TI ADS1174IPAPT

AD
ADS1174
ADS1178
AD
S1
174
S1
17
8
www.ti.com ........................................................................................................................................ SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008
Quad/Octal, Simultaneous Sampling, 16-Bit Analog-to-Digital Converters
FEATURES
DESCRIPTION
1
• Simultaneously Sample Four/Eight Channels
• Selectable Operating Modes:
High-Speed: 52kSPS Data Rate, 31mW/ch
Low-Power: 10kSPS Data Rate, 7mW/ch
• AC Performance:
25kHz Bandwidth
97dB SNR
–105dB THD
• DC Performance:
2µV/°C Offset Drift
2ppm/°C Gain Drift
• Digital Filter:
Linear Phase Response
Passband Ripple: ±0.005dB
Stop Band Attenuation: 100dB
• Selectable SPI™ or Frame Sync Serial
Interface
• Simple Pin-Driven Control
• Low Sampling Aperture Error
• Specified from –40°C to +105°C
• Analog Supply: 5V
• I/O Supply: 1.8V to 3.3V
• Digital Core Supply: 1.8V
234
APPLICATIONS
•
•
•
•
3-Phase Power Monitors
Defibrillators and ECG Monitors
Coriolis Flow Meters
Vibration/Modal Analysis
VREFP VREFN
Input1
DS
Input2
DS
Input3
DS
Input4
DS
AVDD
DVDD
SPI
and
FrameSync
Interface
Four
Digital
Filters
DGND
ADS1174
The delta-sigma architecture offers near ideal 16-bit
ac performance (97dB SNR, –105dB THD, 1LSB
linearity) combined with 0.005dB passband ripple and
linear phase response.
The
high-order,
chopper-stabilized
modulator
achieves very low drift (2µV/°C offset, 2ppm/°C gain)
and low noise (1LSBPP). The on-chip finite impulse
response (FIR) filter provides a usable signal
bandwidth up to 90% of the Nyquist rate with 100dB
of stop band attenuation while suppressing modulator
and signal out-of-band noise.
Two operating modes allow for optimization of speed
and power: High-speed mode (31mW/Ch at 52kSPS),
and Low-power mode (7mW/Ch at 10kSPS).
A SYNC input control pin allows the device
conversions to be started and synchronized to an
external event. SPI and Frame-Sync serial interfaces
are supported. The device is fully specified over the
extended industrial range (–40°C to +105°C) and is
available in an HTQFP-64 PowerPAD™ package.
IOVDD
Control
Logic
AGND
The ADS1174 (quad) and ADS1178 (octal) are
multiple delta-sigma (ΔΣ) analog-to-digital converters
(ADCs) with data rates up to 52k samples-per-second
(SPS), which allow synchronous sampling of four and
eight channels. These devices use identical
packages, and are also compatible with the
high-performance 24-bit ADS1274 and ADS1278,
permitting drop-in upgrades.
VREFP VREFN AVDD
DRDY/FSYNC
SCLK
DOUT[4:1]
DIN
TEST[1:0]
FORMAT[2:0]
CLK
SYNC
PWDN[4:1]
CLKDIV
MODE
Input1
DS
Input2
DS
Input3
DS
Input4
DS
Input5
DS
Input6
DS
Input7
DS
Input8
DS
AGND
DVDD
IOVDD
SPI
and
FrameSync
Interface
DRDY/FSYNC
SCLK
DOUT[8:1]
DIN
Control
Logic
TEST[1:0]
FORMAT[2:0]
CLK
SYNC
PWDN[8:1]
CLKDIV
MODE
Eight
Digital
Filters
DGND
ADS1178
1
2
3
4
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PowerPAD is a trademark of Texas Instruments.
SPI is a trademark of Motorola, Inc.
All other trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2007–2008, Texas Instruments Incorporated
ADS1174
ADS1178
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
ORDERING INFORMATION
For the most current package and ordering information see the Package Option Addendum at the end of this
document, or see the TI web site at www.ti.com.
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range unless otherwise noted (1)
PARAMETER
ADS1174, ADS1178
UNIT
AVDD to AGND
–0.3 to +6.0
V
DVDD, IOVDD to DGND
–0.3 to +3.6
V
AGND to DGND
–0.3 to +0.3
V
100, Momentary
mA
10, Continuous
mA
Analog Input to AGND
–0.3 to AVDD + 0.3
V
Digital Input or Output to DGND
–0.3 to IOVDD + 0.3
V
Input Current
Maximum Junction Temperature
+150
°C
Operating Temperature Range
–40 to +125
°C
Storage Temperature Range
–60 to +150
°C
(1)
2
Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may
degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond
those specified is not implied.
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Copyright © 2007–2008, Texas Instruments Incorporated
Product Folder Link(s): ADS1174 ADS1178
ADS1174
ADS1178
www.ti.com ........................................................................................................................................ SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008
ELECTRICAL CHARACTERISTICS
Limit specifications at TA = –40°C to +105°C. Typical specifications at TA = +25°C, AVDD = +5V, DVDD = +1.8V, IOVDD =
+3.3V, fCLK = 27MHz, VREFP = 2.5V, VREFN = 0V, and all channels active, unless otherwise noted.
ADS1174, ADS1178
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ANALOG INPUTS
Full-scale input voltage (FSR (1))
VIN = (AINP – AINN)
Absolute input voltage
AINP or AINN to AGND
Common-mode input voltage
VCM = (AINP + AINN)/2
Differential input impedance
±VREF
AGND – 0.1
V
AVDD + 0.1
V
2.5
V
High-Speed mode
28
kΩ
Low-Power mode
140
kΩ
DC PERFORMANCE
Resolution
Data rate (fDATA)
No missing codes
16
High-Speed mode
Bits
52,734
Low-Power mode
SPS
10,547
Integral nonlinearity (INL) (2)
Differential input
Offset error
±1
0.3
2
Offset drift
2
Gain error
0.1
Gain drift
SPS
±0.3
LSB
mV
µV/°C
0.5
%
2
ppm/°C
LSBPP
Noise
Shorted input
1
Common-mode rejection
fCM = 60Hz (3)
100
dB
AVDD
fPS = 60Hz (3)
75
dB
DVDD
fPS = 60Hz (3)
85
dB
IOVDD
fPS = 60Hz (3)
90
dB
AVDD/2
V
–107
dB
Power-supply rejection
VCOM output voltage
No load
AC PERFORMANCE
Crosstalk
VIN = 1kHz, –0.5dBFS
Signal-to-noise ratio (SNR) (unweighted)
VIN = 1kHz, –0.5dBFS
Total harmonic distortion (THD) (4)
VIN = 1kHz, –0.5dBFS
High-Speed mode
92
97
–105
Spurious-free dynamic range
106
Passband ripple
–3dB Bandwidth
Stop band attenuation
Hz
0.49 fDATA
Hz
dB
0.547 fDATA
Group delay
Settling time (latency)
Complete settling
dB
0.453 fDATA
100
Stop band
dB
dB
±0.005
Passband
(1)
(2)
(3)
(4)
dB
–96
63.453 fDATA
Hz
38/fDATA
s
76/fDATA
s
FSR = full-scale range = 2VREF
Best-fit method.
fCM is the input common-mode frequency. fPS is the power-supply frequency.
THD includes the first nine harmonics of the input signal.
Copyright © 2007–2008, Texas Instruments Incorporated
Product Folder Link(s): ADS1174 ADS1178
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ADS1174
ADS1178
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
ELECTRICAL CHARACTERISTICS (continued)
Limit specifications at TA = –40°C to +105°C. Typical specifications at TA = +25°C, AVDD = +5V, DVDD = +1.8V, IOVDD =
+3.3V, fCLK = 27MHz, VREFP = 2.5V, VREFN = 0V, and all channels active, unless otherwise noted.
ADS1174, ADS1178
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VREF = VREFP – VREFN
0.5
2.5
3.1
V
V
VOLTAGE REFERENCE INPUTS
Reference input voltage (VREF)
Negative reference input (VREFN)
AGND – 0.1
AGND + 0.1
Positive reference input (VREFP)
VREFN + 0.5
VREFN + 3.1
ADS1174
Reference Input impedance
High-Speed mode
ADS1178
Reference Input impedance
V
2.6
kΩ
Low-Power mode
13
kΩ
High-Speed mode
1.3
kΩ
Low-Power mode
6.5
kΩ
DIGITAL INPUT/OUTPUT (IOVDD = 1.8V to 3.6V)
VIH
0.7 IOVDD
IOVDD
V
VIL
DGND
0.3 IOVDD
V
V
VOH
IOH = 4mA
0.8 IOVDD
IOVDD
VOL
IOL = 4mA
DGND
0.2 IOVDD
V
±10
µA
27
MHz
Input leakage
0 < VIN DIGITAL < IOVDD
Master clock rate (fCLK)
0.1
POWER SUPPLY
AVDD
4.75
5
5.25
V
DVDD
1.65
1.8
1.95
V
IOVDD
1.65
Power-down current
3.6
V
AVDD
1
10
µA
DVDD
1
15
µA
IOVDD
1
10
µA
ADS1174
ADS1174
AVDD current
High-Speed mode
23
35
mA
Low-Power mode
5
9
mA
ADS1174
DVDD current
High-Speed mode
10
15
mA
Low-Power mode
2.5
4.5
mA
ADS1174
IOVDD current
High-Speed mode
0.075
0.3
mA
Low-Power mode
0.02
0.15
mA
ADS1174
Power dissipation
High-Speed mode
135
210
mW
Low-Power mode
30
55
mW
ADS1178
AVDD current
High-Speed mode
44
64
mA
Low-Power mode
9
14
mA
ADS1178
DVDD current
High-Speed mode
12
17
mA
Low-Power mode
3
4.5
mA
ADS1178
IOVDD current
High-Speed mode
0.125
0.5
mA
Low-Power mode
0.035
0.2
mA
ADS1178
Power dissipation
High-Speed mode
245
355
mW
Low-Power mode
50
80
mW
ADS1178
4
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Product Folder Link(s): ADS1174 ADS1178
ADS1174
ADS1178
www.ti.com ........................................................................................................................................ SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008
ADS1174/ADS1178 PIN ASSIGNMENTS
AINP6(1)
49
AINN6(1)
AINN5(1)
52
50
AVDD
53
AINP5(1)
AGND
54
51
VREFP
VREFN
57
VCOM
AGND
58
55
AGND
59
56
AINP4
AVDD
AINN4
62
60
AINP3
63
61
AINN3
64
PAP PACKAGE
HTQFP-64
(TOP VIEW)
AINP2
1
48
AINN7(1)
AINN2
2
47
AINP7(1)
AINP1
3
46
AINN8(1)
AINN1
4
45
AINP8(1)
AVDD
5
44
AVDD
AGND
6
43
AGND
DGND
7
42
PWDN1
TEST0
8
41
PWDN2
TEST1
9
40
PWDN3
39
PWDN4
ADS1174/ADS1178
NOTE: (1) Boldface pin names are for ADS1178 only;
see pin descriptions.
CLKDIV
10
SYNC
11
38
PWDN5(1)
DIN
12
37
PWDN6(1)
DOUT8(1)
13
36
PWDN7(1)
DOUT7(1)
14
35
PWDN8(1)
DOUT6(1)
15
34
MODE
DOUT5(1)
16
33
NC
23
24
25
26
27
28
29
30
IOVDD
DGND
DGND
DVDD
CLK
SCLK
DRDY/FSYNC
FORMAT2
32
22
IOVDD
FORMAT0
21
DGND
31
20
DOUT1
FORMAT1
19
18
DOUT3
DOUT2
17
DOUT4
(PowerPAD Outline)
ADS1174/ADS1178 PIN DESCRIPTIONS
PIN
NAME
NO.
FUNCTION
AGND
6, 43, 54,
58, 59
DESCRIPTION
Analog ground
AINP1
3
Analog input
AINP2
1
Analog input
AINP3
63
Analog input
AINP4
61
Analog input
AINP5
51
Analog input
AINP6
49
Analog input
AINP7
47
Analog input
AINP8
45
Analog input
Analog ground; connect to DGND using a single plane.
ADS1178: AINP[8:1] Positive analog input, channels 8 through 1.
ADS1174: AINP[8:5] Connected to internal ESD rails. The inputs may float.
AINP[4:1] Positive analog input, channels 4 through 1.
Copyright © 2007–2008, Texas Instruments Incorporated
Product Folder Link(s): ADS1174 ADS1178
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ADS1174
ADS1178
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
ADS1174/ADS1178 PIN DESCRIPTIONS (continued)
PIN
6
NAME
NO.
FUNCTION
AINN1
4
Analog input
DESCRIPTION
AINN2
2
Analog input
AINN3
64
Analog input
AINN4
62
Analog input
AINN5
52
Analog input
AINN6
50
Analog input
AINN7
48
Analog input
AINN8
46
Analog input
AVDD
5, 44, 53, 60
Analog power supply
ADS1178: AINN[8:1] Negative analog input, channels 8 through 1.
ADS1174: AINN[8:5] Connected to internal ESD rails. The inputs may float.
AINN[4:1] Negative analog input, channels 4 through 1.
Analog power supply (4.75V to 5.25V).
VCOM
55
Analog output
AVDD/2 Unbuffered analog output.
VREFN
57
Analog input
Negative reference input.
VREFP
56
Analog input
Positive reference input.
CLK
27
Digital input
Master clock input (maximum 27MHz).
CLKDIV
10
Digital input
DGND
7, 21, 24, 25
Digital ground
DIN
12
Digital input
DOUT1
20
Digital output
DOUT2
19
Digital output
DOUT3
18
Digital output
DOUT4
17
Digital output
DOUT5
16
Digital output
DOUT6
15
Digital output
DOUT7
14
Digital output
DOUT8
13
Digital output
DRDY/
FSYNC
29
Digital input/output
CLK input divider control:
1 = 27MHz
0 = 13.5MHz (high-speed) / 5.4MHz (low-power)
Digital ground power supply.
Daisy-chain data input.
DVDD
26
Digital power supply
FORMAT0
32
Digital input
FORMAT1
31
Digital input
DOUT1 is TDM data output (TDM mode).
ADS1178: DOUT[8:1] Data output for channels 8 through 1.
ADS1174: DOUT[8:5] Internally connected to active circuitry; outputs are driven.
DOUT[4:1] Data output for channels 4 through 1.
Frame-Sync protocol: frame clock input; SPI protocol: data ready output.
Digital core power supply (+1.65V to +1.95V).
FORMAT[2:0] Selects between Frame-Sync/SPI protocol, TDM/discrete data
outputs, fixed/dynamic position TDM data, and modulator mode/normal operating
mode.
FORMAT2
30
Digital input
IOVDD
22, 23
Digital power supply
MODE
34
Digital input
I/O power supply (+1.65V to +3.6V).
MODE:
0 = High-Speed mode
1 = Low-Power mode.
NC
33
—
PWDN1
42
Digital input
PWDN2
41
Digital input
PWDN3
40
Digital input
PWDN4
39
Digital input
PWDN5
38
Digital input
PWDN6
37
Digital input
PWDN7
36
Digital input
PWDN8
35
Digital input
SCLK
28
Digital input
Serial clock input.
SYNC
11
Digital input
Synchronize input (all channels).
TEST0
8
Digital input
TEST1
9
Digital input
TEST[1:0] Test mode select: 00 = normal operation
11 = test mode
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Internally connected to IOVDD (connect to IOVDD or leave open).
ADS1178: PWDN[8:1] Power-down control for channels 8 through 1.
ADS1174: PWDN[8:5] must = 0V.
PWDN[4:1] Power-down control for channels 4 through 1.
Copyright © 2007–2008, Texas Instruments Incorporated
Product Folder Link(s): ADS1174 ADS1178
ADS1174
ADS1178
www.ti.com ........................................................................................................................................ SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008
TIMING CHARACTERISTICS: SPI FORMAT
tCLK
tCPW
CLK
· · ·
tCPW
tCD
tCONV
DRDY
tSD
tDS
tSCLK
tSPW
SCLK
tSPW
tMSBPD
DOUT
Bit 15 (MSB)
tDOPD
tDOHD
Bit 14
tDIST
Bit 13
tDIHD
DIN
TIMING REQUIREMENTS: SPI FORMAT
For TA = –40°C to +105°C, IOVDD = 1.65V to 3.6V, and DVDD = 1.65V to 1.95V.
SYMBOL
PARAMETER
tCLK
CLK period (1/fCLK) (1)
MIN
37
tCPW
CLK positive or negative pulse width
15
(2)
tCONV
Conversion period (1/fDATA)
tCD (3)
Falling edge of CLK to falling edge of DRDY
tDS (3)
Falling edge of DRDY to rising edge of first SCLK to retrieve data
tMSBPD
DRDY falling edge to DOUT MSB valid (propagation delay)
tSD (3)
Falling edge of SCLK to rising edge of DRDY
tSCLK (4)
SCLK period
tSPW
tDOHD
(3) (5)
TYP
MAX
10,000
UNIT
ns
ns
256
2560
22
tCLK
ns
1
tCLK
16
18
ns
ns
1
tCLK
SCLK positive or negative pulse width
0.4
tCLK
SCLK falling edge to new DOUT invalid (hold time)
10
ns
tDOPD (3)
SCLK falling edge to new DOUT valid (propagation delay)
tDIST
New DIN valid to falling edge of SCLK (setup time)
6
ns
Old DIN valid to falling edge of SCLK (hold time)
6
ns
tDIHD
(1)
(2)
(3)
(4)
(5)
(5)
32
ns
fCLK = 27MHz maximum.
Depends on MODE[1:0] and CLKDIV selection. See Table 4 (fCLK/fDATA).
Load on DRDY and DOUT = 20pF.
For best performance, limit fSCLK/fCLK to ratios of 1, 1/2, 1/4, 1/8, etc.
tDOHD (DOUT hold time) and tDIHD (DIN hold time) are specified under opposite worst-case conditions (digital supply voltage and
ambient temperature). Under equal conditions, with DOUT connected directly to DIN, the timing margin is >4ns.
Copyright © 2007–2008, Texas Instruments Incorporated
Product Folder Link(s): ADS1174 ADS1178
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ADS1174
ADS1178
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
TIMING CHARACTERISTICS: FRAME-SYNC FORMAT
tCPW
tCLK
CLK
tCPW
tCS
tFRAME
tFPW
tFPW
FSYNC
tFS
tSCLK
tSPW
tSF
SCLK
tSPW
tMSBPD
DOUT
tDOPD
tDOHD
Bit 15 (MSB)
Bit 14
tDIST
Bit 13
tDIHD
DIN
TIMING REQUIREMENTS: FRAME-SYNC FORMAT
For TA = –40°C to +105°C, IOVDD = 1.65V to 3.6V, and DVDD = 1.65V to 1.95V.
SYMBOL
PARAMETER
MIN
tCLK
CLK period (1/fCLK)
37
tCPW
CLK positive or negative pulse width
12
tCS
Falling edge of CLK to falling edge of SCLK
tFRAME
Frame period (1/fDATA) (1)
tFPW
FSYNC positive or negative pulse width
1
tSCLK
tFS
Rising edge of FSYNC to rising edge of SCLK
5
ns
tSF
Rising edge of SCLK to rising edge of FSYNC
5
ns
(2)
TYP
MAX
UNIT
10,000
ns
ns
–0.25
0.25
tCLK
256
2560
tCLK
tSCLK
SCLK period
1
tCLK
tSPW
SCLK positive or negative pulse width
0.4
tCLK
tDOHD (3) (4)
SCLK falling edge to old DOUT invalid (hold time)
10
ns
tDOPD
(4)
SCLK falling edge to new DOUT valid (propagation delay)
31
ns
tMSBPD
FSYNC rising edge to DOUT MSB valid (propagation delay)
31
ns
tDIST
New DIN valid to falling edge of SCLK (setup time)
6
ns
tDIHD (3)
Old DIN valid to falling edge of SCLK (hold time)
6
ns
(1)
(2)
(3)
(4)
8
Depends on MODE[1:0] and CLKDIV selection. See Table 4 (fCLK/fDATA).
SCLK must be continuously running and limited to ratios of 1, 1/2, 1/4, and 1/8 of fCLK.
tDOHD (DOUT hold time) and tDIHD (DIN hold time) are specified under opposite worst-case conditions (digital supply voltage and
ambient temperature). Under equal conditions, with DOUT connected directly to DIN, the timing margin is >4ns.
Load on DOUT = 20pF.
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ADS1174
ADS1178
www.ti.com ........................................................................................................................................ SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008
OVERVIEW
The ADS1174 (quad) and ADS1178 (octal) are 16-bit,
delta-sigma ADCs. They offer the combination of
excellent linearity, low noise, and low power
consumption. Figure 1 shows the block diagram. Note
that both devices are the same, except the ADS1174
has four ADCs, and the ADS1178 has eight ADCs.
The pinout and package of the ADS1178 are
compatible with the ADS1174 (and the 24-bit
ADS1274 and ADS1278), permitting drop-in
expandability or upgrades. The converters are
comprised of either four (ADS1174) or eight
(ADS1178) advanced, 6th-order, chopper-stabilized,
delta-sigma modulators followed by low-ripple, linear
phase FIR filters. The modulators measure the
differential input signal, VIN = (AINP – AINN), against
the differential reference, VREF = (VREFP – VREFN).
The digital filters receive the modulator signal and
provide a low-noise digital output.
VREFP
AVDD
VREFN
To allow tradeoffs between speed and power, two
modes of operation are supported: High-Speed and
Low-Power. Table 1 summarizes the performance of
each mode.
In High-Speed mode, the data rate is 52kSPS, and in
Low-Power mode, the power dissipation is only
7mW/channel at 10.5kSPS.
The ADS1174/78 is configured by simply setting the
appropriate I/O pins—there are no registers to
program. Data are retrieved over a serial interface
that supports both SPI and Frame-Sync formats. The
ADS1174/78 has a daisy-chainable output and the
ability to synchronize externally, so it can be used
conveniently in systems requiring more than eight
channels.
DVDD
IOVDD
S
R
VCOM
VREF
R
AINP1
AINN1
AINP2
AINN2
S
S
VIN1
DS
Modulator1
VIN2
DS
Modulator2
Digital
Filter1
DRDY/FSYNC
SPI
and
Frame-Sync
Interface
SCLK
DOUT[4:1]/[8:1](1)
DIN
Digital
Filter2
TEST[1:0]
FORMAT[2:0]
CLK
Control
Logic
AINP4/8(1)
AINN4/8(1)
S
VIN4/8
DS
Modulator4/8(1)
SYNC
PWDN[4:1]/[8:1](1)
Digital
Filter4/8(1)
CLKDIV
MODE
AGND
DGND
NOTE: (1) The ADS1174 has four channels; the ADS1178 has eight channels.
Figure 1. ADS1174/ADS1178 Block Diagram
Table 1. Operating Mode Performance Summary
(1)
MODE
DATA RATE
(SPS)
PASSBAND
(Hz)
SNR
(dB)
NOISE
(LSBPP)
POWER DISSIPATION
PER CHANNEL (1)
(mW)
High-Speed
52,734
23,889
97
1
31
Low-Power
10,547
4,778
97
1
7
Measured with all channels operating.
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ADS1174
ADS1178
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FUNCTIONAL DESCRIPTION
FREQUENCY RESPONSE
The ADS1174 and ADS1178 are 16-bit delta/sigma
ADCs consisting of independent converters that
digitize input signals simultaneously. The ADS1174
consists of four independent converters, while the
ADS1178 has eight independent converters.
The digital filter sets the overall frequency response.
The filter uses a multi-stage FIR topology to provide
linear phase with minimal passband ripple and high
stop band attenuation. The oversampling ratio of the
digital filter (that is, the ratio of the modulator
sampling to the output data rate: fMOD/fDATA) is 64 for
both High-Speed and Low-Power modes.
In operation, the signal inputs and reference inputs
are sampled by the modulator at a high rate (typically
64x higher than the final output data rate). The
quantization noise of the modulator is moved to a
higher frequency range where the internal digital filter
removes it. This process results in very low levels of
noise within the signal passband.
Figure 2 shows the frequency response of the
ADS1174/78 normalized to fDATA. Figure 3 shows the
passband ripple. The transition from passband to stop
band is illustrated in Figure 4. The overall frequency
response repeats at 64x multiples of the modulator
frequency fMOD, as shown in Figure 5.
0
-20
Amplitude (dB)
The converter is composed of two main functional
blocks to perform the ADC conversions: the
modulator and the digital filter. The modulator
samples the input signal together with sampling the
reference voltage to produce a 1's density output
stream. The density of the output stream is
proportional to the analog input level relative to the
reference voltage. The pulse stream is filtered by the
internal digital filter where the output conversion
result is produced.
10
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-80
-120
-140
0
0.2
0.6
0.4
0.8
1.0
Normalized Input Frequency (fIN/fDATA)
Figure 2. Frequency Response
SAMPLING APERTURE MATCHING
The phase match of one four-channel ADS1174 to
that of another ADS1174 may not have the same
degree of sampling match (the same is true for two
8-channel ADS1178s). As a result of manufacturing
variations, differences in internal propagation delay of
the internal CLK signal coupled with differences of
the arrival of the external CLK signal to each device
may cause larger sampling match errors. Equal
length CLK traces or external clock distribution
devices can be used to control the arrival of the CLK
signals to help reduce the sampling match error.
-60
-100
Because the input signal is sampled at a very high
rate, input signal aliasing does not occur until the
input signal frequency approaches the modulator
sampling rate. The high sampling rate of the
modulator greatly relaxes the requirement of external
antialiasing filters, thus eliminating passband phase
errors that otherwise may be caused by the analog
filter.
0.02
0
Amplitude (dB)
The converters of the ADS1174/78 operate from the
same CLK input. The CLK input controls the timing of
the modulator sampling instant. The converter is
designed so that the sampling skew (or modulator
sampling aperture match) between channels is
controlled. Furthermore, the digital filters are
synchronized to start the convolution phase at the
same modulator clock cycle. This design results in
excellent phase match among the ADS1174/78
channels.
-40
-0.02
-0.04
-0.06
-0.08
-0.10
0
0.1
0.2
0.3
0.4
0.5
0.6
Normalized Input Frequency (fIN/fDATA)
Figure 3. Passband Response
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PHASE RESPONSE
0
The ADS1174/78 incorporates a multiple stage, linear
phase digital filter. Linear phase filters exhibit
constant delay time versus input frequency (constant
group delay), which means the time delay from any
instant of the input signal to the same instant of the
output data is constant, and is independent of input
signal frequency. This behavior results in essentially
zero phase errors when analyzing multi-tone signals.
-1
Amplitude (dB)
-2
-3
-4
-5
-6
-7
-8
SETTLING TIME
-9
-10
0.45
0.47
0.49
0.51
0.53
0.55
Normalized Input Frequency (fIN/fDATA)
Figure 4. Transition Band Response
20
0
As with frequency and phase response, the digital
filter also determines settling time. Figure 6 shows
the output settling behavior after a step change on
the analog inputs normalized to conversion periods.
The X-axis is given in units of conversion. Note that
after the step change on the input occurs, the output
data change very little prior to 30 conversion periods.
The output data are fully settled after 76 conversion
periods.
-20
Final Value
-60
100
-80
Fully Settled Data
at 76 Conversions
Settling (%)
Gain (dB)
-40
-100
-120
-140
-160
0
16
32
48
64
Input Frequency (fIN/fDATA)
Figure 5. Frequency Response Out to fMOD
Initial Value
0
0
10
20
30
40
50
60
70
80
Conversions (1/fDATA)
These image frequencies, if present in the signal and
not externally filtered, fold back (or alias) into the
passband, causing errors. Table 2 lists the degree of
image rejection versus external antialiasing filter
order. The stop band of the ADS1174/78 provides
100dB attenuation of frequencies that begin just
beyond the passband and continue out to fMOD.
Placing an antialiasing, low-pass filter in front of the
ADS1174/78 inputs is recommended to limit possible
high-amplitude, out-of-band signals and noise.
Table 2. Antialiasing Filter Order Image Rejection
ANTIALIASING FILTER
ORDER
IMAGE REJECTION (dB)
(f–3dB at fDATA)
1
39
2
75
3
111
Figure 6. Step Response
ANALOG INPUTS (AINP, AINN)
The ADS1174/78 measures each differential input
signal VIN = (AINP – AINN) against the common
differential reference VREF = (VREFP – VREFN). The
most positive measurable differential input is +VREF,
which produces the most positive digital output code
of 7FFFh. Likewise, the most negative measurable
differential input is –VREF, which produces the most
negative digital output code of 8000h.
For optimal performance, drive the ADS1174/78
inputs
differentially.
For
single-ended
input
applications, one of the inputs (AINP or AINN) can be
driven while the other input is fixed (typically, to
AGND or +2.5V); fixing the input to +2.5V permits
bipolar operation, thereby using the full range of the
converter.
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ADS1178
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While the ADS1174/78 measures the differential input
signal, the absolute input voltage is also important.
This is the voltage on either input (AINP or AINN)
with respect to AGND. The range for this voltage is:
AVDD AGND
–0.1V < (AINN or AINP) < AVDD + 0.1V
S1
AINP
If either input is taken below –0.4V or above (AVDD +
0.4), ESD protection diodes on the inputs may turn
on.
9pF
AINN
S1
If these conditions are possible, external Schottky
clamp diodes or series resistors may be required to
limit the input current to safe levels (see Absolute
Maximum Ratings table).
The ADS1174/78 is a high-performance ADC. For
optimum performance, it is critical that the appropriate
circuitry be used to drive the ADS1174/78 inputs. See
the Applications Information section for the
recommended circuits.
The ADS1174/78 uses switched-capacitor circuitry to
measure the input voltage. Internal capacitors are
charged by the inputs and then discharged. Figure 7
shows a conceptual diagram of these circuits. Switch
S2 represents the net effect of the modulator circuitry
in discharging the sampling capacitor; the actual
implementation is different. The timing for switches S1
and S2 is shown in Figure 8. The sampling time
(tSAMPLE) is the inverse of modulator sampling
frequency (fMOD) and is a function of the mode, the
CLKDIV input, and frequency of CLK, as shown in
Table 3.
The average load presented by the switched
capacitor input can be modeled with an effective
differential impedance, as shown in Figure 9. Note
that the effective impedance is a function of fMOD.
S2
AGND AVDD
ESD Protection
Figure 7. Equivalent Analog Input Circuitry
tSAMPLE = 1/fMOD
S1
S2
ON
OFF
ON
OFF
Figure 8. S1 and S2 Switch Timing for Figure 7
Table 3. Modulator Frequency (fMOD) versus Mode
Selection
MODE SELECTION
High-Speed
Low-Power
CLKDIV
fMOD
1
fCLK/8
0
fCLK/4
1
fCLK/40
0
fCLK/8
AINP
Zeff = 14kW ´ (6.75MHz/fMOD)
AINN
Figure 9. Effective Input Impedances
12
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VOLTAGE REFERENCE INPUTS
(VREFP, VREFN)
The voltage reference for the ADS1174/78 ADC is
the differential voltage between VREFP and VREFN:
VREF = (VREFP – VREFN). The voltage reference is
common to all channels. The reference inputs use a
structure similar to that of the analog inputs with the
equivalent circuitry on the reference inputs shown in
Figure 10. As with the analog inputs, the load
presented by the switched capacitor can be modeled
with an effective impedance, as shown in Figure 11.
However, the reference input impedance depends on
the number of active (enabled) channels in addition to
fMOD. As a result of the change of reference input
impedance caused by enabling and disabling
channels, the regulation and settling time of the
external reference should be noted, so as not to
affect the readings of other channels.
VREFP
VREFN
AGND
AGND
AVDD
AVDD
ESD
Protection
Figure 10. Equivalent Reference Input Circuitry
VREFP
If these conditions are possible, external Schottky
clamp diodes or series resistors may be required to
limit the input current to safe levels (see Absolute
Maximum Ratings table).
Note that the valid operating range of the reference
inputs is limited to the following:
–0.1V ≤ VREFN ≤ 0.1V
VREFN + 0.5V ≤ VREFP ≤ VREFN + 3.1V
A high-quality reference voltage with the appropriate
drive strength is essential for achieving the best
performance from the ADS1174/78. Noise and drift
on the
reference
degrade
overall system
performance. See the Application Information section
for example reference circuits.
CLOCK INPUT (CLK)
The ADS1174/78 requires a clock input for operation.
Each ADS1174/78 converter operates from the same
clock input. At the maximum data rate, the clock input
can be either 27MHz or 13.5MHz (5.4MHz, low-power
mode), determined by the setting of the CLKDIV
input. The selection of the external clock frequency
(fCLK) does not affect the resolution (the oversampling
ratio, OSR, remains fixed) or power dissipation of the
ADS1174/78. However, a slower fCLK can reduce the
power consumption of an external clock driver. The
output data rate scales with clock frequency, down to
a minimum clock frequency of fCLK = 100kHz. Table 4
summarizes the ratio of clock input frequency (fCLK) to
data rate (fDATA), maximum data rate and
corresponding maximum clock input for the two
operating modes.
Table 4. Clock Input Options
VREFN
MODE
SELECTION
High-Speed
5.2kW
Zeff =
´ (6.75MHz/fMOD)
N
Low-Power
fCLK
(MHz)
CLKDIV
fCLK/fDATA
27
1
512
13.5
0
256
27
1
2,560
5.4
0
512
DATA RATE
(SPS)
52,734
10,547
N = number of active channels.
Figure 11. Effective Reference Impedance
ESD diodes protect the reference inputs. To keep
these diodes from turning on, make sure the voltages
on the reference pins do not go below AGND by
more than 0.4V, and likewise do not exceed AVDD by
0.4V.
As with any high-speed data converter, a high-quality,
low-jitter clock is essential for optimum performance.
Crystal clock oscillators are the recommended clock
source. Make sure to avoid excess ringing on the
clock input; keeping the clock trace as short as
possible using a 50Ω series resistor, placed close to
the source end, often helps.
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ADS1174
ADS1178
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MODE SELECTION (MODE)
SYNCHRONIZATION (SYNC)
The ADS1174/78 supports two modes of operation:
High-Speed and Low-Power. These modes offer
optimization of speed and power. The mode selection
is determined by the status of the digital input MODE
pins, as shown in Table 5. The ADS1174/78
constantly monitors the status of the MODE pin
during operation.
The ADS1174/78 can be synchronized by pulsing the
SYNC pin low and then returning the pin high. When
the pin goes low, the conversion process stops, and
the internal counters used by the digital filter are
reset. When the SYNC pin returns high, the
conversion process restarts. Synchronization allows
the conversion to be aligned with an external event,
such as a reference timing pulse.
Table 5. Mode Selection
MODE
MODE SELECTION
MAX fDATA(1)
0
High-Speed
52,734
1
Low-Power
10,547
(1) fCLK = 27MHz (CLKDIV = 1).
When using the SPI protocol, DRDY is held high after
a mode change occurs until settled (or valid) data are
ready, as shown in Figure 12 and Table 6.
In Frame-Sync protocol, the DOUT pins are held low
after a mode change occurs until settled data are
ready, as shown in Figure 12 and Table 6. Data can
be read from the device to detect when DOUT
changes to logic 1, indicating valid data.
Since the converters of the ADS1174/78 operate in
parallel from the same master clock and use the
same SYNC input control, they are, by default, in
synchronization with each other. However, the
synchronization of multiple ADS1174/78s is
somewhat different. At device power-on, variations in
internal reset thresholds from device to device may
result in uncertainty in conversion timing.
The SYNC pin can be used to synchronize multiple
ADS1174/78s to within the same CLK cycle.
Figure 13 illustrates the timing requirement of SYNC
and CLK in SPI format.
See Figure 14 for the Frame-Sync format timing
requirement.
MODE
ADS1174/78
Mode
Previous
Mode
New Mode
tNDR-SPI
SPI
Protocol
DRDY
New Mode
Valid Data Ready
tNDR-FS
Frame-Sync DOUT
Protocol
New Mode
Valid Data on DOUT
Figure 12. Mode Change Timing
Table 6. Mode Change
SYMBOL
14
DESCRIPTION
MIN
tNDR-SPI
Time for new data to be ready (SPI)
tNDR-FS
Time for new data to be ready (Frame-Sync)
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TYP
127
MAX
UNITS
129
Conversions (1/fDATA)
128
Conversions (1/fDATA)
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After synchronization, indication of valid data
depends on the whether SPI or Frame-Sync format is
used.
In the SPI format, DRDY goes high as soon as SYNC
is taken low; see Figure 13. After SYNC is returned
high, DRDY stays high while the digital filter is
settling. Once valid data are ready for retrieval,
DRDY goes low.
In the Frame-Sync format, DOUT goes low as soon
as SYNC is taken low; see Figure 14. After SYNC is
returned high, DOUT stays low while the digital filter
is settling. Once valid data are ready for retrieval,
DOUT begins to output valid data. For proper
synchronization, FSYNC, SCLK, and CLK must be
established before taking SYNC high, and must then
remain running.
tCSHD
CLK
tSCSU
tSYN
SYNC
tNDR
DRDY
Figure 13. Synchronization Timing for SPI Protocol
Table 7. SPI Protocol
SYMBOL
DESCRIPTION
MIN
TYP
MAX
UNITS
tCSHD
CLK to SYNC hold time (to not latch on CLK edge)
10
ns
tSCSU
SYNC to CLK setup time (to latch on CLK edge)
5
ns
tSYN
Synchronize pulse width
1
tNDR
Time for new data to be ready
CLK periods
129
Conversions (1/fDATA)
tCSHD
CLK
tSCSU
tSYN
SYNC
FSYNC
tNDR
Valid Data
DOUT
Figure 14. Synchronization Timing for Frame-Sync Protocol
Table 8. Frame-Sync Protocol
SYMBOL
DESCRIPTION
MIN
TYP
MAX
UNITS
tCSHD
CLK to SYNC hold time (to not latch on CLK edge)
10
ns
tSCSU
SYNC to CLK setup time (to latch on CLK edge)
5
ns
tSYN
Synchronize pulse width
tNDR
Time for new data to be ready
1
127
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CLK periods
128
Conversions (1/fDATA)
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ADS1174
ADS1178
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POWER-DOWN (PWDN)
The ADS1174/78 measurement channels can be
independently powered down by use of the PWDN
inputs. To enter the power-down mode, hold the
respective PWDN pin low for at least two fCLK cycles.
To exit power-down, return the corresponding PWDN
pin high. Note that when all channels are powered
down, the ADS1174/78 enters a microwatt (µW)
power state where all internal biasing is powered
down. In this event, the TEST[1:0] input pins must be
driven; all other input pins can float (the ADS1174/78
outputs remain driven).
As shown in Figure 15 and Table 9, a maximum of
130 conversion cycles (SPI interface) or 129
conversion cycles (Frame-Sync interface) must
elapse before reading data after exiting power-down.
Data from channels already running are not affected.
The user software can perform the required delay
time in the following ways:
1. Count the number of data conversions after
taking the PWDN pin high.
After powering up one or more channels, the
channels are synchronized to each other. It is not
necessary to use the SYNC pin to synchronize them.
When a channel is powered down in TDM data
format, the data for the powered-down channel are
either forced to zero (fixed-position TDM data mode)
or replaced by shifting the data from the next channel
into the vacated data position (dynamic-position TDM
data mode).
In discrete data format, the data are always forced to
zero.
When
powering-up
a
channel
in
dynamic-position TDM data format mode, the channel
data remain packed until the data are ready, at which
time the data frame is expanded to include the
just-powered channel data. See the Data Format
section for details.
···
CLK
PWDN
2. Wait
for
130/fDATA
(SPI)
or
129/fDATA
(Frame-Sync) after taking the PWDN pins high.
3. Detect for non-zero data in the powered-up
channel.
···
tPDWN
tNDR
(1)
DRDY/FSYNC
DOUT
(Discrete Data Output Mode)
Post Power-Up Data
DOUT1
(TDM Mode, Dynamic Position)
Normal Position
Data Shift Position
Normal Position
DOUT1
(TDM Mode, Fixed Position)
Normal Position
Data Remain in Position
Normal Position
NOTE: (1) In SPI protocol, the timing occurs on the falling edge of DRDY/FSYNC. Powering down all channels forces DRDY/FSYNC high.
Figure 15. Power-Down Timing
Table 9. Power-Down Timing
SYMBOL
tPDWN
tNDR
16
DESCRIPTION
MIN
PDWN pulse width to enter Power-Down mode
TYP
MAX
2
UNITS
CLK periods
Time for new data to be ready (SPI)
129
130
Conversions (1/fDATA)
Time for new data to be ready (Frame-Sync)
128
129
Conversions (1/fDATA)
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FORMAT[2:0]
SERIAL INTERFACE PROTOCOLS
Data can be read from the ADS1174/78 with two
serial interface protocols (SPI or Frame-Sync) and
several options of data formats (TDM/Discrete and
Fixed/Dynamic data positions). The FORMAT[2:0]
inputs are used to select among the options. Table 10
lists the available options. See the DOUT Modes
section for details of the DOUT modes and data
positions.
Data are retrieved from the ADS1174/78 using the
serial interface. Two protocols are available: SPI and
Frame-Sync. The same pins are used for both
interfaces: SCLK, DRDY/FSYNC, DOUT[4:1] (or
DOUT[8:1] for the ADS1178), and DIN. The
FORMAT[2:0] pins select the desired interface
protocol.
SPI SERIAL INTERFACE
Table 10. Data Output Format
FORMAT[2:0]
INTERFACE
PROTOCOL
DOUT
MODE
DATA
POSITION
000
SPI
TDM
Dynamic
001
SPI
TDM
Fixed
010
SPI
Discrete
—
011
Frame-Sync
TDM
Dynamic
100
Frame-Sync
TDM
Fixed
101
Frame-Sync
Discrete
—
DATA FORMAT
The ADS1174/78 outputs 16 bits of data in two’s
complement format.
A positive full-scale input produces an ideal output
code of 7FFFh, and the negative full-scale input
produces an ideal output code of 8000h. The output
clips at these codes for signals exceeding full-scale.
Table 11 summarizes the ideal output codes for
different input signals.
Table 11. Ideal Output Code versus Input Signal
INPUT SIGNAL VIN
(AINP – AINN)
IDEAL OUTPUT CODE(1)
≥ +VREF
7FFFh
) VREF
2 15 * 1
0001h
0
0000h
* VREF
2 15 * 1
FFFFh
ǒ2 2* 1Ǔ
v −VREF
15
15
8000h
(1) Excludes effects of noise, INL, offset, and gain errors.
The SPI-compatible format is a simple read-only
interface. Data ready for retrieval are indicated by the
falling DRDY output and are shifted out on the falling
edge of SCLK, MSB first. The interface can be
daisy-chained using the DIN input when using
multiple ADS1174/78s. See the Daisy-Chaining
section for more information.
SCLK
The serial clock (SCLK) features a Schmitt-triggered
input and shifts out data on DOUT on the falling
edge. It also shifts in data on the falling edge on DIN
when this pin is being used for daisy-chaining. The
device shifts data out on the falling edge and the user
typically shifts this data in on the rising edge. Even
though the SCLK input has hysteresis, it is
recommended to keep SCLK as clean as possible to
prevent glitches from accidentally shifting the data.
SCLK may be run as fast as the CLK frequency.
SCLK may be either in free-running or stop-clock
operation
between
conversions.
For
best
performance, use fSCLK/fCLK ratios of 1, 1/2, 1/4, 1/8,
etc. NOTE: One CLK period is required after DRDY
falls, to start shifting data (see Timing Requirements:
SPI Format ).
DRDY/FSYNC (SPI Format)
In the SPI format, this pin functions as the DRDY
output. It goes low when data are ready for retrieval
and then returns high on the falling edge of the first
subsequent SCLK. If data are not retrieved (that is,
SCLK is held low), DRDY pulses high just before the
next conversion data are ready, as shown in
Figure 16. The new data are loaded within one CLK
cycle before DRDY goes low. All data must be shifted
out before this time to avoid being overwritten.
1/fDATA
1/fCLK
DRDY
SCLK
Figure 16. DRDY Timing with No Readback
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DOUT
In Discrete Data Output mode, the conversion data
are output on the individual DOUT pins (DOUT1,
DOUT2, etc.), whereas in TDM mode, data are output
only on DOUT1. The MSB data are valid on
DOUT[4:1]/[8:1] when DRDY goes low. The
subsequent bits are shifted out with each falling edge
of SCLK. If daisy-chaining (TDM mode), the data
shifted in using DIN appear on DOUT1 after all
channel data have been shifted out.
DIN
This input is used when multiple ADS1174/78s are to
be daisy-chained together. The DOUT1 pin of the first
device connects to the DIN pin of the next, etc. It can
be used with either the SPI or Frame-Sync formats.
Data are shifted in on the falling edge of SCLK. When
using only one ADS1174/78, tie DIN low. See the
Daisy-Chaining section for more information.
FRAME-SYNC SERIAL INTERFACE
Frame-Sync format is similar to the interface often
used on audio ADCs. It operates in slave
fashion—the user must supply framing signal FSYNC
(similar to the left/right clock on stereo audio ADCs)
and the serial clock SCLK (similar to the bit clock on
audio ADCs). The data is output MSB first or
left-justified. When using Frame-Sync format, the
FSYNC and SCLK inputs must be continuously
running with the required relationships shown in the
Frame-Sync Timing Requirements.
SCLK
The serial clock (SCLK) features a Schmitt-triggered
input and shifts out data on DOUT on the falling
edge. It also shifts in data on the falling edge on DIN
when this pin is being used for daisy-chaining. Even
though SCLK has hysteresis, it is recommended to
keep SCLK as clean as possible to prevent glitches
from accidentally shifting the data. When using
Frame-Sync format, SCLK must run continuously; if
SCLK is disabled or interrupted, the data readback
18
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will be corrupted. The number of SCLKs within a
frame period (FSYNC clock) can be any power of two
ratio of clock cycles (1, 1/2, 1/4, etc.), as long as the
number of cycles is sufficient to shift the data output
from all channels within one data frame.
DRDY/FSYNC (Frame-Sync Format)
In Frame-Sync format, this pin is used as the FSYNC
input. The frame-sync input (FSYNC) sets the frame
period which must be same as the data rate. The
required number of fCLK cycles to each FSYNC period
depends on the mode selection and the CLKDIN
input. Table 4 indicates the number of CLK cycles to
each frame (fCLK/fDATA). If the FSYNC period is not
the proper value, data readback is corrupted.
DOUT
In Discrete Data Output mode, the conversion data
are shifted out on the individual DOUT pins (DOUT1,
DOUT2, etc.), whereas in TDM mode, data are output
only on DOUT1. The MSB data become valid on
DOUT[4:1]/[8:1] on the SCLK rising edge prior to
FSYNC going high. The subsequent bits are shifted
out with each falling edge of SCLK. If daisy-chaining
(TDM mode), the data shifted in using DIN appear on
DOUT1 after all channel data have been shifted out
(that is, 4 channels × 16 bits per channel = 64 bits for
the ADS1174, and 8 channels × 16 bits per channel =
128 bits for the ADS1178).
DIN
This input is used when multiple ADS1174/78s are to
be daisy-chained together. It can be used with either
SPI or Frame-Sync formats. Data are shifted in on
the falling edge of SCLK. When using only one
ADS1174/78, tie DIN low. See the Daisy-Chaining
section for more information.
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DOUT MODES
For both SPI and Frame-Sync interface protocols,
either the data are shifted out through individual
channel DOUT pins in a parallel data format (Discrete
mode), or the data for all channels are shifted out in
series through common pin DOUT1 (TDM mode).
output from another ADS1174, ADS1178, or other
compatible device. Note that when all channels of the
ADS1174/78 are powered down, the interface is
powered down, rendering the DIN input powered
down as well. When one or more channels of the
device are powered down, the data format of the
TDM mode can be fixed or dynamic.
TDM Mode
TDM Mode, Fixed-Position Data
In time division multiplexed (TDM) data output mode,
the data for all channels are shifted out, in series, on
a single pin (DOUT1). As shown in Figure 17, the
data from channel 1 are shifted out first, followed by
channel 2 data, etc. After the data from the last
channel are shifted out (channel 4 for the ADS1174
or channel 8 for the ADS1178), the data from the DIN
input follow. DIN is used to daisy-chain the data
In this TDM data output mode, the data position of
the channels remains fixed, regardless of whether
channels are disabled. If a channel is powered down,
data are forced to zero, but occupy the same position
within the data stream. Figure 18 shows the data
stream with channel 1 and channel 3 powered down.
SCLK
1
2
15
16
17
31
32
33
47
48
49
63
64
65
66
67
DOUT1
(ADS1174)
CH1
CH2
CH3
CH4
DIN
DOUT1
(ADS1178)
CH1
CH2
CH3
CH4
CH5
113
127
128
129
CH8
130
131
DIN
DRDY
(SPI)
FSYNC
(Frame-Sync)
Figure 17. TDM Mode (All Channels Enabled)
SCLK
1
2
15
16
17
31
32
33
47
48
49
63
64
65
66
67
DOUT1
(ADS1174)
CH1
CH2
CH3
CH4
DIN
DOUT1
(ADS1178)
CH1
CH2
CH3
CH4
CH5
113
127
128
129
CH8
130
131
DIN
DRDY
(SPI)
FSYNC
(Frame-Sync)
Figure 18. TDM Mode, Fixed-Position Data (Channels 1 and 3 Shown Powered Down)
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ADS1174
ADS1178
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TDM Mode, Dynamic Position Data
Discrete Data Output Mode
In this TDM data output mode, when a channel is
powered down, the data from higher channels shift
one position in the data stream to fill the vacated data
slot. Figure 19 shows the data stream with channel 1
and channel 3 powered down.
In Discrete data output mode, the channel data are
shifted out in parallel using individual channel data
output pins DOUT[4:1] for the ADS1174, or
DOUT[8:1] for the ADS1178. After the 16th SCLK,
the channel data are forced to zero. The data are
also forced to zero for powered-down channels.
Figure 20 depicts the data format.
SCLK
1
2
15
16
17
31
32
33
34
DOUT1
(ADS1174)
CH2
CH4
DIN
DOUT1
(ADS1178)
CH2
CH4
CH5
35
80
81
95
CH8
96
97
98
99
DIN
DRDY
(SPI)
FSYNC
(Frame- Sync)
Figure 19. TDM Mode, Dynamic Position Data (Channels 1 and 3 Shown powered Down)
SCLK
1
2
14
DOUT1
CH1
DOUT2
CH2
DOUT3
CH3
DOUT4
CH4
DOUT5
CH5
DOUT6
CH6
DOUT7
CH7
DOUT8
CH8
15
16
ADS1178 Only
DRDY
(SPI)
FSYNC
(Frame-Sync)
Figure 20. Discrete Data Output Mode
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DAISY-CHAINING
The maximum number of channels that may be
daisy-chained in this way is limited by the frequency
of fSCLK, the mode selection, and the CLKDIV input.
The frequency of fSCLK must be high enough to
completely shift the data out from all channels within
one fDATA period. Table 12 lists the maximum number
of daisy-chained channels when fSCLK = fCLK.
Multiple ADS1174/78s can be daisy-chained together
to simplify the serial interface connections. The
DOUT1 data output pin of one ADS1174/78 is
connected to the DIN input of the next ADS1174/78.
As Figure 21 illustrates, the DOUT1 pin of device 1
provides the output data to a controller, and the DIN
input of device 2 is grounded. Figure 22 describes the
data format when reading data back in a daisy-chain
configuration.
SYNC
SYNC
CLK
CLK
DIN
DIN
ADS1178
U2
SYNC
ADS1178
U1
DRDY
CLK
DOUT1
DRDY Output from Device 1
DIN
DOUT1
SCLK
SCLK
Serial Data from Devices 1 and 2
SCLK
Figure 21. Daisy-Chaining of Two ADS1178s, SPI Protocol (FORMAT[2:0] = 000 or 001)
SCLK
DOUT1
1
2
CH1, U1
17
18
33
CH2, U1
34
CH3, U1
49
50
CH4, U1
65
66
CH5, U1
129
130
CH1, U2
145
146
CH2, U2
257
258
DIN2
DRDY
(SPI)
FSYNC
(Frame-Sync)
Figure 22. Daisy-Chain Data Format of Figure 21
Table 12. Maximum Channels in a Daisy-Chain (fSCLK = fCLK)
MODE SELECTION
High-Speed
Low-Power
CLKDIV
MAXIMUM NUMBER OF CHANNELS
1
32
0
16
1
160
0
32
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ADS1174
ADS1178
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To increase the number of data channels possible in
a chain, a segmented DOUT scheme may be used,
producing two data streams. Figure 23 illustrates four
ADS1178s, with a pair of ADS1178s daisy-chained
together. The channel data of each daisy-chained
pair are shifted out in parallel and are received by the
processor through independent data channels.
Whether the interface protocol is SPI or Frame-Sync,
it is recommended to synchronize all devices by tying
the SYNC inputs together. When synchronized in SPI
protocol, it is only necessary to monitor the DRDY
output of one ADS1178.
In Frame-Sync interface protocol, the data from all
devices are ready on the rising edge of FSYNC.
Since DOUT1 and DIN are both shifted on the falling
edge of SCLK, the propagation delay on DOUT1
creates a setup time for DIN. Minimize the skew in
SCLK to avoid timing violations.
SYNC
CLK
ADS1178
U4
SYNC
ADS1178
U3
SYNC
ADS1178
U2
SYNC
ADS1178
U1
SYNC
CLK
CLK
CLK
CLK
DIN
DOUT1
DIN
DOUT1
DIN
DOUT1
DIN
FSYNC
FSYNC
FSYNC
FSYNC
SCLK
SCLK
SCLK
SCLK
DOUT1
Serial
Data
from
Devices
3 and 4
Serial
Data
from
Devices
1 and 2
SCLK
FSYNC
Figure 23. Segmented DOUT Daisy-Chain, Frame-Sync Protocol (FORMAT[2:0] = 011 or 100)
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POWER SUPPLIES
be sequenced at the same time if the supplies are
tied together. Each supply has an internal reset circuit
whose outputs are summed together to generate a
global power-on reset. After the supplies have
exceeded the reset thresholds, 218 fCLK cycles are
counted before the converter initiates the conversion
process. Following the CLK cycles, the data for 129
conversions are suppressed by the ADS1174/78 to
allow output of fully-settled data. In SPI protocol,
DRDY is held high during this interval. In frame-sync
protocol, DOUT is forced to zero. The power supplies
should be applied before any analog or digital pin is
driven. For consistent performance, assert SYNC
after device power-on when data first appear.
The ADS1174/78 has three power supplies: AVDD,
DVDD, and IOVDD. AVDD is the analog supply that
powers the modulator, DVDD is the digital supply that
powers the digital core, and IOVDD is the digital I/O
power supply. The IOVDD and DVDD power supplies
can be tied together if desired (+1.8V). To achieve
rated performance, it is critical that the power
supplies are bypassed with 0.1µF and 10µF
capacitors placed as close as possible to the supply
pins. A single 10µF ceramic capacitor may be
substituted in place of the two capacitors.
Figure 24 shows the start-up sequence of the
ADS1174/78. At power-on, bring up the DVDD supply
first, followed by IOVDD and then AVDD. Check the
power-supply sequence for proper order, including
the ramp rate of each supply. DVDD and IOVDD may
DVDD
1V nom
(1)
1V nom
IOVDD
AVDD
(1)
3V nom
(1)
Internal Reset
CLK
18
2
fCLK
129 (max)
tDATA
DRDY
(SPI Protocol)
DOUT
(Frame-Sync Protocol)
Valid Data
(1) The power-supply reset thresholds are approximate.
Figure 24. Start-Up Sequence
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ADS1174
ADS1178
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
PIN TEST USING TEST[1:0] INPUTS
Test mode allows continuity testing of the digital I/O
pins. In this mode, the normal functions of the digital
pins are disabled and routed to each other as pairs
through internal logic, as shown in Table 13. Note
that some of the digital input pins become outputs;
this configuration should be taken into account when
using test mode.
Table 13. Test Mode Pin Map (TEST[1:0] = 11)
TEST MODE PIN MAP (1)
(1)
(2)
24
INPUT PINS
OUTPUT PINS
PWDN1
DOUT1
PWDN2
DOUT2
PWDN3
DOUT3
PWDN4
DOUT4
PWDN5
(2)
DOUT5 (2)
PWDN6
(2)
DOUT6
(2)
PWDN7
(2)
DOUT7 (2)
PWDN8
(2)
DOUT8 (2)
MODE
DIN
FORMAT0
CLKDIV
FORMAT1
DRDY/FSYNC
FORMAT2
SCLK
The analog input, power supply, and ground pins
remain connected as normal. The test mode is
engaged by the setting the pins TEST[1:0] = 11. For
normal converter operation, set TEST[1:0] = 00.
VCOM OUTPUT
The VCOM pin is an analog output of approximately
AVDD/2. This voltage may be used to set the
common-mode voltage of the input buffers. The drive
capability of this output is limited; most cases require
an external buffer to minimize loading. A 0.1µF
capacitor to AGND is recommended to reduce noise
pick-up.
ADS1174/ADS1178
OPA350
VCOM » (AVDD/2)
0.1mF
NOTE: Buffer is required if VCOM is used for any purpose.
Figure 25. VCOM Output
The CLK input does not have a test output; SYNC = 1 and is
an output.
ADS1178 only.
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APPLICATION INFORMATION
To obtain the specified performance from the
ADS1174/78, the following layout and component
guidelines should be considered.
1. Power Supplies: The device requires three
power supplies for operation: DVDD, IOVDD, and
AVDD. The range for DVDD is 1.65V to 1.95V;
the range of IOVDD is 1.65V to 3.6V; and AVDD
is restricted to 4.75V to 5.25V. For all supplies,
use a 10µF tantalum capacitor, bypassed with a
0.1µF ceramic capacitor, placed close to the
device pins. Alternatively, a single 10µF ceramic
capacitor can be used. The supplies should be
relatively free of noise and should not be shared
with devices that produce voltage spikes (such as
relays, LED display drivers, etc.). If a switching
power-supply source is used, the voltage ripple
should be low (< 2mV) and the switching
frequency outside the passband of the converter.
2. Ground Plane: A single ground plane connecting
both AGND and DGND pins can be used. If
separate digital and analog grounds are used,
connect the grounds together at the converter, or
at the power entry point of the printed circuit
board (PCB).
3. Digital Inputs: It is recommended to
source-terminate the digital inputs to the device
with 50Ω series resistors. The resistors should be
placed close to the driving end of the digital
source (oscillator, logic gates, DSP, etc.) This
placement helps to reduce ringing on the digital
lines, which may lead to degraded ADC
performance.
4. Analog/Digital Circuits: Place analog circuitry
(input buffer, reference) and associated tracks
together, keeping them away from digital circuitry
(DSP, microcontroller, logic). Avoid crossing
digital tracks across analog tracks to reduce
noise coupling and crosstalk.
5. Reference Inputs: It is recommended to use
either a minimum 10µF tantalum with a 0.1µF
ceramic capacitor, or a single 1µF ceramic
capacitor, directly across the reference inputs,
VREFP and VREFN. The reference input should
be driven by a low-impedance source. For best
performance, the reference should be low-noise.
6. Analog Inputs: The analog input pins must be
driven differentially to achieve specified
performance. A true differential driver or
transformer (for ac applications) can be used for
this purpose. Route the analog inputs tracks
(AINP, AINN) as a pair from the buffer to the
converter using short, direct tracks and away
from digital tracks.
A 1nF to 10nF capacitor should be used directly
across the analog input pins, AINP and AINN. A
low-k dielectric (such as COG or film type) should
be used to maintain low THD. Capacitors from
each analog input to ground can be used. They
should be no larger than 1/10 the size of the
difference capacitor (typically 100pF) to preserve
the AC common-mode performance.
7. Component Placement: Place the power supply,
analog input, and reference input bypass
capacitors as close as possible to the device
pins. This layout is particularly important for the
small-value ceramic capacitors. Surface-mount
components are recommended to avoid the
higher inductance of leaded components.
Figure 26 to Figure 28 illustrate basic connections
and interfaces that can be used with the
ADS1174/78.
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ADS1174
ADS1178
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OPA1632
(1)
+3.3V
ADS1174
AINP1
(3)
10mF
AINN1
AINP2
CLK
AINN2
DRDY/FSYNC
50W
IN2
2.2nF
(3)
IN3
2.2nF
(3)
AINN3
U1
AINP4
+5V
2.2nF
+
DVDD
+1.8V
(2)
1kW
See
Note (5) 100W
1kW
100mF
+
AINN4
AVDD
(2)
10mF
10mF
20kW
REF1004
(3)
DOUT2
CVDD
(CORE)
50W
See
Note (6)
+1.6V
CLKR
200MHz
DOUT4
SYNC
PWDN1
I/O
PWDN2
PWDN4
VREFP
OPA350
+
(2)
10mF
0.1mF
VREFN
0.1mF
VCOM
(2)
0.1mF
Buffered
VCOM
Output
DR
PWDN3
0.1mF
100W
(2)
0 Q
> Q
SCLK
DOUT3
IN4
FSR
U2
DOUT1
AINP3
DVDD (I/O)
(2)
IN1
2.2nF
TMS320VC5509
IOVDD
(4)
100W
OPA350
TEST0
TEST1
DIN
AGND
DGND
+3.3V
CLKDIV
(High-Speed, Frame-Sync, TDM,
and Fixed-Position data selected.)
MODE
+3.3V
FORMAT2
FORMAT1
FORMAT0
(1) External Schottky clamp diodes or series resistors may be needed to prevent overvoltage on the inputs. See the Analog Inputs section.
(2) Indicates ceramic capacitors.
(3) Indicates COG ceramic capacitors.
(4) For pin test mode, set to logic high.
(5) The op amp and input RC components filter the REF1004 noise.
(6) U1: SN74LVC1G04. U2: SN74LVC2G74. These components re-clock the ADS1174 data output to interface to the TMS320VC5509.
Figure 26. ADS1174 Basic Connection Circuit
26
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1kW
1kW
2.7nF
Buffered
VCOM
Output
+15V
(1)
49.9W
VOCM
VIN
(2)
AINP
OPA1632
49.9W
0.1mF
AINN
-15V
(1)
2.7nF
1kW
(2)
1kW
(1) Bypass with 10µF and 0.1µF capacitors.
(2) 15nF for Low-Speed mode.
Figure 27. Basic Differential Input Signal Interface
1kW
249W
VIN
10nF
Buffered
VCOM
Output
+15V
(2)
(1)
49.9W
VOCM
AINP
OPA1632
0.1mF
AINN
-15V
(1)
10nF
1kW
49.9W
VO DIFF = 0.25 ´ VIN
VO COMM = VREF
(2)
249W
(1) Bypass with 10µF and 0.1µF capacitors.
(2) 56nF for Low-Speed mode.
Figure 28. Basic Single-Ended Input Signal Interface
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ADS1174
ADS1178
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
PowerPAD THERMALLY-ENHANCED
PACKAGING
The PowerPAD concept is implemented in standard
epoxy resin package material. The integrated circuit
is attached to the leadframe die pad using thermally
conductive epoxy. The package is molded so that the
leadframe die pad is exposed at a surface of the
package. This exposure provides an extremely low
thermal resistance to the path between the IC
junction and the exterior case. The external surface
of the leadframe die pad is located on the PCB side
of the package, allowing the die pad to be attached to
IC Die
the PCB using standard flow soldering techniques.
This soldering allows efficient attachment to the PCB
and permits the board structure to be used as a
heat-sink for the package. Using a thermal pad
identical in size to the die pad and vias connected to
the PCB ground plane, the board designer can now
implement power packaging without additional
thermal hardware (for example, external heat sinks)
or the need for specialized assembly instructions.
Figure 29 illustrates a cross-section view of a
PowerPAD package.
Mold Compount
(Epoxy)
Wire Bond
Wire Bond
Leadframe Die Pad
Exposed at Base of Package
Die Attach Epoxy
(thermally conductive)
Leadframe
Figure 29. Cross-Section View of a PowerPAD Thermally-Enhanced Package
28
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PowerPAD PCB Layout Considerations for the
ADS1174/78
Figure 30 shows the recommended layer structure for
thermal management when using a PowerPad
package on a 4-layer PCB design. Note that the
thermal pad is placed on both the top and bottom
sides of the board. The ground plane is used as the
heat-sink, while the power plane is thermally isolated
from the thermal vias.
Figure 31 shows the required thermal pad etch
pattern for the 64-lead HTQFP package used for the
ADS1174/78. Nine 13mil (0.33mm) thermal vias
plated with one ounce of copper are placed within the
thermal pad area for the purpose of connecting the
pad to the ground plane layer. The ground plane is
used as a heatsink in this application. It is very
important that the thermal via diameter be no larger
than 13mils in order to avoid solder wicking during
the reflow process. Solder wicking results in thermal
voids that reduce heat dissipation efficiency and
hamper heat flow away from the IC die.
The via connections to the thermal pad and internal
ground plane should be plated completely around the
hole, as opposed to the typical web or spoke thermal
relief connection. Plating entirely around the thermal
via provides the most efficient thermal connection to
the ground plane.
Additional PowerPAD Package Information
Texas Instruments publishes the PowerPAD
Thermally-Enhanced Package Application Report (TI
literature number SLMA002), available for download
at www.ti.com, which provides a more detailed
discussion of PowerPAD design and layout
considerations. Before attempting a board layout with
the ADS1174/78, it is recommended that the
hardware engineer and/or layout designer be familiar
with the information contained in this document.
Package
Thermal Pad
Component
Traces
13mils (0.33mm)
Component (top) Side
Thermal Via
Ground Plane
Power Plane
Thermal Isolation
(power plane only)
Solder (bottom) Side
Package
Thermal Pad
(bottom trace)
Figure 30. Recommended PCB Structure for a 4-Layer Board
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ADS1174
ADS1178
118mils (3mm)
40mils (1mm)
40mils (1mm)
SBAS373B – OCTOBER 2007 – REVISED SEPTEMBER 2008 ........................................................................................................................................ www.ti.com
Package Outline
Thermal Pad
40mils (1mm)
40mils (1mm)
118mils (3mm)
316mils (8mm)
Thermal Via
13mils (0.33mm)
316mils (8mm)
Figure 31. Thermal Pad Etch and Via Pattern for the 64-Lead HTQFP Package
30
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Revision History
Changes from Revision A (December 2007) to Revision B ........................................................................................... Page
•
•
•
•
•
Corrected typo in the Absolute Maximum Ratings table........................................................................................................ 2
Corrected caption of Figure 21; FORMAT[2:0] = 000 or 001 (instead of 011 or 100)......................................................... 21
Corrected caption of Figure 23; FORMAT[2:0] = 011 or 100 (instead of 000 or 001)......................................................... 22
Revised the Power Supplies section ................................................................................................................................... 23
Changed Figure 26 illustrating Frame-Sync connection to the DSP ................................................................................... 26
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PACKAGE OPTION ADDENDUM
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21-May-2010
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
ADS1174IPAPR
ACTIVE
HTQFP
PAP
64
1000
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1174IPAPRG4
ACTIVE
HTQFP
PAP
64
1000
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1174IPAPT
ACTIVE
HTQFP
PAP
64
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1174IPAPTG4
ACTIVE
HTQFP
PAP
64
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1178IPAPR
ACTIVE
HTQFP
PAP
64
1000
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1178IPAPRG4
ACTIVE
HTQFP
PAP
64
1000
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1178IPAPT
ACTIVE
HTQFP
PAP
64
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
ADS1178IPAPTG4
ACTIVE
HTQFP
PAP
64
250
Green (RoHS
& no Sb/Br)
CU NIPDAU Level-3-260C-168 HR
Samples
(Requires Login)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
21-May-2010
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
29-Oct-2009
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
ADS1174IPAPR
HTQFP
PAP
64
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
1000
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
ADS1174IPAPT
HTQFP
PAP
64
250
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
ADS1178IPAPR
HTQFP
PAP
64
1000
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
ADS1178IPAPT
HTQFP
PAP
64
250
330.0
24.4
13.0
13.0
1.5
16.0
24.0
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
29-Oct-2009
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
ADS1174IPAPR
HTQFP
PAP
64
1000
346.0
346.0
41.0
ADS1174IPAPT
HTQFP
PAP
64
250
346.0
346.0
41.0
ADS1178IPAPR
HTQFP
PAP
64
1000
346.0
346.0
41.0
ADS1178IPAPT
HTQFP
PAP
64
250
346.0
346.0
41.0
Pack Materials-Page 2
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