Abstract: A hybrid twin process uses an independent mechanical destructive process and an illumination process to change of state of weed seeds to having reduced germination viability by illuminating a seed with at least one of 2 J/cm2 cumulative illumination energy, and 0.2 W/cm2 irradiance, but no more than 7 W/cm2 average irradiance, of at least one of an Indigo Region Illumination Distribution (IRID), and infrared radiation that is substantially Medium Wavelength Infrared (MWIR) radiation, preferably 2-8 microns. The process can be incorporated into a harvester combine to convert a tailings flow prior to discharge on an agricultural field. For the mechanical destructive process, high required applied energy, noise, wear, and difficulty treating impact-resistant seeds are avoided by modifying a driven load flow via increased capability of exposure to illumination and underdriving the mechanical destructive process. This can include randomization, rarefaction and enhanced circulation.

Abstract: Plant eradication and stressing of plants using illumination signaling where a short-time dual component, low energy, unnatural set of irradiances is applied, with no mutagenic or high radiative energy transfers in any wavelength for eradication by substantial high temperature thermally-induced leaf and plant component failure or incineration. An Indigo Region Illumination Distribution of wavelength 300 nm to 550 nm is directed to plant foliage and/or a plant root crown, while infrared radiation that is substantially Medium Wavelength Infrared radiation of 2-20 microns wavelength, 2.4-8.0 microns preferred, is directed to a plant root crown and/or soil immediately adjacent the root crown. The Indigo Region Illumination Distribution can pass through the MWIR emitter to form a compact illuminator that uses specific unnatural irradiances that provide unexpected plant control. The MWIR emitter can comprise borosilicate glass at 400° F. to 1000° F.

Abstract: Rapid pulse programming of a seed, to obtain improved germination probability, and increased root mass, and crop yield, by illuminating the seed with radiation of a wavelength distribution from 300 nm to 20 microns, with a minimum average irradiance of 0.2 Watts/cm2 and a maximum average irradiance of 7 Watts/cm2, and having a narrow specific range of cumulative illumination energy from ½ Joules/cm2 to 3 Joules/cm2 or a higher transition point cumulative illumination energy, so as to specifically engage an irradiance-sensitive and energy-sensitive hidden stimulative exposure response in the seed and so as to avoid illumination of higher cumulative illumination energy that would cause a different and destructive exposure response in the seed. Preferred wavelengths include one or both of Medium Wavelength Infrared (MWIR) radiation and an Indigo Region Illumination Distribution (IRID), which may be applied to an illuminated agricultural planter.

Abstract: Plant eradication and stressing of plants using illumination signaling where a short-time dual component, low energy, unnatural set of irradiances is applied, with no mutagenic or high radiative energy transfers in any wavelength for eradication by substantial high temperature thermally-induced leaf and plant component failure or incineration. An Indigo Region Illumination Distribution of wavelength 300 nm to 550 nm is directed to plant foliage and/or a plant root crown, while infrared radiation that is substantially Medium Wavelength Infrared radiation of 2-20 microns wavelength, 2.4-8.0 microns preferred, is directed to a plant root crown and/or soil immediately adjacent the root crown. The Indigo Region Illumination Distribution can pass through the MWIR emitter to form a compact illuminator that uses specific unnatural irradiances that provide unexpected plant control. The MWIR emitter can comprise borosilicate glass at 400° F. to 1000° F.

Abstract: Plant eradication and stressing of plants using illumination signaling where a short-time dual component, low energy, unnatural set of irradiances is applied, with no mutagenic or high radiative energy transfers in any wavelength for eradication by substantial high temperature thermally-induced leaf and plant component failure or incineration. An Indigo Region Illumination Distribution of wavelength 300 nm to 550 nm is directed to plant foliage and/or a plant root crown, while infrared radiation that is substantially Medium Wavelength Infrared radiation of 2-20 microns wavelength, 2.4-8.0 microns preferred, is directed to a plant root crown and/or soil immediately adjacent the root crown. The Indigo Region Illumination Distribution can pass through the MWIR emitter to form a compact illuminator. The MWIR emitter can comprise borosilicate glass at 400° F. to 1000° F.

Abstract: Plant eradication and stressing of plants using illumination trauma where a dual component, low energy, unnatural set of irradiances is applied, with no mutagenic or high radiative energy transfers in any wavelength for eradication by severe scalding, heat shock, or incineration. Two radiations are applied: an Indigo Region Illumination Distribution that can extend from 300 nm to 550 nm to be directed to plant foliage and/or a plant root crown, and a Medium Wavelength Infrared distribution of light, ranging from 2-20 microns wavelength to be directed to the ground, to a plant root crown and/or soil immediately adjacent the root crown. Plants can include seeds, and seedlings, and biomass can be irradiated to control weed seeds such as from a combine. The Indigo Region Illumination Distribution can pass through the MWIR emitter to form a compact illuminator. The MWIR emitter can comprise borosilicate glass at 400 F to 1000 F.

Abstract: A field image is formed using a tristimulus color model and used to detect target plants or entities on a field. Through the use of a luminance parameter floor, hue and saturation selection steps, feature recognition, a sizing floor and an aspect ratio ceiling, a very fast way is devised to recognize a target plant without need for consulting plant attribute databases, or to analyze spectral or other specialized data for comparison with known attributes. This allows a low calculational processing load and use of simple hardware such as a single board computer to handle machine vision in real time. Treatment steps can include a spray event, a light treatment, and a thermal/mechanical trauma.

Abstract: Non soil-invasive four-parameter rapid unnatural dual component selective illumination protocol (UDCIP) for plant eradication using a process time under one minute. Application of a relatively low level of non-mutating UV-A optical energy to root crowns and/or soil grades allows below-ground UV-A penetration into soil to illuminate root crowns, and when preceded by or coincident with an above ground near-IR defoliation and root crown illumination step, results in an unexpected rise in lethality. Very high lethality, including 100 percent, is obtained using low deposited energy. UV-A optical energy can be delivered to root crowns and adjacent soil via a UV-transmissive knive blade.

Abstract: Plant eradication using by inflicting upon a plant root (R) unnatural hot wound mechanical and thermal trauma delivered from a hot stab knife (V) which produces a stab gash (K) sufficiently deep to traverse plant cortex (C) and penetrate to plant xylem (X), simultaneous with or followed by heating the damaged area to a temperature of higher than 70 C, preferably 200 C for a sufficient time to cause cellular damage to the plant root. The root and hot stab knife may be shrouded to increase the temperature adjacent the stab gash. Preferably, the stab knife is formed to be sufficiently acuate and flat so as to allow a surface/volume ratio for the stab knife to be at least twice that of a cone of similar size and extent. Unhealable damage results, believed to caused by role conversion of organisms in the rhizosphere from sybiosis to antagonism.

Abstract: Plant eradication using by inflicting upon a plant root (R) unnatural hot wound mechanical and thermal trauma delivered from a hot stab knife (V) which produces a stab gash (K) sufficiently deep to traverse plant cortex (C) and penetrate to plant xylem (X), simultaneous with or followed by heating the damaged area to a temperature of higher than 70 C, preferably 200 C for a sufficient time to cause cellular damage to the plant root. The root and hot stab knife may be shrouded to increase the temperature adjacent the stab gash. Preferably, the stab knife is formed to be sufficiently acuate and flat so as to allow a surface/volume ratio for the stab knife to be at least twice that of a cone of similar size and extent. Unhealable damage results, believed to caused by role conversion of organisms in the rhizosphere from sybiosis to antagonism.

Abstract: Plant eradication using by inflicting upon a plant root (R) unnatural hot wound mechanical and thermal trauma delivered from a hot stab knife (V) which produces a stab gash (K) sufficiently deep to traverse plant cortex (C) and penetrate to plant xylem (X), simultaneous with or followed by heating the damaged area to a temperature of higher than 70 C, preferably 200 C for a sufficient time to cause cellular damage to the plant root. The root and hot stab knife may be shrouded to increase the temperature adjacent the stab gash. Preferably, the stab knife is formed to be sufficiently acuate and flat so as to allow a surface/volume ratio for the stab knife to be at least twice that of a cone of similar size and extent. Unhealable damage results, believed to caused by role conversion of organisms in the rhizosphere from symbiosis to antagonism.

Abstract: Controlled gap thin blade shear process to cut grass using a low energy sickle mower. A thin dull blade moves without interference across a stator. Blades and stators are not biased or pressed together while cutting, but rather the cutting blade is guidingly supported by upper and lower stators formed and positioned to maintain forceably a total controlled gap (Z) therebetween of preferably 1-5 mils. The cutting blade is thin (10-50 mils). Tensile failure of grass is avoided. Torque management system performs motor load monitoring and modulation of blade position. To reject obstructions and clean the blade, the blade can reverse, jitter, or reciprocate. Instead of attempting to slice or slam through obstructions using a high torque prime mover, a low energy low torque prime mover is utilized with intelligent reversing, obstruction clearing, and blade cleaning that saves energy, reduces noise, rejects obstructions, and prevents blade damage or operator injury.