Maxim MAX148ACAP 2.7v to 5.25v, low-power, 8-channel, serial 10-bit adc Datasheet

19-0464; Rev 3; 5/09
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
Features
The MAX148/MAX149 10-bit data-acquisition systems
combine an 8-channel multiplexer, high-bandwidth
track/hold, and serial interface with high conversion
speed and low power consumption. They operate from a
single +2.7V to +5.25V supply, and sample to 133ksps.
Both devices’ analog inputs are software configurable for
unipolar/bipolar and single-ended/differential operation.
S 8-Channel Single-Ended or 4-Channel Differential
The 4-wire serial interface connects directly to SPIK/
QSPIK and MICROWIREK devices without external
logic. A serial-strobe output allows direct connection to
TMS320-family digital signal processors. The MAX148/
MAX149 use either the internal clock or an external serial-interface clock to perform successive-approximation
analog-to-digital conversions.
The MAX149 has an internal 2.5V reference, while the
MAX148 requires an external reference. Both parts
have a reference-buffer amplifier with a Q1.5% voltageadjustment range.
These devices provide a hard-wired SHDN pin and
a software-selectable power-down, and can be programmed to automatically shut down at the end of a
conversion. Accessing the serial interface automatically
powers up the MAX148/MAX149, and the quick turn-on
time allows them to be shut down between all conversions. This technique can cut supply current to under
60FA at reduced sampling rates.
The MAX148/MAX149 are available in a 20-pin DIP and
a 20-pin SSOP.
Inputs
S Single-Supply Operation: +2.7V to +5.25V
S Internal 2.5V Reference (MAX149)
S Low Power: 1.2mA (133ksps, 3V Supply)
54µA (1ksps, 3V Supply)
1µA (Power-Down Mode)
S SPI/QSPI/MICROWIRE/TMS320-Compatible 4-Wire
Serial Interface
S Software-Configurable Unipolar or Bipolar Inputs
S 20-Pin DIP/SSOP Packages
Ordering Information
TEMP RANGE
PINPACKAGE
INL
(LSB)
MAX148ACPP
0°C to +70°C
20 Plastic DIP
±1/2
MAX148BCPP
0°C to +70°C
20 Plastic DIP
±1
MAX148ACAP
0°C to +70°C
20 SSOP
±1/2
MAX148BCAP
0°C to +70°C
20 SSOP
±1
PART†
Ordering Information continued at end of data sheet.
†Contact factory for availability of alternate surface-mount
package. Specify lead-free by placing + by the part number
when ordering.
*Contact factory for availability of CERDIP package, and for
processing to MIL-STD-883B. Not available in lead-free.
For 4-channel versions of these devices, see the
MAX1248/MAX1249 data sheet.
Typical Operating Circuit
+3V
Applications
Portable Data Logging
Data Acquisition
Medical Instruments
Process Control
DGND
MAX149
CH7
AGND
VREF
COM
CPU
CS
SCLK
DIN
DOUT
SSTRB
SHDN
I/O
SCK (SK)
MOSI (SO)
MISO (SI)
4.7FF
READJ
Pin Configuration appears at end of data sheet.
0.01FF
VDD
0.1FF
O TO
+2.5V
ANALOG
INPUTS
Battery-Powered Instruments
Pen Digitizers
VDD
CH0
VSS
SPI and QSPI are trademarks of Motorola, Inc. MICROWIRE is a trademark of National Semiconductor Corp.
________________________________________________________________ Maxim Integrated Products 1
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX148/MAX149
General Description
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
ABSOLUTE MAXIMUM RATINGS
VDD to AGND, DGND...............................................-0.3V to +6V
AGND to DGND....................................................-0.3V to +0.3V
CH0–CH7, COM to AGND, DGND............ -0.3V to (VDD + 0.3V)
VREF, REFADJ to AGND............................-0.3V to (VDD + 0.3V)
Digital Inputs to DGND............................................-0.3V to +6V
Digital Outputs to DGND........................... -0.3V to (VDD + 0.3V)
Digital Output Sink Current.................................................25mA
Continuous Power Dissipation (TA = +70NC)
Plastic DIP (derate 11.11mW/NC above +70NC)...........889mW
SSOP (derate 8.00mW/NC above +70NC).....................640mW
CERDIP (derate 11.11mW/NC above +70NC)...............889mW
Operating Temperature Ranges
MAX148_C_P/MAX149_C_P............................... 0NC to +70NC
MAX148_E_P/MAX149_E_P............................. -40NC to +85NC
MAX148_MJP/MAX149_MJP......................... -55NC to +125NC
MAX149BMAP................................................ -55NC to +125NC
Storage Temperature Range............................. -60NC to +150NC
Lead Temperature (soldering, 10s).................................+300NC
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these
or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may
affect device reliability.
ELECTRICAL CHARACTERISTICS
(VDD = +2.7V to +5.25V; COM = 0; fSCLK = 2.0MHz; external clock (50% duty cycle); 15 clocks/conversion cycle (133ksps);
MAX149—4.7FF capacitor at VREF pin; MAX148—external reference, VREF = 2.500V applied to VREF pin; TA = TMIN to TMAX, unless
otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
DC ACCURACY (Note 1)
Resolution
10
Relative Accuracy (Note 2)
INL
Differential Nonlinearity
DNL
Offset Error
Gain Error (Note 3)
Bits
MAX14_A
±0.5
MAX14_B
±1.0
No missing codes over temperature
±1
MAX14_A
±0.15
±1
MAX14_B
±0.15
±2
MAX14_A
±1
MAX14_B
±2
LSB
LSB
LSB
LSB
Gain Temperature Coefficient
±0.25
ppm/°C
Channel-to-Channel Offset
Matching
±0.05
LSB
DYNAMIC SPECIFICATIONS (10kHz Sine-Wave Input, 0 to 2.500VP-P, 133ksps, 2.0MHz External Clock, Bipolar Input Mode)
Signal-to-Noise + Distortion
Noise
SINAD
66
dB
Up to the 5th harmonic
-70
dB
70
dB
Channel-to-Channel Crosstalk
65kHz, 2.500VP-P (Note 4)
-75
dB
Small-Signal Bandwidth
-3dB rolloff
2.25
MHz
1.0
MHz
Total Harmonic Distortion
THD
Spurious-Free Dynamic Range
SFDR
Full-Power Bandwidth
CONVERSION RATE
Conversion Time (Note 5)
Track/Hold Acquisition Time
tCONV
Internal clock, SHDN = unconnected
5.5
7.5
Internal clock, SHDN = VDD
35
65
External clock = 2MHz, 12 clocks/
conversion
6
tACQ
1.5
μs
μs
Aperture Delay
30
ns
Aperture Jitter
< 50
ps
2 _______________________________________________________________________________________
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
(VDD = +2.7V to +5.25V; COM = 0; fSCLK = 2.0MHz; external clock (50% duty cycle); 15 clocks/conversion cycle (133ksps);
MAX149—4.7FF capacitor at VREF pin; MAX148—external reference, VREF = 2.500V applied to VREF pin; TA = TMIN to TMAX, unless
otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
CONVERSION RATE (continued)
Internal Clock Frequency
External Clock Frequency
SHDN = unconnected
1.8
SHDN = VDD
Data transfer only
MHz
0.225
0.1
2.0
1
2.0
MHz
ANALOG/COM INPUTS
Input Voltage Range, SingleEnded and Differential (Note 6)
Unipolar, COM = 0
Multiplexer Leakage Current
On/off leakage current, VCH_ = 0 or VDD
0 to VREF
Bipolar, COM = VREF/2
±VREF/2
±0.01
Input Capacitance
±1
16
V
μA
pF
INTERNAL REFERENCE (MAX149 Only, Reference Buffer Enabled)
VREF Output Voltage
TA = +25°C (Note 7)
2.470
2.500
VREF Short-Circuit Current
30
VREF Temperature Coefficient
MAX149
Load Regulation (Note 8)
0 to 0.2mA output load
Capacitive Bypass at VREF
2.530
Internal compensation mode
0
External compensation mode
4.7
Capacitive Bypass at REFADJ
mA
±30
ppm/°C
0.35
mV
μF
0.01
REFADJ Adjustment Range
V
μF
±1.5
%
EXTERNAL REFERENCE AT VREF (Buffer Disabled)
VREF Input Voltage Range
(Note 9)
VREF Input Current
VDD +
50mV
1.0
VREF = 2.500V
VREF Input Resistance
100
18
Shutdown VREF Input Current
150
25
0.01
μA
kΩ
10
VDD 0.5
REFADJ Buffer-Disable Threshold
V
µA
V
EXTERNAL REFERENCE AT REFADJ
Capacitive Bypass at VREF
Reference Buffer Gain
REFADJ Input Current
Internal compensation mode
0
External compensation mode
4.7
µF
MAX149
2.06
MAX148
2.00
V/V
MAX149
±50
MAX148
±10
µA
_______________________________________________________________________________________ 3
MAX148/MAX149
ELECTRICAL CHARACTERISTICS (continued)
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
ELECTRICAL CHARACTERISTICS (continued)
(VDD = +2.7V to +5.25V; COM = 0; fSCLK = 2.0MHz; external clock (50% duty cycle); 15 clocks/conversion cycle (133ksps);
MAX149—4.7FF capacitor at VREF pin; MAX148—external reference, VREF = 2.500V applied to VREF pin; TA = TMIN to TMAX, unless
otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
DIGITAL INPUTS (DIN, SCLK, CS, SHDN)
DIN, SCLK, CS Input High Voltage
VIH
DIN, SCLK, CS Input Low Voltage
VIL
DIN, SCLK, CS Input Hysteresis
VHYST
VDD ≤ 3.6V
2.0
VDD > 3.6V
3.0
0.8
0.2
DIN, SCLK, CS Input Leakage
IIN
VIN = 0 or VDD
DIN, SCLK, CS Input Capacitance
CIN
(Note 10)
±0.01
SHDN Input High Voltage
VSH
VDD 0.4
SHDN Input Mid Voltage
VSM
1.1
SHDN Input Low Voltage
VSL
SHDN Input Current
SHDN Voltage, Unconnected
IS
VFLT
SHDN Maximum Allowed
Leakage, Mid Input
V
V
±1
µA
15
pF
V
VDD 1.1
SHDN = 0 or VDD
SHDN = unconnected
V
0.4
V
±4.0
µA
VDD/2
SHDN = unconnected
V
V
±100
nA
DIGITAL OUTPUTS (DOUT, SSTRB)
Output-Voltage Low
VOL
Output-Voltage High
VOH
Three-State Leakage Current
Three-State Output Capacitance
IL
COUT
ISINK = 5mA
0.4
ISINK = 16mA
0.8
VDD 0.5
ISOURCE = 0.5mA
CS = VDD
V
V
±0.01
CS = VDD (Note 10)
±10
µA
15
pF
5.25
V
POWER REQUIREMENTS
Positive Supply Voltage
Positive Supply Current
VDD
IDD
2.70
Operating mode, full-scale VDD = 5.25V
input (Note 11)
VDD = 3.6V
1.6
3.0
1.2
2.0
VDD = 5.25V
3.5
15
VDD = 3.6V
1.2
10
30
70
Full power-down
Fast power-down (MAX149)
Supply Rejection (Note 12)
PSR
Full-scale input, external reference =
2.500V, VDD = 2.7V to 5.25V
±0.3
4 _______________________________________________________________________________________
mA
µA
mV
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
(VDD = +2.7V to +5.25V, TA = TMIN to TMAX, unless otherwise noted.)
PARAMETER
Acquisition Time
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
tACQ
1.5
μs
DIN to SCLK Setup
tDS
100
ns
DIN to SCLK Hold
tDH
0
SCLK Fall to Output Data Valid
tDO
Figure 1
CS Fall to Output Enable
tDV
Figure 1
tTR
Figure 2
CS Rise to Output Disable
ns
MAX14_ _C/E
20
200
MAX14_ _M
20
240
ns
240
ns
240
ns
CS to SCLK Rise Setup
tCSS
100
ns
CS to SCLK Rise Hold
tCSH
0
ns
SCLK Pulse Width High
tCH
200
ns
SCLK Pulse Width Low
SCLK Fall to SSTRB
tCL
tSSTRB
200
ns
Figure 1
240
ns
CS Fall to SSTRB Output Enable
tSDV
External clock mode only, Figure 1
240
ns
CS Rise to SSTRB Output Disable
tSTR
External clock mode only, Figure 2
240
ns
SSTRB Rise to SCLK Rise
tSCK
Internal clock mode only (Note 7)
0
ns
Note 1: Tested at VDD = 2.7V; COM = 0; unipolar single-ended input mode.
Note 2: Relative accuracy is the deviation of the analog value at any code from its theoretical value after the full-scale range has
been calibrated.
Note 3: MAX149—internal reference, offset nulled; MAX148—external reference (VREF = +2.500V), offset nulled.
Note 4: Ground “on” channel; sine wave applied to all “off” channels.
Note 5: Conversion time defined as the number of clock cycles multiplied by the clock period; clock has 50% duty cycle.
Note 6: The common-mode range for the analog inputs is from AGND to VDD.
Note 7: Sample tested to 0.1% AQL.
Note 8: External load should not change during conversion for specified accuracy.
Note 9: ADC performance is limited by the converter’s noise floor, typically 300FVP-P.
Note 10: Guaranteed by design. Not subject to production testing.
Note 11: The MAX148 typically draws 400FA less than the values shown.
Note 12: Measured as |VFS(2.7V) - VFS(5.25V)|.
_______________________________________________________________________________________ 5
MAX148/MAX149
TIMING CHARACTERISTICS
Typical Operating Characteristics
(VDD = 3.0V, VREF = 2.500V, fSCLK = 2.0MHz, CLOAD = 20pF, TA = +25NC, unless otherwise noted.)
MAX149
0.075
0.050
MAX148
-0.05
VDD = 2.7V
0.100
INL (LSB)
0
0.125
MAX148-MAX149 toc02
0.100
INL (LSB)
0.05
INL (LSB)
0.125
MAX148-MAX149 toc01
0.10
INTEGRAL NONLINEARITY
vs. TEMPERATURE
MAX148-MAX149 toc03
INTEGRAL NONLINEARITY
vs. SUPPLY VOLTAGE
INTEGRAL NONLINEARITY
vs. CODE
MAX149
0.075
0.050
MAX148
0.025
0.025
-0.10
0
1024
0
2.25
CLOAD = 50pF
MAX149
1.50
1.25
CLOAD = 20pF
1.00
0.75
4.75
5.25
MAX148
3.0
0.50
2.75
3.25 3.75 4.25
SUPPLY VOLTAGE (V)
FULL POWER-DOWN
2.5
2.0
1.5
1.0
0.5
4.75
5.25
1.1
1.0
MAX148
0.9
RL0AD = J
CODE = 1010101000
0.8
-60
-20
20
60
TEMPERATURE (NC)
100
2.75
3.25 3.75 4.25
SUPPLY VOLTAGE (V)
4.75
140
2.5015
2.5010
2.5005
2.5000
2.4995
2.25
5.25
1.6
2.75
3.25 3.75 4.25
SUPPLY VOLTAGE (V)
4.75
5.25
MAX149 INTERNAL REFERENCE
VOLTAGE vs. TEMPERATURE
MAX148-MAX149 toc08
2.0
SHUTDOWN CURRENT (mA)
MAX149
140
100
2.5020
SHUTDOWN CURRENT
vs. TEMPERATURE
MAX148-MAX149 toc07
1.3
20
60
TEMPERATURE (NC)
2.4990
2.25
SUPPLY CURRENT vs. TEMPERATURE
1.2
-20
MAX149 INTERNAL REFERENCE
VOLTAGE vs. SUPPLY VOLTAGE
0
2.25
-60
MAX148-MAX149 toc06
SUPPLY CURRENT (mA)
1.75
RL = J
CODE = 1010101000
SHUTDOWN SUPPLY CURRENT (FA)
2.00
3.25 3.75 4.25
SUPPLY VOLTAGE (V)
SHUTDOWN SUPPLY CURRENT
vs. SUPPLY VOLTAGE
MAX148-MAX149 toc04
SUPPLY CURRENT
vs. SUPPLY VOLTAGE
2.75
1.2
0.8
0.4
0
2.501
VDD = 5.25V
2.500
VDD = 3.6V
2.499
MAX148-MAX149 toc09
768
INTERNAL REFERENCE VOLTAGE (V)
512
CODE
INTERNAL REFERENCE VOLTAGE (V)
256
MAX148-MAX149 toc05
0
SUPPLY CURRENT (mA)
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
VDD = 2.7V
2.498
2.497
2.496
2.495
2.494
-60
-20
20
60
TEMPERATURE (NC)
100
140
-60
-20
20
60
TEMPERATURE (NC)
6 _______________________________________________________________________________________
100
140
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
PIN
NAME
1–8
CH0–CH7
9
COM
Ground Reference for Analog Inputs. COM sets zero-code voltage in single-ended mode. Must be
stable to ±0.5 LSB.
SHDN
Three-Level Shutdown Input. Pulling SHDN low shuts the MAX148/MAX149 down; otherwise, they
are fully operational. Pulling SHDN high puts the reference-buffer amplifier in internal compensation
mode. Leaving SHDN unconnected puts the reference-buffer amplifier in external compensation
mode.
11
VREF
Reference-Buffer Output/ADC Reference Input. Reference voltage for analog-to-digital conversion.
In internal reference mode (MAX149 only), the reference buffer provides a 2.500V nominal output,
externally adjustable at REFADJ. In external reference mode, disable the internal buffer by pulling
REFADJ to VDD.
12
REFADJ
13
AGND
Analog Ground
14
DGND
Digital Ground
15
DOUT
Serial-Data Output. Data is clocked out at SCLK’s falling edge. High impedance when CS is high.
16
SSTRB
Serial-Strobe Output. In internal clock mode, SSTRB goes low when the MAX148/MAX149 begin
the A/D conversion, and goes high when the conversion is finished. In external clock mode, SSTRB
pulses high for one clock period before the MSB decision. High impedance when CS is high
(external clock mode).
17
DIN
Serial-Data Input. Data is clocked in at SCLK’s rising edge.
18
CS
Active-Low Chip Select. Data will not be clocked into DIN unless CS is low. When CS is high, DOUT
is high impedance.
19
SCLK
Serial-Clock Input. Clocks data in and out of serial interface. In external clock mode, SCLK also sets
the conversion speed (duty cycle must be 40% to 60%).
20
VDD
10
FUNCTION
Sampling Analog Inputs
Input to the Reference-Buffer Amplifier. To disable the reference-buffer amplifier, tie REFADJ to VDD.
Positive Supply Voltage
VDD
VDD
6kI
6kI
DOUT
DOUT
6kI
DOUT
CLOAD
50pF
CLOAD
50pF
DOUT
CLOAD
50pF
6kI
DGND
DGND
DGND
a) HIGH-Z TO VOH AND VOL TO VOH
b) HIGH-Z TO VOL AND VOH TO VOL
Figure 1. Load Circuits for Enable Time
a) VOH TO HIGH-Z
CLOAD
50pF
DGND
b) VOL TO HIGH-Z
Figure 2. Load Circuits for Disable Time
_______________________________________________________________________________________ 7
MAX148/MAX149
Pin Description
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
Detailed Description
The MAX148/MAX149 analog-to-digital converters
(ADCs) use a successive-approximation conversion
technique and input track/hold (T/H) circuitry to convert
an analog signal to a 10-bit digital output. A flexible
serial interface provides easy interface to microprocessors (FPs). Figure 3 is a block diagram of the MAX148/
MAX149.
Pseudo-Differential Input
The sampling architecture of the ADC’s analog comparator is illustrated in the equivalent input circuit (Figure
4). In single-ended mode, IN+ is internally switched to
CH0–CH7, and IN- is switched to COM. In differential
mode, IN+ and IN- are selected from the following
pairs: CH0/CH1, CH2/CH3, CH4/CH5, and CH6/CH7.
Configure the channels with Tables 2 and 3.
In differential mode, IN- and IN+ are internally switched
to either of the analog inputs. This configuration is
pseudo-differential to the effect that only the signal at
IN+ is sampled. The return side (IN-) must remain stable
within Q0.5 LSB (Q0.1 LSB for best results) with respect
to AGND during a conversion. To accomplish this, connect a 0.1FF capacitor from IN- (the selected analog
input) to AGND.
During the acquisition interval, the channel selected as
the positive input (IN+) charges capacitor CHOLD. The
acquisition interval spans three SCLK cycles and ends
on the falling SCLK edge after the last bit of the input
CS
SCLK
DIN
SHDN
VREF
The conversion interval begins with the input multiplexer
switching CHOLD from the positive input (IN+) to the
negative input (IN-). In single-ended mode, IN- is simply
COM. This unbalances node ZERO at the comparator’s
input. The capacitive DAC adjusts during the remainder
of the conversion cycle to restore node ZERO to 0 within
the limits of 10-bit resolution. This action is equivalent to
transferring a 16pF x [(VIN+) - (VIN-)] charge from CHOLD
to the binary-weighted capacitive DAC, which in turn
forms a digital representation of the analog input signal.
Track/Hold
The T/H enters its tracking mode on the falling clock
edge after the fifth bit of the 8-bit control word has been
shifted in. It enters its hold mode on the falling clock
edge after the eighth bit of the control word has been
shifted in. If the converter is set up for single-ended
inputs, IN- is connected to COM, and the converter
samples the “+” input. If the converter is set up for differential inputs, IN- connects to the “-” input, and the
difference of |IN+ - IN-| is sampled. At the end of the
conversion, the positive input connects back to IN+, and
CHOLD charges to the input signal.
The time required for the T/H to acquire an input signal
is a function of how quickly its input capacitance is
charged. If the input signal’s source impedance is high,
the acquisition time lengthens, and more time must be
18
19
17
10
1
2
3
4
5
6
7
8
9
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
COM
REFADJ
control word has been entered. At the end of the acquisition interval, the T/H switch opens, retaining charge on
CHOLD as a sample of the signal at IN+.
12
11
INPUT
SHIFT
REGISTER
CONTROL
LOGIC
CAPACITIVE DAC
INT
CLOCK
VREF
OUTPUT
SHIFT
REGISTER
ANALOG
INPUT
MUX
+1.21V
REFERENCE
(MAX149)
T/H
CLOCK
IN 10+2-BIT
SAR
ADC OUT
REF
A ≈ 2.06*
20kΩ
15
16
20
14
13
+2.500V
MAX148
MAX149
DOUT
SSTRB
VDD
DGND
AGND
CH0
CH1
CH2
CH3
CH4
CH5
CH6
CH7
COM
INPUT
MUX
CHOLD
+
COMPARATOR
ZERO
16pF
CSWITCH
TRACK
RIN
9kΩ
HOLD
T/H
SWITCH
AT THE SAMPLING INSTANT,
THE MUX INPUT SWITCHES
FROM THE SELECTED IN+
CHANNEL TO THE SELECTED
IN- CHANNEL.
SINGLE-ENDED MODE: IN+ = CH0–CH7, IN- = COM.
DIFFERENTIAL MODE: IN+ AND IN- SELECTED FROM PAIRS OF
CH0/CH1, CH2/CH3, CH4/CH5, AND CH6/CH7.
*A ≈ 2.00 (MAX148)
Figure 3. Block Diagram
Figure 4. Equivalent Input Circuit
8 _______________________________________________________________________________________
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
+3V
OSCILLOSCOPE
0.1µF
DGND
SCLK
AGND
MAX148
MAX149
0 TO
+2.500V
ANALOG
INPUT 0.01µF
+3V
CH7
1000pF
MAX872
SSTRB
CS
DOUT*
SCLK
+3V
2.5V
VOUT
COM
REFADJ
VREF
C1
0.1µF
+3V
DIN
2MHz
OSCILLATOR CH1
CH2
CH3
CH4
DOUT
SSTRB
COMP
SHDN
N.C.
OPTIONAL FOR MAX149,
REQUIRED FOR MAX148
*FULL-SCALE ANALOG INPUT, CONVERSION RESULT = $FFF (HEX)
Figure 5. Quick-Look Circuit
allowed between conversions. The acquisition time,
tACQ, is the maximum time the device takes to acquire
the signal, and is also the minimum time needed for the
signal to be acquired. It is calculated by the following
equation:
tACQ = 7 x (RS + RIN) x 16pF
where RIN = 9kI, RS = the source impedance of the
input signal, and tACQ is never less than 1.5Fs. Note that
source impedances below 4kI do not significantly affect
the ADC’s AC performance.
Higher source impedances can be used if a 0.01FF
capacitor is connected to the individual analog inputs.
Note that the input capacitor forms an RC filter with
the input source impedance, limiting the ADC’s signal
bandwidth.
Input Bandwidth
The ADC’s input tracking circuitry has a 2.25MHz
small-signal bandwidth, so it is possible to digitize highspeed transient events and measure periodic signals
with bandwidths exceeding the ADC’s sampling rate
by using undersampling techniques. To avoid highfrequency signals being aliased into the frequency band
of interest, anti-alias filtering is recommended.
Analog Input Protection
Internal protection diodes, which clamp the analog
input to VDD and AGND, allow the channel input pins to
swing from AGND - 0.3V to VDD + 0.3V without damage.
However, for accurate conversions near full scale, the
inputs must not exceed VDD by more than 50mV or be
lower than AGND by 50mV.
If the analog input exceeds 50mV beyond the supplies, do not forward bias the protection diodes of off
channels over 2mA.
Quick Look
To quickly evaluate the MAX148/MAX149’s analog performance, use the circuit of Figure 5. The MAX148/
MAX149 require a control byte to be written to DIN
before each conversion. Tying DIN to +3V feeds in
control bytes of $FF (HEX), which trigger single-ended
unipolar conversions on CH7 in external clock mode
without powering down between conversions. In external
clock mode, the SSTRB output pulses high for one clock
period before the most significant bit of the conversion
result is shifted out of DOUT. Varying the analog input to
CH7 will alter the sequence of bits from DOUT. A total of
15 clock cycles is required per conversion. All transitions
of the SSTRB and DOUT outputs occur on the falling
edge of SCLK.
_______________________________________________________________________________________ 9
MAX148/MAX149
VDD
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
Table 1. Control-Byte Format
BIT 7
(MSB)
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
(LSB)
START
SEL2
SEL1
SEL0
UNI/BIP
SGL//DIF
PD1
PD0
BIT
NAME
7(MSB)
START
6
5
4
SEL2
SEL1
SEL0
These three bits select which of the eight channels are used for the conversion (Tables 2 and 3)
3
UNI/BIP
1 = unipolar, 0 = bipolar. Selects unipolar or bipolar conversion mode. In unipolar mode, an
analog input signal from 0 to VREF can be converted; in bipolar mode, the signal can range from
-VREF/2 to +VREF/2.
2
SGL/DIF
1 = single ended, 0 = differential. Selects single-ended or differential conversions. In singleended mode, input signal voltages are referred to COM. In differential mode, the voltage
difference between two channels is measured (Tables 2 and 3).
1
PD1
0(LSB)
DESCRIPTION
The first logic “1” bit after CS goes low defines the beginning of the control byte.
Selects clock and power-down modes.
PD1
PD0
0
0
Full power-down
0
1
Fast power-down (MAX149 only)
1
0
Internal clock mode
1
1
External clock mode
PD0
Mode
Table 2. Channel Selection in Single-Ended Mode (SGL/DIF = 1)
SEL2
SEL1
SEL0
CH0
0
0
0
+
1
0
0
0
0
1
1
0
1
0
1
0
1
1
0
0
1
1
1
1
1
CH1
CH2
CH3
CH4
CH5
CH6
CH7
COM
-
+
+
How to Start a Conversion
Start a conversion by clocking a control byte into DIN.
With CS low, each rising edge on SCLK clocks a bit from
DIN into the MAX148/MAX149’s internal shift register.
After CS falls, the first arriving logic “1” bit defines the
control byte’s MSB. Until this first “start” bit arrives, any
number of logic “0” bits can be clocked into DIN with no
effect. Table 1 shows the control-byte format.
The MAX148/MAX149 are compatible with SPI/QSPI and
MICROWIRE devices. For SPI, select the correct clock
+
+
+
+
+
-
polarity and sampling edge in the SPI control registers:
set CPOL = 0 and CPHA = 0. MICROWIRE, SPI, and
QSPI all transmit a byte and receive a byte at the same
time. Using the Typical Operating Circuit, the simplest
software interface requires only three 8-bit transfers to
perform a conversion (one 8-bit transfer to configure
the ADC, and two more 8-bit transfers to clock out the
conversion result). See Figure 20 for MAX148/ MAX149
QSPI connections.
10 �������������������������������������������������������������������������������������
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
SEL2
SEL1
SEL0
CH0
CH1
0
0
0
+
-
0
0
1
0
1
0
0
1
1
1
0
0
1
0
1
1
1
0
1
1
1
-
CH2
CH3
+
-
CH4
CH5
+
-
CH6
CH7
+
-
-
+
+
-
+
-
+
CS
tACQ
SCLK
1
DIN
SSTRB
4
SEL2 SEL1 SEL0
8
UNI/ SGL/
BIP DIF PD1
12
16
20
24
PD0
START
RB2
RB1
B9
MSB
DOUT
B8
B7
B6
RB3
B5
B4
B3
B2
B1
B0
LSB
S1
S0
FILLED WITH
ZEROS
ACQUISITION
A/D STATE
IDLE
1.5Fs
CONVERSION
IDLE
(fSCLK = 2MHz)
Figure 6. 24-Clock External Clock Mode Conversion Timing (MICROWIRE and SPI-Compatible, QSPI-Compatible with fSCLK P 2MHz)
Simple Software Interface
Make sure the CPU’s serial interface runs in master
mode so the CPU generates the serial clock. Choose a
clock frequency from 100kHz to 2MHz.
1) Set up the control byte for external clock mode and
call it TB1. TB1 should be of the format: 1XXXXX11
binary, where the Xs denote the particular channel
and conversion mode selected.
2) Use a general-purpose I/O line on the CPU to pull CS
low.
3) Transmit TB1 and, simultaneously, receive a byte
and call it RB1. Ignore RB1.
4) Transmit a byte of all zeros ($00 hex) and, simultaneously, receive byte RB2.
5) Transmit a byte of all zeros ($00 hex) and, simultaneously, receive byte RB3.
6) Pull CS high.
Figure 6 shows the timing for this sequence. Bytes RB2
and RB3 contain the result of the conversion, padded
with one leading zero, two sub-LSB bits, and three
trailing zeros. The total conversion time is a function of
the serial-clock frequency and the amount of idle time
between 8-bit transfers. To avoid excessive T/H droop,
make sure the total conversion time does not exceed
120Fs.
Digital Output
In unipolar input mode, the output is straight binary
(Figure 17). For bipolar input mode, the output is twos
complement (Figure 18). Data is clocked out at the falling edge of SCLK in MSB-first format.
Clock Modes
The MAX148/MAX149 may use either an external serial
clock or the internal clock to perform the successiveapproximation conversion. In both clock modes, the external clock shifts data in and out of the MAX148/MAX149.
______________________________________________________________________________________ 11
MAX148/MAX149
Table 3. Channel Selection in Differential Mode (SGL/DIF = 0)
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
CS
tCSH
tCSS
tCL
tCSH
tCH
SCLK
tDS
tDH
DIN
tDV
tDO
tTR
DOUT
Figure 7. Detailed Serial-Interface Timing
CS
tSDV
tSTR
SSRTB
tSSTRB
tSSTRB
SCLK
PD0 CLOCKED IN
Figure 8. External Clock Mode SSTRB Detailed Timing
The T/H acquires the input signal as the last three bits of
the control byte are clocked into DIN. Bits PD1 and PD0
of the control byte program the clock mode. Figures 7–10
show the timing characteristics common to both modes.
and DOUT go into a high-impedance state when CS goes
high; after the next CS falling edge, SSTRB outputs a
logic-low. Figure 8 shows the SSTRB timing in external
clock mode.
External Clock
In external clock mode, the external clock not only shifts
data in and out, but it also drives the analog-to-digital
conversion steps. SSTRB pulses high for one clock period
after the last bit of the control byte. Successive- approximation bit decisions are made and appear at DOUT on
each of the next 12 SCLK falling edges (Figure 6). SSTRB
The conversion must complete in some minimum time, or
droop on the sample-and-hold capacitors may degrade
conversion results. Use internal clock mode if the serialclock frequency is less than 100kHz, or if serial-clock
interruptions could cause the conversion interval to
exceed 120Fs.
12 �������������������������������������������������������������������������������������
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
MAX148/MAX149
CS
SCLK
1
3
4
5
6
7
8
9
10
11
12
18
19
20
21
22
23
24
SGL/
SEL2 SEL1 SEL0 UNI/
BIP DIF PD1 PD0
DIN
SSTRB
2
START
tCONV
B9
MSB B8
DOUT
AD STATE
IDLE
ACQUISITION
1.5Fs
CONVERSION
7.5Fs MAX
B0
LSB S1
B7
FILLED WITH
S0 ZEROS
IDLE
(fSCLK = 2MHz)(SHDN = UNCONNECTED)
Figure 9. Internal Clock Mode Timing
CS
tCONV
tSCK
tCSH
tCSS
SSTRB
tSSTRB
SCLK
tD0
PD0 CLOCK IN
DOUT
NOTE: FOR BEST NOISE PERFORMANCE, KEEP SCLK LOW DURING CONVERSION.
Figure 10. Internal Clock Mode SSTRB Detailed Timing
Internal Clock
In internal clock mode, the MAX148/MAX149 generate
their own conversion clocks internally. This frees the FP
from the burden of running the SAR conversion clock
and allows the conversion results to be read back at
the processor’s convenience, at any clock rate from 0
to 2MHz. SSTRB goes low at the start of the conversion
and then goes high when the conversion is complete.
SSTRB is low for a maximum of 7.5Fs (SHDN = unconnected), during which time SCLK should remain low for
best noise performance.
An internal register stores data when the conversion
is in progress. SCLK clocks the data out of this register at any time after the conversion is complete. After
SSTRB goes high, the next falling clock edge produces
the MSB of the conversion at DOUT, followed by the
remaining bits in MSB-first format (Figure 9). CS does
not need to be held low once a conversion is started.
Pulling CS high prevents data from being clocked into
the MAX148/MAX149 and three-states DOUT, but it
does not adversely affect an internal clock mode conversion already in progress. When internal clock mode
is selected, SSTRB does not go into a high-impedance
state when CS goes high.
Figure 10 shows the SSTRB timing in internal clock
mode. In this mode, data can be shifted in and out of
the MAX148/MAX149 at clock rates exceeding 2.0MHz if
the minimum acquisition time (tACQ) is kept above 1.5Fs.
Data Framing
The falling edge of CS does not start a conversion. The
first logic high clocked into DIN is interpreted as a start
bit and defines the first bit of the control byte. A conversion starts on SCLK’s falling edge, after the eighth bit of
______________________________________________________________________________________ 13
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
Table 4. Typical Power-Up Delay Times
REFERENCE
BUFFER
REFERENCEBUFFER
COMPENSATION
MODE
VREF
CAPACITOR
(µF)
POWER-DOWN
MODE
Enabled
Internal
—
Enabled
Internal
—
Enabled
External
Enabled
POWER-UP DELAY
(µs)
MAXIMUM
SAMPLING RATE
(ksps)
Fast
5
26
Full
300
26
4.7
Fast
See Figure 14c
133
External
4.7
Full
See Figure 14c
133
Disabled
—
—
Fast
2
133
Disabled
—
—
Full
2
133
the control byte (the PD0 bit) is clocked into DIN. The
start bit is defined as follows:
The first high bit clocked into DIN with CS low any time
the converter is idle; e.g., after VDD is applied.
OR
The first high bit clocked into DIN after bit 3 of a conversion in progress is clocked onto the DOUT pin.
If CS is toggled before the current conversion is complete, the next high bit clocked into DIN is recognized
as a start bit; the current conversion is terminated, and
a new one is started.
The fastest the MAX148/MAX149 can run with CS held
low between conversions is 15 clocks per conversion.
Figure 11a shows the serial-interface timing necessary
to perform a conversion every 15 SCLK cycles in external clock mode. If CS is tied low and SCLK is continuous,
guarantee a start bit by first clocking in 16 zeros.
Most microcontrollers (FCs) require that conversions
occur in multiples of 8 SCLK clocks; 16 clocks per conversion is typically the fastest that a FC can drive the
MAX148/MAX149. Figure 11b shows the serialinterface
timing necessary to perform a conversion every 16 SCLK
cycles in external clock mode.
Applications Information
Power-On Reset
When power is first applied, and if SHDN is not pulled
low, internal power-on reset circuitry activates the
MAX148/MAX149 in internal clock mode, ready to convert with SSTRB = high. After the power supplies stabilize, the internal reset time is 10Fs, and no conversions
should be performed during this phase. SSTRB is high
on power-up and, if CS is low, the first logical 1 on DIN is
interpreted as a start bit. Until a conversion takes place,
DOUT shifts out zeros. Also see Table 4.
Reference-Buffer Compensation
In addition to its shutdown function, SHDN selects internal or external compensation. The compensation affects
both power-up time and maximum conversion speed.
The 100kHz minimum clock rate is limited by droop on
the sample-and-hold and is independent of the compensation used.
Unconnect SHDN to select external compensation. The
Typical Operating Circuit uses a 4.7FF capacitor at VREF.
A 4.7FF value ensures reference-buffer stability and
allows converter operation at the 2MHz full clock speed.
External compensation increases power-up time (see the
Choosing Power-Down Mode section and Table 4).
Pull SHDN high to select internal compensation. Internal
compensation requires no external capacitor at VREF
and allows for the shortest power-up times. The maximum clock rate is 2MHz in internal clock mode and
400kHz in external clock mode.
Choosing Power-Down Mode
You can save power by placing the converter in a lowcurrent shutdown state between conversions. Select full
power-down mode or fast power-down mode via bits 1
and 0 of the DIN control byte with SHDN high or unconnected (Tables 1 and 5). In both software power-down
modes, the serial interface remains operational, but the
ADC does not convert. Pull SHDN low at any time to shut
down the converter completely. SHDN overrides bits 1
and 0 of the control byte.
Full power-down mode turns off all chip functions that
draw quiescent current, reducing supply current to
2FA (typ). Fast power-down mode turns off all circuitry
except the bandgap reference. With fast power-down
mode, the supply current is 30FA. Power-up time can be
shortened to 5Fs in internal compensation mode.
Table 4 shows how the choice of reference-buffer compensation and power-down mode affects both power-up
14 �������������������������������������������������������������������������������������
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
1
8
15
1
8
15
1
SCLK
DIN
S
CONTROL BYTE 0
DOUT
S
CONTROL BYTE 1
S
CONTROL BYTE 2
B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 S1 S0
B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 S1 S0
CONVERSION RESULT 0
CONVERSION RESULT 1
SSTRB
Figure 11a. External Clock Mode, 15 Clocks/Conversion Timing
CS
1
8
16
1
8
16
SCLK
DIN
S
CONTROL BYTE 0
S
B9
DOUT
B8
B7
B6
B5
B4
B3
B2
CONTROL BYTE 1
B1
B0
S1
S0
B9
B8
B7
B6
CONVERSION RESULT 1
CONVERSION RESULT 0
Figure 11b. External Clock Mode, 16 Clocks/Conversion Timing
EXTERNAL
CLOCK
MODE
EXTERNAL
SHDN
SETS SOFTWARE
POWER-DOWN
SETS EXTERNAL
CLOCK MODE
DIN
DOUT
MODE
S X X X X X 1 1
SX X XX X 0 0
10 + 2 DATA BITS
SETS EXTERNAL
CLOCK MODE
S XX XXX 1 1
10 + 2 DATA BITS
VALID
DATA
POWERED UP
POWERED UP
INVALID
DATA
HARDWARE
POWER-DOWN
POWERED UP
SOFTWARE
POWER-DOWN
Figure 12a. Timing Diagram Power-Down Modes, External Clock
delay and maximum sample rate. In external compensation mode, power-up time is 20ms with a 4.7FF compensation capacitor when the capacitor is initially fully
discharged. From fast power-down, startup time can be
eliminated by using low-leakage capacitors that do not
discharge more than ½ LSB while shut down. In powerdown, leakage currents at VREF cause droop on the
reference bypass capacitor. Figures 12a and 12b show
the various power-down sequences in both external and
internal clock modes.
______________________________________________________________________________________ 15
MAX148/MAX149
CS
INTERNAL
CLOCK
MODE
SETS INTERNAL
CLOCK MODE
SETS
POWER-DOWN
5XXXXX00
SXXXXX10
DIN
S
DATA VALID
DOUT
DATA VALID
SSTRB
CONVERSION
CONVERSION
MODE
POWER-DOWN
POWERED OFF
POWERED UP
Figure 12b. Timing Diagram Power-Down Modes, Internal Clock
PD1
PD0
DEVICE MODE
0
0
Full Power-Down
0
1
Fast Power-Down
1
0
Internal Clock
1
1
External Clock
Table 6. Hard-Wired Power-Down and
Internal Clock Frequency
SHDN
STATE
DEVICE
MODE
REFERENCE
BUFFER
COMPENSATION
INTERNAL
CLOCK
FREQUENCY
1
Enabled
Internal
225kHz
Unconnected
Enabled
External
1.8MHz
0
PowerDown
—
—
AVERAGE SUPPLY CURRENT
vs. CONVERSION RATE (USING FULLPD)
AVERAGE SUPPLY CURRENT vs. CONVERSION
RATE WITH EXTERNAL REFERENCE
VREF = VDD = 3.0V
RLOAD = ∞
CODE = 1010101000
1000
100
8 CHANNELS
10
1 CHANNEL
1
100
AVERAGE SUPPLY CURRENT (µA)
MAX148/9-F13
10,000
MAX148/9-F14A
Table 5. Software Power-Down and Clock
Mode
AVERAGE SUPPLY CURRENT (µA)
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
RLOAD = ∞
CODE = 1010101000
8 CHANNELS
10
1 CHANNEL
1
0.1
0.1
1
10
100
1k
10k
100k
1M
CONVERSION RATE (Hz)
Figure 13. Average Supply Current vs. Conversion Rate with
External Reference
0.01
0.1
1
10
100
1k
CONVERSION RATE (Hz)
Figure 14a. MAX149 Supply Current vs. Conversion Rate,
FULLPD
16 �������������������������������������������������������������������������������������
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
MAX148/9-F14B
AVERAGE SUPPLY CURRENT (µA)
10,000
RLOAD = ∞
CODE = 1010101000
1000
8 CHANNELS
1 CHANNEL
100
0
1
0.1
1
10
100
1k
10k
100k
1M
CONVERSION RATE (Hz)
Figure 14b. MAX149 Supply Current vs. Conversion Rate,
FASTPD
TYPICAL REFERENCE-BUFFER POWER-UP
DELAY vs. TIME IN SHUTDOWN
POWER-UP DELAY (ms)
MAX148/9-F14C
2.0
1.5
1.0
0.5
0
0.001
0.01
0.1
1
10
TIME IN SHUTDOWN (s)
Figure 14c. Typical Reference-Buffer Power-Up Delay vs.
Time in Shutdown
Software Power-Down
Software power-down is activated using bits PD1 and
PD0 of the control byte. As shown in Table 5, PD1 and
PD0 also specify the clock mode. When software shutdown is asserted, the ADC operates in the last specified
clock mode until the conversion is complete. Then the
ADC powers down into a low quiescent-current state.
In internal clock mode, the interface remains active
and conversion results may be clocked out after the
MAX148/MAX149 enter a software power-down.
The first logical 1 on DIN is interpreted as a start bit and
powers up the MAX148/MAX149. Following the start bit, the
data input word or control byte also determines clock mode
and power-down states. For example, if the DIN word contains PD1 = 1, then the chip remains powered up. If PD0
= PD1 = 0, a power-down resumes after one conversion.
Hardware Power-Down
Pulling SHDN low places the converter in hardware power-down (Table 6). Unlike software power-down mode, the
conversion is not completed; it stops coincidentally with
SHDN being brought low. SHDN also controls the clock
frequency in internal clock mode. Leaving SHDN unconnected sets the internal clock frequency to 1.8MHz. When
returning to normal operation with SHDN unconnected,
there is a tRC delay of approximately 2MI x CL, where CL
is the capacitive loading on the SHDN pin. Pulling SHDN
high sets internal clock frequency to 225kHz. This feature
eases the settling-time requirement for the reference voltage. With an external reference, the MAX148/MAX149
can be considered fully powered up within 2Fs of actively
pulling SHDN high.
Power-Down Sequencing
The MAX148/MAX149 auto power-down modes can
save considerable power when operating at less than
maximum sample rates. Figures 13, 14a, and 14b show
the average supply current as a function of the sampling
rate. The following discussion illustrates the various
power-down sequences.
Lowest Power at Up to 500
Conversions/Channel/Second
The following examples show two different power-down
sequences. Other combinations of clock rates, compensation modes, and power-down modes may give lowest
power consumption in other applications.
Figure 14a depicts the MAX149 power consumption for
one or eight channel conversions utilizing full powerdown mode and internal-reference compensation. A
0.01FF bypass capacitor at REFADJ forms an RC filter
with the internal 20kI reference resistor with a 0.2ms
time constant. To achieve full 10-bit accuracy, 8 time
constants or 1.6ms are required after power-up. Waiting
this 1.6ms in FASTPD mode instead of in full power-up
can reduce power consumption by a factor of 10 or
more. This is achieved by using the sequence shown in
Figure 15.
______________________________________________________________________________________ 17
MAX148/MAX149
AVERAGE SUPPLY CURRENT
vs. CONVERSION RATE (USING FASTPD)
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
COMPLETE CONVERSION SEQUENCE
1.6ms WAIT
DIN
1
(ZEROS)
00
FULLPD
1
0 1
FASTPD
CH1
(ZEROS)
CH7
1
1 1
1
0 0
1
FULLPD
NOPD
0 1
FASTPD
1.21V
0
REFADJ
H = RC = 20kI x CREFADJ
2.50V
0
VREF
tBUFFEN = 75Fs
Figure 15. MAX149 FULLPD/FASTPD Power-Up Sequence
+3.3V
OUTPUT CODE
24kI
MAX149
510kI
100kI
12
REFADJ
TRANSITION
11...111
FULL-SCALE
TRANSITION
11...110
11...101
0.01µF
FS = VREF + COM
ZS = COM
Figure 16. MAX149 Reference-Adjust Circuit
1 LSB =
VREF
1024
00...011
Lowest Power at Higher Throughputs
Figure 14b shows the power consumption with externalreference compensation in fast power-down, with one
and eight channels converted. The external 4.7FF compensation requires a 75Fs wait after power-up with one
dummy conversion. This graph shows fast multichannel
conversion with the lowest power consumption possible.
Full power-down mode may provide increased power
savings in applications where the MAX148/MAX149 are
inactive for long periods of time, but where intermittent
bursts of high-speed conversions are required.
Internal and External References
The MAX149 can be used with an internal or external
reference voltage, whereas an external reference is
required for the MAX148. An external reference can be
connected directly at VREF or at the REFADJ pin.
An internal buffer is designed to provide 2.5V at VREF
for both the MAX149 and the MAX148. The MAX149’s
internally trimmed 1.21V reference is buffered with a
2.06 gain. The MAX148’s REFADJ pin is also buffered
with a 2.00 gain to scale an external 1.25V reference at
REFADJ to 2.5V at VREF.
00...010
00...001
00...000
0
(COM)
1
2
FS
3
INPUT VOLTAGE (LSB)
FS - 3/2 LSB
Figure 17. Unipolar Transfer Function, Full Scale (FS) = VREF
+ COM, Zero Scale (ZS) = COM
Internal Reference (MAX149)
The MAX149’s full-scale range with the internal reference is 2.5V with unipolar inputs and Q1.25V with bipolar
inputs. The internal reference voltage is adjustable to
Q1.5% with the circuit in Figure 16.
External Reference
With both the MAX149 and MAX148, an external reference can be placed at either the input (REFADJ) or the
output (VREF) of the internal reference-buffer amplifier.
The REFADJ input impedance is typically 20kI for the
MAX149, and higher than 100kI for the MAX148. At
VREF, the DC input resistance is a minimum of 18kI.
During conversion, an external reference at VREF must
18 �������������������������������������������������������������������������������������
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
UNIPOLAR MODE
BIPOLAR MODE
Full Scale
Zero Scale
Positive Full Scale
Zero Scale
Negative Full Scale
VREF + COM
COM
VREF/2 + COM
COM
-VREF/2 + COM
OUTPUT CODE
VREF
+ COM
2
011 . . . 111
FS =
011 . . . 110
ZS = COM
000 . . . 010
000 . . . 001
-FS =
-VREF
+ COM
2
1LSB =
000 . . . 000
SUPPLIES
+3V
VREF
1024
+3V
GND
+3V
DGND
R* = 10Ω
111 . . . 111
111 . . . 110
111 . . . 101
VDD
AGND
COM
DGND
DIGITAL
CIRCUITRY
100 . . . 001
MAX148
MAX149
100 . . . 000
- FS
COM*
+FS - 1LSB
*OPTIONAL
INPUT VOLTAGE (LSB)
*COM ≥ VREF/2
Figure 18. Bipolar Transfer Function, Full Scale (FS) = VREF/2
+ COM, Zero Scale (ZS) = COM
deliver up to 350FA DC load current and have 10I or
less output impedance. If the reference has a higher output impedance or is noisy, bypass it close to the VREF
pin with a 4.7FF capacitor.
Using the REFADJ input makes buffering the external
reference unnecessary. To use the direct VREF input,
disable the internal buffer by tying REFADJ to VDD.
In power-down, the input bias current to REFADJ is
typically 25FA (MAX149) with REFADJ tied to VDD. Pull
REFADJ to AGND to minimize the input bias current in
power-down.
Figure 19. Power-Supply Grounding Connection
Transfer Function
Table 7 shows the full-scale voltage ranges for unipolar
and bipolar modes.
The external reference must have a temperature coefficient of 20ppm/NC or less to achieve accuracy to within
1 LSB over the 0NC to +70NC commercial temperature
range.
Figure 17 depicts the nominal, unipolar input/output
(I/O) transfer function, and Figure 18 shows the bipolar
input/output transfer function. Code transitions occur
halfway between successive-integer LSB values. Output
coding is binary, with 1 LSB = 2.44mV (2.500V/1024)
for unipolar operation, and 1 LSB = 2.44mV [(2.500V/2 -2.500V/2)/1024] for bipolar operation.
______________________________________________________________________________________ 19
MAX148/MAX149
Table 7. Full Scale and Zero Scale
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
+3V +3V
0.1µF
ANALOG
INPUTS
1µF
VDD
20
(POWER SUPPLIES)
SCLK
19
SCK
CS
18
PCS0
DIN
17
MOSI
CH4
SSTRB
16
6
CH5
DOUT
15
7
CH6
DGND
14
8
CH7
AGND
13
9
COM
REFADJ
12
10
SHDN
VREF
11
1
CH0
2
CH1
3
4
CH2 MAX148
MAX149
CH3
5
MC683XX
MISO
(GND)
0.1µF
+2.5V
Figure 20. MAX148/MAX149 QSPI Connections, External Reference
Layout, Grounding, and Bypassing
XF
CLKX
For best performance, use PCBs. Wire-wrap boards
are not recommended. Board layout should ensure that
digital and analog signal lines are separated from each
other. Do not run analog and digital (especially clock)
lines parallel to one another, or digital lines underneath
the ADC package.
CS
SCLK
TMS320LC3x
MAX148
MAX149
CLKR
DX
DIN
DR
DOUT
FSR
SSTRB
Figure 21. MAX148/MAX149-to-TMS320 Serial Interface
Figure 19 shows the recommended system ground connections. Establish a single-point analog ground (star
ground point) at AGND, separate from the logic ground.
Connect all other analog grounds and DGND to the star
ground. No other digital system ground should be connected to this ground. For lowest-noise operation, the
ground return to the star ground’s power supply should
be low impedance and as short as possible.
High-frequency noise in the VDD power supply may
affect the high-speed comparator in the ADC. Bypass
the supply to the star ground with 0.1FF and 1FF capacitors close to pin 20 of the MAX148/MAX149. Minimize
capacitor lead lengths for best supply-noise rejection.
If the power supply is very noisy, a 10I resistor can be
connected as a lowpass filter (Figure 19).
20 �������������������������������������������������������������������������������������
8-string WLED Driver with Integrated Step-up
Regulator and SMBus/PWM Dimming Capability
SCLK
DIN
START
SEL2
SEL1
SEL0
UNI/BIP
SGL/DIF
PD1
PD0
HIGH
IMPEDANCE
SSTRB
DOUT
MSB
B8
S1
S0
HIGH
IMPEDANCE
Figure 22. TMS320 Serial-Interface Timing Diagram
High-Speed Digital Interfacing with QSPI
The MAX148/MAX149 can interface with QSPI using the
circuit in Figure 20 (fSCLK = 2.0MHz, CPOL = 0, CPHA =
0). This QSPI circuit can be programmed to do a conversion on each of the eight channels. The result is stored
in memory without taxing the CPU, since QSPI incorporates its own microsequencer.
The MAX148/MAX149 are QSPI compatible up to the
maximum external clock frequency of 2MHz.
TMS320LC3x Interface
Figure 21 shows an application circuit to interface the
MAX148/MAX149 to the TMS320 in external clock mode.
The timing diagram for this interface circuit is shown in
Figure 22.
Use the following steps to initiate a conversion in the
MAX148/MAX149 and to read the results:
1) The TMS320 should be configured with CLKX (transmit clock) as an active-high output clock and CLKR
(TMS320 receive clock) as an active-high input
clock. CLKX and CLKR on the TMS320 are tied
together with the MAX148/MAX149’s SCLK input.
2) The MAX148/MAX149’s CS pin is driven low by the
TMS320’s XF_ I/O port to enable data to be clocked
into the MAX148/MAX149’s DIN.
3) An 8-bit word (1XXXXX11) should be written to the
MAX148/MAX149 to initiate a conversion and place
the device into external clock mode. See Table 1 to
select the proper XXXXX bit values for your specific
application.
4) The MAX148/MAX149’s SSTRB output is monitored
through the TMS320’s FSR input. A falling edge on
the SSTRB output indicates that the conversion is in
progress and data is ready to be received from the
MAX148/MAX149.
5) The TMS320 reads in one data bit on each of the
next 16 rising edges of SCLK. These data bits represent the 10 + 2-bit conversion result followed by 4
trailing bits, which should be ignored.
6) Pull CS high to disable the MAX148/MAX149 until
the next conversion is initiated.
______________________________________________________________________________________ 21
MAX148/MAX149
CS
MAX148/MAX149
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
Ordering Information (continued)
Pin Configuration
TEMP RANGE
PINPACKAGE
INL
(LSB)
MAX148AEPP
-40°C to +85°C
20 Plastic DIP
±1/2
MAX148BEPP
-40°C to +85°C
20 Plastic DIP
±1
CHO
1
11 VDD
MAX148AEAP
-40°C to +85°C
20 SSOP
±1/2
CH1
2
12 SCLK
MAX148BEAP
-40°C to +85°C
20 SSOP
±1
3
MAX148AMJP
-55°C to +125°C
20 CERDIP*
±1/2
CH2
MAX148BMJP
-55°C to +125°C
20 CERDIP*
±1
CH3
4
MAX149ACPP
0°C to +70°C
20 Plastic DIP
±1/2
CH4
5
MAX149BCPP
0°C to +70°C
20 Plastic DIP
±1
CH5
6
16 DOUT
MAX149ACAP
0°C to +70°C
±1/2
CH6
7
17 DGND
MAX149BCAP
0°C to +70°C
20 SSOP
20 Plastic DIP
CH7
8
18 AGND
MAX149AEPP
-40°C to +85°C
20 Plastic DIP
±1/2
COM
9
19 REFADJ
PART†
TOP VIEW
±1
MAX149BEPP
-40°C to +85°C
20 Plastic DIP
±1
MAX149AEAP
-40°C to +85°C
20 SSOP
±1/2
MAX149BEAP
-40°C to +85°C
20 SSOP
±1
MAX149AMJP
-55°C to +125°C
20 CERDIP*
±1/2
MAX149BMAP/PR
-55°C to +125°C
20 SSOP
±1
MAX149BMJP
-55°C to +125°C
20 CERDIP*
±1
†Contact factory for availability of alternate surface-mount
package. Specify lead-free by placing + by the part number
when ordering.
*Contact factory for availability of CERDIP package, and for
processing to MIL-STD-883B. Not available in lead-free.
13 CS
MAX148
MAX149
SHDN 10
14 DIN
15 SSTRB
20 VREF
DIP/SSOP
Package Information
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
20 Plastic Dip
P20-4
21-0043
20 SSOP
A20-1
21-0056
20 CERDIP
J20-2
21-0045
22 �������������������������������������������������������������������������������������
+2.7V to +5.25V, Low-Power, 8-Channel,
Serial 10-Bit ADCs
REVISION
NUMBER
REVISION
DATE
3
5/09
DESCRIPTION
Revised Ordering Information, Electrical Characteristics table, Pin
Description, Figure 9, added ruggedized plastic information.
PAGES
CHANGED
1–4, 7, 13, 14, 16, 17,
22–23
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied.
Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
©
2009 Maxim Integrated Products
23
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX148/MAX149
Revision History
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