diff --git a/config/zh/mkdocs.yml b/config/zh/mkdocs.yml index a7468a8..3b46a61 100644 --- a/config/zh/mkdocs.yml +++ b/config/zh/mkdocs.yml @@ -71,6 +71,7 @@ nav: - "快速入门": 如何搭配飞控使用.md - "解析GRTK定位信息": RTK-lib.md - "Pixhawk的使用": Pixhawk飞控的使用.md + - "网络RTK的配置使用": 配置网络RTK基站.md - "AutoRover-H3使用说明": AutoRover-H3使用说明.md - "Extra": diff --git a/docs/en/GRTK_User_Manual.md b/docs/en/GRTK_User_Manual.md index 522f0a7..9cc4f92 100644 --- a/docs/en/GRTK_User_Manual.md +++ b/docs/en/GRTK_User_Manual.md @@ -15,7 +15,7 @@ If you are interested with GRTK, welcome to join [GRTK Discord Community](https: GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by **Blicube**. A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). -The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. +The module is based on a new generation of high-performance GNSS SoC chip design (UM982 Inside), supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. **![](../media/grtk_1.1.png )** @@ -34,8 +34,8 @@ Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation s | Frequencies | BDS B1I/B2I1
GPS L1/L2
GLONASS L1/L2
Galileo E1/E5b
QZSS L1/L2 | | Single Point Positioning (RMS) | Horizontal:1.5m
Vertical:2.5m | | DGPS (RMS) | Horizontal:0.4m
Vertical:0.8m | -| RTK (RMS) | Horizontal:1cm+1ppm
Vertical:1.5cm+1ppm | -| Heading Accuracy (RMS) | 0.2 degree/1 m baseline | +| RTK (RMS) | Horizontal:0.8cm+1ppm
Vertical:1.5cm+1ppm | +| Heading Accuracy (RMS) | 0.1 degree/1 m baseline | | Velocity Accuracy (RMS) | 0.03 m/s | | Time Accuracy (RMS) | 20 ns | | Time to First Fix (TTFF) | Cold start < 25 s | @@ -47,8 +47,8 @@ Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation s | Inertial Navigation Accuracy | < 5% of distance travelled during GPS denied conditions | | Working Temperature | -20℃ to +85℃ | | Power Supply | 5v to 35v -| Power Dissipation | ~2.5W -| Compass inside | support +| Power Dissipation | ~1W +| Compass inside | IST8310 - **Physical size** diff --git a/docs/media/mp-ntrip-1.png b/docs/media/mp-ntrip-1.png new file mode 100644 index 0000000..6a09194 Binary files /dev/null and b/docs/media/mp-ntrip-1.png differ diff --git a/docs/media/mp-ntrip-2.png b/docs/media/mp-ntrip-2.png new file mode 100644 index 0000000..06e8a6c Binary files /dev/null and b/docs/media/mp-ntrip-2.png differ diff --git a/docs/media/mp-ntrip-3.png b/docs/media/mp-ntrip-3.png new file mode 100644 index 0000000..af22b2a Binary files /dev/null and b/docs/media/mp-ntrip-3.png differ diff --git a/docs/media/mp-ntrip-4.png b/docs/media/mp-ntrip-4.png new file mode 100644 index 0000000..8f76951 Binary files /dev/null and b/docs/media/mp-ntrip-4.png differ diff --git a/docs/media/mp-ntrip-5.png b/docs/media/mp-ntrip-5.png new file mode 100644 index 0000000..4fbc3fc Binary files /dev/null and b/docs/media/mp-ntrip-5.png differ diff --git "a/docs/zh/GRTK\347\224\250\346\210\267\346\211\213\345\206\214.md" "b/docs/zh/GRTK\347\224\250\346\210\267\346\211\213\345\206\214.md" index 6abd341..3c4a433 100644 --- "a/docs/zh/GRTK\347\224\250\346\210\267\346\211\213\345\206\214.md" +++ "b/docs/zh/GRTK\347\224\250\346\210\267\346\211\213\345\206\214.md" @@ -27,7 +27,7 @@ GRTK是blicube(北力电子)独立研发的双天线高精度差分定位定向模块(Real Time Kinematics),通过两个GRTK模块(一个移动端,一个基站端)可组成完整的RTK系统。 -该模块基于新一代国产高性能GNSS SoC芯片设计,支持多系统多频点RTK定位,支持双天线高精度定向,支持北斗导航定位,支持内置罗盘以满足单天线时航向需求,主要面向无人机、机器人及智能驾驶等高精度定位定向需求。 +该模块基于新一代国产高性能GNSS SoC芯片设计(UM982 inside),支持多系统多频点RTK定位,支持双天线高精度定向,支持北斗导航定位,支持内置罗盘以满足单天线时航向需求,主要面向无人机、机器人及智能驾驶等高精度定位定向需求。
![](../media/grtk_1.1.png ){ width="300" } @@ -50,13 +50,13 @@ GRTK是blicube(北力电子)独立研发的双天线高精度差分定位定 | 时间精度(RMS) | 20ns | | 单点定位(RMS) | 平面:1.5m
高程:2.5m | | DGPS (RMS) | 平面:0.4m
高程:0.8m | -| RTK (RMS) | 平面:1cm+1ppm
高程:1.5cm+1ppm | -| 定向精度(RMS) | 0.2度/1m基线 | +| RTK (RMS) | 平面:0.8cm+1ppm
高程:1.5cm+1ppm | +| 定向精度(RMS) | 0.1度/1m基线 | | 速度精度(RMS) | 0.03m/s | | 工作温度 | -20℃到+85℃ | | 工作电压 | 支持宽压输入:5v-35v | | 工作功耗 | 2.5W | - | 内置罗盘 | 支持 | + | 内置罗盘 | IST8310 | - **实物尺寸** diff --git "a/docs/zh/\351\205\215\347\275\256\347\275\221\347\273\234RTK\345\237\272\347\253\231.md" "b/docs/zh/\351\205\215\347\275\256\347\275\221\347\273\234RTK\345\237\272\347\253\231.md" new file mode 100644 index 0000000..5e51547 --- /dev/null +++ "b/docs/zh/\351\205\215\347\275\256\347\275\221\347\273\234RTK\345\237\272\347\253\231.md" @@ -0,0 +1,69 @@ +# 网络RTK基站配置给GRTK Rover使用实现RTK定位 + +!!! warning "网络RTK基站具有覆盖范围大,不受基站位置限制的优势,但由于基站距离移动站距离通常较远,而GRTK的水位定位精度为 0.8cm+1ppm,即基站与移动站距离每超过10Km,定位精度将下降1cm,因而出现定位精度下降的情况是预期中的,实际定位精度需综合网络基站服务提供商和网络状态等因素。" + +!!! info "网络RTK基站服务通常遵从Ntrip协议" + GRTK为五星设备,请在 + +## 网络RTK基站服务的选择 + +!!! info + - 网络RTK基站服务通常遵从`Ntrip`协议, 购买服务请与服务提供商确认 + - `端口`请选择 **WGS84坐标系** + - `源节点`请选择**五星十六频** + +## CORS账号示例 + +!!! info "账号信息" + 网络RTK服务账号至少应包含: + - 账号 + - 密码 + - IP + - 端口(port) + - 源节点(mount) + +``` +账号:cedr5668 密码:km1y27vr + +cors账号配置方法: +移动CORS设置方式: +①IP:120.253.239.161 +②端口:8001对应CGCS2000坐标系,8002端口对应WGS84坐标系,记得中央子午线改成当地 +③源节点: +RTCM33_GRCEJ(五星十六频,推荐五星仪器以上使用) +RTCM33_GRCEpro(四星十三频,推荐四星仪器以上使用) +RTCM33_GRCE(四星十一频,推荐四星仪器以上使用) +RTCM33_GRC(三星八频,推荐三星仪器使用) +RTCM30_GR(双星仪器使用) +``` + +## 使用Mission Planner转发基站RTCM数据给Rover + +### RTK/GPS Inject + +!!! info "初始设置 -> RTK/GPS Inject -> Ntrip -> Connect" + +![](../media/mp-ntrip-1.png){ width="500" } + +### 输入Ntrip账号信息 + +!!! info "以CORS账号服务为例" + http://cedr5668:km1y27vr@120.253.239.161:8002/RTCM33_GRCEJ + +![](../media/mp-ntrip-2.png){ width="500" } + +### 连接成功 + +![](../media/mp-ntrip-3.png){ width="500" } + +!!! info "GPS 显示为 RTK Float" + 进入rtk定位,但此时GRTK的`RTK`灯并不会亮 + +![](../media/mp-ntrip-4.png){ width="500" } + + +!!! info "GPS 显示为 RTK Fixed" + 进入高精rtk定位,此时GRTK的`RTK`灯亮起 + 具体进入RTK Fixed的时间主要取决于网络RTK数据 + +![](../media/mp-ntrip-5.png){ width="500" } diff --git a/generated/en/GRTK_User_Manual/index.html b/generated/en/GRTK_User_Manual/index.html index 5bff4da..f378d36 100644 --- a/generated/en/GRTK_User_Manual/index.html +++ b/generated/en/GRTK_User_Manual/index.html @@ -960,7 +960,7 @@

GRTK User Manual

Part 1 System Introduction

1.1 Introduction

GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube. A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal).

-

The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving.

+

The module is based on a new generation of high-performance GNSS SoC chip design (UM982 Inside), supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving.

Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation system @@ -991,11 +991,11 @@

1.2 Parameters

RTK (RMS) -Horizontal:1cm+1ppm
Vertical:1.5cm+1ppm +Horizontal:0.8cm+1ppm
Vertical:1.5cm+1ppm Heading Accuracy (RMS) -0.2 degree/1 m baseline +0.1 degree/1 m baseline Velocity Accuracy (RMS) @@ -1043,11 +1043,11 @@

1.2 Parameters

Power Dissipation -~2.5W +~1W Compass inside -support +IST8310 diff --git a/generated/en/media/mp-ntrip-1.png b/generated/en/media/mp-ntrip-1.png new file mode 100644 index 0000000..6a09194 Binary files /dev/null and b/generated/en/media/mp-ntrip-1.png differ diff --git a/generated/en/media/mp-ntrip-2.png b/generated/en/media/mp-ntrip-2.png new file mode 100644 index 0000000..06e8a6c Binary files /dev/null and b/generated/en/media/mp-ntrip-2.png differ diff --git a/generated/en/media/mp-ntrip-3.png b/generated/en/media/mp-ntrip-3.png new file mode 100644 index 0000000..af22b2a Binary files /dev/null and b/generated/en/media/mp-ntrip-3.png differ diff --git a/generated/en/media/mp-ntrip-4.png b/generated/en/media/mp-ntrip-4.png new file mode 100644 index 0000000..8f76951 Binary files /dev/null and b/generated/en/media/mp-ntrip-4.png differ diff --git a/generated/en/media/mp-ntrip-5.png b/generated/en/media/mp-ntrip-5.png new file mode 100644 index 0000000..4fbc3fc Binary files /dev/null and b/generated/en/media/mp-ntrip-5.png differ diff --git a/generated/en/search/search_index.json b/generated/en/search/search_index.json index 9fe637c..e1330bb 100644 --- a/generated/en/search/search_index.json +++ b/generated/en/search/search_index.json @@ -1 +1 @@ -{"config":{"indexing":"full","lang":["en"],"min_search_length":3,"prebuild_index":false,"separator":"[\\s\\-]+"},"docs":[{"location":"","text":"GRTK Introduction GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning, and heading with compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback. Performance Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a1cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.2 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~2.5W Compass inside Support Physical size Test Video Unmanned vehicle automatic route mission measurement.","title":"GRTK Overview"},{"location":"#grtk-introduction","text":"GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning, and heading with compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback.","title":"GRTK Introduction"},{"location":"#performance","text":"Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a1cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.2 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~2.5W Compass inside Support","title":"Performance"},{"location":"#physical-size","text":"","title":"Physical size"},{"location":"#test-video","text":"Unmanned vehicle automatic route mission measurement.","title":"Test Video"},{"location":"FAQ/","text":"FAQ Installation Can I use the GRTK without any settings when I get it? A: Of course! GRTK are all set and tested before we send it to you. I bought a GRTK kit, but how can I identify which one is base and which one is rover? A: We will label different devices respectively. The rover station has 2 antennas, where does GRTK positioning data mean? A: The master antenna, aka \"ANT1\", represents the location GRTK is positioning. Extra Settings How can I set a special NMEA output not only default settings? A: You can config GRTK by serial port, please follow GRTK User Manual . Others Can GRTK rover station work with a base station but not GRTK base which supports RTCM data? A: Of course. But you should have a special config for your base station to adapt to our rover station. We strongly suggest that use a GRTK kit for RTK positioning, and we can't make sure the rover station's performance. Can serval rover stations work with only one base station? A: Yes, you can have a point to multipoint RLINK kit to make GRTKs work.","title":"FAQ"},{"location":"FAQ/#faq","text":"","title":"FAQ"},{"location":"FAQ/#installation","text":"Can I use the GRTK without any settings when I get it? A: Of course! GRTK are all set and tested before we send it to you. I bought a GRTK kit, but how can I identify which one is base and which one is rover? A: We will label different devices respectively. The rover station has 2 antennas, where does GRTK positioning data mean? A: The master antenna, aka \"ANT1\", represents the location GRTK is positioning.","title":"Installation"},{"location":"FAQ/#extra-settings","text":"How can I set a special NMEA output not only default settings? A: You can config GRTK by serial port, please follow GRTK User Manual .","title":"Extra Settings"},{"location":"FAQ/#others","text":"Can GRTK rover station work with a base station but not GRTK base which supports RTCM data? A: Of course. But you should have a special config for your base station to adapt to our rover station. We strongly suggest that use a GRTK kit for RTK positioning, and we can't make sure the rover station's performance. Can serval rover stations work with only one base station? A: Yes, you can have a point to multipoint RLINK kit to make GRTKs work.","title":"Others"},{"location":"GRTK_User_Manual/","text":"GRTK User Manual Statement: The user using the GRTK centimeter-level positioning module is deemed to have automatically accepted this statement. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback. Part 1 System Introduction 1.1 Introduction GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation system 1.2 Parameters Performance Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a1cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.2 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~2.5W Compass inside support Physical size Figure 1.2 Schematic diagram of physical size Part 2 Usage 2.1 Interfaces The GRTK module can be used as a base station or as a mobile station. There are three interfaces in total, as shown in Figure 2.1. They are the Power port for powering the device, the com1 port(UART1) for communication between the Rover and the Base, and the com2 port for communicating with the flight controller to transmit positioning information and heading from internal compass. The com2 port includes UART2 and I2C, and UART2 for NMEA data, I2C for internal compass as default. Figure 2.1 GRTK module interfaces diagram In addition, there are four LED indicators on the front of the module. The three on the left display the module's operating status, which are 3D Fix positioning status, operating error, and RTK positioning status; a single indicator on the right is used to display the power supply status. The GRTK module supports dual-antenna heading, and the antenna named ANT1 is the master antenna, the antenna named ANT2 is the slave antenna, and the single antenna needs to be connected to the master antenna. 2.2 Hardware connection Base station connection Figure 2.2 Base station connection diagram Figure 2.3 Schematic diagram of base station tripod installation Rover connection Figure 2.4 Rover connection diagram Dual-antenna rover connection Figure 2.5 Dual antenna rover connection diagram When the base station is not used, only the rover can be used as a conventional positioning device for positioning. The connection is shown in Figure 2.3. The base station and the rover can be used together to form an RTK centimeter-level positioning system, and the base station supports plug and play. The dual-antenna direction finding of the rover needs to keep the master-slave antenna consistent with the heading in accordance with the master-back-and-forward. The distance between the master-slave antennas should be greater than 30cm to ensure the direction finding accuracy. Compass inside connection GRTK has a compass inside that can provide extra heading data from the I2C port. Usually, autopilot has an I2C port to read the data. The head of the compass is as Figure 2.6 shown, and should be consistent with the head of autopilot. Figure 2.6 The head of the internal compass 2.3 Indicator light & Positioning status There are 4 indicators on the GRTK module, the specific meanings are shown in the table below: Light Status Describe FIX On Enter 3D Fixed state. Off Not in 3D Fixed state. ERR On Error! The module does not work properly. Off No error has occurred and is working properly. RTK On Enter RTK Fixed state. Off Not in RTK Fixed state. PWR On The power supply is OK. Off The power supply is abnormal. When the Base is working properly, the status light changes\uff1a PWR and FIX are on\uff0cthe other lights are off. When the Rover is working properly, there are two conditions in which the status light changes: PWR and FIX are on\uff0cthe other lights are off, that means Rover has been in 3D Fixed state. PWR, FIX and RTK are on, the other lights are off, that means Rover has been in RTK Fixed state. 2.4 Positioning data description The GRTK module outputs NMEA protocol positioning data by default, connects computer with GRTK module\u2019s Tx2 and Rx2 by USB-to-TTL module, then you can use the serial assistant to read or configure the output message. GRTK Rover and Base are factory configured, non-professionals do not configure equipment please. PS: Please set the line break to CR&LF. 2.4.1 Rover with a single antenna $GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands: FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF) 2.4.2 Rover with dual antennas for heading Output messages at 5Hz by factory default: $GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF) Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands: Part 3 Guidance for Use The current version of the GRTK cm positioning system supports the output of NMEA protocol positioning data, the following guidance is based on the Ardupilot firmware(v4.2.0 or higher) using the Mission Planer ground station. 3.1 Connection for modules Have the hardware, including Pixhawk controller, GRTK, radio, battery, etc, shown in Figure 3.1 ready for connection before wiring: Figure 3.1 Hardware physical diagram Rover Base and data transmissions need to be supplied separately. 3.2 The communication mode between Rover and Base GRTK can achieve RTK positioning by communicating through independent links between the base station and the rover station or by forwarding the base station data by the ground station. Independent link a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk and the com1 port(TX1 RX1) to connect the data transmission device that communicates with the Base side. b.Connect antenna to the GRTK Base and connect the com1 port of the base side to the data transmission device that communicates with the Rover terminal. Forwarding the base station data by the ground station a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk. b.Connect the GRTK Base com1 port(TX1 RX1) to the computer through the serial port. c.Open Mission Planner , find the Optional Hardware at the Initial Setup , and select RTK/GPS Inject . d.Choose the correct com port and click Connect . e.Wait for about one minute for Base to complete the base station positioning, at this time the red in the RTCM column turns green, and the latitude and longitude information of the current base station is displayed, that is, the ground station has been realized to forward the Base positioning data 3.3 Mission Planner settings 3.3.1 RTK settings GRTK Base supports plug-and-play and does not require additional setup at the ground station. However, before actually using RTK, you need to set the parameters for flight control in MP, and the necessary parameter settings are given below, which can be referred to as follows: https://ardupilot.org/copter/docs/common-gps-for-yaw.html Configure the GPS protocol as NMEA and set the GPS data refresh rate to 5Hz. GPS_TYPE is set to 5 to configure the GPS protocol as NMEA. GPS_RATE_MS is set to 200ms , meaning the GPS data refresh rate is 5Hz. Set GRTK as the source of yaw EK3_SRC1_YAW is set to 2 to set GPS as the source of yaw. COMPASS_ENABLE is set to 0 to disable compass if needed . 3.3.2 Compass inside settings a. If you connect GRTK to autopilot by I2C correctly, you can see an extra compass when you connect the autopilot to MP. b. Set the compass as External. c. If you want to use the compass only, you need to disable the other compasses and enable the compass of GRTK. 3.4 Positioning testing Quickly deployed within 30s. Unmanned vehicle automatic route mission measurement. Part 4 Modes of Base Station GRTK Base has two modes of operation\uff0cself-optimizing base station and fixed base station. Self-optimizing base station\uff1a When it is not clear exactly where the base station will be located, Base will position itself and average itself for a certain period of time after installation as the coordinates of the base station. Fixed base station: When know the exact coordinates of the base station location will be set up, you need to enter that exact coordinate into the base station. 4.1 Self-optimizing base station Base station default operating mode is self-optimizing base station. Using USB to TTL module to connect the base station serial 2 (Rx2&Tx2) to the computer, the computer runs serial debugging assistant, open the corresponding serial port with the baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. After configuration, send the following command (PS: Commands need to end with a line break) to base station by serial to save configuration. saveconfig 4.2 Fixed base station Fixed base station mode configuration is divided into two steps, the first step is to obtain the current exact coordinates, the second step is to enter the base station's precise coordinates into the base station. Step1: Get the current exact coordinates Using the USB-to-TTL module to connect the base station serial 2 to the computer, the computer runs the serial debugging assistant, open the corresponding serial port, Baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. Note that the obtained WGS84 coordinates indicate that the base station initialization is complete when the data is stable. Step2: Enter the exact coordinates of the base station into the base station Copy the location information of the base station output Example: #BESTPOSA,COM2,0,91.0,FINE,2164,52077.000,420887,32,18;SOL_COMPUTED,FIXEDPOS,32.02245993006,118.85899391094,68.5505,2.0115,WGS84,0.0000,0.0000,0.0000,\"\",0.000,0.000,40,28,28,16,0,06,03,53\\*17b29c25 Analyze and get longitude, latitude and elevation data Please replace it with the actual measurement data 32.02245993006,118.85899391094,68.5505 The configuration command is generated based on the exact coordinates of the base station mode base 32.02245993006 118.85899391094 68.5505 Send the configuration command (note that the command needs to end with a line break) to the base station through a serial port. When the configuration is complete, the following command (note that they need to end with a line break) is sent to the base station through a serial port to save the configuration. html saveconfig - Part 5 Precautions With our GRTK Kit, the base station side supports plug-and-play. If only Rover is purchased, the use of other companies' base station end requires additional RTK base station configuration at the ground station, which does not guarantee compatibility and positioning accuracy. This product is positioning equipment, which needs to search for satellite positioning, try to test it in the open and undisturbed site. The positioning status of GRTK should be mainly decided by the ground station. Part 6 Purchase 6.1 Link for purchase AliExpress: GRTK ( BLI Store ) 6.2 List 6.3 Express delivery Appropriate logistics methods need to be adopted according to the actual situation. 6.4 Wholesale Wholesale prices vary depending on the quantity of the wholesale, please email us( blicube.sp@gmail.com ) for more details.","title":"User Manual"},{"location":"GRTK_User_Manual/#grtk-user-manual","text":"Statement: The user using the GRTK centimeter-level positioning module is deemed to have automatically accepted this statement. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback.","title":"GRTK User Manual"},{"location":"GRTK_User_Manual/#part-1-system-introduction","text":"","title":"Part 1 System Introduction"},{"location":"GRTK_User_Manual/#11-introduction","text":"GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation system","title":"1.1 Introduction"},{"location":"GRTK_User_Manual/#12-parameters","text":"Performance Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a1cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.2 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~2.5W Compass inside support Physical size Figure 1.2 Schematic diagram of physical size","title":"1.2 Parameters"},{"location":"GRTK_User_Manual/#part-2-usage","text":"","title":"Part 2 Usage"},{"location":"GRTK_User_Manual/#21-interfaces","text":"The GRTK module can be used as a base station or as a mobile station. There are three interfaces in total, as shown in Figure 2.1. They are the Power port for powering the device, the com1 port(UART1) for communication between the Rover and the Base, and the com2 port for communicating with the flight controller to transmit positioning information and heading from internal compass. The com2 port includes UART2 and I2C, and UART2 for NMEA data, I2C for internal compass as default. Figure 2.1 GRTK module interfaces diagram In addition, there are four LED indicators on the front of the module. The three on the left display the module's operating status, which are 3D Fix positioning status, operating error, and RTK positioning status; a single indicator on the right is used to display the power supply status. The GRTK module supports dual-antenna heading, and the antenna named ANT1 is the master antenna, the antenna named ANT2 is the slave antenna, and the single antenna needs to be connected to the master antenna.","title":"2.1 Interfaces"},{"location":"GRTK_User_Manual/#22-hardware-connection","text":"Base station connection Figure 2.2 Base station connection diagram Figure 2.3 Schematic diagram of base station tripod installation Rover connection Figure 2.4 Rover connection diagram Dual-antenna rover connection Figure 2.5 Dual antenna rover connection diagram When the base station is not used, only the rover can be used as a conventional positioning device for positioning. The connection is shown in Figure 2.3. The base station and the rover can be used together to form an RTK centimeter-level positioning system, and the base station supports plug and play. The dual-antenna direction finding of the rover needs to keep the master-slave antenna consistent with the heading in accordance with the master-back-and-forward. The distance between the master-slave antennas should be greater than 30cm to ensure the direction finding accuracy. Compass inside connection GRTK has a compass inside that can provide extra heading data from the I2C port. Usually, autopilot has an I2C port to read the data. The head of the compass is as Figure 2.6 shown, and should be consistent with the head of autopilot. Figure 2.6 The head of the internal compass","title":"2.2 Hardware connection"},{"location":"GRTK_User_Manual/#23-indicator-light-positioning-status","text":"There are 4 indicators on the GRTK module, the specific meanings are shown in the table below: Light Status Describe FIX On Enter 3D Fixed state. Off Not in 3D Fixed state. ERR On Error! The module does not work properly. Off No error has occurred and is working properly. RTK On Enter RTK Fixed state. Off Not in RTK Fixed state. PWR On The power supply is OK. Off The power supply is abnormal. When the Base is working properly, the status light changes\uff1a PWR and FIX are on\uff0cthe other lights are off. When the Rover is working properly, there are two conditions in which the status light changes: PWR and FIX are on\uff0cthe other lights are off, that means Rover has been in 3D Fixed state. PWR, FIX and RTK are on, the other lights are off, that means Rover has been in RTK Fixed state.","title":"2.3 Indicator light & Positioning status"},{"location":"GRTK_User_Manual/#24-positioning-data-description","text":"The GRTK module outputs NMEA protocol positioning data by default, connects computer with GRTK module\u2019s Tx2 and Rx2 by USB-to-TTL module, then you can use the serial assistant to read or configure the output message. GRTK Rover and Base are factory configured, non-professionals do not configure equipment please. PS: Please set the line break to CR&LF.","title":"2.4 Positioning data description"},{"location":"GRTK_User_Manual/#241-rover-with-a-single-antenna","text":"$GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands: FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF)","title":"2.4.1 Rover with a single antenna"},{"location":"GRTK_User_Manual/#242-rover-with-dual-antennas-for-heading","text":"Output messages at 5Hz by factory default: $GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF) Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands:","title":"2.4.2 Rover with dual antennas for heading"},{"location":"GRTK_User_Manual/#part-3-guidance-for-use","text":"The current version of the GRTK cm positioning system supports the output of NMEA protocol positioning data, the following guidance is based on the Ardupilot firmware(v4.2.0 or higher) using the Mission Planer ground station.","title":"Part 3 Guidance for Use"},{"location":"GRTK_User_Manual/#31-connection-for-modules","text":"Have the hardware, including Pixhawk controller, GRTK, radio, battery, etc, shown in Figure 3.1 ready for connection before wiring: Figure 3.1 Hardware physical diagram Rover Base and data transmissions need to be supplied separately.","title":"3.1 Connection for modules"},{"location":"GRTK_User_Manual/#32-the-communication-mode-between-rover-and-base","text":"GRTK can achieve RTK positioning by communicating through independent links between the base station and the rover station or by forwarding the base station data by the ground station. Independent link a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk and the com1 port(TX1 RX1) to connect the data transmission device that communicates with the Base side. b.Connect antenna to the GRTK Base and connect the com1 port of the base side to the data transmission device that communicates with the Rover terminal. Forwarding the base station data by the ground station a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk. b.Connect the GRTK Base com1 port(TX1 RX1) to the computer through the serial port. c.Open Mission Planner , find the Optional Hardware at the Initial Setup , and select RTK/GPS Inject . d.Choose the correct com port and click Connect . e.Wait for about one minute for Base to complete the base station positioning, at this time the red in the RTCM column turns green, and the latitude and longitude information of the current base station is displayed, that is, the ground station has been realized to forward the Base positioning data","title":"3.2 The communication mode between Rover and Base"},{"location":"GRTK_User_Manual/#33-mission-planner-settings","text":"","title":"3.3 Mission Planner settings"},{"location":"GRTK_User_Manual/#331-rtk-settings","text":"GRTK Base supports plug-and-play and does not require additional setup at the ground station. However, before actually using RTK, you need to set the parameters for flight control in MP, and the necessary parameter settings are given below, which can be referred to as follows: https://ardupilot.org/copter/docs/common-gps-for-yaw.html Configure the GPS protocol as NMEA and set the GPS data refresh rate to 5Hz. GPS_TYPE is set to 5 to configure the GPS protocol as NMEA. GPS_RATE_MS is set to 200ms , meaning the GPS data refresh rate is 5Hz. Set GRTK as the source of yaw EK3_SRC1_YAW is set to 2 to set GPS as the source of yaw. COMPASS_ENABLE is set to 0 to disable compass if needed .","title":"3.3.1 RTK settings"},{"location":"GRTK_User_Manual/#332-compass-inside-settings","text":"a. If you connect GRTK to autopilot by I2C correctly, you can see an extra compass when you connect the autopilot to MP. b. Set the compass as External. c. If you want to use the compass only, you need to disable the other compasses and enable the compass of GRTK.","title":"3.3.2 Compass inside settings"},{"location":"GRTK_User_Manual/#34-positioning-testing","text":"Quickly deployed within 30s. Unmanned vehicle automatic route mission measurement.","title":"3.4 Positioning testing"},{"location":"GRTK_User_Manual/#part-4-modes-of-base-station","text":"GRTK Base has two modes of operation\uff0cself-optimizing base station and fixed base station. Self-optimizing base station\uff1a When it is not clear exactly where the base station will be located, Base will position itself and average itself for a certain period of time after installation as the coordinates of the base station. Fixed base station: When know the exact coordinates of the base station location will be set up, you need to enter that exact coordinate into the base station.","title":"Part 4 Modes of Base Station"},{"location":"GRTK_User_Manual/#41-self-optimizing-base-station","text":"Base station default operating mode is self-optimizing base station. Using USB to TTL module to connect the base station serial 2 (Rx2&Tx2) to the computer, the computer runs serial debugging assistant, open the corresponding serial port with the baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. After configuration, send the following command (PS: Commands need to end with a line break) to base station by serial to save configuration. saveconfig","title":"4.1 Self-optimizing base station"},{"location":"GRTK_User_Manual/#42-fixed-base-station","text":"Fixed base station mode configuration is divided into two steps, the first step is to obtain the current exact coordinates, the second step is to enter the base station's precise coordinates into the base station. Step1: Get the current exact coordinates Using the USB-to-TTL module to connect the base station serial 2 to the computer, the computer runs the serial debugging assistant, open the corresponding serial port, Baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. Note that the obtained WGS84 coordinates indicate that the base station initialization is complete when the data is stable. Step2: Enter the exact coordinates of the base station into the base station Copy the location information of the base station output Example: #BESTPOSA,COM2,0,91.0,FINE,2164,52077.000,420887,32,18;SOL_COMPUTED,FIXEDPOS,32.02245993006,118.85899391094,68.5505,2.0115,WGS84,0.0000,0.0000,0.0000,\"\",0.000,0.000,40,28,28,16,0,06,03,53\\*17b29c25 Analyze and get longitude, latitude and elevation data Please replace it with the actual measurement data 32.02245993006,118.85899391094,68.5505 The configuration command is generated based on the exact coordinates of the base station mode base 32.02245993006 118.85899391094 68.5505 Send the configuration command (note that the command needs to end with a line break) to the base station through a serial port. When the configuration is complete, the following command (note that they need to end with a line break) is sent to the base station through a serial port to save the configuration. html saveconfig -","title":"4.2 Fixed base station"},{"location":"GRTK_User_Manual/#part-5-precautions","text":"With our GRTK Kit, the base station side supports plug-and-play. If only Rover is purchased, the use of other companies' base station end requires additional RTK base station configuration at the ground station, which does not guarantee compatibility and positioning accuracy. This product is positioning equipment, which needs to search for satellite positioning, try to test it in the open and undisturbed site. The positioning status of GRTK should be mainly decided by the ground station.","title":"Part 5 Precautions"},{"location":"GRTK_User_Manual/#part-6-purchase","text":"","title":"Part 6 Purchase"},{"location":"GRTK_User_Manual/#61-link-for-purchase","text":"AliExpress: GRTK ( BLI Store )","title":"6.1 Link for purchase"},{"location":"GRTK_User_Manual/#62-list","text":"","title":"6.2 List"},{"location":"GRTK_User_Manual/#63-express-delivery","text":"Appropriate logistics methods need to be adopted according to the actual situation.","title":"6.3 Express delivery"},{"location":"GRTK_User_Manual/#64-wholesale","text":"Wholesale prices vary depending on the quantity of the wholesale, please email us( blicube.sp@gmail.com ) for more details.","title":"6.4 Wholesale"}]} \ No newline at end of file +{"config":{"indexing":"full","lang":["en"],"min_search_length":3,"prebuild_index":false,"separator":"[\\s\\-]+"},"docs":[{"location":"","text":"GRTK Introduction GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning, and heading with compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback. Performance Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a1cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.2 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~2.5W Compass inside Support Physical size Test Video Unmanned vehicle automatic route mission measurement.","title":"GRTK Overview"},{"location":"#grtk-introduction","text":"GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design, supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning, and heading with compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback.","title":"GRTK Introduction"},{"location":"#performance","text":"Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a1cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.2 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~2.5W Compass inside Support","title":"Performance"},{"location":"#physical-size","text":"","title":"Physical size"},{"location":"#test-video","text":"Unmanned vehicle automatic route mission measurement.","title":"Test Video"},{"location":"FAQ/","text":"FAQ Installation Can I use the GRTK without any settings when I get it? A: Of course! GRTK are all set and tested before we send it to you. I bought a GRTK kit, but how can I identify which one is base and which one is rover? A: We will label different devices respectively. The rover station has 2 antennas, where does GRTK positioning data mean? A: The master antenna, aka \"ANT1\", represents the location GRTK is positioning. Extra Settings How can I set a special NMEA output not only default settings? A: You can config GRTK by serial port, please follow GRTK User Manual . Others Can GRTK rover station work with a base station but not GRTK base which supports RTCM data? A: Of course. But you should have a special config for your base station to adapt to our rover station. We strongly suggest that use a GRTK kit for RTK positioning, and we can't make sure the rover station's performance. Can serval rover stations work with only one base station? A: Yes, you can have a point to multipoint RLINK kit to make GRTKs work.","title":"FAQ"},{"location":"FAQ/#faq","text":"","title":"FAQ"},{"location":"FAQ/#installation","text":"Can I use the GRTK without any settings when I get it? A: Of course! GRTK are all set and tested before we send it to you. I bought a GRTK kit, but how can I identify which one is base and which one is rover? A: We will label different devices respectively. The rover station has 2 antennas, where does GRTK positioning data mean? A: The master antenna, aka \"ANT1\", represents the location GRTK is positioning.","title":"Installation"},{"location":"FAQ/#extra-settings","text":"How can I set a special NMEA output not only default settings? A: You can config GRTK by serial port, please follow GRTK User Manual .","title":"Extra Settings"},{"location":"FAQ/#others","text":"Can GRTK rover station work with a base station but not GRTK base which supports RTCM data? A: Of course. But you should have a special config for your base station to adapt to our rover station. We strongly suggest that use a GRTK kit for RTK positioning, and we can't make sure the rover station's performance. Can serval rover stations work with only one base station? A: Yes, you can have a point to multipoint RLINK kit to make GRTKs work.","title":"Others"},{"location":"GRTK_User_Manual/","text":"GRTK User Manual Statement: The user using the GRTK centimeter-level positioning module is deemed to have automatically accepted this statement. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback. Part 1 System Introduction 1.1 Introduction GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design (UM982 Inside), supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation system 1.2 Parameters Performance Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a0.8cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.1 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~1W Compass inside IST8310 Physical size Figure 1.2 Schematic diagram of physical size Part 2 Usage 2.1 Interfaces The GRTK module can be used as a base station or as a mobile station. There are three interfaces in total, as shown in Figure 2.1. They are the Power port for powering the device, the com1 port(UART1) for communication between the Rover and the Base, and the com2 port for communicating with the flight controller to transmit positioning information and heading from internal compass. The com2 port includes UART2 and I2C, and UART2 for NMEA data, I2C for internal compass as default. Figure 2.1 GRTK module interfaces diagram In addition, there are four LED indicators on the front of the module. The three on the left display the module's operating status, which are 3D Fix positioning status, operating error, and RTK positioning status; a single indicator on the right is used to display the power supply status. The GRTK module supports dual-antenna heading, and the antenna named ANT1 is the master antenna, the antenna named ANT2 is the slave antenna, and the single antenna needs to be connected to the master antenna. 2.2 Hardware connection Base station connection Figure 2.2 Base station connection diagram Figure 2.3 Schematic diagram of base station tripod installation Rover connection Figure 2.4 Rover connection diagram Dual-antenna rover connection Figure 2.5 Dual antenna rover connection diagram When the base station is not used, only the rover can be used as a conventional positioning device for positioning. The connection is shown in Figure 2.3. The base station and the rover can be used together to form an RTK centimeter-level positioning system, and the base station supports plug and play. The dual-antenna direction finding of the rover needs to keep the master-slave antenna consistent with the heading in accordance with the master-back-and-forward. The distance between the master-slave antennas should be greater than 30cm to ensure the direction finding accuracy. Compass inside connection GRTK has a compass inside that can provide extra heading data from the I2C port. Usually, autopilot has an I2C port to read the data. The head of the compass is as Figure 2.6 shown, and should be consistent with the head of autopilot. Figure 2.6 The head of the internal compass 2.3 Indicator light & Positioning status There are 4 indicators on the GRTK module, the specific meanings are shown in the table below: Light Status Describe FIX On Enter 3D Fixed state. Off Not in 3D Fixed state. ERR On Error! The module does not work properly. Off No error has occurred and is working properly. RTK On Enter RTK Fixed state. Off Not in RTK Fixed state. PWR On The power supply is OK. Off The power supply is abnormal. When the Base is working properly, the status light changes\uff1a PWR and FIX are on\uff0cthe other lights are off. When the Rover is working properly, there are two conditions in which the status light changes: PWR and FIX are on\uff0cthe other lights are off, that means Rover has been in 3D Fixed state. PWR, FIX and RTK are on, the other lights are off, that means Rover has been in RTK Fixed state. 2.4 Positioning data description The GRTK module outputs NMEA protocol positioning data by default, connects computer with GRTK module\u2019s Tx2 and Rx2 by USB-to-TTL module, then you can use the serial assistant to read or configure the output message. GRTK Rover and Base are factory configured, non-professionals do not configure equipment please. PS: Please set the line break to CR&LF. 2.4.1 Rover with a single antenna $GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands: FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF) 2.4.2 Rover with dual antennas for heading Output messages at 5Hz by factory default: $GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF) Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands: Part 3 Guidance for Use The current version of the GRTK cm positioning system supports the output of NMEA protocol positioning data, the following guidance is based on the Ardupilot firmware(v4.2.0 or higher) using the Mission Planer ground station. 3.1 Connection for modules Have the hardware, including Pixhawk controller, GRTK, radio, battery, etc, shown in Figure 3.1 ready for connection before wiring: Figure 3.1 Hardware physical diagram Rover Base and data transmissions need to be supplied separately. 3.2 The communication mode between Rover and Base GRTK can achieve RTK positioning by communicating through independent links between the base station and the rover station or by forwarding the base station data by the ground station. Independent link a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk and the com1 port(TX1 RX1) to connect the data transmission device that communicates with the Base side. b.Connect antenna to the GRTK Base and connect the com1 port of the base side to the data transmission device that communicates with the Rover terminal. Forwarding the base station data by the ground station a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk. b.Connect the GRTK Base com1 port(TX1 RX1) to the computer through the serial port. c.Open Mission Planner , find the Optional Hardware at the Initial Setup , and select RTK/GPS Inject . d.Choose the correct com port and click Connect . e.Wait for about one minute for Base to complete the base station positioning, at this time the red in the RTCM column turns green, and the latitude and longitude information of the current base station is displayed, that is, the ground station has been realized to forward the Base positioning data 3.3 Mission Planner settings 3.3.1 RTK settings GRTK Base supports plug-and-play and does not require additional setup at the ground station. However, before actually using RTK, you need to set the parameters for flight control in MP, and the necessary parameter settings are given below, which can be referred to as follows: https://ardupilot.org/copter/docs/common-gps-for-yaw.html Configure the GPS protocol as NMEA and set the GPS data refresh rate to 5Hz. GPS_TYPE is set to 5 to configure the GPS protocol as NMEA. GPS_RATE_MS is set to 200ms , meaning the GPS data refresh rate is 5Hz. Set GRTK as the source of yaw EK3_SRC1_YAW is set to 2 to set GPS as the source of yaw. COMPASS_ENABLE is set to 0 to disable compass if needed . 3.3.2 Compass inside settings a. If you connect GRTK to autopilot by I2C correctly, you can see an extra compass when you connect the autopilot to MP. b. Set the compass as External. c. If you want to use the compass only, you need to disable the other compasses and enable the compass of GRTK. 3.4 Positioning testing Quickly deployed within 30s. Unmanned vehicle automatic route mission measurement. Part 4 Modes of Base Station GRTK Base has two modes of operation\uff0cself-optimizing base station and fixed base station. Self-optimizing base station\uff1a When it is not clear exactly where the base station will be located, Base will position itself and average itself for a certain period of time after installation as the coordinates of the base station. Fixed base station: When know the exact coordinates of the base station location will be set up, you need to enter that exact coordinate into the base station. 4.1 Self-optimizing base station Base station default operating mode is self-optimizing base station. Using USB to TTL module to connect the base station serial 2 (Rx2&Tx2) to the computer, the computer runs serial debugging assistant, open the corresponding serial port with the baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. After configuration, send the following command (PS: Commands need to end with a line break) to base station by serial to save configuration. saveconfig 4.2 Fixed base station Fixed base station mode configuration is divided into two steps, the first step is to obtain the current exact coordinates, the second step is to enter the base station's precise coordinates into the base station. Step1: Get the current exact coordinates Using the USB-to-TTL module to connect the base station serial 2 to the computer, the computer runs the serial debugging assistant, open the corresponding serial port, Baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. Note that the obtained WGS84 coordinates indicate that the base station initialization is complete when the data is stable. Step2: Enter the exact coordinates of the base station into the base station Copy the location information of the base station output Example: #BESTPOSA,COM2,0,91.0,FINE,2164,52077.000,420887,32,18;SOL_COMPUTED,FIXEDPOS,32.02245993006,118.85899391094,68.5505,2.0115,WGS84,0.0000,0.0000,0.0000,\"\",0.000,0.000,40,28,28,16,0,06,03,53\\*17b29c25 Analyze and get longitude, latitude and elevation data Please replace it with the actual measurement data 32.02245993006,118.85899391094,68.5505 The configuration command is generated based on the exact coordinates of the base station mode base 32.02245993006 118.85899391094 68.5505 Send the configuration command (note that the command needs to end with a line break) to the base station through a serial port. When the configuration is complete, the following command (note that they need to end with a line break) is sent to the base station through a serial port to save the configuration. html saveconfig - Part 5 Precautions With our GRTK Kit, the base station side supports plug-and-play. If only Rover is purchased, the use of other companies' base station end requires additional RTK base station configuration at the ground station, which does not guarantee compatibility and positioning accuracy. This product is positioning equipment, which needs to search for satellite positioning, try to test it in the open and undisturbed site. The positioning status of GRTK should be mainly decided by the ground station. Part 6 Purchase 6.1 Link for purchase AliExpress: GRTK ( BLI Store ) 6.2 List 6.3 Express delivery Appropriate logistics methods need to be adopted according to the actual situation. 6.4 Wholesale Wholesale prices vary depending on the quantity of the wholesale, please email us( blicube.sp@gmail.com ) for more details.","title":"User Manual"},{"location":"GRTK_User_Manual/#grtk-user-manual","text":"Statement: The user using the GRTK centimeter-level positioning module is deemed to have automatically accepted this statement. Please read this manual carefully before using the GRTK centimeter-level positioning module. If you have any questions you don't understand, please contact our technical support email info@blicube.com . If you are interested with GRTK, welcome to join GRTK Discord Community to give us feedback.","title":"GRTK User Manual"},{"location":"GRTK_User_Manual/#part-1-system-introduction","text":"","title":"Part 1 System Introduction"},{"location":"GRTK_User_Manual/#11-introduction","text":"GRTK is a dual-antenna high-precision differential positioning and directional module (Real Time Kinematics) independently developed by Blicube . A complete RTK system can be formed through two GRTK modules (one mobile terminal and one base station terminal). The module is based on a new generation of high-performance GNSS SoC chip design (UM982 Inside), supports multi-system multi-frequency RTK positioning, dual-antenna high-precision orientation, GPS, GLONASS, Beidou, Galileo & QZSS navigation and positioning and heading with a compass inside. It is mainly for high-precision positioning and orientation requirements such as drones, robots and intelligent driving. Figure 1.1 Physical image of GRTK centimeter-level positioning and orientation system","title":"1.1 Introduction"},{"location":"GRTK_User_Manual/#12-parameters","text":"Performance Item Frequencies BDS B1I/B2I1 GPS L1/L2 GLONASS L1/L2 Galileo E1/E5b QZSS L1/L2 Single Point Positioning (RMS) Horizontal\uff1a1.5m Vertical\uff1a2.5m DGPS (RMS) Horizontal\uff1a0.4m Vertical\uff1a0.8m RTK (RMS) Horizontal\uff1a0.8cm+1ppm Vertical\uff1a1.5cm+1ppm Heading Accuracy (RMS) 0.1 degree/1 m baseline Velocity Accuracy (RMS) 0.03 m/s Time Accuracy (RMS) 20 ns Time to First Fix (TTFF) Cold start < 25 s Initialization Time < 5s (typical) Reacquisition < 1 s Correction RTCM v2.3/3.0/3.2 Data Output NMEA-0183 Update Rate 20 Hz Inertial Navigation Accuracy < 5% of distance travelled during GPS denied conditions Working Temperature -20\u2103 to +85\u2103 Power Supply 5v to 35v Power Dissipation ~1W Compass inside IST8310 Physical size Figure 1.2 Schematic diagram of physical size","title":"1.2 Parameters"},{"location":"GRTK_User_Manual/#part-2-usage","text":"","title":"Part 2 Usage"},{"location":"GRTK_User_Manual/#21-interfaces","text":"The GRTK module can be used as a base station or as a mobile station. There are three interfaces in total, as shown in Figure 2.1. They are the Power port for powering the device, the com1 port(UART1) for communication between the Rover and the Base, and the com2 port for communicating with the flight controller to transmit positioning information and heading from internal compass. The com2 port includes UART2 and I2C, and UART2 for NMEA data, I2C for internal compass as default. Figure 2.1 GRTK module interfaces diagram In addition, there are four LED indicators on the front of the module. The three on the left display the module's operating status, which are 3D Fix positioning status, operating error, and RTK positioning status; a single indicator on the right is used to display the power supply status. The GRTK module supports dual-antenna heading, and the antenna named ANT1 is the master antenna, the antenna named ANT2 is the slave antenna, and the single antenna needs to be connected to the master antenna.","title":"2.1 Interfaces"},{"location":"GRTK_User_Manual/#22-hardware-connection","text":"Base station connection Figure 2.2 Base station connection diagram Figure 2.3 Schematic diagram of base station tripod installation Rover connection Figure 2.4 Rover connection diagram Dual-antenna rover connection Figure 2.5 Dual antenna rover connection diagram When the base station is not used, only the rover can be used as a conventional positioning device for positioning. The connection is shown in Figure 2.3. The base station and the rover can be used together to form an RTK centimeter-level positioning system, and the base station supports plug and play. The dual-antenna direction finding of the rover needs to keep the master-slave antenna consistent with the heading in accordance with the master-back-and-forward. The distance between the master-slave antennas should be greater than 30cm to ensure the direction finding accuracy. Compass inside connection GRTK has a compass inside that can provide extra heading data from the I2C port. Usually, autopilot has an I2C port to read the data. The head of the compass is as Figure 2.6 shown, and should be consistent with the head of autopilot. Figure 2.6 The head of the internal compass","title":"2.2 Hardware connection"},{"location":"GRTK_User_Manual/#23-indicator-light-positioning-status","text":"There are 4 indicators on the GRTK module, the specific meanings are shown in the table below: Light Status Describe FIX On Enter 3D Fixed state. Off Not in 3D Fixed state. ERR On Error! The module does not work properly. Off No error has occurred and is working properly. RTK On Enter RTK Fixed state. Off Not in RTK Fixed state. PWR On The power supply is OK. Off The power supply is abnormal. When the Base is working properly, the status light changes\uff1a PWR and FIX are on\uff0cthe other lights are off. When the Rover is working properly, there are two conditions in which the status light changes: PWR and FIX are on\uff0cthe other lights are off, that means Rover has been in 3D Fixed state. PWR, FIX and RTK are on, the other lights are off, that means Rover has been in RTK Fixed state.","title":"2.3 Indicator light & Positioning status"},{"location":"GRTK_User_Manual/#24-positioning-data-description","text":"The GRTK module outputs NMEA protocol positioning data by default, connects computer with GRTK module\u2019s Tx2 and Rx2 by USB-to-TTL module, then you can use the serial assistant to read or configure the output message. GRTK Rover and Base are factory configured, non-professionals do not configure equipment please. PS: Please set the line break to CR&LF.","title":"2.4 Positioning data description"},{"location":"GRTK_User_Manual/#241-rover-with-a-single-antenna","text":"$GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands: FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF)","title":"2.4.1 Rover with a single antenna"},{"location":"GRTK_User_Manual/#242-rover-with-dual-antennas-for-heading","text":"Output messages at 5Hz by factory default: $GPGGA: Global positioning system fix data $GPRMC: Recommended minimum data $GPHDT: Output current heading information $KSXT: Time, positioning and heading of GNSS receiver Other messages If needed, you can send ASCII syntax by serial port to configurate it\uff1a FRESET GPGGA COM2 0.2 GPRMC COM2 0.2 GPHDT COM2 0.2 KSXT COM2 0.2 SAVECONFIG (CR & LF) Configuration Format: GPXXX COMX XX\uff08message + output port + output rate\uff09 SAVECONFIG\uff08Save configuration\uff09 Reset If output message is inconsistent with the factory during use, the output can be reset by following commands:","title":"2.4.2 Rover with dual antennas for heading"},{"location":"GRTK_User_Manual/#part-3-guidance-for-use","text":"The current version of the GRTK cm positioning system supports the output of NMEA protocol positioning data, the following guidance is based on the Ardupilot firmware(v4.2.0 or higher) using the Mission Planer ground station.","title":"Part 3 Guidance for Use"},{"location":"GRTK_User_Manual/#31-connection-for-modules","text":"Have the hardware, including Pixhawk controller, GRTK, radio, battery, etc, shown in Figure 3.1 ready for connection before wiring: Figure 3.1 Hardware physical diagram Rover Base and data transmissions need to be supplied separately.","title":"3.1 Connection for modules"},{"location":"GRTK_User_Manual/#32-the-communication-mode-between-rover-and-base","text":"GRTK can achieve RTK positioning by communicating through independent links between the base station and the rover station or by forwarding the base station data by the ground station. Independent link a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk and the com1 port(TX1 RX1) to connect the data transmission device that communicates with the Base side. b.Connect antenna to the GRTK Base and connect the com1 port of the base side to the data transmission device that communicates with the Rover terminal. Forwarding the base station data by the ground station a.Please connect the COM2 port(TX2 RX2) of the GRTK Rover to the GPS port of Pixhawk. b.Connect the GRTK Base com1 port(TX1 RX1) to the computer through the serial port. c.Open Mission Planner , find the Optional Hardware at the Initial Setup , and select RTK/GPS Inject . d.Choose the correct com port and click Connect . e.Wait for about one minute for Base to complete the base station positioning, at this time the red in the RTCM column turns green, and the latitude and longitude information of the current base station is displayed, that is, the ground station has been realized to forward the Base positioning data","title":"3.2 The communication mode between Rover and Base"},{"location":"GRTK_User_Manual/#33-mission-planner-settings","text":"","title":"3.3 Mission Planner settings"},{"location":"GRTK_User_Manual/#331-rtk-settings","text":"GRTK Base supports plug-and-play and does not require additional setup at the ground station. However, before actually using RTK, you need to set the parameters for flight control in MP, and the necessary parameter settings are given below, which can be referred to as follows: https://ardupilot.org/copter/docs/common-gps-for-yaw.html Configure the GPS protocol as NMEA and set the GPS data refresh rate to 5Hz. GPS_TYPE is set to 5 to configure the GPS protocol as NMEA. GPS_RATE_MS is set to 200ms , meaning the GPS data refresh rate is 5Hz. Set GRTK as the source of yaw EK3_SRC1_YAW is set to 2 to set GPS as the source of yaw. COMPASS_ENABLE is set to 0 to disable compass if needed .","title":"3.3.1 RTK settings"},{"location":"GRTK_User_Manual/#332-compass-inside-settings","text":"a. If you connect GRTK to autopilot by I2C correctly, you can see an extra compass when you connect the autopilot to MP. b. Set the compass as External. c. If you want to use the compass only, you need to disable the other compasses and enable the compass of GRTK.","title":"3.3.2 Compass inside settings"},{"location":"GRTK_User_Manual/#34-positioning-testing","text":"Quickly deployed within 30s. Unmanned vehicle automatic route mission measurement.","title":"3.4 Positioning testing"},{"location":"GRTK_User_Manual/#part-4-modes-of-base-station","text":"GRTK Base has two modes of operation\uff0cself-optimizing base station and fixed base station. Self-optimizing base station\uff1a When it is not clear exactly where the base station will be located, Base will position itself and average itself for a certain period of time after installation as the coordinates of the base station. Fixed base station: When know the exact coordinates of the base station location will be set up, you need to enter that exact coordinate into the base station.","title":"Part 4 Modes of Base Station"},{"location":"GRTK_User_Manual/#41-self-optimizing-base-station","text":"Base station default operating mode is self-optimizing base station. Using USB to TTL module to connect the base station serial 2 (Rx2&Tx2) to the computer, the computer runs serial debugging assistant, open the corresponding serial port with the baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. After configuration, send the following command (PS: Commands need to end with a line break) to base station by serial to save configuration. saveconfig","title":"4.1 Self-optimizing base station"},{"location":"GRTK_User_Manual/#42-fixed-base-station","text":"Fixed base station mode configuration is divided into two steps, the first step is to obtain the current exact coordinates, the second step is to enter the base station's precise coordinates into the base station. Step1: Get the current exact coordinates Using the USB-to-TTL module to connect the base station serial 2 to the computer, the computer runs the serial debugging assistant, open the corresponding serial port, Baud rate of 115200. The base station returns the current location information. Send the following command (PS: Commands need to end with a line break) to base station by serial to complete configuration. mode base time 60 1.5 2.5 Within 60-second automatic positioning of the base station, or when the standard deviation of horizontal positioning is no more than 1.5 m and that of vertical positioning is no more than 2.5 m, set the average value of horizontal and vertical positioning results as the base station coordinates. Restarting the base station triggers a new calculation and reposition of the datum coordinates. Users can modify parameters according to their needs. Note that the obtained WGS84 coordinates indicate that the base station initialization is complete when the data is stable. Step2: Enter the exact coordinates of the base station into the base station Copy the location information of the base station output Example: #BESTPOSA,COM2,0,91.0,FINE,2164,52077.000,420887,32,18;SOL_COMPUTED,FIXEDPOS,32.02245993006,118.85899391094,68.5505,2.0115,WGS84,0.0000,0.0000,0.0000,\"\",0.000,0.000,40,28,28,16,0,06,03,53\\*17b29c25 Analyze and get longitude, latitude and elevation data Please replace it with the actual measurement data 32.02245993006,118.85899391094,68.5505 The configuration command is generated based on the exact coordinates of the base station mode base 32.02245993006 118.85899391094 68.5505 Send the configuration command (note that the command needs to end with a line break) to the base station through a serial port. When the configuration is complete, the following command (note that they need to end with a line break) is sent to the base station through a serial port to save the configuration. html saveconfig -","title":"4.2 Fixed base station"},{"location":"GRTK_User_Manual/#part-5-precautions","text":"With our GRTK Kit, the base station side supports plug-and-play. If only Rover is purchased, the use of other companies' base station end requires additional RTK base station configuration at the ground station, which does not guarantee compatibility and positioning accuracy. This product is positioning equipment, which needs to search for satellite positioning, try to test it in the open and undisturbed site. The positioning status of GRTK should be mainly decided by the ground station.","title":"Part 5 Precautions"},{"location":"GRTK_User_Manual/#part-6-purchase","text":"","title":"Part 6 Purchase"},{"location":"GRTK_User_Manual/#61-link-for-purchase","text":"AliExpress: GRTK ( BLI Store )","title":"6.1 Link for purchase"},{"location":"GRTK_User_Manual/#62-list","text":"","title":"6.2 List"},{"location":"GRTK_User_Manual/#63-express-delivery","text":"Appropriate logistics methods need to be adopted according to the actual situation.","title":"6.3 Express delivery"},{"location":"GRTK_User_Manual/#64-wholesale","text":"Wholesale prices vary depending on the quantity of the wholesale, please email us( blicube.sp@gmail.com ) for more details.","title":"6.4 Wholesale"}]} \ No newline at end of file diff --git a/generated/en/sitemap.xml b/generated/en/sitemap.xml index 780f591..84078dc 100644 --- a/generated/en/sitemap.xml +++ b/generated/en/sitemap.xml @@ -2,17 +2,17 @@ None - 2023-07-11 + 2023-08-20 daily None - 2023-07-11 + 2023-08-20 daily None - 2023-07-11 + 2023-08-20 daily \ No newline at end of file diff --git a/generated/en/sitemap.xml.gz b/generated/en/sitemap.xml.gz index 97e2e13..bcfdcc3 100644 Binary files a/generated/en/sitemap.xml.gz and b/generated/en/sitemap.xml.gz differ diff --git a/generated/zh/404.html b/generated/zh/404.html index 21efeac..a5f3a93 100644 --- a/generated/zh/404.html +++ b/generated/zh/404.html @@ -302,6 +302,8 @@ + +