The present invention relates to optical sensors, and more particularly, to an optical sensor which can be used to perform odometry tracking.
Optical sensors, such as those commonly used in a computer mouse, can detect miniscule changes in direction in order to track the motion of an object over a 2D surface. Optical sensors work by illuminating the surface on which the object moves to capture an image, and comparing a reference image and the captured image in order to determine how far from the origin the object has moved. This image comparison generates accumulated delta y and delta x values; computer algorithms can then be used to determine the resultant motion of the object.
The advantage of optical sensors is that only a single sensor is needed to determine angular motion, as the optical sensor can generate both delta x and delta y values. Optical sensors are typically used in applications where only small distances need to be determined, however. If an optical sensor could be implemented in an application which moves via the use of wheels, the optical sensor could track the motion of the wheels and then convert the detected motion to real-life distance.
It is therefore an objective of the present invention to employ a single optical sensor for tracking motion of a wheel in order to perform distance and odometry tracking.
An optical sensor system for determining trajectory of a wheel comprises: a wheel mounted in a wheel arch having an outer surface covered with evenly-spaced wheel treads; an optical sensor mounted in the wheel arch but not touching the wheel, for performing a plurality of counts corresponding to respectively capturing a plurality of images of the wheel according to the wheel treads, and comparing the captured images with a reference image to determine a 2D displacement. The optical sensor further performs a calculation to convert the measured 2D displacement of the wheel from its original position into a distance the wheel travels along a path in order to determine the wheel trajectory.
A method for determining trajectory of a wheel comprises: mounting a wheel in a wheel arch, the wheel having an outer surface covered with evenly-spaced wheel treads; utilizing an optical sensor mounted in the wheel arch but not touching the wheel to perform the following steps: capturing a plurality of images of the wheel according to the wheel treads to generate a plurality of counts, respectively; comparing the captured images with a reference image to determine a 2D displacement of the wheel; and performing a calculation to convert the measured 2D displacement of the wheel from its original position into a distance the wheel travels along a path in order to determine the wheel trajectory.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
An exemplary embodiment of the present invention uses an optical sensor positioned above a wheel, as illustrated in
The casings 133, 163, 193 are provided in order to protect the respective optical sensor 131, 161, 191 from damage. These casings can be clear housings that are flush with the wheel arch 120 or protrude. The aim of the casings 133, 163, 193 is to protect the optical sensor 131, 161, 191 from damage. Further, when the optical sensor 131, 161, 191 is used to determine motion of a wheel in a car, the casing 133, 163, 193 can also protect it from splashes etc.
By using one of the optical sensors 131, 161, 191, an accurate determination of how far the wheel 150 has travelled, as well as the trajectory of the wheel 150, can be estimated. As detailed above, the optical sensors 131, 161, 191 are mounted on the top of the wheel arch 120. The wheel arch 120 could be a wheel arch of a motorized vehicle such as a car, or a wheel arch in a treadmill. As the wheel 150 rotates, the optical sensors 131, 161, 191 generate reports based on a number of treads which are imaged.
Refer to
A calibration step generates a ratio that can be used for conversion. The calibration process is performed to calculate how far the wheel turns for each count of the sensor. As noted above, the count corresponds to a sensor tread of the sensor. Assuming the wheel rotates as illustrated in
The circumference of the wheel can be calculated using the Pythagorean equation: C=2πr
As the wheel rotates, delta y values are accumulated until Dy corresponds to one rotation of the wheel. The accumulated value Dy has a direct relationship to C. It is determined how many reports/counts there are in Dy, and this value is used to divide the circumference C in order to generate a distance per count (dpc). This is illustrated by the following equation:
A trajectory of the wheel 150 is then determined. If the optical sensor 131, 161, 191 only plots a change in the y direction, i.e. only delta y values are generated, then the wheel 150 is determined to be rotating without turning and a simple conversion of counts can be used to generate the distance travelled by the wheel 150. If, however, the wheel 150 is both turning and rotating then the angle θ of the wheel turn can be calculated using simple trigonometry, as illustrated in
Once the turning angle of the wheel 150 is determined, a trajectory of the wheel 150 can be plotted, as illustrated in
A perpendicular line to the turned wheel 150 will intersect with an extended line from the rear axles of the car 100 to form a right-angled triangle having sides L, R and E. L is the length of the car 100 and therefore is a known value. Using trigonometry, the length of R and E can be calculated, as illustrated by the following equations:
As illustrated by the dotted lines, the car 100 will move along a curve having a radius R from point O. By using the optical sensor 131, 161, 191 to determine a rotated distance of the wheel 150 and converting that distance into real-world values, a total distance d moved along the curve by the car 100 can be calculated.
As detailed above, a distance per count has been calculated in the calibration stage. This value can be used to calculate a real distance taken by the vehicle 100. When the vehicle 100 moves in a straight direction i.e. no change in x, the values can be directly put into equation (1) by multiplying a number of counts (treads) with the distance per count. In effect, this converts a distance monitored by the optical sensor 131, 161, 191 into a real distance. This is shown below as equation (5):
Distance=Dy×dpc
If the vehicle 100 is turning, the displacement measured by the optical sensor 131, 161, 191 is calculated number by using the hypotenuse of Dx and Dy. This value is then converted into counts, and is multiplied with the value dpc to determine a distance travelled along the curve. This is shown below as equation (6):
Distance=√{square root over (Dx2+Dy2)}×dpc
The final stage in the calculation places this determined distance on the curve calculated in
Although the above is described using a car as an exemplary embodiment, it should be appreciated that the concept can be applied to any application which tracks the motion of a wheel. Further, the optical sensor can also be calibrated to determine a vertical distance from the wheel, so that if air pressure of the wheel changes or some other factors cause the distance between the optical sensor and the wheel to change (the vehicle moves over rocky terrain, for example) the change in distance can be compensated for.
No matter what implementation the optical sensor is applied to, the wheel radius should be set as a known parameter in an initialization procedure. In the example provided in
To summarize, the present invention provides an optical sensor which can utilize changes in 2D motion of a wheel to determine angular motion of the wheel. By plotting a trajectory of the wheel using the determined change in motion, a distance the wheel moves along said trajectory can also be determined.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
This application is a continuation application of U.S. application Ser. No. 17/509,056, filed on Oct. 24, 2021, which is a continuation application of U.S. application Ser. No. 16/831,825, filed on Mar. 27, 2020, which is a continuation application of U.S. application Ser. No. 16/140,444, filed on Sep. 24, 2018, which is a continuation application of U.S. application Ser. No. 14/930,668, filed on Nov. 3, 2015. The contents of these applications are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 17509056 | Oct 2021 | US |
Child | 18223021 | US | |
Parent | 16831825 | Mar 2020 | US |
Child | 17509056 | US | |
Parent | 16140444 | Sep 2018 | US |
Child | 16831825 | US | |
Parent | 14930668 | Nov 2015 | US |
Child | 16140444 | US |