177 lines
No EOL
6.6 KiB
BibTeX
177 lines
No EOL
6.6 KiB
BibTeX
@book{Horowitz:1981307,
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author = "Horowitz, Paul and Hill, Winfield",
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title = "{The art of electronics; 3rd ed.}",
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publisher = "Cambridge University Press",
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address = "Cambridge",
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year = "2015",
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url = "https://cds.cern.ch/record/1981307",
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}
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@article{Reinecke2018Oct,
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author = {Reinecke, Tobias and Clowers, Brian H.},
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title = {{Implementation of a flexible, open-source platform for ion mobility spectrometry}},
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journal = {HardwareX},
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volume = {4},
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pages = {e00030},
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year = {2018},
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month = oct,
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issn = {2468-0672},
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publisher = {Elsevier},
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doi = {10.1016/j.ohx.2018.e00030}
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}
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@book{Cox2002,
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author = {Cox, James F.},
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title = {{Fundamentals of Linear Electronics: Integrated and Discrete}},
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year = {2002},
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isbn = {978-0-76683018-9},
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publisher = {Delmar Thomson Learning},
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url = {https://books.google.de/books?vid=ISBN0766830187&redir_esc=y}
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}
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@book{Eiceman2013Oct,
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author = {G. A. Eiceman, Z.Karpas, Herbert H. Hill Jr.},
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editor = {},
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publisher = {{Taylor and Francis Group}},
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title = {{Ion Mobility Spectrometry}},
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year = {2013},
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isbn = {978-1-4398-5998-8}
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}
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@techreport{tiNoise2007,
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author = {Texas Instruments},
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institution = {Texas Instruments},
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journal = {Digital Signal Processing Solutions},
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title = {{Noise Analysis in Operational Amplifier Circuits}},
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year = {2007},
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url = {{https://www.ti.com/lit/an/slva043b/slva043b.pdf}},
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eid = {SLVA043B}
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}
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@techreport{tiOpAmpCap2000,
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author = {Texas Instruments},
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institution = {Texas Instruments},
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title = {{Effect of Parasitic Capacitance in Op Amp Circuits}},
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year = {2007},
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month = sep,
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url = {{https://www.ti.com/lit/an/sloa013a/sloa013a.pdf?ts=1715091777328}},
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eid = {SLOA013A}
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}
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@techreport{analogINBIAS2008,
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author = {Analog Devices},
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institution = {Analog Devices},
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title = {Op Amp Input Bias Current},
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year = {2008},
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url = {{https://www.analog.com/media/en/training-seminars/tutorials/MT-038.pdf}},
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eid = {MT-038}
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}
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@misc{ADFilterDesign,
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author = {{Analog Devices}},
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title = {{Filter Design Tool}},
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year = {2024},
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month = jul,
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note = {[Online; accessed 05. July 2024]},
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url = {https://tools.analog.com/en/filterwizard/}
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}
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@misc{JBellemann22,
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author = {{Jeroen Belleman}},
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title = {{Shunt capacitance of 1206 SMD resistors}},
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year = {2010},
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month = dec,
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note = {[Online; accessed 28th August 2024]},
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url = {http://jeroen.web.cern.ch/jeroen/resistor/shuntC.html}
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}
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@misc{VishayRFreq,
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title = {{Frequency Response of Thin Film Chip Resistors}},
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year = {2009},
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month = feb,
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note = {[Online; accessed 28th August 2024]},
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url = {https://www.vishay.com/docs/60107/freqresp.pdf}
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}
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@misc{DatasheetADA4530,
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title = {{Datasheet ADA4530 - Femtoampere Input Bias Current Electrometer Amplifier}},
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year = {2024},
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month = jun,
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note = {[Online; accessed 12th June 2024]},
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url = {https://www.analog.com/media/en/technical-documentation/data-sheets/ada4530-1.pdf}
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}
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@misc{DatasheetLTC2274,
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title = {{Datasheet LTC2274 - 16-Bit, 105Msps Serial Output ADC}},
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year = {2009},
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month = jun,
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note = {[Online; accessed 21th June 2024]},
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url = {https://www.analog.com/media/en/technical-documentation/data-sheets/2274fb.pdf}
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}
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@misc{DatasheetLTC626810,
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title = {{Datasheet LTC6268-10 - 4GHz Ultra-Low Bias Current FET Input Op Amp}},
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year = {2015},
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month = feb,
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note = {[Online; accessed 21th June 2024]},
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url = {https://www.analog.com/media/en/technical-documentation/data-sheets/626810f.pdf}
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}
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@misc{DatasheetADA4817,
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title = {{Datasheet ADA4817 - Low Noise, 1 GHz FastFET Op Amps}},
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year = {2008},
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month = oct,
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note = {[Online; accessed 21th June 2024]},
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url = {https://www.analog.com/media/en/technical-documentation/data-sheets/ADA4817-1_4817-2.pdf}
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}
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@misc{DatasheetLMP7721,
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title = {{Datasheet LMP7721 - 3-Femtoampere Input Bias Current Precision Amplifier}},
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year = {2014},
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month = dec,
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note = {[Online; accessed 21th June 2024]},
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url = {https://www.ti.com/lit/ds/symlink/lmp7721.pdf}
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}
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@misc{SierraReduceCapacitances,
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title = {{How to reduce parasitic capacitance in PCB layout}},
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year = {2021},
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month = feb,
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note = {[Online; accessed 10th June 2024]},
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url = {https://www.protoexpress.com/blog/how-to-reduce-parasitic-capacitance-pcb-layout/}
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}
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@misc{AltiumReduceCapacitance,
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title = {{How to Reduce Parasitic Capacitance in a PCB Layout}},
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author = {{Zachariah Peterson }},
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year = {2022},
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month = mar,
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note = {[Online; accessed 10th June 2024]},
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url = {https://resources.altium.com/p/how-reduce-parasitic-capacitance-pcb-layout}
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}
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@misc{AltiumLeakages,
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title = {{PCB Leakage Current and Breakdown in High Voltage Design}},
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author = {{Zachariah Peterson}},
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year = {2020},
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month = jan,
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note = {[Online; accessed 3rd June 2024]},
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url = {https://resources.altium.com/p/pcb-leakage-current-and-breakdown-in-high-voltage-design}
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}
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@article{Yang:21,
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author = {Jinqing Yang and Minjie Wan and Weixian Qian and Kan Ren and Dongming Lu and Jun Zhang and Guohua Gu and Qian Chen},
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journal = {Appl. Opt.},
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keywords = {Avalanche photodiodes; Fiber optic gyroscopes; Optical signals; Phase compensation; Photodetectors; Photodiodes},
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number = {31},
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pages = {9748--9756},
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publisher = {Optica Publishing Group},
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title = {Bandwidth extension method based on the field-shunting effect in a high-gain photoelectric receiver circuit},
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volume = {60},
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month = {Nov},
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year = {2021},
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url = {https://opg.optica.org/ao/abstract.cfm?URI=ao-60-31-9748},
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doi = {10.1364/AO.442413},
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abstract = {In the high-gain photoelectric receiver circuit, the method based on the field-shunting effect is applied to improve the bandwidth of the transimpedance amplifier. This method is implemented by adding a ground trace under the gain resistor, which reduces the parasitic capacitance of the gain resistor and thus increases the bandwidth. To obtain the specific impact of this method on bandwidth, a series of simulations are carried out, including electromagnetic simulations of a three-dimensional structure of circuit gain part and simulation program with integrated circuit emphasis (SPICE) simulations of the high-gain voltage-current feedback transimpedance amplifier. Finally, the optimal simulation result shows that selecting a 1206 size chip fixed resistor and setting the ground trace width to 1.1 mm can greatly reduce the influence of resistor parasitic effects on the circuit, thereby achieving the best performance of bandwidth extension. Further, the comparative experiment also verifies the effectiveness of the method for bandwidth enhancement.},
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} |