Our LED system dynamically adapts the light spectrum to each plant’s species and growth stage — going beyond natural sunlight by optimizing it through AI. Powered by thousands of growth experiments, our self-learning “light recipes” deliver consistent, high-quality results while minimizing energy use. This adaptive intelligence ensures every plant receives precisely what it needs for faster, healthier, and more sustainable growth.
Solis Technology brings full intelligence to modern agriculture. Our proprietary control board enables real-time sensing and automation through a mobile app, while standard IoT compatibility allows seamless integration with irrigation, climate, and nutrient systems. Growers can monitor and fine-tune all parameters remotely, achieving precision farming at any scale without the complexity of traditional automation systems.
Designed with four independently controlled LED channels, our system allows complete customization of spectrum and intensity for each crop. Using high-efficiency LEDs from leading European manufacturers, Solis modules are engineered for durability and long-term stability under demanding greenhouse conditions. This modular architecture scales effortlessly from R&D setups to industrial farms — ensuring flexibility, reliability, and readiness for mass production.
As climate change intensifies and fertile land diminishes due to pesticide use, soil degradation, and water scarcity, Solis provides a smarter alternative. Our dynamic LED systems enable up to 40% energy savings and nearly double yields compared to conventional lighting. By empowering food production in controlled environments with fewer resources and minimal environmental impact, we contribute directly to sustainable agriculture and the global effort against food insecurity.
SLS-L36
36
400x200x80
800
56~90 / m2
Developed for experimental research and spectrum optimization, the SLS-L36 provides open-frame hardware access for direct control-board interaction. Equipped with a DC output, I²C communication and additional GPIO interfaces that can be configured for external sensors such as temperature or humidity probes. Ideal for academic laboratories and plant physiology studies where fine-tuning of wavelength and intensity is essential.
SLS-LCx
22 - 74
Customizable
Variable
Negotiable
A fully customizable lighting architecture for design-specific or prototyping applications.
Mechanical layout and optical geometry can be adapted to research rigs, architectural green walls or compact cultivation modules. Solis Technology collaborates directly with clients to balance optical efficiency, spectral fidelity and aesthetic integration, ensuring each system meets both technical and creative demands.
SLS-H100
100
700x85x80
2180
180 / m2
Engineered for high-efficiency, long-range illumination in commercial greenhouses and vertical farms. Features IP67-rated protection for durable operation under humid and high-temperature conditions. Ensures uniform light distribution across wide canopies with advanced heat management and minimal maintenance requirements, delivering consistent performance and longevity for industrial-scale agriculture.
Our greenhouse in Kartepe has been the testing ground for more than 3,000 plant experiments across 20 plant species, validating how dynamic lighting reshapes growth efficiency and quality.
These trials proved that precise wavelength control and spectral balance not only accelerate photosynthesis but also reduce plant stress, resulting in healthier and denser foliage.
In tomato trials, plants grown under Solis dynamic lighting showed significant improvements in mineral absorption, particularly in calcium (Ca), magnesium (Mg), Ferrium (Fe) and potassium (K) levels, these are key indicators of stronger cell walls and improved fruit firmness.
Compared to fixed-spectrum systems, Solis Technology lighting resulted in more uniform fruit size, richer color development and shorter maturation time, supporting both yield quality and shelf life.
Beyond growth metrics, strawberries tell a story of how light shapes experience. Under our S4 recipe, strawberries developed a naturally sweet flavor profile. Meanwhile, the S2 recipe produced berries with a pleasantly tart note and firmer texture. Antioxidant levels remained similar across both conditions, the difference in flavor complexity revealed a new dimension of horticultural lighting: customized taste.
This opens the door to cultivating strawberries tailored to diverse diets and markets like from low-calorie, high-acid fruits to richly aromatic varieties designed for premium desserts.
Using our A3 dynamic light recipe, basil plants achieved nearly double the total leaf area compared to those grown under standard horticultural white LEDs — while consuming 40% less energy.
These trials proved that precise wavelength control and spectral balance not only accelerate photosynthesis but also reduce plant stress, resulting in healthier and denser foliage.
This benchmark experiment demonstrated how adaptive spectrum control directly translates to measurable efficiency and productivity gains.
less energy,
less waste,
less uncertainty.
