DJI Phantom 4 RTK with Standard Controller (without screen)
- Brand: DJI
- Product Code: P4 RTK
- Availability: In Stock
- Ex Tax:£4,165.83
DJI Phantom 4 RTK
- RTK Module
- 1" CMOS Sensor
- GS RTK App
- 1cm+1ppm RTK Horizontal Positioning Accuracy
- 1.5cm+1ppm RTK Vertical Positioning Accuracy
- 5cm Absolute Horizontal Accuracy of Photogrammetric Models
How does the Phantom 4 RTK differ from previous Phantom Series products?
While previous Phantom series drones were built around professional photographers and hobbyists, the Phantom 4 RTK was designed for industrial users for high-precision mapping and other data acquisition missions. While the Phantom 4 RTK shares a similar camera and form size, it also adds a RTK positioning module, a new TimeSync system, a purpose-built mapping app and more.
What propellers does the Phantom 4 RTK use?
The Phantom 4 RTK uses the same 9450s Quick Release Propellers as the Phantom 4 Pro.
Can I fly the Phantom 4 RTK in other countries or regions?
You can fly the P4 RTK in EU countries, the version you receive from leicesterdrones will be a UK/EU version
What is the difference between the Phantom 4 RTK's camera and the camera on the Phantom 4 Advanced/Pro?
While the Phantom 4 RTK and Phantom 4 Pro/Advanced share the same 1-inch, 20 megapixel CMOS sensor, the Phantom 4 RTK has improved the capabilities of the camera for mapping through a new lens distortion recording process. Each Phantom 4 RTK camera goes through a calibration process that measures the distortions of the lens, and records the corresponding undistort parameters. The camera allows users to output the original images without distortion correction as well as the undistort parameters in the XMP file for post-processing
Can the ND filter of the Phantom 4 Pro be used on the Phantom 4 RTK?
Yes, the ND filters made for the Phantom 4 Pro can also be used for the Phantom 4 RTK.
Does the Phantom 4 RTK camera digital signal processor (DSP) support distortion correction?
No, you can enable the distortion correction in the camera but the images will be less precise compared to distortion elimination in post-processing software.
How is the Phantom 4 RTK camera calibrated?
Each Phantom 4 RTK camera goes through a calibration process that measures the distortions of the lens, and records the corresponding undistort parameters in XMP DewarpData. When the “distortion correction” is switched off, the original image with distortion will be generated. When the “distortion correction” is switched on, the parameters used to eliminate distortion is not the parameters calibrated, but the design parameters of the camera. When eliminating the distortions, it is not done pixel by pixel.
How can I switch between FCC and CE modes?
FCC and CE mode switching is not available.
Can I connect the Phantom 4 RTK to other Phantom series controllers?
What is the video transmission distance of the Phantom 4 RTK?
The effective video transmission distance depends on your method of operation (such as the antenna position) and actual flight environment. In an open and unobscured environment, the maximum distance is 7 km when FCC compliant, and 5 km when CE compliant. (2.4 GHz).
What should I do if the app sends me the following notification: "the remote controller signal is weak, please adjust the antenna"?
This means that improper antenna positioning is likely affecting the video transmission signal, and therefore the quality of the real-time view. You can try to adjust the antennas so the flat sides of the antenna point towards the Phantom 4 RTK.
Can I continue my automated mapping mission if the Phantom 4 RTK loses video transmission signal during its mission?
Yes, if the video transmission signal is lost, you can reconnect and continue the mapping mission.
Can I use my Phantom 4 Pro batteries with the Phantom 4 RTK and vice versa?
Yes, the Phantom 4 RTK and Pro batteries are cross compatible and have the same capacity, meaning flight time won't be effected.
How long does it take to fully charge a Phantom 4 RTK battery?
It takes roughly 60 minutes to fully charge a Phantom 4 RTK battery.
How should I take care and store my batteries?
Batteries should be stored in a dry, ventilated, cool environment, away from fire, high temperature and flammable materials. Do not put the battery in an environment that may cause the battery temperature to rise, such as in direct sunlight. If you are putting the drone/batteries into long term storage it is best for the batteries to be at around 50% charge. The battery should be charged and discharged to maintain the battery activity every 3 month for long-term storage.
What does it mean when the battery icon turns yellow in the app?
This means the voltage of the battery cell is low and should be charged soon. Please be cautious when flying under this situation.
Can I use Phantom 4 RTK batteries in low temperatures?
The battery capacity (and therefore flight time) will sharply decrease in low temperatures (< -10℃). It is recommended to heat the batteries to 20℃ before flying to limit this effect. For flight safety, the battery cannot be charged when the temperature is below 5℃ or above 40℃.
Why do batteries start to heat up after long-term storage?
This is a normal phenomenon. When batteries have been stored for a long time with over 65% of the charge remaining, an automatic discharging procedure is activated to decrease battery level to 65%, during which the batteries will heat up.
What options do I have to reference the positioning data from the Phantom 4 RTK?
1. Connect locally via OcuSync to your D-RTK 2 Mobile Station. (RTCM3.2)
2. Connect remotely via a 4G Dongle to a custom RTK network using a NTRIP account.(RTCM3.2)
3. Connect remotely via a WiFi hotspot to a custom RTK network using a NTRIP account. Not available in Europe.(RTCM3.0/RTCM3.1/RTCM3.2)
What positioning accuracy can the Phantom 4 RTK achieve?
The Phantom 4 RTK can achieve 1 cm+1 ppm (horizontal), 1.5 cm + 1 ppm (vertical) accurate data.
What is TimeSync and how does it ensure the positioning accuracy of each image taken on the Phantom 4 RTK?
TimeSync continually aligns the flight controller, camera and RTK module, then adjusts the positioning data to the centre of the CMOS and records the data in EXIF and XMP format.
What are the differences between PPK and RTK mode? How to use them?
RTK and PPK are two different kinematics technologies that reference data in different ways. Although PPK generally has slightly higher positioning accuracy than RTK, both achieve centimetre-level precision. RTK is recommended for users flying in environments that allow for real-time connection via OcuSync or 4G and prefer convenience and efficiency. For users who have no demand on timeliness and/or need to operate in conditions without connectivity, PPK is a better option.
Which PPK file types does the Phantom 4 RTK support? What are these files for and how do I use them?
EVENTLOG.bin is a binary format that stores exposure, time stamp and log file.
PPKRAW.bin is an RTCM3.2 MSM5 format that stores satellite observation data and ephemeris data.
Rinex.obs is a Rinex file format that is created after transcoding.
Timestamps.MRK is a ASCII format that stores exposure and time stamp.
*DJI does not provide any PPK software.
How do I find the XMP information of my Phantom 4 RTK photos?
Open the photo in text format and search "XMP" to find this information on each photo.
When I take a photo with the Phantom 4 RTK, where is the location metadata logging the position from?
Due to the new TimeSync system, each photo stores the position of the CMOS centre in its metadata.
How can I get the compensation value between the antenna phase centre and CMOS centre?
For each photo, the compensation value between the RTK module's antenna phase centre and the CMOS centre in NED coordinate system is recorded in the timestamp. MRK file under a folder named “survey”.
How do I update the Phantom 4 RTK firmware?
The Phantom 4 RTK firmware upgrade process is similar to that of the Phantom 4 Pro. Using the DJI Assistant 2 software, you can update the remote controller and aircraft firmware separately .
You can also update the drone and remote controller simultaneously through the GS RTK app. First you connect the remote controller to the aircraft with OTG and USB cables, then follow the procedures explained in the remote controller's GS RTK app.
In what situations are the left/right TOF and infrared sensors active?
Currently the left/right TOF and infrared sensors are not active, so please fly with caution.
What apps have mapping or inspection function?
Users can use the pre-installed GS RTK app for mapping or inspection missions. Additionally, users can install apps built on DJI's Mobile SDK.
Does the Phantom 4 RTK's return to home logic differ from that of the Phantom 4 Pro?
No.The RTH logics in both aircraft are almost the same.
What mapping platform is being used to provide map data to the Phantom 4 RTK app?
Mapbox is used to provide map data to the GS RTK app.
Are there any limitations to the Phantom 4 RTK's waypoints?
There is no limitation when using the GS RTK App.
Can I set waypoints by entering longitude and latitude values when using Waypoint mode?
Does the GS RTK app have 3D flight path planning functions?
When importing KML area files with the GS RTK app, what is the maximum number of boundary points that I can set?
Currently the GS RTK app supports up to 99 boundary points through KML files.
What formats of differential data does the Phantom 4 RTK support?
Currently the Phantom 4 RTK supports RTCM 3.0 data, RTCM 3.1 data, MSM4, MSM5, MSM6 and MSM7 data under RTCM3.2.
Are the coordinates measured by the Phantom 4 RTK relative coordinates or absolute coordinates?
The coordinates measured by the Phantom 4 RTK are absolute coordinates under WGS84.
How do I calculate an appropriate flight altitude based on a GSD value?
You can refer to the equation H=36*GSD to estimate an appropriate flight altitude. Please note that GSD ground sampling distance in this equation is measured by centimetres, while H (Height or flight altitude) is measured by meters. For example, GSD=2.74 cm, when altitude=100 m.
Do images captured by the Phantom 4 RTK store altitude any information? If so, how is this data stored?
Elevation and relative altitude (relative to your takeoff point) are stored in photos captured by the Phantom 4 RTK. Absolute altitude can be used for mapping, and relative altitude can be found in the XMP file.
How can I capture oblique photography when using the Phantom 4 RTK?
Oblique imagery can be captured while flying in the Photogrammetry mode on the GS RTK app. In the Photogrammetry mode, you can adjust gimbal angle from -90 °to -45° under Camera Settings for your flight plan.You can only set one gimbal angle value at a time, so for sites where you want to capture multiple angles you can plan the same mission and just adjust the camera angle.
Can I create a 3D model or point cloud with third-party software using the images captured by the Phantom 4 RTK? If yes, what is the accuracy of the model created?
Yes, you can use third-party software to process Phantom 4 RTK image data and create models, however the accuracy will vary based on the photogrammetric algorithm used. Please refer to the third-party software provider for more information on expected accuracy.
When there are no Ground Control Points (GCPs), what is the accuracy of the model that the Phantom 4 RTK data can make? Can the accuracy meet the requirements of 1:500 scale aerial triangulation?
The orthoimages created with the images captured by the Phantom 4 RTK and select reconstruction software have shown an absolute accuracy of roughly 5 cm, while the accuracy required in 1:500 scale aerial triangulation is less than 30 cm. This means the Phantom 4 RTK's accuracy meets the requirements of 1:500 scale aerial maps.
Is the Phantom 4 RTK compatible with third-party base stations?
No, you cannot connect third-party base stations to the Phantom 4 RTK or the remote controller via a radio station. However, you can obtain data from a network RTK server via Ntrip protocol in 4G/Wi-Fi network environment. Satellite observation data can also be saved in the aircraft for users to conduct post processed kinematics (PPK) to complete their tasks.
|Max Service Ceiling Above Sea Level:||6000 m|
|Operating Frequency:||2.400 GHz to 2.483 GHz (UK, Europe, Japan, Korea) 5.725 GHz to 5.850 GHz (United States, China)|
|Transmitter Power (EIRP):||2.4 GHz CE (UK, Europe) / MIC (Japan) / KCC (Korea) ：< 20 dBm 5.8 GHz SRRC（China） / FCC（United States）/NCC(Taiwan,China)：< 26 dBm|
|Max Ascent Speed:||6 m/s (automatic flight); 5 m/s (manual control)|
|Max Descent Speed:||3 m/s|
|Hover Accuracy:||RTK enabled and functioning properly： Vertical：±0.1 m；Horizontal：±0.1 m RTK disabled Vertical：±0.1 m（with vision positioning ）； ±0.5 m（with GNSS positioning） Horizontal：±0.3 m（with vision positioning）; ±1.5 m（with GNSS positioning）|
|Max Speed:||50 kph (31 mph)(P-mode) 58 kph (36 mph)(A-mode)|
|Operating Temperature:||0° to 40℃|
|Image Position Offset:||The position of the camera centre is relative to the phase centre of the onboard D-RTK antenna under the aircraft body's axis: (36, 0, and 192 mm) already applied to the image coordinates in Exif data. The positive x, y, and z axes of the aircraft body point to the forward, rightward, and downward of the aircraft, respectively.|
|Diagonal Distance:||350 mm|
|Max Flight Time:||Approx. 30 minutes|
|Max Transmitting Distance:||SRRC / CE / MIC / KCC：5 km (3.1 mi) FCC：7 km (4.3 mi)；|
|Operating Frequency:||2.400 GHz-2.483 GHz(UK, Europe, Japan, Korea) 5.725 GHz-5.850 GHz(United States, China)|
|Operating Temperature:||0° to 40℃|
|Power Consumption:||16 W (typical value)|
|Display:||5.5 inch screen, 1920×1080, 1000 cd/m², Android System Memory 4G RAM+16G ROM|
|GNSS:||Single-Frequency, High-Sensitivity GNSS Module: GPS+BeiDou+Galileo（Asia)； GPS+GLONASS+Galileo（other regions） Multi-Frequency Multi-System High-Precision RTK GNSS: Frequency Used： GPS：L1/L2； GLONASS：L1/L2； BeiDou：B1/B2； Galileo：E1/E5a First-Fixed Time：< 50 s Positioning Accuracy: Vertical 1.5 cm + 1 ppm（RMS）； Horizontal 1 cm + 1 ppm（RMS） 1 ppm means the error has a 1 mm increase for every 1 km of movement from the aircraft.|
|Transmitter Power (EIRP):||2.4 GHz CE / MIC / KCC：< 20 dBm 5.8 GHz SRRC / FCC：< 26 dBm|
|Battery Type:||LiPo 4S|
|Charging Temperature:||-10° to 40℃|
|Max Charging Power:||160 W|
|Net Weight:||468 g|
|Altitude Range:||0 - 10 m|
|Operating Environment:||Surfaces with clear patterns and adequate lighting(＞ 15 lux)|
|Operating Range:||0 - 10 m|
|Velocity Range:||≤50 kph (31 mph) at 2 m (6.6 ft) above ground with adequate lighting|
|Electronic Shutter Speed:||8 - 1/8000 s|
|Max Image Size:||4864×3648（4:3）； 5472×3648（3:2）|
|Mechanical Shutter:||8 - 1/2000 s|
|Supported File Systems:||FAT32（≤ 32 GB）； exFAT（> 32 GB）|
|Sensor:||1" CMOS; Effective pixels: 20 M|
|Lens:||FOV 84°；8.8 mm / 24 mm(35 mm format equivalent:24 mm)； f/2.8 - f/11, auto focus at 1 m - ∞|
|ISO Range:||Video:100-3200(Auto) 100-6400(Manual)； Photo:100-3200(Auto) 100-12800(Manual)|
|Video Recording Modes:||H.264，4K：3840×2160 30p|
|Supported SD Card Types:||MicroSD, Max Capacity: 128 GB. Class 10 or UHS-1 rating required Write speed≥15 MB/s|
|Operating Temperature:||0° to 40℃|
|Mapping Accuracy:||Mapping accuracy meets the requirements of the ASPRS Accuracy Standards for Digital Orthophotos Class Ⅲ|
|Ground Sample Distance(GSD):||(H/36.5) cm/pixel， H means the aircraft altitude relative to shooting scene (unit: m)|
|Data Acquisition Efficiency:||Max operating area of approx. 1 km² for a single flight (at an altitude of 182 m, i.e., GSD is approx. 5 cm/pixel, meeting the requirements of the ASPRS Accuracy Standards for Digital Orthophotos Class Ⅲ|
|Stabilization:||3-axis (tilt, roll, yaw)|
|Pitch:||-90° to +30°|
|Angular Vibration Range:||±0.02°|
|Max Controllable Speed:||90°/s|
|Charging Hub for Remote/Misc|
|Input Voltage:||17.3 - 26.2 V|
|Output Voltage and Current:||8.7 V，6 A；5 V，2 A|
|Infrared Sensing System|
|Obstacle Sensory Range:||0.2 - 7 m|
|Operating Environment:||Surface with diffuse reflection material, and reflectivity＞ 8%（such as wall, trees, humans, etc.)|
|Measuring Frequency :||10 Hz|
|FOV:||Forward/Rear: 60° (horizontal), ±27° (vertical) Downward: 70° (front and rear), 50° (left and right)|
|Measuring Frequency:||Forward/Rear：10 Hz; Downward： 20 Hz|
|Obstacle Sensory Range :||0.7 - 30 m|