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RaMSiS WP3: Robust Design Technique. Tasks: 3.1 Statistical analysis and simulations for RF robustness 3.2 Mixed-signal integration and robustness enhancement. Mechanism of substrate noise coupling in mixed-signal SoC. 50. 40. (%). 30. Distribution. 20. 10. A. C. B. 0. 14. 16.
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RaMSiS WP3: Robust Design Technique Tasks: 3.1 Statistical analysis and simulations for RF robustness 3.2 Mixed-signal integration and robustness enhancement Mechanism of substrate noise coupling in mixed-signal SoC
50 40 (%) 30 Distribution 20 10 A C B 0 14 16 18 20 22 24 26 28 D Yield Gain(dB) WP3 Status on Task 3.1: • RF robustness enhancement through statistical analysis of chip-package co-design of RF circuits • Status: Case studies have been performed on 2.5/5.2GHz LNA design, one manuscript has been completed, which includes • a. Process variation model of IC devices and interconnection parameters • b. Process variation model of RF-chip package technologies • c. On-chip versus off-chip inductors (BPF) trade-offs • d. Statistical analysis and simulations were performed in Agilent-ADS A: Single-chip integrated LNA B: LNA on MCM-D package C: LNA on MCM-C Package D: LNA on MCM-L package
LNA2 LNA1 Noise Sensors VCO1 VCO2 Mixer1 Mixer2 Digital Noise Source WP3 Status on Task 3.2: • Studies of substrate noise coupling to critical RF circuits • Avoid of substrate coupling problem by careful frequency planning of RF circuits and the noise spectrum • Status: • A test chip has been designed and fabricated with both single-ended and differential circuits of LNAs, VCOs, and mixers; on-chip digital noise source and noise sensors are also designed; • Two experiments are in preparation: • a. Measuring the impact of substrate noise coupling to these critical RF circuits; • b. How to push the substrate noise peaks off the working frequencies of these critical circuits by for example allocating different decoupling capacitors