In indoor grow rooms, every environmental factor directly influences plant health, growth speed, and yield quality. By using advanced IoT sensors, growers can create the perfect climate and for each growth phase from seedling to harvest.
Photosynthetically Active Radiation (PAR)
Measure the available light spectrum for photosynthesis to ensure plants receive the optimal light intensity at every stage of growth. Precise PAR control improves energy efficiency and boosts overall yield and quality.
Bulk Electrical Conductivity (EC)
Monitor the concentration of nutrients in the soil or growing medium. EC data helps fine-tune fertilizer dosing to avoid underfeeding or overfeeding, ensuring strong, balanced plant development.
Temperature
Maintain a stable climate by monitoring air temperature to prevent heat stress or cold shock. Consistent temperatures support steady growth and help avoid reduced yields or quality loss.
Humidity
Track relative humidity to create the ideal environment for plant transpiration, nutrient uptake, and pest prevention. Humidity control is key for healthy leaf and root development.
Barometric Pressure
Monitor air pressure to anticipate weather changes or airflow shifts in the growing environment. Pressure data can signal when ventilation adjustments are needed to maintain stable indoor conditions.
CO₂ Levels
Measure and control carbon dioxide concentrations to maximize photosynthesis, which directly drives plant growth and yield. CO₂ enrichment strategies rely on real-time, accurate monitoring for best results.
Soil Temperature
Monitor soil or substrate temperature to ensure optimal conditions for root development and nutrient absorption. Stable soil temperatures promote strong root systems and healthy plant metabolism.
Precision is the key to success in grow rooms. IoT sensor monitoring allows growers to create a fully optimized, controlled environment where plants can thrive — from seedling to harvest — while reducing waste and improving efficiency.
Temperature Measurement Range: -200 to >+1000 cm/hr (heat velocity) Temperature Range: -30 ... +70 °C Resolution: 0.01°C Accuracy: ±0.1 °C Cable length: 5 meter LoRaWAN® class A External power supply: 12.0 VDC regulated, 0.3 A max.
CO₂ Range: From 0 to 10,000 ppm Accuracy: ±50 ppm, ±3% of the reading Temperature Range: From -40 to +125 °C Accuracy: ±0.3 °C Relative Humidity Range: From 0 to 100% RH Accuracy: ±2% RH Barometric Pressure Range: From 300 to 1,100 hPa Accuracy: ±1 hPa absolute, ±0.12 hPa relative LoRaWAN® class A 2 C alkaline batteries
Sub-surface 600 mm profile with 6x capacitance-based soil moisture and soil temperature sensors Moisture / Scaled Frequency Unit Range: From 0 (air) to 100% (water) Resolution: 0.01 Accuracy: ±1% at calibration Temperature Range: From -20 to +50 °C Resolution: 0.1 °C Accuracy: ±0.2 °C, 0.1% per °C Length cable: 5m *Custom profile configuration and length on request LoRaWAN® class A 2 C alkaline batteries
Temperature Range: From -40 to +85 °C Resolution: 0.01°C Accuracy: ±0.1 °C from -5 to +50 °C, ±0.5 °C from -40 to +85 °C Temperature sensor levels: max 16 elements, freely configurable along the cable. Cable length up to 250 m Sensor element: ultra stable silicium sensor Sensor housing: stainless steel, DIN 1.4571 Cable Length: 19 meter LoRaWAN® class A 2 C alkaline batteries
Range: From 0 to 2'500 μmol/m²/s Measurement repeatability: 0.5 % or better Absolute accuracy: ±5% Spectral range: From 370 to 650 nm Length cable: 5m LoRaWAN® class A 2 C alkaline batteries
Photosynthetically Active Radiation (PAR) Range: From 0 to 4000 µmol m-2 s-1 Temperature Range: From -60 to 80 °C Accuracy: ± 0.2 C Relative Humidity Range: From 0 to 95% CO2 Range: From 0 to 2000 ppm Barometric Pressure From 70 to 110 kPa Calibration Uncertainty ± 5 % Cable Length: 5 meter LoRaWAN® class A External power supply: 5.0 V regulated, 0.3 A max.
Optimized Growth Conditions
Real-time monitoring of light, temperature, humidity, and CO₂ ensures that plants always grow under the best possible conditions for photosynthesis, development, and flowering.
Improved Nutrient Management
Bulk Electrical Conductivity (EC) data allows for fine-tuning of fertilizer strategies, reducing nutrient waste and preventing plant stress caused by overfeeding or underfeeding.
Enhanced Yield and Quality
Stable, well-monitored conditions lead to uniform, predictable harvests with higher quality crops — improving both output and profitability.
Energy and Resource Efficiency
Accurate PAR and climate data help optimize lighting, heating, cooling, and CO₂ enrichment systems, lowering energy consumption and operating costs.
Early Detection of Environmental Risks
Continuous monitoring helps detect problems such as humidity spikes, temperature fluctuations, or nutrient imbalances before they can impact plant health — allowing for quick corrective action.
Stable Root Zone Development
Soil temperature monitoring ensures root systems develop in an ideal environment, strengthening plant structure and improving nutrient absorption.
Data-Driven Cultivation
Historical and real-time sensor data empower growers to refine and automate their growing strategies, making each cycle more efficient, sustainable, and predictable.
