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Integrated CMOS 18V 240 μ A Charge Pump with Passive Level Shifters

Integrated CMOS 18V 240 μ A Charge Pump with Passive Level Shifters. Vratislav MICHAL, Denis COTTIN, Nicolas MARTY and Patrik ARNO STMicroelectronics, 12 rue Jules Horowitz, Grenoble, France vratislav.michal@st.com. Motivation – High power density.

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Integrated CMOS 18V 240 μ A Charge Pump with Passive Level Shifters

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  1. Integrated CMOS 18V 240μA Charge Pump with Passive Level Shifters Vratislav MICHAL, Denis COTTIN, Nicolas MARTY and Patrik ARNO STMicroelectronics, 12 rue Jules Horowitz, Grenoble, France vratislav.michal@st.com

  2. Motivation – High power density • Structures with low voltage vs. high voltage capacitors wikipedia Dickson charge pump with linear MOSFET in parallel with diode-wired MOSFET. 4-stage (x5 multiplier) • Small area •  Complicated switches driving  well-known active switches structures  low-denisty capacitors X

  3. Preferred architecture: dual phase voltage multiplier • Output power is delivered by one of complementary inputs VIN • Only small output capacitor (high-voltage) • Small CMID filters the voltage spikes in the active structure • First node delivered by the DC input voltage

  4. Active level shifter solution • Very high output voltage reached in ref [*] • Active switches driving rely on the floating active level shifters • High-voltage floating level shifters are difficult to design [*] A. Emiraet al. “All-pMOS 50-V charge pump using low voltage capacitors,” IEEE Tran. on ind. Electronics, Vol. 60, No. 10, 2013

  5. Single cell - Diodes replacement by the active switches • Complementary gate signals generated by the structure • Steady-state reached by the transistor diodes Pelliconi cell

  6. Final structure: Passive level shifter • Passive level shifters helps the fast propagation of the driving signals • Act as HP bypass for driving signal and LP link for DC voltage • Fast driving signals prevent energy loss in the charge-pump structure • FEEDFORWARD capacitor considerably increase the output power

  7. Final structure: simulation Internal nodes of Fig. 4 charge pump (upper phase). Lower phase is identical with 180° phase shift. The solid lines correspond to the floating nodes ① to ④ , whereas the dashed lines to the DC middle nodes M1-4. Simulation of the internal nodes of the charge pump (upper phase) without passive level shifter (R = 0).

  8. Capacitor Area Optimization • Capacitor are dominant silicon area contributor. • Capacitor distribution is not uniformacross CP stages. • Approximate analytical solution known in the literature. • It is impossible to cover all parasitic elements in the analytical capacitor area distribution. [*] A. Emiraet al. “All-pMOS 50-V charge pump using low voltage capacitors,” IEEE Tran. on ind. Electronics, Vol. 60, No. 10, 2013

  9. Capacitor Area Optimization (cont’d) • Optimization target: higher output current for given capacitor area CTOT • Set of equation can be written: • Leading to the capacitor parameters: • These equations can be inserted in the capacitor value property

  10. Capacitor Area Optimization results • Optimization is parametric simulation, accounting for all dominant parameters of the charge pump: • Target: higher output voltage for given output current: α = 1.7, β = 1.5 and γ = 2. The CP was connected in the open-loop with G_CTRL = 1V. Simulation done in the worst-case corner (CMIN, slow, 120°C with load current 260μA)

  11. 18V Output voltage control • Output voltage control is provided via charge control of the main (input) tank capacitor. • Tank capacitor is used in the input voltage doubler. Charging control

  12. Conclusion - Results UV photography 160nm CMOS High-voltage isolated NMOS with >20V breakdown voltage Obtained features Feedback control loop

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