Story Highlights

• Built on the Inertial Navigation System (INS), OpenShoe started as an academic project developed to track the velocity and position of one’s foot, to track his or her movement
• The INS uses a computer and inertial sensors, like motion and rotation sensors (accelerometers and gyroscopes), to track the position and orientation of an object
• When you are in an elevator or driving through cities like New York, INS may still be a game-changer in making your navigation system work without a glitch

On June 14, 2017, tragedy struck an apartment block in Chelsea, West London, when a gigantic fire engulfed it, resulting in 80 fatalities and severely injuring many. Firefighters fought the blaze for 24 hours before they could bring it under control, while rescuers rummaged through the burning rubble to find survivors. Wouldn’t it be useful if one could efficiently monitor the entire rescue operation and help rescuers reach the exact positions of stranded people to save lives amidst all the smoke and rubble?

The OpenShoe project — a collaborative effort by KTH Royal Institute of Technology, Stockholm, Sweden, and the Indian Institute of Science (IISc), Bengaluru, with support from the Department of Science and Technology (DST), Government of India, and VINNOVA, Sweden’s innovation agency — is now stepping towards making such tracking a reality! Built on Inertial Navigation System (INS), OpenShoe started as an academic project developed to track the velocity and position of one’s foot (the module is installed in just one of the shoes), to track his or her movement. “The project is about developing an indoor positioning system,” remarks professor KVS Hari, chair of the department of electrical communication engineering at IISc, and a research investigator of the OpenShoe project along with professor Peter Handel from KTH Royal Institute of Technology, Sweden.

“It was meant to be used by rescue and firefighting teams that enter a building devastated by a fire, earthquake or an attack. The rescuers enter the building and the command team outside can monitor each team member’s location with an accuracy of up to one meter,” said Hari, adding that such INS systems work without extra infrastructure, like Wi-Fi or satellites, unlike other navigation systems.

The OpenShoe project has contributed significantly to the understanding of inertial systems and pedestrian navigation. After successfully designing and developing the foot-mounted sensor capable of transferring data to a receiver through Bluetooth, the researchers can now make shoes with these sensors. The project has been open-sourced since its inception, putting out all its designs and software in the public domain.

Satellite navigation vs inertial navigation

How does the Inertial Navigation System differ from the well-known Global Navigation Satellite System (GNSS) that powers the maps in our smartphones or our cars? GNSS uses a network of satellites in low-earth orbits that beam down signals which are received by electronic receivers to pinpoint a location using information regarding the latitude, longitude and altitude.

Though this system is highly accurate, there is a frustrating drawback — these devices need to have a clear line of sight with the satellites to work. When one has to navigate within buildings or drive through areas with high-rise buildings, this line of sight is disrupted, and the navigation system ceases to work until the line of sight is restored.

The Inertial Navigation System, on the other hand, uses a computer and inertial sensors, like motion and rotation sensors (accelerometers and gyroscopes), to track the position and orientation of an object. Once an initial position is known, a computer can use data from the sensors to calculate the velocity and orientation of an object. Using a technique called ‘dead reckoning’, the computer continuously tracks the position and orientation of the object relative to its initial position using the estimated speed of the object over elapsed time. In addition, unlike GNSS, INS is a “self-contained” navigation technique that does not need satellites or Wi-Fi connectivity to track an object.

But this convenience comes at a cost — the ‘dead reckoning’ technique suffers from accumulation of small errors with successive position estimates, resulting in larger deviations over time. Hence INS is still waiting to reach a widespread adoption akin to satellite based navigation systems like the US’s Global Positioning System (GPS).

Yet, when you are in an elevator or driving through cities like New York, INS may still be a game-changer in making your navigation system work without a glitch. “Inside a building, satellite navigation does not give an accurate position estimate because of problems like loss of signal. It works really well in a satellite-friendly environment like open spaces, but in a devastated building, which is where we want our device to work, satellite navigation doesn’t do so well,” explains Hari. In fact, the modules from the OpenShoe project have already been tested by Swedish firefighters in a mock drill session, and the feedback has been positive.

Niche application of INS are increasingly found in missile systems, artificial intelligence robots and rovers, and even in our smartphones and watches, allowing runners and athletes to track where, how far and how fast they run each day. This is why INS is now gaining traction, and spinning off successful startups like Inertial Elements based on the OpenShoe project.

Inertial Elements — stepping towards success with INS

Inertial Elements, founded in 2014 by Amit K Gupta along with Peter Handel and John-Olof Nilsson, supervisors of the OpenShoe project from KTH, is currently incubated at IIT-Kanpur. “We focus on precision shoe-mounted sensors (also known as Pedestrian Dead Reckoning or PDR sensors) for indoor positioning,” says Gupta, who also worked on the hardware design of OpenShoe. “Our high performance, affordable and easy-to-use miniaturised inertial sensor platforms enable many niche applications such as indoor pedestrian navigation, industrial safety and resource management, positioning system for rescue agents, autonomous robotics, gaming, treatment of movement disorders and understanding the physics of motion,” says Gupta.

Realising the potential INS has in such applications, the founders of Inertial Elements ventured into building oblu — an open source, wearable, motion-sensing development board that acts as a development platform for motion sensing and robot navigation. For a cost, oblu will provide a pedestrian navigation sensor and the associated software that can be implemented in various motion-sensing applications. If you fancy building an autonomous robot or a tracking collar for your pet, oblu is your go-to device that allows customisable hardware and software. “Oblu is a development board for students, DIY hobbyists, navigation and robotics researchers,” remarks Gupta. Besides this, oblu has been used as a teaching aid in laboratories.

Towards a universal navigation system

With technologies like the Internet of Things, everything around us is turning ‘smart’, ‘context-aware’ and ‘intelligent’. Navigation systems and sensors, needless to say, play a key role in building ‘smarter’ systems for the future. While technological advancements like laser-based accelerometers and gyroscopes have been built to address the accuracy of Inertial Navigation Systems up to centimetre scale, scientists and researchers are now trying to combine INS and GNSS to build a universal navigation system that works everywhere — be it your car basement or the open skies of Maldives.

And the idea is already catching up — luxury automobile manufacturers like Tesla and Mercedes Benz have already implemented a combination of GNSS and INS to provide such a universal navigation system that work everywhere. “GPS and INS are complementary to each other. One is good for outdoors, while the other is good for indoor positioning. Therefore, these two together can make for a great universal positioning system,” signs off Gupta, hoping the future of navigation combines the best of both worlds.

Also read our other Science Language articles.

---