LINER LTC6655BHMS8-4.096 0.25ppm noise, low drift precision buffered reference family Datasheet

LTC6655
0.25ppm Noise, Low Drift
Precision Buffered
Reference Family
Features
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Description
Low Noise: 0.25ppmP-P (0.1Hz to 10Hz)
625nVP-P for the LTC6655-2.5
Low Drift: 2ppm/°C Max
High Accuracy: ±0.025% Max
Fully Specified from –40°C to 125°C
100% Tested at –40°C, 25°C and 125°C
Load Regulation: <10ppm/mA
Sinks and Sources Current: ±5mA
Low Dropout: 500mV
Maximum Supply Voltage: 13.2V
Low Power Shutdown: <20µA Max
Available Output Voltages: 1.25V, 2.048V, 2.5V, 3V,
3.3V, 4.096V, 5V
Available in an 8-Lead MSOP Package
Applications
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Instrumentation and Test Equipment
High Resolution Data Acquisition Systems
Weigh Scales
Precision Battery Monitors
High Temperature Applications
Precision Regulators
Medical Equipment
High Output Current Precision Reference
The LTC®6655 is a complete family of precision bandgap
voltage references, offering exceptional noise and drift
performance. This low noise and drift is ideally suited for
the high resolution measurements required by instrumentation and test equipment. In addition, the LTC6655 is fully
specified over the temperature range of –40°C to 125°C,
ensuring its suitability for demanding automotive and
industrial applications. Advanced curvature compensation
allows this bandgap reference to achieve a drift of less than
2ppm/°C with a predictable temperature characteristic
and an output voltage accurate to ±0.025%, reducing or
eliminating the need for calibration.
The LTC6655 can be powered from as little as 500mV
above the output voltage to as much as 13.2V. Superior
load regulation with source and sink capability, coupled
with exceptional line rejection, ensures consistent performance over a wide range of operating conditions. A
shutdown mode is provided for low power applications.
Available in a small MSOP package, the LTC6655 family
of references is an excellent choice for demanding precision applications.
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
Low Frequency 0.1Hz to 10Hz Noise (LTC6655-2.5)
Basic Connection
LTC6655-2.5
3V < VIN ≤ 13.2V
CIN
0.1µF
VIN
VOUT_F
SHDN
VOUT_S
GND
VOUT
COUT
10µF
500nV/DIV
6655 TA01a
1s/DIV
6655 TA01b
6655fa
LTC6655
Absolute Maximum Ratings
(Note 1)
Pin Configuration
Input Voltage
VIN to GND........................................... –0.3V to 13.2V
SHDN to GND............................ –0.3V to (VIN + 0.3V)
Output Voltage:
VOUT_F....................................... –0.3V to (VIN + 0.3V)
VOUT_S...................................................... –0.3V to 6V
Output Short-Circuit Duration....................... Indefinite
Operating Temperature Range (Note 2).. –40°C to 125°C
Storage Temperature Range (Note 2)...... –65°C to 150°C
Lead Temperature Range (Soldering, 10 sec)
(Note 3).................................................................. 300°C
TOP VIEW
SHDN
VIN
GND*
GND
1
2
3
4
8
7
6
5
GND*
VOUT_F
VOUT_S
GND*
MS8 PACKAGE
8-LEAD PLASTIC MSOP
TJMAX = 150°C, θJA = 300°C/W
*CONNECT PINS TO DEVICE GND (PIN 4)
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING
PACKAGE DESCRIPTION
SPECIFIED TEMPERATURE RANGE
LTC6655BHMS8-1.25#PBF
LTC6655BHMS8-1.25#TRPBF
LTFDG
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-1.25#PBF
LTC6655CHMS8-1.25#TRPBF
LTFDG
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655BHMS8-2.048#PBF
LTC6655BHMS8-2.048#TRPBF
LTFDH
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-2.048#PBF
LTC6655CHMS8-2.048#TRPBF
LTFDH
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655BHMS8-2.5#PBF
LTC6655BHMS8-2.5#TRPBF
LTFCY
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-2.5#PBF
LTC6655CHMS8-2.5#TRPBF
LTFCY
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655BHMS8-3#PBF
LTC6655BHMS8-3#TRPBF
LTFDJ
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-3#PBF
LTC6655CHMS8-3#TRPBF
LTFDJ
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655BHMS8-3.3#PBF
LTC6655BHMS8-3.3#TRPBF
LTFDK
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-3.3#PBF
LTC6655CHMS8-3.3#TRPBF
LTFDK
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655BHMS8-4.096#PBF
LTC6655BHMS8-4.096#TRPBF
LTFDM
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-4.096#PBF
LTC6655CHMS8-4.096#TRPBF
LTFDM
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655BHMS8-5#PBF
LTC6655BHMS8-5#TRPBF
LTFDN
8-Lead Plastic MSOP
–40°C to 125°C
LTC6655CHMS8-5#PBF
LTC6655CHMS8-5#TRPBF
LTFDN
8-Lead Plastic MSOP
–40°C to 125°C
Consult LTC Marketing for parts specified with wider operating temperature ranges.
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/
6655fa
LTC6655
AVAILABLE OPTIONS
OUTPUT VOLTAGE
INITIAL ACCURACY
TEMPERATURE COEFFICIENT
PART NUMBER†
1.250
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-1.25
LTC6655CHMS8-1.25
2.048
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-2.048
LTC6655CHMS8-2.048
2.500
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-2.5
LTC6655CHMS8-2.5
3.000
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-3.0
LTC6655CHMS8-3.0
3.300
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-3.3
LTC6655CHMS8-3.3
4.096
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-4.096
LTC6655CHMS8-4.096
5.000
0.025%
0.05%
2ppm/°C
5ppm/°C
LTC6655BHMS8-5
LTC6655CHMS8-5
†See Order Information section for complete part number listing.
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = VOUT + 0.5V, VOUT_S connected to VOUT_F, unless otherwise noted.
PARAMETER
CONDITIONS
Output Voltage
LTC6655B
LTC6655C
Output Voltage Temperature Coefficient
(Note 4)
LTC6655B
LTC6655C
Line Regulation
VOUT + 0.5V ≤ VIN ≤ 13.2V, SHDN = VIN
MIN
TYP
–0.025
–0.05
l
l
ISOURCE = 5mA
5
25
40
ppm/V
ppm/V
15
ppm/mA
ppm/mA
30
ppm/mA
ppm/mA
3
10
LTC6655-1.25, LTC6655-2.048, LTC6655-2.5
ISOURCE = 5mA, VOUT Error ≤ 0.1%
l
LTC6655-3, LTC6655-3.3, LTC6655-4.096, LTC6655-5
ISOURCE = ±5mA, VOUT Error ≤ 0.1%
IOUT = 0mA, VOUT Error ≤ 0.1%
l VOUT + 0.5
l VOUT + 0.2
Output Short-Circuit Current
Short VOUT to GND
Short VOUT to VIN
Shutdown Pin (SHDN)
Logic High Input Voltage
Logic High Input Current, SHDN = 2V
l
l
Logic Low Input Voltage
Logic Low Input Current, SHDN = 0.8V
l
l
Supply Current
Shutdown Current
3
13.2
V
13.2
13.2
V
V
20
20
2.0
mA
mA
12
V
µA
0.8
15
V
µA
l
7
7.5
mA
mA
l
20
µA
5
No Load
SHDN Tied to GND
%
%
ppm/°C
ppm/°C
l
Operating Voltage (Note 6)
0.025
0.05
2
5
l
ISINK = 5mA
UNITS
1
2.5
l
Load Regulation (Note 5)
MAX
6655fa
LTC6655
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = VOUT + 0.5V, VOUT_S connected to VOUT_F, unless otherwise noted.
PARAMETER
CONDITIONS
Output Voltage Noise (Note 7)
0.1Hz ≤ f ≤ 10Hz
10Hz ≤ f ≤ 1kHz
0.25
0.67
ppmP-P
ppmRMS
Turn-On Time
0.1% Settling, COUT = 2.7µF
400
µs
60
ppm/√kHr
30
35
60
ppm
ppm
ppm
Long-Term Drift of Output Voltage (Note 8)
Hysteresis (Note 9)
∆T = –0°C to 70°C
∆T = –40°C to 85°C
∆T = –40°C to 125°C
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: Precision may be affected if the parts are stored outside of the
specified temperature range. Large temperature changes may cause
changes in device performance due to thermal hysteresis. For best
performance, extreme temperatures should be avoided whenever possible.
Note 3: The stated temperature is typical for soldering of the leads during
manual rework. For detailed IR reflow recommendations, refer to the
Applications Information section.
Note 4: Temperature coefficient is measured by dividing the maximum
change in output voltage by the specified temperature range.
Note 5: Load regulation is measured on a pulse basis from no load to
the specified load current. Load current does not include the 2mA sense
current. Output changes due to die temperature change must be taken into
account separately.
Note 6: Excludes load regulation errors. Minimum supply for the
LTC6655‑1.25, LTC6655-2.048 and LTC6655-2.5 is set by internal circuitry
supply requirements, regardless of load condition. Minimum supply for
the LTC6655-3, LTC6655-3.3, LTC6655-4.096 and LTC6655-5 is specified
by load current.
Note 7: Peak-to-peak noise is measured with a 2-pole highpass filter at
0.1Hz and 3-pole lowpass filter at 10Hz. The unit is enclosed in a still-air
environment to eliminate thermocouple effects on the leads, and the
test time is 10 seconds. Due to the statistical nature of noise, repeating
MIN
TYP
MAX
UNITS
noise measurements will yield larger and smaller peak values in a given
measurement interval. By repeating the measurement for 1000 intervals,
each 10 seconds long, it is shown that there are time intervals during
which the noise is higher than in a typical single interval, as predicted by
statistical theory. In general, typical values are considered to be those for
which at least 50% of the units may be expected to perform similarly or
better. For the 1000 interval test, a typical unit will exhibit noise that is
less than the typical value listed in the Electrical Characteristics table in
more than 50% of its measurement intervals. See Application Note 124 for
noise testing details. RMS noise is measured with a spectrum analyzer in a
shielded environment.
Note 8: Long-term stability typically has a logarithmic characteristic and
therefore, changes after 1000 hours tend to be much smaller than before
that time. Total drift in the second thousand hours is normally less than
one-third that of the first thousand hours with a continuing trend toward
reduced drift with time. Long-term stability is also affected by differential
stresses between the IC and the board material created during board
assembly.
Note 9: Hysteresis in output voltage is created by mechanical stress
that differs depending on whether the IC was previously at a higher or
lower temperature. Output voltage is always measured at 25°C, but
the IC is cycled to the hot or cold temperature limit before successive
measurements. Hysteresis is roughly proportional to the square of the
temperature change. For instruments that are stored at well controlled
temperatures (within 20 or 30 degrees of operational temperature),
hysteresis is usually not a significant error source.
6655fa
LTC6655
Typical Performance Characteristics
Characteristic curves are similar for most voltage options of the LTC6655. Curves from the LTC6655-1.25, LTC6655-2.5 and the
LTC6655-5 represent the range of performance across the entire family of references. Characteristic curves for other output voltages
fall between these curves and can be estimated based on their voltage output.
1.25V Low Frequency
0.1Hz to 10Hz Noise
1.25V Output Voltage
Temperature Drift
200nV/
DIV
1s/DIV
6655 G01
1.25V Load Regulation (Sourcing)
20
3 TYPICAL UNITS
OUTPUT VOLTAGE CHANGE (ppm)
OUTPUT VOLTAGE (V)
1.2504
1.2502
1.2500
1.2498
1.2496
–50
–25
50
25
0
75
TEMPERATURE (°C)
100
125°C
25°C
–40°C
10
0
–10
–20
–30
–40
0.001
125
0.01
0.1
1
OUTPUT CURRENT (mA)
6655 G03
6655 G02
1.25V Output Voltage Noise
Spectrum
1.25V Load Regulation (Sinking)
160
35
120
80
40
IOUT
30
0.01
0.1
1
OUTPUT CURRENT (mA)
20
10
2.7µF
10µF
100µF
0.1
COUT = 3.3µF
1
10
FREQUENCY (kHz)
6655 G04
6655 G07
10
8
6
4
40
30
20
10
2
0
TA = 25°C
50
NUMBER OF PARTS
SUPPLY CURRENT (µA)
VOUT
10mV/DIV
1.25V VOUT Distribution
60
125°C
25°C
–40°C
12
0mA
IOUT
–5mA
6655 G06
1000
1.25V Shutdown Supply Current
vs Input Voltage
14
200µs/DIV
100
200µs/DIV
6655 G05
1.25V Sourcing Current with a
3.3µF Output Capacitor
COUT = 3.3µF
0mA
VOUT
10mV/DIV
15
0
0.01
10
5mA
25
5
0
0.001
1.25V Sinking Current with a
3.3µF Output Capacitor
40
125°C
25°C
–40°C
NOISE VOLTAGE (nV/√Hz)
OUTPUT VOLTAGE CHANGE (ppm)
200
10
0
2
8
6
10
4
INPUT VOLTAGE (V)
12
14
6655 G08
0
1.2495
1.2498
1.2500
VOUT (V)
1.2503
1.2505
6655 G09
6655fa
LTC6655
Typical Performance Characteristics
Characteristic curves are similar for most voltage options of the LTC6655. Curves from the LTC6655-1.25, LTC6655-2.5 and the
LTC6655-5 represent the range of performance across the entire family of references. Characteristic curves for other output voltages
fall between these curves and can be estimated based on their voltage output.
2.5V Low Frequency
0.1Hz to 10Hz Noise
2.5V Output Voltage
Temperature Drift
500nV/
DIV
6655 G10
1s/DIV
2.5V Load Regulation (Sourcing)
10
3 TYPICAL UNITS
OUTPUT VOLTAGE CHANGE (ppm)
OUTPUT VOLTAGE (V)
2.5010
2.5005
2.5000
2.4995
2.4990
–50
0
50
100
TEMPERATURE (°C)
0
–10
–20
–30
–40
125°C
25°C
–40°C
–50
0.001
150
0.01
0.1
1
OUTPUT CURRENT (mA)
10
6655 G12
6655 G11
2.5V Supply Current
vs Input Voltage
2.5V Load Regulation (Sinking)
140
120
100
80
60
40
20
8
14
7
12
6
SUPPLY CURRENT (µA)
125°C
25°C
–40°C
SUPPLY CURRENT (mA)
OUTPUT VOLTAGE CHANGE (ppm)
160
5
4
3
2
125°C
25°C
–40°C
1
0
–20
0.001
0.01
0.1
1
OUTPUT CURRENT (mA)
0
10
2.5V Shutdown Supply Current
vs Input Voltage
0
6655 G13
2.5V Minimum VIN – VOUT
Differential (Sourcing)
2
4
6
8
10
INPUT VOLTAGE (V)
12
10
8
6
4
0
14
0
2
4
6
8
10
INPUT VOLTAGE (V)
6655 G14
2.5V Minimum VIN – VOUT
Differential (Sinking)
10
125°C
25°C
–40°C
2
120
COUT = 2.7µF
0.01
0.01
125°C
25°C
–40°C
0.1
INPUT – OUTPUT VOLTAGE (V)
1
6655 G16
NOISE VOLTAGE (nV√Hz)
OUTPUT CURRENT (mA)
OUTPUT CURRENT (mA)
100
0.1
1
0.1
0.01
–0.15
14
6655 G15
2.5V Output Voltage Noise
Spectrum
10
1
12
125°C
25°C
–40°C
–0.05
0.05
INPUT – OUTPUT VOLTAGE (V)
80
60
COUT = 10µF
COUT = 100µF
40
20
0.15
6655 G17
0
0.01
0.1
1
10
FREQUENCY (kHz)
100
1000
6655 F01
6655fa
LTC6655
Typical Performance Characteristics
Characteristic curves are similar for most voltage options of the LTC6655. Curves from the LTC6655-1.25, LTC6655-2.5 and the
LTC6655-5 represent the range of performance across the entire family of references. Characteristic curves for other output voltages
fall between these curves and can be estimated based on their voltage output.
2.5V Temperature Drift
Distribution
2.5V VOUT Distribution
90
14
TA = 25°C
12
80
70
NUMBER OF PARTS
NUMBER OF PARTS
2.5
–40°C TO 125°C
60
50
40
30
20
2.0
10
VTH_UP
VTRIP (V)
100
8
6
0
2.4992
2.4996
2.5000
VOUT (V)
2.5004
0
2.5008
0
0.4
0.8
1.2
1.6
2
2.5V Output Impedance
vs Frequency
2
4
80
60
40
COUT = 2.7µF
COUT = 10µF
COUT = 100µF
10
100
6655 G22
6
8
VIN (V)
10
12
14
6655 G21
2.5V Line Regulation
2.502
COUT = 2.7µF
COUT = 10µF
COUT = 100µF
OUTPUT VOLTAGE (V)
100
OUTPUT IMPEDENCE (Ω)
POWER SUPPLY REJECTION RATIO (dB)
10
0.1
1
FREQUENCY (kHz)
0.0
2.8
6655 G20
120
0.01
2.4
DRIFT (ppm/C)
2.5V Power Supply Rejection
Ratio vs Frequency
0
0.001
VTH_DN
1.0
0.5
6655 G19
20
1.5
4
2
10
2.5V SHDN Input Voltage
Thresholds vs VIN
1
0.1
0.01
0.001
0.01
0.1
1
10
FREQUENCY (kHz)
100
1000
6655 G23
2.501
2.500
2.499
2.498
125°C
25°C
–40°C
0
2
10
4
6
8
INPUT VOLTAGE (V)
12
14
6655 G24
6655fa
LTC6655
Typical Performance Characteristics
Characteristic curves are similar for most voltage options of the LTC6655. Curves from the LTC6655-1.25, LTC6655-2.5 and the
LTC6655-5 represent the range of performance across the entire family of references. Characteristic curves for other output voltages
fall between these curves and can be estimated based on their voltage output.
5V Low Frequency
0.1Hz to 10Hz Noise
5V Output Voltage
Temperature Drift
5.0010
5V Load Regulation (Sourcing)
10
OUTPUT VOLTAGE CHANGE (ppm)
3 TYPICAL UNITS
OUTPUT VOLTAGE (V)
5.0005
500nV/
DIV
5.0000
4.9995
4.9990
6655 G25
1s/DIV
4.9985
–50
–25
0
25
50
75
TEMPERATURE (°C)
100
0
–10
–20
–30
–40
–50
0.01
125
125°C
25°C
–40°C
0.1
1
OUTPUT CURRENT (mA)
6655 G26
200
180
5
60
40
20
NOISE VOLTAGE (nV/√Hz)
80
4
3
2
125°C
25°C
–40°C
1
0
–20
0.01
0.1
1
OUTPUT CURRENT (mA)
0
10
0
2
8
6
10
4
INPUT VOLTAGE (V)
6655 G28
14
140
120
100
80
60
40
20
0
0.01
2.7µF
10µF
100µF
0.1
1
10
FREQUENCY (kHz)
100
1000
6655 G30
5V Minimum VIN-VOUT
Differential (Sinking)
10
5V Start-Up Response with a
3.3µF Output Capacitor
10
OUTPUT CURRENT (mA)
OUTPUT CURRENT (mA)
12
160
6655 G29
5V Minimum VIN-VOUT
Differential (Sourcing)
1
0.1
0.01
0.01
5V Output Voltage Noise
Spectrum
6
125°C
25°C
–40°C
SUPPLY CURRENT (mA)
OUTPUT VOLTAGE CHANGE (ppm)
100
6655 G27
5V Supply Current
vs Input Voltage
5V Load Regulation (Sinking)
10
125°C
25°C
–40°C
0.1
INPUT-OUTPUT VOLTAGE (V)
1
6655 G31
VIN
2V/DIV
1
VOUT
2V/DIV
0.1
0.01
–0.3
125°C
25°C
–40°C
–0.2
–0.1
0
INPUT-OUTPUT VOLTAGE (V)
COUT = 3.3µF
400µs/DIV
6655 G33
0.1
6655 G32
6655fa
LTC6655
Pin Functions
SHDN (Pin 1): Shutdown Input. This active low input
powers down the device to <20µA. If left open, an internal pull-up resistor puts the part in normal operation. It
is recommended to tie this pin high externally for best
performance during normal operation.
VOUT_S (Pin 6): VOUT Sense Pin. Connect this pin at the
load and route with a wide metal trace to minimize load
regulation errors. This pin sinks 2mA. Output error is
RTRACE • 2mA, regardless of load current. For load currents
<100µA, tie directly to VOUT_F pin.
VIN (Pin 2): Power Supply. Bypass VIN with a 0.1µF, or
larger, capacitor to GND.
VOUT_F (Pin 7): VOUT Force Pin. This pin sources and
sinks current to the load. An output capacitor of 2.7µF to
100µF is required.
GND (Pin 4): Device Ground. This pin is the main ground
and must be connected to a noise-free ground plane.
GND (Pins 3, 5, 8): Internal Function. Ground these
pins.
BLOCK DIAGRAM
2
1
VIN
SHDN
+
BANDGAP
VOUT_F
7
–
VOUT_S
4
GND
6
6655 BD
GND
3,5,8
6655fa
LTC6655
Applications Information
Bypass and Load Capacitors
The LTC6655 voltage references require a 0.1µF or larger
input capacitor located close to the part to improve power
supply rejection. An output capacitor with a value between
2.7µF and 100µF is also required.
The output capacitor has a direct effect on the stability,
turn-on time and settling behavior. Choose a capacitor
with low ESR to insure stability. Resistance in series with
the output capacitor (ESR) introduces a zero in the output
buffer transfer function and could cause instability. The
2.7μF to 100μF range includes several types of capacitors
that are readily available as through-hole and surface mount
components. It is recommended to keep ESR less than or
equal to 0.1Ω. Capacitance and ESR are both frequency
dependent. At higher frequencies capacitance drops and
ESR increases. To insure stable operation the output capacitor should have the required values at 100kHz.
In order to achieve the best performance, caution should
be used when choosing a capacitor. X7R ceramic capacitors are small, come in appropriate values and are
relatively stable over a wide temperature range. However,
for a low noise application X7R capacitors may not be
suitable since they may exhibit a piezoelectric effect. The
mechanical vibrations cause a charge displacement in the
ceramic dielectric and the resulting perturbation can look
like noise. If X7R capacitors are necessary, a thorough
bench evaluation should be completed to verify proper
performance.
For very low noise applications where every nanovolt
counts, film capacitors should be considered for their
low noise and lack of piezoelectric effects. Film capacitors such as polyester, polystyrene, polycarbonate, and
polypropylene have good temperature stability. Additional
care must be taken as polystyrene and polypropylene have
an upper temperature limit of 85°C to 105°C. Above these
temperatures, the working voltages need to be derated
according to manufacturer’s specifications. Another type
of film capacitor is polyphenylene sulfide (PPS). These
devices work over a wide temperature range, are stable,
and have large capacitance values beyond 1μF. In general,
film capacitors are found in surface mount and leaded
packages. Table 1 is a partial list of capacitor companies
and some of their available products.
In voltage reference applications, film capacitor lifetime
is affected by temperature and applied voltage. When
polyester capacitors are operated beyond their rated
temperatures (some capacitors are not rated for operation
above 85°C) they need to be derated. Voltage derating is
usually accomplished as a ratio of applied voltage to rated
voltage limit. Contact specific film capacitor manufacturers
to determine exact lifetime and derating information.
The lifetime of X7R capacitors is long, especially for
reference applications. Capacitor lifetime is degraded by
operating near or exceeding the rated voltage, at high
temperature, with AC ripple or some combination of these.
Most reference applications have AC ripple only during
transient events.
Table 1. Film Capacitor Companies
COMPANY
DIELECTRIC
AVAILABLE CAPACITANCE
TEMPERATURE RANGE
TYPE
Cornell Dublier
Polyester
0.5µF to 10µF
–55°C to 125°C
DME
Dearborn Electronics
Polyester
0.1µF to 12µF
–55°C to 125°C
218P, 430P, 431P, 442P, and 410P
Tecate
Polyester
0.01µF to 18µF
–40°C to 105°C
901, 914, and 914D
Wima
Polyester
10µF to 22µF
–55°C to 100°C
MKS 4, MKS 2-XL
Vishay
Polyester
1000pF to 15µF
–55°C to 125°C
MKT1820
Vishay
Polycarbonate
0.01µF to 10µF
–55°C to 100°C
MKC1862, 632P
Dearborn Electronics
Polyphenylene Sulfide (PPS)
0.01µF to 15µF
–55°C to 125°C
820P, 832P, 842P, 860P, and 880P
Wima
Polyphenylene Sulfide (PPS)
0.01µF to 6.8µF
–55°C to 140°C
SMD-PPS
6655fa
10
LTC6655
Applications Information
The choice of output capacitor also affects the bandwidth
of the reference circuitry and resultant noise peaking. As
shown in Figure 1, the bandwidth is inversely proportional
to the value of the output capacitor.
120
NOISE VOLTAGE (nV√Hz)
Noise peaking is related to the phase margin of the output
buffer. Higher peaking generally indicates lower phase margin. Other factors affecting noise peaking are temperature,
input voltage, and output load current.
80
40
0
0.01
2.5V •
–6
3.3 • 10 F
= 412µs
0.02A
The resulting turn-on time is shown in Figure 3. Here
the output capacitor is 3.3µF and the input capacitor is
0.1µF.
1,2
VIN
3V
CIN
0.1µF
1
10
FREQUENCY (kHz)
100
1000
6655 F01
7
LTC6655-2.5
6
VOUT 100Ω
COUT
3.3µF
3,4,5,8
VGEN
0.5V
6655 F02
Figure 2. Transient Load Test Circuit
VIN
2V/DIV
VOUT
1V/DIV
COUT = 3.3µF
Figure 4 shows the output response to a 500mV step on
VIN. The output response to a current step sourcing and
sinking is shown in Figures 5 and 6, respectively.
Figure 7 shows the output response as the current goes
from sourcing to sinking.
0.1
Figure 1. Output Voltage Noise Spectrum
COUT
ISC
For example, the LTC6655-2.5V, with a 3.3µF output
capacitor and a typical short-circuit current of 20mA, the
start-up time would be approximately:
COUT = 100µF
20
Results for the transient response plots (Figures 3 to 8)
were produced with the test circuit shown in Figure 2
unless otherwise indicated.
tON = VOUT •
COUT = 10µF
60
Start-Up and Load Transient Response
The turn-on time is slew limited and determined by the
short-circuit current, the output capacitor, and output
voltage as shown in the equation:
COUT = 2.7µF
100
200µs/DIV
6655 F03
Figure 3. Start-Up Response
VIN
3.5V
3V
Shutdown Mode
The LTC6655 family of references can be shut down by
tying the SHDN pin to ground. There is an internal pull-up
resistor tied to this pin. If left unconnected this pin rises to
VIN and the part is enabled. Due to the low internal pull-up
current, it is recommended that the SHDN pin be pulled
high externally for normal operation to prevent accidental
VOUT
50mV/DIV
COUT = 3.3µF
400µs/DIV
6655 F04
Figure 4. Output Response with a 500mV Step On VIN
6655fa
11
LTC6655
Applications Information
shutdown due to system noise or leakage currents. The
turn-on/turn-off response due to shutdown is shown in
Figure 8.
0mA
IOUT
–5mA
VOUT
10mV/DIV
COUT = 3.3µF
200µs/DIV
6655 F05
Figure 5. Output Response with a 5mA Load Step Sourcing
To control shutdown from a low voltage source, a MOSFET
can be used as a pull-down device as shown in Figure 9.
Note that an external resistor is unnecessary. A MOSFET
with a low drain-to-source leakage over the operating
temperature range should be chosen to avoid inadvertently
pulling down the SHDN pin. A resistor may be added from
SHDN to VIN to overcome excessive MOSFET leakage.
The SHDN thresholds have some dependency on VIN
and temperature as shown in the Typical Performance
Characteristics section. Avoid leaving SHDN at a voltage
between the thresholds as this will cause an increase in
supply current due to shoot-through current.
5mA
IOUT
0mA
VOUT
10mV/DIV
3V ≤ VIN ≤ 13.2V
COUT = 3.3µF
200µs/DIV
6655 F06
C1
1µF
VIN
VOUT_F
LTC6655-2.5
Figure 6. Output Response with 5mA Load Step Sinking
SHDN
TO µC
GND
VOUT_S
VOUT
C2
10µF
2N7002
6655 F09
2mA
IOUT
–2mA
Figure 9. Open-Drain Shutdown Circuit
Long-Term Drift
VOUT
10mV/DIV
COUT = 3.3µF
200µs/DIV
6655 F07
Figure 7. Output Response Showing a
Sinking to Sourcing Transition
SHDN
2V/DIV
Long-term drift cannot be extrapolated from accelerated
high temperature testing. This erroneous technique gives
drift numbers that are wildly optimistic. The only way
long-term drift can be determined is to measure it over
the time interval of interest.
The LTC6655 long-term drift data was collected on 80 parts
that were soldered into printed circuit boards similar to a
real world application. The boards were then placed into a
constant temperature oven with a TA = 35°C, their outputs
were scanned regularly and measured with an 8.5 digit
DVM. Typical long-term drift is illustrated in Figure 10.
VOUT
1V/DIV
COUT = 3.3µF
1ms/DIV
6655 F08
Figure 8. Shutdown Response with 5mA Source Load
6655fa
12
LTC6655
Applications Information
30
4 TYPICAL UNITS
LTC6655-2.5
25
80
NUMBER OF UNITS
LONG-TERM DRIFT (ppm)
120
40
0
20
15
10
–40
–80
5
0
500
1500
1000
HOURS
2000
0
–90 –70 –50 –30 –10 10 30 50 70 90 110
DISTRIBUTION (ppm)
2500
6655 F11
6655 F10
Figure 11. Hysteresis Plot –40°C to 125°C
Figure 10. Long-Term Drift
0.14
Hysteresis
0.12
NO LOAD
0.06
0.02
0
0
10
5
15
VIN (V)
6655 F12
Figure 12. LTC6655-2.5 Power Consumption
125
MAXIMUM AMBIENT
OPERATING TEMPERATURE (°C)
The MSOP8 package has a thermal resistance (θJA)
equal to 300°C/W. Under the maximum loaded condition,
the increase in die temperature is over 35°C. If operated at
these conditions with an ambient temperature of 125°C,
the absolute maximum junction temperature rating of
the device would be exceeded. Although the maximum
junction temperature is 150°C, for best performance it
is recommended to not exceed a junction temperature
of 125°C. The plot in Figure 13 shows the recommended
maximum ambient temperature limits for differing VIN and
load conditions using a maximum junction temperature
of 125°C.
0.08
0.04
Power Dissipation
Power dissipation for the LTC6655 depends on VIN and
load current. Figure 12 illustrates the power consumption versus VIN under a no-load and 5mA load condition
at room temperature for the LTC6655-2.5. Other voltage
options display similar behavior.
5mA LOAD
0.10
POWER (W)
Thermal hysteresis is a measure of change of output
voltage as a result of temperature cycling. Figure 11
illustrates the typical hysteresis based on data taken from
the LTC6655-2.5. A proprietary design technique minimizes
thermal hysteresis.
115
NO LOAD
105
5mA LOAD
95
85
75
65
55
0
3
6
9
VIN (V)
15
12
6655 F13
Figure 13. LTC6655-2.5 Maximum
Ambient Operating Temperature
6655fa
13
LTC6655
Applications Information
PC Board Layout
7
The LTC6655 reference is a precision device that is factory
trimmed to an initial accuracy of ±0.025%, as shown in the
Typical Performance Characteristic section. The mechanical
stress caused by soldering parts to a printed circuit board
may cause the output voltage to shift and the temperature
coefficient to change.
To reduce the effects of stress-related shifts, mount the
reference near the short edge of a printed circuit board
or in a corner. In addition, slots can be cut into the board
on two sides of the device to reduce mechanical stress. A
thicker and smaller board is stiffer and less prone to bend.
Finally, use stress relief, such as flexible standoffs, when
mounting the board.
Additional precautions include making sure the solder
joints are clean and the board is flux free to avoid leakage
paths. A sample PCB layout is shown in Figure 14.
+
2
LTC6655-2.5
6
2mA
4
LOAD
STAR
6655 F15
MINIMIZE RESISTANCE
OF METAL
Figure 15. Kelvin Connection for Good Load Regulation
output current <100µA), VOUT_S should be tied to VOUT_F
by the shortest possible path to reduce errors caused by
resistance in the sense trace.
Careful attention to grounding is also important, especially when sourcing current. The return load current can
produce an I • R drop causing poor load regulation. Use
a “star” ground connection and minimize the ground to
load metal resistance. Although there are several pins that
are required to be connected to ground, Pin 4 is the actual
ground for return current.
Optimal Noise Performance
VIN
GND
The LTC6655 offers extraordinarily low noise for a bandgap
reference—only 0.25ppm in 0.1Hz to 10Hz. As a result,
system noise performance may be dominated by system
design and physical layout.
VOUT
6655 F14
Figure 14. Sample PCB Layout
Load Regulation
To take advantage of the VOUT Kelvin force/sense pins,
the VOUT_S pin should be connected separately from the
VOUT_F pin as shown in Figure 15.
The VOUT_S pin sinks 2mA, which is unusual for a Kelvin
connection. However, this is required to achieve the exceptional low noise performance. The I • R drop on the
VOUT_S line directly affects load regulation. The VOUT_S
trace should be as short and wide as practical to minimize
series resistance The VOUT_S trace adds error as RTRACE
• 2mA, so a 0.1Ω trace adds 200µV error. The VOUT_F pin
is not as important as the VOUT_S pin in this regard. An
I • R drop on the VOUT_F pin increases the minimum supply
voltage when sourcing current, but does not directly affect
load regulation. For light loading of the output (maximum
Some care is required to achieve the best possible noise
performance. The use of dissimilar metals in component
leads and PC board traces creates thermocouples. Variations in thermal resistance, caused by uneven air flow,
create differential lead temperatures, thereby causing
thermoelectric voltage noise at the output of the reference. Minimizing the number of thermocouples, as well
as limiting airflow, can substantially reduce these errors.
Additional information can be found in Linear Technology
Application Note 82. Position the input and load capacitors
close to the part. Although the LTC6655 has a DC PSRR
of over 100dB, the power supply should be as stable as
possible to guarantee optimal performance. A plot of the
0.1Hz to 10Hz low frequency noise is shown in the Typical
Performance Characteristic section. Noise performance
can be further improved by wiring several LTC6655s in
parallel as shown in the Typical Applications section. With
this technique the noise is reduced by √N, where N is the
number of LTC6655s in parallel.
6655fa
14
LTC6655
Applications Information
Noise Specification
Noise in any frequency band is a random function based
on physical properties such as thermal noise, shot noise,
and flicker noise. The most precise way to specify a random
error such as noise is in terms of its statistics, for example
as an RMS value. This allows for relatively simple maximum
error estimation, generally involving assumptions about
noise bandwidth and crest factor. Unlike wideband noise,
low frequency noise, typically specified in a 0.1Hz to 10Hz
band, has traditionally been specified in terms of expected
error, illustrated as peak-to-peak error. Low frequency
noise is generally measured with an oscilloscope over a
10 second time frame. This is a pragmatic approach, given
that it can be difficult to measure noise accurately at low
frequencies, and that it can also be difficult to agree on the
statistical characteristics of the noise, since flicker noise
dominates the spectral density. While practical, a random
sampling of 10 second intervals is an inadequate method
for representation of low frequency noise, especially for
systems where this noise is a dominant limit of system
performance. Given the random nature of noise, the output
voltage may be observed over many time intervals, each
giving different results. Noise specifications that were
determined using this method are prone to subjectivity,
and will tend toward a mean statistical value, rather than
the maximum noise that is likely to be produced by the
device in question.
Because the majority of voltage reference data sheets
express low frequency noise as a typical number, and as
it tends to be illustrated with a repeatable plot near the
mean of a distribution of peak-to-peak values, the LTC6655
data sheet provides a similarly defined typical specification
in order to allow a reasonable direct comparison against
similar products. Data produced with this method generally suggests that in a series of 10 second output voltage
measurements, at least half the observations should have a
peak-to-peak value that is below this number. For example,
the LTC6655-2.5 measures less than 0.25ppmP-P in at
least 50% of the 10 second observations.
As mentioned above, the statistical distribution of noise
is such that if observed for long periods of time, the
peak error in output voltage due to noise may be much
larger than that observed in a smaller interval. The likely
maximum error due to noise is often estimated using the
RMS value, multiplied by an estimated crest factor, assumed
to be in the range of 6 to 8.4. This maximum possible value
will only be observed if the output voltage is measured
for very long periods of time. Therefore, in addition to the
common method, a more thorough approach to measuring
noise has been used for the LTC6655 (described in detail in
Linear Technology’s AN124) that allows more information
to be obtained from the result. In particular, this method
characterizes the noise over a significantly greater length
of time, resulting in a more complete description of low
frequency noise. The peak-to-peak voltage is measured
for 10 second intervals over hundreds of intervals. In addition, an electronic peak-detect circuit stores an objective
value for each interval. The results are then summarized in
terms of the fraction of measurement intervals for which
observed noise is below a specified level. For example,
the LTC6655-2.5 measures less than 0.27ppmP-P in 80%
of the measurement intervals, and less than 0.295ppmP-P
in 95% of observation intervals. This statistical variation
in noise is illustrated in Table 2 and Figure 17. The test
circuit is shown in Figure 16.
Table 2
50%
60%
70%
80%
90%
Low Frequency Noise (ppmP-P)
0.246
0.252
0.260
0.268
0.292
This method of testing low frequency noise is superior to
more common methods. The results yield a comprehensive
statistical description, rather than a single observation. In
addition, the direct measurement of output voltage over
time gives an actual representation of peak noise, rather
than an estimate based on statistical assumptions such
as crest factor. Additional information can be derived from
a measurement of low frequency noise spectral density,
as shown in Figure 18.
It should be noted from Figure 18 that the LTC6655 has
not only a low wideband noise, but an exceptionally low
flicker noise corner of 1Hz! This substantially reduces
low frequency noise, as well as long-term variation in
peak noise.
6655fa
15
15
RST
–15
RST
LTC6655
2.5V
10k
10k
1µF
P
P
1µF
F
S
1µF
REFERENCE
UNDER TEST
SD
IN
9V
1300µF
1µF
4
**1.2k
T
100k
0.005µF
+
–15V
4.7k
4.7k
A1
LT1012
100k
–
+
0.005µF
A6
1/4 LT1058
–
+
A5
1/4 LT1058
–
SHIELD
100k
A = 10
LOW NOISE
PRE-AMP
100k
+
16
0.1µF
–
A8
1/4 LT1058
+
–
A7
1/4 LT1058
–15V
Q2
1k
–
DVM
+
1k
5
A2
LT1097
0.022µF
SEE APPENDIX C FOR POWER, SHIELDING
AND GROUNDING SCHEME
= 1/4 LTC202
= 2N4393
= 1N4148
RST = Q2
+
10k*
1M*
RC2
+V
10k
B2
+15
BAT-85
BAT-85
RESET PULSE
GENERATOR
+15
= POLYPROPELENE
P
10k
330µF
16V
330µF
16V
+
6655 F16
A4 330µF OUTPUT CAPACITORS = <200nA LEAKAGE
AT 1VDC AT 25°C
= TANTALUM,WET SLUG
ILEAK < 5nA
SEE TEXT/APPENDIX B
FROM OSCILLOSCOPE
SWEEP GATE OUTPUT
VIA ISOLATION
PULSE TRANSFORMER
10k
+
A4
LT1012
–
ROOT-SUM-SQUARE
CORRECTION
SEE TEXT
T
A2
0.1µF
124k*
0.1µF
0.1µF
100Ω*
OUT
124k*
74C221
C2
CLR2
+15
0.22µF
330µF
16V
330µF
16V
IN
330Ω*
+15
–
A3
LT1012
+
A = 100 AND
0.1Hz TO 10Hz FILTER
Q1, Q2 = THERMALLY MATED
2SK369 (MATCH VGS 10%)
OR LSK389 DUAL
THERMALLY LAG
SEE TEXT
TO OSCILLOSCOPE INPUT
VIA ISOLATED PROBE,
1V/DIV = 1µV/DIV,
REFERRED TO INPUT,
SWEEP = 1s/DIV
10Ω*
100k*
* = 1% METAL FILM
** = 1% WIREWOUND, ULTRONIX105A
O TO 1V =
O TO 1µV
SHIELDED CAN
– INPUT
+
–
1µF
2k
Figure 16. Detailed Noise Test Circuitry. See Application Note 124.
– PEAK
+ PEAK
+
Q1
900Ω*
15V
200Ω*
750Ω*
450Ω*
1k*
PEAK TO PEAK
NOISE DETECTOR
AC LINE GROUND
1µF
–15V
Q3
2N2907
10k
1N4697
10V
+
0.15µF
+
15V
LTC6655
Applications Information
6655fa
LTC6655
Applications Information
shown in Figure 19, the output voltage shifts. After the
device expands, due to the heat, and then contracts, the
stresses on the die have changed position. This shift is
similar, but more extreme than thermal hysteresis.
35
NUMBER OF OBSERVATIONS
30
25
20
Experimental results of IR reflow shift are shown below
in Figure 20. These results show only shift due to reflow
and not mechanical stress.
15
10
5
300
750
850
650
550
PEAK-TO-PEAK NOISE (nV)
380s
950
6655 F17
Figure 17. Low Frequency Noise Histogram of the LTC6655-2.5
200
TP = 260°C
TL = 217°C
TS(MAX) = 200°C
TS = 190°C
225
TEMPERATURE (°C)
0
450
150
tP
30s
T = 150°C
tL
130s
RAMP TO
150°C
75
40s
160
120s
0
120
0
2
6
4
MINUTES
8
10
6655 F19
80
Figure 19. Lead-Free Reflow Profile
40
0
8
0.1
1
10
FREQUENCY (Hz)
100
6655 F18
Figure 18. LTC6655-2.5 Low Frequency Noise Spectrum
IR Reflow Shift
The mechanical stress of soldering a part to a board can
cause the output voltage to shift. Moreover, the heat of
an IR reflow or convection soldering oven can also cause
the output voltage to shift. The materials that make up a
semiconductor device and its package have different rates
of expansion and contraction. After a part undergoes the
extreme heat of a lead-free IR reflow profile, like the one
7
6
NUMBER OF UNITS
NOISE VOLTAGE (nV/√Hz)
RAMP
DOWN
5
4
3
2
1
0
–0.029 –0.023 –0.017 –0.011 –0.005
OUTPUT VOLTAGE SHIFT DUE TO IR REFLOW (%)
6655 F20
Figure 20. Output Voltage Shift Due to IR Reflow
6655fa
17
LTC6655
Typical Applications
Extended Supply Range Reference
Extended Supply Range Reference
4V TO 30V
R1
BZX84C12
C1
0.1µF
6V TO 80V
R1
R2
100k 4.7k
LTC6655-2.5
VIN
VOUT_F
SHDN
VOUT_S
VOUT
C1
0.1µF
BZX84C12
C2
10µF
GND
ON SEMI
MMBT5551
0.1µF
VIN SHDN
VOUT_F
LTC6655-2.5
VOUT_S
GND
6655 TA02
VOUT
C2
10µF
6655 TA03
Boosted Output Current
4V TO 13.2V
Boosted Output Current
LTC6655-2.5
SHDN
VOUT_F
VIN
C1
0.1µF
GND
Q1
2N2222
VOUT + 1.8V TO 13.2V
VOUT
VOUT_S
C1
1µF
C2
4.7µF
6655 TA05
C3
0.1µF
IMAX SET BY NPN
R1
220Ω
R2
1k
C4
1µF
2N2905
35mA MAX
VIN SHDN
VOUT_F
LTC6655-2.5
VOUT_S
GND
VOUT
C2
10µF
6655 TA04
Output Voltage Boost
VIN
VOUT + 0.5V TO 13.2V
VIN
C1
1µF
VOUT_F
LTC6655-2.5
SHDN
VOUT_S
GND
VOUT = VOLTAGE OPTION + 0.002 • R
THIS EXAMPLE USES 2.5V AS THE
VOLTAGE OPTION
C2
10µF
R
VOUT
2.5V TO 4.5V
R = 0k to 1k
6655 TA07
FOR R USE A POTENTIOMETER THAT
CAN HANDLE 2mA, IS LOW NOISE AND
HAS A LOW TEMPERATURE COEFFICIENT
Low Noise Precision Voltage Boost Circuit
VIN
VOUT + 0.5V TO 13.2V
C1
1µF
VIN
VOUT_F
LTC6655-2.5
SHDN
VOUT_S
VIN
LT1677 +
+
––
GND
R3
5k
VOUT = VOLTAGE OPTION • (1 + R1/R2)
THIS EXAMPLE USES 2.5V AS THE
VOLTAGE OPTION
R1
10k
C2
10µF
VOUT
5V
RLOAD
R2
10k
6655 TA08
FOR R1 AND R2 USE VISHAY TRIMMED
RESISTOR ARRAY (VSR144 OR MPM).
WITH A PRECISION ARRAY THE
MATCHING AND LOW TC WILL HELP
PRESERVE LOW DRIFT. R3 = R1||R2
6655fa
18
LTC6655
Typical Applications
Low Noise Statistical Averaging Reference
e′N = eN/√N; Where N is the Number of LTC6655s in Parallel
LTC6655-2.5
SHDN
VOUT_F
3V TO
13.2V
VIN
C1
0.1µF
GND
R1
32.4Ω
VOUT_S
VOUT
C2
2.7µF
C9
4.7µF
LTC6655-2.5
SHDN
VOUT_F
VIN
C3
0.1µF
GND
R2
32.4Ω
VOUT_S
C4
2.7µF
LTC6655-2.5
SHDN
VOUT_F
VIN
C5
0.1µF
GND
R3
32.4Ω
VOUT_S
C6
2.7µF
LTC6655-2.5
SHDN
VOUT_F
VIN
6655 TA06a
C7
0.1µF
GND
VOUT_S
R4
32.4Ω
C8
2.7µF
Low Frequency Noise (0.1Hz to 10Hz)
with Four LTC6655-2.5 in Parallel
200nV/
DIV
320nVP-P
0.1Hz to 10Hz
1s/DIV
6655 TA06b
6655fa
19
LTC6655
Package Description
MS8 Package
8-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1660 Rev F)
0.889 p 0.127
(.035 p .005)
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
3.00 p 0.102
(.118 p .004)
(NOTE 3)
0.65
(.0256)
BSC
0.42 p 0.038
(.0165 p .0015)
TYP
8
7 6 5
0.52
(.0205)
REF
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
3.00 p 0.102
(.118 p .004)
(NOTE 4)
4.90 p 0.152
(.193 p .006)
DETAIL “A”
0o – 6o TYP
GAUGE PLANE
0.53 p 0.152
(.021 p .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 p 0.0508
(.004 p .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
6655fa
20
LTC6655
Revision History
REV
DATE
DESCRIPTION
A
02/10
Voltage Options Added (1.250, 2.048, 3.000, 3.300, 4.096, 5.000), Reflected Throughout the Data Sheet
PAGE NUMBER
1 to 22
6655fa
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
LTC6655
Typical Application
Low Noise Precision 24-Bit Analog-to-Digital Converter Application
2.5k
5V
VREF
0.01µF
LTC2449
10µF
0.01µF
1nF
50Ω
SDI
SCK
SDO
CS
SPI INTERFACE
–
1/2
LTC6241
+
BUSY
EXT
fO
REF+
REF–
4
2.5k
ADCINP
GND
GND
–2.5V
MUXOUTP
GND
GND
3,5,8
–
1/2
LTC6241
+
GND
0.1µF
VREF
GND
LTC6655
7
VOUT_F
1
6
SHDN
VOUT_S
VIN
50Ω
ADCINN
GND
THERMOCOUPLE
1nF
MUXOUTN
GND
RTD
2
VCC
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
CH8
CH9
CH10
CH11
CH12
CH13
CH14
CH15
COM
GND
5k
7.5V
RREF
400Ω
6655 TA09
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
LT®1236
Precision Low Drift Low Noise Reference
0.05% Max, 5ppm/°C Max, 1ppm (Peak-to-Peak) Noise
LT1460
Micropower Series References
0.075% Max, 10ppm/°C Max, 20mA Output Current
LT1461
Micropower Series Low Dropout
0.04% Max, 3ppm/°C Max, 50mA Output Current
LT1790
Micropower Precision Series References
0.05% Max, 10ppm/°C Max, 60mA Supply, SOT23 Package
LT6650
Micropower Reference with Buffer Amplifier
0.5% Max, 5.6µA Supply, SOT23 Package
LTC6652
Precision Low Drift Low Noise Reference
0.05% Max, 5ppm/°C Max, –40°C to 125°C, MSOP8
LT6660
Tiny Micropower Series Reference
0.2% Max, 20ppm/°C Max, 20mA Output Current, 2mm × 2mm DFN
6655fa
22 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
LT 0210 REV A • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2009
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