As global demand for sustainable, year-round crop production intensifies, controlled environment agriculture (CEA)—including vertical farms and greenhouses—has emerged as a viable solution. Central to this model is lighting: optimizing light delivery in terms of spectrum, intensity, and uniformity is essential to maximize photosynthetic efficiency while minimizing energy expenditure.
Designing optical systems for indoor agriculture requires modeling of light interactions with structural and biological elements—tasks that demand non-sequential ray tracing. TracePro® by Lambda Research Corporation enables photometrically accurate simulation of real-world indoor farming environments, allowing engineers to virtually test and refine grow lighting systems for both optical performance and thermal behavior.
TracePro supports full CAD model integration, spectral source definition, wavelength-specific material properties, and irradiance analysis—all critical to optimizing horticultural lighting designs.
Indoor farms substitute solar radiation with artificial lighting, where photon efficiency—not just quantity but spectral quality—is paramount. Plants respond to Photosynthetically Active Radiation (PAR) across 400–700 nm, with red (660 nm), blue (450 nm), and far-red (730 nm) light playing distinct roles in different growth stages.
Using TracePro, designers can:
These capabilities help mitigate risks such as shadowing, over-illumination, and spectral mismatch—all of which can impair biomass yield and energy efficiency.
Lenses and reflectors, including TIR optics, can be imported via CAD or designed in TracePro, then assigned precise material indices and surface textures to shape beam profiles.
Highly reflective inner surfaces (e.g., anodized aluminum) are modeled with real-world BRDF or user-defined scattering profiles to enhance photon recycling within the enclosure.
Angular diffusion and transmission losses are quantified to tune the optical spread and minimize spectral distortion.
TracePro enables absorbed power mapping across materials, identifying heat accumulation zones on components such as diffuser panels or optical lenses. This supports thermal mitigation via:
In vertical farming stacks, light pipes and waveguides are modeled for total internal reflection, loss mapping, and uniform out-coupling. TracePro's ray-tracing can verify light uniformity across multiple layers using.
The rising global demand for sustainable agriculture and year-round crop production has propelled indoor farming into the spotlight. Whether in vertical farms, greenhouses, or controlled-environment agriculture (CEA) facilities, light is one of the most crucial inputs. Efficient optical systems that can deliver the appropriate spectral distribution, intensity, and uniformity of light are essential for maximizing plant growth while minimizing energy consumption.
Designing these lighting systems requires optical precision. Misaligned optics, suboptimal light distribution, or inefficient energy usage can reduce crop yield and elevate operational costs. TracePro®, an advanced non-sequential ray tracing software developed by Lambda Research Corporation, allows engineers to simulate and optimize light propagation in complex three-dimensional environments. By modeling real-world grow environments and assigning precise optical properties to each component, users can validate lighting designs that meet the strict performance requirements of modern indoor agriculture.
In indoor agriculture, artificial lighting replaces natural sunlight, making every photon critical—not only in quantity but also in spectral quality. Plants require specific wavelength bands at various stages of growth. Failure to deliver the right spectral mix or uniformity can result in wasted energy, uneven growth, and reduced productivity. Structural elements such as racks, trays, and foliage introduce reflective and absorptive interactions that must be accounted for.
TracePro provides a physics-based approach to light modeling. It simulates non-sequential interactions, including reflection, absorption, transmission, and scattering. Users can import CAD files of entire grow room assemblies, apply spectral and angular emission profiles to LED sources, and analyze light behavior using irradiance maps, flux calculations, and absorbed power data. This enables designers to fine-tune fixture spacing, beam angles, and optical accessories like reflectors and diffusers.
A typical workflow begins with importing a 3D CAD model of the grow room and lighting fixture. Spectral data and angular intensity distributions are assigned to light sources, and surface properties are selected from TracePro's extensive materials library or defined by the user. Simulations are performed to assess PAR uniformity, total and absorbed flux, and light losses.
Design parameters such as optical geometries, source placement, and surface finishes are iteratively refined based on simulation output. Once optimal performance is achieved, final simulations verify thermal load distribution and efficiency before physical prototyping.
As indoor agriculture advances toward more dynamic systems—such as tunable spectrum lighting and sensor-driven feedback loops—TracePro’s capabilities are positioned to support evolving needs. With scripting automation, support for diffractive optics, and the ability to interface with external growth models, it remains a leading solution for engineers developing high-performance, energy-efficient lighting systems for precision agriculture.