According to embodiments of the present invention, a circuit is provided. The circuit includes a first set of transistors configured to receive one or more input signals provided to the circuit, and a second set of transistors electrically coupled to each other, wherein the second set of transistors is configured to provide one or more output signals of the circuit, wherein the first set of transistors and the second set of transistors are electrically coupled to each other, and wherein, for each transistor of the first set of transistors and the second set of transistors, the transistor is configured to drive a load associated with the transistor and has an aspect ratio that is sized larger than an aspect ratio of a transistor that is optimized for driving the load.

A flip flop circuit includes a first master portion, a second master portion, at least one determining portion and a slave portion. The first master portion is configured to operate at a first mode and to receive a first input and generate first master outputs. The second master portion is configured to operate at a second mode and to receive a second input and generate second master outputs. The at least one determining portion is configured to receive at least one enable signal, and has determining inputs and determining outputs. The determining inputs are connected to the first master outputs and the second master outputs. The determining portion is configured to determine the determining outputs being the first master outputs or the second master outputs according to the at least one enable signal. The slave portion is configured to receive the determining outputs and generate an output signal.

A flip flop circuit includes a first master portion, a second master portion, at least one determining portion and a slave portion. The first master portion is configured to operate at a first mode and to receive a first input and generate first master outputs. The second master portion is configured to operate at a second mode and to receive a second input and generate second master outputs. The at least one determining portion is configured to receive at least one enable signal, and has determining inputs and determining outputs. The determining inputs are connected to the first master outputs and the second master outputs. The determining portion is configured to determine the determining outputs being the first master outputs or the second master outputs according to the at least one enable signal. The slave portion is configured to receive the determining outputs and generate an output signal.

As a scanning line drive circuit of a display device, a shift register having a configuration in which a plurality of unit circuits are connected to each other in multiple stages is used. The unit circuits each include: a plurality of control transistors; an internal node connected to a terminal of one of the plurality of control transistors; and a depletion mode initialization transistor having a first conduction terminal connected directly or through a resistor to the internal node, a second conduction terminal, and a control terminal. One of a power supply voltage and a ground voltage is applied to the second conduction terminal, and the other voltage is applied to the control terminal. The initialization transistor is turned on in a power-off state.

A system and method for efficiently retaining data in sequential elements during power down modes. In various embodiments, a master latch of a flip-flop circuit receives an always-on first power supply voltage, whereas, a slave latch and other surrounding circuitry receives a second power supply voltage capable of being powered down. During a power down mode, circuitry consumes less power while the master latch retains stored data. In some designs, the flip-flop circuit is a level shifting circuit, and the always-on first power supply voltage is less than the second power supply voltage. The master latch uses complex gates with a p-type transistor at the top of a stack of p-type transistors receiving the always-on power supply voltage level on its source terminal and the retained data value on its gate terminal. This top p-type transistor is capable of remaining disabled even when used in a level shifting manner.

In an embodiment, an electronic circuit includes: a supply management circuit for receiving an input supply voltage and providing a first supply voltage; and a main circuit configured to: when the input supply voltage becomes higher than a first threshold, cause the electronic circuit to transition into an initialization state in which an oscillator is enabled and configuration data is copied from an NVM to configuration registers, and then to transition into a standby state in which the oscillator is disabled and content of the configuration registers is preserved by the first supply voltage, and, upon reception of a wakeup event, cause the configuration data from the configuration registers to be applied to the first circuit, and cause the electronic circuit to transition into an active state in which the first oscillator is enabled and the first circuit is configured to operate based on the configuration data.

A level converting enable latch includes a level shifter circuit and a latch circuit. The level shifter circuit receives a first data input signal, and generates a first data output signal, wherein the first data input signal and the first data output signal have different voltage swings. The latch circuit sets a second data output signal in response to the first data output signal when a latch enable signal is set by a first logic value, and latches the second data output signal when the latch enable signal is set by a second logic value. The latch circuit includes a first control circuit. The first control circuit enables a latch feedback loop of the latch circuit when the latch enable signal is set by the second logic value, and disables the latch feedback loop of the latch circuit when the latch enable signal is set by the first logic value.

Systems, apparatuses, and methods for implementing a low-power, single-pin retention flip-flop with a balloon latch are described. A flip-flop is connected to a retention latch to store a value of the flip-flop during a reduced power state. A single retention pin is used to turn on the retention latch. During normal mode, the retention latch is pre-charged and a change in the value stored by the flip-flop does not cause the retention latch to toggle. This helps to reduce the power consumed by the circuit during normal mode (i.e., non-retention mode). When the retention signal becomes active, the retention latch gets triggered and the value stored by the flip-flop is written into the retention latch. Later, if the flip-flop is powered down and then powered back up while the circuit is in retention mode, the value in the retention latch gets written back into the flip-flop.

A master-slave D flip-flop is disclosed having gates configured to supply two second intermediate signals as a function of first intermediate signals and a clock signal, and a slave circuit connected to a transfer circuit to form at least one output signal of the flip-flop from the second intermediate signals. The slave circuit is configured, when the second intermediate signals have, after a preceding pair of states, a predetermined pair of states, to maintain the at least one output signal as given by the preceding pair of states. The transfer circuit has a control input and is configured to generate the second intermediate signals to have the predetermined pair of states in response to a predetermined control signal state at the control input.

Systems and methods for propagating control signals in memories are described. One implementation includes a plurality of logic gates and a latch coupled between a control signal input and a delay line. The latch may store the value of the control signal before the control signal floats, thereby reducing the risk of incorrect signal propagation. Furthermore, the implementation may also include a clamp signal that isolates the plurality of logic gates before the control signal floats and continues to isolate the plurality of logic gates until after the control signal returns to either a digital one or a digital zero. The clamp signal may reduce leakage by disconnecting transistors within the logic gates from their power supply.