Abstract: Overload detection and protection for power switch circuits. For circuits with faster switching speed, fast fault detection and response to a detected overload condition may be desirable. Detection circuitry may monitor a voltage on the control terminal of one or more power switches. Based on empirical measurements, in an overload condition of a power switch circuit, e.g., a half-bridge circuit, the voltage at the control terminal may increase, and in some examples, increase to a magnitude that is greater than a supply voltage. A comparator may detect a voltage increase that exceeds a voltage magnitude threshold, output an indication to control circuitry for the power switch circuit, and the control circuitry may take action to protect the rest of the circuitry, such as reduce voltage or shut off the power switch circuit.

Abstract: This disclosure describes circuits and techniques for identifying potential problems with control signals for power switches. More specifically, this disclosure describes the use of registers, e.g., volatile or non-volatile storage elements, configured to count the rising and/or falling edges of pulse modulation (PM) signals within driver circuits or other control circuits. By counting the edges of PM signals within driver circuits, signaling problems can be identified based on mismatch between different counters. The techniques may be used by a driver circuit to detect circuit problems, or readout of the registers can be done after device failure, in order to help identify whether signaling problems may have caused the device failure.

Abstract: An example a circuit for controlling a power converter comprises a first power domain circuit including a first control circuit and a first driver circuit, wherein the first control circuit controls the first driver circuit to drive a first semiconductor device, wherein a second power domain circuit includes a second control circuit and a second driver circuit. The first control circuit is configured to receive a control signal for controlling the second driver circuit to drive a second semiconductor device; and identify, based on the control signal, a future electrical characteristic of a second power domain output of the power converter. Additionally, the first control circuit is configured to determine, based on the future electrical characteristic of the second power domain output of the power converter, whether to adjust one or more control parameters for controlling the first driver circuit to drive the first semiconductor device.

Abstract: This disclosure describes circuits and techniques for identifying potential problems with control signals for power switches. More specifically, this disclosure describes the use of registers, e.g., volatile or non-volatile storage elements, configured to count the rising and/or falling edges of pulse modulation (PM) signals within driver circuits or other control circuits. By counting the edges of PM signals within driver circuits, signaling problems can be identified based on mismatch between different counters. The techniques may be used by a driver circuit to detect circuit problems, or readout of the registers can be done after device failure, in order to help identify whether signaling problems may have caused the device failure.

Abstract: Overload detection and protection for power switch circuits. For circuits with faster switching speed, fast fault detection and response to a detected overload condition may be desirable. Detection circuitry may monitor a voltage on the control terminal of one or more power switches. Based on empirical measurements, in an overload condition of a power switch circuit, e.g., a half-bridge circuit, the voltage at the control terminal may increase, and in some examples, increase to a magnitude that is greater than a supply voltage. A comparator may detect a voltage increase that exceeds a voltage magnitude threshold, output an indication to control circuitry for the power switch circuit, and the control circuitry may take action to protect the rest of the circuitry, such as reduce voltage or shut off the power switch circuit.

Abstract: An example a circuit for controlling a power converter comprises a first power domain circuit including a first control circuit and a first driver circuit, wherein the first control circuit controls the first driver circuit to drive a first semiconductor device, wherein a second power domain circuit includes a second control circuit and a second driver circuit. The first control circuit is configured to receive a control signal for controlling the second driver circuit to drive a second semiconductor device; and identify, based on the control signal, a future electrical characteristic of a second power domain output of the power converter. Additionally, the first control circuit is configured to determine, based on the future electrical characteristic of the second power domain output of the power converter, whether to adjust one or more control parameters for controlling the first driver circuit to drive the first semiconductor device.

Abstract: A driver circuit is configured to deliver drive signals from an output pin to a power switch to control ON/OFF switching of the power switch. A first detection pin of the driver circuit is configured to receive a first signal associated with the power switch, wherein the first signal indicates a voltage drop over the power switch and a voltage drop over one or more other circuit elements. A second detection pin is configured to receive a second signal, wherein the second signal indicates a voltage drop over one or more matched circuit elements, wherein the one or more matched circuit elements associated with the second signal are substantially identical to the one or more other circuit elements associated with the first signal. The driver circuit is configured to determine the voltage drop over the power switch based on a difference between the first signal and the second signal.

Abstract: A driver circuit is configured to deliver drive signals from an output pin to a power switch to control ON/OFF switching of the power switch. A first detection pin of the driver circuit is configured to receive a first signal associated with the power switch, wherein the first signal indicates a voltage drop over the power switch and a voltage drop over one or more other circuit elements. A second detection pin is configured to receive a second signal, wherein the second signal indicates a voltage drop over one or more matched circuit elements, wherein the one or more matched circuit elements associated with the second signal are substantially identical to the one or more other circuit elements associated with the first signal. The driver circuit is configured to determine the voltage drop over the power switch based on a difference between the first signal and the second signal.

Abstract: This disclosure is directed to circuits and techniques for protecting a body diode of a power switch from an inductive load when the power switch is turned OFF. A driver circuit may detect whether the power switch is in a desaturation mode when the power switch is turned ON and disable the power switch in response to detecting that the power switch is in the desaturation mode. In addition, the driver circuit may detect whether the body diode of the power switch needs protection when the power switch is turned OFF, and in response to detecting that the body diode needs protection, control the power switch according to a body diode protection scheme.

Abstract: A method of operating a power switch driver circuit coupled to a power switch includes producing, by a controller of the power switch driver circuit, a first driving signal to a control terminal of the power switch to turn on the power switch; comparing, by a first comparator of the power switch driver circuit, a first voltage at the control terminal of the power switch with a first pre-determined threshold; and starting monitoring a desaturation condition of the power switch a pre-determined period of time after detecting that the first voltage is above the first pre-determined threshold, wherein monitoring the desaturation condition comprises monitoring a second voltage at a load path terminal of the power switch.

Abstract: A method of operating a power switch driver circuit coupled to a power switch includes producing, by a controller of the power switch driver circuit, a first driving signal to a control terminal of the power switch to turn on the power switch; comparing, by a first comparator of the power switch driver circuit, a first voltage at the control terminal of the power switch with a first pre-determined threshold; and starting monitoring a desaturation condition of the power switch a pre-determined period of time after detecting that the first voltage is above the first pre-determined threshold, wherein monitoring the desaturation condition comprises monitoring a second voltage at a load path terminal of the power switch.

Abstract: A gate driver is described that includes a gate signal module configured to output a gate signal of the gate driver for driving a gate terminal of a semiconductor device. The gate driver further includes a test module configured to generate a simulated failure condition at a semiconductor device during a test of a monitoring and protection feature of the gate driver. The gate drier further includes a monitor module configured to output an indication of the simulated failure condition in response to detecting the simulated failure condition at the semiconductor device.

Abstract: A gate driver is described that includes a gate signal module configured to output a gate signal of the gate driver for driving a gate terminal of a semiconductor device. The gate driver further includes a test module configured to generate a simulated failure condition at a semiconductor device during a test of a monitoring and protection feature of the gate driver. The gate drier further includes a monitor module configured to output an indication of the simulated failure condition in response to detecting the simulated failure condition at the semiconductor device.

Abstract: In accordance with an embodiment, a method of operating a gate driving circuit includes receiving a reference timing pulse, measuring the received timing pulse according to a local clock generator of the gate driving circuit, and generating a switching control signal based on the measured received timing pulse.

Abstract: In accordance with an embodiment, a method of operating a gate driving circuit includes receiving a reference timing pulse, measuring the received timing pulse according to a local clock generator of the gate driving circuit, and generating a switching control signal based on the measured received timing pulse.

Abstract: Digital-to-analogue converter for converting a digital input signal into an analogue output signal includes a resistor string with switchable taps, a decoder circuit for connecting or disconnecting the taps in a manner dependent on the digital input signal, and a voltage divider. The voltage divider is operable to generate a divider voltage that divides a voltage difference that occurs between two connectable taps. The analogue output voltage is dependent on the divider voltage generated by the voltage divider.

Abstract: Digital-to-analogue converter for converting a digital input signal into an analogue output signal includes a resistor string with switchable taps, a decoder circuit for connecting or disconnecting the taps in a manner dependent on the digital input signal, and a voltage divider. The voltage divider is operable to generate a divider voltage that divides a voltage difference that occurs between two connectable taps. The analogue output voltage is dependent on the divider voltage generated by the voltage divider.

Abstract: An apparatus converts a digital value including “a” bits into an analog signal and has 2b D/A converters. Here, b is an integer number that is greater than 0. Each of the D/A converters is designed to convert a digital value having “a−b” bits. The digital value that is supplied (for i=1 . . . 2b) to the ith D/A converter for the purpose of D/A conversion corresponds to the “a−b” most significant bits in the sum of the digital value that will be converted by the apparatus and to i−1. The output signal for the apparatus is the mean value for the output signals from the D/A converters. Such an apparatus can be produced such that it can be accommodated easily and efficiently on a semiconductor chip and, irrespective of the details of protocol implementation, permits a completely linear conversion of the digital value being converted into an analog signal.

Abstract: An apparatus converts a digital value including “a” bits into an analog signal and has 2b D/A converters. Here, b is an integer number that is greater than 0. Each of the D/A converters is designed to convert a digital value having “a-b” bits. The digital value that is supplied (for i=1 . . . 2b) to the ith D/A converter for the purpose of D/A conversion corresponds to the “a-b” most significant bits in the sum of the digital value that will be converted by the apparatus and to i−1. The output signal for the apparatus is the mean value for the output signals from the D/A converters. Such an apparatus can be produced such that it can be accommodated easily and efficiently on a semiconductor chip and, irrespective of the details of protocol implementation, permits a completely linear conversion of the digital value being converted into an analog signal.