Abstract: A circuit for use with PWM signal having first pulse and a second pulse, wherein the first pulse has a period and a first duty cycle, and the second pulse has the period and a second duty cycle. The period has clock information therein, the first duty cycle has first data information therein, and the second duty cycle has second data information therein. The circuit includes a first integrating component and a second integrating component. The first integrating component can generate a first voltage corresponding to the first duty cycle and a second voltage corresponding to the first duty cycle. The second integrating component can generate a third voltage corresponding to the second duty cycle and a fourth voltage corresponding to the second duty cycle.

Abstract: In an embodiment, a duty cycle correction circuit comprises a first set of inverters connected in series, a first filter, a first feedback circuit and a second feedback circuit. A first inverter in the series is configured to receive a clock signal and a last inverter in the series is configured to provide a first output clock signal. The first filter is configured to generate a first direct current (DC) voltage signal at an output of the first filter. The first feedback circuit is configured to control a rise time of a signal transition at an output terminal of the first inverter to control a duty cycle of the first output clock cycle. The second feedback circuit is configured to control a fall time of the signal transition at the output terminal of the first inverter to control the duty cycle of the first output clock cycle.

Abstract: Architecture for VBUS pulsing in an Ultra Deep Sub Micron (UDSM) process for ensuring USB-OTG (On The Go) session request protocol, the architecture being of the type wherein at least a charging circuit is deployed, uses a diode-means connected in a forward path of the charging circuit. The architecture might include a diode-divider including nodes and connected from VBUS in said charging circuit. One embodiment uses both charging and discharging circuits comprising transistors. The charging circuit transistor might comprise a PMOS transistor and the discharging circuit transistor might comprise a NMOS transistor. The architecture might include a three resistance string of a total resistance value approximating 100K Ohms connected between said VBUS and ground, wherein the discharging circuit transistor might comprise a drain extended NMOS transistor. The charging and discharging circuit transistors have VDS and VGD of about 3.6V, whereby high VGS transistors are not needed.

Abstract: A device includes a sense circuit configured to detect a leakage current from a driver output pad. A current mirror responds to the sense circuit and compensates for the leakage current detected at the driver output pad. A scaled compensation circuit can supply compensation current to the current mirror.

Abstract: Architecture for VBUS pulsing in an Ultra Deep Sub Micron (UDSM) process for ensuring USB-OTG (On The Go) session request protocol, the architecture being of the type wherein at least a charging circuit is deployed, uses a diode-means connected in a forward path of the charging circuit. The architecture might include a diode-divider including nodes and connected from VBUS in said charging circuit. One embodiment uses both charging and discharging circuits comprising transistors. The charging circuit transistor might comprise a PMOS transistor and the discharging circuit transistor might comprise a NMOS transistor. The architecture might include a three resistance string of a total resistance value approximating 100K Ohms connected between said VBUS and ground, wherein the discharging circuit transistor might comprise a drain extended NMOS transistor. The charging and discharging circuit transistors have VDS and VGD of about 3.6V, whereby high VGS transistors are not needed.

Abstract: A thin-oxide current clamp includes a clamp transistor in current-conducting relation between a voltage-sensitive circuit and a common return of a power supply, the clamp transistor responsive to a sense output signal to provide a low-resistance current flow path from the voltage-sensitive circuit to the common return and thereby clamp a voltage in the voltage-sensitive circuit. The thin-oxide current clamp also includes a current source and a reference current mirror, the reference current mirror providing a reference current. Further, the thin-oxide current clamp includes a sense current mirror providing a sense current. Further, the thin-oxide current clamp also includes an output transistor that receives the sense current and provides a current flow to a gate of the clamp transistors if the sense current exceeds the reference current.

Abstract: A device includes a sense circuit configured to detect a leakage current from a driver output pad. A current mirror responds to the sense circuit and compensates for the leakage current detected at the driver output pad. A scaled compensation circuit can supply compensation current to the current mirror.

Abstract: A voltage-mode driver circuit supporting pre-emphasis includes multiple resistors, and multiple transistors operated as switches. Control signals operating the transistors represent a logic level of an input signal to the driver circuit. To generate a pre-emphasized output, the transistors are operated to connect a parallel arrangement of the resistors between output terminals of the driver and corresponding constant reference potentials. To generate an output in the steady-state, the transistors are operated to connect some of the resistors across the output terminals of the driver, thereby reducing the output voltage. A desired output impedance of the driver, and a desired level of pre-emphasis are obtained by appropriate selection of the resistance values of the resistors. The current consumption of the driver is less in the steady-state than in the pre-emphasis mode.

Abstract: A voltage-mode driver circuit supporting pre-emphasis includes multiple resistors, and multiple transistors operated as switches. Control signals operating the transistors represent a logic level of an input signal to the driver circuit. To generate a pre-emphasized output, the transistors are operated to connect a parallel arrangement of the resistors between output terminals of the driver and corresponding constant reference potentials. To generate an output in the steady-state, the transistors are operated to connect some of the resistors across the output terminals of the driver, thereby reducing the output voltage. A desired output impedance of the driver, and a desired level of pre-emphasis are obtained by appropriate selection of the resistance values of the resistors. The current consumption of the driver is less in the steady-state than in the pre-emphasis mode.

Abstract: Driver circuit for high voltage differential signaling. The circuit includes a first positive driver that generates a first positive transition at a first output in response to an input. The circuit also includes a first current element coupled to the first positive driver to enable generation of a current. Further, the circuit includes a first negative driver coupled to the first current element, and responsive to the input and the current, due to the first current element, to generate a first negative transition, at a second output, at a rate similar to that of the first positive transition.

Abstract: A thin-oxide current clamp includes a clamp transistor in current-conducting relation between a voltage-sensitive circuit and a common return of a power supply, the clamp transistor responsive to a sense output signal to provide a low-resistance current flow path from the voltage-sensitive circuit to the common return and thereby clamp a voltage in the voltage-sensitive circuit. The thin-oxide current clamp also includes a current source and a reference current minor, the reference current minor providing a reference current. Further, the thin-oxide current clamp includes a sense current mirror providing a sense current. Further, the thin-oxide current clamp also includes an output transistor that receives the sense current and provides a current flow to a gate of the clamp transistors if the sense current exceeds the reference current.

Abstract: Driver circuit for high voltage differential signaling. The circuit includes a first positive driver that generates a first positive transition at a first output in response to an input. The circuit also includes a first current element coupled to the first positive driver to enable generation of a current. Further, the circuit includes a first negative driver coupled to the first current element, and responsive to the input and the current, due to the first current element, to generate a first negative transition, at a second output, at a rate similar to that of the first positive transition.

Abstract: An output buffer provided according to an aspect of the present invention is designed to generate an output signal with a slew rate that is substantially independent of the threshold voltage of transistors contained within. An output buffer provided according to another aspect of the present invention provides output signals with different slew rates depending on the magnitude of the load capacitance at the output node of the output buffer.

Abstract: A comparator component having a comparison circuit and bias generator circuit, with the bias generator circuit also having a same number of transistors connected in an identical configuration, as those contained in the comparison circuit to generate a comparison result based on the bias signal generated by the bias generator circuit. A transistor of the comparison circuit receiving the bias signal is connected to a corresponding transistor in the bias generator circuit, in a current mirror configuration. The same bias circuit may be shared by many comparison circuits of corresponding comparator components. The features can be extended to provide hysteresis.

Abstract: A comparator component having a comparison circuit and bias generator circuit, with the bias generator circuit also having a same number of transistors connected in an identical configuration, as those contained in the comparison circuit to generate a comparison result based on the bias signal generated by the bias generator circuit. A transistor of the comparison circuit receiving the bias signal is connected to a corresponding transistor in the bias generator circuit, in a current mirror configuration. The same bias circuit may be shared by many comparison circuits of corresponding comparator components. The features can be extended to provide hysteresis.

Abstract: A method, apparatus and system of constant output common mode voltage of a pre-amplifier circuit are disclosed. In one embodiment, a system includes a first circuit, a comparator circuit coupled with an output of the first circuit, a pre-amplifier circuit of the comparator circuit, a tracking circuit coupled with a common output location of the pre-amplifier circuit to provide (e.g., source/sink) an additional current to the common output location of the pre-amplifier circuit using an alternate current path in the tracking circuit when an input common mode of the pre-amplifier circuit is beyond a saturation range, and a second circuit of the comparator circuit coupled with the pre-amplifier circuit. A scaled version of a pair of input transistors of a pre-amplifier circuit of the tracking circuit may be created using a scaling factor (‘N’).

Abstract: A method, apparatus and system of constant output common mode voltage of a pre-amplifier circuit are disclosed. In one embodiment, a system includes a first circuit, a comparator circuit coupled with an output of the first circuit, a pre-amplifier circuit of the comparator circuit, a tracking circuit coupled with a common output location of the pre-amplifier circuit to provide (e.g., source/sink) an additional current to the common output location of the pre-amplifier circuit using an alternate current path in the tracking circuit when an input common mode of the pre-amplifier circuit is beyond a saturation range, and a second circuit of the comparator circuit coupled with the pre-amplifier circuit. A scaled version of a pair of input transistors of a pre-amplifier circuit of the tracking circuit may be created using a scaling factor (‘N’).

Abstract: An output buffer provided according to an aspect of the present invention is designed to generate an output signal with a slew rate that is substantially independent of the threshold voltage of transistors contained within. An output buffer provided according to another aspect of the present invention provides output signals with different slew rates depending on the magnitude of the load capacitance at the output node of the output buffer.

Abstract: Architecture for VBUS pulsing in an Ultra Deep Sub Micron (UDSM) process for ensuring USB-OTG (On The Go) session request protocol, the architecture being of the type wherein at least a charging circuit is deployed, uses a diode-means connected in a forward path of the charging circuit. The architecture might include a diode-divider including nodes and connected from VBUS in said charging circuit. One embodiment uses both charging and discharging circuits comprising transistors. The charging circuit transistor might comprise a PMOS transistor and the discharging circuit transistor might comprise a NMOS transistor. The architecture might include a three resistance string of a total resistance value approximating 100K Ohms connected between said VBUS and ground, wherein the discharging circuit transistor might comprise a drain extended NMOS transistor. The charging and discharging circuit transistors have VDS and VGD of about 3.6V, whereby high VGS transistors are not needed.

Abstract: Various systems and methods for common mode detection are disclosed. As one example, a common mode detection circuit including a differential input stage, a common mode replica stage, and an amplifier is disclosed. The differential input stage exhibits an input common mode, and includes two differential inputs. A signal from the differential input stage representing the input common mode is electrically coupled to an input of the amplifier. Another input of the amplifier is electrically coupled to the common mode replica stage, and the amplifier outputs a signal indicative of the input common mode.