connections. Furthermore, it can process approximately 30,000 data frames every second, with each frame containing a commercially viable amount of digital information. The technology also achieved a measured spectral efficiency of 0.8 bits per second per Hertz (bps/Hz), a significant improvement over existing narrowband satellite systems in terms of both throughput and spectrum utilization.
Simple Design, Global Reach
Beyond its impressive performance metrics, the E-SSA waveform boasts a design that considerably simplifies the overall system architecture, making global deployment more feasible. A key advantage is that devices can transmit their data to satellites as they pass overhead without requiring any prior registration, synchronization, or complex network coordination. Each data packet is equipped with a preamble, a short sequence that alerts the satellite receivers to its presence. This inherent design effectively eliminates the need for scheduling overhead and minimizes inefficiencies within the communication protocol, allowing a much larger portion of the allocated bandwidth to be dedicated to carrying actual user data. The streamlined nature of this approach brings several substantial benefits, including the ability for instantaneous deployment in environments that are remote or lack existing infrastructure. It also leads to less complicated satellite payloads, reduces communication latency, and enhances energy efficiency, which is particularly crucial for battery-powered devices that rely on sustained operation.
Strengthening Connectivity Future
The successful development of the E-SSA technology significantly enhances a robust technology portfolio focused on combining cybersecurity, AI-driven network management, and proprietary communication methods into a unified, secure connectivity platform. This integration aims to make seamless communication for mobile and IoT applications via satellite a commercial reality. Over the past two years, the organization has expanded its expertise in satellite-terrestrial interoperability and secure communication through strategic acquisitions and the cultivation of intellectual property, accumulating over 53 patents. This expansion included acquiring a Munich-based company in October 2025 and establishing a presence in Poland in February 2026, specifically to bolster innovation in satellite waveform technology, digital signal processing, and related software development. The E-SSA technique further bolsters this foundation by effectively addressing the critical challenges of scalability and efficiency in space-based narrowband communications, which are essential components for future global mobile connectivity infrastructure.
