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LMP90100, LMP90099, LMP90098, LMP90097
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
LMP90100 and LMP9009x Sensor AFE System: Multichannel, Low-Power, 24-Bit Sensor
AFE With True Continuous Background Calibration
1
1 Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
24-Bit, Low-Power Sigma-Delta ADC
True Continuous Background Calibration at all
Gains
In-Place System Calibration Using Expected
Value Programming
Low-Noise Programmable Gain (1x to 128x)
Continuous Background Open / Short and Out-ofRange Sensor Diagnostics
8 Output Data Rates (ODR) With Single-Cycle
Settling
2 Matched Excitation Current Sources From 100
µA to 1000 µA (LMP90100/LMP90098)
4-DIFF / 7-SE Inputs (LMP90100/LMP90099)
2-DIFF / 4-SE Inputs (LMP90098/LMP90097)
7 General-Purpose Input/Output Pins
Chopper-Stabilized Buffer for Low Offset
SPI 4/3-wire With CRC Data Link Error Detection
50-Hz to 60-Hz Line Rejection at ODR
≤13.42 SPS
Independent Gain and ODR Selection per
Channel
Supported by WEBENCH® Sensor AFE Designer
Automatic Channel Sequencer
Key Specifications
– ENOB/NFR Up to 21.5/19 Bits
– Offset Error (Typical) 8.4 nV
– Gain Error (Typical) 7 ppm
– Total Noise < 10 µV-rms
– Integral Nonlinearity (INL Maximum) ± 15 ppm
of FSR
– Output Data Rates (ODR) 1.6775 - 214.65
SPS
– Analog Voltage, VA 2.85 to 5.5 V
– Operating Temp Range –40°C to 125°C
– 28-Pin HTSSOP Exposed Pad
2 Applications
•
•
•
Temperature and Pressure Transmitters
Strain Gauge Interface
Industrial Process Control
3 Description
The LMP90xxx is a highly integrated, multichannel,
low-power, 24-bit Sensor AFEs. The devices features
a precision, 24-bit Sigma-Delta analog-to-digital
converter (ADC) with a low-noise programmable gain
amplifier and a fully differential high-impedance
analog input multiplexer. A true continuous
background calibration feature allows calibration at all
gains and output data rates without interrupting the
signal path. The background calibration feature
essentially eliminates gain and offset errors across
temperature and time, providing measurement
accuracy without sacrificing speed and power
consumption.
Device Information(1)
PART NUMBER
PACKAGE
BODY SIZE (NOM)
HTSSOP (28)
9.70 mm x 4.40 mm
LMP90097
LMP90098
LMP90099
LMP90100
(1) For all available packages, see the orderable addendum at
the end of the datasheet.
4 Typical Application Schematic
3-Wire RTD
2 -Wire RTD
IB1
VIO
SCLK
IB2
CSB
1
+
VREFP1 VREFN1
VA
4-Wire RTD
Thermocouple
VA
2
3
4
VIN0
...
VIN2
...
VIN4
...
VIN6/VREFP2
VIN7/
VREFN2
GND
SDO/DRDYB
LMP90100
LM90xxx 24-bit Sensor AFE Family of Products
MicroController
SDI
D0
...
D6/DRDYB
CLK/XIN XOUT
LEDs/
Switches
Product
Channel Configuration
LMP90100
4 Differential/7 Single-Ended
Current Sources
LMP90099
4 Differential/7 Single-Ended
No
LMP90098
2 Differential/4 Single-Ended
Yes
LMP90097
2 Differential/4 Single-Ended
No
Yes
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
LMP90100, LMP90099, LMP90098, LMP90097
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
www.ti.com
Table of Contents
1
2
3
4
5
6
7
8
Features ..................................................................
Applications ...........................................................
Description .............................................................
Typical Application Schematic.............................
Revision History.....................................................
Description (continued).........................................
Pin Configuration and Functions .........................
Specifications.........................................................
8.1
8.2
8.3
8.4
8.5
8.6
8.7
8.8
8.9
8.10
8.11
9
1
1
1
1
2
3
4
5
Absolute Maximum Ratings ...................................... 5
ESD Ratings.............................................................. 5
Recommended Operating Conditions....................... 5
Thermal Information .................................................. 5
Electrical Characteristics .......................................... 6
SPI Timing Requirements ....................................... 11
CBS Setup and Hold Timing Requirements ........... 11
SCLK and SDI Timing Requirements ..................... 12
SDO Timing Requirements ..................................... 12
SDO and DRDYB Timing Requirements .............. 13
Typical Characteristics .......................................... 14
Detailed Description ............................................ 20
9.1 Overview ................................................................. 20
9.2 Functional Block Diagram ....................................... 20
9.3
9.4
9.5
9.6
Feature Description.................................................
Device Functional Modes........................................
Programming...........................................................
Register Maps .........................................................
20
32
33
45
10 Application and Implementation........................ 56
10.1 Application Information.......................................... 56
10.2 Typical Applications .............................................. 57
11 Power Supply Recommendations ..................... 63
11.1 VA and VIO ........................................................... 63
11.2 VREF..................................................................... 63
12 Layout................................................................... 64
12.1 Layout Guidelines ................................................. 64
12.2 Layout Example .................................................... 64
13 Device and Documentation Support ................. 65
13.1
13.2
13.3
13.4
13.5
13.6
Device Support ....................................................
Related Links ........................................................
Community Resources..........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
65
66
66
66
66
66
14 Mechanical, Packaging, and Orderable
Information ........................................................... 66
5 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision R (January 2015) to Revision S
Page
•
Changed Buffer Enable/Disable. ......................................................................................................................................... 54
•
Changed BUF_EN = 1 to 0. ................................................................................................................................................ 56
Changes from Revision Q (December 2014) to Revision R
•
Page
Added SDO Timing Requirements back in. ......................................................................................................................... 12
Changes from Revision P (March 2013) to Revision Q
Page
•
Added Pin Configuration and Functions section, ESD Ratings table, Feature Description section, Device Functional
Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device
and Documentation Support section, and Mechanical, Packaging, and Orderable Information section .............................. 1
•
Added footnote to INL, GE, and Crosstalk specifications. ..................................................................................................... 6
•
Changed tDOD1 specification to 27ns..................................................................................................................................... 12
•
Added sentence to the end of the Reset and Restart section.............................................................................................. 32
•
Deleted CH_STS from Compute the CRC... sentence......................................................................................................... 40
Changes from Revision O (March 2013) to Revision P
•
2
Page
Changed layout of National Data Sheet to TI format ........................................................................................................... 48
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Copyright © 2011–2016, Texas Instruments Incorporated
Product Folder Links: LMP90100 LMP90099 LMP90098 LMP90097
LMP90100, LMP90099, LMP90098, LMP90097
www.ti.com
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
6 Description (continued)
Another feature of the LMP90100/LMP90099/LMP90098/LMP90097 is continuous background sensor
diagnostics, allowing the detection of open and short-circuit conditions and out-of-range signals, without requiring
user intervention, resulting in enhanced system reliability.
Two sets of independent external reference voltage pins allow multiple ratiometric measurements. In addition,
two matched programmable current sources are available in the LMP90100/LMP90098 to excite external sensors
such as resistive temperature detectors and bridge sensors. Furthermore, seven GPIO pins are provided for
interfacing to external LEDs and switches to simplify control across an isolation barrier.
Collectively, these features make the LMP90100/LMP90099/LMP90098/LMP90097 complete analog front-ends
for low-power, precision sensor applications such as temperature, pressure, strain gauge, and industrial process
control. The LMP90100/LMP90099/LMP90098/LMP90097 are ensured over the extended temperature range of
-40°C to +125°C and are available in a 28-pin HTSSOP package with an exposed pad.
Copyright © 2011–2016, Texas Instruments Incorporated
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3
LMP90100, LMP90099, LMP90098, LMP90097
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
www.ti.com
7 Pin Configuration and Functions
HTSSOP (PWP0028A) PACKAGE
28 PINS
TOP VIEW
LMP90100/
LMP90099 only
VA
1
28
VIO
VIN0
2
27
D6/DRDYB
VIN1
3
26
D5
VIN2
4
25
D4
VIN3
5
24
D3
VIN4
6
23
D2
22
D1
VIN5
7
VREFP1
8
VREFN1
LMP90xxx
28-pin HTSSOP
21
D0
9
20
SDO/DRDYB
SDI
VIN6/VREFP2
10
19
VIN7/VREFN2
11
18
SCLK
IB2
12
17
CSB
IB1
13
16
GND
XOUT
14
15
XIN/CLK
LMP90100/
LMP90098 only
See below for specific information regarding options LMP90099, LMP90098, and LMP90097.
Pin Functions
PIN
NAME
VA
NO.
TYPE
DESCRIPTION
1
Analog Supply
VIN0 to VIN2
2 to 4
Analog Input
Analog input pins
VIN3 to VIN5
5 to 7
(LMP90100, LMP90099
only)
Analog Input
Analog input pins
VIN3 to VIN5
5-7
(LMP90098, LMP90097
only)
No Connect
No connect: must be left unconnected
8
Analog Input
Positive reference input
VREFN1
9
Analog Input
Negative reference input
VIN6 / VREFP2
10
Analog Input
Analog input pin or VREFP2 input
VIN7 / VREFN2
11
Analog Input
Analog input pin or VREFN2 input
IB2, IB1
12 to 13
(LMP90100, LMP90098
only)
Analog Output
IB2, IB1
12 - 13
(LMP90099, LMP90097
only)
No Connect
XOUT
14
Analog Output
XIN / CLK
15
Analog Input
GND
16
Ground
CSB
17
Digital Input
Chip select bar
SCLK
18
Digital Input
Serial clock
SDI
19
Digital Input
Serial data input
SDO / DRDYB
20
Digital Output
21 to 26
Digital IO
General purpose input/output (GPIO) pins
D6 / DRDYB
27
Digital IO
General purpose input/output pin or data ready bar
VIO
28
Digital Supply
Thermal Pad
—
—
VREFP1
D0 to D5
4
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Analog power supply pin
Excitation current sources for external RTDs
No connect: must be left unconnected
External crystal oscillator connection
External crystal oscillator connection or external clock input
Power supply ground
Serial data output and data ready bar
Digital input/output supply pin
You can leave this thermal pad floating.
Copyright © 2011–2016, Texas Instruments Incorporated
Product Folder Links: LMP90100 LMP90099 LMP90098 LMP90097
LMP90100, LMP90099, LMP90098, LMP90097
www.ti.com
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
8 Specifications
8.1 Absolute Maximum Ratings
(1) (2) (3)
See
.
MIN
MAX
UNIT
VA
Analog Supply Voltage
-0.3
6.0
V
VIO
Digital I/O Supply Voltage
-0.3
6.0
V
VREF
Reference Voltage
-0.3
VA+0.3
V
Voltage on Any Analog Input Pin to GND
(4)
-0.3
VA+0.3
V
Voltage on Any Digital Input PIN to GND
(4)
-0.3
VIO+0.3
V
-0.3
VIO+0.3
V
5
mA
Output Current Source or Sink by SDO
3
mA
Total Package Input and Output Current
20
mA
TJMAX
Junction Temperature
150
°C
Tstg
Storage Temperature
150
°C
Voltage on SDO
(4)
Input Current at Any Pin
(1)
(2)
(3)
(4)
(4)
–65
All voltages are measured with respect to GND, unless otherwise specified
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Recommended Operating Conditions indicate
conditions for which the device is functional, but do not ensure specific performance limits. For ensured specifications and test
conditions, see the Electrical Characteristics . The ensured specifications apply only for the test conditions listed. Some performance
characteristics may degrade when the device is not operated under the listed test conditions.
For soldering specifications: see product folder at www.ti.com and SNOA549.
When the input voltage (VIN) exceeds the power supply (VIN < GND or VIN > VA), the current at that pin must be limited to 5mA and
VIN has to be within the Absolute Maximum Rating for that pin. The 20 mA package input current rating limits the number of pins that
can safely exceed the power supplies with current flow to four pins.
8.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±2500
Charged-device model (CDM), per JEDEC specification JESD22C101 (2)
±1250
Machine Model (MM)
+200
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
8.3 Recommended Operating Conditions
VA
Analog Supply Voltage
VIO
Digital I/O Supply Voltage
VIN
Full Scale Input Range
VREF
Reference Voltage
Temperature Range for Electrical Characteristics
TA
MIN
MAX
2.85
5.5
V
2.7
5.5
V
±VREF / PGA
V
0.5
VA
V
TMIN = –40
TMAX = 125
°C
–40
125
°C
Operating Temperature Range
UNIT
8.4 Thermal Information
LMP90100,
LMP9009x
THERMAL METRIC (1)
PWP
UNIT
28 PINS
RθJA
(1)
(2)
Junction-to-ambient thermal resistance
(2)
41
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
The maximum power dissipation is a function of TJ(MAX) AND θJA. The maximum allowable power dissipation at any ambient
temperature is PD = (TJ(MAX) - TA) / θJA.
Copyright © 2011–2016, Texas Instruments Incorporated
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Product Folder Links: LMP90100 LMP90099 LMP90098 LMP90097
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LMP90100, LMP90099, LMP90098, LMP90097
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
www.ti.com
8.5 Electrical Characteristics
Unless otherwise noted, the key for the condition is (VA = VIO = VREF) / ODR (SPS) / buffer / calibration / gain. The typical
values apply for TA = 25°C.
PARAMETER
TEST CONDITIONS
n
Resolution
ENOB /
NFR
Effective Number of Bits
and Noise Free Resolution
ODR
Output Data Rates
Gain
Total Noise
Offset Error
Table 1
Bits
5V / all / ON / OFF / all. Shorted input.
Table 3
3V / 214.65 / ON / ON / 1
Table 1
214.6
1
Table 1
128
±7
+15
-15
3V & 5V / 214.65 / ON / ON / 16
± 15
5V / all / ON / OFF / all. Shorted input.
Table 4
µV
Below
Noise
Floor
(rms)
µV
9.52
µV
0.70
µV
1.79
8.25
µV
0.0112
0.63
µV
nV/°C
3V & 5V / 214.65 / ON / ON / 1-8
3
nV/°C
3V & 5V / 214.65 / ON / OFF / 16
25
nV/°C
3V & 5V / 214.65 / ON / ON / 16
0.4
nV/°C
6
nV/°C
3V & 5V / 214.65 / ON / ON / 128
0.125
nV/°C
5V / 214.65 / ON / OFF / 1, TA = 150°C
2360
nV / 1000
hours
5V / 214.65 / ON / ON / 1, TA = 150°C
100
nV / 1000
hours
(1)
3V & 5V / 214.65 / ON / ON / 1
Gain Drift over Time
1.22
0.00838
100
3V & 5V / 214.65 / ON / OFF / 128
Gain Drift over Temp
ppm
µV
3V & 5V / 214.65 / ON or OFF / OFF / 1-8
(1)
ppm
Table 2
5V / 214.65 / ON / ON / 128
Gain Error (1)
SPS
3V / all / ON / ON / all. Shorted input.
5V / 214.65 / ON / ON / 1
GE
Bits
1.6675
3V / 214.65 / ON / ON / 128
Offset Drift over Time
UNIT
3V / all / ON / OFF / all. Shorted input.
3V / 214.65 / ON / ON / 1
Offset Drift Over Temp (1)
MAX
Bits
3V & 5V / all / ON or OFF / ON / all
OE
TYP
24
FGA × PGA
Integral Non-Linearity (1)
INL
MIN
25°C
7
Full Range
-80
80
ppm
3V & 5V / 13.42 / ON / ON / 16
50
ppm
3V & 5V / 13.42 / ON / ON / 64
50
ppm
3V & 5V / 13.42 / ON / ON / 128
100
ppm
3V & 5V / 214.65 / ON / ON / all
0.5
ppm/°C
5V / 214.65 / ON / OFF / 1, TA = 150°C
5.9
ppm /
1000
hours
5V / 214.65 / ON / ON / 1, TA = 150°C
1.6
ppm /
1000
hours
(1)
CONVERTER'S CHARACTERISTIC
DC, 3V / 214.65 / ON / ON / 1
CMRR
Input Common Mode
Rejection Ratio
(1)
6
117
Full Range
70
25°C
dB
120
dB
50/60 Hz, 5V / 214.65 / OFF / OFF / 1
117
dB
VREF = 2.5V
101
dB
DC, 5V / 214.65 / OFF / OFF /
1
Reference Common Mode
Rejection
25°C
Full Range
90
This parameter is specified by design and/or characterization and is not tested in production
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Product Folder Links: LMP90100 LMP90099 LMP90098 LMP90097
LMP90100, LMP90099, LMP90098, LMP90097
www.ti.com
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
Electrical Characteristics (continued)
Unless otherwise noted, the key for the condition is (VA = VIO = VREF) / ODR (SPS) / buffer / calibration / gain. The typical
values apply for TA = 25°C.
PARAMETER
TEST CONDITIONS
PSRR
Power Supply Rejection
Ratio
DC, 3V / 214.65 / ON / ON / 1
NMRR
Normal Mode Rejection
Ratio (1)
47 Hz to 63 Hz, 5V / 13.42 /
OFF / OFF / 1
MIN
TYP
75
115
dB
112
dB
DC, 5V / 214.65 / ON / ON / 1
3V / 214.65 / OFF / OFF / 1
Cross-talk (1)
5V / 214.65 / OFF / OFF / 1
MAX
25°C
Full Range
Full Range
136
dB
143
dB
95
25°C
Full Range
dB
78
25°C
UNIT
95
POWER SUPPLY CHARACTERISTICS
VA
Analog Supply Voltage
2.85
3.0
5.5
V
VIO
Digital Supply Voltage
2.7
3.3
5.5
V
IVA
3V / 13.42 / OFF / OFF / 1,
ext. CLK
25°C
5V / 13.42 / OFF / OFF / 1,
ext. CLK
25°C
3V / 13.42 / ON / OFF / 64,
ext. CLK
25°C
5V / 13.42 / ON / OFF / 64,
ext. CLK
25°C
3V / 214.65 / ON / OFF / 64,
int. CLK
25°C
5V / 214.65 / ON / OFF / 64,
int. CLK
25°C
3V / 214.65 / OFF / OFF / 1,
int. CLK
25°C
5V / 214.65 / OFF / OFF / 1,
int. CLK
25°C
Analog Supply Current
400
Full Range
500
464
Full Range
555
Full Range
700
690
Full Range
800
1547
Full Range
1700
1760
Full Range
2000
826
Full Range
1000
941
Full Range
1100
3
Standby, 3V , ext. CLK
257
Standby, 5V, int. CLK
5
Standby, 3V, ext. CLK
300
Power-down, 5 V, int/ext CLK
µA
600
Standby, 3V , int. CLK
Power-down, 3 V, int/ext CLK
µA
25°C
10
4.6
Full Range
µA
µA
µA
µA
µA
µA
µA
5
25°C
µA
µA
15
2.6
Full Range
µA
9
µA
µA
REFERENCE INPUT
VREFN
+ 0.5
VA
V
GND
VREFP 0.5
V
0.5
VA
V
VREFP
Positive Reference
VREFN
Negative Reference
VREF
Differential Reference
VREF = VREFP - VREFN
ZREF
Reference Impedance
3 V / 13.42 / OFF / OFF / 1
10
MΩ
IREF
Reference Input
3 V / 13.42 / ON or OFF / ON or OFF / all
±2
µA
CREFP
Capacitance of the Positive
Reference
6
pF
See
(1)
Copyright © 2011–2016, Texas Instruments Incorporated
, gain = 1
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SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
www.ti.com
Electrical Characteristics (continued)
Unless otherwise noted, the key for the condition is (VA = VIO = VREF) / ODR (SPS) / buffer / calibration / gain. The typical
values apply for TA = 25°C.
PARAMETER
TEST CONDITIONS
CREFN
Capacitance of the
Negative Reference
ILREF
Reference Leakage Current Power-down
See
MIN
(1)
, gain = 1
TYP
MAX
UNIT
6
pF
1
nA
ANALOG INPUT
VINP
Positive Input
Gain = 1-8, buffer ON
GND +
0.1
VA - 0.1
V
Gain = 16 - 128, buffer ON
GND +
0.4
VA - 1.5
V
Gain = 1-8, buffer OFF
VINN
Negative Input
GND
VA
V
Gain = 1-8, buffer ON
GND +
0.1
VA - 0.1
V
Gain = 16 - 128, buffer ON
GND +
0.4
VA - 1.5
V
VA
V
Gain = 1-8, buffer OFF
GND
VIN
Differential Input
VIN = VINP - VINN
±VREF /
PGA
ZIN
Differential Input Impedance ODR = 13.42 SPS
15.4
MΩ
CINP
Capacitance of the Positive
Input
5V / 214.65 / OFF / OFF / 1
4
pF
CINN
Capacitance of the
Negative Input
5V / 214.65 / OFF / OFF / 1
4
pF
IIN
Input Leakage Current
3V & 5V / 13.42 / ON / OFF / 1-8
500
pA
3V & 5V / 13.42 / ON / OFF / 16 - 128
100
pA
DIGITAL INPUT CHARACTERISTICS at VA = VIO = VREF = 3.0V
VIH
Logical "1" Input Voltage
VIL
Logical "0" Input Voltage
IIL
Digital Input Leakage
Current
VHYST
Digital Input Hysteresis
0.7 x
VIO
V
-10
0.3 x VIO
V
+10
µA
0.1 x VIO
V
DIGITAL OUTPUT CHARACTERISTICS at VA = VIO = VREF = 3.0V
VOH
Logical "1" Output Voltage
Source 300 µA
VOL
Logical "0" Output Voltage
Sink 300 µA
IOZH,
IOZL
Tri-state Leakage Current
COUT
Tri-state Capacitance
2.6
V
-10
See
(1)
0.4
V
10
µA
5
pF
0, 100,
200, 300,
400, 500,
600, 700,
800, 900,
1000
µA
EXCITATION CURRENT SOURCES CHARACTERISTICS (LMP90100/LMP90098 only)
IB1, IB2
Excitation Current Source
Output
VA = VREF = 3 V
IB1/IB2 Tolerance
VA = VREF = 5 V
8
25°C
2.5%
Full Range
-7%
25°C
Full Range
-3.5%
IB1/IB2 Output Compliance
Range
VA = 3.0 V & 5.0 V, IB1/IB2 = 100 µA to 1000 µA
IB1/IB2 Regulation
VA = 5.0 V, IB1/IB2 = 100 µA to 1000 µA
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7%
0.2%
3.5%
VA - 0.8
0.07
V
%/V
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Electrical Characteristics (continued)
Unless otherwise noted, the key for the condition is (VA = VIO = VREF) / ODR (SPS) / buffer / calibration / gain. The typical
values apply for TA = 25°C.
PARAMETER
IBTC
IBMT
IBMTC
TEST CONDITIONS
MIN
VA = 3.0 V
IB1/IB2 Drift
VA = 5.0 V
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 100 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 200 µA
25°C
3V & 5V / 214.65 / OFF / OFF
/ 1, IB1/IB2 = 300 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 400 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 500 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 600 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 700 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 800 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 900 µA
25°C
3 V and 5 V / 214.65 / OFF /
OFF / 1, IB1/IB2 = 1000 µA
25°C
IB1/IB2 Matching
IB1/IB2 Matching Drift
TYP
MAX
UNIT
95
ppm/°C
60
ppm/°C
0.34%
Full Range
1.53%
0.22%
Full Range
1%
0.2%
Full Range
0.85%
0.15%
Full Range
0.8%
0.14%
Full Range
0.7%
0.13%
Full Range
0.7%
0.075%
Full Range
0.65%
0.085%
Full Range
0.6%
0.11%
Full Range
0.55%
0.11%
Full Range
0.45%
VA = 3.0 V and 5.0 V, IB1/IB2 = 100 µA to 1000 µA
2
ppm/°C
INTERNAL/EXTERNAL CLK
CLKIN
Internal Clock Frequency
CLKEXT
External Clock Frequency
External Crystal Frequency
893
See
(1)
1.8
kHz
7.2
MHz
Input Low Voltage
0
V
Input High Voltage
1
V
Frequency
1.8
Start-up time
SCLK
3.5717
7.2
MHz
10
MHz
7
Serial Clock
Copyright © 2011–2016, Texas Instruments Incorporated
3.5717
ms
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Table 1. ENOB (Noise Free Resolution) vs. Sampling Rate and Gain at VA = VIO = VREF = 3 V
Gain of the ADC
ODR (SPS)
1
2
4
8
16
32
64
128
1.6775
20.5 (18)
20.5 (18)
19.5 (17)
19 (16.5)
20.5 (18)
19.5 (17)
19 (16.5)
18 (15.5)
3.355
20 (17.5)
20 (17.5)
19 (16.5)
18.5 (16)
20 (17.5)
19 (16.5)
18.5 (16)
17 (14.5)
6.71
19.5 (17)
19.5 (17)
18.5 (16)
18 (15.5)
19.5 (17)
18.5 (16)
17.5 (15)
17 (14.5)
13.42
19 (16.5)
18.5 (16)
18 (15.5)
17.5 (15)
19 (16.5)
18 (15.5)
17.5 (15)
16.5 (14)
26.83125
20.5 (18)
20 (17.5)
19.5 (17)
19 (16.5)
20 (17.5)
19 (16.5)
18 (15.5)
17.5 (15)
53.6625
20 (17.5)
19.5 (17)
19 (16.5)
18.5 (16)
19.5 (17)
18.5 (16)
17.5 (15)
17 (14.5)
107.325
19.5 (17)
19 (16.5)
18.5 (16)
18 (15.5)
19 (16.5)
18 (15.5)
17 (14.5)
16.5 (14)
214.65
19 (16.5)
18.5 (16)
18 (15.5)
17.5 (15)
18.5 (16)
17.5 (15)
17 (14.5)
16 (13.5)
Table 2. RMS Noise (µV) vs. Sampling Rate and Gain at VA = VIO = VREF = 3 V
Gain of the ADC
ODR (SPS)
1
2
4
8
16
32
64
128
1.6775
3.08
1.90
1.53
1.27
0.23
0.21
0.15
0.14
3.355
4.56
2.70
2.21
1.67
0.34
0.27
0.24
0.26
6.71
6.15
4.10
3.16
2.39
0.51
0.40
0.37
0.35
13.42
8.60
5.85
4.29
3.64
0.67
0.54
0.51
0.49
26.83125
3.35
2.24
1.65
1.33
0.33
0.27
0.26
0.25
53.6625
4.81
3.11
2.37
1.90
0.44
0.39
0.37
0.36
107.325
6.74
4.51
3.38
2.66
0.63
0.54
0.52
0.49
214.65
9.52
6.37
4.72
3.79
0.90
0.79
0.72
0.70
Table 3. ENOB (Noise Free Resolution) vs. Sampling Rate and Gain at VA = VIO = VREF = 5 V
Gain of the ADC
SPS
1
2
4
8
16
32
64
128
1.6775
21.5 (19)
21.5 (19)
20.5 (18)
20 (17.5)
21 (18.5)
20.5 (18)
19.5 (17)
18.5 (16)
3.355
21 (18.5)
21 (18.5)
20 (17.5)
19.5 (17)
20.5 (18)
20 (17.5)
19 (16.5)
18 (15.5)
6.71
20.5 (18)
20 (17.5)
19.5 (17)
19 (16.5)
20 (17.5)
19.5 (17)
19 (16.5)
17.5 (15)
13.42
20 (17.5)
19.5 (17)
19 (16.5)
18.5 (16)
20 (17.5)
19 (16.5)
18 (15.5)
17.5 (15)
26.83125
21.5 (19)
21 (18.5)
20.5 (18)
20 (17.5)
21 (18.5)
20 (17.5)
19.5 (17)
18 (15.5)
53.6625
21 (18.5)
20.5 (18)
20 (17.5)
19.5 (17)
20.5 (18)
19.5 (17)
18.5 (16)
17.5 (15)
107.325
20.5 (18)
20 (17.5)
19.5 (17)
19 (16.5)
20 (17.5)
19 (16.5)
18 (15.5)
17 (14.5)
214.65
20 (17.5)
19.5 (17)
19 (16.5)
18.5 (16)
19.5 (17)
18.5 (16)
17.5 (15)
16.5 (14)
Table 4. RMS Noise (µV) vs. Sampling Rate and Gain at VA = VIO = VREF = 5 V
Gain of the ADC
SPS
1
2
4
8
16
32
64
128
1.6775
2.68
1.65
1.24
1.00
0.22
0.19
0.17
0.16
3.355
3.86
2.36
1.78
1.47
0.34
0.27
0.22
0.22
6.71
5.23
3.49
2.47
2.09
0.44
0.34
0.30
0.32
13.42
7.94
5.01
3.74
2.94
0.61
0.50
0.45
0.43
26.83125
2.90
1.86
1.34
1.08
0.29
0.24
0.23
0.23
53.6625
4.11
2.60
1.90
1.50
0.39
0.35
0.32
0.31
107.325
5.74
3.72
2.72
2.11
0.56
0.48
0.46
0.44
214.65
8.25
5.31
3.82
2.97
0.79
0.68
0.64
0.63
10
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SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
8.6 SPI Timing Requirements
Unless otherwise noted, specified limits apply for VA = VIO = 3.0 V.
MIN
NOM
MAX
UNIT
10
MHz
fSCLK
tCH
SCLK High time
0.4 / fSCLK
ns
tCL
SCLK Low time
0.4 / fSCLK
ns
CSB
tCH
SCLK
1
2
3
1/fSCLK
tCL
4
5
6
7
8
9
10
11
12
13
14
15
16
n
17
INST2
SDI
MSB
LSB
DRDYB is driving the pin
SDO is driving the pin
Data Byte (s)
SDO/
DRDYB
MSB
LSB
Figure 1. SPI Timing Diagram
8.7 CBS Setup and Hold Timing Requirements
Unless otherwise noted, specified limits apply for VA = VIO = 3.0 V.
MIN
NOM
MAX
UNIT
tCSSU
CSB Setup time prior to an SCLK rising edge
5
ns
tCSH
CSB Hold time after the last rising edge of
SCLK
6
ns
CSB
0.3VIO
tCSSUmin
CSB
tCSHmin
0.7VIO
SCLK
SCLK
Figure 2. CBS Setup Timing
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0.7VIO
Figure 3. CSB Hold Timing
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8.8 SCLK and SDI Timing Requirements
Unless otherwise noted, specified limits apply for VA = VIO = 3.0 V.
MIN
NOM
MAX
UNIT
tCLKR
SCLK Rise time
1.15
ns
tCLKF
SCLK Fall time
1.15
ns
tDISU
SDI Setup time prior to an SCLK rising edge
5
ns
tDIH
SDI Hold time after an SCLK rising edge
6
ns
0.9VIO
0.9VIO
0.7VIO
SCLK
SCLK
0.1VIO
0.1VIO
t CLKR
t DISU
t CLKF
SDI
0.7VIO
0.3VIO
Figure 4. SCLK Rise and Fall Time
t DIH
0.7VIO
DB
0.3VIO
Figure 5. SDI Setup and Hold Time
8.9 SDO Timing Requirements
Unless otherwise noted, specified limits apply for VA = VIO = 3.0 V.
MIN
NOM
MAX
UNIT
tDOA
SDO Access time after a
SCLK falling edge
tDOH
SDO Hold time after a
SCLK falling edge
tDOD1
SDO Disable time after
the rising edge of CSB
27
ns
tDOD2
SDO Disable time after
either edge of SCLK
27
ns
35
5
ns
ns
0.7VIO
SCLK
0.3VIO
CSB
t DOH
t DOD1
t DOA
0.9VIO
0.7VIO
0.7VIO
0.3VIO
0.3VIO
DB
DB
SDO
Figure 6. SDO and SCLK Timing
0.7VIO
SDO
DB0
0.1VIO
Figure 7. SDO and CS Timing
SCLK
SCLK
tDOD2 (optional,
0.3 VIO
SW_OFF_TRG = 1)
t DOD2
0.9VIO
SDO
0.9 VIO
SDO
DB0
DB0
0.1 VIO
0.1VIO
Figure 8. SDO Disable and SCLK Timing
12
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Figure 9. SDO Disable and SCLK Timing
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8.10 SDO and DRDYB Timing Requirements
Unless otherwise noted, specified limits apply for VA = VIO = 3.0 V.
MIN
NOM
MAX
tDOE
SDO Enable time from the falling edge of the 8th SCLK
tDOR
SDO Rise time
See
(1)
7
ns
tDOF
SDO Fall time
See
(1)
7
ns
ODR ≤ 13.42 SPS
tDRDYB
Data Ready Bar pulse at
every
1/ODR second, see
Figure 62
(1)
35
UNIT
ns
64
13.42 < ODR ≤ 214.65 SPS
µs
4
This parameter is specified by design and/or characterization and is not tested in production
SCLK
8
SDO
tDOE
SDO
0.9VIO
0.9VIO
9
0.3VIO
0.1VIO
0.7VIO
0.1VIO
t DOR
t DOF
DB7
0.3VIO
Figure 10. SDO and SCLK Enable Timing
Copyright © 2011–2016, Texas Instruments Incorporated
Figure 11. SDO Rise and Fall Timing
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8.11 Typical Characteristics
250
50
230
30
VOUT ( V)
VOUT ( V)
Unless otherwise noted, specified limits apply for VA = VIO = VREF = 3.0 V. The maximum and minimum values apply for TA
= TMIN to TMAX; the typical values apply for TA = 25°C.
210
190
170
10
-10
-30
VA = 3V
VA = 3V
150
-50
0
200
400
600
TIME (ms)
800
1000
Figure 12. Noise Measurement Without Calibration
at Gain = 1
1400
1200
1200
1000
1000
800
600
400
400
200
200
190
210
230
0
-50
250
-30
-10
10
30
50
VOUT (PV)
Figure 14. Histogram Without Calibration at Gain = 1
Figure 15. Histogram With Calibration at Gain = 1
40
20
35
15
30
10
VOUT ( V)
VOUT ( V)
1000
VA = 3V
VOUT (PV)
25
20
15
10
5
0
-5
-10
5
-15
VA = 3V
0
0
200
VA = 3V
-20
400
600
TIME (ms)
800
1000
Figure 16. Noise Measurement Without Calibration
at Gain = 8
14
800
800
600
170
400
600
TIME (ms)
1600
VA = 3V
1400
0
150
200
Figure 13. Noise Measurement With Calibration
at Gain = 1
COUNT
COUNT
1600
0
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0
200
400
600
TIME (ms)
800
1000
Figure 17. Noise Measurement With Calibration
at Gain = 8
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Typical Characteristics (continued)
Unless otherwise noted, specified limits apply for VA = VIO = VREF = 3.0 V. The maximum and minimum values apply for TA
= TMIN to TMAX; the typical values apply for TA = 25°C.
2000
2000
1500
COUNT
COUNT
1500
1000
500
0
-25
VA = 3V
VA = 3V
1000
500
-15
-5
5
15
25
0
-25
35
-15
-5
5
15
25
35
VOUT (µV)
Figure 18. Histogram Without Calibration at Gain = 8
Figure 19. Histogram With Calibration at Gain = 8
4
4
3
3
2
2
VOUT ( V)
VOUT ( V)
VOUT (PV)
1
0
-1
-2
0
-1
-2
-3
-3
VA = 3V
-4
0
200
VA = 3V
-4
400
600
TIME (ms)
800
1000
Figure 20. Noise Measurement Without Calibration
at Gain = 128
3000
0
2500
2000
2000
1500
1000
500
500
-3
-1
1
3
5
800
1000
VA = 3V
1500
1000
-5
400
600
TIME (ms)
3000
VA = 3V
2500
0
200
Figure 21. Noise Measurement With Calibration
at Gain = 128
COUNT
COUNT
1
0
-5
-3
-1
1
3
5
VOUT (PV)
VOUT (PV)
Figure 22. Histogram Without Calibration at Gain = 128
Figure 23. Histogram With Calibration at Gain = 128
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Typical Characteristics (continued)
Unless otherwise noted, specified limits apply for VA = VIO = VREF = 3.0 V. The maximum and minimum values apply for TA
= TMIN to TMAX; the typical values apply for TA = 25°C.
21
21
VA = 3V
VA = 5V
20
20
19
19
ENOB (bits)
ENOB (bits)
VA = 3V
VA = 5V
18
17
18
17
16
16
15
1
2
4
8
16
32
15
64 128
1
2
4
8
16
32
GAIN
Figure 24. ENOB vs. Gain Without Calibration
at ODR = 13.42 SPS
Figure 25. ENOB vs. Gain With Calibration
at ODR = 13.42 SPS
12
12
VA = 3V
VA = 5V
VA = 3V
VA = 5V
10
RMS NOISE (#V)
RMS NOISE (#V)
10
8
6
4
2
0
8
6
4
2
1
2
4
8
16
32
0
64 128
1
2
4
GAIN
8
16
32
Figure 27. Noise vs. Gain With Calibration
at ODR = 13.42 SPS
21
21
VA = 3V
VA = 5V
20
20
19
19
ENOB (bits)
ENOB (bits)
VA = 3V
VA = 5V
18
17
16
18
17
16
1
2
4
8
16
32
64 128
15
1
2
4
GAIN
Figure 28. ENOB vs. Gain Without Calibration
at ODR = 214.65 SPS
16
64 128
GAIN
Figure 26. Noise vs. Gain Without Calibration
at ODR = 13.42 SPS
15
64 128
GAIN
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8
16
32
64 128
GAIN
Figure 29. ENOB vs. Gain With Calibration
at ODR = 214.65 SPS
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SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
Typical Characteristics (continued)
Unless otherwise noted, specified limits apply for VA = VIO = VREF = 3.0 V. The maximum and minimum values apply for TA
= TMIN to TMAX; the typical values apply for TA = 25°C.
12
12
VA = 3V
VA = 5V
VA = 3V
VA = 5V
10
RMS NOISE (#V)
RMS NOISE (#V)
10
8
6
4
2
8
6
4
2
0
0
1
2
4
8
16
32
64 128
1
2
4
8
GAIN
64 128
Figure 31. Noise vs. Gain With Calibration
at ODR = 214.65 SPS
300
2.0
VA = 3V
250
200
VA = 5V
150
VA = 3V
100
50
OFFSET VOLTAGE ( V)
OFFSET VOLTAGE ( V)
32
GAIN
Figure 30. Noise vs. Gain Without Calibration
at ODR = 214.65 SPS
0
1.5
1.0
0.5
VA = 5V
0.0
-40 -20
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 32. Offset Error vs. Temperature Without Calibration
at Gain = 1
-40 -20
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 33. Offset Error vs. Temperature With Calibration at
Gain = 1
0.4
20
VA = 5V
15
10
VA = 3V
5
0
OFFSET VOLTAGE (uV)
25
OFFSET VOLTAGE ( V)
16
0.2
VA = 3V
0.0
VA = 5V
-0.2
-0.4
-40 -20
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 34. Offset Error vs. Temperature Without Calibration
at Gain = 8
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-40 -20
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 35. Offset Error vs. Temperature With Calibration at
Gain = 8
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Typical Characteristics (continued)
Unless otherwise noted, specified limits apply for VA = VIO = VREF = 3.0 V. The maximum and minimum values apply for TA
= TMIN to TMAX; the typical values apply for TA = 25°C.
40
160
VA = 5V
GAIN ERROR (ppm)
GAIN ERROR (ppm)
150
140
130
VA = 3V
120
20
VA = 5V
0
-20
VA = 3V
110
-40
-40 -20
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 36. Gain Error vs. Temperature Without Calibration
at Gain = 1
-40 -20
Figure 37. Gain Error vs. Temperature With Calibration
at Gain = 1
-100
-20
-120
VA = 3V
-130
-140
VA = 5V
-60
-80
VA = 5V
-100
-150
-160
-120
-40 -20
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 38. Gain Error vs. Temperature Without Calibration
at Gain = 8
-40 -20
0
0
-20
-20
-40
-40
-60
-80
0 20 40 60 80 100 120
TEMPERATURE (°C)
Figure 39. Gain Error vs. Temperature With Calibration
at Gain = 8
GAIN (dB)
GAIN (dB)
VA = 3V
-40
GAIN ERROR (ppm)
GAIN ERROR (ppm)
-110
-60
-80
1.7 SPS
3.4 SPS
6.7 SPS
13.4 SPS
-100
-100
-120
26.83 SPS
53.66 SPS
107.33 SPS
214.65 SPS
-120
1
10
FREQUENCY (Hz)
100
Figure 40. Digital Filter Frequency Response
18
0 20 40 60 80 100 120
TEMPERATURE (°C)
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10
100
FREQUENCY (Hz)
1k
Figure 41. Digital Filter Frequency Response
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Typical Characteristics (continued)
Unless otherwise noted, specified limits apply for VA = VIO = VREF = 3.0 V. The maximum and minimum values apply for TA
= TMIN to TMAX; the typical values apply for TA = 25°C.
INL (ppm of FSR)
10
5
0
-5
VA = 5V, 13.4 SPS
-10
-5 -4 -3 -2 -1 0 1
VIN (V)
2
3
4
5
Figure 42. INL at Gain = 1
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9 Detailed Description
9.1 Overview
The LMP90xxx is a low-power 24-Bit ΣΔ ADC with 4 fully differential / 7 single-ended analog channels for the
LMP90100/LMP90099 and 2 full differential / 4 single-ended for the LMP90098/LMP90097. Its serial data output
is two’s complement format. The output data rate (ODR) ranges from 1.6775 SPS to 214.65 SPS.
The serial communication for LMP90xxx is SPI, a synchronous serial interface that operates using 4 pins: chip
select bar (CSB), serial clock (SCLK), serial data in (SDI), and serial data out / data ready bar (SDO/DRYDYB).
True continuous built-in offset and gain background calibration is also available to improve measurement
accuracy. Unlike other ADCs, the LMP90xxx’s background calibration can run without heavily impacting the input
signal. This unique technique allows for positive as well as negative gain calibration and is available at all gain
settings.
The registers can be found in Programming, and a detailed description of the LMP90xxx are provided in the
following sections.
9.2 Functional Block Diagram
Chip Configurable
LMP90xxx
Channel Configurable
Fixed
EXC.
CURRENT
EXC.
CURRENT
IB1
LMP90100/LMP9
0098 only
VIO
VA
VA
IB2
POR
Open/Short
Sensor Diag.
SERIAL I/F
CONTROL
&
CALIBRATION
DATA PATH
VIN0
VIN1
VIN3
LMP90100/LMP9
0099 only
VIN4
VIN5
BACKGROUND
CALIBRATION
INPUT MUX
VIN2
PGA
1x, 2x,
4x, 8x
SCLK
SDI
SDO/DRDYB
CSB
FGA
16x
BUFF
24 bit SD
Module
VIN6/VREFP2
DIGITAL
FILTER
VIN7/VREFN2
CLK
MUX
VREF
Ext. Clk
Detect
Internal
CLK
MUX
GND
VREFP1
GPIO
VREFN1
XOUT
CLK/ D6/
XIN DRDYB
D0
9.3 Feature Description
9.3.1 True Continuous Background Calibration
The LMP90100/LMP90099/LMP90098/LMP90097 feature a 24 bit ΣΔ core with continuous background
calibration to compensate for gain and offset errors in the ADC, virtually eliminating any drift with time and
temperature. The calibration is performed in the background without user or ADC input interruption, making it
unique in the industry and eliminating down time associated with field calibration required with other solutions.
Having this continuous calibration improves performance over the entire life span of the end product.
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Feature Description (continued)
9.3.2 Continuous Background Sensor Diagnostics
Sensor diagnostics are also performed in the background, without interfering with signal path performance,
allowing the detection of sensor shorts, opens, and out-of-range signals, which vastly improves system reliability.
In addition, the fully flexible input multiplexer described below allows any input pin to be connected to any ADC
input channel providing additional sensor path diagnostic capability.
9.3.3 Flexible Input MUX Channels
The flexible input MUX allows interfacing to a wide range of sensors such as thermocouples, RTDs, thermistors,
and bridge sensors. The LMP90100/LMP90099’s multiplexer supports 4 differential channels while the
LMP90098/LMP90097 supports 2. Each effective input voltage that is digitized is VIN = VINx – VINy, where x
and y are any input. In addition, the input multiplexer of the LMP90100/LMP90099 also supports 7 single-ended
channels (LMP90098/LMP90097 supports 4), where the common ground is any one of the inputs.
9.3.4 Programmable Gain Amplifiers (FGA and PGA)
The LMP90100/LMP90099/LMP90098/LMP90097 contain an internal 16x fixed gain amplifier (FGA) and a 1x,
2x, 4x, or 8x programmable gain amplifier (PGA). This allows accurate gain settings of 1x, 2x, 4x, 8x, 16x, 32x,
64x, or 128x through configuration of internal registers. Having an internal amplifier eliminates the need for
external amplifiers that are costly, space consuming, and difficult to calibrate.
9.3.5 Excitation Current Sources (IB1 and IB2) - LMP90100/LMP90098
Two matched internal excitation currents, IB1 and IB2, can be used for sourcing currents to a variety of sensors.
The current range is from 100 µA to 1000 µA in steps of 100 µA.
9.3.6 Signal Path
9.3.6.1 Reference Input (VREF)
The differential reference voltage VREF (VREFP – VREFN) sets the range for VIN.
The muxed VREF allows the user to choose between VREF1 or VREF2 for each channel. This selection can be
made by programming the VREF_SEL bit in the CHx_INPUTCN registers (CHx_INPUTCN: VREF_SEL). The
default mode is VREF1. If VREF2 is used, then VIN6 and VIN7 cannot be used as inputs because they share the
same pin.
Refer to VREF for VREF applications information.
9.3.6.2 Flexible Input MUX (VIN)
The LMP90xxx provides a flexible input MUX as shown in Figure 43. The input that is digitized is VIN = VINP –
VINN; where VINP and VINN can be any available input.
The digitized input is also known as a channel, where CH = VIN = VINP – VINN. Thus, there are a maximum of 4
differential channels: CH0, CH1, CH2, and CH3 for the LMP90100/LMP90099. The LMP90098/LMP90097 has a
maximum of 2 differential channels: CH0 and CH1 because it does not have access to the VIN3, VIN4, and VIN5
pins.
The LMP90xxx can also be configured single-endedly, where the common ground is any one of the inputs. There
are a maximum of 7 single-ended channels: CH0, CH1, CH2, CH3, CH4, CH5, and CH6 for the
LMP90100/LMP90099 and 4: CH0, CH1, CH2, CH3 for the LMP90098/LMP90097.
The input MUX can be programmed in the CHx_INPUTCN registers. For example on the LMP90100, to program
CH0 = VIN = VIN4 – VIN1, go to the CH0_INPUTCN register and set:
1. VINP = 0x4
2. VINN = 0x1
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Feature Description (continued)
VREFP1
VIN0
VIN1
VIN2
VIN3*
VINP
+
+
-
ADC
BUFF
FGA
VINN
+
-
-
VIN4*
VIN5*
VIN6/VREFP2
VIN7/VREFN2
VREFN1
* VIN3, VIN4, VIN5 are only available for LMP90100 and LMP90099
Figure 43. Simplified VIN Circuitry
9.3.6.3
Selectable Gains (FGA and PGA)
The LMP90xxx provides two types of gain amplifiers: a fixed gain amplifier (FGA) and a programmable gain
amplifier (PGA). FGA has a fixed gain of 16x or it can be bypassed, while the PGA has programmable gain
settings of 1x, 2x, 4x, or 8x.
Total gain is defined as FGA x PGA. Thus, LMP90xxx provides gain settings of 1x, 2x, 4x, 8x, 16x, 32x, 64x, or
128x with true continuous background calibration.
The gain is channel specific, which means that one channel can have one gain, while another channel can have
the same or a different gain.
The gain can be selected by programming the CHx_CONFIG: GAIN_SEL bits.
9.3.6.4 Buffer (BUFF)
There is an internal unity gain buffer that can be included or excluded from the signal path. Including the buffer
provides a high input impedance but increases the power consumption.
When gain ≥ 16, the buffer is automatically included in the signal path. When gain < 16, including or excluding
the buffer from the signal path can be done by programming the CHX_CONFIG: BUF_EN bit.
9.3.6.5 Internal/External CLK Selection
LMP90xxx allows two clock options: internal CLK or external CLK (crystal (XTAL) or clock source).
There is an “External Clock Detection” mode, which detects the external XTAL if it is connected to XOUT and
XIN. When operating in this mode, the LMP90xxx shuts off the internal clock to reduce power consumption.
Below is a flow chart to help set the appropriate clock registers.
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Feature Description (continued)
Clock
Options
Internal CLK
External CLK Source
External
XTAL
LMP90100 will use the
internal clock
Is there a XTAL
connected to XIN and
XOUT?
No
Connect a XTAL
to XIN and XOUT
Connect an external
CLK source to the
XIN/CLK pin
LMP90100 will
automatically detect
and use the XTAL if
CLK_EXT_DET = 0
(default)
LMP90100 will
automatically use the
external CLK source
Yes
Set CLK_EXT_DET = 1 to
E\SDVV WKH ³([WHUQDO-Clock
'HWHFWLRQ´ PRGH
Set CLK_SEL = 0 to select
the internal clock
Figure 44. CLK Register Settings
The recommended value for the external CLK is discussed in the next sections.
9.3.6.6 Programmable ODRs
If using the internal CLK or external CLK of 3.5717 MHz, then the output date rates (ODR) can be selected
(using the ODR_SEL bit) as:
1. 13.42/8 = 1.6775 SPS
2. 13.42/4 = 3.355 SPS
3. 13.42/2 = 6.71SPS
4. 13.42 SPS
5. 214.65/8 = 26.83125 SPS
6. 214.65/4 = 53.6625 SPS
7. 214.65/2 = 107.325 SPS
8. 214.65 SPS (default)
If the internal CLK is not being used and the external CLK is not 3.5717 MHz, then the ODR will be different. If
this is the case, use the equation below to calculate the new ODR values.
ODR_Base1 = (CLKEXT) / (266,240)
ODR_Base2 = (CLKEXT) / (16,640)
ODR1 = (ODR_Base1) / n
(1)
(2)
where
• n = 1,2,4,8
ODR2 = (ODR_Base2) / n
(3)
where
•
n = 1,2,4,8
(4)
For example, a 3.6864 MHz XTAL or external clock has the following ODR values:
ODR_Base1 = (3.6864 MHz) / (266,240) = 13.85 SPS
ODR_Base2 = (3.6864 MHz) / (16,640) = 221.54 SPS
ODR1 = (13.85 SPS) / n = 13.85, 6.92, 3.46, 1.73 SPS
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(5)
(6)
(7)
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Feature Description (continued)
ODR2 = (221.54 SPS) / n = 221.54, 110.77, 55.38, 27.69 SPS
(8)
The ODR is channel specific, which means that one channel can have one ODR, while another channel can
have the same or a different ODR.
Note that these ODRs are meant for a single channel conversion; the ODR needs to be divided by n for n
channels scanning. For example, if the ADC were running at 214.65 SPS and four channels are being scanned,
then the ODR per channel would be 214.65/4 = 53.6625 SPS.
9.3.6.7 Digital Filter
The LMP90xxx has a fourth order rotated sinc filter that is used to configure various ODRs and to reject power
supply frequencies of 50Hz and 60Hz. The 50/60 Hz rejection is only effective when the device is operating at
ODR ≤ 13.42 SPS. If the internal CLK or the external CLK of 3.5717 MHz is used, then the LMP90xxx will have
the frequency response shown in Figure 45 to Figure 49.
0
0
6.71 SPS
13.42 SPS
-20
-20
-40
-40
GAIN (dB)
GAIN (dB)
1.6775 SPS
3.355 SPS
-60
-60
-80
-80
-100
-100
-120
-120
0
12
24
36
48
60
72
84
96
108
120
0
12
24
36
48
FREQUENCY (Hz)
Figure 45. Digital Filter Response, 1.6775 SPS and 3.355
SPS
-60
60
84
96
108
120
Figure 46. Digital Filter Response, 6.71 SPS and 13.42 SPS
0
13.42 SPS
26.83125 SPS
53.6625 SPS
-70
-80
-40
GAIN (dB)
GAIN (dB)
72
FREQUENCY (Hz)
-90
-100
-80
-110
-120
-120
45
47
49
51
53
55
57
59
61
63
65
0
200
400
600
800
FREQUENCY (Hz)
1000
1200
1400
1600
1800
2000
FREQUENCY (Hz)
Figure 47. Digital Filter Response at 13.42 SPS
Figure 48. Digital Filter Response, 26.83125 SPS and
53.6625 SPS
0
0
107.325 SPS
214.65 SPS
Crystal = 3.5717 MHz
Crystal = 3.6864 MHz
-20
-40
GAIN (dB)
GAIN (dB)
-40
-80
-60
-80
-100
-120
-120
0
200
400
600
800
1000
1200
1400
1600
1800
2000
FREQUENCY (Hz)
-140
40
Figure 49. Digital Filter Response 107.325 SPS and 214.65
SPS
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45
50
55
60
FREQUENCY (Hz)
65
70
Figure 50. Digital Filter Response for a 3.5717 MHz versus
3.6864 MHz XTAL
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Feature Description (continued)
If the internal CLK is not being used and the external CLK is not 3.5717 MHz, then the filter response would be
the same as the response shown in Figure 49, but the frequency will change according to the equation:
fNEW = [(CLKEXT) / 256 ] x (fOLD / 13.952k)
(9)
Using Equation 9, an example of the filter response for a 3.5717 MHz XTAL versus a 3.6864 MHz XTAL can be
seen in Figure 50.
9.3.6.8 GPIO (D0–D6)
Pins D0-D6 are general-purpose input/output (GPIO) pins that can be used to control external LEDs or switches.
Only a high or low value can be sourced to or read from each pin.
Figure 51 shows a flow chart how these GPIOs can be programmed.
inputs
outputs
Pins
D0 ± D6 =
Set
GPIO_DIRCNx = 0
Set
GPIO_DIRCNx = 1
Read the
GPIO_DAT: Dx bit to
determine if Dx is
high or low, where
0 ” [ ” 6.
Write to GPIO_DAT: Dx bit
to drive Dx high or low,
where 0 ” [ ” 6.
Figure 51. GPIO Register Settings
9.3.7 Calibration
As seen in Figure 52, there are two types of calibration: background calibration and system calibration. These
calibrations are further described in the next sections.
Calibration
Background
calibration
Correction
System
calibration
Estimation
Offset
Gain
Figure 52. Types of Calibration
9.3.7.1 Background Calibration
Background calibration is the process of continuously determining and applying the offset and gain calibration
coefficients to the output codes to minimize the LMP90xxx’s offset and gain errors. Background calibration is a
feature built into the LMP90xxx and is automatically done by the hardware without interrupting the input signal.
Four differential channels, CH0-CH3, each with its own gain and ODRs, can be calibrated to improve the
accuracy.
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Feature Description (continued)
9.3.7.1.1 Types of Background Calibration
Figure 52 also shows that there are two types of background calibration:
1. Type 1: Correction - the process of continuously determining and applying the offset and gain calibration
coefficients to the output codes to minimize the LMP90xxx’s offset and gain errors.
– This method keeps track of changes in the LMP90xxx's gain and offset errors due to changes in the
operating condition such as voltage, temperature, or time.
2. Type 2: Estimation - the process of determining and continuously applying the last known offset and gain
calibration coefficients to the output codes to minimize the LMP90xxx’s offset and gain errors.
– The last known offset or gain calibration coefficients can come from two sources. The first source is the
default coefficient which is pre-determined and burnt in the device’s non-volatile memory. The second
source is from a previous calibration run of Type 1: Correction.
The benefits of using type 2 calibration are a higher throughput, lower power consumption, and slightly better
noise. The exact savings would depend on the number of channels being scanned, and the ODR and gain of
each channel.
9.3.7.1.2 Using Background Calibration
There are four modes of background calibration, which can be programmed using the BGCALCN bits. They are
as follows:
1. BgcalMode0: Background Calibration OFF
2. BgcalMode1: Offset Correction / Gain Estimation
3. BgcalMode2: Offset Correction / Gain Correction
– Follow Figure 53 to set other appropriate registers when using this mode.
4. BgcalMode3: Offset Estimation / Gain Estimation
Is the channel
JDLQ • 16x?
No
Set
BGCALCN = 10b to
operate the device in
BgcalMode2
Yes
Set CH_SCAN_SEL = 10b to
operate the device in
ScanMode2. Set FIRST_CH &
LAST_CH accordingly.
Correct FGA
error?
No
Set
FGA_BGCAL = 1 to
correct for FGA error
using the last known
coefficients.
Yes
Set FGA_BGCAL = 0 (default)
Figure 53. BgcalMode2 Register Settings
If operating in BgcalMode2, four channels (with the same ODR) are being converted, and FGA_BGCAL = 0
(default), then the ODR is reduced by:
1. 0.19% of 1.6775 SPS
2. 0.39% of 3.355 SPS
3. 0.78% of 6.71 SPS
4. 1.54% of 13.42 SPS
5. 3.03% of 26.83125 SPS
6. 5.88% of 53.6625 SPS
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Feature Description (continued)
7. 11.11% of 107.325 SPS
8. 20% of 214.65 SPS
9.3.7.2 System Calibration
The LMP90xxx provides some unique features to support easy system offset and system gain calibrations.
The System Calibration Offset Registers (CHx_SCAL_OFFSET) hold the System Calibration Offset Coefficients
in 24-bit, two's complement binary format. The System Calibration Gain Registers (CHx_SCAL_GAIN) hold the
System Calibration Gain Coefficient in 24-bit, 1.23, unsigned, fixed-point binary format. For each channel, the
System Calibration Offset coefficient is subtracted from the conversion result prior to the division by the System
Calibration Gain Coefficient.
A data-flow diagram of these coefficients can be seen in Figure 54.
Uncalibrated
VIN
±
OFFSET
[CHx_SCAL_
OFFSET]
y
Calibrated
ADC_DOUT
GAIN
[CHx_SCAL_
GAIN]
Figure 54. System Calibration Data-Flow Diagram
There are four distinct sets of System Calibration Offset and System Calibration Gain Registers for use with
CH0-CH3. CH4-CH6 reuse the registers of CH0-CH2, respectively.
The LMP90xxx provides two system calibration modes that automatically fill the Offset and Gain coefficients for
each channel. These modes are the System Calibration Offset Coefficient Determination mode and the System
Calibration Gain Coefficient Determination mode. The System Calibration Offset Coefficient Determination mode
must be entered prior to the System Calibration Gain Coefficient Determination mode, for each channel.
The system zero-scale condition is a system input condition (sensor loading) for which zero (0x00_0000) systemcalibrated output code is desired. It may not, however, cause a zero input voltage at the input of the ADC.
The system reference-scale condition is usually the system full-scale condition in which the system's input (or
sensor's loading) would be full-scale and the desired system-calibrated output code would be 0x80_0000
(unsigned 24-bit binary). However, system full-scale condition need not cause full-scale input voltage at the input
of the ADC.
The system reference-scale condition is not restricted to just the system full-scale condition. In fact, it can be any
arbitrary fraction of full-scale (up to 1.25 times) and the desired system-calibrated output code can be any
appropriate value (up to 0xA00000). The CHx_SCAL_GAIN register must be written with the desired systemcalibrated output code (default:0x800000) before entering the System Calibration Gain Coefficient Determination
mode. This helps in in-place system calibration.
Below are the detailed procedures for using the System Calibration Offset Coefficient Determination and System
Calibration Gain Coefficient Determination modes.
9.3.7.2.1 System Calibration Offset Coefficient Determination Mode
1. Apply system zero-scale condition to the channel (CH0/CH1/CH2/CH3).
2. Enter the System Calibration Offset Coefficient Determination mode by programming 0x1 in the SCALCN
register.
3. LMP90xxx starts a fresh conversion at the selected output data rate for the selected channel. At the end of
the conversion, the CHx_SCAL_OFFSET register is filled-in with the System Calibration Offset coefficient.
4. The System Calibration Offset Coefficient Determination mode is automatically exited.
5. The computed calibration coefficient is accurate only to the effective resolution of the device and will
probably contain some noise. The noise factor can be minimized by computing over many times, averaging
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Feature Description (continued)
(externally) and putting the resultant value back into the register. Alternatively, select the output data rate to
be 26.83 sps or 1.67 sps.
9.3.7.2.2 System Calibration Gain Coefficient Determination Mode
1. Repeat the System Calibration Offset Coefficient Determination mode to calibrate for the channel's system
offset.
2. Apply the system reference-scale condition to the channel CH0/CH1/CH2/CH3.
3. In the CHx_SCAL_GAIN Register, program the expected (desired) system-calibrated output code for this
condition in 24-bit unsigned format.
4. Enter the System Calibration Gain Coefficient Determination mode by programming 0x3 in the SCALCN
register.
5. LMP90xxx starts a fresh conversion at the selected output data rate for the channel. At the end of the
conversion, the CHx_SCAL_GAIN is filled-in (or overwritten) with the System Calibration Gain coefficient.
6. The System Calibration Gain Coefficient Determination mode is automatically exited.
7. The computed calibration coefficient is accurate only to the effective resolution of the device and will
probably contain some noise. The noise factor can be minimized by computing over many times, averaging
(externally) and putting the resultant value back into the register. Alternatively, select the output data rate to
be 26.83 sps or 1.67 sps.
9.3.7.2.3 Post-Calibration Scaling
LMP90xxx allows scaling (multiplication and shifting) for the System Calibrated result. This eases downstream
processing, if any. Multiplication is done using the System Calibration Scaling Coefficient in the
CHx_SCAL_SCALING register and shifting is done using the System Calibration Bits Selector in the
CHx_SCAL_BITS_SELECTOR register.
The System Calibration Bits Selector value should ideally be the logarithm (to the base 2) of the System
Calibration Scaling Coefficient value.
There are four distinct sets of System Calibration Scaling and System Calibration Bits Selector Registers for use
with Channels 0-3. Channels 4-6 reuse the registers of Channels 0-2, respectively.
A data-flow diagram of these coefficients can be seen in Figure 55
X
System Calibrated
Code[23:0]
SCALING
[CHx_SCAL_
SCALING]
[28:0]
Scaled and Calibrated
ADC_DOUT
BITS SELECTOR
[CHx_SCAL_
BITS_SELECTOR]
Figure 55. Post-calibration Scaling Data-Flow Diagram
9.3.8 Sensor Interface
LMP90100/LMP90098 contain two types of current sources: excitation currents (IB1 & IB2) and burnout currents.
They are described in the next sections.
9.3.8.1 IB1 and IB2 - Excitation Currents
IB1 and IB2 can be used for providing currents to external sensors, such as RTDs or bridge sensors. 100µA to
1000µA, in steps of 100µA, can be sourced by programming the ADC_AUXCN: RTD_CUR_SEL bits.
Refer to 3-Wire RTD Using 2 Current Sources to see how IB1 and IB2 can be used to source a 3-wire RTD.
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Feature Description (continued)
9.3.8.2 Burnout Currents
As shown in Figure 56, the LMP90xxx contains two internal 10 µA burnout current sources, one sourcing current
from VA to VINP, and the other sinking current from VINN to ground. These currents are used for sensor
diagnostics and can be enabled for each channel using the CHx_INPUTCN: BURNOUT_EN bit.
Burnout
Current = 10 PA
VIN0
VIN1
VIN2
VIN3*
VINP
VINN
VIN4*
VIN5*
VIN6/VREFP2
VIN7/VREFN2
Burnout
Current = 10 PA
* VIN3, VIN4, VIN5 are only available for LMP90100 and LMP90099
Figure 56. Burnout Currents
9.3.8.2.1 Burnout Current Injection
Burnout currents are injected differently depending on the channel scan mode selected.
When BURNOUT_EN = 1 and the device is operating in ScanMode0, 1, or 2, the burnout currents are injected
into all the channels for which the BURNOUT_EN bit is selected. This will cause problems and hence in this
mode, more than one channel should not have its BURNOUT_EN bit selected. Also, the burnout current will
interfere with the signal and introduce a fixed error depending on the particular external sensor.
When BURNOUT_EN = 1 and the device is operating in ScanMode3, burnout currents are injected into the last
sampled channel on a cyclical basis (Figure 57). In this mode, burnout currents injection is truly done in the
background without affecting the accuracy of the on-going conversion. Operating in this mode is recommended.
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Feature Description (continued)
Burnout Currents
BURNOUT_EN
CH0 is being sampled
CH0
CH1
CH2
CH3
BURNOUT_EN
CH1 is being sampled
CH0
CH1
CH2
CH3
BURNOUT_EN
CH2 is being sampled
CH0
CH1
CH2
CH3
BURNOUT_EN
CH3 is being sampled
CH0
CH1
CH2
CH3
Figure 57. Burnout Currents Injection for ScanMode3
9.3.8.3 Sensor Diagnostic Flags
Burnout currents can be used to verify that an external sensor is still operational before attempting to make
measurements on that channel. A non-operational sensor means that there is a possibility the connection
between the sensor and the LMP90xxx is open circuited, short circuited, shorted to VA or GND, overloaded, or
the reference may be absent. The sensor diagnostic flags diagram can be seen in Figure 58.
RAILS_FLAG
Generator
RAILS_FLAG
Overflow detection
OFLO_FLAGS
VINP
FGA
VINN
BUFF
Modulator
Filter
RAILS_FLAG
Generator
ADC_DOUT
RAILS_FLAG
SENDIAG_THLDH
and SENDIAG_THLDL
SHORT_THLD_
FLAG
Figure 58. Sensor Diagnostic Flags Diagram
The sensor diagnostic flags are located in the SENDIAG_FLAGS register and are described in further details
below.
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Feature Description (continued)
9.3.8.3.1 SHORT_THLD_FLAG
The short circuit threshold flag is used to report a short-circuit condition. It is set when the output voltage (VOUT)
is within the absolute Vthreshold. Vthreshold can be programmed using the 8-bit SENDIAG_THLDH register
concatenated with the 8-bit SENDIAG_THLDL register.
For example, assume VREF = 5V, gain = 1, SENDIAG_THLDH = 0xFA, and SENDIAG_THLDL = 0x45. In this
case, Dthreshold = 0xFA45 = 64069d, and Vthreshold can be calculated as:
Vthreshold = [(Dthreshold)(2)(VREF)] / [(Gain)(224)]
Vthreshold = [(64069)(2)(5V)] / [(1)(224)]
Vthreshold = 38.2 mV
(10)
(11)
(12)
When (-38.2mV) ≤ VOUT ≤ (38.2mV), then SHORT_THLD_FLAG = 1; otherwise, SHORT_THLD_FLAG = 0.
9.3.8.3.2 RAILS_FLAG
The rails flag is used to detect if one of the sampled channels is within 50mV of the rails potential (VA or VSS).
This can be further investigated to detect an open-circuit or short-circuit condition. If the sampled channel is near
a rail, then RAILS_FLAG = 1; otherwise, RAILS_FLAG = 0.
9.3.8.3.3 POR_AFT_LST_RD:
If POR_AFT_LST_READ = 1, then there was a power-on reset because the last time the SENDIAG_FLAGS
register was read. This flag's status is cleared when this bit is read, unless this bit is set again on account of
another power-on-reset event in the intervening period.
9.3.8.3.4 OFLO_FLAGS
OFLO_FLAGS is used to indicate whether the modulator is over-ranged or under-ranged. The following
conditions are possible:
1. OFLO_FLAGS = 0x0: Normal Operation
2. OFLO_FLAGS = 0x1: The differential input is more than (±VREF/Gain) but is not more than
±(1.3*VREF/Gain) to cause a modulator over-range.
3. OFLO_FLAGS = 0x2: The modulator was over-ranged towards +VREF/Gain.
4. OFLO_FLAGS = 0x3: The modulator was over-ranged towards −VREF/Gain.
The condition of OFLO_FLAGS = 10b or 11b can be used in conjunction with the RAILS_FLAG to determine the
fault condition.
9.3.8.3.5 SAMPLED_CH
These three bits show the channel number for which the ADC_DOUT and SENDIAG_FLAGS are available. This
does not necessarily indicate the current channel under conversion because the conversion frame and
computation of results from the channels are pipelined. That is, while the conversion is going on for a particular
channel, the results for the previous conversion (of the same or a different channel) are available.
9.3.9 RESET and RESTART
Writing 0xC3 to the REG_AND_CNV_RST field will reset the conversion and most of the programmable registers
to their default values. The only registers that will not be reset are the System Calibration Registers
(CHx_SCAL_OFFSET, CHx_SCAL_GAIN) and the DT_AVAIL_B bit.
If it is desirable to reset the System Calibration Coefficient Registers, then set RESET_SYSCAL = 1 before
writing 0xC3 to REG_AND_CNV_RST. If the device is operating in the “System Calibration Offset/Gain
Coefficient Determination” mode (SCALCN register), then write REG_AND_CNV_RST = 0xC3 twice to get out of
this mode.
After a register reset, any on-going conversions will be aborted and restarted. If the device is in the power-down
state, then a register reset will bring it out of the power-down state.
To restart a conversion, write 1 to the RESTART bit. This bit can be used to synchronize the conversion to an
external event.
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Feature Description (continued)
After a restart conversion, the first sample is not valid. To restart with a valid first sample, issue a stand-by
command followed by an active command.
9.4 Device Functional Modes
9.4.1 Power Management
The device can be placed in Active, Power-Down, or Stand-By state.
In Power-Down, the ADC is not converting data, contents of the registers are unaffected, and there is a drastic
power reduction. In Stand-By, the ADC is not converting data, but the power is only slightly reduced so that the
device can quickly transition into the active state if desired.
These states can be selected using the PWRCN register. When written, PWRCN brings the device into the
Active, Power-Down, or Stand-By state. When read, PWRCN indicates the state of the device.
The read value would confirm the write value after a small latency (approximately 15 µs with the internal CLK). It
may be appropriate to wait for this latency to confirm the state change. Requests not adhering to this latency
requirement may be rejected.
It is not possible to make a direct transition from the power-down state to the stand-by state. This state diagram
is shown in Figure 59.
PWRCN
= 11b
PWRCN
= 01b
Active
PWRCN
= 00b
PWRCN
= 00b
Stand-by
Power-down
Figure 59. Active, Power-Down, Stand-by State Diagram
9.4.2 Channels Scan Mode
There are four scan modes. These scan modes are selected using the CH_SCAN: CH_SCAN_SEL bit. The first
scanned channel is FIRST_CH, and the last scanned channel is LAST_CH; they are both located in the
CH_SCAN register.
The CH_SCAN register is double buffered. That is, user inputs are stored in a slave buffer until the start of the
next conversion during which time they are transferred to the master buffer. Once the slave buffer is written,
subsequent updates are disregarded until a transfer to the master buffer happens. Hence, it may be appropriate
to check the CH_SCAN_NRDY bit before programming the CH_SCAN register.
9.4.2.1 ScanMode0: Single-Channel Continuous Conversion
LMP90xxx continuously converts the selected FIRST_CH.
Do not operate in this scan mode if gain ≥ 16 and the LMP90xxx is running in background calibration modes
BgcalMode1 or BgcalMode2. If this is the case, then it is more suitable to operate the device in ScanMode2
instead.
9.4.2.2 ScanMode1: Multiple-Channels Single Scan
LMP90xxx converts one or more channels starting from FIRST_CH to LAST_CH, and then enters the stand-by
state.
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Device Functional Modes (continued)
9.4.2.3 ScanMode2: Multiple-Channels Continuous Scan
LMP90xxx continuously converts one or more channels starting from FIRST_CH to LAST_CH, and then it
repeats this process.
9.4.2.4 ScanMode3: Multiple-Channels Continuous Scan with Burnout Currents
This mode is the same as ScanMode2 except that the burnout current is provided in a serially scanned fashion
(injected in a channel after it has undergone a conversion). Thus it avoids burnout current injection from
interfering with the conversion result for the channel.
The sensor diagnostic burnout currents are available for all four scan modes. The burnout current is further gated
by the BURNOUT_EN bit for each channel. ScanMode3 is the only mode that scans multiple channels while
injecting burnout currents without interfering with the signal. This is described in details in Burnout Currents.
9.5 Programming
9.5.1 General Rules
1. If written to, RESERVED bits must be written to only 0 unless otherwise indicated.
2. Read back value of RESERVED bits and registers is unspecified and should be discarded.
3. Recommended values must be programmed and forbidden values must not be programmed where they are
indicated in order to avoid unexpected results.
4. If written to, registers indicated as Reserved must have the indicated default value as shown in the Register
Maps. Any other value can cause unexpected results.
9.5.2 Serial Digital Interface
A synchronous 4-wire serial peripheral interface (SPI) provides access to the internal registers of LMP90xxx via
CSB, SCLK, SDI, SDO/DRDYB.
9.5.3 Register Address (ADDR)
All registers are memory-mapped. A register address (ADDR) is composed of an upper register address (URA)
and lower register address (LRA) as shown in Table 5. For example, ADDR 0x3A has URA=0x3 and LRA=0xA.
Table 5. ADDR Map
9.5.4
Bit
[6:4]
[3:0]
Name
URA
LRA
Register Read/Write Protocol
Figure 60 shows the protocol how to write to or read from a register.
Transaction 1 sets up the upper register address (URA) where the user wants to start the register-write or
register-read.
Transaction 2 sets the lower register address (LRA) and includes the Data Byte(s), which contains the incoming
data from the master or outgoing data from the LMP90xxx.
Examples of register-reads or register-writes can be found in Register Read/Write Examples.
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Transaction 1 ± URA Setup ± necessary only when the previous URA is different than the desired URA.
Instruction Byte 1 (INST1)
Upper Address Byte (UAB)
[7:0]
[7:3]
[2:0]
RA/WAB
0x0
Upper Register
Address (URA)
R/WB = Read/Write Address
0x10: Write Address
0x90: Read Address
Transaction 2 ± Data Access
Instruction Byte 2 (INST2)
Data Byte (s)
7
[6:5]
4
[3:0]
[N:0]
R/WB
SZ
0
Lower Register
Address (LRA)
Data Byte (s)
R/WB = Read/Write Data
0: Write Data
1: Read Data
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 60. Register Read / Write Protocol
9.5.5 Streaming
When writing/reading 3+ bytes, the user must operate the device in Normal Streaming mode or Controlled
Streaming mode. In the Normal Streaming mode, which is the default mode, data runs continuously starting from
ADDR until CSB deasserts. This mode is especially useful when programming all the configuration registers in a
single transaction. See Normal Streaming Example for an example of the Normal Streaming mode.
In the Controlled Streaming mode, data runs continuously starting from ADDR until the data has run through all
(STRM_RANGE + 1) registers. For example, if the starting ADDR is 0x1C, STRM_RANGE = 5, then data will be
written to or read from the following ADDRs: 0x1C, 0x1D, 0x1E, 0x1F, 0x20, 0x21. Once the data reaches ADDR
0x21, LMP90xxx will wrap back to ADDR 0x1C and repeat this process until CSB deasserts. See Controlled
Streaming Example for an example of the Controlled Streaming mode.
If streaming reaches ADDR 0x7F, then it will wrap back to ADDR 0x00. Furthermore, reading back the Upper
Register Address after streaming will report the Upper Register Address at the start of streaming, not the Upper
Register Address at the end of streaming.
To stream, write 0x3 to INST2’s SZ bits as seen in Figure 60. To select the stream type, program the
SPI_STREAMCN: STRM_TYPE bit. The STRM_RANGE can also be programmed in the same register.
9.5.6 CSB - Chip Select Bar
An SPI transaction begins when the master asserts (active low) CSB and ends when the master deasserts
(active high) CSB. Each transaction might be separated by a subsequent one with a CSB deassertion, but this is
optional. Once CSB is asserted, it must not pulse (deassert and assert again) during a (desired) transaction.
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CSB can be grounded in systems where LMP90xxx is the only SPI slave. This frees the software from handling
the CSB. Care has to be taken to avoid any false edge on SCLK, and while operating in this mode, the streaming
transaction should not be used because exiting from this mode can only be done through a CSB deassertion.
9.5.7 SPI Reset
SPI Reset resets the SPI-Protocol State Machine by monitoring the SDI for at least 73 consecutive 1's at each
SCLK rising edge. After an SPI Reset, SDI is monitored for a possible Write Instruction at each SCLK rising
edge.
SPI Reset will reset the Upper Address Register (URA) to 0, but the register contents are not reset.
By default, SPI reset is disabled, but it can be enabled by writing 0x01 to SPI Reset Register (ADDR 0x02).
9.5.8 DRDYB - Data Ready Bar
DRDYB is a signal generated by the LMP90xxx that indicates a fresh conversion data is available in the
ADC_DOUT registers.
DRDYB is automatically asserted every (1/ODR) second and deasserts when ADC_DOUT is completely read out
(LSB of ADC_DOUTL) (Figure 61).
1/ODR
DRDYB:
SDO:
...
...
LSB
LSB
Figure 61. DRDYB Behavior for a Complete ADC_DOUT Reading
If ADC_DOUT is not completely read out (Figure 62) or is not read out at all, but a new ADC_DOUT is available,
then DRDYB will automatically pulse for tDRDYB second. The value for tDRDYB can be found in Timing Diagrams.
1/ODR
DRDYB:
tDRDYB
SDO:
Figure 62. DRDYB Behavior for an ADC_DOUT not Read
If ADC_DOUT is being read, while the new ADC_DOUT becomes available, then the ADC_DOUT that is being
read is still valid (Figure 63). DRDYB will be deasserted at the LSB of the data being read, but a consecutive
read on the ADC_DOUT register will fetch the newly converted data available.
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1/ODR
D6 = drdyb
1/ODR
ADC
Data
1
ADC
Data
2
Valid
ADC_DOUT
(ADC Data 2)
Valid
ADC_DOUT
(ADC Data 1)
LSB
MSB
SDO
MSB
LSB
Figure 63. DRDYB Behavior for an Incomplete ADC_DOUT Reading
DRDYB can also be accessed via registers using the DT_AVAIL_B bit. This bit indicates when fresh conversion
data is available in the ADC_DOUT registers. If new conversion data is available, then DT_AVAIL_B = 0;
otherwise, DT_AVAIL_B = 1.
As opposed to the DRDYB signal, a complete reading for DT_AVAIL_B occurs when the MSB of ADC_DOUTH
is read out. This bit cannot be reset even if REG_AND_CNV_RST = 0xC3.
9.5.9 DRDYB Case1: Combining SDO/DRDYB with SDO_DRDYB_DRIVER = 0x00
LMP90100
uC
SCLK
SCLK
CSB
CSB
SDI
MOSI
SDO/
DRDYB
MISO
INT
Figure 64. DRDYB Case1 Connection Diagram
As shown in Figure 64, the DRDYB signal and SDO can be multiplexed on the same pin as their functions are
mostly complementary. In fact, this is the default mode for the SDO/DRDYB pin.
Figure 65 shows a timing protocol for DRDYB Case1. In this case, start by asserting CSB first to monitor a
DRDYB assertion. When the DRDYB signal asserts, begin writing the Instruction Bytes (INST1, UAB, INST2) to
read from or write to registers. Note that INST1 and UAB are omitted from the figure below because this
transaction is only required if a new UAB needs to be implemented.
While the CSB is asserted, DRDYB is driving the SDO/DRDYB pin unless the device is reading data, in which
case, SDO will be driving the pin. If CSB is deasserted, then the SDO/DRDYB pin is High-Z.
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CSB
tCH
SCLK
1
2
3
4
1/fSCLK
tCL
5
6
7
8
9
10
11
12
13
14
15
16
n
17
INST2
SDI
MSB
LSB
DRDYB is driving the pin
SDO is driving the pin
Data Byte (s)
SDO/
DRDYB
MSB
LSB
Figure 65. Timing Protocol for DRDYB Case1
9.5.10 DRDYB Case2: Combining SDO/DRDYB with SDO_DRDYB_DRIVER = 0x03
SDO/DRDYB can be made independent of CSB by setting SDO_DRDYB_DRIVER = 0x03 in the SPI Handshake
Control register. In this case, DRDYB will drive the pin unless the device is reading data, independent of the
state of CSB. SDO will drive the pin when CSB is asserted and the device is reading data.
With this scheme, one can use SDO/DRDYB as a true interrupt source, independent of the state of CSB. But this
scheme can only be used when the LMP900xx is the only device connected to the master's SPI bus because the
SDO/DRDYB pin will be DRDYB even when CSB is deasserted.
The timing protocol for this case can be seen in Figure 66. When DRDYB asserts, assert CSB to start the SPI
transaction and begin writing the Instruction Bytes (INST1, UAB, INST2) to read from or write to registers.
CSB
tCH
SCLK
1
4
1/fSCLK
tCL
5
6
7
8
9
10
11
12
13
14
15
16
n
17
INST2
SDI
MSB
LSB
DRDYB is driving the pin
SDO is driving the pin
Data Byte (s)
SDO/
DRDYB
MSB
LSB
Figure 66. Timing Protocol for DRDYB Case2
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9.5.11 DRDYB Case3: Routing DRDYB to D6
LMP90100
uC
SCLK
SCLK
CSB
CSB
SDI
MOSI
SDO
MISO
Interrupt
D6 = DRDYB
Figure 67. DRDYB Case3 Connection Diagram
The DRDYB signal can be routed to pin D6 by setting SPI_DRDYB_D6 high and SDO_DRDYB_DRIVER to 0x4.
This is the behavior for DrdybCase3 as shown in Figure 67.
The timing protocol for this case can be seen in Figure 68. Because DRDYB is separated from SDO, it can be
monitored using the interrupt or polling method. If polled, the DRDYB signal needs to be polled faster than tDRDYB
to detect a DRDYB assertion. When DRDYB asserts, assert CSB to start the SPI transaction and begin writing
the Instruction Bytes (INST1, UAB, INST2) to read from or write to registers.
CSB
SCLK
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
n
INST2
SDI
MSB
LSB
Drdyb = D6
Data Byte (s)
SDO
High-Z
MSB
LSB
Figure 68. Timing Protocol for DRDYB Case3
9.5.12 Data Only Read Transaction
In a data only read transaction, one can directly access the data byte(s) as soon as the CSB is asserted without
having to send any instruction byte. This is useful as it brings down the latency as well as the overhead
associated with the instruction byte (as well as the Upper Address Byte, if any).
In order to use the data only transaction, the device must be placed in the data first mode. The following table
lists transaction formats for placing the device in and out of the data first mode and reading the mode status.
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Table 6. Data First Mode Transactions
Bit[7]
Bits[6:5]
Bit[4]
Bits[3:0]
Data Bytes
Enable Data First
Mode Instruction
1
11
1
1010
None
Disable Data First
Mode Instruction
1
11
1
1011
None
Read Mode Status
Transaction
1
00
1
1111
One
Note that while being in the data first mode, once the data bytes in the data only read transaction are sent out,
the device is ready to start on any normal (non-data-only) transaction including the Disable Data First Mode
Instruction. The current status of the data first mode (enabled/disabled status) can be read back using the Read
Mode Status Transaction. This transaction consists of the Read Mode Status Instruction followed by a single
data byte (driven by the device). The data first mode status is available on bit [1] of this data byte.
The data only read transaction allows reading up to eight consecutive registers, starting from any start address.
Usually, the start address will be the address of the most significant byte of conversion data, but it could just as
well be any other address. The start address and number of bytes to be read during the data only read
transaction can be programmed using the DATA_ONLY_1 AND DATA_ONLY_2 registers respectively.
The upper register address is unaffected by a data only read transaction. That is, it retains its setting even after
encountering a data only transaction. The data only transaction uses its own address (including the upper
address) from the DATA_ONLY_1 register. When in the data first mode, the SCLK must stop high before
entering the Data Only Read Transaction; this transaction should be completed before the next scheduled
DRDYB deassertion.
9.5.13 Cyclic Redundancy Check (CRC)
CRC can be used to ensure integrity of data read from LMP90xxx. To enable CRC, set EN_CRC high. Once
CRC is enabled, the CRC value is calculated and stored in SPI_CRC_DAT so that the master device can
periodically read for data comparison. Conveniently, the SPI_CRC_DAT register address is located next to the
ADC_DOUT register address so that the CRC value can be easily read as part of the data set. The CRC is
automatically reset when CSB or DRDYB is deasserted.
The CRC polynomial is x8 + x5 + x4 + 1. The reset value of the SPI_CRC_DAT register is zero, and the final
value is ones-complemented before it is sent out. Note that CRC computation only includes the bits sent out on
SDO and does not include the bits of the SPI_CRC_DAT itself; thus it is okay to read SPI_CRC_DAT repeatedly.
The DRDYB signal normally deasserts (active high) every 1/ODR second or when the LSB of ADC_DOUTL is
read. However, this behavior can be changed so that DRDYB deassertion can occur after SPI_CRC_DAT is
read, but not later than normal DRDYB deassertion which occurs at every 1/ODR seconds. This is done by
setting bit DRDYB_AFT_CRC high.
The timing protocol for CRC can be found in Figure 69.
1/ODR
1/ODR
Sampling CH0
Sampling CH1
Reading
SPI_CRC_DAT
Reading
ADC_DOUT of CH0
SDO
MSB
LSB
MSB
LSB
Reading
SPI_CRC_DAT
Reading
ADC_DOUT of CH1
MSB
LSB
MSB
LSB
Figure 69. Timing Protocol for Reading SPI_CRC_DAT
If SPI_CRC_DAT read extends beyond the normal DRDYB deassertion at every 1/ODR seconds, then
CRC_RST has to be set in the SPI Data Ready Bar Control Register. This is done to avoid a CRC reset at the
DRDYB deassertion. Timing protocol for reading CRC with CRC_RST set is shown in Figure 70.
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1/ODR
CH0
1/ODR
CH1
LSB
MSB
SDO
MSB
Reading
SPI_CRC_DAT
Reading
ADC_DOUT of CH1
Reading
SPI_CRC_DAT
Reading
ADC_DOUT of CH0
LSB
MSB
LSB
MSB
LSB
Figure 70. Timing Protocol for Reading SPI_CRC_DAT Beyond Normal DRDYB Deassertion at Every
1/ODR seconds
Follow the steps below to enable CRC:
1. Set SPI_CRC_CN = 1 (register 0x13, bit 4) to enable CRC.
2. Set DRDYB_AFT_CRC = 1 (register 0x13, bit 2) to dessert the DRDYB after CRC.
3. Compute the CRC externally, which should include ADC_DOUTH, ADC_DOUTM , and ADC_DOUTL.
4. Collect the data and verify the reported CRC matches with the computed CRC (step above).
9.5.14 Register Read/Write Examples
9.5.14.1 Writing To Register Examples
Using the register read/write protocol shown in Figure 60, the following example shows how to write three data
bytes starting at register address (ADDR) 0x1F. After the last byte has been written to ADDR 0x21, deassert
CSB to end the register-write.
Transaction 1 ± URA Setup ± necessary only when the previous URA is different than the desired URA.
Instruction Byte 1 (INST1)
Upper Address Byte (UAB)
[7:0]
[7:3]
[2:0]
0x10
0x0
0x1
R/WB = Read/Write Address
0x10: Write Address
0x90: Read Address
Transaction 2 ± Data Access
Data Bytes
Instruction Byte 2 (INST2)
7
4
[6:5]
[3:0]
[23:0]
st
The 1 Data Byte will be written to ADDR 0x1F, the 2
0
0x2
0
R/WB = Read/Write Data
0: Write Data
1: Read Data
0xF
nd
Data Byte will
rd
be written to ADDR 0x20, and the 3 Data Byte will be written to ADR
0x21. After this process, deassert CSB.
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 71. Register-Write Example 1
The next example shows how to write one data byte to ADDR 0x12. Because the URA for this example is the
same as the last example, transaction 1 can be omitted.
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Transaction 2 ± Data Access
Instruction Byte 2 (INST2)
Data Byte (s)
7
[6:5]
4
[3:0]
[7:0]
0
0x00
0
0x2
One Data Byte will be written to ADDR 0x12. After this process, deassert CSB.
R/WB = Read/Write Data
0: Write Data
1: Read Data
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 72. Register-Write Example 2
9.5.14.2 Reading From Register Example
The following example shows how to read two bytes. The first byte will be read from starting ADDR 0x24, and
the second byte will be read from ADDR 0x25.
Transaction 1 ± URA Setup ± necessary only when the previous URA is different than the desired URA.
Instruction Byte 1 (INST1)
Upper Address Byte (UAB)
[7:0]
[7:3]
[2:0]
0x10
0x0
0x2
R/WB = Read/Write Address
0x10: Write Address
0x90: Read Address
Transaction 2 ± Data Access
Instruction Byte 2 (INST2)
7
[6:5]
4
[3:0]
1
0x1
0
0x4
R/WB = Read/Write Data
0: Write Data
1: Read Data
Data Bytes
[15:0]
2 Data Bytes will be read from ADDR 0x24 and ADDR 0x25.
After this process, deassert CSB.
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 73. Register-Read Example
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9.5.15 Streaming Examples
9.5.15.1 Normal Streaming Example
This example shows how to write six data bytes starting at ADDR 0x28 using the Normal Streaming mode.
Because the default STRM_TYPE is the Normal Streaming mode, setting up the SPI_STREAMCN register can
be omitted.
Transaction 1 ± URA Setup ± necessary only when the previous URA is different than the desired URA.
Upper Address Byte (UAB)
Instruction Byte 1 (INST1)
[7:0]
[7:3]
[2:0]
0x10
0x0
0x2
R/WB = Read/Write Address
0x10: Write Address
0x90: Read Address
Transaction 2 ± Data Access
Instruction Byte 2 (INST2)
7
[6:5]
4
Data Bytes
[3:0]
[47:0]
st
nd
The 1 Data Byte will be written to ADDR 0x28, the 2
0
0x3
R/WB = Read/Write Data
0: Write Data
1: Read Data
0
0x8
Data Byte will be
th
written to ADDR 0x29, etc. The last and 6 Data Byte will be written to
ADDR 0x2D. After this process, deassert CSB.
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 74. Normal Streaming Example
9.5.15.2 Controlled Streaming Example
This example shows how to read the 24-bit conversion data (ADC_DOUT) four times using the Controlled
Streaming mode. The ADC_DOUT registers consist of ADC_DOUTH at ADDR 0x1A, ADC_DOUTM at ADDR
0x1B, and ADC_DOUTL at ADDR 0x1C.
The first step (Figure 75) sets up the SPI_STREAMCN register. This step enters the Controlled Streaming mode
by setting STRM_TYPE high in ADDR 0x03. Because three registers (ADDR 0x1A - 0x1C) need to be read, the
STRM_RANGE is 2.
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Transaction 1 ± URA Setup ± necessary only when the previous URA is different than the desired URA.
Instruction Byte 1 (INST1)
Upper Address Byte (UAB)
[7:0]
[7:3]
[2:0]
0x10
0x0
0x0
R/WB = Read/Write Address
0x10: Write Address
0x90: Read Address
Transaction 2 ± Data Access
Instruction Byte 2 (INST2)
Data Byte (s)
7
[6:5]
4
[3:0]
[7:0]
0
0x0
0
0x3
1000_0010b
R/WB = Read/Write Data
0: Write Data
1: Read Data
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 75. Setting up SPI_STREAMCN
The next step shows how to perform the Controlled Streaming mode so that the master device will read
ADC_DOUT from ADDR 0x1A, 0x1B, 0x1C, then wrap back to ADDR 0x1A, and repeat this process for four
times. After this process, deassert CSB to end the Controlled Streaming mode.
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Transaction 1 ± URA Setup ± necessary only when the previous URA is different than the desired URA.
Instruction Byte 1 (INST1)
Upper Address Byte (UAB)
[7:0]
[7:3]
[2:0]
0x10
0x0
0x1
R/WB = Read/Write Address
0x10: Write Address
0x90: Read Address
Transaction 2 ± Data Access
Instruction Byte 2 (INST2)
Data Byte (s)
7
[6:5]
4
[3:0]
[95:0]
1
0x3
0
0xA
Read ADC_DOUTH, ADC_DOUTM, and ADC_DOUTL four times. After this
process, deassert CSB.
R/WB = Read/Write Data
0: Write Data
1: Read Data
SZ = Size
0x0: 1 byte
0x1: 2 bytes
0x2: 3 bytes
0x3: Streaming ± 3+ bytes until CSB is de-asserted
Figure 76. Controlled Streaming Example
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9.6 Register Maps
Register Name
ADDR
(URA & LRA)
Type
Default
RESETCN
Reset Control
0x00
WO
-
SPI_HANDSHAKECN
SPI Handshake Control
0x01
R/W
0x00
SPI_RESET
SPI Reset Control
0x02
R/W
0x00
SPI_STREAMCN
SPI Stream Control
0x03
R/W
0x00
Reserved
-
0x04 - 0x07
-
0x00
PWRCN
Power Mode Control and Status
0x08
RO & WO
0x00
DATA_ONLY_1
Data Only Read Control 1
0x09
R/W
0x1A
DATA_ONLY_2
Data Only Read Control 2
0x0A
R/W
0x02
ADC_RESTART
ADC Restart Conversion
0x0B
WO
-
Reserved
-
0x0C - 0x0D
-
0x00
GPIO_DIRCN
GPIO Direction Control
0x0E
R/W
0x00
GPIO_DAT
GPIO Data
0x0F
RO & WO
-
BGCALCN
Background Calibration Control
0x10
R/W
0x00
SPI_DRDYBCN
SPI Data Ready Bar Control
0x11
R/W
0x03
ADC_AUXCN
ADC Auxiliary Control
0x12
R/W
0x00
SPI_CRC_CN
CRC Control
SENDIAG_THLD
Sensor Diagnostic Threshold 1,0
Reserved
0x13
R/W
0x02
0x14 - 0x15
R/W
0x0000
-
0x16
-
0x00
SCALCN
System Calibration Control
0x17
R/W
0x00
ADC_DONE
ADC Data Available
0x18
RO
-
SENDIAG_FLAGS
Sensor Diagnostic Flags
0x19
RO
-
ADC_DOUT
Conversion Data 2,1,0
0x1A - 0x1C
RO
-
SPI_CRC_DAT
CRC Data
0x1D
RO & WO
-
CHANNEL CONFIGURATION REGISTERS (CH4 to CH6 for LMP90100/LMP9099 only)
CH_STS
Channel Status
0x1E
RO
0x00
CH_SCAN
Channel Scan Mode
0x1F
R/W
0x30
CH0_INPUTCN
CH0 Input Control
0x20
R/W
0x01
CH0_CONFIG
CH0 Configuration
0x21
R/W
0x70
CH1_INPUTCN
CH1 Input Control
0X22
R/W
0x13
CH1_CONFIG
CH1 Configuration
0x23
R/W
0x70
CH2_INPUTCN
CH2 Input Control
0x24
R/W
0x25
CH2_CONFIG
CH2 Configuration
0x25
R/W
0x70
CH3_INPUTCN
CH3 Input Control
0x26
R/W
0x37
CH3_CONFIG
CH3 Configuration
0x27
R/W
0x70
CH4_INPUTCN
CH4 Input Control
0x28
R/W
0x01
CH4_CONFIG
CH4 Configuration
0x29
R/W
0x70
CH5_INPUTCN
CH5 Input Control
0x2A
R/W
0x13
CH5_CONFIG
CH5 Configuration
0x2B
R/W
0x70
CH6_INPUTCN
CH6 Input Control
0x2C
R/W
0x25
CH6_CONFIG
CH6 Configuration
0x2D
R/W
0x70
Reserved
-
0x2E - 0x2F
-
0x00
SYSTEM CALIBRATION REGISTERS
CH0_SCAL_OFFSET
CH0 System Calibration Offset Coefficients
0x30 - 0x32
R/W
0x00_0000
CH0_SCAL_GAIN
CH0 System Calibration Gain Coefficients
0x33 - 0x35
R/W
0x80_0000
CH0_SCAL_SCALING
CH0 System Calibration Scaling Coefficients
0x36
R/W
0x01
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Register Maps (continued)
Register Name
CH0_SCAL_BITS_SELECT
CH0 System Calibration Bits Selector
OR
ADDR
(URA & LRA)
Type
Default
0x37
R/W
0x00
CH1_SCAL_OFFSET
CH1 System Calibration Offset Coefficients
0x38 - 0x3A
R/W
0x00_0000
CH1_SCAL_GAIN
CH1 System Calibration Gain Coefficient
0x3B - 0x3D
R/W
0x80_0000
CH1_SCAL_SCALING
CH1 System Calibration Scaling Coefficients
0x3E
R/W
0x01
CH1_SCAL_BITS_SELECT
CH1 System Calibration Bits Selector
OR
0x3F
R/W
0x00
CH2_SCAL_OFFSET
CH2 System Calibration Offset Coefficients
0x40 - 0x42
R/W
0x00_0000
CH2_SCAL_GAIN
CH2 System Calibration Gain Coefficient
0x43 - 0x45
R/W
0x80_0000
CH2_SCAL_SCALING
CH2 System Calibration Scaling Coefficients
0x46
R/W
0x01
0x47
R/W
0x00
CH2_SCAL_BITS_SELECT
CH2 System Calibration Bits Selector
OR
CH3_SCAL_OFFSET
CH3 System Calibration Offset Coefficients
0x48 - 0x4A
R/W
0x00_0000
CH3_SCAL_GAIN
CH3 System Calibration Gain Coefficient
0x4B - 0x4D
R/W
0x80_0000
CH3_SCAL_SCALING
CH3 System Calibration Scaling Coefficients
0x4E
R/W
0x01
0x4F
R/W
0x00
0x50 - 0x7F
-
0x00
CH3_SCAL_BITS_SELECT
CH3 System Calibration Bits Selector
OR
Reserved
-
Table 7. RESETCN: Reset Control (Address 0x00)
Bit
Bit Symbol
Bit Description
Register and Conversion Reset
[7:0] REG_AND_CNV_ RST
0xC3: Register and conversion reset
Others: Neglected
Table 8. SPI_HANDSHAKECN: SPI Handshake Control (Address 0x01)
Bit
Bit Symbol
Bit Description
[7:4] Reserved
SDO/DRDYB Driver – sets who is driving the SDO/DRYB pin
[3:1] SDO_DRDYB_ DRIVER
Whenever CSB is
Asserted and the Device
is Reading ADC_DOUT
Whenever CSB is
Asserted and the Device
is Not Reading
ADC_DOUT
CSB is Deasserted
0x0 (default)
SDO is driving
DRDYB is driving
High-Z
0x3
SDO is driving
DRDYB is driving
DRDYB is driving
0x4
SDO is driving
High-Z
High-Z
Others
Forbidden
Switch-off trigger - refers to the switching of the output drive from the slave to the master.
0 (default): SDO will be high-Z after the last (16th, 24th, 32nd, etc) rising edge of SCLK. This
option allows time for the slave to transfer control back to the master at the end of the frame.
0
SW_OFF_TRG
1: SDO’s high-Z is postponed to the subsequent falling edge following the last (16th, 24th, 32nd,
etc) rising edge of SCLK. This option provides additional hold time for the last bit, DB0, in nonstreaming read transfers.
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Table 9. SPI_RESET: SPI Reset Control (Address 0x02)
Bit
Bit Symbol
Bit Description
SPI Reset Enable
0x0 (default): SPI Reset Disabled
[0]
0x1: SPI Reset Enabled
SPI_ RST
Note: Once Written, The contents of this register are sticky. That is, the content of this register
cannot be changed with subsequent write. However, a Register reset clears the register as well as
the sticky status.
Table 10. SPI_STREAMCN: SPI Streaming Control (Address 0x03)
Bit
Bit Symbol
Bit Description
Stream type
7
STRM_TYPE
0 (default): Normal Streaming mode
1: Controlled Streaming mode
Stream range – selects Range for Controlled Streaming mode
[6:0] STRM_ RANGE
Default: 0x00
Table 11. PWRCN: Power Mode Control and Status (Address 0x08)
Bit
Bit Symbol
Bit Description
[7:2] Reserved
Power Control
Write Only – power down mode control
0x0: Active Mode
0x1: Power-down Mode
0x3: Stand-by Mode
[1:0] PWRCN
Read Only – the present mode is:
0x0 (default): Active Mode
0x1: Power-down Mode
0x3: Stand-by Mode
Table 12. DATA_ONLY_1: Data Only Read Control 1 (Address 0x09)
Bit Symbol
Bit Description
7
Bit
Reserved
-
[6:0]
DATA_ONLY_ADR
Start address for the Data Only Read Transaction
Default: 0x1A
Please refer to the description of DT_ONLY_SZ in DATA_ONLY_2 register.
Table 13. DATA_ONLY_2: Data Only Read Control 2 (Address 0x0A)
Bit
[7:3]
Bit Symbol
Bit Description
Reserved
-
DATA_ONLY_SZ
Number of bytes to be read out in Data Only mode. A value of 0x0 means read one byte and 0x7
means read 8 bytes.
[2:0]
Default: 0x2
Table 14. ADC_RESTART: ADC Restart Conversion (Address 0x0B)
Bit
Bit Symbol
[7:1] Reserved
0
RESTART
Bit Description
Restart conversion
1: Restart conversion.
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Table 15. GPIO_DIRCN: GPIO Direction (Address 0x0E)
Bit
7
Bit Symbol
Bit Description
Reserved
GPIO direction control – these bits are used to control the direction of each General Purpose
Input/Outputs (GPIO) pins D0 - D6.
0 (default): Dx is an Input
1: Dx is an Output
x
GPIO_DIRCNx
where 0 ≤ x ≤ 6.
For example, writing a 1 to bit 6 means D6 is an Output.
Note: If D6 is used for DRDYB, then it cannot be used for GPIO.
Table 16. GPIO_DAT: GPIO Data (Address 0x0F)
Bit
7
Bit Symbol
Bit Description
Reserved
Write Only - when GPIO_DIRCNx = 0
0: Dx is LO
1: Dx is HI
Read Only - when GPIO_DIRCNx = 1
0: Dx driven LO
x
1: Dx driven HI
Dx
where 0 ≤ x ≤ 6.
For example, writing a 0 to bit 4 means D4 is LO.
It is okay to Read the GPIOs that are configured as outputs and write to GPIOs that are configured
as inputs. Reading the GPIOs that are outputs would return the current value on those GPIOs, and
writing to the GPIOs that are inputs are neglected
Table 17. BGCALCN: Background Calibration Control (Address 0x10)
Bit
Bit Symbol
Bit Description
[7:2] Reserved
Background calibration control – selects scheme for continuous background calibration.
0x0 (default): BgcalMode0: Background Calibration OFF
[1:0] BGCALN
0x1: BgcalMode1: Offset Correction / Gain Estimation
0x2: BgcalMode2: Offset Correction / Gain Correction
0x3: BgcalMode3: Offset Estimation / Gain Estimation
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Table 18. SPI_DRDYBCN: SPI Data Ready Bar Control (Address 0x11)
Bit
Bit Symbol
Bit Description
Enable DRDYB on D6
7
SPI_DRDYB_D6
0 (default): D6 is a GPIO
1: D6 = DRDYB signal
6
Reserved
5
CRC_RST
4
Reserved
CRC Reset
0 (default): Enable CRC reset on DRDYB deassertion
1: Disable CRC reset on DRDYB deassertion
Gain background calibration
3
0 (default): Correct FGA gain error. This is useful only if the device is operating in BgcalMode2
and ScanMode2 or ScanMode3.
FGA_BGCAL
1: Correct FGA gain error using the last known coefficients.
[2:0] Reserved
Default - 0x3 (do not change this value)
Table 19. ADC_AUXCN: ADC Auxiliary Control (Address 0x12)
Bit
Bit Symbol
Bit Description
7
Reserved
-
6
RESET_SYSCAL
The System Calibration registers (CHx_SCAL_OFFSET and CHx_SCAL_GAIN) are:
0 (default): preserved even when "REG_AND_CNV_ RST" = 0xC3.
1: reset by setting "REG_AND_CNV_ RST" = 0xC3.
External clock detection
5
CLK_EXT_DET
0 (default): "External Clock Detection" is operational
1: "External-Clock Detection" is bypassed
Clock select – only valid if CLK_EXT_DET = 1
4
CLK_SEL
0 (default): Selects internal clock
1: Selects external clock
Selects RTD Current as follows:
0x0 (default): 0 µA
0x1: 100 µA
0x2: 200 µA
0x3: 300 µA
RTD_CUR_SEL
[3:0] (LMP90100 and LMP90098
only)
0x4: 400 µA
0x5: 500 µA
0x6: 600 µA
0x7: 700 µA
0x8: 800 µA
0x9: 900 µA
0xA: 1000 µA
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Table 20. SPI_CRC_CN: CRC Control (Address 0x13)
Bit
Bit Symbol
Bit Description
[7:5] Reserved
Enable CRC
4
EN_CRC
0 (default): Disable CRC
3
Reserved
2
DRDYB_AFT_CRC
1: Enable CRC
Default - 0x0 (do not change this value)
DRDYB After CRC
0 (default): DRDYB is deasserted (active high) after ADC_DOUTL is read.
1: DRDYB is deasserted after SPI_CRC_DAT (which follows ADC_DOUTL), is read.
[1:0] Reserved
-
Table 21. SENDIAG_THLD: Sensor Diagnostic Threshold (Address 0x14 to 0x15)
Address
Name
Register Description
0x14
SENDIAG_THLDH
Sensor Diagnostic threshold [15:8]
0x15
SENDIAG_THLDL
Sensor Diagnostic threshold [7:0]
Table 22. SCALCN: System Calibration Control (Address 0x17)
Bit
Bit Symbol
Bit Description
[7:2] Reserved
System Calibration Control
When written, set SCALCN to:
0x0 (default): Normal Mode
0x1: “System Calibration Offset Coefficient Determination” mode
0x2: “System Calibration Gain Coefficient Determination” mode
0x3: Reserved
[1:0] SCALCN
When read, this bit indicates the system calibration mode is in:
0x0: Normal Mode
0x1: "System Calibration Offset Coefficient Determination" mode
0x2: "System Calibration Gain Coefficient Determination" mode
0x3: Reserved
Note: when read, this bit will indicate the current System Calibration status. Because this
coefficient determination mode will only take 1 conversion cycle, reading this register will only
return 0x00, unless this register is read within 1 conversion window.
Table 23. ADC_DONE: ADC Data Available (Address 0x18)
Bit
Bit Symbol
Bit Description
Data Available – indicates if new conversion data is available
0x00 − 0xFE: Available
[7:0] DT_AVAIL_B
0xFF: Not available
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Table 24. SENDIAG_FLAGS: Sensor Diagnostic Flags (Address 0x19)
Bit
Bit Symbol
Bit Description
7
SHORT_THLD_ FLAG
Short Circuit Threshold Flag = 1 when the absolute value of VOUT is within the absolute threshold
voltage set by SENDIAG_THLDH and SENDIAG_THLDL.
6
RAILS_FLAG
Rails Flag = 1 when at least one of the inputs is near rail (VA or GND).
5
POR_AFT_LST_RD
Power-on-reset after last read = 1 when there was a power-on-reset event because the last time
the SENDIAG_FLAGS register was read.
Overflow flags
0x0: Normal operation
[4:3] OFLO_FLAGS
0x1: The modulator was not overranged, but ADC_DOUT got clamped to 0x7f_ffff (positive
fullscale) or 0x80_0000 (negative full scale)
0x2: The modulator was over-ranged (VIN > 1.3*VREF/GAIN)
0x3: The modulator was over-ranged (VIN < -1.3*VREF/GAIN)
[2:0] SAMPLED_CH
Channel Number – the sampled channel for ADC_DOUT and SENDIAG_FLAGS.
Table 25. ADC_DOUT: 24-Bit Conversion Data (Two’s Complement) (Address 0x1A - 0x1C)
Address
Name
Register Description
0x1A
ADC_DOUTH
ADC Conversion Data [23:16]
0x1B
ADC_DOUTM
ADC Conversion Data [15:8]
0x1C
ADC_DOUTL
ADC Conversion Data [7:0]
Note: Repeat reads of these registers are allowed as long as such reads are spaced apart by at least 72 µs.
Table 26. SPI_CRC_DAT: CRC Data (Address 0x1D)
Bit
Bit Symbol
Bit Description
CRC Data
[7:0] CRC_DAT
When written, this register reset CRC:
Any Value: Reset CRC
When read, this register indicates the CRC data.
Table 27. CH_STS: Channel Status (Address 0x1E)
Bit
Bit Symbol
[7:2] Reserved
Bit Description
Channel Scan Not Ready – indicates if it is okay to program CH_SCAN
1
CH_SCAN_NRDY
0: Update not pending, CH_SCAN register is okay to program
1: Update pending, CH_SCAN register is not ready to be programmed
Invalid or Repeated Read Status
0
INV_OR_RPT_RD_STS
0: ADC_DOUT just read was valid and hitherto unread
1: ADC_DOUT just read was either invalid (not ready) or there was a repeated read.
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Table 28. CH_SCAN: Channel Scan Mode (Address 0x1F)
Bit
Bit Symbol
Bit Description
Channel Scan Select
0x0 (default): ScanMode0: Single-Channel Continuous Conversion
[7:6] CH_SCAN_SEL
0x1: ScanMode1: One or more channels Single Scan
0x2: ScanMode2: One or more channels Continuous Scan
0x3: ScanMode3: One or more channels Continuous Scan with Burnout Currents
Last channel for conversion
0x0: CH0
0x1: CH1
0x2: CH2
LAST_CH
0x3: CH3
[5:3] (CH4 to CH6 for LMP90100 and
0x4: CH4
LMP90099 only)
0x5: CH5
0x6 (default): CH6
Note: LAST_CH cannot be smaller than FIRST_CH. For example, if LAST_CH = CH5, then
FIRST_CH cannot be CH6. If 0x7 is written it is ignored.
Starting channel for conversion
0x0 (default): CH0
0x1: CH1
0x2: CH2
FIRST_CH
0x3: CH3
[2:0] (CH4 to CH6 for LMP90100 and
0x4: CH4
LMP90099 only)
0x5: CH5
0x6: CH6
Note: FIRST_CH cannot be greater than LAST_CH. For example, if FIRST_CH = CH1, then
LAST_CH cannot be CH0. If 0x7 is written it is ignored.
Note: While writing to the CH_SCAN register, if 0x7 is written to FIRST_CH or LAST_CH the write to the entire
CH_SCAN register is ignored.
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Table 29. CHx_INPUTCN: Channel Input Control (CH4 to CH6 for LMP90100/LMP9099 Only) (1)
Bit
Bit Symbol
Bit Description
Enable sensor diagnostic
7
BURNOUT_EN
0 (default): Disable Sensor Diagnostics current injection for this Channel
1: Enable Sensor Diagnostics current injection for this Channel
Select the reference
6
VREF_SEL
0 (Default): Select VREFP1 and VREFN1
1: Select VREFP2 and VREFN2
Positive input select
0x0: VIN0
0x1: VIN1
0x2: VIN2
[5:3]
VINP
0x3: VIN3 (LMP90100/LMP90099 only)
0x4: VIN4 (LMP90100/LMP90099 only)
0x5: VIN5 (LMP90100/LMP90099 only)
0x6: VIN6
0x7: VIN7
Note: to see the default values for each channel, refer to the table below.
Negative input select
0x0: VIN0
0x1: VIN1
0x2: VIN2
[2:0]
VINN
0x3: VIN3 (LMP90100/LMP90099 only)
0x4: VIN4 (LMP90100/LMP90099 only)
0x5: VIN5 (LMP90100/LMP90099 only)
0x6: VIN6
0x7: VIN7
Note: to see the default values for each channel, refer to the table below.
(1)
Register Address (hex):
(a) CH0: 0x20
(b) CH1: 0X22
(c) CH2: 0x24
(d) CH3: 0x26
(e) CH4: 0x28
(f) CH5: 0x2A
(g) CH6: 0x2C
Table 30. Default VINx for CH0 to CH6
VINP
VINN
CH0
VIN0
VIN1
CH1
VIN2
VIN3 (LMP90100/LMP90099
only)
CH2
VIN4 (LMP90100/LMP90099 only)
VIN5 (LMP90100/LMP90099
only)
CH3
VIN6
VIN7
CH4 (LMP90100/LMP90099 only)
VIN0
VIN1
CH5 (LMP90100/LMP90099 only)
VIN2
VIN3
CH6 (LMP90100/LMP90099 only)
VIN4
VIN5
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Table 31. CHx_CONFIG: Channel Configuration (CH4 to CH6 LMP90100/LMP90099 Only) (1)
Bit
7
Bit Symbol
Bit Description
Reserved
ODR Select
0x0: 13.42 / 8 = 1.6775 SPS
0x1: 13.42 / 4 = 3.355 SPS
0x2: 13.42 / 2 = 6.71 SPS
[6:4] ODR_SEL
0x3: 13.42 SPS
0x4: 214.65 / 8 = 26.83125 SPS
0x5: 214.65 / 4 = 53.6625 SPS
0x6: 214.65 / 2 = 107.325 SPS
0x7(default): 214.65 SPS
Gain Select
0x0 (default): 1 (FGA OFF)
0x1: 2 (FGA OFF)
0x2: 4 (FGA OFF)
[3:1] GAIN_SEL
0x3: 8 (FGA OFF)
0x4: 16 (FGA ON)
0x5: 32 (FGA ON)
0x6: 64 (FGA ON)
0x7: 128 (FGA ON)
Enable/Disable the buffer
0
0 (default): Exclude the buffer in the signal path
BUF_EN
1: Include the buffer from the signal path
Note: When gain ≥ 16, the buffer is automatically included in the signal path irrespective of this bit.
(1)
Register Address (hex):
(a) CH0: 0x21
(b) CH1: 0x23
(c) CH2: 0x25
(d) CH3: 0x27
(e) CH4: 0x29
(f) CH5: 0x2B
(g) CH6: 0x2D
Table 32. CHX_SCAL_OFFSET: CH0 to CH3 System Calibration Offset Registers (Two's Complement)
ADDR
CH0
NAME
DESCRIPTION
0x48
CHx_SCAL_OFFSETH
System Calibration Offset Coefficient Data [23:16]
0x41
0x49
CHx_SCAL_OFFSETM
System Calibration Offset Coefficient Data [15:8]
0x42
0x4A
CHx_SCAL_OFFSETL
System Calibration Offset Coefficient Data[7:0]
CH1
CH2
CH3
0x30 0x38
0x40
0x31 0x39
0x32 0x3A
Table 33. CHX_SCAL_GAIN: CH0 to CH3 System Calibration Gain Registers (Fixed Point 1.23 Format)
ADDR
CH0
NAME
DESCRIPTION
0x4B
CHx_SCAL_GAINH
System Calibration Gain Coefficient Data [23:16]
0x4C
CHx_SCAL_GAINM
System Calibration Gain Coefficient Data [15:8]
0x4D
CHx_SCAL_GAINL
System Calibration Gain Coefficient Data[7:0]
CH1
CH2
CH3
0x33 0x3B
0x43
0x34 0x3C
0x44
0x35 0x3D
0x45
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Table 34. CHX_SCAL_SCALING: CH0 to CH3 System Calibration Scaling Coefficient Registers
ADDR
CH0
CH1
CH2
CH3
0x36 0x3E
0x46
0x4E
NAME
DESCRIPTION
CHx_SCAL_SCALING
System Calibration Scaling Coefficient Data [5:0]
Table 35. CHX_SCAL_BITS_SELECTOR: CH0 to CH3 System Calibration Bits Selector Registers
ADDR
CH0
CH1
CH2
CH3
0x37 0x3F
0x47
0x4F
NAME
DESCRIPTION
CHx_SCAL_BITS_SELECTOR
System Calibration Bits Selection Data [2:0]
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10 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
10.1 Application Information
The LMP90100/LMP90099/LMP90098/LMP90097 are highly integrated, multi-channel, low power 24-bit Sensor
AFEs. The devices features a precision, 24-bit Sigma Delta Analog-to-Digital Converter (ADC) with a low-noise
programmable gain amplifier and a fully differential high impedance analog input multiplexer. A true continuous
background calibration feature allows calibration at all gains and output data rates without interrupting the signal
path. The background calibration feature essentially eliminates gain and offset errors across temperature and
time, providing measurement accuracy without sacrificing speed and power consumption.
10.1.1 Quick Start
This section shows step-by-step instructions to configure the LMP90xxx to perform a simple DC reading from
CH0.
1. Apply VA = VIO = VREFP1 = 5V, and ground VREFN1
2. Apply VINP = ¾VREF and VINN = ¼VREF for CH0. Thus, set CH0 = VIN = VINP - VINN = ½VREF
(CH0_INPUTCN register)
3. Set gain = 1 (CH0_CONFIG: GAIN_SEL = 0x0)
4. Exclude the buffer from the signal path (CH0_CONFIG: BUF_EN = 0)
5. Set the background to BgcalMode2 (BGCALCN = 0x2)
6. Select VREF1 (CH0_INPUTCN: VREF_SEL = 0)
7. To use the internal CLK, set CLK_EXT_DET = 1 and CLK_SEL = 0.
8. Follow the register read/write protocol (Figure 60) to capture ADC_DOUT from CH0.
10.1.2 ADC_DOUT Calculation
The output code of the LMP90xxx can be calculated as:
§ (VINP - VINN) x GAIN ·
23
ADC_DOUT = ± ¨
¸ x (2 )
VREFP
VREFN
¹
©
Equation 1 — Output Code
(13)
ADC_DOUT is in 24−bit two's complement binary format. The largest positive value is 0x7F_FFFF while the
largest negative value is 0x80_0000. In case of an over range the value is automatically clamped to one of these
two values.
Figure 77 shows the theoretical output code, ADC_DOUT, vs. analog input voltage, VIN, using the equation
above.
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Application Information (continued)
ADC_DOUT
8,388,607d
-1 LSB
|
|
(-VREF + 1LSB)
1d
|
|
+1LSB
- 16, 777, 215d
VIN
(VREF - 1LSB)
|
|
- 8,388,608d
Figure 77. ADC_DOUT vs. VIN of a 24-Bit Resolution (VREF = 5.5V, Gain = 1).
10.2 Typical Applications
10.2.1 3-Wire RTD Using 2 Current Sources
+
3V
3V
VA
VIO
+
0.1 PF
1 PF
0.1 PF
1 PF
SCLK
IB1
CSB
IB1 =
1 mA
SDO
SDI
drdyb = D6
VIN0
LMP90100
RLINE1
RTD
PT-100
RCOMP
= 0:
D5
VIN1
RLINE2
Microcontroller
IB2 =
1 mA
IB2
12 pF
VIN6/VREFP2
RLINE3
3.57
MHz
XOUT
RREF
VIN7/VREFN2
XIN/CLK
12 pF
Figure 78. Topology 1: 3-Wire RTD Using 2 Current Sources
10.2.1.1 Design Requirements
•
•
•
VA = 3V
VIO = 3V
3-Wire RTD using 2 current sources
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Typical Applications (continued)
10.2.1.2 Detailed Design Procedure
Figure 78 shows the first topology for a 3-wire resistive temperature detector (RTD) application. Topology 1 uses
two excitation current sources, IB1 and IB2, to create a differential voltage across VIN0 and VIN1. As a result of
using both IB1 and IB2, only one channel (VIN0-VIN1) needs to be measured. As shown in Equation 14, the
equation for this channel is IB1 x (RTD – RCOMP) assuming that RLINE1 = RLINE2. Equation 14 is the VIN
equation for Topology 1.
VIN0 = IB1 (RLINE1 + RTD) + (IB1 + IB2) (RLINE3 + RREF)
VIN1 = IB2 (RLINE2 + RCOMP) + (IB1 + IB2) (RLINE3 + RREF)
If RLINE1 = RLINE2, then:
VIN = (VIN0 - VIN1) = IB1 (RTD - RCOMP)
(14)
The PT-100 changes linearly from 100Ω at 0°C to 146.07Ω at 120°C. If desired, choose a suitable compensating
resistor (RCOMP) so that VIN can be virtually 0V at any desirable temperature. For example, if RCOMP = 100Ω,
then at 0°C, VIN = 0V and thus a higher gain can be used.
The advantage of this circuit is its ratiometric configuration, where VREF = (IB1 + IB2) x (RREF). Equation 15
shows that a ratiometric configuration eliminates IB1 and IB2 from the output equation, thus increasing the
overall performance. Equation 15 is for ADC_DOUT showing IB1 and IB2 eimination.
ADC_DOUT =
VIN (Gain) ( n)
2
2 VREF
ADC_DOUT =
[IB1( RTD - RCOMP) Gain] n
(2 )
2( IB1 + IB 2 ) RREF
ADC_DOUT =
>(RTD - RCOMP) Gain@
2 (2 ) RREF
( 2 n)
(15)
Resistance ( )
10.2.1.3 Application Curve
RTD
(Temp)
Temperature (°C)
Figure 79. PT-100 RTD Resistance from –200°C to 850°C
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Typical Applications (continued)
10.2.2 3-Wire RTD Using 1 Current Source
3V
3V
+
+
0.1 PF
2.2 PF
0.1 PF
VA
1 PF
VIO
SCLK
IB1
IB1 =
1 mA
CSB
SDO/DRDYB
RLINE1
SDI
VIN0
Microcontroller
RTD
PT-100
LMP90100
D2
VIN1
RLINE2
VIN6/VREFP2
RLINE3
RREF
OSC
XIN/CLK
VIN7/VREFN2
51:
Figure 80. Topology 2: 3-Wire RTD Using 1 Current Source
10.2.2.1 Design Requirements
•
•
•
VA = 3V
VIO = 3V
3-Wire RTD using 1 current source
10.2.2.2 Detailed Design Procedure
Figure 80 shows the second topology for a 3-wire RTD application. Topology 2 shows the same connection as
topology 1, but without IB2. Although this topology eliminates a current source, it requires two channel
measurements as shown in Equation 4.
VIN0 = IB1 (RLINE1 + RTD + RLINE3 + RREF)
VIN1 = IB1 (RLINE3 + RREF)
VIN6 = IB1 (RREF)
CH0 = VIN0 - VIN1 = IB1 (RLINE1 + RTD)
CH1 = VIN1 - VIN6 = IB1 (RLINE3)
Assume RLINE1 = RLINE3, thus:
CH0 - CH1 = IB1 (RTD)
Equation 4 — VIN Equation for Topology 2
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Typical Applications (continued)
Resistance ( )
10.2.2.3 Application Curve
RTD
(Temp)
Temperature (°C)
Figure 81. PT-100 RTD Resistance from –200°C to 850°C
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Typical Applications (continued)
10.2.3 Thermocouple with Cold Junction Compensation
5V
2.7V
+
+
0.1 PF
1 PF
VA
Thermocouple
VIO
10 nF
VREFP1
SCLK
+
TC [ VIN4 ± VIN3]
-
2.2 PF
CSB
SDO
2k
SDI
VIN3
2k
1 PF
Tcold
VIN4
Thot
0.1 PF
D6 = DRDYB
10 nF
LMP90100
Microcontroller
5V
LM94022
IC Temp
Sensor
+
1 PF
Tcold
VIN5
+
LM [ VIN5]
-
0.1 PF
XOUT
VIN7
5V
VREFP1
LM4140-4.1
+
1 PF
0.1 PF
0.1 PF
XIN/CLK
VREFN1
GND
Figure 82. Thermocouple With CJC
10.2.3.1 Design Requirements
•
•
•
VA = 5V
VIO = 2.7V
Thermocouple with Cold Junction Compensation
10.2.3.2 Detailed Design Procedure
The LMP90xxx is also ideal for thermocouple temperature applications. Thermocouples have several advantages
that make them popular in many industrial and medical applications. Compare to RTDs, thermistors, and IC
sensors, thermocouples are the most rugged, least expensive, and can operate over the largest temperature
range.
A thermocouple is a sensor whose junction generates a differential voltage, VIN, that is relative to the
temperature difference (Thot – Tcold). Thot is also known as the measuring junction or “hot” junction, which is
placed at the measured environment. Tcold is also known as the reference or “cold” junction, which is placed at
the measuring system environment.
Because a thermocouple can only measure a temperature difference, it does not have the ability to measure
absolute temperature. To determine the absolute temperature of the measured environment (Thot), a technique
known as cold junction compensation (CJC) must be used.
In a CJC technique, the “cold” junction temperature, Tcold, is sensed by using an IC temperature sensor, such
as the LM94022. The temperature sensor should be placed within close proximity of the reference junction and
should have an isothermal connection to the board to minimize any potential temperature gradients.
Once Tcold is obtained, use a standard thermocouple look-up-table to find its equivalent voltage. Next, measure
the differential thermocouple voltage and add the equivalent cold junction voltage. Lastly, convert the resulting
voltage to temperature using a standard thermocouple look-up-table.
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Typical Applications (continued)
For example, assume Tcold = 20°C. The equivalent voltage from a type K thermocouple look-up-table is 0.798
mV. Next, add the measured differential thermocouple voltage to the Tcold equivalent voltage. For example, if
the thermocouple voltage is 4.096 mV, the total would be 0.798 mV + 4.096 mV = 4.894 mV. Referring to the
type K thermocouple table gives a temperature of 119.37°C for 4.894 mV.
10.2.4 Application Curve
Figure 83. Thermocouple Output as Function of Temperature
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11 Power Supply Recommendations
11.1 VA and VIO
Any ADC architecture is sensitive to spikes on the analog voltage, VA, digital input/output voltage, VIO, and
ground pins. These spikes may originate from switching power supplies, digital logic, high power devices, and
other sources. To diminish these spikes, the LMP90xxx’s VA and VIO pins should be clean and well bypassed. A
0.1 µF ceramic bypass capacitor and a 1 µF tantalum capacitor should be used to bypass the LMP90xxx
supplies, with the 0.1 µF capacitor placed as close to the LMP90xxx as possible.
Because the LMP90xxx has both external VA and VIO pins, the user has two options on how to connect these
pins. The first option is to tie VA and VIO together and power them with the same power supply. This is the most
cost effective way of powering the LMP90xxx but is also the least ideal because noise from VIO can couple into
VA and negatively affect performance. The second option involves powering VA and VIO with separate power
supplies. These supply voltages can have the same amplitude or they can be different.
11.2 VREF
Operation with VREF below VA is also possible with slightly diminished performance. As VREF is reduced, the
range of acceptable analog input voltages is also reduced. Reducing the value of VREF also reduces the size of
the LSB. When the LSB size goes below the noise floor of the LMP90xxx, the noise will span an increasing
number of codes and performance will degrade. For optimal performance, VREF should be the same as VA and
sourced with a clean source that is bypassed with a ceramic capacitor value of 0.1 µF and a tantalum capacitor
of 10 µF.
LMP90xxx also allows ratiometric connection for noise immunity reasons. A ratiometric connection is when the
ADC’s VREFP and VREFN are used to excite the input device’s (i.e. a bridge sensor) voltage references. This
type of connection severely attenuates any VREF ripple seen the ADC output, and is thus strongly
recommended.
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12 Layout
12.1 Layout Guidelines
1.
2.
3.
4.
5.
Follow the guidelines in the Power Supply Recommendations section.
Keep analog traces away from digital traces.
Never run an analog and digital trace parallel to each other.
If a digital and analog need to cross each other cross them at a 90° angle.
Use a solid ground plane under the LMP90100.
12.2 Layout Example
The example layout in Figure 84 is for the Typical Application, 3-Wire RTD Using 2 Current Sources shown in
Figure 78.
Figure 84. LMP90xxx Sample Layout
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13 Device and Documentation Support
13.1 Device Support
13.1.1 Device Nomenclature
13.1.1.1 Specific Definitions
CMRR
= 20 LOG(ΔCommon Input / ΔOutput Offset)
COMMON MODE REJECTION RATIO is a measure of how well in-phase signals common to both input pins are
rejected. To calculate CMRR, the change in output offset is measured while the common mode
input voltage is changed.
EFFECTIVE NUMBER OF BITS (ENOB, or EFFECTIVE BITS) – says that the converter is equivalent to a
perfect ADC of this (ENOB) number of bits. LMP90xxx’s ENOB is a DC ENOB spec, not the
dynamic ENOB that is measured using FFT and SINAD. Its equation is as follows:
§ 2 x VREF/Gain·
ENOB = log2 ¨¨
¸¸
© RMS Noise ¹
(17)
GAIN ERROR is the deviation from the ideal slope of the transfer function.
INTEGRAL NON-LINEARITY (INL) is a measure of the deviation of each individual code from a straight line
through the input to output transfer function. The deviation of any given code from this straight line
is measured from the center of that code value. The end point fit method is used. INL for this
product is specified over a limited range, per the Electrical Tables.
NEGATIVE FULL-SCALE ERROR is the difference between the differential input voltage at which the output
code transitions to negative full scale and (-VREF + 1LSB).
NEGATIVE GAIN ERROR is the difference between the negative full-scale error and the offset error divided by
(VREF / Gain).
NOISE FREE RESOLUTION is a method of specifying the number of bits for a converter with noise.
§ 2 x VREF/Gain ·
¸¸
NFR = log2 ¨¨
© Peak-to-Peak Noise¹
ODR
(18)
Output Data Rate.
OFFSET ERROR is the difference between the differential input voltage at which the output code transitions
from code 0000h to 0001h and 1 LSB.
POSITIVE FULL-SCALE ERROR is the difference between the differential input voltage at which the output
code transitions to positive full scale and (VREF – 1LSB).
POSITIVE GAIN ERROR is the difference between the positive full-scale error and the offset error divided by
(VREF / Gain).
POWER SUPPLY REJECTION RATIO (PSRR) is a measure of how well a change in the analog supply voltage
is rejected. PSRR is calculated from the ratio of the change in offset error for a given change in
supply voltage, expressed in dB.
PSRR
= 20 LOG (ΔVA / ΔOutput Offset)
Copyright © 2011–2016, Texas Instruments Incorporated
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Product Folder Links: LMP90100 LMP90099 LMP90098 LMP90097
65
LMP90100, LMP90099, LMP90098, LMP90097
SNAS510S – JANUARY 2011 – REVISED JANUARY 2016
www.ti.com
13.2 Related Links
The table below lists quick access links. Categories include technical documents, support and community
resources, tools and software, and quick access to sample or buy.
Table 36. Related Links
PARTS
PRODUCT FOLDER
SAMPLE & BUY
TECHNICAL
DOCUMENTS
TOOLS &
SOFTWARE
SUPPORT &
COMMUNITY
LMP90100
Click here
Click here
Click here
Click here
Click here
LMP90099
Click here
Click here
Click here
Click here
Click here
LMP90098
Click here
Click here
Click here
Click here
Click here
LMP90097
Click here
Click here
Click here
Click here
Click here
13.3 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
13.4 Trademarks
E2E is a trademark of Texas Instruments.
WEBENCH is a registered trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
13.5 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
13.6 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
14 Mechanical, Packaging, and Orderable Information
The following pages include mechanical packaging and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
66
Submit Documentation Feedback
Copyright © 2011–2016, Texas Instruments Incorporated
Product Folder Links: LMP90100 LMP90099 LMP90098 LMP90097
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
LMP90097MH/NOPB
ACTIVE
HTSSOP
PWP
28
48
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90097
MH
LMP90097MHE/NOPB
ACTIVE
HTSSOP
PWP
28
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90097
MH
LMP90097MHX/NOPB
ACTIVE
HTSSOP
PWP
28
2500
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90097
MH
LMP90098MH/NOPB
ACTIVE
HTSSOP
PWP
28
48
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90098
MH
LMP90098MHE/NOPB
ACTIVE
HTSSOP
PWP
28
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90098
MH
LMP90098MHX/NOPB
ACTIVE
HTSSOP
PWP
28
2500
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90098
MH
LMP90099MH/NOPB
ACTIVE
HTSSOP
PWP
28
48
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90099
MH
LMP90099MHE/NOPB
ACTIVE
HTSSOP
PWP
28
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90099
MH
LMP90099MHX/NOPB
ACTIVE
HTSSOP
PWP
28
2500
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90099
MH
LMP90100MH/NOPB
ACTIVE
HTSSOP
PWP
28
48
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90100
MH
LMP90100MHE/NOPB
ACTIVE
HTSSOP
PWP
28
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90100
MH
LMP90100MHX/NOPB
ACTIVE
HTSSOP
PWP
28
2500
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 125
LMP90100
MH
(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)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of