Circuit for measuring absolute spread in capacitors implemented in planary technology
First Claim
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1. A circuit for measuring absolute spread in capacitors implemented in planary technology comprising:
- a charge pump that is configured to supply a charge current to an internal capacitor (Cint), a voltage across the internal capacitor (Cint) being coupled through a comparator for comparing said voltage with first and second threshold levels to a bistable multivibrator for reversing the direction of the charge current;
to charge the internal capacitor (Cint) when said voltage decreases below the second threshold level and to decharge the internal capacitor (Cint), when said voltage increases above the first threshold level, wherein the charge current, as well as a voltage range between said first and second threshold levels, is dependent upon a reference voltage, and an output signal of the bistable multivibrator is coupled to a frequency measuring device that is configured to compare a repetition frequency of the output signal with a reference frequency.
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Abstract
A circuit for measuring absolute spread in capacitors implemented in planary technology. A charge pump supplying a charge current to an internal capacitor (Cint) is used, the voltage across the internal capacitor (Cint) being coupled through a comparator for comparing the voltage with first and second threshold levels. A bistable multivibrator reverses the direction of the charge current, to charge the internal capacitor (Cint) when the voltage decreases below the second threshold level, and to decharge the internal capacitor (Cint) when the voltage increases above the first threshold level. The charge current is determined by a reference voltage that is provided across an external resistor (Rext), the first and second threshold levels defining a voltage range being proportional to the reference voltage. An output signal of the bistable multivibrator is coupled to frequency measuring means to compare the repetition frequency thereof with a reference frequency.
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Citations
20 Claims
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1. A circuit for measuring absolute spread in capacitors implemented in planary technology comprising:
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a charge pump that is configured to supply a charge current to an internal capacitor (Cint), a voltage across the internal capacitor (Cint) being coupled through a comparator for comparing said voltage with first and second threshold levels to a bistable multivibrator for reversing the direction of the charge current;
to charge the internal capacitor (Cint) when said voltage decreases below the second threshold level and to decharge the internal capacitor (Cint), when said voltage increases above the first threshold level, wherein the charge current, as well as a voltage range between said first and second threshold levels, is dependent upon a reference voltage, and an output signal of the bistable multivibrator is coupled to a frequency measuring device that is configured to compare a repetition frequency of the output signal with a reference frequency. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
said voltage range is proportional to the reference voltage. -
3. The circuit of claim 2, wherein
said internal capacitor (Cint) is coupled between emitters of first and second transistors, collectors and bases of the first and second transistors being coupled through mutually equal load resistors to a first supply voltage, said collectors being coupled to inputs of a negative feedback circuit for a negative feedback of output voltages of the collectors of said first and second transistors to the base inputs thereof, the emitters of said first and second transistors being coupled to first and second outputs of said charge pump. -
4. The circuit of claim 1, wherein
the charge current is generated by the reference voltage being provided across an external resistor Rext. -
5. The circuit of claim 4, wherein
said internal capacitor (Cint) is coupled between emitters of first and second transistors, collectors and bases of the first and second transistors being coupled through mutually equal load resistors to a first supply voltage, said collectors being coupled to inputs of a negative feedback circuit for a negative feedback of output voltages of the collectors of said first and second transistors to the base inputs thereof, the emitters of said first and second transistors being coupled to first and second outputs of said charge pump. -
6. The circuit of claim 5, wherein
a monotonous variation of the voltage across said internal capacitor in the range between first and second threshold levels corresponds to a quotient of the reference voltage and the internal capacitor (Cint), said range is dependent upon a magnitude of the reference voltage and said charge current is dependent upon a quotient of the reference voltage and the external resistor (Rext). -
7. The circuit of claim 5, wherein
the negative feedback circuit comprises third and fourth transistors having bases coupled to the collectors of said first and second transistors, collectors coupled to the supply voltage and emitters coupled through mutually equal resistors to a second supply voltage as well as to bases of fifth and sixth emitter coupled transistors, collectors of the fifth and sixth emitter coupled transistors being cross coupled to the bases of the second and first transistors, and emitters of the fifth and sixth emitter coupled transistors being commonly coupled to a third output of the charge pump. -
8. The circuit of claim 7, wherein
the charge pump comprises a pair of emitter coupled seventh and eighth transistors, collectors of the seventh and eighth transistors providing respectively said first and second outputs of the charge pump, bases of the seventh and eighth transistors being mutually coupled to the reference voltage and emitters of the seventh and eighth transistors being coupled through said external resistor (Rext) to the second supply voltage, as well as a ninth transistor having: -
a collector that provides said third output of the charge pump, a base that is coupled to said reference voltage and an emitter that is coupled via an emitter resistor to the second supply voltage.
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9. The circuit of claim 8, further including
a stabilizer that is configured to stabilize the emitter voltage of the ninth transistor. -
10. The circuit of claim 9, wherein
a monotonous variation of the voltage across said internal capacitor in the range between first and second threshold levels corresponds to a quotient of the reference voltage and the internal capacitor (Cint), said range is dependent upon a magnitude of the reference voltage and said charge current is dependent upon a quotient of the reference voltage and the external resistor (Rext). -
11. The circuit of claim 10, wherein
said frequency measuring means comprises a clock controlled microprocessor that is configured to measure the repetition frequency of the bistable multivibrator output signal. -
12. The circuit of claim 1, wherein
said internal capacitor (Cint) is coupled between emitters of first and second transistors, collectors and bases of the first and second transistors being coupled through mutually equal load resistors to a first supply voltage, said collectors being coupled to inputs of a negative feedback circuit for a negative feedback of output voltages of the collectors of said first and second transistors to the base inputs thereof, the emitters of said first and second transistors being coupled to first and second outputs of said charge pump. -
13. The circuit of claim 12, wherein
a monotonous variation of the voltage across said internal capacitor in the range between first and second threshold levels corresponds to a quotient of the reference voltage and the internal capacitor (Cint), said range is dependent upon a magnitude of the reference voltage and said charge current is dependent upon a quotient of the reference voltage and an external resistor (Rext). -
14. The circuit of claim 12, wherein
the negative feedback circuit comprises third and fourth transistors having bases coupled to the collectors of said first and second transistors, collectors coupled to the supply voltage and emitters coupled through mutually equal resistors to a second supply voltage as well as to bases of fifth and sixth emitter coupled transistors, collectors of the fifth and sixth emitter coupled transistors being cross coupled to the bases of the second and first transistors, and emitters of the fifth and sixth emitter coupled transistors being commonly coupled to a third output of the charge pump. -
15. The circuit of claim 14, wherein
the charge pump comprises a pair of emitter coupled seventh and eighth transistors, collectors of the seventh and eighth transistors providing respectively said first and second outputs of the charge pump, bases of the seventh and eighth transistors being mutually coupled to the reference voltage and emitters of the seventh and eighth transistors being coupled through an external resistor (Rext) to the second supply voltage, as well as a ninth transistor having: -
a collector that provides said third output of the charge pump, a base that is coupled to said reference voltage and an emitter that is coupled via an emitter resistor to the second supply voltage.
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16. The circuit of claim 15, wherein
a monotonous variation of the voltage across said internal capacitor in the range between first and second threshold levels corresponds to a quotient of the reference voltage and the internal capacitor (Cint), said range is dependent upon a magnitude of the reference voltage and said charge current is dependent upon a quotient of the reference voltage and the external resistor (Rext). -
17. The circuit of claim 1, wherein
a monotonous variation of the voltage across said internal capacitor in the range between first and second threshold levels corresponds to a quotient of the reference voltage and the internal capacitor (Cint), said range is dependent upon a magnitude of the reference voltage and said charge current is dependent upon a quotient of the reference voltage and an external resistor (Rext). -
18. The circuit of claim 1, wherein
said frequency measuring means comprises a clock controlled microprocessor that is configured to measure the repetition frequency of the bistable multivibrator output signal.
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19. A method of measuring an absolute spread in capacitance of a capacitor, comprising:
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applying a charge current to the capacitor to provide thereby a capacitor voltage, comparing the capacitor voltage to a first threshold level and a second threshold level, reversing the charge current when the capacitor voltage rises to the first threshold level, thereby discharging the capacitor, and reversing the charge current when the capacitor voltage falls to the second threshold level, thereby charging the capacitor, and measuring a frequency of reversals of the charge current. - View Dependent Claims (20)
providing a reference voltage, controlling the charge current based on the reference voltage, and determining the first threshold level and the second threshold level based on the reference voltage.
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Specification
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Current AssigneeSemiconductor Ideas to the Market ItoM BV (Robert Bosch GmbH)
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Original AssigneeSemiconductor Ideas To The Market BV
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InventorsKasperkovitz, Wolfdietrich Georg
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Primary Examiner(s)Le, N.
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Assistant Examiner(s)Nguyen, Vincent Q.
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Application NumberUS10/296,292Publication NumberTime in Patent Office677 DaysField of Search324/658, 324/676, 324/679, 324/681, 324/683, 324/709, 324/710-712, 324/537, 324/765, 324/158.1, 324/76.52, 324/76.53, 324/76.55, 327/157, 327/536, 327/537US Class Current324/658CPC Class CodesG01R 27/2605 Measuring capacitance capac...G01R 31/2884 using dedicated test connec...
