Abstract: Provided herein are delay locked loops (DLLs) with calibration for external delay. In certain embodiments, a timing alignment system includes a DLL including a detector that generates a delay control signal based on comparing a reference clock signal to a feedback clock signal, and a controllable delay line configured to generate the feedback clock signal by delaying the reference clock signal based on the delay control signal. The timing alignment system further includes a delay compensation circuit that provides an adjustment to the controllable delay line to compensate for a delay of the feedback clock signal in reaching the detector.

Abstract: A time-of-flight (ToF) transmitter with self-stabilized optical output phase with minimal overhead is described, where the transmitter may either function as a slave in that the laser pulse phase and width can be controlled by the master ToF receiver, or it can function as a master where the laser control pulse is generated on the same chip or a companion chip. When the ToF transmitter functions as a slave and receives the laser pulse control signal, the techniques of this disclosure can transform the receive path and the pre-driver circuit into part of a delay locked loop (DLL).

Abstract: Edge combiners with symmetrical operation range at high speed are provided. In certain embodiments, an edge combiner (80) includes a circuit state element (71) having a first input controlled by a first timing signal (SI), and a pulse generator (72) that resets the circuit state element by controlling a second input (R) of the circuit state element based on a second timing signal (S2). The edge combiner further includes a first delay circuit (75), and an output logic gate (77) having a first input connected to a data output (Q) of the circuit state element through a first signal path that bypasses the first delay circuit (75), a second input (QD) connected to the data output through a second signal path that includes the first delay circuit, and an output (OUT) that provides an output signal indicating delay between an edge of the first timing signal and an edge of the second timing signal.

Abstract: Provided herein are delay locked loops (DLLs) with calibration for external delay. In certain embodiments, a timing alignment system includes a DLL including a detector that generates a delay control signal based on comparing a reference clock signal to a feedback clock signal, and a controllable delay line configured to generate the feedback clock signal by delaying the reference clock signal based on the delay control signal. The timing alignment system further includes a delay compensation circuit that provides an adjustment to the controllable delay line to compensate for a delay of the feedback clock signal in reaching the detector.

Abstract: Provided herein are gap detection and compensation schemes for timing alignment systems. In certain embodiments, a timing alignment system includes a detector that generates one or more loop control signals based on comparing a reference clock signal to a feedback clock signal, a loop filter having a loop voltage that is adjusted based on the one or more loop control signals, and a gap detection and compensation circuit that processes the one or more loop control signals to detect a gap in at least one of the reference clock signal or the feedback clock signal. In response to detecting the gap, the gap detection and compensation circuit modifies the one or more loop control signals to provide an adjustment to the loop voltage.

Abstract: Provided herein are gap detection and compensation schemes for timing alignment systems. In certain embodiments, a timing alignment system includes a detector that generates one or more loop control signals based on comparing a reference clock signal to a feedback clock signal, a loop filter having a loop voltage that is adjusted based on the one or more loop control signals, and a gap detection and compensation circuit that processes the one or more loop control signals to detect a gap in at least one of the reference clock signal or the feedback clock signal. In response to detecting the gap, the gap detection and compensation circuit modifies the one or more loop control signals to provide an adjustment to the loop voltage.

Abstract: A time-of-flight (ToF) transmitter with self-stabilized optical output phase with minimal overhead is described, where the transmitter may either function as a slave in that the laser pulse phase and width can be controlled by the master ToF receiver, or it can function as a master where the laser control pulse is generated on the same chip or a companion chip. When the ToF transmitter functions as a slave and receives the laser pulse control signal, the techniques of this disclosure can transform the receive path and the pre-driver circuit into part of a delay locked loop (DLL).