New Method Accelerates AI Decision-Making
A new solution compresses and offloads critical data from battlefield machines more efficiently, enabling faster AI processing and decision-making on the battlefield.
Researchers from the U.S. Army Combat Capabilities Development Command, known as DEVCOM, Army Research Laboratory, and university partners from the Internet of Battlefield Things Collaborative Research Alliance (IoBT CRA) developed a new solution to provide battlefield applications with pressing machine intelligence, even when the local environment is not able to facilitate AI processing. This new solution offloads data from the battlefield to remote processing engines by enabling a much higher degree of data compression than previously possible.
“The computational requirements of AI in the battlefield are burdensome for many low-capacity devices,” said Dr. Tarek Abdelzaher, a professor at the University of Illinois Urbana-Champaign and the academic lead of the lab’s IoBT CRA. “Offloading data from the field to a more computationally capable machine is a potential solution to facilitate more efficient processing.”
Transferring data between field devices like Army-relevant sensors, such as cameras, LiDARs, Radars, IR sensors and a remote server, can take significant amounts of time, Abdelzaher said. Compressing the data puts less burden on the battlefield system, allowing it to send the data to the processing machine elsewhere more efficiently, even across low-bandwidth, contested links. This improved processing speed significantly reduces the delay between initial sensing and subsequent decision-making, enabling commanders to immediately act on data in an intelligent manner.
Researchers recently tested the compression solution by offloading an image from one device at the lab’s Multi-Purpose Sensing Area at White Sands Missile Range and an IoBT CRA server in Massachusetts. Testing of this solution showed that compression was four times more effective than an image’s compression capability, which is the current image compression standard, researchers said.
Researchers achieved this ultra-high compression capability by considering future use needs; only those data features that the AI will need to use later for accurate processing are preserved during compression. This enables the machine to achieve a much higher compression ratio than existing compression techniques that do not consider future use, all without a significant loss of accuracy.
“For example, in an application where the goal is to recognize different types of vehicles in an image, what cues are used by the AI to distinguish the different types of vehicles?” Abdelzaher asked. “Those cues should be preserved by compression when data is sent from the field. Other irrelevant information can be compressed away to improve compression abilities.”
This solution can revolutionize AI for Army applications and increase autonomy in mission execution by bringing AI virtually to the point of need in the field through faster offloading and remote processing.
Top Stories
INSIDERManned Systems
Turkey's KAAN Combat Aircraft Completes First Flight - Mobility Engineering...
INSIDERMaterials
FAA Expands Boeing 737 Investigation to Manufacturing and Production Lines -...
INSIDERImaging
New Video Card Enables Supersonic Vision System for NASA's X-59 Demonstrator -...
INSIDERManned Systems
Stratolaunch Approaches Hypersonic Speed in First Powered TA-1 Test Flight -...
INSIDERUnmanned Systems
Army Ends Future Attack and Reconnaissance Helicopter Development Program -...
ArticlesEnergy
Can Solid-State Batteries Commercialize by 2030? - Mobility Engineering...
Webcasts
AR/AI
From Data to Decision: How AI Enhances Warfighter Readiness
Energy
April Battery & Electrification Summit
Manufacturing & Prototyping
Tech Update: 3D Printing for Transportation in 2024
Test & Measurement
Building an Automotive EMC Test Plan
Manufacturing & Prototyping
The Moon and Beyond from a Thermal Perspective
Software
Mastering Software Complexity in Automotive: Is Release Possible...