Undoubtedly, you’ve heard the term GPS. It’s not uncommon for consumers to refer to navigation software like Waze, Google Maps, Apple Maps or a portable navigation device from Garmin or TomTom as a GPS. Unfortunately, giving these solutions the GPS title is incorrect. Let’s look at GPS, how it works, and how similar technologies are evolving.

What Is GPS?

The Global Positioning System (GPS) is one type of global navigation satellite system (GNSS). A GNSS uses an array (also called a constellation) of satellites that broadcast extremely accurate time signals. A receiver on the ground (or in your vehicle, a portable navigation device or a smartphone) receives several of these signals. Based on the information from multiple satellites, the receiver can calculate its location and altitude.

GPS was a project started in the early 1970s by the U.S. Department of Defense to provide accurate location information to military troops and was initially called Navstar GPS. Previous terrestrial locating systems such as Decca, LORAN and Omega used longwave radio transmissions from ground-based antennae. A receiver would capture a master signal, then signals from slave transmitters. Analyzing the time differences between the signals allowed for location calculation.

GPS uses a satellite constellation that circles the globe in medium Earth orbits about 20,000 kilometers above the ground. The first satellite was launched in 1978, and the full constellation was completed in 1993. There are currently 32 operational satellites, and the United States Space Force operates the system.

How Does GPS Locating Work?

Each GPS satellite orbits the Earth once every 11 hours, 58 minutes and 2 seconds. Each satellite continuously transmits a signal containing the satellite’s orbit details and precise time information from an onboard atomic clock. The receiver can calculate the distance to the satellite by comparing the time that the signal left the satellite to when it arrived at the antenna. Once the receiver has distance information from several satellites, it can attempt to pinpoint a location using a process called trilateration.

In the image above, we see a circle on the Earth. This circle represents all the possible locations where the distance between the ground and the satellite is equal. Let’s say the satellite is 26,000 kilometers away from this location. It would take 0.0867266647515195 second for the signal from the satellite to reach any place on this red circle. This information alone doesn’t tell us much about the location, other than perhaps what part of the planet we are on. We likely already know that. Let’s add another satellite.

We’ve added information from a second satellite, shown by the yellow circle. This satellite appears to be a bit farther away from our location at 29,000 kilometers. It would take the signal from the satellite 0.0967335876074641 second to travel that distance.

Whatever GNSS receiver we are using can analyze the data from the satellite and determine that we are 26,000 kilometers from one source and 29,000 kilometers from the other. This information gives us two possible locations on the Earth’s surface. The small green dots in the image above mark these locations. We are close to having our position, but we need more data. One more satellite is required.

We’ve added a third circle. This satellite might be 22,000 kilometers away. As such, we know the time it takes for the data to arrive at our receiver should be 0.0733841009435934 second. Only one location on the Earth has these three signal travel times to their respective satellites. The blue dot represents that location.

Satellite-Based Positioning System Accuracy

Unfortunately, the clock on our GPS receiver is nowhere near as accurate as the atomic clocks on the $250 million satellites. This reduction in timing accuracy decreases the location accuracy as we have to throw away some of those decimal places from the timing calculations. Some quick math shows us that limiting the timing accuracy to eight decimal places reduces the accuracy to an area of over 2 meters when the satellite is far away and about 30 centimeters when the satellite is close.

Other issues like atmospheric effects can cause timing errors. Part of the cost of operating GPS is constantly checking and calibrating each satellite’s signals. High-precision receivers at fixed locations on the ground continuously monitor the signals from all the orbiting satellites. Measurement of errors because of humidity, atmospheric pressure and ionospheric delay can reduce accuracy to dozens of kilometers. The operators use data from fixed ground stations to create compensation signals transmitted back to the satellites to counteract these and many other errors.

In real-world applications, GNSS systems require data from at least four satellites, as this allows for some error correction. Consumer-level GPS receivers typically have a published accuracy of about 30 centimeters or 1 foot. The latest high-precision receivers can provide locations with an accuracy of 8 mm in longitude and latitude and 15 millimeters in altitude.

If you’ve seen a YouTube video of a 3D drone show, they use GNSS modules that provide location accuracy with real-time precision of about 1 inch.

Below, a fleet of 200 Lumenier Arora light show drones doing testing at the Freedom Factory in Florida.

Are There Alternatives to GPS Locating?

While everyone talks about GPS locating as the de facto standard in GNSS systems, the reality is that many similar systems are in operation around the world. Aside from the U.S.-operated GPS, the Russian Federation operates GLONASS, China has the BeiDou system, and the European Union has Galileo. There are also regional systems like India’s NavIC and Japan’s QZSS. As of this article’s writing, there are 136 GNSS satellites in operation around the Earth, with 15 more as backups or in various commissioning stages.

The highest precision receivers, like those used for military and surveying, can simultaneously receive location data from multiple systems to increase accuracy. Many solutions, like Galileo, offer precision down to 1 centimeter or 0.39 inch with access to encoded data.

How Do We Use GNSS Services?

Navigation systems are among North America’s most popular consumer applications for GNSS information. Whether you have a portable navigation device (PND) like a Garmin or TomTom or rely on a smartphone-integration solution like Google Maps, Apple Maps or Waze, these systems pinpoint your location on a map database using a combination of GPS and location calculation using a system called Assisted GNSS. If you’ve ever put an iPhone into airplane mode, you may have seen a message about location services being more accurate when connected to a cellular service. Assisted GNSS downloads position data from a server over the cellular data network. In short, this technology knows which cellular towers you are close to and can use that information to help triangulate your location. Data about which GNSS satellites are in (relatively) close proximity is also downloaded to speed up the acquisition time of the GNSS receiver.

Of course, tracking and locating systems like the popular DroneMobile solution from Firstech combine a GNSS receiver with a cellular data radio. You can control a Compustar remote car starter or security system from the DroneMobile app on your smartphone. If you’ve signed up for location-based services, you can pinpoint the position of your vehicle or configure location-based alerts to help you monitor your car or truck.

GPS location information and tracking are great for hikers who want to venture into the woods and still find their way back home. Devices like SPOT satellite communication devices use GNSS information with Globalstar satellite messaging services to provide emergency support services almost anywhere on the planet.

There are dozens of commercial applications for GNSS data. Construction of large buildings often starts with surveying. Precision survey equipment uses GNSS data to mark property boundaries and denote parking lot elevations for proper drainage. The corners of building footings are also crucial identifiers based on GNSS data. If you’ve ever wondered how bridges are constructed simultaneously from opposing sides of a river to meet perfectly in the middle, it is attributable to accurate GNSS data. Modern construction equipment also uses GNSS data to provide exact elevation information.

Almost every commercial vehicle has location tracking — from airplanes and ships to trains, buses and transport trucks. Companies must keep track of their assets and ensure that they are safe and comply with company usage guidelines. GNSS information can help global operations avoid weather concerns.

The Future of GNSS Information

So what does the future hold for location information services like GPS, GLONASS and BeiDou? Companies like ALPS Alpine are working on location-based sensors for vehicles as part of the vehicle-to-everything (V2X) push. These products will dramatically improve autonomous driving technologies and help develop intelligent AI-based accident prevention as vehicles can communicate with one another with impressive location precision.

For now, when someone tells you to use GPS to get directions, they are referring to a navigation device that uses some or many forms of GNSS, including GPS locating. If you want to integrate the latest navigation technologies into your vehicle, drop by a local specialty mobile enhancement retailer and ask about a new radio or smartphone integration solution with Apple CarPlay and Android Auto.

This article is written and produced by the team at www.BestCarAudio.com. Reproduction or use of any kind is prohibited without the express written permission of 1sixty8 media.

Do you wish you could keep an eye on your kids when they borrow the family car or know where your fleet of work trucks are at any time? A GPS-based tracking system is an easy way to keep tabs on your vehicle. In this article, we’ll discuss some of the options for vehicle locating and tracking systems and, of course, explain how they work.

How Does GPS Vehicle Tracking Work?

A tracking module contains three primary components. First and foremost, a CPU controls the system. The CPU runs software that communicates with the rest of the hardware on the device. The next important component is a GPS receiver and antenna. The GPS receiver provides the CPU with the location, velocity and altitude of the vehicle. Third is a cellular radio. The cellular radio communicates with a server to store information about the vehicle’s location and operation.

GPS tracking systems communicate with the server at predetermined intervals based on the service package you have chosen. These intervals could be one, three, five or 20 minutes, or on-demand as required. More frequent updates use more cellular data and are typically associated with more expensive tracking service packages.

Tracking Hardware Options

Some tracking systems include additional features such as inputs for seat belts and doors, accelerometers to log sudden acceleration and braking, RFID fob readers to identify drivers and A/V inputs so you can see and hear what’s going on in the vehicle. Some premium hardware solutions include a lithium ion backup battery so the system will continue to function even if the vehicle battery is disconnected or completely dead. Other systems with integrated solar panels are available for trailers or infrequently used equipment. If you need a solution that can handle getting wet or dirty, tracking hardware is available in an IP65-rated water- and dust-resistant enclosure.

Custom solutions are available for specific applications. If you operate a fleet of waste removal vehicles, you can log each time they lift a bin. The same logic applies to tow trucks, snow plows and, of course, delivery vehicles. Custom sensors and switches can interact with the logging system to store and log almost any conceivable function. Perhaps you have an armored car service and need a panic button – that’s an easy solution.

Tracking Interface Options

Two interface options are available, depending on your needs. For most consumers, an app on your smartphone is available to let you see the location of your vehicle. In most cases, the location is overlaid on Google or Apple maps so you can understand the vehicle location graphically. In most cases, the location is accurate to within about 25 feet of where the vehicle actually is. If the GPS receiver receives signals from enough satellites, the accuracy can be even better.

For clients using their tracking system for business applications, most services provide a web-based interface that can show you the location of your entire fleet and allow you to configure warnings and reports.

Software-Based Features for Consumers

Consumer tracking solutions typically offer five or six software-based features. These include geofencing and over-speed alert, as well as tow alerts and after-hours motion alerts. Geofencing is an alert option that will let the operator know when the vehicle enters or exits a particular geographical area. In most cases, this feature is configured by placing a pin or marker at a location and identifying a boundary radius in miles around that position. Depending on how it’s configured, a warning is displayed on the operator’s smartphone when the vehicle enters or exits this area. Over-speed alerts are easy to understand. The operator configures a maximum speed for the system and will receive a notification if that speed is exceeded.

Two advanced features are the tow and after-hours motion alerts. The after-hours alert will send a warning if the vehicle moves during a preset time. If you never drive your vehicle after midnight and are rarely up before 6 a.m., you can set an alert to let you know if your vehicle moves during that period. Tow alerts are another great feature that helps alert the operator to potential vehicle theft. You will receive a tow alert when the vehicle moves without the ignition being turned on.

Business Applications and Features

For business owners, knowing how your vehicles are operated is as important as knowing their location. Many commercial solutions include accelerometers that log aggressive acceleration and abrupt stops. Smooth driving reduces wear on the vehicle and improves fuel economy. Many systems provide audible warnings to the operator to coach them in improving their driving habits. Commercial tracking solutions can typically generate reports that will identify idle time to reduce fuel consumption further.

Some tracking solution providers offer devices that comply with the Federal Motor Carrier Safety Administration’s Electronic Logging Device mandates. If you need to track Hours of Service or generate Record of Duty Status reports, several companies provide these services.

Benefits of Vehicle Tracking

From a business owner’s perspective, knowing where your vehicles are and how they are being used lets you manage your assets reliably. If your staff knows that they are being monitored, they typically drive more safely and waste less time on personal matters. Those savings alone can dramatically reduce your costs. You can generate usage logs based on distance traveled or hours of operation to schedule maintenance and streamline your operations. Research indicates that vehicles with GPS tracking where the operator knows you are logging the vehicle position are 7 percent more productive and use 8 percent less fuel. The same logic applies to letting your kids borrow your car. If they know you are keeping an eye on them, they are less likely to go places they aren’t supposed to.

Install a Vehicle Tracking System Today

Whether you want to log your mileage for your tax return, keep tabs on your son or daughter or monitor how your fleet of service vehicles is operated, your local mobile electronics retailer can help you choose a hardware solution that meets your needs.

This article is written and produced by the team at www.BestCarAudio.com. Reproduction or use of any kind is prohibited without the express written permission of 1sixty8 media.