Title :
Multi-Phase 1 GHz Voltage Doubler Charge Pump in 32 nm Logic Process
Author :
Somasekhar, Dinesh ; Srinivasan, Balaji ; Pandya, Gunjan ; Hamzaoglu, Fatih ; Khellah, Muhammad ; Karnik, Tanay ; Zhang, Kevin
Author_Institution :
Intel Corp., Hillsboro, OR, USA
fDate :
4/1/2010 12:00:00 AM
Abstract :
A multi-phase 1 GHz charge pump in 32 nm logic process demonstrates a compact area (159 × 42 ¿m2) for boosting supply voltage from twice the threshold voltage (2 Vth) to 3-4 Vth. Self contained clocking with metal-finger flying capacitors enable embedding voltage boost functionality in close proximity to digital logic for supplying low current Vmin requirement of state elements in logic blocks. Multi-phase operation with phase separation of the order of buffer delays avoids the need for a large storage reservoir capacitor. Special configuration of the pump stages to work in parallel enables a fast (5 ns) output transition from disable to enable state. The multi-phase pump operated as a 1 V to 2 V doubler with >5 mA output capability addresses the need for a gated power delivery solution for logic blocks having state-preservation Vmin requirements.
Keywords :
CMOS logic circuits; CMOS memory circuits; SRAM chips; charge pump circuits; phase separation; voltage multipliers; CMOS logic technology; SRAM cell; buffer delays; digital logic; disable state; enable state; logic blocks; metal-finger flying capacitors; multi-phase voltage doubler charge pump; output transition; phase separation; self contained clocking; size 32 nm; state elements; storage reservoir capacitor; threshold voltage; voltage 1 V to 2 V; Boosting; Buffer storage; Capacitors; Charge pumps; Clocks; Current supplies; Delay; Logic; Reservoirs; Threshold voltage; Charge pumps; Vccmin; Vmin; multi-phase; voltage doubler;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2010.2042253
