A planting method for morels is disclosed, including the following steps of: (1) preparing spawn; (2) flipping the spawn; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawn, thereby reducing planting costs and product costs.

A planting method for morels is disclosed, including the following steps of: (1) preparing spawn; (2) flipping the spawn; (3) managing the humidity; and (4) fruiting for harvesting. The planting method is simple, is easy to learn and promote, has a high yield, and requires few spawn, thereby reducing planting costs and product costs.

A system that is able to vary a depth of a row cleaner by adjusting a downforce applied to the row cleaner to promote planting at a desired seed depth and soil moisture.

A system that is able to vary a depth of a row cleaner by adjusting a downforce applied to the row cleaner to promote planting at a desired seed depth and soil moisture.

In one aspect, a system for controlling the operation of a seed-planting implement may include a ground-engaging tool and an actuator configured to adjust an operating parameter of the ground-engaging tool. Furthermore, the system may include a controller configured to control the operation of the seed-planting implement such that a primary crop is planted in a field as the seed-planting implement is being moved across the field. Additionally, the controller may be configured to determine a density of a cover crop present within the field. Moreover, the controller may be configured to determine an adjustment to be made to the operating parameter of the ground-engaging tool based on the determined density. In addition, the controller may be configured to control the operation of the actuator to execute the adjustment of the operating parameter.

In one aspect, a system for controlling the operation of a seed-planting implement may include a ground-engaging tool and an actuator configured to adjust an operating parameter of the ground-engaging tool. Furthermore, the system may include a controller configured to control the operation of the seed-planting implement such that a primary crop is planted in a field as the seed-planting implement is being moved across the field. Additionally, the controller may be configured to determine a density of a cover crop present within the field. Moreover, the controller may be configured to determine an adjustment to be made to the operating parameter of the ground-engaging tool based on the determined density. In addition, the controller may be configured to control the operation of the actuator to execute the adjustment of the operating parameter.

A method for planting crops that involves covering the planted seeds of the crop with an elongate sheet of mulch. The elongate sheet of mulch has lateral edges that determine its width. A combustible cord that is affixed to it between the lateral edges. The combustible cord may be formed within plies of the mulch or adhered thereto. The mulch is placed over the planted crop and held in place over the crop. This may be done by burying lateral edges of the mulch. When a user of the mulch wishes to remove the mulch, he will burn the combustible cord and that will separate the mulch along the cord.

A method for planting crops that involves covering the planted seeds of the crop with an elongate sheet of mulch. The elongate sheet of mulch has lateral edges that determine its width. A combustible cord that is affixed to it between the lateral edges. The combustible cord may be formed within plies of the mulch or adhered thereto. The mulch is placed over the planted crop and held in place over the crop. This may be done by burying lateral edges of the mulch. When a user of the mulch wishes to remove the mulch, he will burn the combustible cord and that will separate the mulch along the cord.

A method for soil moisture retrieval using multi-channel collaboration algorithm and passive microwave radiometry including: establishing mathematical relationship formula between brightness temperatures at any two channels according to microwave radiative transfer equation; collecting actual brightness temperatures of core channel and collaborative channels; selecting parameters to be retrieved including soil moisture value; giving a series of estimated values of parameters to be retrieved, calculating a series of predicted brightness temperatures of collaborative channels according to actual brightness temperature of core channel, microwave radiative transfer equation and mathematical relationship formula, comparing predicted brightness temperatures with actual brightness temperature, and determining soil moisture value.

A method for soil moisture retrieval using multi-channel collaboration algorithm and passive microwave radiometry including: establishing mathematical relationship formula between brightness temperatures at any two channels according to microwave radiative transfer equation; collecting actual brightness temperatures of core channel and collaborative channels; selecting parameters to be retrieved including soil moisture value; giving a series of estimated values of parameters to be retrieved, calculating a series of predicted brightness temperatures of collaborative channels according to actual brightness temperature of core channel, microwave radiative transfer equation and mathematical relationship formula, comparing predicted brightness temperatures with actual brightness temperature, and determining soil moisture value.