This invention generally relates to measurement devices, and more particularly, to an angular position measurement device and method of operating the same.
Many types of rotatable structures, such as motors, gimbal joints, hinges, and the like have a rotating shaft. In some instances, it has been desirable to measure the angular position of the shaft at various times during its operation. A gimbal is one type of rotatable structure that provides for rotation of an object in three dimensions. Objects such as cameras or other visual aid devices have been implemented on gimbals to enable rotation of the camera's eyepiece to virtually any geometrical orientation. One such type of visual aid device is an electro optical/infrared (EO/IR) sensor. The electro optical/infrared sensor is a type of camera that is capable of taking pictures using both the visible and infrared portions of the electromagnetic spectrum. When mounted onto a gimbal, the electro optical/infrared sensor is capable of deriving images from virtually any orientation.
In one embodiment, a sensor assembly for measuring an angular position of a rotatable structure includes an annular ring that is eccentrically rotatable about an axis, a first and second sensors, and a sensor transducing circuit to combine the measurements from the two sensors. The first and second sensors are rotatable relative to the annular ring and disposed a predetermined distance from the axis such that the first and second sensors have a first and second output level respectively that is proportional to the angular position of the annular ring. The sensor transducing circuit is operable to proportionally combine the first and second output levels into an output signal based upon a weighting factor, the weighting factor being proportional to the angular position of at least one of the first and second sensors.
In another embodiment, a method for measuring the angular position of a rotatable structure includes rotating an annular ring that is eccentrically coupled to an axis, measuring a first output level and a second output level from a first and second sensors respectively, and combining the first and second output levels using a weighting factor. The first and second sensors are disposed at a predetermined angular distance from one another such that the resulting waveform produced by each sensor is out of phase with one another as the shaft rotates about the axis. The first and second sensors are combined using a weighting factor in which the output level of the second sensor is more heavily weighted as the output level of the first sensor approaches a relative peak value.
Depending on the specific features implemented, particular embodiments of the present invention may exhibit some, none, or all of the following technical advantages. Various embodiments may be capable of providing two or more sensors that do not make contact with any portion of the shaft. By placement of these sensors in a generally perpendicular relation to each other around the axis of the shaft, a weighting factor may be applied to combine the outputs of each such that relatively accurate measurements may be taken over a continuous angular displacement of the shaft. Certain embodiments may provide other advantages such as implementation of a angular position measurement device that does not create any discontinuities in the output signal. For instance, the sensing surface that may be the inner or outer surface of an annular ring is generally smooth in contour. In this manner, no discontinuous spikes, or glitches are outputted by the sensors as the shaft rotates about its axis. Additionally, the weighting factor may be essentially continuous throughout the rotational range of the annular ring. In this manner, no step function may be applied as the shaft rotates into or out of a particular range of travel. Other technical advantages will be readily apparent to one skilled in the art from the following figures, description and claims.
A more complete understanding of embodiments of the invention will be apparent from the detailed description taken in conjunction with the accompanying drawings in which:
Reference will now be made to the drawings in which various embodiments of an angular position measurement device 10 are shown and described. Specifically as shown in
The angular position measurement device 10 may be implemented on any suitable structure that has a rotatable shaft.
In one embodiment, the outer surface 26 of the annular ring 12 has an essentially smooth contour. That is, there are no significant notches, slots, or other discontinuous surface features on the outer surface 26. In this manner, the resulting output signal from either sensor 14a or 14b may be free of glitches, spikes, or other discontinuous type signals as the shaft rotates. Thus, the angular position measurement device 10 may provide relatively accurate angular position measurements at each point throughout the rotational range of the shaft.
Measurements of the angular position of the annular ring 12 may be provided by at least two sensors that are disposed a predetermined angular distance from one another around the shaft axis 18. In one embodiment, the two sensors 14a and 14b are displaced from one another at an angle of approximately 90 degrees. In another embodiment, each of the two sensors may be a pair of sensors 14a and 14b such that four sensors are used. Thus as shown in
In this particular embodiment, each pair of sensors 14a or 14b are generally perpendicular to one another. That is, a first pair of sensors 14a may be positioned around the shaft axis 18 such that they are generally 90 degrees apart with relation to the other pair of sensors 14b. Thus, certain embodiments of the present invention may provide enhanced accuracy for measurements that are taken by angular position measurement device 10. Each pair of sensors 14a and 14b may be operable to output an output level indicative of the relative distance of each pair of sensors 14a or 14b from the annular ring 12.
In the particular embodiment described above, the two pairs of sensors 14a and 14b are disposed outside of the annular ring 12. Using this approach, the two pair of sensors 14a and 14b may be adapted to measure the distance from an outside surface 26 of the annular ring 12. In another embodiment of an angular position measurement device 30 shown in
The annular ring 32 is also similar in structure and purpose to the annular ring 12 of
The annular ring 32 of
In one embodiment, the angular position measurement device 30 may be implemented on a rotatable structure 36 that may be a gimbal assembly as shown in
A schematic diagram of the angular position measurement device 30 of
A graphical representation showing the output level OL1 of the first pair of sensors 14a and the output level OL2 of the second pair of sensors 14b as the annular ring rotates about the shaft axis 18 is shown in
The sensor transducing circuit 22 may be operable to resolve the angular position of the annular ring 12 to any angular position within a 360 degree radius. In one embodiment, sensor transducing circuit 22 may include a microprocessor circuit that is operable to execute instructions stored in a memory. To resolve the angular position of the annular ring 12 to any angular position, the sensor transducing circuit 22 may receive measurements from the first and second pair of sensors 14a and 14b and combine these measurements using the following computer implemented algorithm in the sensor transducing circuit:
IF OL1>0 AND OL2>0
Θ2=ARCCOS(OL2)
ELSE
ELSEIF OL1<0 AND OL2>0
Θ1=ARCCOS(OL1)
Θ2=180−ARCCOS(OL2)
ELSE
ELSEIF OL1<0 AND OL2<0
Θ1=360−ARCCOS(OL1)
Θ2=180−ARCCOS(OL2)
ELSE
ELSEIF OL1>0 AND OL2<0
Θ1=360−ARCCOS(OL1)
Θ2=360−ARCCOS(OL2)
ENDIF
Θ1 refers to an angular position measurement calculated by the sensor transducing circuit 22 based upon the first pair of sensors 14a. Θ2 refers to an angular position measurement calculated by the sensor transducing circuit 22 based upon the second pair of sensors 14b. The sensor transducing circuit 22 may combine the output levels of each pair of sensors 14a and 14b using any suitable means to resolve the angular position of the annular ring 12 within a 360 degree radius. In one embodiment, the output levels OL1 and OL2 of both waveforms 50 and 52 has been normalized to be between 1 and −1. Therefore, the algorithm as shown above may be able to resolve the angular position of the annular ring 12 within any quadrant based upon the combined polarity of measurements taken.
Waveform 50 has a relative maximum peak region 50a and a relative minimum peak region 50b. Additionally, waveform 52 has a relative maximum peak region 52a and a relative minimum peak region 52b. Within either of these peak regions 50a, 50b, 52a, and 52b, a relatively large angular displacement occurs for a relatively small change in output level of its associated sensor 14. Thus, when operating independently of each other, each pair of sensors 14a or 14b may provide a signal level that may have reduced accuracy at angular positions in which the sensor 14 is at a relative peak level. Certain embodiments of the present invention may provide enhanced accuracy to measurements taken when the angular position of the annular ring 12 is within any of these peak regions 50a, 50b, 52a, and 52b by combining the measurement data from each pair of sensors 14a and 14b using a weighting factor. That is, the sensor transducing circuit 22 may be configured to combine measurements from both pairs of sensors 14a and 14b such that measurements from any particular pair of sensors 14 are more lightly weighted when the annular ring 12 is within the peak region of that particular pair of sensors 14a or 14b. In one embodiment, the weighting factor may be configured to heavily weight measurements taken from the first pair of sensors 14a except when the first pair of sensors 14a is proximate a relative peak level 50a or 50b. In this particular embodiment, if the first pair of sensors 14a is proximate one of the relative peak levels 50a or 50b, the sensor transducing circuit 22 may then be operable to more heavily weight measurements from the second pair of sensors 14b. Thus, the weighting factor may be proportionally applied to measurements taken from the sensors 14a and 14b. That is, the weighting factor may be increasingly applied to the second pair of sensors 14b as the angular position of the first pair of sensors 14a approaches the relative peak level 50a or 50b. In one embodiment, the weighting factor may be an executable algorithm that is executed by the sensor transducing circuit 22. In this particular embodiment, the executable algorithm that is used to calculate the output signal 24 may be:
Angular position=Θ1+(Θ2−Θ1)*ABS(COS(Θ1))
The portion of the above algorithm, namely “(Θ2−Θ1) *ABS(COS(Θ1))” may be referred to as a weighting factor. Thus, if the output level OL1 of the first pair of sensors 14a is not proximate a relative maximum output level, then the angular position measurement output by the system is predominantly given by Θ1. However, as the angular position of the annular ring 12 approaches one of the relative maximum output levels 50a or 50b, the weighting factor increasingly weights the output level of Θ2 to the angular position measurement value outputted on output signal 24. This formula may be stored in the memory of sensor transducing circuit 22 as an algorithm that continually calculates the angular position based upon output level measurements taken by the sensor transducing circuit 22. Thus, certain embodiments of the present invention may provide a non-contact angular position measurement system that maintains a relatively high degree of accuracy throughout 360 degrees of movement of its shaft.
The output levels of both sensors are then combined using the sensor transducing circuit 22 at act 104. As mentioned previously, the act of combining the output levels may incorporate a weighting factor that increases the weighting of a particular output level that is not proximate a relative peak value. In one embodiment, angular measurements are taken from a first sensor 14a and the output level of the second sensor 14b is increasingly weighted as the output level of the first sensor 14a approaches an relative peak value. In this manner, no abrupt changes in measurements are incurred as the annular ring 12 rotates through its full range of motion. In act 106, the combined angular measurement may then be reported on output signal 24 or 44.
Although the present invention has been described in several embodiments, a myriad of changes, variations, alterations, transformations, and modifications may be suggested to one skilled in the art, and it is intended that the present invention encompass such changes, variations, alterations, transformations, and modifications as falling within the spirit and scope of the appended claims.
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