Design-Oriented Modeling of TSV Substrate Noise Coupling to Ring VCOs
For 3D-IC and chiplet designers, this work provides a practical methodology to predict TSV noise impact on RF circuits, though it is an incremental extension of existing coupling models.
This paper presents a compact analytical model for TSV-induced substrate noise coupling and validates it on a 22 nm FD-SOI ring VCO, showing that a 1 GHz, 0.5 Vpp aggressor induces a -35.2 dBc sideband spur, with a low-pass coupling response from -20.2 dBc at 500 MHz to -33.1 dBc at 2 GHz.
Through-silicon vias (TSVs) enable dense vertical interconnects in 3D-IC and chiplet systems, but their metal-oxide-silicon structure introduces significant parasitic coupling paths that can degrade the spectral purity of sensitive RF blocks. This paper presents a compact, design-oriented methodology for assessing TSV-induced substrate noise in mixed-signal circuits. We derive a closed-form analytical three-port RLGC macromodel for a Signal-Ground TSV pair that explicitly exposes the substrate node. The methodology is validated using a three-stage Ring VCO designed in a 22 nm FD-SOI technology, where specific RF devices from the process design kit (PDK) provide direct access to the transistor substrate terminals for controlled noise injection. Multi-tone Harmonic Balance simulations in Spectre RF quantify the impact of TSV aggressors on the oscillator's output spectrum. The results indicate that an aggressor of 1 GHz, 0.5 V$_{pp}$ induces a primary sideband spur of -35.2 dBc. Sensitivity characterization reveals that the magnitude of these sideband spurs increases monotonically with the aggressor amplitude. Furthermore, frequency sweeps demonstrate a low-pass coupling response, where the induced spur magnitude decreases from -20.2 dBc at 500 MHz to -33.1 dBc at 2 GHz.