Medicine
Wearable systems for physiological insight, assistive function, safety monitoring, and adaptive intervention.
Founder-led systems engineering for AI-enabled wearables
AI-enabled wearable systems for medicine, defense, and human augmentation.
Hammond Systems Laboratory LLC develops concepts, architectures, and translational strategies for wearable sensing, robotic assistance, adaptive interfaces, and human-machine teaming.
Engineering augmentation with clinical discipline.
HSL bridges robotics, wearable devices, AI-enabled perception, physiological monitoring, and assistive systems for high-impact applications.
- Focus
- Wearable AI
- Domains
- Medical · Defense · Commercial
- Model
- IP · Grants · Consulting
Defense & human performance
Fieldable interfaces, operator-aware sensing, wearable support, and human-machine teaming for demanding environments.
Commercial systems
Product concepts and prototype architectures for advanced wearables, robotics, sensing, and human augmentation.
About HSL
Hammond Systems Laboratory is built for translational wearable-systems innovation.
Founded by Frank L. Hammond III, Ph.D., Hammond Systems Laboratory LLC focuses on AI-enabled wearable systems, robotics, human augmentation, and adaptive sensing for medical, defense, and commercial applications.
The laboratory combines experience in soft robotics, wearable devices, haptics, prosthetics, orthotics, human-machine interaction, sensing, control, and prototype systems architecture.
HSL is designed to support grant-funded R&D, early-stage product development, technical consulting, IP generation, and strategic partnerships.
Technology focus
Systems that sense, interpret, adapt, and augment.
HSL works at the intersection of embodied AI, wearable robotics, physiological sensing, and human-centered engineering.
AI-enabled wearable sensing
Sensor fusion, context-aware monitoring, physiological inference, and adaptive interpretation for wearable and human-centered systems.
Robotic prostheses, orthoses & exoskeletons
Attachment interfaces, adaptive control, comfort, safety, and self-regulating wearable robotic architectures.
Human-machine teaming
Interfaces that account for cognitive state, attention, environmental context, and changing human capability.
Clinical and safety-oriented systems
Device concepts that support usability, monitoring, risk reduction, functional assistance, and translational validation.
Haptic and perceptual augmentation
Wearable feedback, perception support, and intelligent sensory interfaces for improved human awareness and interaction.
Prototype architecture & technical roadmaps
System decomposition, technology-risk planning, SBIR/STTR strategy, and hardware-software integration pathways.
Capabilities
Useful for grants, consulting, partnerships, and technical leadership.
These capabilities can be adapted for a grant proposal, capability statement, investor teaser, or consulting scope of work.
Grant and SBIR/STTR strategy
Technical aims, innovation framing, commercialization logic, work plans, milestone definition, and reviewer-facing narrative support.
Wearable device and robotics architecture
Early system design, prototype roadmaps, sensor/actuator selection, integration tradeoffs, and risk-reduction planning.
AI/ML systems strategy
Data flows, model roles, user-adaptive logic, safety constraints, and product-level AI architecture for embodied systems.
Technical consulting and diligence
Engineering review, product feasibility, human factors assessment, IP-informed positioning, and translational planning.
Collaboration
Seeking partners in medical wearables, defense human performance, assistive robotics, and AI-enabled sensing.
Selected project themes
High-level, non-confidential invention areas.
Replace these summaries with public-facing descriptions as filings, prototypes, and collaborations mature.
Adaptive disease intelligence and physiological monitoring
AI-enabled approaches for longitudinal health-state interpretation, delayed symptom-physiology coupling, and personalized monitoring workflows.
Wearable perception and attention-aware sensing
Systems that combine gaze, environmental sensing, cognitive-state awareness, and hierarchical alerts for enhanced situational awareness.
Self-regulating wearable robotic interfaces
Prosthesis, orthosis, and exoskeleton attachment concepts focused on comfort, stability, interface adaptation, and functional support.
Haptically enabled human augmentation
Wearable feedback architectures that support perception, guidance, safety, and task-relevant information delivery.
Contact
Discuss a collaboration, consulting engagement, grant, or technical role.
Hammond Systems Laboratory LLC is available for selected collaborations, proposal support, technical consulting, and strategic product-development discussions.
Frank L. Hammond III, Ph.D.
Founder & Principal Engineer
Hammond Systems Laboratory LLC
Atlanta, Georgia