LT6600IS8-5#PBF Linear Technology, LT6600IS8-5#PBF Datasheet - Page 8
LT6600IS8-5#PBF
Manufacturer Part Number
LT6600IS8-5#PBF
Description
IC AMP DIFF LP FLTR 5MHZ 8-SOIC
Manufacturer
Linear Technology
Datasheet
1.LT6600CS8-5PBF.pdf
(12 pages)
Specifications of LT6600IS8-5#PBF
Amplifier Type
Differential
Number Of Circuits
1
Output Type
Differential
Current - Input Bias
30µA
Voltage - Input Offset
8000µV
Current - Supply
30mA
Voltage - Supply, Single/dual (±)
3 V ~ 11 V, ±1.5 V ~ 5.5 V
Operating Temperature
-40°C ~ 85°C
Mounting Type
Surface Mount
Package / Case
8-SOIC (3.9mm Width)
No. Of Amplifiers
1
Input Offset Voltage
35mV
Gain Db Max
11.5dB
Bandwidth
5MHz
Supply Voltage Range
3V To 11V
Supply Current
30mA
Amplifier Case Style
SOIC
No. Of Pins
8
Rohs Compliant
Yes
Operating Temperature (min)
-40C
Operating Temperature (max)
85C
Operating Temperature Classification
Industrial
Mounting
Surface Mount
Pin Count
8
Package Type
SOIC N
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Current - Output / Channel
-
-3db Bandwidth
-
Slew Rate
-
Gain Bandwidth Product
-
Lead Free Status / Rohs Status
Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
APPLICATIONS INFORMATION
Evaluating the LT6600-5
The low impedance levels and high frequency operation
of the LT6600-5 require some attention to the matching
networks between the LT6600-5 and other devices. The
previous examples assume an ideal (0Ω) source imped-
ance and a large (1kΩ) load resistance. Among practi-
cal examples where impedance must be considered is
the evaluation of the LT6600-5 with a network analyzer.
LT6600-5
the passband fl atness near 5MHz. The common mode
output voltage is set to 2V.
Use Figure 4 to determine the interface between the
LT6600-5 and a current output DAC. The gain, or “tran-
simpedance,” is defi ned as A = V
the transimpedance, use the following equation:
By setting R1 + R2 = 806Ω, the gain equation reduces
to A = R1Ω.
The voltage at the pins of the DAC is determined by R1,
R2, the voltage on Pin 7 and the DAC output current
(I
= 750Ω. The voltage at Pin 7 is 1.65V. The voltage at the
DAC pins is given by:
I
50.3Ω.
8
IN
IN
A =
V
is I
+
DAC
or I
IN
CURRENT
806 • R1
OUTPUT
R1+ R2
–
IN
= V
DAC
= 51mV +I
or I
–
). Consider Figure 4 with R1 = 49.9Ω and R2
PIN7
IN
I
I
IN
IN
+
Ω
–
+
. The transimpedance in this example is
•
R1+ R2 + 806
IN
R1
R1
46.8Ω
0.01μF
R1
Figure 4
R2
R2
+I
1
7
2
8
OUT
+
–
IN
LT6600-5
3
6
3.3V
/I
R1+ R2
R1• R2
+
–
IN
0.1μF
4
5
Ω. To compute
V
V
66005 F04
OUT
OUT
+
–
Figure 5 is a laboratory setup that can be used to character-
ize the LT6600-5 using single-ended instruments with 50Ω
source impedance and 50Ω input impedance. For a unity
gain confi guration the LT6600-5 requires a 806Ω source
resistance yet the network analyzer output is calibrated
for a 50Ω load resistance. The 1:1 transformer, 51.1Ω
and 787Ω resistors satisfy the two constraints above.
The transformer converts the single-ended source into a
differential stimulus. Similarly, the output the LT6600-5
will have lower distortion with larger load resistance yet
the analyzer input is typically 50Ω. The 4:1 turns (16:1
impedance) transformer and the two 402Ω resistors of
Figure 5, present the output of the LT6600-5 with a 1600Ω
differential load, or the equivalent of 800Ω to ground at
each output. The impedance seen by the network analyzer
input is still 50Ω, reducing refl ections in the cabling be-
tween the transformer and analyzer input.
Differential and Common Mode Voltage Ranges
The differential amplifi ers inside the LT6600-5 contain
circuitry to limit the maximum peak-to-peak differential
voltage through the fi lter. This limiting function prevents
excessive power dissipation in the internal circuitry and
provides output short-circuit protection. The limiting
function begins to take effect at output signal levels above
2V
illustrated in Figure 6; the LTC6600-5 was confi gured with
unity passband gain and the input of the fi lter was driven
with a 1MHz signal. Because this voltage limiting takes
place well before the output stage of the fi lter reaches the
supply rails, the input/output behavior of the IC shown
in Figure 6 is relatively independent of the power supply
voltage.
ANALYZER
NETWORK
SOURCE
P-P
50Ω
and it becomes noticeable above 3.5V
51.1Ω
TTWB-1010
COILCRAFT
1:1
787Ω
787Ω
Figure 5
1
7
2
8
–
+
LT6600-5
–2.5V
2.5V
3
6
+
–
0.1μF
0.1μF
4
5
402Ω
402Ω
COILCRAFT
TTWB-16A
4:1
P-P
. This is
ANALYZER
NETWORK
INPUT
66005fb
66005 F05
50Ω
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