English
Language : 

LMH6321_07 Datasheet, PDF (15/22 Pages) National Semiconductor (TI) – 300mA High Speed Buffer with Adjustable Current Limit
FIGURE 2. 50Ω Coaxial Cable Driver with Dual Supplies
20138628
For values of capacitors in the 10 μF to 100 μF range, ce-
ramics are usually larger and more costly than tantalums but
give superior AC performance for bypassing high frequency
noise because of their very low ESR (typically less than 10
MΩ) and low ESL.
LOAD IMPEDANCE
The LMH6321 is stable under any capacitive load when driv-
en by a 50Ω source. As shown by the Overshoot vs. Capac-
itive Load graph in the Typical Performance Characteristics,
worst case overshoot is for a purely capacitive load of about
1 nF. Shunting the load capacitance with a resistor will reduce
the overshoot.
SOURCE INDUCTANCE
Like any high frequency buffer, the LMH6321 can oscillate
with high values of source inductance. The worst case con-
dition occurs with no input resistor, and a purely capacitive
load of 50 pF, where up to 100 nH of source inductance can
be tolerated. With a 50Ω load, this goes up to 200 nH. How-
ever, a 100Ω resistor placed in series with the buffer input will
ensure stability with a source inductances up to 400 nH with
any load.
OVERVOLTAGE PROTECTION
(Refer to the simplified schematic in Figure 1).
If the input-to-output differential voltage were allowed to ex-
ceed the Absolute Maximum Rating of 5V, an internal diode
clamp would turn on and divert the current around the com-
pound emitter followers of Q1/Q3 (D1 – D11 for positive
input), or around Q2/Q4 (D2 – D12 for negative inputs). With-
out this clamp, the input transistors Q1 – Q4 would zener,
thereby damaging the buffer.
To limit the current through this clamp, a series resistor should
be added to the buffer input (see R1 in Figure 2). Although the
allowed current in the clamp can be as high as 5 mA, which
would suggest a 2 kΩ resistor from a 15V source, it is rec-
ommended that the current be limited to about 1 mA, hence
the 10 kΩ shown.
The reason for this larger resistor is explained in the following:
One way that the input/output voltage differential can exceed
the Abs Max value is under a short circuit condition to ground
while driving the input with up to ±15V. However, in the
LMH6321 the maximum output current is set by the pro-
grammable Current Limit pin (CL). The value set by this pin is
guaranteed to be accurate to 5 mA ±5%. If the input/output
differential exceeds 5V while the output is trying to supply the
maximum set current to a shorted condition or to a very low
resistance load, a portion of that current will flow through the
clamp diodes, thus creating an error in the total load current.
If the input resistor is too low, the error current can exceed the
5 mA ±5% budget.
BANDWIDTH AND STABILITY
As can be seen in the schematic of Figure 2, a small capacitor
is inserted in parallel with the series input resistors. The rea-
son for this is to compensate for the natural band-limiting
effect of the 1st order filter formed by this resistor and the input
capacitance of the buffer. With a typical CIN of 3.5 pF
(Figure 2), a pole is created at
fp2 = 1/(2πR1CIN) = 4.5 MHz
(1)
This will band-limit the buffer and produce further phase lag.
If used in an op amp-loop application with an amplifier that
has the same order of magnitude of unity gain crossing as
fp2, this additional phase lag will produce oscillation.
The solution is to add a small feed-forward capacitor (phase
lead) around the input resistor, as shown in Figure 2. The
value of this capacitor is not critical but should be such that
the time constant formed by it and the input resistor that it is
in parallel with (RIN) be at least five times the time constant of
RINCIN. Therefore,
C1 = (5RIN/R1)(CIN)
(2)
from the Electrical Characteristics, RIN is 250 kΩ.
In the case of the example in Figure 2, RINCIN produces a
time-constant of 870 ns, so C1 should be chosen to be a min-
imum of 4.4 μs, or 438 pF. The value of C1 (1000 pF) shown
in Figure 2 gives 10 μs.
15
www.national.com