What Is NTRIP and how to use It for RTK

To perform an accurate RTK survey, you usually need a rover and a base that transmits the corrections in real-time. You can either use your own base or a remote one using a technology called NTRIP.

What Is NTRIP

The Networked Transport of RTCM via Internet Protocol or NTRIP network was developed by the German Federal Agency for Cartography and Geodesy in 2004. NTRIP allows your rover to accept corrections over the Internet with no need for the second local receiver acting as a base.

NTRIP includes three main components of the system: base, caster, and client’s rover. Usually, in this case, there’s a stationary Continuously Operating Reference Station or CORS. The data is then sent to the NTRIP caster, where it is retransmitted through the Internet port to the client rover connected via a particular port and authorized.

Eventually, when using NTRIP, you receive all these corrections via a cellular modem installed in your rover.

 

How to Connect to NTRIP

To get access to the NTRIP network, you need to contact your local NTRIP service to create an account. Some of the NTRIP networks are run by states, some are free of charge, some of them are private and are pretty costly when it comes to the subscription fees.

We have our own NTRIP caster—it,  you have to get credentials and enter them in your rover. It takes just a few steps to register and acquire the data for your account. The service allows working  free of charge until 31 December 2021 and you can register here.

Once you’re registered, you’ll get a approval email with parameters Domain or IP address and port to access and get authorized by the network. You’ll also need a username and password to log into the network.

Once you’ve completed the registration, you can use your credentials to connect your rover to the NTRIP network and receive connections.

 

What Is VRS

If you’re working with NTRIP, there’s a good chance you’ll come across this term. VRS or Virtual Reference Station is a useful tool for long baselines.

The density of NTRIP bases and CORS can vary greatly from place to place. If the density of stations is enough, but you are too far from any of them, VRS helps you eliminate your baseline.

Say, you are 90 km away from the nearest station. When working in RTK mode, this baseline is quite long. To create a VRS, your rover sends data back to the NTRIP caster. NTRIP allows the uniting of the data from your rover and the data from dense NTRIP bases and models a virtual base next to you. Thus, your baseline will go from 90 km to 0 km.

The elimination of a baseline helps establish a fixed solution faster and keep it stable.

서울특별시 네트워크 RTK 시스템 | GNSS 시스템 | 고정밀 GNSS 위치결정 | 네트워크 RTK

 

Pros and Cons of Using NTRIP

NTRIP is a very useful method to implement when working in RTK. However, it has its advantages and disadvantages.

Advantages:

  • High absolute accuracy. With corrections from NTRIP, you obtain high accuracy in your data.
  • No need for a local base. You can work with just a rover and still perform an accurate survey.
  • Fast fix. Internet connection to NTRIP helps you find the fix solution faster.

Disadvantages:

  • Fees. Some NTRIP networks are private or for special governmental use, so you need to pay for using them..
  • Being dependent on the Internet. NTRIP only works via the Internet, so you need the cellular network coverage to use it. That means if the surveying ground is beyond Internet coverage, NTRIP is unavailable.

Your decision on whether to use NTRIP or not mostly depends on your particular case and conditions you’re going to work in.

Why you should use the new CORS

So far CORS systems have provided Mountpoints of RTCM3 LEGACY format with message types 1001-1004, 1009-1012, which have enabled the sending of corrections for GPS and GLONASS navigation systems.

The new RKSCORS system offers a wide range of Mountpoints, to support corrections from all navigation systems (GPS + GLO + GAL + BDS + QZS) with the latest MSM multiple resolution message formats and resolution high, in order to support all types of GNSS receivers (rovers) with all frequencies.

Register and discover the advantages of your GNSS rover

with continuous operation of GNSS reference stations (CORS)
NEAR
NEAR_MSM4
VRS
NEAR_GG
MAX

Mountpoints

NEAR

Mountpoint: NEAR

Identifier: NEAR_MSM7

Format: RTCM3.3 

Format-Details: 1006(10),1008(10),1033(10),1077(1),1087(1),1097(1),1117(1),1127(1),1230(10)

Carrier: 5

Nav-System: GPS+GLO+GAL+BDS+QZS

Description:http://cors.consult-eng.com/?p=112

Mountpoint: NEAR_MSM4

Identifier: NEAR_MSM4

Format: RTCM3.2 

Format-Details: 1006(10),1033(10),1074(1),1084(1),1094(1),1114(1),1124(1),1230(10)

Carrier: 5

Nav-System: GPS+GLO+GAL+BDS+QZS

Description:

Mountpoint: VRS

Identifier: VRS

Format: RTCM3.3 

Format-Details: Virtual Reference Station

Carrier: 5

Nav-System: GPS+GLO+GAL+BDS+QZS

Description:

Mountpoint: NEAR_GG

Identifier: NEAR_GG

Format: RTCM3 

Format-Details: 1004(1), 1006(10),1008(10),1012(1), 1033(10),1230(10)

Carrier: 2

Nav-System: GPS+GLO

Description:

Mountpoint: MAX

Identifier: MAX_MSM7_EPH

Format: RTCM3.3 

Format-Details: 1006(10),1008(10),1019(5),1020(5),1042(5),1044(5),1045(5),1046(5),1033(10),1077(1),1087(1),1097(1),1117(1),1127(1),1230(10)

Carrier: 5

Nav-System: GPS+GLO+GAL+BDS+QZS

Description: