Abstract: A real-image picking-up means picks up a real image of a blind area. A moving object detecting means recognizes a moving object from the real image and detects a moving state of the moving object. An imaginary-image specifying means specifies an indication manner of an imaginary image which is to be indicated for showing the moving state of the moving object. An indicating means indicates the imaginary image of the moving object in the indication manner which is specified by the imaginary-image specifying means such that the imaginary image of the moving object indicated by the indicating means overlaps the real image picked up by the real-image picking-up means. There can be provided a surroundings monitoring device for a vehicle which can easily recognize the state of the moving object in the image of the blind area.

Abstract: A vehicle peripheral monitoring apparatus is disclosed. The apparatus includes a forward monitoring unit for monitoring an obstacle within a predetermined forward area extending in a direction forward of an own vehicle; one or more forward-lateral monitoring units for monitoring an obstacle within a predetermined forward-lateral area extending in a direction lateral of the own vehicle relative to the predetermined forward area; and a traveling environment detecting unit for detecting a traveling environment of the own vehicle, wherein the monitoring with the forward-lateral monitoring units is suppressed when the traveling environment detecting unit detects that the own vehicle is traveling on a predetermined road including a highway, and a level of the suppressing of the monitoring with the forward-lateral monitoring unit is eased when the traveling environment detecting unit detects that the own vehicle is traveling in a predetermined area, including a junction, of the predetermined road.

Abstract: The invention relates to a method and apparatus for predicting/alarming the moving of hidden objects. The apparatus comprises: a distance sensing unit, for obtaining a distance data detected within a specific sensing range and thus outputting the distance data; a speed sensing unit, for measuring the movement of a carrier to obtain a real-time speed data of the carrier and thus output the speed data; a control unit, for receiving and analyzing the distance data and the speed data to obtain information relating to the position of the carrier, the environment surrounding the carrier and positions of objects moving in the blind spots of the carrier, and thus to perform an evaluation based upon the aforesaid information to determine a danger level for issuing a control signal accordingly; and an alarm unit, for issuing an alarm signal according to the control signal.

Abstract: A lane-change assistant for motor vehicles, having a sensor system to locate vehicles on adjacent lanes in the rear space of the own vehicle, a decision module to decide whether a vehicle located in the rear space is on an immediately adjacent lane, and a driver interface to output the decision result, characterized in that a determination module is provided to determine the lane on which the own vehicle is traveling, and the decision module is designed to make the decision as a function of the result of the determination module.

Abstract: A dangerous drive predicting apparatus is provided which is capable of rapidly recognizing a future situation of the own vehicle by other vehicles. The dangerous drive predicting apparatus is equipped with: drive information detecting section 110 for detecting drive information containing at least one of a drive action and vehicle information; traffic environment detecting section 120 for detecting a traffic environment around a first vehicle; driving characteristic producing/storing section 130 for producing and storing a driving characteristic every traffic environment based upon the drive information and the traffic environment; and a driving characteristic transmitting section for transmitting the driving characteristic to a second vehicle.

Abstract: Zone selection logic in an area monitoring device increases the number of unique monitoring zone selections that can be selected using a limited number of discrete zone selection inputs, without compromising the safety critical operation of zone selection. The device monitors the logical state of each input in a set of individual inputs and recognizes each unique logical combination of zone selection inputs as a different zone selection. For example, each of two or more configured monitoring zones is associated with a different combinatorial zone selection pattern of asserted zone selection input signals. Correspondingly, a control circuit within the area monitoring device is configured to monitor the discrete zone selection inputs and activate a given one of the configured monitoring zones based on recognizing the associated combinatorial zone selection pattern of asserted zone selection signals.

Abstract: An obstacle detecting portion (11) on a vehicle detects an obstacle behind the vehicle. A CPU (20) detects the direction of the driver's line of sight based on a driver's face image captured by a camera (12). The CPU (20) determines whether the direction of the driver's line of sight directed to mirrors (51L, 51R) reflecting an image of the obstacle behind the vehicle. According to the result of the determination, the CPU (20) sets the level of an alarm to be outputted by warning signal outputting portions (15, 16).

Abstract: A system and method for warning vehicle operators of obstructions are provided. First clearance data of the vehicle, including vehicle height and width, are obtained and stored in memory. An obstruction in the vehicle's path and the travel surface between the vehicle and the obstruction are scanned by a sensor device. Second clearance data of the obstruction, including the height and width of the vehicle passage defined by the obstruction, are determined and are stored in memory. Utilizing a comparison/warning signal generating device, the first and second clearance data are compared, and a warning signal is generated when values of the first clearance data are equal to or greater than corresponding values of the second clearance data. A monitoring device monitors the time period between generation of the warning signal and responsive action by the vehicle operator to avoid a collision.

Abstract: The present invention relates to a method for avoiding a collision between a vehicle and another traffic participant. According to the inventive method, a cell phone carried by the traffic participant sends a signal including a position of the traffic participant. A processing unit processes the signal including the position of the traffic participant for a position or evaluation history. The processing unit determines an estimation of a future position of the traffic participant on the basis of the position or evaluation history. The processing unit evaluates a likelihood of a collision between the vehicle and the traffic participant on the basis of the estimated future position of the traffic participant and an estimation of a future position of the vehicle. An acceleration of the traffic participant is sensed by an acceleration sensor of the cell phone.

Abstract: Disclosed herein is a traffic control apparatus and method. The traffic control apparatus includes a navigation route database (DB) for storing navigation routes of a vehicle for respective navigational situations. A vehicle situation information collection unit collects current navigational situation information of the vehicle. A preferred route extraction unit extracts a preferred navigation route of the vehicle corresponding to the collected current navigational situation information from the navigation route DB. A predicted route estimation unit estimates a predicted navigation route of the vehicle based on the extracted preferred navigation route with to reference to a traveling state of the vehicle.

Abstract: A display device of the present invention is mounted on an automotive vehicle. An obstacle located in front of the vehicle is detected by a camera, and its features including speed, distance, size, etc. are analyzed by electronic circuits. An image showing the features of the front object is outputted from a liquid crystal panel. The outputted image is reflected on the windshield, displaying a virtual image to a driver. The virtual image is displayed in a form of a spot encircling the front obstacle seen through the windshield. The ways of displaying the encircling spot are variously changed according to a degree of collision danger that is determined according to a period in which the vehicle reaches the obstacle. For example, if the degree of collision danger is high, the spot is shown in red-orange color and/or with a high brightness. Thus, the driver easily recognizes the front obstacle in a high degree of collision danger.

Abstract: A vehicular blind spot detection system (700) for alerting a driver of a motor vehicle to an object in the vehicle's blind spot, the system includes a first imaging device (707) used typically used to control vehicle lighting and that works to detect objects substantially forward of the vehicle and a second imaging device (709) typically used with a rear camera display (RCD) for detecting objects substantially rearward of the vehicle. A control unit (711) is coupled to the first imaging device (707) and second imaging device (709) that includes a graphic processing unit (713) for processing images captured by the first imaging device (707) and second imaging device (709) for detecting an optical flow of objects within the images so as to discriminate between vehicles and other objects entering the driver's blind spot.

Abstract: A method and system for using vehicle-to-vehicle cooperative communications for traffic collision avoidance. One vehicle detects a “situation”, such as a pedestrian within the crosswalk, where an “offending object” is in or near a roadway feature, which could result in a collision. The detecting vehicle informs a second vehicle via wireless communications, of the detecting vehicle's GPS location, the GPS location of the detected object, and the GPS location of the roadway feature, i.e., a crosswalk boundary. Additional data about the “offending object” can include its speed and heading. A receiving vehicle receives this data and takes appropriate avoidance action.

Abstract: Accident avoidance system using an infrastructure system to convey location information between vehicles includes at least two vehicles approaching or traveling on a roadway and each having onboard, a position determining system onboard that receives satellite positioning signals from a plurality of satellites and determines location information based on the satellite positioning signals, a transmitter that transmits the location information for the vehicle to an infrastructure system, a receiver that receives location information for another vehicle from the infrastructure system, and an accident risk warning system that alerts its operator of a risk of an accident based on the location information for any other vehicles and map data representing the roadway including edges or lane boundaries of the roadway.

Abstract: A cruise control for a vehicle that detects an inter-vehicle distance to a preceding vehicle. A first vehicle speed instruction value is computed based on the inter-vehicle distance. Curve information of a curve in the road ahead of the vehicle is detected, and a second vehicle speed instruction value is computed for traveling on the curve based on the curve information. A final target vehicle speed is set based on the vehicle speed instruction values. When the vehicle travels through the curve while the first vehicle speed instruction value is larger than the second vehicle speed instruction value, the final target vehicle speed is set to a vehicle speed higher than the second vehicle speed instruction value and lower than the first vehicle speed instruction value. The speed of the vehicle is controlled based on the final target vehicle speed.

Abstract: Disclosed are embodiments of a vehicle-to-vehicle traffic queue information communication system, a traffic queue information communication device, and method. The system and method embodiments incorporate the use of multiple vehicles. Each vehicle is equipped with a traffic queue information communication device. Each traffic queue information communication device can be used to determine if its corresponding vehicle has entered or exited a queue in a single lane of traffic. When the vehicle is in a queue, the device can communicate with the immediately adjacent vehicles in front and behind. Specifically, it can receive data from the preceding vehicle in the queue and use the received data to determine its position in the queue as well as the estimated time it will take to travel through the queue. Revised data can then be transmitted by the device to the next vehicle in the queue for making the same determinations.

Abstract: A collision predicting apparatus detects subject targets present in the traveling course of the own vehicle by using the relative distance and the relative velocity, etc. The apparatus also calculates the predicted collision time of each subject target on the basis of the relative distance and the relative velocity. The apparatus also detects the relative lateral position of each subject target, and corrects the relative lateral position. The apparatus then executes a collision-predicted target selecting routine, in which the predicted collision time of each subject target that does not meet a predetermined condition is set at a predetermined maximum value. The apparatus selects a subject target that meets the predetermined condition as a collision subject target, and predicts whether the collision subject target will collide with the own vehicle.

Abstract: A vehicle periphery monitoring device which determines type of an object with high accuracy, wherein the size of object regions that are set in each of the image representing the peripheral condition of the vehicle in each of two different points in time and that include the identical objects, are aligned on the basis of the distance from the vehicle to the object in each of the two different point in time. Further, local regions with the same arrangement pattern are set taking each of the object regions with aligned size as reference. Still further, the object is classified into the object class which corresponds to the arrangement pattern in the case where the degree of correlation between the local regions becomes equal to or larger than a threshold value.

Abstract: A vehicle blind spot occupation warning system includes a vehicle that has a front end, a rear end, a first lateral side and a second lateral side. A first rear view mirror is mounted on the first lateral side and a second rear view mirror is mounted on the second lateral side. A pair of heat detecting sensors is provided. Each of the first and second lateral sides has one of the sensors attached thereto and the sensors are positioned adjacent to the rear end. The heat detecting sensors detect heat from vehicles positioned at least within 30 feet laterally and rearwardly of the first and second lateral sides. At least one light emitter is in communication with the heat detecting sensors and emits light when the first or second sensor detects heat.

Abstract: A movable area acquisition ECU 1 compares a possible path for a host vehicle and a predicted path of another vehicle in a travel area of the host vehicle with each other to obtain a possibility of collision between the two vehicles, thus computing a degree of danger to the host vehicle. If the degree of danger to the host vehicle exceeds a predetermined threshold, the travel area is extended and then a degree of danger to the host vehicle is computed and acquired.

Abstract: The present invention discloses a direction guiding apparatus for indicating a guidance direction to a user. The direction guiding apparatus includes an operation device having an operations part movable on an operation plane, and a control part for transmitting control data to the operation device for controlling the movement of the operations part. The guidance direction is distinguishable by the movement of the operations part.

Abstract: Various approaches for a traffic control preemption system that includes a receiver, a light emitter, and control circuitry. The receiver includes a photodetector and circuitry that produces a number of electrical pulses in response to each detected light pulse. For each detected light pulse the number of electrical pulses represents a level of radiant power of the light pulse, and a threshold number of electrical pulses and an activation frequency at which the threshold number of electrical pulses is repeated activates preemption. The control circuitry is coupled to the light emitter and controls the light emitter to emit bursts of light pulses. Each burst includes at least two light pulses and a frequency of light pulses in each burst and a frequency of the bursts cause the receiver to produce at least the threshold number of electrical pulses at the activation frequency and activate the preemption.

Abstract: Image information apparatuses, methods, and programs acquire image information of a plurality of frames of images sensed at predetermined regular time intervals. The apparatuses, methods, and programs detect a leading and trailing end of a lane mark included in a detection area defined in each frame of the image information. The apparatuses, methods, and programs detect a detected distance from one of the leading and trailing end of the lane mark to the other one as a detected distance based on the speed of the vehicle and the number of frames between a frame in which one of the leading end and the trailing end of the lane mark is detected and a frame in which the other one of the leading end and the trailing end of the lane mark is detected and determine a lane mark type of the lane mark on the basis of the detected distance.

Abstract: An obstacle avoidance control device has a detector for detecting the distance between a vehicle and an obstacle and the relative speed of the vehicle with respect to the obstacle, a memory for storing a map for calculating vehicle generation force to avoid the obstacle based on a parameter set by a physical quantity determined by a component Vx in the vehicle front-rear direction as of the relative speed, a component Vy in the vehicle lateral direction of the relative speed, and a distance Ye? in the vehicle lateral direction, for avoiding the obstacle, and a computing unit for computing the parameter based on the distance and the relative speed that are detected by the detector and computing vehicle generation force by using the calculated parameter and the map.

Abstract: A method and an apparatus for warning of emergency vehicles in emergency service. The emergency vehicles use vehicle-to-vehicle communication to transmit warning messages which are received by other vehicles and are indicated to the driver of the receiving vehicle. In order to allow rapid orientation of the driver, provision is made for the warning message from the emergency vehicle to have a position statement for the emergency vehicle and for the position statement to be evaluated in the vehicle which receives the warning message, wherein the position of the emergency vehicle is indicated relative to the position of the receiving vehicle.

Abstract: A mirror reflective element sub-assembly suitable for use for an exterior rearview mirror assembly of a vehicle includes a mirror reflective element, a mirror back plate having an indicator receiving portion established thereat, and a signal indication module having a light source. The signal indication module attaches to the indicator receiving portion of the mirror back plate and the light source is activatable to emit light through the indicator receiving portion. The light source is established at a circuit element and the signal indication module includes a housing that substantially encases the circuit element therein. The circuit element has electrical terminals extending therefrom and protruding at least partially at a connector portion of the housing so as to be electrically connectable to a power source of the vehicle. The connector portion of the housing is configured to provide a plug-socket connection between the power source and the signal indication module.

Abstract: An object of the present invention is to provide a steering assist system capable of showing a driver an appropriate direction of steering operation in advance and correctly, and without impairing safety, and shortening an operation time during collision avoidance, in particular, reducing an idle running time. It is another object of the present invention to provide a vehicle mounted with such a steering assist system. A recommended steering direction determination unit 102 determines a recommended steering direction using measurements of a lateral position taken by an obstacle position measurement unit 101. After a collision determination unit 103 determines that risk of collision is high, a steering assist torque is generated using a first assist torque command value set by a first torque calculation unit 105.

Abstract: A parking space is detected by using a range sensor. Distance data in a predetermined period is collected by using the range sensor according to a user's selection and mapping the collected distance data on a coordinates system based on a parking space searching vehicle. The collected distance data are classified into short distance data and long distance data. Parking-available distance data, is calculated. Whether the parking space exists based on the calculated parking-available distance data is checked. The parking space searching vehicle is stopped by controlling an active braking apparatus or recommending a driver to stop the parking space searching vehicle by means of a voice and alarm sounds when it has been checked that the parking space exists.

Abstract: A system for monitoring a volume of space surrounding an aircraft having a plurality of extremity portions includes a plurality of sensors. Each sensor is disposed at a respective corresponding one of the aircraft extremity portions. Each sensor is configured to generate an image of a monitored area covering a predetermined distance from the extremity portion at which the sensor is disposed. A processing device is configured to determine, from an image generated by a first sensor of the plurality, a characteristic of an object within the monitored area covering the predetermined distance from the extremity portion at which the first sensor is disposed. The processing device is further configured to generate a signal in response to determining the object characteristic.

Abstract: An object detection system is provided for detecting a thermal emitting object in a blind zone proximate to a host vehicle. The system includes a thermal radiation detector located on a host vehicle and configured to sense temperature of multiple coverage zones proximate to the host vehicle. A processor processes temperature sensed by an infrared detector. The processor determines a change in thermal temperature sensed by the infrared detector and determines the presence of an object in the coverage zone based on the change in the sensed temperature. An output provides a signal indicative of an object sensed in the coverage zone based on the determined change in temperature.

Abstract: A vehicle control system controls the speed of a vehicle according to actual road conditions and state of the vehicle. The control system acquires a present value of lateral acceleration occurring in a direction lateral to a controlled vehicle when the controlled vehicle avoids a collision with an obstacle or passes the obstacle. A target relative speed between the obstacle and the controlled vehicle is calculated from the present value of lateral acceleration and a turning radius of the controlled vehicle required for the controlled vehicle to avoid a collision with the obstacle or to pass the obstacle. Then, deceleration control is executed based on target relative deceleration rate at which the controlled vehicle is to be decelerated to reach the target relative speed.

Abstract: A method is provided for efficiently processing messages staged for authentication in a security layer of a protocol stack in a wireless vehicle-to-vehicle communication system. The vehicle-to-vehicle communication system includes a host vehicle receiver for receiving messages transmitted by one or more remote vehicles. The host receiver is configured to authenticate received messages in a security layer of a protocol stack. A wireless message broadcast by a remote vehicle is received. The wireless message contains characteristic data of the remote vehicle. The characteristic data is analyzed for determining whether the wireless message is in compliance with a predetermined parameter of the host vehicle. The wireless message is discarded prior to a transfer of the wireless message to the security layer in response to a determination that the wireless message is not in compliance with the predetermined parameter of the host vehicle. Otherwise, the wireless message is transferred to the security layer.

Abstract: A collision avoidance system for a mobile unit includes an image capturing unit for capturing an image of an environment surrounding a mobile unit. Motion vector is calculated based on the captured image. Collision probability is calculated based on the motion vectors of the image. The system includes a plurality of receptive field units that are modeled on the optic lobe cells of the flies. Each of the receptive field units includes a filter producing an excitatory response to the motion vector diverging from the center of the receptive field in the central area of the receptive field and producing an inhibitory response to the motion vector converging toward the center of the receptive field in the areas around the central area. The outputs of the receptive field units are compared to determine a direction in which the obstacle approaches the mobile unit. The mobile unit moves in a direction to avoid collision.

Abstract: A tracking system adapted for use with communicatively coupled traveling host and remote vehicles, includes a locator device configured to determine sets of current position, and trail coordinates for each of the vehicles. The preferred system further includes sensors operable to determine a condition value for each vehicle at each of said set of coordinates, and a controller configured to determine a congruent path between the vehicles, and a congruent path divergence by the host vehicle, and cause the transmission of an alert of the divergence from the host vehicle to the remote vehicle using vehicle-to-vehicle communication.

Abstract: A vehicle has a safety system including at least one object sensor to detect a distance from an object in a path of the vehicle and the speed and acceleration of the object. The sensor data is input into a control to determine a desired braking judgment line and a steering judgment line between the vehicle and the object. The safety system then compares the vehicle and object acceleration. Following, the safety system calculates a judgment line between the object and the vehicle based upon equations for the determined scenario. The judgment line is then used to determine a warning distance and warn a vehicle operator.

Abstract: Different types of position solutions may be used to determine the position of a mobile station (104) in a wireless communication system (101). The position solutions include terrestrial, or network (102, 103), based techniques and non-network, such as satellite (160), based techniques. An apparatus and method whereby different position solutions are selected based on a figure of merit of the different solutions in determining a position of a mobile remote unit (104).

Abstract: A method for detecting and alerting a user of objects in their blind spots, includes: tracking movement and relative position of a user to one or more objects; determining a blind spot of the user; determining when at least one of the one or more objects occupies the blind spot of the user; and transmitting a signal to a user mobile device to perform an alarm operation when at least one of the one or more objects occupies the blind spot of the user.

Abstract: A vehicle driving assist system is configured to provide a driver with advanced notification regarding changes in the operating states of the controls when several controls are being executed. The vehicle driving assist system has a controller configured to execute an accelerator pedal actuation reaction force control based on a risk potential that indicates a degree of convergence between the host vehicle and a preceding obstacle and an automatic braking control based on the possibility of contact between the host vehicle and the preceding obstacle. When the automatic braking control will change from a low operating state to a high operating state while an actuation reaction force is being generated in the accelerator pedal in accordance with the risk potential, a pulsed supplemental reaction force is generated in the accelerator pedal and an alarm sound is generated.

Abstract: Devices, systems, and methods are provided for alerting a driver that a potential hazard is in the vicinity of the driver's vehicle. In general, activation signals transmitted from a vehicle are received at a potential hazard, and hazard signals are, in response, transmitted from the potential hazard to the vehicle. The hazard signals provide an indication of the potential hazard to the driver so that he may be aware of the potential hazard and react accordingly. The indication may be provided to the driver visually, such as on a display of the vehicle, and/or audibly, such as in the form of an audible alert issued by a speaker. The hazard signals may also include one or more characteristics of the potential hazard to provide more information about the potential hazard to the driver, such as the type of potential hazard and/or the degree of danger associated with the potential hazard.

Abstract: A system and method of controlling deployment of a safety device for a vehicle. The system may include a pre-impact collision assessment system, an impact detection system, and an inflatable safety device. The safety device may be partially inflated when a collision threat is detected based on a signal from the pre-impact collision assessment system. The inflatable device may be subsequently either more fully inflated or deflated.

Abstract: A mounting bracket for a vehicle backup camera, including: a lengthwise portion; and a camera mounting portion connected to the lengthwise portion, the camera mounting portion including a protrusion, the protrusion forming a gap between the camera mounting portion and the lengthwise portion so that the lengthwise portion can be mounted behind a license plate of a vehicle and a camera can be suspended by the camera mounting portion for viewing a rear of the vehicle when the vehicle is in reverse.

Abstract: A driving support target braking/driving force is calculated by a driving support electronic controller, and transmitted to a first arbiter of a driving force control electronic controller. A vehicle driver requested target braking/driving force and the driving support target braking/driving force are arbitrated by the first arbiter, whereby a vehicle total target braking/driving force is calculated, and the vehicle total target braking/driving force is distributed to a vehicle target driving force and a vehicle target braking force by a braking/driving force distributor. A final target driving force is calculated by a second arbiter on the basis of the target driving force, and a driver requested braking force and the target braking force are arbitrated by an arbiter of a braking force control electronic controller, whereby a vehicle total target braking force is calculated.

Abstract: One embodiment of the present invention provides a system that facilitates warning of collision between a primary principal and one or more non-primary principals. The system includes a triggering mechanism and a preliminary assessment mechanism. During operation, the triggering mechanism determines whether a trigger condition is met based on the state of the primary principal. When the trigger condition is met, the preliminary assessment mechanism generates one or more collision scenarios associated with the trigger condition, assesses a preliminary probability of collision in a collision scenario, and, based on the preliminary probability of collision in the collision scenario, activates a specialized assessment mechanism to assess a refined probability of collision in the collision scenario.

Abstract: An apparatus is provided that includes at least one image sensor, and at least one processor. The processor is configured to receive at least a portion of at least one image from the at least one image sensor, wherein an aim of the at least one image sensor is a function of the at least one image. The processor is further configured to generate at least one vehicle equipment control signal as a function of at least one feature extracted from at least a portion of at least one image.

Abstract: A collision determination system for a vehicle is disclosed. The system includes a vehicle behavior recognition unit that recognizes specific vehicle behavior indicative of a probable vehicle collision. The system also includes a collision detection sensor that detects a predetermined state change resulting from a vehicle collision. Furthermore, the system includes a collision determination unit that determines whether the vehicle collision necessitates activation of a vehicle passenger protection device based on the specific vehicle behavior recognized by the vehicle behavior recognition unit and the detected predetermined state change.

Abstract: A vehicle collision avoidance system is implemented in a host vehicle. A wireless communication module in the host vehicles wirelessly broadcasts vehicle information packages of the host vehicle and receives external vehicle information packages from other neighboring vehicles. Based on the received vehicle information packages, a collision avoidance process is performed. The process has steps of mapping coordinates system, categorizing collision zones, determining whether a possible collision position exists, calculating a collision time and outputting warning messages. The estimations of the possible collision position and the collision time are not affected by the positions of the neighboring vehicles. Therefore, the neighboring vehicles approaching the host vehicle from different direction are effectively monitored.

Abstract: Rooftop cargo racks, otherwise simply known as roof-racks, provide an option for transporting cargo that does not use space inside a vehicle. However, despite the usefulness of roof-racks, once cargo is secured to a roof-rack on a vehicle there is the added potential for a collision between the cargo and some overhead obstruction—such as, for example only, a garage door, over-hanging sign, public parking structures, and tree branch. Previous collision avoidance systems that employ either ultrasonic acoustic or Doppler-based radar systems are poorly suited for detecting the potential of a collision between rooftop mounted cargo and an overhead obstruction. By contrast, aspects of the present invention provide systems and methods for reducing the risk of a collision between rooftop mounted cargo and overhead obstructions by providing a more suitable radar-based means for detecting overhead obstructions and warning drivers and, if present, passengers in vehicles when there is a risk of a collision.

Abstract: A navigation device provides support for a driver of a vehicle in merging from one road onto another road (main road). The navigation device receives traffic information including at least positions and speeds of other vehicles traveling the main road. The navigation device then detects at least positions of inter-vehicle spaces between those other vehicles, using the traffic information, and determines which one of the detected inter-vehicle spaces is most suitable for the driver's vehicle to enter for merging. A beam radiating unit provided in the driver's vehicle is used to form a moving first entry point mark on the road surface to indicate the inter-vehicle space the driver's vehicle is going to enter upon merging.

Abstract: A head of train device is configured to examine messages received from end of train units other than the end of train unit attached to the same train and to alert an operator to the presence of an end of train unit from another train that indicates that the end of train unit from the other train has stopped. The indication can take the form of a zero brake pipe pressure.

Abstract: An active safety device for a motor vehicle comprises: obstacle detection device for detecting an obstacle; vehicle path prediction device for predicting a future path of the vehicle; collision possibility calculation device for calculating the possibility of a collision between the vehicle and the obstacle; and collision responding device for informing a driver of the presence of the obstacle or controlling the vehicle so as not to approach the obstacle according to the possibility of the collision between the vehicle and the obstacle, wherein the device further comprises: obstacle storage device for storing a position of the obstacle; and position estimation device for estimating a relative position between the vehicle and the obstacle from the position of the obstacle stored by the obstacle storage device, a vehicle speed of the vehicle, a yaw angular velocity of the vehicle, and a sideslip angle of the vehicle.