According to French Acoustics researchers, U.S. soldiers will soon be able to use their smartphones to locate enemy gunfire on the battlefield.
Technology keeps getting better by the minute.
For decades, U.S. Military have worked diligently to develop technologies that simultaneously protect infantry soldiers’ hearing and provide support to aid battlefield communication.
However these advanced Tactical Communication and Protective Systems, or TCAPS – earmuffs or earplugs with built-in microphones which allow active hearing protection – don’t help if a soldier takes them off to assess the location of incoming gunfire.
Now a French researcher has developed a proof of concept that uses the microphones in a TCAPS system to capture a shooter’s acoustic information and transmit this to a soldier’s smartphone to display shooter location in real time.
“At the beginning of an ambush, the most important thing for soldiers is to know where the shooting is coming from so that they can hide on the right side of a vehicle or at least aim in the right direction – and they need this information very fast,” said Sébastien Hengy, a combat acoustics researcher at the French-German Research Institute of Saint-Louis (ISL).
In addition to the military, law enforcement agencies also use gunfire locators. Gunfire locators or gunshot detection systems are technology systems that detect and convey the location of gunfire or other weapon fire using acoustics, optical, or potentially other types of sensors.
Many systems consist of three primary components:
- An array of microphones or sensors either co-located or geographically dispersed.
- Processing unit
- A user-interface that displays gunfire alert systems
Sebastien Hengy will present his TCAPS-based shooter location research at the 177th Meeting of the Acoustical Society of America, which takes place May 13-17, at the Galt House in Louisville, Kentucky.
TCAPS have four microphones: two outside the ear canal and two inside it, underneath the hearing protection. In the French case, this is an electronic filter that activates to block out loud noises, such as when a soldier fires his or her own weapon.
Hengy’s shooter location technology uses the fact that most modern combat weapons fire bullets at supersonic speeds, creating two acoustic waves. The first is a supersonic shock wave (similar to that formed in front of a jet at supersonic speeds) that travels in front of the bullet and propagates outward in a cone shape. The explosion of the bullet in the barrel creates a muzzle wave which radiates out spherically in all directions.
“Our system uses the microphone underneath the hearing protection to detect the shock and muzzle waves generated by supersonic shots and record the time difference of arrival of the Mach wave between the left and right ear. By combining the information sent by all the TCAPS deployed on the field, this gives you the direction of arrival of the waves and thus the direction in which the shooter is,” explained Hengy.
This information is sent via Bluetooth or USB to a soldier’s smartphone which uses a data fusion algorithm developed by Hengy to calculate the shooter’s position.
“If it’s a smartphone with a good processor, the computation time to get the complete trajectory is about half a second,” said Hengy, noting that once a soldier begins returning fire, the location system automatically turns off.
Soldiers in France’s Operation Sentinel domestic anti-terror force are already equipped with smartphones.
To date, Hengy has successfully demonstrated the system with microphones mounted ear width apart (about 10 centimeters) in a field, and is currently finessing the technology, including integrating head orientation information from tiny compasses mounted in the hearing protection.
Later this year they’ll begin tests with the system on an artificial head and, if all goes well, deploy the technology as early as 2021. The TCAPS technology is being developed in collaboration with French company Cotral.
Newsblaze Reporter Clarence Walker can be contacted via email: [email protected]