Linear-in-dB RMS Power Detector Spans 100 MHz to 70 GHz


The RF signal chain is defined by power rather than voltage or current. Providing root-mean-square (RMS) measurement of this power over a wide dynamic range is critical circuit and system requirement. Fortunately, today’s ICs feature frequency range and performance capabilities that continue to extend to meet the needs of the ever-growing electromagnetic spectrum of interest.

Among the latest offerings is the LTC5597 RMS Power Detector from Analog Devices. As with so many tightly focused RF parts, it implements one primary function and does it well. This 8-lead device in a diminutive 2- × 2-mm package (Fig. 1) boasts a fully specified operating span of 100 MHz to 70 GHz with a 35-db “linear” dynamic range. Its 28.5-mV/dB logarithmic slope has a typical error of less than ±1 dB. Among its other specifications are ±2-dB flat response from 100 MHz to 60 GHz.

1. The functionality and pinout of the LTC5597 are simple, which is commensurate with the role it plays in the RF signal chain.

The device is well-suited for measurement of waveforms with crest factor (CF) as high as 12 dB, including waveforms that exhibit a significant variation of the crest factor during measurement—an increasingly frequent scenario in today’s advanced-modulation environments. Such specifications and performance make it a good option for a wide range of applications, including but not limited to point-to-point microwave links, satellite communication links, instrumentation and measurement equipment, military radios, 5G/LTE/Wi-Fi wireless networks, RMS power measurement, and transmit power/receive gain control.

The averaging bandwidth can be externally adjusted using a capacitor to achieve higher accuracy along with lower output ripple. The 3.3 V draws just 33 mA (typical) while an enable pin switches the device between active-measurement mode and a low power shutdown mode.

As with most RF parts, designers prefer an abundance of charts and graphs on the datasheet. The comprehensive 22-page datasheet includes over two dozen graphs (Figure 2 is one example) plus tables showing performance, errors, and deviations across a wide array of factors including voltage, input power, temperature, and more.

2. Among the many performance graphs on the datasheet is this one quantifying the tight “linearity” of the output voltage versus input frequency over a wide range of power levels.2. Among the many performance graphs on the datasheet is this one quantifying the tight “linearity” of the output voltage versus input frequency over a wide range of power levels.

Designs also welcome (and expect) evaluation boards for these devices, even though their basic interconnection schematic is quite simple. The DC2932A ($600) provides a PCB layout that employs the recommended microstrip transmission-line structure and endpoint transitions (Fig. 3). (Note that the input impedance to LTC5597 is internally matched to 50 Ω.) Support for the demonstration circuit includes schematic, design, and integration files, and a user guide. 

3. The DC2932A evaluation board/demonstration circuit, which enables designers to exercise the LTC5597 RMS Power Detector IC, comes with full schematic, layout, and user guide.3. The DC2932A evaluation board/demonstration circuit, which enables designers to exercise the LTC5597 RMS Power Detector IC, comes with full schematic, layout, and user guide.

The LTC5597 is offered fully specified over the −40 to +105°C and −40 to +125C ranges; prices begin at $48.95 (1000+ pieces). More information on the LTC5597 is available on the datasheet; the evaluation board with its demonstration circuit is discussed here.



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