MMA8491QR1 [NXP]
SPECIALTY ANALOG CIRCUIT;MMA8491Q
3-Axis Multifunction Digital Accelerometer
Rev. 2.1 — 26 April 2016
Data sheet: Technical data
COMPANY PUBLIC
1 General description
The MMA8491Q is a low voltage, 3-axis low-g accelerometer housed in a 3 mm x 3 mm
QFN package. The device can accommodate two accelerometer configurations, acting
as either a 45° tilt sensor or a digital output accelerometer with I2C bus.
• As a 45° tilt sensor, the MMA8491Q device offers extreme ease of implementation by
using a single line output per axis.
• As a digital output accelerometer, the 14-bit ±8 g accelerometer data can be read from
the device with a 1 mg/LSB sensitivity.
The extreme low power capabilities of the MMA8491Q will reduce the low data rate
current consumption to less than 400 nA per Hz.
2 Features and benefits
• Extreme low power, 400 nA per Hz
• Ultra-fast data output time, ~700 μs
• VDD supply range of 1.95 V to 3.6 V
• 3 mm x 3 mm, 0.65 mm pitch with visual solder joint inspection
• ±8 g full-scale range
• 14-bit digital output, 1 mg/LSB sensitivity
• Output Data Rate (ODR), implementation based from < 1 Hz to 800 Hz1
• I2C digital interface
• 3-axis, 45° tilt outputs
3 Typical applications
• Smart grid: tamper detect
• Anti-theft
• White goods tilt
• Remote controls
1 The ODR for this device is user defined by the period of the Enable pulsed signal. The maximum
recommended frequency of the Enable signal or the ODR that can be achieved for this device is 800 Hz.
NXP Semiconductors
MMA8491Q
3-Axis Multifunction Digital Accelerometer
4 Ordering information
Table 1. Ordering information
Part Number
Temperature Range
Package
Shipping
MMA8491QT
–40 to +85 °C
–40 to +85 °C
–40 to +85 °C
QFN 12
QFN 12
QFN 12
Tray
MMA8491QR1
MMA8491QR2
1000 pc / Tape & Reel
5000 pc / Tape & Reel
5 Related documentation
The MMA8491Q device features and operations are described in a variety of reference
manuals, user guides, and application notes. To find the most current versions of these
documents:
1. Go to the NXP homepage at: http://www.nxp.com/
2. In the Keyword search box at the top of the page, enter the device number
MMA8491Q. In the Refine Your Result pane on the left, click on the Documentation
link.
6 Block diagram
Figure 1. Block Diagram
7 Pinout
MMA8491Q is hosted in a 12-pin 3 mm x 3 mm QFN package. Ten pins are used for
functions; two pins are unconnected. Refer to Table 2 for complete pin descriptions and
functions.
MMA8491Q
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Data sheet: Technical data
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
MMA8491Q
Byp
VDD
1
2
3
4
10 Xout
9
8
7
Yout
Zout
Gnd
SDA
EN
Transparent top view
Figure 2. Pin connection diagram
Function
Table 2. Pin descriptions
Pin
Symbol
Description
Pin status
1
Byp
Internal regulator The internal regulator voltage of 1.8 V is present on this
output capacitor pin. Connect to external 0.1 μF bypass capacitor.
connection
Output
2
3
VDD
Power Supply
Device power is supplied through the VDD line. Power
supply decoupling capacitors should be placed as near as
possible to pin 1 of the device.
Input
SDA
I2C Data
I2C Slave Data Line, open drain
Input/Output
• 7-bit I2C device address is 0x55
• The SDA and SCL I2C connections are open drain, and
therefore usually require a pull-up resistor
4
EN
Enable pin
The Enable pin fully turns on the accelerometer system
when it is pulled up to logic high. The accelerometer
system is turned off when the Enable pin is logic low.
Input
5
6
7
8
SCL
Gnd
Gnd
Zout
I2C Clock
Ground
Ground
I2C Slave Clock Line, open drain
Input
Ground
Ground
Ground
Ground
Push-pull Z-Axis • Output is high when acceleration is > 0.688 g (axis is | Output
Tilt Detection
Output
φ| > 45°).
• Output is low when acceleration is ≤ 0.688 g (axis is |φ|
≤ 45°).
9
Yout
Xout
Push-pull Y-Axis
Tilt Detection
Output
Output
Output
• These pins are push-pull output pins.
10
Push-pull X-Axis
Tilt Detection
Output
11
12
NC
NC
No internal
connection
No internal connection
No internal connection
No internal
connection
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
8 Recommended application diagram
Figure 3. VDD connects to power supply and EN is pulsed
To ensure the accelerometer is fully functional, connect the MMA8491Q as suggested in
Figure 3.
• A capacitor must be connected to the Bypass pin (pin 1) to assist the internal voltage
regulator. It is recommended to use a 0.1 μF capacitor. The capacitor should be placed
as near as possible to the Bypass pin.
• The device power is supplied through the VDD line. The power supply decoupling
capacitor should be placed as close as possible to the VDD pin.
– Use a 1.0 or 4.7 μF capacitor when the VDD and EN are not tied together.
– When VDD and EN are tied together, use a 0.1 μF capacitor. The 0.1 μF capacitor
value has been chosen to minimize the average current consumption while still
maintaining an acceptable level of power supply high frequency filtering.
• Both ground pins (pins 6 and 7) must be connected to ground.
• When the I2C communication line is used, use a pull-up resistor to connect to line SDA
and SCL. The SCL line can be driven by a push-pull driver, in which case, no pull-up
resistor is necessary. If SDA and SCL pins are not used, then they should be tied to
ground.
9 Sensing direction and output response
The MMA8491Q has three tilt detection outputs: Xout, Yout, and Zout. The following
figure shows the output results at the six different orientation positions.
MMA8491Q
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Data sheet: Technical data
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Top view
Side view
Back
Portrait Up
Pin 1
Xout @ 0 g
Yout @ 0 g
Zout @ –1 g
Gravity
Xout @ 0 g
Yout @ –1 g
Zout @ 0 g
Front
Landscape Right
Landscape Left
Xout @ 0 g
Yout @ 0 g
Zout @ 1 g
Xout @ –1 g
Yout @ 0 g
Zout @ 0 g
Xout @ 1 g
Yout @ 0 g
Zout @ 0 g
Z
Portrait Down
X
Y
Xout @ 0 g
Yout @ 1 g
Zout @ 0 g
(Top view)
Reference frame for acceleration measurement
Figure 4. Sensitive axes orientation and output response to ±1 g (gravity) stimulus
10 Mechanical and electrical specifications
10.1 Absolute maximum ratings
Absolute maximum ratings are the limits the device can be exposed to without damage.
Functional operation at absolute maximum rating is not guaranteed.
Although this device contains circuitry to protect against damage due to high static
voltage or electrostatic fields, it is advised that normal precautions be taken to avoid
application of any voltage higher than the maximum-rated voltage.
Table 3. Absolute maximum ratings
Symbol
gmax
Rating
Maximum acceleration (all axes, 100 μs)
Analog supply voltage
Min
—
Max
10 000
3.6
Unit
V
VDD
–0.3
—
V
Ddrop
Drop test
1.8
m
TAGOC
TSTG
Operating temperature
–40
–40
+85
°C
°C
Storage temperature
+125
Table 4. ESD and latch-up protection characteristics
Symbol
VHBM
Rating
Value
Unit
V
Human body model (HBM)
Machine model (MM)
±2000
±200
VMM
V
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Symbol
Rating
Value
±500
Unit
V
VCDM
ILU
Charge device model (CDM)
Latch-up current at TA = 85 °C
±100
mA
10.2 Mechanical characteristics
Table 5. Accelerometer mechanical characteristics
VDD = 2.8 V, T = 25 °C, unless otherwise noted.
Typical number is the target number, unless otherwise specified.
All numbers are based on VDD cap = 4.7 μF.
Parameter
Symbol
FS[1]
So[2]
Conditions
Min
—
Typ
±8
Max
—
Unit
g
Full-scale measurement range
Sensitivity
—
—
973
1024
—
1075
5
counts/g
%
Calibrated sensitivity error
Cross-axis sensitivity
Sensitivity temperature variation
Zero-g level temperature variation
Zero-g level offset accuracy
Zero-g level after board mount
Noise
CSE[2]
All axes, all ranges
–5
[1]
CXSEN
Die rotation included
–4.2
–0.014
–0.98
–100
–120
—
—
4.2
%
TCS[1]
TCO[1]
TyOff[2][3]
TyOffPBM[1][4]
RMS[1]
NL[1]
TDL[6]
TDL[1][4][6]
–40 °C to +85 °C
—
0.014
0.98
100
120
18
%/°C
mg/°C
mg
–40 °C to +85 °C
—
—
—
—
—
mg
—
11.5
—
mg-rms
%FS
g
Nonlinearity
Threshold / g-value[5]
—
25 °C
—
1
0.583
0.577
35.6
35.2
–40
0.688
0.688
43.5
43.5
25
0.780
0.784
51.3
51.7
85
–40 °C to +85 °C
25 °C
[1]
Threshold / Tilt angle[7]
Temperature range
TAGOC
degrees
°C
–40 °C to +85 °C
—
[1] Verified by characterization; not tested in production.
[2] Parameters tested 100% at final test at room temperature.
[3] Before board mount.
[4] Post-board mount offset specifications are based on a 4-layer PCB, relative to 25 °C.
[5] Internal threshold of output level change (from 0 g reference), g values are calculated from trip angles.
[6] All angles are based on the trip angle from static 0 g to 1 g; the g-values are calculated from the trip angle.
[7] Internal threshold of output level change (from 0 g reference).
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
10.3 Electrical characteristics
Table 6. Electrical characteristics
VDD = 2.8 V, T = 25 °C, unless otherwise noted.
Typical values represent mean or mean ±1 σ values, depending on the specific parameter.
Typical number is the target number unless otherwise specified.
All numbers are based on VDD cap = 4.7 μF.
Symbol
Parameter
Supply voltage[1]
Conditions
Min
1.71
—
Typ
1.8
400[2][3][4]
Max
3.6
980[1][5][6]
Unit
V
VDD
—
IDD
Supply current in one-shot mode
VDD = 2.8 V, EN is
nA/Hz
pulsed to VDD for 1 ms
ISD
Supply current in shutdown
mode
VDD = 2.8 V, EN = 0
—
1.8[2][3]
68[1][6]
nA
[2]
CBYP
Bypass capacitor at Byp pin
—
70
100
—
470
—
nF
V
[1]
VOH
High level output voltage Xout,
Yout, Zout
IO = 500 μA
0.85
* VDD
[1]
VOL
Low level output voltage Xout,
Yout, Zout
IO = 500 μA
VDD = 2.8 V
—
—
—
0.15 * VDD
—
V
V
[1]
VIH
High level input voltage EN
0.85
* VDD
[1]
VIL
Low level input voltage EN
VDD = 2.8 V
IO = 3 mA
—
—
—
—
—
0.15 * VDD
V
V
V
[7]
VOLS
Low level output voltage SDA
0.4
—
[7]
VIH
High level input voltage SDA,
SCL
VDD = 2.8 V
0.7 * VDD
[7]
VIL
Low level input voltage SDA,
SCL
VDD = 2.8 V
—
—
—
—
0.3 * VDD
7.3
V
[1]
ISOURCE
Output source current Xout,
Yout, Zout
Voltage high level
mA
Vout = 0.85 x
VDD, VDD = 2.8 V
[1]
ISINK
Output sink current Xout, Yout,
Zout
Voltage low level
—
—
—
720[2][3][4]
—
8.9
900[1][5][6]
—
mA
μs
Vout = 0.15 x
VDD, VDD = 2.8 V
TON
/
Turn-on time
—
[8]
TACTIVE
Measured from the time EN =
1.95 V to valid outputs
[7]
TRST
Reset Time
VDD = 2.8 V
1000
μs
The time between falling edge of
EN and next rising edge of EN
[1] Verified by characterization; not tested in production.
[2] Evaluation data: not tested in production.
[3] Typical number is mean data.
[4] Data is based on typical bypass cap = 100 nF.
[5] Data is based on max bypass cap = 470 nF.
[6] Over temperature -40 °C to 85 °C.
[7] Guaranteed by design.
[8] For application connection, see Figure 3
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
11 I2C Interface
Acceleration data may be accessed through an I2C interface, thus making the device
particularly suitable for direct interfacing with a microcontroller. The MMA8491Q features
three interrupt signals that indicate the tilt-sensing results on X, Y, Z axis respectively.
The raw accelerometer data are readable via I2C at the same time when an interrupt
signal is available.
The registers embedded inside the MMA8491Q are accessible through the I2C serial
interface, Table 7. To enable the I2C interface, the EN pin must be HIGH. If either EN or
VDD are absent, the MMA8491Q I2C interface reads invalid data. The I2C interface may
be used for communications along with other I2C devices. Removing power from the VDD
pin of the MMA8491Q does not affect the I2C bus.
Table 7. Serial interface pins
Pin
SCL
SDA
Description
I2C Serial Clock
I2C Serial Data
There are two signals associated with the I2C bus; the Serial Clock Line (SCL) and the
Serial Data Line (SDA). The SDA is a bidirectional line used for sending and receiving
the data to/from the interface. External pull-up resistors connected to VDD are expected
for SDA and SCL. When the bus is free both the lines are HIGH. The I2C interface is
compliant with Fast mode (400 kHz, Table 8).
Table 8. I2C slave timing values
Parameter
Symbol
I2C Fast Mode[1]
Unit
Min
Max
400
—
SCL clock frequency
fSCL
0
kHz
μs
μs
μs
μs
μs
μs
μs
μs
μs
μs
μs
μs
μs
Bus-free time between STOP and START condition
(Repeated) START hold time
Repeated START setup time
STOP condition setup time
SDA data hold time
tBUF
1.3
tHD;STA
tSU;STA
tSU;STO
tHD;DAT
tSU;DAT
tLOW
0.6
—
0.6
—
0.6
—
0.9[2]
0.05
SDA setup time
100
—
SCL clock low time
1.3
—
SCL clock high time
tHIGH
tr
0.6
—
[3]
[3]
SDA and SCL rise time
SDA and SCL fall time
SDA valid time[4]
20 + 0.1 Cb
300
300
0.9[2]
0.9[2]
50
tf
20 + 0.1 Cb
tVD;DAT
tVD;ACK
—
—
0
SDA valid acknowledge time[5]
Pulse width of spikes on SDA and SCL that must be suppressed by tSP
internal input filter
Capacitive load for each bus line
Cb
—
400
pF
[1] All values referred to VIH(min) (0.3VDD) and VIL(max) (0.7VDD) levels.
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
[2] This device does not stretch the LOW period (tLOW) of the SCL signal.
[3] Cb = total capacitance of one bus line in pF.
[4] tVD;DAT = time for data signal from SCL LOW to SDA output (HIGH or LOW, depending on which one is worse).
[5] tVD;ACK = time for Acknowledgement signal from SCL LOW to SDA output (HIGH or LOW, depending on which one is worse).
Figure 5. I2C slave timing diagram
11.1 I2C read operations
The transaction on the bus is started through a start condition (START) signal. A START
condition is defined as a HIGH-to-LOW transition on the data line while the SCL line is
held HIGH.
After START has been transmitted by the Master, the bus is considered busy. The next
byte of data transmitted after START contains the slave address in the first seven bits,
and the eighth bit tells whether the Master is receiving data from the slave or transmitting
data to the slave. When an address is sent, each device in the system compares the first
seven bits after a start condition with its address. If they match, then the device considers
itself addressed by the Master.
The ninth clock pulse, following the slave address byte, and each subsequent byte, is the
acknowledge (ACK). The transmitter must release the SDA line during the ACK period.
The receiver must then pull the data line LOW so that it remains stable low during the
high period of the acknowledge clock period.
A LOW-to-HIGH transition on SDA while SCL is HIGH is defined as a stop condition
(STOP). A data transfer is always terminated by a STOP.
A Master may also issue a repeated START during a data transfer. The MMA8491Q
expects repeated STARTs to be used to randomly read from specific registers.
The MMA8491Q accelerometer standard 7-bit slave address is 01010101(0x55).
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Table 9. I2C device address sequence
Command
[7:1] Device
[7:1] Device
Address
[0] R/W
[7:0] 8-bit
Final Value
Address
01010101
01010101
Read
Write
0x55
0x55
1
0
0xAB
0xAA
11.1.1 Single-byte read
The transmission of an 8-bit command begins on the falling edge of SCL. After the 8
clock cycles are used to send the command, note that the data returned is sent with
the MSB first after the data is received. Figure 6 shows the timing diagram for the
accelerometer 8-bit I2C read operation.
1. The Master (or MCU) transmits a start condition (ST) to the MMA8491Q, slave
address (0x55), with the R/W bit set to “0” for a write, and the MMA8491Q sends an
acknowledgement.
2. Then the Master (or MCU) transmits the address of the register to read and the
MMA8491Q sends an acknowledgement.
3. The Master (or MCU) transmits a repeated start condition (SR) and then addresses
the MMA8491Q (0x1D) with the R/ W bit set to 1 for a read from the previously
selected register.
4. The Slave then acknowledges and transmits the data from the requested register.
5. The Master does not acknowledge (NAK) the transmitted data, but transmits a stop
condition to end the data transfer.
11.1.2 Multiple-byte read
When performing a multiple-byte read or burst read, the MMA8491Q automatically
increments the received register address commands after a read command is received.
Therefore, after following the steps of a single-byte read, multiple bytes of data can be
read from sequential registers after each MMA8491Q acknowledgment (AK) is received,
until a no acknowledge (NAK) occurs from the Master, followed by a stop condition (SP)
signaling an end of transmission.
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
11.1.3 I2C data sequence diagrams
Single-byte read
Device
Address[7:1]
Register
Address[7:0]
Device
Address[7:1]
ST
W
SR
R
NAK SP
Master
AK
AK
AK
Data[7:0]
Slave
Multiple-byte read
Device
Address[7:1]
Register
Address[7:0]
Device
Address[7:1]
ST
W
SR
R
AK
Master
AK
AK
AK Data[7:0]
Slave
c o n tin u ed . . .
AK
AK
NAK SP
Master
Data[7:0]
Data[7:0]
Data[7:0]
Slave
Legend
ST: Start Condition
SP: Stop Condition
AK: Acknowledge
NAK: No Acknowledge
R: Read = 1
W: Write = 0
SR: Repeated Start Condition
Figure 6. I2C data sequence diagrams
12 Modes of operation
EN = Low
One sample
is acquired
V
= On
EN = High
DD
OFF*
Mode
ACTIVE
Mode
STANDBY
Mode
SHUTDOWN
Mode
V
= Off
V
= On
V
= On
V
= On
DD
DD
DD
DD
EN = Don’t Care
EN = Low
EN = High
EN = High
*OFF mode can be entered from any state by removing the power.
Figure 7. MMA8491Q operating modes
Table 10. MMA8491Q operating modes
Mode
Conditions
Function description
Digital output state
OFF
VDD = OFF
Device is powered off.
Hi-Z
Hi-Z
EN = Don’t Care
SHUTDOWN VDD = ON
EN = Low
All blocks are shut down.
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Mode
Conditions
Function description
Digital output state
ACTIVE
VDD = ON
All blocks are enabled.
Deasserted, Xout = 0, Yout= 0, Zout = 0
EN = High
Device enters Standby mode automatically
after data conversion.
STANDBY
VDD = ON
EN = High
Only digital output subsystem is enabled. Active, I2C outputs become valid
Data is valid and available only in this
stage.
12.1 ACTIVE mode
The accelerometer subsystem is turned on at the rising edge of the EN pin, and acquires
one sample for each of the three axes. Note that EN should not be asserted before VDD
reaches 1.95 V. Samples are acquired, converted, and compensated for zero-g offset
and gain errors, and then compared to an internal threshold value of 0.688 g and stored.
• If any of the X, Y, Z axes sample’s absolute value > this threshold, then the
corresponding outputs on these axes drive logic highs.
• If any of the X, Y, Z axes sample’s absolute value ≤ this threshold, then the
corresponding outputs on these axes drive logic lows.
Read register 00h in this stage to determine whether the sample data is ready to be read.
12.2 STANDBY mode
The device enters STANDBY mode automatically after the previously described function
(powers into SHUTDOWN mode, ACTIVE mode) is accomplished. The digital output
system outputs valid data, which can also be read via the I2C communication bus. This
is the appropriate phase to read the measured data, either from the three push-pull logic
outputs or through the I2C transaction. All other subsystems are turned off.
These outputs are held until the MMA8491Q operation mode changes. For lower power
consumption, deassert the EN pin as soon as data is read (to enter SHUTDOWN mode).
12.3 Next sample acquisition
The MMA8491Q needs to be brought back to the ACTIVE mode again by pulling EN pin
up to a Logic 1. Another option is to power down the device and start from OFF mode as
illustrated in Figure 7.
For applications where sampling intervals are greater than 30 seconds, the host can shut
off the tilt sensor power after acquisition of tilt sensor output data to conserve energy and
prolong battery life.
12.4 Power-up timing sequences
The power-up timing sequence for MMA84591Q is shown in the following figure, where
VDD is powered and the EN pin is activated to acquire a single sample. Additional
samples can be acquired by repeating the EN pulse.
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
OFF
Hi-Z
SHUTDOWN
ACTIVE
STANDBY
SHUTDOWN
V
DD
EN
Data
Available
Data
t
ON
Figure 8. MMA8491Q timing sequence
tON is the time between EN to the end of ACTIVE stage, after which the newly acquired
sample data is available.
12.5 45° tilt detection
The output value changes according to the absolute value of the acceleration of the
MMA8491Q compared to the threshold:
• When the acceleration’s absolute value > the threshold 0.688 g, the output = 1.
• When the acceleration’s absolute value ≤ the threshold, the output = 0.
For example,
• When the MMA8491Q is set on a table, it senses 1 g acceleration on Z-axis and
senses 0 g on X- and Y-axes.
• When the MMA8491Q is flipped upside down on the table, it senses –1 g acceleration
on Z-axis and senses 0 g on X- and Y-axes.
In both cases Xout = 0, Yout = 0, and Zout = 1.
12.6 Tilt angle
Tilt angles can be calculated from the g-value threshold using the equation below. The
tilt threshold is 0.688 g, which corresponds to 43.5°. Figure 9 illustrates the tilt angle
threshold.
g-value
1g
-------------------
Tilt Angle = asin
(
)
• When 0 g acceleration is present on an axis, the tilt angle = 0°; when 1 g acceleration
is present on an axis, the tilt angle = 90°.
• When the tilt angle > the tilt threshold, the output for the axis is HIGH; when the tilt
angle ≤ the tilt threshold, the output for the axis is LOW.
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Tilt Angle φ = 55°
Output = 1
Ø
Horizontal
Reference
Projected g-value =
Threshold (g-value) = 0.688g
Threshold= 0.688g
1g
Ø
Horizontal
Reference
Ø
Horizontal
Reference
0.688g
0.688g
1g
1g
Tilt Angle φ = 70°
Output = 1
Tilt Angle φ = 30°
Output = 0
Figure 9. MMA8491Q output is based on tilt angle and sensor g-value
MMA8491Q
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3-Axis Multifunction Digital Accelerometer
13 Register descriptions
Table 11. Register address map
Name
Type
Register
Address
Auto-
Reset
Comment
increment
Address[1]
STATUS
R
R
R
R
R
R
R
0x00
0x01
0x02
0x03
0x04
0x05
0x06
0x01
0x02
0x03
0x04
0x05
0x06
0x00
0x00
Read time status
OUT_X_MSB
OUT_X_LSB
OUT_Y_MSB
OUT_Y_LSB
OUT_Z_MSB
OUT_Z_LSB
Output
Output
Output
Output
Output
Output
[7:0] are the 8 MSBs of the 14-bit sample
[7:2] are the 6 LSBs of the 14-bit sample
[7:0] are the 8 MSBs of the 14-bit sample
[7:2] are the 6 LSBs of the 14-bit sample
[7:0] are the 8 MSBs of the 14-bit sample
[7:2] are the 6 LSBs of the 14-bit sample
[1] Auto-increment is the I2C feature that the I2C read address is automatically updated after each read. Auto-increment addresses that are not a simple
increment are highlighted in bold. The auto-increment addressing is only enabled when device registers are read using I2C burst read mode. Therefore
the internal storage of the auto-increment address is cleared whenever a stop-bit is detected.
Notes:
• Register contents are preserved when EN pin is set high after sampling.
• Register contents are reset when EN pin is set low.
13.1 STATUS - Status register (address 00h)
Register 0x00 reflects the real-time status information of the X, Y, and Z sample data.
The data read bits (ZYXDR, ZDR, YDR, XDR) are set when samples are taken and ready
to be read.
Table 12. STATUS - Status register (address 00h) bit allocation
Bit
7
6
5
4
3
2
ZDR
0
1
YDR
0
0
XDR
0
Symbol
Reset
—
ZYXDR
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
Table 13. STATUS - Status register (address 00h) field descriptions
Field
Description
3
X-, Y-, Z-axis new Data Ready (and available)
• ZYXDR signals that a new sample for all channels is available.
ZYXDR
• ZYXDR is cleared when the high-bytes of the acceleration data (OUT_X_MSB, OUT_Y_MSB,
OUT_Z_MSB) of all channels are read..
0: No new set of data ready (default value)
1: A new set of XYZ acceleration and temperature data is available
2
Z-axis new Data Ready (and available)
ZDR
• ZDR is set whenever a new acceleration sample related to the Z-axis is generated.
• ZDR is cleared anytime OUT_Z_MSB register is read.
0: No new Z-axis data is ready (default value)
1: A new Z-axis data is ready
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3-Axis Multifunction Digital Accelerometer
Field
Description
1
Y-axis new Data Ready (and available)
YDR
• YDR is set whenever a new acceleration sample related to the Y-axis is generated.
• YDR is cleared anytime OUT_Y_MSB register is read.
0: No new Y-axis data ready (default value)
1: A new Y-axis data is ready
0
X-axis new Data Ready (and available)
XDR
• XDR is set whenever a new acceleration sample related to the X-axis is generated.
• XDR is cleared anytime OUT_X_MSB register is read.
0: No new X-axis data ready (default value)
1: A new X-axis data is ready
13.2 Output data registers (addresses 01h to 06h)
These registers contain the X-axis, Y-axis, and Z-axis14-bit output sample data
(expressed as 2's complement numbers).
• OUT_X_MSB, OUT_X_LSB, OUT_Y_MSB, OUT_Y_LSB, OUT_Z_MSB, and
OUT_Z_LSB are stored in the autoincrementing address range of 0x01 – 0x06.
• The LSB registers can only be read immediately following the read access of the
corresponding MSB register. A random read access to the LSB registers is not
possible.
• Reading the MSB register and then the LSB register in sequence ensures that both
bytes (LSB and MSB) belong to the same data sample, even if a new data sample
arrives between reading the MSB and the LSB byte.
• The accelerometer data registers should be read only after the status register has
confirmed that new data on all axes is available.
Table 14. OUT_X_MSB - Output data register (address 01h) bit allocation
Bit
7
6
5
4
3
2
1
0
Symbol
Reset
XD[13:6]
0
0
0
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
Table 15. OUT_X_LSB - Output data register (address 02h) bit allocation
Bit
7
6
5
4
3
2
1
0
—
0
Symbol
Reset
XD[5:0]
—
0
0
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
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3-Axis Multifunction Digital Accelerometer
Table 16. OUT_Y_MSB - Output data register (address 03h) bit allocation
Bit
7
6
5
4
3
2
1
0
Symbol
Reset
YD[13:6]
0
0
0
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
Table 17. OUT_Y_LSB - Output data register (address 04h) bit allocation
Bit
7
6
5
4
3
2
1
—
0
0
—
0
Symbol
Reset
YD[13:6]
0
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
Table 18. OUT_Z_MSB - Output data register (address 05h) bit allocation
Bit
7
6
5
4
3
2
1
0
Symbol
Reset
OUT_Z[7:0]
0
0
0
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
Table 19. OUT_Z_LSB - Output data register (address 06h) bit allocation
Bit
7
6
5
4
3
2
1
—
0
0
—
0
Symbol
Reset
ZD[5:0]
0
0
0
0
0
0
Access
R
R
R
R
R
R
R
R
13.3 Accelerometer output conversion
Table 20. Accelerometer output data
14-bit Data
Range ±8 g (1 mg/count)
01 1111 1111 1111
01 1111 1111 1110
...
+8.000 g
+7.998 g
...
00 0000 0000 0000
11 1111 1111 1111
...
0.000 g
–0.001 g
...
10 0000 0000 0001
10 0000 0000 0000
–7.998 g
–8.000 g
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3-Axis Multifunction Digital Accelerometer
14 Mounting guidelines
Surface-mount printed circuit board (PCB) layout is a critical portion of the total design.
The footprint for the surface mount package must be the correct size to ensure proper
solder connection interface between the PCB and the package. With the correct
footprint, the package will self-align when subjected to a solder reflow process. The
purpose is to minimize the stress on the package after board mounting. The MMA8491Q
accelerometers use the QFN package. This section describes suggested methods of
soldering and mounting these devices to the PCB for consumer applications.
14.1 Overview of soldering considerations
The information provided here is based on experiments executed on QFN devices. They
do not represent exact conditions present at a customer site. Therefore, information
herein should be used as guidance only, and process and design optimizations are
recommended to develop an application specific solution. It should be noted that with
the proper PCB footprint and solder stencil designs, the package will self-align during the
solder reflow process.
14.2 Halogen content
This package is designed to be Halogen Free, exceeding most industry and customer
standards. Halogen Free means that no homogeneous material within the assembly
package shall contain chlorine (Cl) in excess of 700 ppm or 0.07% weight/weight or
bromine (Br) in excess of 900 ppm or 0.09% weight/weight.
14.3 PCB mounting recommendations
• Do not solder down the six exposed pads under the package, thus minimizing board-
mounting stress impact to product performance.
• PCB landing pad is 0.675 mm x 0.325 mm as shown in Figure 10.
• Solder mask opening = PCB land pad edge + 0.2 mm larger all around.
• Stencil opening size is 0.625 mm x 0.3 mm.
• Stencil thickness is 100 μm or 125 μm.
• The solder mask should not cover any of the PCB landing pads, as shown in Figure 10.
• No additional via nor metal pattern underneath package on the top of the PCB layer.
• Do not place any components or vias within 2 mm of the package land area. This may
cause additional package stress if it is too close to the package land area.
• Signal traces connected to pads should be as symmetric as possible. Put dummy
traces on NC pads, to have the same length of exposed trace for all pads.
• Use a standard pick-and-place process and equipment. Do not use a hand soldering
process.
• Customers are advised to be cautious about the proximity of screw-down holes to the
sensor, and the location of any press fit to the assembled PCB when in an enclosure.
It is important that the assembled PCB remain flat after assembly to keep electronic
operation of the device optimal.
• The PCB should be rated for the multiple lead-free reflow condition with a maximum
260 °C temperature.
• NXP sensors are compliant with Restrictions on Hazardous Substances (RoHS),
having halide-free molding compound (green) and lead-free terminations. These
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NXP Semiconductors
MMA8491Q
3-Axis Multifunction Digital Accelerometer
terminations are compatible with tin-lead (Sn-Pb) as well as tin-silver-copper (Sn-Ag-
Cu) solder paste soldering processes. Reflow profiles applicable to those processes
can be used successfully for soldering the devices.
Figure 10. PCB footprint guidelines
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
15 Package Information
The MMA8491Q uses a 12-lead QFN package, case number 98ASA00290D.
15.1 Tape and reel information
Figure 11. Tape dimensions
Pin 1
Direction
to unreel
Barcode label
side of reel
Figure 12. Tape and reel orientation
15.2 Package description
This drawing is available for download at http://www.nxp.com/files/shared/doc/
package_info/98ASA00290D.pdf. Please consult the most recently issued drawing before
initiating or completing a design.
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Figure 13. Case 2169-02, Issue X1, 12-Lead QFN—page 1
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Figure 14. Case 2169-02, Issue X1, 12-Lead QFN—page 2
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Figure 15. Case 2169-02, Issue X1, 12-Lead QFN—page 3
MMA8491Q
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3-Axis Multifunction Digital Accelerometer
16 Revision history
Revision Revision
Description
number
date
1.0
10/2012
11/2012
4/2016
• Initial release
2.0
• Characterization data verified to be complete and final
2.1
• Added MMA8491QR2 to Ordering information table
• Added paragraphs describing absolute maximum ratings
• Revised package dimensions drawings to the NXP format, no technical changes
• The format of this data sheet has been redesigned to comply with the new identity guidelines
of NXP Semiconductors
• Legal texts have been adapted to the new company name where appropriate
MMA8491Q
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3-Axis Multifunction Digital Accelerometer
17 Legal information
Data sheet status
Document status[1]
Product status[2] Definition
Data sheet: Product preview
Development
This document contains information on a product
under development. NXP reserves the right to change
or discontinue this product without notice.
Data sheet: Advance information Qualification
This document contains information on a pre-
production product. Specifications and pre-production
information herein are subject to change without
notice.
Data sheet: Technical data
Production
NXP reserves the right to change the production
detail specifications as may be required to permit
improvements in the design of its products.
[1] Please consult the most recently issued document before initiating or completing a design.
[2] The product status of device(s) described in this document may have changed since this document was published and
may differ in case of multiple devices. The latest product status information is available on the Internet at URL nxp.com.
Definitions
Disclaimers
Draft — The document is a draft version only. The
content is still under internal review and subject to formal
approval, which may result in modifications or additions.
NXP Semiconductors does not give any representations
or warranties as to the accuracy or completeness of
information included herein and shall have no liability for the
consequences of use of such information.
Information in this document is provided solely to enable
system and software implementers to use NXP products.
There are no express or implied copyright licenses granted
hereunder to design or fabricate any integrated circuits based
on the information in this document. NXP reserves the right to
make changes without further notice to any products herein.
NXP makes no warranty, representation, or guarantee
regarding the suitability of its products for any particular
purpose, nor does NXP assume any liability arising out
of the application or use of any product or circuit, and
specifically disclaims any and all liability, including without
limitation consequential or incidental damages. “Typical”
parameters that may be provided in NXP data sheets and/
or specifications can and do vary in different applications,
and actual performance may vary over time. All operating
parameters, including “typicals,” must be validated for each
customer application by customer's technical experts. NXP
does not convey any license under its patent rights nor the
rights of others. NXP sells products pursuant to standard
terms and conditions of sale, which can be found at the
following address: nxp.com/salestermsandconditions.
Trademarks
NXP, the NXP logo, Freescale, the Freescale logo and
SMARTMOS are trademarks of NXP B.V. All other product or
service names are the property of their respective owners.
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3-Axis Multifunction Digital Accelerometer
Tables
Tab. 1.
Tab. 2.
Tab. 3.
Tab. 4.
Tab. 5.
Tab. 6.
Tab. 7.
Tab. 8.
Tab. 9.
Ordering information ..........................................2
Tab. 14. OUT_X_MSB
-
Output data register
Pin descriptions .................................................3
Absolute maximum ratings ................................5
ESD and latch-up protection characteristics ......5
Accelerometer mechanical characteristics ........ 6
Electrical characteristics ....................................7
Serial interface pins .......................................... 8
I2C slave timing values .....................................8
I2C device address sequence .........................10
(address 01h) bit allocation .............................16
Tab. 15. OUT_X_LSB - Output data register (address
02h) bit allocation ............................................16
Tab. 16. OUT_Y_MSB
-
Output data register
(address 03h) bit allocation .............................17
Tab. 17. OUT_Y_LSB - Output data register (address
04h) bit allocation ............................................17
Tab. 18. OUT_Z_MSB
-
Output data register
Tab. 10. MMA8491Q operating modes ......................... 11
Tab. 11. Register address map .....................................15
Tab. 12. STATUS - Status register (address 00h) bit
allocation ......................................................... 15
(address 05h) bit allocation .............................17
Tab. 19. OUT_Z_LSB - Output data register (address
06h) bit allocation ............................................17
Tab. 20. Accelerometer output data .............................. 17
Tab. 13. STATUS - Status register (address 00h) field
descriptions ..................................................... 15
MMA8491Q
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MMA8491Q
3-Axis Multifunction Digital Accelerometer
Figures
Fig. 1.
Fig. 2.
Fig. 3.
Block Diagram ...................................................2
Fig. 9.
MMA8491Q output is based on tilt angle and
sensor g-value .................................................14
Pin connection diagram .....................................3
VDD connects to power supply and EN is
pulsed ................................................................4
Sensitive axes orientation and output
response to ±1 g (gravity) stimulus ................... 5
I2C slave timing diagram .................................. 9
I2C data sequence diagrams .......................... 11
MMA8491Q operating modes ......................... 11
MMA8491Q timing sequence ..........................13
Fig. 10. PCB footprint guidelines ..................................19
Fig. 11. Tape dimensions .............................................20
Fig. 12. Tape and reel orientation ................................20
Fig. 13. Case 2169-02, Issue X1, 12-Lead QFN—
page 1 ............................................................. 21
Fig. 14. Case 2169-02, Issue X1, 12-Lead QFN—
page 2 ............................................................. 22
Fig. 15. Case 2169-02, Issue X1, 12-Lead QFN—
page 3 ............................................................. 23
Fig. 4.
Fig. 5.
Fig. 6.
Fig. 7.
Fig. 8.
MMA8491Q
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3-Axis Multifunction Digital Accelerometer
Contents
1
General description ............................................ 1
2
3
4
5
6
7
8
9
Features and benefits .........................................1
Typical applications ............................................1
Ordering information .......................................... 2
Related documentation ...................................... 2
Block diagram ..................................................... 2
Pinout ................................................................... 2
Recommended application diagram ..................4
Sensing direction and output response ............4
Mechanical and electrical specifications .......... 5
Absolute maximum ratings ................................ 5
Mechanical characteristics .................................6
Electrical characteristics .................................... 7
I2C Interface ........................................................ 8
I2C read operations ...........................................9
Single-byte read .............................................. 10
Multiple-byte read ............................................ 10
I2C data sequence diagrams ...........................11
Modes of operation ...........................................11
ACTIVE mode ..................................................12
STANDBY mode ..............................................12
Next sample acquisition ...................................12
Power-up timing sequences ............................ 12
45° tilt detection ...............................................13
Tilt angle ..........................................................13
Register descriptions ....................................... 15
STATUS - Status register (address 00h) ......... 15
Output data registers (addresses 01h to 06h) .. 16
Accelerometer output conversion .................... 17
Mounting guidelines ......................................... 18
Overview of soldering considerations .............. 18
Halogen content .............................................. 18
PCB mounting recommendations .................... 18
Package Information .........................................20
Tape and reel information ............................... 20
Package description ........................................ 20
Revision history ................................................ 24
Legal information ..............................................25
10
10.1
10.2
10.3
11
11.1
11.1.1
11.1.2
11.1.3
12
12.1
12.2
12.3
12.4
12.5
12.6
13
13.1
13.2
13.3
14
14.1
14.2
14.3
15
15.1
15.2
16
17
© NXP B.V. 2016. All rights reserved
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: salesaddresses@nxp.com
Released on 26 April 2016
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