LINER LTC2376-18 Precision, low power rail-to-rail input/output Datasheet

LTC6362
Precision, Low Power
Rail-to-Rail Input/Output
Differential Op Amp/SAR
ADC Driver
DESCRIPTION
FEATURES
n
n
n
n
n
n
n
n
n
n
n
n
n
1mA Supply Current
Single 2.8V to 5.25V supply
Fully Differential Input and Output
200μV Max Offset Voltage
260nA Max Input Bias Current
Fast Settling: 550ns to 18-Bit, 8VP-P Output
Low Distortion: –116dBc at 1kHz, 8VP-P
Rail-to-Rail Inputs and Outputs
3.9nV/√Hz Input-Referred Noise
180MHz Gain-Bandwidth Product
34MHz –3dB Bandwidth
Low Power Shutdown: 70µA
8-Lead MSOP and 3mm × 3mm 8-Lead DFN Packages
APPLICATIONS
n
n
n
n
n
16-Bit and 18-Bit SAR ADC Drivers
Single-Ended-to-Differential Conversion
Low Power Pipeline ADC Driver
Differential Line Drivers
Battery-Powered Instrumentation
The LTC®6362 is a low power, low noise differential op
amp with rail-to-rail input and output swing that has been
optimized to drive low power SAR ADCs. The LTC6362
draws only 1mA of supply current in active operation, and
features a shutdown mode in which the current consumption is reduced to 70μA.
The amplifier may be configured to convert a singleended input signal to a differential output signal, and is
capable of being operated in an inverting or noninverting
configuration.
Low offset voltage, low input bias current, and a stable
high impedance configuration make this amplifier suitable for use not only as an ADC driver but also earlier in
the signal chain, to convert a precision sensor signal to
a balanced (differential) signal for processing in noisy
industrial environments.
The LTC6362 is available in an 8-lead MSOP package and
also in a compact 3mm × 3mm 8-pin leadless DFN package, and operates with guaranteed specifications over a
–40°C to 125°C temperature range.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
TYPICAL APPLICATION
LTC6362 Driving LTC2379-18
fIN = 2kHz, –1dBFS, 16384-Point FFT
1k
5V
1k
VIN
VOCM
0.1µF
SHDN
1k
5V
2.5V
VREF
VDD
3.9nF
35.7Ω
– +
LTC6362
+ –
1k
35.7Ω
AIN+
3.9nF
3.9nF
AIN–
18-BIT
LTC2379-18
SAR ADC
1.6Msps
GND
6362 TA01a
AMPLITUDE (dBFS)
DC-Coupled Interface from a Ground-Referenced
Single-Ended Input to an LTC2379-18 SAR ADC
0
–10
–20
–30
–40
–50
–60
–70
–80
–90
–100
–110
–120
–130
–140
–150
VS = 5V, 0V
VOUTDIFF = 8.9VP-P
HD2 = –116.0dBc
HD3 = –114.9dBc
SFDR = 110.1dB
THD = –108.0dB
SNR = 101.2dB
SINAD = 99.9dB
0
100 200 300 400 500 600 700 800
FREQUENCY (kHz)
6362 TA01b
6362fa
1
LTC6362
ABSOLUTE MAXIMUM RATINGS
(Note 1)
Total Supply Voltage (V+ – V–)..................................5.5V
Input Current (+IN, –IN, VOCM, SHDN) (Note 2).... ±10mA
Output Short-Circuit Duration (Note 3)............. Indefinite
Operating Temperature Range (Note 4)
LTC6362C/LTC6362I.............................–40°C to 85°C
LTC6362H........................................... –40°C to 125°C
Specified Temperature Range (Note 5)
LTC6362C................................................. 0°C to 70°C
LTC6362I..............................................–40°C to 85°C
LTC6362H........................................... –40°C to 125°C
Maximum Junction Temperature........................... 150°C
Storage Temperature Range................... –65°C to 150°C
PIN CONFIGURATION
TOP VIEW
TOP VIEW
–IN 1
VOCM 2
V+ 3
+OUT 4
8
7
6
5
+IN
SHDN
V–
–OUT
–IN 1
8
+IN
VOCM 2
7
SHDN
V+ 3
6
V–
5
–OUT
+OUT 4
MS8 PACKAGE
8-LEAD PLASTIC MSOP
TJMAX = 150°C, θJA = 273°C/W, θJC = 45°C/W
9
V–
DD PACKAGE
8-LEAD (3mm × 3mm) PLASTIC DFN
TJMAX = 150°C, θJA = 39.7°C/W, θJC = 45°C/W
EXPOSED PAD (PIN 9) IS V–, MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
SPECIFIED TEMPERATURE RANGE
LTC6362CMS8#PBF
LTC6362CMS8#TRPBF
LTGCN
8-Lead Plastic MSOP
0°C to 70°C
LTC6362IMS8#PBF
LTC6362IMS8#TRPBF
LTGCN
8-Lead Plastic MSOP
–40°C to 85°C
LTC6362HMS8#PBF
LTC6362HMS8#TRPBF
LTGCN
8-Lead Plastic MSOP
–40°C to 125°C
LTC6362CDD#PBF
LTC6362CDD#TRPBF
LGCM
8-Lead (3mm × 3mm) Plastic DFN
0°C to 70°C
LTC6362IDD#PBF
LTC6362IDD#TRPBF
LGCM
8-Lead (3mm × 3mm) Plastic DFN
–40°C to 85°C
LTC6362HDD#PBF
LTC6362HDD#TRPBF
LGCM
8-Lead (3mm × 3mm) Plastic DFN
–40°C to 125°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
Consult LTC Marketing for information on non-standard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
6362fa
2
LTC6362
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. 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
VOSDIFF (Note 6)
PARAMETER
Differential Offset Voltage (Input Referred)
CONDITIONS
VS = 3V
VICM =1.5V
MIN
TYP
MAX
UNITS
50
200
350
250
600
µV
µV
µV
µV
200
350
260
600
2.5
2.5
µV
µV
µV
µV
µV/°C
µV/°C
±350
±500
±350
±850
nA
nA
nA
nA
±260
±460
±350
±850
nA
nA
nA
nA
nA/°C
nA/°C
±325
±650
±425
±1200
nA
nA
nA
nA
±325
±500
±425
±1200
l
65
VICM = 2.75V
l
VS = 5V
VICM = 2.5V
50
l
75
VICM = 4.5V
l
∆VOSDIFF/∆T (Note 7) Differential Offset Voltage Drift (Input Referred) VS = 3V
VS = 5V
Input Bias Current
VS = 3V
IB (Note 8)
VICM =1.5V
0.9
0.9
l
l
±100
l
±75
VICM = 2.5V
l
VS = 5V
VICM = 2.5V
±75
l
±75
VICM = 4.5V
l
∆IB/∆T
Input Bias Current Drift
IOS (Note 8)
Input Offset Current
VS = 3V
VS = 5V
VS = 3V
VICM =1.5V
1.1
0.9
l
l
±75
l
±125
VICM = 2.5V
l
VS = 5V
VICM =2.5V
±75
l
0
0
70
73
75
55
80
95
98
100
90
105
nA
nA
nA
nA
MΩ
kΩ
pF
nV/√Hz
pA/√Hz
nV/√Hz
V
V
dB
dB
dB
dB
dB
l
58
72
dB
l
±125
VICM = 4.5V
l
RIN
Input Resistance
CIN
en
in
envocm
VICMR (Note 9)
Input Capacitance
Differential Input Noise Voltage Density
Input Noise Current Density
Common Mode Noise Voltage Density
Input Common Mode Range
CMRRI (Note 10)
Input Common Mode Rejection Ratio
(Input Referred) ∆VICM/∆VOSDIFF
Output Common Mode Rejection Ratio
(Input Referred) ∆VOCM/∆VOSDIFF
Differential Power Supply Rejection
(∆VS/∆VOSDIFF)
Output Common Mode Power Supply Rejection VS = 2.8V to 5.25V
(∆VS/∆VOSCM)
CMRRIO (Note 10)
PSRR (Note 11)
PSRRCM (Note 11)
Common Mode
Differential Mode
Differential Mode
f = 100kHz, Not Including RI/RF Noise
f = 100kHz, Not Including RI/RF Noise
f = 100kHz
VS = 3V
VS = 5V
VS = 3V, VICM from 0V to 3V
VS = 5V, VICM from 0V to 5V
VS = 3V, VOCM from 0.5V to 2.5V
VS = 5V, VOCM from 0.5V to 4.5V
VS = 2.8V to 5.25V
14
32
2
3.9
0.8
14.3
l
l
l
l
l
l
3
5
6362fa
3
LTC6362
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. 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
GCM
Common Mode Gain (∆VOUTCM/∆VOCM)
∆GCM
Common Mode Gain Error 100 • (GCM – 1)
BAL
Output Balance (∆VOUTCM/∆VOUTDIFF)
AVOL
VOSCM
∆VOSCM/∆T
VOUTCMR (Note 9)
PARAMETER
Open-Loop Voltage Gain
Common Mode Offset Voltage
(VOUTCM – VOCM)
Common Mode Offset Voltage Drift
VOCM
Output Signal Common Mode Range
(Voltage Range for the VOCM Pin)
Self-Biased Voltage at the VOCM Pin
RINVOCM
VOUT
Input Resistance, VOCM Pin
Output Voltage, High, Either Output Pin
ISC
SR
GBWP
l
l
TYP
1
1
±0.07
±0.07
±0.16
±0.4
∆VOUTDIFF = 2V
Single-Ended Input
Differential Input
l
l
–57
–57
–35
–35
dB
dB
VS = 3V
VS = 5V
l
l
95
±6
±6
45
±30
±30
dB
mV
mV
μV/°C
–3dB Bandwidth
2nd/3rd Order Harmonic Distortion
Single-Ended Input
ts
Settling Time to a 2VP-P Output Step
Settling Time to a 8VP-P Output Step
Supply Voltage Range
Supply Current
MIN
l
l
l
VOCM Driven Externally, VS = 3V
VOCM Driven Externally, VS = 5V
VOCM Not Connected, VS = 3V
VOCM Not Connected, VS = 5V
l
l
l
l
l
IL= 0mA, VS = 3V
IL = –5mA, VS = 3V
IL= 0mA, VS = 5V
IL = –5mA, VS = 5V
Output Voltage, Low , Either Output Pin
IL= 0mA, VS = 3V
IL = 5mA, VS = 3V
IL= 0mA, VS = 5V
IL = 5mA, VS = 5V
Output Short-Circuit Current, Either Output Pin VS = 3V
VS = 5V
Slew Rate
Differential 8VP-P Output
Gain-Bandwidth Product
fTEST = 200kHz
f–3dB
HD2/HD3
VS (Note 12)
IS
CONDITIONS
VS = 3V, VOCM from 0.5V to 2.5V
VS = 5V, VOCM from 0.5V to 4.5V
VS = 3V, VOCM from 0.5V to 2.5V
VS = 5V, VOCM from 0.5V to 4.5V
l
l
l
l
0.5
0.5
1.475
2.475
110
2.85
2.75
4.8
4.7
l
l
l
l
l
l
13
15
l
145
90
RI = RF = 1k
f = 1kHz, VOUT = 8VP-P
f = 10kHz, VOUT = 8VP-P
f = 100kHz, VOUT = 8VP-P
0.1%
0.01%
0.0015% (16-Bit)
4ppm (18-Bit)
0.1%
0.01%
0.0015% (16-Bit)
4ppm (18-Bit)
1.5
2.5
170
2.93
2.85
4.93
4.85
0.05
0.13
0.05
0.13
25
35
45
180
MAX
2.5
4.5
1.525
2.525
230
0.15
0.3
0.2
0.4
34
–120/–116
–106/–103
–84/–76
160
180
230
440
230
300
460
550
l
VS = 3V, Active
2.8
0.9
l
VS = 3V, Shutdown
VS = 5V, Active
l
VS = 5V, Shutdown
l
55
1
l
70
5.25
0.96
1.05
130
1.06
1.18
140
UNITS
V/V
V/V
%
%
V
V
V
V
kΩ
V
V
V
V
V
V
V
V
mA
mA
V/μs
MHz
MHz
MHz
dBc
dBc
dBc
ns
ns
ns
ns
ns
ns
ns
ns
V
mA
mA
µA
mA
mA
µA
6362fa
4
LTC6362
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. 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
VIL
VIH
tON
tOFF
PARAMETER
SHDN Input Logic Low
SHDN Input Logic High
Turn-On Time
Turn-Off Time
CONDITIONS
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 and SHDN) 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 LTC6362C and LTC6362I are guaranteed functional over
the operating temperature range of –40°C to 85°C. The LTC6362H is
guaranteed functional over the operating temperature range of –40°C to
125°C.
Note 5: The LTC6362C is guaranteed to meet specified performance from
0°C to 70°C.The LTC6362I is guaranteed to meet specified performance
from –40°C to 85°C. The LTC6362C 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 LTC6362H is guaranteed
to meet specified performance from –40°C to 125°C.
Note 6: Differential input referred offset voltage includes offset due to
input offset current across 1k source resistance.
Note 7: Maximum differential input referred offset voltage drift is
determined by a large sampling of typical parts. Drift is not guaranteed by
test or QA sampled at this value.
Note 8: Input bias current is defined as the maximum of the input currents
flowing into either of the input pins (–IN and +IN). Input Offset current is
defined as the difference between the input currents (IOS = IB+ – IB–).
MIN
TYP
l
l
2
2
2
MAX
0.8
UNITS
V
V
μs
μs
Note 9: Input common mode range is tested by verifying that at the limits
stated in the Electrical Characteristics table, the differential offset (VOSDIFF)
and common mode offset (VOSCM) have not deviated by more than ±1mV
and ±35mV respectively compared to the VICM = 2.5V (at VS = 5V) and
VICM = 1.5V (at VS = 3V) cases.
Output common mode range is tested by verifying that at the limits stated
in the Electrical Characteristics table, the common mode offset (VOSCM)
has not deviated by more than ±15mV compared to the VOCM = 2.5V
(at VS = 5V) and VOCM = 1.5V (at VS = 3V) cases.
Note 10: 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 offset voltage. Output CMRR is defined as the ratio of
the change in the voltage at the VOCM pin to the change in differential
input referred offset voltage. 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
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 11: Differential power supply rejection (PSRR) is defined as the
ratio of the change in supply voltage to the change in differential input
referred offset voltage. 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 voltage.
Note 12: Supply voltage range is guaranteed by power supply rejection
ratio test.
6362fa
5
LTC6362
TYPICAL PERFORMANCE CHARACTERISTICS
100
VS = ±2.5V
VICM = 0V
VOCM = 0V
FIVE TYPICAL UNITS
250
200
150
Differential Input Offset Voltage
vs Input Common Mode Voltage
100
50
0
–50
–100
VS = ±2.5V
75 VICM = 0V
VOCM = 0V
50 FIVE TYPICAL UNITS
DIFFERENTIAL INPUT OFFSET VOLTAGE (µV)
300
Input Offset Current
vs Temperature
INPUT OFFSET CURRENT (nA)
DIFFERENTIAL INPUT OFFSET VOLTAGE (µV)
Differential Input Offset Voltage
vs Temperature
25
0
–25
–50
–75
–150
–200
–50 –25
50
25
0
75
TEMPERATURE (°C)
100
–100
–50 –25
125
75
50
25
TEMPERATURE (°C)
0
100
Common Mode Offset Voltage
vs Temperature
800
100
50
0
–50
–100
–200
–5
1
3
4
2
INPUT COMMON MODE VOLTAGE (V)
5
Supply Current vs Temperature
1.2
1.1
200
0
–200
–400
–600
–800
–1000
VS = 5V
1.0
VS = 3V
0.9
0.8
–1200
–10
0
6362 G03
SUPPLY CURRENT (mA)
0
TA = 125°C
TA = 25°C
TA = –40°C
–150
400
5
–1400
–15
–50
50
25
0
75
TEMPERATURE (°C)
–25
100
125
–1600
0
1
3
4
2
INPUT COMMON MODE VOLTAGE (V)
Supply Current
vs Supply Voltage
1.2
90
VS = 5V
0.4
TA = 125°C
TA = 25°C
TA = –40°C
0.2
0
1
3
4
2
SUPPLY VOLTAGE (V)
0.8
0.6
0.4
TA = 125°C
TA = 25°C
TA = –40°C
0.2
5
6362 G07
0
0
1
3
2
SHDN VOLTAGE (V)
4
125
VSHDN = V–
80
SUPPLY CURRENT (µA)
0.6
100
Shutdown Supply Current
vs Supply Voltage
1.0
SUPPLY CURRENT (mA)
1.0
0.8
50
25
0
75
TEMPERATURE (°C)
6362 G06
Supply Current vs SHDN Voltage
1.2
0
0.7
–50 –25
5
6362 G05
6362 G04
SUPPLY CURRENT (mA)
150
VS = 5V
600
INPUT BIAS CURRENT (nA)
COMMON MODE OFFSET VOLTAGE (mV)
10
200
Input Bias Current vs Input
Common Mode Voltage
VS = ±2.5V
VICM = 0V
VOCM = 0V
FIVE TYPICAL UNITS
VS = 5V, 0V
VOCM = 2.5V
TYPICAL UNIT
250
6362 G02
6362 G01
15
125
300
70
60
50
40
30
20
TA = 125°C
TA = 25°C
TA = –40°C
10
5
6362 G08
0
0
1
2
3
SUPPLY VOLTAGE (V)
4
5
6362 G09
6362fa
6
LTC6362
TYPICAL PERFORMANCE CHARACTERISTICS
Input Noise Density vs Frequency
INPUT VOLTAGE NOISE DENSITY (nV/√Hz)
VSHDN
1V/DIV
VOUTDIFF
5µs/DIV
10
100
10
en
in
1
0.1
6362 G10
VS = ±2.5V
VICM = VOCM = 0V
10
100
1
1k
10k 100k
FREQUENCY (Hz)
1M
1000
INPUT CURRENT NOISE DENSITY (pA/√Hz)
100
OUTPUT IMPEDANCE (Ω)
Turn-On and Turn-Off
Transient Response
Differential Output Impedance
vs Frequency
VS = ±2.5V
RI = RF = 1k
100
10
1
100k
0.1
10M
1M
10M
100M
FREQUENCY (Hz)
6362 G11
Common Mode Rejection Ratio
vs Frequency
70
60
50
40
1k
10k
100k
1M
10M
FREQUENCY (Hz)
100M
1G
Slew Rate vs Temperature
60
VS = ±2.5V
PSRR+
PSRR–
110
100
55
90
SLEW RATE (V/µs)
80
120
POWER SUPPLY REJECTION RATIO (dB)
VS = ±2.5V
90
30
6362 G12
Differential Power Supply
Rejection Ratio vs Frequency
80
70
60
50
40
30
VS = ±2.5V
RI = RF = 1k
VOUTDIFF = 8VP-P
DIFFERENTIAL INPUT
SLEW MEASURED 10% TO 90%
FALLING
50
RISING
45
20
10
0
1k
10k
100k
1M
10M
FREQUENCY (Hz)
100M
6362 G13
1G
40
–50 –25
75
50
25
TEMPERATURE (°C)
0
6362 G14
Small-Signal Step Response
100
125
6362 G15
Overdriven Output Transient
Response
Large-Signal Step Response
VINDIFF
V+OUT
1V/DIV
500mV/DIV
V+OUT
20mV/DIV
COMMON MODE REJECTION RATIO (dB)
100
1G
V–OUT
V–OUT
100ns/DIV
VS = ±2.5V
VINDIFF = 200mVP-P
RI = RF = 1k
RLOAD = 1k
6362 G16
VS = ±2.5V
VINDIFF = 8VP-P
RLOAD = 1k
100ns/DIV
VOUTDIFF
6362 G17
VS = ±2.5V
VINDIFF = 13VP-P
RLOAD = 1k
1µs/DIV
6362 G18
6362fa
7
LTC6362
TYPICAL PERFORMANCE CHARACTERISTICS
Frequency Response
vs Closed-Loop Gain
Frequency Peaking
vs Load Capacitance
2.00
60
VS = ±2.5V
50 VICM = VOCM = 0V
RLOAD = 1k
FREQUENCY PEAKING (dB)
GAIN (dB)
40
AV = 1, RI = 1k, RF = 1k
AV = 2, RI = 500Ω, RF = 1k
AV = 5, RI = 400Ω, RF = 2k
AV = 10, RI = 200Ω, RF = 2k
AV = 20, RI = 100Ω, RF = 2k
AV = 100, RI = 20Ω, RF = 2k
30
20
10
0
1.50
1.25
1.00
0.75
0.50
CAPACITOR VALUES ARE
FROM EACH OUTPUT TO
GROUND THROUGH 35Ω
SERIES RESISTANCE
0.25
–10
–20
100k
VS = ±2.5V
VICM = 0V
VOCM = 0V
RI = RF = 1k
RLOAD = 1k
1.75
1M
10M
100M
FREQUENCY (Hz)
0
1G
10
100
1000
CAPACITIVE LOAD (pF)
6362 G19
500
16-BIT
400
300
200
100
0
2
6
3
7
5
4
DIFFERENTIAL OUTPUT STEP (VP-P)
8
VS = 5V, 0V
RI = RF = 1k
4
100
120
80
3
90
2
60
1
30
ERROR
0
0
–1
–30
–2
–60
–3
–90
VOUTDIFF
–4
–5
0.5µs/DIV
DIFFERENTIAL OUTPUT ERROR
FROM LINEAR FIT (µV)
SETTLING TIME (ns)
18-BIT
DC Linearity
150
ERROR (µV) 1 DIV = 18-BIT ERROR
VS = 5V, 0V
RI = RF = 1k
600
5
DIFFERENTIAL OUTPUT VOLTAGE (V)
700
6362 G20
Settling Time to 8VP-P
Output Step
Settling Time vs Output Step
10000
40
20
0
–20
VS = ±2.5V
VICM = VOCM = 0V
RI = RF = 1k
NO LOAD
LINEAR FIT FOR –4V < VINDIFF < 4V
–40
–60
–80
–120
–100
–5 –4 –3 –2 –1 0 1
VINDIFF (V)
–150
6362 G22
60
2
4
3
6362 G21
6362 G23
Harmonic Distortion vs Input
Common Mode Voltage
–90
HD3
–100
HD2
–110
–90
–100
HD3
–110
–120
10
FREQUENCY (kHz)
100
6362 G24
–140
0
–100
HD2
–110
HD3
–120
–130
1
VS = 5V, 0V
VOCM = 2.5V
RI = RF = 1k
fIN = 2kHz
SINGLE-ENDED INPUT,
GROUND REFERENCED
–90
HD2
–120
–130
–80
VS = 5V, 0V
VOCM = 2.5V
RI = RF = 1k
VOUTDIFF = 8VP-P
fIN = 2kHz
DIFFERENTIAL INPUTS
–80
DISTORTION (dBc)
–80
DISTORTION (dBc)
–70
VS = 5V, 0V
VOCM = 2.5V
RI = RF = 1k
VOUTDIFF = 8VP-P
SINGLE-ENDED INPUT,
GROUND REFERENCED
Harmonic Distortion vs Output
Amplitude
DISTORTION (dBc)
Harmonic Distortion vs Frequency
–70
5
4
1
3
2
INPUT COMMON MODE VOLTAGE (V)
5
6362 G25
–130
0
2
6
4
VOUTDIFF (VP-P)
8
10
6362 G26
6362fa
8
LTC6362
PIN FUNCTIONS
–IN (Pin 1): Inverting Input of Amplifier. Valid input range
is from V– to V+.
VOCM (Pin 2): Output Common Mode Reference Voltage.
The voltage on this pin sets the output common mode
voltage level. If left floating, an internal resistor divider
develops a default voltage of 2.5V with a 5V supply.
V+ (Pin 3): Positive Power Supply. Operational supply
range is 2.8V to 5.25V when V– = 0V.
+OUT (Pin 4): Positive Output Pin. Output capable of
swinging rail-to-rail.
V– (Pin 6/Exposed Pad Pin 9): Negative Power Supply,
Typically 0V. Negative supply can be negative as long as
2.8V ≤ (V+ – V–) ≤ 5.25V still holds.
SHDN (Pin 7): When SHDN is floating or directly tied to
V+ the LTC6362 is in the normal (active) operating mode.
When the SHDN pin is connected to V–, the part is disabled
and draws approximately 70µA of supply current.
+IN (Pin 8): Noninverting Input of Amplifier. Valid input
range is from V– to V+.
–OUT (Pin 5): Negative Output Pin. Output capable of
swinging rail-to-rail.
BLOCK DIAGRAM
8
7
+IN
V–
6
V+ V–
5
V–
SHDN
V+
–OUT
V–
V+
V–
V+
V+
V+
340k
+
340k
–
VOCM
V–
V–
V–
V+ V–
V+
–IN
1
V–
V+
VOCM
2
3
+OUT
4
6362 BD
6362fa
9
LTC6362
APPLICATIONS INFORMATION
Functional Description
General Amplifier Applications
The LTC6362 is a low power, low noise, high DC accuracy
fully differential operational amplifier/ADC driver. The
amplifier is optimized to convert a fully differential or
single-ended signal to a low impedance, balanced differential output suitable for driving high performance, low
power differential successive approximation register (SAR)
ADCs. The balanced differential nature of the amplifier
also provides even-order harmonic distortion cancellation, and low susceptibility to common mode noise (like
power supply noise).
In Figure 1, the gain to VOUTDIFF from VINP and VINM is
given by:
The outputs of the LTC6362 are capable of swinging railto-rail and can source or sink up to 35mA of current. The
LTC6362 is optimized for high bandwidth and low power
applications. Load capacitances above 10pF to ground or
5pF differentially should be decoupled with 10Ω to 100Ω
of series resistance from each output to prevent oscillation or ringing. Feedback should be taken directly from
the amplifier output. Higher voltage gain configurations
tend to have better capacitive drive capability than lower
gain configurations due to lower closed-loop bandwidth.
Input Pin Protection
The LTC6362 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.
Moreover, all pins have clamping diodes to both power
supplies. If any pin is driven to voltages which exceed
either supply, the current should be limited to under 10mA
to prevent damage to the IC.
SHDN Pin
The LTC6362 has a SHDN pin which when driven to within
0.8V above the negative rail, will shut down amplifier operation such that only 70µA is drawn from the supplies.
Pull-down circuitry should be capable of sinking at least
4µA to guarantee complete shutdown across all conditions. For normal operation, the SHDN pin should be left
floating or tied to the positive rail.
R 
VOUTDIFF = V+OUT − V–OUT ≈  F  • ( VINP – VINM )
 RI 
Note from the previous 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 LTC6362 ideally
suited for pre-amplification, level shifting and conversion
of single-ended signals to differential output signals for
driving differential input ADCs.
Output Common Mode and VOCM Pin
The output common mode voltage is defined as the average of the two outputs:
+ V–OUT 
V
VOUTCM = VOCM =  +OUT


2
As the equation shows, the output common mode voltage
is independent of the input common mode voltage, and
is instead determined by the voltage on the VOCM pin, by
means of an internal common mode feedback loop.
If the VOCM pin is left open, an internal resistor divider
develops a default voltage of 2.5V with a 5V supply. The
VOCM pin can be overdriven to another voltage if desired.
For example, when driving an ADC, if the ADC makes a
reference available for setting the common mode voltage, it can be directly tied to the VOCM pin, as long as
the ADC is capable of driving the 170k input resistance
presented by the VOCM pin. The Electrical Characteristics
table specifies the valid range that can be applied to the
VOCM pin (VOUTCMR).
6362fa
10
LTC6362
APPLICATIONS INFORMATION
Input Common Mode Voltage Range
The LTC6362’s input common mode voltage (VICM) is
defined as the average of the two input pins, V+IN and
V–IN. The inputs of the LTC6362 are capable of swinging
rail-to-rail and as such the valid range that can be used for
VICM is V– to V+. However, 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 1). For fully differential input applications, where
VINP = –VINM, the common mode input is approximately:
V +V
RI
RF
VICM = +IN –IN ≈ VOCM •
+ VCM •
2
RI +RF
RI +RF
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:
VICM =
V+IN + V–IN
2
≈ VOCM •
RI
RF
V
RF
+ VCM •
+ INP •
RI +RF
RI +RF
2 RI +RF
This means that if, for example, the input signal (VINP)
is a sine, an attenuated version of that sine signal also
appears at the op amp inputs.
RI
VINP
VCM
+
–
V+IN
+
–
V–OUT
+
VOCM
VINM
RF
VOCM
–
+
–
RI
V–IN
RF
6362 F01
V+OUT
Figure 1. Definitions and Terminology
Input Bias Current
Input bias current varies according to VICM. For common
mode voltages ranging from 0.2V above the negative
supply to 1.1V below the positive supply, input bias
current follows ∆IB/∆VICM = 75nA/V, with IB at VICM = 2.5V
typically below 75nA on a 5V supply. For common mode
voltages ranging from 1.1V below the positive supply to
0.2V below the positive supply, input bias current follows
∆IB/∆VICM = 25nA/V, with IB at VICM = 4.5V typically below
75nA on a 5V supply. Operating within these ranges allows
the amplifier to be used in applications with high source
resistances where errors due to voltage drops must be
minimized. For applications where VICM is within 0.2V of
either rail, input bias current may reach values over 1µA.
Input Impedance and Loading Effects
The low frequency input impedance looking into the VINP
or VINM input of Figure 1 depends on how the inputs are
driven. For fully differential input sources (VINP = –VINM),
the input impedance seen at either input is simply:
RINP = RINM = RI
For single-ended inputs, because of the signal imbalance
at the input, the input impedance actually increases over
the balanced differential case. The input impedance looking
into either input is:
RINP = RINM =
RI
 1  RF 
1–   • 
 2   RI +RF 
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.
If input impedance matching is required by the source, a
termination resistor R1 should be chosen (see Figure 2)
such that:
R1=
RINM •RS
RINM –RS
According to Figure 2, the input impedance looking into
the differential amp (RINM) reflects the single-ended source
case, given above. Also, R2 is chosen as:
R2 = R1||RS =
R1•RS
R1+RS
6362fa
11
LTC6362
APPLICATIONS INFORMATION
RINM
RS
VS
RI2
RI
RF
VINP
R1
R1 CHOSEN SO THAT R1 || RINM = RS
R2 CHOSEN TO BALANCE R1 || RS
RI
–
+
+
–
VCM
VOCM
–
+
–
V–IN
RF1
6362 F03
Figure 2. Optimal Compensation for Signal Source Impedance
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:
VOUT(DIFF) = V+OUT – V–OUT
R
∆β
∆β
≈ VINDIFF • F + VCM •
– VOCM •
β AVG
β AVG
RI
where 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:
RI2 
1  RI1
β AVG = • 
+
2  RI1 +RF1 RI2 +RF2 
∆β is defined as the difference in the feedback factors:
RI2
RI1
∆β =
–
RI2 +RF2 RI1 +RF1
Here, VCM and VINDIFF are defined as the average and
the difference of the two input voltages VINP and VINM,
respectively:
VINDIFF = VINP – VINM
VINM
V–OUT
+
VVOCM
RI1
V+OUT
Figure 3. Real-World Application with
Feedback Resistor Pair Mismatch
6405 F04
VINP + VINM
2
+
–
RF2
RF
R2 = RS || R1
VCM =
+
–
V+IN
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 ≈ (VCM – VOCM) • ∆β/βAVG
In general, the degree of feedback pair mismatch is a
source of common mode to differential conversion of
both signals and noise. Using 0.1% resistors or better will
mitigate most problems. A low impedance ground plane
should be used as a reference for both the input signal
source and the VOCM pin.
Noise
The LTC6362’s differential input referred voltage and current
noise densities are 3.9nV/√Hz and 0.8pA/√Hz, respectively.
In addition to the noise generated by the amplifier, the
surrounding feedback resistors also contribute noise. A
simplified noise model is shown in Figure 4. The output
noise generated by both the amplifier and the feedback
components is given by the equation:
2
eno =

 RF  
2
eni •  1+   + 2 • (in •RF )
 RI  

2

R 
2
+ 2 • enRI • F  + 2 • enRF
RI 

For example, if RF = RI = 1k, the output noise of the circuit
eno = 12nV/√Hz.
If the circuits surrounding the amplifier are well balanced,
common mode noise (envocm) does not appear in the differential output noise equation given above.
6362fa
12
LTC6362
APPLICATIONS INFORMATION
enRI2
RI
RF
speed of the amplifier as well as the feedback factor. Since
the LTC6362 is designed to be stable in a differential signal
gain of 1 (where RI = RF or β = 1/2), the maximum f–3dB
is obtained and measured in this gain setting, as reported
in the Electrical Characteristics table.
enRF2
in+2
+
in–2
enRI2
–
eni2
RI
eno2
RF
enRF2
6362 F04
Figure 4. Simplified Noise Model
The LTC6362’s input referred voltage noise contributes the
equivalent noise of a 920Ω resistor. When the feedback
network is comprised of resistors whose values are larger
than this, the output noise is resistor noise and amplifier
current noise dominant. For feedback networks consisting
of resistors with values smaller than 920Ω, the output
noise is voltage noise dominant.
Lower resistor values 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
will result in higher output noise, but typically improved
distortion due to less loading on the output. For this reason, when LTC6362 is configured in a differential gain of
1, using feedback resistors of at least 1k is recommended.
GBW vs f–3dB
Gain-bandwidth product (GBW) and –3dB frequency
(f–3dB) have been specified in the Electrical Characteristics
table as two different metrics for the speed of the LTC6362.
GBW is obtained by measuring the open-loop gain of the
amplifier at a specific frequency (fTEST), then calculating
gain • fTEST. GBW is a parameter that depends only on the
internal design and compensation of the amplifier and is
a suitable metric to specify the inherent speed capability
of the amplifier.
f–3dB, on the other hand, is a parameter of more practical
interest in different applications and is by definition the
frequency at which the closed-loop gain is 3dB lower than
its low frequency value. The value of f–3dB depends on the
In most amplifiers, the open-loop gain response exhibits a
conventional single-pole roll-off for most of the frequencies
before the unity-gain crossover frequency, and the GBW and
unity-gain frequency are close to each other. However, the
LTC6362 is intentionally compensated in such a way that
its GBW is significantly larger than its f–3dB. This means
that at lower frequencies where the amplifier inputs generally operate, the amplifier’s gain and thus the feedback
loop gain is larger. This has the important advantage of
further linearizing the amplifier and improving distortion
at those frequencies.
Feedback Capacitors
In cases where the LTC6362 is connected such that the
combination of parasitic capacitances (device + PCB) at the
inverting input forms a pole whose frequency lies within
the closed-loop bandwidth of the amplifier, a capacitor
(CF) can be added in parallel with the feedback resistor
(RF) to cancel the degradation on stability. CF should be
chosen such that it generates a zero at a frequency close
to the frequency of the pole.
In general, a larger value for CF reduces the peaking (overshoot) of the amplifier in both frequency and time domains,
but also decreases the closed-loop bandwidth (f–3dB).
Board Layout and Bypass Capacitors
For single supply applications, it is recommended that
high quality 0.1µF ceramic bypass capacitors be placed
directly between the V+ and the V– pin with short connections. The V– pins (including the exposed pad in the
DD8 package) 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 be used to bypass V+ to ground
and V– to ground, again with minimal routing. Small
geometry (e.g., 0603) surface mount ceramic capacitors
have a much higher self-resonant frequency than leaded
capacitors, and perform best with LTC6362.
6362fa
13
LTC6362
APPLICATIONS INFORMATION
To prevent degradation in stability response, it is highly
recommended that any stray capacitance at the input pins,
+IN and –IN, be kept to an absolute minimum by keeping
printed circuit connections as short as possible.
At the output, always keep in mind the differential nature of
the LTC6362, because it is critical that the load impedances
seen by both outputs (stray or intended), be as balanced
and symmetric as possible. This will help preserve the
balanced operation of the LTC6362 that minimizes the
generation of even-order harmonics and maximizes the
rejection of common mode signals and noise.
The VOCM pin should be bypassed to the ground plane with
a high quality 0.1µF ceramic capacitor. This will prevent
common mode signals and noise on this pin from being
inadvertently converted to differential signals and noise
by impedance mismatches both externally and internally
to the IC.
Interfacing to ADCs
When driving an ADC, an additional passive filter should be
used between the outputs of the LTC6362 and the inputs
of the ADC. Depending on the application, a single-pole
RC filter will often be sufficient. The sampling process
of ADCs creates a charge transient that is caused by the
switching in of the ADC sampling capacitor. This momentarily “shorts” the output of the amplifier as charge
is transferred between amplifier and sampling capacitor.
The amplifier must recover and settle from this load
transient before the acquisition period has ended, for a
valid representation of the input signal. The RC network
between the outputs of the driver and the inputs of the
ADC decouples the sampling transient of the ADC (see
Figure 5). The capacitance serves to provide the bulk
of the charge during the sampling process, while the
two resistors at the outputs of the LTC6362 are used to
dampen and attenuate any charge injected by the ADC.
The RC filter gives the additional benefit of band limiting
broadband output noise.
The selection of an appropriate filter depends on the specific
ADC, however the following procedure is suggested for
choosing filter component values. Begin by selecting an
appropriate RC time constant for the input signal. Generally, longer time constants improve SNR at the expense of
settling time. Output transient settling to 18-bit accuracy
will typically require over twelve RC time constants. To
select the resistor value, remember the resistors in the
decoupling network should be at least 10Ω. Keep in mind
that these resistors also serve to decouple the LTC6362
outputs from load capacitance. Too large of a resistor will
leave insufficient settling time. Too small of a resistor will
not properly dampen the load transient of the sampling
process, prolonging the time required for settling. For
lowest distortion, choose capacitors with low dielectric
absorption (such as a C0G multilayer ceramic capacitor). In
general, large capacitor values attenuate the fixed nonlinear
charge kickback, however very large capacitor values will
detrimentally load the driver at the desired input frequency
and thus cause driver distortion. Smaller input swings will
in general allow for larger filter capacitor values due to
decreased loading demands on the driver. This property
however may be limited by the particular input amplitude
dependence of differential nonlinear charge kickback for
the specific ADC used.
In some applications, placing series resistors at the inputs
of the ADC may further improve distortion performance.
These series resistors function with the ADC sampling
capacitor to filter potential ground bounce or other high
speed sampling disturbances. Additionally the resistors
limit the rise time of residual filter glitches that manage to
propagate to the driver outputs. Restricting possible glitch
propagation rise time to within the small signal bandwidth
of the driver enables less disturbed output settling.
For the specific application of LTC6362 driving the
LTC2379‑18 SAR ADC in a gain of AV = –1 configuration,
the recommended component values of the RC filter for
varying filter bandwidths are provided in Figure 5. These
component values are chosen for optimal distortion performance. Broadband output noise will vary with filter
bandwidth.
6362fa
14
LTC6362
APPLICATIONS INFORMATION
1k
5V
1k
8
+IN
RFILT
7
6
SHDN
V–
CCM
5
–OUT
LTC6362
V+
V+
RS
+
340k
VOCM
AIN+
CDIFF
340k
–
V–
2.5V
VREF
VDD
LTC2379-18
SAR ADC
GND
V–
–IN
1
1k
AIN–
RS
5V
VOCM
V+
2
3
FILTER BW RFILT CCM CDIFF RS
(Ω) (pF) (pF) (Ω)
(Hz)
+OUT
4
RFILT
1k
0.1µF
VIN
CCM
0.1µF
6362 F05
5V
125 3900 3900
35.7 3900 3900
100 470 470
175 100 100
75
68
68
100 18
18
110k
380k
1.1M
3.0M
10M
29M
0
0
0
0
0
0
Figure 5. Recommended Interface Solutions for Driving the LTC2379-18 SAR ADC
TYPICAL APPLICATIONS
Single-Ended-to-Differential Conversion of a 20VP-P Ground-Referenced Input with Gain of AV = –0.4 to Drive an ADC
4.5V
V+OUT
10V
806Ω
VIN
–10V
2k
VIN
0.5V
3.9nF
5V
VOCM
0.1µF
SHDN
2k
35.7Ω
– +
LTC6362
35.7Ω
+ –
0Ω
3.9nF
3.9nF
806Ω
0Ω
AIN+
AIN–
5V
2.5V
VREF
VDD
LTC2379-18
SAR ADC
GND
6362 TA02
4.5V
V–OUT
0.5V
6362fa
15
LTC6362
TYPICAL APPLICATIONS
Single-Ended-to-Differential Conversion of a 5VP-P, 2.5V Referenced Input with Gain of AV = –1.6 to Drive an ADC
4.5V
V+OUT
1k
0.5V
3.9nF
5V
619Ω
5V
VOCM
VIN
0.1µF
0V
SHDN
35.7Ω
– +
LTC6362
+
–
3.9nF
35.7Ω
+ –
619Ω
0Ω
AIN+
0Ω
AIN–
3.9nF
1k
5V
2.5V
VREF
VDD
LTC2379-18
SAR ADC
GND
6362 TA03
4.5V
VCM
2.5V
V–OUT
0.5V
Differentially Driving an ADC with ∆VIN = 8VP-P and Gain of AV = 1
4.5V
V+OUT
1k
0.5V
3.9nF
5V
1k
4.5V
VOCM
VINM
0.1µF
0.5V
SHDN
35.7Ω
– +
LTC6362
3.9nF
35.7Ω
+ –
1k
4.5V
0Ω
AIN+
0Ω
AIN–
3.9nF
1k
5V
2.5V
VREF
VDD
LTC2379-18
SAR ADC
GND
6362 TA04
4.5V
VINP
V–OUT
0.5V
0.5V
Single-Ended-to-Differential Conversion of a 4VP-P Input with Gain of AV = 2 to Drive an ADC for Applications Where
the Importance of High Input Impedance Justifies Some Degradation in Distortion, Noise, and DC Accuracy. Input Is
True High Impedance, However Common Mode Noise and Offset Are Present on the Output. Additionally, When the
Input Signal Exceeds 2.8VP-P, a Step in Input Offset Will Occur That Will Degrade Distortion Performance
4.5V
V+OUT
0.5V
3.9nF
5V
VOCM
0.1µF
SHDN
– +
LTC6362
+ –
35.7Ω
35.7Ω
0Ω
3.9nF
3.9nF
4.5V
0Ω
AIN+
AIN–
5V
2.5V
VREF
VDD
LTC2379-18
SAR ADC
GND
6362 TA05
VIN
4.5V
0.5V
V–OUT
0.5V
6362fa
16
LTC6362
TYPICAL APPLICATIONS
Differentially Driving a Pipeline ADC with AV = 1
100Ω
VCM = 0.9V
0.1µF
V+OUT
1k
1k
VOCM
INPUT BW = 1.2MHz
FULL SCALE = 2VP-P
0.1µF
SHDN
1.8V
1.5nF
3.3V
5Ω
30Ω
– +
LTC6362
30Ω
+ –
1k
1.5nF
1k
VIN
1.5nF
5Ω
AIN+
AIN–
VDD
VCM
16 BIT
LTC2160
PIPELINE ADC
25Msps
GND
6362 TA08
V–OUT
MEASURED PERFORMANCE FOR LTC6362 DRIVING LTC2160:
INPUT: fIN = 2kHz, –1dBFS
SNR: 77.0dB
HD2: –98.9dBc
HD3: –102.3dBc
THD: –96.3dB
Differential Line Driver Connected in Gain of AV = –1
3V
V+OUT
1V
1k
VIN
5V
–1V
1k
VIN
2V
VOCM
0.1µF
SHDN
1k
49.9Ω
– +
LTC6362
+ –
100Ω
49.9Ω
6362 TA06
1k
3V
V–OUT
2V
6362fa
17
LTC6362
TYPICAL APPLICATIONS
LTC6362 Used as Lowpass Filter/Driver with 10VP-P Singled-Ended Input, Driving a SAR ADC
1.8nF
2k
1.8nF
4-POLE FILTER
f–3dB = 50kHz
0.1µF
VCM
5V
V
–5V IN
1.27k
1.27k
1.27k
– +
1.8nF
0.1µF
1.8nF
VCM
1.27k
4.5V
5V
1.27k
LTC6362
1.8nF
AIN+
1.8nF
1.8nF
100Ω
+ –
1.27k
0.5V
100Ω
1.8nF
AIN–
5V
2.5V
VREF
VDD
4.5V
2k
16 BIT
LTC2380-16
SAR ADC
2Msps
GND
6362 TA09
0.5V
1.8nF
Differential AV = 1 Configuration Using an LT®5400 Quad-Matched Resistor Network
4.5V
0.5V VINM
4.5V VINP
1
LT5400 R1
R2
2
R3
3
R4
4
5V
8
6
– +
VOCM
7
0.1µF
4.5V
V+OUT
LTC6362
SHDN
+ –
5
V–OUT
0.5V
4.5V
0.5V
0.5V
6362 TA10a
CMRR Comparison Using the LT5400 and 1% 0402 Resistors
100
90
80
CMRR (dB)
70
60
50
40
30
20
VS = 5V, 0V
USING LT5400 MATCHED RESISTORS
USING 1% 0402 RESISTORS
10
0
10
100
1k
10k
FREQUENCY (Hz)
100k
6362 TA10b
6362fa
18
LTC6362
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
MS8 Package
8-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1660 Rev F)
0.889 ±0.127
(.035 ±.005)
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
3.00 ±0.102
(.118 ±.004)
(NOTE 3)
0.65
(.0256)
BSC
0.42 ± 0.038
(.0165 ±.0015)
TYP
8
7 6 5
0.52
(.0205)
REF
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
3.00 ±0.102
(.118 ±.004)
(NOTE 4)
4.90 ±0.152
(.193 ±.006)
DETAIL “A”
0° – 6° TYP
GAUGE PLANE
0.53 ±0.152
(.021 ±.006)
DETAIL “A”
1
2 3
4
1.10
(.043)
MAX
0.86
(.034)
REF
0.18
(.007)
SEATING
PLANE
0.22 – 0.38
(.009 – .015)
TYP
0.65
(.0256)
BSC
0.1016 ±0.0508
(.004 ±.002)
MSOP (MS8) 0307 REV F
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
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
6362fa
19
LTC6362
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
DD Package
8-Lead Plastic DFN (3mm × 3mm)
(Reference LTC DWG # 05-08-1698 Rev C)
0.70 ±0.05
3.5 ±0.05
1.65 ±0.05
2.10 ±0.05 (2 SIDES)
PACKAGE
OUTLINE
0.25 ±0.05
0.50
BSC
2.38 ±0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
PIN 1
TOP MARK
(NOTE 6)
0.200 REF
3.00 ±0.10
(4 SIDES)
R = 0.125
TYP
5
0.40 ±0.10
8
1.65 ±0.10
(2 SIDES)
0.75 ±0.05
4
0.25 ±0.05
1
(DD8) DFN 0509 REV C
0.50 BSC
2.38 ±0.10
0.00 – 0.05
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING TO BE MADE A JEDEC PACKAGE OUTLINE M0-229 VARIATION OF (WEED-1)
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 TOP AND BOTTOM OF PACKAGE
6362fa
20
LTC6362
REVISION HISTORY
REV
DATE
DESCRIPTION
PAGE NUMBER
A
05/12
Added DFN package
1, 2, 9, 13, 20
Added typical spec for 2VP-P tS
4
6362fa
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.
21
LTC6362
TYPICAL APPLICATION
Single-Ended-to-Differential Conversion of a 10VP-P Ground-Referenced Input with Gain of AV = –0.8
to Drive a 5V Reference SAR ADC
4.5V
V+OUT
5V
1k
VIN
–5V
1.24k
VIN
0.5V
3.9nF
5V
VOCM
0.1µF
SHDN
LTC6362
35.7Ω
+ –
1.24k
0Ω
35.7Ω
– +
3.9nF
0Ω
3.9nF
1k
AIN+
AIN–
5V
2.5V
VREF
VDD
18 BIT
LTC2379-18
SAR ADC
1.6Msps
GND
6362 TA07
4.5V
V–OUT
0.5V
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT6350
Low Noise, Single-Ended to Differential Converter/
ADC Driver
4.8mA, –97dBc Distortion at 100kHz, 4VP–P Output
LTC6246/LTC6247/
LTC6248
Single/Dual/Quad 180MHz Rail-to-Rail Low Power
Op Amps
1mA/Amplifier, 4.2nV/√Hz
LTC6360
1GHz Very Low Noise Single-Ended SAR ADC Driver 13.6mA, HD2/HD3 = –103dBc/–109dBc at 40kHz, 4VP-P Output
with True Zero Output
LTC1992/LTC1992-X
3MHz to 4MHz Fully Differential Input/Output
Amplifiers
Internal Feedback Resistors Available (G =1, 2, 5,10)
LT1994
70MHz Low Noise, Low Distortion Fully Differential
Input/Output Amplifier/Driver
13mA, –94dBc Distortion at 1MHz, 2VP-P Output
Operational Amplifiers
ADCs
LTC2379-18/LTC2378-18 18-Bit, 1.6Msps/1Msps/500ksps/250ksps Serial,
LTC2377-18/LTC2376-18 Low Power ADC
2.5V Supply, Differential Input, 101.2dB SNR, ±5V Input Range, DGC,
Pin Compatible Family in MSOP-16 and 4mm × 3mm DFN-16 Packages
LTC2380-16/LTC2378-16 16-Bit, 2Msps/1Msps/500ksps/250ksps Serial,
LTC2377-16/LTC2376-16 Low Power ADC
2.5V Supply, Differential Input, 96.2dB SNR, ±5V Input Range, DGC,
Pin Compatible Family in MSOP-16 and 4mm × 3mm DFN-16 Packages
LTC2383-16/LTC2382-16/ 16-Bit, 1Msps/500ksps/250ksps Serial, Low
LTC2381-16
Power ADC
2.5V Supply, Differential Input, 92dB SNR, ±2.5V Input Range, Pin
Compatible Family in MSOP-16 and 4mm × 3mm DFN-16 Packages
LTC2393-16/LTC2392-16/ 16-Bit, 1Msps/500ksps/250ksps Parallel/Serial ADC 5V Supply, Differential Input, 94dB SNR, ±4.096V Input Range, Pin
LTC2391-16
Compatible Family in 7mm × 7mm LQFP-48 and QFN-48 Packages
LTC2355-14/LTC2356-14 14-Bit, 3.5Msps Serial ADC
3.3V Supply, 1-Channel, Unipolar/Bipolar, 18mW, MSOP-10 Package
LTC2366
12-Bit, 3Msps Serial ADC
2.35V to 3.6V Supply 6- and 8-Lead TSOT-23 Packages
LTC2162/LTC2161/
LTC2160
16-Bit, 65/40/25Msps Low Power ADC
1.8V Supply, Differential Input, 77dB SNR, 2VP-P Input Range, Pipeline
Converter in 7mm × 7mm QFN-48 Package
6362fa
22 Linear Technology Corporation
LT 0612 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 2012
Similar pages