Abstract: Methods and apparatuses for optimizing switching delay in integrated circuits are described. Combinational logic gates are modified with precharge circuitry and instantiated in order to reduce switching transitions of circuit elements in a signal path.

Abstract: A circuit includes a first transistor stack that receives an input signal, a voltage reference, a reference potential, a clock signal and an inverted clock signal, and generates an output signal that is an inverse of the input signal. A first inverter receives the output signal from the first transistor stack. A second transistor stack receives the voltage reference, the reference potential, the clock signal and the inverted clock signal, and generates an output signal that is an inverse of an output signal from the first inverter. A pass control circuit includes first and second transistors. The first terminals of the first and second transistors are coupled together and receive the output signal of the second transistor stack, control terminals of the first and second transistors receive the clock signal and the inverted clock signal, respectively, and second terminals of the first and second transistors are coupled together and output the output signal of the second transistor stack.

Abstract: A semiconductor integrated circuit device has a combinational logic circuit including one or plural logic cells connected in series. At least one of the logic cells includes a standard cell which includes a MIS transistor, an input terminal to which an output signal from a previous stage is inputted as an input signal, and an output terminal. A first conductivity-type first MIS transistor which is provided between the output terminal of the standard cell and a first power supply voltage, the first MIS transistor including a control terminal to which a circuit control signal is inputted, and the first MIS transistor supplying the first power supply voltage to the output terminal of the standard cell based on the circuit control signal in order to bring the standard cell into an operation-stopped state. A second conductivity-type second MIS transistor cuts off a leakage current of the MIS transistor in the standard cell.

Abstract: A circuit includes an operational PMOS transistor of a logic gate driver. A control circuit is configured to turn off the operational PMOS transistor during a standby mode. The circuit also includes a sacrificial PMOS transistor coupled to an output node. The operational PMOS transistor is coupled to the output node. The sacrificial PMOS transistor is configured to keep the output node at a logical 1 during the standby mode.

Abstract: In a dynamic flip-flop circuit with a data selection function, for example, when data having an H value has been selected using a selection signal S0, a first node N1 is L and a second node N2 of a second dynamic circuit 1B is H, so that an output signal Q has an H level. In this case, when none of a plurality of pieces of data D0 to D2 is selected using selection signals S0 to S2, the first node N1 is H, so that the electric charge of the second node N2 is discharged and the output signal Q erroneously has an L level. However, in this case, an output node N3 is H and a fourth node N4 is L, so that an n-type transistor Tr6 of the second dynamic circuit 1B is turned OFF, thereby preventing the second node N2 from being discharged. Therefore, a normal operation is performed while securing a satisfactorily high-speed operation even when none of the pieces of data is selected.

Abstract: A circuit having an active clock shielding structure includes a logic circuit that receives a clock signal and performs a logic operation based on the clock signal, a power gating circuit that switches a mode of the logic circuit between an active mode and an sleep mode based on a power gating signal, a clock signal transmission line that transmits the clock signal to the logic circuit, and at least one power gating signal transmission line that transmits the power gating signal to the power gating circuit and functions as a shielding line pair with the clock signal transmission line.

Abstract: Multi-mode circuit (the circuit) and a method for preventing degradation in the circuit. The circuit includes a first transistor that enables functioning of the circuit in a first mode. The first transistor is responsive to a first signal to become inactive when the circuit enters into a second mode, thereby preventing degradation of the first transistor when the circuit enters into the second mode. A second transistor is coupled to the first transistor. The second transistor is responsive to a second signal to generate a third signal. A third transistor is coupled to the second transistor. The third transistor is responsive to the third signal to become inactive when the circuit enters into the second mode, thereby preventing degradation of the third transistor when the circuit enters into the second mode.

Abstract: A clockless return to state domino logic gate is disclosed responsive to multiple input nodes including at least one return to state node. A domino circuit presets a preset node to a second state. The domino circuit switches to a latch state and switches an output node when the preset node is pulled to a first state, and resets back to the preset state and switches the output node back to its default state when a reset node is pulled to the second state. An evaluation circuit pulls the preset node to the second state when the input nodes are in an evaluation state. An enable circuit enables a reset condition when the domino circuit is in its latch state. A reset circuit pulls the reset node to the first state after an evaluation event when the input nodes are no longer in the evaluation state.

Abstract: A fast dynamic register circuit including first and second precharge circuits, a keeper circuit and an output circuit. The first and second precharge circuits each precharge a corresponding one of a pair of precharge nodes and cooperate to minimize setup and hold times. If an input data node is low when the clock goes high, the first precharge node remains high causing the second precharge node to be discharged. Otherwise if the input node is high, the first precharge node is discharged and the second remains charged. Once either precharge node is discharged, the output state of the register remains fixed until the next rising clock edge independent of changes of the input data node. The fast dynamic register may be implemented with multiple inputs to perform common logic operations, such as OR, NOR, AND and NAND logic operations.

Abstract: A clock buffer for a clock network that reduces leakage current and lowers power consumption. The clock buffer includes a first CMOS transistor, a second CMOS transistor, and a leakage current prevention circuit connected to the first and second CMOS transistors. The leakage current prevention circuit includes a first PMOS transistor, which is connected between the source of a PMOS transistor of the first CMOS transistor and a power supply line, and a second PMOS transistor, which is connected between the source of a PMOS transistor of the second CMOS transistor and the power supply line. The first and second PMOS transistors are deactivated in response to an enable signal generated when a circuit block does not require the clock signal. The first and the second PMOS transistors have predefined widths and lengths such that the addition of these transistors in series with the CMOS transistors does not increase the propagation delay of the clock buffer circuit.

Abstract: A logic circuit includes a control circuit including a first logic gate to receive a selection signal and a first input signal and to output a pulse control signal and a second logic gate to receive the pulse control signal, a clock signal, and a delayed clock signal and to output a pulse signal, and a multiplexing logic circuit to receive the selection signal and the pulse signal from the control circuit, to receive at least one second, static input signal, and to output a signal corresponding to one of the first input signal and the second, static input signal based on the state of the selection signal.

Abstract: A circuit including is disclosed. The circuit includes a precharge circuit configured to pull a dynamic node toward a voltage present on the voltage supply node during a precharge phase, and an evaluation circuit configured to, during an evaluation phase, pull the dynamic node toward a ground voltage responsive to a first input condition and configured to inhibit pulling of the dynamic node down responsive to a second input condition. A pull-up circuit coupled between the first dynamic node and the voltage supply node includes first and second pull-up transistors. The first pull-up transistor is configured to activate responsive to the precharge phase. The second pull-up transistor is configured to activate at a delay time subsequent to entry of the evaluation phase. When the first and second pull-up transistors are active, a pull-up path is provided between the dynamic node and the voltage supply node.

Abstract: The domino logic of the general inventive concept receives a feedback signal and an input signal and outputs any one of the feedback signal and the input signal as an output signal in response to an enable signal and a clock signal. The feedback signal is an output signal of a previous cycle of a clock signal. When an enable signal is a first level, the domino logic maintains an output signal of a previous cycle instead of an input signal. According to the present general inventive concept, the domino logic having a data hold function can be embodied.

Abstract: A dynamic logic circuit includes a first region including a plurality of PMOS transistors and a second region, adjacent to the first region, including a plurality of NMOS transistors connected with at least one of the plurality of PMOS transistors. Channel sizes of the plurality of NMOS transistors are greater than channel sizes of the plurality of PMOS transistors.

Abstract: A flip-flop circuit with an internal level shifter includes an input stage, a clock input stage, an output stage and a level shifting stage. The output stage generates an output signal based on an input signal received by the input stage and a clock signal received by the clock input stage. The level shifting stage shifts-up the voltage level of the output signal.

Abstract: A clockless return to state domino logic gate is disclosed responsive to multiple return to state input nodes. A domino circuit has a preset state in which it presets a preset node to a second state. The domino circuit switches to a latch state and switches an output node when the preset node is pulled to a first state. The domino circuit resets back to the preset state and switches the output node back to its default state when a reset node is pulled to the second state. An evaluation circuit pulls the preset node to the second state when the input nodes are in an evaluation state. An enable circuit enables a reset condition when the domino circuit is in its latch state. A reset circuit pulls the reset node to the first state after an evaluation event when the input nodes are no longer in the evaluation state.

Abstract: To include a first X decoder constituted by a transistor whose off-leakage current has a first temperature characteristic, a pre-decoder circuit and a peripheral circuit constituted by a transistor whose off-leakage current has a second temperature characteristic, a power supply control circuit that inactivates the X decoder when a temperature exceeds a first threshold during a standby state, and a power supply control circuit that inactivates the pre-decoder and the peripheral circuit when a temperature exceeds a second threshold during the standby state. According to the present invention, whether power supply control is performed on a plurality of circuit blocks is determined based on different temperatures, therefore optimum power supply control can be performed on each of circuit blocks.

Abstract: In a logic circuit where clock gating is performed, the standby power is reduced or malfunction is suppressed. The logic circuit includes a transistor which is in an off state where a potential difference exists between a source terminal and a drain terminal over a period during which a clock signal is not supplied. A channel formation region of the transistor is formed using an oxide semiconductor in which the hydrogen concentration is reduced. Specifically, the hydrogen concentration of the oxide semiconductor is 5x1019 (atoms/cm3) or lower. Thus, leakage current of the transistor can be reduced. As a result, in the logic circuit, reduction in standby power and suppression of malfunction can be achieved.

Abstract: A clockless return to state domino logic gate including a domino circuit and an input circuit. The domino circuit asserts s preset node and an enable node to a first logic state and asserts an output node and a reset node to a second logic state in a preset state, and switches to a latch state when the preset node is pulled to the second state. In the latch state, the domino circuit pulls the output node to the first logic state and pulls the enable node to the second logic state. The domino circuit resets back to the preset state when the first reset node is pulled to the first logic state. The input circuit controls the domino circuit based on collective state of input signals, and is configured to perform a selected logic function using at least one return to state signal without use of a clock signal.

Abstract: A single-path latch, a dual-path latch, a method of operating a DFF and a library of cells. In one embodiment, the single-path latch includes: (1) a passgate coupled to the data input, (2) a feedback path coupled to the passgate, the data output coupled thereto and (3) tristate circuitry coupled to the passgate and having a single transistor pair of opposite conductivity coupled to Boolean logic gates, the Boolean logic gates configured to control operation of the single transistor pair based on the data input and a pulse clock signal to drive the feedbacks path.

Abstract: Some embodiments regard a circuit comprising a current source network configured to generate a first current; a leakage circuit having a leakage current in at least two leakage conditions; the leakage currents affecting the flow of the first current; a current source generator configured to generate a similar first current corresponding to the first current, a similar first leakage current corresponding to a first leakage current in a first leakage condition, a similar second leakage current corresponding to a second leakage current in a second leakage condition; and a current control circuit configured to provide a current control signal controlling the first current based on the similar first current, the similar first leakage current, and the similar second leakage current.

Abstract: The present invention relates to scannable D flip-flops, which are improved to solve the problem of the conventional designs and provides a small and fast scannable D flip-flop without compensating its testability. The embodiment of the present invention provides a scannable D flip-flop, comprising a source coupled logic, comprising a trigger circuit for reading a clock input; a scannable input circuit coupled to the trigger circuit having four NMOS transistors; a first feedback circuit for a first output; and a second feedback circuit for a second output; a latch circuit coupled to the source coupled logic; and an output buffer coupled to the latch circuit.

Abstract: A clock gating system and method is disclosed. In a particular embodiment, the system includes an input logic circuit having at least one input to receive at least one input signal and having an output at an internal enable node. A keeper circuit includes at least one switching element that is responsive to a gated clock signal and is coupled to the internal enable node to selectively hold a logical voltage level at the internal enable node. The system further includes a gating element responsive to an input clock signal and to the logical voltage level at the internal enable node to generate the gated clock signal.

Abstract: Metal-oxide semiconductor (MOS) transistors that are operable at voltages below 1.5V, that are area efficient, and that exhibit improved drive strength and leakage current that are disclosed. A dynamic threshold voltage control scheme is used that does not require a change to existing MOS technology processes. Threshold voltage of the transistor is controlled, such that in the Off state, the threshold voltage of the transistor is set high, keeping the transistor leakage to a small value. The advantages provided by apply to dynamic logic, as well as in the specific well separation imposed by design rules because well potential difference are lower than the supply voltage swing.

Abstract: A power control apparatus including an active block in which power is always maintained in an on state and an N number of power management units having a hierarchical structure where N is a natural number greater than or equal to 1. Each of the power management units controls power of at least one power domain block Power of a first power management unit of the N number of the power management units is controlled by the active block, and power of an Nth power management unit of the N number of the power management units is controlled by an (N?1)th power management unit.

Abstract: A Multi-Threshold CMOS NULL Convention Logic asynchronous circuit (MTNCL). The MTNCL circuit provides delay-insensitive logic operation with significant leakage power and active energy reduction. The MTNCL circuit is also capable of functioning properly under extreme supply voltage scaling down to the sub-threshold region for further power reduction. Four MTNCL architectures and four MTNCL threshold gate designs offer an asynchronous logic design methodology for glitch-free, ultra-low power, and faster circuits without area overhead.

Abstract: Techniques in which an optimal set of clock gating elements is determined for a selected circuit design. Those clock gating elements are coupled to selected flip-flops, with the effect that those selected flip-flops will consume less dynamic power during operation of the logic circuit. The selected set of clock gating elements provides an optimal savings in overall power consumption after modification of that selected circuit design.

Abstract: A logic circuit latch including an input stage for receiving a logical input signal and a pair of differential amplifiers, each having an input operatively coupled to the input stage, and at least one of them having an output arranged to supply the logical output of the latch. Each of the differential amplifiers includes a transistor connected as a load, and an output of each of the differential amplifiers is coupled to bias the load transistor of the other differential amplifier. If the latch switches from the transparent state to the closed state while the logical input signal is transitioning between logical levels, the differential amplifiers drive up the logical output of the latch if the logical input signal transitions from a first to a second logical level, and drive down the logical output of the latch if the input signal transitions from the second to the first logical level.

Abstract: A semiconductor integrated circuit includes logic circuits connected in a plurality of stages, a voltage-level inverting unit that is inserted in a signal transmission path of the logic circuits and inverts a voltage level input to the logic circuits, and an inversion-timing control unit that controls inversion timing for the voltage level inverted by the voltage-level inverting unit.

Abstract: A dynamic logic gate has a device for charging a dynamic node during a pre-charge phase of a clock. A logic tree evaluates the dynamic node with a device during an evaluate phase of the clock. The dynamic node has a keeper circuit comprising an inverter with its input coupled to the dynamic node and its output coupled to the back gate of a dual gate PFET device. The source of the dual gate PFET is coupled to the power supply and its drain is coupled to the dynamic node forming a half latch. The front gate of the dual gate PFET is coupled to a logic circuit with a mode input and a logic input coupled back to a node sensing the state of the dynamic node. The mode input may be a slow mode to preserve dynamic node state or the clock delayed that turns ON the strong keeper after evaluation.

Abstract: Latch circuit and clock signal dividing circuit comprises sequentially connected latch circuits. Each latch circuit has D-type latch with latch clock input, data input and data output. A difference detector is coupled to D-type latch, and has a difference output that provides a difference signal when data at input is different than data at output. Each latch circuit has an edge triggered gate that has gate clock input, output coupled to latch clock input and gate control input coupled to difference output of difference detector. In operation, when both a transition of clock signal supplied at gate clock input is detected by edge triggered gate, and the difference signal is provided to gate control input, will edge triggered gate allow an edge of a clock signal supplied at gate clock input to determine logic values supplied to latch clock input. As a result, data at input is transferred to output.

Abstract: In a dynamic flip-flop circuit with a data selection function, for example, when data having an H value has been selected using a selection signal S0, a first node N1 is L and a second node N2 of a second dynamic circuit 1B is H, so that an output signal Q has an H level. In this case, when none of a plurality of pieces of data D0 to D2 is selected using selection signals S0 to S2, the first node N1 is H, so that the electric charge of the second node N2 is discharged and the output signal Q erroneously has an L level. However, in this case, an output node N3 is H and a fourth node N4 is L, so that an n-type transistor Tr6 of the second dynamic circuit 1B is turned OFF, thereby preventing the second node N2 from being discharged. Therefore, a normal operation is performed while securing a satisfactorily high-speed operation even when none of the pieces of data is selected.

Abstract: Reconfigurable logic cells based on dual gate MOSFET transistors (DG MOSFETs) including n inputs (A,B), n being greater than or equal to 2 and capable of performing at least four logic functions with which logical signals provided on the n inputs (A,B) may be processed. The cell contains, between the ground and the output (F) of the cell, at least one first branch including n dual gate N-type MOSFET transistors (M1,M2) in series and n?1 branches in parallel with the first branch, each provided with a dual gate N-type MOSFET transistor (M3), each of the logic functions corresponding to a given configuration of the cell. A specific set of control signals (C1,C2) is applied on the rear gates of at least one portion of the transistors (M2,M3), each control signal (C1,C2) being capable of setting the transistor (M2,M3) to a particular operating mode.

Abstract: Circuits are provided for simultaneously reducing the subthreshold and gate oxide leakage power consumption in domino logic circuits. Sleep transistors and a dual threshold voltage CMOS technology may be utilized to place idle domino logic circuits into a low leakage state. The circuits may significantly lower the total leakage power as compared to the standard dual threshold voltage domino logic circuits at both the high and low die temperatures. The energy overheads of the circuit techniques may be low, justifying the activation of the proposed sleep schemes by providing net savings in total power consumption during short idle periods.

Abstract: A logic circuit includes a control circuit including a first logic gate to receive a selection signal and a first input signal and to output a pulse control signal and a second logic gate to receive the pulse control signal, a clock signal, and a delayed clock signal and to output a pulse signal, and a multiplexing logic circuit to receive the selection signal and the pulse signal from the control circuit, to receive at least one second, static input signal, and to output a signal corresponding to one of the first input signal and the second, static input signal based on the state of the selection signal.

Abstract: A domino logic circuit includes an input circuit and an output circuit. The input circuit precharges a dynamic node at a first phase of a clock signal. The input circuit determines a logic level of the dynamic node by performing a logic evaluation of input data at a second phase of the clock signal. The output circuit is coupled between an output node and the dynamic node. The output circuit determines a logic level of the output node in response to the clock signal and the logic level of the dynamic node. The output circuit maintains the logic level of the output node while the logic evaluation is performed.

Abstract: A communication system includes master and slave controllers, a local device connected to the slave controller, and a communication cable having a pair of wires and connected between the master and slave controllers. The master controller feeds a first DC voltage to the slave controller via the communication cable and communicates with the slave controller by changing the first DC voltage such that voltages on the wires of the communication cable are opposite in phase. The slave controller generates a second DC voltage from the first DC voltage and feeds the second DC voltage to the local device. When the master and slave controllers communicate with each other, the slave controller changes the second DC voltage such that voltages on terminals of the local device are opposite in phase and vary synchronously with the voltages on the communication cable.

Abstract: Embodiments of the invention relate to a chip-to-chip communication system including a transmitter and a receiver connected to receive respective transmitter and receiver clock signals. The transmitter includes precharge and evaluation blocks connected to each other and to a transmitter clock terminal. The receiver includes a precharge block connected to a receiver clock terminal. The precharge blocks precharge an output terminal of the transmitter and an input terminal of the receiver, respectively, to a value corresponding to a first voltage reference during a low phase of the transmitter clock signal.

Abstract: The present invention provides an adaptive keeper circuit to control Domino Logic Dynamic Circuits using Rate Sensing Technique to provide reduced contention and efficient process tracking at given noise robustness with less overhead in area, power and delay, said adaptive keeper comprising, keeper PMOS transistor (M1), wherein the drain of M1 is connected to wide AND-OR logic circuit; the rate controller consisting of reference rate transistor (M4), feedback PMOS transistor (M2), feedback shutoff transistor (M5), clock shutoff transistor (M6), pre-charge PMOS transistor (M3), wherein the input of the rate controller is directly connected to drain of the keeper PMOS (M1) and the output of the rate controller is directly connected to the gate of the PMOS keeper (M1).

Abstract: To pre-charge a node to one of first and second voltage levels in response to inputs received at the corresponding voltage level, to selectively level shift the node from the first voltage level to the second voltage level when in a first voltage mode, and to maintain the node at the second voltage level when in a second voltage mode. Level shifting from first voltage level may be performed within one gate stage that may be bypassed when in the second voltage mode. The node may be discharged with no delay difference between the first and second voltage modes. Inputs may include a clock signal, which may be received at either of the first and second voltage levels without level shifting the clock signal. A circuit may be implemented with a multi-core processor system to permit selective voltage mode operation of the cores.

Abstract: First circuitry is powered by a first power supply domain and provides a data signal referenced to the first power supply domain. Second circuitry is powered by a second power supply domain that differs from the first power supply domain. The data signal becomes referenced to the second power supply domain by a clocked level shifter that couples the first circuitry to the second circuitry and buffers the data signal from the first power supply domain to the second power supply domain by only using a single supply voltage. The clocked level shifter is clocked by a signal that is used to precharge a first node and a second node of the clocked level shifter until the data signal is valid for at least a setup time period. The first and second nodes are precharged to establish a known state in the clocked level shifter.

Abstract: Various systems and methods for implementing dynamic logic are disclosed herein. For example, some embodiments of the present invention provide dynamic logic devices with a logic circuit that includes an inverting output buffer, a logic function, a bias transistor, and a current circuit. An input of the logic function is electrically coupled to a logic input, an output of the logic function is electrically coupled to an input of the inverting output buffer, and the logic function exhibits a leakage current. The gate of the bias transistor is electrically coupled to an output of the inverting buffer, and a first leg of the bias transistor is electrically coupled to the input of the inverting buffer. The current circuit supplies a current corresponding to the to a second leg of the bias transistor. In some cases, an improved performance may be achieved for a given leakage, or a reduced leakage may be achieved for a given performance.

Abstract: Apparatuses and methods are provided for a self-timed dynamic sense amplifier flop circuit, wherein a pulse generating circuit may be adapted to generate at least a first logic signal based, at least in part, on a first evaluation node signal, and a discharge path circuit comprising at least a first transistor within a first stack of transistors may be operatively responsive to the first timing signal.

Abstract: Low voltage swing techniques are provided for simultaneously reducing the active and standby mode power consumption and enhancing the noise immunity in domino logic circuits. One or both the upper and lower boundaries of the voltage swing at the dynamic node may be different from the upper and lower boundaries of the voltage swing at the output node. Further, the domino logic circuit may use dual Vt thereby reducing the short-circuit current during operation. Meanwhile, full voltage swing signals may be maintained at the inputs and outputs for high speed operation. The low swing circuit techniques are provided that modify the output voltage swing of a domino gate, thereby reducing the active mode power consumption.

Abstract: A method extends a clock-gating technique to provide a sleep signal for controlling switch circuits that reduce active leakage power. Using this extension of the clock-gating technique, fine-grained power-gating is achieved. The method automatically identifies, at an RTL or a gate level, the logic circuits that can be power-gated. The method of the present invention derives a sleep signal for fine-grained power-gating that may be applicable to both time-critical and non-time-critical designs.

Abstract: A semiconductor integrated circuit includes a MOS logic operating by first and second voltages; a switching transistor unit disposed between a supply terminal of the first voltage or the second voltage and the MOS logic, and turned on or off in response to a control signal so as to control a supply of the first or second voltage to the MOS logic; and a fuse unit disposed between the supply terminal of the first voltage or the second voltage and the switching transistor unit, for cutting off a supply of the first or second voltage to the switching transistor unit by a selective cut based on a test result. Whereby, a product development or production difficulty or a yield decrease based on a performance drop or leakage current increase in a circuit having a power gate or MTCMOS may be improved. In addition, a product development delay caused by a mask revision required at a transistor level may be improved in a revision of an NMOS or PMOS transistor.

Abstract: A scannable latch is disclosed. The scannable latch includes a dynamic circuit, two cross-coupled NAND gates coupled to the dynamic circuit, and a pair of stacked transistors coupled to the dynamic circuit. One of the stacked transistors is for receiving data signals, and the other stacked transistors is for receiving scan in signals.

Abstract: A method is disclosed that includes propagating data via a first data path of a sequential circuit element in response to a clock signal received at a single clocked transistor of the sequential circuit element. The method also includes retaining information related to the data propagated via the first path at a retention circuit element of a second data path, where the first data path includes a first transistor that is responsive to an output of the single clocked transistor. The first transistor has a higher current flow capacity than a second transistor associated with the second data path.

Abstract: A complementary energy path adiabatic logic (CEPAL) includes an evaluation network and a power clock network. The evaluation network is a logic circuit composed of P-type MOS transistors and N-type MOS transistors. The power clock network includes a P-type and N-type MOS transistors and additional P-type and N-type MOS transistors, with each of the transistors involved in the power clock network acting as an active diode.

Abstract: Methods and apparatuses for optimizing switching delay in integrated circuits are described. Combinational logic gates are modified with precharge circuitry and instantiated in order to reduce switching transitions of circuit elements in a signal path.