GPS technology, an integral component of modern navigation, often encounters significant challenges in urban environments. In cities, where tall buildings and reflective surfaces abound, GPS signals can be unreliable, leading to frustrating navigation experiences. Renowned researcher Ardeshir Mohamadi at the Norwegian University of Science and Technology (NTNU) is at the forefront of efforts to enhance GPS technology, aiming to improve its accuracy in densely built-up environments. This revolutionary approach primarily focuses on urban canyons, areas characterized by their reflective structures that distort satellite signals.
When GPS technology was first implemented, its utility was extraordinary, but as urbanization progressed, the challenges grew. In city settings, GPS signals often bounce off buildings, leading to distorted readings that can depict a user as jumping from one location to another instead of providing a steady, accurate representation of their actual movement. Mohamadi elucidates the issue, highlighting how urban environments create unique challenges for satellite navigation that aren’t present in more open areas, such as highways. These challenges echo the frustrations of many relying on GPS for navigation; thus, the need for a more sophisticated solution is evident.
The researchers at NTNU have developed an innovative system called SmartNav, specifically designed to overcome the obstacles posed by urban canyons. The name itself reveals a focus on smart navigation solutions that can effectively manage the complications presented by the urban landscape. By employing particle filtering techniques and advanced sensor fusion, SmartNav recalibrates GPS readings, providing self-driving vehicles with the level of accuracy required for safe operation in cities. Such technology can dramatically enhance the reliability of navigation systems in urban settings.
One significant aspect of GPS technology is its dependence on small satellites orbiting the Earth, which communicate their positions through radio wave signals received by GPS devices. This communication exchange permits devices to triangulate their positions by analyzing signals received from multiple satellites. However, urban obstacles block direct lines of sight, leading to reflections and delayed signals that can throw off the calculations. Mohamadi notes that these disruptions can create navigational errors that significantly impact the efficacy of both personal navigation devices and autonomous vehicles.
Under normal circumstances, a GPS receiver requires signals from a minimum of four satellites to calculate an accurate position. In urban areas, however, the presence of barriers such as buildings creates the so-called “multipath error,” where signals bounce off walls and surfaces before reaching the receiver. The resulting inaccuracies could pose safety risks for autonomous vehicles, making precise navigation even more critical. By addressing these issues through SmartNav, researchers aim to provide vehicles with reliable positioning data, thereby ensuring safer transportation solutions as self-driving cars become more integrated into everyday life.
For those unfamiliar with the intricacies of GPS technology, understanding how signals work is fundamental to appreciating the advancements being made. The signals emitted by satellites contain a time-stamped message indicating the satellite’s position and the time the signal was transmitted. However, the critical aspect of working with this information lies in the code. Urban interference often disrupts the code, leading to inaccuracies in positioning. Mohamadi and his colleagues explored the feasibility of an alternative approach—abandoning the code altogether and utilizing the carrier phase of the signal for enhanced accuracy.
This technique, while promising, presents one major challenge: when using carrier phase measurements alone, the receiver must remain stationary for an extended period, a scenario that poses practical challenges in dynamic environments such as urban streets. Recognizing this limitation, researchers investigated innovative ways to improve GPS signal accuracy while maintaining the ability to continue moving, making the SmartNav system particularly advantageous for mobile users.
In recent years, advances in supporting technologies like Real-Time Kinetics (RTK) have also come to the fore. RTK aids in enhancing GPS signal accuracy through the use of nearby base stations to relay corrections, but these systems can be expensive and less accessible to the average user. An alternative, which also shows promise, is Precise Point Positioning – Real-Time Kinematic (PPP-RTK). This approach improves GPS readings by integrating corrections from satellite signals, eliminating the need for costly local base station infrastructure. Such advancements exemplify the ongoing efforts to make highly accurate GPS technology more accessible to the general populace.
During the research project, an interesting collaboration occurred when Google introduced a service intended to mitigate urban navigation issues. Google began employing sophisticated 3D city models to predict how satellite signals manifest in varied urban environments. Combining data from different sources, such as Wi-Fi and sensor networks alongside these 3D models, the system enhances the ability to estimate position accurately, overcoming errors caused by nearby structures reflecting satellite signals.
Early tests conducted in Trondheim’s urban landscape demonstrated the effectiveness of these combined technologies. With the integration of SmartNav and Google’s techniques, researchers achieved astonishing results, attaining positions with an accuracy of better than ten centimeters 90% of the time. Such precise measurements could revolutionize how we navigate cities, particularly with the proliferation of self-driving cars, bringing us closer to a future where technology seamlessly supports daily life in urban environments.
The implications of these advancements are profound, suggesting that improved GPS accuracy could revolutionize transportation systems and urban planning. By offering enhanced and affordable GPS solutions capable of delivering reliable location data, this research could potentially change how people interact with technology in urban environments. Consumers may find their navigation devices more trustworthy, while companies developing autonomous vehicles will have the tools needed to operate reliably in cities.
In conclusion, as urban spaces continue to expand and evolve, the urgency to address GPS navigation challenges becomes undeniably clear. The innovations spearheaded by Mohamadi and his team represent a monumental step in ensuring that users can confidently rely on GPS technology in urban environments, paving the way for safer and more efficient navigation solutions in the years to come.
Subject of Research: Phase-Only positioning in urban environments
Article Title: Phase-Only positioning in urban environments: assessing its potential for mass-market GNSS receivers
News Publication Date: 25-Jul-2025
Web References: 10.1080/14498596.2025.2536567
References: Mohamadi, A., Nahavandchi, H., & Khodabandeh, A.
Image Credits: Photo: Anne Sliper Midling
Keywords
GPS, urban navigation, satellite signals, autonomous vehicles, SmartNav, phase-only positioning, Real-Time Kinetics, precision technology, urban canyons, 3D mapping.
Tags: accuracy in dense environmentsArdeshir Mohamadi researchenhancing navigation technologyGPS technology improvementinnovative GPS solutionsmodern GPS applicationsovercoming urbanization obstaclesreflective surfaces in citiessatellite signal distortion issuesSmartNav system developmenturban canyon GPS solutionsurban navigation challenges
