User's Guide
SNAA066B – May 2009 – Revised May 2013
AN-1948 LMV1090 Noise Suppression Microphone
Amplifier Evaluation Kit
1
Overview
The LMV1090TL evaluation kit contains the following:
• LMV1090TL Demonstration Board, 551600317–001
• Mini USB Board, 551600192–002
• Control Software
• Microphone board
• Microphone cable
• I2C cable
MIC 1
MIC
CABLE
LMV1090TL Demo
Board
MIC 2
Connect via 6 pin
connector
MICROPHONE
BOARD
Mini-USB Board
GUI (Control
Software)
PC
Mini USB 2.0 to USB
cable
Figure 1. Basic Evaluation System
2
Introduction
The LMV1090 demo board (Figure 2) offers the means for easy evaluation of the LMV1090 Dual input,
Far Field Noise Suppression (FFNS) Microphone Amplifier with Differential Outputs. This board has the
LMV1090TL mounted on the PCB together with surrounding components ready for evaluation. This board
offers interfaces for connecting two microphones and an I2C interface for controlling the settings of the
LMV1090.
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1
General Description
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Figure 2. LMV1090TL Demo Board
3
General Description
The LMV1090 is a fully analog dual input, differential output, microphone array amplifier designed to
reduce background acoustic noise, while delivering superb speech clarity in voice communications
applications. The LMV1090 has two differential input microphone amplifier channels plus far-field noise
suppression (FFNS) circuitry. The LMV1090 preserves near-field wire signals within 4cm of the
microphones. While rejecting far-field acoustic noise greater than 50cm from the microphones. Up to 20dB
of far-field rejection is possible in a properly configured and using ±0.5dB matched microphones.
4
Operating Conditions
•
•
•
5
Temperature Range -40°C ≤ TA ≤ 85°C
Power Supply Voltage 2.7V ≤ VDD ≤ 5.5V
I2C supply voltage 1.7V ≤ I2CVDD ≤ 5.5V
LMV1090 Demo Board
The LMV1090TL Demonstration Board takes analog inputs from two microphones and performs the Far
Field noise cancellation process. It outputs an analog differential signal. This output can be connected to a
recording device, such as a personal computer sound card through its LINE IN/MIC IN input or mobile
phone through its MIC IN input, for evaluation purposes.
The LMV1090TL contains programmable pre and post gain amplifiers, which can be adjusted through I2C
commands and the software GUI. See Section 8.
The LMV1090TL has four operating modes:
• Noise cancellation
• Mic1 enabled
• Mic2 enabled
• Mic1 + Mic2
The operating modes can all be controlled through I2C commands and the software GUI. See Section 8.
2
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Power Supply of the LMV1090 Demo Board
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Power Supply of the LMV1090 Demo Board
The LMV1090 demo board provides three possible sources for the power supply:
• Using the external supply via header J12 for VDD and GND. I2CVDD pin can get its supply from the VDD
pin by placing a jumper across J21 and J22. See Figure 3.
• Using a small battery placed in battery holder mounted on the PCB. See Figure 4. For a limited time,
the demo board can be operated from the board battery (CR1220 placed in the battery holder BT1). To
operate the board using a battery, the following jumpers: J26, J21, and J22 must be configured as
shown in Figure 4.
• Via the I2C interface header J20. See Figure 5. This is the default configuration of the LMV1090TL
demonstration board when received by customer. Using this configuration and a mini USB board
eliminates the need for a separate power supply for evaluation. Supplying the demo board is possible
by generating jumpers on headers J21 and J22.
6.1
Enable Pin
The enable pin must be logic high for operating the on board LMV1090. This is done by placing a jumper
on header J25 (see Figure 5).
Apply Vdd and GND
on header J12
remove current jumpers on
J21 and J22. Put jumper
across these pins shorting
J21 and J22,
Figure 3. Power Supply Connectors and Headers
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Power Supply of the LMV1090 Demo Board
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Take current jumper
off and connect to
BAT and middle pin
remove current
jumpers on J21 and
J22. Put jumper
across these pins
shorting J21 and
J22
Figure 4. Battery Power Supply
EN,
Enable
pin
VDD
I2C VDD
Figure 5. I2C Power Supply
4
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The On Board I2C Compatible Interface
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The On Board I2C Compatible Interface
The I2C Compatible Interface that is available on the LMV1090 demo board is located at the header J20
(see Figure 6). The signals on this header are described in Table 1.
SCL
I2CVDD
SDA
GND
GND
Figure 6. Demo Board I2C Mic Inputs
Table 1. I2C Connector
PIN
Function
1
SCL
2
I2CVDD
3
NC
4
GND
5
SDA
6
NC
The SCL pin and the SDA pin both have a 10kΩ pull-up resistor to I2CVDDmounted on the PCB.
Figure 6 shows how the mini USB board should be connected to the LMV1090TL demo board. Note the
USB cable should be connected away from the board. The supply voltage for the I2C interface of the
LMV1090 can be selected with the jumper J22. To avoid possible damages to the LMV1090 part, the
I2CVDD voltage should not exceed the VDD voltage.
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LMV1090 Control Demo Software
8
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LMV1090 Control Demo Software
Together with the LMV1090 demo board, there is a software package available that can assist in
evaluation, programming, and testing of the LMV1090 chip via the I2C Interface. This software is operated
via the graphical user interface as shown in Figure 7. This software provides two groups of functions.
There are four buttons in the top of the screen that allows the following:
• Enable and Disable the microphone amplifiers
• Muting the microphone input amplifier
• Default button for resetting part on the left side of the screen is the mode
The 4 buttons on the side select the 4 modes: Noise Cancellation Mode, Only MIC 1 On, Only MIC 2 On,
and MIC 1 + MIC 2.
On the right side of the screen are 2 slide bars that control the preamplifier and postamplifier gains.
Figure 7. Control Demo Software GUI
6
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Connecting Microphones to the LMV1090 Demo Board
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9
Connecting Microphones to the LMV1090 Demo Board
The demo board can be used to connect a set of two microphones to the LMV1090 to evaluate the
performance of the LMV1090 in a customer application. To enable these microphone input connectors, the
jumpers on header J11 and J16 (see Figure 9) must be placed between pin 3–5 and pin 4–6 of both
headers. Microphones can also be connected to 3.5mm connectors J9 and J15 (see Figure 6).
For a optimal performance of the Far Field Noise Reduction system it is important to find the correct
placement of the microphones. In many applications the microphones are placed next to each other with a
distance of 1.5cm to 2.5cm between the microphones. The best noise cancelling performance will occur in
systems where the far field signals comes from a source orthogonal to the plane of the microphones and
where the desired signal is close to the microphones and is located in line with the microphones as shown
in Figure 8.
FAR
NOISE
LMV1090
OPTIMIZED
SPEECH
NEAR
SPEECH
Figure 8. Orientation of Microphones and Sound Sources
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Microphone Placement in the Application
10
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Microphone Placement in the Application
Because the LMV1090 is a microphone array Far Field Noise Reduction solution, proper microphone
placement is critical for optimum performance. Two things need to be considered: The spacing between
the two microphones and the position of the two microphones relative to near field source.
If the spacing between the two microphones is too small, near field speech will be canceled along with the
far field noise. Conversely, if the spacing between the two microphones is large, the far field noise
reduction performance will be degraded. The optimum spacing between Mic 1 and Mic 2 is 1.5-2.5cm.
This range provides a balance of minimal near field speech loss and maximum far field noise reduction.
The microphones should be in line with the desired sound source 'near speech' and configured in an
endfire array orientation from the sound source (see Figure 9). If the 'near speech' (desired sound source)
is equidistant to the source like a broadside array (see Figure 10) the result will be a great deal of near
field speech loss.
LMV1090
1.5~2.5 cm
OPTIMIZED
SPEECH
NEAR
SPEECH
CORRECT
Figure 9. Endfire Array (Correct)
NEAR
SPEECH
LMV1090
OPTIMIZED
SPEECH
WRONG
Figure 10. Broadside Array (Incorrect)
8
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PCB Layout Guidelines
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11
PCB Layout Guidelines
This section provides general practical guidelines for PCB layouts that use various power and ground
traces. Designers should note that these are only "rule-of-thumb" recommendations and the actual results
are predicated on the final layout.
11.1 Differential Signals
Keep both signals coupled by routing them closely together and keeping them of equal length. Keep all
impedances in both traces of the signal equal.
11.2 Power and Ground
Connect all ground pins together under the part forming a star point. Keep the current for the de-coupling
capacitor of the REF pin B4and the accompanying ground pin B1separated from the other currents. Keep
the location of the supply de-coupling capacitor close to VDD pin C1 and ground.
12
Description of Headers and Connectors of the LMV1090 Demo Board
The LMV1090 demo board provides many headers and connectors for connecting test equipment and
controlling the settings of the part, see Table 2. The function that is controlled by the jumpers on the
LMV1090 demo board is also indicated on the PCB in silk screen as shown in Figure 11 (The name in
parenthesis is as shown in the silk screen).
Table 2. Connector and Header Functions
Designator
Function or Use
J12
Power supply connector for external supply
J26
Supply select pin external (VDD) or battery (BAT)
J11, J16
Connection for input of electrical test signals at
pin 4+5
J8, J10
Low pass filter selection (LPF+, LPF-)
J25
Enable pin
J21
I2CVDD connect to I2C interface
J22
VDD connect to I2C interface
J25
Enable pin
J26
Supply select pin external (VDD) or battery (BAT)
J27
Connects Supply to VDD pin
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Comment
Pin 3+4 differential input with ground at Pin 5+6
Pin 1+2 to connect to an external LPF capacitor.
Pin 2+3 select the on board LPF capacitor C5,
C14 (a minimum of 1nF is always mounted on the
board)
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Copyright © 2009–2013, Texas Instruments Incorporated
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Schematic
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Schematic
10
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Layout
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14
Layout
EN
Figure 11. Layout, Silk Screen
Figure 12. Layout, Top Layer
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Layout
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Figure 13. Layout, Top Inner Layer
Figure 14. Layout, Bottom Inner Layer
12
AN-1948 LMV1090 Noise Suppression Microphone Amplifier Evaluation Kit
Copyright © 2009–2013, Texas Instruments Incorporated
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Layout
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Figure 15. Layout, Bottom Layer
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Bill of Materials
15
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Bill of Materials
Designator
Component
Value
Tolerance
Rating
Package Type
Capacitor Ceramic
1.0μF
10%
16V
0603
Capacitor Ceramic
10000pF
10%
50V
0603
C3, C4, C7, C8, C9
Capacitor Ceramic
0.47pF
10%
16V
0603
C5, C14
No Load
C5A, C14A
Capacitor Ceramic
1nF
10%
100V
0603
C10, C13
Capacitor Ceramic
1μF
10%
16V
0603
C11
No Load
C12
Capacitor Tantalum
100μF
10%
10V
Case C
R1, R2, R4, R5
Resistor
1.1k
1%
1/10W
0603
R3
Resistor
100k
1%
1/10W
0603
R9, R10
Resistor
10k
1%
1/10W
0603
J12, J13, J14, J20,
J21, J22, J23, J24,
J25, J27
Connector Header Brkway .100
02POS STR
U1
LMV1090
C15, C16
C2
No Load
No Load
J8, J10, J20, J26
Connector Header Brkway .100
06POS STR
J11, J16
Connector Header Brkway .100
06POS VERT
J9, J15, J28
5 Pole Headphone conn jack stereo
3.5mm horizontal
GND
Ground hook jumper 5mm high
mount
BT1
Battery holder CR1220, 1 cell 12mm
J8_SH, J10_SH,
Jumper Shunt 0.100” 30μin AU (no
J11_SH1, J11_SH2, handle)
J16_SH2, J21_SH,
J22_SH, J25_SH,
J26_SH, J27_SH
16
14
Revision History
Rev
Date
1.0
05/21/09
Initial release.
Description
1.01
06/30/09
Corrected graphic 30092061.
AN-1948 LMV1090 Noise Suppression Microphone Amplifier Evaluation Kit
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