Electrification Solution Assessment
Decide with confidence before committing. Early-stage technical assessment for OEM electrification — feasibility, risks, and the best way forward.
We Provide
Power cycle measurement
Preliminary data analysis
Simulation
Powertrain architecture proposal
BOM cost estimation
Key outcomes
Validate feasibility with real or estimated duty cycle data (power and energy demand, peaks, constraints)
Compare architectures (BEV vs hybrid) and charging assumptions (CCS/MCS readiness)
Get a clear recommendation package: sizing, risk list, cost drivers, and next steps
Make the right powertrain decision — based on data
Electrification projects get expensive when decisions are made without data: sizing, packaging, thermal, safety, controls, charging, and serviceability can all force redesigns later. We bring these into one assessment early.
Our Solution Assessment answers the key feasibility questions so you can choose the right powertrain technology and architecture for your application. And your team can move forward with confidence, backed by a solid, data-driven assessment.
Data-Driven Design of Electric Powertrain Solutions
By analyzing real duty cycle data and operational parameters, we identify which powertrain technologies and system architectures best suit your specific application. Existing ICE-powered machines often provide a valuable reference point for building efficient, sustainable electric alternatives.
Finally, the bill of materials (BOM) cost estimation allows you to evaluate the market potential of your electrification project. By understanding the cost structure early on, you can assess the commercial feasibility, compare technology options, and make informed decisions about pricing, positioning, and potential return on investment.
What we need from you
Key factors we evaluate include operating environment, charging options, and energy and power demands for key components. Based on this, we recommend the optimal powertrain type – hybrid or fully electric – and propose a system topology tailored to your requirements.
You don’t need a full spec to start. Typically enough:
Machine type and performance targets (power, speed, duty, runtime)
Duty cycle information (logs if available, or a best estimate)
Packaging and cooling constraints (space, mounting, airflow/liquid)
Charging assumptions (power level, connector/interface preference, operational reality)
Any existing components you want to reuse (hydraulics, auxiliaries, driveline constraints)