A sensor package including a metal carrier and a sensor chip arranged on the metal carrier and having a first sensor element. In an orthogonal projection of the sensor chip onto a surface of the metal carrier, at least two edge sections of the sensor chip are free of overlap with the surface of the metal carrier. The sensor chip is designed to detect a magnetic field induced by an electric current flowing through a current conductor.

A planar Hall sensing element includes a first pair of sensing electrodes mutually opposed in a first direction across the sensing element and a second pair of sensing electrodes mutually opposed in a second direction across the sensing element, with the second direction orthogonal to the first direction. A first pair of bias electrodes is mutually opposed in a third direction and a second pair mutually opposed in a fourth direction across the sensing element, the fourth direction orthogonal to the third direction. The third and fourth directions are rotated 45° with respect to the first and second directions so each sensing electrode is arranged between a bias electrode of the first pair and second pair. A DC bias current is supplied between the first and second pairs of bias electrodes. First and second Hall voltages are sensed at the first and second pairs of sensing electrodes.

An all-band magnetic sensor is provided. The all-band magnetic sensor comprises an induction coil, a voltage measurement module, and an integrator; the induction coil is used for generating an induced electromotive force according to magnetic flux passing therethrough; an impedance transformation circuit is connected to the output end of the induction coil and used for improving the loop resistance of the induction coil; the voltage measurement module is electrically connected to the impedance transformation circuit, and used for measuring the induced electromotive force generated by the induction coil; and the integrator is electrically connected to the voltage measurement module, and used for expanding a bandwidth.

Magnetic field components are measured at multiple longitudinal positions and used to calculate estimated longitudinal position and length of a transversely localized electric current segment flowing across a gap between conductive bodies. The apparatus can be used with a remelting furnace. The electrode and ingot act as the conductive bodies, and arcs, discharges, or slag currents are the current segments spanning the gap. Actuators for movable sensors can be coupled to the sensors in a servomechanism arrangement to move the sensors along with the moving gap. An actuator for moving one of the conductive bodies can be coupled to sensors in a servomechanism arrangement to maintain the gap distance within a selected range as the gap moves.

Magnetic field components are measured at multiple longitudinal positions and used to calculate estimated longitudinal position and length of a transversely localized electric current segment flowing across a gap between conductive bodies. The apparatus can be used with a remelting furnace. The electrode and ingot act as the conductive bodies, and arcs, discharges, or slag currents are the current segments spanning the gap. Actuators for movable sensors can be coupled to the sensors in a servomechanism arrangement to move the sensors along with the moving gap. An actuator for moving one of the conductive bodies can be coupled to sensors in a servomechanism arrangement to maintain the gap distance within a selected range as the gap moves.

A magnetic field applicator (1, 55) that has a ramped signal curve for the coil currents (10, 37, 44, 49) that are used, comprised of low frequency base pulses (10, 37) of the coil current with ramp-shaped rising amplitudes, which are active during a defined treatment period (1), which are a component of the pulse packets (44) composed of the base pulses (10, 37), the envelopes (17, 17a, 17b) of which, described by the amplitudes of the base pulses (10, 37) are likewise ramp-shaped, wherein the envelopes (17a, 17b, 17c) of which form the amplitudes of the base pulses (10, 37) of a rising curve segment (57) starting from close to zero, which rises until approximately the midpoint of a treatment period (11) and subsequently forms a constant curve segment (58) corresponding to a maximum current strength, until the end of the treatment period (11) (FIGS. 13-15).

A magnetic field applicator (1, 55) that has a ramped signal curve for the coil currents (10, 37, 44, 49) that are used, comprised of low frequency base pulses (10, 37) of the coil current with ramp-shaped rising amplitudes, which are active during a defined treatment period (1), which are a component of the pulse packets (44) composed of the base pulses (10, 37), the envelopes (17, 17a, 17b) of which, described by the amplitudes of the base pulses (10, 37) are likewise ramp-shaped, wherein the envelopes (17a, 17b, 17c) of which form the amplitudes of the base pulses (10, 37) of a rising curve segment (57) starting from close to zero, which rises until approximately the midpoint of a treatment period (11) and subsequently forms a constant curve segment (58) corresponding to a maximum current strength, until the end of the treatment period (11) (FIGS. 13-15).

Magnetic sensor for measuring an external magnetic field angle in a two-dimensional plane, including: a first and second sensing unit outputting, respectively, a first signal sin(θ) and a second signal cos(θ); a first multiplying DAC receiving the first signal and a first digital input sin(f*t) and outputting a first modulated output signal; a second multiplying DAC receiving the second signal and a second digital input cos(f*t) and outputting a second modulated output signal; a first RC filter receiving the first modulated output signal and outputting a first filtered signal sin(θ)*sin(f*t+RCd); a second RC filter receiving the second modulated output signal and outputting a second filtered signal sin(θ)*sin(f*t+RCd); an adder adding the first and second filtered signals and outputting a summed signal cos(f*t+RCd+θ); and an angle extracting unit for measuring the phase delay between the summed signal and a synchronization signal and determining the angle from the phase delay.

A magnetic field sensor of the present invention includes a first electrode including a magnetic material, a second electrode including a non-magnetic material, a common electrode disposed between the first electrode and the second electrode and connected to a ground terminal, a power supplier of which one end is connected to the first electrode and the second electrode and of which another end is connected to the common electrode to supply power of a frequency band required, a variable resistor configured to control at least one of a resistance value between the first electrode and the power supplier or a resistance value between the second electrode and the power supplier, and a differential amplifier connected to the first electrode through a positive terminal and connected to the second electrode through a negative terminal to output a difference value between a first capacitance generated by the first electrode and a second capacitance generated by the second electrode in response to external application of a magnetic field.

Methods for forming an efficient and effective crossed-fins FinFET device for sensing and measuring magnetic fields and resulting devices are disclosed. Embodiments include forming first-fins, parallel to and spaced from each other, in a first direction on a substrate; forming second-fins, parallel to and spaced from each other on the substrate, in a same plane as the first fins and in a second direction perpendicular to and crossing the first-fins; forming a dummy gate with a spacer on each side over channel areas of the first and second fins; forming source/drain (S/D) regions at opposite ends of each first and second fin; forming an ILD over the fins and the dummy gate and planarizing to reveal the dummy gate; removing the dummy gate, forming a cavity; and forming a high-k/metal gate in the cavity.