The invention discloses a method of rapid generation-adding breeding of rice in the technical field of rice breeding, including soaking seeds of the rice, germination, seedlings cultivation, managing and regulating of the rice at the growth stage, and harvesting the rice. The managing and regulating the rice at the growth stage includes dynamic light quality and photoperiod control in vegetative growth period, heading period and pustulation period; growth period involves light environment regulation with the ratio of red light:blue light:white light of 0.8-1:0.8-1:1.0, photoperiod of 16-18 h; heading period involves light environment regulation with the ratio of red light:blue light:white light of 1-2:0.5-1:1, photoperiod of 12-13.5 h; and pustulation period includes light environment regulation with the ratio of red light:blue light:white light of 1-2:1:1, photoperiod of 16-18 h.

The invention discloses a method of rapid generation-adding breeding of rice in the technical field of rice breeding, including soaking seeds of the rice, germination, seedlings cultivation, managing and regulating of the rice at the growth stage, and harvesting the rice. The managing and regulating the rice at the growth stage includes dynamic light quality and photoperiod control in vegetative growth period, heading period and pustulation period; growth period involves light environment regulation with the ratio of red light:blue light:white light of 0.8-1:0.8-1:1.0, photoperiod of 16-18 h; heading period involves light environment regulation with the ratio of red light:blue light:white light of 1-2:0.5-1:1, photoperiod of 12-13.5 h; and pustulation period includes light environment regulation with the ratio of red light:blue light:white light of 1-2:1:1, photoperiod of 16-18 h.

A kit for simultaneously detecting the droplet drift or deposition of multiple sprays includes detection membranes fixed with immobilized probes, transition probes capable of specifically binding to the immobilized probes, and biotinylated chromogenic probes capable of specifically binding to the transition probes. The transition probes are added to the spray liquids as tracers. After spraying, the transition probes specifically bind to the immobilized probes on the detection membranes. The biotinylated chromogenic probes bind to the transition probes through hybridization. After the chromogenic treatment, the droplet volume is determined according to the color depth, and the spray deposition parameters of droplets are determined according to the location and size of colored spots.

A pick-and-place system for plant embryos includes a tray for receiving a suspension of plant embryos. The tray is movable to repeatedly reposition the plant embryos. An identification system is proximate the tray for identifying a target plant embryo amongst the plant embryos in the suspension. The identification system is configured to identify the target plant embryo while the tray is moving. A robotic arm is proximate the tray and is in communication with the identification system. The robotic arm is actuatable to pick the target plant embryo out of the suspension while the tray is moving, and deposit the target plant embryo at a target location.

A pick-and-place system for plant embryos includes a tray for receiving a suspension of plant embryos. The tray is movable to repeatedly reposition the plant embryos. An identification system is proximate the tray for identifying a target plant embryo amongst the plant embryos in the suspension. The identification system is configured to identify the target plant embryo while the tray is moving. A robotic arm is proximate the tray and is in communication with the identification system. The robotic arm is actuatable to pick the target plant embryo out of the suspension while the tray is moving, and deposit the target plant embryo at a target location.

A grow light system for growing plants. The grow light system can have a carrier board assembly containing a plurality of apertures and a plurality of LED modules and secondary LED modules removably engaged with the carrier board in the apertures and forming a gap between LED module and the carrier board. The grow light system can be configured to draw air through the gap over the LEDs and along the heat sink fin to reduce the temperature of the LED module. A plurality of the LED modules can be connected in series and the carrier board can include a dedicated receptacle for a single LED module that is not connected in series with the remaining LED modules.

A grow light system for growing plants. The grow light system can have a carrier board assembly containing a plurality of apertures and a plurality of LED modules and secondary LED modules removably engaged with the carrier board in the apertures and forming a gap between LED module and the carrier board. The grow light system can be configured to draw air through the gap over the LEDs and along the heat sink fin to reduce the temperature of the LED module. A plurality of the LED modules can be connected in series and the carrier board can include a dedicated receptacle for a single LED module that is not connected in series with the remaining LED modules.

The presently claimed invention is related to a method for vegetative propagation of woody plants selected from the group consisting of Eucalyptus (Eucalyptus sp.), Salix sp., olive tree (Olea europaea), rootstock Atlas (Prunus persica x Prunus dulcis x Prunus blireiana), blueberries (Vaccinum corymbosurn), Vitis vinifera, Aristotelia chilensis, Quillaja saponaria and Quercus ilex, from prepared leaf cuttings, wherein the method comprises the steps of: a) providing cuts of leaf cuttings from a donor tree, b) immersing the prepared leaf cutting into a combination of growth regulators, c) planting the prepared leaf cutting into a solid substrate of organic and/or inorganic origin, d) inducing sprouting and rooting of the prepared leaf cutting, by means of controlled ambient temperature, humidity and illumination, wherein steps a) through d) always occur outside an in vitro environment; and embodiments thereof.

The presently claimed invention is related to a method for vegetative propagation of woody plants selected from the group consisting of Eucalyptus (Eucalyptus sp.), Salix sp., olive tree (Olea europaea), rootstock Atlas (Prunus persica x Prunus dulcis x Prunus blireiana), blueberries (Vaccinum corymbosurn), Vitis vinifera, Aristotelia chilensis, Quillaja saponaria and Quercus ilex, from prepared leaf cuttings, wherein the method comprises the steps of: a) providing cuts of leaf cuttings from a donor tree, b) immersing the prepared leaf cutting into a combination of growth regulators, c) planting the prepared leaf cutting into a solid substrate of organic and/or inorganic origin, d) inducing sprouting and rooting of the prepared leaf cutting, by means of controlled ambient temperature, humidity and illumination, wherein steps a) through d) always occur outside an in vitro environment; and embodiments thereof.

A system and method for selecting plants based on climate data and plant data. The system receives climate data and plant data and selects plants for a geographical division based on the climate data and plant data. The system generates durable plant tags with for the plants that have an icon that identifies the lighting level and watering level of the plants using a color and a number.