Analog integrator system and method
First Claim
1. An integrator circuit comprising:
- an active input having a first resistance, a first inductance, and a first capacitance;
a passive input, having a second resistance, a second inductance, and a second capacitance, wherein the first resistance is substantially similar to the second resistance, the first inductance is substantially similar to the second inductance, and the first capacitance is substantially similar to the second capacitance;
a first integrator having a first integrator input and a first integrator output, wherein there is no feedback loop between the first integrator input and the first integrator output;
a second integrator having a second integrator input and a second integrator output, wherein there is no feedback loop between the second integrator input and the second integrator output;
a first plurality of switches coupled with and configured to switch the first integrator input between the active input and the passive input, and coupled with and configured to switch the second integrator input between the active input and the passive input;
a second plurality of switches coupled with the first integrator output and the second integrator output; and
a controller coupled with the first plurality of switches and the second plurality of switches, configured to control the operation of the first plurality of switches to switch the active input between the first integrator input and the second integrator input, and configured to control the operation of the first plurality of switches to switch the passive input between the first integrator input and the second integrator input.
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Abstract
Systems and methods are disclosed to integrate signals. Some embodiments include an integrator comprising an active input; a passive input; a first integrator having a first integrator input and a first integrator output; a second integrator having a second integrator input and a second integrator output; a first plurality of switches coupled with the first integrator input, the second integrator input, the active input, and the passive input; a second plurality of switches coupled with the first integrator output and the second integrator output; and a controller. The controller may be configured to control the operation of the first plurality of switches to switch the active input between the first integrator input and the second integrator input, and control the operation of the first plurality of switches to switch the passive input between the first integrator input and the second integrator input.
32 Citations
16 Claims
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1. An integrator circuit comprising:
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an active input having a first resistance, a first inductance, and a first capacitance; a passive input, having a second resistance, a second inductance, and a second capacitance, wherein the first resistance is substantially similar to the second resistance, the first inductance is substantially similar to the second inductance, and the first capacitance is substantially similar to the second capacitance; a first integrator having a first integrator input and a first integrator output, wherein there is no feedback loop between the first integrator input and the first integrator output; a second integrator having a second integrator input and a second integrator output, wherein there is no feedback loop between the second integrator input and the second integrator output; a first plurality of switches coupled with and configured to switch the first integrator input between the active input and the passive input, and coupled with and configured to switch the second integrator input between the active input and the passive input; a second plurality of switches coupled with the first integrator output and the second integrator output; and a controller coupled with the first plurality of switches and the second plurality of switches, configured to control the operation of the first plurality of switches to switch the active input between the first integrator input and the second integrator input, and configured to control the operation of the first plurality of switches to switch the passive input between the first integrator input and the second integrator input. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A method comprising:
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integrating an active input signal from an active input, having a first resistance, a first inductance and a first capacitance, with a first integrator, wherein there is no feedback loop between a first integrator input and a first integrator output; integrating a passive input signal from a passive input, having a second resistance, a second inductance and a second capacitance, with a second integrator, wherein the passive input signal includes substantially no voltage or current, wherein the first resistance is substantially similar to the second resistance, the first inductance is substantially similar to the second inductance, and the first capacitance is substantially similar to the second capacitance, such that there is no feedback loop between a second integrator input and a second integrator output; switching a first plurality of switches coupled with and configured to switch the first integrator between the active input signal and the passive input signal and coupled with and configured to switch the second integrator between the active input signal and the passive input signal; integrating the active input signal with the second integrator; and integrating the passive input signal with the first integrator. - View Dependent Claims (11, 12, 13, 14, 15)
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16. A method comprising:
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integrating an active input, having a first resistance, a first inductance, and a first capacitance, with a first integrator during a first time period to produce first integration data, wherein there is no feedback loop between a first integrator input and a first integrator output; integrating a passive input with a second integrator during the first time period, wherein the passive input has a second resistance, a second capacitance and a second inductance, wherein the first resistance is substantially similar to the second resistance, the first inductance is substantially similar to the second inductance, and the first capacitance is substantially similar to the second capacitance, wherein there is no feedback loop between the second integrator input and the second integrator output; integrating the active input with the second integrator during a second time period to produce second integration data; integrating the passive input with the first integrator during the second time period; integrating the active input with the first integrator during a third time period to produce third integration data; integrating the passive input with the second integrator during the third time period; integrating the active input with the second integrator during a fourth time period to produce fourth integration data; integrating the passive input with the first integrator during the fourth time period, such that a first plurality of switches is coupled with and configured to switch the first integrator input between the active input and the passive input, and coupled with and configured to switch the second integrator input between the active input and the passive input; and combining the first integration data, the second integration data, the third integration data, and the fourth integration data to produce integration data of the active input signal over the total time period comprising the first time period, the second time period, the third time period, and the fourth time period, such that a continuous switching between the first integrator and the second integrator is based on a switching criteria being met.
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Specification