A multiplexer selects one of a first to a fourth data signal in response to a first to a fourth pulse. The first to fourth pulses respectively correspond to the first to fourth data signals and sequentially toggle. The multiplexer includes: (1) a NAND gate that receives the first data signal, a fourth complementary data signal that is a complementary signal of the fourth data signal, and the first pulse and outputs a first gate signal and (2) a NOR gate that receives the first data signal, the fourth complementary data signal, and a first complementary pulse that is complementary to the first pulse and outputs a second gate signal. The first data signal corresponds to a rising edge of the first pulse, and the fourth complementary data signal corresponds to a rising edge of the fourth pulse.

A multiplexer selects one of a first to a fourth data signal in response to a first to a fourth pulse. The first to fourth pulses respectively correspond to the first to fourth data signals and sequentially toggle. The multiplexer includes: (1) a NAND gate that receives the first data signal, a fourth complementary data signal that is a complementary signal of the fourth data signal, and the first pulse and outputs a first gate signal and (2) a NOR gate that receives the first data signal, the fourth complementary data signal, and a first complementary pulse that is complementary to the first pulse and outputs a second gate signal. The first data signal corresponds to a rising edge of the first pulse, and the fourth complementary data signal corresponds to a rising edge of the fourth pulse.

A tunnel field effect transistor includes a source region and a drain region, positioned on a substrate, a channel region positioned between the source region and the drain region and having a first length in a first direction, a gate electrode positioned on the channel region, and a gate insulating layer positioned between the channel region and the gate electrode, wherein the source region is doped with impurities of a first conductivity type and the drain region is doped with impurities of a second conductivity type that is different from the first conductivity type, and one of the source region and the drain region includes an extension region extending toward the other region, the extension region being positioned under the channel region to form a constant current independent of a gate voltage of the gate electrode.

Methods, systems and apparatus for producing quantum circuits with low T gate counts. In one aspect, a method for performing a temporary logical AND operation on two control qubits includes the actions of obtaining an ancilla qubit in an A-state; computing a logical-AND of the two control qubits and storing the computed logical-AND in the state of the ancilla qubit, comprising replacing the A-state of the ancilla qubit with the logical-AND of the two control qubits; maintaining the ancilla qubit storing the logical-AND of the two controls until a first condition is satisfied; and erasing the ancilla qubit when the first condition is satisfied.

Methods, systems and apparatus for producing quantum circuits with low T gate counts. In one aspect, a method for performing a temporary logical AND operation on two control qubits includes the actions of obtaining an ancilla qubit in an A-state; computing a logical-AND of the two control qubits and storing the computed logical-AND in the state of the ancilla qubit, comprising replacing the A-state of the ancilla qubit with the logical-AND of the two control qubits; maintaining the ancilla qubit storing the logical-AND of the two controls until a first condition is satisfied; and erasing the ancilla qubit when the first condition is satisfied.

A clock gating circuit includes a NOR logic gate, a transmission gate, a cross-coupled pair of transistors, and a first transistor. The NOR logic gate is coupled to a first node, and receives a first and a second enable signal, and outputs a first control signal. The transmission gate is coupled between the first and a second node, and receives the first control signal, an inverted clock input signal and a clock output signal. The cross-coupled pair of transistors is coupled between the second node and an output node, and receives at least a second control signal. The first transistor includes a first gate terminal configured to receive the inverted clock input signal, a first drain terminal coupled to the output node, and a first source terminal coupled to a reference voltage supply. The first transistor adjusts the clock output signal responsive to the inverted clock input signal.

A clock gating circuit includes a NOR logic gate, a transmission gate, a cross-coupled pair of transistors, and a first transistor. The NOR logic gate is coupled to a first node, and receives a first and a second enable signal, and outputs a first control signal. The transmission gate is coupled between the first and a second node, and receives the first control signal, an inverted clock input signal and a clock output signal. The cross-coupled pair of transistors is coupled between the second node and an output node, and receives at least a second control signal. The first transistor includes a first gate terminal configured to receive the inverted clock input signal, a first drain terminal coupled to the output node, and a first source terminal coupled to a reference voltage supply. The first transistor adjusts the clock output signal responsive to the inverted clock input signal.

A data control circuit includes a first latch circuit, a self-block circuit, a second latch circuit, a third latch circuit, a first data timing-labeled signal generating circuit, and a second data timing-labeled signal generating circuit. The first latch circuit is arranged to receive a data window signal. The self-block circuit is coupled to the first latch circuit, and is arranged to generate a protection signal. The second latch circuit is coupled to the self-block circuit, and is arranged to output a first data timing-labeled signal. The third latch circuit is coupled to the second latch circuit, and is arranged to generate a second data timing-labeled signal. The first data timing-labeled signal generating circuit is arranged to generate a third data timing-labeled signal. The second data timing-labeled signal generating circuit is arranged to generate a fourth data timing-labeled signal.

A data control circuit includes a first latch circuit, a self-block circuit, a second latch circuit, a third latch circuit, a first data timing-labeled signal generating circuit, and a second data timing-labeled signal generating circuit. The first latch circuit is arranged to receive a data window signal. The self-block circuit is coupled to the first latch circuit, and is arranged to generate a protection signal. The second latch circuit is coupled to the self-block circuit, and is arranged to output a first data timing-labeled signal. The third latch circuit is coupled to the second latch circuit, and is arranged to generate a second data timing-labeled signal. The first data timing-labeled signal generating circuit is arranged to generate a third data timing-labeled signal. The second data timing-labeled signal generating circuit is arranged to generate a fourth data timing-labeled signal.

A power supply circuit is configured to supply power to a display panel. The power supply circuit includes a receiver circuit and a transmitter circuit. The receiver circuit is configured to couple the display panel and output a hot plugging signal. The transmitter circuit is configured to receive the hot plugging signal and couple a power circuit. The transmitter circuit is further configured to communicate the receiver circuit to generate an enable signal. The hot plugging signal and the enable signal are configured to control whether a first voltage signal from the power circuit is transmitted to the receiver circuit and the display panel via the transmitter circuit.