Over the last decade, there has been a significant advancement in the capabilities of the Global Navigation Satellite System (GNSS). The rise of autonomous vehicles, advanced robotic applications, precision agriculture, and more is spurring this demand. As a result, we are witnessing high-precision GNSS technology become more integral to our daily lives, cities, and industries.
As Global Navigation Satellite Systems (GNSS) technology advances, our reliance on location-based services grows. According to research by MarketsandMarkets, the global GNSS chip market is projected to grow to $4.9 billion by 2026, representing a remarkable 48% growth over the next five years.
In recent years, there has been a trend towards combined technologies (sensor fusion, PPP, RTK, etc.) in GNSS systems, resulting in productivity gains and increasingly accurate and versatile devices. However, this adds further complexities and challenges for antenna design. When developing a GNSS-based solution, device OEMs, IoT service providers and systems designers need to carefully consider the GNSS antenna.
Integrating high-precision GNSS antennas into products is complex. Position accuracy, integrity, and correct, high-quality antenna integration are essential for success.
Be sure you’re making a high-performance product from beginning to end – the first time!
Join Taoglas experts Baha Badran, Global Head of Engineering and Pat Frank, Principal RF Engineer, Taoglas as they delve into the opportunities, pitfalls, and strategies for successfully integrating high-precision GNSS antennas. In this webinar, you will gain insights into:
- GNSS fundamentals, including bands and constellations.
- Selecting the optimal antenna for specific applications.
- Key considerations for assessing antenna performance.
- Techniques for enhancing precision with multiband antennas.
- Essential testing and validation procedures.