This paper presents the implementation of a 31-tap FIR Hilbert transform digital filter chip used in the digital-IF receivers, to confirm the effectiveness of our new design method. Our design method that we previously reported is based on a computation sharing multiplier using a new horizontal and vertical common subexpression techniques. A 31-tap FIR Hilbert transform digital filter was implemented and fabricated in 0.35 µm CMOS standard cell library. The chip's core contains approximately 33k transistors and occupies 0.86 mm2. The chip also has an operating speed of 70 MHz over. The implementation results show that the proposed Hilbert transformer has a smallest cost factor and so that is a high performance filter.

An adiabatic logic is a technique to design low power digital VLSI's. This paper describes the design and VLSI implementation of a multiplier using a two phase drive adiabatic dynamic CMOS logic (2PADCL) circuit. Circuit operation and performance have been evaluated using a 44-bit 2PADCL multiplier fabricated in a 1.2 µm CMOS process. The experimental results show that the multiplier was operated with clock frequencies 800 kHz. The total power dissipation of the 44-bit 2PADCL multiplier was also 5.19 mW at the 1.5 V DC power supply voltage.