What is a growing degree day (GDD)?

A growing degree day (GDD), also called a heat unit or growing degree unit (GDU), measures heat accumulation above a crop's minimum growth temperature on a given day. Formula: GDD = ((daily high + daily low) / 2) minus the base temperature. If the result is negative it is set to zero. GDDs accumulate from planting through harvest to predict crop development timing.

How does the automatic GDD tracking work?

When you set your location, the GDD Tracker fetches historical daily high and low temperatures from Open-Meteo, a free global weather API using ECMWF ERA5 reanalysis data. It calculates GDD for each day from your planting date through yesterday and adds them to your log automatically. Each time you return to the page, it detects the gap since your last visit and fills in all the missing days — you never need to enter temperatures manually.

Does the GDD tracker work outside the United States?

Yes. Open-Meteo covers the entire globe at approximately 9km grid resolution. The tracker supports international crop terminology: corn is listed as Corn/Maize/Mealie, canola as Canola/Oilseed Rape/Rapeseed/Colza, soybeans as Soybeans/Soya Beans, and wheat by regional variety names including CWRS, HRS, HRW, and SRW. Celsius and Fahrenheit are both supported. Type any city, region, or postal code worldwide to set your location.

What base temperature does corn (maize) use for GDD?

Corn uses a base temperature of 50 degrees F (10 degrees C) and a ceiling of 86 degrees F (30 degrees C). Daily highs above 86 F are capped and daily lows below 50 F are raised to 50 F before averaging. This is the USDA modified method. A 100-day hybrid typically needs approximately 2,700 GDD from planting to black layer (physiological maturity).

What base temperature does wheat use for GDD?

Winter and spring wheat use a base temperature of 32 degrees F (0 degrees C) with no upper ceiling temperature. This matches the most widely used agronomic standard. Wheat typically requires 2,000 to 2,500 GDD (base 32 F) from planting to harvest maturity depending on variety and region.

What is the difference between GDD and GDU (growing degree units)?

GDD and GDU are the same calculation with different regional names. GDU is commonly used in the Upper Midwest United States and Canada. GDD is used in the western US, UK, Europe, and internationally. Both formulas are identical: average daily temperature minus base temperature, with negative values set to zero.

Can I track multiple crops or fields at the same time?

Yes. Click Add Planting to add as many tracked plantings as you need. Each planting has its own crop type, planting date, variety name, GDD log, and milestone tracking. All plantings are saved in your browser and restored automatically on every visit. Click any planting card to switch the active view.

Can I override automatic temperatures with my own field readings?

Yes. Click Add or Override Day to enter your own high and low temperatures for any date. If that date already has an auto-filled entry it will be replaced. This is useful when your field runs warmer or cooler than the weather grid — for example near an irrigation canal, on a south-facing slope, or in a frost pocket. Manual entries are marked with a pencil icon in the log.

How accurate is the weather data used for GDD calculations?

Open-Meteo uses ECMWF ERA5 reanalysis data at approximately 9km grid resolution. It is typically accurate to within 1 to 3 degrees F for most agricultural locations. Accuracy decreases in complex terrain, near water bodies, in frost pockets, and during radiative frost events where local temperatures can differ from the grid estimate by 5 to 10 degrees F or more. For critical decisions, verify with an on-farm sensor or nearby official weather station.

What crops does the GDD tracker support?

The tracker supports 15 crops plus custom: corn (maize, mealie), soybeans (soya beans), winter wheat (HRW, SRW), spring wheat (CWRS, HRS), durum wheat (pasta wheat), barley (malting barley), oats, grain sorghum (milo, jowar), canola (oilseed rape, rapeseed, colza), sunflower, dry beans (navy, pinto, haricot), lentils (masoor, pulses), field peas (marrowfat), potatoes (Solanum tuberosum), sugar beet (fodder beet), and a fully custom crop with user-defined base and ceiling temperatures.

Rastreador de Grados-Día de Crecimiento (GDD)

Rastree la acumulación de unidades de calor automáticamente usando su ubicación y datos climáticos en vivo. Ingrese su cultivo y fecha de siembra — la calculadora obtiene las temperaturas diarias reales y completa los GDDs cada vez que regresa al sitio. Realice seguimiento de múltiples siembras simultáneamente.

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USDA Modified GDD Method

This calculator uses the USDA Modified method: GDD = ((min(High, Ceiling) + max(Low, Base)) ÷ 2) − Base This averages the adjusted daily high and low before subtracting the base temperature, rather than using the high alone. It accounts for nighttime temperatures — crops accumulate heat 24 hours a day, not just during the warmest part of the afternoon. The ceiling cap (86°F for corn) prevents overstating development on very hot days, since growth rate plateaus above that threshold. This is the standard method used by Iowa State, Purdue, Kansas State, and WSU Extension for corn and most row crops.

Air temperature vs. soil temperature: GDDs are calculated from air temperature measured at 2 metres above the ground — the standard for all weather stations and agronomic models. However, early-season crop development (germination, emergence, and the first vegetative stages) is driven primarily by soil temperature at seed depth (typically 2 inches / 5 cm), which can differ significantly from air temperature. In spring, dark soils in direct sun can warm 5–15°F above air temperature during the day, meaning the crop may develop faster than air-temp GDDs suggest. Conversely, on cold clear nights soil at seed depth retains heat longer than the air above it. The practical result: GDD-calculated stages often lag visible field stages in early spring, especially in dark irrigated soils like those in the Columbia Basin. The manual stage override (✏️) lets you correct for this by anchoring the projection to what you actually observe in the field.

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GDD Calculator

Automatic GDD accumulation from planting date · weather-powered · persists across visits · worldwide coverage

Tracked Plantings

Crop & Temperature Unit

Crop

Temperature Unit

Base: 50°F Ceiling: 86°F Method: Modified (USDA) Season total: 0 GDD

Location — for automatic weather data

📍 No location set — GDDs will be entered manually

Add Daily Temperature

Date

Daily High (°F)

Daily Low (°F)

Tip — add days in sequence from planting date. Date auto-advances after each entry.

Season Summary —

Crop: Planted: Base: Method: Season Total:

Season Summary

Total GDD

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Avg GDD / Day

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Projected Days to Maturity

Development Milestones

Daily Log

Date	High (°F)	Low (°F)	Avg	GDD	Season Total	Stage	Source

Weather Data & Location Accuracy — Temperature data is sourced from the Open-Meteo API using ECMWF ERA5 reanalysis, a gridded atmospheric model with global coverage at approximately 9 km (5.6 mi) grid resolution, updated daily. This is not data from a specific weather station — it represents a modeled estimate interpolated to the nearest grid point to your coordinates. Actual field temperatures commonly differ from this estimate by 1–5°F (0.5–3°C) and can differ by more due to local conditions including elevation changes, slope aspect, proximity to rivers or irrigation canals, urban heat islands, frost pockets, or overhead canopy. In complex terrain or during radiative frost events, discrepancies can exceed 10°F. Weather data typically lags 1–5 days; the most recent days in your log may not yet be populated. For critical agronomic or spray timing decisions, verify with an on-farm temperature sensor or a nearby official weather station record.

GDD Milestone Accuracy — Development stage milestones shown in this tool are general agronomic averages based on published research and are not calibrated to a specific hybrid or variety. Actual crop development can vary by 5–15% from these averages depending on the hybrid GDD rating, planting depth, seed-to-soil contact, soil temperature (which lags air temperature by several days in spring), soil moisture, plant population, and regional adaptation. A hybrid or variety rated at 2,650 GDD by its seed company may reach physiological maturity anywhere from 2,500 to 2,800 accumulated GDD depending on the growing season. Always cross-reference with your seed company’s hybrid-specific GDD ratings and your own field scouting records. This tool is designed for planning and season monitoring only — it is not a substitute for direct field observation.

Preguntas Frecuentes

Un grado-día de crecimiento (GDD), también llamado unidad de calor, es una medida de acumulación de calor usada para predecir el desarrollo de las plantas. Se calcula como el promedio de las temperaturas máxima y mínima diarias menos una temperatura base (10°C para maíz, usando 30°C como techo). Las plantas se desarrollan más rápido con temperaturas altas y más lento con temperaturas frías.

Para maíz, la temperatura base es 10°C (50°F) y el techo es 30°C (86°F) usando el Método Modificado del USDA. Esto significa que las temperaturas por encima de 30°C se limitan a 30°C en el cálculo. Otras culturas usan temperaturas base diferentes: trigo usa 0°C (32°F), soja usa 10°C (50°F).

El maíz de campo típico necesita aproximadamente 1.135 GDDs (base 10°C, techo 30°C) para alcanzar VT/R1 (espigamiento/floración). Hitos importantes: VE (emergencia) = 120 GDDs, V6 = 475 GDDs, VT/R1 = 1.135 GDDs, R3 (grano lechoso) = 1.400 GDDs, madurez fisiológica (R6) = 2.700 GDDs.

El trigo de invierno típicamente necesita 1.500–2.000 GDDs (base 0°C) desde la emergencia hasta la madurez. El trigo de primavera puede necesitar menos GDDs dependiendo de la variedad y región.

El rastreador usa la API Open-Meteo (datos climáticos históricos del ECMWF) para obtener temperaturas máximas y mínimas diarias para las coordenadas de su ubicación. Los datos se completan automáticamente para todos los días desde la fecha de siembra hasta ayer. En visitas de retorno, solo se agregan los días nuevos — sin necesidad de ingresar datos manualmente.