Build a battery “digital twin” model to preview temperature distribution, stress/strain, and thermal runaway paths during the design stage—bringing risks forward into design.

Model-based design methodology from algorithm development to embedded code generation, validated via simulation across scenarios to maintain integrity and efficiency.

Millisecond-level anomaly response via multimodal sensors, providing end-to-end protection from intrinsic safety to emergency firefighting.

Combine thermal management with thermal runaway path simulation to identify risks early and trigger warnings.

Millisecond-level autonomous protection for abnormalities such as overcharge, overdischarge, short circuit, and overtemperature.

Monitor cell temperature differences in real time and dynamically adjust voltage and temperature to slow performance degradation.

Real-time accurate estimation of SOC/SOH/SOP via multi-model fusion algorithms, reducing battery gauge error and range anxiety.

Deep integration of embedded systems and battery chemistry: sleep power as low as μA-level, instant wake-up when needed—shifting from “passive consumption” to “active intelligent control”.

Support lifecycle data upload and analysis; continuously optimize BMS strategies via remote diagnostics and firmware upgrades to adapt to different usage scenarios and aging states.

Reduce module weight via topology optimization and advanced materials while maintaining strength.

Waterproof, dustproof, and shock-resistant to handle harsh operating conditions.

Collaborate with universities on cutting-edge technologies including high-performance lithium battery safety management and control, PV energy storage, and cloud monitoring.