Computation sharing programmable FIR filter for low-power and high-performance applications

This paper presents a programmable digital finite-impulse response (FIR) filter for high-performance and low-power applications. The architecture is based on a computation sharing multiplier (CSHM) which specifically targets computation re-use in vector-scalar products and can be effectively used in the low-complexity programmable FIR filter design. Efficient circuit-level techniques, namely a new carry-select adder and conditional capture flip-flop (CCFF), are also used to further improve power and performance. A 10-tap programmable FIR filter was implemented and fabricated in CMOS 0.25-/spl mu/m technology based on the proposed architectural and circuit-level techniques. The chip's core contains approximately 130 K transistors and occupies 9.93 mm/sup 2/ area.     

Leakage current mechanisms and leakage reduction techniques in deep-submicrometer CMOS circuits

High leakage current in deep-submicrometer regimes is becoming a significant contributor to power dissipation of CMOS circuits as threshold voltage, channel length, and gate oxide thickness are reduced. Consequently, the identification and modeling of different leakage components is very important for estimation and reduction of leakage power, especially for low-power applications. This paper reviews various transistor intrinsic leakage mechanisms, including weak inversion, drain-induced barrier lowering, gate-induced drain leakage, and gate oxide tunneling. Channel engineering techniques including retrograde well and halo doping are explained as means to manage short-channel effects for continuous scaling of CMOS devices. Finally, the paper explores different circuit techniques to reduce the leakage power consumption.     

Diode-footed domino: a leakage-tolerant high fan-in dynamic circuit design style

A leakage-tolerant design technique for high fan-in dynamic logic circuits is presented. An NMOS transistor with gate and drain terminals tied together (diode) is added in series with the evaluation network of standard domino circuits. Due to the stacking effect, the leakage of the evaluation path significantly decreases, thereby improving the robustness of the circuit against deep-submicron subthreshold leakage and input noise. To improve the speed of the circuit, a current mirror is also employed in the evaluation network to increase the evaluation current. The proposed technique (diode-footed domino) exhibits considerable improvement in leakage and noise immunity as compared to the standard domino circuits. Simulation results of wide fan-in gates designed using Berkeley Predictive Technology Models of 70-nm technology demonstrate at least 1.9/spl times/ noise-immunity improvement at the same delay compared to the standard domino circuits. Dynamic comparators and multiplexers are designed using the diode-footed domino and conventional techniques to demonstrate the effectiveness of the proposed scheme in improving leakage-tolerance and performance of high fan-in circuits.