MPU-9250_技术文档

InvenSense Inc.

Document Number: PS-MPU-9250A-01

Revision: 1.1

1745 Technology Drive, San Jose, CA 95110 U.S.A.

Tel: +1 (408) 988-7339 Fax: +1 (408) 988-8104

Website: www.invensense.com

Release Date: 06/20/2016

MPU-9250

Product Specification

Revision 1.1

Page 1 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

CONTENTS

1

DOCUMENT INFORMATION......................................................................................................................4

1.1

REVISION HISTORY ..............................................................................................................................4

PURPOSE AND SCOPE..........................................................................................................................5

PRODUCT OVERVIEW...........................................................................................................................5

APPLICATIONS .....................................................................................................................................5

1.2

1.3

1.4

2

FEATURES..................................................................................................................................................6

2.1

GYROSCOPE FEATURES.......................................................................................................................6

ACCELEROMETER FEATURES ...............................................................................................................6

MAGNETOMETER FEATURES.................................................................................................................6

ADDITIONAL FEATURES ........................................................................................................................6

MOTIONPROCESSING...........................................................................................................................7

2.2

2.3

2.4

2.5

3

ELECTRICAL CHARACTERISTICS...........................................................................................................8

3.1

GYROSCOPE SPECIFICATIONS..............................................................................................................8

ACCELEROMETER SPECIFICATIONS.......................................................................................................9

MAGNETOMETER SPECIFICATIONS......................................................................................................10

ELECTRICAL SPECIFICATIONS.............................................................................................................11

I2C TIMING CHARACTERIZATION.........................................................................................................15

SPI TIMING CHARACTERIZATION.........................................................................................................16

ABSOLUTE MAXIMUM RATINGS ...........................................................................................................18

3.2

3.3

3.4

3.5

3.6

3.7

4

APPLICATIONS INFORMATION..............................................................................................................19

4.1

PIN OUT AND SIGNAL DESCRIPTION....................................................................................................19

TYPICAL OPERATING CIRCUIT.............................................................................................................20

BILL OF MATERIALS FOR EXTERNAL COMPONENTS..............................................................................20

BLOCK DIAGRAM ...............................................................................................................................21

OVERVIEW ........................................................................................................................................22

THREE-AXIS MEMS GYROSCOPE WITH 16-BIT ADCS AND SIGNAL CONDITIONING................................22

THREE-AXIS MEMS ACCELEROMETER WITH 16-BIT ADCS AND SIGNAL CONDITIONING ........................22

THREE-AXIS MEMS MAGNETOMETER WITH 16-BIT ADCS AND SIGNAL CONDITIONING .........................22

DIGITAL MOTION PROCESSOR ............................................................................................................22

PRIMARY I2C AND SPI SERIAL COMMUNICATIONS INTERFACES............................................................23

AUXILIARY I2C SERIAL INTERFACE......................................................................................................23

SELF-TEST........................................................................................................................................24

MPU-9250 SOLUTION USING I2C INTERFACE.....................................................................................25

4.2

4.3

4.4

4.5

4.6

4.7

4.8

4.9

4.10

4.11

4.12

4.13

Page 2 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

4.14

4.15

4.16

4.17

4.18

4.19

4.20

4.21

4.22

4.23

MPU-9250 SOLUTION USING SPI INTERFACE.....................................................................................26

CLOCKING.........................................................................................................................................26

SENSOR DATA REGISTERS.................................................................................................................27

FIFO ................................................................................................................................................27

INTERRUPTS......................................................................................................................................27

DIGITAL-OUTPUT TEMPERATURE SENSOR ..........................................................................................27

BIAS AND LDO ..................................................................................................................................28

CHARGE PUMP ..................................................................................................................................28

STANDARD POWER MODE..................................................................................................................28

POWER SEQUENCING REQUIREMENTS AND POWER ON RESET ............................................................28

5

6

ADVANCED HARDWARE FEATURES....................................................................................................29

PROGRAMMABLE INTERRUPTS............................................................................................................30

6.1

WAKE-ON-MOTION INTERRUPT...........................................................................................................30

7

DIGITAL INTERFACE ...............................................................................................................................32

7.1

I2C AND SPI SERIAL INTERFACES ......................................................................................................32

I2C INTERFACE..................................................................................................................................32

I2C COMMUNICATIONS PROTOCOL .....................................................................................................32

I2C TERMS........................................................................................................................................35

SPI INTERFACE .................................................................................................................................36

7.2

7.3

7.4

7.5

8

9

SERIAL INTERFACE CONSIDERATIONS...............................................................................................37

8.1

MPU-9250 SUPPORTED INTERFACES.................................................................................................37

ASSEMBLY ...............................................................................................................................................38

9.1

9.2

ORIENTATION OF AXES ......................................................................................................................38

PACKAGE DIMENSIONS ......................................................................................................................38

10 PART NUMBER PACKAGE MARKING ...................................................................................................40

11 RELIABILITY .............................................................................................................................................41

11.1

11.2

QUALIFICATION TEST POLICY .............................................................................................................41

QUALIFICATION TEST PLAN ................................................................................................................41

12 REFERENCE .............................................................................................................................................42

Page 3 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

1 Document Information

1.1 Revision History

Revision

Date

Revision Description

12/18/13

1.0

1.1

Initial Release

Updated Section 4

06/20/16

Page 4 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

1.2 Purpose and Scope

This document provides a description, specifications, and design related information on the MPU-9250

MotionTracking device. The device is housed in a small 3x3x1mm QFN package.

Specifications are subject to change without notice. Final specifications will be updated based upon

characterization of production silicon. For references to register map and descriptions of individual registers,

please refer to the MPU-9250 Register Map and Register Descriptions document.

1.3 Product Overview

MPU-9250 is a multi-chip module (MCM) consisting of two dies integrated into a single QFN package. One die

houses the 3-Axis gyroscope and the 3-Axis accelerometer. The other die houses the AK8963 3-Axis

magnetometer from Asahi Kasei Microdevices Corporation. Hence, the MPU-9250 is a 9-axis MotionTracking

device that combines a 3-axis gyroscope, 3-axis accelerometer, 3-axis magnetometer and a Digital Motion

Processor™ (DMP) all in a small 3x3x1mm package available as a pin-compatible upgrade from the MPU-

6515. With its dedicated I²C sensor bus, the MPU-9250 directly provides complete 9-axis MotionFusion™

output. The MPU-9250 MotionTracking device, with its 9-axis integration, on-chip MotionFusion™, and run-

time calibration firmware, enables manufacturers to eliminate the costly and complex selection, qualification,

and system level integration of discrete devices, guaranteeing optimal motion performance for consumers.

MPU-9250 is also designed to interface with multiple non-inertial digital sensors, such as pressure sensors,

on its auxiliary I²C port.

MPU-9250 features three 16-bit analog-to-digital converters (ADCs) for digitizing the gyroscope outputs, three

16-bit ADCs for digitizing the accelerometer outputs, and three 16-bit ADCs for digitizing the magnetometer

outputs. For precision tracking of both fast and slow motions, the parts feature a user-programmable

gyroscope full-scale range of ±250, ±500, ±1000, and ±2000°/sec (dps), a user-programmable accelerometer

full-scale range of ±2g, ±4g, ±8g, and ±16g, and a magnetometer full-scale range of ±4800µT.

Other industry-leading features include programmable digital filters, a precision clock with 1% drift from -40°C

to 85°C, an embedded temperature sensor, and programmable interrupts. The device features I²C and SPI

serial interfaces, a VDD operating range of 2.4V to 3.6V, and a separate digital IO supply, VDDIO from 1.71V

to VDD.

Communication with all registers of the device is performed using either I²C at 400kHz or SPI at 1MHz. For

applications requiring faster communications, the sensor and interrupt registers may be read using SPI at

20MHz.

By leveraging its patented and volume-proven CMOS-MEMS fabrication platform, which integrates MEMS

wafers with companion CMOS electronics through wafer-level bonding, InvenSense has driven the package

size down to a footprint and thickness of 3x3x1mm, to provide a very small yet high performance low cost

package. The device provides high robustness by supporting 10,000g shock reliability.

1.4 Applications



Location based services, points of interest, and dead reckoning

Handset and portable gaming

Motion-based game controllers

3D remote controls for Internet connected DTVs and set top boxes, 3D mice

Wearable sensors for health, fitness and sports

Page 5 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

2 Features

2.1 Gyroscope Features

The triple-axis MEMS gyroscope in the MPU-9250 includes a wide range of features:



Digital-output X-, Y-, and Z-Axis angular rate sensors (gyroscopes) with a user-programmable full-

scale range of ±250, ±500, ±1000, and ±2000°/sec and integrated 16-bit ADCs

Digitally-programmable low-pass filter

Gyroscope operating current: 3.2mA

Sleep mode current: 8µA



Factory calibrated sensitivity scale factor

Self-test

2.2 Accelerometer Features

The triple-axis MEMS accelerometer in MPU-9250 includes a wide range of features:



Digital-output triple-axis accelerometer with a programmable full scale range of ±2g, ±4g, ±8g and

±16g and integrated 16-bit ADCs



Accelerometer normal operating current: 450µA

Low power accelerometer mode current: 8.4µA at 0.98Hz, 19.8µA at 31.25Hz

Sleep mode current: 8µA

User-programmable interrupts

Wake-on-motion interrupt for low power operation of applications processor

Self-test

2.3 Magnetometer Features

The triple-axis MEMS magnetometer in MPU-9250 includes a wide range of features:



3-axis silicon monolithic Hall-effect magnetic sensor with magnetic concentrator

Wide dynamic measurement range and high resolution with lower current consumption.

Output data resolution of 14 bit (0.6µT/LSB)

Full scale measurement range is ±4800µT

Magnetometer normal operating current: 280µA at 8Hz repetition rate

Self-test function with internal magnetic source to confirm magnetic sensor operation on end products

2.4 Additional Features

The MPU-9250 includes the following additional features:



Auxiliary master I²C bus for reading data from external sensors (e.g. pressure sensor)

3.5mA operating current when all 9 motion sensing axes and the DMP are enabled

VDD supply voltage range of 2.4 – 3.6V

VDDIO reference voltage for auxiliary I²C devices

Smallest and thinnest QFN package for portable devices: 3x3x1mm

Minimal cross-axis sensitivity between the accelerometer, gyroscope and magnetometer axes

512 byte FIFO buffer enables the applications processor to read the data in bursts

Digital-output temperature sensor

User-programmable digital filters for gyroscope, accelerometer, and temp sensor

10,000 g shock tolerant

400kHz Fast Mode I²C for communicating with all registers

1MHz SPI serial interface for communicating with all registers

Page 6 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification



20MHz SPI serial interface for reading sensor and interrupt registers

MEMS structure hermetically sealed and bonded at wafer level

RoHS and Green compliant

2.5 MotionProcessing



Internal Digital Motion Processing™ (DMP™) engine supports advanced MotionProcessing and low

power functions such as gesture recognition using programmable interrupts

Low-power pedometer functionality allows the host processor to sleep while the DMP maintains the

step count.



Page 7 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3 Electrical Characteristics

3.1 Gyroscope Specifications

Typical Operating Circuit of section 4.2, VDD = 2.5V, VDDIO = 2.5V, T_A=25°C, unless otherwise noted.

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

Full-Scale Range

FS_SEL=0

FS_SEL=1

FS_SEL=2

FS_SEL=3

±250

±500

±1000

±2000

16

º/s

Gyroscope ADC Word Length

Sensitivity Scale Factor

bits

FS_SEL=0

FS_SEL=1

FS_SEL=2

FS_SEL=3

25°C

131

LSB/(º/s)

%

65.5

32.8

16.4

±3

Sensitivity Scale Factor Tolerance

Sensitivity Scale Factor Variation Over

Temperature

-40°C to +85°C

±4

%

Nonlinearity

Best fit straight line; 25°C

±0.1

±2

%

Cross-Axis Sensitivity

Initial ZRO Tolerance

25°C

±5

º/s

ZRO Variation Over Temperature

Total RMS Noise

-40°C to +85°C

DLPFCFG=2 (92 Hz)

±30

0.1

0.01

27

º/s

º/s-rms

º/s/√Hz

KHz

Hz

Rate Noise Spectral Density

Gyroscope Mechanical Frequencies

Low Pass Filter Response

25

5

29

Programmable Range

From Sleep mode

250

Gyroscope Startup Time

Output Data Rate

35

ms

Hz

Programmable, Normal mode

4

8000

Table 1 Gyroscope Specifications

Page 8 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.2 Accelerometer Specifications

Typical Operating Circuit of section 4.2, VDD = 2.5V, VDDIO = 2.5V, T_A=25°C, unless otherwise noted.

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

AFS_SEL=0

±2

±4

g

AFS_SEL=1

g

Full-Scale Range

ADC Word Length

Sensitivity Scale Factor

AFS_SEL=2

±8

g

AFS_SEL=3

±16

g

Output in two’s complement format

AFS_SEL=0

16

bits

LSB/g

%

16,384

8,192

4,096

2,048

±3

AFS_SEL=1

AFS_SEL=2

AFS_SEL=3

Initial Tolerance

Component-Level

-40°C to +85°C AFS_SEL=0

Component-level

Sensitivity Change vs. Temperature

±0.026

%/°C

Nonlinearity

Best Fit Straight Line

±0.5

±2

%

Cross-Axis Sensitivity

Zero-G Initial Calibration Tolerance

%

Component-level, X,Y

Component-level, Z

-40°C to +85°C

±60

±80

±1.5

300

mg

Zero-G Level Change vs. Temperature

Noise Power Spectral Density

Total RMS Noise

mg/°C

µg/√Hz

Low noise mode

DLPFCFG=2 (94Hz)

Programmable Range

8

mg-rms

Hz

Low Pass Filter Response

Intelligence Function Increment

5

260

4

20

30

mg/LSB

ms

From Sleep mode

From Cold Start, 1ms V_DDramp

Accelerometer Startup Time

ms

Low power (duty-cycled)

Duty-cycled, over temp

Low noise (active)

0.24

4

500

Hz

%

Output Data Rate

±15

4000

Hz

Table 2 Accelerometer Specifications

Page 9 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.3 Magnetometer Specifications

Typical Operating Circuit of section 4.2, VDD = 2.5V, VDDIO = 2.5V, T_A=25°C, unless otherwise noted.

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

MAGNETOMETER SENSITIVITY

Full-Scale Range

±4800

14

µT

ADC Word Length

bits

Sensitivity Scale Factor

ZERO-FIELD OUTPUT

Initial Calibration Tolerance

0.6

µT / LSB

±500

LSB

Page 10 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.4 Electrical Specifications

3.4.1 D.C. Electrical Characteristics

Typical Operating Circuit of section 4.2, VDD = 2.5V, VDDIO = 2.5V, T_A=25°C, unless otherwise noted.

PARAMETER

CONDITIONS

MIN

TYP

MAX

Units

Notes

SUPPLY VOLTAGES

VDD

2.4

2.5

1.8

3.6

V

VDDIO

1.71

VDD

SUPPLY CURRENTS

Normal Mode

9-axis (no DMP), 1 kHz gyro ODR, 4 kHz

accel ODR, 8 Hz mag. repetition rate

3.7

mA

6-axis (accel + gyro, no DMP), 1 kHz gyro

ODR, 4 kHz accel ODR

3.4

3.2

mA

µA

3-axis Gyroscope only (no DMP), 1 kHz ODR

6-axis (accel + magnetometer, no DMP), 4

kHz accel ODR, mag. repetition rate = 8 Hz

730

450

280

3-Axis Accelerometer, 4kHz ODR (no DMP)

3-axis Magnetometer only (no DMP), 8 Hz

repetition rate

Accelerometer Low Power Mode

(DMP, Gyroscope, Magnetometer

disabled)

0.98 Hz update rate

31.25 Hz update rate

8.4

19.8

8

µA

1

Full Chip Idle Mode Supply Current

TEMPERATURE RANGE

Specified Temperature Range

Performance parameters are not applicable

beyond Specified Temperature Range

-40

+85

°C

Table 3 D.C. Electrical Characteristics

Notes:

1. Accelerometer Low Power Mode supports the following output data rates (ODRs): 0.24, 0.49, 0.98,

1.95, 3.91, 7.81, 15.63, 31.25, 62.50, 125, 250, 500Hz. Supply current for any update rate can be

calculated as:

Supply Current in µA = Sleep Current + Update Rate * 0.376

Page 11 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.4.2 A.C. Electrical Characteristics

Typical Operating Circuit of section 4.2, VDD = 2.5V, VDDIO = 2.5V, T_A=25°C, unless otherwise noted.

Parameter

Conditions

MIN

TYP

MAX

Units

Monotonic ramp. Ramp rate

is 10% to 90% of the final

value

Supply Ramp Time

0.1

-40

100

ms

Operating Range

Sensitivity

Ambient

85

°C

Untrimmed

21°C

333.87

LSB/°C

Room Temp Offset

Supply Ramp Time (T_RAMP

0

LSB

ms

)

Valid power-on RESET

0.01

20

100

Start-up time for register read/write

From power-up

11

ms

AD0 = 0

AD0 = 1

1101000

1101001

I²C ADDRESS

V_IH, High Level Input Voltage

V_IL, Low Level Input Voltage

C_I, Input Capacitance

0.7*VDDIO

0.9*VDDIO

V

0.3*VDDIO

< 10

pF

V

V_OH, High Level Output Voltage

V_OL1, LOW-Level Output Voltage

V_OL.INT1, INT Low-Level Output Voltage

R_LOAD=1MΩ;

0.1*VDDIO

0.1

V

OPEN=1, 0.3mA sink

Current

V

Output Leakage Current

t_INT, INT Pulse Width

OPEN=1

100

50

nA

µs

V

LATCH_INT_EN=0

V_IL, LOW Level Input Voltage

V_IH, HIGH-Level Input Voltage

-0.5V

0.3*VDDIO

0.7*VDDIO

VDDIO +

0.5V

V

V_hys, Hysteresis

0.1*VDDIO

V

V_OL, LOW-Level Output Voltage

I_OL, LOW-Level Output Current

3mA sink current

0

0.4

V_OL=0.4V

V_OL=0.6V

3

6

mA

Output Leakage Current

100

nA

ns

V

t_of, Output Fall Time from V_IHmaxto V_ILmax

V_IL, LOW-Level Input Voltage

V_IH, HIGH-Level Input Voltage

C_bbus capacitance in pf

20+0.1C_b

-0.5V

250

0.3*VDDIO

0.7* VDDIO

VDDIO +

0.5V

V

V_hys, Hysteresis

0.1* VDDIO

V

V_OL1, LOW-Level Output Voltage

VDDIO

current

VDDIO

current

V_OL

>

<

2V; 1mA sink

0

0.4

V_OL3, LOW-Level Output Voltage

I_OL, LOW-Level Output Current

0.2* VDDIO

V

=

0.4V

3

6

mA

V_OL= 0.6V

Output Leakage Current

100

nA

ns

t_of, Output Fall Time from V_IHmaxto V_ILmax

C_bbus capacitance in pF

20+0.1C_b

250

Fchoice=0,1,2

SMPLRT_DIV=0

Fchoice=3;

DLPFCFG=0 or 7

SMPLRT_DIV=0

Fchoice=3;

32

8

kHz

Sample Rate

DLPFCFG=1,2,3,4,5,6;

SMPLRT_DIV=0

CLK_SEL=0, 6; 25°C

1

kHz

%

Clock Frequency Initial Tolerance

-2

+2

Page 12 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

CLK_SEL=1,2,3,4,5; 25°C

CLK_SEL=0,6

-1

+1

%

-10

+10

Frequency Variation over Temperature

CLK_SEL=1,2,3,4,5

±1

Table 4 A.C. Electrical Characteristics

Page 13 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.4.3 Other Electrical Specifications

Typical Operating Circuit of section 4.2, VDD = 2.5V, VDDIO = 2.5V, T_A=25°C, unless otherwise noted.

PARAMETER

CONDITIONS

MIN

TYP

MAX

Units

kHz

100

±10%

Low Speed Characterization

High Speed Characterization

SPI Operating Frequency, All

Registers Read/Write

1 ±10%

MHz

SPI Operating Frequency, Sensor

and Interrupt Registers Read Only

20 ±10%

All registers, Fast-mode

400

100

kHz

I²C Operating Frequency

All registers, Standard-mode

Table 5 Other Electrical Specifications

Page 14 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.5 I2C Timing Characterization

Typical Operating Circuit of section 4.2, VDD = 2.4V to 3.6V, VDDIO = 1.71 to VDD, T_A=25°C, unless otherwise

noted.

Parameters

I²C TIMING

Conditions

I²C FAST-MODE

Min

Typical

Max

Units

Notes

f_SCL, SCL Clock Frequency

400

kHz

µs

t_HD.STA, (Repeated) START Condition Hold

Time

0.6

t_LOW, SCL Low Period

t_HIGH, SCL High Period

1.3

0.6

µs

t_SU.STA, Repeated START Condition Setup

Time

t_HD.DAT, SDA Data Hold Time

t_SU.DAT, SDA Data Setup Time

t_r, SDA and SCL Rise Time

t_f, SDA and SCL Fall Time

0

µs

ns

µs

100

C_bbus cap. from 10 to 400pF

20+0.1C_b

0.6

300

t_SU.STO, STOP Condition Setup Time

t_BUF, Bus Free Time Between STOP and

START Condition

1.3

µs

C_b, Capacitive Load for each Bus Line

t_VD.DAT, Data Valid Time

< 400

pF

µs

0.9

t_VD.ACK, Data Valid Acknowledge Time

Table 6 I²C Timing Characteristics

Notes:



Timing Characteristics apply to both Primary and Auxiliary I2C Bus

Based on characterization of 5 parts over temperature and voltage as mounted on evaluation board or in

sockets

I²C Bus Timing Diagram

Page 15 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.6 SPI Timing Characterization

Typical Operating Circuit of section 4.2, VDD = 2.4V to 3.6V, VDDIO = 1.71V to VDD, T_A=25°C, unless

otherwise noted.

Notes

Parameters

Conditions

Min

Typical

Max

Units

SPI TIMING

f_SCLK, SCLK Clock Frequency

t_LOW, SCLK Low Period

t_HIGH, SCLK High Period

t_SU.CS, CS Setup Time

t_HD.CS, CS Hold Time

t_SU.SDI, SDI Setup Time

1

MHz

ns

400

8

ns

500

11

7

ns

t_HD.SDI, SDI Hold Time

ns

t_VD.SDO, SDO Valid Time

t_HD.SDO, SDO Hold Time

t_DIS.SDO, SDO Output Disable Time

C_load= 20pF

100

50

4

Table 7 SPI Timing Characteristics

Notes:

1. Based on characterization of 5 parts over temperature and voltage as mounted on evaluation board or in sockets

SPI Bus Timing Diagram

3.6.1 fSCLK = 20MHz

Parameters

Conditions

Min

Typical

Max

Units

SPI TIMING

f_SCLK, SCLK Clock Frequency

t_LOW, SCLK Low Period

t_HIGH, SCLK High Period

t_SU.CS, CS Setup Time

t_HD.CS, CS Hold Time

0.9

-

20

-

MHz

ns

-

ns

1

ns

1

ns

Page 16 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

t_SU.SDI, SDI Setup Time

0

1

ns

t_HD.SDI, SDI Hold Time

t_VD.SDO, SDO Valid Time

t_DIS.SDO, SDO Output Disable Time

C_load= 20pF

25

ns

25

Table 8 fCLK = 20MHz

Note:

1. Based on characterization of 5 parts over temperature and voltage as mounted on evaluation board or in sockets

Page 17 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

3.7 Absolute Maximum Ratings

Stress above those listed as “Absolute Maximum Ratings” may cause permanent damage to the device. These

are stress ratings only and functional operation of the device at these conditions is not implied. Exposure to

the absolute maximum ratings conditions for extended periods may affect device reliability.

Specification

Symbol

V_DD

Conditions

MIN

-0.5

MAX

4.0

Units

Supply Voltage

V

g

V_DDIO

4.0

Acceleration

Temperature

Any axis, unpowered,

0.2ms duration

10,000

Operating

Storage

HBM

-40

2

105

125

°C

KV

V

ESD Tolerance

MM

250

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

4 Applications Information

4.1 Pin Out and Signal Description

Pin Number

Pin Name

RESV

Pin Description

Reserved. Connect to VDDIO.

1

7

AUX_CL

VDDIO

AD0 / SDO

REGOUT

FSYNC

INT

I²C Master serial clock, for connecting to external sensors

8

Digital I/O supply voltage

9

I²C Slave Address LSB (AD0); SPI serial data output (SDO)

Regulator filter capacitor connection

10

11

Frame synchronization digital input. Connect to GND if unused.

Interrupt digital output (totem pole or open-drain)

Power supply voltage and Digital I/O supply voltage

Power supply ground

12

13

VDD

18

GND

19

RESV

Reserved. Do not connect.

20

RESV

Reserved. Connect to GND.

21

AUX_DA

nCS

I²C master serial data, for connecting to external sensors

22

Chip select (SPI mode only)

23

24

SCL / SCLK

SDA / SDI

NC

I²C serial clock (SCL); SPI serial clock (SCLK)

I²C serial data (SDA); SPI serial data input (SDI)

Not internally connected. May be used for PCB trace routing.

2 – 6, 14 - 17

Table 9 Signal Descriptions

GND

RESV

1

2

3

4

5

6

18

17

16

15

14

NC

MPU-9250

13 VDD

Figure 1 Pin Out Diagram for MPU-9250 3.0x3.0x1.0mm QFN

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MPU-9250 Product Specification

4.2 Typical Operating Circuit

nCS

VDDIO

SCL

SCLK

SDI

SDA

VDDIO

RESV

1

RESV

NC

GND

18

17

16

15

14

13

1

2

3

4

5

6

NC

2

3

4

5

6

17

NC

16

15

14

13

MPU-9250

NC

VDD

2.4 – 3.3VDC

C2, 0.1 mF

2.4 – 3.3VDC

C2, 0.1 mF

1.8 – 3.3VDC

C1, 0.1 mF

C3, 10 nF

AD0

SDO

(a)

(b)

Figure 2 MPU-9250 QFN Application Schematic: (a) I2C operation, (b) SPI operation

Note that the INT pin should be connected to a GPIO pin on the system processor that is capable of waking

the system processor from suspend mode.

4.3 Bill of Materials for External Components

Component

Label

C1

Specification

Quantity

Regulator Filter Capacitor

VDD Bypass Capacitor

VDDIO Bypass Capacitor

Ceramic, X7R, 0.1µF ±10%, 2V

Ceramic, X7R, 0.1µF ±10%, 4V

Ceramic, X7R, 10nF ±10%, 4V

1

C2

C3

Table 10 Bill of Materials

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

4.4 Block Diagram

MPU-9250

Self

test

X Accel

ADC

INT

Interrupt

Status

Register

nCS

Self

test

Y Accel

ADC

Slave I2C and

SPI Serial

Interface

AD0 / SDO

SCL / SCLK

SDA / SDI

FIFO

Self

test

Z Accel

X Gyro

ADC

User & Config

Registers

Serial

Interface

Bypass

Master I2C

Serial

Interface

AUX_CL

Self

test

AUX_DA

Mux

Sensor

Registers

FSYNC

Self

test

Y Gyro

Z Gyro

ADC

Digital Motion

Processor

(DMP)

Self

test

Signal Conditioning

Temp Sensor

ADC

X

Y

Z

Compass

Bias & LDOs

Charge

Pump

VDDIO

VDD

GND

REGOUT

Page 21 of 42

Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

4.5 Overview

The MPU-9250 is comprised of the following key blocks and functions:



Three-axis MEMS rate gyroscope sensor with 16-bit ADCs and signal conditioning

Three-axis MEMS accelerometer sensor with 16-bit ADCs and signal conditioning

Three-axis MEMS magnetometer sensor with 16-bit ADCs and signal conditioning

Digital Motion Processor (DMP) engine

Primary I²C and SPI serial communications interfaces

Auxiliary I²C serial interface for 3^rdparty sensors

Clocking

Sensor Data Registers

FIFO

Interrupts

Digital-Output Temperature Sensor

Gyroscope, Accelerometer and Magnetometer Self-test

Bias and LDO

Charge Pump

4.6 Three-Axis MEMS Gyroscope with 16-bit ADCs and Signal Conditioning

The MPU-9250 consists of three independent vibratory MEMS rate gyroscopes, which detect rotation about

the X-, Y-, and Z- Axes. When the gyros are rotated about any of the sense axes, the Coriolis Effect causes

a vibration that is detected by a capacitive pickoff. The resulting signal is amplified, demodulated, and filtered

to produce a voltage that is proportional to the angular rate. This voltage is digitized using individual on-chip

16-bit Analog-to-Digital Converters (ADCs) to sample each axis. The full-scale range of the gyro sensors may

be digitally programmed to ±250, ±500, ±1000, or ±2000 degrees per second (dps). The ADC sample rate is

programmable from 8,000 samples per second, down to 3.9 samples per second, and user-selectable low-

pass filters enable a wide range of cut-off frequencies.

4.7 Three-Axis MEMS Accelerometer with 16-bit ADCs and Signal Conditioning

The MPU-9250’s 3-Axis accelerometer uses separate proof masses for each axis. Acceleration along a

particular axis induces displacement on the corresponding proof mass, and capacitive sensors detect the

displacement differentially. The MPU-9250’s architecture reduces the accelerometers’ susceptibility to

fabrication variations as well as to thermal drift. When the device is placed on a flat surface, it will measure 0g

on the X- and Y-axes and +1g on the Z-axis. The accelerometers’ scale factor is calibrated at the factory and

is nominally independent of supply voltage. Each sensor has a dedicated sigma-delta ADC for providing digital

outputs. The full scale range of the digital output can be adjusted to ±2g, ±4g, ±8g, or ±16g.

4.8 Three-Axis MEMS Magnetometer with 16-bit ADCs and Signal Conditioning

The 3-axis magnetometer uses highly sensitive Hall sensor technology. The magnetometer portion of the IC

incorporates magnetic sensors for detecting terrestrial magnetism in the X-, Y-, and Z- Axes, a sensor driving

circuit, a signal amplifier chain, and an arithmetic circuit for processing the signal from each sensor. Each ADC

has a 16-bit resolution and a full scale range of ±4800 µT.

4.9 Digital Motion Processor

The embedded Digital Motion Processor (DMP) is located within the MPU-9250 and offloads computation of

motion processing algorithms from the host processor. The DMP acquires data from accelerometers,

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

gyroscopes, magnetometers and additional 3^rdparty sensors, and processes the data. The resulting data can

be read from the DMP’s registers, or can be buffered in a FIFO. The DMP has access to one of the MPU’s

external pins, which can be used for generating interrupts. This pin (pin 12) should be connected to a pin on

the host processor that can wake the host from suspend mode.

The purpose of the DMP is to offload both timing requirements and processing power from the host processor.

Typically, motion processing algorithms should be run at a high rate, often around 200Hz, in order to provide

accurate results with low latency. This is required even if the application updates at a much lower rate; for

example, a low power user interface may update as slowly as 5Hz, but the motion processing should still run

at 200Hz. The DMP can be used as a tool in order to minimize power, simplify timing, simplify the software

architecture, and save valuable MIPS on the host processor for use in the application.

4.10 Primary I2C and SPI Serial Communications Interfaces

The MPU-9250 communicates to a system processor using either a SPI or an I²C serial interface. The MPU-

9250 always acts as a slave when communicating to the system processor. The LSB of the of the I²C slave

address is set by pin 9 (AD0).

4.11 Auxiliary I2C Serial Interface

The MPU-9250 has an auxiliary I²C bus for communicating to off-chip sensors. This bus has two operating

modes:



I²C Master Mode: The MPU-9250 acts as a master to any external sensors connected to the auxiliary

I²C bus

Pass-Through Mode: The MPU-9250 directly connects the primary and auxiliary I²C buses together,

allowing the system processor to directly communicate with any external sensors.

Note: AUX_DA and AUX_CL should be left unconnected if the Auxiliary I²C mode is not used.

Auxiliary I²C Bus Modes of Operation:



I²C Master Mode: Allows the MPU-9250 to directly access the data registers of external digital

sensors, such as a magnetometer. In this mode, the MPU-9250 directly obtains data from auxiliary

sensors without intervention from the system applications processor.

For example, In I²C Master mode, the MPU-9250 can be configured to perform burst reads, returning

the following data from a magnetometer:

.

X magnetometer data (2 bytes)

Y magnetometer data (2 bytes)

Z magnetometer data (2 bytes)

The I²C Master can be configured to read up to 24 bytes from up to 4 auxiliary sensors. A fifth sensor

can be configured to work single byte read/write mode.



Pass-Through Mode: Allows an external system processor to act as master and directly communicate

to the external sensors connected to the auxiliary I²C bus pins (AUX_DA and AUX_CL). In this mode,

the auxiliary I²C bus control logic (3^rdparty sensor interface block) of the MPU-9250 is disabled, and

the auxiliary I²C pins AUX_DA and AUX_CL are connected to the main I²C bus through analog

switches internally.

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

Pass-Through mode is useful for configuring the external sensors, or for keeping the MPU-9250 in a

low-power mode when only the external sensors are used. In this mode, the system processor can

still access MPU-9250 data through the I²C interface.

Pass-Through mode is also used to access the AK8963 magnetometer directly from the host. In this

configuration the slave address for the AK8963 is 0X0C or 12 decimal.

Auxiliary I²C Bus IO Logic Levels

For MPU-9250, the logic level of the auxiliary I²C bus is VDDIO. For further information regarding the MPU-

9250 logic levels, please refer to Section 10.2.

4.12 Self-Test

Please refer to the register map document for more details on self-test.

Self-test allows for the testing of the mechanical and electrical portions of the sensors. The self-test for each

measurement axis can be activated by means of the gyroscope and accelerometer self-test registers (registers

13 to 16).

When the self-test is activated, the electronics cause the sensors to be actuated and produce an output signal.

The output signal is used to observe the self-test response.

The self-test response is defined as follows:

Self-test response = Sensor output with self-test enabled – Sensor output without self-test enabled

When the value of the self-test response is within the appropriate limits, the part has passed self-test. When

the self-test response exceeds the appropriate values, the part is deemed to have failed self-test. It is

recommended to use InvenSense MotionApps software for executing self-test. Further details, including the

self-test limits are included in the MPU-9250 Self-Test applications note available from InvenSense.

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

4.13 MPU-9250 Solution Using I2C Interface

In the figure below, the system processor is an I²C master to the MPU-9250. In addition, the MPU-9250 is an

I²C master to the optional external 3^rdparty sensor. The MPU-9250 has limited capabilities as an I²C Master,

and depends on the system processor to manage the initial configuration of any auxiliary sensors. The MPU-

9250 has an interface bypass multiplexer, which connects the system processor I²C bus (SDA and SCL)

directly to the auxiliary sensor I²C bus (AUX_DA and AUX_CL).

Once the auxiliary sensors have been configured by the system processor, the interface bypass multiplexer

should be disabled so that the MPU-9250 auxiliary I²C master can take control of the sensor I²C bus and gather

data from the auxiliary sensors. The INT pin should be connected to a GPIO on the system processor that

can wake the system from suspend mode.

Interrupt

Status

INT

I²C Processor Bus: for reading all

sensor data from MPU and for

configuring external sensors (i.e.

compass in this example)

Register

MPU-9250

AD0

SCL

VDD or GND

Slave I²C

or SPI

SCL

SDA

System

Processor

Serial

Interface

SDA/SDI

FIFO

Sensor I²C Bus: for

configuring and reading

from external sensors

User & Config

Registers

Optional

Sensor

Master I²C

Serial

AUX_CL

AUX_DA

SCL

SDA

Sensor

Register

Interface

Bypass

Mux

3^rdparty

sensor

Interface

Factory

Calibration

Digital

Motion

Processor

(DMP)

Interface bypass mux allows

direct configuration of

compass by system processor

Bias & LDOs

VDD

GND

REGOUT

VDDIO

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

4.14 MPU-9250 Solution Using SPI Interface

In the figure below, the system processor is a SPI master to the MPU-9250. The CS, SDO, SCLK, and SDI

signals are used for SPI communications. Because these SPI pins are shared with the I²C slave pins, the

system processor cannot access the auxiliary I²C bus through the interface bypass multiplexer, which connects

the processor I²C interface pins to the sensor I²C interface pins.

Since the MPU-9250 has limited capabilities as an I²C Master, and depends on the system processor to

manage the initial configuration of any auxiliary sensors, another method must be used for programming the

sensors on the auxiliary sensor I²C bus (AUX_DA and AUX_CL).

When using SPI communications between the MPU-9250 and the system processor, configuration of devices

on the auxiliary I²C sensor bus can be achieved by using I²C Slaves 0-4 to perform read and write transactions

on any device and register on the auxiliary I²C bus. The I²C Slave 4 interface can be used to perform only

single byte read and write transactions.

Once the external sensors have been configured, the MPU-9250 can perform single or multi-byte reads using

the sensor I²C bus. The read results from the Slave 0-3 controllers can be written to the FIFO buffer as well as

to the external sensor registers.

The INT pin should be connected to a GPIO on the system processor capable of waking the processor from

suspend

For further information regarding the control of the MPU-9250’s auxiliary I²C interface, please refer to the MPU-

9250 Register Map and Register Descriptions document.

Interrupt

Status

Register

Processor SPI Bus: for reading all

data from MPU and for configuring

MPU and external sensors

INT

nCS

SDI

nCS

SDO

MPU-9250

Slave I²C

or SPI

Serial

Interface

System

Processor

SCLK

SDI

SCLK

SDO

FIFO

Sensor I²C Bus: for

configuring and

reading data from

external sensors

Config

Register

Optional

Sensor

Master I²C

Serial

AUX_CL

AUX_DA

SCL

SDA

Sensor

Register

Interface

Bypass

Mux

3^rdparty

sensor

Interface

Factory

Calibration

Digital

Motion

Processor

(DMP)

I²C Master performs

read and write

transactions on

Sensor I²C bus.

Bias & LDOs

VDD

GND

REGOUT

VDDIO

4.15 Clocking

The MPU-9250 has a flexible clocking scheme, allowing a variety of internal clock sources to be used for the

internal synchronous circuitry. This synchronous circuitry includes the signal conditioning and ADCs, the DMP,

and various control circuits and registers. An on-chip PLL provides flexibility in the allowable inputs for

generating this clock.

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MPU-9250 Product Specification

Allowable internal sources for generating the internal clock are:



An internal relaxation oscillator

Any of the X, Y, or Z gyros (MEMS oscillators with a variation of ±1% over temperature)

Selection of the source for generating the internal synchronous clock depends on the requirements for power

consumption and clock accuracy. These requirements will most likely vary by mode of operation. For example,

in one mode, where the biggest concern is power consumption, the user may wish to operate the Digital Motion

Processor of the MPU-9250 to process accelerometer data, while keeping the gyros off. In this case, the

internal relaxation oscillator is a good clock choice. However, in another mode, where the gyros are active,

selecting the gyros as the clock source provides for a more accurate clock source.

Clock accuracy is important, since timing errors directly affect the distance and angle calculations performed

by the Digital Motion Processor (and by extension, by any processor).

There are also start-up conditions to consider. When the MPU-9250 first starts up, the device uses its internal

clock until programmed to operate from another source. This allows the user, for example, to wait for the

MEMS oscillators to stabilize before they are selected as the clock source.

4.16 Sensor Data Registers

The sensor data registers contain the latest gyroscope, accelerometer, magnetometer, auxiliary sensor, and

temperature measurement data. They are read-only registers, and are accessed via the serial interface. Data

from these registers may be read anytime.

4.17 FIFO

The MPU-9250 contains a 512-byte FIFO register that is accessible via the Serial Interface. The FIFO

configuration register determines which data is written into the FIFO. Possible choices include gyro data,

accelerometer data, temperature readings, auxiliary sensor readings, and FSYNC input. A FIFO counter keeps

track of how many bytes of valid data are contained in the FIFO. The FIFO register supports burst reads. The

interrupt function may be used to determine when new data is available.

For further information regarding the FIFO, please refer to the MPU-9250 Register Map and Register

Descriptions document.

4.18 Interrupts

Interrupt functionality is configured via the Interrupt Configuration register. Items that are configurable include

the INT pin configuration, the interrupt latching and clearing method, and triggers for the interrupt. Items that

can trigger an interrupt are (1) Clock generator locked to new reference oscillator (used when switching clock

sources); (2) new data is available to be read (from the FIFO and Data registers); (3) accelerometer event

interrupts; and (4) the MPU-9250 did not receive an acknowledge from an auxiliary sensor on the secondary

I²C bus. The interrupt status can be read from the Interrupt Status register.

The INT pin should be connected to a pin on the host processor capable of waking that processor from

suspend.

For further information regarding interrupts, please refer to the MPU-9250 Register Map and Register

Descriptions document.

4.19 Digital-Output Temperature Sensor

An on-chip temperature sensor and ADC are used to measure the MPU-9250 die temperature. The readings

from the ADC can be read from the FIFO or the Sensor Data registers.

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

4.20 Bias and LDO

The bias and LDO section generates the internal supply and the reference voltages and currents required by

the MPU-9250. Its two inputs are an unregulated VDD and a VDDIO logic reference supply voltage. The LDO

output is bypassed by a capacitor at REGOUT. For further details on the capacitor, please refer to the Bill of

Materials for External Components.

4.21 Charge Pump

An on-chip charge pump generates the high voltage required for the MEMS oscillators.

4.22 Standard Power Mode

The following table lists the user-accessible power modes for MPU-9250.

Mode Name

Gyro

Off

Accel

Magnetometer

DMP

Off

1

2

3

4

5

6

7

8

9

Sleep Mode

Off

On

Off

On

Standby Mode

Drive On

Off

Low-Power Accelerometer Mode

Low-Noise Accelerometer Mode

Gyroscope Mode

Duty-Cycled

On or Off

Off

On

Off

On

Magnetometer Mode

Accel + Gyro Mode

Off

On

Accel + Magnetometer Mode

9-Axis Mode

Off

On

Notes:

1. Power consumption for individual modes can be found in Electrical Characteristics section.

4.23 Power Sequencing Requirements and Power on Reset

During power up and in normal operation, VDDIO must not exceed VDD. During power up, VDD and VDDIO

must be monotonic ramps. As stated in Table 4, the minimum VDD rise time is 0.1ms and the maximum rise

time is 100 ms. Valid gyroscope data is available 35 ms (typical) after VDD has risen to its final voltage from

a cold start and valid accelerometer data is available 30 ms (typical) after VDD has risen to its final voltage

assuming a 1ms VDD ramp from cold start. Magnetometer data is valid 7.3ms (typical) after VDD has risen to

its final voltage value from a cold start.

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Document Number: PS-MPU-9250A-01

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MPU-9250 Product Specification

5 Advanced Hardware Features

The MPU-9250 includes advanced hardware features that can be enabled and disabled through simple

hardware register settings. The advanced hardware features are not initially enabled after device power up.

These features must be individually enabled and configured. These advanced hardware features enable the

following motion-based functions without using an external microprocessor:



Low Power Quaternion (3-Axis Gyro & 6-Axis Gyro + Accel)



Android Orientation (A low-power implementation of Android’s screen rotation algorithm)

Tap (detects the tap gesture)

Pedometer



Significant Motion Detection

To ensure significant motion detection can operate properly, the INT pin should be connected to a GPIO pin

on the host processor that can wake that processor from suspend mode.

Note: Android Orientation is compliant to the Ice Cream Sandwich definition of the function.

For further details on advanced hardware features please refer to the MPU-9250 Register Map.

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MPU-9250 Product Specification

6 Programmable Interrupts

The MPU-9250 has a programmable interrupt system which can generate an interrupt signal on the INT pin.

Status flags indicate the source of an interrupt. Interrupt sources may be enabled and disabled individually.

Table of Interrupt Sources

Interrupt Name

Module

Motion Detection

Motion

FIFO Overflow

FIFO

Data Ready

Sensor Registers

I²C Master

I²C Master errors: Lost Arbitration, NACKs

I²C Slave 4

For information regarding the interrupt enable/disable registers and flag registers, please refer to the MPU-

9250 Register Map and Register Descriptions document. Some interrupt sources are explained below.

6.1 Wake-on-Motion Interrupt

The MPU-9250 provides motion detection capability. A qualifying motion sample is one where the high passed

sample from any axis has an absolute value exceeding a user-programmable threshold. The following

flowchart explains how to configure the Wake-on-Motion Interrupt. For further details on individual registers,

please refer to the MPU-9250 Registers Map and Registers Description document.

In order to properly enable motion interrupts, the INT pin should be connected to a GPIO on the system

processor that is capable of waking up the system processor.

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MPU-9250 Product Specification

Configuration Wake-on-Motion Interrupt using low power Accel mode

Make Sure Accel is running:

In PWR_MGMT_1 (0x6B) make CYCLE =0, SLEEP = 0 and STANDBY = 0

In PWR_MGMT_2 (0x6C) set DIS_XA, DIS_YA, DIS_ZA = 0 and DIS_XG, DIS_YG, DIS_ZG = 1

•

Set Accel LPF setting to 184 Hz Bandwidth:

•

In ACCEL_CONFIG 2 (0x1D) set ACCEL_FCHOICE_B = 0 and A_DLPFCFG[2:0]=1(b001)

.

In ACCEL_CONFIG 2 (0x1D) set ACCEL_FCHOICE_B = 1 and A_DLPFCFG[2:]=1(b001)

Enable Motion Interrupt:

In INT_ENABLE (0x38), set the whole register to 0x40 to enable motion interrupt only.

•

Enable Accel Hardware Intelligence:

In MOT_DETECT_CTRL (0x69), set ACCEL_INTEL_EN = 1 and ACCEL_INTEL_MODE = 1

Set Motion Threshold:

In WOM_THR (0x1F), set the WOM_Threshold [7:0] to 1~255 LSBs (0~1020mg)

•

Set Frequency of Wake-up:

In LP_ACCEL_ODR (0x1E), set Lposc_clksel [3:0] = 0.24Hz ~ 500Hz

•

Enable Cycle Mode (Accel Low Power Mode):

In PWR_MGMT_1 (0x6B) make CYCLE =1

•

Motion Interrupt Configuration Completed

Figure 3. Wake-on-Motion Interrupt Configuration

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MPU-9250 Product Specification

7 Digital Interface

7.1 I2C and SPI Serial Interfaces

The internal registers and memory of the MPU-9250 can be accessed using either I²C at 400 kHz or SPI at

1MHz. SPI operates in four-wire mode.

Serial Interface

Pin Number

Pin Name

VDDIO

Pin Description

8

9

Digital I/O supply voltage.

AD0 / SDO

SCL / SCLK

SDA / SDI

I²C Slave Address LSB (AD0); SPI serial data output (SDO)

I²C serial clock (SCL); SPI serial clock (SCLK)

I²C serial data (SDA); SPI serial data input (SDI)

23

24

Note:

To prevent switching into I²C mode when using SPI, the I²C interface should be disabled by setting the

I2C_IF_DIS configuration bit. Setting this bit should be performed immediately after waiting for the time

specified by the “Start-Up Time for Register Read/Write” in Section 6.3.

For further information regarding the I2C_IF_DIS bit, please refer to the MPU-9250 Register Map and Register

Descriptions document.

7.2 I2C Interface

I²C is a two-wire interface comprised of the signals serial data (SDA) and serial clock (SCL). In general, the

lines are open-drain and bi-directional. In a generalized I²C interface implementation, attached devices can be

a master or a slave. The master device puts the slave address on the bus, and the slave device with the

matching address acknowledges the master.

The MPU-9250 always operates as a slave device when communicating to the system processor, which thus

acts as the master. SDA and SCL lines typically need pull-up resistors to VDD. The maximum bus speed is

400 kHz.

The slave address of the MPU-9250 is b110100X which is 7 bits long. The LSB bit of the 7 bit address is

determined by the logic level on pin AD0. This allows two MPU-9250s to be connected to the same I²C bus.

When used in this configuration, the address of the one of the devices should be b1101000 (pin AD0 is logic

low) and the address of the other should be b1101001 (pin AD0 is logic high).

7.3 I2C Communications Protocol

START (S) and STOP (P) Conditions

Communication on the I²C bus starts when the master puts the START condition (S) on the bus, which is

defined as a HIGH-to-LOW transition of the SDA line while SCL line is HIGH (see figure below). The bus is

considered to be busy until the master puts a STOP condition (P) on the bus, which is defined as a LOW to

HIGH transition on the SDA line while SCL is HIGH (see figure below).

Additionally, the bus remains busy if a repeated START (Sr) is generated instead of a STOP condition.

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Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

SDA

SCL

S

P

START condition

STOP condition

START and STOP Conditions

Data Format / Acknowledge

I²C data bytes are defined to be 8-bits long. There is no restriction to the number of bytes transmitted per data

transfer. Each byte transferred must be followed by an acknowledge (ACK) signal. The clock for the

acknowledge signal is generated by the master, while the receiver generates the actual acknowledge signal

by pulling down SDA and holding it low during the HIGH portion of the acknowledge clock pulse.

If a slave is busy and cannot transmit or receive another byte of data until some other task has been performed,

it can hold SCL LOW, thus forcing the master into a wait state. Normal data transfer resumes when the slave

is ready, and releases the clock line (refer to the following figure).

DATA OUTPUT BY

TRANSMITTER (SDA)

not acknowledge

DATA OUTPUT BY

RECEIVER (SDA)

acknowledge

SCL FROM

MASTER

1

2

8

9

clock pulse for

acknowledgement

START

condition

Acknowledge on the I²C Bus

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Document Number: PS-MPU-9250A-01

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Release Date: 06/20/2016

MPU-9250 Product Specification

Communications

After beginning communications with the START condition (S), the master sends a 7-bit slave address followed

by an 8^thbit, the read/write bit. The read/write bit indicates whether the master is receiving data from or is

writing to the slave device. Then, the master releases the SDA line and waits for the acknowledge signal (ACK)

from the slave device. Each byte transferred must be followed by an acknowledge bit. To acknowledge, the

slave device pulls the SDA line LOW and keeps it LOW for the high period of the SCL line. Data transmission

is always terminated by the master with a STOP condition (P), thus freeing the communications line. However,

the master can generate a repeated START condition (Sr), and address another slave without first generating

a STOP condition (P). A LOW to HIGH transition on the SDA line while SCL is HIGH defines the stop condition.

All SDA changes should take place when SCL is low, with the exception of start and stop conditions.

SDA

SCL

1 – 7

8

9

1 – 7

8

9

1 – 7

8

9

S

P

START

STOP

ADDRESS

R/W

ACK

DATA

ACK

DATA

ACK

condition

Complete I²C Data Transfer

To write the internal MPU-9250 registers, the master transmits the start condition (S), followed by the I²C

address and the write bit (0). At the 9^thclock cycle (when the clock is high), the MPU-9250 acknowledges the

transfer. Then the master puts the register address (RA) on the bus. After the MPU-9250 acknowledges the

reception of the register address, the master puts the register data onto the bus. This is followed by the ACK

signal, and data transfer may be concluded by the stop condition (P). To write multiple bytes after the last ACK

signal, the master can continue outputting data rather than transmitting a stop signal. In this case, the MPU-

9250 automatically increments the register address and loads the data to the appropriate register. The

following figures show single and two-byte write sequences.

Single-Byte Write Sequence

Master

Slave

S

AD+W

RA

DATA

P

ACK

Burst Write Sequence

Master

Slave

S

AD+W

DATA

P

ACK

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Document Number: PS-MPU-9250A-01

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Release Date: 06/20/2016

MPU-9250 Product Specification

To read the internal MPU-9250 registers, the master sends a start condition, followed by the I²C address and

a write bit, and then the register address that is going to be read. Upon receiving the ACK signal from the MPU-

9250, the master transmits a start signal followed by the slave address and read bit. As a result, the MPU-

9250 sends an ACK signal and the data. The communication ends with a not acknowledge (NACK) signal and

a stop bit from master. The NACK condition is defined such that the SDA line remains high at the 9^thclock

cycle. The following figures show single and two-byte read sequences.

Single-Byte Read Sequence

Master

Slave

S

AD+W

RA

S

AD+R

NACK

ACK

P

ACK

ACK DATA

Burst Read Sequence

Master

Slave

S

AD+W

NACK

P

DATA

7.4 I2C Terms

Signal Description

S

AD

W

Start Condition: SDA goes from high to low while SCL is high

Slave I²C address

Write bit (0)

R

Read bit (1)

ACK

Acknowledge: SDA line is low while the SCL line is high at the 9^th

clock cycle

NACK Not-Acknowledge: SDA line stays high at the 9^thclock cycle

RA

DATA

P

MPU-9250 internal register address

Transmit or received data

Stop condition: SDA going from low to high while SCL is high

Page 35 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

7.5 SPI Interface

SPI is a 4-wire synchronous serial interface that uses two control lines and two data lines. The MPU-9250

always operates as a Slave device during standard Master-Slave SPI operation.

With respect to the Master, the Serial Clock output (SCLK), the Serial Data Output (SDO) and the Serial Data

Input (SDI) are shared among the Slave devices. Each SPI slave device requires its own Chip Select (CS) line

from the master.

CS goes low (active) at the start of transmission and goes back high (inactive) at the end. Only one CS line is

active at a time, ensuring that only one slave is selected at any given time. The CS lines of the non-selected

slave devices are held high, causing their SDO lines to remain in a high-impedance (high-z) state so that they

do not interfere with any active devices.

SPI Operational Features

1. Data is delivered MSB first and LSB last

2. Data is latched on the rising edge of SCLK

3. Data should be transitioned on the falling edge of SCLK

4. The maximum frequency of SCLK is 1MHz

5. SPI read and write operations are completed in 16 or more clock cycles (two or more bytes). The

first byte contains the SPI Address, and the following byte(s) contain(s) the SPI data. The first bit

of the first byte contains the Read/Write bit and indicates the Read (1) or Write (0) operation. The

following 7 bits contain the Register Address. In cases of multiple-byte Read/Writes, data is two

or more bytes:

SPI Address format

MSB

LSB

R/W A6 A5 A4 A3 A2 A1

A0

SPI Data format

MSB

LSB

D7

D6 D5 D4 D3 D2 D1

D0

6. Supports Single or Burst Read/Writes.

SCLK

SDI

SPI Master

/CS1

SPI Slave 1

SDO

/CS

/CS2

SCLK

SDI

SDO

/CS

SPI Slave 2

Typical SPI Master / Slave Configuration

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Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

8 Serial Interface Considerations

8.1 MPU-9250 Supported Interfaces

The MPU-9250 supports I²C communications on both its primary (microprocessor) serial interface and its

auxiliary interface.

The MPU-9250’s I/O logic levels are set to be VDDIO.

The figure below depicts a sample circuit of MPU-9250 with a third party sensor attached to the auxiliary I²C

bus. It shows the relevant logic levels and voltage connections.

Note: Actual configuration will depend on the auxiliary sensors used.

VDDIO

VDD_IO

(0V - VDDIO)

SYSTEM BUS

System

Processor IO

VDD

VDDIO

(0V - VDDIO)

VDD

INT

VDDIO

(0V - VDDIO)

SDA

SCL

(0V - VDDIO)

FSYNC

VDDIO

MPU-9250

VDD_IO

VDDIO

AD0

(0V, VDDIO)

CS

3^rdParty

Sensor

(0V - VDDIO)

(0V, VDDIO)

AUX_DA

AUX_CL

SDA

SCL

INT 1

INT 2

SA0

(0V, VDDIO)

I/O Levels and Connections

Page 37 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

9 Assembly

This section provides general guidelines for assembling InvenSense Micro Electro-Mechanical Systems

(MEMS) devices packaged in quad flat no-lead package (QFN) surface mount integrated circuits.

9.1 Orientation of Axes

The diagram below shows the orientation of the axes of sensitivity and the polarity of rotation. Note the pin 1

identifier (•) in the figure.

+Z

+Y

+Z

M

+Y

P

U

-

9

2

5

0

+X

Figure 4. Orientation of Axes of Sensitivity and Polarity of Rotation for Accelerometer and Gyroscope

+X

M

P

U

-

9

2

5

0

+Y

+Z

Figure 5. Orientation of Axes of Sensitivity for Compass

9.2 Package Dimensions

24 Lead QFN (3x3x1) mm NiPdAu Lead-frame finish

Page 38 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

DIMENSIONS IN

MILLIMETERS

SYMBOLS

DESCRIPTION

MIN

NOM

MAX

A

A1

b

c

D

D2

E

E2

e

f (e-b)

K

Package thickness

0.95

0.00

0.15

---

2.90

1.65

2.90

1.49

---

0.15

---

0.25

0.075

1.00

0.02

0.20

1.05

0.05

0.25

---

3.10

1.75

3.10

1.59

---

0.25

---

0.35

---

Lead finger (pad) seating height

Lead finger (pad) width

Lead frame (pad) height

Package width

0.15 REF

3.00

Exposed pad width

Package length

1.70

3.00

1.54

0.40

Exposed pad length

Lead finger-finger (pad-pad) pitch

Lead-lead (Pad-Pad) space

Lead (pad) to Exposed Pad Space

Lead (pad) length

Lead (pad) corner radius

Corner lead (pad) outer radius to corner

lead outer radius

0.20

0.35 REF

0.30

L

R

REF

s

y

---

0.00

0.25 REF

---

0.075

Page 39 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

10 Part Number Package Marking

The part number package marking for MPU-9250 devices is summarized below:

Part Number

Part Number Package Marking

MP92

MPU-9250

Page 40 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

11 Reliability

11.1 Qualification Test Policy

InvenSense’s products complete a Qualification Test Plan before being released to production. The

Qualification Test Plan for the MPU-9250 followed the JEDEC JESD 47I Standard, “Stress-Test-Driven

Qualification of Integrated Circuits,” with the individual tests described below.

11.2 Qualification Test Plan

Accelerated Life Tests

TEST

Method/Condition

Lot

Quantity

Sample

/ Lot

Acc /

Reject

Criteria

(HTOL/LFR)

High Temperature Operating Life

JEDEC JESD22-A108D

Dynamic, 3.63V biased, Tj>125°C

[read-points: 168, 500, 1000 hours]

3

77

(0/1)

(HAST)

JEDEC JESD22-A118A

Condition A, 130°C, 85%RH, 33.3 psia., unbiased

[read-point: 96 hours]

Highly Accelerated Stress Test ⁽¹⁾

(HTS)

JEDEC JESD22-A103D

High Temperature Storage Life

Condition A, 125°C Non-Bias Bake

[read-points: 168, 500, 1000 hours]

Device Component Level Tests

Method/Condition

TEST

Lot

Quantity

Sample

/ Lot

Acc /

Reject

Criteria

(ESD-HBM)

ESD-Human Body Model

JEDEC JS-001-2012

(2KV)

1

3

6

(0/1)

(ESD-MM)

ESD-Machine Model

JEDEC JESD22-A115C

(250V)

(ESD-CDM)

ESD-Charged Device Model

JEDEC JESD22-C101E

(500V)

(LU)

JEDEC JESD-78D

Latch Up

Class II (2), 125°C; ±100mA

1.5X Vdd Over-voltage

(MS)

Mechanical Shock

JEDEC JESD22-B104C, Mil-Std-883, Method

2002.5 Cond. E, 10,000g’s, 0.2ms,

±X, Y, Z – 6 directions, 5 times/direction

3

1

3

5

(0/1)

(VIB)

Vibration

JEDEC JESD22-B103B

Variable Frequency (random), Cond. B, 5-500Hz,

X, Y, Z – 4 times/direction

(TC)

JEDEC JESD22-A104D

Condition G [-40°C to +125°C], Soak Mode 2 [5’]

[read-Point: 1000 cycles]

77

Temperature Cycling ⁽¹⁾

(1) Tests are preceded by MSL3 Preconditioning in accordance with JEDEC JESD22-A113F

Page 41 of 42

Document Number: PS-MPU-9250A-01

Revision: 1.1

Release Date: 06/20/2016

MPU-9250 Product Specification

12 Reference

Please refer to “InvenSense MEMS Handling Application Note (AN-IVS-0002A-00)” for the following

information:

 Manufacturing Recommendations

o

Assembly Guidelines and Recommendations

PCB Design Guidelines and Recommendations

MEMS Handling Instructions

ESD Considerations

Reflow Specification

Storage Specifications

Package Marking Specification

Tape & Reel Specification

Reel & Pizza Box Label

Packaging

Representative Shipping Carton Label

 Compliance

o

Environmental Compliance

DRC Compliance

Compliance Declaration Disclaimer

This information furnished by InvenSense is believed to be accurate and reliable. However, no responsibility is assumed by InvenSense

for its use, or for any infringements of patents or other rights of third parties that may result from its use. Specifications are subject to

change without notice. InvenSense reserves the right to make changes to this product, including its circuits and software, in order to

improve its design and/or performance, without prior notice. InvenSense makes no warranties, neither expressed nor implied, regarding

the information and specifications contained in this document. InvenSense assumes no responsibility for any claims or damages arising

from information contained in this document, or from the use of products and services detailed therein. This includes, but is not limited to,

claims or damages based on the infringement of patents, copyrights, mask work and/or other intellectual property rights.

Certain intellectual property owned by InvenSense and described in this document is patent protected. No license is granted by implication

or otherwise under any patent or patent rights of InvenSense. This publication supersedes and replaces all information previously supplied.

Trademarks that are registered trademarks are the property of their respective companies. InvenSense sensors should not be used or

sold in the development, storage, production or utilization of any conventional or mass-destructive weapons or for any other weapons or

life threatening applications, as well as in any other life critical applications such as medical equipment, transportation, aerospace and

nuclear instruments, undersea equipment, power plant equipment, disaster prevention and crime prevention equipment.

MotionApps, DMP, and the InvenSense logo are trademarks of InvenSense, Inc. Other company and product names may be trademarks

of the respective companies with which they are associated.

Page 42 of 42


型号：	MPU-9250
厂家：	TDK ELECTRONICS
描述：	IMU (惯性测量设备)
文件：	总42页 (文件大小：939K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

MPU-9250 [TDK]

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