The present invention discloses a comparator circuit having false-alarm preventing mechanism. An input pair circuit receives a first and a second input voltages from a first and a second input terminals in an the operation state. The input pair circuit and a latch circuit cooperate to perform comparison thereon in the operation state to generate a first and a second output voltages at a first and a second output terminals. A gate and a drain of a first latch transistor are electrically coupled to the first and the second output terminals respectively. A gate and a drain of a second latch transistor are electrically coupled to the second and the first output terminals respectively. A conduction adjusting circuit enhances the conduction of the latch circuit when being triggered. A voltage detection circuit triggers the conduction adjusting circuit when the first and the second output voltages are not within a predetermined range.

A duobinary receiver includes a signal dividing circuit configured to output a plurality of data by dividing an input signal according to a plurality of multi-phase sampling clocks signals; a level detecting circuit configured to output a plurality of state signals respectively corresponding to duobinary levels of the plurality of data; and a data converting circuit configured to decode the plurality of state signals to output a corresponding plurality of bits.

A voltage regulator receives an input voltage and produces a regulated output voltage. A first feedback network compares a feedback signal to a reference signal to assert/de-assert a first pulsed control signal when the reference signal is higher/lower than the feedback signal. A second feedback network compares the output voltage to a threshold signal to assert/de-assert a second control signal when the threshold signal is higher/lower than the output voltage. A charge pump is enabled if the second control signal is de-asserted and is clocked by the first pulsed control signal to produce a supply voltage higher than the input voltage. A first pass element is enabled when the second control signal is asserted and is selectively activated when the first pulsed control signal is asserted. A second pass element is selectively activated when the second control signal is de-asserted.

The present disclosure provides a substrate-enhanced comparator and electronic device, the comparator including: a cross-coupled latch, for connecting input signals to the gate of a cross-coupled MOS transistor to form a first input of the latch; output buffers, connected to the cross-coupled latch for amplifying output signals of the latch; AC couplers, connected to the output buffers for receiving and amplifying the output signals of the latch, coupling the output signals to substrates of the cross-coupled MOS transistors to form second inputs of the latch. The cross-coupled latch is also for output signal regenerative latching based on input signals sampled at the first inputs and input signals sampled at the second inputs. The present disclosure introduces additional substrate inputs to the cross-coupled structure of the conventional latch as the second inputs of the latch.

A comparator includes a second-stage circuit, a first input circuit, a second input circuit, a first cross-coupled circuit and a second cross-coupled circuit. The first input circuit is configured to generate a first data terminal voltage and a first reference terminal voltage. The first cross-coupled circuit is configured to perform mutual positive feedback on the first data terminal voltage and the first reference terminal voltage to generate a first differential signal. The second input circuit is configured to generate a second data terminal voltage and a second reference terminal voltage. The second cross-coupled circuit is configured to perform mutual positive feedback on the second data terminal voltage and the second reference terminal voltage to generate a second differential signal. The second-stage circuit is configured to amplify and latch the first differential signal or the second differential signal in a regeneration phase to output a comparison signal.

Varactors may be employed to enable enhanced performance and/or reduced power consumption of integration-based voltage comparators. One illustrative voltage comparator includes: a latch having two sense transistors to set a latch to either of two complementary states; two varactors each coupled to enable one of the two sense transistors upon reaching a turn on voltage; and a differential amplifier to charge or discharge the two varactors at a differential rate proportional to a difference in input voltages. An illustrative voltage comparison method includes: converting two input voltages into two respective currents; applying each of the two respective currents to one of two respective varactors; and deriving a latch state from the varactor voltages, the latch state indicating which of the two input voltages is greater.

Provided is a comparison circuit to which a negative voltage to be compared can be input directly. The comparison circuit includes a first input terminal, a second input terminal, a first output terminal, and a differential pair. The comparison circuit compares a negative voltage and a negative reference voltage and outputs a first output voltage from the first output terminal in response to the comparison result. The negative voltage is input to the first input terminal. A positive reference voltage is input to the second input terminal. The positive reference voltage is determined so that comparison is performed. The differential pair includes a first n-channel transistor and a second n-channel transistor each having a gate and a backgate. The first input terminal is electrically connected to the backgate of the first n-channel transistor. The second input terminal is electrically connected to the gate of the second n-channel transistor.

A clock signal generation circuit, a method for generating a clock signal, and an electronic device are provided, relating to the field of communications technology. In the clock signal generation circuit, an initial clock providing circuit can generate an initial clock signal having an initial frequency; a control word providing circuit can determine a target frequency offset of the initial frequency based on a detected target parameter and generate a frequency control word based on the target frequency offset; a target clock generating circuit can generate a target clock signal having a target output frequency based on the frequency control word and the initial clock signal, wherein the target output frequency is negatively correlated with a value of the frequency control word and positively correlated with the initial frequency.

In certain aspects, a comparator includes an input stage and a regeneration stage. The input stage includes a first input circuit coupled to a first node and a second node, a first switching transistor configured to enable the first input circuit if a previous bit value is one, a second input circuit coupled to the first node and the second node, and a second switching transistor configured to enable the second input circuit if the previous bit value is zero. The regeneration stage includes a first inverter, a second inverter cross coupled with the first inverter, a first drive transistor coupled to the first inverter, wherein a gate of the first drive transistor is coupled to the second node, and a second drive transistor coupled to the second inverter, wherein a gate of the second drive transistor is coupled to the first node.

The present invention discloses a comparison circuit having adaptive comparison mechanism is provided. A comparator is enabled by an enabling signal having an enabling state during a comparison stage to compare a first voltage and a second voltage to generate a comparison result. A comparison determining circuit sets a stage indication signal at an unfinished state and a finished state before and after the comparison result is generated. A time accumulating circuit starts to accumulate an accumulated time when the enabling signal is at the enabling state and stops accumulating when the stage indication signal is at the finished state to generate a comparison time. A determining circuit performs statistics on the comparison time to generate a predetermined threshold time and sets a predetermined comparison result as the comparison result under the condition that the comparison result is not generated and the accumulated time exceeds the predetermined threshold time.