Calculate DLI from PPFD and photoperiod. Determine if your grow lights provide enough light for optimal plant growth with PAR-based analysis.
Daily Light Integral (DLI) measures the total amount of photosynthetically active radiation (PAR) that a plant receives over one day. Expressed in moles of photons per square meter per day (mol/m²/d), DLI is the single best metric for determining whether plants are receiving adequate light for healthy growth, flowering, and fruit production.
Unlike instantaneous light intensity (PPFD, measured in µmol/m²/s), DLI accounts for both intensity and duration. A plant can receive the same DLI from high-intensity light for a short period or moderate light for a longer period. This makes DLI essential for indoor growers who need to know not just how bright their lights are, but how long to run them.
This calculator converts between PPFD and DLI, helps you determine the required photoperiod for your target DLI, and includes reference data for dozens of crop species. Whether you're growing lettuce in a vertical farm, flowering orchids under LEDs, or supplementing greenhouse light in winter, DLI is the metric that connects light management to plant performance. Understanding and optimizing your DLI can mean the difference between leggy, underperforming plants and compact, productive ones.
DLI is the gold standard for horticultural lighting decisions. This calculator instantly converts between PPFD and DLI, helps size your lighting system, and compares your actual DLI to crop-specific requirements — preventing both under-lighting (leggy plants) and over-lighting (wasted electricity). This daily light integral (dli) calculator helps you compare outcomes quickly and reduce avoidable mistakes when making day-to-day care decisions. Use the estimate as a planning baseline and confirm final decisions with a qualified professional when risk is high.
DLI (mol/m²/d) = PPFD (µmol/m²/s) × Photoperiod (hours) × 3600 / 1,000,000. Conversely: Required PPFD = DLI × 1,000,000 / (Photoperiod × 3600).
Result: 23.04 mol/m²/d
A grow light providing 400 µmol/m²/s PPFD running for 16 hours produces a DLI of 400 × 16 × 3600 / 1,000,000 = 23.04 mol/m²/d, suitable for most flowering plants.
Understanding crop-specific DLI needs is essential for efficient growing. **Low-light plants** like ferns, pothos, and African violets thrive at 4-8 mol/m²/d — they evolved under forest canopies. **Leafy greens** (lettuce, spinach, herbs) need 12-17 mol/m²/d for compact, flavorful growth. **Flowering crops** (tomatoes, peppers, strawberries, cannabis) demand 20-30+ mol/m²/d for productive fruiting. **Full-sun crops** in open fields receive 40-60 mol/m²/d at peak summer in the US, which is why artificially matching outdoor conditions requires serious lighting investment.
To size a grow light system, work backwards from your target DLI. For example, if you need 20 mol/m²/d with an 18-hour photoperiod, the required average PPFD is 20 × 1,000,000 / (18 × 3600) = 309 µmol/m²/s. Account for fixture efficiency, distance from canopy, and edge falloff — practical PPFD is typically 60-80% of center-point measurements. This means you likely need a fixture that delivers 400+ µmol/m²/s at center to average 300+ across the growing area.
Natural DLI varies dramatically by season and latitude. In the northern US (42°N), outdoor DLI ranges from 10-15 mol/m²/d in December-January to 50-60 mol/m²/d in June-July. Greenhouses typically capture 50-70% of outdoor light, so winter greenhouse DLI may drop to 5-10 mol/m²/d — insufficient for most crops. Supplemental lighting bridges the gap: adding 100-200 µmol/m²/s PPFD for 16 hours contributes 5.8-11.5 mol/m²/d to the natural baseline.
Low-light foliage plants: 4-8 mol/m²/d. Herbs and leafy greens: 12-17 mol/m²/d. Flowering plants and fruiting crops: 20-30 mol/m²/d. Cannabis: 30-50+ mol/m²/d with CO₂ supplementation.
Photosynthetic Photon Flux Density measures the number of photons in the 400-700nm range hitting a surface per second. It's the instantaneous light intensity relevant to photosynthesis, measured in µmol/m²/s.
Yes. Lux measures brightness as perceived by human eyes and over-weights green light. PPFD/DLI measures all photosynthetically active wavelengths equally, which is what plants actually use.
Yes. Most plants experience light saturation and eventually photoinhibition at very high PPFD. Without CO₂ supplementation, diminishing returns start above 800-1000 µmol/m²/s for most species.
Use a quantum PAR meter (like Apogee MQ-500 or similar). Phone apps and lux meters are inaccurate for PAR measurement. Many LED manufacturers also publish PPFD maps for their fixtures.
Standard DLI counts all photons from 400-700nm equally. Extended PAR (ePAR) also includes 380-400nm and 700-780nm wavelengths which contribute to photosynthesis, but standard DLI remains the industry norm.