Maxim MAX1458AAE, MAX1458CAE, MAX1458C-D Datasheet

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General Description
The MAX1458 highly integrated analog-sensor signal processor is optimized for piezoresistive sensor calibra­tion and compensation without any external compo­nents. It includes a programmable current source for sensor excitation, a 3-bit programmable-gain amplifier (PGA), a 128-bit internal EEPROM, and four 12-bit DACs. Achieving a total error factor within 1% of the sensor’s repeatability errors, the MAX1458 compen­sates offset, offset temperature coefficient, full-span output (FSO), FSO temperature coefficient (FSOTC), and FSO nonlinearity of silicon piezoresistive sensors.
The MAX1458 calibrates and compensates first-order temperature errors by adjusting the offset and span of the input signal via digital-to-analog converters (DACs), thereby eliminating quantization noise. Built-in testabili­ty features on the MAX1458 result in the integration of three traditional sensor-manufacturing operations into one automated process:
Pretest:
Data acquisition of sensor performance
under the control of a host test computer.
Calibration and compensation:
Computation and storage (in an internal EEPROM) of calibration and compensation coefficients computed by the test computer and downloaded to the MAX1458.
Final test operation:
Verification of transducer cali­bration and compensation without removal from the pretest socket.
Although optimized for use with piezoresistive sensors, the MAX1458 may also be used with other resistive sensors (i.e., accelerometers and strain gauges) with some additional external components.
______________________Customization
Maxim can customize the MAX1458 for unique require­ments. With a dedicated cell library consisting of more than 90 sensor-specific functional blocks, Maxim can quickly provide customized MAX1458 solutions. Please contact Maxim for further information.
________________________Applications
Piezoresistive Pressure and Acceleration Transducers and Transmitters MAP (Manifold Absolute Pressure) Sensors Automotive Systems Hydraulic Systems Industrial Pressure Sensors
Features
Medium Accuracy (±1%), Single-Chip Sensor
Signal Conditioning
Sensor Errors Trimmed Using Correction
Coefficients Stored in Internal EEPROM— Eliminates the Need for Laser Trimming and Potentiometers
Compensates Offset, Offset-TC, FSO, FSOTC,
FSO Linearity
Programmable Current Source (0.1mA to 2.0mA)
for Sensor Excitation
Fast Signal-Path Settling Time (<1ms)Accepts Sensor Outputs from 10mV/V to 40mV/V Fully Analog Signal Path
MAX1458
1%-Accurate, Digitally Trimmed
Sensor Signal Conditioner
________________________________________________________________
Maxim Integrated Products
1
16 15 14 13 12 11 10
9
1 2 3 4 5 6 7 8
SCLK LIMIT
V
DD
INP BDRIVE INM I.C. OUT ISRC
TOP VIEW
MAX1458
SSOP
CS
I.C.
DIO
TEMP
FSOTC
WE
V
SS
19-1373; Rev 0; 5/98
PART
MAX1458CAE MAX1458C/D MAX1458AAE -40°C to +125°C
0°C to +70°C
0°C to +70°C
TEMP. RANGE PIN-PACKAGE
16 SSOP
Dice*
16 SSOP
*
Dice are tested at TA= +25°C, DC parameters only.
Functional Diagram appears at end of data sheet.
Pin Configuration
Ordering Information
MAX1458
1%-Accurate, Digitally Trimmed Sensor Signal Conditioner
2 _______________________________________________________________________________________
ABSOLUTE MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
(VDD= +5V, VSS= 0, TA= +25°C, unless otherwise noted.)
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Supply Voltage, VDDto VSS......................................-0.3V to +6V
All Other Pins ...................................(V
SS
- 0.3V) to (VDD+ 0.3V)
Short-Circuit Duration, FSOTC, OUT, BDRIVE...........Continuous
Continuous Power Dissipation (T
A
= +70°C)
SSOP (derate 8.00mW/°C above +70°C) .....................640mW
Operating Temperature Ranges
MAX1458CAE ......................................................0°C to +70°C
MAX1458AAE .................................................-40°C to +125°C
Storage Temperature Range.............................-65°C to +160°C
Lead Temperature (soldering, 10sec).............................+300°C
(Note 1)
DC to 10Hz (gain = 41, source impedance = 5k)
V
LIMIT
= 4.6V,
V
OUT
= (VSS+ 0.25V) to (V
LIMIT
- 0.3V)
At minimum gain (Note 4)
From VSSto V
DD
TA= T
MIN
to T
MAX
Selectable in eight steps
63% of final value
(Notes 2, 3)
(Note 5)
CONDITIONS
µV
RMS
500Output Noise
mA
-0.45 0.45
(sink) (source)
Output Current Range
V
SS
+ 0.15 VDD- 0.25
ppm/°C±50Differential Signal-Gain Tempco
V/V36 41 45Minimum Differential Signal Gain
V/V41 to 230Differential Signal-Gain Range
mV/V10 to 40
Input-Referred Adjustable FSO Range
mA3 6I
DD
Supply Current
V4.5 5.0 5.5V
DD
Supply Voltage
mV±150
Input-Referred Adjustable Offset Range
dB90CMRRCommon-Mode Rejection Ratio
ms1Output Step Response
M1R
IN
Input Impedance
µV/°C±0.5Input-Referred Offset Tempco
%V
DD
0.01Amplifier Gain Nonlinearity
UNITSMIN TYP MAXSYMBOLPARAMETER
10kload to V
SS
or V
DD
V
LIMIT
= 4.6V
VOutput Voltage Swing V
SS
+ 0.25 V
LIMIT
± 0.3
V
SS
+ 0.1 V
LIMIT
± 0.2No load
GENERAL CHARACTERISTICS
ANALOG INPUT (PGA)
ANALOG OUTPUT (PGA)
V
LIMIT
= 5.0V, no load
ELECTRICAL CHARACTERISTICS (continued)
(VDD= +5V, VSS= 0, TA= +25°C, unless otherwise noted.)
Note 1: Excludes the sensor or load current. Note 2: All electronics temperature errors are compensated together with sensor errors. Note 3: The sensor and the MAX1458 must always be at the same temperature during calibration and use. Note 4: This is the maximum allowable sensor offset. Note 5: This is the sensor’s sensitivity normalized to its drive voltage, assuming a desired full-span output of 4V and a bridge
voltage of 2.5V.
Note 6: Bit weight is ratiometric to V
DD
.
MAX1458
1%-Accurate, Digitally Trimmed
Sensor Signal Conditioner
_______________________________________________________________________________________ 3
Typically 4600ppm/°C tempco
V
FSOTC
= 2.5V
No load
Input referred, VDD= 5V (Note 6)
CONDITIONS
k100R
TEMP
Temperature-Dependent Resistor
k75R
FTC
FSO Trim Resistor
k75R
ISRC
Current-Source Reference Resistor
VV
SS
+ 1.3 VDD- 1.3V
BDRIVE
Bridge Voltage Swing
mA0.1 0.5 2.0I
BDRIVE
Bridge Current Range
µA-20 20Current Drive
VV
SS
+ 0.3 VDD- 1.3Output Voltage Swing
Bits3DAC Resolution
mV/bit9DAC Bit Weight
UNITSMIN TYP MAXSYMBOLPARAMETER
LSB±1.5DNLDifferential Nonlinearity
Bits12DAC Resolution
VV
SS
+ 1.3 VDD- 1.3V
ISRC
Reference Input Voltage Range (ISRC)
DAC reference = V
BDRIVE
= 2.5V
DAC reference = VDD= 5.0V
mV/bit1.4
V
OUT
Code
Offset TC DAC Bit Weight
mV/bit2.8
V
OUT
Code
Offset DAC Bit Weight
DAC reference = V
BDRIVE
= 2.5V
DAC reference = VDD= 5.0V
mV/bit0.6
V
FSOTC
Code
FSO TC DAC Bit Weight
mV/bit1.22
V
ISRC
Code
FSO DAC Bit Weight
CURRENT SOURCE
DIGITAL-TO-ANALOG CONVERTERS
IRO DAC
FSOTC BUFFER
INTERNAL RESISTORS
_______________Detailed Description
The MAX1458 provides an analog amplification path for the sensor signal. Calibration and temperature com­pensation are achieved by varying the offset and gain of a programmable-gain amplifier (PGA) and by varying the sensor bridge current. The PGA uses a switched­capacitor CMOS technology, with an input-referred coarse offset trimming range of approximately ±63mV (9mV steps). An additional output-referred fine offset trim is provided by the Offset DAC (approximately
2.8mV steps). The PGA provides eight gain values from +41V/V to +230V/V. The bridge current source is pro­grammable from 0.1mA to 2mA.
The MAX1458 uses four 12-bit DACs and one 3-bit DAC, with calibration coefficients stored by the user in
an internal 128-bit EEPROM. This memory contains the following information as 12-bit-wide words:
Configuration register
Offset calibration coefficient
Offset temperature error compensation coefficient
FSO (full-span output) calibration coefficient
FSO temperature error compensation coefficient
24 user-defined bits for customer programming of
manufacturing data (e.g., serial number and date)
Figure 1 shows a typical pressure-sensor output and defines the offset, full-scale, and full-span output values as a function of voltage.
MAX1458
1%-Accurate, Digitally Trimmed Sensor Signal Conditioner
4 _______________________________________________________________________________________
NAME FUNCTION
1 SCLK
Data Clock Input. Used only during programming/testing. Internally pulled to VSSwith a 1M(typical) resis­tor. Data is clocked in on the rising edge of the clock. The maximum SCLK frequency is 10kHz.
2 CS
Chip-Select Input. The MAX1458 is selected when this pin is high. When low, OUT and DIO become high impedance. Internally pulled to VDDwith a 1M(typical) resistor. Leave unconnected for normal operation.
PIN
3, 11 I.C. Internally Connected. Leave unconnected.
4 TEMP
Temperature Sensor Output. An internal temperature sensor (a 100k, 4600ppm/°C TC resistor) which can provide a temperature-dependent voltage.
8 V
SS
Negative Power-Supply Input
7 WE
Dual-Function Input Pin. Used to enable EEPROM erase/write operations. Also used to set the DAC refresh­rate mode. Internally pulled to V
DD
with a 1M(typical) resistor. Refer to the
Chip-Select (CS) and Write-
Enable (WE)
section.
6 DIO
Data Input/Output. Used only during programming/testing. Internally pulled to VSSwith a 1M(typical) resistor. High impedance when CS is low.
5 FSOTC
Buffered FSOTC DAC Output. An internal 75kresistor (R
FTC
) connects FSOTC to ISRC (see
Functional
Diagram
). Optionally, external resistors can be used in place of or in parallel with R
FTC
and R
ISRC
.
14 INP Positive Sensor Input. Input impedance >1M. Rail-to-rail input range.
13 BDRIVE Sensor Excitation Current Output. This current source drives the bridge.
12 INM Negative Sensor Input. Input impedance >1M. Rail-to-rail input range.
10 OUT PGA Output Voltage
9 ISRC
Current-Source Reference. An internal 75kresistor (R
ISRC
) connects ISRC to VSS(see
Functional
Diagram
). Optionally, external resistors can be used in place of or in parallel with R
FTC
and R
ISRC
.
Pin Description
16 LIMIT
Voltage Limit Input. This pin sets the maximum voltage at OUT. If left unconnected, the output voltage will be limited to 4.6V (VDD= 5V). Connect to VDDfor maximum output swing. The acceptable range is 4.5V V
LIMIT
VDD.
15 V
DD
Positive Power-Supply Input. Connect a 0.1µF capacitor from VDDto V
SS.
FSOTC Compensation
Silicon piezoresistive transducers (PRTs) exhibit a large positive input resistance tempco (TCR) so that, while under constant current excitation, the bridge voltage (V
BDRIVE
) increases with temperature. This depen-
dence of V
BDRIVE
on the sensor temperature can be used to compensate the sensor temperature errors. PRTs also have a large negative full-span output sensi­tivity tempco (TCS) so that, with constant voltage exci­tation, full-span output (FSO) will decrease with temperature, causing a full-span output temperature coefficient (FSOTC) error. However, if the bridge volt­age can be made to increase with temperature at the same rate that TCS decreases with temperature, the FSO will remain constant.
FSOTC compensation is accomplished by resistor R
FTC
and the FSOTC DAC, which modulate the excita­tion reference current at ISRC as a function of tempera­ture (Figure 3). FSO DAC sets V
ISRC
and remains constant with temperature while the voltage at FSOTC varies with temperature. FSOTC is the buffered output of the FSOTC DAC. The reference DAC voltage is V
BDRIVE
, which is temperature dependent. The FSOTC DAC alters the tempco of the current source. When the tempco of the bridge voltage is equal in magnitude and opposite in polarity to the TCS, the FSOTC errors are compensated and FSO will be constant with tempera­ture.
OFFSET TC Compensation
Compensating offset TC errors involves first measuring the uncompensated offset TC error, then determining the percentage of the temperature-dependent voltage
V
BDRIVE
that must be added to the output summing junction to correct the error. Use the Offset TC DAC to adjust the amount of BDRIVE voltage that is added to the output summing junction (Figure 2).
Analog Signal Path
The fully differential analog signal path consists of four stages:
Front-end summing junction for coarse offset correction
3-bit PGA with eight selectable gains ranging from
41 through 230
Three-input-channel summing junction
Differential to single-ended output buffer (Figure 2)
Coarse Offset Correction
The sensor output is first fed into a differential summing junction (INM (negative input) and INP (positive input)) with a CMRR > 90dB, an input impedance of approxi­mately 1M, and a common-mode input voltage range from VSSto VDD. At this summing junction, a coarse off­set-correction voltage is added, and the resultant volt­age is fed into the PGA. The 3-bit (plus sign) input-referred Offset DAC (IRO DAC) generates the coarse offset-correction voltage. The DAC voltage ref­erence is 1.25% of VDD; thus, a VDDof 5V results in a front-end offset-correction voltage ranging from -63mV to +63mV, in 9mV steps (Table 1). To add an offset to the input signal, set the IRO sign bit high; to subtract an offset from the input signal, set the IRO sign bit low. The IRO DAC bits (C2, C1, C0, and IRO sign bit) are programmed in the configuration register (see
Internal
EEPROM
section).
MAX1458
1%-Accurate, Digitally Trimmed
Sensor Signal Conditioner
_______________________________________________________________________________________ 5
VOLTAGE (V)
PRESSURE
P
MIN
P
MAX
FULL-SCALE (FS)
4.5
0.5
FULL-SPAN OUTPUT (FSO)
OFFSET
Figure 1. Typical Pressure-Sensor Output
SOTC
BDRIVE
1.25% V
DD
SOFF
±
±
A2
INP
INM
A1 A0
PGA
ΣΣ
A = 1
OUT
LIMIT
A = 2.3
A = 2.3
OFFTC
DAC
IRO
DAC
V
DD
Offset
DAC
Figure 2. Signal-Path Block Diagram
MAX1458
Table 1. Input-Referred Offset DAC Correction Values
Programmable-Gain Amplifier
The programmable-gain amplifier (PGA), which is used to set the coarse FSO, uses a switched-capacitor CMOS technology and contains eight selectable gain levels from 41 to 230, in increments of 27 (Table 2). The output of the PGA is fed to the output summing junc­tion. The three PGA gain bits A2, A1, and A0 are stored in the configuration register.
Output Summing Junction
The third stage in the analog signal path consists of a summing junction for the PGA output, offset correction, and the offset TC correction. Both the offset and the off­set TC correction voltages are gained by a factor of 2.3 before being fed into the summing junction, increasing the offset and offset TC correction range. The offset sign bit and offset TC sign bit are stored in the configu­ration register. The offset sign bit determines if the off­set correction voltage is added to (sign bit is high) or subtracted from (sign bit is low) the PGA output. Negative offset TC errors require a logic high for the offset TC sign bit. Alternately, positive offset TC errors dictate a logic low for the offset TC sign bit. The output of the summing junction is fed to the output buffer.
Output Buffer
OUT can drive 0.1µF of capacitance. If CS is brought low, OUT becomes high impedance (resulting in typical output impedance of 1M). The output is current limit­ed and can be shorted to either VDDor VSSindefinitely.
The maximum output voltage can be limited using the LIMIT pin. Output limiting can be performed for sensor diagnostic purposes. Connect LIMIT to VDDto disable the voltage-limiting feature.
Bridge Drive
Fine FSO correction is accomplished by varying the sensor excitation current with the 12-bit FSO DAC (Figure 3). Sensor bridge excitation is performed by a programmable current source capable of delivering up to 2mA. The reference current at ISRC is established by resistor R
ISRC
and by the voltage at node ISRC (con­trolled by the FSO DAC). The reference current flowing through this pin is multiplied by a current mirror (AA
14) and then made available at BDRIVE for sensor exci­tation. Modulation of this current with respect to tem­perature can be used to correct FSOTC errors, while modulation with respect to the output voltage (V
OUT
)
can be used to correct FSO linearity errors.
Digital-to-Analog Converters
The four 12-bit, sigma-delta DACs typically settle in less than 100ms. The four DACs have a corresponding memory register in EEPROM for storage of correction coefficients.
Use the FSO DAC for fine FSO adjustments. The FSO DAC takes its reference from VDDand controls V
ISRC
which, in conjunction with R
ISRC
, sets the baseline sen­sor excitation current. The Offset DAC also takes its ref­erence from VDDand provides a 1.22mV resolution with
1%-Accurate, Digitally Trimmed Sensor Signal Conditioner
6 _______________________________________________________________________________________
+7 1 1 1
IRO DAC
1
OFFSET
CORREC-
TION
% of V
DD
(%)
+1.25
OFFSET
CORREC-
TION AT
V
DD
= 5V
(mV)
+63
SIGN C1C2 C0VALUE
+6 1 1 1 0 +1.08 +54 +5 1 1 0 1 +0.90 +45 +4 1 1 0 0 +0.72 +36 +3 1 0 1 1 +0.54 +27 +2 1 0 1 0 +0.36 +18 +1 1 0 0 1 +0.18 +9 +0 1 0 0 0
0
0
-0 0 0 0 0
-1 0 0 0 1 -0.18 -9
-2 0 0 1 0 -0.36 -18
-3 0 0 1 1 -0.54 -27
-4 0 1 0 0 -0.72 -36
-5 0 1 0 1 -0.90 -45
-6 0 1 1 0 -1.08 -54
-7 0 1 1 1 -1.25 -63
A1
0 0 0
A2 A0
PGA
VALUE
0
PGA
GAIN
(V/V)
41
OUTPUT­REFERRED IRO DAC STEP SIZE
(VDD= 5V) (V)
0.369 1 0 0 1 68 0.612 2 0 1 0 95 0.855 3 0 1 1 122 1.098 4 1 0 0 149 1.341 5 1 0 1 176 1.584 6 1 1 0 203 1.827 7 1 1 1 230 2.070
Table 2. PGA Gain Settings and IRO DAC Step Size
0
0
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