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= Research on existing front-end solutions
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= Research on existing front-end solutions
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To gather more knowledge about how a typical oscilloscope performs analog-signal processing, the results of the state-of-the-art research (see https://es.technikum-wien.at/openlab/openlab_wiki/wikis/SOTA_osci[State of the Art Research (SOTA) (Oscilloscope)]) were further analyzed.
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To gather more knowledge about how a typical oscilloscope performs analog-signal processing, the results of the state-of-the-art research (see https://es.technikum-wien.at/openlab/openlab_wiki/wikis/SOTA_osci[State of the Art Research (Oscilloscope)]) were further analyzed.
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For this purpose, only projects with access to the schematic of the hardware provided enough information.
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For this purpose, only projects with access to the schematic of the hardware provided enough information.
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The three most interesting projects were selected for deeper investigation.
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The three most interesting projects were selected for deeper investigation.
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The XMEGA Xminilab developed by Gabotronics [1], for example, designed a front-end which is capable of processing analog signals at a voltage range of -14V to +20V.
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The XMEGA Xminilab developed by Gabotronics [1], for example, designed a front-end which is capable of processing analog signals at a voltage range of -14V to +20V.
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