A high-speed 4:1 multiplexer according to an embodiment comprises an input circuit unit including a first circuit that receives a first data as an input signal, and outputs a first output data as an output signal, a second circuit that receives a second data as an input signal, and outputs a second output data as an output signal, a third circuit that receives a third data as an input signal, and outputs a third output data as an output signal, and a fourth circuit that receives a fourth data as an input signal, and outputs a fourth output data as an output signal, a first stage for dividing the output data of the input circuit unit by two and receiving as an input signal, and outputting a first intermediate data and a second intermediate data as an output signal and a second stage of receiving the first intermediate data and the second intermediate data as an input signal and outputting a final data as an output signal.

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.

An integrated circuit includes a delay circuit and first and second interface circuits. The delay circuit delays a first timing signal by an internal delay to generate an internal timing signal. The first interface circuit communicates data to an external device in response to the internal timing signal. The second interface circuit transmits an external timing signal for capturing the data in the external device. An external delay is added to the external timing signal in the external device to generate a delayed external timing signal. The delay circuit sets the internal delay based on a comparison between the delayed external timing signal and a calibration signal transmitted by the first interface circuit.

An integrated circuit includes a delay circuit and first and second interface circuits. The delay circuit delays a first timing signal by an internal delay to generate an internal timing signal. The first interface circuit communicates data to an external device in response to the internal timing signal. The second interface circuit transmits an external timing signal for capturing the data in the external device. An external delay is added to the external timing signal in the external device to generate a delayed external timing signal. The delay circuit sets the internal delay based on a comparison between the delayed external timing signal and a calibration signal transmitted by the first interface circuit.

A digital control ring oscillator (DCO) generally comprises a first delay element and at least one second delay element that is coupled to the first delay element, wherein each of the first and second delay elements are disposed laterally with respect to one another in a first direction and include at least one cell. The cell includes a plurality of transistors arranged in at least one stack.

The present description concerns a comparator (1) of a first voltage (V+) and of a second voltage (V−), comprising first (100) and second (102) branches each comprising a same succession of alternated first (106) and second (108) gates in series between a node (104) and an output (1002; 1022) of the branch (100; 102), wherein: each branch starts with a first gate (106), each gate (106; 108) has a second node (114) receiving a bias voltage, the second node (114) of each first gate (106) of the first branch (100) and of each second gate (108) of the second branch (102) receives the first voltage (V+), the second node of the other gates receiving the second voltage (V−), and an order of arrival of the edges on the outputs (1002; 1022) of the branches determines a result of a comparison.

A duty cycle correction circuit includes a first duty cycle detecting circuit configured to detect a duty cycle of a clock signal with a first resolution; a reference clock generating circuit configured to generate a reference clock signal by adjusting a phase of the clock signal; a second duty cycle detecting circuit configured to detect a duty cycle of the clock signal with a second resolution according to the reference clock signal and the clock signal, the second resolution being finer than the first resolution; a first duty cycle adjusting circuit configured to adjust the duty cycle of the clock signal according to one or more first control signals output from the first duty cycle detecting circuit; and a second duty cycle adjusting circuit configured to adjust the duty cycle of the clock signal according to one or more second control signals output from the second duty cycle detecting circuit.

A duty cycle correction circuit includes a first duty cycle detecting circuit configured to detect a duty cycle of a clock signal with a first resolution; a reference clock generating circuit configured to generate a reference clock signal by adjusting a phase of the clock signal; a second duty cycle detecting circuit configured to detect a duty cycle of the clock signal with a second resolution according to the reference clock signal and the clock signal, the second resolution being finer than the first resolution; a first duty cycle adjusting circuit configured to adjust the duty cycle of the clock signal according to one or more first control signals output from the first duty cycle detecting circuit; and a second duty cycle adjusting circuit configured to adjust the duty cycle of the clock signal according to one or more second control signals output from the second duty cycle detecting circuit.

Devices and methods for implementing an RF integrated circuit device operatively configured to provide the function of RF power splitter with programmable output phase shift are described. Configurable and adjustable phase shift units for use in such IC device are also described.

Devices and methods for implementing an RF integrated circuit device operatively configured to provide the function of RF power splitter with programmable output phase shift are described. Configurable and adjustable phase shift units for use in such IC device are also described.