Abstract: A metallic leadframe for use with a semiconductor chip intended for operation in a changing magnetic field comprises a chip mount pad having at least one slit penetrating the whole thickness of the pad and substantially traversing the area of the pad from one edge to the opposite edge. This slit is wide enough to interrupt electron flow in the pad plane, but not wide enough to significantly reduce thermal conduction in a direction normal to the pad plane, whereby the slit is operable to disrupt eddy currents induced in the pad by the changing magnetic field.

Abstract: A metallic leadframe for use with a semiconductor chip intended for operation in a changing magnetic field comprises a chip mount pad having at least one slit penetrating the whole thickness of the pad and substantially traversing the area of the pad from one edge to the opposite edge. This slit is wide enough to interrupt electron flow in the pad plane, but not wide enough to significantly reduce thermal conduction in a direction normal to the pad plane, whereby the slit is operable to disrupt eddy currents induced in the pad by the changing magnetic field.

Abstract: A metallic leadframe for use with a semiconductor chip intended for operation in a changing magnetic field comprises a chip mount pad having at least one slit penetrating the whole thickness of the pad and substantially traversing the area of the pad from one edge to the opposite edge. This slit is wide enough to interrupt electron flow in the pad plane, but not wide enough to significantly reduce thermal conduction in a direction normal to the pad plane, whereby the slit is operable to disrupt eddy currents induced in the pad by the changing magnetic field.

Abstract: A metallic leadframe for use with a semiconductor chip intended for operation in a changing magnetic field comprises a chip mount pad having at least one slit penetrating the whole thickness of the pad and substantially traversing the area of the pad from one edge to the opposite edge. This slit is wide enough to interrupt electron flow in the pad plane, but not wide enough to significantly reduce thermal conduction in a direction normal to the pad plane, whereby the slit is operable to disrupt eddy currents induced in the pad by the changing magnetic field.

Abstract: A two stage amplifier circuit (10), the first stage (12) comprising a modified quad configuration and the second stage (14) comprising a translinear current amplifier configuration. The present invention achieves the advantages of fast response time, low distortion and improved bandwidth. The current gain of the second stage is represented by: (IAout1−IAout2)/(Iout1−Iout2)=(1+R123/R124)·(I135/I134)·(A/(1+A)) where A=gmQ109·R124.

Abstract: A method for isolatively coupling an input signal to an output signal, where the input signal is a first voltage differential, comprises three steps. Step one calls for generating a magnetic field that is indicative of the input signal in at least one magnetic sensor in an integrated circuit by generating a current through a conductor in the integrated circuit. The current is generated by applying the first voltage differential across the conductor, which is proximate the magnetic sensor. Step two requires generating a second voltage differential between two points of the magnetic sensor by providing a current through the magnetic sensor in a direction having a component transverse to the magnetic field. Step three calls for providing a signal indicative of the second voltage differential as the output signal, thereby isolatively coupling the input signal to the output signal.

Abstract: A two stage amplifier circuit (10), the first stage (12) comprising a modified quad configuration and the second stage (14) comprising a translinear current amplifier configuration. The present invention achieves the advantages of fast response time, low distortion and improved bandwidth.

Abstract: A differential line driver with 4X supply voltage swing with a 1:1 transformer, which enhances the loop length for applications such as digital subscriber line includes: a differential circuit having first and second input nodes, first and second output nodes 52 and 54, and a supply voltage node; a transformer 22 having a first coil coupled between the first and second output nodes; and a center tap 50 of the first coil coupled to the supply voltage node. The device also acts as an active impedance termination, which eliminates the series termination resistor in conventional hybrids and thereby saving 6 dB transmit power.

Abstract: A class AB input differential amplifier employs a single loop output common mode feedback circuit (CMFC) to achieve high performance by controlling the common mode output voltage. The CMFC includes a small amplifier to compare the common mode voltage at the output with a desired voltage specified at the common mode output voltage pin. Having only one loop to control this voltage instead of two makes the design more reliable and easier to compensate since there is no need to worry about how multiple loops will interact.

Abstract: A low noise, low distortion, power efficient DSL/cable line driver has a double Wheatstone impedance bridge network that functions to prevent contamination of DSL signals that are received by and transmitted from the line driver. The line driver employs an external current sensing impedance that can be either purely resistive or complex and that can be selected to accommodate a particular transmission medium. The line driver further employs an internal programmable resistor that can be programmably adjusted to accommodate changes in transmission medium impedance to optimize sidetone rejection.

Abstract: A method for isolatively coupling an input signal to an output signal, where the input signal is a first voltage differential, comprises three steps. Step one calls for generating a magnetic field that is indicative of the input signal in at least one magnetic sensor in an integrated circuit by generating a current through a conductor in the integrated circuit. The current is generated by applying the first voltage differential across the conductor, which is proximate the magnetic sensor. Step two requires generating a second voltage differential between two points of the magnetic sensor by providing a current through the magnetic sensor in a direction having a component transverse to the magnetic field. Step three calls for providing a signal indicative of the second voltage differential as the output signal, thereby isolatively coupling the input signal to the output signal.

Abstract: A differential line driver with 4×supply voltage swing with a 1:1 transformer, which enhances the loop length for applications such as digital subscriber line includes: a differential circuit having first and second input nodes, first and second output nodes 52 and 54, and a supply voltage node; a transformer 22 having a first coil coupled between the first and second output nodes; and a center tap 50 of the first coil coupled to the supply voltage node. The device also acts as an active impedance termination, which eliminates the series termination resistor in conventional hybrids and thereby saving 6 dB transmit power.

Abstract: An integrated circuit includes a magnetic sensor that comprises a region of conductive material operable to receive a current from a current source and to conduct the current through the region of conductive material. At least one conductive node is electrically connected to the region of conductive material and is operable to allow measurement of a differential voltage arising due to a magnetic field acting on the region of conductive material. A copper conductor is disposed adjacent the region of conductive material such that a current through the copper conductor generates a magnetic field.

Abstract: A metallic leadframe for use with a semiconductor chip intended for operation in a changing magnetic field comprises a chip mount pad having at least one slit penetrating the whole thickness of the pad and substantially traversing the area of the pad from one edge to the opposite edge. This slit is wide enough to interrupt electron flow in the pad plane, but not wide enough to significantly reduce thermal conduction in a direction normal to the pad plane, whereby the slit is operable to disrupt eddy currents induced in the pad by the changing magnetic field.