The present invention relates generally to artificial illumination, and in particular, to using diffuse scattering illumination for growing plants.
Light is a critical environmental condition, having significant effects on living organisms. In particular, light has consistent and direct effects on plants. For example, spatial variation in light irradiance on plants can affect plant growth and development. Indeed, the degree of plant growth variability is significantly influenced by light field spatial uniformity or the lack thereof.
Artificial light is often used for growing plants. Artificial light is used where natural light isn't available as well as to control undesirable variations occurring in natural illumination environments. To optimize plant growth under artificial illumination, several illumination characteristics should be considered. These characteristics include, for example, spectral content, irradiance or Photosynthetically Active Radiation (PAR) levels, spatial uniformity, shading potential, and efficiency.
To achieve optimal results, artificial lighting systems should provide spatially uniform light and promote energy efficiency. Artificial lighting systems should also maximize photon flux in the appropriate spectral range to satisfy plant photosynthesis needs. Plants typically require PAR levels between 400 and 700 nanometers for photosynthesis. In some cases, longer wavelengths (e.g., near infrared (NIR)) may be needed for healthy plant growth. To maximize photosynthetic activity, shading potential for natural light should be minimized over an entire plant area.
Several artificial lighting systems for growing plants exist. Traditionally, artificial lighting systems employed fluorescent, high pressure sodium and other conventional lighting technologies to illuminate plant canopies or suitable enclosures. Discrete light sources such as Light Emitting Diodes (LEDs), however, are replacing these traditional technologies. Because LEDs are directional in nature (i.e., they emit light in a specific direction), LEDs are typically arranged in arrays and placed above a plant canopy. To provide the required spectral distribution for optimal plant growth, different wavelength LEDs (e.g., blue and red) are often integrated into the array. In LED systems, the discrete LEDs are arranged into a pattern that produces uniform illumination with the proper spectral distribution.
Conventional artificial lighting systems are deficient in several aspects. For example, conventional systems often fail to provide a desirable intensity and quality of light so as to effectively minimize variations and maximize overall plant growth. These conventional lighting systems often lose efficiency by illuminating areas where there are no photosynthetic areas and the light is lost. In addition, the enclosures used by conventional systems may allow contamination (e.g., pests, diseases, etc.) of the plants. Conventional systems also fail to maximize efficiency. That is, they often fail to maximize growth for each energy unit of light and therefore fail to effectively reduce energy requirements.
In addition, for many plant varieties, array lighting (such as LED arrays) placed above a plant canopy produces large shadow fractions. These shadow fractions often reduce the amount of light available for photosynthesis. Shadowing from direct illumination can also limit the effectiveness of systems used to monitor a canopy or specific plant's health. Moreover, in cases where there is a desire for a large number of wavelengths, the design and fabrication of a lighting array, especially an LED array, can be complex and expensive.
Systems, apparatus, methods and articles of manufacture consistent with the present invention may obviate one or more of the above and/or other issues. In one example, systems, apparatus, methods and articles of manufacture are provided for using diffuse scattering illumination to optimize plant growth.
The present invention provides an artificial lighting system for growing plants that includes an enclosure having an internal growth chamber for containing plants. The enclosure has an outer surface that is exposed to an external environment and an inner surface that is exposed to the internal growth chamber and provides diffuse reflection. At least one light source illuminates the internal growth chamber, and the inner surface affects light from the at least one light source incident on the inner surface so as to provide substantially uniform and diffuse illumination to plants in the internal growth chamber.
The present invention also provides a method for growing plants. The method may comprise: enclosing a plant in a growth chamber; illuminating the growth chamber with light from a light source; and providing an inner surface of the growth chamber with at least one of a shape, a composition, and a texture such that the inner surface affects the light from the light source in a manner that provides a substantially uniform and diffuse illumination to the plant in the growth chamber.
Another artificial lighting system for growing plants includes means for containing plants, wherein the means for containing plants includes reflecting means exposed to the plants for providing diffuse reflection of light; and means for illuminating plants in the containing means, wherein the reflecting means manipulates light from the illuminating means to provide substantially uniform and diffuse illumination to the plants.
The present invention facilitates optimized and uniform plant growth. A desirable intensity and quality of light may be provided so as to effectively minimize variations and maximize overall plant growth. Available light may be maximized, thereby reducing the amount of light required and minimizing associated energy costs. Shadowing and contamination (pests, diseases, etc.), as well as the time required to achieve harvest-stage plants, may also be reduced. Additionally, uniform illumination of varying and complex enclosures is facilitated, which allows for effective plant stress imaging. Moreover, arrays for direct illumination are not required and various wavelengths of light may be mixed using multiple scattering, allowing for flexible and adaptable lighting.
The foregoing background and summary are not intended to be comprehensive, but instead serve to help artisans of ordinary skill understand implementations consistent with the present invention set forth in the appended claims. The foregoing background and summary are not intended to provide any independent limitations on the claimed invention or equivalents thereof.
The accompanying drawings show features of implementations consistent with the present invention and, together with the corresponding written description, help explain principles associated with the invention. In the drawings:
The following description refers to the accompanying drawings, in which, in the absence of a contrary representation, the same numbers in different drawings represent similar elements. The implementations set forth in the following description do not represent all implementations consistent with the claimed invention. Other implementations may be used and structural and procedural changes may be made without departing from the scope of present invention.
Enclosure 110 may include any suitable structure for containing or confining one or more plants 105 from an external environment. Enclosure 110 may be configured in a variety of shapes and sizes and may be formed from one or more natural, synthetic, and/or semi-synthetic materials, such as plastics, resins, fibreglass, metals, alloys, glass, acrylics, etc. Enclosure 110 may exhibit various textures and porosity depending on the requirements of the application.
Enclosure 110 may be configured so as to prevent contamination of plants 105. In one implementation, enclosure 110 may be of a suitable shape, size, texture, and porosity to keep plants 105 free of spores and other diseases. Enclosure 100 may be configured, for example, to allow for over pressuring above ambient with a filtered gas, dry air, etc. to minimize contamination from spores, insects, and/or diseases.
In one exemplary configuration, as illustrated in
Referring again to
Inner surface 114 of enclosure 110 may be exposed to internal growth chamber 116 and may be configured to affect or manipulate light. For example, inner surface 114 may be configured to affect or manipulate light incident on the inner surface 114 (e.g., light 122 from light sources 120) so as to provide substantially uniform and diffuse illumination (e.g., illumination 124) to plants 105 within internal growth chamber 116. Inner surface 114 may have an appropriate shape (e.g., dome), composition, and/or texture such that the inner surface affects light from light sources 120 in a manner that provides the substantially uniform and diffuse illumination. In one configuration, inner surface 114 may include or be coated with highly diffuse reflective material (which could be natural, synthetic, and/or semisynthetic) to affect or manipulate light and provide such illumination. For example, inner surface 114 could include or be coated with suitable compounds (e.g., barium sulfate), thermoplastic or other resins (e.g., Spectralon™, and/or polymers. Inner surface 114 may be configured to provide an appropriate uniform and diffuse reflectance so as to provide a desired illumination to plants 105. Inner surface 114 may be configured so as to provide a diffuse reflectance between 95-99.9% over a range of 350-900 nm and to be spectrally flat to ± a few percent (e.g., 4%) over the range.
Inner surface 114 may reflect and scatter light at a multitude of angles, providing diffuse reflection. Thus, light rays incident on inner surface 114 (e.g., light 122) may be distributed by multiple scattering reflections such that the directionality of the light is minimized. In one configuration, inner surface 114 may exhibit near Lambertian reflectance (i.e., perfect angular uniform scattering of light). As a Lambertian reflector, inner surface 114 may provide a surface luminance or reflected intensity that is independent of the viewing angle, with the total reflected intensity decreasing according to Lambert's cosine law.
Inner surface 114 may also be configured to spatially mix various wavelengths of light originating from light source 120, and to recycle photons to produce a highly uniform illumination. The shape, texture, and/or composition of inner surface 114 may facilitate or influence the effectiveness of such mixing. In one example, inner surface 114 may be configured in a spherical or dome-like shape to facilitate effective spatial mixing of light. Other shapes may be appropriate as long as they can efficiently mix light from various sources. Inner surface 114 may, for example, facilitate nearly 100% spatial mixing of various wavelengths and produce illumination spatial uniformities better than 1%. Examples of such various wavelengths are discussed below in connection with light sources 120.
In certain implementations, enclosure 110 may be configured to minimize energy expenditure by maximizing plant growth for each energy unit of light. Enclosure 110 may be configured to efficiently use light available from light sources 120 and to encourage absorption of light only by plant tissue. For example, inner surface 114 or enclosure 110 may provide high reflectivity and cause photosynthetic surfaces of plants 105 to become dominant absorption surfaces. That is, inner surface 114 may substantially limit light loss to that which is attributable to plant photosynthetic surfaces. Plant tissue with weak absorption can be covered by reflective surfaces to magnify the effect.
Quantitatively, inner surface 114 may cause the amount of irradiance (i.e., the power of electromagnetic radiation at a plant surface per unit area) to approach the input power divided by the effective plant absorbing surface area. This effect can be observed by considering equations (1) and (2) below.
The irradiance H for any wavelength of light inside growth chamber 116 can be expressed by the following equation:
In the above equation, ΦI is the input power at a specific wavelength, AS is the surface area of the enclosure, ρ is the surface reflectance, and f is the fraction of power lost. As the reflectance approaches unity and the fraction of power lost is dominated by the plant surfaces, the irradiance approaches input power divided by the effective plant surface. In the case where the fraction of power lost (f) equals AP/AS→0 (i.e., f=AP/AS, and ρ approaches unity), where AP is the effective plant area, then the irradiance H approaches the input power divided by effective plant surface as shown in the formula below.
As shown above, in a system with high reflectivity and limited losses other than the plant photosynthetic surfaces, the actual plant photosynthetic surfaces become the dominant absorption surfaces. In this fashion, the use of light can be maximized.
Referring again to
Light sources 120 may generate various colors or wavelengths of electromagnetic radiation. In one configuration, they may generate Photosynthetically Active Radiation (PAR), which is the spectral range of light from 400 to 700 nanometers useful for photosynthesis. In addition or as an alternative, they may also generate light in wavelengths outside the PAR range, such as ultraviolet (UV) and near-infrared (NIR) wavelengths. Wavelengths outside the PAR range could be used for various purposes, such as to provide fluorescence, for vegetation health indices, and/or to facilitate healthy plant growth.
Light sources 120 may be situated relative to enclosure 110 so as to illuminate internal growth chamber 116. For example, as depicted in
In certain configurations, light sources 120 may be arranged and/or include optional components to affect generated light. For example, light sources 120 may be baffled to minimize any direct illumination on plants 105.
The number and arrangement of light sources 120 are not limited to what is depicted in
Light sources 120 may be automated and include one or more automation, control, and/or monitoring/diagnostic components. Each of a plurality of discrete light sources 120 may be independently and individually controllable and/or operable for monitoring. Alternatively, all of the light sources may be controllable and observable as a single system. In one configuration, light sources 120 may include one or more individually controllable and observable sets of lights, each set including one or more discrete light sources. One or more external or peripheral systems may facilitate monitoring and controlling light sources 120, as discussed further below in connection with peripheral systems 150.
As discussed above, inner surface 114 may spatially mix various wavelengths of light originating from a plurality of discrete light sources 120. Inner surface 114 may, for example, facilitate spatial mixing of light in the PAR range originating from certain discrete light sources and light in the NIR range.
In one exemplary configuration, as illustrated in
Consistent with the present invention, artificial lighting system 100 may include and/or be used in conjunction with one or more peripheral systems 150. Peripheral systems 150 may include one or more components suitable for be providing system 100 with monitoring and control functionality. For example, peripheral systems 150 may provide automatic and/or remote control and monitoring of components of lighting system 100, environmental conditions, and/or inputs (e.g., nutrients and chemicals) to plants 105. Peripheral systems 150 may include various hardware, software, and/or firmware components, including imagers, detectors, sensors, combinational logic, processors and microprocessors, storage facilities, I/O devices, networks (e.g., neural networks), communication devices, and/or other suitable components. In one configuration, peripheral systems 150 may include one or more multispectral and/or hyperspectral image sensor components for providing remotely sensed imagery.
Peripheral systems 150 may be configured to detect and analyze various components and/or conditions associated with artificial lighting system 100. For example, peripheral systems 150 may be configured to detect and analyze operational information (e.g., diagnostic and state information) associated with components of lighting system 100, such as light sources 120. Peripheral systems 150 may also be configured to detect and analyze conditions within growth chamber 116 and/or conditions associated with plant 105. Peripheral systems 150 may, for example, analyze various lighting conditions such as illumination levels, spectral content, spatial uniformity, PAR levels, shading, photon flux, reflectance, transmittance, absorbance, etc. Peripheral systems 150 may also analyze other conditions such as pH levels, oxygen and carbon dioxide levels, amounts of trace gases, temperature, humidity, aerosol levels, plant stress, biomass, etc.
Peripheral devices 150 may perform monitoring and control functionality using one or more algorithms, state machines, and/or processors. Peripheral devices 150 may perform control and monitoring functionality based on various information (e.g., lighting conditions within growth chamber 116) dynamically and automatically obtained by peripheral systems 150. The monitoring and control functionality could also be based on one or more commands received from a user or system. For example, a user may input commands to one or more components of peripheral devices 150 using a data processing system, such as a desktop computer.
In one configuration, peripheral systems 150 may be configured to monitor and control illumination levels and lighting mixtures in artificial lighting system 100. In such a configuration, peripheral systems 150 may include, among other components, one or more photodetectors (not shown). For example, peripheral systems 150 may include a single photodetector and a set of spectrally filtered photodetectors to monitor and control the illumination level as well as the lighting mixture.
Peripheral systems 150 may monitor and control actuation and/or modulation of light sources 120, as well as the various wavelengths provided by each light source. In one example, systems 150 may monitor and control light sources 120 in order to produce or effect changes in illumination levels, spectral content, spatial lighting patterns, and/or temporal lighting patterns within growth chamber 116. Peripheral systems 150 may be configured to effect a desirable intensity and quality of light using light sources 120 so as to effectively minimize variations and maximize overall plant growth.
The monitoring and control of lighting sources 120 may be based on detected lighting conditions and operational information. Alternatively, the monitoring and control of light sources 120 may occur independent of detected information and conditions. For example, light sources 120 may be actuated and modulated according to a pre-determined sequence, which may be pre-stored in a memory. A combination of these approaches could also be used.
In addition to illumination, peripheral systems 150 may be configured to control and effect changes to other conditions within growth chamber 116 and/or inputs to plants 105. For example, systems 150 may be configured to adjust pH levels, temperature, or humidity. Peripheral systems 150 could also control the administration of nutrients and chemicals to plants 105. In one configuration, systems 150 may examine various measured information and then identify and implement cultivation and/or remediation in order to optimize plant growth.
Consistent with one particular implementation, peripheral systems 150 may include or be part of an “expert system” or other knowledge-based system, which may, among other things, control illumination and the addition of plant inputs. Such an expert system may be trained to analyze and evaluate various conditions, for example, using one or more heuristic techniques. The expert system may control, for example, the spatial and temporal lighting pattern within the contained area, as well as the timing and allocation of plant inputs. An exemplary “expert system” is described in co-pending U.S. patent application Ser. No. 11/312,464, filed Dec. 21, 2005, entitled “Expert System for Controlling Plant Growth in a Contained Environment,” the entire disclosure of which is herein expressly incorporated by reference.
Imaging device 160 may collect images of plants 105. This device may include and/or leverage a variety of technologies including multispectral, hyperspectral, RAMAN, thermal, luminescence, photoacoustics, black and white or color digital cameras. Imaging device 160 may be used to detect stress of plants 105 and provide images of plant biomass. Device 160 can be programmed to capture plant images on a frequent basis that allows for time-lapse photography of the growing plant. Detection of plant stresses and biomass measurements from device 160 may be used to improve plant growth. Consistent with one particular implementation, device 160 (or information from device 160) may include or be used in conjunction with an “expert system” or other knowledge-based system. Such an “expert system” is described in co-pending U.S. patent application Ser. No. 11/312,464, filed Dec. 21, 2005, entitled “Expert System for Controlling Plant Growth in a Contained Environment.”
As discussed above, artificial lighting system 100 can be configured in various shapes and sizes with various lighting arrangements.
The number and arrangement of lights 120 are not limited to the depiction in
For purposes of explanation only, certain aspects of the present invention are described herein with reference to the elements and components illustrated in
Process 500 may begin with enclosing a plant in a growth chamber (510). For example, plant 105 may be enclosed within internal growth chamber 116 of artificial lighting system 100 via one or more access ports. Once the plant is enclosed, light may be directed into the growth chamber (520). This may involve installing and activating one or more discrete light sources so as to illuminate growth chamber 116. This may also involve individually and/or collaboratively modulating and/or otherwise controlling the light sources so as to achieve certain objectives, such as desired spectral contents, illumination levels, power consumption levels, energy efficiencies, etc. In certain embodiments, directing light into the growth chamber may involve installing, operating, and/or otherwise interacting with one or more peripheral systems 150.
Once light is directed into the growth chamber, the light may be manipulated so as to provide a substantially uniform and diffuse illumination to the plant in the growth chamber (530). This manipulation may be achieved by way of enclosure 110. For example, enclosure 100 may be configured such that inner surface 114 manipulates light and provides the uniform and diffuse illumination. This could also involve appropriately monitoring and adjusting the uniformity and diffuseness of light within growth chamber 116 to achieve certain objectives, such as those mentioned above. The manipulation stage may, in certain embodiments, involve interacting with one or more peripheral systems 150.
In certain embodiments, process 500 may also include various supplemental sub-processes and stages. For example, process 500 may include various monitoring processes that occur at various times during the process. Such monitoring could include monitoring plant stress levels, conditions within the growth chamber, conditions external to the growth chamber, levels of plant inputs, etc. In addition to monitoring, process 500 may also include, for example, performing various calculations, executing algorithms, receiving and processing user and other inputs, recommending and effecting inputs to plants and various remediation measures, and/or controlling various systems and components.
The following description is intended merely to introduce some possible benefits and applications of the present invention. It is not intended to be a comprehensive list of all possible benefits and applications or of all details and variations of those benefits and applications described. In addition, the following description is not intended to provide any independent limitations on the claimed invention or its equivalents.
Plant Growth Facilities
A plant growth facility (e.g., a green house) typically provides a confined space in which desirable environmental conditions for plant growth can be maintained. To be effective, plant growth facility designs must satisfy at least the fundamental water, air, and light requirements for plant growth and survival. Incorporating uniform and diffuse illumination consistent with the present invention to plant growth facility designs could yield at least some of the benefits discussed above.
Tissue Culture Propagation
Tissue culture involves the propagation of plant and animal cells through the placement of small amounts of tissue in an artificial environment. A plant would respond to tissue culture if a suitable formula and process were developed for its culture. For plant tissue culture, a portion of the plant (e.g., stem, root, leaf, bud, single cell, etc.) would be placed in a test tube or other suitable structure. The portion of the plant would form plantlets, given a sterile environment and a balanced nutrient medium. These plantlets would multiply indefinitely if given proper care and could then be taken out of the tissue culture environment and planted normally. Using tissue culture, the plant environment can be controlled and optimized such that all of the plants from the tissue culture are identical for a particular desired quality, such as resistance to plant diseases or production of a plant chemical.
Incorporating aspects of the present invention to tissue culture processes may benefit tissue culture in a variety of ways. First, it could accelerate the growth of plantlets, which would reduce propagation time and expense. Second, it could increase the uniformity of tissue being cultured, thus providing more desirable plants. Third, it could eliminate or reduce contamination that may occur in current propagation processes. Conducting tissue culture propagation in a sphere or other contained configuration (e.g., cave, bunker, balloon, etc.) that would allow for implementation of aspects of the present invention could minimize or even eliminate exposure to external contaminants. Such an enclosed environment could allow for the over pressuring slightly above ambient with a filtered gas, dry air, etc. during the plant introduction and during the plant growth phases to minimize the introduction of spores.
Biopharming or Molecular Farming
Plants are frequently used to produce pharmaceuticals. Often, specific proteins grown in plants (e.g., tobacco, sweet potatoes, etc.) are extracted to produce various pharmaceutical products. Growing these protein-specific plants on the Earth's surface, however, has raised considerable concern. Incorporating aspects of the present invention to biopharming techniques could alleviate much of this concern. Aspects of the present invention could provide an alternative approach by growing in an environment contained above the Earth's surface or below the Earth's surface. As an example, biopharming could be carried out in a salt dome where plants are grown on stacked trays and the dome is configured to allow implementation of aspects of the present invention.
The foregoing description is not intended to be limiting. The foregoing description does not represent a comprehensive list of all possible implementations consistent with the present invention or of all possible details and variations of the implementations described. Those skilled in the art will understand how to implement the invention in the appended claims in many other ways, using equivalents and alternatives that do not depart from the scope of the following claims.