LINER LTC6405CUD-PBF

LTC6405
2.7GHz, 5V, Low Noise,
Rail-to-Rail Input Differential
Amplifier/Driver
FEATURES
DESCRIPTION
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The LTC®6405 is a very low noise, low distortion, fully
differential input/output amplifier optimized for 5V, single
supply operation. The LTC6405 input common mode range
is rail-to-rail, while the output common mode voltage is
independently adjustable by applying a voltage on the
VOCM pin. This makes the LTC6405 ideal for level shifting
signals with a wide common mode range for driving 12-bit
to 16-bit single supply, differential input ADCs.
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Low Noise: 1.6nV/√Hz RTI
Low Power: 18mA at 5V
Low Distortion (HD2/HD3):
–82dBc/–65dBc at 50MHz, 2VP-P
–97dBc/–91dBc at 25MHz, 2VP-P
Rail-to-Rail Differential Input
4.5V to 5.5V Supply Voltage Range
Fully Differential Input and Output
Adjustable Output Common Mode Voltage
800MHz –3dB Bandwidth with AV = 1
Gain-Bandwidth Product: 2.7GHz
Low Power Shutdown
Available in 8-Lead MSOP and 16-Lead
3mm × 3mm × 0.75mm QFN Packages
A 2.7GHz gain-bandwidth product results in 65dB linearity
for 50MHz input signals. The LTC6405 is unity gain stable
and the closed-loop bandwidth extends from DC to 800MHz.
The output voltage swing extends from near-ground to
4V, to be compatible with a wide range of ADC converter
input requirements. The LTC6405 draws only 18mA, and
has a hardware shutdown feature which reduces current
consumption to 400μA.
APPLICATIONS
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Differential Input ADC Driver
Single-Ended to Differential Conversion
Level-Shifting Ground-Referenced Signals
Level-Shifting VCC-Referenced Signals
High-Linearity Direct Conversion Receivers
The LTC6405 is available in a compact 3mm × 3mm 16-pin
leadless QFN package, as well as an 8-lead MSOP package,
and operates over a –40°C to 85°C temperature range.
L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
TYPICAL APPLICATION
Single-Ended Input to Differential Output
with Common Mode Level Shifting
50Ω
196Ω
200Ω
5V 0.1μF
61.9Ω
SIGNAL
GENERATOR
1VP-P
VOCM
0.01μF
+
2.5V
LTC6405UD
–
2.5V
1VP-P
200Ω
221Ω
1.8pF
4
VS = 5V
NOISE MEASURED AT f = 1MHz
3
3
in
2
2
en
1
1
INPUT CURRENT NOISE DENSITY (pA/ Hz)
1.8pF
INPUT VOLTAGE NOISE DENSITY (nV/ Hz)
4
2VP-P
0V
VS
Input Noise Density vs Input
Common Mode Voltage
0
0
0
0.5 1 1.5 2 2.5 3 3.5 4 4.5
INPUT COMMON MODE VOLTAGE (V)
5
6405 TA01b
6405 TA01
6405fa
1
LTC6405
ABSOLUTE MAXIMUM RATINGS
(Note 1)
Total Supply Voltage (V+ to V–) ................................5.5V
Input Current
(+IN, –IN, VOCM, SHDN, VTIP) (Note 2) ............±10mA
Output Short-Circuit Duration (Note 3) ............ Indefinite
Operating Temperature Range
(Note 4) ............................................... –40°C to 85°C
Specified Temperature Range (Note 5)
LTC6405I.............................................. –40°C to 85°C
LTC6405C ................................................ 0°C to 70°C
Junction Temperature ........................................... 150°C
Storage Temperature Range................... –65°C to 150°C
PIN CONFIGURATION
2
V–
3
VOCM
4
TJMAX = 150°C, θJA = 40°C/W, θJC = 10°C/W
EXPOSED PAD (PIN 9) IS V –, MUST BE SOLDERED TO PCB
–OUTF
12 V–
11 V+
17
10 V+
9
5
6
7
V–
8
+OUTF
MS8E PACKAGE
8-LEAD PLASTIC MSOP
V+
+OUT
+IN
SHDN
V–
–OUT
1
–IN
8
7
6
5
SHDN
VTIP
9
–OUT
16 15 14 13
TOP VIEW
–IN 1
VOCM 2
V+ 3
+OUT 4
+IN
NC
TOP VIEW
UD PACKAGE
16-LEAD (3mm × 3mm) PLASTIC QFN
TJMAX = 150°C, θJA = 68°C/W, θJC = 4.2°C/W
EXPOSED PAD (PIN 17) IS V–, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
SPECIFIED TEMPERATURE RANGE
LTC6405CMS8E#PBF
LTC6405CMS8E#TRPBF
LTDKN
8-Lead Plastic MSOP
0°C to 70°C
LTC6405IMS8E#PBF
LTC6405IMS8E#TRPBF
LTDKN
8-Lead Plastic MSOP
–40°C to 85°C
LTC6405CUD#PBF
LTC6405CUD#TRPBF
LDKP
16-Lead (3mm × 3mm) Plastic QFN
0°C to 70°C
LTC6405IUD#PBF
LTC6405IUD#TRPBF
LDKP
16-Lead (3mm × 3mm) Plastic QFN
–40°C to 85°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
This product is only offered in trays. For more information go to: http://www.linear.com/packaging/
6405fa
2
LTC6405
DC ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full
operating temperature range, otherwise specifications are at TA = 25°C. V+ = 5V, V– = 0V, VCM = VOCM = VICM = 2.5V, VSHDN = open,
circuit component values in Figure 1 used, unless otherwise noted. VS is defined as (V+ – V–). VOUTCM is defined as (V+OUT + V–OUT)/2.
VICM is defined as (V+IN + V–IN)/2. VOUTDIFF is defined as (V+OUT – V–OUT).
SYMBOL
PARAMETER
CONDITIONS
VOSDIFF
Differential Offset Voltage (Input Referred)
ΔVOSDIFF/ΔT
Differential Offset Voltage Drift (Input Referred)
IB
Input Bias Current (Note 6)
VICM = 5V (Note 12)
VICM = 2.5V
VICM = 0V (Note 12)
VICM = 5V (Note 12)
VICM = 2.5V
VICM = 0V (Note 12)
VICM = 5V
VICM = 2.5V
VICM = 0V
VICM = 5V
VICM = 2.5V
VICM = 0V
Common Mode
Differential Mode
Differential
IOS
Input Offset Current (Note 6)
RIN
Input Resistance
CIN
Input Capacitance
en
Differential Input Referred Noise Voltage Density
in
Input Noise Current Density
enVOCM
Input Referred Common Mode Output Noise Voltage
Density
Input Signal Common Mode Range
VICMR (Note 7)
MIN
TYP
MAX
UNITS
±7
±3.5
±7
–24
±1
±0.5
±1
1.5
1
3
8
–7
–14
±0.5
±0.5
±0.5
230
3.5
1
mV
mV
mV
μV/°C
μV/°C
μV/°C
μA
μA
μA
μA
μA
μA
kΩ
kΩ
pF
l
l
l
l
l
l
l
l
f = 1MHz, Not Including RI/RF
Noise
f = 1MHz, Not Including RI/RF
Noise
f = 1MHz
±4
1.6
nV/√Hz
2.4
pA/√Hz
9.5
nV/√Hz
Op-Amp Inputs
l
V–
V+
VICM from 0V to 5V
l
50
75
dB
VOCM from 0.5V to 3.9V
l
50
75
dB
VS = 4.5V to 5.5V
l
50
75
dB
VS = 4.5V to 5.5V
l
55
70
dB
VOCM from 0.5V to 3.9V
l
1
V/V
V
CMRRI
(Note 8)
CMRRIO
(Note 8)
PSRR
(Note 9)
PSRRCM
(Note 9)
GCM
Input Common Mode Rejection Ratio
(Input Referred) ΔVICM/ΔVOSDIFF
Output Common Mode Rejection Ratio
(Input Referred) ΔVOCM/ΔVOSDIFF
Differential Power Supply Rejection
(ΔVS/ΔVOSDIFF)
Output Common Mode Power Supply Rejection
(ΔVS/ΔVOSCM)
Common Mode Gain (ΔVOUTCM/ΔVOCM)
ΔGCM
Common Mode Gain Error 100 • (GCM – 1)
VOCM from 0.5V to 3.9V
l
±0.25
±0.8
%
BAL
Output Balance (ΔVOUTCM/ΔVOUTDIFF)
ΔVOUTDIFF = 2V
Single-Ended Input
Differential Input
l
l
–60
–65
±6
–40
–40
±15
dB
dB
mV
VOSCM
Common Mode Offset Voltage (VOUTCM – VOCM)
l
ΔVOSCM/ΔT
Common Mode Offset Voltage Drift
l
VOUTCMR
(Note 7)
RINVOCM
Output Signal Common Mode Range
(Voltage Range for the VOCM Pin)
Input Resistance, VOCM Pin
l
0.5
l
13
VOCM
Self-Biased Voltage at the VOCM Pin
VOCM = Open
l
VOUT
Output Voltage, High, +OUT/–OUT Pins
IL = 0
IL = –5mA
IL = 0
IL = 5mA
l
l
Output Voltage, Low, +OUT/–OUT Pins
ISC
Output Short-Circuit Current, +OUT/–OUT Pins
(Note 10)
20
V
19
25
kΩ
2.35
2.5
2.65
3.9
3.85
4
3.95
0.3
0.42
±60
l
l
l
μV/°C
3.9
±40
0.4
0.54
V
V
V
V
V
mA
6405fa
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LTC6405
DC ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full
operating temperature range, otherwise specifications are at TA = 25°C. V+ = 5V, V– = 0V, VCM = VOCM = VICM = 2.5V, VSHDN = open,
circuit component values in Figure 1 used, unless otherwise noted. VS is defined as (V+ – V–). VOUTCM is defined as (V+OUT + V–OUT)/2.
VICM is defined as (V+IN + V–IN)/2. VOUTDIFF is defined as (V+OUT – V–OUT).
SYMBOL
PARAMETER
AVOL
Large-Signal Open Loop Voltage Gain
CONDITIONS
MIN
TYP
MAX
VS
Supply Voltage Range
l
l
18
23
mA
0.4
1
mA
70
kΩ
90
4.5
UNITS
dB
5.5
V
IS
Supply Current
ISHDN
Supply Current in Shutdown
VSHDN = 0V
l
RSHDN
SHDN Pull-Up Resistor
VSHDN = 0V to 0.5V
l
30
50
VIL
SHDN Input Logic Low
l
1.25
1.8
VIH
SHDN Input Logic High
l
tON
Turn-On Time
200
ns
tOFF
Turn-Off Time
50
ns
2
V
2.55
V
AC ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full
operating temperature range, otherwise specifications are at TA = 25°C. V+ = 5V, V– = 0V, VCM = VOCM = VICM = 2.5V, VSHDN = open,
RLOAD = 400Ω, circuit component values in Figure 2 used, unless otherwise noted. VS is defined as (V+ – V–). VICM is defined as (V+IN
+ V–IN)/2. VOUTDIFF is defined as (V+OUT – V–OUT).
SYMBOL
PARAMETER
CONDITIONS
SR
Slew Rate
Differential Output
690
V/μS
GBW
Gain-Bandwidth Product
fTEST = 27MHz
2.7
GHz
f–3dB
–3dB Frequency (See Figure 2)
QFN Package
MSOP Package
800
750
MHz
MHz
50MHz Distortion
Differential Input, VOUTDIFF = 2VP-P
(Note 13)
VOCM = 2.5V, VS = 5V
2nd Harmonic
3rd Harmonic
tS
NF
MIN
500
400
l
TYP
–80
–64
MAX
–53
UNITS
dBc
dBc
VOCM = 2.5V, VS = 5V, RLOAD = 800Ω
2nd Harmonic
3rd Harmonic
–82
–66
dBc
dBc
VOCM = 2.5V, VS = 5V, RLOAD = 800Ω,
RI = RF = 499Ω
2nd Harmonic
3rd Harmonic
–82
–64
dBc
dBc
50MHz Distortion
Single-Ended Input, VOUTDIFF = 2VP-P
(Note 13)
VOCM = 2.5V, VS = 5V, RLOAD = 800Ω,
RI = RF = 499Ω
2nd Harmonic
3rd Harmonic
–72
–77
dBc
dBc
3rd-Order IMD at 49.5MHz, 50.5MHz
VOUTDIFF = 2VP-P Envelope,
RLOAD = 800Ω
–63
dBc
Equivalent OIP3 at 50MHz (Note 11)
RLOAD = 800Ω
35.5
dBm
Settling Time
VOUTDIFF = 2V Step
1% Settling
0.1% Settling
Noise Figure at 50MHz
Shunt-Terminated to 50Ω, RS = 50Ω
ZIN = 200Ω (RI = 100Ω, RF = 300Ω)
6
11
ns
ns
14.4
7.5
dB
dB
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LTC6405
ELECTRICAL CHARACTERISTICS
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: Input pins (+IN, –IN, VOCM, SHDN and VTIP) are protected by
steering diodes to either supply. If the inputs should exceed either supply
voltage, the input current should be limited to less than 10mA. In addition,
the inputs +IN, –IN are protected by a pair of back-to-back diodes. If the
differential input voltage exceeds 1.4V, the input current should be limited
to less than 10mA.
Note 3: A heat sink may be required to keep the junction temperature
below the Absolute Maximum Rating when the output is shorted
indefinitely.
Note 4: The LTC6405C/LTC6405I are guaranteed functional over the
operating temperature range –40°C to 85°C.
Note 5: The LTC6405C is guaranteed to meet specified performance from
0°C to 70°C. The LTC6405C is designed, characterized, and expected
to meet specified performance from –40°C to 85°C but is not tested or
QA sampled at these temperatures. The LTC6405I is guaranteed to meet
specified performance from –40°C to 85°C.
Note 6: Input bias current is defined as the average of the input currents
flowing into the inputs (–IN, and +IN). Input Offset current is defined as
the difference between the input currents (IOS = IB+ – IB–).
Note 7: Input common mode range is tested using the test circuit of Figure
1 by taking 3 measurements of differential gain with a ±1VDC differential
output with VICM = 0V; VICM = 2.5V; VICM = 5V, verifying that the differential
gain has not deviated from the VICM = 2.5V case by more than 0.5%, and
that the common mode offset (VOSCM) has not deviated from the common
mode offset at VICM = 2.5V by more than ±35mV.
The voltage range for the output common mode range is tested using the
test circuit of Figure 1 by applying a voltage on the VOCM pin and testing at
both VOCM = 2.5V and at the Electrical Characteristics table limits to verify
that the common mode offset (VOSCM) has not deviated by more than
±20mV from the VOCM = 2.5V case.
Note 8: Input CMRR is defined as the ratio of the change in the input
common mode voltage at the pins +IN or –IN to the change in differential
input referred voltage offset. Output CMRR is defined as the ratio of
the change in the voltage at the VOCM pin to the change in differential
input referred voltage offset. This specification is strongly dependent on
feedback ratio matching between the two outputs and their respective
inputs, and it is difficult to measure actual amplifier performance. (See
the “Effects of Resistor Pair Mismatch” in the Applications Information
section of this data sheet.) For a better indicator of actual amplifier
performance independent of feedback component matching, refer to the
PSRR specification.
Note 9: Differential Power Supply Rejection (PSRR) is defined as the
ratio of the change in supply voltage to the change in differential input
referred voltage offset. Common mode power supply rejection (PSRRCM)
is defined as the ratio of the change in supply voltage to the change in the
common mode offset, VOUTCM – VOCM.
Note 10: Extended operation with the output shorted may cause the
junction temperature to exceed the 150°C limit.
Note 11: Because the LTC6405 is a feedback amplifier with low output
impedance, a resistive load is not required when driving an ADC.
Therefore, typical output power can be very small in many applications. In
order to compare the LTC6405 with “RF style” amplifiers that require 50Ω
load, the output voltage swing is converted to dBm as if the outputs were
driving a 50Ω load. For example, 2VP-P output swing is equal to 10dBm
using this convention.
Note 12: Includes offset/drift induced by feedback resistors mismatch. See
the Applications Information section for more details.
Note 13: QFN package only—refer to datasheet curves for MSOP package
numbers.
6405fa
5
LTC6405
TYPICAL PERFORMANCE CHARACTERISTICS
Differential Input Referred
Offset Voltage vs Input Common
Mode Voltage
1.0
1.0
0.4
0.6
0.2
0
0.4
0.2
0
–0.2
–0.2
–0.4
–0.4
–0.6
–0.6
–0.8
–0.8
–1.0
–50
TA = –40°C
TA = 0°C
TA = 25°C
TA = 70°C
TA = 85°C
–1.0
–25
25
50
0
TEMPERATURE (°C)
75
0
100
0.5 1 1.5 2 2.5 3 3.5 4 4.5
INPUT COMMON MODE VOLTAGE (V)
TOTAL SUPPLY CURRENT (mA)
TOTAL SUPPLY CURRENT (mA)
20
VSHDN = OPEN
TA = –40°C
TA = 0°C
TA = 25°C
TA = 70°C
TA = 85°C
10
5
0
6405 G04
4
3
–25
25
50
0
TEMPERATURE (°C)
15
10
TA = –40°C
TA = 0°C
TA = 25°C
TA = 70°C
TA = 85°C
0
0.5
1
1.5 2 2.5 3 3.5
SHDN VOLTAGE (V)
4
4.5
100
Shutdown Supply Current
vs Supply Voltage
600
5
75
6405 G03
VS = 5V
0
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5
SUPPLY VOLTAGE (V)
5
Supply Current vs SHDN Voltage
Supply Current vs Supply Voltage
15
6
6405 G02
6405 G01
20
VS = 5V
VOCM = 2.5V
8 VICM = 2.5V
FIVE REPRESENTATIVE UNITS
7
2
–50
5
SHUTDOWN SUPPLY CURRENT (μA)
DIFFERENTIAL VOS (mV)
0.6
9
VS = 5V
0.1% FEEDBACK NETWORK
VOCM = 2.5V
RESISTORS REPRESENTRI = RF = 200Ω ATIVE UNIT
0.8
DIFFERENTIAL VOS (V)
0.8
VS = 5V
VOCM = 2.5V
VICM = 2.5V
RI = RF = 200Ω
FIVE REPRESENTATIVE UNITS
Common Mode Offset Voltage
vs Temperature
COMMON MODE OFFSET VOLTAGE (mV)
Differential Input Referred Offset
Voltage vs Temperature
5
6405 G05
500
400
VSHDN = V –
TA = – 40°C
TA = 0°C
TA = 25°C
TA = 70°C
TA = 85°C
300
200
100
0
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5
SUPPLY VOLTAGE (V)
6405 G06
6405fa
6
LTC6405
TYPICAL PERFORMANCE CHARACTERISTICS
Input Noise Density vs Input
Common Mode Voltage
100
10
in
en
1
100
1k
10k
100k
FREQUENCY (Hz)
INPUT VOLTAGE NOISE DENSITY (nV/ Hz)
10
4
1
10M
1M
in
2
2
en
1
1
720
0
0.5 1 1.5 2 2.5 3 3.5 4 4.5
INPUT COMMON MODE VOLTAGE (V)
VS = 5V
700
680
660
640
620
600
–50
0
0
5
–25
25
50
0
TEMPERATURE (°C)
6405 G08
Differential Output Impedance
vs Frequency
VS = 5V
RI = RF = 2007
100
75
6405 G09
CMRR vs Frequency
Differential PSRR vs Frequency
90
80
80
70
70
60
VS = 5V
10
1
PSRR (dB)
100
CMRR (dB)
OUTPUT IMPEDANCE (Ω)
3
3
6405 G07
1000
4
VS = 5V
NOISE MEASURED AT f = 1MHz
INPUT CURRENT NOISE DENSITY (pA/ Hz)
VS = 5V
VICM = 2.5V
INPUT CURRENT NOISE DENSITY (pA/ Hz)
INPUT VOLTAGE NOISE DENSITY (nV/ Hz)
100
Differential Slew Rate
vs Temperature
SLEW RATE (V/μs)
Input Noise Density vs Frequency
60
50
0.01
1
10
100
FREQUENCY (MHz)
1000 2000
6405 G10
40
30
40
0.1
50
VS = 5V
VOCM = 2.5V
30
RI = RF = 2007, CF = 1.8pF
0.1% FEEDBACK NETWORK RESISTORS
20
1
10
100
1000 2000
FREQUENCY (MHz)
6405 G11
20
10
1
10
100
FREQUENCY (MHz)
1000 2000
6405 G12
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7
LTC6405
TYPICAL PERFORMANCE CHARACTERISTICS
Small Signal Step Response
(QFN Package)
Overdriven Output
Transient Response
Large Signal Step Response
4.5
4.0
+OUT
+OUT
VOLTAGE (V)
0.2V/DIV
20mV/DIV
3.5
–OUT
6405 G13
10ns/DIV
VS = 5V
RI = RF = 2007
VOCM = VICM = 2.5V CF = 1.8pF
RLOAD = 4007
CL = 0pF
10ns/DIV
VS = 5V
RLOAD = 4007
VIN = 2VP-P, DIFFERENTIAL
Frequency Response
vs Closed Loop Gain
30
AV = 100
–10
–20
–30
1000 2000
1
2
5
10
20
100
200
200
200
200
200
200
RF (7)
CF (pF)
200
400
1k
2k
4k
20k
1.8
1.5
0.6
0.2
0
0
+OUT
6405 G15
100ns/DIV
VS = 5V
VOCM = 2.5V
RLOAD = 4007 TO GROUND PER OUTPUT
Frequency Response vs Input
Common Mode Voltage
10
CL = 0pF
CL = 2pF
CL = 3pF
CL= 4.7pF
CL = 10pF
5
0
–5
–10
–20
VS = 5V
–30 VOCM = VICM = 2.5V
RLOAD = 4007
–40 RI = RF = 2007, CF = 1.8pF
CAPACITOR VALUES ARE FROM EACH
–50 OUTPUT TO GROUND.
NO SERIES RESISTORS ARE USED.
–60
1
10
100
1000 2000
FREQUENCY (MHz)
6405 G17
AV (V/V) RI (7)
1.5
0
6405 G14
0
AV = 2
AV = 1
VS = 5V
–40 VOCM = VICM = 2.5V
RLOAD = 4007
–50
1
10
100
FREQUENCY (MHz)
2.0
0.5
GAIN (dB)
0
10
AV = 10
AV = 5
GAIN (dB)
GAIN (dB)
10
20
AV = 20
20
2.5
Frequency Response
vs Load Capacitance
50
30
3.0
1.0
–OUT
40
–OUT
–10
–15
–20
VICM = 0V
VICM = 0.5V
VICM = 1.25V
VICM = 2.5V
VICM = 4V
VICM = 5V
–25
VS = 5V
VOCM = 2.5V
–35 RLOAD = 4007
RI = RF = 2007, CF = 1.8pF
–40
1
10
100
FREQUENCY (MHz)
–30
1000 2000
6405 G18
6405 G16
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8
LTC6405
TYPICAL PERFORMANCE CHARACTERISTICS
Harmonic Distortion
vs Input Common Mode Voltage
Harmonic Distortion vs Frequency
–60
–70
DISTORTION (dBc)
DISTORTION (dBc)
–50
HD3
RI = RF = 4997
–80
HD3
RI = RF = 2007
–90
–40
–40
VS = 5V
VOCM = VICM = 2.5V
VTIP = OPEN (2.8V)
RLOAD = 8007, VOUTDIFF = 2VP-P
DIFFERENTIAL INPUTS
–40
Harmonic Distortion
vs Input Amplitude
RLOAD = 8007
VS = 5V
VOCM = 2.5V
VOUTDIFF = 2VP-P
–50 VTIP = OPEN (2.8V) DIFFERENTIAL INPUTS
fIN = 50MHz
RI = RF = 2007
HD3
–60
–70
–80
RI = RF = 4997
HD2
VS = 5V
VOCM = VICM = 2.5V
–50 VTIP = OPEN (2.8V)
fIN = 50MHz
RLOAD = 8007
–60 RI = RF = 2007
DIFFERENTIAL INPUTS
DISTORTION (dBc)
–30
(QFN Package)
RI = RF = 4997
–70
HD3
–80
HD2
–100
–110
HD2
RI = RF = 4997
–120
1
–90
HD2
RI = RF = 2007
10
FREQUENCY (MHz)
–90
RI = RF = 2007
–100
100
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5
INPUT COMMON MODE VOLTAGE (V)
5
–100
–4
–2
(0.4VP-P)
0
2
4
6
INPUT AMPLITUDE (dBm)
8
10
(2VP-P)
6405 G21
6405 G20
6405 G19
Harmonic Distortion
vs Input Common Mode Voltage
Harmonic Distortion vs Frequency
–40
–40
–30
VS = 5V
RLOAD = 8007
–40 VOCM = VICM = 2.5V VOUTDIFF = 2VP-P
SINGLE-ENDED INPUT
VTIP = 2.35V
–50
–60
–70
–80
HD2, RI = RF = 2007
HD2, RI = RF = 4997
HD3, RI = RF = 2007
HD3, RI = RF = 4997
–100
–110
1
10
FREQUENCY (MHz)
–60
–70
HD3
–80
–90
–100
VS = 5V
VOCM = VICM = 2.5V
–50 VTIP = 2.35V
fIN = 50MHz
RLOAD = 8007
–60 RI = RF = 4997
SINGLE-ENDED INPUT
–70
HD2
–80
HD3
–90
–100
–4
–2
(0.4VP-P)
5
–30
–40
THIRD ORDER IMD (dBc)
–50
–90
–100
–110
100
6405 G25
10
(2VP-P)
Intermodulation Distortion
vs Input Amplitude
–40
–80
8
6405 G24
Intermodulation Distortion
vs Input Common Mode Voltage
VS = 5V
–40 VOCM = VICM = 2.5V
VTIP = OPEN (2.8V)
RLOAD = 8007
–50
RI = RF = 2007
2 TONES, 1MHz TONE SPACING,
–60
2VP-P COMPOSITE
DIFFERENTIAL INPUTS
–70
0
2
4
6
INPUT AMPLITUDE (dBm)
6405 G23
Intermodulation Distortion
vs Frequency
10
FREQUENCY (MHz)
RLOAD = 8007
RI = RF = 4997
VOUTDIFF = 2VP-P
SINGLE-ENDED INPUT
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5
INPUT COMMON MODE VOLTAGE (V)
100
6405 G22
1
VS = 5V
VOCM = 2.5V
VTIP = 2.35V
fIN = 50MHz
THIRD ORDER IMD (dBc)
–90
DISTORTION (dBc)
HD2
DISTORTION (dBc)
DISTORTION (dBc)
–50
THIRD ORDER IMD (dBc)
Harmonic Distortion
vs Input Amplitude
–60
VS = 5V
VOCM = 2.5V
VTIP = OPEN (2.8V)
–80 fIN = 50MHz
RLOAD = 8007
RI = RF = 2007
–90 2TONES,1MHz TONE SPACING,
2VP-P COMPOSITE
DIFFERENTIAL INPUTS
–100
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5
INPUT COMMON MODE VOLTAGE (V)
–70
VS = 5V
VOCM = VICM = 2.5V
–50 VTIP = OPEN (2.8V)
fIN = 50MHz
RLOAD = 8007
–60 RI = RF = 2007
2 TONES, 1MHz TONE SPACING
DIFFERENTIAL INPUTS
–70
–80
–90
5
6405 G26
–100
–4
–2
(0.4VP-P)
0
2
4
6
INPUT AMPLITUDE (dBm)
8
10
(2VP-P)
6405 G27
6405fa
9
LTC6405
TYPICAL PERFORMANCE CHARACTERISTICS
Frequency Response
vs Load Capacitance
Harmonic Distortion
vs Input Amplitude
Harmonic Distortion vs Frequency
–30
CL = 10pF
20
0
CL = 0pF
–10
VS = 5V
VOCM = VICM = 2.5V
= 4007
R
–30 RLOAD
I = RF = 3007, CF = 1pF
CAPACITOR VALUES ARE FROM EACH
–40 OUTPUT TO GROUND.
NO SERIES RESISTORS ARE USED.
–50
1
10
100
1000 2000
FREQUENCY (MHz)
–20
DISTORTION (dBc)
10
–40
VS = 5V
–40 VOCM = VICM = 2.5V
VTIP = OPEN (2.8V)
RLOAD = 8007
–50
RI = RF = 3007
= 2VP-P
V
–60 OUTDIFF
DIFFERENTIAL INPUTS
DISTORTION (dBc)
30
GAIN (dB)
(MSOP Package)
–70
–80
HD3
HD2
HD3
–80
–90
–100
–110
1
10
FREQUENCY (MHz)
100
–100
–4
–2
(0.4VP-P)
0
2
4
6
INPUT AMPLITUDE (dBm)
6405 G29
–40
–30
DISTORTION (dBc)
VS = 5V
–40 VOCM = VICM = 2.5V
VTIP = OPEN (2.8V)
RLOAD = 8007
–50
RI = RF = 3007
= 2VP-P
V
–60 OUTDIFF
SINGLE-ENDED INPUT
–70
HD2
8
10
(2VP-P)
6405 G30
Harmonic Distortion
vs Input Amplitude
Harmonic Distortion vs Frequency
DISTORTION (dBc)
HD2
–70
–90
6405 G28
–80
VS = 5V
VOCM = VICM = 2.5V
–50 VTIP = OPEN (2.8V)
fIN = 50MHz
RLOAD = 8007
–60 RI = RF = 3007
DIFFERENTIAL INPUTS
VS = 5V
VOCM = VICM = 2.5V
–50 VTIP = OPEN (2.8V)
fIN = 50MHz
RLOAD = 8007
–60
–70
RI = RF = 3007
SINGLE-ENDED INPUT
HD2
HD3
–80
–90
HD3
–90
–100
–110
1
10
FREQUENCY (MHz)
100
6405 G31
–100
–4
–2
(0.4VP-P)
0
2
4
6
INPUT AMPLITUDE (dBm)
8
10
(2VP-P)
6405 G32
6405fa
10
LTC6405
PIN FUNCTIONS
(MSOP/QFN)
VOCM (Pin 2/Pin 4): Output Common Mode Reference
Voltage. The voltage on VOCM sets the output common
mode voltage level (which is defined as the average of the
voltages on the +OUT and –OUT pins). The VOCM voltage
is internally set by a resistive divider between the supplies,
developing a default voltage potential of 2.5V with a 5V
supply. The VOCM pin can be over-driven by an external
voltage capable of driving the 19kΩ Thevenin equivalent
impedance presented by the pin. The VOCM pin should be
bypassed with a high quality ceramic bypass capacitor of at
least 0.01μF, to minimize common mode noise from being
converted to differential noise by impedance mismatches
both externally and internally to the IC.
V+ (Pin 3/Pins 2, 10, 11):
V– (Pin 6/Pins 3, 9, 12):
Power Supply Pins. It is critical that close attention be
paid to supply bypassing. For single supply applications,
it is recommended that a high quality 0.1μF surface mount
ceramic bypass capacitor be placed between V+ and V– with
direct short connections. In addition, V– should be tied
directly to a low impedance ground plane with minimal
routing. For dual (split) power supplies, it is recommended
that additional high quality, 0.1μF ceramic capacitors are
used to bypass V+ to ground and V– to ground, again
with minimal routing. For driving large loads (<200Ω),
additional bypass capacitance may be needed for optimal
performance. Keep in mind that small geometry (e.g., 0603
or smaller) surface mount ceramic capacitors have a much
higher self resonant frequency than do leaded capacitors,
and perform best in high speed applications.
+OUT, –OUT (Pins 4, 5/Pins 7, 14): Unfiltered Output
Pins. Besides driving the feedback network, each pin
can drive an additional 50Ω to ground with typical short
circuit current limiting of ±60mA. Each amplifier output
is designed to drive a load capacitance of 5pF. Larger
capacitive loads should be decoupled with at least 15Ω
resistors from each output.
VTIP (Pin 5) QFN Only: This pin can normally be left floating. It determines which pair of input transistors (NPN or
PNP or both) is sensing the input signal. The VTIP pin is
set by an internal resistive divider between the supplies,
developing a default 2.8V voltage with a 5V supply. VTIP
has a Thevenin equivalent resistance of approximately
17k and can be over-driven by an external voltage. The
VTIP pin should be bypassed with a high quality ceramic
bypass capacitor of at least 0.01μF. See the Applications
Information section for more details.
SHDN (Pin 7/Pin 1): When SHDN is floating or directly
tied to V+, the LTC6405 is in the normal (active) operating mode. When the SHDN pin is connected to V–, the
LTC6405 enters into a low power shutdown state with
Hi-Z outputs.
+IN, –IN (Pins 8, 1/Pins 15, 6): Noninverting and Inverting
Input Pins of the Amplifier, Respectively. For best performance, it is highly recommended that stray capacitance
be kept to an absolute minimum by keeping printed circuit
connections as short as possible.
+OUTF, –OUTF (Pins 8, 13) QFN Only: Filtered Output
Pins. These pins have a series RC network (R = 50Ω,
C = 3.75pF) connected between the filtered and unfiltered
outputs. See the Applications Information section for
more details.
NC (Pin 16) QFN Only: No Connection. This pin is not
connected internally.
Exposed Pad (Pin 9/Pin 17): Tie the bottom pad to V–. If
split supplies are used, DO NOT tie the pad to ground.
6405fa
11
LTC6405
BLOCK DIAGRAMS
LTC6405 Block Diagram/Pinout in MSOP Package
8
+IN
7
6
SHDN
5
V–
–OUT
V–
V+
V+
37k
+
37k
–
V–
V–
V+
–IN
1
2
V+
VOCM
+OUT
3
4
6405 BD01
LTC6405 Block Diagram/Pinout in QFN Package
16
15
NC
14
+IN
–OUT
13
–OUTF
1.25pF
SHDN
V–
12
1
V+
V+
V+
2
V–
3
V+
37k
V–
50Ω
+
V+
V+
11
V+
V+
10
1.25pF
V+
V–
–
37k
50Ω
30k
V–
VOCM
V–
V–
4
V–
9
38k
1.25pF
V–
5
VTIP
–IN
6
+OUT
7
+OUTF
8
6405 BD02
6405fa
12
LTC6405
APPLICATIONS INFORMATION
Functional Description
The LTC6405 is a small outline, wideband, low noise, and
low distortion fully-differential amplifier with accurate
output phase balancing. The LTC6405 is optimized to
drive low voltage, single-supply, differential input analogto-digital converters (ADCs). The LTC6405 input common
mode range is rail-to-rail, while the output common mode
voltage is independently adjustable by applying a voltage
on the VOCM pin. The output voltage swing extends from
near-ground to 4V, to be compatible with a wide range of
ADC converter input requirements. This makes the LTC6405
ideal for level shifting signals with a wide common mode
range for driving 12-bit to 16-bit single supply, differential
input ADCs. The differential output allows for twice the
signal swing in low voltage systems when compared to
single-ended output amplifiers. The balanced differential
nature of the amplifier also provides even-order harmonic
distortion cancellation, and less susceptibility to common
mode noise (like power supply noise). The LTC6405 can be
used as a single ended input to differential output amplifier,
or as a differential input to differential output amplifier.
The LTC6405 output common mode voltage, defined as the
average of the two output voltages, is independent of the
input common mode voltage, and is adjusted by applying
a voltage on the VOCM pin. If the pin is left open, there
is an internal resistive voltage divider, which develops a
potential of 2.5V (if the supply is 5V). It is recommended
that a high quality ceramic cap is used to bypass the VOCM
pin to a low impedance ground plane. The LTC6405’s
internal common mode feedback path forces accurate
output phase balancing to reduce even order harmonics,
and centers each individual output about the potential set
by the VOCM pin.
VOUTCM = VOCM =
V+OUT + V–OUT
2
CF
RI
V+IN
+
16
VINP
–
NC
15
14
+IN
13
–OUT
SHDN
1
2
0.1μF
VCM
+
–
V–
3
1.25pF
V+
VOCM
V–
V–
V – V+
11
50Ω
V+
V+
50Ω
VTIP
6
–IN
7
0.01μF
–
0.1μF
RI
V–IN
RF
+OUT
V–
0.1μF
VOUTCM
V+
V – 0.1μF
8
0.1μF
V–
9
5
VINM
RBAL
100k
10
4
0.01μF
+
V–
V+
–
1.25pF V V –
VOCM
VVOCM
–OUTF
LTC6405
1.25pF
V–
12
SHDN
VSHDN
V–OUT
V–OUTF
RF
RBAL
100k
0.1μF
+OUTF
6405 F01
V+OUTF
V+OUT
DEFAULT VALUES
PACKAGE
RI
RF
CF
MSOP*
300Ω
300Ω
1.0pF
QFN
200Ω
200Ω
1.8pF
CF
(RI, RF : 0.1% RESISTORS)
*TO OPTIMIZE THE HIGH FREQUENCY PERFORMANCE FOR THE PIN CONFIGURATION OF THE LTC6405
IN THE SMALL MSOP PACKAGE, A FEEDBACK RESISTANCE OF AT LEAST 300Ω IS RECOMMENDED.
Figure 1. DC Test Circuit
6405fa
13
LTC6405
APPLICATIONS INFORMATION
The outputs (+OUT and –OUT) of the LTC6405 are capable
of swinging from close-to-ground to typically 1V below
V+. They can source or sink up to approximately 60mA of
current. Each output is designed to directly drive up to 5pF
to ground. Higher load capacitances should be decoupled
with at least 15Ω of series resistance from each output.
IC. The LTC6405 also has clamping diodes to either power
supply on the VOCM, VTIP and SHDN pins and if driven to
voltages which exceed either supply, they too, should be
current limited to under 10mA.
SHDN Pin
The SHDN pin is a CMOS logic input with a 50k internal
pull-up resistor. If the pin is driven low, the LTC6405 powers
down with Hi-Z outputs. If the pin is left unconnected or
driven high, the part is in normal active operation. Some
care should be taken to control leakage currents at this pin
to prevent inadvertently putting the LTC6405 into shutdown.
The turn-on and turn-off time between the shutdown and
active states are typically less than 1μs.
Input Pin Protection
The LTC6405 input stage is protected against differential
input voltages which exceed 1.4V by two pairs of series
diodes connected back to back between +IN and –IN. In
addition, the input pins have clamping diodes to either
power supply. If the input pins are over-driven, the current
should be limited to under 10mA to prevent damage to the
CF
0.1μF
RI
RF
RT
16
NC
15
+IN
V–OUTF
13
–OUTF
V–OUT
14
–OUT
LTC6405
1.25pF
V–
12
SHDN
•
VSHDN
1
50Ω
V+
+
V+
VIN
–
2
0.1μF
+
V+
50Ω
RT CHOSEN SO
THAT RT||RI = 100Ω
V–
0.1μF
4
50Ω
V+
V+
10
V – 0.1μF
–
1.25pF V V –
VOCM
VVOCM
0.1μF
1.25pF
–
V–
3
MINI-CIRCUITS
TCM4-19
V – V+
11
VOCM
V–
V–
V–
•
•
SHDN
•
50Ω
MINI-CIRCUITS
TCM4-19
0.1μF
100Ω
V+IN
0.1μF
V–
9
0.1μF
0.01μF
5
VTIP
6
–IN
7
+OUT
0.01μF
RT 0.1μF
RI
V–IN
8
+OUTF
V+OUTF
RF
V+OUT
100Ω
0.1μF
6405 F02
DEFAULT VALUES
PACKAGE
RI
RF
CF
MSOP*
300Ω
300Ω
1.0pF
QFN
200Ω
200Ω
1.8pF
CF
(RI, RF : 0.1% RESISTORS)
*TO OPTIMIZE THE HIGH FREQUENCY PERFORMANCE FOR THE PIN CONFIGURATION OF THE LTC6405
IN THE SMALL MSOP PACKAGE, A FEEDBACK RESISTANCE OF AT LEAST 300Ω IS RECOMMENDED.
Figure 2. AC Test Circuit (–3dB BW Testing)
6405fa
14
LTC6405
APPLICATIONS INFORMATION
General Amplifier Applications
As levels of integration have increased and correspondingly, system supply voltages decreased, there has been
a need for ADCs to process signals differentially in order
to maintain good signal to noise ratios. These ADCs are
typically supplied from a single supply voltage which can
be as low as 3V, and will have an optimal common mode
input range of 1.25V or 1.5V. The LTC6405 makes interfacing to these ADCs easy, by providing both single-ended
to differential conversion as well as common mode level
shifting. The gain to VOUTDIFF from VINM and VINP is:
R
VOUTDIFF = V+OUT – V–OUT ≈ F • ( VINP – VINM )
RI
Note from the above equation, the differential output voltage (V+OUT – V–OUT) is completely independent of input
and output common mode voltages, or the voltage at the
common mode pin. This makes the LTC6405 ideally suited
for pre-amplification, level shifting and conversion of single
ended signals to differential output signals in preparation
for driving differential input ADCs.
Effects of Resistor Pair Mismatch
Figure 3 shows a circuit diagram which takes into consideration that real world resistors will not match perfectly.
Assuming infinite open loop gain, the differential output
relationship is given by the equation:
R
VOUTDIFF = V+OUT – V–OUT ≅ F • VINDIFF +
RI
Δβ
Δβ
• VICM –
•V
β AVG OCM
β AVG
Δβ is defined as the difference in feedback factors:
Δβ =
RI2
RI1
–
RI2 + RF2 RI1 + RF1
VICM is defined as the average of the two input voltages VINP
and VINM (also called the input common mode voltage):
1
VICM = • ( VINP + VINM )
2
and VINDIFF is defined as the difference of the input voltages:
VINDIFF = VINP – VINM
VOCM is defined as the average of the two output voltages
V+OUT and V–OUT:
VOCM =
V+OUT + V−OUT
2
When the feedback ratios mismatch (Δβ), common mode
to differential conversion occurs.
Setting the differential input to zero (VINDIFF = 0), the degree of common mode to differential conversion is given
by the equation:
VOUTDIFF = V+OUT – V–OUT ≈ ( VICM – VOCM ) •
RI2
RF2
V–OUT
+
VINP
–
+
VVOCM
VOCM
–
–
VINM
where:
V+IN
+
RI1
V–IN
RF1
6405 F03
RF is the average of RF1, and RF2, and RI is the average
of RI1, and RI2.
βAVG is defined as the average feedback factor from the
outputs to their respective inputs:
Δβ
β AVG
V+OUT
Figure 3. Real-World Application with
Feedback Resistor Pair Mismatch
RI2 ⎞
1 ⎛ RI1
β AVG = • ⎜
+
2 ⎝ RI1 + RF1 RI2 + RF2 ⎟⎠
6405fa
15
LTC6405
APPLICATIONS INFORMATION
In general, the degree of feedback pair mismatch is a
source of common mode to differential conversion of both
signals and noise. Using 1% resistors or better will mitigate
most problems, and will provide about 34dB worst case of
common mode rejection. Using 0.1% resistors will provide
about 54dB of common mode rejection. A low impedance
ground plane should be used as a reference for both the
input signal source and the VOCM pin. Bypassing the VOCM
with a high quality 0.1μF ceramic capacitor to this ground
plane will further help prevent common mode signals from
being converted to differential signals.
There may be concern on how feedback factor mismatch
affects distortion. Feedback factor mismatch from using
1% resistors or better, has a negligible effect on distortion.
However, in single supply level shifting applications where
there is a voltage difference between the input common
mode voltage and the output common mode voltage,
resistor mismatch can make the apparent voltage offset
of the amplifier appear worse than specified.
The apparent input referred offset induced by feedback
factor mismatch is derived from the above equation:
the balanced differential case. The input impedance looking
into either input is:
RINP = RINM =
RI
⎛ 1 ⎛ RF ⎞ ⎞
⎜ 1– 2 • ⎜ R + R ⎟ ⎟
⎝ I F ⎠⎠
⎝
Input signal sources with non-zero output impedances
can also cause feedback imbalance between the pair of
feedback networks. For the best performance, it is recommended that the input source output impedance be
compensated for. If input impedance matching is required
by the source, a termination resistor R1 should be chosen
(see Figure 4):
R1=
RINM • RS
RINM – RS
RINM
RS
RI
RF
R1
VS
–
+
+
–
VOSDIFF(APPARENT) ≈ (VICM – VOCM) • Δβ
Using the LTC6405 in a single supply application on a
single 5V supply with 1% resistors, and the input common mode grounded, with the VOCM pin biased at 2.5V, the
worst case DC offset can induce 25mV of apparent offset
voltage. With 0.1% resistors, the worst case apparent
offset reduces to 2.5mV.
Input Impedance and Loading Effects
The input impedance looking into the VINP or VINM input
of Figure 1 depends on whether or not the sources VINP
and VINM are fully differential or not. For balanced input
sources (VINP = –VINM), the input impedance seen at either
input is simply:
R1 CHOSEN SO THAT R1 || RINM = RS
R2 CHOSEN TO BALANCE R1 || RS
RI
6405 F04
R2 = RS || R1
Figure 4. Optimal Compensation for Signal Source Impedance
According to Figure 4, the input impedance looking into
the differential amp (RINM) reflects the single ended source
case, thus:
RINM =
RINP = RINM = RI
For single ended inputs, because of the signal imbalance
at the input, the input impedance actually increases over
RF
RI
⎛ 1 ⎛ RF ⎞ ⎞
⎜ 1– 2 • ⎜ R + R ⎟ ⎟
⎝ I F ⎠⎠
⎝
R2 is chosen to equal R1 || RS:
R2 =
R1• RS
R1+ RS
6405fa
16
LTC6405
APPLICATIONS INFORMATION
Input Common Mode Voltage Range
Manipulating the Rail-to-Rail Input Stage with VTIP
The LTC6405’s input common mode voltage (VICM) is
defined as the average of the two input voltages, V+IN, and
V–IN. At the inputs to the actual op amp, the range extends
from V– to V+. This makes it easy to interface to a wide
range of common mode signals, from ground referenced to
VCC referenced signals. Moreover, due to external resistive
divider action of the gain and feedback resistors, the effective
range of signals that can be processed is even wider. The
input common mode range at the op amp inputs depends
on the circuit configuration (gain), VOCM and VCM (refer to
Figure 5). For fully differential input applications, where
VINP = –VINM, the common mode input is approximately:
To achieve rail-to-rail input operation, the LTC6405 features
an NPN input stage in parallel with a PNP input stage. When
the input common mode voltage is near V+, the NPNs are
active while the PNPs are off. When the input common
mode is near V–, the PNPs are active while the NPNs are
off. At some range in the middle, both input stages are
active. This ‘hand-off’ operation happens automatically.
VICM =
⎛ RI ⎞
V+IN + V–IN
+
≈ VOCM • ⎜
2
⎝ RI + RF ⎟⎠
⎛ RF ⎞
VCM • ⎜
⎝ RF + RI ⎟⎠
RI
V+IN
RF
V–OUT
+
VINP
–
+
VVOCM
+
VOCM
–
VCM
–
–
VINM
RI
+
V–IN
RF
6405 F05
V+OUT
In the QFN package, a special pin, VTIP, is made available
that can be used to manipulate the ‘hand-off’ operation
between the NPN and PNP input stages. By default, the
VTIP pin is internally biased by an internal resistive divider
between the supplies, developing a default 2.8V voltage
with a 5V supply. If desired, VTIP can be over-driven by
an external voltage (the Thevenin equivalent resistance is
approximately 17k).
If VTIP is pulled closer to V–, the range over which the NPN
input pair remains active is increased, while the range over
which the PNP input pair is active is reduced. In applications where the input common mode does not come close
to V– , this mode can be used to further improve linearity
beyond the specified performance (see Figure 6).
If VTIP is pulled closer to V+, the range over which the PNP
input pair remains active is increased, while the range over
which the NPN input pair is active is reduced. In applications where the input common mode does not come close
to V+, this mode can be used to further improve linearity
beyond the specified performance.
Figure 5. Circuit for Common Mode Range
⎛ RI ⎞
V + V–IN
VICM = +IN
≈ VOCM • ⎜
+
2
⎝ RI + RF ⎟⎠
⎛ RF
VCM • ⎜
⎝ R +R
F
I
⎞ VINP
⎟⎠ + 2
⎛ RF ⎞
•⎜
⎝ RF + RI ⎟⎠
DISTORTION (dBc)
With single ended inputs, there is an input signal component to the input common mode voltage. Applying only
VINP (setting VINM to zero), the input common voltage is
approximately:
–30
VS = 5V
RI = RF = 4997
–40 VOCM =VICM = 2.5V VOUTDIFF = 2VP-P
SINGLE-ENDED INPUT
RLOAD = 8007
QFN PACKAGE
–50
HD2
VTIP = OPEN
–60
HD3
–70
VTIP = OPEN
–80
HD2
VTIP =1V
–90
HD3
VTIP =1V
–100
–110
1
10
FREQUENCY (MHz)
100
6405 F06
Use the equations above to check that the VICM at the op
amp inputs is within range (V– to V+).
Figure 6. Manipulating VTIP to Improve Harmonic Distortion
6405fa
17
LTC6405
APPLICATIONS INFORMATION
Output Common Mode Voltage Range
Output Filter Considerations and Use
The output common mode voltage is defined as the average of the two outputs:
Filtering at the output of the LTC6405 is often desired to
provide anti-aliasing or to improve signal to noise ratio.
To simplify this filtering, the LTC6405 in the QFN package
includes an additional pair of differential outputs (+OUTF
and –OUTF) which incorporate an internal lowpass RC
network with a –3dB bandwidth of 850MHz (Figure 7).
VOUTCM = VOCM =
V+OUT + V–OUT
2
The VOCM pin sets this average by an internal common
mode feedback loop which internally forces VOUTCM = VOCM.
The output common mode range extends from 0.5V above
V– to typically 1V below V+. The VOCM voltage is internally
set by a resistive divider between the supplies, developing
a default voltage potential of 2.5V with a 5V supply.
In single supply applications, where the LTC6405 is used
to interface to an ADC, the optimal common mode input
range to the ADC is often determined by the ADC’s reference. If the ADC makes a reference available for setting
the input common mode voltage, it can be directly tied
to the VOCM pin (as long as it is able to drive the 19kΩ
Thevenin equivalent input impedance presented by the
VOCM pin).
The VOCM pin should be bypassed with a high quality
ceramic bypass capacitor of at least 0.01μF to filter any
common mode noise rather than being converted to differential noise and to prevent common mode signals on
this pin from being inadvertently converted to differential
signals by impedance mismatches both externally and
internally to the IC.
These pins each have an output resistance of 50Ω (tolerance ±12%). Internal capacitances are 1.25pF (tolerance
±15%) to V– on each filtered output, plus an additional
1.25pF (tolerance ±15%) capacitor connected between the
two filtered outputs. This resistor/capacitor combination
creates filtered outputs that look like a series 50Ω resistor
with a 3.75pF capacitor shunting each filtered output to
AC ground, providing a –3dB bandwidth of 850MHz, and
a noise bandwidth of 1335MHz. The filter cutoff frequency
is easily modified with just a few external components. To
increase the cutoff frequency, simply add two equal value
resistors, one between +OUT and +OUTF and the other
between –OUT and –OUTF (Figure 8). These resistors, in
parallel with the internal 50Ω resistors, lower the overall
resistance and therefore increase filter bandwidth. For
example, to double the filter bandwidth, add two external
50Ω resistors to lower the series filter resistance to 25Ω.
The 3.75pF of capacitance remains unchanged, so filter
bandwidth doubles. Keep in mind, the series resistance
also serves to decouple the outputs from load capacitance.
49.9Ω
–OUTF
–OUTF
LTC6405
14
–OUT
13
LTC6405
–OUTF
1.25pF
50Ω
14
–OUT
13
–OUTF
1.25pF
V–
12
50Ω
V–
V–
12
V–
+
+
FILTERED OUTPUT
1.25pF
–
–
50Ω
50Ω
–
1.25pF V V –
–
1.25pF V V –
9
9
7
+OUT
8
FILTERED OUTPUT
(1.7GHz)
1.25pF
+OUTF
7
6405 F07
+OUTF
Figure 7. LTC6405 Internal Filter Topology
+OUT
49.9Ω
8
+OUTF
6405 F08
+OUTF
Figure 8. LTC6405 Filter Topology Modified for 2x Filter
Bandwidth (Two External Resistors)
6405fa
18
LTC6405
APPLICATIONS INFORMATION
The outputs of the LTC6405 are designed to drive 5pF to
ground, so care should be taken to not lower the effective impedance between +OUT and +OUTF or –OUT and
–OUTF below 15Ω.
To decrease filter bandwidth, add two external capacitors,
one from +OUTF to ground, and the other from –OUTF to
ground. A single differential capacitor connected between
+OUTF and –OUTF can also be used, but since it is being
driven differentially it will appear at each filtered output
as a single-ended capacitance of twice the value. To halve
the filter bandwidth, for example, two 3.9pF capacitors
could be added (one from each filtered output to ground).
Alternatively, one 1.8pF capacitor could be added between
the filtered outputs, which also halves the filter bandwidth.
Combinations of capacitors could be used as well; a three
capacitor solution of 1.2pF from each filtered output to
ground plus a 1.2pF capacitor between the filtered outputs
would also halve the filter bandwidth (Figure 9).
the amplifier and the feedback components is governed
by the equation:
2
⎛
⎛ RF ⎞ ⎞
2
e
•
⎜ ni ⎜ 1+ R ⎟ ⎟ + 2 • (In • RF ) +
⎝
⎝
I ⎠⎠
eno =
2
⎛
⎛ R ⎞⎞
2 • ⎜ enRI • ⎜ F ⎟ ⎟ + 2 • enRF 2
⎝ RI ⎠ ⎠
⎝
A plot of this equation, and a plot of the noise generated
by the feedback components for the LTC6405 is shown
in Figure 11.
enRI2
RI
RF
in+2
encm2
+
–OUT
FILTERED OUTPUT
(425MHz)
50Ω
–
1.25pF V V –
7
TOTAL (AMPLIFIER AND
FEEDBACK NETWORK)
OUTPUT NOISE
10
1.2pF
9
6405 F09
8
enRF2
100
1.2pF
1.25pF
+OUT
RF
Figure 10. Noise Model of the LTC6405
V–
12
V–
–
RI
1.2pF
–OUTF
50Ω
eni2
6405 F10
–OUTF
1.25pF
+
enRI2
+OUTF
+OUTF
Figure 9. LTC6405 Filter Topology Modified for 1/2x Filter
Bandwidth (Three External Capacitors)
nV/ Hz
LTC6405
–
in–2
The LTC6405’s input referred voltage noise is 1.6nV/√Hz.
Its input referred current noise is 2.4pA/√Hz. In addition
to the noise generated by the amplifier, the surrounding
feedback resistors also contribute noise. A noise model is
shown in Figure 10. The output noise generated by both
13
eno2
VOCM
Noise Considerations
14
enRF2
FEEDBACK NETWORK
NOISE ALONE
1
0.1
10
100
1000
RI = RF (Ω)
10000
6405 F11
Figure 11. LTC6405 Output Spot Noise vs Spot Noise
Contributed by Feedback Network Alone
6405fa
19
LTC6405
APPLICATIONS INFORMATION
The LTC6405’s input referred voltage noise contributes the
equivalent noise of a 155Ω resistor. When the feedback
network is comprised of resistors whose values are less
than this, the LTC6405’s output noise is voltage noise
dominant (see Figure 11):
⎛ R ⎞
eno ≈ eni • ⎜ 1+ F ⎟
⎝ RI ⎠
Feedback networks consisting of resistors with values
greater than about 200Ω will result in output noise which
is resistor noise and amplifier current noise dominant.
eno ≈ 2 •
⎛
⎞
(In • RF )2 + ⎜⎝ 1+ RRF ⎟⎠ • 4 • k • T • RF
I
Lower resistor values (<100Ω) always result in lower noise
at the penalty of increased distortion due to increased loading of the feedback network on the output. Higher resistor
values (but still less than <500Ω) will result in higher
output noise, but typically improved distortion due to less
loading on the output. The optimal feedback resistance for
the LTC6405 runs in between 100Ω to 500Ω.
The differential filtered outputs +OUTF and –OUTF will
have a little higher noise than the unfiltered outputs (due
to the two 50Ω resistors which contribute 0.9nV/√Hz
each), but can provide superior signal-to-noise due to the
output noise filtering.
Layout Considerations
Because the LTC6405 is a very high speed amplifier, it is
sensitive to both stray capacitance and stray inductance.
In the QFN package, three pairs of power supply pins are
provided to keep the power supply inductance as low
as possible to prevent any degradation of amplifier 2nd
harmonic performance. It is critical that close attention be
paid to supply bypassing. For single supply applications
it is recommended that high quality 0.1μF surface mount
ceramic bypass capacitor be placed directly between each
V+ and V– pin with direct short connections. The V– pins
should be tied directly to a low impedance ground plane
with minimal routing. For dual (split) power supplies, it is
recommended that additional high quality, 0.1μF ceramic
capacitors are used to bypass V+ to ground and V– to
ground, again with minimal routing. For driving large loads
(<200Ω), additional bypass capacitance may be needed for
optimal performance. Keep in mind that small geometry
(e.g., 0603) surface mount ceramic capacitors have a much
higher self resonant frequency than do leaded capacitors,
and perform best in high speed applications.
Any stray parasitic capacitances to ground at the summing
junctions, +IN and –IN, should be minimized. This becomes
especially true when the feedback resistor network uses
resistor values >500Ω in circuits with RF = RI. Always keep
in mind the differential nature of the LTC6405, and that it
is critical that the load impedances seen by both outputs
(stray or intended), should be as balanced and symmetric
as possible. This will help preserve the natural balance
of the LTC6405, which minimizes the generation of even
order harmonics, and improves the rejection of common
mode signals and noise.
It is highly recommended that the VOCM pin be bypassed
to ground with a high quality ceramic capacitor whose
value exceeds 0.01μF. This will help stabilize the common
mode feedback loop as well as prevent thermal noise from
the internal voltage divider and other external sources of
noise from being converted to differential noise due to
divider mismatches in the feedback networks. It is also
recommended that the resistive feedback networks be
comprised of 1% resistors (or better) to enhance the
output common mode rejection. This will also prevent
VOCM input referred common mode noise of the common
mode amplifier path (which cannot be filtered) from being
converted to differential noise, degrading the differential
noise performance.
Feedback factor mismatch has a weak effect on distortion.
Using 1% or better resistors will limit any mismatch from
impacting amplifier linearity. However, in single supply
level shifting applications where there is a voltage difference between the input common mode voltage and the
output common mode voltage, resistor mismatch can
make the apparent voltage offset of the amplifier appear
worse than specified.
6405fa
20
LTC6405
APPLICATIONS INFORMATION
Interfacing the LTC6405 to A/D Converters
Rail-to-rail input and fast settling time make the LTC6405
ideal for interfacing to low voltage, single supply, differential input ADCs. The sampling process of ADCs create
a sampling glitch caused by switching in the sampling
capacitor on the ADC front end which momentarily “shorts”
the output of the amplifier as charge is transferred between
the amplifier and the sampling capacitor. The amplifier
must recover and settle from this load transient before
this acquisition period ends for a valid representation of
the input signal. In general, the LTC6405 will settle much
more quickly from these periodic load impulses than from
a 2V input step, but it is a good idea to place an R-C filter
network between the differential outputs of the LTC6405
and the input of the ADC to help absorb the charge injection
that comes out of the ADC from the sampling process.
The capacitance of the filter network serves as a charge
reservoir to provide high frequency charging during the
sampling process, while the resistors of the filter network
are used to dampen and attenuate any charge kickback
from the ADC. The selection of the R-C time constant is
trial and error for a given ADC, but the following guidelines
are recommended: Choosing too large of a resistor in the
decoupling network leaving insufficient settling time will
create a voltage divider between the dynamic input impedance of the ADC and the decoupling resistors. Choosing
too small of a resistor will possibly prevent the resistor
from properly dampening the load transient caused by
the sampling process, prolonging the time required for
settling. In 16-bit applications, this will typically require
a minimum of 11 R-C time constants. It is recommended
that the capacitor chosen have a high quality dielectric
(such as C0G multilayer ceramic).
1.8pF
VIN, 2VP-P
200Ω
200Ω
16
NC
15
+IN
20Ω
14
–OUT
13
SHDN
SHDN
–OUTF
LTC6405
1.25pF
V–
1
2
0.1μF
+
1.25pF
V+
VOCM
V–
–
V–
3
V– V+
11
50Ω
V+
5V
CONTROL
12
50Ω
V+
10
–
1.25pF V V–
VOCM
4
0.1μF
5V
0.1μF
+INA
4.7pF
4.7pF
4.7pF
LTC2208
D15
•
•
D0
–INA
VCM GND VDD
1μF
3.3V
1μF
9
0.1μF
5
VTIP
6
–IN
7
+OUT
8
+OUTF
6405 F12
2.2μF
0.1μF
100Ω
200Ω
200Ω
20Ω
1.8pF
Figure 12. Interfacing the LTC6405 to an ADC
6405fa
21
LTC6405
TYPICAL APPLICATION
Attenuating and Level Shifting a Single-Ended ±5V Signal to a
Differential 2VP-P Signal at a 1.25V Common Mode
C1, 2.7pF
2VP-P DIFF OUTPUT
LEVEL-SHIFTED TO 1.25V
R3, 1007
R5
5117
p5V SINE WAVE
(10VP-P)
CENTERED AT 0V
R1
51.17
– +
R6
5117
VIN
3.3V
5V
R2
51.17
LTC6405
+ –
LTC2207
6405 TA03
VCM = 1.25V
R4, 1007
2.2μF
C2, 2.7pF
PACKAGE DESCRIPTION
MS8E Package
8-Lead Plastic MSOP, Exposed Die Pad
(Reference LTC DWG # 05-08-1662 Rev D)
BOTTOM VIEW OF
EXPOSED PAD OPTION
0.889 ± 0.127
(.035 ± .005)
2.794 ± 0.102
(.110 ± .004)
1
2.06 ± 0.102
(.081 ± .004)
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
8
7 6 5
1.83 ± 0.102
(.072 ± .004)
5.23
(.206)
MIN
2.083 ± 0.102 3.20 – 3.45
(.082 ± .004) (.126 – .136)
0.65
(.0256)
BSC
0.42 ± 0.038
(.0165 ± .0015)
TYP
0.254
(.010)
1
8
0° – 6° TYP
2 3
1.10
(.043)
MAX
DETAIL “A”
DETAIL “A”
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
RECOMMENDED SOLDER PAD LAYOUT
0.52
(.0205)
REF
4
0.86
(.034)
REF
0.18
(.007)
SEATING
PLANE
GAUGE PLANE
0.53 ± 0.152
(.021 ± .006)
NOTE:
1. DIMENSIONS IN MILLIMETER/(INCH)
2. DRAWING NOT TO SCALE
3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR
GATE BURRS. MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL
NOT EXCEED 0.152mm (.006") PER SIDE
0.22 – 0.38
(.009 – .015)
TYP
0.65
(.0256)
BSC
0.1016 ± 0.0508
(.004 ± .002)
MSOP (MS8E) 0307 REV D
4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
6405fa
22
LTC6405
PACKAGE DESCRIPTION
UD Package
16-Lead Plastic QFN (3mm × 3mm)
(Reference LTC DWG # 05-08-1691)
0.70 ±0.05
3.50 ± 0.05
1.45 ± 0.05
2.10 ± 0.05 (4 SIDES)
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
3.00 ± 0.10
(4 SIDES)
BOTTOM VIEW—EXPOSED PAD
PIN 1 NOTCH R = 0.20 TYP
OR 0.25 × 45° CHAMFER
R = 0.115
TYP
0.75 ± 0.05
15
16
PIN 1
TOP MARK
(NOTE 6)
0.40 ± 0.10
1
1.45 ± 0.10
(4-SIDES)
2
(UD16) QFN 0904
0.200 REF
0.00 – 0.05
NOTE:
1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION (WEED-2)
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
0.25 ± 0.05
0.50 BSC
6405fa
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
23
LTC6405
TYPICAL APPLICATION
DC-Coupled Level Shifting of Demodulator Output
5V
LT5575
5V
C5, 10pF
DIFF OUTPUT Z
1307\\2.5pF
5V
DC LEVEL
1.5V
R5, 3247
5pF
I
657
5pF
DC LEVEL
3.8V
657
5V
+ –
LTC6405
15nH
RF IN
900MHz
–7dBm
5V
– +
5V
C1
4.7pF
4.7pF
5pF
LO
OdBm
Q
657
R9
107 10dBm
R7
49.97
15nH
3.3V
C8
4.7pF
R8
49.97
C2
4.7pF
C6
R10
4.7pF 107
LTC2249
14-BIT ADC
VCM
C7
4.7pF
5pF
6405 TA02
VOCM = 1.5V
657
R6, 3247
3.9pF
C4, 10pF
IDENTICAL
Q CHANNEL
GAIN: 3dB
INPUT NF: 13dB
OIP3: 31dBm
80MHz
SAMPLE
CLOCK
GAIN: 14dB
INPUT NF: 11dB
OIP3: 44dBm AT 30MHz
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1993-2/LT1993-4/
LT1993-10
800MHz/900MHz/700MHz Low Distortion, Low Noise Differential A V = 2V/V / A V = 4V/V / A V = 10V/V, NF = 12.3dB/14.5dB/
12.7dB, OIP3 = 38dBm/40dBm/40dBm at 70MHz
Amplifier/ADC Driver
LT1994
Low Noise, Low Distortion Fully differential Input/Output
Amplifier/Driver
Low Distortion, 2VP-P, 1MHz: –94dBc, 13mA,
Low Noise: 3nV/√Hz
LTC6400-8/LTC6400-14/ 1.8GHz Low Noise, Low Distortion, Differential ADC Driver
LTC6400-20/LTC6400-26
300MHz IF Amplifier, A V = 20dB/26dB
LTC6401-8/LTC6401-14/ 1.3GHz Low Noise, Low Distortion, Differential ADC Driver
LTC6401-20/LTC6401-26
140MHz IF Amplifier, A V = 20dB/26dB
LT6402-6/LT6402-12/
LT6402-20
300MHz/300MHz/300MHz Low Distortion, Low Noise Differential A V = 6dB/A V = 12dB/A V = 20dB, NF = 18.6dB/15dB/12.4dB,
Amplifier/ADC Driver
OIP3 = 49dBm/43dBm/51dBm at 20MHz
LTC6404-1/ LTC6404-2/ 600MHz Low Noise, Low Distortion, Differential ADC Driver
LTC6404-4
1.5nV/√Hz Noise, –90dBc Distortion at 10MHz
LTC6406
3GHz Low Noise, 3V, Rail-to-Rail Input Differential Amplifier/Driver 1.6nV/√Hz Noise, –70dBc Distortion at 50MHz, 18mA, 3V Supply
LTC6411
Low Power Differential ADC Driver/Dual Selectable Gain Amplifier 16mA Supply Current, IMD3 = –83dBC at 70MHz, AV = 1, –1,
or 2
LT6600-2.5/LT6600-5/
LT6600-10/LT6600-20
Very Low Noise, Fully Differential Amplifier and 4th
Order Filter
2.5MHz/5MHz/10MHz/20MHz Integrated Filter, 3V Supply,
SO-8 Package
LTC6403-1
200MHz Low Noise, Low Power Differential ADC Driver
–95dBc Distortion at 3MHz, 10.8mA Supply Current
6405fa
24 Linear Technology Corporation
LT 1008 REV A • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2008