Abstract: Systems and methods for operating a voltage converter are described. A circuit can multiply a digital code by a predetermined multiplier to obtain a product. The digital code can represent a desired output voltage of the voltage converter. The predetermined multiplier can cause the product to be maintained within a predetermined window. The product can be maintained within the predetermined window to cause an output of a reference digital-to-analog converter of the voltage converter to be maintained within a predetermined voltage window. The circuit can receive a feedback voltage indicating an output voltage of the voltage converter. The circuit can divide the feedback voltage by a divisor to obtain a divided voltage. The divisor can correspond to the digital code. The circuit can send the divided voltage to an error amplifier of the voltage converter.

Abstract: In an embodiment, a semiconductor device is disclosed. The semiconductor device includes a plurality of output pins. Each of the output pins is electrically connected to an input pin of a buzzer and to a buzzer driver. The buzzer driver is configured to cause the buzzer to emit an audible sound. The semiconductor device further includes a plurality of ground switches. Each ground switch is configured to connect a corresponding output pin of the plurality of output pins to ground when closed. The semiconductor device further includes a current generator that is configured to supply a test current to a given output pin of the plurality of output pins and a clamp switch that is configured to connect the given output pin to an analog-to-digital converter.

Abstract: In an embodiment, a semiconductor device is disclosed. The semiconductor device includes a plurality of output pins. Each of the output pins is electrically connected to an input pin of a buzzer and to a buzzer driver. The buzzer driver is configured to cause the buzzer to emit an audible sound. The semiconductor device further includes a plurality of ground switches. Each ground switch is configured to connect a corresponding output pin of the plurality of output pins to ground when closed. The semiconductor device further includes a current generator that is configured to supply a test current to a given output pin of the plurality of output pins and a clamp switch that is configured to connect the given output pin to an analog-to-digital converter.

Abstract: Example implementations include a method of pre-bootup fault monitor of a LASER diode driver output, by applying a first power to a pre-bootup fault monitor device, setting a fault condition at the pre-bootup fault monitor device to a no-fault state, initiating the pre-bootup fault monitor device, determining whether a first impedance of driver output satisfies an impedance threshold, and in response to a determination that the first impedance satisfies the impedance threshold, applying a second power to the output device.

Abstract: Example implementations include a method of pre-bootup fault monitor of a LASER diode driver output, by applying a first power to a pre-bootup fault monitor device, setting a fault condition at the pre-bootup fault monitor device to a no-fault state, initiating the pre-bootup fault monitor device, determining whether a first impedance of driver output satisfies an impedance threshold, and in response to a determination that the first impedance satisfies the impedance threshold, applying a second power to the output device.

Abstract: Circuits, methods, and apparatus that provide highly accurate DCPs. One example provides a DCP that includes a resistor string having taps that may be selected by a corresponding number of switches under the control of a digital word. To compensate for parasitic switch resistances and for variations in the values of the resistor sting caused by processing tolerances, a voltage-controlled resistor (VCR) is placed in parallel with the resistor string and switches. A control voltage generated using a control loop adjusts the parallel VCR such that the resistance seen across the DCP is the desired value. The control loop compares a reference resistor to loop components that are scaled to the resistor string, switches, and VCR. The reference resistor may be an external resistor or an internal resistor. If the resistor is internal, it may be trimmed, for example with lasers or fuses.

Abstract: An external resistive element is used to provide a substantially constant output impedance for multiple drivers disposed on an IC. The drivers may operate at different supply voltages. Accordingly, the parameters which depend on the driver output impedance, such as rise/fall time, propagation delay, and the like are made substantially constant and independent of the semiconductor process variations, operating supply voltages, and the temperature. The substantially constant output impedance maintains the stability of the crossing point of a true and its complementary clock signal in high-speed applications, such as in the drivers used in charge-coupled devices. A number of feedback loops are used together with the external resistive element to achieve the substantially constant output impedance. The feedback loops compensate for the ageing effects, temperature gradients and changes in the operating conditions of the IC.