What’s the difference between PPK and RTK drones, and which one is better?
Post-processed kinematic (PPK) and real-time kinematic (RTK) are not new technologies. They’ve been used in terrestrial surveying for years to improve the accuracy of GNSS data. Both methods correct the location of drone mapping data and remove the need for GCPs, bringing absolute accuracy down to cm (sub-inch) range.
However, when you factor in obstacles and environmental conditions common to aerial surveying, the difference between a PPK drone and an RTK drone becomes more important to understand. In fact, choosing the best correction method for your surveys will save you time and project costs. But how do you know which is best? The answer can be found in learning about how each method works, including its inherent strengths and drawbacks.
Post-processed kinematic (PPK) and real-time kinematic (RTK) are not new technologies. They’ve been used in terrestrial surveying for years to improve the accuracy of GNSS data. Both methods correct the location of drone mapping data and remove the need for GCPs, bringing absolute accuracy down to cm (sub-inch) range.
However, when you factor in obstacles and environmental conditions common to aerial surveying, the difference between a PPK drone and an RTK drone becomes more important to understand. In fact, choosing the best correction method for your surveys will save you time and project costs. But how do you know which is best? The answer can be found in learning about how each method works, including its inherent strengths and drawbacks.
What is an RTK drone (and how does RTK work)?
- An RTK drone carries an onboard GNSS RTK receiver that gathers data from satellites and a stationary base (ground) station to more accurately correct image location, in real time as it flies
- Satellite data—by itself, and in any case—is error-prone due to tropospheric delays, etc., providing a maximum accuracy of about 1 meter (3.3 ft)
- The data from a ground station is factored in to correct satellite signal error, bringing accuracy down to cm (sub-inch)-level range
- In the case of RTK technology, uninterrupted communications are required from the GNSS base station, through the drone base station to the drone
- When the drone lands, if all signals were constant, data with absolute accuracy is available for post processing into mapping survey results
What is a PPK drone (and how does PPK work)?
- A PPK drone flies with an onboard GNSS PPK receiver that gathers data from satellites and logs it for retri after the flight
- Satellite data—by itself, and in any case—is error prone due to tropospheric delays, etc., providing a maximum accuracy of about 1 meter (3.3 ft)
- The satellite data from a GNSS receiver on a nearby base (ground) station is collected and, after the flight, it’s factored in with the drone data to correct satellite signal error, bringing accuracy down to cm (sub-inch)-level range
- In the case of PPK technology, neither GNSS base station to drone base station, nor drone base station to drone correction data communications are required; only the telemetry between drone and drone base station is needed
- When the drone lands, a correction process needs to be applied through a suitable software, e.g., WingtraHub. Data with absolute accuracy is then available for post processing into mapping survey results
Because you don’t need to maintain a link between the stationary base station and drone base station, and a link between the drone base station and the drone in the case of PPK, this method presents more reliable data correction and easier set-up.
If you’ve ever worked with drones, you know that short interruptions in telemetry links happen quite frequently. When they do, the loss of lock lasts longer than just a moment. It takes time to reinitialize. And until it does, you lose correction data for that particular area of your drone survey.
So with RTK, you are more likely to end up with significant gaps in your data where accuracy degrades to GPS quality.
