In accordance with an embodiment, a method includes: receiving, by an adjustable frequency doubling circuit, a first clock signal having a first clock frequency; using the adjustable frequency doubling circuit, generating a second clock signal having a second clock frequency that is twice the first clock frequency; measuring a duty cycle parameter of the second clock signal, where the duty cycle parameter is dependent on a duty cycle of the first clock signal or a duty cycle of the second clock signal; and using the adjustable frequency doubling circuit, adjusting the duty cycle of the first clock signal or the second clock signal based on the measuring.

A circuit includes a first node, a first inverter connected to the first node and a second node. A variable resistive element is connected to the second node and a third node. A first switch is connected to the second node, a first capacitive element is connected in series with the first switch and the third node, a second switch connected to the second node, a second capacitive element is connected in series with the second switch and the third node, and a second inverter is connected to the third node and a fourth node.

The present invention provides a system and method of correcting duty cycle (DC) and compensating for active clock edge shift. In an embodiment, the system includes at least one control circuit to receive DCC control signals and to output at least one first adjustment signal, at least one second adjustment signal, at least one first correction signal, and at least one second correction signal, at least one adjustment circuit to change a DC value of an input clock signal, at least one correction circuit to compensate for a shift of an active clock edge of the input clock signal, and where one of the at least one adjustment circuit and the at least one correction circuit is to receive the input clock signal and wherein one of the at least one adjustment circuit and the at least one correction circuit is to transmit a corrected output clock signal.

A clock recovery circuit includes a first pulse circuit, a second pulse circuit, a state change circuit connected to the first pulse circuit and the second pulse circuit and a first delay circuit connected to the state change circuit and each of the first pulse circuit and the second pulse circuit. The first pulse circuit receives data inputs to generate a first pulse signal. The second pulse circuit receives the data inputs to generate a second pulse signal. The state change circuit receives the first pulse signal and the second pulse signal and generate a first clock signal for a first transition of one of the data inputs in a first unit interval (UI). The first delay circuit receives the generated first clock signal and mask other transitions of the data inputs in the first UI.

A method of generating precise and PVT-stable time delay or frequency using CMOS circuits is disclosed. In some implementations, the method includes providing a reference voltage using a resistive module at a positive input terminal of an operational amplifier, coupling gates of a pair of p-type metal oxide semiconductor (pMOS) transistors and a compensation capacitor to an output terminal of the operational amplifier to generate a first bias signal, and coupling a pair of n-type metal oxide semiconductor (nMOS) transistors to a negative terminal of the operational amplifier to generate a second bias signal at the negative terminal, wherein the pair of nMOS transistors is substantially the same as a pair of nMOS transistors in the CMOS delay circuit.

A noise detection circuit includes a first delay circuit which has a propagation delay of a first delay time when a signal propagates therethrough and a second delay circuit which has a propagation delay of a second delay time when the signal propagates therethrough, and outputs, based on a sum of the first delay time and the second delay time, a detection result indicating the magnitude of noise on power supply voltage applied to the first delay circuit and the second delay circuit. A control unit controls, based on the detection result, a frequency of a clock signal supplied to a circuit unit to which the power supply voltage is applied and the second delay time in such a manner as to exhibit an opposite behavior to a change in the first delay time induced by temperature.

A noise detection circuit includes a first delay circuit which has a propagation delay of a first delay time when a signal propagates therethrough and a second delay circuit which has a propagation delay of a second delay time when the signal propagates therethrough, and outputs, based on a sum of the first delay time and the second delay time, a detection result indicating the magnitude of noise on power supply voltage applied to the first delay circuit and the second delay circuit. A control unit controls, based on the detection result, a frequency of a clock signal supplied to a circuit unit to which the power supply voltage is applied and the second delay time in such a manner as to exhibit an opposite behavior to a change in the first delay time induced by temperature.

A temperature sensor circuit may include a ring oscillator being enabled according to an enable signal and outputting a square wave signal with a first frequency, a divider dividing the first frequency of the square wave signal from the ring oscillator to generate a pulse signal with a second frequency, a counter counting a time interval of the pulse signal outputted from the divider according to an external clock to generate a count signal, a latch temporarily storing a value of the counter signal according to the pulse signal and outputting a digital code, and a supply voltage monitor being enabled according to the pulse signal, comparing a reference voltage to one or more comparison voltages and generating a switching logic signal. The reference voltage is kept at a substantially constant level when a level of a supply voltage changes.

A delay adjustment circuit according to an embodiment includes: a plurality of delay adjustment units connected in series, each of the plurality of delay adjustment units including one or more first delay elements (102) connected in series that delay an input signal on the basis of a clock, and a first selector (120) that outputs one of the input signal and an output of the first delay element at a last stage among the one or more first delay elements; and an output unit (103, 104, 130a, 130b, 140) that outputs a clock according to an output of the first selector included in a delay adjustment unit at a last stage among the plurality of delay adjustment units, in which each of the plurality of delay adjustment units includes a different number of the first delay elements.

A master/slave configuration of a frequency locked Loop (FLL) decouples the process, target voltage, temperature (PVT) tracking goals of locking the loop from adapting the clock frequency in response to voltage droops in the supply. A master oscillator circuit receives a regulated supply voltage and supplies a master oscillator signal. A control circuit supplies a master frequency control signal to control a frequency of the master oscillator signal to a target frequency. A slave oscillator circuit is coupled to a regulated supply voltage and a droopy supply voltage and supplies a slave oscillator signal having a frequency responsive to a slave frequency control signal that is based on the master frequency control signal. The frequency of the second oscillator signal is further responsive to a voltage change of the droopy supply voltage.