Method and system for communicating data between a transmitter and a receiver via a physical transmission medium interposed there between, wherein the transmitter outputs over the transmission medium towards the receiver, a predefined precursor signal followed by a target signal carrying data packet. Based on the precursor signal received at the receiver, estimated values of actual electrical parameters of the physical transmission medium are computed via a predetermined model of the physical transmission medium, wherein the computed estimated values of the electrical parameters are indicative of a distortion caused by the physical transmission medium on the predefined precursor signal outputted by the transmitter. The data packets originally outputted by the transmitter are estimated based on the computed estimated values of the actual electrical parameters and on the target signal received at the receiver.

A train control network includes a rail, a first communication element and a second communication element, which are to communicate with each other. The first communication element includes a first HF-injector, adapted for injecting HF-signals into the rail. The second communication element includes a HF-receiver, adapted for receiving HF-signals transmitted via the rail. An evaluation unit is provided for analyzing the received HF-signals.

A train control network includes a rail, a first communication element and a second communication element, which are to communicate with each other. The first communication element includes a first HF-injector, adapted for injecting HF-signals into the rail. The second communication element includes a HF-receiver, adapted for receiving HF-signals transmitted via the rail. An evaluation unit is provided for analyzing the received HF-signals.

A method of performing remote subsea inspection includes processing mission data from a UUV at an offshore location to produce a low-resolution output and a high-resolution output, automatically and in real time. The high-resolution output is stored at the offshore location while the low-resolution output is transmitted wirelessly across a low-bandwidth communication also automatically and in real time, to be reviewed by subject-matter experts at one or more onshore or inshore locations. Selected portions of the high-resolution output can be transmitted across the communication link to the subject-matter experts on demand. Data outputs can be transmitted across the communication link at a resolution adjusted automatically in accordance with the bandwidth measured to be available on that link.

A method for producing, especially configuring, a system is provided, including a contact wire and an apparatus, and device for carrying out the method. The apparatus is able to be supplied with energy with the aid of the contact wire, and information is transmittable from and/or receivable by the apparatus via the contact wire. The contact wire has at least a first, second, fourth and fifth contact conductor that are connected to one respective connector element of the apparatus. The first and second contact conductors have one respective phase of the AC voltage supplying the apparatus. The fourth contact conductor is provided for transmitting information and the fifth contact conductor is provided for receiving information. One of the phases, thus especially the phase acting as signaling phase, is connected electrically to a first connector element, in particular, the first connector element is provided with a corresponding marking or identification when producing the apparatus. A controllable switch, particularly a semiconductor switch, of the apparatus electrically connects the first connector element for periods of time to the connector element connected to the fourth contact conductor, or breaks this connection.

A method for producing, especially configuring, a system is provided, including a contact wire and an apparatus, and device for carrying out the method. The apparatus is able to be supplied with energy with the aid of the contact wire, and information is transmittable from and/or receivable by the apparatus via the contact wire. The contact wire has at least a first, second, fourth and fifth contact conductor that are connected to one respective connector element of the apparatus. The first and second contact conductors have one respective phase of the AC voltage supplying the apparatus. The fourth contact conductor is provided for transmitting information and the fifth contact conductor is provided for receiving information. One of the phases, thus especially the phase acting as signaling phase, is connected electrically to a first connector element, in particular, the first connector element is provided with a corresponding marking or identification when producing the apparatus. A controllable switch, particularly a semiconductor switch, of the apparatus electrically connects the first connector element for periods of time to the connector element connected to the fourth contact conductor, or breaks this connection.

The present invention provides a system for providing power, control and communications within an irrigation system having at least one span and a drive system for moving the span. According to a preferred embodiment, the present invention preferably includes a pivot panel which includes a pivot panel processor for receiving, controlling and initiating the transmission of power and control signals to a plurality of solid state tower boxes. According to a further preferred embodiment, a system in accordance with the present invention preferably further includes a power-line BUS electrically connected to the pivot panel processor and to a power-line carrier. According to a further preferred embodiment, the power-line carrier of the present invention preferably provides power and electrical control signals to a number of solid state tower boxes. According to a further preferred embodiment, the solid-state tower boxes preferably control power to motor elements within each tower box.

A resident remotely operated vehicle may be deployed subsea by deploying a remotely operated vehicle (ROV) (200) configured to be disposed and remain resident subsea for an extended time where the ROV comprises an ROV electrical power connector port (202) to be operatively connected to an electrical power supply (700) dedicated to the ROV. An RTMS configured to be disposed subsea for an extended time is also deployed subsea (210), typically proximate the ROV. A subsea docking hub subsea is also deployed subsea proximate the RTMS and operatively connected to the ROV and the RTMS. In addition, an umbilical is connected from the subsea docking hub to a subsea structure and a signal supplied from the subsea structure to the ROV.

The invention relates to a mobile network subscriber (10) for use in a cabled network (1), particularly in a collector wire network of an electric telpher, wherein the cabled network (1) has at least one first segment (S1) and at least one second segment (S2) and wherein the mobile network subscriber (10) has a first slave modem (SM1), a second slave modem (SM2), a first contact arrangement (K1) and a second contact arrangement (K2) in each case. In order to allow a change between two segments of a network in a simple and efficient manner, it is proposed that the slave modems (SM1, SM2) be provided for communication with at least one first master modem (MM1) and/or at least one second master modem (M2) via the contact arrangements (K1, K2) and the segments (S1, S2), wherein the mobile network subscriber (10) is provided for movement along the segments (S1, S2), the contact arrangements (K1, K2) of the mobile network subscriber (10) being arranged such that the change from the first segment (S1) to the second segment (S2) involves at least one of the contact arrangements (K1, K2) being connected to the first segment (S1) and at least one further contact arrangement (K1, K2) being connected to the second segment (S2).

The invention relates to a mobile network subscriber (10) for use in a cabled network (1), particularly in a collector wire network of an electric telpher, wherein the cabled network (1) has at least one first segment (S1) and at least one second segment (S2) and wherein the mobile network subscriber (10) has a first slave modem (SM1), a second slave modem (SM2), a first contact arrangement (K1) and a second contact arrangement (K2) in each case. In order to allow a change between two segments of a network in a simple and efficient manner, it is proposed that the slave modems (SM1, SM2) be provided for communication with at least one first master modem (MM1) and/or at least one second master modem (M2) via the contact arrangements (K1, K2) and the segments (S1, S2), wherein the mobile network subscriber (10) is provided for movement along the segments (S1, S2), the contact arrangements (K1, K2) of the mobile network subscriber (10) being arranged such that the change from the first segment (S1) to the second segment (S2) involves at least one of the contact arrangements (K1, K2) being connected to the first segment (S1) and at least one further contact arrangement (K1, K2) being connected to the second segment (S2).