EL4094 Просмотр технического описания (PDF) - Intersil
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EL4094 Datasheet PDF : 12 Pages
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EL4094
supply voltage nor output loading, at least down to 150Ω. For
settling to 0.1%, however, it is best to not load the output
heavily and to run the EL4094 on the lowest practical supply
voltages, so that thermal effects are minimized.
Gain Control Inputs
The gain control inputs are differential and may be biased at
any voltage as long as VGAIN is less than 2.5V below V+ and
3V above V-. The differential input impedance is 5.5kΩ, and
the common-mode impedance is more than 500kΩ. With
zero differential voltage on the gain inputs, both signal inputs
have a 50% gain factor. Nominal calibration sets the 100%
gain of VINA input at +0.5V of gain control voltage, and 0% at
-0.5V of gain control. VINB’s gain is complementary to that of
VINA; +0.5V of gain control sets 0% gain at VINB and -0.5V
gain control sets 100% VINB gain. The gain control does not
have a completely abrupt transition at the 0% and 100%
points. There is about 10mV of “soft” transfer at the gain
endpoints. To obtain the most accurate 100% gain factor or
best attenuation at 0% gain, it is necessary to overdrive the
gain control input by 30mV or more. This would set the gain
control voltage range as -0.565V to +0.565V, or 30mV
beyond the maximum guaranteed 0% to 100% range. In fact,
the gain control inputs are very complex. Here is a
representation of the terminals:
FIGURE 1. REPRESENTATION OF GAIN CONTROL
INPUTS VG AND /VG
For gain control inputs between ±0.5V (±90µA), the diode
bridge is a low impedance and all of the current into VG flows
back out through/VG. When gain control inputs exceed this
amount, the bridge becomes a high impedance as some of
the diodes shut off, and the VG impedance rises sharply
from the nominal 5.5KΩ to about 500KΩ. This is the
condition of gain control overdrive. The actual circuit
produces a much sharper overdrive characteristic than does
the simple diode bridge of this representation.
The gain input has a 20MHz -3dB bandwidth and 17ns
risetime for inputs to ±0.45V. When the gain control voltage
exceeds the 0% or 100% values, a 70ns overdrive recovery
transient will occur when it is brought back to linear range. If
quicker gain overdrive response is required, the Force
control inputs of the EL4095 can be used.
Output Loading
The EL4094 does not work well with heavy capacitive loads.
Like all amplifier outputs, the output impedance becomes
inductive over frequency resonating with a capacitive load.
The effective output inductance of the EL4094 is about
350nH. More than 50pF will cause excessive frequency
response peaking and transient ringing. The problem can be
solved by inserting a low-value resistor in series with the
load, 22Ω or more. If a series resistance cannot be used,
then adding a 300Ω or less load resistor to ground or a
“snubber” network may help. A snubber is a resistor in series
with a capacitor, 150Ω and 100pF being typical values. The
advantage of a snubber is that it does not draw DC load
current.
Unterminated coaxial line loads can also cause resonances,
and they should be terminated either at the far end or a
series back-match resistor installed between the EL4094
and the cable.
The output stage can deliver up to 140mA into a short-circuit
load, but it is only rated for a continuous 35mA. More
continuous current can cause reliability problems with the
on-chip metal interconnect. Video levels and loads cause no
problems at all.
Noise
The EL4094 has a very simple noise characteristic: the
output noise is constant (40nV/√Hz wideband) for all gain
settings. The input-referred noise is then the output noise
divided by the gain. For instance, at a gain of 50% the input
noise is 40nV/√Hz/0.5, or 80nV/√Hz.
Bypassing
The EL4094 is fairly tolerant of power-supply bypassing, but
best multiplier performance is obtained with closely
connected 0.1µF ceramic capacitors. The leaded chip
capacitors are good, but neither additional tantalums nor
chip components are necessary. The signal inputs can
oscillate locally when connected to long lines or
unterminated cables.
Power Dissipation
Peak die temperature must not exceed 150°C. At this
temperature, the epoxy begins to soften and becomes
unstable, chemically and mechanically. This allows 75°C
internal temperature rise for a 75°C ambient. The EL4094 in
the 8-pin PDIP package has a thermal resistance of 87°/W,
and can thus dissipate 862mW at a 75°C ambient
temperature. The device draws 17mA maximum supply
current, only 510mW at ±15V supplies, and the circuit has no
dissipation problems in this package.
The SO-8 surface-mount package has a 153°/W thermal
resistance with the EL4094, and only 490mW can be
dissipated at 75°C ambient temperature. The EL4094 thus
cannot be operated with ±15V supplies at 75°C in the
surface-mount package; the supplies should be reduced to
8
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