NSC ADC081C021CIMKX

ADC081C021/ADC081C027
I2C-Compatible, 8-Bit Analog-to-Digital Converter (ADC)
with Alert Function
General Description
Features
The ADC081C021 is a low-power, monolithic, 8-bit,
analog-to-digital converter(ADC) that operates from a +2.7 to
5.5V supply. The converter is based on a successive approximation register architecture with an internal track-and-hold
circuit that can handle input frequencies up to 11MHz. The
ADC081C021 operates from a single supply which also
serves as the reference. The device features an
I2C-compatible serial interface that operates in all three speed
modes, including high speed mode (3.4MHz).
The ADC's Alert feature provides an interrupt that is activated
when the analog input violates a programmable upper or lower limit value. The device features an automatic conversion
mode, which frees up the controller and I2C interface. In this
mode, the ADC continuously monitors the analog input for an
"out-of-range" condition and provides an interrupt if the measured voltage goes out-of-range.
The ADC081C021 comes in a small TSOT-6 package with an
alert output. The ADC081C027 comes in a small TSOT-6
package with an address selection input. The ADC081C027
provides three pin-selectable addresses. Pin-compatible alternatives are available with additional address options.
Normal power consumption using a +3V or +5V supply is
0.26mW or 0.78mW, respectively. The automatic powerdown feature reduces the power consumption to less than
1µW while not converting. Operation over the industrial temperature range of −40°C to +105°C is guaranteed. Their low
power consumption and small packages make this family of
ADCs an excellent choice for use in battery operated equipment.
The ADC081C021 and ADC081C027 are part of a family of
pin-compatible ADCs that also provide 12 and 10 bit resolution. For 12-bit ADCs see the ADC121C021 and
ADC121C027. For 10-bit ADCs see the ADC101C021 and
ADC101C027.
■ I2C-Compatible 2-wire Interface which supports standard
■
■
■
■
■
■
(100kHz), fast (400kHz), and high speed (3.4MHz) modes
Extended power supply range (+2.7V to +5.5V)
Up to four pin-selectable chip addresses
Out-of-range Alert Function
Automatic Power-down mode while not converting
Very small 6-pin TSOT packages
±8kV HBM ESD protection (SDA, SCL)
Key Specifications
■
■
■
■
■
Resolution
8 bits; no missing codes
Conversion Time
1µs (typ)
INL & DNL
±0.2 LSB (max)
Throughput Rate
188.9kSPS (max)
Power Consumption (at 22kSPS)
0.26 mW (typ)
— 3V Supply
0.78 mW (typ)
— 5V Supply
Applications
■
■
■
■
■
System Monitoring
Peak Detection
Portable Instruments
Medical Instruments
Test Equipment
Pin-Compatible Alternatives
All devices are fully pin and function compatible.
Resolution
ALERT Output
ADDR Input
12-bit
ADC121C021
ADC121C027
10-bit
ADC101C021
ADC101C027
8-bit
ADC081C021
ADC081C027
Connection Diagrams
30052101
30052102
I2C® is a registered trademark of Phillips Corporation.
© 2008 National Semiconductor Corporation
300521
www.national.com
ADC081C021/ADC081C027 I2C-Compatible, 8-Bit Analog-to-Digital Converter (ADC) with Alert
May 5, 2008
ADC081C021/ADC081C027
Ordering Information
Order Code
ADC081C021CIMK
ADC081C021CIMKX
Option
Package
Top Mark
Alert pin
TSOT-6
X34C
Alert pin
TSOT-6 Tape-and-Reel
X34C
ADC081C027CIMK
Address pin
TSOT-6
X35C
ADC081C027CIMKX
Address pin
TSOT-6 Tape-and-Reel
X35C
Shipped with the ADC081C021.
Also compatible with the
ADC081C027 option.
Please order samples.
Evaluation Board
ADC081C021EB
Block Diagram
30052103
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2
Symbol
VA
Type
Equivalent Circuit
Description
Power and unbufferred reference voltage. VA must be free
of noise and decoupled to GND.
Supply
GND
Ground
VIN
Analog Input
ALERT
Digital Output
Alert output. Can be configured as active high or active
low. This is an open drain data line that must be pulled to
the supply (VA) with an external pull-up resistor.
Digital Input
Serial Clock Input. SCL is used together with SDA to
control the transfer of data in and out of the device. This is
an open drain data line that must be pulled to the supply
(VA) with an external pull-up resistor. This pin's extended
ESD tolerance( 8kV HBM) allows extension of the I2C bus
across multiple boards without extra ESD protection.
SDA
Digital
Input/Output
Serial Data bi-directional connection. Data is clocked into
or out of the internal 16-bit register with SCL. This is an
open drain data line that must be pulled to the supply
(VA) with an external pull-up resistor. This pin's extended
ESD tolerance( 8kV HBM) allows extension of the I2C bus
across multiple boards without extra ESD protection.
ADDR
Digital Input,
three levels
Tri-level Address Selection Input. Sets Bits A0 & A1 of the
7-bit slave address. (see ///)
SCL
Ground for all on-chip circuitry.
Analog input. This signal can range from GND to VA.
See Figure 4
Package Pinouts
VA
GND
VIN
ALERT
SCL
SDA
ADDR
ADC081C021
TSOT-6
1
2
3
4
5
6
N/A
ADC081C027
TSOT-6
1
2
3
N/A
5
6
4
3
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ADC081C021/ADC081C027
Pin Descriptions
ADC081C021/ADC081C027
Absolute Maximum Ratings
Operating Ratings (Notes 1, 2)
(Notes 1, 2)
Operating Temperature Range
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Supply Voltage, VA
Analog Input Voltage, VIN
Digital Input Voltage (Note 7)
Sample Rate
Supply Voltage, VA
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 Dissipation at TA = 25°C
ESD Susceptibility (Note 5)
VA, GND, VIN, ALERT,
ADDR pins:
Human Body Model
Machine Model
Charged Device Model (CDM)
SDA, SCL pins:
Human Body Model
Machine Model
Junction Temperature
Storage Temperature
-0.3V to +6.5V
−40°C ≤ TA ≤ +105°C
+2.7V to 5.5V
0V to VA
0V to 5.5V
up to 188.9 kSPS
Package Thermal Resistances
−0.3V to (VA +0.3V)
−0.3V to 6.5V
±15 mA
±20 mA
See (Note 4)
Package
θJA
6-Lead TSOT
250°C/W
Soldering
process
must
comply
with
National
Semiconductor's Reflow Temperature Profile specifications.
Refer to www.national.com/packaging. (Note 6)
2500V
250V
1250V
8000V
400V
+150°C
−65°C to +150°C
Electrical Characteristics
The following specifications apply for VA = +2.7V to +5.5V, GND = 0V, fSCL up to 3.4MHz, fIN = 1kHz for fSCL up to 400kHz,
fIN = 10kHz for fSCL = 3.4MHz unless otherwise noted. Boldface limits apply for TA = TMIN to TMAX: all other limits TA = 25°C
unless otherwise noted.
Symbol
Parameter
Conditions
Typical
(Note 9)
Limits
(Note 9)
Units (Limits)
8
Bits
STATIC CONVERTER CHARACTERISTICS
Resolution with No Missing Codes
INL
DNL
Integral Non-Linearity (End Point
Method)
Differential Non-Linearity
VOFF
Offset Error
GE
Gain Error
VA = +2.7V to +3.6V
±0.04
±0.2
LSB (max)
VA = +2.7V to +5.5V. fSCL up to 400kHz
(Note 13)
±0.1
±0.25
LSB (max)
VA = +2.7V to +3.6V
+0.04
±0.2
LSB (max)
VA = +2.7V to +5.5V. fSCL up to 400kHz
(Note 13)
±0.08
±0.25
LSB (max)
VA = +2.7V to +3.6V
+0.26
±0.5
LSB (max)
VA = +2.7V to +5.5V. fSCL up to 400kHz
(Note 13)
+0.25
±0.5
LSB (max)
-0.01
±0.4
LSB (max)
Bits (min)
DYNAMIC CONVERTER CHARACTERISTICS
ENOB
Effective Number of Bits
7.98
7.8
SNR
Signal-to-Noise Ratio
49.8
49
dB (min)
THD
Total Harmonic Distortion
−70.6
−64
dB (max)
SINAD
Signal-to-Noise Plus Distortion Ratio
49.8
49
dB (min)
SFDR
Spurious-Free Dynamic Range
-68.8
65
dB (min)
IMD
FPBW
Intermodulation Distortion, Second
Order Terms (IMD2)
VA = +3.0V,
fa = 1.035 kHz, fb = 1.135 kHz
−75.5
dB
Intermodulation Distortion, Third
Order Terms (IMD3)
VA = +3.0V,
fa = 1.035 kHz, fb = 1.135 kHz
−71.8
dB
VA = +3.0V
8
MHz
VA = +5.0V
11
MHz
Full Power Bandwidth (−3dB)
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4
Parameter
Conditions
Typical
(Note 9)
Limits
(Note 9)
Units (Limits)
±1
µA (max)
ANALOG INPUT CHARACTERISTICS
VIN
Input Range
IDCL
DC Leakage Current (Note 10)
CINA
Input Capacitance
0 to VA
V
Track Mode
30
pF
Hold Mode
3
pF
SERIAL INTERFACE INPUT CHARACTERISTICS (SCL, SDA)
VIH
Input High Voltage
0.7 x VA
V (min)
VIL
Input Low Voltage
0.3 x VA
V (max)
IIN
Input Current (Note 10)
±1
µA (max)
CIN
Input Pin Capacitance
VHYST
3
Input Hysteresis
pF
0.1 x VA
V (min)
V (min)
ADDRESS SELECTION INPUT CHARACTERISTICS (ADDR)
VIH
Input High Voltage
VA - 0.5V
VIL
Input Low Voltage
0.5
V (max)
IIN
Input Current (Note 10)
±1
µA (max)
ISINK = 3 mA
0.4
V (max)
ISINK = 6 mA
0.6
V (max)
±1
µA (max)
LOGIC OUTPUT CHARACTERISTICS, OPEN-DRAIN (SDA, ALERT)
VOL
Output Low Voltage
IOZ
High-Impedence Output
Leakage Current (Note 10)
Output Coding
Straight (Natural) Binary
5
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ADC081C021/ADC081C027
Symbol
ADC081C021/ADC081C027
Symbol
Parameter
Conditions
Typical
(Note 9)
Limits
(Note 9)
Units (Limits)
POWER REQUIREMENTS
VA
Supply Voltage Minimum
2.7
V (min)
Supply Voltage Maximum
5.5
V (max)
Continuous Operation Mode -- 2-wire interface active.
fSCL=400kHz
IN
Supply Current
fSCL=3.4MHz
fSCL=400kHz
PN
Power Consumption
fSCL=3.4MHz
VA = 2.7V to 3.6V
0.08
0.14
mA (max)
VA = 4.5V to 5.5V
0.16
0.30
mA (max)
VA = 2.7V to 3.6V
0.37
0.55
mA (max)
VA = 4.5V to 5.5V
0.74
0.99
mA (max)
VA = 3.0V
0.26
mW
VA = 5.0V
0.78
mW
VA = 3.0V
1.22
mW
VA = 5.0V
3.67
mW
Automatic Conversion Mode -- 2-wire interface stopped and quiet (SCL = SDA = VA). fSAMPLE = TCONVERT * 32
IA
PA
Supply Current
Power Consumption
VA = 2.7V to 3.6V
0.41
0.59
mA (max)
VA = 4.5V to 5.5V
0.78
1.2
mA (max)
VA = 3.0V
1.35
mW
VA = 5.0V
3.91
mW
Power Down Mode (PD1) -- 2-wire interface stopped and quiet. (SCL = SDA = VA).(Note 10)
IPD1
Supply Current
0.1
0.2
µA (max)
PPD1
Power Consumption
0.5
0.9
µW (max)
45
µA (max)
Power Down Mode (PD2) -- 2-wire interface active. Master communicating with a different device on the bus.
fSCL=400kHz
IPD2
Supply Current
fSCL=3.4MHz
fSCL=400kHz
PPD2
Power Consumption
fSCL=3.4MHz
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6
VA = 2.7V to 3.6V
13
VA = 4.5V to 5.5V
27
80
µA (max)
VA = 2.7V to 3.6V
89
150
µA (max)
VA = 4.5V to 5.5V
168
250
µA (max)
VA = 3.0V
0.04
mW
VA = 5.0V
0.14
mW
VA = 3.0V
0.29
mW
VA = 5.0V
0.84
mW
The following specifications apply for VA = +2.7V to +5.5V. Boldface limits apply for TMIN ≤ TA ≤ TMAX and all other limits are at
TA = 25°C, unless otherwise specified.
Symbol
Parameter
Conditions (Note 12)
Typical
(Note 9)
Limits
(Notes 9,
12)
Units
(Limits)
CONVERSION RATE
Conversion Time
fCONV
Conversion Rate
1
µs
fSCL = 100kHz
5.56
kSPS
fSCL = 400kHz
22.2
kSPS
fSCL = 1.7MHz
94.4
kSPS
fSCL = 3.4MHz
188.9
kSPS
DIGITAL TIMING SPECS (SCL, SDA)
Serial Clock Frequency
Standard Mode
Fast Mode
High Speed Mode, Cb = 100pF
High Speed Mode, Cb = 400pF
100
400
3.4
1.7
kHz (max)
kHz (max)
MHz (max)
MHz (max)
SCL Low Time
Standard Mode
Fast Mode
High Speed Mode, Cb = 100pF
High Speed Mode, Cb = 400pF
4.7
1.3
160
320
us (min)
us (min)
ns (min)
ns (min)
tHIGH
SCL High Time
Standard Mode
Fast Mode
High Speed Mode, Cb = 100pF
High Speed Mode, Cb = 400pF
4.0
0.6
60
120
us (min)
us (min)
ns (min)
ns (min)
tSU;DAT
Data Setup Time
Standard Mode
Fast Mode
High Speed Mode
250
100
10
ns (min)
ns (min)
ns (min)
Standard Mode (Note 14)
0
3.45
us (min)
us (max)
Fast Mode (Note 14)
0
0.9
us (min)
us (max)
High Speed Mode, Cb = 100pF
0
70
ns (min)
ns (max)
High Speed Mode, Cb = 400pF
0
150
ns (min)
ns (max)
fSCL
tLOW
tHD;DAT
Data Hold Time
tSU;STA
Setup time for a start or a repeated
start condition
Standard Mode
Fast Mode
High Speed Mode
4.7
0.6
160
us (min)
us (min)
ns (min)
tHD;STA
Standard Mode
Hold time for a start or a repeated start
Fast Mode
condition
High Speed Mode
4.0
0.6
160
us (min)
us (min)
ns (min)
tBUF
Bus free time between a stop and start Standard Mode
condition
Fast Mode
4.7
1.3
us (min)
us (min)
tSU;STO
Setup time for a stop condition
4.0
0.6
160
us (min)
us (min)
ns (min)
Standard Mode
Fast Mode
High Speed Mode
7
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ADC081C021/ADC081C027
A.C. and Timing Characteristics
ADC081C021/ADC081C027
Symbol
Parameter
Limits
(Notes 9,
12)
Units
(Limits)
1000
ns (max)
20+0.1Cb
300
ns (min)
ns (max)
High Speed Mode, Cb = 100pF
10
80
ns (min)
ns (max)
High Speed Mode, Cb = 400pF
20
160
ns (min)
ns (max)
Standard Mode
250
ns (max)
20+0.1Cb
250
ns (min)
ns (max)
High Speed Mode, Cb = 100pF
10
80
ns (min)
ns (max)
High Speed Mode, Cb = 400pF
20
160
ns (min)
ns (max)
Standard Mode
1000
ns (max)
20+0.1Cb
300
ns (min)
ns (max)
High Speed Mode, Cb = 100pF
10
40
ns (min)
ns (max)
High Speed Mode, Cb = 400pF
20
80
ns (min)
ns (max)
1000
ns (max)
20+0.1Cb
300
ns (min)
ns (max)
High Speed Mode, Cb = 100pF
10
80
ns (min)
ns (max)
High Speed Mode, Cb = 400pF
20
160
ns (min)
ns (max)
Standard Mode
300
ns (max)
20+0.1Cb
300
ns (min)
ns (max)
High Speed Mode, Cb = 100pF
10
40
ns (min)
ns (max)
High Speed Mode, Cb = 400pF
20
80
ns (min)
ns (max)
400
pF (max)
50
10
ns (max)
ns (max)
Conditions (Note 12)
Standard Mode
Fast Mode
trDA
Rise time of SDA signal
Fast Mode
tfDA
Fall time of SDA signal
Fast Mode
trCL
Rise time of SCL signal
Standard Mode
trCL1
Rise time of SCL signal after a
repeated start condition and after an
acknowledge bit.
Fast Mode
Fast Mode
tfCL
Fall time of a SCL signal
Cb
Capacitive load for each bus line (SCL
and SDA)
tSP
Pulse Width of spike suppressed
(Note 11)
Fast Mode
High Speed Mode
Typical
(Note 9)
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 5.5V or is less than GND, the current at that pin should be limited per the Absolute Maximum Ratings. The
mximum package input current rating limits the number of pins that can safely exceed the power supplies.
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 will be reached only when the device is operated in a severe fault condition (e.g., when input or output pins are driven beyond
the operating ratings, or the power supply polarity is reversed).
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. Charged
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.
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8
30052104
Note 8: To guarantee accuracy, it is required that VA be well bypassed and free of noise.
Note 9: Typical figures are at TJ = 25°C, and represent most likely parametric norms. Test limits are guaranteed to National's AOQL (Average Outgoing Quality
Level).
Note 10: This parameter is guaranteed by design and/or characterization and is not tested in production.
Note 11: Spike suppression filtering on SCL and SDA will supress spikes that are less than 50ns for standard and fast modes, and less than 10ns for hs-mode.
Note 12: Cb refers to the capacitance of one bus line. Cb is expressed in pF units.
Note 13: The ADC will meet Minimum/Maximum specifications for fSCL up to 3.4MHz and VA = 2.7V to 3.6V when operating in the Quiet Interface Mode (Section
1.11).
Note 14: The ADC081C021 will provide a minimum data hold time of 300ns to comply with the I2C Specification.
Timing Diagrams
30052160
FIGURE 1. Serial Timing Diagram
9
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ADC081C021/ADC081C027
Note 7: The inputs are protected as shown below. Input voltage magnitudes up to 5.5V, regardless of VA, will not cause errors in the conversion result. For
example, if VA is 3V, the digital input pins can be driven with a 5V logic device.
ADC081C021/ADC081C027
Specification Definitions
ACQUISITION TIME is the time required for the ADC to acquire the input voltage. During this time, the hold capacitor is
charged by the input voltage.
APERTURE DELAY is the time between the start of a conversion and the time when the input signal is internally acquired or held for conversion.
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.
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 of the last code transition
(111...110) to (111...111) from the ideal (VREF - 1.5 LSB), after
adjusting for offset error.
INTEGRAL NON-LINEARITY (INL) is a measure of the deviation of each individual code from a line drawn from negative
full scale (½ LSB below the first code transition) through positive full scale (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.
INTERMODULATION DISTORTION (IMD) is the creation of
additional spectral components as a result of two sinusoidal
frequencies being applied to an individual ADC input at the
same time. It is defined as the ratio of the power in either the
second or the third order intermodulation products to the sum
of the power in both of the original frequencies. Second order
products are fa ± fb, where fa and fb are the two sine wave
input frequencies. Third order products are (2fa ± fb ) and
(fa ± 2fb). IMD is usually expressed in dB.
MISSING CODES are those output codes that will never appear at the ADC output. The ADC081C021 is guaranteed not
to have any missing codes.
OFFSET ERROR is the deviation of the first code transition
(000...000) to (000...001) from the ideal (i.e. GND + 0.5 LSB).
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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 half the clock 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,
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, expressed in dBc, of the rms total of the first n harmonic components at the output to the rms level of the input signal
frequency as seen at the output. THD is calculated as
where Af1 is the RMS power of the input frequency at the output and Af2 through Afn are the RMS power in the first n
harmonic frequencies.
THROUGHPUT TIME is the minimum time required between
the start of two successive conversions. It is the acquisition
time plus the conversion time.
LEAST SIGNIFICANT BIT (LSB) is the bit that has the smallest value or weight of all bits in a word. This value is
LSB = VA / 2n
where VA is the supply voltage for this product, and "n" is the
resolution in bits, which is 8 for the ADC081C021.
MOST SIGNIFICANT BIT (MSB) is the bit that has the largest
value or weight of all bits in a word. Its value is 1/2 of VA.
10
fSCL = 400kHz, fSAMPLE = 22kSPS, fIN = 1kHz, VA = 5.0V, TA =
+25°C, unless otherwise stated.
INL vs. Code - VA=3V
DNL vs. Code - VA=3V
30052122
30052123
INL vs. Code - VA=5V
DNL vs. Code - VA=5V
30052124
30052125
INL vs. Supply
DNL vs. Supply
30052126
30052127
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ADC081C021/ADC081C027
Typical Performance Characteristics
ADC081C021/ADC081C027
ENOB vs. Supply
SINAD vs. Supply
30052128
30052129
FFT Plot - VA=3V
FFT Plot - VA=3V
30052130
30052131
Offset Error vs. Temperature
Gain Error vs. Temperature
30052132
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30052133
12
Automatic Conversion Supply Current vs. VA
30052134
30052135
Power Down (PD1) Supply Current vs. VA
30052136
13
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ADC081C021/ADC081C027
Continuous Operation Supply Current vs. VA
ADC081C021/ADC081C027
1.2 ANALOG INPUT
An equivalent circuit for the input of the ADC081C021 is
shown in Figure 4. Diodes D1 and D2 provide ESD protection
for the analog input. The operating range for the analog input
is 0 V to VA. Going beyond this range will cause the ESD
diodes to conduct and result in erratic operation.
The capacitor C1 in Figure 4 has a typical value of 3 pF and
is mainly the package pin capacitance. Resistor R1 is the on
resistance (RON) of the multiplexer and track / hold switch and
is typically 500Ω. Capacitor C2 is the ADC081C021 sampling
capacitor, and is typically 30 pF. The ADC081C021 will deliver best performance when driven by a low-impedance
source (less than 100Ω). This is especially important when
using the ADC081C021 to sample dynamic signals. The dynamic performance of the ADC will be affected significantly
by large source impedances. An input buffer amplifier may be
necessary to limit source impedance. A high-accuracy opamp is recommended to maximize circuit performance. Also
important when sampling dynamic signals is an anti-aliasing
band-pass or low-pass filter which reduces harmonics and
noise at the input.
1.0 Functional Description
The ADC081C021 is a successive-approximation analog-todigital converter designed around a charge-redistribution digital-to-analog converter. Unless otherwise stated, references
to the ADC081C021 in this section will apply to both the
ADC081C021 and the ADC081C027.
1.1 CONVERTER OPERATION
Simplified schematics of the ADC081C021 in both track and
hold operation are shown in Figure 2 and Figure 3 respectively. In Figure 2, the ADC081C021 is in track mode; switch
SW1 connects the sampling capacitor to the analog input
channel, and SW2 equalizes the comparator inputs. The ADC
is in this state for approximately 0.4µs at the beginning of every conversion cycle. Conversions occur when the conversion result register is read by the I2C controller and when the
ADC is in automatic conversion mode. (see Section 1.9)
Figure 3 shows the ADC081C021 in hold mode: switch SW1
connects the sampling capacitor to ground and switch SW2
unbalances the comparator. The control logic then instructs
the charge-redistribution DAC to add or subtract fixed
amounts of charge to or from the sampling capacitor until the
comparator is balanced. When the comparator is balanced,
the digital word supplied to the DAC is also the digital representation of the analog input voltage. This digital word is
stored in the conversion result register and read via the 2-wire
interface.
30052167
FIGURE 4. Equivalent Input Circuit
30052165
FIGURE 2. ADC081C021 in Track Mode
30052166
FIGURE 3. ADC081C021 in Hold Mode
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30052168
1.5 POWER-ON RESET
The power-on reset (POR) state is the point at which the supply voltage rises above the power-on reset threshold, generating an internal reset. Each of the registers contains a
defined value upon POR and this data remains there until any
of the following occurs:
• The first conversion is completed, causing the Conversion
Result Register and various status registers to be updated
internally.
• The master writes a different data word to any of the
writeable registers.
• The ADC is powered down.
When resetting the device, it is crutial that the VA supply be
lowered to a maximum of 200mV before the supply is raised
again to power-up the device. Dropping the supply to within
200mV of GND during a reset will ensure the ADC performs
as specified.
FIGURE 5. Ideal Transfer Characteristic
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ADC081C021/ADC081C027
1.4 REFERENCE VOLTAGE
The ADC081C021 uses the supply (VA) as the reference.
With that said, VA must be treated as a reference. The analogto-digital conversion will only be as precise as the reference
(VA). Therefore, the reference (VA) should be free of noise. It
is also recommended that the reference be driven by a voltage source with low output impedance.
The Applications section provides recommended ways to
drive the reference (VA) appropriately. Refer to Section 2.1 for
details.
1.3 ADC TRANSFER FUNCTION
The output format of the ADC081C021 is straight binary.
Code transitions occur midway between successive integer
LSB values. The LSB width for the ADC081C021 is VA / 256.
The ideal transfer characteristic is shown in Figure 5. The
transition from an output code of 0000 0000 0000 to a code
of 0000 0000 0001 is at 1/2 LSB, or a voltage of VA / 512.
Other code transitions occur at intervals of 1 LSB.
ADC081C021/ADC081C027
1.6 INTERNAL REGISTERS
The ADC081C021 is equipped with 8 internal data registers
and one address pointer register. The registers provide additional ADC functions such as storing minimum and maximum
conversion results, setting alert threshold levels, and storing
data to configure the operation of the device. Figure 6 shows
all of the registers and their corresponding address pointer
values. All of the registers are read/write capable except the
conversion result register which is read-only.
1.6.1 Address Pointer Register
The address pointer register controls which of the data registers is accessed by the I2C interface. The first data byte of
every write operation is stored in the address pointer register.
This value selects the register that the following data bytes
will be written to or read from. Only the three LSBs of this
register are relevant. The other bits must always be written as
zeros. After a power-on reset, the pointer register defaults to
all zeros (conversion result register).
Default Value: 00h
30052169
FIGURE 6. Register Structure
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P7
P6
P5
P4
P3
0
0
0
0
0
P2
P1
P0
P2
P1
P0
REGISTER
0
0
0
Conversion Result (read only)
0
0
1
Alert Status (read/write)
0
1
0
Configuration (read/write)
0
1
1
Low Limit (read/write)
1
0
0
High Limit (read/write)
1
0
1
Hysteresis (read/write)
1
1
0
Lowest Conversion (read/write)
1
1
1
Highest Conversion (read/write)
Register Select
Pointer Address 00h (Read Only)
Default Value: 0000h
D15
D14
D13
Alert Flag
D12
D11
Reserved
D7
D6
D5
D10
D9
D8
Conversion Result[7:4]
D4
D3
D2
Conversion Result[3:0]
D1
D0
Reserved
Bits
Name
Description
15
Alert Flag
When the Alert Bit Enable is set in the Configuration Register, this bit will be high if either alert
flag is set in the Alert Status Register. Otherwise, this bit is a zero. This bit indicates that an alert
condition has occured. The I2C controller will typically read the Alert Status register and other
data registers to determine the source of the alert.
14:12
Reserved
Always reads zeros.
11:4
Conversion Result
The Analog-to-Digital conversion result. The Conversion result data is a 8-bit data word in straight
binary format. The MSB is D11.
3:0
Reserved
Always reads zeros.
1.6.3 Alert Status Register
Pointer Address 01h (Read/Write)
Default Value: 00h
D7
D6
D5
D4
D3
D2
Reserved
D1
D0
Over Range
Alert
Under Range
Alert
Bits
Name
Description
7:2
Reserved
Always reads zeros. Zeros must be written to these bits.
1
Over Range
Alert Flag
Bit is set to 1 when the measured voltage exceeds the VHIGH limit stored in the programmable
VHIGH limit register. Flag is reset to 0 when one of the following two conditions is met: (1) The
controller writes a one to this bit. (2) The measured voltage decreases below the programmed
VHIGH limit minus the programmed VHYST value (See Figure 9) . The alert will only self-clear if the
Alert Hold bit is cleared in the Configuration register. If the Alert Hold bit is set, the only way to
clear an over range alert is to write a one to this bit.
0
Under Range
Alert Flag
Bit is set to 1 when the measured voltage falls below the VLOW limit stored in the programmable
VLOW limit register. Flag is reset to 0 when one of the following two conditions is met: (1) The
controller writes a one to this bit. (2) The measured voltage increases above the programmed
VLOW limit plus the programmed VHYST value. The alert will only self-clear if the Alert Hold bit is
cleared in the Configuration register. If the Alert Hold bit is set, the only way to clear an under
range alert is to write a one to this bit.
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ADC081C021/ADC081C027
1.6.2 Conversion Result Register
ADC081C021/ADC081C027
1.6.4 Configuration Register
Pointer Address 02h (Read/Write)
Default Value: 00h
D7 D6 D5
D4
Cycle Time [2:0]
Alert
Hold
D3
D2
D1
D0
Alert
Flag
Enable
Alert
Pin
Enable
0
Polarity
D7
Cycle Time[2:0]
D6
D5
Conversion
Interval
Typical
fconvert
(kSPS)
0
0
0
Mode Disabled
0
0
0
1
Tconvert x 32
27
0
1
0
Tconvert x 64
13.5
0
1
1
Tconvert x 128
6.7
1
0
0
Tconvert x 256
3.4
1
0
1
Tconvert x 512
1.7
1
1
0
Tconvert x 1024
0.9
1
1
1
Tconvert x 2048
0.4
Bits
Name
Description
7:5
Cycle Time
Configures Automatic Conversion mode. When these bits are set to zeros, the automatic
conversion mode is disabled. This is the case at power-up.
When these bits are set to a non-zero value, the ADC will begin operating in automatic conversion
mode. (See Section 1.9). The Cycle Time table shows how different values provide various
conversion intervals.
4
Alert Hold
0: Alerts will self-clear when the measured voltage moves within the limits by more than the
hysteresis register value.
1: Alerts will not self-clear and are only cleared when a one is written to the alert high flag or the
alert low flag in the Alert Status register.
3
Alert Flag Enable
0: Disables alert status bit [D15] in the Conversion Result register.
1: Enables alert status bit [D15] in the Conversion Result register.
2
Alert Pin Enable
0: Disables the ALERT output pin. The ALERT output will TRI-STATE when the pin is disabled.
1: Enables the ALERT output pin.
*This bit does not apply to the ADC081C027.
1
Reserved
Always reads zeros. Zeros must be written to these bits.
0
Polarity
This bit configures the active level polarity of the ALERT output pin.
0: Sets the ALERT pin to active low.
1: Sets the ALERT pin to active high.
*This bit does not apply to the ADC081C027.
1.6.5 VLOW -- Alert Limit Register - Under Range
Pointer Address 03h (Read/Write)
Default Value: 0000h
D15
D14
D13
D12
D11
Reserved
D7
D6
D10
D9
D8
VLOW Limit[7:4]
D5
D4
D3
D2
VLOW Limit[3:0]
D1
D0
Reserved
Bits
Name
Description
15:12
Reserved
Always reads zeros. Zeros must be written to these bits.
11:4
VLOW Limit
Sets the lower limit threshold used to determine the alert condition. If the conversion moves lower
than this limit, a VLOW alert is generated.
3:0
Reserved
Always reads zeros. Zeros must be written to these bits.
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Pointer Address 04h (Read/Write)
Default Value: 0FFFh
D15
D14
D13
D12
D11
Reserved
D7
D6
D10
D9
D8
VHIGH Limit[7:4]
D5
D4
D3
D2
VHIGH Limit[3:0]
D1
D0
Reserved
Bits
Name
Description
15:12
Reserved
Always reads zeros. Zeros must be written to these bits.
11:4
VHIGH Limit
Sets the upper limit threshold used to determine the alert condition. If the conversion moves
higher than this limit, a VHIGH alert is generated.
3:0
Reserved
Always reads zeros. Zeros must be written to these bits.
1.6.7 VHYST -- Alert Hysteresis Register
Pointer Address 05h (Read/Write)
Default Value: 0000h
D15
D14
D13
D12
D11
Reserved
D7
D6
D10
D9
D8
Hysteresis[7:4]
D5
D4
D3
D2
Hysteresis[3:0]
D1
D0
Reserved
Bits
Name
Description
15:12
Reserved
Always reads zeros. Zeros must be written to these bits.
11:4
Hysteresis
Sets the hysteresis value used to determine the alert condition. After a VHIGH or VLOW alert occurs,
the conversion result must move within the VHIGH or VLOW limit by more than this value to clear
the alert condition.
Note: If the Alert Hold bit is set in the configuration register, alert conditions will not self-clear.
3:0
Reserved
Always reads zeros. Zeros must be written to these bits.
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ADC081C021/ADC081C027
1.6.6 VHIGH -- Alert Limit Register - Over Range
ADC081C021/ADC081C027
1.6.8 VMIN -- Lowest Conversion Register
Pointer Address 06h (Read/Write)
Default Value: 0FFFh
D15
D14
D13
D12
D11
Reserved
D7
D6
D10
D9
D8
Lowest Conversion[7:4]
D5
D4
D3
D2
Lowest Conversion[3:0]
D1
D0
Reserved
Bits
Name
Description
15:12
Reserved
Always reads zeros. Zeros must be written to these bits.
11:4
Lowest Conversion
Contains the Lowest Conversion result. Each conversion result is compared against the contents
of this register. If the value is lower, it becomes the lowest conversion and replaces the current
value. If the value is higher, the register contents remain unchanged. The lowest conversion value
can be cleared at any time by writting 0FFFh to this register. The value of this register will update
automatically when the automatic conversion mode is enabled.
3:0
Reserved
Always reads zeros. Zeros must be written to these bits.
1.6.9 VMAX -- Highest Conversion Register
Pointer Address 07h (Read/Write)
Default Value: 0000h
D15
D14
D13
D12
D11
Reserved
D7
D6
D10
D9
D8
Highest Conversion[7:4]
D5
D4
D3
D2
Highest Conversion[3:0]
D1
D0
Reserved
Bits
Name
Description
15:12
Reserved
Always reads zeros. Zeros must be written to these bits.
11:4
Highest Conversion
Contains the Highest Conversion result. Each conversion result is compared against the contents
of this register. If the value is higher, it becomes the highest conversion and replaces the previous
value. If the value is lower, the register contents remain unchanged. The highest conversion value
can be cleared at any time by writting 0000h to this register. The value of this register will update
automatically when the automatic conversion mode is enabled.
3:0
Reserved
Always reads zeros. Zeros must be written to these bits.
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1.7.1 Basic I2C Protocol
The I2C interface is bi-directional and allows multiple devices
to operate on the same bus. The bus consists of master devices and slave devices which can communicate back and
forth over the I2C interface. Master devices control the bus
and are typically microcontrollers, FPGAs, DSPs, or other
digital controllers. Slave devices are controlled by a master
and are typically peripheral devices such as the
ADC081C021. To support multiple devices on the same bus,
each slave has a unique hardware address which is referred
to as the "slave address." To communicate with a particular
device on the bus, the controller (master) sends the slave address and listens for a response from the slave. This response
is referred to as an acknowledge bit. If a slave on the bus is
addressed correctly, it Acknowledges(ACKs) the master by
30052111
FIGURE 7. Basic Operation.
the master sends the upper 8-bits to the ADC081C021. Then
the ADC081C021 ACKs the transfer by driving SDA low. For
a single byte transfer, the master should generate a stop condition at this point. For a 2-byte write operation, the lower 8bits are sent by the master. The ADC081C021 then ACKs the
transfer, and the master either sends another pair of data
bytes, generates a Repeated Start condition to read or write
another register, or generates a Stop condition to end communication.
A read operation can take place either of two ways:
If the address pointer is pre-set before the read operation, the
desired register can be read immediately following the slave
1.7.2 Standard-Fast Mode
In Standard-Fast mode, the master generates a start condition by driving SDA from high to low while SCL is high. The
start condition is always followed by a 7-bit slave address and
a Read/Write bit. After these 8 bits have been transmitted by
the master, SDA is released by the master and the
ADC081C021 either ACKs or NACKs the address. If the slave
address matches, the ADC081C021 ACKs the master. If the
address doesn't match, the ADC081C021 NACKs the master.
For a write operation, the master follows the ACK by sending
the 8-bit register address pointer to the ADC. Then the
ADC081C021 ACKs the transfer by driving SDA low. Next,
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ADC081C021/ADC081C027
driving the SDA bus low. If the address doesn't match a
device's slave address, it Not-acknowledges(NACKs) the
master by letting SDA be pulled high. ACKs also occur on the
bus when data is being transmitted. When the master is writing data, the slave ACKs after every data byte is successfully
received. When the master is reading data, the master ACKs
after every data byte is received to let the slave know it wants
to receive another data byte. When the master wants to stop
reading, it NACKs after the last data byte and creates a stop
condition on the bus.
All communication on the bus begins with either a Start condition or a Repeated Start condition. The protocol for starting
the bus varies between Standard-Fast mode and Hs-mode.
In Standard-Fast mode, the master generates a
Start condition by driving SDA from high to low while SCL is
high. In Hs-mode, starting the bus is more complicated.
Please refer to section 1.7.3 for the full details of a Hs-mode
Start condition. A Repeated Start is generated to address a
different device or register, or to switch between read and
write modes. The master generates a Repeated Start condition by driving SDA low while SCL is high. Following the
Repeated Start, the master sends out the slave address and
a read/write bit as shown in Figure 7. The bus continues to
operate in the same speed mode as before the Repeated
Start condition.
All communication on the bus ends with a Stop condition. In
either Standard-Fast mode or Hs-Mode, a Stop condition occurs when SDA is pulled from low to high while SCL is high.
After a Stop condition, the bus remains idle until a master
generates a Start condition.
Please refer to the Philips I2C® Specification (Version 2.1
Jan, 2000) for a detailed description of the serial interface.
1.7 SERIAL INTERFACE
The I2C-compatible interface operates in all three speed
modes. Standard mode (100kHz) and Fast mode (400kHz)
are functionally the same and will be referred to as StandardFast mode in this document. High-Speed mode (3.4MHz) is
an extension of Standard-Fast mode and will be referred to
as Hs-mode in this document. The following diagrams describe the timing relationships of the clock (SCL) and data
(SDA) signals. Pull-up resistors or current sources are required on the SCL and SDA busses to pull them high when
they are not being driven low. A logic zero is transmitted by
driving the output low. A logic high is transmitted by releasing
the output and allowing it to be pulled-up externally. The appropriate pull-up resistor values will depend upon the total bus
capacitance and operating speed. The ADC081C021 offers
extended ESD tolerance (8kV HBM) for the I2C bus pins (SCL
& SDA) allowing extension of the bus across multiple boards
without extra ESD protection.
ADC081C021/ADC081C027
address. In this case, the upper 8-bits of the register, set by
the pre-set address pointer, are sent out by the ADC. For a
single byte read operation, the Master sends a NACK to the
ADC and generates a Stop condition to end communication
after receiving 8-bits of data. For a 2-Byte read operation, the
Master continues the transmission by sending an ACK to the
ADC. Then, the ADC sends out the lower 8-bits of the ADC
register. At this point, the master either sends; an ACK to receive more data or, a NACK followed by a Stop or Repeated
Start. If the master sends an ACK, the ADC sends the next
upper data byte, and the read cycle repeats.
If the address pointer needs to be set, the ADC081C021
needs to write to the device and set the address pointer before
reading from the desired register. This type of read requires
a start, the slave address, a write bit, the address pointer, a
Repeated Start, the slave address, and a read bit (refer to
Figure 12). Following this sequence, the ADC sends out the
upper 8-bits of the register. For a single byte read operation,
the Master must send a NACK to the ADC and generate a
Stop condition to end communication. For a 2-Byte write operation, the Master sends an ACK to the ADC. Then, the ADC
sends out the lower 8-bits of the ADC register. At this point,
the master sends either an ACK to receive more data, or a
NACK followed by a Stop or Repeated Start. If the master
sends an ACK, the ADC sends another pair of data bytes, and
the read cycle will repeat. The number of data words that can
be read is unlimited.
1.7.3 High-Speed (Hs) Mode
For Hs-mode, the sequence of events to begin communication differs slightly from Standard-Fast mode. Figure 8 describes this in further detail. Initially, the bus begins running
in Standard-Fast mode. The master generates a
Start condition and sends the 8-bit Hs master code
(00001XXX) to the ADC081C021. Next, the ADC081C021
responds with a NACK. Once the SCL line has been pulled to
a high level, the master switches to Hs-mode by increasing
the bus speed and generating a Repeated Start condition
(driving SDA low while SCL is pulled high). At this point, the
master sends the slave address to the ADC081C021, and
communication continues as shown above in the "Basic Operation" Diagram (see Figure 7).
When the master generates a Repeated Start condition while
in Hs-mode, the bus stays in Hs-mode awaiting the slave address from the master. The bus continues to run in Hs-mode
until a Stop condition is generated by the master. When the
master generates a Stop condition on the bus, the bus must
be started in Standard-Fast mode again before increasing the
bus speed and switching to Hs-mode.
30052112
FIGURE 8. Beginning Hs-Mode Communication
1.7.4 I2C Slave (Hardware) Address
The ADC has a seven-bit hardware address which is also referred to as a slave address. For the ADC081C027, the
address is configured by the ADDR address selection input.
ADDR can be grounded, left floating, or tied to VA. If desired,
ADDR can be set to VA/2 rather than left floating. The state of
the ADDR input sets the hardware address that the ADC responds to on the I2C bus (see ). For the ADC081C021, the
hardware address is not pin-configurable and is set to
1010100. The diagrams in Section 1.10 describe how the I2C
controller should address the ADC via the I2C interface.
TABLE 1. Slave Addresses
Slave Address
[A6 - A0]
ADC081C027*
1010000
Floating
-----------------
1010001
GND
-----------------
1010010
VA
-----------------
1010100
-----------------
Single Address
1010101
-----------------
-----------------
1010110
-----------------
-----------------
1011000
-----------------
-----------------
1011001
-----------------
-----------------
1011010
-----------------
-----------------
ADDR
ADC081C021*
* Pin-compatible alternatives to the ADC081C021 and the
ADC081C027 are available with additional address options.
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ADC081C021/ADC081C027
1.8 ALERT FUNCTION
The ALERT function is an "out-of-range" indicator. At the end
of every conversion, the measured voltage is compared to the
values in the VHIGH and VLOW registers. If the measured voltage exceeds the value stored in VHIGH or falls below the value
stored in VLOW, an alert condition occurs. The Alert condition
is indicated in up to three places. First, the alert condition always causes either or both of the alert flags in the Alert Status
register to go high. If the measured voltage exceeds the
VHIGH limit, the Over Range Alert Flag is set. If the measured
voltage falls below the VLOW limit, the Under Range Alert Flag
is set. Second, if the Alert Flag Enable bit is set in the Configuration register, the alert condition also sets the MSB of the
Conversion Result register. Third, if the Alert Pin Enable bit is
set in the Configuration register, the ALERT output becomes
active (see Figure 9). The ALERT output can be configured
as an active high or active low output via the Polarity bit in the
Configuration register. If the Polarity bit is cleared, the ALERT
output is configured as active low. If the Polarity bit is set, the
ALERT output is configured as active high.
The Over Range Alert condition is cleared when one of the
following two conditions is met:
1. The controller writes a one to the Over Range Alert Flag
bit.
2. The measured voltage reduces below the programmed
VHIGH limit minus the programmed VHYST value and the
Alert Hold bit is cleared in the Configuration register. (see
Figure 9). If the Alert Hold bit is set, the alert condition
persists and only clears when a one is written to the Over
Range Alert Flag bit.
The Under Range Alert condition is cleared when one of the
following two conditions is met:
1. The controller writes a one to the Under Range Alert Flag
bit.
2. The measured voltage increases above the programmed
VLOW limit plus the programmed VHYST value and the
Alert Hold bit is cleared in the Configuration register. If
the Alert Hold bit is set, the alert condition persists and
only clears when a one is written to the Under Range
Alert Flag bit.
If the alert condition has been cleared by writing a one to the
alert flag while the measured voltage still violates the VHIGH
or VLOW limits, an alert condition will occur again after the
completion of the next conversion (see Figure 10).
Alert conditions only occur if the input voltage exceeds the
VHIGH limit or falls below the VLOW limit at the sample-hold
instant. The input voltage can exceed the VHIGH limit or fall
below the VLOW limit briefly between conversions without
causing an alert condition.
30052174
FIGURE 9. Alert condition cleared when measured
voltage crosses VHIGH - VHYST
30052175
FIGURE 10. Alert condition cleared by writing a "1" to the
Alert Flag.
1.9 AUTOMATIC CONVERSION MODE
The automatic conversion mode configures the ADC to continually perform conversions without receiving "read" instructions from the controller over the I2C interface. The mode is
activated by writing a non-zero value into the Cycle Time bits
- D[7:5] - of the configuration register (see section 1.6.4).
Once the ADC081C021 enters this mode, the internal oscillator is always enabled. The ADC's control logic samples the
input at the sample rate set by the cycle time bits. Although
the conversion result is not transmitted by the 2-wire interface,
it is stored in the conversion result register and updates the
various status registers of the device.
In automatic conversion mode, the out-of-range alert function
is active and updates after every conversion. The ADC can
operate independently of the controller in automatic conversion mode. When the input signal goes "out-of-range", an
alert signal is sent to the controller. The controller can then
read the status registers and determine the source of the alert
condition. Also, comparison and updating of the VMIN and
VMAX registers occurs after every conversion in automatic
conversion mode. The controller can ocassionally read the
VMIN and/or VMAX registers to determine the sampled input
extremes. These register values persist until the user resets
the VMIN and VMAX registers. These two features are useful in
system monitoring, peak detection, and sensing applications.
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ADC081C021/ADC081C027
operation must preceed the read operation to set the pointer
address correctly. On the other hand, if the pointer is preset
correctly, a read operation can occur without writing the address pointer register. The following timing diagrams describe
the various read and write operations supported by the ADC.
1.10 COMMUNICATING WITH THE ADC081C021
The ADC081C021's data registers are selected by the address pointer (see Section 1.6.1). To read/write a specific data
register, the pointer must be set to that register's address. The
pointer is always written at the beginning of a write operation.
When the pointer needs to be updated for a read cycle, a write
1.10.1 Reading from a 2-Byte ADC Register
30052163
FIGURE 11. (a) Typical Read from a 2-Byte ADC Register with Preset Pointer
30052170
FIGURE 12. (b) Typical Pointer Set Followed by Immediate Read of a 2-Byte ADC Register
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ADC081C021/ADC081C027
1.10.2 Reading from a 1-Byte ADC Register
30052171
FIGURE 13. (a) Typical Read from a 1-Byte ADC Register with Preset Pointer
30052172
FIGURE 14. (b) Typical Pointer Set Followed by Immediate Read of a 1-Byte ADC Register
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ADC081C021/ADC081C027
1.10.3 Writing to an ADC Register
30052164
FIGURE 15. (a) Typical Write to a 1-Byte ADC Register
30052173
FIGURE 16. (b) Typical Write to a 2-Byte ADC Register
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30052176
FIGURE 17. Reading in Quiet Interface Mode
27
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ADC081C021/ADC081C027
at least 1µs before the MSB of every upper data byte. The
diagram assumes that the address pointer register is set to
its default value.
Quiet Interface mode will only improve INL and DNL performance in Hs-Mode. Standard and Fast mode performance is
unaffected by the Quiet Interface mode.
1.11 QUIET INTERFACE MODE
To improve performance at High Speed, operate the ADC in
Quiet Interface Mode. This mode provides improved INL and
DNL performance in I2C Hs-Mode (3.4MHz). The Quiet Interface mode provides a maximum throughput rate of 162ksps.
Figure 17 describes how to read the conversion result register
in this mode. Basically, the Master needs to release SCL for
ADC081C021/ADC081C027
priate bypass capacitor should be added between the
controller's supply pin and the pull-up resistors. For Hs-mode
applications, this bypass capacitance will improve the accuracy of the ADC.
The value of the pull-up resistors (RP) depends upon the
characteristics of each particular I2C bus. The I2C specification describes how to choose an appropriate value. As a
general rule-of-thumb, we suggest using a 1kΩ resistor for
Hs-mode bus configurations and a 5kΩ resistor for Standard
or Fast Mode bus configurations. Depending upon the bus
capacitance, these values may not be sufficient to meet the
timing requirements of the I2C bus specification. Please see
the I2C specification for further information.
2.0 Applications Information
2.1 TYPICAL APPLICATION CIRCUIT
A typical application circuit is shown in Figure 18. The analog
supply is bypassed with a capacitor network located close to
the ADC081C021. The ADC uses the analog supply (VA) as
its reference voltage, so it is very important that VA be kept as
clean as possible. Due to the low power requirements of the
ADC081C021, it is possible to use a precision reference as a
power supply. The pull-up resistors (RP) should be powered
by the controller's supply. It is important that the pull-up resistors are pulled to the same voltage potential VA is set to.
This will ensure that the logic levels of all devices on the bus
are compatible. If the controller's supply is noisy, an appro-
30052120
FIGURE 18. Typical Application Circuit
single-ended sensor interface. The input must have a DC bias
level that keeps the ADC input signal from swinging below
GND or above the supply (+5V in this case).
The LM4132, with its 0.05% accuracy over temperature, is an
excelent choice as a reference source for the ADC081C021.
2.2 BUFFERED INPUT
A bufferred input application circuit is shown in Figure 19. The
analog input is buffered by National's LMP7731. The non-inverting amplifier configuration provides a buffered gain stage
for a single ended source. This application circuit is good for
30052121
FIGURE 19. Buffered Input Circuit
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2.3.1 Trickle Charge Controller
While a battery is discharging, the ADC081C021 can be used
to control a trickle charge to keep the battery near full capacity
(see Figure 23). When the alert output is active, the battery
will recharge. An intelligent recharge cycle will prevent overcharging and damaging the battery. With a trickle charge, the
battery powered device can be disconnected from the charger
at any time with a full charge.
30052177
FIGURE 20. Intelligent Battery Monitor Circuit
30052180
FIGURE 23. Trickle Charge
30052178
FIGURE 21. Recharge Cycle
30052179
FIGURE 22. Discharge Cycle
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ADC081C021/ADC081C027
In addition to the window supervisory feature, the
ADC081C021 will allow the controller to read the battery voltage at any time during operation. Reading the conversion
result via the I2C interface provides an accurate voltage reading.
The accurate voltage reading and the alert feature will allow
a controller to improve the efficiency of a battery-powered
device. During the discharge cycle, the controller can switch
to a low-battery mode, safely suspend operation, or report a
precise battery level to the user. During the recharge cycle,
the controller can implement an intelligent recharge cycle,
decreasing the charge rate when the battery charge nears
capacity.
2.3 INTELLIGENT BATTERY MONITOR
The ADC081C021 is easily used as an intelligent battery
monitor. The simple circuit shown in Figure 20, uses the
ADC081C021, the LP2980 fixed reference, and a resistor divider to implement an intelligent battery monitor with a window
supervisory feature. The window supervisory feature is implemented by the "out of range" alert function. When the
battery is recharging, the Over Range Alert will indicate that
the charging cycle is complete (see Figure 21). When the
battery is nearing depletion, the Under Range Alert will indicate that the battery is low (see Figure 22).
ADC081C021/ADC081C027
guarantee that signals do not pass over power plane boundaries. They must always have a continuous return path below
their traces.
The ADC081C021 power supply should be bypassed with a
4.7µF and a 0.1µF capacitor as close as possible to the device
with the 0.1µF right at the device supply pin. The 4.7µF capacitor should be a tantalum type and the 0.1µF capacitor
should be a low ESL type. The power supply for the
ADC081C021 should only be used for analog circuits.
Avoid crossover of analog and digital signals and keep the
clock and data lines on the component side of the board. The
clock and data lines should have controlled impedances.
2.4 LAYOUT, GROUNDING, AND BYPASSING
For best accuracy and minimum noise, the printed circuit
board containing the ADC081C021 should have separate
analog and digital areas. The areas are defined by the locations of the analog and digital power planes. Both of these
planes should be located on the same board layer. There
should be a single ground plane. A single, solid ground plane
is preferred if digital return current does not flow through the
analog ground area. Frequently a single ground plane design
will utilize a "fencing" technique to prevent the mixing of analog and digital ground current. Separate ground planes should
only be utilized when the fencing technique is inadequate.
The separate ground planes must be connected in one place,
preferably near the ADC081C021. Special care is required to
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ADC081C021/ADC081C027
Physical Dimensions inches (millimeters) unless otherwise noted
6-Lead TSOT
Order Numbers ADC081C021CIMK & ADC081C027CIMK
NS Package Number MK06A
31
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ADC081C021/ADC081C027 I2C-Compatible, 8-Bit Analog-to-Digital Converter (ADC) with Alert
Notes
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