SARA-G3 and SARA-U2 series - System Integration Manual
UBX-13000995 - R26
Design-in
Page 151 of 217
2.7.1.2
Guidelines for microphone and loudspeaker connection circuit design (hands-free mode)
Figure 84 shows an application circuit for the analog audio interface in hands-free mode, connecting a 2.2 k
electret microphone and an 8
or 4
loudspeaker:
External microphone can be connected to the uplink path of the module, since the module provides supply
and reference as well as differential signal input for the external microphone.
Using an 8
or 4
loudspeaker for the hands-free mode, an external audio amplifier must be provided on
the application board to amplify the low power audio signal provided by the downlink path of the module,
so that the external audio amplifier will drive the 8
or 4
loudspeaker, since differential analog audio
output of the module is able to directly drive loads with resistance rating greater than 14
.
As in the example circuit in Figure 84, follow the general guidelines for the design of an analog audio circuit for
hands-free mode:
Provide proper supply to the used electret microphone, providing a proper connection from the MIC_BIAS
supply output to the microphone. It is suggested to implement a bridge:
o
The electret microphone, with its nominal intrinsic resistance value, represents one resistor of the bridge.
o
To achieve good supply noise rejection, the ratio of the two resistance in one leg (R2/R3) should be
equal to the ratio of the two resistance in the other leg (R4/MIC), i.e. R2 must be equal to R4
(e.g. 2.2 k
) and R3 must be equal to the microphone nominal intrinsic resistance value (e.g. 2.2 k
).
Provide a series resistor at the
MIC_BIAS
supply output and then mount a good bypass capacitor to provide
additional supply noise filtering, as the R1 series resistor (2.2 k
) and the C1 bypass capacitor (10 µF).
Do not place a bypass capacitor directly at the
MIC_BIAS
supply output, since proper internal bypass
capacitor is already provided to guarantee stable operation of the internal regulator.
Connect the reference of the microphone circuit to the
MIC_GND
pin of the module as a sense line.
Provide a proper series capacitor at both
MIC_P
and
MIC_N
analog uplink inputs for DC blocking (C2 and
C3 100 nF Murata GRM155R71C104K capacitors in Figure 84). This provides a high-pass filter for the
microphone DC bias with proper cut-off frequency according to the value of the resistors of the microphone
supply circuit. Then connect the signal lines to the microphone.
Provide proper parts on each line connected to the external microphone as noise and EMI improvements, to
minimize RF coupling and TDMA noise, according to the custom application requirements.
o
Mount an 82 nH series inductor with a Self Resonance Frequency ~1 GHz (e.g. the Murata
LQG15HS82NJ02) on each microphone line (L1 and L2 inductors in Figure 84).
o
Mount a 27 pF bypass capacitor (e.g. Murata GRM1555C1H270J) from each microphone line to solid
ground plane (C4 and C5 capacitors in Figure 84).
Use a microphone designed for GSM applications, which typically have internal built-in bypass capacitor.
Provide a 47 nF series capacitor at both
SPK_P
and
SPK_N
analog downlink outputs for DC blocking (C8
and C9 Murata GRM155R71C473K capacitors in Figure 84). Then connect the lines to the differential input
of a proper external audio amplifier, differential output which must be connected to the 8
or 4
loudspeaker. (See the Analog Devices SSM2305CPZ filter-less mono 2.8 W class-D Audio Amplifier in the
circuit described in Figure 84.)
Provide proper parts on each line connected to the external loudspeaker as noise and EMI improvements, to
minimize RF coupling, according to EMC requirements of the custom application.
o
Mount a 27 pF bypass capacitor (e.g. Murata GRM1555C1H270J) from each loudspeaker line to solid
ground plane (C6 and C7 capacitors in Figure 84).
Provide additional ESD protection (e.g. Bourns CG0402MLE-18G varistor) if the analog audio lines will be
externally accessible on the application device, according to the EMC/ESD requirements of the custom
application. The protection should be mounted close to an accessible point of the line (D1-D4 parts in the
circuit described in Figure 84).