A phase interpolator with a DAC outputting a first and second value responsive to a control code. A first current mirror generates a first current proportional to the first value. A second current mirror generates a second current proportional to the second value. A first FET pair comprising a first and second FET such that the source terminals of the first FET and the second FET are electrically connected and connect to the first current mirror. A second FET pair comprising a third and fourth FET such that the source terminals of the third FET and the fourth FET are electrically connected and connect to the second current mirror. A first terminal outputs a phase adjusted clock signal as compared to the clock signal, from the first FET and the third FET. A second terminal outputs an inverted phase adjusted clock signal, from the second FET and the fourth FET.

In a delay circuit, first and second sets of transistors are connected in series between a supply voltage and a ground. The first and second sets of transistors both include a current source transistor, a cascode transistor, and a control transistor. The first set of transistors generates a current that charges a capacitor to generate a ramp signal with a positive slope. A first bias transistor may cause the ramp signal to be biased to ground upon activating the first set of transistors. The second set of transistors generates a current that discharges the capacitor to generate the ramp signal with a negative slope. A second bias transistor may cause the ramp signal to be biased to the supply voltage upon activating the second set of transistors. The delay circuit transitions the state of the output signal based on a voltage level of the ramp signal.

Certain aspects of the present disclosure generally relate to circuitry and techniques for digital-to-analog conversion. For example, certain aspects provide an apparatus for digital-to-analog conversion. The apparatus generally includes a mixing-mode digital-to-analog converter (DAC), a duty cycle adjustment circuit having an input coupled to an input clock node and having an output coupled to a clock input of the mixing-mode DAC, and a current comparison circuit having inputs coupled to outputs of the mixing-mode DAC and having an output coupled to a control input of the duty cycle adjustment circuit.

In a delay circuit, first and second sets of transistors are connected in series between a supply voltage and a ground. The first and second sets of transistors both include a current source transistor, a cascode transistor, and a control transistor. The first set of transistors generates a current that charges a capacitor to generate a ramp signal with a positive slope. A first bias transistor may cause the ramp signal to be biased to ground upon activating the first set of transistors. The second set of transistors generates a current that discharges the capacitor to generate the ramp signal with a negative slope. A second bias transistor may cause the ramp signal to be biased to the supply voltage upon activating the second set of transistors. The delay circuit transitions the state of the output signal based on a voltage level of the ramp signal.

In a delay circuit, first and second sets of transistors are connected in series between a supply voltage and a ground. The first and second sets of transistors both include a current source transistor, a cascode transistor, and a control transistor. The first set of transistors generates a current that charges a capacitor to generate a ramp signal with a positive slope. A first bias transistor may cause the ramp signal to be biased to ground upon activating the first set of transistors. The second set of transistors generates a current that discharges the capacitor to generate the ramp signal with a negative slope. A second bias transistor may cause the ramp signal to be biased to the supply voltage upon activating the second set of transistors. The delay circuit transitions the state of the output signal based on a voltage level of the ramp signal.

In a delay circuit, first and second sets of transistors are connected in series between a supply voltage and a ground. The first and second sets of transistors both include a current source transistor, a cascode transistor, and a control transistor. The first set of transistors generates a current that charges a capacitor to generate a ramp signal with a positive slope. A first bias transistor may cause the ramp signal to be biased to ground upon activating the first set of transistors. The second set of transistors generates a current that discharges the capacitor to generate the ramp signal with a negative slope. A second bias transistor may cause the ramp signal to be biased to the supply voltage upon activating the second set of transistors. The delay circuit transitions the state of the output signal based on a voltage level of the ramp signal.

A low-power-consumption high-speed zero-current switch includes a delay controller, a driving stage and a power transistor MN, wherein: an input of the delay controller is connected with an external clock CLK, an output of the delay controller is connected with an input of the driving stage, and an output of the driving stage is connected with a gate of the power transistor MN; the delay controller includes a gate signal generator, a sampling circuit and a current controller, and three of which form a negative feedback loop for stabilizing the turn-on voltage V.sub.ON and the turn-off voltage V.sub.D to 0, so that when the power transistor MN is turned on or off, the source-drain voltage thereof is 0. The present invention no longer uses a high-power-consumption high-speed comparator, but uses a low-power-consumption delay controller to generate turn-on and turn-off signals of the power transistor.

A PVT-independent fixed delay circuit includes a circuit structure that has a current generator and a multi-level inverter-based time delay unit. The inverter-based time delay unit has at least two NMOS transistors M5, M6, and at least two PMOS transistors M7, M8. The current generator has a circuit structure including at least two NMOS transistors M1, M2, at least two PMOS transistors M3, M4 and a resistor R.sub.S.

A delay circuit and an electronic system equipped with the delay circuit are provided. The delay circuit includes an input terminal, an output terminal, a bias current generator and a delay generator. The bias current generator is coupled between a first reference voltage and a second reference voltage, and is configured to generate a bias current. The delay generator is coupled between the first reference voltage and the second reference voltage, and is configured to generate a delay of the delay signal relative to the input signal according to the bias current. The bias current generator includes a current mirror, a current module and a transistor. The delay generator includes a first current mirror sub-circuit, a second current mirror sub-circuit, a transistor, a capacitor, a switch circuit and a Schmitt inverter, wherein the output terminal is coupled to the Schmitt inverter to output the delay signal.

A low-power-consumption high-speed zero-current switch includes a delay controller, a driving stage and a power transistor MN, wherein: an input of the delay controller is connected with an external clock CLK, an output of the delay controller is connected with an input of the driving stage, and an output of the driving stage is connected with a gate of the power transistor MN; the delay controller includes a gate signal generator, a sampling circuit and a current controller, and three of which form a negative feedback loop for stabilizing the turn-on voltage V.sub.ON and the turn-off voltage V.sub.D to 0, so that when the power transistor MN is turned on or off, the source-drain voltage thereof is 0. The present invention no longer uses a high-power-consumption high-speed comparator, but uses a low-power-consumption delay controller to generate turn-on and turn-off signals of the power transistor.