Voltage reference circuits are provided. A voltage reference circuit includes a transistor, a flipped-gate transistor, a first current mirror unit, a second current mirror unit, and an output note. A gate and a drain of the flipped-gate transistor are coupled to a gate and a drain of the transistor. A bulk and a source of the flipped-gate transistor are coupled to a ground. The first current mirror unit is configured to provide a first current to the flipped-gate transistor and a mirroring current in response to a bias current. The second current mirror unit is configured to drain a second current from the first transistor in response to the mirroring current. The output node is coupled to a source of the transistor and the second current mirror unit, and configured to output a reference voltage. Size of the flipped-gate transistor is less than that of the first transistor.

The present invention discloses a voltage reference buffer circuit. An embodiment of the voltage reference buffer circuit includes: a first bias generator configured to generate a first bias voltage; a second bias generator configured to generate a second bias voltage different from the first bias voltage; a first driving component coupled to a high voltage terminal, the first bias generator and a reference voltage output terminal, and configured to control a reference voltage at the reference voltage output terminal according to the first bias voltage; and a second driving component coupled to the reference voltage output terminal, the second bias generator and a low voltage terminal, and configured to control a current between the reference voltage output terminal and the second driving component according to the second bias voltage.

A bandgap reference circuit and method of using the same are provided. The bandgap reference circuit includes a startup component; an output component; and a bandgap core component coupled there-between. The bandgap core component includes a reference point having a voltage associated with an output signal of the output component. A controller is configured for controlling the bandgap core component and the output component to switch between a low power consumption mode and a normal operation mode based on the voltage at the reference point. When the bandgap core component and the output component operate in the normal operation mode, the bandgap reference circuit outputs a stable voltage and has a first power consumption. When the bandgap core component and the output component operate in the low power consumption mode, the bandgap reference circuit has a second power consumption less than the first power consumption.

A clamp circuit includes a first MOS transistor and a second MOS transistor connected in series with the first MOS transistor. The first MOS transistor has a gate connected to a drain of the first MOS transistor. The second MOS transistor has a gate connected to a drain of the second MOS transistor. The clamp circuit is configured so that at least one of the first MOS transistor and the second MOS transistor causes a body effect.

A buffer stage includes a control circuit. The control circuit includes a voltage generator, a voltage-to-current converter, and a current-to-voltage converter. The voltage generator is configured to generate a compensation voltage. The voltage-to-current converter is configured to convert the compensation voltage into a compensation current. The current-to-voltage converter is configured to convert the compensation current into a recovery compensation voltage. The recovery compensation voltage is arranged for modifying an output voltage of the buffer stage.

Some embodiments relate to a two transistor band gap reference circuit. A first transistor includes a first source, a first drain, a first body region separating the first source from the first drain, and a first gate. The first drain and first gate are coupled to a DC supply terminal. The second transistor includes a second source, a second drain, a second body region separating the second source from the second drain, and a second gate. The second gate is coupled to the DC supply terminal, and the second drain is coupled to the first source. Body bias circuitry is configured to apply a body bias voltage to at least one of the first and second body regions. Other embodiments relate to FinFET devices.

An electronic device and an integrated circuit thereof are provided. The integrated circuit includes a voltage generator and a current generator with a negative temperature coefficient. The voltage generator generates a reference voltage proportional to an absolute temperature based on a predetermined value. The current generator with the negative temperature coefficient receives the reference voltage and generates a reference current based on the reference voltage.

An environmental sensor implementing a sleep mode timer with an oscillator circuit suitable for low power applications is presented. The oscillator circuit includes a plurality of timer stages cascaded in series with each other. Each timer circuit includes a plurality of transistors and operates to output two voltages with opposite polarities, such that the polarities of the two voltages oscillate periodically based on leakage current in the plurality of transistors. Each timer circuit further includes one or more tuning transistors that operate to adjust a frequency at which the polarities of the voltages oscillate. A complementary-to-absolute temperature (CTAT) voltage generator is configured to receive a regulated voltage and supply a bias voltage to the one or more tuning transistors in each of the plurality of timer circuits, where the CTAT voltage generator adjusts the bias voltage linearly and inversely with changes in temperature.

A voltage generation circuit may include: a main code table suitable for outputting a main code based on an operation signal; a main voltage generator suitable for generating a main voltage corresponding to the main code; a trimming module suitable for comparing the main voltage with a target voltage to output a trimming signal; a trimming code table suitable for outputting a trimming code corresponding to the trimming signal; a code determination module suitable for outputting the main code and the trimming code when the trimming code is determined to be valid, and outputting the main code and a output code when the trimming code is determined to be invalid; and an operation voltage generator suitable for outputting an operation voltage based on the main code and a code selected from the trimming code and the substitute code.

A voltage generation circuit may include: a main code table suitable for outputting a main code based on an operation signal; a main voltage generator suitable for generating a main voltage corresponding to the main code; a trimming module suitable for comparing the main voltage with a target voltage to output a trimming signal; a trimming code table suitable for outputting a trimming code corresponding to the trimming signal; a code determination module suitable for outputting the main code and the trimming code when the trimming code is determined to be valid, and outputting the main code and a output code when the trimming code is determined to be invalid; and an operation voltage generator suitable for outputting an operation voltage based on the main code and a code selected from the trimming code and the substitute code.