Blogs

Dual-board heading uses two GNSS boards to achieve high-precision heading. By receiving positional information from two antennas, the internal algorithms and data processing of the boards calculate the device's attitude and azimuth. Dual-board heading has wide applications in high-precision positioning, navigation, autonomous driving, and surveying. So, how can we perform dual-board heading using two SinoGNSS K803 boards?

Velocity is a crucial parameter in collecting navigation information, significantly influencing navigation accuracy and performance. ComNav's products excel at capturing and tracking satellite signals, providing valuable information about velocity during movement. In this blog, we will introduce some logs related to speed as below:

ComNav proudly offers free PPP-HAS/B2B services, with its K8 series OEM boards providing significant cost savings for customers, while achieving a horizontal positioning accuracy of up to 20cm. In the two years since its launch, this technology has gained wide recognition in the market, delivering high-precision positioning solutions to clients.

GNSS, as a technology for spatial positioning based on signals from multiple satellites, has found widespread application across numerous critical fields, ranging from convenient navigation in daily life to complex and precise geographic surveying and mapping, aerospace control, and even emergency rescue and disaster monitoring. In these applications, the accuracy of location data is directly related to the precision of navigation, the rationality of decision-making, and the guarantee of safety.

For a forest area, it is necessary to map the boundaries of the area, and measure and record information such as the longitude and latitude coordinates of the trees in the area, tree species, tree height, diameter at breast height, tree age, whether there are pests and diseases, and whether they can be cut down. It is difficult to obtain high-resolution images using traditional remote sensing images, and the specific information of each tree needs to be recorded manually. If high-precision RTK equipment is used, it is difficult to get fixed solution because of dense forests, and it is difficult to walk on forest roads and difficult to carry the equipment. In fact, forest operations do not require such high precision.

NMEA 0183 is the abbreviation of the National Marine Electronics Association, which is now the unified standard protocol for GNSS navigation devices. There are general statements and special statements in NMEA protocol. Common statements include GGA, GSA, GSV, RMC, VTG, GLL, and so on.

With the continuous development of satellite navigation systems, satellite positioning and heading technology has become very mature. Dual-antenna heading has the advantages of high precision, simple structure, cost-effectiveness. It can be widely used in agricultural machinery navigation, unmanned driving, intelligent robot control, drones, unmanned ships, and many other fields. So how does the dual antenna perform heading? What is the accuracy of heading performance? Let's learn about it together.

In the realm of deformation monitoring, where precision and efficiency are paramount, ComNav's A300 emerges as a formidable solution. This monitoring beast is designed to address the complexities of high-value and critical areas such as dams, mine-pits, and underground tunnels. With a compact design that integrates the receiver and antenna into one unit, the A300 not only streamlines the monitoring process but also minimizes the risk associated with multiple devices spread across delicate sites. This article explores the key advantages of the A300 and its transformative impact on deformation monitoring.

With the continuous development of technology, GNSS (Global Navigation Satellite System) receivers have become an indispensable part of our lives, providing us with accurate location information and navigation functions. However, to ensure that your GNSS receiver is performing at its best, timely firmware upgrades are crucial. In this blog, we will discuss the importance of upgrading GNSS receiver firmware and how to do it safely.

The evolution of Global Navigation Satellite Systems (GNSS) has been pivotal in revolutionizing precise positioning across industries. In recent years, a significant stride in this domain has been the integration of Laser Pointing Technology into GNSS receivers. ComNav Technology ventured into these uncharted waters to develop a highly advanced GNSS unit with laser pointer and has gone to create a family of receivers with different capabilities of Laser and GNSS. This convergence signifies a groundbreaking advancement, enhancing accuracy, reliability, and applicability across diverse sectors.

With the development of global satellite navigation systems, RTK technology has also gradually evolved and improved. In this process, multiple satellite navigation systems such as GPS, GLONASS, Galileo, and BeiDou have successively introduced multi-frequency signals, providing possibilities for achieving higher positioning accuracy.

Precise Point Positioning (PPP) technology can achieve high-precision positioning anywhere in the world. Compared with real-time dynamic differential positioning technology, PPP technology does not require a dense reference station network, but its accuracy relies on high-precision satellite orbits and clock deviation products. The Galileo satellite navigation system is a global navigation satellite system (GNSS) jointly developed by the European Union (EU) and the European Space Agency (ESA). Among them, the High Accuracy Service (HAS) issued by the Galileo satellite navigation system can provide real-time precision single point positioning (PPP) services worldwide. Since the birth of the Galileo satellite navigation system, many domestic and foreign scholars and experts have conducted a large amount of research on satellite signal modes, satellite data quality, navigation algorithms, positioning performance evaluation and other aspects based on simulated data or measured data.

​ComNav, a global leader in GNSS technology, has unleashed a groundbreaking innovation that is set to redefine the landscape of Geographic Information System (GIS) mapping. The High Precision GIS Pocket Tablet P6H combines the convenience of a handheld device with cutting-edge GNSS technology, making it a game-changer for GIS specialists and investors alike. This article explores the remarkable features and potential impact of ComNav's P6H on the GIS sector.

The 23 March CME arrived at around 24/1411 UTC. Severe (G4) geomagnetic storming has been observed and is expected to continue through the remainder of the 24 March-UTC day and into the first half of 25 March. The alert issued by NOAA's Space Weather Prediction Center in Boulder, Colorado.

Galileo, Europe's Global Navigation Satellite System, introduced the High Accuracy Service (HAS) to enhance positioning precision. The implementation of HAS in Africa holds substantial promise for revolutionizing Positioning, Navigation, and Timing (PNT) services across the continent. This article examines the transformative impact of Galileo's HAS in Africa and explores the valuable insights that other GNSS constellations can glean from its successful application.

This blog delineates the meticulous process of logging raw observation data from your GNSS device. This data serves a dual purpose: primarily, it is indispensable for post-processing analysis, and secondarily, it furnishes valuable debug information for troubleshooting anomalies. We'll delve into both aspects comprehensively.

In an impressive display of technological prowess, ComNav Technology Ltd. has completed a challenging scanning demonstration with the LS300 Laser Scanner. This test highlighted not just the speed of the LS300, but also the exceptional quality of data it can collect, setting a new benchmark in precision scanning solutions.

SinoGNSS K8 series modules have been fully upgraded. The latest V8 official firmware version supports both PPP and RTK, users have the flexibility to switch between different work modes. SinoGNSS modules support PPP service including PPP-B2b from Beidou, and PPP-HAS from Galileo, no matter where you located, you can benefit from the PPP service. In this article, we will introduce the configuration step by step, to help you enable PPP option.

Event technology refers to enhancing the acquisition and utilization of location information by capturing and processing specific events related to location.The technology records the precise moment and precise coordinate information of an event. When the module receives the EVENT triggers pulse signal, it locks the data at the corresponding time in time for processing, and outputs the original observation, time, position and other information.

Innovation in Global Navigation Satellite Systems (GNSS) technology has transformed various industries, and the realm of lawn mowing is no exception. Navigation and positioning is a key part of the lawn mower's ability to operate autonomously, the integration of GNSS applications into lawn mowers has led to a revolution, offering precise and efficient solutions that benefit both users and society at large.

Global Navigation Satellite Systems (GNSS) serve as indispensable tools for precise positioning and navigation across various fields. However, positioning along the equator presents unique challenges due to several factors such as ionospheric disturbances, satellite geometry, and multipath effects. This article aims to delineate these challenges and provide strategies to mitigate their impact on GNSS users operating in equatorial regions.

ComNav Technology Ltd. has recently unveiled an innovative update to its K8 GNSS Module - the 'appscene' command. This groundbreaking development promises to enhance the adaptability and precision of the K803 module across various application scenarios.

As more and more of users integrate ComNav high precision GNSS modules into various applications, such as Robotics, UAV, Surveying and Mapping, Precision Agriculture, Automatic Driving, to improve the system's debuggability, it is advisable to reserve a port for communication with the internal module in ComNav's high precision GNSS modules. This allows users to easily view module information at a later time and access the data for analysis when needed.

In this article, we will have a general introduction of SinoGNSS data link modules, and show detail steps on how to setup it during integration.ComNav provides mainly two types of datalink modules, one is U50 series which can be compatible with other brands on the market, another one is U70 series which is special designed for longer working distance.

In today's advanced technological era, accurate positioning has become a cornerstone for numerous applications, ranging from agriculture to construction and beyond. But what exactly is RTK, and how does it stand out in the vast landscape of satellite navigation systems?

In previous blog, we introduced how to setup a static observation, in today’s article, we will introduce the steps of configuring static parameters with K8 GNSS receivers. SinoGNSS K8 GNSS receivers allow to modify logging parameters like sample interval, data format and other parameters via WEB UI or data collection software Survey Master, and start data logging. In this article, we will introduce steps of the two methods.

Static observation is a commonly used method in geographical surveying and navigation for accurately measuring the coordinates of points. In static observation, a receiver remains stationary at the observation point and collects satellite signal data over a period of time. These satellite signals contain navigation information transmitted by satellites, and by analyzing these signals, the coordinates of the receiver's location can be calculated. Static observation typically requires a longer observation time to enhance measurement accuracy.

PPS is a precise time marker that emits a pulse every second. The emission of this pulse is extremely accurate, typically with an error in the nanosecond range. A pulse per second (PPS or 1PPS) is an electrical signal that has a width of less than one second and a sharply rising or abruptly falling edge that accurately repeats once per second. PPS signals are output by radio beacons, frequency standards, other types of precision oscillators and some GPS receivers.

​Upon receiving any GNSS modules/GPS modules for the first time, it's natural to want to verify certain essential information. To assist you with SinoGNSS K8-series GNSS modules in this process, We've compiled a list of frequently used checking commands that we'd like to share with you today.

In today's article, we will introduce the most frequently used information about the system configuration. By command “log sysconfig”, clients can check basic configuration, rtk configuration and work mode like PPS, Event, and SBAS.