Abstract: Methods for surveilling a tolling system, in which vehicles carry onboard units and travel on a multilane road on which a surveillance station is set up, are described. A picture of each passing vehicle is taken, and the pictures are stored in a database. In each onboard unit, when the vehicle is within a predefined area of the surveillance station, a tolling message is generated and sent via the mobile network to the tolling server. In the database, those pictures whose timestamp matches the timestamp of a tolling message are deleted if the lane information of this tolling message corresponds to the lane identification of this picture.

Abstract: Methods for tolling locations of a vehicle having a license plate number are performed by means of a tolling system. The tolling system has a camera at each location to be tolled, a server, a user terminal, linked by a network, and a database The method includes: generating one or more tolling records, each including a picture of the vehicle taken by one of the cameras, the location of the camera, and a license plate number read by optical character recognition from the picture, and storing the tolling records in the database; sending a confirmation request to the user terminal including the read license plate number and location information dependent on the locations in the tolling records; and receiving a response from the user terminal and, if the response confirms the request, deleting the pictures from the tolling records in the database. Alternative embodiments include pre-/post-registration of locations to toll.

Abstract: The present subject matter relates to a method and a roadside unit for generating a digital record of a vehicle in a road toll system, comprising: capturing an image of the vehicle on a roadway; data-compressing the image depending on at least one of a confidence level obtained from the image for one or more characters therein by means of OCR, and a contrast parameter obtained from the image or a region of interest therein or a section of the latter, to generate the digital record; and sending the digital record from the roadside unit to a data center of the road toll system.

Abstract: The disclosed subject matter relates to a vehicle identification system comprising a central station, a roadside reader for wirelessly communicating with radio tags carried by vehicles, a mapping unit connected to the reader, and a correlation unit connected to the mapping unit, wherein the correlation unit is configured to correlate second-protocol tag identifications to first-protocol tag identifications from a reserved subset of first-protocol tag identifications, wherein the mapping unit is configured to generate a new first-protocol message upon receiving a second-protocol message from the reader, and wherein the central station is configured to receive and store first-protocol messages from the reader as well as new first-protocol messages from the mapping unit and to identify a vehicle. The disclosed subject matter further relates to a method for identifying vehicles by means of this system.

Abstract: The subject matter disclosed herein relates to a method for checking toll transactions, produced from position notifications of a mobile phone connected via a mobile network to a transaction server, with the aid of a network of distributed toll beacons, which can communicate via short-range radio with on-board units of passing vehicles and are connected to the transaction server. To this end, a interoperable multi-functional OBU is created that is formed from a GNSS- and NFC-enabled mobile phone on the one hand and an NFC- and DSRC-enabled OBU on the other hand, which exchange data concerning a session identifier (SID) via their common NFC interface, which session identifier forms a link between the infrastructureless and the infrastructure-bound billing functions of the multi-functional OBU. The disclosed subject matter also relates to a toll beacon and a transaction server for same.

Abstract: The present subject matter relates to an onboard unit for a traffic telematics system, comprising: a first communication module, designed for near-range radio communication with a first external communication device, a second communication module, designed for far-range radio communication with a second external communication device, and a non-volatile memory, which can be accessed both by the first and the second communication module, wherein each communication module has a power-supplied communication mode and a powerless or power-saving rest mode, and wherein the power supply of the memory during an access thereto is effected by the accessing communication module. The present subject matter further relates to an onboard system for a vehicle comprising such an onboard unit, and to a communication device for said system.

Abstract: A method provides for wireless transmission and reception of messages in an asynchronous ad hoc network having multiple network nodes, of which at least a first network node periodically transmits messages with a predefined period length. A second network node carries out: Defining two consecutive time intervals, each having the length of one period and a first time interval being past and a second time interval being future; subdividing the time intervals into two time slots each; calculating an occupancy for each time slot of the first time interval based on the number of messages of other network node(s) received in this time slot; identifying the time slot having the lowest occupancy; and transmitting a message in a time slot of the second time interval that corresponds to the identified time slot. The exact transmission point is defined on the basis of the time stamp derived from the synchronized TSF.

Abstract: A transponder, such as an electronic toll transponder, is configured to recognize when it is being subjected to consistent and repeated trigger signals over an extended period of time and, in response, the transponder enters a reduced-responsiveness state. In the reduced-responsiveness state, the transponder may only intermittently respond to detected trigger signals. The transponder may recognize when the repeated trigger signal situation has been resolved and then return to normal responsiveness.

Abstract: An onboard unit for levying tolls for a vehicle comprises a satellite navigation receiver for generating position fixes, a memory for recording geoobjects, a radio interface, and a processor, which generates toll data from a geographical comparison of position fixes with geoobjects in a digital map and transmits this data via the radio interface. The memory has an index memory region for an index tree for geoobjects, a first static object memory region for a primary list with geoobjects, and a second object memory region, which can be written dynamically via the radio interface, for a secondary list with geoobjects. At least one leaf of the index tree contains a reference to a secondary list, and wherein the processor is configured, upon accessing a geoobject via a leaf, to use the secondary list before the primary list. A method for updating geodata in such an onboard unit is also disclosed.

Abstract: Methods are described for charging fees in a road toll system. An on-board unit identification is input into a toll terminal to generate a transaction identification. The transaction identification is transmitted to a transaction server, and from the server to a transaction terminal. A payment card identification is input into the transaction terminal, and is transmitted with the transaction identification to the server. A substitute identification, generated in the transaction server and associated with the card identification, and the transaction identification are transmitted from the transaction server to the toll terminal. The on-board unit identification and substitute identification, associated by the transaction identification, are transmitted from the toll terminal to a toll server.

Abstract: A radio-frequency identification (RFID) reader having fast-adaptive echo cancellation for backscatter-modulated signals is described. The echo cancellation includes subtracting an RF-level cancel signal from the received signal, where the cancel signal is generated based upon an error measured in the receive signal after down-conversion to baseband and low-pass filtering. The cancel signal is based upon a cumulative sum or integral of error signals and an estimated complex-valued transfer function of the scaling circuit. Methods of quick calibration of the reader are described, including accounting for circuit offsets and determining the estimated complex-valued transfer function.

Abstract: A vehicle device for a road tolling or road communication system for installation in a vehicle, comprising electronic components, which are supplied with energy by a thermoelectric generator, which produces electrical energy from a temperature difference present on two sides of the generator, wherein in the installed position of the vehicle device, one of said sides faces a window pane of the vehicle and the other of said sides faces the interior of the vehicle.

Abstract: An onboard unit for a vehicular identification system is disclosed herein. The onboard unit comprises a housing attachable to an exterior surface of a vehicle's windscreen, a transceiver, and a processor coupled to the transceiver and configured to communicate with the identification system via the transceiver. The transceiver and processor are contained in the housing. The onboard unit comprises a tampering protection unit which is split into a first part which is contained in the housing and a second part which is attachable to an inner surface of the windscreen. The first and the second part each comprise a limited range communication module for communication between each other. The tampering protection unit is configured to detect a loss of communication between both communication modules and, upon detection, to trigger an alarm event.

Abstract: Techniques are disclosed for determining characteristic feature(s) of a vehicle travelling on a roadway, comprising: a detector, which is directed towards the roadway and is configured to measure the movement vector of the vehicle at a current location and time, a tracking unit, connected to the detector, for calculating a target location of the vehicle at a target time on the basis of current location and time and movement vector, a first radar sensor, connected to the detector, for transmitting a radar beam directed towards the current location, receiving a reflected radar beam, and determining a frequency spectrum thereof, a second radar sensor, connected to the tracking unit, for transmitting a radar beam directed towards the target location at the target time, receiving a reflected radar beam and determining a frequency spectrum thereof, and an evaluation unit for generating characteristic feature(s) of the vehicle from the determined frequency spectra.

Abstract: An apparatus is disclosed for measuring the position of a vehicle or a surface thereof on a roadway. The apparatus comprises at least one radar transmitter, which is arranged in a transmitting position above the plane of the roadway and transmits radar beams downwardly, a plurality of radar receivers, which are distributed above the plane of the roadway in different receiving positions at distances from one another, receive reflections of the radar beams from beneath, and convert the reflections into a received signal, and an evaluation device, which is connected to the radar transmitter and the radar receivers and is configured to measure the said position from the transmitting position, the receiving positions and the received signals.

Abstract: Methods of estimating vehicle location in a roadway using an automatic vehicle identification system are described. The methods involve receiving a set of response signals from a vehicle-mounted transponder at points in time and determining a range rate of the transponder relative to the antenna at each point in time; identifying a minima in the magnitude of the range rate; estimating a first position of the transponder at a first time corresponding to the occurrence of the minima; estimating a velocity of the vehicle based upon one or more of the determined range rates; and estimating a second position of the transponder based upon the first position and the velocity.

Abstract: An onboard unit for a vehicle for providing information to the driver when travelling on a road portion with at least two adjacent lanes forming a common traffic area, the onboard unit having a position detection device for determining the position thereof and having a measured value of the speed thereof, comprising a lane detector, connected to the position detection device, with a map memory for a digital road map for locating in the road map a lane corresponding to the determined position, a traffic jam detector for detecting a traffic jam when at least the speed measured value falls below a predefined threshold value, and an evaluation and output unit, which is connected to the lane detector and the traffic jam detector and which is configured, upon detection of a traffic jam, to output direction of travel information specific for the located lane.

Abstract: Methods for determining a range rate of a backscatter transponder and readers implementing the methods are described. The reader transmits a continuous wave signal and receives a modulated reflected response signal from the transponder, mixes the modulated reflected response signal with the carrier frequency to produce a downconverted signal, bandpass filters the downconverted signal to pass a bandpass filtered signal containing at least the modulation frequency, applies a non-linear amplitude transfer function to produce a modulation-suppressed signal, and measures the frequency of the modulation-suppressed signal and determines the range rate from the measured frequency.

Abstract: Methods and devices are provided for recording images of vehicles that pass through a section between an entrance and an exit at excessive speed, comprising the following steps: capturing an entry time of a vehicle at the entrance, generating a unique object identifier for the vehicle and storing the entry time under the object identifier; tracking the movement of the vehicle, which is being continuously referenced by way of the object identifier, over the entire section using a sensor arrangement; capturing an exit time of the vehicle that is referenced by way of the object identifier at the exit; and if a comparison of the captured exit time to the stored entry time indicates a speed that exceeds a threshold value: determining an entry image stored under the object identifier or creating an exit image of the vehicle.

Abstract: A method for measuring a height profile of a vehicle passing on a road, said method comprising the following steps: directing a monocular camera from a point above the road onto the road with an angle of aperture that captures a section of the road from above, recording at least a first image of the passing vehicle by the camera at a first moment in time, recording at least a second image of the passing vehicle by the camera at a second moment in time, generating a movement vector image of the vehicle from an analysis of the optical flow between the first and the second image, and creating the height profile of the vehicle from the movement vector image.