Chip Attenuator Steps 31.5 dB to 55 GHz (.PDF Download)

Nov. 30, 2018
Chip Attenuator Steps 31.5 dB to 55 GHz (.PDF Download)

Whether now as pSemi or formerly as Peregrine Semiconductor, the company has shown that its UltraCMOS silicon-on-insulator (SOI) semiconductor technology is quite capable of excellent electrical performance well into the millimeter-wave (mmWave) frequency range. Its latest demonstration is the model PE43508 digital step attenuator (DSA), a monolithic IC with 6-b digital control of a 31.5-dB attenuation range in 0.5- and 1.0-dB steps across the impressively wide frequency range of 9 kHz to 55 GHz.

With such high frequency coverage, this tiny step attenuator is well-suited for precision level control in various automotive and 5G mmWave circuits and test equipment. It maintains accurate attenuation across the attenuation and frequency ranges, with low return loss and insertion loss. In addition, it changes attenuation levels with 330-ns switching speed.

Model PE43508 is a 50-Ω IC DSA that can maintain 0.5-dB (or 1.0-dB) monotonicity across its 31.5-dB (or 31.0-dB) attenuation range. And it changes attenuation levels without positive glitches throughout the frequency range. As a result, no power spikes or attenuation errors occur even during constantly changing attenuation, as in an automatic-test-equipment (ATE) applications or satellite-communications (satcom) terminals. It’s a high-performance companion to the company’s two 60-GHz UltraCMOS switches (models PE42525 and PE426525) for mmWave circuit and system applications.

Accurate Attenuation

The DSA’s RF performance is superior even across the wide frequency range. It’s aided by the company’s HaRP technology to achieve reduced gate lag and low drift in loss characteristics—the DSA suffers relatively low insertion and return losses through 55 GHz. For example, typical insertion loss is 4.7 dB from 26.5 to 45.0 GHz, 5.3 dB from 45.0 to 50.0 GHz, and 5.9 dB from 50 to 55 GHz. Typical return loss is 16 dB from 13.0 to 26.5 GHz, 14 dB from 26.5 to 45.0 GHz, and 13 dB from 45 to 55 GHz. The worst-case attenuation error is within +10% to +12% of a reading at the highest frequencies. The attenuator has a typical third-order input intercept point (IIP3) of +50 dBm