Abstract: A method for ascertaining illegal driving behavior of at least one road user in the surroundings of a vehicle includes the surroundings being detected by vehicle sensors, a surroundings model being created based on the sensor data of the vehicle sensors, an illegal behavior of the at least one road user being detected on the basis of the surroundings model, and the sensor data in a time window of the detected illegal behavior being stored as evidence.

Abstract: A processor comprises an execution unit and a detection unit which are functionally connected. The execution unit is configured to execute computer programs, and the detection unit is configured to detect infinite loops during the execution of a computer program in the execution unit during run-time. The computer program has a plurality of go-to instructions, and each go-to instruction is characterized by a corresponding branch address. The detection unit is configured to calculate a detection function of the branch addresses of a branch sequence, the branch sequence including a sequence of executed go-to instructions. The detection function is chosen such that an increased value of the detection function is characteristic of an infinite loop in the branch sequence in which at least one go-to instruction is repeated.

Abstract: A method for ascertaining illegal driving behavior of at least one road user in the surroundings of a vehicle includes the surroundings being detected by vehicle sensors, a surroundings model being created based on the sensor data of the vehicle sensors, an illegal behavior of the at least one road user being detected on the basis of the surroundings model, and the sensor data in a time window of the detected illegal behavior being stored as evidence.

Abstract: Processor comprising an execution unit and a detection unit which are functionally connected, wherein the execution unit is configured to execute computer programs, and wherein the detection unit is configured to detect infinite loops during the execution of a computer program in the execution unit during run-time, wherein the computer program comprises a plurality of go-to instructions, wherein each go-to instruction is characterized by a corresponding branch address, wherein the detection unit is configured to calculate a detection function of the branch addresses of a branch sequence, the branch sequence comprising a sequence of executed go-to instructions, and wherein the detection function is chosen such that an increased value of the detection function is characteristic of an infinite loop in the branch sequence in which at least one go-to instruction is repeated.

Abstract: The invention relates to a wireless telecommunication system including at least one Base Station (BS) for communicating with at least one multihop Relay Node (RN) using a wireless link of a first type and with at least one local user equipment unit (UE) located within a range of the base station (BS) using at least one wireless link of a second type, wherein the wireless link of the first type is used to transmit a combined data flow encapsulating multiple individual data flows relating to different services and/or remote user equipment (UE) units.

Abstract: A receiver is provided to receive a secondary bitstream which is transmitted by a secondary signal together with a primary signal. The receiver includes a down-converter configured to convert an input signal containing the primary and secondary signals, to a baseband complex symbol stream, A first processing unit processes the baseband complex symbol stream and provides a primary bitstream transmitted by the primary signal or a decoded primary log-likelihood ratio stream. A symbol reconstructing unit is configured to process the primary bitstream or the decoded primary log-likelihood ratio stream and to provide a reconstructed primary symbol stream. A subtraction unit is configured to provide a difference symbol stream by substracting the baseband complex symbol stream and the reconstructed primary symbol stream from each other. A second processing unit is provided to process the difference symbol stream and to provide the secondary bitstream transmitted by the secondary signal.

Abstract: The present invention relates to ad hoc mobile devices and to ad-hoc networks. An embodiment of the invention relates to an ad hoc mobile device capable of transmitting and receiving data in an ad-hoc network, comprising a receiver capable of receiving and decoding an encoded signal which is transmitted over a physical transmission channel, wherein said receiver is able to handle at least two different code structures; a transmitter capable of generating and transmitting an encoded signal, wherein said transmitter is able to handle at least two different code structures; and a control unit which is connected to said receiver and said transmitter, said control unit being able to change the code structure currently used by the receiver and the transmitter.

Abstract: An embodiment of the invention relates to a receiver capable of receiving a secondary bitstream which is transmitted by a secondary signal over a physical transmission channel together with a primary signal having higher signal strength than the secondary signal, said primary signal being generated according to a first transmission standard and said secondary signal being generated according to a second transmission standard, which differs from the first transmission standard; said receiver comprising: a down-converter configured to convert an input signal that contains said primary and secondary signal, to a baseband complex symbol stream; a first signal processing unit configured to process the baseband complex symbol stream and to provide a primary bitstream transmitted by said primary signal or a decoded primary log-likelihood ratio stream; a symbol reconstructing unit configured to process the primary bitstream or the decoded primary log-likelihood ratio stream and to provide a reconstructed primary symb

Abstract: An embodiment of the invention relates to a method of determining an optimum sequence of algorithms, wherein each algorithm defines a receiver function of a receiver, which has a plurality of receiver functions and which is adapted to receive bits sent by a transmitter.

Abstract: One exemplary aspect of the invention provides a routing node for an FDD communication network, which node has a node receiving apparatus, which is set up in such a manner that it can be used to receive signals from a terminal at a first frequency, and a node transmitting apparatus which is set up in such a manner that it can be used to transmit signals to the terminal at a second frequency. In this case, the routing node is set up in such a manner that it can transmit an indication signal to the terminal, which signal indicates whether the routing node can receive signals at the first frequency at a given point in time.

Abstract: The invention relates to a wireless telecommunication system including at least one Base Station (BS) for communicating with at least one multihop Relay Node (RN) using a wireless link of a first type and with at least one local user equipment unit (UE) located within a range of the base station (BS) using at least one wireless link of a second type, wherein the wireless link of the first type is used to transmit a combined data flow encapsulating multiple individual data flows relating to different services and/or remote user equipment (UE) units.