Details
| Original language | English |
|---|---|
| Title of host publication | Sensoren und Messsysteme - 21. ITG/GMA-Fachtagung |
| Publisher | VDE Verlag GmbH |
| Pages | 293-296 |
| Number of pages | 4 |
| ISBN (print) | 978-3-8007-5835-7 |
| Publication status | Published - 2022 |
| Event | 21. ITG/GMA-Fachtagung Sensoren und Messsysteme - 21st ITG/GMA Conference on Sensors and Measuring Systems - Nuremberg, Germany Duration: 10 May 2022 → 11 May 2022 |
Publication series
| Name | Sensoren und Messsysteme - 21. ITG/GMA-Fachtagung |
|---|
Abstract
In a large number of sensor principles, small currents are being measured and the performance of the current amplifier has a decisive influence on the performance of the entire measurement system. Usually current amplifiers are designed as a so-called resistive transimpedance amplifier, i.e. the current to be measured is converted into a voltage via a resistor. The higher its resistance, the lower the noise current density caused by thermal noise. At the same time, however, a higher resistance reduces the maximum measurable current at a given output voltage and the maximum bandwidth at a given parasitic capacitance. An alternative are capacitive transimpedance amplifiers, which integrate the current to be measured on a capacitor, corresponding to a nearly infinite resistance. However, leakage currents and charge injection of the switches necessary for resetting the capacitor in this setup result in new sources of error. These errors can be compensated successfully by the novel active reset architecture presented here, which actively regulates the voltage across the capacitor to zero during reset. This enables the design of a current amplifier with a unique combination of ultra-low noise, wide linear dynamic range and high bandwidth. A demonstrator of the current amplifier achieves a standard deviation of the measured current of 3.4 fA at a 3-dB bandwidth of48 Hz, which corresponds to a noise current density of 0.49 fA/VTLZ assuming a uniform distribution over the frequency spectrum. Moreover, the demonstrator achieves excellent zero-point stability even without temperature control. Over a period of several days, the zero-point remained within ± 500 aA.
ASJC Scopus subject areas
- Engineering(all)
- Control and Systems Engineering
- Engineering(all)
- Electrical and Electronic Engineering
- Physics and Astronomy(all)
- Instrumentation
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Sensoren und Messsysteme - 21. ITG/GMA-Fachtagung. VDE Verlag GmbH, 2022. p. 293-296 (Sensoren und Messsysteme - 21. ITG/GMA-Fachtagung).
Research output: Chapter in book/report/conference proceeding › Conference contribution › Research › peer review
}
TY - GEN
T1 - A Fast, Ultra-Low Noise Current Amplifier with Linear Range from Femtoamperes to Nanoamperes
AU - Wendt, Cornelius
AU - Bohnhorst, Alexander
AU - Zimmermann, Stefan
AU - Kirk, Ansgar T.
N1 - Funding Information: The project "Femtoampere (fA) bis Mikroampere (uA) schnell erfassen - FUSE" is funded by the German Federal Ministry for Economic Affairs and Climate Action and the European Social Fund as part ofthe EXIST program.
PY - 2022
Y1 - 2022
N2 - In a large number of sensor principles, small currents are being measured and the performance of the current amplifier has a decisive influence on the performance of the entire measurement system. Usually current amplifiers are designed as a so-called resistive transimpedance amplifier, i.e. the current to be measured is converted into a voltage via a resistor. The higher its resistance, the lower the noise current density caused by thermal noise. At the same time, however, a higher resistance reduces the maximum measurable current at a given output voltage and the maximum bandwidth at a given parasitic capacitance. An alternative are capacitive transimpedance amplifiers, which integrate the current to be measured on a capacitor, corresponding to a nearly infinite resistance. However, leakage currents and charge injection of the switches necessary for resetting the capacitor in this setup result in new sources of error. These errors can be compensated successfully by the novel active reset architecture presented here, which actively regulates the voltage across the capacitor to zero during reset. This enables the design of a current amplifier with a unique combination of ultra-low noise, wide linear dynamic range and high bandwidth. A demonstrator of the current amplifier achieves a standard deviation of the measured current of 3.4 fA at a 3-dB bandwidth of48 Hz, which corresponds to a noise current density of 0.49 fA/VTLZ assuming a uniform distribution over the frequency spectrum. Moreover, the demonstrator achieves excellent zero-point stability even without temperature control. Over a period of several days, the zero-point remained within ± 500 aA.
AB - In a large number of sensor principles, small currents are being measured and the performance of the current amplifier has a decisive influence on the performance of the entire measurement system. Usually current amplifiers are designed as a so-called resistive transimpedance amplifier, i.e. the current to be measured is converted into a voltage via a resistor. The higher its resistance, the lower the noise current density caused by thermal noise. At the same time, however, a higher resistance reduces the maximum measurable current at a given output voltage and the maximum bandwidth at a given parasitic capacitance. An alternative are capacitive transimpedance amplifiers, which integrate the current to be measured on a capacitor, corresponding to a nearly infinite resistance. However, leakage currents and charge injection of the switches necessary for resetting the capacitor in this setup result in new sources of error. These errors can be compensated successfully by the novel active reset architecture presented here, which actively regulates the voltage across the capacitor to zero during reset. This enables the design of a current amplifier with a unique combination of ultra-low noise, wide linear dynamic range and high bandwidth. A demonstrator of the current amplifier achieves a standard deviation of the measured current of 3.4 fA at a 3-dB bandwidth of48 Hz, which corresponds to a noise current density of 0.49 fA/VTLZ assuming a uniform distribution over the frequency spectrum. Moreover, the demonstrator achieves excellent zero-point stability even without temperature control. Over a period of several days, the zero-point remained within ± 500 aA.
UR - http://www.scopus.com/inward/record.url?scp=85143255341&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85143255341
SN - 978-3-8007-5835-7
T3 - Sensoren und Messsysteme - 21. ITG/GMA-Fachtagung
SP - 293
EP - 296
BT - Sensoren und Messsysteme - 21. ITG/GMA-Fachtagung
PB - VDE Verlag GmbH
T2 - 21. ITG/GMA-Fachtagung Sensoren und Messsysteme - 21st ITG/GMA Conference on Sensors and Measuring Systems
Y2 - 10 May 2022 through 11 May 2022
ER -