An Advanced Full Adder Based Arithmetic Logic Unit (ALU) Using Low-Temperature Poly-Si Oxide TFTs

This work presents a full adder-based CMOS arithmetic logic unit (ALU) made of p-type low-temperature poly-Si (LTPS) and n-type amorphous indium–gallium–zine oxide (a-IGZO) thin-film transistors (TFTs). The p-type TFT performs the maximum field-effect mobility ( $\mu $ ) of 70 cm2/V $\cdot $ s and subthreshold swing (SS) of 0.6 V/decade. The n-type TFT exhibits the mobility of 10.8 cm2/V $\cdot $ s and SS of 0.4 V/decade. The six-clock signals and three-supply voltage are employed to obtain a full output swing from high output voltage to low output voltage, where three clocks are used for selection operation mode and three clocks are input signals. For input swing of −15 to 15 V, constant high voltage of 15 V, and low voltage of 0 V, the proposed ALU shows a full output swing of 0–15 V with a fast fall time of $32~\mu \text{s}$ and a rise time of $64~\mu \text{s}$ in the worst situation. The proposed ALU is fully cascadable with five functionalities. The first LTPO CMOS-based ALU circuit demonstrates the potentiality of this emerging technology in logic operation.