A USB Type-C module has a plurality of ground pins including a first ground pin, a first configuration pin, a second configuration pin and a detector. The detector is electrically connected to the first ground pin and configured to detect a voltage value at the first ground pin so as to selectively enable a controller to determine a configuration of a corresponding connector via at least one of the first configuration pin and the second configuration pin.

A USB Type-C module has a plurality of ground pins including a first ground pin, a first configuration pin, a second configuration pin and a detector. The detector is electrically connected to the first ground pin and configured to detect a voltage value at the first ground pin so as to selectively enable a controller to determine a configuration of a corresponding connector via at least one of the first configuration pin and the second configuration pin.

Techniques for low-power USB Type-C receivers with high DC-level shift tolerance and high noise rejection are described herein. In an example embodiment, a USB-enabled device comprises a receiver circuit coupled to a Configuration Channel (CC) line of a USB Type-C subsystem. The receiver circuit is configured to receive data from an incoming signal on the CC line even when the incoming signal has more than 250 mV of DC offset with respect to local ground, and to reject the incoming signal even when the incoming signal includes noise with a magnitude of more than 300 mVpp.

Techniques for low-power USB Type-C receivers with high DC-level shift tolerance and high noise rejection are described herein. In an example embodiment, a USB-enabled device comprises a receiver circuit coupled to a Configuration Channel (CC) line of a USB Type-C subsystem. The receiver circuit is configured to receive data from an incoming signal on the CC line even when the incoming signal has more than 250 mV of DC offset with respect to local ground, and to reject the incoming signal even when the incoming signal includes noise with a magnitude of more than 300 mVpp.

This specification describes an integrated circuit comprising: a single wire interface; a clock circuit configured to detect a voltage from the single wire interface and to generate a clock signal having a frequency that is based on the detected voltage; and a digital system coupled with the single wire interface and the clock circuit. The digital system is configured to: receive a data signal from the single wire interface; power the digital system using a power signal from the single wire interface; and perform one or more operations clocked by the clock signal.

A single pin is used to control an operating mode of an integrated circuit and to supply serial data to a host controller. The internal operating mode can be changed by changing a static level on an input/output terminal and maintaining that static level longer than a first time threshold. A read transaction from the integrated circuit can be performed in response to a predetermined sequence on the input/output terminal that includes a pulse that lasts a first predetermined time, the first predetermined time being less than the first time threshold.

A single pin is used to control an operating mode of an integrated circuit and to supply serial data to a host controller. The internal operating mode can be changed by changing a static level on an input/output terminal and maintaining that static level longer than a first time threshold. A read transaction from the integrated circuit can be performed in response to a predetermined sequence on the input/output terminal that includes a pulse that lasts a first predetermined time, the first predetermined time being less than the first time threshold.

This specification describes an integrated circuit comprising: a single wire interface; a clock circuit configured to detect a voltage from the single wire interface and to generate a clock signal having a frequency that is based on the detected voltage; and a digital system coupled with the single wire interface and the clock circuit. The digital system is configured to: receive a data signal from the single wire interface; power the digital system using a power signal from the single wire interface; and perform one or more operations clocked by the clock signal.

This specification describes an integrated circuit comprising: a single wire interface; a clock circuit configured to detect a voltage from the single wire interface and to generate a clock signal having a frequency that is based on the detected voltage; and a digital system coupled with the single wire interface and the clock circuit. The digital system is configured to: receive a data signal from the single wire interface; power the digital system using a power signal from the single wire interface; and perform one or more operations clocked by the clock signal.

One example discloses a driver circuit, comprising: a first transistor (Q.sub.TN) coupled to a first differential input (IN) and a power supply input (VCC); a second transistor (Q.sub.TP) coupled to a second differential input (IP) and the power supply input; a third transistor (Q.sub.BN) coupled to a first differential output (ON); a fourth transistor (Q.sub.BP) coupled to a second differential output (OP); a first resistance (R.sub.P1) coupling the first transistor (Q.sub.TN) to the third transistor (Q.sub.BN); a second resistance (R.sub.P2) coupling the second transistor (Q.sub.TP) to the fourth transistor (Q.sub.BP); and a controller coupled to the power supply input; wherein the controller is configured to detect a ramp-down of a power supply coupled to the power supply input and in response disable a set of circuit elements in the driver circuit.