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MAX1455 Datasheet, PDF (6/25 Pages) Maxim Integrated Products – Low-Cost Automotive Sensor Signal Conditioner
Low-Cost Automotive Sensor Signal
Conditioner
The MAX1455 allows complete calibration and sensor
verification to be performed at a single test station. Once
calibration coefficients have been stored in the ASIC, the
customer can choose to retest in order to verify perfor-
mance as part of a regular QA audit or to generate final
test data on individual sensors. In addition, Maxim has
developed a pilot production test system to reduce time
to market. Engineering test evaluation and pilot produc-
tion of the MAX1455 can be performed without expending
the cost and time to develop in-house test capabilities.
Contact Maxim for additional information.
Frequency response can be user adjusted to values
lower than the 3.2kHz bandwidth by using the uncom-
mitted op amp and simple passive components.
The MAX1455 (Figure 1) provides an analog amplifica-
tion path for the sensor signal. It uses a digitally con-
trolled analog path for nonlinear temperature correction.
For PRT applications, analog architecture is available for
first-order temperature correction. Calibration and cor-
rection are achieved by varying the offset and gain of a
PGA and by varying the sensor bridge excitation current
or voltage. The PGA utilizes a switched capacitor CMOS
technology, with an input-referred offset trimming range
of more than ±150mV with an approximate 3µV resolution
(16 bits). The PGA provides gain values from 39V/V to
234V/V in 16 steps.
The MAX1455 uses four 16-bit DACs with calibration
coefficients stored by the user in an internal 768 x 8
EEPROM (6144 bits). This memory contains the follow-
ing information, as 16-bit-wide words:
• Configuration register
• Offset calibration coefficient table
• Offset temperature coefficient register
• FSO calibration coefficient table
• FSO temperature correction register
• 52 bytes (416 bits) uncommitted for customer pro-
gramming of manufacturing data (e.g., serial num-
ber and date)
Offset Correction
Initial offset correction is accomplished at the input
stage of the signal gain amplifiers by a coarse offset
setting. Final offset correction occurs through the use of
a temperature-indexed lookup table with one hundred
seventy-six 16-bit entries. The on-chip temperature sen-
sor provides a unique 16-bit offset trim value from the
table with an indexing resolution of approximately 1.5°C
from -40°C to +125°C. Every millisecond, the on-chip
temperature sensor provides indexing into the offset
lookup table in EEPROM and the resulting value is
BIAS
GENERATOR
TEST 1
IRO
DAC
MAX1455 OSCILLATOR
TEST 2
TEST 3
CLIP-TOP
TEST 4
INP
∑
PGA
OUT
INM
CLIP-BOT
CURRENT
SOURCE
ANAMUX
BDR
TEMP
SENSOR
8-BIT A/D
VDD1
VDD2
DIO
UNLOCK
VSS
CONTROL
176-POINT
TEMPERATURE-
INDEXED
FSO
COEFFICIENTS
176-POINT
TEMPERATURE-
INDEXED
OFFSET
COEFFICIENTS
416 BITS FOR
USER DATA
CONFIG REG
6144-BIT
EEPROM
AMP+
AMP-
AMPOUT
Figure 1. Functional Diagram
transferred to the offset DAC register. The resulting volt-
age is fed into a summing junction at the PGA output,
compensating the sensor offset with a resolution of
±76µV (±0.0019% FSO). If the offset TC DAC is set to
zero, then the maximum temperature error is equivalent
to 1°C of temperature drift of the sensor, given that the
Offset DAC has corrected the sensor every 1.5°C. The
temperature indexing boundaries are outside the speci-
fied absolute maximum ratings. The minimum indexing
value is 00hex, corresponding to approximately -69°C.
All temperatures below this value output the coefficient
value at index 00hex. The maximum indexing value is
AFhex, which is the highest lookup table entry. All tem-
peratures higher than approximately +184°C output the
highest lookup table index value. No indexing wrap-
around errors are produced.
FSO Correction
Two functional blocks control the FSO gain calibration.
First, a coarse gain is set by digitally selecting the gain of
the PGA. Second, FSODAC sets the sensor bridge cur-
rent or voltage with the digital input obtained from a tem-
perature indexed reference to the FSO lookup table in
EEPROM. FSO correction occurs through the use of a
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