Abstract: Embodiments of a discharge circuit are disclosed for quickly and safely discharging energy from an inductor load. The discharge circuit comprises a first switch, a second switch and a voltage regulator. The inductor load couples between the first switch and the second switch. During fast demagnetization, a high side switch is tuned off to decouple the load from a voltage source and the second switch is turned on. Voltage on one end of the load is pushed high and maintained at a predetermined level due to the voltage regulator. The predetermined voltage pulls down the current at the inductive load and causes temperature of the discharge circuit going up quickly. Once the temperature reaches a predetermined threshold, a comparing circuit outputs a signal to a driver and eventually pulls down voltage of the inductor load for low-power demagnetization.

Abstract: An integrated circuit for demagnetizing an inductive load includes a first switch to control current supplied by a voltage supply to the inductive load. A Zener diode includes an anode connected to a control terminal of the first switch and a cathode connected to the voltage supply. A second switch includes a control terminal and first and second terminals. A temperature sensing circuit is configured to sense a temperature of the first switch and to generate a sensed temperature. A comparing circuit includes inputs that receive a reference temperature and the sensed temperature and an output connected to the control terminal of the second switch.

Abstract: Embodiments of a discharge circuit are disclosed for quickly and safely discharging energy from an inductor load. The discharge circuit comprises a first switch, a second switch and a voltage regulator. The inductor load couples between the first switch and the second switch. During fast demagnetization, a high side switch is tuned off to decouple the load from a voltage source and the second switch is turned on. Voltage on one end of the load is pushed high and maintained at a predetermined level due to the voltage regulator. The predetermined voltage pulls down the current at the inductive load and causes temperature of the discharge circuit going up quickly. Once the temperature reaches a predetermined threshold, a comparing circuit outputs a signal to a driver and eventually pulls down voltage of the inductor load for low-power demagnetization.

Abstract: A discharge circuit for demagnetizing an inductive load includes a first switch comprising a control terminal and first and second terminals. The first terminal is connected to a voltage supply. A second switch includes a control terminal and first and second terminals. The second terminal of the first switch and the second terminal of the second switch are connected to the inductive load. A third switch includes a control terminal and first and second terminals. The first terminal of the third switch is connected to the first terminal of the second switch. A first Zener diode includes an anode connected to the control terminal of the second switch and a cathode connected to the voltage supply. A first temperature sensing circuit generates a first sensed temperature signal based on a temperature of at least one component of the circuit. A first comparing circuit receives a first reference temperature signal and the first sensed temperature signal and that generates a first output.

Abstract: An integrated circuit for demagnetizing an inductive load includes a first switch to control current supplied by a voltage supply to the inductive load. A Zener diode includes an anode connected to a control terminal of the first switch and a cathode connected to the voltage supply. A second switch includes a control terminal and first and second terminals. A temperature sensing circuit is configured to sense a temperature of the first switch and to generate a sensed temperature. A comparing circuit includes inputs that receive a reference temperature and the sensed temperature and an output connected to the control terminal of the second switch.

Abstract: An integrated circuit for demagnetizing an inductive load includes a first switch to control current supplied by a voltage supply to the inductive load. A Zener diode includes an anode connected to a control terminal of the first switch and a cathode connected to the voltage supply. A second switch includes a control terminal and first and second terminals. A temperature sensing circuit is configured to sense a temperature of the first switch and to generate a sensed temperature. A comparing circuit includes inputs that receive a reference temperature and the sensed temperature and an output connected to the control terminal of the second switch.

Abstract: An integrated circuit for demagnetizing an inductive load includes a first switch to control current supplied by a voltage supply to the inductive load. A Zener diode includes an anode connected to a control terminal of the first switch and a cathode connected to the voltage supply. A second switch includes a control terminal and first and second terminals. A temperature sensing circuit is configured to sense a temperature of the first switch and to generate a sensed temperature. A comparing circuit includes inputs that receive a reference temperature and the sensed temperature and an output connected to the control terminal of the second switch.

Abstract: In an embodiment, an analog front end (AFE) bridge for a SLPI PHY includes: an AFE LINK-side circuit having at least one pair of differential LINK-side nodes which does not conform to SLPI PHY specifications; an AFE PHY-side circuit having a pair of differential PHY-side nodes conforming to SLPI PHY specifications, wherein the AFE PHY-side circuit is coupled to the AFE LINK-side circuit; and a termination control circuit coupled to the AFE PHY-side circuit. A method of bridging a legacy LINK circuit to a SLPI PHY circuit includes: communicating with a legacy LINK circuit with a legacy LINK protocol; communicating with a SLPI PHY circuit with a SLPY PHY protocol over a differential pair; converting outputs of the legacy LINK circuit into inputs of the SLPI PHY circuit; converting outputs of the SLPI PHY circuit into inputs of the legacy LINK circuit; controlling a termination of the differential pair.

Abstract: In an embodiment, an analog front end (AFE) bridge for a SLPI PHY includes: an AFE LINK-side circuit having at least one pair of differential LINK-side nodes which does not conform to SLPI PHY specifications; an AFE PHY-side circuit having a pair of differential PHY-side nodes conforming to SLPI PHY specifications, wherein the AFE PHY-side circuit is coupled to the AFE LINK-side circuit; and a termination control circuit coupled to the AFE PHY-side circuit. A method of bridging a legacy LINK circuit to a SLPI PHY circuit includes: communicating with a legacy LINK circuit with a legacy LINK protocol; communicating with a SLPI PHY circuit with a SLPY PHY protocol over a differential pair; converting outputs of the legacy LINK circuit into inputs of the SLPI PHY circuit; converting outputs of the SLPI PHY circuit into inputs of the legacy LINK circuit; controlling a termination of the differential pair.

Abstract: A method of assessing the offset on the output nodes of an amplifying channel includes generating a logic signal for signaling the existence of an offset having a level exceeding a window of permitted levels symmetric about the zero level. The window is defined by a negative limit value and by a positive limit value. The method includes establishing an interval or phase of detection by applying to an input of a detection circuit a timing pulse with a certain frequency, sensing the rising edge of the timing pulse and setting a bistable circuit, and comparing the signal on the output nodes of the amplifiers channel with the window of permitted values. The bistable circuit is reset upon the occurrence, after the initial setting, of an output signal amplitude within the window of permitted values. Failure of the bistable circuit to reset before the end of the detection phase signals an excessive offset.

Abstract: A method of voltage driving a load using a controlled current includes providing a negative feedback of an output current, measuring the output current on a collector of an output transistor of an output stage, comparing the measured output current with an input current to define a current difference, and providing the current difference at a base of the output transistor to provide the voltage driving.

Abstract: A switching output power stage, including a power switching device for the supply line and a complementary power switching device for the ground rail driven in phase opposition by a pulse width modulated (PWM) drive signal, is provided with sensors detecting a substantial turn-off state of each of the two power switching devices and generating a pair of logic signals. A combinatory logic circuit combines the drive signal and the pair of logic signals and generates a pair of driving signals of opposite phase for the respective power switching devices. The switching to a turn-on state of any of the two power devices is enabled upon verifying a substantially attained turn-off state by the device complementary to the device commanded to turn-on, irrespective of the process spread and of changes of temperature load conditions and of configuration of a plurality of output stages of a multichannel amplifier.