Abstract: A system for distributing seeds includes a storage tank operable to store a plurality of seeds. A seed-on-demand distribution system is operable to transfer at least some seeds of the plurality of seeds from the storage tank to a distribution system outlet. A dispersion unit has an inlet, a first outlet, and a second outlet. The inlet is in communication with the distribution system outlet. The first outlet is in communication with a first secondary conduit. The second outlet is in communication with a second secondary conduit. A first volumetric meter is operable to volumetrically meter at least some seeds of the plurality of seeds from the first secondary conduit. A second volumetric meter is operable to volumetrically meter at least some seeds of the plurality of seeds from the secondary conduit.

Abstract: A row unit for a seeding machine. The row unit includes a frame, a first gauge wheel arm pivotally coupled to the frame, a first gauge wheel coupled to the first gauge wheel arm, a second gauge wheel arm pivotally coupled to the frame, a second gauge wheel coupled to the second gauge wheel arm, and a position sensor assembly having a position sensor at least partially disposed between the first gauge wheel arm and the second gauge wheel arm such that the position sensor is at least partially concealed from view between the first and second gauge wheels when viewing the row unit along an axis of rotation of the first gauge wheel.

Abstract: The measurement device comprises a transmitter for providing a transmitted signal at a frequency. The transmitter provides the transmitted signal to the transmitting antenna. A receiving antenna is arranged to receive the transmitted signal. A receiver is capable of receiving the transmitted signal from the receiving antenna. An electronic data processor is adapted to measure an observed parameter of the transmitted signal between the transmitting antenna and the receiving antenna to estimate the precise yield, where the observed parameter comprises observed attenuation, phase or both of the transmitted signal, as received at the receiver.

Abstract: A data processor retrieves or accesses a reference bin level versus reference phase for a determined seed type. A measurement device, receiver, or phase measurement module measures an observed phase of a primary received signal. The data processor is adapted to determine an estimated bin level of seeds, where the estimated bin level is established as the reference bin level that corresponds to a respective reference phase that is closest in value to the observed phase.

Abstract: A method dynamically reconstructing a stress and strain field of a turbine blade includes providing a set of response measurements from at least one location on a turbine blade, band-pass filtering the set of response measurements based on an upper frequency limit and a lower frequency limit, determining an upper envelope and a lower envelope of the set of response measurements from local minima and local maxima of the set of response measurements, calculating a candidate intrinsic mode function (IMF) from the upper envelope and the lower envelope of the set of response measurements, providing an N×N mode shape matrix for the turbine blade, where N is the number of degrees of freedom of the turbine blade, when the candidate IMF is an actual IMF, and calculating a response for another location on the turbine blade from the actual IMF and mode shapes in the mode shape matrix.

Abstract: A detection system for a turbine engine that is configured to identify the presence of at least a partial blockage of guide vanes by monitoring deflection of an adjacent row of turbine blades. The detection system may include one or more sensors positioned radially outward from tips of turbine blades in a row of turbine blades adjacent an upstream row of guide vanes that remain stationary. The detection system may also include a conditioning module in communication with the sensor to amplify the output signals received from the sensor. A processing module may be in communication with conditioning module to analyze signals produced by the sensor via the conditioning module and generate an alarm if the processing module detects a change in amplitude, such as an increase of amplitude at frequencies between about 400 Hertz and about 900 Hertz.

Abstract: A row unit for a seeding machine. The row unit includes a frame, a first gauge wheel arm pivotally coupled to the frame, a first gauge wheel coupled to the first gauge wheel arm, a second gauge wheel arm pivotally coupled to the frame, a second gauge wheel coupled to the second gauge wheel arm, and a position sensor assembly having a position sensor at least partially disposed between the first gauge wheel arm and the second gauge wheel arm such that the position sensor is at least partially concealed from view between the first and second gauge wheels when viewing the row unit along an axis of rotation of the first gauge wheel.

Abstract: A data processor retrieves or accesses a reference bin level versus reference phase for a determined seed type. A measurement device, receiver, or phase measurement module measures an observed phase of a primary received signal. The data processor is adapted to determine an estimated bin level of seeds, where the estimated bin level is established as the reference bin level that corresponds to a respective reference phase that is closest in value to the observed phase.

Abstract: The measurement device comprises a transmitter for providing a transmitted signal at a frequency. The transmitter provides the transmitted signal to the transmitting antenna. A receiving antenna is arranged to receive the transmitted signal. A receiver is capable of receiving the transmitted signal from the receiving antenna. An electronic data processor is adapted to measure an observed parameter of the transmitted signal between the transmitting antenna and the receiving antenna to estimate the precise yield, where the observed parameter comprises observed attenuation, phase or both of the transmitted signal, as received at the receiver.

Abstract: An agricultural planting machine is described. In one example, the machine comprises a trench opener configured to open a trench, and a trench depth sensing system comprising a ground-engaging component and a trench depth sensor configured to generate a signal indicative a displacement of the ground-engaging component by directly sensing a surface of the ground engaging component. In one example, an agricultural planting machine comprising a trench opener configured to open a trench, and a trench depth sensing system comprising a ground-engaging component and a capacitive sensor comprising a transmitter element driven by an input signal to generate an electric field and a receiver element configured to generate an output signal based on a capacitive coupling between the transmitter and receiver elements, wherein the capacitive coupling changes based on movement of the ground-engaging component within the electric field.

Abstract: An agricultural planting machine is described. In one example, the machine comprises a trench opener configured to open a trench, and a trench depth sensing system comprising a ground-engaging component and a trench depth sensor configured to generate a signal indicative a displacement of the ground-engaging component by directly sensing a surface of the ground engaging component. In one example, an agricultural planting machine comprising a trench opener configured to open a trench, and a trench depth sensing system comprising a ground-engaging component and a capacitive sensor comprising a transmitter element driven by an input signal to generate an electric field and a receiver element configured to generate an output signal based on a capacitive coupling between the transmitter and receiver elements, wherein the capacitive coupling changes based on movement of the ground-engaging component within the electric field.

Abstract: A method and system for determining a distance from a probe to an object includes generating a first electric field by applying a first signal across a first pair of electrodes aligned along a first axis and generating a second electric field by applying a second signal across a second pair of electrodes aligned along a second axis substantially perpendicular to the first axis. After generating the signals, a first change in the first signal due to the object interacting with the first electric field and a second change in the second signal due to the object interacting with the second electric field is concurrently detected. A distance of the object from the first and second pair of electrodes can be calculated based on a ratio of the first and second changes.

Abstract: A detection system for a turbine engine that is configured to identify the presence of at least a partial blockage of guide vanes by monitoring deflection of an adjacent row of turbine blades. The detection system may include one or more sensors positioned radially outward from tips of turbine blades in a row of turbine blades adjacent an upstream row of guide vanes that remain stationary. The detection system may also include a conditioning module in communication with the sensor to amplify the output signals received from the sensor. A processing module may be in communication with conditioning module to analyze signals produced by the sensor via the conditioning module and generate an alarm if the processing module detects a change in amplitude, such as an increase of amplitude at frequencies between about 400 Hertz and about 900 Hertz.

Abstract: A first slave electronic module and a second slave electronic module are adapted for communicating over the data bus. The first slave electronic module has a first resistor coupled in series with a main power line. The second electronic module has a second resistor coupled in series with the main power line. A master electronic module has a master current measurement circuit for determining an aggregate current level indicative of the total number of slave electronic modules on the main power line. A first current measurement circuits is capable of measuring a node current indicative of a number of other active slaves connected to the main power line and data bus. A master data processor in the master electronic module is arranged to assign a unique module identifier to a first slave electronic module based on the first node current and the aggregate current level, the unique module identifier indicating a respective position of the first slave electronic module on the data bus.

Abstract: A method and system for determining a distance from a probe to an object includes generating a first electric field by applying a first signal across a first pair of electrodes aligned along a first axis and generating a second electric field by applying a second signal across a second pair of electrodes aligned along a second axis substantially perpendicular to the first axis. After generating the signals, a first change in the first signal due to the object interacting with the first electric field and a second change in the second signal due to the object interacting with the second electric field is concurrently detected. A distance of the object from the first and second pair of electrodes can be calculated based on a ratio of the first and second changes.

Abstract: A method dynamically reconstructing a stress and strain field of a turbine blade includes providing a set of response measurements from at least one location on a turbine blade, band-pass filtering the set of response measurements based on an upper frequency limit and a lower frequency limit, determining an upper envelope and a lower envelope of the set of response measurements from local minima and local maxima of the set of response measurements, calculating a candidate intrinsic mode function (IMF) from the upper envelope and the lower envelope of the set of response measurements, providing an N×N mode shape matrix for the turbine blade, where N is the number of degrees of freedom of the turbine blade, when the candidate IMF is an actual IMF, and calculating a response for another location on the turbine blade from the actual IMF and mode shapes in the mode shape matrix.

Abstract: A seed sensor system determines the position of the seed relative to the seed tube as the seed passes the sensor. The position of the seed as well as the speed of the planter and the position of the seed tube above the planting furrow are used to calculate trajectory of the seed into the furrow from which the seed spacing is predicated. By sensing the seed in both X and Y directions in the seed tube, the sensor is better able to determine multiple seeds as well providing more precision to the seed population.

Abstract: A tilt sensor and method comprises a first accelerometer for measuring a first acceleration level associated with a first axis of the vehicle. A second accelerometer measures a second acceleration level associated with a second axis of the vehicle that is generally perpendicular to the first axis. A data processor is capable of determining an arcsine-derived tilt based on an arcsine equation and the determined first acceleration level. The data processor is capable of determining an arc-cosine-derived tilt based on an arccosine equation and the determined second acceleration level. The data processor comprises a selector for selecting the arcsine-derived tilt as the final tilt of the vehicle if the determined arcsine-derived tilt is lesser than the determined arccosine derived tilt such that the final tilt compensates for vertical acceleration associated with changes in the terrain in the direction of travel of the vehicle.

Abstract: A row crop unit for use in an agricultural seeder includes a furrow opener for opening a furrow in the soil, a seed metering system for metering seed to be placed in the furrow, and a seed placement system for placing seeds in the furrow. The seed placement system and the seed metering system are in communication with each other and at least in part define a seed travel path associated with the furrow. A furrow closer covers the seed in the furrow with soil. A seed temperature conditioner is associated with the seed travel path for varying a temperature of seed traveling through the seed travel path. A temperature sensitive sensor is positioned to sense seed which has been deposited in the furrow between the furrow opener and the furrow closer. An optional packaging tube holds a temperature sensor or sensor array. A lens is mounted with the same tube. A larger diameter tube may be positioned around the sensor packaging tube. A positive air pressure/air flow may be introduced between the two tubes.

Abstract: A tilt sensor and method comprises a first accelerometer for measuring a first acceleration level associated with a first axis of the vehicle. A second accelerometer measures a second acceleration level associated with a second axis of the vehicle that is generally perpendicular to the first axis. A data processor is capable of determining an arcsine-derived tilt based on an arcsine equation and the determined first acceleration level. The data processor is capable of determining an arc-cosine-derived tilt based on an arccosine equation and the determined second acceleration level. The data processor comprises a selector for selecting the arcsine-derived tilt as the final tilt of the vehicle if the determined arcsine-derived tilt is lesser than the determined arccosine derived tilt such that the final tilt compensates for vertical acceleration associated with changes in the terrain in the direction of travel of the vehicle.