orbis systems

 As wireless technologies evolve toward higher frequencies, greater bandwidths, and more complex architectures, test environments are becoming increasingly demanding. Engineers and researchers need reliable, high-performance solutions that can handle high signal levels, rapid switching speeds, and consistent repeatability across a wide frequency range. At the center of these requirements lies one critical component — the high power RF switch . High power RF switches form the backbone of automated and high-frequency test systems, ensuring smooth signal routing, precise measurements, and long-term reliability. Without them, advanced systems in telecom, aerospace, defense, and automotive testing would struggle to meet performance and safety standards. Key Takeaways High power RF switches enable precise, efficient signal routing in automated and high-frequency test systems. Their robust design ensures durability, low insertion loss, and consistent performance under high-power ...

In today’s hyperconnected world, where wireless devices power everything from smartphones and smart homes to industrial IoT systems, ensuring reliability and compliance has never been more critical. Every wireless product must undergo rigorous testing and certification to meet global standards for electromagnetic compatibility (EMC), radio frequency (RF) performance, and safety. This is where the RF shielded box plays a crucial role in improving test accuracy, minimizing interference, and streamlining the certification process. Modern wireless technologies—such as 5G, Wi-Fi 6, and Bluetooth—operate in crowded frequency bands. Even minor interference or signal leakage can distort test results, leading to compliance failures or delayed product launches. By creating a controlled, interference-free environment, an RF shielded box helps manufacturers and test engineers achieve reliable results, faster approvals, and higher customer confidence. Key Takeaways An RF shielded box elimina...

In today’s fast-paced electronics and telecommunications industries, Original Equipment Manufacturers (OEMs) face constant pressure to innovate while maintaining precision and speed in production. To stay competitive, they rely heavily on Automated Test Equipment (ATE) — systems designed to streamline testing processes, reduce human error, and ensure consistent product quality. From semiconductor validation to complex RF testing, ATE helps manufacturers handle rising production volumes, shrinking design cycles, and increasingly stringent performance standards. But behind every efficient ATE setup stands a trusted manufacturer — one that understands the intricacies of automation, calibration, and high-frequency testing. This partnership is what allows OEMs to balance innovation with reliability. Key Takeaways Automated Test Equipment enables OEMs to achieve faster production cycles and maintain product accuracy. Partnering with expert ATE manufacturers ensures better system ...

The rollout of 5G has transformed wireless testing requirements in ways previous generations never demanded. Devices now rely on higher frequency bands, complex antenna designs, and advanced features like beamforming and Massive MIMO. To validate performance in these challenging conditions, engineers must carefully select the right testing approach. This is where the debate arises: should you rely on a 5G OTA chamber or stick with traditional test setups? Both methods serve important purposes, but their effectiveness varies depending on testing goals, device complexity, and budget. Understanding their differences helps organizations make smarter decisions for reliable wireless validation. Key Takeaways 5G OTA chambers provide a shielded, controlled environment for testing advanced 5G features with high accuracy and consistency. Traditional setups are cost-effective and simple but often fall short for mmWave and beamforming validation. OTA chambers excel in eliminating in...