StrideIQLabs™

Sector: Precision Biomechanics / Sensor-Integrated Equine Systems
Stage: Computationally modeled; simulation-validated architecture; patent-pending
Application Domain: Equine performance optimization, injury prevention, data-integrated training systems, real-time biomechanical assessment

StrideIQLabs™ is a smart sensor platform engineered to capture and interpret high-resolution biomechanical data directly from equine motion in real-world environments.

Through a proprietary sensor architecture embedded in adaptive support structures (e.g., horseshoes, wraps), the system enables field-grade biomechanical analysis without disrupting natural movement or requiring lab-based infrastructure.

Where traditional gait analysis relies on optical treadmills or limb-worn sensors, StrideIQLabs™ delivers continuous, high-frequency insight into impact distribution, stride symmetry, fatigue indicators, and performance anomalies—directly at the point of contact.

Validation to date has been conducted via computer-aided simulations approximating field loading, terrain variation, and sensor signal behavior. Physical prototyping is in development.

Performance & Modeling Metrics
Simulations and digital modeling have demonstrated system viability under realistic equine locomotion conditions, guiding hardware integration and analytics logic:

Performance Indicator Modeled Result

Sensor Refresh Rate: 1,000Hz+ real-time capture with <3ms latency

Impact Force Resolution: >95% accuracy across variable terrain profiles

Battery Life (Projected): 8+ hours continuous runtime (detachable power module)

Data Transmission: Encrypted BLE 5.0 or local cache + upload mode

Modular Fit Configurable insert formats for hooves or wraps

All firmware and analytics algorithms are proprietary; physical designs are patent-filed and modular for sector-specific deployment.

Strategic Differentiation
StrideIQLabs™ enables next-generation biomechanical intelligence through:

• Real-time impact and stride diagnostics—ideal for training oversight and asymmetry detection

• Equine-specific architecture—purpose-built to preserve gait mechanics and maintain farrier compatibility

• Cloud-synced analytics—supporting longitudinal trend analysis, recovery baselining, and predictive injury detection

• Zero-lab deployment—designed for use in live training, competition, and therapeutic settings

This positions StrideIQLabs™ as a category-defining solution for equine sports science, veterinary performance medicine, and data-integrated coaching systems.

Commercial & Licensing Readiness

StrideIQLabs™ is available for strategic licensing and co-development in verticals including:

• Equine performance training, rehabilitation, and conditioning

• Veterinary and orthopedic diagnostics

• Sensor-integrated tack, footwear, or therapeutic wearables

• Performance analytics platforms and AI modeling engines

The system supports both branded deployment and OEM integration models. Sector-specific SDKs, trainer dashboards, and sensor interface APIs are available under license.

Computational Model of Durability

Forlytica computational modeling indicates that the embedded horseshoe sensor—when exposed to high-impact equine use (e.g., galloping 2 hours/day for 180 days)—accumulates approximately 1.3 billion Newton-seconds of mechanical load.

Given a conservative fatigue threshold of 10 billion N·s, the potential operational lifespan is approximately 1,389 days, or about 3.8 years under consistent high-load conditions.

This suggests a strong durability margin, indicating that the design can withstand prolonged field use even as we project physical prototyping outcomes.

Licensing Engagement
StrideIQLabs™ is actively engaging with licensing partners positioned to scale biomechanical intelligence across high-performance equine applications. Co-branding, exclusivity, and platform integration are available.

To access simulation data, technical briefs, or integration options, request a private briefing through:
contact@ipboardwalk.com