LTC1992-2CMS8 Linear Technology, LTC1992-2CMS8 Datasheet - Page 27
LTC1992-2CMS8
Manufacturer Part Number
LTC1992-2CMS8
Description
IC AMP/DVR I/O GAIN OF 2 8MSOP
Manufacturer
Linear Technology
Datasheet
1.LTC1992CMS8PBF.pdf
(42 pages)
Specifications of LTC1992-2CMS8
Amplifier Type
Differential
Number Of Circuits
1
Output Type
Differential, Rail-to-Rail
Slew Rate
1.5 V/µs
Gain Bandwidth Product
3.2MHz
Current - Input Bias
2pA
Voltage - Input Offset
250µV
Current - Supply
700µA
Current - Output / Channel
30mA
Voltage - Supply, Single/dual (±)
2.7 V ~ 11 V, ±1.35 V ~ 5.5 V
Operating Temperature
0°C ~ 70°C
Mounting Type
Surface Mount
Package / Case
8-MSOP, Micro8™, 8-uMAX, 8-uSOP,
Lead Free Status / RoHS Status
Contains lead / RoHS non-compliant
-3db Bandwidth
-
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
LTC1992-2CMS8
Manufacturer:
LT
Quantity:
10 000
Part Number:
LTC1992-2CMS8
Manufacturer:
LINEAR/凌特
Quantity:
20 000
Company:
Part Number:
LTC1992-2CMS8#PBF
Manufacturer:
LT
Quantity:
759
applicaTions inForMaTion
negative feedback and using an op amp’s differential input
to create the servo’s summing junction.
One servo controls the signal gain path. The differential
input of op amp A1 creates the summing junction of this
servo. Any voltage present at the input of A1 is amplified (by
the op amp’s large open-loop gain), sent to the summing
blocks and then onto the outputs. Taking note of the signs on
the summing blocks, op amp A1’s output moves +OUT and
the INM node increases the +OUT voltage while the –OUT
voltage decreases. The RFB resistors connect the outputs
to the appropriate inputs establishing negative feedback and
closing the servo’s loop. Any servo loop always attempts
to drive its error voltage to zero. In this servo, the error
voltage is the voltage between the INM and INP nodes,
thus A1 will force the voltages on the INP and INM nodes
to be equal (within the part’s DC offset, open loop gain
and bandwidth limits). The “virtual short” between the
two inputs is conceptually the same as that for op amps
and is critical to understanding fully differential amplifier
applications.
The other servo controls the output common mode level.
The differential input of op amp A2 creates the summing
junction of this servo. Similar to the signal gain servo
above, any voltage present at the input of A2 is amplified,
sent to the summing blocks and then onto the outputs.
However, in this case, both outputs move in the same direc-
tion. The resistors R
–OUT outputs to A2’s inverting input establishing negative
feedback and closing the servo’s loop. The midpoint of
resistors R
mode level (i.e., its average). This measure of the output’s
common mode level connects to A2’s inverting input while
A2’s noninverting input connects directly to the V
A2 forces the voltages on its inverting and noninverting
inputs to be equal. In other words, it forces the output
common mode voltage to be equal to the voltage on the
V
For any fully differential amplifier application to function
properly both the signal gain servo and the common mode
level servo must be satisfied. When analyzing an applica-
tions circuit, the INP node voltage must equal the INM node
voltage and the output common mode voltage must equal
–OUT in opposite directions. Applying a voltage step at
OCM
input pin.
CMP
and R
CMP
CMM
and R
derives the output’s common
CMM
connect the +OUT and
OCM
pin.
the V
the specified areas of operation (e.g., inputs taken beyond
the common mode range specifications, outputs hitting the
supply rails or input signals varying faster than the part
can track), the circuit will not function properly.
Fully Differential Amplifier Signal Conventions
Fully differential amplifiers have a multitude of signals and
signal ranges to consider. To maintain proper operation
with conventional op amps, the op amp’s inputs and its
output must not hit the supply rails and the input signal’s
common mode level must also be within the part’s speci-
fied limits. These considerations also apply to fully dif-
ferential amplifiers, but here there is an additional output
to consider and common mode level shifting complicates
matters. Figure 3 provides a list of the many signals and
specifications as well as the naming convention. The
phrase “common mode” appears in many places and often
leads to confusion. The fully differential amplifier’s ability
to uncouple input and output common mode levels yields
great design flexibility, but also complicates matters some.
For simplicity, the equations in Figure 3 also assume an
ideal amplifier and perfect resistor matching. For a detailed
analysis, consult the fully differential amplifier applications
circuit analysis section.
Basic Applications Circuits
Most fully differential amplifier applications circuits employ
symmetrical feedback networks and are familiar territory
for op amp users. Symmetrical feedback networks require
that the –V
the +V
cally just a standard inverting gain op amp circuit. Figure 4
shows three basic inverting gain op amp circuits and their
corresponding fully differential amplifier cousins. The vast
majority of fully differential amplifier circuits derive from
old tried and true inverting op amp circuits. To create a
fully differential amplifier circuit from an inverting op amp
circuit, first simply transfer the op amp’s V
to the fully differential amplifier’s –V
take a mirror image duplicate of the network and apply it
to the fully differential amplifier’s +V
amp users can comfortably transfer any inverting op amp
circuit to a fully differential amplifier in this manner.
OCM
IN
/–V
voltage. If either of these servos is taken out of
IN
OUT
/+V
network. Each of these half circuits is basi-
OUT
network is a mirror image duplicate of
LTC1992 Family
IN
/+V
IN
/–V
OUT
IN
OUT
/V
nodes. Then,
OUT
nodes. Op
network
1992fa
Related parts for LTC1992-2CMS8
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
IC AMP/DVR I/O GAIN-1 DIFF 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR I/O GAIN OF 2 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR DIFF I/O GAIN10 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR DIFF I/O GAIN-5 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR I/O GAIN-5 DIFF 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR DIFF I/O GAIN10 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP DIFF GAIN-2 ADJ I/O 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP DIFF GAIN-1 ADJ I/O 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR DIFF I/O GAIN10 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR DIFF I/O GAIN-5 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR I/O GAIN-2 DIFF 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR DIFF I/O GAIN10 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR I/O GAIN-1 DIFF 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR I/O GAIN-5 DIFF 8MSOP
Manufacturer:
Linear Technology
Datasheet:
Part Number:
Description:
IC AMP/DVR I/O GAIN-5 DIFF 8MSOP
Manufacturer:
Linear Technology
Datasheet: