A flip-flop includes a first master latch in a first row, a second master latch in a second row, a first slave latch in the first row, and a second slave latch in the second row. The first master latch and the second master latch are adjacently disposed in the second direction, and the first slave latch and the second slave latch are adjacently disposed in the second direction.

An integrated circuit (IC) device includes a master latch circuit having a first clock input and a data output, a slave latch circuit having a second clock input and a data input electrically coupled to the data output of the master latch circuit, and a clock circuit. The clock circuit is electrically coupled to the first clock input by a first electrical connection configured to have a first time delay between the clock circuit and the first clock input. The clock circuit is electrically coupled to the second clock input by a second electrical connection configured to have a second time delay between the clock circuit and the second clock input. The first time delay is longer than the second time delay.

To provide a miniaturized data holding circuit. First and second MOS transistors respectively transmit a data signal and an inverted data signal to inputs of first and second inverting gates that constitute a state holding circuit when a clock signal is at a first level. Fifth and sixth MOS transistors are respectively inserted in a feedback path from an output of the second inverting gate to the input of the first inverting gate and a feedback path from an output of the first inverting gate to the input of the second inverting gate, and respectively transmit the outputs of the second and first inverting gates when the clock signal is at a second signal level. Seventh and eighth MOS transistors are constituted in a channel of a conductive type different from the first MOS transistor and connected in parallel to the fifth and sixth MOS transistors, respectively, and transmit the output of the second inverting gate and the output of the first inverting gate on the basis of the inverted data signal and the data signal, respectively.

An integrated circuit including a first active region and a second active region extending in a first direction and spaced apart from each other in a second direction intersecting the first direction; a power rail and a ground rail extending in the first direction and spaced apart from the first and second active regions and each other in the second direction; source/drain contacts extending in the second direction on at least a portion of the first or second active region, gate structures extending in the second direction and on at least a portion of the first and second active regions, a power rail configured to supply power through source/drain contact vias, and a ground rail configured to supply a ground voltage through source/drain contact vias.

A flip-flop circuit includes a clock generator configured to generate first and second clock signals having different phases relative to each other, and a master-slave latch circuit including master and slave latches. The master latch includes a scan path configured to output a scan path signal in response to a scan enable signal and a scan input signal, and a data path configured to output a first latch signal in response to a data signal and the scan path signal. A feedback path is provided, which includes a tri-state inverter responsive to the first and second clock signals. The tri-state inverter has an input terminal connected to an output terminal of the data path and an output terminal connected to a node of the scan path.

Provided is a semiconductor device including a sequential circuit including a first transistor and a capacitor. The first transistor includes a semiconductor layer including indium, zinc, and oxygen to form a channel formation region. A node electrically connected to a source or a drain of the first transistor and a capacitor becomes a floating state when the first transistor turns off, so that a potential of the node can be maintained for a long period. A power-gating control circuit may be provided to control supply of power supply potential to the sequential circuit. The potential of the node still can be maintained while supply of the power supply potential is stopped.

A flip-flop circuit includes a first inverter configured to receive a first clock signal and output a second clock signal, a second inverter configured to receive the second clock signal and output a third clock signal, a master stage, and a slave stage including a first feedback inverter and a first transmission gate. The first feedback inverter includes a first transistor configured to receive the first clock signal and a second transistor configured to receive the second clock signal, and the first transmission gate includes first and second input terminals configured to receive the second and third clock signals.

Systems and methods for detecting an open condition in a master-slave configuration are described. In an example, a controller can be integrated in a slave device of a master-slave configuration. The controller can be configured to activate a current source to supply a current to a pin of the slave device. The controller can be further configured to compare a voltage measured at the pin of the slave device with a reference voltage. The controller can be further configured to, based on the comparison, determine a presence or an absence of an open condition associated with the pin of the slave device. The controller can be further configured to output a signal representing the determination of the presence or the absence of the open condition to a master device.

Various implementations described herein are directed to a device having multiple stages. The device may have a first stage that provides a data path for an input data signal. The first stage may receive the input data signal, receive feedback signals, and provide an intermediate data signal based on the input data signal and/or the feedback signals. The device may have a second stage that provides set/reset signals based on the intermediate data signal and/or a clock signal. The second stage may receive the intermediate data signal, receive the clock signal, and generate the set/reset signals based on the intermediate data signal and the clock signal. The second stage may also provide the set/reset signals as the feedback signals to the first stage.

A scan chain architecture with lowered power consumption comprises a multiplexer selecting between a functional input and a test input. The output of the multiplexer is coupled to a low threshold voltage latch and, in test mode, to a standard threshold voltage latch. The low threshold voltage latch and standard threshold voltage latch are configured to store data when a clock input falls, using a master latch functional clock M_F_CLK, master latch test clock M_T_CLK, slave latch functional clock S_F_CLK, and slave latch test clock S_T_CLK. The slave latch has lower power consumption than the master latch.