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Calculate the output (junction) capacitance for the following 32 nm CMOS gates. For an NMOS assume: Cj = 25 fF/nm2 and Cisw = 2.6 fF/nm, and for PMOS assume: Cj = 20 fF/nm2 and Cjsw = 2.2 fF/nm. Use LD = 4 nm. Assume minimum length transistors, and no shared diffusion between transistors. a) Inverter: PMOSW = 8 λ, NMOSW = 4 λ b) 2-input NOR: PMOS W = 8 λ, NMOSW = 10 λ

Calculate the output (junction) capacitance for the following 32 nm CMOS gates. For an NMOS assume: Cj = 25 fF/nm2 and Cisw = 2.6 fF/nm, and for PMOS assume: Cj = 20 fF/nm2 and Cjsw = 2.2 fF/nm. Use LD = 4 nm. Assume minimum length transistors, and no shared diffusion between transistors. a) Inverter: PMOSW = 8 λ, NMOSW = 4 λ b) 2-input NOR: PMOS W = 8 λ, NMOSW = 10 λ

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Calculate the output (junction) capacitance for the following 32 n m CMOS gates. For an NMOS assume: C j = 25 f F / n m 2 and C i s w = 2.6 f F / n m , and for PMOS assume: C j = 20 f F / n m 2 and C j s w = 2.2 f F / n m . Use L D = 4 n m . Assume minimum length transistors, and no shared diffusion between transistors. a) Inverter: P M O S W = 8 λ , N M O S W = 4 λ b) 2-input NOR: PMOS W = 8 λ , N M O S W = 10 λ

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