I. Introduction

Spatial signal processing in multiantenna receivers offers not only higher received power and signal-to-noise ratio (SNR) because of a higher number of reception antennas but also enables spatial diversity and simultaneous communication with multiple devices. For the past several years, there have been many works on integrated multiantenna receivers. Approximating the time delay with a phase shift element is the basis of large portion of these works [1]–[8]. However, the frequency-dependent approximation of true-time-delay (TTD) with a phase-shift element results in beam-squinting in the angular domain [9] and limited fractional bandwidth (BW) in the frequency domain [10]. Using TTD with the spatial signal processor (SSP) results in frequency-uniform processing, which translates to beam-squinting free beamforming. The beam-squint issue has its parallel in beam-nulling arrays handling wide modulated bandwidths. The state-of-the-art phase-shifter-based arrays targeting beam-nulling [1], [4], [11]–[15] has limited rejection capability toward wideband interference because the array gain variation at different frequency components makes it hard to steer a deep null toward interference. For multiantenna receivers, it results in interference leakage and significantly higher dynamic range requirements for the baseband (BB) and the ADC [16].