Patent Description:
The present invention relates generally to rotating laser systems, and more particularly to a self-leveling laser transmitter for rotating laser systems.

Preparation of worksites, such as, e.g., construction and agricultural worksites, typically involves grading and excavating portions of the worksite into desired topologies. Positional measuring is an important aspect in worksite preparation in order to improve the accuracy of such grading and excavating. Laser measuring systems are commonly used by construction machines (e.g., dozers, scrapers, excavators, etc.) to facilitate positional measuring. Specifically, a laser transmitter of a laser measuring system will transmit a laser signal and a laser receiver of the laser measuring system will receive the laser signal to determine positional measurements of the laser receiver. However, in order to provide accurate measurement results, the laser transmitter must be leveled.

Conventionally, laser measuring systems are self-leveled by measuring tilt angles using two non-rotating inclinometers either of vial type or MEMS (microelectromechanical systems) type and adjusting the tilt using one or more motors. One disadvantage of such conventional laser measuring systems is that the assembly of the inclinometers must be calibrated so that the zero angles of the inclinometers exactly correspond to the vertical axis of rotation. Such calibration is typically performed during manufacturing by applying additional calibration steps to align the inclinometers to the rotational axis. Such conventional laser measuring systems are also prone to losing calibration due to, e.g., the laser transmitter being dropped.

<CIT> discloses the following: It is disclosed a laser leveling device suitable for ultra-high collision avoidance of bridges, comprising a laser range finder, a controller and a power supply for supplying power to the laser leveling instrument and characterized in that it further comprises a driving mechanism and a single degree of freedom gravity accelerometer and a horizontal positioning locking mechanism for fixing the position of a laser emitting head of the laser range finder, wherein the driving mechanism comprises a driver, a laser emitting head rotating seat, wherein the output end of the driver is connected to the laser emitting head rotating seat, wherein the laser emitting head rotating seat is mounted on the rotating base of the laser emitting head, wherein the gravity accelerometer is mounted coaxially with the laser emitting head of the laser range finder, wherein the controller controls the driver to drive the rotation of the laser emitting head, and wherein the acceleration signal of the gravity accelerometer is fed back to the controller.

<CIT> discloses the following: A laser surveying system comprises a leveling unit having a motor for leveling, a light source unit for emitting a laser beam, a light projecting optical system installed on the leveling unit and for projecting the laser beam, a power supply unit for supplying electric power to each of component sites, a control unit for driving and controlling each of the component sites, a storage unit, a tilt detecting means installed on the leveling unit and used for detecting leveling conditions, a rotation number detecting means for detecting number of rotations of the motor, a light source detecting means for detecting light emitting condition of the light source unit, a voltage detecting means for detecting output voltage of the power source unit, and an abnormality detecting means for detecting operational abnormality, and in the laser surveying system, the control unit monitors whether there is abnormality or not by the abnormality detecting means, samples a detection signal from each of the detecting means at a predetermined time interval, and stores signal groups thus detected in the storage unit in time series as sampling data, and when the stored sampling data exceeds a predetermined amount, older data are deleted, and new sampling data are sequentially overwritten, and when at least one of the detection signals for monitoring indicates abnormality, using a point to indicate the abnormality as a base point, the sampling data in a range of a predetermined time period are exempted from the objects of deletion and are preserved as data for analysis of the cause of abnormality.

In accordance with one or more embodiments, a self-leveling laser transmitter is provided. The self-leveling laser transmitter achieves a high degree of accuracy without the use of expensive inclinometers.

In one embodiment, a laser transmitter comprises a rotation head and an accelerometer mounted on the rotation head. An acceleration signal is received from the accelerometer and one or more tilt adjustment signals for adjusting a tilt of the rotation head to a leveled orientation are generated based on the acceleration signal. One or more actuators adjust the tilt of the rotation head based on the one or more tilt adjustment signals.

The acceleration signal represents at least one of acceleration on a tangential axis of the accelerometer and acceleration on a radius axis of the accelerometer as the accelerometer rotates. The one or more tilt adjustment signals are determined to substantially eliminate a sinusoidal component from the acceleration signal. In one embodiment, the one or more tilt adjustment signals are determined based on an angle of misalignment between a reference angle of an encoder of the laser transmitter and a reference angle of the one or more actuators. In another embodiment, the one or more tilt adjustment signals are determined to minimize an amplitude of the acceleration signal.

In one embodiment, a first tilt adjustment signal for adjusting a tilt of the rotation head in a first dimension and a second tilt adjustment signal for adjusting a tilt of the rotation head in a second dimension are determined. A first actuator adjusts the tilt of the rotation head in the first dimension based on the first tilt adjustment signal and a second actuator adjusts the tilt of the rotation head in the second dimension based on the second tilt adjustment signal.

In accordance with one or more embodiments, a self-leveling apparatus is provided, such as, e.g., a laser transmitter. The self-leveling apparatus comprises a rotation head and an accelerometer mounted on the rotation head. An acceleration signal is received from the accelerometer and one or more tilt adjustment signals for adjusting a tilt of the rotation head to a leveled orientation are generated based on the acceleration signal. The acceleration signal represents at least one of acceleration on a tangential axis of the accelerometer and acceleration on a radial axis of the accelerometer as the accelerometer rotates; One or more actuators adjust the tilt of the rotation head based on the one or more tilt adjustment signals.

<FIG> shows a laser measuring system <NUM>, in accordance with one or more embodiments. Laser measuring system <NUM> includes a laser transmitter <NUM> and a laser receiver <NUM>. As illustratively shown in <FIG>, laser receiver <NUM> is configured to be attached to a surveying pole <NUM>. However, it should be understood that various configurations of laser receiver <NUM> are possible. For example, laser receiver <NUM> may be configured to be attached to a construction machine (e.g., excavator, dump truck, bull dozer, etc.) or may be a hand held device. It should be understood that laser measuring system <NUM> may include any number of laser receivers for calculating position and orientation information for each laser receiver <NUM> based on laser beams received from laser transmitter <NUM>.

Laser Transmitter <NUM> comprises a rotation head <NUM> mounted on a tripod <NUM> or any other base (e.g., surveying pole, construction machine, etc.) on which rotation head <NUM> rotates. Laser transmitter <NUM> projects laser signal <NUM> in rotary irradiation at a constant speed to laser receiver <NUM>. In one embodiment, laser signal <NUM> is an N-shaped beam, as described in <CIT>, the disclosure of which is incorporated herein by reference in its entirety. However, laser beam <NUM> may be any suitable laser beam (e.g., an I-shaped beam). In one embodiment, laser transmitter <NUM> is laser transmitter <NUM> shown in <FIG>, described in detail below.

Positional measurements of laser receiver <NUM> are determined based on laser signals transmitted by laser transmitter <NUM> and received by laser receiver <NUM>. However, in order for laser measuring system <NUM> to provide accurate positional measurements of laser receiver <NUM>, rotation head <NUM> of laser transmitter <NUM> must be leveled. Rotation head <NUM> is leveled when the rotation axis of rotation head <NUM> is substantially parallel to the vector of gravity. In accordance with embodiments of the present invention, rotation head <NUM> of laser transmitter <NUM> is configured with an accelerometer and rotation head <NUM> is leveled by determining tilt adjustment signals based on an acceleration measured by the accelerometer and adjusting the tilt of rotation head <NUM> to a leveled orientation based on the one or more tilt adjustment signals.

Embodiments of the present invention may be applied for leveling a laser transmitter, such as, e.g., a 3D laser transmitter as described in <CIT>, or an N-beam laser transmitter. However, it should be understood that embodiments of the present invention may be applied for leveling rotational systems of any type, such as, e.g., for leveling a reference plane of a laser system or for a high-accuracy plumb tool for construction.

<FIG> shows a detailed view of a laser transmitter <NUM>, in accordance with one or more embodiments. In one embodiment, laser transmitter <NUM> is laser transmitter <NUM> of <FIG>. Laser transmitter <NUM> comprises a rotation head <NUM> mounted on a base <NUM> attached to, e.g., tripod, surveying pole, construction machine, etc. Rotation head <NUM> rotates about rotation axis <NUM> in a clockwise direction <NUM> (or a counter-clockwise direction in some embodiments). As rotation head <NUM> rotates, one or more laser diodes (not shown), or other laser sources, project laser signals through transmitter lens <NUM>.

Rotation head <NUM> includes an accelerometer <NUM> to facilitate leveling of rotation head <NUM>. Accelerometer <NUM> may be any suitable accelerometer having at least one sensing axis and having a suitable minimum sampling frequency and noise density. Leveling accuracy of rotation head <NUM> can be estimated according to Equation (<NUM>) as follows: <MAT> where Lacc is the leveling accuracy in mkrad, Nd is the noise density of accelerometer <NUM> in <MAT>, and leveling_duration is the duration of leveling in seconds. The minimum sampling frequency is preferably at least twice bigger than the output bandwidth of accelerometer <NUM>. The output bandwidth of accelerometer <NUM> is preferably bigger than the rotation rate of rotation head <NUM>. In an advantageous embodiment, the output bandwidth of accelerometer <NUM> is at least twice bigger that the rotation rate of rotation head <NUM>. Accelerometer <NUM> may be positioned at any location on or in rotation head <NUM>. In an advantageous embodiment, accelerometer <NUM> is placed as close as possible to rotation axis <NUM>.

In one embodiment, accelerometer <NUM> is a single axis accelerometer having sensing axis <NUM> oriented to measure tangential acceleration of accelerometer <NUM> as accelerometer <NUM> rotates (via rotation head <NUM>, e.g., during rotary irradiation) about rotation axis <NUM>. As illustratively shown in <FIG>, accelerometer <NUM> rotates (via rotation head <NUM>) about rotation axis <NUM> along a circular path <NUM>. Accelerometer <NUM> is oriented such that its sensing axis <NUM> is aligned with a tangential axis <NUM> of circular path <NUM> of accelerometer <NUM>. Tangential axis <NUM> of accelerometer <NUM> is perpendicular to rotation axis <NUM> and perpendicular to a radial axis <NUM> of accelerometer <NUM>. Radial axis <NUM> is the axis formed between rotation axis <NUM> and accelerometer <NUM> and corresponds to the radius of circular path <NUM> at the location of accelerometer <NUM>. Axes <NUM>, <NUM>, and <NUM> are perpendicular to each other and form an orthogonal 3D system.

In one embodiment, accelerometer <NUM> is a three axis accelerometer having a first sensing axis <NUM> oriented to measure radial acceleration of accelerometer <NUM>, a second sensing axis <NUM> oriented to measure tangential acceleration of accelerometer <NUM>, and a third sensing axis <NUM> oriented to measure a gravitational acceleration of accelerometer <NUM>. Accordingly, accelerometer <NUM> is oriented such that the first sensing axis <NUM> is aligned with radial axis <NUM>, the second sensing axis <NUM> is aligned with tangential axis <NUM>, and the third sensing axis <NUM> is aligned with a gravitational axis <NUM> parallel to rotation axis <NUM>. An exemplary output of acceleration signals from a three axis accelerometer is illustratively shown in graph <NUM> of <FIG>, described in more detail below.

It should be understood that accelerometer <NUM> may be any suitable accelerometer having at least one sensing axis that is not parallel to rotation axis <NUM>. If the at least one sensing axis of accelerometer <NUM> is parallel to rotation axis <NUM>, the at least one accelerometer will sense only the DC (direct current) component and no AC (alternating current) component and, thus, cannot be used for self-leveling. In one example, accelerometer <NUM> may be an inertial measurement unit.

Accelerometer <NUM> generates acceleration signals representing acceleration on tangential axis <NUM> (and, in some embodiments, radial acceleration signals and/or gravitational acceleration signals) and transmits the acceleration signals to a data processor <NUM> using any suitable data transmission mechanism. Data processor <NUM> may be implemented using any computing device, such as, e.g., computer <NUM> of <FIG>, and may be integrated within base <NUM> as shown in <FIG> or may be integrated within rotation head <NUM>. The data transmission mechanism may transmit acceleration signals between accelerometer <NUM> and data processor <NUM>, e.g., where data processor <NUM> is integrated in base <NUM>. The data transmission mechanism may also transmits actuator control signals between one or more actuators <NUM> and data processor <NUM>, e.g., where data processor <NUM> is integrated in rotation head <NUM>. The data transmission mechanism may be based on a wired connection implemented using, e.g., a slip ring. Additionally or alternatively, the data transmission mechanism may be based on a wireless connection implemented using, e.g., radio frequency (RF) transmission or optical transmission using separate simplex channels in both directions. Other data transmission mechanisms may also be employed.

Data processor <NUM> receives the acceleration signals from accelerometer <NUM>, generates tilt adjustment signals for adjusting a tilt of rotation head <NUM> to a leveled orientation, and outputs the tilt adjustment signals to (e.g., two) actuators <NUM> for adjusting the tilt of rotation head <NUM> based on the tilt adjustment signals. Data processor <NUM> determines the tilt adjustment signals to remove any sinusoidal component from the acceleration signals to thereby level rotation head <NUM>. When rotation head <NUM> is level, rotation axis <NUM> is parallel to gravitational vector <NUM>. In one embodiment, data processor <NUM> determines the tilt adjustment signals for leveling rotation head <NUM> according to method <NUM> of <FIG>. Actuators <NUM> are coupled between rotation head <NUM> and base <NUM> to adjust the tilt of rotation head <NUM> in two dimensions. In one embodiment, actuators <NUM> include first and second actuators for adjusting the tilt of rotation head <NUM> in an X dimension and a Y dimension, respectively. Actuators <NUM> may include one or more stepper motors with lead screws or any other suitable actuators.

Accelerometer <NUM> may be powered via any suitable power transmission mechanism (not shown in <FIG>). The power transmission mechanism may be based on a wired connection implemented using, e.g., a slip ring. Additionally or alternatively, the power transmission mechanism may be based on a wireless connection implemented using, e.g., RF power transmission with antennas on the rotation head <NUM> and base <NUM> or optical power transmission with light emitting diodes (LEDs) mounted on base <NUM> and photo diodes or solar cells mounted on rotation head <NUM> to collect light from the LEDs and convert the light into electricity. Other power transmission mechanisms may also be employed.

<FIG> shows an exemplary graph <NUM> of acceleration signals generated and output by a three axis accelerometer, in accordance with one or more embodiments. The acceleration signals in graph <NUM> represent acceleration (in m/s<NUM>) over time (in seconds). <FIG> will be described with reference to <FIG>. In one embodiment, the acceleration signals in graph <NUM> may be output by accelerometer <NUM> of <FIG> mounted on rotation head <NUM> of a laser transmitter <NUM>. Accelerometer <NUM> is oriented such that its first sensing axis <NUM> is aligned with radial axis <NUM>, its second sensing axis <NUM> is aligned with a tangential axis <NUM>, and its third sensing axis <NUM> is aligned with gravitational axis <NUM> (parallel to rotation axis <NUM>). Some misalignment of the sensing axes is acceptable as long as clipping does not occur. An example of clipping is illustratively shown in <FIG>, described below.

Radial acceleration signal <NUM> represents radial acceleration measured along the radial axis <NUM> by the first sensing axis <NUM> when rotation head <NUM> is not level and radial acceleration signal <NUM> represents radial acceleration measured along the radial axis <NUM> by the first sensing axis <NUM> when rotation head <NUM> is level. Tangential acceleration signal <NUM> represents tangential acceleration measured along the tangential axis <NUM> by the second sensing axis <NUM> when rotation head <NUM> is not level and tangential acceleration signal <NUM> represents tangential acceleration measured along the tangential axis <NUM> by the second sensing axis <NUM> when rotation head <NUM> is level. Gravitational acceleration signal <NUM> represents gravitational acceleration measured along the gravitational axis <NUM> by the third sensing axis <NUM> when rotation head <NUM> is not level and gravitational acceleration signal <NUM> represents gravitational acceleration measured along the gravitational axis <NUM> by the third sensing axis <NUM> when rotation head <NUM> is level.

As shown in graph <NUM>, radial acceleration signals <NUM> and <NUM> are subject to a bias of a = <NUM>π<NUM>f<NUM>r, where f is the frequency of rotation in Hertz and r is the accelerometer offset radius in meters. Tangential acceleration signals <NUM> and <NUM> are not subject to a bias. Acceleration signals <NUM> and <NUM> are sinusoidal due to the non-level orientation of rotation head <NUM>. Gravitational acceleration signals <NUM> and <NUM> represent acceleration due to gravity and are not sensitive to the level or non-level orientation of rotation head <NUM>.

When rotation head <NUM> is level, accelerometer <NUM> will output a radial acceleration of the bias of a = 4π<NUM>f <NUM>r, a tangential acceleration of zero, and a gravitational acceleration approximately equal to the acceleration of gravity. In practice, acceleration signals from accelerometer <NUM> may have noise and drift offset.

<FIG> shows an exemplary graph <NUM> of a clipping effect of an acceleration signal output by a three axis accelerometer, in accordance with one or more embodiments. The acceleration signals in graph <NUM> represent acceleration (in m/s<NUM>) over time (in seconds). <FIG> will be described with reference to <FIG>. In one embodiment, the acceleration signals in graph <NUM> may be output by accelerometer <NUM> of <FIG> mounted and oriented as described above with respect to <FIG>.

Radial acceleration signal <NUM> represents radial acceleration measured along radial axis <NUM>, tangential acceleration signal <NUM> represents tangential acceleration measured along tangential axis <NUM>, and gravitational acceleration signal <NUM> represents gravitational acceleration measured along gravitational axis <NUM>. As illustratively shown in <FIG>, radial acceleration signal <NUM> experiences clipping due to the output range of accelerometer <NUM> being too small for a given radial offset and for a given rotation rate, so the bias of a = <NUM>π<NUM>f<NUM>r offsets the signal to the edge of output range. The clipping results in a flat cutoff at, e.g., <NUM> times gravitational acceleration in radial acceleration signal <NUM> due to data range constraints of accelerometer <NUM>. Some misalignment of the sensing axes is acceptable as long as clipping does not occur, particularly in tangential acceleration signal <NUM>.

<FIG> shows a method <NUM> for leveling a rotation head of a laser transmitter, in accordance with one or more embodiments. Method <NUM> will be described with reference to <FIG>. In one embodiment, method <NUM> is performed by data processor <NUM>.

At step <NUM>, an acceleration signal is received from an accelerometer <NUM> mounted on a rotation head <NUM> of a laser transmitter <NUM>. In one embodiment, the acceleration signal represents an acceleration on accelerometer <NUM> measured by a sensing axis <NUM> of accelerometer <NUM> aligned with tangential axis <NUM> as accelerometer <NUM> rotates about rotation axis <NUM>. In another embodiment, the acceleration signal represents an acceleration on accelerometer <NUM> measured by a sensing axis <NUM> of accelerometer <NUM> aligned with radial axis <NUM> as accelerometer <NUM> rotates about rotation axis <NUM>. In another embodiment, the acceleration signal represents a linear combination of an acceleration on accelerometer <NUM> measured by a sensing axis <NUM> of accelerometer <NUM> aligned with tangential axis <NUM> and by a sensing axis <NUM> of accelerometer <NUM> aligned with radial axis <NUM>.

At step <NUM>, one or more tilt adjustment signals for adjusting a tilt of the rotation head <NUM> to a leveled orientation are determined based on the acceleration signal. The tilt adjustment signals adjust the tilt of rotation head <NUM> in two dimensions to substantially eliminate a sinusoidal component in the acceleration signal. In one embodiment, a first tilt adjustment signal is generated for adjusting the tilt of the rotation head <NUM> in a first dimension (e.g., X dimension) and a second tilt adjustment signal is generated for adjusting the tilt of the rotation head <NUM> in a second dimension (e.g., Y dimension). In one embodiment, for example where laser transmitter <NUM> is equipped with an encoder, the tilt adjustment signals are determined as described with respect to <FIG>. In another embodiment, for example where laser transmitter <NUM> is not equipped with an encoder, the tilt adjustment signals are determined as described with respect to <FIG>. In one embodiment, where the acceleration signal represents (at least in part) acceleration measured by a sensing axis <NUM> on radial axis <NUM>, in order to avoid clipping of the acceleration signal, the output range of accelerometer <NUM> is bigger than a = <NUM>π<NUM>f<NUM>r or accelerometer <NUM> must be placed close enough to the center so the bias is within the range of accelerometer <NUM>.

At step <NUM>, the tilt of the rotation head <NUM> is adjusted based on the one or more tilt adjustment signals. In one embodiment, a first actuator adjusts the tilt of rotation head <NUM> in the first dimension based on the first tilt adjustment signal and a second actuator adjusts the tilt of rotation head <NUM> in a second dimension based on the second tilt adjustment signal to bring rotation head <NUM> to a leveled orientation.

<FIG> shows a functional diagram <NUM> for determining tilt adjustment signals for adjusting a tilt of a rotation head of a laser transmitter to a leveled orientation, in accordance with one or more embodiments. Step <NUM> of <FIG> may be implemented according to functional diagram <NUM>, e.g., where the laser transmitter is equipped with an encoder.

In functional diagram <NUM>, an encoder <NUM> of a laser transmitter provides an angular position of the rotation head of the laser transmitter. Encoder <NUM> may be any suitable encoder, such as, e.g., an absolute or incremental rotary encoder. The angular position is converted to a sine and a cosine signals by sin/cos converter <NUM>, e.g., using a sine look up table or by performing direct calculation of sin(x) and cos(x) functions, where x is the angular position in radians or degrees. Multipliers <NUM> and <NUM> multiply an acceleration at <NUM> with the sine and the cosine respectively to perform a frequency shift. Tangential acceleration at <NUM> is received from an accelerator mounted on the rotation head and represents acceleration on the accelerator as the accelerator rotates. Results of multipliers <NUM> and <NUM> are accumulated by integrators <NUM> and <NUM> respectively over a period of time for an integer number of rotations of the rotation head. Then the output of integrators <NUM> and <NUM> (e.g., a 2D vector) is rotated to an angle of misalignment α by multiplying the output with a rotation matrix <MAT> in following steps. The integrated results from integrator <NUM> are multiplied by sin(α) and cos(α) by multipliers <NUM> and <NUM> respectively and the integrated results from integrator <NUM> are multiplied by cos(α) and -sin(α) by multipliers <NUM> and <NUM> respectively, where α is the angle of misalignment between one or more actuators and the reference angle of encoder <NUM> of the laser transmitter. The angle α of misalignment is further described below with respect to <FIG>. The results of multipliers <NUM> and <NUM> are combined by adder <NUM> to provide tilt adjustment signals for adjusting the tilt of the rotation head in an X dimension, which are output to an actuator <NUM>. The results of multipliers <NUM> and <NUM> are combined by adder <NUM> to provide tilt adjustment signals for adjusting the tilt of the rotation head in a Y dimension, which are output to an actuator <NUM>. The tilt adjustment signals eliminate any sinusoidal component on acceleration at <NUM>. Actuators <NUM> and <NUM> adjust the tilt of the rotation head in the X and Y dimension respectively according to the tilt adjustment signals to level the rotation head of the laser transmitter.

<FIG> shows a graph <NUM> showing an angle of misalignment between a reference angle of one or more actuators adjusting a tilt of a rotation head of a laser transmitter and a reference angle of an encoder of the laser transmitter, in accordance with one or more embodiments. The reference angle (zero) of the encoder is represented by line <NUM> and corresponds to the cos line. The reference angle (zero) of the actuators is represented by the +x axis. The angle α <NUM> of misalignment is shown as the angle formed by the +x axis and line <NUM>.

<FIG> shows a functional diagram <NUM> for determining tilt adjustment signals for adjusting a tilt of a rotation head of a laser transmitter to a leveled orientation, in accordance with one or more embodiments. Step <NUM> of <FIG> may be implemented according to functional diagram <NUM>, e.g., where the laser transmitter is not equipped with an encoder.

Local oscillator <NUM> outputs sin and cos signals at an approximate rate of rotation, which are multiplied with an acceleration at <NUM> (e.g., tangential or radial acceleration) by multipliers <NUM> and <NUM> respectively. Acceleration at <NUM> is received from an accelerator mounted on the rotation head and represents acceleration on the accelerator as the accelerator rotates. The results of multipliers <NUM> and <NUM> are respectively processed by low pass filters <NUM> and <NUM> with a bandwidth larger than the difference between the actual rate of rotation and the approximate rate of rotation and squared functions <NUM> and <NUM>, and are combined by adder <NUM>. A minimum search logic block <NUM> determines tilt adjustment signals for adjusting the tilt of the rotation head in an X dimension and a Y dimension from results of adder <NUM>, which are then output to actuators <NUM> and <NUM> to adjust the tilt of the rotation head in the X and Y dimension respectively to a leveled orientation by eliminating sinusoidal component on tangential acceleration at <NUM>. Minimum search logic block <NUM> determines tilt adjustment signals that substantially eliminate any sinusoidal component from tangential acceleration at <NUM>. In one embodiment, minimum search logic block <NUM> may implemented to apply an algorithm (e.g., minimum search algorithm) to minimize the amplitude of tangential acceleration at <NUM>. Exemplary minimum search algorithms include gradient descent algorithm or an eight point approximation algorithm, as described below with respect to <FIG> and <FIG> respectively.

<FIG> shows a high-level diagram <NUM> for determining tilt adjustment signals to level a rotation head of a laser transmitter using a gradient descent algorithm, in accordance with one or more embodiments. The gradient descent algorithm determines tilt adjustment signals to provide a minimum amplitude for the acceleration signal (e.g., tangential or radial acceleration signal). Starting at an initial point (x, y) <NUM> (e.g., determined as the output of adder <NUM>), the amplitude a<NUM> of the acceleration signal is measured for initial point (x, y) <NUM> and adx for point (x+dx, y) <NUM> and ady for point (x, y+dy) <NUM>. Initial steps dx and dy can be selected arbitrarily or based on the total range of actuator adjustment, e.g. <NUM>% or <NUM>% of total range. The gradient is calculated ∇ = <MAT> and the initial point (x, y) <NUM> is moved in the direction of the gradient to point <NUM>. The process repeated to identify the minimum amplitude for the tangential acceleration at point <NUM>.

<FIG> shows a high-level diagram <NUM> for determining tilt adjustment signals to level a rotation head of a laser transmitter using an eight point approximation algorithm, in accordance with one or more embodiments. The eight point approximation algorithm determines tilt adjustment signals to provide a minimum amplitude for the tangential acceleration. Starting from an initial point (x, y) (e.g., determined as the output of adder <NUM>), an arbitrary dx and dy (dx may equal dy) is determined (e.g., as <NUM>% of the total actuator range). The amplitude of the tangential acceleration is measured for eight points: A<NUM>(x+dx, y-dy), A<NUM>(x, y-dy), A<NUM>(x-dx, y-dy), A<NUM>(x-dx, y), A<NUM>(x-dx, y+dy), A<NUM>(x, y+dy), A<NUM>(x+dx, y+dy), and A<NUM>(x+dx, y). Coefficient k is calculated as k = A<NUM>+A<NUM>+A<NUM>+A<NUM>-A<NUM>-A<NUM>-A<NUM>-A<NUM>. Δx and Δy are calculated as <MAT> and <MAT>. The tilt adjustment signals are determined as (x + Δx) and (y + Δy), which correspond to the leveled orientation of the rotation head of the laser transmitter.

Systems, apparatuses, and methods described herein may be implemented using digital circuitry, or using one or more computers using well-known computer processors, memory units, storage devices, computer software, and other components. Typically, a computer includes a processor for executing instructions and one or more memories for storing instructions and data. A computer may also include, or be coupled to, one or more mass storage devices, such as one or more magnetic disks, internal hard disks and removable disks, magneto-optical disks, optical disks, etc..

Systems, apparatus, and methods described herein may be implemented using a computer program product tangibly embodied in an information carrier, e.g., in a non-transitory machine-readable storage device, for execution by a programmable processor; and the method and workflow steps described herein, including one or more of the steps or functions of <FIG>, may be implemented using one or more computer programs that are executable by such a processor. A computer program is a set of computer program instructions that can be used, directly or indirectly, in a computer to perform a certain activity or bring about a certain result.

A high-level block diagram of an example computer <NUM> that may be used to implement systems, apparatus, and methods described herein is depicted in <FIG>. Computer <NUM> includes a processor <NUM> operatively coupled to a data storage device <NUM> and a memory <NUM>. Processor <NUM> controls the overall operation of computer <NUM> by executing computer program instructions that define such operations. The computer program instructions may be stored in data storage device <NUM>, or other computer readable medium, and loaded into memory <NUM> when execution of the computer program instructions is desired. Thus, the method and workflow steps or functions of <FIG> can be defined by the computer program instructions stored in memory <NUM> and/or data storage device <NUM> and controlled by processor <NUM> executing the computer program instructions. For example, the computer program instructions can be implemented as computer executable code programmed by one skilled in the art to perform the method and workflow steps or functions of <FIG>. Accordingly, by executing the computer program instructions, the processor <NUM> executes the method and workflow steps or functions of <FIG>. Computer <NUM> may also include one or more network interfaces <NUM> for communicating with other devices via a network. Computer <NUM> may also include one or more input/output devices <NUM> that enable user interaction with computer <NUM> (e.g., display, keyboard, mouse, speakers, buttons, etc.).

Processor <NUM> may include both general and special purpose microprocessors, and may be the sole processor or one of multiple processors of computer <NUM>. Processor <NUM> may include one or more central processing units (CPUs), for example. Processor <NUM>, data storage device <NUM>, and/or memory <NUM> may include, be supplemented by, or incorporated in, one or more application-specific integrated circuits (ASICs) and/or one or more field programmable gate arrays (FPGAs).

Data storage device <NUM> and memory <NUM> each include a tangible non-transitory computer readable storage medium. Data storage device <NUM>, and memory <NUM>, may each include high-speed random access memory, such as dynamic random access memory (DRAM), static random access memory (SRAM), double data rate synchronous dynamic random access memory (DDR RAM), or other random access solid state memory devices, and may include non-volatile memory, such as one or more magnetic disk storage devices such as internal hard disks and removable disks, magneto-optical disk storage devices, optical disk storage devices, flash memory devices, semiconductor memory devices, such as erasable programmable read-only memory (EPROM), electrically erasable programmable read-only memory (EEPROM), compact disc read-only memory (CD-ROM), digital versatile disc read-only memory (DVD-ROM) disks, or other non-volatile solid state storage devices.

Input/output devices <NUM> may include peripherals, such as a printer, scanner, display screen, etc. For example, input/output devices <NUM> may include a display device such as a cathode ray tube (CRT) or liquid crystal display (LCD) monitor for displaying information to the user, a keyboard, and a pointing device such as a mouse or a trackball by which the user can provide input to computer <NUM>.

Any or all of the systems and apparatus discussed herein, including elements of data processor <NUM> of <FIG>, may be implemented using one or more computers such as computer <NUM>.

One skilled in the art will recognize that an implementation of an actual computer or computer system may have other structures and may contain other components as well, and that <FIG> is a high level representation of some of the components of such a computer for illustrative purposes.

Claim 1:
A method comprising:
receiving (<NUM>) an acceleration signal (<NUM>) from an accelerometer (<NUM>) mounted on a rotation head (<NUM>, <NUM>) of a laser transmitter (<NUM>, <NUM>), wherein the acceleration signal represents at least one of acceleration on a tangential axis (<NUM>) of the accelerometer and acceleration on a radial axis (<NUM>) of the accelerometer as the accelerometer rotates;
generating (<NUM>) one or more tilt adjustment signals for adjusting a tilt of the rotation head to a leveled orientation based on the acceleration signal; and
adjusting (<NUM>) the tilt of the rotation head based on the one or more tilt adjustment signals.