Models 900CT & 900BT
Model 900 Series
Single Channel –
Certified
Initial Setup Procedure
Initial Setup
Select desired operating voltage 115 Vac
or 230 Vac. See note "Q" on Page 5.
Set the OFFSET control for a zero-volt
reading on the scope or DVM.
The B, C and D switches combined can
select base corner frequency values
ranging from 1 to 499 Hz in 1 Hz steps
with switch weightings as just described.
Set the POWER ON/OFF Switch to ON.
A continuously lit POWER lamp indicates
proper internal DC voltages, an essential
requirement for battery-powered models.
Subsequent changes of CORNER
FREQUENCY and GAIN control settings
will introduce a small dc output offset,
which should be zeroed for critical
applications.
The accuracy of the corner frequency is
improved by selecting the largest possible
base frequency and down scaling by the
MULTIPLIER. The greatest accuracy is
obtained with the largest base 400, and
the 0.1X MULTIPLIER switch setting.
Allow the instrument
a
three-minute
warm-up period to achieve thermal
equilibrium.
Leaving all other controls unchanged, set
the Input Switch to (A-B) and apply a
5Vdc signal simultaneously to input BNCs
(A) and (B). The voltage measured at the
OUT BNC should be 5 - 5 = 0 Vdc. This
To perform initial adjustment and/or
operational testing, set the remaining front
panel controls as follows:
Relative accuracy of selected 40 Hz
actual corner frequency for different
multiplier switch settings.
a)
The
three
base
CORNER
and the
completes
preliminary
test
and
FREQUENCY
switches
adjustment.
BASE
FREQ
Msd
C
0
4
0
X
MULT
Lsd
E
0.1X
1X
RELATIVE
TUNING ACCURACY
MULTIPLIER to the desired corner
frequency…
Corner Frequency Selection
To select a corner frequency, simply set
the CORNER FREQUENCY switches and
the MULTIPLIER switch for the desired
numerical value.
B
4
0
0
D
0
0
4
b) The OFFSET control to approximately
mid-range…
GREATEST
LESS
LEAST
10X
c) The GAIN switch to the desired value…
d) The BYPASS switch to OUT…
The CORNER FREQUENCY switch
weightings follow standard decimal
positional conventions.
The differential input
The instrument input utilizes a differential
input amplifier to reject prevalent forms of
electrical interference, while presenting
desirable input characteristics to the
e) The INPUT switch to ground ( ).
Connect a dc-coupled oscilloscope, of
vertical sensitivity 10mV/CM or better, or
a digital voltmeter (DVM) to the instrument
front panel BNC connector labeled OUT.
signal source requiring filtering.
The
differential input configuration is ideal for
measuring the difference between two
values rather than the values themselves.
Bridge circuits utilizing strain gages,
Circuit model illustrating the relationship between a filter’s differential
input and amplifier and external signal and error sources.
thermocouples and
a variety of other
types of transducers generate differential
full-scale output voltages in the order of
millivolts that are often superimposed
upon volt-level reference and noise
values.
DIFFERENTIAL
INPUT AMPLIFIER
INPUT SIGNAL AND
NOISE VOLTAGE SOURCES
The importance of CMRR
In actual system environments, each
signal and power return conductor can
A
R
SA
*
(+)
GAIN = K
generate
an
interference
voltage
V
OUT
A
+
-
RCM+
RD
proportional to the net conductor
resistance and the electrical current level.
Any such interference voltages appear as
common mode signals to the amplifier,
and are rejected as such.
V
CM
FILTER/
BYPASS
DIFF
AMP
OUTPUT
AMPLIFER
VB
RCM-
SIGNAL
COMMON
(-)
RSB
Vo = K(VA - VB) + Vcm/CMRR : WHERE
K = 1, 10 AND 10 FOR GAIN SETTINGS
B
OF 0, 10 AND 20dB RESPECTIVELY.
SEE TEXT FOR REMAINING TERMS.
+Vs
COM
-Vs
COUPLED
POWER LINE
NOISE VOLTAGE
DENOTES FRONT PANEL ACCESS
*
(-)
(+)
AC POWER SUPPLY
OR
VP
INTERNAL BATTERIES
SIGNAL
COMMON
3
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