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sensors:gnss:synchronized [2012/11/07 13:35] karina |
sensors:gnss:synchronized [2021/08/14 04:21] (current) |
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==== Synchronized RTK mode ==== | ==== Synchronized RTK mode ==== | ||
- | Precise time reference | + | Very precise position |
== From: " | == From: " | ||
[[http:// | [[http:// | ||
- | Synchronized RTK is the most widely used technique to achieve centimeter-level position estimates between a fixed base station and a roving receiver. Typically, the update rate for Synchronized RTK is once per second (1Hz). With Synchronized RTK, the rover receiver must wait until the base station measurements are received before computing a baseline vector. The latency of the synchronized position fixes is dominated by the data link delay (seeFigure2.1). Given a 4800 baud data link, the latency of the Synchronized RTK fixes will approach 0.5 seconds. The solution latency could be reduced by using a 9600 baud or higher bandwidth data link.\\ | + | Synchronized RTK is the most widely used technique to achieve centimeter-level position estimates between a fixed base station and a roving receiver. Typically, the update rate for Synchronized RTK is once per second (1Hz). With Synchronized RTK, the rover receiver must wait until the base station measurements are received before computing a baseline vector. The latency of the synchronized position fixes is dominated by the data link delay (see Figure2.1). Given a 4800 baud data link, the latency of the Synchronized RTK fixes will approach 0.5 seconds. The solution latency could be reduced by using a 9600 baud or higher bandwidth data link.\\ |
- | The Synchronized RTK solution yields the highest precision possible and suits low dynamic applications such as human-mounted guidance. Airborne applications such as photogrammetry, | + | The Synchronized RTK solution yields the highest precision possible and suits low dynamic applications such as human-mounted guidance. Airborne applications such as photogrammetry, |
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- | == Fast Update Synchronized RTK (5 or 10 Hz) == | + | {{ : |
- | The Fast Update Synchronized RTK scheme has the same latency and precision as the 1 Hz synchronized approach. However, position solutions are generated 5 or 10 times per second (5 or 10 Hz), see Figure 2.2. | + | |
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- | The BD950 base station must be configured to output CMR data in either the 5 Hz or 10 Hz CMR Mode. In the Fast Output Mode, the BD950 base receiver interleaves the 1Hz CMR measurement data with highly compressed information at the x.2, x.4, x.6 and x.8 second epochs for 5Hz output. At the 10Hz CMR output rate, packets are sent at x.1, x.2, x.3,..., x.9 seconds between the x.0 epochs. The total data throughput requirement for the Fast Mode is less than 9600 bps for 9 satellites. | + | |
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- | The BD950 rover synchronizes its own 5 or 10Hz measurements with those received from the base. Results are then generated and can be output at 5 or 10 Hz. The data link throughput is critical | + | |
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- | //**Note** – The Fast Update Synchronized RTK mode is only supported through the CMR format. The RTCM messages cannot be output at 5 or 10 Hz.// | + |