SparkFun

GNSS Flex pHAT with LG580P RTK Heading Module

Name: GNSS Flex pHAT with LG580P RTK Heading Module
Brand: SparkFun
SKU: SF-GPS-29890
Price: 477.3 AUD
Availability: InStock

· MPN: GPS-29890

GPS & Location Sensors Raspberry Pi Hats Raspberry Pi Sensors

$477.30 |

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Add precise position and orientation data to a Raspberry Pi with this GNSS Flex pHAT and LG580P module combination. It is built for advanced navigation proje...

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Add precise position and orientation data to a Raspberry Pi with this GNSS Flex pHAT and LG580P module combination. It is built for advanced navigation projects that need centimetre-level RTK positioning plus real-time heading data, such as intelligent robots, precision agriculture systems and autonomous vehicle prototypes.

The pHAT connects to a Raspberry Pi through the standard 40-pin GPIO header and links to the included SparkPNT GNSS Flex module using standardised 2x10-pin headers, making it easier to swap modules later. The kit includes the standoffs, screws and extended header needed for a neat, stable Raspberry Pi setup.

External GNSS antennas are required. The GNSS Flex Module provides two U.FL connectors, while the pHAT includes an SMA connector bridged to U.FL for a sturdier antenna connection when jumpered with a short U.FL cable. By default, communication uses the Raspberry Pi primary serial bus, but other interfaces are also available.

Documentation includes design files, board dimensions, STEP files, a hookup guide, QGNSS Software (v2.0), component documentation, protocol and hardware design resources, application notes and firmware upgrade information. According to Quectel, I²C support is still under development for a future firmware update, and corrections for some PPP services such as HAS E6 have not yet been implemented.

Features:

Raspberry Pi Connectivity: Standard 40-pin GPIO header for a direct, secure connection.
Mounting Hardware Included: Comes with the necessary standoffs, screws, and an extended header for a clean, stable setup.
RTK + Heading: Delivers centimeter-level position accuracy and high-precision attitude (orientation) data.
Quad-Band & Multi-Constellation: Simultaneously receives signals from the L1, L2, L5, and L6/E6 bands across GPS, GLONASS, Galileo, BDS, QZSS, and NavIC.
Advanced Anti-Jamming: Built-in algorithms detect and mitigate interference.
RTK/RTCM corrections: Broad support for standard RTK/RTCM corrections.
SBAS augmentation: Supports WAAS, EGNOS, BDSBAS, MSAS, GAGAN, KASS, ASECNA, SouthPAN, and SDCM.
PPP services: Supports BDS PPP-B2b, QZSS CLAS, MADOCA-PPP, and Galileo HAS*.
GNSS Flex pHAT: 40-pin socket for Raspberry Pi header
GNSS Flex pHAT: 40-pin header for GNSS Flex modules
GNSS Flex pHAT: Two 2x20-pin, 2mm-pitch male headers
GNSS Flex pHAT: Power
GNSS Flex pHAT: 3.3V
GNSS Flex pHAT: Backup power
GNSS Flex pHAT: USB bus detect (not a power source)
GNSS Flex pHAT: USB data
GNSS Flex pHAT: UART (x4)
GNSS Flex pHAT: SD card
GNSS Flex pHAT: I2C bus*
GNSS Flex pHAT: PPS signal (x2)
GNSS Flex pHAT: LED indicators (x2)
GNSS Flex pHAT: Event indicators (x2)
GNSS Flex pHAT: USB-C connector
GNSS Flex pHAT: Interfaces directly w/ GNSS Flex Module
GNSS Flex pHAT: Antenna bridge
GNSS Flex pHAT: U.FL connector
GNSS Flex pHAT: SMA connector
GNSS Flex pHAT: µSD card socket
GNSS Flex pHAT: Qwiic connector*
GNSS Flex pHAT: Indicator LEDs
GNSS Flex pHAT: PWR (Red)
GNSS Flex pHAT: PPS (Yellow)
GNSS Flex pHAT: RTK (White)
GNSS Flex pHAT: PVT (Blue)
GNSS Flex pHAT: Twenty-four jumpers
GNSS Flex pHAT: Raspberry Pi GPIO isolation (x16)
GNSS Flex pHAT: LED power isolation (x4)
GNSS Flex pHAT: I2C pull-up resistors (x4)*
LG580P GNSS Flex Module: Quectel LG580P quad-band, GNSS module
LG580P GNSS Flex Module: Concurrent signal reception: 5 + QZSS
LG580P GNSS Flex Module: L1, L2, L5, E6 frequency bands
GNSS Constellations: GPS (USA)
GNSS Constellations: GLONASS (Russia)
GNSS Constellations: Galileo (EU)
GNSS Constellations: BDS (China)
GNSS Constellations: QZSS (Japan)
GNSS Constellations: NavIC (India)
SBAS Systems: WAAS (USA)
SBAS Systems: SDCM (Russia)
SBAS Systems: EGNOS (EU)
SBAS Systems: BDSBAS (China)
SBAS Systems: MSAS (Japan)
SBAS Systems: GAGAN (India)
SBAS Systems: KASS (Korea)
SBAS Systems: ASECNA (Africa)
SBAS Systems: SouthPAN (Aus/NZ)
LG580P GNSS Flex Module: Two 2x20-pin, 2mm-pitch male headers
LG580P GNSS Flex Module: 40-pin socket for GNSS Flex system
LG580P GNSS Flex Module: Power
LG580P GNSS Flex Module: 3.3V
LG580P GNSS Flex Module: Backup power
LG580P GNSS Flex Module: UART (x3)
LG580P GNSS Flex Module: I2C bus*
LG580P GNSS Flex Module: PPS signal (x1)
LG580P GNSS Flex Module: LED indicators (x1)
LG580P GNSS Flex Module: Event indicators (x1)
LG580P GNSS Flex Module: Two U.FL connectors
LG580P GNSS Flex Module: GNSS antennas (Active, Multi-band)
LG580P General Features: High-precision RTK, and Heading GNSS module
Development note: *: Feature is still under development

Specifications:

Supply Voltage: 3.0–3.6V
Current Consumption - Normal Operation - Acquisition: 98mA (323.4mW) (Acquisition)
Current Consumption - Normal Operation - Tracking: 116mA (382.8mW) (Tracking)
Current Consumption - Power Saving Mode - Backup Mode: 18μA (59.4μmW) (Backup Mode)
GPS: L1 C/A, L5, L2C
GLONASS: L1, L2
Galileo: E1, E5a, E5b, E6
BDS: B1I, B1C, B2a, B2b, B2I, B3I
QZSS: L1 C/A, L5, L2C, L6
NavIC: L5
SBAS: L1
PPP: B2b
QZSS: L6
Galileo HAS: E6*
Tracking Channels: 1040
Horizontal Position Accuracy - Autonomous: 1m
Horizontal Position Accuracy - RTK: 0.8cm + 1ppm
Vertical Accuracy - Autonomous: 1.5m
Vertical Accuracy - RTK: 1.5cm + 1ppm
Heading Accuracy: 0.1°
Velocity Accuracy Without Aid: 0.03m/s
Accuracy of 1PPS Signal: 5ns
RTK Convergence Time: 5s
Time to First Fix (without AGNSS) - Cold Start: 28s
Time to First Fix (without AGNSS) - Warm Start: 28s
Time to First Fix (without AGNSS) - Hot Start: 1.8s
Sensitivity - Acquisition: -145dBm
Sensitivity - Tracking: -160dBm
Sensitivity - Reacquisition: -155dBm
Dynamic Performance - Maximum Altitude: 10000m
Dynamic Performance - Maximum Velocity: 490m/s
Dynamic Performance - Maximum Acceleration: 4g
Update Rate - Default: 10Hz
Update Rate - Max: 20Hz
Antenna Interface: External active antenna
Power Supply: External
UART: UART (x3)
Baud Rate: 9600–3000000bps
Default: 460800bps
Protocol: NMEA 0183/RTCM 3.x/QGC
SPI*: SPI* (x1)
I2C*: I2C* (x1)
CAN*: CAN* (x1)
Operating temperature: -40°C to +85°C
Footprint: 21mm × 16mm × 2.7mm
Weight: 1.4g
Default Raspberry Pi serial TX: GPIO14/Pin 8
Default Raspberry Pi serial RX: GPIO15/Pin 9

A Raspberry Pi or similar single-board computer and suitable external GNSS antennas are required for operation.

Jargon buster

Plain-language definitions for the technical terms used above.

1PPS: One Pulse Per Second is a precise timing signal often provided by a satellite positioning receiver. It matters when a project needs very accurate time alignment, such as timestamping logged data.
B1I: A BeiDou satellite signal used for standard positioning. It matters because the receiver must support the signal bands used by a constellation to take advantage of those satellites.
B2a: A BeiDou satellite signal used by newer dual-band GNSS receivers. Support for B2a can improve accuracy and reliability when combined with other GNSS bands.
baud: Baud is the signalling rate of a serial connection, often used as the speed setting for UART communication. Matching the baud rate matters because both connected devices must use the same setting for readable data.
BDS: BeiDou, China’s satellite navigation system. Support for BDS gives the receiver access to more satellites, which can help maintain a better position fix in challenging locations.
E1: A Galileo satellite signal band used for standard positioning. Knowing which signal bands are supported helps you judge compatibility and expected performance of a GNSS receiver.
E5a: A Galileo satellite signal band used for higher-performance positioning services. Support for E5a can help dual-band GNSS receivers improve accuracy and reduce errors from atmospheric delay.
EGNOS: Europe’s SBAS service for improving GNSS positioning accuracy and reliability. It is relevant if the receiver will be used in Europe or nearby supported areas without an RTK correction link.
GAGAN: India’s SBAS service for improving GNSS positioning. It matters for projects in its coverage region because it can improve standard GNSS accuracy when RTK is not being used.
Galileo: Europe’s satellite navigation system. Galileo support can improve satellite availability and accuracy, especially when combined with GPS and other constellations.
GLONASS: Russia’s satellite navigation system. A receiver that can also use GLONASS has more satellites to choose from, which can improve positioning reliability when the sky view is partly blocked.
GNSS: GNSS stands for Global Navigation Satellite System, covering positioning systems such as GPS and similar satellite networks. It matters here because high-precision GNSS modules can output lots of serial position data that this product can send wirelessly to a computer or phone.
GPIO: General-purpose input/output pins are microcontroller pins you can set in software to read signals, switch devices on and off, or connect to peripherals. The number of GPIO pins matters because it limits how many buttons, LEDs, sensors, and other parts you can wire directly to the board.
GPS: The US satellite navigation system used by GNSS receivers to calculate position and time. Support for GPS is important because it is widely available and often used together with other constellations for more reliable positioning.
Headers: Rows of metal pins used to plug a module into a breadboard or connect it with jumper wires. Pre-soldered headers make the module easier to use straight away without needing to solder the pins yourself.
I2C: I2C is a two-wire communication bus used by many sensors and small modules. It matters because several I2C devices can share the same two wires, but each device needs a compatible address and your controller must support I2C.
L2C: A second GPS signal band used by dual-band GNSS receivers to improve precision and reduce errors caused by the atmosphere. It matters for RTK and high-accuracy applications because using two bands can produce faster and more reliable centimetre-level fixes.
L5: A modern GNSS signal band used by several satellite systems for more accurate and robust positioning. Dual-band receivers that include L5 can often perform better than single-band receivers, especially for RTK and areas with reflected signals.
LED: A light-emitting diode is a small electronic component that lights up when current flows through it in the correct direction. In this kit, LEDs create the flashing effect, so polarity and correct soldering matter for the project to work.
MSAS: Japan’s SBAS service for improving GNSS positioning. It is useful to know because SBAS benefits depend on whether your project is located in the service’s coverage area.
NMEA 0183: A standard text-based data format used by GPS and GNSS receivers to send position, time and satellite information. If your microcontroller or software can read NMEA 0183, it can usually parse basic location data from this kit.
pHAT: A smaller add-on board format for Raspberry Pi, similar in idea to a HAT but usually not full-sized. It matters because pHAT compatibility can affect how neatly a board stacks or fits into a Raspberry Pi project.
PVT: Position, velocity and time data reported by a GNSS receiver. Knowing the PVT update rate helps you judge how often the board can provide basic navigation information to your project.
Qwiic: Qwiic is a plug-in connector system for I2C devices that uses small 4-pin cables, so you can connect compatible sensors without soldering. It matters because your controller or adapter also needs Qwiic, or you will need a cable or breakout to wire it up.
QZSS: Japan’s regional satellite navigation system designed to improve coverage around Japan and the Asia-Pacific region. QZSS support can improve satellite availability in supported regions when used alongside GPS.
RTCM 3.x: RTCM 3.x is a standard data format used to send GNSS correction information from a base station to a rover. It matters because both ends of an RTK setup need to understand the correction format to achieve high-accuracy positioning.
RTK: Real-Time Kinematic positioning is a GNSS technique that uses correction data from a base station to greatly improve location accuracy. It matters if you need centimetre-level positioning for robotics, mapping, surveying, or tracking rather than ordinary metre-level GPS accuracy.
SBAS: Satellite-Based Augmentation System, a set of regional services that broadcast correction information for GNSS receivers. SBAS can improve ordinary GPS-style positioning, although it is not the same as centimetre-level RTK correction.
single-board computer: A complete computer built onto one circuit board, usually including the processor, memory, ports, and connectors. This matters because accessories like heatsinks must match the board’s layout and mounting holes to fit properly.
SMA: A threaded coaxial connector commonly used for antennas. It matters because you need antennas with matching SMA connectors, or suitable adapters, for the LTE and GNSS antenna ports.
SPI: A fast serial communication bus often used for displays, memory cards, and sensors. It matters because SPI devices need specific pins for clock and data, plus a separate chip-select line for each device.
u.FL: u.FL is a tiny snap-on antenna connector often used on compact wireless boards. A board with u.FL usually needs an external antenna, which matters if the product will be inside an enclosure or needs better antenna placement.
UART: UART is a simple serial connection that sends data over separate transmit and receive wires, often labelled TX and RX. It matters because this module is designed to replace a wired UART cable with a wireless link while keeping the same serial data format.
USB-C: A modern reversible USB connector used for power and data connections. On this product it matters because it can connect directly to a computer as well as to a microcontroller project.
WAAS: A North American SBAS service that provides correction data for GNSS receivers. It matters if you are using the product in a supported region and want better non-RTK positioning accuracy.