Abstract: An apparatus for transporting data in a network-based data communication system includes a first network node comprising a first port couplable to at least a second network node for transferring data in a first format between the first and second network nodes. The first network node further includes a processor operatively coupled to the first port, the processor being configurable to receive one or more frames of data and/or transmit one or more frames of data, the frames of data having an overhead processing portion that is otherwise standard. The processor uses only a subset of the overhead processing portion and is configured such that utilizing only the subset of the overhead processing portion of the one or more data frames enables one or more functional blocks to be eliminated from the first network node, the one or more functional blocks being otherwise required for implementing substantially all of the overhead processing portion of the one or more data frames.

Abstract: An apparatus for transporting data in a network-based data communication system includes a first network node comprising a first port couplable to at least a second network node for transferring data in a first format between the first and second network nodes. The first network node further includes a processor operatively coupled to the first port, the processor being configurable to receive one or more frames of data and/or transmit one or more frames of data, the frames of data having an overhead processing portion that is otherwise standard. The processor uses only a subset of the overhead processing portion and is configured such that utilizing only the subset of the overhead processing portion of the one or more data frames enables one or more functional blocks to be eliminated from the first network node, the one or more functional blocks being otherwise required for implementing substantially all of the overhead processing portion of the one or more data frames.

Abstract: A linear position encoder is provided which is not affected by ambient light, smoke, moisture, particulate matter, and also not affected by electrical interference such as may be caused by stray fields or permanent magnets or magnetic particles. The encoder comprises a linear scale having an excitation loop disposed along the length of the scale and having electrical terminals preferably disposed at one end of the scale. An alternating current is applied to the excitation loop to create an alternating magnetic field. At least one periodic conductive pattern is provided on an outer side of the excitation loop. The periodic pattern has electrical terminals preferably at the same end of the scale as the terminals of the excitation loop. A sensor is provided on a small printed circuit card that is movable in relation to the scale. The card has a pickup loop which receives energy coupled from the scale excitation loop and which induces current in the periodic pattern.

Abstract: A magnetic encoder is disclosed that provides a uniform magnetic field which is time modulated at a carrier frequency and space modulated by a repetitive pattern of eddy-current conducting lands that move with variable motion. The time modulation is provided by driving an electrical coil in a resonant tank circuit. The space modulation provides areas of higher and lower magnetic field intensity which change in correspondence with the motion of the conducting lands. The intensity of the varying magnetic field is detected by a series connected pair of stationary coils that are positioned orthogonal to both the direction of the changing magnetic field and the direction of the motion of the conducting lands. The pair of stationary coils yield a differential electrical signal that is representative of the motion of the conducting lands.