CS35L32 Datasheet, PDF(19/51 Page) Cirrus Logic – Boosted Class D Amplifier with Speaker-Protection Monitoring and Flash LED Drivers

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CS35L32 Datasheet, PDF (19/51 Pages) Cirrus Logic – Boosted Class D Amplifier with Speaker-Protection Monitoring and Flash LED Drivers

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4.7.1 Error Conditions

Table 4-3 lists overtemperature error status and mask bits.

CS35L32

4.8 Signal Monitoring

Table 4-3. Die Temperature Monitoring Configuration

Error

Cross-Reference to Register Field Description

Overtemperature error/Overtemperature error mask

OTE p. 41/M_OTE p. 40

Overtemperature warning/Overtemperature warning mask OTW p. 41/M_OTW p. 40

Overtemperature error release

OTE_RLS p. 40

The overtemperature error and warning error conditions are described in detail in the following:

â¢ Overtemperature warning (OTW). An OTW event occurs when the die temperature exceeds the overtemperature

threshold (listed in Table 3-3). When this occurs, an OTW (see p. 41) event is registered in the interrupt status

(Section 7.19); if M_OTW = 0, INT is asserted.

To exit the condition, the temperature must drop below the threshold and interrupt status 1 register must be read.

â¢ Overtemperature error (OTE). An OTE event occurs when the die temperature exceeds the internally preset error

threshold (see Table 3-3). When this occurs, an OTE (see p. 41) event is registered in the interrupt status and, if

M_OTE = 0, INT is asserted. The CS35L32 shuts down, the Class D amplifier enters Speaker Safe Mode, as

described in Section 4.3.4, and the LED drivers shut down.

To exit, the temperature must drop below the overtemperature shutdown threshold and OTE_RLS must be

sequenced as described in Section 7.15. After OTE release, the amplifier and LED drivers recover to preshutdown

settings. The LED drivers must be retriggered with FLEN and/or FLINH inputs for a lighting event to occur.

4.8 Signal Monitoring

Signal-monitoring ADCs, shown in Fig. 4-5, give upstream system processors access to important signals entering and

exiting the device. The three monitoring signals are as follows:

â¢ VPMON: Monitors the voltage on the VP pin, which is most commonly the battery for the system.

â¢ VMON: Monitors the output voltage of the Class D amplifier.

â¢ IMON: Monitors the current that flows into the load being driven by the Class D amplifier.

An integrated ADC digitizes these analog signals, at which point, the audio/data serial port (ADSP) can send them to the

system processor.

VP (3.0â5.25 V)

VSENSE+

VSENSEâ

Signal Monitoring

(PDN_xMON = 0)

Multibit

ïï ADC

VMON ADC Front End

Multibit

ïï ADC

ISENSE+

ISENSEâ

IMON ADC Front End

Multibit

ïï ADC

Range Scaling

â30 to +36 dB

6-dB steps

IMON_SCALE on p. 38

Figure 4-5. Signal Monitoring Block Diagram (PDN_xMON = 0)

To Audio/

Data Serial

port

4.8.1 Power-Up and Power-Down Bits (PDN_xMON)

The three ADCs can be powered down independently via their respective PDN_xMON bit in the control port, see

Section 7.6. To power down an ADC and its associated support circuitry, its PDN_xMON bit must be set; clearing PDN_

xMON powers up the corresponding circuitry.

Note: For proper operation, MCLK must be at the correct frequency (MCLK_ERR = 0; see p. 41) and the device must

be powered (PDN_ALL = 0; see p. 36).

DS963F5

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