Autonomous tennis ball retrieval robot

Abstract

An autonomous robot that collects tennis balls on a tennis court surface and transfers them into a tennis ball shooter.

Claims

1. A machine for autonomously collecting tennis balls and transferring them into a tennis ball shooter, where said machine comprises: a. a motive drive system operable to generate movement of said machine across a level surface, b. a storage receptacle to contain the collected tennis balls, c. a pickup assembly operable to collect tennis balls from said level surface into said storage receptacle, d. a deposit assembly operable to transfer tennis balls from said storage receptacle to said tennis ball shooter.

2. The machine of claim 1 wherein the motors are controlled directly via remote control through an electronic device.

3. The machine of claim 1 wherein there is at least one vision sensor arranged to allow said machine to locate and navigate to tennis balls.

4. A tennis ball of predefined color wherein the vision sensor of claim 3 is configured to detect only objects of said predefined color.

5. The machine of claim 1 wherein there is at least one vision sensor arranged to allow said machine to locate and navigate around people.

6. The machine of claim 1 wherein the deposit assembly comprises: a. a shooting assembly that provides a means for imparting an initial velocity to tennis balls in a desired direction at a desired speed, b. a funnel assembly, wherein the funnel assembly guides tennis balls stored in the storage receptacle of claim 1 into said shooting assembly which launches said tennis balls into the tennis ball shooter of claim 1.

7. The shooting assembly of claim 6 wherein there is at least one vision sensor arranged to provide information regarding the location of a tennis ball shooter, allowing said shooting assembly to accurately launch balls into said tennis ball shooter.

8. An object with a predefined shape, color, or other distinct characteristic that can be attached to a tennis ball shooter wherein the vision sensor of claim 7 can use said object to better distinguish the location of said tennis ball shooter.

9. A method for collecting tennis balls and transferring them into a tennis ball shooter using an autonomous machine comprising: a. providing a machine for autonomous operation comprising: a drive system, and at least one sensor configured for detecting the velocity of said drive system, b. a vision system containing at least one vision sensor configured to locate tennis balls, and c. operating said machine in a level surface including: locating tennis balls on said level surface using said vision system, navigating across said level surface to said tennis balls, collecting said tennis balls, navigating across said level surface to said tennis ball shooter, and transferring said tennis balls into said tennis ball shooter.

10. A machine for automatically collecting tennis balls and transporting them into a tennis ball shooter that keeps track of its position relative to the surface it is located on.

11. The machine of claim 10 wherein there is at least one sensor arranged to record the position of said machine.

12. Markers that can be placed in predetermined positions on a level surface wherein the machine of claim 10 uses said markers to determine its position relative to said level surface.

13. The machine of claim 10 wherein said machine keeps track of its position relative to the tennis ball shooter of claim 10.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIGS. 1A, 1B, and 1C show the autonomous tennis ball retrieval robot from an angled view, lateral view, and the top view respectively.

[0016] FIG. 2 shows an embodiment of a target that can be hung on a tennis ball shooter.

[0017] FIG. 3 shows an embodiment of a target that can be placed at a predetermined position on the tennis court.

[0018] FIG. 4 shows a flowchart demonstrating the robot's autonomous control loop.

DETAILED DESCRIPTION

Robot Mechanical Design (FIGS. 1A, 1B, and 1C)

[0019] One embodiment of the autonomous tennis ball retrieval robot is illustrated in FIGS. 1A (angled view), 1B (lateral view), and 1C (top view). The robot is comprised of a chassis (1), a drive system (2), a pickup assembly (3), a storage assembly (4), a deposit assembly (5), and a control system (6). For the purposes of this specification, the term front in the context of the robot will refer to the side of the robot in which the pickup assembly (3) is attached.

[0020] The robot's four-wheel drive system (2) is mounted to the chassis (1) wherein each wheel (7) is directly attached to an individual electric gearhead motor (8). The wheels (7) are of sufficient diameter to ensure that when the robot is placed on a tennis court surface the chassis (1) does not come in contact with the ground, while remaining small enough to ensure that the robot's pickup assembly (3) is effective. Any gearhead motor configuration and placement are sufficient, provided the robot can navigate as quickly as possible while still able to accurately detect and move towards tennis balls on the tennis court surface.

[0021] The pickup assembly (3) comprises an intake roller (9) and an intake ramp (10), both mountable to the front of the chassis (1). The intake roller (9) has a generally cylindrical base of inflexible material surrounded by a layer of malleable or textured material such as rubber. The cylindrical core is mounted to an axle (11) so it rotates about its center axis, and the axle (11) is in turn attached to an electric motor (12). The intake roller (9) is mounted above the ground such that its outer edge is a certain distance under the diameter of a tennis ball (2.57-2.70 inches) above the ground. This distance, as well as the pickup assembly's (3) rpm and the angle and placement of the intake ramp (10), is inconsequential provided that the pickup assembly (3) is able to effectively transfer tennis balls from a tennis court surface into the robot's storage assembly (4).

[0022] The storage assembly (4) itself comprises a storage receptacle (13) with a ramp (14) as its base. The storage receptacle (13) is constructed with any material inflexible enough to contain a multitude of tennis balls such as plastic, sheet metal, or plywood. Plates of this material are used to form a container able to store a minimum number of 15 tennis balls to ensure that the robot can operate efficiently. In addition, the receptacle (13) must be constructed in a way that it funnels the tennis balls it contains towards the tennis ball opening (17) in the shooter frame (16) which is described in further detail in the following paragraph. In this particular embodiment, this is done using a ramp (14) angled from the top of the intake ramp (10) to the base of the shooter frame (16). Further funneling of the tennis balls is done using two more plates (15) mounted on the left and right of the storage receptacle (13) normal to the chassis (1). These plates (15) begin on either side of the intake ramp (10), and the gap between them gradually narrows until they end on either side of the tennis ball opening (17) in the shooter frame (16). The resulting assembly ensures that the left and right movement of the tennis balls contained within the storage receptacle (13) is restricted, causing them to funnel directly into the tennis ball opening (17) in the shooter frame (16).

[0023] In this embodiment, the deposit assembly (5) comprises a shooter frame (16) on which a flywheel (19) is mounted. The shooter frame (16) consists of a hollow cylinder composed of a light, inflexible material such as plastic. The shooter frame's (16) diameter must be sufficient to allow a single tennis ball to pass through without resistance but should remain small enough to ensure that the accuracy of the deposit assembly (5) is not inhibited by permitting the tennis ball too much freedom of movement. At the base of the shooter frame (16) are two openings: a tennis ball opening (17) just large enough to allow a single tennis ball to pass into the shooter frame (16) at a time, and a flywheel opening (18) in which the flywheel (19) mounted to the shooter frame (16) can contact the tennis ball, providing it with an initial velocity. The flywheel (19) itself is fixed to an axle (20) passing through its center axis, which is in turn attached to an electric motor (21). The assembly is then mounted to the shooter frame (16) in such a way that it can rotate freely. The distance the assembly is mounted above the chassis (1) is immaterial provided that the flywheel (19) supplies tennis balls in the deposit assembly (5) with sufficient initial velocity to exit the opposite end of the shooter frame (16) and land at a desired location within an acceptable margin of error.

[0024] In operation, the robot is capable of autonomously propelling itself across a tennis court surface retrieving and depositing tennis balls. When in autonomous mode, it utilizes information from its sensors and reacts accordingly to adequately execute its respective functions, namely the direction to take and when to deposit the tennis balls. To achieve this, the robot carries an appropriate control system (6), taking the form of a programmable microcontroller (22), a chargeable battery (23), and appropriate control circuitry and processing functionality to control electric motors and process signals received from its various sensors such as a gyroscope (24), an encoder (25), and at least one camera (26).

Operation of Robot Mechanical Design (FIGS. 1A, 1B, and 1C)

[0025] The manner of transporting tennis balls dispersed across a tennis court surface into a tennis ball shooter using the autonomous robot illustrated in FIGS. 1A, 1B, and 1C is as follows:

[0026] The robot's camera (26) locates tennis balls scattered across a tennis court surface using robot vision tracking. The robot uses its drive system (2) in communication with a gyroscope (24) to navigate towards the located tennis balls. When within range to contact a tennis ball, the intake roller (9) rotates at a predetermined rotational speed as the robot drives forward over the tennis ball. The compression and friction acting on the tennis ball from the intake roller (9) causes the tennis ball to travel up the intake ramp (10). Once moved up the intake ramp (10), gravity causes the tennis ball to automatically fall into the storage receptacle (13) where it is funneled towards the shooter frame (16).

[0027] When the robot stops retrieving tennis balls and prepares to shoot the ones it has stored, the flywheel (19) rotates at a constant speed using feedback from an encoder (25) sensor, compressing the tennis balls it comes in contact with and imparting them with an initial velocity, causing them to travel through the shooter frame (16) until they are released into the air at a desired velocity pre-calculated by the robot depending on its distance from the tennis ball shooter.

Vision Target First Embodiment (FIG. 2)

[0028] FIG. 2 depicts one embodiment of a distinct diamond shape (27) serving as an example of an object with a predefined shape, color, or other distinct characteristic that can be recognized by the robot's camera (26). In this particular embodiment, the diamond shape (27) is mounted to a supporting board (28) which is in turn attached to mounting hooks (29). The material of each component is inconsequential providing that the supporting material is distinguishable from the distinct diamond shape (27) by the robot's camera (26) and is able to support itself when hung over an edge.

Operation of Vision Target First Embodiment (FIG. 2)

[0029] The distinct diamond shape (27) serves the purpose of providing the robot's camera (26) with a means of determining its position relative to a tennis ball shooter. The target can be hung on the side of such a shooter using its mounting hooks (29). By using this method, the robot can determine what velocity and direction to shoot tennis balls at by using the size of the target as an indicator for the robot's distance away from the shooter, and the distance between the two side corners of the distinct diamond shape (27) as an indicator for the angle of the robot relative to the tennis ball shooter. This ability to determine what variable speeds to shoot the tennis balls at such that they will land in the shooter ensures that the robot can be used with a variety of different shooters of multiple sizes.

Vision Target Alternative Embodiment (FIG. 3)

[0030] An alternative embodiment of the distinct diamond shape (27) is its being fixed to a supporting beam (30) which is, in turn, mounted such that it is normal to a supporting base (31). Thus, the structure can be placed in a predetermined position on a tennis court, allowing the robot's camera (26) to determine the robot's position relative to the tennis court in order for it to better navigate around the tennis court. This, coupled with the robot's gyroscope (24), provides a means for correcting noisy or drifting gyroscope (24) sensor data.

Control Overview (FIG. 4)

[0031] The robot operates autonomously using the decision-making path depicted in FIG. 4. The robot uses its camera (26) to determine the location of a tennis ball on the tennis court using a robot vision algorithm. If a tennis ball can be located, the robot will instruct the drive system (2) to move toward the closest tennis ball. If the robot comes within a predefined distance from the tennis ball, it will rotate the intake roller (9) and continue to drive over the tennis ball, thereby picking it up. Once the tennis ball has been picked up, the robot will attempt to locate another tennis ball. If another tennis ball is located, the robot will repeat the procedure above. However, if another ball cannot be located, the robot will navigate to the tennis ball shooter. When within a predefined area of the shooter, the robot will shoot balls at a speed calculated depending on the robot's exact location, which is determined using the size and orientation of the distinct diamond shape (27) as seen from the robot's current position. Once the robot has been shooting for a sufficient amount of time, it will begin the loop again by attempting to locate another tennis ball.

CONCLUSION

[0032] Accordingly, the reader will see that by constructing a robot with the ability to pick up, contain, and shoot tennis balls with accuracy, and by giving it the means to do so autonomously, practicing tennis with a tennis ball shooter is vastly more convenient. The robot can continuously pick up tennis balls as they are being scattered and eliminate the need to periodically stop practice to collect tennis balls to refill the tennis ball shooter.

[0033] Although the description above contains many specificities, these should not be constructed as limiting the scope of the embodiments but as merely providing illustrations of some of several embodiments. Thus, the scope of the embodiments should be determined by the appended claims and their legal equivalents, rather than by the examples given.