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Circuit Note
Devices Connected/Referenced
Circuits from the Lab™ reference circuits are engineered and
tested for quick and easy system integration to help solve today’s
analog, mixed-signal, and RF design challenges. For more
information and/or support, visit www.analog.com/CN0208.
ADAU1446
ADMP441 Digital MEMS Microphone
High Performance Digital MEMS Microphone's Simple Interface to SigmaDSP
Audio Processor with I
2
S Output
SigmaDSP® Digital Audio Processor with
Flexible Audio Routing Matrix
CN-0208
EVALUATION AND DESIGN SUPPORT
Circuit Evaluation Boards
ADAU1446 Evaluation Board (EVAL-ADAU1446EBZ)
ADMP441 Evaluation Board (EVAL-ADMP441Z-FLEX)
Design and Integration Files
Schematics, Layout Files, Bill of Materials
CIRCUIT FUNCTION AND BENEFITS
The circuit, shown in Figure 1, allows up to two digital MEMS
microphones to be interfaced to an audio processor on a single
data line. The ADMP441 consists of a MEMS microphone
element and an ASIC with I
microphones to be used in an audio system without the need
for a codec between the MEMS microphones and the processor.
Analog Devices’ MEMS microphones have a high signal-tonoise ratio (SNR) and a flat wideband frequency response,
2
S output. This allows stereo
FROM VOLTAGE
REGULATOR (3.3V)
3.3V
0.1µF
ADAU1446
BCLK0
LRCLK0
SDATA_IN0
making them an excellent choice for high performance, low
power applications.
Up to two ADMP441 MEMS microphones can be input to a single
data line on th
DAU1446 SigmaDSP® audio processor. The
e A
ADAU1446 can be set up with up to nine serial data inputs, so
up to eighteen ADMP441’s can input to a single audio processor.
CIRCUIT DESCRIPTION
The ADMP441 digital MEMS microphones are connected to the
ADAU1446’s SDATA_IN pins. The only necessary passive components
in this circuit are a
and a large p
discharge it while the ADMP441’s output drivers are tri-stated.
The bypass capacitors should be placed as close to the
ADMP441 VDD pin (Pin 7) as possible.
IOVDD
single 0.1 μF bypass capacitor for each ADMP441
ull-down resistor (100 kΩ) on the SD line to
3.3V
0.1µF
3.3V
CHIPEN
L/R
Figure 1. %JHJUBM.&.4Microphone Connection to SigmaDSP Audio Processor (Simplified Schematic: Power Supply Decoupling and All Connections Not Shown)
Rev.A
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engineers. Standard engineering practices have been employed in the desi
each circuit, and their function and performance have been tested and verified in a lab environment at
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suitability and applicability for your use and application. Accordingly, in no event shall Analog Devices
be liable for direct, indirect, special, incidental, consequential or punitive damages due to any cause
whatsoever connected to the use of any Circuits from the Lab circuits. (Continued on last page)
VDD
LEFT
ADMP441
GND GND
SCK
WS
SD
GND
gn and construction of
100kΩ
VDD
SCK
WS
SD
GND GND
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
Fax: 781.461.3113 ©2011 Analog Devices, Inc. All rights reserved.
CHIPEN
RIGHT
ADMP441
GND
L/R
3.3V
09838-001
www.analog.com
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CN-0208 Circuit Note
Figure 2. SigmaStudio Serial Input Port Configuration for ADMP441 Microphone Input to ADAU1446
The MEMS microphone’s VDD sh
source as
the ADAU1446’s 3.3 V IOVDD. Even though the
ould be supplied from the same
ADMP441 can operate with VDD between 1.8 V and 3.3 V,
IOVDD on the ADAU1446 must be 3.3 V.
There are three signals that need to be connected between the
ADMP441 and ADAU1446 for the I
2
S data stream: frame clock,
bit clock, and data. Table 1 shows the connections when using
the ADAU1446’s serial data input port 0.
Table 1. Hardware Signal Connections
Signal ADMP441 ADAU1446
Frame clock WS (pin 3) LRCLK0 (pin 15)
Bit clock SCK (pin 1) BCLK0 (pin 12)
Serial Data SD (pin 2) SDATA_IN0 (pin 11)
The L/R pin on the two ADMP441’s should be set to opposite
settings—one pulled to VDD, and the other to ground. When
pulled to GND, the microphone will output its data on the left
2
channel of the I
S stream, and when pulled to VDD, it will
output its data on the right channel.
The ADMP441 is enabled by pulling the CHIPEN pin high.
This pin can either be tied directly to the microphone’s VDD,
which will keep it always enabled while it is powered, or it could
be connected to a GPIO on the ADAU1446, allowing the
SigmaDSP to enable and disable the microphone.
The ADMP441 has a sensitivity of −26 dBFS. In most
applications, the microphone output needs to have some gain
added in the ADAU1446’s signal flow. The SigmaDSP core can
add up to 24 dB of gain to the input signal before a full-scale
signal at 120 dB SPL is clipped. If gain is added to the signal in
the SigmaDSP, then the processor’s output must still be limited
to 0 dBFS.
• LRCLK polarity set for left channel low, right channel
high.
• 24-bit, I
2
S data format.
A screenshot of the SigmaStudio register controls for the serial
input port is shown in Figure 2.
The register settings described here are for using serial input
port 0 with clock input 0, but they could be applied to any of the
nine serial input ports. Serial inputs 1–8 are controlled with
registers 0xE001 to 0xE008. If any of these serial input ports
are connected to additional ADMP441 MEMS microphones, the
corre
nding registers should be set in the same way as serial
spo
input port 0 described above.
In the SigmaStudio schematic, the data from serial input port 0
is on pins 0 and 1 of the Input cell. The left channel is on pin 0
and the right channel on pin 1. Figure 3 shows a simple
SigmaStudio schematic with two audio channels going through
a volume control to the outputs.
09838-002
Register Settings
Register 0xE000 must be set in the ADAU1446 to enable its
2
serial input port for I
S input. When this register is set to 0xA4
0x00, Serial Input Port 0 will be configured for:
• Enabling the clock outputs.
• 50% duty cycle clock.
• 48 kHz clock master.
• Data changes on the falling edge of BCLK, clocked on
the BCLK rising edge.
Rev. A | Page 2 of 4
09838-003
Figure 3. SigmaStudio Schematic with Stereo Input on Serial Input Port 0
Page 3
Circuit Note CN-0208
CIRCUIT EVALUATION AND TEST
Evaluation boards for the ADMP441 and ADAU1446 are
available and can be easily connected using headers on the
boards.
Equipment Needed
The SigmaStudio GUI software requires a PC meeting the
following: Windows® 7, Windows Vista, or Windows XP
Professional or Home Edition with SP2, 128 MB of RAM
(256 MB recommended), 50 MB of available hard disk space,
1024 × 768 screen resolution, USB 2.0 data port.
In addition, the ADAU1446 Evaluation Board
(EVA L-ADAU1446EBZ) and the ADMP441 Evaluation
Board (E VA L-ADMP441-FLEX) are needed.
Getting Started
The E VA L-ADMP441Z-FLEX has eight output wires including
VDD, ground, data, and clocks. The VDD wire should be
connected to IOVDD on the EVA L-ADAU1446EBZ. The
ADMP441 board’s serial data port signals (SD, WS, and SCK)
can be connected to the appropriate serial data inputs on
header J21.
Complete documentation for the E VA L-ADAU1446EBZ
evaluation board can be found in User Guide UG-032.
Complete documentation for the E VA L-ADMP441Z-FLEX
evaluation board can be found in User Guide UG-303.
The SigmaStudio™ software is used to program and
tune the registers and SigmaDSP core in the ADAU1446.
SigmaStudio is available to download from
www.analog.com/sigmastudiodownload.
Functional Block Diagram
The documentation for the ADAU1446 evaluation board
describes the system setup and gives a complete schematic of
the board. The only external connections required are the
USB connection to the PC and to the audio outputs of the
ADAU1446.
Setup and Test
See the EVA L-ADAU1446EBZ board documentation for
additional details regarding circuit description, jumper settings,
setup, and testing.
COMMON VARIATIONS
Audio Processors
This circuit can also be set up with an ADAU1442 or
ADAU1445 instead of the ADAU1446. The difference between
these processors is that the ADAU1446 does not have any
asynchronous sample rate converters (ASRCs), and the
ADAU1442 and ADAU1445 have different numbers of ASRC
channels. These other processors with ASRCs could be used if
microphones are to be run at different sampling rates or if
multiple I
processor. The ADAU1442, ADAU1445, and ADAU1446 are all
pin-compatible.
2
S master devices need to be connected to the
.&.4Microphones
A mono MEMS microphone circuit using a single ADMP441 can be
set up by simply removing one of the ADMP441 MEMS microphones.
The other connections remain the same in this mono configuration.
Additional ADMP441 MEMS microphones can be connected to
the ADAU
stereo pa
1446’s serial input ports in the same way as the first
ir.
LEARN MORE
CN0208 Design Support Package:
www.analog.com/CN0208-DesignSupport
Elko, Gary W. and Kieran P. Harney, "A History of Consumer
Microphones: The Electret Condenser Microphone Meets
Micro-Electro-Mechanical-Systems," Acoustics Today, April
2009.
Nielsen, Jannik Hammel Nielsen and Claus Fürst, “Toward
More Compact Digital Microphones,” Analog Dialogue.
September 2007.
Lewis, Jerad, "Microphone Specs Explained," Application Note
AN-1112, Analog Devices.
Data Sheets and Evaluation Boards
ADAU1446 Data Sheet
ADAU1446 Evaluation Board
ADMP441 Data Sheet
ADMP441 Evaluation Board
ADAU1442 Data Sheet
ADAU1445 Data Sheet
Rev. A | Page 3 of 4
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CN-0208 Circuit Note
REVISION HISTORY
12/11—Rev. 0 to Rev. A
Changes to Circuit Note Title .......................................................... 1
Changes to Circuit Function and Benefits ..................................... 1
Changes to Circuit Description ....................................................... 1
Changes to Common Variations ..................................................... 3
10/11—Revision 0: Initial Version
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CN09838-0-12/11(A
)
Rev. A | Page 4 of 4
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