Embodiments include methods, systems, and computer program products for generating a designer nutrition supplement for insect transport is provided. Aspects include receiving a target location and target commercial activity for an insect. Aspects include determining an arrival time window for the target location. Aspects include receiving a base nutrition supplement formula for the insect. Aspects include determining a commercially-based nutrition modification to optimize the target commercial activity. Aspects include generating a designer nutrition supplement specification based at least in part upon the commercially-based nutrition modification.

A bee cup includes a bowl, a stem, and an ultraviolet pattern. The bowl is configured to capture water for bees to drink. The stem is attached to an outside surface of a bowl and configured to support the bowl. The ultraviolet pattern is applied to an inside surface of the bowl. The ultraviolet pattern includes a center portion of a non-ultraviolet color, and alternating ultraviolet and non-ultraviolet concentric rings around the center portion.

A bee cup includes a bowl, a stem, and an ultraviolet pattern. The bowl is configured to capture water for bees to drink. The stem is attached to an outside surface of a bowl and configured to support the bowl. The ultraviolet pattern is applied to an inside surface of the bowl. The ultraviolet pattern includes a center portion of a non-ultraviolet color, and alternating ultraviolet and non-ultraviolet concentric rings around the center portion.

An artificially-created honey-yielding environment is established, including a hive and an associated flora cell, within which first and second plant populations cohabit. Within the cell, honey-producing insects from the hive are permitted to forage. One of the populations has been artificially introduced. The other may be indigenous to the cell. The first plant population serves as a primary source of nectar which yields bioactive honey and the second serves as a source of a nutrient, such as protein, which is not abundantly available from the first species at a nutritionally adequate level for sustaining the metabolism and energy of the foraging honey-producing insects for returning to the hive. The first flora population may be a Leptospermum species. An example of the second is Corymbia maculata.

An artificially-created honey-yielding environment is established, including a hive and an associated flora cell, within which first and second plant populations cohabit. Within the cell, honey-producing insects from the hive are permitted to forage. One of the populations has been artificially introduced. The other may be indigenous to the cell. The first plant population serves as a primary source of nectar which yields bioactive honey and the second serves as a source of a nutrient, such as protein, which is not abundantly available from the first species at a nutritionally adequate level for sustaining the metabolism and energy of the foraging honey-producing insects for returning to the hive. The first flora population may be a Leptospermum species. An example of the second is Corymbia maculata.

An automatic unit for one or several beehives for commercial or recreational beekeeping including honey production and pollination services comprises: (a) a plurality of bee frames (honeycomb, brood frames and other bee frames) releasably mounted within at least one hive chamber; (b) a mechanism for removing the bee frames from the hive chamber and inserting the bee frames thereinto; (c) an automated honey harvesting arrangement; (d) an arrangement for monitoring bees conditions, analyzing obtained data and reporting results to a user; and (e) an arrangement for feeding bees, pest and climate control. The mechanism for removing and inserting the bee frames comprises a frame loader linearly displaceable along at least one hive chamber.

An automatic unit for one or several beehives for commercial or recreational beekeeping including honey production and pollination services comprises: (a) a plurality of bee frames (honeycomb, brood frames and other bee frames) releasably mounted within at least one hive chamber; (b) a mechanism for removing the bee frames from the hive chamber and inserting the bee frames thereinto; (c) an automated honey harvesting arrangement; (d) an arrangement for monitoring bees conditions, analyzing obtained data and reporting results to a user; and (e) an arrangement for feeding bees, pest and climate control. The mechanism for removing and inserting the bee frames comprises a frame loader linearly displaceable along at least one hive chamber.

A Bee Hydration Station system and methods are disclosed. The bee hydration station has a flower basin or landing pod for bees to land and to collect water for bees to gather. The flower basin member has at least a first hole and a second hole; a stem member coupled to a bottom portion of the flower basin member; an inflow tube coupled to the first hole of the flower basin member; and an overflow tube coupled to the second hole of the flower basin member.

A Bee Hydration Station system and methods are disclosed. The bee hydration station has a flower basin or landing pod for bees to land and to collect water for bees to gather. The flower basin member has at least a first hole and a second hole; a stem member coupled to a bottom portion of the flower basin member; an inflow tube coupled to the first hole of the flower basin member; and an overflow tube coupled to the second hole of the flower basin member.

An insect watering station includes a bowl, a stem, and an ultraviolet pattern. The bowl is configured to capture water for bees to drink. The stem is attached to an outside surface of a bowl and configured to support the bowl. The ultraviolet pattern is applied to an inside surface of the bowl. The ultraviolet pattern includes a center portion of a non-ultraviolet color, and alternating ultraviolet and non-ultraviolet concentric rings around the center portion.