ETC ADS1252U/2K5

ADS1252
ADS
125
2
www.ti.com
24-Bit, 40kHz
ANALOG-TO-DIGITAL CONVERTER
FEATURES
DESCRIPTION
● 24 BITS—NO MISSING CODES
● 19 BITS EFFECTIVE RESOLUTION UP TO
40kHz DATA RATE
● LOW NOISE: 2.5ppm
● DIFFERENTIAL INPUTS
● INL: 0.0015% (max)
● EXTERNAL REFERENCE (0.5V to 5V)
● POWER-DOWN MODE
● SYNC MODE
The ADS1252 is a precision, wide dynamic range,
delta-sigma, Analog-to-Digital (A/D) converter with
24-bit resolution operating from a single +5V supply.
The delta-sigma architecture is used for wide dynamic
range and to guarantee 24 bits of no missing codes
performance. An effective resolution of 19 bits (2.5ppm
of rms noise) is achieved for conversion rates up to
40kHz.
The ADS1252 is designed for high-resolution measurement applications in cardiac diagnostics, smart
transmitters, industrial process control, weight scales,
chromatography, and portable instrumentation. The
converter includes a flexible, two-wire synchronous
serial interface for low-cost isolation.
The ADS1252 is a single-channel converter and is
offered in an SO-8 package.
APPLICATIONS
●
●
●
●
●
●
CARDIAC DIAGNOSTICS
DIRECT THERMOCOUPLE INTERFACES
BLOOD ANALYSIS
INFRARED PYROMETERS
LIQUID/GAS CHROMATOGRAPHY
PRECISION PROCESS CONTROL
ADS1252
VREF
CLK
+VIN
–VIN
4th-Order
∆Σ
Modulator
Digital
Filter
Serial
Interface
SCLK
DOUT/DRDY
+VDD
GND
Control
Copyright © 2000, Texas Instruments Incorporated
SBAS127A
Printed in U.S.A. November, 2000
SPECIFICATIONS
All specifications at TMIN to TMAX, VDD = +5V, CLK = 16MHz, and VREF = 4.096, unless otherwise specified.
ADS1252U
PARAMETER
ANALOG INPUT
Input Voltage Range
Input Impedance
Input Capacitance
Input Leakage
CONDITIONS
PERFORMANCE OVER TEMPERATURE
Offset Drift
Gain Drift
POWER-SUPPLY REQUIREMENTS
Operation
Quiescent Current
Operating Power
Power-Down Current
TEMPERATURE RANGE
Operating
Storage
79
300
19
20
5
At +25°C
At TMIN to TMAX
MAX
UNITS
±VREF
V
MΩ
kΩ
kΩ
pF
pA
nA
50
1
41.7
–3dB
9
16
16
±0.0003
97
2.5
1kHz Input; 0.1dB below FS
at DC
24
24
90
VREF = 4.096V ±0.1V
60
CLK
CLK
CLK
CLK
=
=
=
<
±0.0015
3.8
100
0.4
±100
1:1
80
1
±200
0.5
kHz
kHz
MHz
MHz
% of FSR
dB
ppm of FSR, rms
Bits
Bits
dB
% of FSR
ppm of FSR
dB
0.07
7.5
5.2
3.9
3.4
16MHz
14MHz
12MHz
10MHz
VOLTAGE REFERENCE
VREF
Load Current
DIGITAL INPUT/OUTPUT
Logic Family
Logic Level: VIH
VIL
VOH
VOL
Input (SCLK, CLK) Hysteresis
Data Format
TYP
0
CLK = 3,840Hz
CLK = 1MHz
CLK = 16MHz
DYNAMIC CHARACTERISTICS
Data Rate
Bandwidth
Serial Clock (SCLK)
System Clock Input (CLK)
ACCURACY
Integral Non-Linearity(1)
THD
Noise
Resolution
No Missing Codes
Common-Mode Rejection(2)
Gain Error
Offset Error
Gain Sensitivity to VREF
Power-Supply Rejection Ratio
MIN
ppm/°C
ppm/°C
ppm/°C
ppm/°C
ppm/°C
4.096
220
VDD
V
µA
+VDD + 0.3
+0.8
V
V
V
V
V
CMOS
IOH = –500µA
IOL = 500µA
+4.0
–0.3
+4.5
0.4
0.6
Offset Binary Two’s Complement
+4.75
VDD = +5VDC
+5
8
40
1
–40
–60
+5.25
10
50
10
VDC
mA
mW
µA
+85
+100
°C
°C
NOTES: (1) Applies to full-differential signals. (2) The common-mode rejection test is performed with a 100mV differential input.
2
ADS1252
SBAS127A
PIN CONFIGURATION
PIN DESCRIPTIONS
Top View
+VIN
–VIN
SO-8
8
1
2
PIN
NAME
1
+VIN
Analog Input: Positive Input of the Differential Analog Input.
2
–VIN
Analog Input: Negative Input of the Differential Analog Input.
3
+VDD
Input: Power Supply Voltage, +5V.
4
CLK
Digital Input: Device System Clock. The
system clock is in the form of a CMOScompatible clock. This is a Schmitt-Trigger
input.
5
DOUT/DRDY
Digital Output: Serial Data Output/Data
Ready. A logic LOW on this output indicates that a new output word is available
from the ADS1252 data output register.
The serial data is clocked out of the serial
data output shift register using SCLK.
6
SCLK
Digital Input: Serial Clock. The serial clock
is in the form of a CMOS-compatible clock.
The serial clock operates independently
from the system clock, therefore, it is possible to run SCLK at a higher frequency
than CLK. The normal state of SCLK is
LOW. Holding SCLK HIGH will either initiate a modulator reset for synchronizing
multiple converters or enter power-down
mode. This is a Schmitt-Trigger input.
7
GND
Input: Ground.
8
VREF
Analog Input: Reference Voltage Input.
VREF
7
GND
ADS1252U
+VDD
3
6
SCLK
CLK
4
5
DOUT/DRDY
PIN DESCRIPTION
ELECTROSTATIC
DISCHARGE SENSITIVITY
ABSOLUTE MAXIMUM RATINGS
Analog Input: Current ............................................... ±100mA, Momentary
±10mA, Continuous
Voltage .................................... GND – 0.3V to VDD + 0.3V
VDD to GND ............................................................................ –0.3V to 6V
VREF Voltage to GND ............................................... –0.3V to VDD + 0.3V
Digital Input Voltage to GND ................................... –0.3V to VDD + 0.3V
Digital Output Voltage to GND ................................. –0.3V to VDD + 0.3V
Lead Temperature (soldering, 10s) .............................................. +300°C
Power Dissipation (any package) ................................................. 500mW
This integrated circuit can be damaged by ESD. Burr-Brown
recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and
installation procedures can cause damage.
Electrostatic discharge can cause damage ranging from
performance degradation to complete device failure. BurrBrown Corporation recommends that all integrated circuits be
handled and stored using appropriate ESD protection
methods.
PACKAGE/ORDERING INFORMATION
PRODUCT
PACKAGE
PACKAGE
DRAWING
NUMBER
ADS1252U
SO-8
182
–40°C to +85°C
ADS1252U
"
"
"
"
"
SPECIFIED
TEMPERATURE
RANGE
PACKAGE
MARKING
ORDERING
NUMBER(1)
TRANSPORT
MEDIA
ADS1252U
ADS1252U/2K5
Rails
Tape and Reel
NOTE: (1) Models with a slash (/) are available only in Tape and Reel in the quantities indicated (e.g., /2K5 indicates 2500 devices per reel). Ordering 2500 pieces
of “ADS1252U/2K5” will get a single 2500-piece Tape and Reel.
ADS1252
SBAS127A
3
TYPICAL PERFORMANCE CURVES
At TA = +25°C, VDD = +5V, CLK = 16MHz, and VREF = 4.096, unless otherwise specified.
RMS NOISE vs DATA OUTPUT RATE
EFFECTIVE RESOLUTION vs DATA OUTPUT RATE
3.0
19.5
Effective Resolution (Bits)
RMS Noise (ppm of FS)
2.5
2.0
1.5
1.0
0.5
19.25
19
18.75
0
18.5
100
1k
10k
100
100k
1k
10k
100k
Data Output Rate (Hz)
Data Output Rate (Hz)
RMS NOISE vs TEMPERATURE
EFFECTIVE RESOLUTION vs TEMPERATURE
3.0
19.0
18.9
Effective Resolution (Bits)
RMS Noise (ppm of FS)
2.5
2.0
1.5
1.0
0.5
18.8
18.7
18.6
18.5
18.4
18.3
18.2
18.1
0
18.0
–40
–20
0
20
40
60
–40
80 100
–20
40
60
80 100
25
2.5
20
RMS Noise (µV)
RMS Noise (ppm of FS)
20
RMS NOISE µV vs VREF
RMS NOISE vs INPUT VOLTAGE
3.0
2.0
1.5
1.0
15
10
5
0.5
0
0
–40
–20
0
20
40
Differential Input Voltage (V)
4
0
Temperature (°C)
Temperature (°C)
60
80
0
1
2
3
4
5
6
VREF (V)
ADS1252
SBAS127A
TYPICAL PERFORMANCE CURVES (Cont.)
At TA = +25°C, VDD = +5V, CLK = 16MHz, and VREF = 4.096, unless otherwise specified.
EFFECTIVE RESOLUTION vs VREF
RMS NOISE vs VREF
19
10
8
Effective Resolution (Bits)
RMS Noise (ppm of FS)
9
7
6
5
4
3
2
18.5
18
17.5
17
1
0
16.5
0
1
2
3
4
5
6
0
1
2
3
VREF (V)
4
5
6
VREF (V)
INTEGRAL NON-LINEARITY vs TEMPERATURE
INTEGRAL NON-LINEARITY vs DATA OUTPUT RATE
4
4
3.5
3
INL (ppm of FS)
INL (ppm of FS)
3
2.5
2
1.5
2
1
1
0.5
0
–40
0
–20
0
20
40
60
80
100
100
1k
Temperature (°C)
10k
GAIN DRIFT vs TEMPERATURE
OFFSET DRIFT vs TEMPERATURE
800
10
8
CLK = 16MHz
600
6
4
400
Drift (ppm)
Offset Drift (ppm of FS)
100k
Data Output Rate (Hz)
2
0
–2
CLK = 14.3MHz
200
CLK < 10MHz
0
–4
CLK < 10MHz
–6
–200
–8
CLK = 16MHz
–10
–40
–20
0
20
40
Temperature (°C)
ADS1252
SBAS127A
60
80
100
–400
–40
–20
0
20
40
60
80
100
Temperature (°C)
5
TYPICAL PERFORMANCE CURVES (Cont.)
At TA = +25°C, VDD = +5V, CLK = 16MHz, and VREF = 4.096, unless otherwise specified.
POWER SUPPLY REJECTION RATIO
vs CLK FREQUENCY
COMMON-MODE REJECTION RATIO
vs CLK FREQUENCY
100
110
95
105
85
CMRR (dB)
PSRR (dB)
90
80
75
100
95
90
70
85
65
60
80
0
5
10
15
20
0
5
10
CLK Frequency (MHz)
20
POWER DISSIPATION vs CLOCK FREQUENCY
CURRENT vs TEMPERATURE
9.5
45
9.0
40
8.5
35
Power Dissipation (mW)
Supply Current (mA)
15
CLK Frequency (MHz)
8.0
7.5
7.0
6.5
6.0
30
25
20
15
10
5
5.5
0
5.0
–40
–20
0
20
40
60
80
0
100
5
10
15
20
CLK Frequency (MHz)
Temperature (°C)
TYPICAL FFT ANALYSIS
OF THE 1kHz fS INPUT SIGNAL
0
Dynamic Range (dB)
–20
–40
–60
–80
–100
–120
–140
–160
–180
0
2000
4000
6000
8000
10000 12000
14000
Imput Signal Frequency (Hz)
6
ADS1252
SBAS127A
THEORY OF OPERATION
The ADS1252 is a precision, high-dynamic range, 24-bit,
delta-sigma, A/D converter capable of achieving very
high-resolution digital results at high data rates.
The analog-input signal is sampled at a rate determined by the
frequency of the system clock (CLK). The sampled analog
input is modulated by the delta-sigma A/D modulator, which
is followed by a digital filter. A sinc5 digital low-pass filter
processes the output of the delta-sigma modulator and writes
the result into the data-output register. The DOUT/DRDY pin
is pulled LOW, indicating that new data is available to be read
by the external microcontroller/microprocessor. As shown in
the block diagram, the main functional blocks of the ADS1252
are the fourth-order delta-sigma modulator, a digital filter,
control logic, and a serial interface. Each of these functional
blocks is described below.
ANALOG INPUT
The ADS1252 contains a fully differential analog input. In
order to provide low system noise, common-mode rejection
of 100dB and excellent power-supply rejection, the design
topology is based on a fully differential switched-capacitor
architecture. The bipolar input voltage range is from –4.096
to +4.096V, when the reference input voltage equals +4.096V.
The bipolar range is with respect to –VIN, and not with
respect to GND.
Figure 1 shows the basic input structure of the ADS1252.
The impedance is directly related to the sampling frequency
of the input capacitor which is set by the CLK rate. Higher
CLK rates result in lower impedance, and lower CLK rates
result in higher impedance.
BIPOLAR INPUT
The differential inputs of the ADS1252 were designed to
accept differential inputs. However, each analog input voltage must stay between –0.3V and VDD. With a reference
voltage at less than half of VDD, one input can be tied to the
reference voltage, and the other input can range from 0 to
2 • VREF. By using a single op amp circuit featuring a single
amplifier and four external resistors, the ADS1252 can be
configured to accept bipolar inputs referenced to ground.
The conventional ±2.5V, ±5V, and ±10V input ranges can
be interfaced to the ADS1252 using the resistor values
shown in Figure 2.
R1
RSW
(300Ω typical)
Internal
Circuitry
AIN
Modulator Frequency
= fMOD
With regard to the analog-input signal, the overall analog
performance of the device is affected by three items: first,
the input impedance can affect accuracy. If the source
impedance of the input signal is significant, or if there is
passive filtering prior to the ADS1252, a significant portion
of the signal can be lost across this external impedance. The
magnitude of the effect is dependent on the desired system
performance.
Second, the current into or out of the analog inputs must be
limited. Under no conditions should the current into or out
of the analog inputs exceed 10mA.
Third, to prevent aliasing of the input signal, the bandwidth
of the analog-input signal must be band limited; the bandwidth is a function of the system clock frequency. With a
system clock frequency of 16MHz, the data-output rate is
41.667kHz with a –3dB frequency of 9kHz. The –3dB
frequency scales with the system clock frequency.
To guarantee the best linearity of the ADS1252, a fully
differential signal is recommended.
CINT
(20pF typical)
10kΩ
+IN
OPA2350
20kΩ
Bipolar Input
ADS1252
–IN
VCM
VREF
R2
FIGURE 1. Analog-Input Structure.
OPA2350
The input impedance of the analog input changes with
ADS1252 system clock frequency (CLK). The relationship is:
AIN Impedance (Ω) = (16MHz/CLK) • 19,000
BIPOLAR INPUT
R1
R2
±10V
±5V
±2.5V
2.5kΩ
5kΩ
10kΩ
5kΩ
10kΩ
20kΩ
REF
2.5V
FIGURE 2. Level Shift Circuit for Bipolar Input Ranges.
ADS1252
SBAS127A
7
DELTA-SIGMA MODULATOR
REFERENCE INPUT
The ADS1252 operates from a nominal system clock frequency of 16MHz. The modulator frequency is fixed in
relation to the system clock frequency. The system clock
frequency is divided by 6 to derive the modulator frequency.
Therefore, with a system clock frequency of 16MHz, the
modulator frequency is 2.667MHz. Furthermore, the
oversampling ratio of the modulator is fixed in relation to the
modulator frequency. The oversampling ratio of the modulator is 64, and with the modulator frequency running at
2.667MHz, the data rate is 41.667kHz. Using a slower
system clock frequency will result in a lower data output
rate, as shown in Table I.
Reference input takes an average current of 220µA with a
16MHz system clock. This current will be proportional to
the system clock. A buffered reference is recommended for
ADS1252. The recommended reference circuit is shown in
Figure 3.
Reference voltages higher than 4.096V will increase the
full-scale range, while the absolute internal circuit noise of
the converter remains the same. This will decrease the noise
in terms of ppm of full scale, which increases the effective
resolution (see the Typical Performance Curve “RMS Noise
vs VREF”).
CLK (MHz)
DIGITAL FILTER
The digital filter of the ADS1252, referred to as a sinc5 filter,
computes the digital result based on the most recent outputs
from the delta-sigma modulator. At the most basic level, the
digital filter can be thought of as simply averaging the
modulator results in a weighted form and presenting this
average as the digital output. The digital output rate, or data
rate, scales directly with the system CLK frequency. This
allows the data output rate to be changed over a very wide
range (five orders of magnitude) by changing the system
CLK frequency. However, it is important to note that the
–3dB point of the filter is 0.216 times the data output rate,
so the data output rate should allow for sufficient margin to
prevent attenuation of the signal of interest.
Since the conversion result is essentially an average, the
data-output rate determines the location of the resulting
notches in the digital filter (see Figure 4). Note that the first
notch is located at the data-output rate frequency, and
subsequent notches are located at integer multiples of the
data-output rate to allow for rejection of not only the
fundamental frequency, but also harmonic frequencies. In
this manner, the data-output rate can be used to set specific
notch frequencies in the digital filter response.
For example, if the rejection of power-line frequencies is
desired, then the data-output rate can simply be set to the
power-line frequency. For 50Hz rejection, the system CLK
DATA OUTPUT RATE (Hz)
16.000(1)
15.360(1)
15.000(1)
14.745600(1)
14.318180(1)
12.288000(1)
12.000000(1)
11.059220(1)
10.000000(1)
9.600000
7.372800(1)
6.144000(1)
6.000000(1)
4.915200(1)
3.686400(1)
3.072000(1)
2.457600(1)
1.843200(1)
0.921600
0.460800
0.384000
0.192000
0.038400
0.023040
0.019200
0.011520
0.009600
0.007680
0.006400
0.005760
0.004800
0.003840
NOTE: (1) Standard Clock Oscillator.
41,667
40,000
30,063
38,400
37,287
32,000
31,250
28,800
26,042
25,000
19,200
16,000
15,625
12,800
9,600
8,000
6,400
4,800
2,400
1,200
1,000
500
100
60
50
30
25
20
16.67
15
12.50
10
TABLE I. CLK Rate versus Data Output Rate.
+5V
+5V
0.10µF
7
4.99kΩ
2
To VREF
Pin 8 of
the ADS1252
6
10kΩ
3
1
OPA350
+
+
LM404-4.1
10µF
0.10µF
10µF
0.1µF
4
FIGURE 3. Recommended External Voltage Reference Circuit for Best Low-Noise Operation with the ADS1252.
8
ADS1252
SBAS127A
frequency should be 19.200kHz, this will set the data-output
rate to 50Hz (see Table I and Figure 5). For 60Hz rejection,
the system CLK frequency should be 20.040kHz, this will
set the data-output rate to 60Hz (see Table I and Figure 6).
If both 50Hz and 60Hz rejection is required, then the system
CLK should be 3.840kHz; this will set the data-output rate
to 10Hz and reject both 50Hz and 60Hz (See Table I and
Figure 7).
There is an additional benefit in using a lower data-output
rate. It provides better rejection of signals in the frequency
band of interest. For example, with a 50Hz data-output rate,
a significant signal at 75Hz may alias back into the passband
at 25Hz. This is due to the fact that rejection at 75Hz may
only be 66dB in the stopband—frequencies higher than the
first-notch frequency (see Figure 5). However, setting the
data-output rate to 10Hz will provide 135dB rejection at
75Hz (see Figure 7). A similar benefit is gained at frequencies near the data-output rate (see Figures 8, 9, 10, and 11).
For example, with a 50Hz data-output rate, rejection at 55Hz
may only be 105dB (see Figure 8). However, with a 10Hz
data-output rate, rejection at 55Hz will be 122dB (see Figure
9). If a slower data-output rate does not meet the system
requirements, then the analog front end can be designed to
provide the needed attenuation to prevent aliasing. Additionally, the data-output rate may be increased and additional
digital filtering may be done in the processor or controller.
The digital filter is described by the following transfer
function:
 π • f • 64 
sin 

 fMOD 
H( f ) =
 π•f 
64 • sin 

 fMOD 
or
 1 – z –64
H( z ) = 
 64 • 1 – z –1

(
ADS1252
SBAS127A
)




5
5
The digital filter requires five conversions to fully settle. The
modulator has an oversampling ratio of 64, therefore, it
requires 5 • 64, or 320 modulator results, or clocks, to fully
settle. Since the modulator clock is derived from the system
clock (CLK) (modulator clock = CLK ÷ 6), the number of
system clocks required for the digital filter to fully settle is
5 • 64 • 6, or 1920 CLKs. This means that any significant
step change at the analog input requires five full conversions
to settle. However, if the analog input change occurs asynchronously to the DOUT/DRDY pulse, six conversions are
required to ensure full settling.
CONTROL LOGIC
The control logic is used for communications and control of
the ADS1252.
Power-Up Sequence
Prior to power-up, all digital and analog-input pins must be
LOW. At the time of power-up, these signal inputs can be
biased to a voltage other than 0V, however, they should
never exceed +VDD.
Once the ADS1252 powers up, the DOUT/DRDY line will
pulse LOW on the first conversion. This data will not be
valid. The sixth pulse of DOUT/DRDY will be valid data
from the analog input signal.
DOUT/DRDY
The DOUT/DRDY output signal alternates between two
modes of operation. The first mode of operation is the Data
Ready mode (DRDY) to indicate that new data has been
loaded into the data-output register and is ready to be read.
The second mode of operation is the Data Output (DOUT)
mode and is used to serially shift data out of the Data Output
Register (DOR). See Figure 12 for the time domain partitioning of the DRDY and DOUT function.
See Figure 13 for the basic timing of DOUT/DRDY. During
the time defined by t2, t3, and t4, the DOUT/DRDY pin
functions in DRDY mode. The state of the
DOUT/DRDY pin would be HIGH prior to the internal
transfer of new data to the DOR. The result of the A/D
9
DIGITAL FILTER RESPONSE
0
–20
–20
–40
–40
–60
–60
–80
–80
Gain (dB)
Gain (dB)
NORMALIZED DIGITAL FILTER RESPONSE
0
–100
–120
–100
–120
–140
–140
–160
–160
–180
–180
–200
–200
0
1
2
3
4
5
6
7
8
9
10
0
50
100
Frequency (Hz)
FIGURE 4. Normalized Digital Filter Response.
0
–20
–20
–40
–40
–60
–60
–80
Gain (dB)
Gain (dB)
250
300
DIGITAL FILTER RESPONSE
0
–100
–120
–80
–100
–120
–140
–140
–160
–160
–180
–180
–200
–200
0
50
100
150
200
250
300
0
10
20
30
Frequency (Hz)
40
50
60
70
80
90
100
Frequency (Hz)
FIGURE 6. Digital Filter Response (60Hz).
FIGURE 7. Digital Filter Response (10Hz Multiples).
DIGITAL FILTER RESPONSE
DIGITAL FILTER RESPONSE
0
0
–20
–20
–40
–40
–60
–60
–80
Gain (dB)
Gain (dB)
200
FIGURE 5. Digital Filter Response (50Hz).
DIGITAL FILTER RESPONSE
–100
–120
–80
–100
–120
–140
–140
–160
–160
–180
–180
–200
–200
45
46
47
48
49
50
51
52
53
54
55
Frequency (Hz)
FIGURE 8. Expanded Digital Filter Response (50Hz with a
50Hz Notch).
10
150
Frequency (Hz)
45
46
47
48
49
50
51
52
53
54
55
Frequency (Hz)
FIGURE 9. Expanded Digital Filter Response (50Hz with a
10Hz Notch).
ADS1252
SBAS127A
DIGITAL FILTER RESPONSE
0
–20
–20
–40
–40
–60
–60
–80
Gain (dB)
Gain (dB)
DIGITAL FILTER RESPONSE
0
–100
–120
–80
–100
–120
–140
–140
–160
–160
–180
–180
–200
–200
55
56
57
58
59
60
61
62
63
64
65
Frequency (Hz)
55
56
57
58
59
60
61
62
63
64
65
Frequency (Hz)
FIGURE 10. Expanded Digital Filter Response (60Hz with
a 60Hz Notch).
FIGURE 11. Expanded Digital Filter Response (60Hz with
a 10Hz Notch).
conversion would be written to the DOR from MSB to LSB
in the time defined by t1 (see Figures 12 and 13). The
DOUT/DRDY line would then pulse LOW for the time
defined by t2, and then pulse HIGH for the time defined by
t3 to indicate that new data was available to be read. At this
point, the function of the DOUT/DRDY pin would change
to DOUT mode. Data would be shifted out on the pin after
t7. The device communicating with the ADS1252 can provide SCLKs to the ADS1252 after the time defined by t6.
The normal mode of reading data from the ADS1252 would
be for the device reading the ADS1252 to latch the data on
the rising edge of SCLK (since data is shifted out of the
ADS1252 on the falling edge of SCLK). In order to retrieve
valid data, the entire DOR must be read before the
DOUT/DRDY pin reverts back to DRDY mode.
If SCLKs were not provided to the ADS1252 during the
DOUT mode, the MSB of the DOR would be present on the
DOUT/DRDY line until the time defined by t4. If an incomplete read of the ADS1252 took place while in DOUT mode
(i.e., less than 24 SCLKs were provided), the state of the last
bit read would be present on the DOUT/DRDY line until the
time defined by t4. If more than 24 SCLKs were provided
during DOUT mode, the DOUT/DRDY line would stay
LOW until the time defined by t4.
The internal data pointer for shifting data out on
DOUT/DRDY is reset on the falling edge of the time defined
by t1 and t4. This ensures that the first bit of data shifted out
of the ADS1252 after DRDY mode is always the MSB of
new data.
ADS1252
SBAS127A
SYNCHRONIZING MULTIPLE CONVERTERS
The normal state of SCLK is LOW, however, by holding
SCLK HIGH, multiple ADS1252s can be synchronized.
This is accomplished by holding SCLK HIGH for at least
four, but less than twenty, consecutive DOUT/DRDY cycles
(see Figure 14). After the ADS1252 circuitry detects that
SCLK has been held HIGH for four consecutive
DOUT/DRDY cycles, the DOUT/DRDY pin will pulse
LOW for 3 CLK cycles and then be held HIGH, and the
modulator will be held in a reset state. The modulator will be
released from reset and synchronization will occur on the
falling edge of SCLK. It is important to note that prior to
synchronization, the DOUT/DRDY pulse of multiple
ADS1252s in the system could have a difference in timing
up to one DRDY period. Therefore to ensure synchronization, the SCLK should be held HIGH for at least five DRDY
cycles. The first DOUT/DRDY pulse after the falling edge
of SCLK will occur at t14. Valid data will not be present until
the sixth DOUT/DRDY pulse.
11
POWER-DOWN MODE
The normal state of SCLK is LOW, however, by holding
SCLK HIGH, the ADS1252 will enter power-down mode.
This is accomplished by holding SCLK HIGH for at least
twenty consecutive DOUT/DRDY periods (see Figure 15).
After the ADS1252 circuitry detects that SCLK has been
held HIGH for four consecutive DOUT/DRDY cycles, the
DOUT/DRDY pin will pulse LOW for 3 CLK cycles and
then be held HIGH, and the modulator will be held in a
reset state. If SCLK is held HIGH for an additional sixteen
DOUT/DRDY periods, the ADS1252 will enter
power-down mode. The part will be released from powerdown mode on the falling edge of SCLK. It is important to
note that the DOUT/DRDY pin will be held HIGH after four
DOUT/DRDY cycles, but power-down mode will not be
entered for an additional sixteen DOUT/DRDY periods. The
first DOUT/DRDY pulse after the falling edge of SCLK will
occur at t16. Subsequent DOUT/DRDY pulses will occur
normally. Valid data will not be present until the sixth
DOUT/DRDY pulse.
SYMBOL
tDRDY
DRDY Mode
DOUT Mode
t1
t2
t3
t4
t5
t6
t7
t8
t9
t10
t11
t12
t13
t14
t15
t16
t17
SERIAL INTERFACE
The ADS1252 includes a simple serial interface which can
be connected to microcontrollers and digital signal processors in a variety of ways. Communications with the ADS1252
can commence on the first detection of the DOUT/DRDY
pulse after power up, although data will not be valid until the
sixth conversion.
It is important to note that the data from the ADS1252 is a
24-bit result transmitted MSB-first in Offset Two’s Complement format, as shown in Table III.
DIFFERENTIAL VOLTAGE INPUT
DIGITAL OUTPUT (HEX)
+Fulll Scale
Zero
–Full Scale
7FFFFFH
000000H
800000H
TABLE III. ADS1252 Data Format (Offset Two's Complement).
DESCRIPTION
MIN
Conversion Cycle
DRDY Mode
DOUT Mode
DOR Write Time
DOUT/DRDY LOW Time
DOUT/DRDY HIGH Time (Prior to Data Out)
DOUT/DRDY HIGH Time (Prior to Data Ready)
Rising Edge of CLK to Falling Edge of DOUT/DRDY
End of DRDY Mode to Rising Edge of First SCLK
End of DRDY Mode to Data Valid (Propogation Delay)
Falling Edge of SCLK to Data Valid (Hold Time)
Falling Edge of SCLK to Next Data Out Valid (Propogation Delay)
SCLK Setup Time for Synchronization or Power Down
DOUT/DRDY Pulse for Synchronization or Power Down
Rising Edge of SCLK Until Start of Synchronization
Synchronization Time
Falling Edge of CLK (After SCLK Goes Low) Until Start of DRDY Mode
Rising Edge of SCLK Until Start of Power Down
Falling Edge of CLK (After SCLK Goes Low) Until Start of DRDY Mode
Falling Edge of Last DOUT/DRDY to Start of Power Down
TYP
MAX
UNITS
384 • CLK
36 • CLK
348 • CLK
6 • CLK
6 • CLK
6 • CLK
24 • CLK
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
30
30
30
5
30
30
3 • CLK
1537 • CLK
0.5 • CLK
7679 • CLK
6143.5 • CLK
314.5 • CLK
7681 • CLK
591.5 • CLK
592.5 • CLK
6143.5 • CLK
TABLE II. Digital Timing.
DOUT Mode
DRDY Mode
t2
t4
DOUT/DRDY
DOUT Mode
DATA
DRDY Mode
t3
DATA
DATA
t1
FIGURE 12. DOUT/DRDY Partitioning.
12
ADS1252
SBAS127A
ADS1252
SBAS127A
13
t4
t1
t10
t2
t3
tDRDY
t10
t2
t3
FIGURE 15. Power-Down Mode.
DOUT/DRDY
SCLK
CLK
tDRDY
FIGURE 14. Synchronization Mode.
DOUT/DRDY
SCLK
CLK
FIGURE 13. DOUT/DRDY Timing.
DOUT/DRDY
SCLK
CLK
t2
DOUT
Mode
DATA
DOUT
Mode
DATA
t4
t4
DRDY Mode
t5
4 tDRDY
4 tDRDY
t12
t3
t15
t11
MSB
t7
t6
DATA
DATA
t8
t9
tDRDY
t11
t11
t17
t13
t16
Power Down Occurs Here
t14
Synchronization Begins Here
Synchronization Mode Starts Here
DOUT Mode
LSB
t2
t2
t3
t3
DATA
DATA
tDRDY
DOUT
Mode
tDRDY
DOUT
Mode
t4
t4
The data must be clocked out before the ADS1252 enters
DRDY mode to ensure reception of valid data, as described
in the DOUT/DRDY section of this data sheet.
ISOLATION
The serial interface of the ADS1252 provides for simple
isolation methods. The CLK signal can be local to the
ADS1252, which then only requires two signals (SCLK, and
DOUT/DRDY) to be used for isolated data acquisition.
LAYOUT
POWER SUPPLY
The power supply should be well regulated and low noise.
For designs requiring very high resolution from the ADS1252,
power-supply rejection will be a concern. Avoid running
digital lines under the device as they may couple noise onto
the die. High-frequency noise can capacitively couple into
the analog portion of the device and will alias back into the
passband of the digital filter, affecting the conversion result.
GROUNDING
The analog and digital sections of the system design should
be carefully and cleanly partitioned. Each section should
have its own ground plane with no overlap between them.
GND should be connected to the analog ground plane, as
well as all other analog grounds. Do not join the analog and
digital ground planes on the board, but instead connect the
two with a moderate signal trace. For multiple converters,
connect the two ground planes at one location as central to
all of the converters as possible. In some cases, experimentation may be required to find the best point to connect the
two planes together. The printed circuit board can be designed to provide different analog/digital ground connections via short jumpers. The initial prototype can be used to
establish which connection works best.
DECOUPLING
Good decoupling practices should be used for the ADS1252
and for all components in the design. All decoupling capacitors, and specifically the 0.1µF ceramic capacitors, should
be placed as close as possible to the pin being decoupled. A
1µF to 10µF capacitor, in parallel with a 0.1µF ceramic
capacitor, should be used to decouple VDD to GND.
14
SYSTEM CONSIDERATIONS
The recommendations for power supplies and grounding
will change depending on the requirements and specific
design of the overall system. Achieving 24 bits of noise
performance is a great deal more difficult than achieving 12
bits of noise performance. In general, a system can be
broken up into four different stages:
•
•
•
•
Analog Processing
Analog Portion of the ADS1252
Digital Portion of the ADS1252
Digital Processing
For the simplest system consisting of minimal analog signal
processing (basic filtering and Gain), a microcontroller, and
one clock source, one can achieve high resolution by
powering all components by a common power supply. In
addition, all components could share a common ground
plane. Thus, there would be no distinctions between “analog” power and ground, and “digital” power and ground.
The layout should still include a power plane, a ground
plane, and careful decoupling. In a more extreme case, the
design could include:
• Multiple ADS1252s
• Extensive Analog Signal Processing
• One or More Microcontrollers, Digital Signal Processors,
or Microprocessors
• Many Different Clock Sources
• Interconnections to Various Other Systems
High resolution will be very difficult to achieve for this
design. The approach would be to break the system into as
many different parts as possible. For example, each ADS1252
may have its own “analog” processing front end.
DEFINITION OF TERMS
An attempt has been made to be consistent with the terminology used in this data sheet. In that regard, the definition
of each term is given as follows:
Analog-Input Differential Voltage—for an analog signal
that is fully differential, the voltage range can be compared
to that of an instrumentation amplifier. For example, if both
analog inputs of the ADS1252 are at 2.048V, the differential voltage is 0V. If one analog input is at 0V and the other
analog input is at 4.096V, then the differential voltage
magnitude is 4.096V. This is the case regardless of which
ADS1252
SBAS127A
input is at 0V and which is at 4.096V. The digital-output
result, however, is quite different. The analog-input differential voltage is given by the following equation:
+VIN – (–VIN)
A positive digital output is produced whenever the
analog-input differential voltage is positive, while a negative
digital output is produced whenever the differential is negative. For example, a positive full-scale output is produced
when the converter is configured with a 4.096V reference,
and the analog-input differential is 4.096V. The negative
full-scale output is produced when the differential voltage is
–4.096V. In each case, the actual input voltages must remain
within the –0.3V to +VDD range.
Actual Analog-Input Voltage—the voltage at any one
analog input relative to GND.
Full-Scale Range (FSR)—as with most ADCs, the fullscale range of the ADS1252 is defined as the “input” which
produces the positive full-scale digital output minus the
“input” which produces the negative full-scale digital output. For example, when the converter is configured with a
4.096V reference, the differential full-scale range is:
[4.096V (positive full scale) – (–4.096V) (negative full scale)] = 8.192V
Least Significant Bit (LSB) Weight—this is the theoretical
amount of voltage that the differential voltage at the analog
input would have to change in order to observe a change in
the output data of one least significant bit. It is computed as
follows:
LSB Weight =
Full−Scale Range
2N
where N is the number of bits in the digital output.
Conversion Cycle—as used here, a conversion cycle refers
to the time period between DOUT/DRDY pulses.
Effective Resolution (ER)—of the ADS1252 in a particular
configuration can be expressed in two different units:
bits rms (referenced to output) and µVrms (referenced to
input). Computed directly from the converter's output data,
each is a statistical calculation based on a given number of
results. Noise occurs randomly; the rms value represents a
statistical measure which is one standard deviation. The ER
in bits can be computed as follows:
 2 • VREF 
20 • log

 Vrms noise 
ER in bits rms =
6.02
The 2 • VREF figure in each calculation represents the
full-scale range of the ADS1252. This means that both units
are absolute expressions of resolution—the performance in
different configurations can be directly compared, regardless of the units.
Noise Reduction—for random noise, the ER can be improved with averaging. The result is the reduction in noise
by the factor √N, where N is the number of averages, as
shown in Table IV. This can be used to achieve true 24-bit
performance at a lower data rate. To achieve 24 bits of
resolution, more than 24 bits must be accumulated. A 36-bit
accumulator is required to achieve an ER of 24 bits. The
following uses VREF = 4.096V, with the ADS1252 outputting data at 40kHz, a 4096 point average will take 102.4ms.
The benefits of averaging will be degraded if the input signal
drifts during that 100ms.
N
(NUMBER
OF AVERAGES)
NOISE
REDUCTION
FACTOR
ER
IN
VRMS
ER
IN
BITS RMS
1
2
4
8
16
32
64
128
256
512
1024
2048
4096
1
1.414
2
2.82
4
5.66
8
11.3
16
22.6
32
45.25
64
31.3µV
22.1µV
15.6µV
11.1µV
7.82µV
5.53µV
3.91µV
2.77µV
1.96µV
1.38µV
978nV
692nV
489nV
18
18.5
19
19.5
20
20.5
21
21.5
22
22.5
23
23.5
24
TABLE IV. Averaging.
ADS1252
SBAS127A
15
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