EVAL-ADXL362Z-DB Analog Devices, EVAL-ADXL362Z-DB Datasheet - Page 17

EVAL-ADXL362Z-DB

Manufacturer Part Number

EVAL-ADXL362Z-DB

Description

Acceleration Sensor Development Tools enl Datalogger Board of ADXL362

Manufacturer

Analog Devices

Datasheet

1.EVAL-ADXL362Z-S.pdf (44 pages)

Specifications of EVAL-ADXL362Z-DB

Rohs

yes

Tool Is For Evaluation Of

ADXL362

Acceleration

2 g, 4 g, 8 g

Sensing Axis

Triple Axis

Interface Type

SPI

Operating Voltage

1.6 V to 3.5 V

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Operating Current

1.8 uA

Output Type

Digital

Product

Development Boards

Sensitivity

1 mg/LSB, 2 mg/LSB, 4 mg/LSB

Factory Pack Quantity

Current page: 17 of 44
Download datasheet (2Mb)

Data Sheet

Using the AWAKE Bit

The AWAKE bit is a status bit that indicates whether the

is awake or asleep. The device is awake when it has experienced

an activity condition, and it is asleep when it has experienced an

inactivity condition.

The awake signal can be mapped to the INT1 or INT2 pin,

allowing the pin to serve as a status output to connect or dis-

connect power to downstream circuitry based on the awake

status of the accelerometer. Used in conjunction with loop

mode, this configuration implements a trivial, autonomous

motion activated switch, as shown in Figure 43.

If the turn-on time of downstream circuitry can be tolerated,

this motion switch configuration can save significant system

level power by eliminating the standby current consumption of

the remainder of the application. This standby current can often

exceed the full operating current of the ADXL362.

FIFO

The

buffer. The FIFO provides benefits primarily in two ways, as

follows.

System Level Power Savings

Appropriate use of the FIFO enables system level power savings

by enabling the host processor to sleep for extended periods of

time while the accelerometer autonomously collects data. Alter-

natively, using the FIFO to collect data can unburden the host

while it tends to other tasks.

Data Recording/Event Context

The FIFO can be used in a triggered mode to record all data

leading up to an activity detection event, thereby providing con-

text for the event. In the case of a system that identifies impact

events, for example, the accelerometer can keep the entire system

off while it stores acceleration data in its FIFO and looks for an

activity event. When the impact event occurs, data that was

collected prior to the event is frozen in the FIFO. The accel-

erometer can then wake the rest of the system and transfer this

data to the host processor, thereby providing context for the

impact event.

Generally, the more context available, the more intelligent

decisions a system can achieve, making a deep FIFO especially

useful. The

of data, providing a clear picture of events prior to an activity

trigger.

All FIFO modes of operation, as well as the structure of the FIFO

and instructions for retrieving data from it, are described in further

detail in the FIFO Modes section of this data sheet.

ADXL362

includes a deep 512-sample first in, first out (FIFO)

FIFO can store up to more than 13 seconds

ADXL362

Rev. B | Page 17 of 44

COMMUNICATIONS

SPI Instructions

The digital interface of the

system level power savings in mind. The following features

enhance power savings:

•

Bus Keepers

The

MISO, MOSI, SCLK, CS , INT1, and INT2. Bus keepers are used

to prevent tristate bus lines from floating when nothing is driving

them, thus preventing through current in any gate inputs that

are on the bus.

MSB Registers

Acceleration and temperature measurements are converted to

12-bit values and transmitted via SPI using two registers per

measurement. To read a full sample set of 3-axis acceleration

data, six registers must be read.

Many applications do not require the accuracy that 12-bit data

provides and prefer, instead, to save system level power. The MSB

registers XDATA, YDATA, and ZDATA enable this tradeoff.

These registers contain the eight MSBs of the x-, y-, and z-axis

acceleration data; reading them effectively provides 8-bit accel-

eration values. Importantly, only three (consecutive) registers

must be read to retrieve a full data set, significantly reducing the

time during which the SPI bus is active and drawing current.

12-bit and 8-bit data are available simultaneously so that both

data formats can be used in a single application, depending on

the needs of the application at a given time. For example, the pro-

cessor can read 12-bit data when higher resolution is required, and

switch to 8-bit data (simply by reading a different set of registers)

when application requirements change.

ADXL362

Burst reads and writes reduce the number of SPI

communication cycles required to configure the part

and retrieve data.

Concurrent operation of activity and inactivity detection

enables “set it and forget it” operation. Loop mode further

reduces communications power by enabling the clearing of

interrupts without processor intervention.

The FIFO is implemented such that consecutive samples

can be read continuously via a multibyte read of unlimited

length; thus, one read FIFO instruction can clear the entire

contents of the FIFO. In many other accelerometers, each

read instruction retrieves a single sample only. In addition, the

ADXL362

access (DMA) to read the FIFO contents.

FIFO construction allows the use of direct memory

includes bus keepers on all digital interface pins:

ADXL362

is implemented with

ADXL362

EVAL-ADXL362Z-DB Analog Devices, EVAL-ADXL362Z-DB Datasheet - Page 17

EVAL-ADXL362Z-DB

Specifications of EVAL-ADXL362Z-DB

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