In certain aspects, an apparatus includes a first gating circuit having an input and an output, wherein the input of the first gating circuit is configured to receive a first clock signal. The apparatus also includes a delay circuit having an input and an output, wherein the input of the delay circuit is coupled to the output of the first gating circuit. The apparatus further includes a control circuit configured to receive an enable signal, detect a logic state at the output of the delay circuit, and cause the first gating circuit to pass or gate the first clock signal based on the enable signal and the detected logic state at the output of the delay circuit.

One embodiment describes a reciprocal quantum logic (RQL) receiver system. The RQL system is configured to convert a serial input data stream provided from a serial data transmitter into an RQL data stream. The RQL receiver system includes a sampling controller configured to oversample the serial input data stream via a plurality of samples over each sampling window of an RQL clock signal to determine a transition sample corresponding to a transition in a digital value of the serial input data stream in a given one sampling window of the RQL clock signal. The RQL receiver system can be further configured to capture the digital value of the serial input data stream via a capture sample that is a predetermined number of samples subsequent to the transition sample in each sampling window of the RQL clock signal.

Apparatuses and methods for partial bit de-emphasis are provided. An example apparatus includes an output driver and control circuit. The output driver includes a pull-up circuit including one or more pull-up legs, and a pull-down circuit including one or more pull-down legs. The control circuit may be coupled to the output driver and configured to receive an input signal having a first logical value and a second logical value, and in response to determining the logical transition has occurred from the second logic value to the first logic value, cause the pull-up circuit and pull-down circuit respectively to enter a first state for a duration of a first portion of a bit period and to enter a second state for a duration of a second portion of the bit period preceding the first portion.

A system-on-chip (SOC) includes a compensation circuit that compensates for PVT variations of the SoC and an external memory connected to the SOC. The compensation circuit includes first through third delay calculators, first through third delay circuits, first through third latches, first and second comparators, and a delay control circuit. The delay calculators generate first through third delay count data. The delay circuits use three delay counts to generate first through third clock signals. The latches receive data stored in the external memory, and output start-point, mid-point, and end-point data, respectively. The first and second comparators generate increment or decrement signals based on the start-point, mid-point and end-point data comparisons. The delay control circuit generates modified first delay count data, which along with the first through third delay count data, compensate for the PVT variations of the SoC and the external memory.

A semiconductor device may include: a first circuit suitable or generating a limit strobe signal by limiting a toggling period of a strobe signal depending on a change of an input code signal; and a second circuit suitable for synchronizing the input code signal based on the limit strobe signal and outputting a synchronized input code signal as an output code signal.

An internal voltage generation circuit includes a comparison circuit, a driving signal generation circuit and a driving circuit. The comparison circuit generates a comparison signal from an internal voltage in response to a reference voltage. The driving signal generation circuit generates a pull-up driving signal and a pull-down driving signal having different duty ratios in response to the comparison signal. The driving circuit drives the internal voltage in response to the pull-up driving signal and the pull-down driving signal.

A scannable data synchronizer including an input circuit, first and second pass gates, first and second inverters, and a gate controller. The input circuit drives the data nodes to opposite logic states in response to an asynchronous input data signal in a normal mode and in response to scan data in a scan test mode. Each pass gate is coupled between one of the data nodes and a corresponding one of the capture nodes, and each has at least one control terminal. The inverters are cross-coupled between the second capture nodes. The gate controller can keep the pass gates at least partially open during a metastable condition of the capture nodes, and can close the pass gates when both capture nodes stabilize to opposite logic states. In the scan test mode, the scan data is used to test the latch or register functions of the scannable data synchronizer.

An interlock circuit utilizes a single combinatorial pseudo-dynamic logic gate to take inputs from two voltage domains at the same time without requiring either input to be level shifted. The interlock design allows hold timing to be met across a large voltage range of both supplies in a dual-voltage supply environment while not significantly hurting setup time by having much lower latency than the latency of a level shifter.

An interlock circuit utilizes a single combinatorial pseudo-dynamic logic gate to take inputs from two voltage domains at the same time without requiring either input to be level shifted. The interlock design allows hold timing to be met across a large voltage range of both supplies in a dual-voltage supply environment while not significantly hurting setup time by having much lower latency than the latency of a level shifter.

Apparatuses and methods for partial bit de-emphasis are provided. An example apparatus includes an output driver and control circuit. The output driver includes a pull-up circuit including one or more pull-up legs, and a pull-down circuit including one or more pull-down legs. The control circuit may be coupled to the output driver and configured to receive an input signal having a first logical value and a second logical value, and in response to determining the logical transition has occurred from the second logic value to the first logic value, cause the pull-up circuit and pull-down circuit respectively to enter a first state for a duration of a first portion of a bit period and to enter a second state for a duration of a second portion of the bit period proceeding the first portion.