Feasibility
Site analysis, agronomic baseline, regulatory pre-screening, financial pre-modeling.
Deliverables
- Site suitability report
- Crop-shading compatibility matrix
- Permit-readiness dossier
- Pre-financial NPV scenarios
The intelligent
infrastructure for agrivoltaics
Will the panels produce enough power?
Will the crops still grow?
Will the math hold for twenty-five years?
Three questions. One answer.
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paradigm shift
The industry runs on qualitative claims.
- Permitting
Permits hinge on data developers cannot produce.
Italy, France, and Germany now require quantitative proof that crops survive under the panels.
Most developers submit qualitative reports and permits stall. - Deployment
Designs optimized for the panel forget the plant below.
Conventional agrivoltaic layouts maximize irradiance on the panel and accept whatever falls on the crop. After the second growing season, yields fall 15 to 35%. Compliance penalties follow. IRR erodes.
- Operations
35 years of operation with no operational data layer.
Once an asset goes live, the industry answer to yield problems is wait and see.
We give the asset the continuous decision layer it has never had.
We replace them with measurable evidence:
the proprietary engine
Three engines, one decision.
- Phenological stage tracking, sowing to harvest
- Crop-specific shading tolerance curves
- Water and thermal stress indicators
- Multi-season yield estimation
- Hourly irradiance simulation at sub-meter resolution
- Thermal and shading distribution maps
- System energy yield, bifacial gain
- Adaptive tracking optimization by crop stage
- NPV, IRR, LCOE with P50/P90 scenarios
- Regulatory incentive integration
- Sensitivity analysis on yield and price assumptions
- Lender-grade reporting templates
Biological Engine
Crop phenology modeling for the principal European arable and tree crops, calibrated to local agronomic conditions, micro-climate variability, and shading interaction with photovoltaic geometry.
Physical Engine
Three-dimensional radiation and thermal modeling for arbitrary panel configurations: vertical bifacial, single-axis tracking, fixed-tilt elevated, dynamic-tracking.
Financial Engine
Bankable financial modeling integrating energy production, agricultural revenue, regulatory incentives, and operational costs across the asset's 35-year horizon.
dynamical control system
A live decision tool, tuned to the plant.
Dual Energy engine consumes telemetry data continously — soil moisture, irradiance, phenological observations, panel state.
01
Sense
Third-party sensors stream telemetry into our middleware layer at minute resolution.
02
Resolve
The biological engine identifies the current phenological stage and stress signals.
03
Decide
Physical engine resolves panel orientation and tracking for the next 24–72 hours.
04
Recommend
The decision engine dispatches actionable interventions to the IPP operator dashboard.
The Asset Lifecycle
From feasibility to 35 years of operation.
We are not a feasibility tool that exits after permitting. The platform stays deployed through every stage of the asset's life — adapting recommendations as crops rotate, regulations evolve, and operating conditions shift.
certification & bankability
Data that make decisions trustable.
Permits, financing, ESG — every gate in an agrivoltaic project depends on trusted, auditable documents. We produce them continuously, in the formats European regulators, lenders, and investors already accept.
