Is it just us, or are there too many tracking-related acronyms flying around the Internet these days? GPS, GLONASS, GNSS, NFC, IoT, BLE...the list goes on and on! In this quick "back to basics" terminology refresher, we'll go over:
- What is GPS?
- How does it work?
- Is tracking with GPS always the right solution?
What is GPS?
GPS (Global Positioning System) is a satellite-based navigation system developed in the United States for location tracking applications. Originally launched by the US Department of Defense for military use, GPS became available to civilians in the 1980s and is the standard for location-based tracking. Today, the United States (GPS), Russia (GLONASS), Europe (Galileo) and China (BeiDou) all maintain operational satellites, enabling coverage across the globe. For improved reliability and accuracy, our GPS tracking devices support both GPS and GLONASS concurrently.
As these satellites orbit Earth, their unique signals and orbital elements are transmitted to GPS-enabled devices, like traditional tracking devices, mobile phones, or on-board navigation systems. Based on the amount of time it takes to receive these signals, the GPS devices compute how far away they are from these satellites, and determine their position.
Now that the GPS-enabled device knows its location, it still needs to communicate the coordinates. GPS devices often also house SIM cards, which are used to transmit their location to users over cellular networks where coordinates are finally decoded and presented in tracking apps or software.
Is tracking with GPS always the right solution?
Due to the profusion of global satellites in orbit, tracking with GNSS (global navigation satellite systems) is highly accurate, often within a few feet or metres. However, as Internet of Things (IoT), or device-to-device tracking applications become more and more prevalent, GPS is not always the most reliable or affordable solution.
IoT tracking and monitoring applications require long-life, often battery powered devices. Extremely low energy consumption is also needed to prolong the life of the tracking device. Though exceedingly accurate, GPS devices use a considerable amount of energy coordinating their positions, which is not a viable solution for IoT. Satellite signals are also substantially weakened indoors, so reliably tracking in warehouses, airports, and underground parking lots for example, isn't possible.
Bluetooth and Bluetooth Low Energy (BLE) devices enable near field communication (NFC) using a system of gateways and tags. BLE devices transmit small amounts of data over short distances with substantially reduced power consumption. Our newest range of traditional GPS tracking devices for example are developed with BLE technology to support concurrent satellite-based location and NFC with lower-valued tagged assets, enhancing traditional GPS tracking applications. Bluetooth tags also don't require the use of SIM cards, which means no ongoing connectivity costs, which most traditional GPS devices incur.
WiFi sniffing is another alternative to GPS and is particularly well suited for tracking assets indoors. Tracking devices with WiFi sniffing scan for all WiFi access points in a vicinity. The device doesn't connect to these WiFi networks, it simply assesses which networks it is near and their signal strengths to assist in the positioning algorithm. Our WiFi sniffing devices access on average 15 different networks while determining positioning, for location accuracy between 10 and 44 yards depending on signal strength.
Wondering what the right solution is for your asset tracking need? Get in touch with us today to discuss your options.