EVAL-SSM2306_15 Datasheet, PDF(5/8 Page) Analog Devices – Evaluation Board for 2 W, Filterless, Class-D Stereo Audio Amplifier

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EVAL-SSM2306_15 Datasheet, PDF (5/8 Pages) Analog Devices – Evaluation Board for 2 W, Filterless, Class-D Stereo Audio Amplifier

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3. Place the decoupling capacitors for the beads (C11 to C14

and C23 to C26) as close to the amplifier chip as possible,

and connect all their ground terminals together, as shown

in Figure 4. The same principle applies to the decoupling

capacitors for the inductors (C15 to C18) if inductors are

used in the application design. Ideally, solder their ground

terminals together; do not rely on PCB tracks or ground

planes to connect their ground terminals together.

4. Place the first decoupling capacitor for the power supply

(C19) as close to the amplifier chip as possible, and connect

its ground terminal directly to the IC GND pins (Pin 13

and Pin 16), as shown in Figure 4.

5. Place the other decoupling capacitor for the power supply

(C20) as close to the amplifier chip as possible, and connect

its ground terminal to the PCB ground area from which

the power supply traces come.

6. Place the bead for the power supply (B5) as close to the

amplifier chip as possible, and keep it on the same side of

the PCB as the chip.

COPPER

FILL

B1 B2 C12 C11

C24

C23

C19

C25

C26

B4 B3 C13 C14

SMALL

INDUCTOR

OUTPUT

TRACK

INPUT

TRACK

Figure 4. Placement and Routing of the Decoupling Capacitors

7. The ferrite beads and their 1 nF decoupling capacitors can

block EMI up to 250 MHz. To eliminate EMI higher than

250 MHz, place a low value, small size capacitor, such as a

100 pF, 0402 size capacitor, in parallel with the decoupling

capacitors, C11, C12, C13, and C14. Place these small capa-

citors (C23, C24, C25, and C26) at least 20 mm away from

the 1 nF decoupling capacitors. Ideally, the ground terminals

of these small capacitors should be connected to the ground

terminals of the 1 nF decoupling capacitors or to the PCB

traces, which are placed as close to the output loads (the

loudspeakers) as possible. In this way, the PCB connecting

EVAL-SSM2306

trace between these two capacitors serves as an inductor

for filtering out the high frequency component, as shown

in Figure 4.

8. Decouple the input port nodes and the digital pins (Pin 3,

Pin 4, Pin 5, Pin 8, and Pin 9) with small capacitors, such

as 100 pF. These capacitors (C5, C6, C7, and C8) are not

required, but they can lower the EMI from these pins. The

ground terminals of these capacitors should be connected

as close to the chip ground as possible (see Figure 7).

9. Ground the unconnected pins, Pin 6 and Pin 7.

10. Connect the GND pins, Pin 13 and Pin 16, to the thermal

pad and place grounding vias, as shown in Figure 7, Figure 8,

and Figure 9.

11. Use a solid polygon plane on the other side of the PCB for

the area of the vias that are placed on the thermal pad of

the chip. See Figure 10 or Figure 11. This polygon serves as

both the EMI shielding ground plane and the heat sink for

the SSM2306.

12. Keep the PCB traces of high EMI nodes on the same side of

the PCB and as short as possible. The high EMI nodes on

the SSM2306 are Pin 1, Pin 2, Pin 11, and Pin 12.

13. The incoming and outgoing PCB track connections to the

decoupling capacitors should not be connected to each

other. An example of a correct layout is shown in Figure 4.

An example of an incorrect layout is shown in Figure 5.

COPPER

FILL

B1 B2 C12 C11

C24

C23

C19

C25

C26

INPUT

TRACK

B4 B3 C13 C14

SMALL

INDUCTOR

OUTPUT

TRACK

Figure 5. Incorrect Routing for the Output Decoupling Capacitors

The SSM2306 evaluation board works well only if these

techniques are implemented in the PCB design to keep EMI

and amplifier temperature low.

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