Automatic Vehicle Collison Avoidance and Warning System

Abstract

An integrated system for automatic vehicle collision avoidance and warning for vehicles operating on any highway or road system globally. The system may be used to not only illuminate the brake lights on the following vehicle but also to begin the application of braking pressure as a result of analysis of the speed of the vehicle. The system includes an RFID transponder (either active or passive) located in the rear and front of the vehicle with discrete recognition capability as to vehicle proximity and resulting action to be taken as a result of driver action. On the vehicle either the brake lights will be illuminated ahead of any actual driver action; an initial application of brake pressure as a result of receiving a signal from the vehicle in front, the pressure which is determined by analysis of the current speed of the vehicle or the system will provide additional warning through brake light illumination to the following vehicle with similar equipment and cruise control will be disengaged. The system can be retrofitted into existing vehicles to provide, at a minimum, brake light illumination indicating an action being taken somewhere ahead of your vehicle. The system thereby warns and prevents serious rear-end collisions at highway speeds especially where vehicle size mismatch contributes to the inability of the following driver to see activity in front of the car in front of him.

Description

DESCRIPTION

Over the years vehicles have become larger and highways have become more crowded. In an effort to combat the higher incidents of rear-end collisions, various education campaigns have been undertaken by the Federal Highway Administration. An example is one car length per ten miles per hour of speed rule-of-thumb to avoid rear-ending another vehicle. In a review of the IVHS (Intelligent Vehicle Highway System) model of the future, vehicles will have the potential to control more of their actions on the highway without driver intervention or action. On-board processors have become a reality in the vehicles of today. With the advent of ABS (Anti-skid braking systems), vehicles have taken the first step toward processor assisted braking control for the driver of today.

As mentioned, size differences between trucks, automobiles and between automobiles of various classes is a problem pointed out in the investigation of rear-end collisions. The driver of an average size automobile has a problem with seeing what is happening in front of the vehicle in front of him. This is made even worse through the use of extensive window tinting. Early warning of an impending braking action is either limited severely or gone altogether. This system, AVCAWS (Automatic Vehicle Collision Avoidance and Warning System), will provide a phased approach to eliminating or mitigating this problem on the modern highways and assist in the control of traffic in the highways of the future.

In the basic embodiment of this invention (FIG. 1), System Operation, car No. 1 begins the process by applying the brakes (100). As the brakes are being applied in car No. 1, an on-board active RFID (radio frequency identification system) located in the rear tail light assembly, is transmitting a signal (110) that is received by the active transponder RFID located in the headlight assembly on car No. 2 (125). Car No. 2's brake lights are automatically illuminated (115). Car No. 3's (135) driver begins to actually apply the brakes (120) thereby taking action ahead of the actual visual slowing of car No. 2 (130). This series of events prevents a total surprise to the driver of car No. 3 since the brake lights of car No. 1 are not visible to the driver of car No. 3 due to the size and the height mismatch of the class of vehicles. Active RFID power limitation and discrete recognition frequency and code prevents false signal representation across multiple lanes of traffic.

In the IVHS of the future, another enhanced embodiment is that the processor in car No. 2 (130) would look at the speed of the vehicle and begin to apply the brakes automatically before the driver could take action. The same event would take place in car No. 3 (135) through a similar active RFID transmitting to car No. 3 and the brakes would be applied as a result of analyzing the current speed and when the driver finally reacts to the brake lights illuminating on car No. 2 the driver would continue the brake application from the current applied brake pressure as already applied by the automatic system. This would also disengage the cruise control system as well.

We therefore have a system that takes both pre-emptive action and also provides a signal that requires a driver to take physical action as well. It is an invention that would be capable of not only saving lives in the initial embodiment but also provide a tool to be retrofitted into existing vehicles during routine maintenance visits.

This invention could apply to not only automobiles but trucks and other typical over-the-road vehicles operated around the globe.

A detailed block diagram, FIG. 2, shows how AVCAWS would be connected on the vehicle. Active RFID receive (200) in the head light assembly, would send a signal to the on-board processor (202). The processor would send a signal to the tail light wiring module (204) to illuminate the rear tail lights (205) and also activate the active RFID located in the rear tail light assembly (203). In the enhanced embodiment, the on-board processor (202) would take additional input from the speed sensor (206) and a signal would be sent to the ABS (anti-skid braking system) (207) and it would apply the brakes automatically (208) and disconnect the cruise control, if engaged, at that time.

Detailed description of the preferred embodiment is provided herein. It is to be understood, however, that the present invention may be embodied in various forms. Therefore, specific details disclosed herein are not to be interpreted as limiting, but rather as a basis for the claims and as a representative basis for teaching one skilled in the art how to employ the present invention in an appropriately detailed system, structure or manner.

In the foregoing specification, the invention has been described with reference to specific embodiments. However, one of ordinary skill in the art appreciates that various modifications and changes can be made without departing from the scope of the present invention as set forth in the claims below. Accordingly, the specification and figures are to be regarded in an illustrative rather than a restrictive sense and all such modifications are intended to be included within the scope of the present invention.

In addition, benefits, other advantages, and solutions to problems, and any element(s) what may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as critical, required, or essential feature or element of any or all the claims. As used herein, the terms “comprises,” “comprising” or any other variation thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

While the invention has been described in connection with a preferred embodiment, it is not intended to limit the scope of the invention to the particular form set forth, but on the contrary, it is intended to cover such alternatives, modifications, and equivalents as may be included within the spirit and scope of the invention as defined by the appended claims.

Claims

1. A totally integrated system for automatic vehicle collision avoidance and warning system for vehicles, said system comprising: an automatic vehicle collision avoidance and warning system having a RFID transponder located on the vehicle to enable communications to another vehicle with similar equipment installed, an RFID transponder located on the vehicle that provides a communication signal to another vehicle with similar equipment, an RFID transponder located on the vehicle that provides a communication signal indicating a braking action being taken by a vehicle, an RFID transponder that has links into the braking system of the vehicle and provides an indication of braking activity through a signal to another vehicle with similar equipment, an RFID transponder on a similar vehicle that is linked to the braking system that provides a signal to illuminate the brake lights on the receiving vehicle, an RFID device that can be either active or passive, a means for sending an RFID signal to another vehicle with similar equipment and that vehicle being able to receive it and take action through the illumination of the brake lights on the receiving vehicle, a means for linking to an existing brake system in order to analyze the speed and have the anti-skid braking system apply the brakes prior to the driver taking action and disconnect the cruise control, a means to link into an existing brake light system on the vehicle, a means to allow the driver of the vehicle to apply brake pressure from the existing pressure application initially applied by the signal and analysis of the AVCAWS system, a means to distinguish the difference through either discrete frequency or identification as to whether the vehicle is following or providing the lead signal for the purposes of braking and brake light illumination.

2. A process for automatic vehicle collision avoidance and warning system comprising a RFID transponder system located on the vehicle that links with the ABS system, the speedometer system and the cruise control system, said system allows the illumination of the brake lighting system ahead of the taking of driver action on vehicles that are following another during highway traffic patterns, linking to the braking system of the vehicle including the brake lights and the speedometer system, providing an early warning brake light to a following vehicle equipped with similar equipment enabling the following driver to be aware of impending braking activity on the lead vehicle, providing a linkage to the ABS on the vehicle in order to begin early application of brake pressure to prevent rear-end collisions, providing a linkage to the speedometer processor on the vehicle in order to compute the amount of brake pressure to be applied as a result of receiving a signal from the RFID transponder on the vehicle in front of the receiving vehicle, providing a discrete RFID signal, either active or passive, that generates a signal for the on-board processor and wiring module, providing a combination of both braking pressure and brake light illumination to the following vehicle equipped with similar RFID AVCAWS installation.