The ADL5391 draws on three decades of experience in advanced analog multiplier products. It provides the same general mathematical function that has been field proven to provide an exceptional degree of versatility in function synthesis:
VW = α × (VX x VY)/1 V + VZ
The most significant advance in the ADL5391 is the use of a
new multiplier core architecture, which differs markedly from
the conventional form that has been in use since 1970. The
conventional structure that employs a current mode, translinear
core is fundamentally asymmetric with respect to the X and Y
inputs, leading to relative amplitude and timing misalignments
that are problematic at high frequencies. The new multiplier core
eliminates these misalignments by offering symmetric signal
paths for both X and Y inputs. The Z input allows a signal to be
added directly to the output. This can be used to cancel a carrier
or to apply a static offset voltage.
The fully differential X, Y, and Z input interfaces are operational
over a ±2 V range, and they can be used in single-ended fashion.
The user can apply a common mode at these inputs to vary
from the internally set VPOS/2 down to ground. If these inputs
are ac-coupled, their nominal voltage will be VPOS/2. These input
interfaces each present a differential 500 Ω input impedance up to
approximately 700 MHz, decreasing to 50 Ω at 2 GHz. The gain
scaling input, GADJ, can be used for fine adjustment of the gain
scaling constant (α) about unity.
The differential output can swing ±2 V about the VPOS/2
common-mode and can be taken in a single-ended fashion as
well. The output common mode is designed to interface directly
to the inputs of another ADL5391. Light dc loads can be ground
referenced; however, ac-coupling of the outputs is recommended
for heavy loads.
The ENBL pin allows the ADL5391 to be disabled quickly to a
standby mode. It operates off supply voltages from 4.5 V to 5.5 V
while consuming approximately 130 mA.
The ADL5391 is fabricated on Analog Devices, Inc. proprietary,
high performance, 65 GHz, SOI complementary, SiGe bipolar
IC process. It is available in a 16-lead, RoHS compliant, LFCSP
and operates over a −40°C to +85°C temperature range.
Evaluation boards are available.
Applications
-
Wideband multiplication and summing
- High frequency analog modulation
- Adaptive antennas (diversity/phased array)
- Square-law detectors and true rms detectors
- Accurate polynomial function synthesis
- DC capable VGA with very fast control
