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HP 8340b Operating Instructions

HP 8340b
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Therefore,
modulation
inputs
with
no
dc
component
do
not
cause
the
POWER
dBm
display
to
shift,
and
this
displayed
number
represents
the
power
of
the
unmodulated
carrier.
A
power
meter
measure¬
ment
of
output
power
changes
with
modulation
present,
increasing
1.76
dB
with
100%
deep,
sinusoidal,
no
dc
component
modulation.
Attempted
deep
modulation
at
high
rates
causes
the
POWER
dBm
display
to
shift,
because
the
AM
system
canot
keep
up
with
the
input
and
the
resultant
high
distortion
causes
a
shift
in
average
power.
Dynamic
Range
As
mentioned
previously
with
reference
to
Figure
3-29,
the
AM
input
is
an
ALC
input
which
does
not
differ
in
its
effect
from
a
power
entry
input.
Therefore,
the
AM
system
is
limited
by
where
it
is
operating
within
the
ALC
range.
In
the
normal
“coupled”
operating
mode,
the
ALC
will
likely
be
set
between
—10
dBm
and
0
dBm
(see
the
preceeding
pertinent
section).
Depending
on
frequency,
the
maximum
available
power
is
between
+1
dBm
(HP
8340B)
and
+21
dBm.
The
ALC
is
reasonably
accurate
down
to
—20
dBm,
and
typically
is
well
behaved
to
about
—30
dBm.
Expressing
the
desired
modulation
depth
in
dB’s
will
let
the
user
determine
the
range
over
which
the
ALC
loop
is
being
exercised.
Thirty
percent
AM
creates
excursions
of
+2.3
dB
to
—3.1
dB,
relative
to
the
quiescent
level;
50%:
+3.5
dB
to
-6.0
dB;
90%:
+5.6
dB
to
-20.0
dB.
(The
above
assumes
a
modulation
waveform
symmetric
about
0
V.)
For
example:
Output
power
=
—19.0
dBm.
In
coupled
mode
this
results
in
ATTN
=
—10
dB,
ALC
=
—9.0
dBm.
Ninety
percent
modulation
depth
results
in
an
ALC
range
of
—9.0
dBm
+
5.6
dB
=
—3.4
dBm
maximum,
9.0
dBm
—20
dB
=
29.0
dBm
minimum.
This
is
within
the
ALC
limits
at
any
frequency
but
the
distortion
may
suffer
due
to
operation
below
—20
dBm.
Using
decoupled
operation
the
desired
output
power
may
be
set
with
ATTN
=
20DB,
ALC
=
+1.0
dBm.
Then
90%
depth
swings
the
ALC
from
+6.6
dBm
to
-19.0
dBm.
The
distortion
will
probably
be
better
under
these
conditions
if
+6.6
dBm
is
available
at
the
frequency
of
interest.
At
some
frequencies
+20
dBm
is
available,
and
setting
ATTN
=
-30
dB,
ALC
=
+11.0
dBm
may
give
a
further
improvement,
especially
if
attempting
greater
than
90%
depth.
For
minimum
distortion
the
ALC
should
be
used
between
—15
dBm
and
+15
dBm,
but
not
within
2
dB
of
maximum
available
power.
On
HP
8340B’s
operating
above
23
GHz
the
available
output
power
is
limited:
+1
dBm
specified,
+3
dbm
typical.
If
the
ALC
is
set
close
to
0
dBm,
the
headroom
available
for
modulation
is
limited.
Three
dB
excess
power
allows
a
maximum
of
40%
peak
modulation.
The
available
depth
is
not
affected.
Decoupled
mode
may
be
used
to
advantage
here.
For
example,
in
coupled
mode
an
output
power
of
—10
dBm
results
in
ATTN
=
10
dB,
ALC
=
0.0
dBm.
Using
decoupled
mode,
setting
ATTN
=
0
dB,
ALC
=
—10.0
dBm
gives
plenty
of
headroom
with
enough
depth
available
for
90%
symmetric
AM.
Available
power
can
be
maximized
at
a
CW
frequency
by
using
the
PEAK
function.
Bandwidth
for
AM
Applicaitons
The
small
signal
AM
bandwidth
extends
from
dc
to
a
-3
dB
frequency
of
at
least
100
kHz.
The
actual
upper
limit
is
a
direct
function
of
the
loop
gain
of
the
ALC
loop.
The
primary
variable
in
the
loop
gain
is
the
gain
of
the
modulator,
which
varies
with
both
power
level
and
frequency.
In
general,
the
modulator
gain
deviates
the
most
from
nominal
at
power
levels
just
below
maximum,
although
at
some
frequen¬
cies
the
gain
will
deviate
at
lower
power
levels
because
of
non-optimum
YTM
bias.
The
latter
is
only
a
problem
above
7.0
GHz.
The
small
signal
(30%
depth)
bandwidth
may
be
expected
to
vary
between
100
kHz
and
300
kHz
as
power
and/or
frequency
is
changed.
The
bandwidth
for
greater
depths
is
less.
At
90%
depth
expect
about
1/2
the
30%
bandwidth.
The
above
bandwidths
are
for
internal
leveling.
When
external
leveling
with
a
crystal
detector
in
its
square
law
region
the
bandwidth
is
1/2
of
the
internally
leveled
bandwidth
at
the
same
frequency
and
output
power
level.
With
a
crystal
detector
in
its
linear
region,
the
bandwidth
is
1/4.
The
external
leveling
system
is
designed
to
provide
linear
AM
when
using
a
square
law
detector.
The
RF
output
follows
this
law:
Vout
=
Vo
X
(Vin
+
1).
HP
8340B/41B
Operating
Information
3-109

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HP 8340b Specifications

General IconGeneral
BrandHP
Model8340b
CategoryInverter
LanguageEnglish

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