Abstract: A control and a method of control for a machine that applies a material to a subgrade at a work site and pulls a floating screed, having a screed plate, over the top surface of the material behind the machine is useful in paving with asphalt material. The floating screed is attached to the machine by a tow arm at a tow point on said tow arm. The vertical height of the tow point is controlled by an hydraulic cylinder on said machine in response to a valve control signal applied to an hydraulic valve by a valve control drive. The screed determines the thickness of the material on the subgrade and is manipulated by adjusting the height of the tow point. A first sensor is mounted on the floating screed for sensing three-dimensional position. A second sensor for senses the pitch of said screed. A processor circuit is responsive to the first and second sensors for determining the height of the trailing edge of the screed plate and the movement of the screed over the top surface of the material.

Abstract: A control system for controlling movement of individual hydraulically moveable ends of a screed head carried by a boom of a machine so as to maintain a selected elevation position between each end of the screed head and a reference in a concrete paving application as the screed head is moved toward the machine, includes elevation receivers mounted on the ends of the screed head, and a first sensor for sensing the orientation of the screed head along its length from the first end to the second end of the screed head. A second sensor senses rotational movement of the machine which will induce an error in the output of the first sensor, and providing an output indicating such rotational movement.

Abstract: A machine control and guidance system for an earthmoving machine, includes one or more sensors and a portable digital media device mounted on the earthmoving machine. The portable digital media device may comprise an iPhone, an iTouch, or other similar device. Each of the sensors senses the position or orientation of a portion of the earthmoving machine and provides a wireless output signal indicating the position or orientation. The portable digital media device is in wireless communication with each of the sensors. The device has an associated display and a memory in which is stored an application program which permits the device to determine the position of one or more portions of the earthmoving machine and to display the position of one or more portions of the earthmoving machine on the display.

Abstract: A GPS reception arrangement includes a GPS radome body having an upper body portion, a lower body portion and a peripheral body portion between the upper body portion and the lower body portion and extending circumferentially there around, and a GPS antenna positioned inside the radome body. A plurality of light sources on the peripheral body portion of the radome body project light in a manner to identify the GPS radome, and distinguish it from other radomes. Retroreflective material is positioned around the radome body on the peripheral body portion, adjacent the plurality of light sources.

Abstract: An earthmoving system, includes in one embodiment a laser transmitter for transmitting a reference beam of laser light, and a laser receiver mounted on a mast on the bulldozer blade. The bulldozer has a frame and a cutting blade supported by a blade support extending from said frame. The blade support includes hydraulic cylinders for raising and lowering the blade in relation to said frame, and for tilting the blade along its length. The mast extends upward from, and is movable with, the blade. An inclinometer is mounted for movement with the blade to provide an indication of the inclination of the blade. A sensor detects turning of the bulldozer. A control is responsive to the laser receiver, to the inclinometer, and to the sensor, for controlling the operation of said cylinders and adjusting the position of said blade. When rapid turning of said bulldozer is detected the control operates to reduce the errors that would otherwise result from an erroneous inclinometer output.

Abstract: A loader and a control system for a loader provide for monitoring the position of a part of the implement carried by the loader. The loader has a body with left and right upright tower portions, and a loader drive system including ground engaging drive elements. Left and right interconnected lift arm assemblies each have an implement lift arm pivotally connected with a corresponding tower portion of the body at a lift arm pivot point. A lift actuator is connected between the body and the lift arm. The implement is pivotally connected with the lift arm assemblies about an implement pivot axis. The lift arm pivot point and the implement pivot axis in side elevation define a straight reference line. At least one implement tilt actuator is connected between at least one of the lift arm assemblies and the implement. A position sensor is mounted on the body at the level of, or above, the lift arm pivot points.

Abstract: A terminator for a CAN bus includes an electronic relay and a termination impedance. The electronic relay has first and second control input conductors and switched output conductors. The electrical connection between the switched output conductors is normally closed. The first control input conductor is connected to the power conductor and the second control input conductor is connected to a fifth terminal of the first CAN bus connector. The termination impedance is connected in series at the end node of the CAN bus with the switched output conductors across the high data conductor and the low data conductor. By this arrangement, the termination impedance is effectively connected across the high data conductor and the low data conductor at the end node of the CAN bus until an extension of the CAN bus is plugged into the first CAN bus connector. When an extension of the CAN bus is plugged into the first CAN bus connector, the fifth terminal of the CAN bus connector is connected to the ground conductor.

Abstract: A control system for a tool coupling of the type that attaches a tool to an excavator dipper stick and provides for rotation of the tool with respect to the dipper stick about an axis, and further provides for tilting of the tool, includes a rotation sensor and a tilt sensor. The rotation sensor is mounted on the coupling for determining the amount of rotation of the tool with respect to the dipper stick about an axis. The tilt sensor is mounted on the coupling for determining the amount of tilt of the tool with respect to gravity. A control is responsive to the rotation sensor and to the tilt sensor for determining the orientation of the tool.

Abstract: A GPS reception arrangement includes a GPS radome body having an upper body portion, a lower body portion and a peripheral body portion between the upper body portion and the lower body portion and extending circumferentially there around, and a GPS antenna positioned inside the radome body. A plurality of light sources on the peripheral body portion of the radome body project light in a manner to identify the GPS radome. Retroreflective material is positioned around the radome body on the peripheral body portion, adjacent the plurality of light sources.

Abstract: A system and method for sensing surface compaction effected by a compactor machine of the type having a vibrating compacting roller, and providing a sensor signal indicating sensed surface compaction to a control mounted on the compactor machine, includes a sensor for sensing compaction and providing a signal indicating sensed surface compaction. The sensor is mounted on the compacting roller support of the compactor machine. The system includes a vibration-to-electric energy converter, mounted with the sensor on the compacting roller support and subjected to vibration. The converter converts the vibration energy to electric energy which may be supplied to the sensor and to a transmitter. The transmitter is powered by the electric energy from said vibration-to-electric energy converter and transmits the sensor signal to a receiver on the machine. The receiver provides the sensor signal to a control for the machine.

Abstract: Systems and methods for sharing terrain data among one or more machines include a communications system associated with the one or more machines in electronic communication with each other and to a communications system associated with a remote location. The terrain data may be determined from information received from satellite positioning systems. New information comprising alterations to a worksite by one or more machines may be stored as a snippet. Collected snippets may be combined to form a data block which is sent to one or more identified machines. A bitmap, corresponding to each snippet, is sent to the one or more identified machines in order to locate the new information in the data block. Using the new information, the one or more identified machines may update a composite model of the worksite located at each of the one or more identified machines.

Abstract: System and method for automatically adjusting control gains on an earthmoving machine include a control system for controlling mechanisms that supply power to an earthmoving implement. The gains associated with the force to the implement are automatically adjusted depending on a blade load that may be determined by a calculation of torque attributable to a blade load. The control gains include a proportional gain and a derivative gain that may be used to determine a control effort lift command associated with the control gains for supplying an appropriate gain to the mechanisms that control the implement.

Abstract: A three dimensional machine scanning arrangement for a machine traveling over a worksite includes a pair of scanners that are mounted on the machine. Each of the pair of scanners measures distances to a number of points on the ground at the worksite. One of the pair of scanners faces rearward and the other of the pair of scanners is faces forward. A control is responsive to the pair of scanners. The control determines the contour of the worksite. A display, mounted on the machine, is responsive to the control for displaying the contour of the worksite.

Abstract: Systems and methods for controlling an implement based upon a gear shift include a shift detector circuit which detects a direction of the gear shift and an implement controller circuit which adjusts an implement in response to the direction of the gear shift.

Abstract: A control is provided for a machine that applies a material to a subgrade and pulls a floating screed over the top surface of the material behind the machine. The floating screed is attached to the machine by at least one tow arm at a tow point on the tow arm. The vertical height of the tow point is controlled by a hydraulic cylinder on the machine in response to a valve control signal applied to a hydraulic valve. The screed determines the thickness of the material on the subgrade as it is manipulated by adjusting the height of the tow point such that the top surface of the material follows a reference surface. A first sensor is mounted on the machine, adjacent the front of the machine, for sensing the relative height of the reference surface and providing a first sensor output related thereto. A second sensor for senses the height of the tow point relative to the machine and provides a second sensor output related thereto.

Abstract: A system and a method sense the inclination of a machine element, such as a platform, and eliminate tangential and radial acceleration errors. The platform defines orthogonal X and Y axes, and is rotatable about a Z axis. An inclinometer, mounted on the platform at a location spaced from the axis of rotation by a distance r, provides inclinometer outputs indicating acceleration in the X and Y directions, Ix and Iy, respectively. A rate gyro on the platform senses the rotational speed w of the platform. The rate gyro output w is differentiated and multiplied by r to determined tangential acceleration at the inclinometer. A circuit resolves the tangential acceleration into X axis and Y axis components, which are used to correct the inclinometer outputs Ix and Iy for errors that would otherwise result from tangential acceleration.

Abstract: The present invention includes a system and a method by which the inclination of a machine element, such as a platform, may be sensed, and errors that might otherwise result from tangential and radial acceleration eliminated. The platform defines orthogonal X and Y axes, and a Z axis orthogonal to both the X and Y axes. The platform is rotatable about an axis extending parallel to the Z axis. The system includes an inclinometer, mounted on the platform at a location spaced from the axis of rotation by a distance r, for providing inclinometer outputs indicating acceleration in the X and Y directions, designated as Ix and Iy, respectively. A line from the axis of rotation to the inclinometer forms an included angle B with the X axis. A rate gyro is mounted on the platform. The rate gyro senses the rotational speed w of the platform about the axis of rotation and provides a rate gyro output indicating the rotational speed w.

Abstract: System and method for presenting a visual image of a work site for an earthmoving machine. In one embodiment, target design data for the work site may be received. A spatial location and orientation for an earthmoving machine operating in relation to the work site may also be received. A visual image of at least a portion of the work site may be received from an imaging device mounted to the earthmoving machine. A visual image of the portion of the work site may be displayed with a subset of the design data overlaying the visual image, wherein the subset of the design data relates to the portion of the work site.

Abstract: System and method for providing an excavation characteristic associated with an earthmoving machine. In one embodiment, a radio frequency identification (RFID) tag associated with an attachment mounted to an earthmoving machine may be identified. An optical benchmark signal may be detected, by an optical receiver. The position of the attachment relative to the earthmoving machine may be determined based, at least in part, on identification of the RFID tag.

Abstract: A method of calibrating an electrically actuated hydraulic valve in a system that controls the flow of hydraulic fluid to a hydraulic cylinder connected to a machine element operates automatically. The system includes an ultrasonic sensor providing an indication of the position of the machine element. The calibration method includes the step of automatically applying a command signal to the hydraulic valve while monitoring the ultrasonic sensor to determine the level of the command signal required to cause the hydraulic cylinder to begin to move. The calibration method includes the additional step of automatically applying in succession a plurality of command signals of increasing level to the hydraulic valve while monitoring the ultrasonic sensor to determine the speed of movement of the hydraulic cylinder resulting from each of the command signals.