This invention relates to optical tracking systems and methods, and more particularly to an optical velocity tracking system and method for a paint spray gun.
Paint spray guns are indispensible for large painting projects. Their use permits any object to be painted faster and without brushmarks. Paint spray systems use varying methods to atomize the paint (or other coating product), and allow for quick and even application of paint to the surface of the object to be painted.
When using a paint spray gun, the spraying motion is somewhat of an art in itself. Ideally, the operator moves the gun at a constant velocity back and forth. Experts learn to push the spray button after the gun is up to speed, and to release the button before the end of the stroke. The strokes should be overlapped, wet on wet.
If the spray gun is not properly operated, the result is a messy, unappealing, and ineffective paint job. For example, if the standoff distance is too great or the painting velocity is too fast, the result is inadequate coverage of the surface. If the standoff distance is too close or the painting velocity is too slow, the result is paint runs and wasted paint.
A more complete understanding of the present embodiments and advantages thereof may be acquired by referring to the following description taken in conjunction with the accompanying drawings, in which like reference numbers indicate like features, and wherein:
The following description is directed to a system and method for tracking and reporting velocity of a hand-held paint spray gun. The spray gun operator is provided with real time feedback of the velocity of the spray gun. This feedback information allows the operator to make immediate corrections of speed, ensuring optimal painting results. Wasted paint is lessened, and an adequate amount of coverage is ensured, while reducing the overall time spent painting.
The object 10 to be painted is located in a room having at least one fudicial wall 11. It should be understood that the number of fudicial walls 11 is related to the type of painting (or other coating) being undertaken. For painting a flat surface, a single wall 11 might suffice. However, as explained below, a painting task often involves painting more than one surface of an object, and there will typically be a number of fudicial walls 11.
A camera 12a is mounted on spray gun 12. When spray gun 12 is in use, camera 12a continuously detects fudicials on wall 11. In the example of
An example of a suitable FOV of camera 12a is 85 degrees. A typical maximum tracking distance is 20× the diameter of a fiducial. Each wall 11 has a minimum of two fiducials. Small fidicials are used for tracking close to wall 11, and larger fidicials are used for tracking further away.
In the example of
Various cameras with compact designs suitable for the present application are commercially available. In general, camera 12a may be any type of optical camera, suitable for mounting on a spray gun 12 without adding undue weight and bulkiness. Camera 12a must also be capable of image speeds sufficient for tracking spray gun motion and providing image data for real time feedback in the manner described herein. As stated above, the distribution of processing between camera 12a and computer 13 is not important to the invention so long as real time velocity computations and operator feedback is provided.
A specific type of suitable camera 12a is an “inertially assisted tracking camera”, which has inertial sensors and an integral optical camera, and provides continuous position referencing from the fiducial markers. The result is an accurate 6-DOF (degrees of freedom) tracking device, which combines inertial sensor, camera components, and image processing in one small package. A specific example of such as camera is the InterSense IS-1200 VisTracker, manufactured by Inition of London, England. An advantage of an inertially assisted camera is that the inertial sensors are able to provide redundant tracking data that can be used if the optical tracking data momentarily fails. For example, if the FOV of camera 12a is obstructed, the inertial position tracking can be used instead of optical tracking data for a short period of time.
Referring again to
The arrangement of fiducials on wall 11 is referred to herein as a “fiducial constellation”. In the preferred embodiment, each fiducial is unique in appearance and the fiducials have varying sizes.
A user interface programmed into computer 13 is used to input a target velocity. Velocity thresholds and ranges, such as “optimal”, “too slow” and “too fast” speeds, can be determined and stored.
In Step 42, during operation, camera 12a detects fiducials. In Step 43, processing hardware and/or software of camera 12a uses the detection data and the position matrix to calculate the current location of one or more fiducials. In Steps 44 and 45, a fiducial's current location is compared to its previous location, and with time data, the travel distance can be used to determine spray gun velocity.
More specifically, spray gun velocity can be calculated by movement from one fiducial to another or by a change in the detected diameter of a single fiducial. For example, if the spray gun 12 is being moved in a plane normal to the fiducial wall in the camera's field of view, the camera would detect fiducial diameter changes. If the spray gun 12 is moved in a plane parallel to the fiducial wall, the camera would detect movement from one fiducial to another.
Velocity is calculated from a change from one 3-D position to another. One form of result is a 3-D velocity vector whose magnitude of this vector is the basis of the comparison to the target velocity.
Computer 13 also stores target spray gun speed and for optimal paint coverage. These settings are adjustable, and may be “field adjustable” by the spray gun operator.
As stated above, the distribution of processing between on board processing hardware of camera 12a and computer 13 is not important to the invention. In some embodiments, where the tracking programming is not embedded with camera 12a, image data could be delivered to computer 13, which would then use a stored position matrix to determine location and change of position of the spray gun, and to calculate the current spray gun velocity. It is assumed that either or both camera 12a or computer 13 has appropriate hardware and software for these velocity calculations. It is also possible that all data storage, user input, and operator output tasks could be performed by processing and memory of camera 12a, eliminating a separate computer 13.
In Step 46, during painting, the calculated velocity is repeatedly compared to the stored target velocity at predetermined time intervals. In Steps 47a and 47b, a deviation between the target velocity and the measured velocity results in a signal or other feedback to the user. This informs the operator whether the speed of the spray gun is too slow, too fast, or correct.
A second example of velocity reporting is audio tones. A first tone indicates “slow”, a second tone “optimal”, and a third tone “fast”. These tones could be used alone or in conjunction with the display of
In the embodiment of
This invention was made with U.S. Government support under Contract No. SP4704-97-C-0004, awarded by the U.S. Army. The Government has certain rights in this invention.
Number | Name | Date | Kind |
---|---|---|---|
4492952 | Miller | Jan 1985 | A |
5951296 | Klein | Sep 1999 | A |
6078670 | Beyer | Jun 2000 | A |
7231063 | Naimark et al. | Jun 2007 | B2 |
7244464 | Robens et al. | Jul 2007 | B2 |
8037870 | Saito et al. | Oct 2011 | B2 |
8300117 | Carter et al. | Oct 2012 | B2 |
20080125909 | Eickmeyer et al. | May 2008 | A1 |
20100077959 | Treloar et al. | Apr 2010 | A1 |
20100143089 | Hvass et al. | Jun 2010 | A1 |
20130323695 | Zboray et al. | Dec 2013 | A1 |
Entry |
---|
Lee et al., “Real-Time Vision-Based Tracking Control of an Unmanned Vehicle”, Dec. 1995, Mechatronics, vol. 5, Issue 8, pp. 973-991. |
Number | Date | Country | |
---|---|---|---|
20110216188 A1 | Sep 2011 | US |