Low-power clock gating circuit
First Claim
1. A clock gating circuit including a first inverter, a second inverter, a third inverter, an AND gate, a power terminal, a data terminal, a clock terminal, a sleep control terminal, and an output terminal, the clock gating circuit comprising:
- a first PMOS transistor electrically connected between the power terminal and the first inverter, a second PMOS transistor electrically connected between the power terminal and the second inverter, and a third PMOS transistor electrically connected between the power terminal and the AND gate wherein each of the first through third PMOS transistors is controlled by a sleep control signal applied via the sleep control terminal, each PMOS transistor having a high threshold voltage; and
a first NMOS transistor electrically connected between a ground and the first inverter, a second NMOS transistor electrically connected between the ground and the second inverter, and a third NMOS transistor electrically connected between the ground and the AND gate wherein each of the first thorough third NMOS transistors is controlled by the sleep control signal, each NMOS transistor having a high threshold voltage; and
a fourth PMOS transistor electrically connected between the output of the second inverter and the third inverter and having a high threshold voltage; and
a fourth NMOS transistor electrically connected between the ground and the second inverter and having a high threshold voltage,wherein the first inverter receives and inverts a data signal to output the inverted signal of the first inverter under control of the sleep control signal,the second inverter for inverting the output signal from the first inverter to output the inverted signal of the second inverter under control of the sleep control signal,the AND gate circuit for receiving the output signal of the second inverter and a clock signal and outputting a gated signal under control of the sleep control signal, andthe third inverter for inverting and outputting the output signal of the second inverter,wherein the output signal of the second inverter is inputted to the third inverter for inverting the output signal from the second inverter to output the inverted signal to the second inverter as a feedback signal under control of the clock signal.
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Accused Products
Abstract
Provided is a low-power clock gating circuit using a Multi-Threshold CMOS (MTCMOS) technique. The low-power clock gating circuit includes a latch circuit of an input stage and an AND gate circuit of an output stage, in which power consumption caused by leakage current in the clock gating circuit is reduced in a sleep mode, and supply of a clock to a unused device of a targeted logic circuit is prevented by the control of a clock enable signal in an active mode, thereby reducing power consumption. The low-power clock gating circuit using an MTCMOS technique uses devices having a low threshold voltage and devices having a high threshold voltage, which makes it possible to implement a high-speed, low-power circuit, unlike a conventional clock gating circuit using a single threshold voltage.
58 Citations
14 Claims
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1. A clock gating circuit including a first inverter, a second inverter, a third inverter, an AND gate, a power terminal, a data terminal, a clock terminal, a sleep control terminal, and an output terminal, the clock gating circuit comprising:
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a first PMOS transistor electrically connected between the power terminal and the first inverter, a second PMOS transistor electrically connected between the power terminal and the second inverter, and a third PMOS transistor electrically connected between the power terminal and the AND gate wherein each of the first through third PMOS transistors is controlled by a sleep control signal applied via the sleep control terminal, each PMOS transistor having a high threshold voltage; and a first NMOS transistor electrically connected between a ground and the first inverter, a second NMOS transistor electrically connected between the ground and the second inverter, and a third NMOS transistor electrically connected between the ground and the AND gate wherein each of the first thorough third NMOS transistors is controlled by the sleep control signal, each NMOS transistor having a high threshold voltage; and a fourth PMOS transistor electrically connected between the output of the second inverter and the third inverter and having a high threshold voltage; and a fourth NMOS transistor electrically connected between the ground and the second inverter and having a high threshold voltage, wherein the first inverter receives and inverts a data signal to output the inverted signal of the first inverter under control of the sleep control signal, the second inverter for inverting the output signal from the first inverter to output the inverted signal of the second inverter under control of the sleep control signal, the AND gate circuit for receiving the output signal of the second inverter and a clock signal and outputting a gated signal under control of the sleep control signal, and the third inverter for inverting and outputting the output signal of the second inverter, wherein the output signal of the second inverter is inputted to the third inverter for inverting the output signal from the second inverter to output the inverted signal to the second inverter as a feedback signal under control of the clock signal. - View Dependent Claims (2, 3, 4, 5, 6)
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7. A clock gating circuit comprising:
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a first signal inverting circuit for inverting a data signal through a first inverter and outputting an inverted signal under control of a sleep control signal; a second signal inverting circuit for inverting the output signal of the first signal inverting circuit through a second inverter and outputting an inverted signal under control of the sleep control signal; an AND gate circuit for receiving the output signal of the second signal inverting circuit and a clock signal and outputting a gated signal under control of the sleep control signal; and a feedback circuit for feeding an output signal of the second signal inverting circuit back to the second signal inverting circuit under control of the clock signal, wherein the feedback circuit comprises; a third inverter for inverting and outputting the output signal of the second signal inverting circuit; a third PMOS transistor having a source for receiving the output signal of the second signal inverting circuit, a gate for receiving an output signal of the third inverter, and a drain connected to the source; and a third NMOS transistor having a drain connected to the second inverter, a gate for receiving an output signal of the third inverter, and a source connected to the ground, wherein the third PMOS transistor and the third NMOS transistor have high threshold voltages. - View Dependent Claims (8, 9, 10, 11, 12, 13, 14)
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Specification