MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 1 / 44
© 2014 mCube Inc. All rights reserved.
GENERAL DESCRIPTION
The MC3236 is a low-noise, integrated
digital output 3-axis accelerometer with a
feature set optimized for cell phones and
consumer product motion sensing.
Applications include user interface control,
gaming motion input, electronic compass tilt
compensation for cell phones, game
controllers, remote controls and portable
media products.
Low noise and low power are inherent in
the monolithic fabrication approach, where
the MEMS accelerometer is integrated in a
single-chip with the electronics integrated
circuit.
In the MC3236 the internal sample rate can
be set from 0.125 to 128 samples / second.
The device supports the reading of sample
and event status via polling or interrupts.
FEATURES
Range, Sampling & Power
± 2g range
6,7, or 8-bit resolution
0.125 to 128 samples/sec
46 to 115 μA typical active current
Simple System Integration
I2C interface, up to 400 kHz
3 × 3 × 0.92 mm 10-pin package
o Pin-compatible to Freescale
MMA7660
Single-chip 3D silicon MEMS
<200µg / √Hz noise
MC3236 3-Axis Accelerometer Preliminary Datasheet
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TABLE OF CONTENTS
1 Order Information ............................................................................................................. 4
2 Functional Block Diagram ................................................................................................ 5
3 Packaging and Pin Description ........................................................................................ 6
3.1 Package Outline ................................................................................................................... 6
3.2 Package Orientation ............................................................................................................. 7
3.3 Pin Description ..................................................................................................................... 8
3.4 Typical Application Circuit .................................................................................................... 9
3.5 Tape and Reel ................................................................................................................... 10
4 Specifications ................................................................................................................. 12
4.1 Absolute Maximum Ratings ................................................................................................ 12
4.2 Sensor Characteristics ....................................................................................................... 13
4.3 Electrical and Timing Characteristics .................................................................................. 14
4.3.1 Electrical Power and Internal Characteristics ....................................................... 14
4.3.2 I2C Electrical Characteristics ............................................................................... 15
4.3.3 I2C Timing Characteristics ................................................................................... 16
5 General Operation ......................................................................................................... 17
5.1 Sensor Sampling ................................................................................................................ 17
5.2 Offset and Gain Calibration ................................................................................................ 18
6 Operational States ......................................................................................................... 19
7 Operational State Flow .................................................................................................. 20
8 Interrupts ........................................................................................................................ 21
8.1 Enabling and Clearing Interrupts ........................................................................................ 21
8.2 ACQ_INT Interrupt ............................................................................................................. 21
9 Sampling ........................................................................................................................ 22
9.1 Continuous Sampling ......................................................................................................... 22
10 I2C Interface .................................................................................................................. 23
10.1 Physical Interface ............................................................................................................... 23
10.2 Timing ................................................................................................................................ 24
10.3 I2C Message Format .......................................................................................................... 24
10.4 Watchdog Timer ................................................................................................................. 25
11 Register Interface .......................................................................................................... 26
11.1 Register Summary ............................................................................................................. 27
MC3236 3-Axis Accelerometer Preliminary Datasheet
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11.2 XOUT, YOUT & ZOUT X, Y & Z-Axis Accelerometer Registers .......................................... 28
11.3 SR Status Register ............................................................................................................. 29
11.4 OPSTAT Device Status Register ........................................................................................ 30
11.5 INTEN Interrupt Enable Register ........................................................................................ 31
11.6 MODE Register .................................................................................................................. 32
11.7 SRFR Sample Rate Register.............................................................................................. 33
11.8 OUTCFG Output Configuration Register ............................................................................ 34
11.9 X-Axis Offset Registers ...................................................................................................... 35
11.10 Y-Axis Offset Registers ...................................................................................................... 36
11.11 Z-Axis Offset Registers ...................................................................................................... 37
11.12 X-Axis Gain Registers ........................................................................................................ 38
11.13 Y-Axis Gain Registers ........................................................................................................ 39
11.14 Z-Axis Gain Registers ........................................................................................................ 40
11.15 PCODE Product Code........................................................................................................ 41
12 Index of Tables .............................................................................................................. 42
13 Revision History ............................................................................................................. 43
14 Legal .............................................................................................................................. 44
MC3236 3-Axis Accelerometer Preliminary Datasheet
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© 2014 mCube Inc. All rights reserved.
1 ORDER INFORMATION
Table 1. Order Information
Part Number
Resolution
Order Number
Package
Shipping
MC3236
8-bit
MC3236
LGA-10
Tape & Reel, 5Ku
MC3236 3-Axis Accelerometer Preliminary Datasheet
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2 FUNCTIONAL BLOCK DIAGRAM
A/D Converter
(Sigma Delta)
C to V
VPP
VDD/VDDIO
GND
Regulators
and Bias
Oscillator/
Clock
Generator Mode Logic
I2C Slave
Interface
Interrupt
X
Y
ZOTP
Memory
Registers
(64 x 8)
SCL
SDA
INTN
Offset/
Gain
Adjust
X,Y,Z
data paths
Sensors
Range &
Scale
en
Figure 1. Block Diagram
MC3236 3-Axis Accelerometer Preliminary Datasheet
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3 PACKAGING AND PIN DESCRIPTION
3.1 PACKAGE OUTLINE
b
BOTTOM VIEW
6 10
5 1
DIMENSION (MM)
SYMBOL MIN. NOM. MAX.
A 0.84 0.92 1.00
D 3.00 BSC
E 3.00 BSC
0.5 BSC
b 0.20 0.25 0.30
L 0.50 0.55 0.60
INDEX AREA
TOP VIEW
L
5 1
6 10
PIN 1 MARK
e
E
D
A
SIDE VIEW
METALIZED PAD
SEATING PLANE
DETAIL “A”
“A”
e
SECTION B-B
B B
b
METALIZED PAD
INSULATION
DO NOT
CONNECT
DO NOT
CONNECT
Figure 2. Package Outline and Mechanical Dimensions
MC3236 3-Axis Accelerometer Preliminary Datasheet
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3.2 PACKAGE ORIENTATION
Direction of
Earth gravity
acceleration
XOUT = +1g
YOUT = 0g
ZOUT = 0g
XOUT = -1g
YOUT = 0g
ZOUT = 0g
XOUT = 0g
YOUT = +1g
ZOUT = 0g
XOUT = 0g
YOUT = -1g
ZOUT = 0g
XOUT = 0g
YOUT = 0g
ZOUT = +1g
XOUT = 0g
YOUT = 0g
ZOUT = -1g
Top View
Side View
Pin 1
Top
a.
b. c.
d.
e.
f.
Figure 3. Package Orientation
+X
-X
-Y
+Y
+Z
-Z
Figure 4. Package Axis Reference
MC3236 3-Axis Accelerometer Preliminary Datasheet
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3.3 PIN DESCRIPTION
Pin
Name
Function
1
NC
No connect
2
NC
No connect
3
NC
No connect
4
VPP
Connect to GND
5
INTN 2
Interrupt input/output, active
LOW 3
6
SCL 1
I2C serial clock input
7
SDA 1
I2C serial data input/output
8
GND
Ground
9
VDD/VDDIO
Power supply
10
NC
No connect
Table 2. Pin Description
Notes:
1) This pin requires a pull-up resistor, typically 4.7kΩ to pin VDD/VDDIO. Refer to I2C
Specification for Fast-Mode devices. Higher resistance values can be used (typically
done to reduce current leakage) but such applications are outside the scope of this
datasheet.
2) This pin can be configured by software to operate either as an open-drain output or
push-pull output (MODE Register). If set to open-drain, then it requires a pull-up
resistor, typically 4.7kΩ to pin VDD/VDDIO.
3) INTN pin polarity is programmable in the MODE Register.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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3.4 TYPICAL APPLICATION CIRCUIT
To Fast-Mode I2C
circuitry1
(optional) To MCU
interrupt input2
0.1µF Place cap close
to VDD/VDDIO
and GND on PCB
}
NOTE1: Rp are typically 4.7 kΩ pull-up resistors to pin VDD/VDDIO, per I2C specification. When
pin VDD/VDDIO is powered down, SDA and SCL will be driven low by internal ESD diodes.
NOTE2: Attach typical 4.7 kΩ pull-up resistor if INTN is defined as open-drain.
NC
NC
NC
VPP
INTN
NC
VDD/VDDIO
GND
SDA
SCL
1
2
3
4
5
10
9
8
7
6
Rp Rp
Rp
(optional) Rp needed
on INTN only if set as
open-drain
Figure 5. Typical Application Circuit
In typical applications, the interface power supply may contain significant noise from external
sources and other circuits which should be kept away from the sensor. Therefore, for some
applications a lower-noise power supply might be desirable to power the VDD/VDDIO pin.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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3.5 TAPE AND REEL
Devices are shipped in reels, in standard cardboard box packaging. See Figure 6. MC3236
Tape Dimensions and Figure 7. MC3236 Reel Dimensions.
Dimensions in mm.
10 sprocket hole pitch cumulative tolerance ±0.2
Pocket position relative to sprocket hole measured as true position of pocket, not pocket
hole.
Ao and Bo measured on a plane 0.3mm above the bottom of the pocket.
Ko measured from a plane on the inside bottom of the pocket to the top surface of the
carrier.
Figure 6. MC3236 Tape Dimensions
MC3236 3-Axis Accelerometer Preliminary Datasheet
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Dimensions in mm.
Figure 7. MC3236 Reel Dimensions
MC3236 3-Axis Accelerometer Preliminary Datasheet
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4 SPECIFICATIONS
4.1 ABSOLUTE MAXIMUM RATINGS
Parameters exceeding the Absolute Maximum Ratings may permanently damage the device.
Rating
Symbol
Minimum / Maximum
Value
Unit
Supply Voltages
Pin
VDD/VDDIO
-0.3 / +3.6
V
Acceleration, any axis, 100 µs
g MAX
10000
g
Ambient operating temperature
TOP
-40 / +85
⁰C
Storage temperature
TSTG
-40 / +125
⁰C
ESD human body model
HBM
± 2000
V
Latch-up current at Top = 25 ⁰C
ILU
200
mA
Input voltage to non-power pin
Pins INTN, SCL
and SDA
-0.3 / (VDD + 0.3) or 3.6
whichever is lower
V
Table 3. Absolute Maximum Ratings
MC3236 3-Axis Accelerometer Preliminary Datasheet
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4.2 SENSOR CHARACTERISTICS
VDD = 2.8V, Top = 25 ⁰C unless otherwise noted
Parameter
Conditions
Min
Typ
Max
Unit
Acceleration range
±2.0
g
Sensitivity
64
LSB/g
Sensitivity Temperature
Coefficient 1
-10 ≤ Top ≤ +55 ⁰C
± 0.025
%/⁰C
Zero-g Offset
± 80
mg
Zero-g Offset
Temperature Coefficient 1
-10 ≤ Top ≤ +55 ⁰C
± 1
mg/⁰C
Noise Density 1
X,Y: 125
Z: 200
μg/√Hz
Nonlinearity 1
2
% FS
Cross-axis Sensitivity 1
Between any two axes
2
%
Table 4. Sensor Characteristics
1
Values are based on device characterization, not tested in production.
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4.3 ELECTRICAL AND TIMING CHARACTERISTICS
4.3.1 ELECTRICAL POWER AND INTERNAL CHARACTERISTICS
Parameter
Conditions
Symbol
Min
Typ
Max
Unit
Supply voltage 2
Pin VDD/VDDIO
VDD
1.7
3.6
V
Sample Rate Tolerance 3
Tclock
-10
10
%
Test condition: VDD = 2.8V, Top = 25 ⁰C unless otherwise noted
Parameter
Conditions
Symbol
Min
Typ
Max
Unit
Standby current
I ddsb
4
μA
WAKE state supply
current
(highly dependent on sample
rate)
I ddw0.125
I ddw128
46
115
μA
Pad Leakage
Per I/O pad
I pad
-1
0.01
1
μA
Table 5. Electrical Characteristics
2
Min and Max limits are hard limits without additional tolerance.
3
Values are based on device characterization, not tested in production.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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4.3.2 I2C ELECTRICAL CHARACTERISTICS
Parameter
Symbol
Min
Max
Unit
LOW level input voltage
VIL
-0.5
0.3*VDD
V
HIGH level input voltage
VIH
0.7*VDD
-
V
Hysteresis of Schmitt trigger inputs
Vhys
0.05*VDD
-
V
Output voltage, pin INTN, Iol ≤ 2 mA
Vol
Voh
0
0
0.4
0.9*VDD
V
V
Output voltage, pin SDA (open drain),
Iol ≤ 1 mA
Vols
-
0.1*VDD
V
Input current, pins SDA and SCL (input voltage
between 0.1*VDD and 0.9*VDD max)
Ii
-10
10
µA
Capacitance, pins SDA and SCL 4
Ci
-
10
pF
Table 6. I2C Electrical and Timing Characteristics
NOTES:
If multiple slaves are connected to the I2C signals in addition to this device, only 1 pull-
up resistor on each of SDA and SCL should exist. Also, care must be taken to not
violate the I2C specification for capacitive loading.
When pin VDD/VDDIO is not powered and set to 0V, INTN, SDA and SCL will be held
to pin VDD/VDDIO plus the forward voltage of the internal static protection diodes,
typically about 0.6V.
When pin VDD/VDDIO is disconnected from power or ground (e.g. Hi-Z), the device
may become inadvertently powered up through the ESD diodes present on other
powered signals.
4
Values are based on device characterization, not tested in production.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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4.3.3 I2C TIMING CHARACTERISTICS
Figure 8. I2C Interface Timing
Parameter
Description
Standard
Mode
Fast Mode
Units
Min
Max
Min
Max
fSCL
SCL clock frequency
0
100
0
400
kHz
tHD; STA
Hold time (repeated) START condition
4.0
-
0.6
-
μs
tLOW
LOW period of the SCL clock
4.7
-
1.3
-
μs
tHIGH
HIGH period of the SCL clock
4.0
-
0.6
-
μs
tSU;STA
Set-up time for a repeated START
condition
4.7
-
0.6
-
μs
tHD;DAT
Data hold time
5.0
-
-
-
μs
tSU;DAT
Data set-up time
250
-
100
-
ns
tSU;STO
Set-up time for STOP condition
4.0
-
0.6
-
μs
tBUF
Bus free time between a STOP and
START
4.7
-
1.3
-
μs
Table 7. I2C Timing Characteristics
NOTE: Values are based on I2C Specification requirements, not tested in production.
See also Section 10.3 I2C Message Format.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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5 GENERAL OPERATION
The device supports the reading of samples and device status upon interrupt or via polling.
5.1 SENSOR SAMPLING
In the WAKE state, acceleration data for X, Y, and Z axes is sampled at a rate between 0.125
and 128 samples/second. See Section11.7 SRFR Sample Rate Register.
The detectable acceleration range is from -2g to +2g.
Resolution
Acceleration
Range
Value per
bit
(mg/LSB)
Full Scale
Negative
Reading
Full Scale
Positive
Reading
Comments
8-bit
± 2g
~15.6
0x80
(-128)
0x7F
(+127)
Signed 2’s
complement number,
results in XOUT,
YOUT, ZOUT. The
MSB is the sign bit.
(Integer interpretation
also shown)
Table 8. Summary of Resolution, Range, and Scaling
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5.2 OFFSET AND GAIN CALIBRATION
Digital offset and gain calibration can be performed on the sensor, if necessary, in order to
reduce the effects of post-assembly influences and stresses which may cause the sensor
readings to be offset from their factory values.
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6 OPERATIONAL STATES
The device has two states of operation: STANDBY (the default state after power-up), and
WAKE.
The STANDBY state offers the lowest power consumption. In this state, the I2C interface is
active and all register reads and writes are allowed. There is no event detection, sampling, or
acceleration measurement in the STANDBY state. Internal clocking is halted. Complete access
to the register set is allowed in this state, but interrupts cannot be serviced. The device
defaults to the STANDBY state following power-up. The time to change states from STANDBY
to WAKE is less than 10uSec.
Registers can be written (and therefore resolution, range. thresholds and other settings
changed) only when the device is in STANDBY state.
The I2C interface allows write access to all registers only in the STANDBY state. In WAKE
state, the only I2C register write access permitted is to the MODE Register. Full read access is
allowed in all states.
State
I2C Bus
Description
STANDBY
Device responds to
I2C bus (R/W)
Device is powered; Registers can be accessed via I2C. Lowest
power state. No interrupt generation, internal clocking disabled.
Default power-on state.
WAKE
Device responds to
I2C bus (Read)
Continuous sampling and reading of sense data. All registers except
the MODE Register are read-only.
Table 9. Operational States
MC3236 3-Axis Accelerometer Preliminary Datasheet
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7 OPERATIONAL STATE FLOW
Figure 9. Operational State Flow shows the operational state flow for the device. The device
defaults to STANDBY following power-on.
WAKE
STANDBY
OPCON=00 OPCON=01
Figure 9. Operational State Flow
The operational state may be forced to a specific state by writing into the OPCON bits, as
shown below. Two bits are specified in order to promote software compatibility with other
mCube devices. The operational state will stay in the mode specified until changed:
Action
Setting
Effect
Force Wake State
OPCON[1:0] = 01
Switch to WAKE state and stay there
Continuous sampling
Force Standby State
OPCON[1:0] = 00
Switch to STANDBY state and stay
there
Disable sensor and event sampling
Table 10. Forcing Operational States
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8 INTERRUPTS
The sensor device utilizes output pin INTN to signal to an external microprocessor that an
event has been sensed. The microprocessor would contain an interrupt service routine which
would perform certain tasks after receiving this interrupt and reading the associated status bits,
perhaps after a sample was made ready. If interrupts are to be used, the microprocessor must
set up the registers in the sensor so that when a specific event is detected, the microprocessor
would receive the interrupt and the interrupt service routine would be executed. If polling is
used there is no need for the interrupt registers to be set up.
For products that will instead use polling, the method of reading sensor data would be slightly
different. Instead of receiving an interrupt when an event occurs, the microprocessor must
periodically poll the sensor and read status data (the INTN pin is not used). For most
applications, this is likely best done at the sensor sampling rate or faster.
Note that at least one I2C STOP condition must be present between samples in order for
the sensor to update the sample data registers.
8.1 ENABLING AND CLEARING INTERRUPTS
The SR Status Register contains the flag bits for the sample acquisition interrupt ACQ_INT.
The INTEN Interrupt Enable Register determines if a flag event generates interrupts.
The flags (and interrupts) are cleared and rearmed each time the SR Status Register is read.
When an event is detected, it is masked with a flag bit in the INTEN Interrupt Enable Register,
and then the corresponding status bit is set in the SR Status Register.
The polarity and driving mode of the external interrupt signal may be chosen by setting the IPP
and IAH bits in the MODE Register.
8.2 ACQ_INT INTERRUPT
The ACQ_INT flag bit in the SR Status Register is always active. This bit is cleared when it is
read. When a sample has been produced, an interrupt will be generated only if the
ACQ_INT_EN bit in the INTEN Interrupt Enable Register is active. Note that the frequency of
this ACQ_INT bit being set active is always the same as the sample rate.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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9 SAMPLING
9.1 CONTINUOUS SAMPLING
The device has the ability to read all sampled readings in a continuous sampling fashion. The
device always updates the XOUT, YOUT, and ZOUT registers at the chosen ODR.
An optional interrupt can be generated each time the sample registers have been updated
(ACQ_INT interrupt bit in the INTEN Interrupt Enable Register). See Sections 8.2 and SR
Status Register for ACQ_INT operation and options.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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10 I2C INTERFACE
10.1 PHYSICAL INTERFACE
The I2C slave interface operates at a maximum speed of 400 kHz. The SDA (data) is an open-
drain, bi-directional pin and the SCL (clock) is an input pin.
The device always operates as an I2C slave.
An I2C master initiates all communication and data transfers and generates the SCL clock that
synchronizes the data transfer. The I2C device address depends upon the state of the VPP pin
during power-up as shown in the table below.
An optional I2C watchdog timer reset can be enabled to prevent bus stall conditions. When
enabled, the sensor I2C circuitry will reset itself if the master takes too long to issue clocks to
the sensor during a read cycle (i.e. if there is a gap in SCL clocks of more than about
200mSec). A status bit can be read to observe if this condition has occurred.
7-bit Device
ID
8-bit Address
– Write
8-bit Address
– Read
VPP level upon
power-up
0x4C
(0b1001100)
0x98
0x99
GND
0x6C
(0b1101100)
0xD8
0xD9
VDD
Table 11. I2C Address Selection
The I2C interface remains active as long as power is applied to the VDD/VDDIO pin. In
STANDBY state the device responds to I2C read and write cycles, but interrupts cannot be
serviced or cleared. All registers can be written in the STANDBY state, but in WAKE only the
MODE Register can be modified.
Internally, the registers which are used to store samples are clocked by the sample clock gated
by I2C activity. Therefore, in order to allow the device to collect and present samples in the
sample registers at least one I2C STOP condition must be present between samples.
Refer to the I2C specification for a detailed discussion of the protocol. Per I2C requirements,
SDA is an open drain, bi-directional pin. SCL and SDA each require an external pull-up
resistor, typically 4.7kΩ.
MC3236 3-Axis Accelerometer Preliminary Datasheet
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To Fast-Mode I2C
circuitry1
(optional) To MCU
interrupt input2
0.1µF Place cap close
to VDD/VDDIO
and GND on PCB
}
NOTE1: Rp are typically 4.7 kΩ pull-up resistors to pin VDD/VDDIO, per I2C specification. When
pin VDD/VDDIO is powered down, SDA and SCL will be driven low by internal ESD diodes.
NOTE2: Attach typical 4.7 kΩ pull-up resistor if INTN is defined as open-drain.
NC
NC
NC
VPP
INTN
NC
VDD/VDDIO
GND
SDA
SCL
1
2
3
4
5
10
9
8
7
6
Rp Rp
Rp
(optional) Rp needed
on INTN only if set as
open-drain
Figure 10. Typical Application Circuit
10.2 TIMING
See Section 4.3.3 I2C Timing Characteristics for I2C timing requirements.
10.3 I2C MESSAGE FORMAT
Note that at least one I2C STOP condition must be present between samples in order for
the sensor to update the sample data registers.
The device uses the following general format for writing to the internal registers. The I2C
master generates a START condition, and then supplies the 7-bit device ID. The 8th bit is the
R/W# flag (write cycle = 0). The device pulls SDA low during the 9th clock cycle indicating a
positive ACK.
The second byte is the 8-bit register address of the device to access, and the last byte is the
data to write.
1 1 0 1 01 1 0
ACK
R7 R6 R5 R4 R1R3 R2 R0 D7 D6 D5 D4 D1D4 D2 D0 PS
ACK ACK
START Device ID R/W#
ACK/NAK
Register Address Register Data to Write Stop
ACK/NAK ACK/NAK
I2C Master
(To Sensor)
I2C Slave
(From Sensor)
Figure 11. I2C Message Format, Write Cycle, Single Register Write
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In a read cycle, the I2C master writes the device ID (R/W#=0) and register address to be read.
The master issues a RESTART condition and then writes the device ID with the R/W# flag set
to ‘1’. The device shifts out the contents of the register address.
1 1 0 1 01 1 0
ACK
R7 R6 R5 R4 R1R3 R2 R0 RS
ACK
I2C Master
(To Sensor)
I2C Slave
(from Sensor)
START Device ID R/W#
ACK/NAK
Register Address Restart
ACK/NAK
D7 D6 D5 D4 D1D3 D2 D0
NAK
Read Data Byte
NAK
1 1 0 1 01 1 1
ACK
Device ID R/W#
ACK/NAK
P
STOP
Figure 12. I2C Message Format, Read Cycle, Single Register Read
The I2C master may write or read consecutive register addresses by writing or reading
additional bytes after the first access. The device will internally increment the register address.
If an I2C burst read operation reads past register address 0x12 the internal address
pointer “wraps” to address 0x03 and the contents of the SR Status Register are
returned.
10.4 WATCHDOG TIMER
When enabled (see MODE Register), the I2C watchdog timer prevents bus stall conditions in
cases where the master does not provide enough clocks to the slave to complete a read cycle.
During a read cycle, the slave that is actively driving the bus (SDA pin) will not release the bus
until 9 SCL clock edges are detected. While the SDA pin is held low by a slave open-drain
output, any other I2C devices attached to the sample bus will be unable to communicate. If the
slave does not see 9 SCL clocks from the master within the timeout period, the slave will
assume a system problem has occurred and so the I2C circuitry will be reset, the SDA pin
released and the sensor made ready for additional I2C commands.
No other changes to registers are made.
When enabled, the I2C watchdog timer does not resolve why the master did not provide
enough clocks to complete a read cycle, but it does prevent a slave from holding the bus
indefinitely.
When enabled, the timeout period is about 200mSec.
When an I2C watchdog timer event is triggered, the I2C_WDT bit in register will be set active
by the Watchdog timer hardware. External software can detect this status by noticing this bit is
active. The act of reading register 0x04 will clears the status.
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 26 / 44
© 2014 mCube Inc. All rights reserved.
11 REGISTER INTERFACE
The device has a simple register interface which allows a MCU or I2C master to configure and
monitor all aspects of the device. This section lists an overview of user programmable
registers. By convention, Bit 0 is the least significant bit (LSB) of a byte register.
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 27 / 44
© 2014 mCube Inc. All rights reserved.
11.1 REGISTER SUMMARY
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W5
0x00
XOUT
XOUT Accelerometer
Register
XOUT[7]
XOUT[6]
XOUT[5]
XOUT[4]
XOUT[3]
XOUT[2]
XOUT[1]
XOUT[0]
0x00
W
0x01
YOUT
YOUT Accelerometer
Register
YOUT[7]
YOUT[6]
YOUT[5]
YOUT[4]
YOUT[3]
YOUT[2]
YOUT[1]
YOUT[0]
0x00
W
0x02
ZOUT
ZOUT Accelerometer
Register
ZOUT[7]
ZOUT[6]
ZOUT[5]
ZOUT[4]
ZOUT[3]
ZOUT[2]
ZOUT[1]
ZOUT[0]
0x00
W
0x03
SR
Status Register
ACQ_INT
Resv
Resv
Resv
Resv
Resv
Resv
Resv
0x00
R
0x04
OPSTAT
Operational Device
Status Register
OTPA
Resv
Resv
I2C_WDT
Resv
Resv
OPSTAT
[1]
OPSTAT
[0]
0x00
R
0x05
RESERVED
0x06
INTEN
Interrupt Enable
Register
ACQ_INT_
EN
Resv
Resv
Resv
Resv
Resv
Resv
Resv
0x00
W
0x07
MODE
Mode Register
IAH
IPP
I2C_WDT
_POS
I2C_WDT_
NEG
Resv
06
OPCON
[1]
OPCON
[0]
0x00
W
0x08
SRFR
Sample Rate Register
Resv
Resv
Resv
Resv
RATE[3]
RATE[2]
RATE[2]
RATE[0]
0x00
W
0x09-0x1F
RESERVED
0x20
OUTCFG
Output
Configuration
Register
06
Resv
Resv
Resv
Resv
Resv
RES[1]
RES[0]
0x00
W
0x21
XOFFL
X-Offset
LSB Register
XOFF[7]
XOFF[6]
XOFF[5]
XOFF[4]
XOFF[3]
XOFF[2]
XOFF[1]
XOFF[0]
Per chip
W
0x22
XOFFH
X-Offset
MSB Register
XGAIN[8]
XOFF[14]
XOFF[13]
XOFF[12]
XOFF[11]
XOFF[10]
XOFF[9]
XOFF[8]
Per chip
W
0x23
YOFFL
Y-Offset
LSB Register
YOFF[7]
YOFF[6]
YOFF[5]
YOFF[4]
YOFF[3]
YOFF[2]
YOFF[1]
YOFF[0]
Per chip
W
0x24
YOFFH
Y-Offset
MSB Register
YGAIN[8]
YOFF[14]
YOFF[13]
YOFF[12]
YOFF[11]
YOFF[10]
YOFF[9]
YOFF[8]
Per chip
W
0x25
ZOFFL
Z-Offset
LSB Register
ZOFF[7]
ZOFF[6]
ZOFF[5]
ZOFF[4]
ZOFF[3]
ZOFF[2]
ZOFF[1]
ZOFF[0]
Per chip
W
0x26
ZOFFH
Z-Offset
MSB Register
ZGAIN[8]
ZOFF[14]
ZOFF[13]
ZOFF[12]
ZOFF[11]
ZOFF[10]
ZOFF[9]
ZOFF[8]
Per chip
W
0x27
XGAIN
X Gain Register
XGAIN[7]
XGAIN[6]
XGAIN[5]
XGAIN[4]
XGAIN[3]
XGAIN[2]
XGAIN[1]
XGAIN[0]
Per chip
W
0x28
YGAIN
Y Gain Register
YGAIN[7]
YGAIN[6]
YGAIN[5]
YGAIN[4]
YGAIN[3]
YGAIN[2]
YGAIN[1]
YGAIN[0]
Per chip
W
0x29
ZGAIN
Z Gain Register
ZGAIN[7]
ZGAIN[6]
ZGAIN[5]
ZGAIN[4]
ZGAIN[3]
ZGAIN[2]
ZGAIN[1]
ZGAIN[0]
Per chip
W
0x2A-0x3A
RESERVED
0x3B
PCODE
Product Code
Register
0
1
1
0
*7
*7
*7
0
NOTE
R
0x3C to 0x3F
RESERVED
Table 12. Register Summary
8
5
‘R’ registers are read-only, via external I2C access. ‘W’ registers are read-write, via external I2C access.
6
Software must always write a zero ‘0’ to this bit.
7
Bits denoted with ‘*’ might be any value, set by the factory. Software should ignore these bits.
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 28 / 44
© 2014 mCube Inc. All rights reserved.
11.2 XOUT, YOUT & ZOUT X, Y & Z-AXIS ACCELEROMETER REGISTERS
Accelerometer measurements are stored in the XOUT, YOUT, and ZOUT registers. The
measurements are in signed 2’s complement format. The range is always ± 2g. XOUT[7],
YOUT[7] and ZOUT[7] are the sign bits for their registers.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/W
0x00
XOUT
XOUT
Accelerometer
Register
XOUT
[7]
XOUT
[6]
XOUT
[5]
XOUT
[4]
XOUT
[3]
XOUT
[2]
XOUT
[1]
XOUT
[0]
0x00
R
0x01
YOUT
YOUT
Accelerometer
Register
YOUT
[7]
YOUT
[6]
YOUT
[5]
YOUT
[4]
YOUT
[3]
YOUT
[2]
YOUT
[1]
YOUT
[0]
0x00
R
0x02
ZOUT
ZOUT
Accelerometer
Register
ZOUT
[7]
ZOUT
[6]
ZOUT
[5]
ZOUT
[4]
ZOUT
[3]
ZOUT
[2]
ZOUT
[1]
ZOUT
[0]
0x00
R
Table 13. Accelerometer Value Registers
8
No registers are updated with new event status or samples while a I2C cycle is in process.
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 29 / 44
© 2014 mCube Inc. All rights reserved.
11.3 SR STATUS REGISTER
This register contains the flag/event bit for sample acquisition.
The flag (and interrupt) is cleared and rearmed each time this register is read.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x03
SR
Status Register
ACQ_INT
Resv
Resv
Resv
Resv
Resv
Resv
Resv
0x00
R
ACQ_INT
0: No sample has been generated by the sensor since last read.
1: Sample has been acquired, flag bit is set in polling mode or interrupt mode. This bit
cannot be disabled and is always set be hardware when a sample is ready. The host
must poll at the sample rate or faster to see this bit transition.
Table 14. SR Status Register
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 30 / 44
© 2014 mCube Inc. All rights reserved.
11.4 OPSTAT DEVICE STATUS REGISTER
The device status register reports various conditions of the sensor circuitry.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x04
OPSTAT
Operational
Device Status
Register
OTPA
Resv
Resv
I2C_WDT
Resv
Resv
OPSTAT
[1]
OPSTAT
[0]
0x00
R
OPSTAT[1:0]
Sampling State Register Status, Wait State Register Status
00: Device is in STANDBY state, no sampling
01: Device is in WAKE state, sampling at set sample rate
10: Reserved
11: Reserved
I2C_WDT
I2C watchdog timeout
0: No watchdog event detected
1: Watchdog event has been detected by hardware, I2C slave state
machine reset to idle. This flag is cleared by reading this register.
OTPA
One-time Programming (OTP) activity status
0: Internal memory is idle and the device is ready for use
1: Internal memory is active and the device is not yet ready for use
Table 15. OPSTAT Device Status Register
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 31 / 44
© 2014 mCube Inc. All rights reserved.
11.5 INTEN INTERRUPT ENABLE REGISTER
The interrupt enable register allows the flag bits for sample events to also trigger a transition of
the external INTN pin. This is the only effect these bits have as the flag bits will be set/cleared
in the SR Status Register regardless of which interrupts are enabled in this register.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x06
INTEN
Interrupt Enable
Register
ACQ_INT_
EN
Resv
Resv
Resv
Resv
Resv
Resv
Resv
0x00
W
ACQ_INT_EN
Generate Interrupt
0: Disable automatic interrupt on INTN pad after each sample (default).
1: Enable automatic interrupt on INTN pad after each sample.
Table 16. INTEN Interrupt Enable Register Settings
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 32 / 44
© 2014 mCube Inc. All rights reserved.
11.6 MODE REGISTER
The MODE register controls the active operating state of the device. This register can be
written from either operational state (STANDBY or WAKE).
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x07
MODE
Mode Register
IAH
IPP
I2C_WDT_
POS
I2C_WDT_
NEG
Resv
0*
OPCON
[1]
OPCON
[0]
0x00
W
NOTE*: Software must always write a zero ‘0’ to Bit 2.
OPCON
[1:0]
00: STANDBY state (default)
Set Device Operational State.
WAKE or STANDBY
01: WAKE state
10: Reserved
11: Reserved
I2C_WDT_NEG
0: I2C watchdog timer for negative SCL
stalls disabled (default)
1: I2C watchdog timer for negative SCL
stalls enabled
WDT for negative SCL stalls
I2C_WDT_POS
0: I2C watchdog timer for positive SCL
stalls disabled (default)
1: I2C watchdog timer for positive SCL
stalls enabled
WDT for positive SCL stalls
IPP
0: Interrupt pin INTN is open drain (default)
and requires an external pull-up to pin
VDD/VDDIO.
Interrupt Push Pull
1: Interrupt pin INTN is push-pull. No
external pull-up resistor should be
installed.
IAH
0: Interrupt pin INTN is active low (default)
Interrupt Active High
1: Interrupt pin INTN is active high
Table 17. MODE Register Functionality
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 33 / 44
© 2014 mCube Inc. All rights reserved.
11.7 SRFR SAMPLE RATE REGISTER
This register sets the sampling output data rate (ODR) for sensor. The lower 4 bits control the
rate, as shown in the table below.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x08
SRFR
Sample Rate Register
Resv
Resv
Resv
Resv
RATE[3]
RATE[2]
RATE[1]
RATE[0]
0x00
W
RATE[3:0]
0000: 16 Hz (default)
0001: 8 Hz
0010: 4 Hz
0011: 2 Hz
0100: 1 Hz
0101: 0.5 Hz
0110: 0.25 Hz
0111: 0.125 Hz
1000: 32 Hz
1001: 64 Hz
1010: 128 Hz
1011: Reserved
1100: Reserved
1101: Reserved
1110: Reserved
1111: Reserved
Table 18. SRFR Register Functionality
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 34 / 44
© 2014 mCube Inc. All rights reserved.
11.8 OUTCFG OUTPUT CONFIGURATION REGISTER
This register can be used to set the resolution of the accelerometer measurements.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x20
OUTCFG
Output
Configuration
Register
0*
Resv
Resv
Resv
Resv
Resv
RES[1]
RES[0]
0x00
W
NOTE*: Software must always write a zero ‘0’ to Bit 7.
RES[1:0]
Accelerometer g Resolution
00: Select 6-bit resolution (Default)
01: Select 7-bit resolution
10: Select 8-bit resolution
11: Reserved
Table 19. OUTCFG Resolution Register Settings
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 35 / 44
© 2014 mCube Inc. All rights reserved.
11.9 X-AXIS OFFSET REGISTERS
This register contains a signed 2’s complement 15-bit value applied as an offset adjustment to
the output of the sensor values, prior to being sent to the OUT registers. The Power-On-Reset
value for each chip is unique and is set as part of factory calibration. If necessary, this value
can be overwritten by software.
NOTE: When modifying these registers with new gain or offset values, software should
perform a read-modify-write type of access to ensure that unrelated bits do not get
changed inadvertently.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x21
XOFFL
X-Offset
LSB Register
XOFF[7]
XOFF[6]
XOFF[5]
XOFF[4]
XOFF[3]
XOFF[2]
XOFF[1]
XOFF[0]
Per chip
W
0x22
XOFFH
X-Offset
MSB Register
XGAIN[8]
XOFF[14]
XOFF[13]
XOFF[12]
XOFF[11]
XOFF[10]
XOFF[9]
XOFF[8]
Per chip
W
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 36 / 44
© 2014 mCube Inc. All rights reserved.
11.10 Y-AXIS OFFSET REGISTERS
This register contains a signed 2’s complement 15-bit value applied as an offset adjustment to
the output of the sensor values, prior to being sent to the OUT registers. The Power-On-Reset
value for each chip is unique and is set as part of factory calibration. If necessary, this value
can be overwritten by software.
NOTE: When modifying these registers with new gain or offset values, software should
perform a read-modify-write type of access to ensure that unrelated bits do not get
changed inadvertently.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x23
YOFFL
Y-Offset
LSB Register
YOFF[7]
YOFF[6]
YOFF[5]
YOFF[4]
YOFF[3]
YOFF[2]
YOFF[1]
YOFF[0]
Per chip
W
0x24
YOFFH
Y-Offset
MSB Register
YGAIN[8]
YOFF[14]
YOFF[13]
YOFF[12]
YOFF[11]
YOFF[10]
YOFF[9]
YOFF[8]
Per chip
W
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 37 / 44
© 2014 mCube Inc. All rights reserved.
11.11 Z-AXIS OFFSET REGISTERS
This register contains a signed 2’s complement 15-bit value applied as an offset adjustment to
the output of the sensor values, prior to being sent to the OUT registers. The Power-On-Reset
value for each chip is unique and is set as part of factory calibration. If necessary, this value
can be overwritten by software.
NOTE: When modifying these registers with new gain or offset values, software should
perform a read-modify-write type of access to ensure that unrelated bits do not get
changed inadvertently.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x25
ZOFFL
Z-Offset
LSB Register
ZOFF[7]
ZOFF[6]
ZOFF[5]
ZOFF[4]
ZOFF[3]
ZOFF[2]
ZOFF[1]
ZOFF[0]
Per chip
W
0x26
ZOFFH
Z-Offset
MSB Register
ZGAIN[8]
ZOFF[14]
ZOFF[13]
ZOFF[12]
ZOFF[11]
ZOFF[10]
ZOFF[9]
ZOFF[8]
Per chip
W
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 38 / 44
© 2014 mCube Inc. All rights reserved.
11.12 X-AXIS GAIN REGISTERS
The gain value is an unsigned 9-bit number.
NOTE: When modifying these registers with new gain or offset values, software should
perform a read-modify-write type of access to ensure that unrelated bits do not get
changed inadvertently.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x22
XOFFH
X-Offset
MSB Register
XGAIN[8]
XOFF[14]
XOFF[13]
XOFF[12]
XOFF[11]
XOFF[10]
XOFF[9]
XOFF[8]
Per chip
W
0x27
XGAIN
X Gain Register
XGAIN[7]
XGAIN[6]
XGAIN[5]
XGAIN[4]
XGAIN[3]
XGAIN[2]
XGAIN[1]
XGAIN[0]
Per chip
W
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 39 / 44
© 2014 mCube Inc. All rights reserved.
11.13 Y-AXIS GAIN REGISTERS
The gain value is an unsigned 9-bit number.
NOTE: When modifying these registers with new gain or offset values, software should
perform a read-modify-write type of access to ensure that unrelated bits do not get
changed inadvertently.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x24
YOFFH
Y-Offset
MSB Register
YGAIN[8]
YOFF[14]
YOFF[13]
YOFF[12]
YOFF[11]
YOFF[10]
YOFF[9]
YOFF[8]
Per chip
W
0x28
YGAIN
Y Gain Register
YGAIN[7]
YGAIN[6]
YGAIN[5]
YGAIN[4]
YGAIN[3]
YGAIN[2]
YGAIN[1]
YGAIN[0]
Per chip
W
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 40 / 44
© 2014 mCube Inc. All rights reserved.
11.14 Z-AXIS GAIN REGISTERS
The gain value is an unsigned 9-bit number.
NOTE: When modifying these registers with new gain or offset values, software should
perform a read-modify-write type of access to ensure that unrelated bits do not get
changed inadvertently.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x26
ZOFFH
Z-Offset
MSB Register
ZGAIN[8]
ZOFF[14]
ZOFF[13]
ZOFF[12]
ZOFF[11]
ZOFF[10]
ZOFF[9]
ZOFF[8]
Per chip
W
0x29
ZGAIN
Z Gain Register
ZGAIN[7]
ZGAIN[6]
ZGAIN[5]
ZGAIN[4]
ZGAIN[3]
ZGAIN[2]
ZGAIN[1]
ZGAIN[0]
Per chip
W
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 41 / 44
© 2014 mCube Inc. All rights reserved.
11.15 PCODE PRODUCT CODE
This register returns a value specific to the part number of this mCube device, noted below.
Addr
Name
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
POR
Value
R/
W
0x3B
PCODE
Product Code
Register
0
1
1
0
*
*
*
0
Note
R
Note: Bits denoted with ‘*’ might be any value, set by the factory. Software should ignore these
bits.
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 42 / 44
© 2014 mCube Inc. All rights reserved.
12 INDEX OF TABLES
Table 1. Order Information.........................................................................................................................................4
Table 2. Pin Description ..............................................................................................................................................8
Table 3. Absolute Maximum Ratings ....................................................................................................................... 12
Table 4. Sensor Characteristics ................................................................................................................................ 13
Table 5. Electrical Characteristics ............................................................................................................................ 14
Table 6. I2C Electrical and Timing Characteristics ................................................................................................... 15
Table 7. I2C Timing Characteristics .......................................................................................................................... 16
Table 8. Summary of Resolution, Range, and Scaling ............................................................................................. 17
Table 9. Operational States ..................................................................................................................................... 19
Table 10. Forcing Operational States ...................................................................................................................... 20
Table 11. I2C Address Selection .............................................................................................................................. 23
Table 12. Register Summary .................................................................................................................................... 27
Table 13. Accelerometer Value Registers ................................................................................................................ 28
Table 14. SR Status Register .................................................................................................................................... 29
Table 15. OPSTAT Device Status Register ................................................................................................................ 30
Table 16. INTEN Interrupt Enable Register Settings ................................................................................................ 31
Table 17. MODE Register Functionality ................................................................................................................... 32
Table 18. SRFR Register Functionality ..................................................................................................................... 33
Table 19. OUTCFG Resolution Register Settings ...................................................................................................... 34
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 43 / 44
© 2014 mCube Inc. All rights reserved.
13 REVISION HISTORY
Date
Revision
Description
2014-04
APS-048-0031v1.0
First release.
2014-07
APS-048-0031v1.1
Updated current and noise.
2014-09
APS-048-0031v1.2
Clarified order number, front page text, min voltage, fast mode I2C min.
Corrected typos. Corrected Default values of OPSTAT and MODE. Clarified
name for pin VDD/VDDIO.
MC3236 3-Axis Accelerometer Preliminary Datasheet
mCube Proprietary. APS-048-0031v1.2 44 / 44
© 2014 mCube Inc. All rights reserved.
14 LEGAL
1. M-CUBE reserves the right to make corrections, modifications, enhancements, improvements and other changes to its
products and to this document at any time and discontinue any product without notice. The information contained in this
document has been carefully checked and is believed to be accurate. However, M-CUBE shall assume no responsibilities for
inaccuracies and make no commitment to update or to keep current the information contained in this document.
2. M-CUBE products are designed only for commercial and normal industrial applications and are not suitable for other
purposes, such as: medical life support equipment; nuclear facilities; critical care equipment; military / aerospace;
automotive; security or any other applications, the failure of which could lead to death, personal injury or environmental or
property damage. Use of the products in unsuitable applications are at the customer’s own risk and expense.
3. M-CUBE shall assume no liability for incidental, consequential or special damages or injury that may result from
misapplication or improper use of operation of the product.
4. No license, express or implied, by estoppel or otherwise, to any intellectual property rights of M-CUBE or any third
party is granted under this document.
5. M-CUBE makes no warranty or representation of non-infringement of intellectual property rights of any third party with
respect to the products. M-CUBE specifically excludes any liability to the customers or any third party regarding
infringement of any intellectual property rights, including the patent, copyright, trademark or trade secret rights of any third
party, relating to any combination, machine, or process in which the M-CUBE products are used.
6. Examples of use described herein are provided solely to guide use of M-CUBE products and merely indicate targeted
characteristics, performance and applications of products. M-CUBE shall assume no responsibility for any intellectual
property claims or other problems that may result from applications based on the examples described herein
7. Information described in this document including parameters, application circuits and its constants and calculation
formulas, programs and control procedures are provided for the purpose of explaining typical operation and usage. “Typical”
parameters that may be provided in M-CUBE 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. In no event shall the information described be regarded as a guarantee of
conditions or characteristics of the products. Therefore, the customer should evaluate the design sufficiently as whole system
under the consideration of various external or environmental conditions and determine their application at the customer’s
own risk. M-CUBE shall assume no responsibility or liability for claims, damages, costs and expenses caused by the
customer or any third party, owing to the use of the above information.
is a trademark of M-CUBE, Inc.
M-CUBE and the M-CUBE logo are trademarks of M-CUBE, Inc.,
All other product or service names are the property of their respective owners.
© M-CUBE, Inc. 2014. All rights reserved.
