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.

A programmable delay device that provides delays of more than 100 ns over a broad bandwidth is disclosed. The device includes an input stage that employs M sampling switched capacitor elements such that each sampling switched capacitor element samples at a rate of only 1/M of the fundamental sampling rate. The device includes a programmable delay stage with M programmable switched capacitor banks, each programmable switched capacitor bank having N delay switched capacitor storage elements. Thus, the programmable delay stage includes a total of M×N delay switched capacitor storage elements, thereby reducing the sampling rate by a factor of M×N. This reduced sampling rate permits much smaller sampling switches, resulting in reduced leakage current and enabling far longer programmable delay times. Lastly, the device includes an output reconstruction stage that reconstructs a delayed version of the input RF signal by combining signals from the programmable delay stage.

A transformer-less DFM device comprising: an input receiving signals that are an integer multiple of an input signal; an edge detector that provides a quantized or a state output comparing an the input signal to a feedback signal; a statemachine that has counters and decimation circuits to provide a digitized output to a DAC that tunes delays between the input/output signals; a DLL for generating delay signals from the input signal that form an input to an edge combiner wherein the edge combiner takes different phases from the DLL to generate a multiplied output signal; a first DAC that takes the signal from the statemachine and provide a control to a supply circuit of the DLL to adjust a delay through a supply voltage; a second DAC that takes a signal from the statemachine and provides control to a backgate circuit of the DLL to adjust the delay.

A voltage-controlled delay line including a clipper configured to produce a clipped input voltage from an input voltage, an oscillator configured to produce a strobe pulse train that is initiated by the clipped input voltage, and a divider module configured to divide the strobe pulse train and produce an output voltage from the divided strobe pulse train.

An analog delay line includes a clock generator, an analog sampling circuit, a bank of analog memory cells, a memory controller, an analog readout circuit, and an analog multiplexer. The clock generator is configured to output plural reception clock signals of different frequencies and plural transmission clock signals of different frequencies, the transmission clock signals offset in accumulated phase relative to the reception clock signals. The analog sampling circuit is controlled by at least one of the reception clock signals, and is configured to output a sequence of sampled voltages of an analog input signal. The memory controller is configured to control a write operation at a write frequency of at least one of the reception clock signals and a read operation at a read frequency of at least one of the transmission clock signals. The write operation is for sequentially storing the sampled voltages received from the analog sampling circuit in the bank of analog memory cells, and the read operation is for sequentially reading the sampled voltages from the bank of analog memory cells. The analog readout circuit is configured to buffer the sampled voltages read from the bank of analog memory cells. The analog multiplexer is controlled by at least one of the transmission clock signals, and is configured to multiplex the sampled voltages buffered by the readout circuit to generate an analog output signal. A sampling rate of the analog input signal is within a factor of 2 of a sampling rate of the analog output signal.

A switched delay section for an integrated circuit device is disclosed. The switched delay section includes a segmented inductor loop comprising a plurality of segments separated by nodes. A plurality of capacitors are coupled between the segmented inductor loop to provide a plurality of delay sections. An image loop is in electrical communication with the segmented inductor loop. The image loop includes a switch configured to place the plurality of capacitors in one of a high capacitance or a low capacitance state to provide a variable delay value.

A processor includes a transmitter to transmit, to a receiver, a differential pair of signals including a positive signal transmitted across a positive conductor and a negative signal transmitted across a negative conductor. A first programmable analog delay circuit is coupled to the positive conductor to provide a first delay to the positive signal and a second programmable analog delay circuit is coupled to the negative conductor to provide a second delay to the negative signal. A controller receives data based on a bit error rate (BER) of the differential pair of signals as measured by a bit error checker of the receiver. In response to determining the BER is less than a threshold BER, the controller stores a first delay value to program the first delay and store a second delay value to program the second delay.

Methods and apparatus for time-to-digital conversion. An example apparatus includes a first input; a second input; a delay line coupled to the first input and comprising a plurality of first delay elements coupled in series, each of the plurality of first delay elements having a first delay time; a second delay element having an input coupled to the second input and having the first delay time; a third delay element having an input coupled to the second input and having a second delay time, the second delay time being smaller than the first delay time; a first set of arbiters having first inputs coupled to the delay line and having second inputs coupled to an output of the second delay element; and a second set of arbiters having first inputs coupled to the delay line and having second inputs coupled to an output of the third delay element.

A switched delay section for an integrated circuit device is disclosed. The switched delay section includes a segmented inductor loop comprising a plurality of segments separated by nodes. A plurality of capacitors are coupled between the segmented inductor loop to provide a plurality of delay sections. An image loop is in electrical communication with the segmented inductor loop. The image loop includes a switch configured to place the plurality of capacitors in one of a high capacitance or a low capacitance state to provide a variable delay value.

A clock recovery circuit may include a first circuit to produce an output signal that is a logical combination of an edge detection signal and a clock signal. At least some transitions in the edge detection signal may correspond to transitions in a set of data signals. The clock recovery circuit may also include a second circuit to average the output signal to produce a voltage, and a third circuit to add a variable delay to the clock signal based on the voltage.