NSC ADC141S626EB

ADC141S626
14-Bit, 50 kSPS to 250 kSPS, Differential Input, Micro Power
A/D Converter
General Description
Features
The ADC141S626 is a 14-bit, 50 kSPS to 250 kSPS sampling
Analog-to-Digital (A/D) converter. The converter is based on
a successive-approximation register architecture where the
differential nature of the analog inputs is maintained from the
internal track-and-hold circuits throughout the A/D converter
to provide excellent common-mode signal rejection. The
ADC141S626 features an external reference that can be varied from 1.0V to VA and a zero-power track mode where the
ADC is consuming the minimum amount of supply current
while the internal sampling capacitor is tracking the applied
analog input voltage.
The serial data output is binary 2's complement and is compatible with several standards, such as SPI™, QSPI™, MICROWIRE™, and many common DSP serial interfaces. The
conversion result is clocked out by the serial clock input and
is the result of the conversion currently in progress.
The ADC141S626 may be operated with independent analog
(VA) and digital input/output (VIO) supplies. VA and VIO can
range from 2.7V to 5.5V and can be set independent of each
other. This allows a user to maximize performance and minimize power consumption by operating the analog portion of
the ADC at a VA of 5V while communicating with a 3V controller on the digital side. Operating from a single 3V supply,
the power consumption when operating at 200 kSPS is 2.0
mW. While operating from a single 5V supply, the power consumption when operating at 250 kSPS is 4.8 mW. The power
consumption drops down to 4 µW and 13 µW respectively
when the ADC141S626 enters acquisition mode. The differential input, low power consumption, and small size make the
ADC141S626 ideal for direct connection to bridge sensors
and transducers in battery operated systems or remote data
acquisition applications.
Operation is guaranteed over the temperature range of −40°
C to +85°C and clock rates of 0.9 MHz to 4.5 MHz. The
ADC141S626 is available in a 10-lead MSOP package.
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True Differential Inputs
Guaranteed performance from 50 kSPS to 250 kSPS
External Reference
Zero-Power Track Mode
Wide Input Common-Mode Voltage Range
Operating Temperature Range of −40°C to +85°C
SPI™/QSPI™/MICROWIRE™/DSP compatible Serial
Interface
Key Specifications
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Conversion Rate
INL
DNL
SNR
THD
ENOB
Power Consumption
— 200 kSPS, 3V
— 250 kSPS, 5V
— Power-Down, 3V
— Power-Down, 5V
50 kSPS to 250 kSPS
± 0.95 LSB (max)
± 0.95 LSB (max)
82 LSB (max)
− 90 dBc (typ)
13.3 bits (min)
2.0 mW (typ)
4.8 mW (typ)
4 µW (typ)
13 µW (typ)
Applications
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Automotive Navigation
Portable Systems
Medical Instruments
Instrumentation and Control Systems
Motor Control
Direct Sensor Interface
Connection Diagram
30041305
TRI-STATE® is a trademark of National Semiconductor Corporation.
MICROWIRE™ is a trademark of National Semiconductor Corporation.
QSPI™ and SPI™ are trademarks of Motorola, Inc.
© 2007 National Semiconductor Corporation
300413
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ADC141S626 14-Bit, 50 kSPS to 250 kSPS, Differential Input, Micro Power A/D Converter
November 30, 2007
ADC141S626
Ordering Information
Temperature Range
Description
Top Mark
ADC141S626CIMM
Order Code
−40°C to +85°C
10-Lead MSOP Package, 1000 Units Tape & Reel
X94C
ADC141S626CIMMX
−40°C to +85°C
10-Lead MSOP Package, 3500 Units Tape & Reel
X94C
ADC141S626EB
Evaluation Board
Block Diagram
30041302
Pin Descriptions and Equivalent Circuits
Pin No.
Symbol
Description
1
VREF
Voltage Reference Input. A voltage reference between 1V and VA must be applied to this
input. VREF must be decoupled to GND with a minimum ceramic capacitor value of 0.1
µF. A bulk capacitor value of 1.0 to 10 µF in parallel with the 0.1 µF capacitor is
recommended for enhanced performance.
2
+IN
Non-Inverting Input. +IN is the positive analog input for the differential signal applied to
the ADC141S626.
3
−IN
Inverting Input. −IN is the negative analog input for the differential signal applied to the
ADC141S626.
4
GND
Ground. GND is the ground reference point for all signals applied to the ADC141S626.
5
GND
Ground. GND is the ground reference point for all signals applied to the ADC141S626.
6
CS
Chip Select Bar. CS is active low. A conversion begins on the falling edge of CS. The
ADC141S626 is in Acquisition Mode when CS is HIGH.
7
DOUT
Serial Data Output. The conversion result is provided on DOUT. The serial data output
word is comprised of 2 null bits followed by 14 data bits (MSB first). During a conversion,
the data is output on the falling edges of SCLK and is valid on the subsequent rising
edges.
8
SCLK
Serial Clock. SCLK is used to control data transfer and serves as the conversion clock.
9
VIO
Digital Input/Output Power Supply Input. A voltage source between 2.7V and 5.5V must
be applied to this input. VIO must be decoupled to GND with a ceramic capacitor value of
0.1 µF in parallel with a bulk capacitor value of 1.0 to 10 µF.
10
VA
Analog Power Supply Input. A voltage source between 2.7V and 5.5V must be applied to
this input. VA must be decoupled to GND with a ceramic capacitor value of 0.1 µF in
parallel with a bulk capacitor value of 1.0 to 10 µF.
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2
Operating Ratings
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Operating Temperature Range
Analog Supply Voltage VA
Digital I/O Supply Voltage VIO
Voltage on Any Analog Input Pin to
GND
Voltage on Any Digital Input Pin to
GND
Input Current at Any Pin (Note 3)
Package Input Current (Note 3)
Power Consumption at TA = 25°C
ESD Susceptibility (Note 5)
Human Body Model
Machine Model
Charge Device Model
Junction Temperature
Storage Temperature
(Notes 1, 2)
−40°C ≤ TA ≤ +85°C
Supply Voltage, VA
+2.7V to +5.5V
Supply Voltage, VIO
+2.7V to +5.5V
Reference Voltage, VREF
1.0V to VA
Analog Input Pins Voltage Range
0 to VA
Differential Analog Input Voltage
−VREF to +VREF
Input Common-Mode Voltage, VCM See Figure 10 (Sect 2.3)
Digital Input Pins Voltage Range
0 to VIO
Clock Frequency
0.9 MHz to 4.5 MHz
−0.3V to 6.5V
−0.3V to 6.5V
−0.3V to (VA + 0.3V)
−0.3V to (VIO + 0.3V)
±10 mA
±50 mA
See (Note 4)
Package Thermal Resistance
4000V
300V
1250V
+150°C
−65°C to +150°C
Package
θJA
10-lead MSOP
240°C / W
Soldering
process
must
comply
with
National
Semiconductor's Reflow Temperature Profile specifications.
Refer to www.national.com/packaging. (Note 6)
ADC141S626 Converter Electrical Characteristics
(Note 7)
The following specifications apply for VA = VIO = VREF = +2.7V to 5.5V and fSCLK = 0.9 to 3.6 MHz or VA = VIO = VREF = +4.5V to
5.5V and fSCLK = 3.6 to 4.5 MHz; fIN = 20 kHz and CL = 25 pF, unless otherwise noted. Boldface limits apply for TA = TMIN to
TMAX; all other limits are at TA = 25°C.
Symbol
Parameter
Conditions
Typical
Limits
Units
14
Bits
STATIC CONVERTER CHARACTERISTICS
Resolution with No Missing Codes
INL
Integral Non-Linearity
±0.5
±0.95
LSB (max)
DNL
Differential Non-Linearity
±0.5
±0.95
LSB (max)
OE
Offset Error
−1
±5
LSB (max)
Positive Full-Scale Error
−3
±7
LSB (max)
Negative Full-Scale Error
0.5
±4
LSB (max)
Positive Gain Error
−1.5
±6
LSB (max)
Negative Gain Error
1.5
±6
LSB (max)
VA = VIO = VREF = +3V, −0.1 dBFS
81.9
80.1
dBc (min)
VA = VIO = VREF = +5V, −0.1 dBFS
84.2
82
dBc (min)
VA = VIO = VREF = +3V, −0.1 dBFS
82
80.2
dBc (min)
VA = VIO = VREF = +5V, −0.1 dBFS
84.3
82
dBc (min)
VA = VIO = VREF = +3V, −0.1 dBFS
−102
dBc
VA = VIO = VREF = +5V, −0.1 dBFS
−102
dBc
VA = VIO = VREF = +3V, −0.1 dBFS
97
dBc
FSE
GE
DYNAMIC CONVERTER CHARACTERISTICS
SINAD
SNR
THD
SFDR
ENOB
FPBW
Signal-to-Noise Plus Distortion Ratio
Signal-to-Noise Ratio
Total Harmonic Distortion
Spurious-Free Dynamic Range
Effective Number of Bits
−3 dB Full Power Bandwidth
VA = VIO = VREF = +5V, −0.1 dBFS
101
VA = VIO = VREF = +3V, −0.1 dBFS
13.3
13.0
bits (min)
VA = VIO = VREF = +5V, −0.1 dBFS
13.7
13.3
bits (min)
Differential
Output at 70.7%FS with Input
FS Input
Single-Ended
Input
3
dBc
26
MHz
22
MHz
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ADC141S626
Absolute Maximum Ratings (Notes 1, 2)
ADC141S626
Symbol
Parameter
Conditions
Typical
Limits
Units
−VREF
V (min)
ANALOG INPUT CHARACTERISTICS
VIN
Differential Input Range
IDCL
DC Leakage Current
CINA
Input Capacitance
CMRR
Common Mode Rejection Ratio
VIN = VREF or VIN = -VREF
+VREF
V (max)
±1
µA (max)
In Acquisition Mode
30
pF
In Conversion Mode
3
pF
See the Specification Definitions for the
test condition
76
dB
DIGITAL INPUT CHARACTERISTICS
VIH
Input High Voltage
VIO = +2.7V to 5.5V
1.9
2.3
V (min)
VIL
Input Low Voltage
VIO = +2.7V to 5.5V
1.0
0.7
V (max)
IIN
Input Current
VIN = 0V or VA
CIND
Input Capacitance
±1
µA (max)
2
4
pF (max)
ISOURCE = 200 µA
VA − 0.05
VA − 0.2
V (min)
ISOURCE = 1 mA
VA − 0.16
ISINK = 200 µA
0.01
ISINK = 1 mA
0.05
DIGITAL OUTPUT CHARACTERISTICS
VOH
Output High Voltage
VOL
Output Low Voltage
IOZH, IOZL
TRI-STATE Leakage Current
Force 0V or VA
COUT
TRI-STATE Output Capacitance
Force 0V or VA
2
Output Coding
V
0.4
V (max)
V
±1
µA (max)
4
pF (max)
Binary 2'S Complement
POWER SUPPLY CHARACTERISTICS
VA
Analog Supply Voltage Range
VIO
Digital Input/Output Supply Voltage
Range
VREF
Reference Voltage Range
IVA (Conv)
IVIO
(Conv)
Analog Supply Current, Conversion
Mode
Digital I/O Supply Current, Conversion
Mode
(Note 9)
V (min)
5.5
V (max)
2.7
V (min)
5.5
V (max)
1.0
V (min)
VA
V (max)
fSCLK = 3.6 MHz, VA = 3V, fS = 200
kSPS, fIN = 20 kHz
540
760
µA (max)
fSCLK = 4.5 MHz, VA = 5V, fS = 250
kSPS, fIN = 20 kHz
740
970
µA (max)
fSCLK = 3.6 MHz, VA = 3V, fS = 200
kSPS, fIN = 20 kHz
90
190
µA (max)
fSCLK = 4.5 MHz, VA = 5V, fS = 250
kSPS, fIN = 20 kHz
170
260
µA (max)
fSCLK = 3.6 MHz, VA = 3V, fS = 200
kSPS, fIN = 20 kHz
25
60
µA (max)
fSCLK = 4.5 MHz, VA = 5V, fS = 250
kSPS, fIN = 20 kHz
45
80
µA (max)
fSCLK = 4.5 MHz, VA = 5V
8
fSCLK = 0 (Note 8)
2
3
µA (max)
0.3
µA (max)
0.2
µA (max)
IVREF
(Conv)
Reference Current, Conversion Mode
IVA (PD)
Analog Supply Current, Power Down
Mode (CS high)
IVIO (PD)
Digital I/O Supply Current, Power Down fSCLK = 4.5 MHz, VA = 5V
Mode (CS high)
fSCLK = 0 (Note 8)
0.1
IVREF (PD)
Reference Current, Power Down Mode
(CS high)
fSCLK = 4.5 MHz, VA = 5V
0.1
fSCLK = 0 (Note 8)
0.1
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2.7
4
µA
3
µA
µA
Parameter
Conditions
Typical
Limits
Units
fSCLK = 3.6 MHz, fS = 200 kSPS, fIN = 20
kHz, VA = VIO = VREF = 3.0V
2.0
3.0
mW
fSCLK = 4.5 MHz, fS = 250 kSPS, fIN = 20
kHz, VA = VIO = VREF = 5.0V
4.8
6.5
mW
3
4
µW (max)
13
17
µW (max)
PWR
(Conv)
Power Consumption, Conversion Mode
PWR
(PD)
fSCLK = 0, VA = VIO = VREF = 3.0V
Power Consumption, Power Down Mode (Note 8)
(CS high)
fSCLK = 0, VA = VIO = VREF = 5.0V
(Note 8)
PSRR
Power Supply Rejection Ratio
See the Specification Definitions for the
test condition
−85
VA = VIO = VREF = +2.7V to 5.5V
4.8
dB
AC ELECTRICAL CHARACTERISTICS
fSCLK
Maximum Clock Frequency
fSCLK
Minimum Clock Frequency
0.9
MHz (max)
fS
Maximum Sample Rate
250
kSPS (min)
tACQ
Acquisition/Track Time
667
ns (min)
tCONV
Conversion/Hold Time
15
SCLK cycles
tAD
Aperture Delay
See the Specification Definitions
4.5
6
MHz (min)
ns
ADC141S626 Timing Specifications
(Note 7)
The following specifications apply for VA = VIO = VREF= +2.7V to 5.5V and fSCLK = 0.9 to 4.5 MHz, CL = 25 pF, Boldface limits
apply for TA = TMIN to TMAX: all other limits TA = 25°C.
Symbol
Parameter
Conditions
Typical
Limits
Units
3
6
ns (min)
1/fSCLK - 3
1/fSCLK - 6
ns (max)
tCSS
CS Setup Time prior to an SCLK rising edge
tDH
DOUT Hold Time after an SCLK falling edge
10
6
ns (min)
tDA
DOUT Access Time after an SCLK falling edge
28
40
ns (max)
tDIS
DOUT Disable Time after the rising edge of CS
(Note 11)
10
20
ns (max)
tCS
Minimum CS Pulse Width
5
20
ns (min)
tEN
DOUT Enable Time after the falling edge of CS
32
51
ns (max)
tCH
SCLK High Time
67
89
ns (min)
tCL
SCLK Low Time
67
89
ns (min)
tr
DOUT Rise Time
7
ns
tf
DOUT Fall Time
7
ns
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed
specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test
conditions. Operation of the device beyond the maximum Operating Ratings is not recommended.
Note 2: All voltages are measured with respect to GND = 0V, unless otherwise specified.
Note 3: When the input voltage at any pin exceeds the power supplies (that is, VIN < GND or VIN > VA), the current at that pin should be limited to 10 mA. The 50
mA maximum package input current rating limits the number of pins that can safely exceed the power supplies with an input current of 10 mA to five.
Note 4: The absolute maximum junction temperature (TJmax) for this device is 150°C. The maximum allowable power dissipation is dictated by TJmax, the
junction-to-ambient thermal resistance (θJA), and the ambient temperature (TA), and can be calculated using the formula PDMAX = (TJmax − TA)/θJA. The values
for maximum power dissipation listed above will be reached only when the ADC141S626 is operated in a severe fault condition (e.g. when input or output pins
are driven beyond the power supply voltages, or the power supply polarity is reversed). Such conditions should always be avoided.
Note 5: Human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor. Machine model is a 220 pF capacitor discharged through 0 Ω. Charge
device model simulates a pin slowly acquiring charge (such as from a device sliding down the feeder in an automated assembler) then rapidly being discharged.
Note 6: Reflow temperature profiles are different for lead-free packages.
Note 7: Typical values are at TJ = 25°C and represent most likely parametric norms. Test limits are guaranteed to National's AOQL (Average Outgoing Quality
Level).
Note 8: This parameter is guaranteed by design and/or characterization and is not tested in production.
Note 9: The value of VIO is independent of the value of VA. For example, VIO could be operating at 5V while VA is operating at 3V or VIO could be operating at 3V
while VA is operating at 5V.
Note 10: While the maximum sample rate is fSCLK/18, the actual sample rate may be lower than this by having the CS rate slower than fSCLK/18.
Note 11: tDIS is the time for DOUT to change 10% while being loaded by the Timing Test Circuit.
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ADC141S626
Symbol
ADC141S626
Timing Diagrams
30041301
FIGURE 1. ADC141S626 Single Conversion Timing Diagram
30041310
FIGURE 5. Valid CS Assertion Times
30041308
FIGURE 2. Timing Test Circuit
30041312
30041306
FIGURE 6. Voltage Waveform for tDIS
FIGURE 3. DOUT Rise and Fall Times
30041311
FIGURE 4. DOUT Hold and Access Times
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APERTURE DELAY is the time between the first falling edge
of SCLK and the time when the input signal is sampled for
conversion.
COMMON MODE REJECTION RATIO (CMRR) is a measure
of how well in-phase signals common to both input pins are
rejected.
To calculate CMRR, the change in output offset is measured
while the common mode input voltage is changed from 2V to
3V.
CMRR = 20 LOG ( Δ Common Input / Δ Output Offset)
CONVERSION TIME is the time required, after the input voltage is acquired, for the ADC to convert the input voltage to a
digital word.
DIFFERENTIAL NON-LINEARITY (DNL) is the measure of
the maximum deviation from the ideal step size of 1 LSB.
DUTY CYCLE is the ratio of the time that a repetitive digital
waveform is high to the total time of one period. The specification here refers to the SCLK.
EFFECTIVE NUMBER OF BITS (ENOB, or EFFECTIVE
BITS) is another method of specifying Signal-to-Noise and
Distortion or SINAD. ENOB is defined as (SINAD − 1.76) /
6.02 and says that the converter is equivalent to a perfect
ADC of this (ENOB) number of bits.
FULL POWER BANDWIDTH is a measure of the frequency
at which the reconstructed output fundamental drops 3 dB
below its low frequency value for a full scale input.
GAIN ERROR is the deviation from the ideal slope of the
transfer function. It is the difference between Positive FullScale Error and Negative Full-Scale Error and can be calculated as:
PSRR = 20 LOG (ΔOutput Offset / ΔVA)
SIGNAL TO NOISE RATIO (SNR) is the ratio, expressed in
dB, of the rms value of the input signal to the rms value of the
sum of all other spectral components below one-half the sampling frequency, not including harmonics or d.c.
SIGNAL TO NOISE PLUS DISTORTION (S/N+D or
SINAD) Is the ratio, expressed in dB, of the rms value of the
input signal to the rms value of all of the other spectral components below one-half the sampling frequency, including
harmonics but excluding d.c.
SPURIOUS FREE DYNAMIC RANGE (SFDR) is the difference, expressed in dB, between the desired signal amplitude
to the amplitude of the peak spurious spectral component below one-half the sampling frequency, where a spurious spectral component is any signal present in the output spectrum
that is not present at the input and may or may not be a harmonic.
TOTAL HARMONIC DISTORTION (THD) is the ratio of the
rms total of the first five harmonic components at the output
to the rms level of the input signal frequency as seen at the
output, expressed in dB. THD is calculated as
Gain Error = Positive Full-Scale Error − Negative Full-Scale
Error
INTEGRAL NON-LINEARITY (INL) is a measure of the deviation of each individual code from a line drawn from ½ LSB
below the first code transition through ½ LSB above the last
code transition. The deviation of any given code from this
straight line is measured from the center of that code value.
MISSING CODES are those output codes that will never appear at the ADC outputs. The ADC141S626 is guaranteed not
to have any missing codes.
NEGATIVE FULL-SCALE ERROR is the difference between
the differential input voltage at which the output code transitions from negative full scale to the next code and −VREF + 1
LSB
where Af1 is the RMS power of the input frequency at the output and Af2 through Af6 are the RMS power in the first 5
harmonic frequencies.
THROUGHPUT TIME is the minimum time required between
the start of two successive conversion.
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ADC141S626
NEGATIVE GAIN ERROR is the difference between the negative full-scale error and the offset error.
OFFSET ERROR is the difference between the differential
input voltage at which the output code transitions from code
0000h to 0001h and 1 LSB.
POSITIVE FULL-SCALE ERROR is the difference between
the differential input voltage at which the output code transitions to positive full scale and VREF minus 1 LSB.
POSITIVE GAIN ERROR is the difference between the positive full-scale error and the offset error.
POWER SUPPLY REJECTION RATIO (PSRR) is a measure
of how well a change in the analog supply voltage is rejected.
PSRR is calculated from the ratio of the change in offset error
for a given change in supply voltage, expressed in dB. For the
ADC141S626, VA is changed from 4.5V to 5.5V.
Specification Definitions
ADC141S626
Typical Performance Characteristics
VA = VIO = VREF = +5V, fSCLK = 4.5 MHz, fSAMPLE = 250 kSPS,
TA = +25°C, and fIN = 20 kHz unless otherwise stated.
DNL - 250 kSPS
INL - 250 kSPS
30041321
30041322
DNL vs. VA
INL vs. VA
30041323
30041324
DNL vs. VREF
INL vs. VREF
30041319
30041318
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VA = VIO = VREF = +5V, fSCLK = 4.5 MHz, fSAMPLE = 250 kSPS,
TA = +25°C, and fIN = 20 kHz unless otherwise stated.
DNL vs. SCLK FREQUENCY
INL vs. SCLK FREQUENCY
30041325
30041326
DNL vs. TEMPERATURE
INL vs. TEMPERATURE
30041329
30041330
SINAD vs. VA
THD vs. VA
30041333
30041332
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ADC141S626
Typical Performance Characteristics
ADC141S626
Typical Performance Characteristics
VA = VIO = VREF = +5V, fSCLK = 4.5 MHz, fSAMPLE = 250 kSPS,
TA = +25°C, and fIN = 20 kHz unless otherwise stated.
SINAD vs. VREF
THD vs. VREF
30041337
30041336
SINAD vs. SCLK FREQUENCY
THD vs. SCLK FREQUENCY
30041341
30041340
SINAD vs. INPUT FREQUENCY
THD vs. INPUT FREQUENCY
30041349
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30041348
10
VA = VIO = VREF = +5V, fSCLK = 4.5 MHz, fSAMPLE = 250 kSPS,
TA = +25°C, and fIN = 20 kHz unless otherwise stated.
SINAD vs. TEMPERATURE
THD vs. TEMPERATURE
30041372
30041371
VA CURRENT vs. VA
VA CURRENT vs. SCLK FREQUENCY
30041335
30041355
VA CURRENT vs. TEMPERATURE
VREF CURRENT vs. VREF
30041354
30041334
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ADC141S626
Typical Performance Characteristics
ADC141S626
Typical Performance Characteristics
VA = VIO = VREF = +5V, fSCLK = 4.5 MHz, fSAMPLE = 250 kSPS,
TA = +25°C, and fIN = 20 kHz unless otherwise stated.
VREF CURRENT vs. SCLK FREQUENCY
VREF CURRENT vs. TEMPERATURE
30041352
30041351
VIO CURRENT vs. VIO
VIO CURRENT vs. SCLK FREQUENCY
30041344
30041342
VIO CURRENT vs. TEMPERATURE
SPECTRAL RESPONSE - 250 kSPS
30041314
30041343
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The ADC141S626 is a 14-bit, 50 kSPS to 250 kSPS sampling
Analog-to-Digital (A/D) converter. The converter uses a successive approximation register (SAR) architecture based upon capacitive redistribution containing an inherent sample/
hold function. The differential nature of the analog inputs is
maintained from the internal track-and-hold circuits throughout the A/D converter to provide excellent common-mode
signal rejection.
The ADC141S626 operates from independent analog and
digital supplies. The analog supply (VA) can range from 2.7V
to 5.5V and the digital input/output supply (VIO) can range
from 2.7V to 5.5V. The ADC141S626 utilizes an external reference. The external reference can be any voltage between
1V and VA. The value of the reference voltage determines the
range of the analog input, while the reference input current
depends upon the conversion rate.
The analog input is presented to the two input pins: +IN and
–IN. Upon initiation of a conversion, the differential input at
these pins is sampled on the internal capacitor array. The inputs are disconnected from the internal circuitry while a conversion is in progress. The ADC141S626 features a zeropower track mode where the ADC is consuming the minimum
amount of supply current while the internal sampling capacitor
is tracking the applied analog input voltage. Zero-power track
mode is exercised by bringing chip select bar (CS) high or
when CS is held low after the conversion is complete (after
the 16th falling edge of the serial clock).
The external serial clock (SCLK) controls data transfer and
serves as the conversion clock. The duty cycle of SCLK is
essentially unimportant, provided the minimum clock high and
low times are met. The minimum SCLK frequency is set by
internal capacitor leakage. Each conversion requires 18
SCLK cycles to complete. If less than 14 bits of conversion
data are required, CS can be brought high at any point during
the conversion. This procedure of terminating a conversion
prior to completion is commonly referred to as short cycling.
The digital conversion result is clocked out by the SCLK input
and is provided serially, most significant bit first, at the DOUT
pin. The digital data that is provided at the DOUT pin is that of
the conversion currently in progress and thus there is no pipe
line delay.
2.0 ANALOG SIGNAL INPUTS
The ADC141S626 has a differential input where the effective
input voltage that is digitized is (+IN) − (−IN). By using this
differential input, small signals common to both inputs are rejected, as shown in Figure 7. As is the case with all differential
input A/D converters, operation with a fully differential input
signal or voltage will provide better performance than with a
single-ended input. However, the ADC141S626 can be presented with a single-ended input.
1.0 REFERENCE INPUT
The externally supplied reference voltage sets the analog input range. The ADC141S626 will operate with a reference
voltage in the range of 1V to VA.
Operation with a reference voltage below 1V is also possible
with slightly diminished performance. As the reference voltage (V REF) is reduced, the range of acceptable analog input
voltages is reduced. Assuming a proper common-mode input
voltage, the differential peak-to-peak input range is limited to
twice VREF. See Section 2.3 for more details. Reducing the
value of VREF also reduces the size of the least significant bit
(LSB). The size of one LSB is equal to twice the reference
voltage divided by 16,384. When the LSB size goes below the
noise floor of the ADC141S626, the noise will span an increasing number of codes and overall performance will suffer.
30041375
FIGURE 7. Analog Input CMRR vs. Frequency
The current required to recharge the input sampling capacitor
will cause voltage spikes at +IN and −IN. Do not try to filter
out these noise spikes. Rather, ensure that the transient settles out during the acquisition period.
13
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ADC141S626
For example, dynamic signals will have their SNR degrade,
while D.C. measurements will have their code uncertainty increase. Since the noise is Gaussian in nature, the effects of
this noise can be reduced by averaging the results of a number of consecutive conversions.
Additionally, since offset and gain errors are specified in LSB,
any offset and/or gain errors inherent in the A/D converter will
increase in terms of LSB size as the reference voltage is reduced.
The reference input and the analog inputs are connected to
the capacitor array through a switch matrix when the input is
sampled. Hence, the current requirements at the reference
and at the analog inputs are a series of transient spikes that
occur at a frequency dependent on the operating sample rate
of the ADC141S626.
The reference current changes only slightly with temperature.
See the curves, “Reference Current vs. SCLK Frequency”
and “Reference Current vs. Temperature” in the Typical Performance Curves section for additional details.
Functional Description
ADC141S626
2.1 Differential Input Operation
With a fully differential input voltage or signal, a positive full
scale output code (01 1111 1111 1111b or 1FFFh) will be
obtained when (+IN) − (−IN) is greater than or equal to VREF
− 1 LSB. A negative full scale code (10 0000 0000 0000b or
2000h) will be obtained when (+IN) − (−IN) is less than or
equal to −VREF + 1 LSB. This ignores gain, offset and linearity
errors, which will affect the exact differential input voltage that
will determine any given output code. Figure 8 shows the
ADC141S626 being driven by a full-scale differential source.
2.3 Input Common Mode Voltage
The allowable input common mode voltage (VCM) range depends upon the supply and reference voltages used for the
ADC141S626. The ranges of VCM are depicted in Figure 10
and Figure 11. Equations for calculating the minimum and
maximum common mode voltages for differential and singleended operation are shown in Table 1.
30041380
30041361
FIGURE 8. Differential Input
FIGURE 10. VCM range for Differential Input operation
2.2 Single-Ended Input Operation
For single-ended operation, the non-inverting input (+IN) of
the ADC141S626 can be driven with a signal that has a maximum to minimum value range that is equal to or less than
twice the reference voltage. The inverting input (−IN) should
be biased at a stable voltage that is halfway between these
maximum and minimum values. In order to utilize the entire
dynamic range of the ADC141S626, the reference voltage is
limited to VA / 2. This allows the non-inverting input a maximum swing range of ground to VA. Figure 9 shows the
ADC141S626 being driven by a full-scale single-ended
source.
30041362
FIGURE 11. VCM range for single-ended operation
TABLE 1. Allowable VCM Range
Input Signal
Differential
30041381
Single-Ended
FIGURE 9. Single-Ended Input
Maximum VCM
VREF / 2
VA − VREF / 2
VREF
VA − VREF
3.0 SERIAL DIGITAL INTERFACE
The ADC141S626 communicates via a synchronous 3-wire
serial interface as shown in the Timing Diagram section. CS,
chip select, initiates conversions and frames the serial data
transfers. SCLK (serial clock) controls both the conversion
process and the timing of serial data. DOUT is the serial data
output pin, where a conversion result is sent as a serial data
stream, MSB first.
A serial frame is initiated on the falling edge of CS and ends
on the rising edge of CS. The ADC141S626's D OUT pin is in
Since the design of the ADC141S626 is optimized for a differential input, the performance degrades slightly when driven
with a single-ended input. Linearity characteristics such as
INL and DNL typically degrade by 0.1 LSB and dynamic characteristics such as SINAD typically degrade by 2 dB. Note that
single-ended operation should only be used if the performance degradation (compared with differential operation) is
acceptable.
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Minimum VCM
14
3.3 Data Output
The data output format of the ADC141S626 is two’s complement, as shown in Table 2. This table indicates the ideal
output code for a given input voltage and does not include the
effects of offset, gain error, linearity errors, or noise. Each
data output bit is output on the falling edges of SCLK. SCLK
falling edges one and two clock out leading zeros while falling
edges three through sixteen clock out the conversion result,
MSB first.
TABLE 2. Ideal Output Code vs. Input Voltage
Analog Input
(+IN) − (−IN)
2's
Complement
Binary Code
2's
2's
Comp.
Comp.
Hex Code Dec Code
VREF − 1 LSB
01 1111 1111
1111
1FFF
8191
+ 1 LSB
00 0000 0000
0001
0001
1
0V
00 0000 0000
0000
0000
0
0V − 1 LSB
11 1111 1111
1111
3FFF
−1
−VREF + 1 LSB
10 0000 0000
0000
2000
−8192
While most receiving systems will capture the digital output
bits on the rising edges of SCLK, the falling edges of SCLK
may be used to capture the conversion result if the minimum
hold time (tDH) for DOUT is acceptable. See Figure 4 for
DOUT hold and access times.
DOUT is enabled on the falling edge of CS and disabled on the
rising edge of CS. If CS is raised prior to the 16th falling edge
of SCLK, the current conversion is aborted and DOUT will go
into its high impedance state. A new conversion will begin
when CS is taken LOW.
3.1 CS Input
The CS (chip select bar) input is active low and is TTL and
CMOS compatible. The ADC141S626 enters conversion
mode when CS is asserted and the SCLK pin is in a logic low
state. The ADC141S626 is always in acquisition mode and
thus consuming the minimum amount of power when CS is
high. Since CS must be asserted to begin a conversion, the
sample rate of the ADC141S626 is equal to the assertion rate
of CS.
Proper operation requires that the fall of CS not occur simultaneously with a rising edge of SCLK. If the fall of CS occurs
during the rising edge of SCLK, the data might be clocked out
one bit early. Whether or not the data is clocked out early
depends upon how close the CS transition is to the SCLK
transition, the device temperature, and characteristics of the
individual device. To ensure that the MSB is always clocked
out at a given time (the 3rd falling edge of SCLK), it is essential
that the fall of CS always meet the timing requirement specified in the Timing Specification table.
Applications Information
OPERATING CONDITIONS
We recommend that the following conditions be observed for
operation of the ADC141S626:
−40°C ≤ TA ≤ +85°C
+2.7V ≤ VA ≤ +5.5V
+2.7V ≤ VIO ≤ +5.5V
1V ≤ VREF ≤ VA
0.9 MHz ≤ fSCLK ≤ 4.5 MHz
VCM: See Section 2.3
3.2 SCLK Input
The SCLK (serial clock) is used as the conversion clock and
to shift out the conversion result. SCLK is TTL and CMOS
compatible. Internal settling time requirements limit the maximum clock frequency while internal capacitor leakage limits
the minimum clock frequency. The ADC141S626 offers guaranteed performance with the clock rates indicated in the
electrical table.
The ADC141S626 enters acquisition mode on the 16th falling
edge of SCLK during a conversion frame. Assuming that the
LSB is clocked into a controller on the 16th rising edge of
SCLK, there is a minimum acquisition time period that must
be met before a new conversion frame can begin. Other than
the 16th rising edge of SCLK that was used to latch the LSB
into a controller, there is no requirement for the SCLK to transition during acquisition mode. Therefore, it is acceptable to
idle SCLK after the LSB has been latched into the controller.
4.0 POWER CONSUMPTION
The architecture, design, and fabrication process allow the
ADC141S626 to operate at conversion rates up to 250 kSPS
while consuming very little power. The ADC141S626 consumes the least amount of power while operating in acquisition mode. For applications where power consumption is
critical, the ADC141S626 should be operated in acquisition
mode as often as the application will tolerate. To further reduce power consumption, stop the SCLK while CS is high.
4.1 Short Cycling
Short cycling refers to the process of halting a conversion after the last needed bit is outputted. Short cycling can be used
to lower the power consumption in those applications that do
not need a full 14-bit resolution, or where an analog signal is
being monitored until some condition occurs. In some circum15
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ADC141S626
a high impedance state when CS is high and is active when
CS is low; thus CS acts as an output enable. A timing diagram
for a single conversion is shown in Figure 1.
The ADC141S626 samples the differential input upon the assertion of CS. Assertion is defined as bringing the CS pin to
a logic low state. For the first fifteen periods of the SCLK following the assertion of CS, the ADC141S626 is converting
the analog input voltage. On the sixteenth falling edge of
SCLK, the ADC141S626 enters acquisition/track mode. For
the next three periods of SCLK, the ADC141S626 is operating
in acquisition mode where the ADC input is tracking the analog input signal applied across +IN and -IN. During acquisition
mode, the ADC141S626 is consuming a minimal amount of
power.
The ADC141S626 can enter conversion mode under three
different conditions. The first condition involves CS going low
(asserted) with SCLK high. In this case, the ADC141S626
enters conversion mode on the first falling edge of SCLK after
CS is asserted. In the second condition, CS goes low with
SCLK low. Under this condition, the ADC141S626 automatically enters conversion mode and the falling edge of CS is
seen as the first falling edge of SCLK. In the third condition,
CS and SCLK go low simultaneously and the ADC141S626
enters conversion mode. While there is no timing restriction
with respect to the falling edges of CS and SCLK, see Figure
5 for minimum and maximum setup time requirements for the
falling edge of CS with respect to the rising edge of SCLK.
ADC141S626
stances, the conversion could be terminated after the first few
bits. This will lower power consumption in the converter since
the ADC141S626 spends more time in acquisition mode and
less time in conversion mode.
Short cycling is accomplished by pulling CS high after the last
required bit is received from the ADC141S626 output. This is
possible because the ADC141S626 places the latest converted data bit on DOUT as it is generated. If only 10-bits of the
conversion result are needed, for example, the conversion
can be terminated by pulling CS high after the 10th bit has
been clocked out.
dynamic performance when the reference voltage pin is also
set to 5V; while operating the digital supply at 3V reduces the
power consumption of the digital logic. Operating the digital
interface at 3V also has the added benefit of decreasing the
noise created by charging and discharging the capacitance of
the digital interface pins.
5.2 Voltage Reference
The reference source must have a low output impedance and
needs to be bypassed with a minimum capacitor value of 0.1
µF. A larger capacitor value of 1 µF to 10 µF placed in parallel
with the 0.1 µF is preferred. While the ADC141S626 draws
very little current from the reference on average, there are
higher instantaneous current spikes at the reference.
The reference input of the ADC141S626, like all A/D converters, does not reject noise or voltage variations. Keep this in
mind if the reference voltage is derived from the power supply.
Any noise and/or ripple from the supply that is not rejected by
the external reference circuitry will appear in the digital results. The use of an active reference source is recommended.
The LM4040 and LM4050 shunt reference families and the
LM4132 and LM4140 series reference families are excellent
choices for a reference source.
4.2 Burst Mode Operation
Normal operation of the ADC141S626 requires the SCLK frequency to be eighteen times the sample rate and the CS rate
to be the same as the sample rate. However, in order to minimize power consumption in applications requiring sample
rates below 250 kSPS, the ADC141S626 should be run with
an SCLK frequency of 4.5 MHz and a CS rate as slow as the
system requires. When this is accomplished, the
ADC141S626 is operating in burst mode. The ADC141S626
enters into acquisition mode at the end of each conversion,
minimizing power consumption. This causes the converter to
spend the longest possible time in acquisition mode. Since
power consumption scales directly with conversion rate, minimizing power consumption requires determining the lowest
conversion rate that will satisfy the requirements of the system.
5.3 PCB Layout
Capacitive coupling between the noisy digital circuitry and the
sensitive analog circuitry can lead to poor performance. The
solution is to keep the analog circuitry separated from the
digital circuitry and the clock line as short as possible. Digital
circuits create substantial supply and ground current transients. The logic noise generated could have significant impact upon system noise performance. To avoid performance
degradation of the ADC141S626 due to supply noise, avoid
using the same supply for the VA and VREF of the
ADC141S626 that is used for digital circuity on the board.
Generally, analog and digital lines should cross each other at
90° to avoid crosstalk. However, to maximize accuracy in high
resolution systems, avoid crossing analog and digital lines altogether. It is important to keep clock lines as short as possible and isolated from ALL other lines, including other digital
lines. In addition, the clock line should also be treated as a
transmission line and be properly terminated. The analog input should be isolated from noisy signal traces to avoid coupling of spurious signals into the input. Any external
component (e.g., a filter capacitor) connected between the
converter's input pins and ground or to the reference input pin
and ground should be connected to a very clean point in the
ground plane.
A single, uniform ground plane and the use of split power
planes are recommended. The power planes should be located within the same board layer. All analog circuitry (input
amplifiers, filters, reference components, etc.) should be
placed over the analog power plane. All digital circuitry should
be placed over the digital power plane. Furthermore, the GND
pins on the ADC141S626 and all the components in the reference circuitry and input signal chain that are connected to
ground should be connected to the ground plane at a quiet
point. Avoid connecting these points too close to the ground
point of a microprocessor, microcontroller, digital signal processor, or other high power digital device.
5.0 PCB LAYOUT AND CIRCUIT CONSIDERATIONS
For best performance, care should be taken with the physical
layout of the printed circuit board. This is especially true with
a low reference voltage or when the conversion rate is high.
At high clock rates there is less time for settling, so it is important that any noise settles out before the conversion begins.
5.1 Analog and Digital Power Supplies
Any ADC architecture is sensitive to spikes on the power supply, reference, and ground pins. These spikes may originate
from switching power supplies, digital logic, high power devices, and other sources. Power to the ADC141S626 should
be clean and well bypassed. A 0.1 µF ceramic bypass capacitor and a 1 µF to 10 µF capacitor should be used to
bypass the ADC141S626 supply, with the 0.1 µF capacitor
placed as close to the ADC141S626 package as possible.
Since the ADC141S626 has both an analog and a digital input/output supply pin, the user has three options. The first
option is to tie the analog and digital supply pins together and
power them with the same power supply. This is the most cost
effective way of powering the ADC141S626 but it is also the
least ideal. As stated previously, noise from the digital supply
pin can couple into the analog supply pin and adversely affect
performance. The other two options involve the user powering
the analog and digital supply pins with separate supply voltages. These supply voltages can have the same amplitude or
they can be different. They may be set independent of each
other to any value between 2.7V and 5.5V.
Best performance will typically be achieved with the analog
supply operating at 5V and the digital supply operating at 3V.
Operating the analog supply at 5V offers the best linearity and
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16
6.1 Data Acquisition
Figure 12 shows a typical connection diagram for the
ADC141S626 operating at a supply voltage of +5V. The reference pin, VREF, is connected to a 4.1V shunt reference, the
LM4040-4.1, to define the analog input range of the
30041363
FIGURE 12. Low cost, low power Data Acquisition System
for dynamically adjusting the gain of the bridge sensor relative
to actual maximum and minimum output conditions. Another
option for biasing the bridge sensor would be powering it from
the same +5V power supply voltage as the analog supply pin
on the ADC141S626. This option has the benefit of providing
the ideal common-mode input voltage for the ADC141S626
while keeping design complexity and cost to a minimum.
However, any fluctuation in the +5V supply will still be visible
in the converted result. The LM4132-4.1, a 4.1V series reference, is used as the reference voltage in the application. The
ADC141S626, DAC081S101, and the LM4132-4.1 are all
powered from the same +5V voltage source.
6.2 Bridge Sensor Application
Figure 13 shows an example of interfacing a bridge sensor to
the ADC141S626. The application assumes that the bridge
sensor requires buffering and amplification to fully utilize the
dynamic range of the ADC and thus optimize the performance
of the entire signal path. The amplification stage consists of
the LMP7702, a dual precision amplifier, and some gain setting passive components. The amplification stage offers the
benefit of high input impedance and high amplification capability. On the other hand, it offers no common-mode rejection
of common-mode noise or DC-voltage coming from the bridge
sensor.
The DAC081S101, a digital-to-analog converter (DAC), is
used to bias the bridge sensor. The DAC provides a means
30041366
FIGURE 13. Interfacing the ADC141S626 to a Bridge Sensor
17
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ADC141S626
ADC141S626 independent of supply variation on the +5V
supply line. The VREF pin should be de-coupled to the ground
plane by a 0.1 µF ceramic capacitor and a tantalum capacitor
of 10 µF. It is important that the 0.1 µF capacitor be placed as
close as possible to the VREF pin while the placement of the
tantalum capacitor is less critical. It is also recommended that
the analog and digital supply pins of the ADC141S626 be decoupled to ground by a 0.1 µF ceramic capacitor in parallel
with a 10 µF tantalum capacitor.
6.0 APPLICATION CIRCUITS
The following figures are examples of the ADC141S626 in
typical application circuits. These circuits are basic and will
generally require modification for specific circumstances.
ADC141S626
The output of the transducer has an output range of ±2V
around the common-mode voltage of 2.5V. As a result, a series reference voltage of 2.0V is connected to the
ADC141S626. This will allow all of the codes of the
ADC141S626 to be available for the application. This configuration of the ADC141S626 is referred to as a single-ended
application of a differential ADC. All of the elements in the
application are conveniently powered by the same +5V power
supply, keeping circuit complexity and cost to a minimum.
6.3 Current Sensing Application
Figure 14 shows an example of interfacing a current transducer to the ADC141S626. The current transducer converts
an input current into a voltage that is converted by the ADC.
Since the output voltage of the current transducer is singleended and centered around a common-mode voltage of 2.5V,
the ADC141S626 is configured with the output of the transducer driving the non-inverting input and the common-mode
output voltage of the transducer driving the inverting input.
30041338
FIGURE 14. Interfacing the ADC141S626 to a Current Transducer
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18
ADC141S626
Physical Dimensions inches (millimeters) unless otherwise noted
10-Lead MSOP
Order Number ADC141S626CIMM
NS Package Number MUB10A
19
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ADC141S626 14-Bit, 50 kSPS to 250 kSPS, Differential Input, Micro Power A/D Converter
Notes
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