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access icon free Analysis and design of wideband active power splitter with interleaf transmission line topology

© The Institution of Engineering and Technology
Received 05/12/2018, Accepted 11/09/2019, Revised 13/05/2019, Published 01/10/2019

This article proposes a new wideband active power splitter design where the gain cells along the input transmission line are arranged in interleaf rather than the conventional parallel style, thus the circuit's high-frequency performance can be greatly improved. Both theoretical analysis and circuit simulation have been carried out; as a demonstration, parallel and interleaf active power splitters are designed using 0.1 μm GaAs pseudo-morphic heterostructure field effect transistors (GaAs pHEMT) process and measured on-wafer. The results clearly indicate the superiority of the interleaf topology. A 40 GHz interleaf active power splitter in 90 nm complementary metal-oxide-semiconductor (CMOS) is then presented where the magnitude and phase imbalance between the two output ports are 0.15 dB and 2.6° at 20 GHz, and 0.16 dB and 14° at 40 GHz. The output-port isolation is better than 30 dB across the whole frequency range.

Inspec keywords: HEMT integrated circuits; transmission lines; III-V semiconductors; gallium arsenide; field effect MIMIC; network topology; CMOS integrated circuits

Other keywords: frequency 20.0 GHz; size 0.1 mum; GaAs pHEMT process; interleaf topology; frequency 40.0 GHz; high-frequency performance; CMOS integrated circuit; interleaf active power splitter; GaAs; interleaf transmission line topology; circuit simulation; output-port isolation; wideband active power splitter; size 90.0 nm

Subjects: Network topology; CMOS integrated circuits; Other field effect integrated circuits; Microwave integrated circuits

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