A clock recovery circuit includes a first pulse circuit, a second pulse circuit, a state change circuit connected to the first pulse circuit and the second pulse circuit and a first delay circuit connected to the state change circuit and each of the first pulse circuit and the second pulse circuit. The first pulse circuit receives data inputs to generate a first pulse signal. The second pulse circuit receives the data inputs to generate a second pulse signal. The state change circuit receives the first pulse signal and the second pulse signal and generate a first clock signal for a first transition of one of the data inputs in a first unit interval (UI). The first delay circuit receives the generated first clock signal and mask other transitions of the data inputs in the first UI.

A disclosed pre-driver circuit includes multiple signal generation stages configured to receive different bias voltages from local switching bias circuit(s). In some embodiment, pre-driver circuit has multiple switching bias circuits, each with a bias voltage node connected to a corresponding stage. In other embodiments, the pre-driver circuit has a single switching bias circuit with multiple bias voltage nodes and a multi-input/multi-output multiplexor with inputs connected to the bias voltage nodes and outputs connected to the stages. The switching bias circuit(s) and a primary inverter in each stage all receive the same input signal. When this input signal transitions, the switching bias circuit(s) supply bias voltages to the stages and the primary inverters turn on in sequence and slowly, thereby ensuring that pre-driver signals generated by the different stages transition in sequence and at a relatively slow rate. Once the last pre-driver signal transitions, the switching bias circuit(s) turn off.

The invention relates to a floating state detection circuit of a node, comprising a first conductivity type MOS transistor (M1) connected between the node (N) and a first power supply line (Vss); and a second MOS transistor (M2) of conductivity type complementary to the first conductivity type, controlled by the node (N) and connected between the gate of the first transistor (M1) and a second supply line (Vdd). In addition, a third MOS transistor (M3) of the first conductivity type connected between the gate of the first transistor (M1) and the first supply line (Vss) may be controlled by the node (N).

A slew-limited output driver circuit facilitates finding a circuitry that allows a flexible setting of the slew-rate of an integrated circuit, with only a small footprint and latency, and which allows realizing different driver modes without additional components integrated protection against ESD. A short circuit will be solved by a slew-limited output driver circuit comprising a switchable current mirror providing an output current equal to an input current, wherein the current mirror is controlled by an additional switch, which is switched in response to control signals and/or an output current level of the output driver circuit, wherein adjustable operating modes of the slew-limited output driver circuit are realized by the control signals.

Inter-integrated circuit input circuitry includes a pull-up current circuit and an input circuit. The input circuit includes an output inverter, an input inverter, and a pull-up circuit. The pull-up circuit is coupled to an input of the input inverter, and includes a pull-up transistor and a cascode transistor. The pull-up transistor is coupled to the input of the input inverter. The cascode transistor is coupled to the pull-up current circuit and the pull-up transistor, and configured to isolate the pull-up transistor from capacitance of a conductor coupled to the pull-up current circuit and the input circuit.

An off chip driving system includes a decision circuit, multiple first and second adjustable-enhancement circuits, and multiple first and second drivers. The decision circuit outputs a first and a second decision signal according to a clock and an input data. Each first adjustable-enhancement circuit generates one of first control signals in response to the first and the second decision signal and one of first optional signals. Each second adjustable-enhancement circuit generates one of second control signals in response to the first and the second decision signal and one of second optional signals. Each first driver is coupled to the corresponding first adjustable-enhancement circuit and configured to be enabled in response to the corresponding first control signal. Each second driver is coupled to the corresponding second adjustable-enhancement circuit and configured to be enabled in response to the corresponding second control signal.

Embodiments of the present disclosure described herein relate to a computing in memory electronic device that supports current based analog operations and time based analog-to-digital conversion.

A receiver includes an input node coupled to receive an analog signal, a first switch coupled between the input node and a first node, a second switch coupled between the input node and a second node, a first resistive element coupled between the first node and a reference node, a second resistive element coupled between the second node and the reference node, a first capacitive element coupled to the first node, and a second capacitive element coupled to the second node. The receiver also includes a comparator having a first input coupled to the input node to receive the analog signal, and a second input coupled to the reference node to receive a reference voltage, wherein an output of the comparator controls the first and second switches.

An apparatus includes: a first inverter configured to receive a first clock signal and output a second clock signal, wherein an input pin, an output pin, a power pin, and a ground pin of the first inverter connect to the first clock signal, the second clock signal, a first source node, and a second source node, respectively; a second inverter configured to receive the second clock signal and output a third clock signal, wherein an input pin, an output pin, a power pin, and a ground pin of the second inverter connect to the second clock signal, the third clock signal, the first source node, and the second source node, respectively; a first resistor connected to a first DC (direct-current) voltage to the first source node; and a second resistor connected to a second DC voltage to the second source node.

A voltage level translator translates signals between first and second voltage domains. An output buffer for a channel thereof includes a first plurality of PFETs and a first plurality of NFETS that are coupled to provide staggering of the output signal. A supply difference sensing circuit can disable staggering when an input voltage supply is greater than or equal to a VCCI trigger for the output voltage supply.