MURATA SCA610

SCA610-E28H1A
Datasheet
SCA610-E28H1A SINGLE AXIS ACCELEROMETER WITH ANALOG
INTERFACE
The SCA610 accelerometer consists of a silicon bulk micro machined sensing element chip and a signal
conditioning ASIC. The chips are mounted on a pre-molded package and wire bonded to appropriate contacts.
The sensing element and ASIC are protected with silicone gel and lid. The sensor has 8 SMD legs (Gull-wing
type).
Applications
Features
•
•
•
•
•
•
•
•
Single +5 V supply
Current consumption 2.5 mA typical
Ratiometric output in relation to supply
voltage (Vdd = 4.75 V...5.25 V)
Enhanced failure detection features
o Digitally activated, true self-test by
proof mass deflection using
electrostatic force
o Memory parity check during power
up, and self-test cycle.
o Built in connection failure detection
Digitally activated, true self-test by proof
mass deflection using electrostatic force
Wide load drive capability (max. 20 nF)
True DC response
Qualified according to AEC-Q100 standard
SCA610 product family is targeted to automotive
applications with high stability and reliability
requirements. Typical applications include:
• Electronic Stability Control (ESC)
• Engine Vibration Measurement
• Roll Over
• Suspension
• Inclination
5V supply
Measurement
circuitry
Sensing
element
Gain &
filtering
EEPROM for calibration
constants (32 bit, pari ty check )
Vout
Digital self
test input
ASIC
GND
4 programming lines
for factory use only
Figure 1. Functional block diagram.
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Rev.B
SCA610-E28H1A
Table of Contents
SCA610-E28H1A single axis accelerometer with analog interface .................................... 1
FEATURES .................................................................................................................................... 1
APPLICATIONS .............................................................................................................................. 1
TABLE OF CONTENTS .................................................................................................................... 2
1.
Electrical Specifications ............................................................................................ 3
1.1.
1.2.
1.3.
1.4.
1.5.
1.6.
1.7.
ABSOLUTE MAXIMUM RATINGS............................................................................................ 3
PERFORMANCE CHARACTERISTICS ..................................................................................... 3
OFFSET AND SENSITIVITY CALIBRATION................................................................................ 4
ERROR CALCULATIONS ....................................................................................................... 4
SUPPLY VOLTAGE ............................................................................................................... 5
ELECTRICAL CONNECTION .................................................................................................. 6
TYPICAL PERFORMANCE CHARACHTERISTICS ...................................................................... 7
2.
Functional description ............................................................................................... 8
2.1.
2.2.
2.3.
2.4.
MEASURING DIRECTIONS .................................................................................................... 8
VOLTAGE TO ACCELERATION CONVERSION .......................................................................... 8
RATIOMETRIC OUTPUT ....................................................................................................... 8
SELFTEST AND FAILURE DETECTION MODES ......................................................................... 8
3.
Mechanical Specification ........................................................................................ 10
3.1.
DIMENSIONS ....................................................................................................................10
4.
Application information............................................................................................ 11
4.1.
4.2.
RECOMMENDED PCB LAY-OUT .........................................................................................11
REFLOW SOLDERING ........................................................................................................12
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Rev.B
SCA610-E28H1A
1. Electrical Specifications
1.1.
Absolute Maximum Ratings
Parameter
Value
Acceleration (powered or non-powered)
20 000
Units
(1
g
Supply voltage
−0.3 to +7.0
V
Voltage at input / output pins
−0.3 to VDD + 0.3
V
ESD HBM (Human Body Model)
±2
kV
ESD CDM (Charged Device Model)
±500 middle pins
V
±750 corner pins
Temperature range (storage)
−50 to +125
°C
Temperature range (operating)
−40 to +125
°C
1
1.2.
Equals to drop from 1 meter on a concrete surface.
Performance Characteristics
VDD = 5.00 V and ambient temperature unless otherwise specified.
KPCA) Parameter
Condition
Min.
<CC>
<CC>
<CC>
B.
g
V
mA
°C
kΩ
nF
V
V
V
V/g
-100
0
+100
mg
−40 °C...125 °C
−125
0
+125
mg
−40 °C...105 °C
−4
0
+4
%
−40 °C...125 °C
+1g ... -1g range
+1.7g ... -1.7g range
end point fit
−5
−20
-40
0
+5
+20
+40
%
mg
mg
20
−2
50
44
62
80
+2
3.9
5
10
80
Hz
%
%
mVrms
ms
kΩ
Linearity error
A.
5.0
2.5
−40 °C...105 °C
<SC>
<SC>
Units
+1.7
5.25
4.0
+125
Offset Error (Output at 0 g)
Sensitivity error
Amplitude response −3 dB
Ratiometric error
Cross-axis sensitivity
Output noise
Start-up delay
Self test pull down resistor
(Internal)
−1.7
4.75
Max.
Vout to Vdd or Vss
Vout to Vdd or Vss
20k from Vout to Vdd
20k from Vout to Vss
@ room temperature
@ room temperature
<SC>
Nominal
Typ
Measuring range
Supply voltage Vdd
Current consumption
Operating temperature
Resistive output load
Capacitive load
Min. output voltage; Vdd = 5 V
Max. output voltage; Vdd = 5 V
Offset (Output at 0 g)
Sensitivity
Vdd = 5 V; No load
B)
Vdd = 4.75 V...5.25 V
@ room temperature
From DC...4 kHz
Reset and parity check
−40
20
20
0.25
5.00
0
4.75
Vdd/2
1.2
(0.24*Vdd)
CC=
SC=
Critical Characteristics. Must be 100% monitored during production
Significant Characteristic. The process capability (Cpk) must be better than 1.33, which allows sample based
testing. If process is not capable the part will be 100% tested
Output has true DC response
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Rev.B
SCA610-E28H1A
1.3.
Offset and sensitivity calibration
Vout offset is calibrated in 0g position:
Offset = Vout (0 g ) [V]
Nominal offset is Vdd/2:
Offset nom =
Vdd
[V]
2
Sensitivity is calibrated as:
Sensitivity =
Vout (+ 1g ) − Vout (− 1g )
[V/g]
2g
Nominal sensitivity is:
Sensitivity nom = 1,2 [V/g]
1.4.
Error calculations
Total error is the allowed maximum error, which include partial error sources. Total error over
lifetime is specified as a sum of offset and sensitivity errors:
Total _ Error = Offset _ Error + Sensitivity _ Error [mg]
Offset error is specified as:
Vdd
2 [mg]
Sensitivity
Vout (0 g ) −
Offset _ Error =
Sensitivity error percent is specified as:
Sensitivity _ Error % =
[Vout (+ 1g ) − Vout (− 1g )] 2 g − Sensitivity nom × 100%
Sensitivity nom
Sensitivity error is specified as:
Sensitivity _ Error =
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[Vout − Vout (0 g )]× Sensitivity _ Error %
Sensitivity
Doc. nr. 82 1580 00
[mg]
4/13
Rev.B
SCA610-E28H1A
1.5.
Suppl y voltage
Usage of external 100 nF power supply bypass capacitor is recommended.
ASIC start-up should be tolerant to noise between Vdd and GND. Recommended power-up ramp is
presented below.
Parameter
T1
T2
V1
V2
Min
T0 + 0.1 µs
−0.3 V
4.5 V
Max
T0 + 100 µs
0.5 V
5.5 V
Supply voltage ramp at startup.
supply voltage
V2
V1
t
T0 T1
T2
Figure 2. VDD Start-up sequence.
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Rev.B
SCA610-E28H1A
1.6.
Electrical Connection
The following is minimum requirement for electrical interface to the SCA610. If over-voltage or
reverse polarity protection is needed, please contact VTI Technologies Oy for application
information.
Usage of external minimum 100 nF power supply bypass capacitor is recommended. Maximum
rise time of VDD is 100 ms.
If self-test (Pin 6) is not used it should be left floating.
Pins 1, 2, 3, and 5 are left floating.
Vdd
Vout
8
7
6
5
Min. 100nF
SCA610
1
2
3
4
GND
Figure 3.
Electrical connection of SCA610 component.
Pin #
Pin Name
1
2
3
4
5
6
7
8
CLK
C1
MODE
GND
PGM
ST
VOUT
VDD
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I/O
Function
Supply
Negative supply voltage (VSS)
Input
Output
Supply
Self-test control
Sensor output voltage
Positive supply voltage (VDD)
Doc. nr. 82 1580 00
Connection on PCB
Float / Not connected
Float / Not connected
Float / Not connected
Ground
Float / Not connected
Float when not used
Measuring circuit input
Vdd (+5V)
6/13
Rev.B
SCA610-E28H1A
1.7.
Typical Performance Charachteristics
Typical offset and sensitivity temperature dependencies of the SCA610-E28H1A are presented in
following diagrams. These results represent the typical performance of SCA610-E28H1A
components. The mean value and 3 sigma limits (mean ± 3× standard deviation) and specification
limits are presented in following diagrams. The 3 sigma limits represents 99.73% of the SCA610E28H1A population.
Figure 5. Typical temperature dependency of offset.
Figure 6. Typical temperature dependency of sensitivity.
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Rev.B
SCA610-E28H1A
2. Functional description
2.1.
Measuring directions
-
+
+
-
-1 g position
Vout,nom = 1.3 V
2.2.
0 g position
Vout,nom = 2.5 V
+1 g position
Vout,nom = 3.7 V
Voltage to acceleration conversion
Analog output can be transferred to acceleration using the following equation for conversion:
Acceleration =
Vout − Vout (0 g )
[g]
Sensitivity
where: Vout(0g) = nominal output of the device at 0g position with 5 V supply voltage (ratiometric
output), Sensitivity is the sensitivity of the device and Vout is the output of the sensor.
2.3.
Ratiometric Output
Ratiometric output means that the zero offset point and sensitivity of the sensor are proportional to
the supply voltage. If the SCA6X0 supply voltage is fluctuating the SCA6X0 output will also vary.
When the same reference voltage for both the SCA6X0 sensor and the measuring part (A/Dconverter) is used, the error caused by reference voltage variation is automatically compensated
for.
2.4.
Selftest and failure detection modes
To ensure reliable measurement results the SCA6X0 has continuous interconnection failure and
calibration memory validity detection. A detected failure forces the output signal close to power
supply ground or VDD level, outside the normal output range.
The calibration memory validity is verified by continuously running parity check for the control
register memory content. In the case where a parity error is detected, the control register is
automatically re-loaded from the EEPROM. If a new parity error is detected after re-loading data
analog output voltage is forced to go close to ground level (<0.25 V).
The SCA6X0 also includes a separate self test mode. The true self test simulates acceleration, or
deceleration, using an electrostatic force. The electrostatic force simulates acceleration that is high
enough to deflect the proof mass to the extreme positive position, and this causes the output signal
to go to the maximum value. The self test function is activated by a separate on-off command on
the self test input.
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Rev.B
SCA610-E28H1A
The self-test generates an electrostatic force, deflecting the sensing element’s proof mass, thus
checking the complete signal path. The true self test performs following checks:
• Sensing element movement check
• ASIC signal path check
• PCB signal path check
• Micro controller A/D and signal path check
The created deflection can be seen in analogue output. Self test can be activated applying logic”1”
(positive supply voltage level) to ST pin (pins 6) of SCA6X0. The self test Input high voltage level is
4 – Vdd+0.3 V and input low voltage level is 0.3 – 1 V.
5V
ST pin
voltage
0V
5V
Vout
V1
V2
T1
0V
T5
TIME [ MS ]
Figure 7. Self test wave forms.
V3
T2
T3
T4
V1 = initial output voltage before the self test function is activated.
V2 = output voltage during the self test function.
V3 = output voltage after the self test function has been de-activated and after stabilization time
Please note that the error band specified for V3 is to guarantee that the output is within 5% of the
initial value after the specified stabilization time. After a longer time (max. 1 second) V1=V3.
T1 = Pulse length for Self test activation
T2 = Saturation delay
T3 = Recovery time
T4 = Stabilization time =T2+T3
T5 = Rise time during self test.
T1 [ms]
10-100
T2 [ms]
Typ. 20
T3 [ms]
Typ. 50
T4 [ms]
Typ. 70
T5 [ms]
Typ. 10
V2:
Min 0.95*VDD
(4.75V @Vdd=5V)
V3:
0.95*V11.05*V1
Self test characteristics.
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Rev.B
SCA610-E28H1A
3. Mechanical Specification
Lead frame material:
Plating:
Solderability:
Co-planarity:
The part weights:
3.1.
Copper
Nickel followed by Gold
JEDEC standard: JESD22-B102-C
0.1 mm max.
~0.73 g
Dimensions
Figure 8. Mechanical dimensions [mm].
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Rev.B
SCA610-E28H1A
4. Application information
The SCA6X0 should be powered from a well regulated 5 V DC power supply. Coupling of digital
noise to the power supply line should be minimized. 100nF filtering capacitor between VDD pin 8
and GND plane must be used. If regulator is placed far from component for example other PCB it
is recommend adding more capacitance between VDD and GND to ensure current drive capability
of the system. For example 470 pF and 1uF capacitor can be used.
The SCA6X0 has a ratiometric output. To get the best performance use the same reference
voltage for both the SCA6X0 and Analog/Digital converter.
Locate the 100nF power supply filtering capacitor close to VDD pin 8. Use as short a trace length
as possible. Connect the other end of capacitor directly to the ground plane. Connect the GND pin
4 to underlying ground plane. Use as wide ground and power supply planes as possible. Avoid
narrow power supply or GND connection strips on PCB.
4.1.
Recommended PCB la y-out
Figure 9. Recommended PCB lay-out [mm].
Notes:
• It is important that the part is parallel to the PCB plane and that there is no angular alignment
error from intended measuring direction during assembly process.
• 1° mounting alignment error will increase the cross-axis sensitivity by 1.7%
• 1° mounting alignment error will change the output by 17 mg
• Wave soldering is not recommended
• Ultrasonic cleaning is not allowed
• A supply voltage by-pass capacitor (> 100 nF) is recommended
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Rev.B
SCA610-E28H1A
4.2.
Reflow soldering
The SCA6X0 is suitable for Sn-Pb eutectic and Pb- free soldering process and mounting with
normal SMD pick-and-place equipment. Recommended body temperature profile during reflow
soldering:
Figure 10.
Recommended body temperature profile during reflow soldering. Ref.
IPC/JEDEC J-STD-020D.
Profile feature
Average ramp-up rate (TL to TP)
Sn-Pb Eutectic
Assembly
Pb-free Assembly
3 °C/second max.
3 °C/second max.
150 °C
Preheat
-
Temperature min (Tsmin)
100 °C
-
Temperature max (Tsmax)
150 °C
200 °C
-
Time (min to max) (ts)
60-120 seconds
60-180 seconds
Tsmax to TL
-
3°C/second max
Ramp up rate
Time maintained above:
-
Temperature (TL)
-
Time (tL)
Peak temperature (TP)
Time within 5 °C of actual Peak Temperature
(TP)
Ramp-down rate
Time 25 °C to Peak temperature
183 °C
217 °C
60-150 seconds
60-150 seconds
240 +0/−5 °C
250 +0/−5 °C
10-30 seconds
20-40 seconds
6 °C/second max
6 °C/second max
6 minutes max
8 minutes max
The Moisture Sensitivity Level of the part is 3 according to the IPC/JEDEC J-STD-020D. The
part should be delivered in a dry pack. The manufacturing floor time (out of bag) in the
customer’s end is 168 hours.
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Rev.B
SCA610-E28H1A
Notes:
• Preheating time and temperatures according to guidance from solder paste
manufacturer.
• It is important that the part is parallel to the PCB plane and that there is no angular
alignment error from intended measuring direction during assembly process.
• Wave soldering is not recommended.
• Ultrasonic cleaning is not allowed. The sensing element may be damaged by an
ultrasonic cleaning process
The Moisture Sensitivity Level of the part is 3 according to the IPC/JEDEC J-STD020B. The part should be delivered in a dry pack. The manufacturing floor time (out of
bag) in the customer’s end is 168 hours. Maximum soldering temperature is
250 °C/40 sec.
Rework after the initial soldering process is not recommended. Rework can cause heat
build-up to the leg and this heat build-up will cause the housing material to get soft
thus allowing the leg to move. The movement can cause bond wire disconnection
inside the part.
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Rev.B