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The Business Advantages of a Multi-GNSS Setup

2022-08-10
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The Internet of Things (IoT) connects a steady information stream between the people and processes powering the world. Global Navigation Satellite Systems (GNSS) provide critical timing and positioning functions for device operations. 

GNSS uses satellite technology to provide insight into connected devices’ geographic locations. GNSS is an inclusive term for the category of global systems, including: 

  • Global Positioning System (GPS)  
  • Globalnaya Navigazionnaya Sputnikovaya Sistema (GLONASS)  
  • BeiDou  
  • Galileo  

When more than one constellation is used simultaneously, the benefits of those systems combine for improved satellite coverage and overall performance.  

In addition, the regional satellite-based augmentation systems (SBAS) assist the global systems:  

  • Wide Area Augmentation System (WAAS) in North and South America
  • European Geostationary Navigation Overlay Service (EGNOS) in Europe
  • GPS Aided GEO Augmented Navigation (GAGAN) in India
  • MTSAT Satellite-Based Augmentation System (MSAS) in Japan

All are vital concerns to consider when choosing how many systems to utilize in IoT endeavors. 

As global demand for connectivity increases, businesses can expect to see more integration of GNSS technologies. Which GNSS platforms are available today, and how do they differ? 

4 GNSS Systems and Their Unique Features

GPS (United States)

While GPS and GNSS are often used interchangeably, GPS is the world’s most utilized satellite navigation system. It operates from 32 satellites across six orbital planes. Developed in the United States for military use, we now see GPS in-car navigation and business tagging in social media. A high-accuracy multifrequency GPS using Precise Point Positioning (PPP) or Real-Time Kinematic (RTK) techniques can identify spatial locations down to 10 centimeters or fewer.

GLONASS (Russia)

Like GPS, GLONASS was designed during the 1970s as Russia’s military positioning system. Commercial applications (e.g., transmitting navigation positioning and weather broadcasts) started in the 1980s with the deployment of 24 satellites across three orbital planes.

BeiDou (China)

Since 2000, China’s BeiDou Navigation Satellite System (BDS) has been on the rise to overtake GPS in global commercial usage. In its third generation, BeiDou claims to reach a millimeter-level accuracy that outperforms other systems.

Galileo (EU)

Developed by the European Union in 2011, Galileo will consist of 30 satellites when it is fully operational (i.e., 24 working satellites with six spares). It provides a more accurate positioning service at higher latitudes than other GNSS systems by using over 24 satellites in six orbital planes. Galileo is currently providing emergency response services and making Europe’s roads and railways safe for everyone.

4 Benefits of Using Multiple Constellation GNSS Receivers at Once

Modern positioning and timing modules have evolved to take advantage of multiple GNSS constellations at once. Combining multiple satellite systems:

  • Improves signal availability
  • Gives operators more access
  • Increases accuracy

Whether you’re navigating in a crowded city or a vast desert, multiple GNSS systems help you stay connected and centered while providing continuous positioning. 

Industries and businesses can achieve the following benefits:

  1. Added Security
    In the unlikely event that a satellite fails, GNSS receivers will automatically remove it from the navigation solution.
  2. Multiple Pathways
    Access to multiple satellites increases visibility in regions with natural or artificial obstructions. (Urban canyons are created by tall, clustered buildings and can impact single-frequency GNSS accuracy.) This access improves Time to First Fix (TTFF), a measure of the time needed for a GNSS-connected device to determine its location from power-up.
  3. Future Proofing
    Integrating multiple GNSS systems helps industries and businesses with future-proofing their products and services. Changes in each system mirror changes in the marketplace at varying rates.
  4. Increased Data Integrity
    Galileo provides increased security features for multiple industries, including:
  • Maritime
  • Rail
  • Logistics
  • Automotive

Layering multiple systems like Galileo with GPS casts a wider net in terms of reach and accuracy. 

Evolution of Low-Power GNSS Solutions

Historically, GNSS receivers have consumed considerable amounts of power. The power consumption requirements have dropped dramatically over the last decade. Today’s GNSS receivers often have many configuration options, allowing users to manage power consumption and adapt functionality to specific use cases. The most challenging use cases for achieving a perfect balance between GNSS capabilities and power consumption include small IoT devices requiring near-continuous connectivity (e.g., pet or child trackers and smartwatches). 

Devices that rely on multiconstellation GNSS tend to consume more power since they require more energy for seeking connections with various satellite signals. Because different GNSS constellations use varying frequency bands, receivers must use more power to track multiple sources.  

4 Ways to Minimize GNSS Receiver Power Consumption

With any IoT device design, there are trade-offs when it comes to functionality and energy consumption. If your use case requires constant connectivity, the device won’t be able to go into a power-conserving sleep mode for long. While trade-offs remain a reality, there are opportunities to minimize GNSS receiver power consumption within a device.  

  1. Selecting Components
    Each component in the GNSS receiver can be selected with care to reduce overall power consumption. Including a backup battery can prevent situations in which power interruptions cause the receiver to reboot. Cold startups consume a significant amount of power. Having a backup battery to keep the receiver operational during outages allows the device to resume operation quickly and use less power. The oscillator is another component that can reduce or increase power usage. However, it must be chosen carefully based on the use case. If temperature fluctuations are possible in deployment (e.g., if the receiver will be in a logistics tracker on a ship or truck), choosing a temperature-controlled crystal oscillator (TCXO) might be wise. A TCXO reduces power while increasing receiver sensitivity. Other components that can affect power consumption include the real-time clock (RTC) and active antennas. Telit integrates RTCs and TCXOs for optimal performance in our GNSS receivers. This integration helps customers save time to market with a ready-to-use product. 
  1. Reducing Update Rate to Utilize Power Save Modes
    GNSS receivers might need to update their position once per second, hour or day depending on the use case. Ensuring the receiver’s update rate matches the use case needs allows operators to minimize power consumption and let devices enter Power Save Mode (PSM) between updates. Today’s GNSS receivers typically include at least one of these PSM options: 
  • Cyclic Tracking  
    Cyclic tracking PSM relies on a reduced-power tracking mode that does not seek new satellites. While not ideal for remotely deployed devices that rely on weak signals, this mode saves considerable power for receivers that enjoy strong, consistent satellite signals. 
  • On/Off Operation 
    The receiver can switch to a deep sleep mode (OFF) in this PSM, reducing power consumption. For devices that require check-ins once or twice per day, this is an excellent choice. 
  • Continuous Tracking 
    After an initial connection to check position, the receiver uses this mode to minimize power consumption while maintaining a continuous connection. This PSM is ideal for use cases requiring near-constant updates on position, such as sports or vehicle trackers. 
  1. Cloud-Based Processing 
    Outsourcing complex computing processes to the cloud is another way for GNSS receivers to minimize power consumption at the end device. With a practice called snapshot positioning, the GNSS receiver carries out reception and processing tasks, but a cloud-based service calculates the actual position.  
  1. Optimizing Power in Multiconstellation GNSS 
    Multiconstellation functionality increases accuracy and provides more continuous positioning updates, but there are trade-offs. When receivers track multiple GNSS constellations, they use more power — especially when different frequency bands are involved. One way to save energy while utilizing multiconstellation GNSS is by paying attention to which constellations your receivers will track depending on their location. Instead of tracking every available constellation, choose a few most likely to provide accurate positioning in the area where the devices are deployed. Try to minimize how many radio frequency (RF) bands the receivers will need to use. 

Finding the Right Multi-Constellation Solutions for the Future

Telit offers many solutions for those curious about which services exist for utilizing signals from multiple GNSS constellations while minimizing power consumption. Telit is one of the few IoT companies delivering different combinations of multiple GNSS solutions for its customers. Test one of our GNSS modules in your application. 


Editor’s Note: This blog was originally published on 6 March 2018 and has since been updated. 

参考译文
多gnss设置的业务优势
物联网(IoT)在驱动世界的人和过程之间连接起稳定的信息流。 全球导航卫星系统(GNSS) 为设备操作提供关键的定时和定位功能。GNSS利用卫星技术洞察连接设备的地理位置。GNSS是全球系统类别的一个包容性术语,包括:当同时使用多个星座时,这些系统的好处结合在一起,可改善卫星覆盖和整体性能。此外,区域卫星增强系统(SBAS)有助于全球系统:当选择在物联网努力中使用多少系统时,所有这些都是至关重要的考虑因素。随着全球对连接的需求增加,企业可以期待看到 更多的GNSS技术集成。现在有哪些GNSS平台,它们有什么不同?虽然GPS和GNSS经常互换使用,但GPS是世界上使用最多的卫星导航系统。它由32颗卫星在6个轨道平面上运行。 GPS是美国为军事用途开发的,我们现在可以在社交媒体上看到车载导航和商业标签。使用精确点定位(PPP)或实时运动学(RTK)技术的高精度多频GPS可以识别10厘米或更少的空间位置。和GPS一样, GLONASS 是在20世纪70年代作为俄罗斯军事定位系统设计的。商业应用(例如,传输导航定位和天气广播)始于20世纪80年代,在三个轨道飞机上部署了24颗卫星。自2000年以来,中国的北斗卫星导航系统(BDS)在全球商业用途上一直处于上升趋势,正在超过GPS。在它的第三代,北斗声称达到毫米级的精度,优于其他系统。伽利略号由欧盟于2011年开发,在完全投入使用时将由30颗卫星组成(即24颗工作卫星和6颗备件)。它在6个轨道面上使用24颗以上卫星,在高纬度地区提供比其他GNSS系统更精确的定位服务。伽利略系统目前正在提供紧急响应服务,使欧洲的公路和铁路对每个人都是安全的。现代的定位和授时模块已经发展到可以同时利用多个GNSS星座。结合多个卫星系统:无论你是在拥挤的城市还是广阔的沙漠中导航,多个GNSS系统可以帮助你保持联系和集中,同时提供持续的定位。行业和企业可以实现以下好处:将多个系统分层,比如伽利略系统和GPS系统,在覆盖范围和精度方面撒下更大的网。从历史上看,GNSS接收器消耗了相当大的能量。在过去的十年里,电力消耗要求急剧下降。今天的GNSS接收器通常有许多配置选项,允许用户管理功耗,并根据特定的用例调整功能。要实现GNSS功能和功耗之间的完美平衡,最具挑战性的用例包括需要接近连续连接的小型物联网设备(例如,宠物或儿童追踪器和智能手表)。使用多星座GNSS的设备在寻找与各种卫星信号的连接时需要消耗更多的能量,因此消耗的能量也更多。由于不同的GNSS星座使用不同的频段,接收器必须使用更多的功率来跟踪多个信号源。对于任何物联网设备的设计,在功能和能源消耗方面都存在权衡。如果你的用例需要持续连接,设备将无法长时间进入省电休眠模式。虽然折衷仍然是现实,但仍有机会将设备内的GNSS接收器功耗最小化。 Telit为那些好奇的人提供了许多解决方案,利用来自多个GNSS星座的信号,同时最大限度地减少功耗。Telit是为数不多的为客户提供多种GNSS解决方案不同组合的物联网公司之一。 在您的应用程序中测试我们的GNSS模块之一。编者注:本博客最初发布于2018年3月6日,随后进行了更新。
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