Robotic platform for autonomous automotive vehicle development

A robotic platform for autonomous automotive vehicle development. The platform includes a frame having a plurality of wheels rotatably mounted to the frame. A motor mechanism is associated with at least one of the wheels and the motor mechanism is responsive to drive signals to rotatably drive its associated wheel. At least one sensor is mounted to the vehicle which provides an output signal representative of a parameter relevant to the position of the robotic platform. A programmable control circuit is programmed to generate drive signals in response to the sensor output(s) to simulate the operation of an automotive vehicle for vehicle development.

BACKGROUND OF THE INVENTION

I. Field of the Invention

The present invention relates to a robotic platform for autonomous automotive vehicle development.

II. Description of Related Art

Modern automotive vehicles typically include numerous electronic systems for safety and collision avoidance systems, as well as navigation systems. Such systems, furthermore, typically employ processors, such as microprocessors, which control the operation of the system and perform the various decisions required by the operation of the system.

The development and debugging of software utilized to control the operation of the processors in these various safety, anti-collision and navigation systems has previously represented a time-consuming process. Furthermore, in order to verify the proper operation of the systems during development, it has been the previous practice to implement these systems on an automotive vehicle during all stages of the system development.

The implementation of the systems on an automotive vehicle during the entire development of the system, however, has proven disadvantageous for a number of reasons. First, the relatively high cost of the automotive vehicle itself represents a significant expenditure in the development of the safety, anti-collision and navigation systems. Additionally, in some situations, such as an anti-collision system, it is necessary to subject the automotive vehicle to a potential collision in order to ensure proper operation of the anti-collision system. In the event the anti-collision system does not operate as intended, which typically occurs during the early development of the anti-collision system, damage to the automotive vehicle can result thus further increasing the development cost of these automotive systems.

SUMMARY OF THE PRESENT INVENTION

The present invention provides a robotic platform for autonomous automotive vehicle development which overcomes all of the above-mentioned disadvantages of the previously known systems for vehicle development.

In brief, the robotic platform of the present invention includes a frame having a plurality of wheels rotatably mounted to the frame. In one embodiment, the frame is generally rectangular and four wheels are rotatably mounted to the frame at the corners of the frame in a fashion analogous to an automotive vehicle.

A motor mechanism is associated with at least one of the wheels, and preferably with each wheel so that the wheels may be independently rotatably driven relative to each other. A linear actuator is also associated with the steerable wheels of the platform to simulate vehicle steering. These motor mechanisms and linear actuators, furthermore, are responsive to drive signals from a control circuit.

Preferably, the frame includes multiple mounting means for the platform wheels. Consequently, vehicles having different wheel bases and track width may be simulated by changing the position of the attachment of the wheels to the frame.

At least one sensor is mounted to the vehicle which provides an output signal representative of a parameter relevant to the position of the robotic platform. These sensors can include, for example, a GPS receiver, a camera, a radar system, such as a dedicated short range radar system of the type used in automotive vehicles, and the like.

The control circuit includes a processor, such as a microprocessor, which is programmed to generate the drive signals to one or more of the drive mechanisms. This control circuit is responsive to the output from at least one of the sensors to simulate the operation of an automotive vehicle. However, the overall size of the robotic platform is much smaller than an automotive vehicle so that relatively high speeds of an automotive vehicle may be simulated at a much slower speed.

Consequently, the control circuit for the robotic platform may be programmed not only to simulate different types of automotive vehicles but also programmed to implement safety, anti-collision and/or navigation systems for the automotive vehicle.

With reference first toFIG. 1, an embodiment of the robotic platform10is there shown for autonomous automotive vehicle development. The robot10includes a chassis or frame12which is rigid in construction and much smaller that an actual automotive vehicle. The frame12is preferably made of a lightweight metal material, such as extruded aluminum. Aluminum is also relative inexpensive to obtain and easily machined.

The frame12is preferably rectangular in shape and has a small fraction, less than one half;, the size of a typical automotive vehicle. Preferably, the overall length of the frame12is less than five feet while the width of the frame12is smaller than its length.

With reference toFIGS. 1 and 3, wheel14is rotatably mounted to each corner of the frame12so that the wheels14support the frame12above a ground support surface. A motor mechanism16, such as a servomotor, is rotatably drivingly connected to at least one and preferably all of the wheels14. Consequently, the wheels14may be independently rotatably driven by the servomotor16in response to drive signals provided to the motor mechanism16.

A gear box17is drivingly connected between each motor mechanism16and its associated wheel14. The gear boxes17provide the torque to rotatably drive the wheels and also preferably have integrated controllers and feedback circuits to facilitate accurate control of the overall wheel drive system.

As best shown inFIG. 3a mounting means60, such as a plate, is associated with each wheel. The mounting means60are attached to the frame12by fasteners62each of which extends into one of a plurality of spaced holes64provided in the frame12for each wheel12.

The mounting means60thus enable the position of the wheels14to be varied relative to the frame12to simulate vehicles having different wheel bases and track width by attaching the mounting means60to different holes64in the frame12. Other means, of course, may also be used to adjust the position of the wheels14on the frame127. Likewise, the wheels14having different diameters are attachable to the frame to simulate different wheel sizes.

A linear actuator66is associated with each steerable wheel14, typically the front wheels, of the simulated vehicle which controls the pivotal position of its associated wheel about a vertical axis as shown in phantom line. These linear actuators66, under computer control, enables different steering attributes to be implemented via simulated steering motions through software control. This allows fill drive train customization and representation by the platform10.

At least one, and preferably several, sensors are mounted to the frame12and each sensor provides an output signal representative of a parameter relevant to the position of the frame. For example, these sensors may include a vision sensor or camera18which provides an output from the camera18representative of the visible view of the robotic platform10, and thus the positions of other objects relative to the platform10.

These sensors may also include a rangefinder20which provides an output signal representative of the distance between the robotic platform10and various objects within the range of the rangefinder20. Similarly, a laser rangefinder22may also generate output signals representative of the distance between the platform12and objects which may be relatively distant from the platform10.

The sensors may also include a global positioning system (GPS) receiver24. The receiver24generates an output signal representative of the geographic position of the robotic platform10in the well known fashion.

A dedicated short range radar system25may also be mounted to the frame12. Such a dedicated short range radar system may be utilized to communicate with objects outside of the robotic platform, such as traffic light warning signals, other vehicles, and the like.

All of the signals from the sensors18-24are coupled as input signals to a programmable control circuit26, such as a laptop computer. The control circuit26generates the drive output signals to the motor mechanism in response to the signals from one or more of the sensors18-24to simulate the operation of an automotive vehicle. Furthermore, the control circuit26may be programmed differently to simulate different types of automotive vehicles.

For example, the control circuit may be programmed to only drive the front two wheels14by the motor mechanism16and associated gear boxes17in order to simulate a front wheel drive. Conversely, the control circuit26generates output drive signals to only the rear two wheels14in order to simulate the operation of a rear wheel drive automotive vehicle and, similarly, to all four wheels14to simulate an all wheel drive vehicle. Likewise, the control circuit26is programmed to simulate other types of parameters for different vehicles, such as braking distance, turning radius, etc. which varies between different types of vehicles.

With reference now toFIG. 2, the robotic platform10, once programmed to simulate a particular type of vehicle and with the wheels14attached to the frame12by the mounting means60may be used for the development of automotive safety, collision avoidance and navigation systems. By way of example only, the robotic platform10is illustrated inFIG. 2as traveling a route50between various objects52. Under control of anti-collision or object avoidance software, the robotic platform10travels the route50which avoids all of the objects52. However, during the development of some software, and when the software is not operating in the desired fashion, the robotic platform10may contact one of the objects52. In that event, the object avoidance or collision avoidance software may be repeatedly improved and “debugged” until it operates in the appropriate fashion. During this entire development, however, the robotic platform10remains undamaged due to both its circuit construction and relatively low speed operation.

The relatively small size of the robotic platform10as compared to the size of an automotive vehicle also enables the robotic platform10to simulate the operation of the automotive vehicle at relatively slow speeds which, when scaled, form an accurate simulation of high speed movement of the automotive vehicle. This low speed of the robotic platform10also facilitates the development of the vehicle software.

Still other types of systems may be easily simulated by the robotic platform10. For example, using dedicated short range radar, the automotive vehicle10may communicate with other devices, such as a traffic light warming system, other vehicles and development of the software for the vehicle.

From the foregoing, it can be seen that the present invention provides a simple and yet effective robotic platform to facilitate in the development of software for automotive vehicle development and particularly for the safety systems, anti-collision systems and navigation systems for the automotive vehicle. Having described my invention, however, many modifications thereto will become apparent to those skilled in the art to which it pertains without deviation from the spirit of the invention as defined by the scope of the appended claims.