A transmitter is provided. the transmitter includes a hybrid feedback circuit and a hybrid driving circuit. The hybrid feedback circuit compares a reference voltage with a feedback voltage in closed-loop, determines whether to perform polarity reversal according to a mode control signal, controls power output according to a comparison result and the mode control signal, and generates a first output signal. The hybrid driving circuit, coupled to the hybrid feedback circuit, receives the first output signal of the hybrid feedback circuit, generates a transmitter output signal according to an input data, and generates a second output signal according to the transmitter output signal. The first output signal and the second output signal are transmitted back to the hybrid feedback circuit.

In certain aspects, a voltage regulator includes a pass transistor coupled between an input of the voltage regulator and an output of the voltage regulator, and an amplifier having a first input coupled to a reference voltage, a second input coupled to the output of the voltage regulator via a feedback path, and an output. The voltage regulator also includes a voltage booster coupled between the output of the amplifier and a gate of the pass transistor. In certain aspects, the voltage booster includes a first capacitor and a second capacitor for double charge pumping. In certain aspects, a control circuit of the voltage booster is coupled to a voltage source that is independent of an output voltage of the amplifier.

In certain aspects, a voltage regulator includes a pass transistor coupled between an input of the voltage regulator and an output of the voltage regulator, and an amplifier having a first input coupled to a reference voltage, a second input coupled to the output of the voltage regulator via a feedback path, and an output. The voltage regulator also includes a voltage booster coupled between the output of the amplifier and a gate of the pass transistor. In certain aspects, the voltage booster includes a first capacitor and a second capacitor for double charge pumping. In certain aspects, a control circuit of the voltage booster is coupled to a voltage source that is independent of an output voltage of the amplifier.

Disclosed is a power supply that automatically switches between a voltage regulation mode and an over current protection mode, as needed. The power supply includes a voltage regulator that generates a first control voltage for applying to the control terminal of a pass transistor during a voltage regulation mode to maintain an output voltage at a desired voltage level. The power supply includes a current limiter that generates a second control voltage for applying to the control terminal of the pass transistor during an over current protection mode to prevent an output current from rising above a maximum output current limit. The power supply includes additional circuitry that detects when over current protection is required and automatically switches the control voltage applied to the control terminal from the first control voltage to the second control voltage or vice versa, as necessary. Also disclosed is an associated power supply method.

Disclosed is a power supply that automatically switches between a voltage regulation mode and an over current protection mode, as needed. The power supply includes a voltage regulator that generates a first control voltage for applying to the control terminal of a pass transistor during a voltage regulation mode to maintain an output voltage at a desired voltage level. The power supply includes a current limiter that generates a second control voltage for applying to the control terminal of the pass transistor during an over current protection mode to prevent an output current from rising above a maximum output current limit. The power supply includes additional circuitry that detects when over current protection is required and automatically switches the control voltage applied to the control terminal from the first control voltage to the second control voltage or vice versa, as necessary. Also disclosed is an associated power supply method.

According to one embodiment, a constant voltage circuit includes: a first gain stage configured to output a first voltage amplified based on an output voltage and a reference voltage; a first transistor configured to control the output voltage based on the first voltage applied to a gate; and a second circuit configured to control a first signal based on a second voltage obtained by delaying an output timing of the output voltage and a third voltage that is based on the output voltage. In a case of the first signal being at a first logic level, a first current flows through the first gain stage, and in a case of the first signal being at a second logic level, a second current flows through the first gain stage.

According to one embodiment, a constant voltage circuit includes: a first gain stage configured to output a first voltage amplified based on an output voltage and a reference voltage; a first transistor configured to control the output voltage based on the first voltage applied to a gate; and a second circuit configured to control a first signal based on a second voltage obtained by delaying an output timing of the output voltage and a third voltage that is based on the output voltage. In a case of the first signal being at a first logic level, a first current flows through the first gain stage, and in a case of the first signal being at a second logic level, a second current flows through the first gain stage.

A time-to-digital converter (TDC) that combines the energy efficiency of a successive approximation (SAR) design with the high speed of pipelined converters by leveraging the inherently pipelined nature of time-domain signaling. The TDC achieves high speed by removing a comparator decision from a signal path, instead using AND/OR gates to separate early and late edges. The TDC uses a pipelined SAR architecture to digitize a differential delay between two incoming clock edges with high speed and low power consumption. Described is a modular digital reference voltage generator that can be used for a capacitive digital-to-analog converter (DAC). The generator comprises a decoupling capacitor, one or more clocked comparators, and power transistor(s). A simplified digital low dropout (LDO) circuitry is used to provide fast reference voltage generation with minimal overhead. The LDO circuitry is arrayed using time-interleaved synchronous clocks or staggered asynchronous clocks to provide finer timing resolution.

A time-to-digital converter (TDC) that combines the energy efficiency of a successive approximation (SAR) design with the high speed of pipelined converters by leveraging the inherently pipelined nature of time-domain signaling. The TDC achieves high speed by removing a comparator decision from a signal path, instead using AND/OR gates to separate early and late edges. The TDC uses a pipelined SAR architecture to digitize a differential delay between two incoming clock edges with high speed and low power consumption. Described is a modular digital reference voltage generator that can be used for a capacitive digital-to-analog converter (DAC). The generator comprises a decoupling capacitor, one or more clocked comparators, and power transistor(s). A simplified digital low dropout (LDO) circuitry is used to provide fast reference voltage generation with minimal overhead. The LDO circuitry is arrayed using time-interleaved synchronous clocks or staggered asynchronous clocks to provide finer timing resolution.

A low dropout (LDO) voltage regulator includes a first LDO stage that receives a first supply voltage and is active during a first time interval and a second LDO stage that receives a second supply voltage and is active during a second time interval. An operational amplifier receives a feedback voltage based on the LDO output voltage and provides an amplified feedback signal to the first and second LDO stages. A compensation capacitor is selectively coupled between the operational amplifier and either the first or the second LDO stage. A current limit circuit includes a sense FET coupled to the LDO pass FET, a drain voltage replication circuit coupled between the pass FET and sense FET to provide a sense current is indicative of load current when the pass FET is in a linear region, and a current comparator to compare the sense current to a predetermined current level.