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1 Figure 7.27 A simple but inefficient approach for differential to single-ended conversion. Differential-to-Single-Ended Conversion Multistage Amplifiers.

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Presentation on theme: "1 Figure 7.27 A simple but inefficient approach for differential to single-ended conversion. Differential-to-Single-Ended Conversion Multistage Amplifiers."— Presentation transcript:

1 1 Figure 7.27 A simple but inefficient approach for differential to single-ended conversion. Differential-to-Single-Ended Conversion Multistage Amplifiers

2 2 Figure 7.28 (a) The active-loaded MOS differential pair. (b) The circuit at equilibrium assuming perfect matching. (c) The circuit with a differential input signal applied, neglecting the r o of all transistors. The Active-Loaded MOS Differential Pair

3 3 Figure 7.29 Determining the short-circuit transconductance G m ; i o / v id of the active-loaded MOS differential pair. Transconductance of the Active-Loaded MOS Pair (Short-Circuit)

4 4 Figure 7.30 Circuit for determining R o. The circled numbers indicate the order of the analysis steps. Output Resistance of the Active-Loaded MOS Pair

5 5 Figure 7.40 Two-stage CMOS op-amp configuration. A Two-Stage CMOS Op Amp

6 6 Figure 7.43 A four-stage bipolar op amp. A Four-Stage Bipolar Op Amp

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