Projects

Researchers at the STRIVE Center are developing a fluid, intuitive exoskeleton system to improve the technology’s use in operational environments.

Researchers at the STRIVE Center are improving methods for identifying the mechanisms underlying balance impairments in patients with mild traumatic brain injury (mTBI).

We are building an open-source toolbox to help researchers more easily design, evaluate, and monitor artificial intelligence (AI) systems.

The application helps users to plan pandemic response by estimating state and regional personal protective equipment (PPE) demand.

An aging weatherproof enclosure protecting one of the space surveillance radars on Kwajalein Atoll is replaced.

Robust, trustworthy, and safe machine learning algorithms that operate in resource-constrained environments will improve missile defense and other target recognition and mission planning systems.

This toolkit uses near-field communications tags to help researchers track biological samples and equipment during large, field-testing events.

We are developing a tool to evaluate the landscape of wearable sensors, algorithms, and technologies and apply them to warfighter health and performance monitoring.

Optical atomic clocks are the most accurate in the world, but they are very large, sensitive instruments. We are transforming the complex components of these clocks into a compact, portable platform.

We developed a ladar that samples at the diffraction limit to collect high-resolution imagery for geospatial mapping missions.