A delay circuit includes precharge and discharge transistors configured to receive an input signal. The delay circuit also includes a resistor coupled to the precharge transistor having a negative temperature coefficient to thereby form a node. A capacitive device and an inverter are coupled to the node. The inverter produces an output signal. Responsive to the input signal having a first polarity, the precharge transistor is configured to be turned on and the discharge transistor is configured to be turned off to thereby cause current to flow through the precharge transistor to the capacitive device to thereby charge the capacitive device. Responsive to the input signal having a second polarity, the precharge and discharge transistors are configured to change state to thereby cause charge from the capacitive device to discharge through the resistor and through the discharge transistor. The voltage on the node decays to a level which eventually causes the inverter's output to change state.

Disclosed herein is a programmable delay circuit for providing an adjustable delay for a signal transmitted from an input node to an output node. The adjustable delay circuit includes an input node; an output node; and a pair of inverter circuits coupled in series between the input node and the output node, wherein the pair of inverter circuits is configured to provide an adjustable delay for a signal transmitted from the input node to the output node. At least one inverter circuit of the pair of inverter circuits includes a state-programmable memory element that allows the pair of inverter circuits to be configurable between a first delay mode or a second delay mode.

A delay circuit includes the following: an input module, configured to receive a target input signal and output the target input signal to a first node, the target input signal being a rising edge signal or a falling edge signal of a pulse signal; an output module, configured to output a target output signal, the target output signal being a delayed signal of the target input signal; and a delay control module, connected to the input module through the first node, and connected to the output module through a second node. The delay control module includes at least one delay capacitor unit, and the delay control module is configured to control a connection between the at least one delay capacitor unit and the first node according to a rising edge delay duration or a falling edge delay duration.

In certain aspects, a duty-cycle monitor includes a first oscillator, and a flop having a signal input, a clock input, and an output, wherein the signal input is coupled to an input of the duty-cycle monitor, and the clock input is coupled to the first oscillator. The duty-cycle monitor also includes a first counter having a count input, an enable input, and a count output, wherein the count input of the first counter is coupled to the first oscillator, and the enable input of the first counter is coupled to the output of the flop. The duty-cycle monitor also includes a second counter having a count input, an enable input, and a count output, wherein the count input of the second counter is coupled to the first oscillator, and the enable input of the second counter is coupled to the output of the flop.

A clock driver circuit for low powered clock driving may include: a multiple phase divider; a buffer supplying at least one of multiple phases to the multiple phase divider at a center frequency that is an integer multiple of an input frequency; and wherein the multiple phase divider and the buffer share a same current from a supply rail.

A system includes a first park circuit having a signal input, an output, and a control input. The system also includes a first signal path having an input and an output, wherein the input of the first signal path is coupled to the output of the first park circuit. The system also includes a second park circuit having a signal input, an output, and a control input, wherein the signal input of the second park circuit is coupled to the output of the first signal path. The system further includes a second signal path having an input and an output, wherein the input of the second signal path is coupled to the output of the second park circuit.

A clock driver circuit for low powered clock driving may include: a multiple phase divider; a buffer supplying at least one of multiple phases to the multiple phase divider at a center frequency that is an integer multiple of an input frequency; and wherein the multiple phase divider and the buffer share a same current from a supply rail.

A delay line includes first to n-th delay cells and a dummy delay cell, ‘n’ being an integer greater than or equal to 3. The first to n-th delay cells sequentially delay an input signal to respectively generate first to n-th output signals. The dummy delay cell delays the n-th output signal based on a delay control voltage to generate a dummy output signal. A delay amount of each of the first to (n−1)-th delay cells is adjusted on a basis of the delay control voltage and the output signal of the delay cell of a next stage of the corresponding delay cell, and a delay amount of the n-th delay cell is adjusted on a basis of the delay control voltage and the dummy output signal.

A clock driver circuit for low powered clock driving may include: a multiple phase divider; a buffer supplying at least one of multiple phases to the multiple phase divider at a center frequency that is an integer multiple of an input frequency; and wherein the multiple phase divider and the buffer share a same current from a supply rail.

A die-to-die data transmitter is disclosed with a pull-up one-shot circuit and a pull-down one-shot circuit, each forming a delay circuit that determines a variable preemphasis period.