ADSP-BF523C AD [Analog Devices], ADSP-BF523C Datasheet - Page 9

ADSP-BF523C

Manufacturer Part Number

ADSP-BF523C

Description

Blackfin Embedded Processor 289-ball MBGA package

Manufacturer

AD [Analog Devices]

Datasheet

1.ADSP-BF523C.pdf (44 pages)

Current page: 9 of 44
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Preliminary Technical Data

The microphone should be connected to the device as shown in

Figure

Recommended component values are C1 = 220 pF (npo

ceramic), C2 = 1 μF, R1 = 680 Ω, R2 = 47 kΩ. R

depend on the gain setting (see previous discussion).

R1 and R2 form part of the biasing network. R1 connected to

MICBIAS is necessary only for electret type microphones that

require a voltage bias. R2 should always be present to prevent

the microphone input from charging to a high voltage which

could damage the microphone upon connection. R1 and R2

should be large so as not to attenuate the signal from the micro-

phone, which can have source impedance greater than 2 kΩ. C1

together with the source impedance of the microphone and the

input impedance of MICIN forms an RF filter. C2 is a dc block-

ing capacitor that allows the microphone to be biased at a

different dc voltage than the MICIN signal.

Microphone Bias

The MICBIAS output (shown in

reference voltage suitable for biasing electret type microphones.

The external resistor biasing network is shown in

where MICBIAS is the output of the device

There is a maximum source current capability of 3 mA available

for the MICBIAS. This limits the smallest value of external bias-

ing resistors that can safely be used.

The MICBIAS output is not active in standby mode.

FROM

MICROPHONE

VMID

AGND

Figure 6. Microphone Input External Circuit

Figure 7. MICBIAS Internal Circuit

AGND

Figure

AGND

MICBIAS

7) provides a low noise

(Figure

MICBIAS

mic

Figure

MIC

values

7).

Rev. PrC | Page 9 of 44 | June 2008

MICIN

ADSP-BF523C/ADSP-BF525C/ADSP-BF527C

ADC

The CODEC uses a multi-bit oversampled sigma-delta ADC. A

single channel of the ADC is illustrated in the

of multi-bit feedback and high oversampling rates reduces the

effects of jitter and high frequency noise.

The ADC full scale input is 1.0 V(rms) at AVDD = 3.3 volts.

Any voltage greater than full scale could overload the ADC and

cause distortion. The full scale input tracks directly with AVDD.

The device uses a pair of ADCs. The input can be selected by

software from either the line inputs or the microphone input.

The two channels cannot be selected independently. The con-

trol is shown in

The digital data from the ADC is fed for signal processing to the

ADC filters.

Table 3. ADC Software Control

ADC Filters

The ADC filters perform true 24-bit signal processing to con-

vert the raw multi-bit oversampled data from the ADC to the

correct sampling frequency to be output on the digital audio

interface.

The ADC digital filters contain a digital high pass filter, select-

able via software control. There are several types of ADC

filters—frequency and phase responses of these are shown in

Address

000 0100 2

FROM

ADC

FROM

MICROPHONE

INPUT

FROM

LINE

INPUT

Figure 9

Bit Label Default Description

DIGITAL

DECIMATOR

Figure 8. MultiBit Oversampling Sigma-Delta ADC

INSEL

INSEL 0

Table

illustrates the digital filter path.

Figure 9. ADC Digital Filter

DIGITAL

DECIMATION

FILTER

ANALOG

INTEGRATOR

Microphone/Line Input Select

1 = Microphone Input Select

0 = Line Input Select

MULTIPLE

BITS

DIGITAL

HPF

HPFEN

Figure

8. The use

TO DIGITAL

AUDIO

INTERFACE

TO ADC

DIGITAL

FILTERS

ADSP-BF523C AD [Analog Devices], ADSP-BF523C Datasheet - Page 9

ADSP-BF523C

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