Dynamic feedback-controlled output driver with minimum slew rate variation from process, temperature and supply
First Claim
1. A buffer circuit, comprising:
- an inverting buffer having an input and an output; and
an active resistance series-coupled with a capacitor between the input and the output,wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a fabrication process, and the passgate is configured to provide the resistance in an exponential manner in response to the variation in the fabrication process.
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Accused Products
Abstract
In examples, apparatus and methods are provided that mitigate buffer slew rate variations due to variations in output capacitive loading, a fabrication process, a voltage, and/or a temperature (PVT). An exemplary embodiment includes an inverting buffer having an input and an output, as well as an active resistance series-coupled with a capacitor between the input and the output. The resistance of the active resistance varies based on a variation in a fabrication process, a voltage, and/or temperature. The active resistance can be a passgate. In another example, a CMOS inverter'"'"'s output is coupled to the input of the inverting buffer, and two series-coupled inverting buffers are coupled between the input of the CMOS inverter and the output of the inverting buffer.
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Citations
40 Claims
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1. A buffer circuit, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a fabrication process, and the passgate is configured to provide the resistance in an exponential manner in response to the variation in the fabrication process. - View Dependent Claims (2, 3, 4, 5, 6)
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7. A method for reducing slew rate variations in a buffer circuit having an inverting buffer with the inverting buffer output coupled to the inverting buffer input via a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate the slew rate variations by actively changing resistance in response to a variation in a fabrication process, comprising:
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feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input via the capacitor and the passgate; and varying the portion of the output voltage to mitigate the slew rate variations, by actively changing the resistance of the passgate, in response to a variation in a fabrication process, wherein resistance of the passgate varies exponentially in response to the variation in the fabrication process. - View Dependent Claims (8)
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9. A buffer circuit, comprising:
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an inverting buffer; means for feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input using a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a fabrication process; and means for varying the portion of the output voltage, using the passgate, in response to the variation in the fabrication process, wherein the passgate is configured to provide the resistance in an exponential manner in response to the variation in the fabrication process.
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10. A non-transitory computer-readable medium, comprising instructions stored thereon that, if executed by a lithographic device, cause the lithographic device to fabricate at least a part of a device, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively varying the resistance in response to a variation in fabrication process, and the resistance of the passgate is configured to vary exponentially in response to the variation in the fabrication process.
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11. A buffer circuit, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in power supply voltage, and the passgate is configured to provide the resistance in an exponential manner in response to the variation in the power supply voltage. - View Dependent Claims (12, 13, 14, 15)
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16. A method for reducing slew rate variations in a buffer circuit having an inverting buffer with the inverting buffer output coupled to the inverting buffer input via a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate the slew rate variations by actively changing resistance in response to a variation in a power supply voltage, comprising:
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feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input via the capacitor and the passgate; and varying the portion of the output voltage to mitigate the slew rate variations, by actively changing the resistance of the passgate, in response to the variation in the power supply voltage, wherein the resistance of the passgate varies exponentially in response to the variation in the power supply voltage. - View Dependent Claims (17)
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18. A buffer circuit, comprising:
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an inverting buffer; means for feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input using a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a power supply voltage; and means for varying the portion of the output voltage, using the passgate, in response to the variation in the power supply voltage, wherein the passgate is configured to provide the resistance in an exponential manner in response to the variation in the power supply voltage.
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19. A non-transitory computer-readable medium, comprising instructions stored thereon that, if executed by a lithographic device, cause the lithographic device to fabricate at least a part of a device, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively varying the resistance in response to a variation in power supply voltage, and the resistance of the passgate is configured to vary exponentially in response to the variation in the power supply voltage.
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20. A buffer circuit, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in temperature, and the passgate is configured to provide the resistance in an exponential manner in response to the variation in the temperature. - View Dependent Claims (21, 22, 23, 24)
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25. A method for reducing slew rate variations in a buffer circuit having an inverting buffer with the inverting buffer output coupled to the inverting buffer input via a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate the slew rate variations by actively changing resistance in response to a variation in temperature, comprising:
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feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input via the capacitor and the passgate; and varying the portion of the output voltage to mitigate the slew rate variations, by actively changing the resistance of the passgate, in response to the variation in the temperature, wherein the resistance of the passgate varies exponentially in response to the variation in the temperature. - View Dependent Claims (26)
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27. A buffer circuit, comprising:
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an inverting buffer; means for feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input using a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a temperature; and means for varying the portion of the output voltage, using the passgate, in response to the variation in the temperature wherein the passgate is configured to provide the resistance in an exponential manner in response to the variation in the temperature.
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28. A non-transitory computer-readable medium, comprising instructions stored thereon that, if executed by a lithographic device, cause the lithographic device to fabricate at least a part of a device, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively varying the resistance in response to the a variation in temperature, and the resistance of the passgate is configured to vary exponentially in response to the variation in the temperature.
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29. A buffer circuit, comprising:
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an inverting buffer having an input and an output; an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a fabrication process; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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30. A buffer circuit, comprising:
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an inverting buffer; means for feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input using a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a fabrication process; means for varying the portion of the output voltage, using the passgate, in response to the variation in the fabrication process; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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31. A non-transitory computer-readable medium, comprising instructions stored thereon that, if executed by a lithographic device, cause the lithographic device to fabricate at least a part of a device, comprising:
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an inverting buffer having an input and an output; an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively varying the resistance in response to a variation in fabrication process; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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32. A buffer circuit, comprising:
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an inverting buffer having an input and an output; an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in power supply voltage; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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33. A buffer circuit, comprising:
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an inverting buffer; means for feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input using a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a power supply voltage; means for varying the portion of the output voltage, using the passgate, in response to the variation in the power supply voltage; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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34. A non-transitory computer-readable medium, comprising instructions stored thereon that, if executed by a lithographic device, cause the lithographic device to fabricate at least a part of a device, comprising:
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an inverting buffer having an input and an output; an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively varying the resistance in response to a variation in power supply voltage; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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35. A buffer circuit, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in temperature; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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36. A buffer circuit, comprising:
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an inverting buffer; means for feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input using a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively changing resistance in response to a variation in a temperature; means for varying the portion of the output voltage, using the passgate, in response to the variation in the temperature; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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37. A non-transitory computer-readable medium, comprising instructions stored thereon that, if executed by a lithographic device, cause the lithographic device to fabricate at least a part of a device, comprising:
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an inverting buffer having an input and an output; and an active resistance series-coupled with a capacitor between the input and the output, wherein the active resistance is a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate a slew rate variation by actively varying the resistance in response to the a variation in temperature; a CMOS inverter having an output, with the CMOS inverter output coupled to the input of the inverting buffer; and two series-coupled inverting buffers coupled between the input of the CMOS inverter and the output of the inverting buffer.
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38. A method for reducing slew rate variations in a buffer circuit having an inverting buffer with the inverting buffer output coupled to a capacitive load and to the inverting buffer input via a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate the slew rate variations by actively changing resistance in response to a variation in a fabrication process, comprising:
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feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input via the capacitor and the passgate; varying the portion of the output voltage to mitigate the slew rate variations, by actively changing the resistance of the passgate, in response to a variation in a fabrication process; and preventing the inverting buffer from turning on, based on the capacitance of the capacitive load.
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39. A method for reducing slew rate variations in a buffer circuit having an inverting buffer with the inverting buffer output coupled to a capacitive load and to the inverting buffer input via a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate the slew rate variations by actively changing resistance in response to a variation in a power supply voltage, comprising:
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feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input via the capacitor and the passgate; varying the portion of the output voltage to mitigate the e slew rate variations, by actively changing the resistance of the passgate, in response to the variation in the power supply voltage; and preventing the inverting buffer from turning on, based on the capacitance of the capacitive load.
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40. A method for reducing slew rate variations in a buffer circuit having an inverting buffer with the inverting buffer output coupled to a capacitive load and to the inverting buffer input via a capacitor series-coupled with a passgate configured to provide feedback from the output of the inverting buffer to the input of the inverting buffer and to mitigate the slew rate variations by actively changing resistance in response to a variation in temperature, comprising:
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feeding a portion of an output voltage from the inverting buffer output to the inverting buffer input via the capacitor and the passgate; and varying the portion of the output voltage to mitigate the slew rate variations, by actively changing the resistance of the passgate, in response to the variation in the temperature; and preventing the inverting buffer from turning on, based on the capacitance of the capacitive load.
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Specification