4 ADC/8 DAC with PLL,

192 kHz, 24-Bit CODEC

AD1939

Rev. 0

Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700

www.analog.com

Fax: 781.461.3113

FEATURES

PLL generated or direct master clock
Low EMI design
112 dB DAC/107 dB ADC dynamic range and SNR
-94 dB THD + N
Single 3.3 V supply
Tolerance for 5 V logic inputs
Supports 24-bits and 8 kHz to 192 kHz sample rates
Differential ADC input
Differential DAC output
Log volume control with autoramp function
SPI® controllable for flexibility
Software controllable clickless mute
Software power-down
Right-justified, left-justified, I

S, and TDM modes

Master and slave modes up to 16-channel in/out
64-lead LQFP package

APPLICATIONS

Automotive audio systems
Home Theater Systems
Set-top boxes
Digital audio effects processors

GENERAL DESCRIPTION

The AD1939 is a high performance, single-chip codec that
provides four analog-to-digital converters (ADCs) with
differential input and eight digital-to-analog converters (DACs)
with differential output using the Analog Devices, Inc. patented
multibit sigma-delta (-) architecture. An SPI port is included,
allowing a microcontroller to adjust volume and many other
parameters. The AD1939 operates from 3.3 V digital and analog
supplies. The AD1939 is available in a 64-lead (differential
output) LQFP package.

The AD1939 is designed for low EMI. This consideration is
apparent in both the system and circuit design architectures.
By using the on-board PLL to derive the master clock from the
LR clock or from an external crystal, the AD1939 eliminates
the need for a separate high frequency master clock and can
also be used with a suppressed bit clock. The digital-to-analog
and analog-to-digital converters are designed using the latest
ADI continuous time architectures to further minimize EMI.
By using 3.3 V supplies, power consumption is minimized,
further reducing emissions.

FUNCTIONAL BLOCK DIAGRAM

DIGITAL

FILTER

SERIAL DATA PORT

DIGITAL AUDIO

INPUT/OUTPUT

PRECISION

VOLTAGE

REFERENCE

TIMING MANAGEMENT

AND CONTROL

(CLOCK AND PLL)

CONTROL PORT

SPI/I

CONTROL DATA

INPUT/OUTPUT

AD1939

ADC

ANALOG

AUDIO

INPUTS

ANALOG

AUDIO

OUTPUTS

DAC

DIGITAL

FILTER

AND

VOLUME

CONTROL

SDATA

OUT

SDATA

CLOCKS

Figure 1.

AD1939

Rev. 0 | Page 2 of 32

TABLE OF CONTENTS

Features .............................................................................................. 1

Applications....................................................................................... 1

General Description ......................................................................... 1

Functional Block Diagram .............................................................. 1

Revision History ............................................................................... 2

Specifications..................................................................................... 3

Test Conditions............................................................................. 3

Analog Performance Specifications ........................................... 3

Crystal Oscillator Specifications................................................. 4

Digital Input/Output Specifications........................................... 5

Power Supply Specifications........................................................ 5

Digital Filters................................................................................. 6

Timing Specifications .................................................................. 6

Absolute Maximum Ratings............................................................ 8

Thermal Resistance ...................................................................... 8

ESD Caution.................................................................................. 8

Pin Configuration and Function Descriptions............................. 9

Typical Performance Characteristics ........................................... 11

Theory of Operation ...................................................................... 13

Analog-to-Digital Converters (ADCs).................................... 13

Digital-to-Analog Converters (DACs) .................................... 13

Clock Signals............................................................................... 13

Reset and Power-Down ............................................................. 14

Serial Control Port ..................................................................... 14

Power Supply and Voltage Reference....................................... 15

Serial Data Ports--Data Format............................................... 15

Time-Division Multiplexed (TDM) Modes............................ 15

Daisy-Chain Mode ..................................................................... 19

Control Registers ............................................................................ 24

Definitions................................................................................... 24

PLL and Clock Control Registers............................................. 24

DAC Control Registers .............................................................. 25

ADC Control Registers.............................................................. 27

Additional Modes....................................................................... 29

Application Circuits ....................................................................... 30

Outline Dimensions ....................................................................... 31

Ordering Guide .......................................................................... 31

REVISION HISTORY

7/06--Revision 0: Initial Version

AD1939

Rev. 0 | Page 3 of 32

SPECIFICATIONS

TEST CONDITIONS

Performance of all channels is identical, exclusive of the interchannel gain mismatch and interchannel phase deviation specifications.

Supply voltages (AVDD, DVDD)

3.3 V

Temperature range

as specified in Table 1 and Table 2

Master clock

12.288 MHz (48 kHz f

, 256 × f

mode)

Input sample rate

48 kHz

Measurement bandwidth

20 Hz to 20 kHz

Word width

24 bits

Load capacitance (digital output)

20 pF

Load current (digital output)

±1 mA or 1.5 k to ½ DVDD supply

Input voltage HI

2.0 V

Input voltage LO

0.8 V

Functionally guaranteed at -40°C to +125°C case temperature.

ANALOG PERFORMANCE SPECIFICATIONS

Specifications guaranteed at 25°C (ambient).

Table 1.

Parameter Conditions/Comments

Min

Typ

Max

Unit

ANALOG-TO-DIGITAL

CONVERTERS

ADC Resolution

All ADCs

Bits

Dynamic Range

20 Hz to 20 kHz, -60 dB input

No Filter (RMS)

102

With A-Weighted Filter (RMS)

105

Total Harmonic Distortion + Noise

-1 dBFS

-96

-87

Gain

Error

-10

+10 %

Interchannel Gain Mismatch

-0.25

+0.25

Offset

Error

-10 0

+10 mV

Gain

Drift

100 ppm/°C

Interchannel

Isolation

-110 dB

CMRR

100 mV rms, 1 kHz

100 mV rms, 20 kHz

Input

Resistance

Input

Capacitance

Input Common-Mode Bias Voltage

1.5

DIGITAL-TO-ANALOG

CONVERTERS

Dynamic Range

20 Hz to 20 kHz, -60 dB input

No Filter (RMS)

102

107

With A-Weighted Filter (RMS)

105

110

With A-Weighted Filter (Avg)

112

Total Harmonic Distortion + Noise

0 dBFS

Two channels running

-94

Eight channels running

-86

-76

Full-Scale Output Voltage

1.76 (4.96)

V rms (V p-p)

Gain

Error

-10

+10 %

Interchannel Gain Mismatch

-0.2

+0.2

Offset

Error

-25 -6

+25 mV

Gain

Drift

-30

+30 ppm/°C

Interchannel

Isolation

100 dB

Interchannel Phase Deviation

Degrees

AD1939

Rev. 0 | Page 4 of 32

Parameter Conditions/Comments

Min

Typ

Max

Unit

Volume

Control

Step

0.375 dB

Volume

Control

Range

De-emphasis Gain Error

±0.6

Output Resistance at Each Pin

100

REFERENCE

Internal Reference Voltage

FILTR pin

1.50

External Reference Voltage

FILTR pin

1.32

1.50

1.68

Common-Mode Reference Output

CM pin

1.50

REGULATOR

Input Supply Voltage

VSUPPLY pin

4.5

5.5

Regulated Output Voltage

VSENSE pin

3.19

3.37

3.55

Specifications measured at 130°C (case).

Table 2.

Parameter Conditions/Comments

Min

Typ

Max

Unit

ANALOG-TO-DIGITAL CONVERTERS

ADC Resolution

All ADCs

Bits

Dynamic Range

20 Hz to 20 kHz, -60 dB input

No Filter (RMS)

102

With A-Weighted Filter (RMS)

104

Total Harmonic Distortion + Noise

-1 dBFS

-96

-87

Gain Error

-10

+10

Interchannel Gain Mismatch

-0.25

+0.25

Offset Error

-10

+10

DIGITAL-TO-ANALOG CONVERTERS

Dynamic Range

20 Hz to 20 kHz, -60 dB input

No Filter (RMS)

101

107

With A-Weighted Filter (RMS)

104

110

With A-Weighted Filter (Average)

112

Total Harmonic Distortion + Noise

0 dBFS

Two channels running

-94

Eight channels running

-86

-70

Full-Scale Output Voltage

1.76 (4.96)

V rms (V p-p)

Gain Error

-10

+10

Interchannel Gain Mismatch

-0.2

+0.2

Offset Error

-25

-6

+25

Gain Drift

-30

+30

ppm/°C

REFERENCE

Internal Reference Voltage

FILTR pin

1.50

External Reference Voltage

FILTR pin

1.32

1.50

1.68

Common-Mode Reference Output

CM pin

1.50

REGULATOR

Input Supply Voltage

VSUPPLY pin

4.5

5.5

Regulated Output Voltage

VSENSE pin

3.2

3.43

3.65

CRYSTAL OSCILLATOR SPECIFICATIONS

Table 3.

Parameter

Min

Typ

Max

Unit

Transconductance

3.5

mmhos

AD1939

Rev. 0 | Page 5 of 32

DIGITAL INPUT/OUTPUT SPECIFICATIONS

-40°C < T

< +130°C, DVDD = 3.3 V ± 10%.

Table 4.

Parameter Conditions/Comments

Min

Typ

Max

Unit

Input Voltage HI (V

)

2.0

Input Voltage HI (V

) MCLKI/XI

2.2

Input Voltage LO (V

)

0.8

Input Leakage

@ V

= 2.4 V

@ V

= 0.8 V

High Level Output Voltage (V

)

= 1 mA

DVDD - 0.60

Low Level Output Voltage (V

)

= 1 mA

0.4

Input Capacitance

POWER SUPPLY SPECIFICATIONS

Table 5.

Parameter Conditions/Comments

Min

Typ

Max

Unit

SUPPLIES

Voltage

DVDD

3.0

3.3

3.6

AVDD

3.0

3.3

3.6

Digital Current

MCLK = 256 f

Normal Operation

= 48 kHz

= 96 kHz

= 192 kHz

Power-Down f

= 48 kHz to 192 kHz

2.0

Analog Current

Normal Operation

Power-Down

DISSIPATION

Operation

MCLK = 256 f

, 48 kHz

All Supplies

429

Digital Supply

185

Analog Supply

244

Power-Down, All Supplies

POWER SUPPLY REJECTION RATIO

Signal at Analog Supply Pins

1 kHz 200 mV p-p

20 kHz 200 mV p-p

AD1939

Rev. 0 | Page 6 of 32

DIGITAL FILTERS

Table 6.

Parameter Mode

Factor

Min

Typ

Max

Unit

ADC DECIMATION FILTER

All modes, typ @ 48 kHz

Pass Band

0.4375 f

21 kHz

Pass-Band Ripple

±0.015

Transition Band

0.5 f

24 kHz

Stop Band

0.5625 f

27 kHz

Stop-Band Attenuation

Group Delay

22.9844/f

479 s

DAC INTERPOLATION FILTER

Pass Band

48 kHz mode, typ @ 48 kHz

0.4535 f

22 kHz

96 kHz mode, typ @ 96 kHz

0.3646 f

kHz

192 kHz mode, typ @ 192 kHz

0.3646 f

70 kHz

Pass-Band Ripple

48 kHz mode, typ @ 48 kHz

±0.01

96 kHz mode, typ @ 96 kHz

±0.05

192 kHz mode, typ @ 192 kHz

±0.1

Transition Band

48 kHz mode, typ @ 48 kHz

0.5 f

24 kHz

96 kHz mode, typ @ 96 kHz

0.5 f

48 kHz

192 kHz mode, typ @ 192 kHz

0.5 f

96 kHz

Stop Band

48 kHz mode, typ @ 48 kHz

0.5465 f

26 kHz

96 kHz mode, typ @ 96 kHz

0.6354 f

61 kHz

192 kHz mode, typ @ 192 kHz

0.6354 f

122 kHz

Stop-Band Attenuation

48 kHz mode, typ @ 48 kHz

96 kHz mode, typ @ 96 kHz

192 kHz mode, typ @ 192 kHz

Group Delay

48 kHz mode, typ @ 48 kHz

25/f

521 s

96 kHz mode, typ @ 96 kHz

11/f

115 s

192 kHz mode, typ @ 192 kHz

8/f

42 s

TIMING SPECIFICATIONS

-40°C < T

< +130°C, DVDD = 3.3 V ± 10%.

Table 7.

Parameter Condition

Comments

Min

Max

Unit

INPUT MASTER CLOCK (MCLK)
AND RESET

MCLK duty cycle

DAC/ADC clock source = PLL clock @ 256 f

, 384 f

512 f

, 768 f

40 60 %

DAC/ADC clock source = direct MCLK @ 512 f

(bypass

on-chip PLL)

40 60 %

MCLK

MCLK frequency

PLL mode, 256 f

reference

6.9

13.8

MHz

MCLK

Direct 512 f

mode

27.6

MHz

PDR

Low

PDRR

Recovery

Reset to active output

4096

MCLK

PLL

Lock time

MCLK and LRCLK
input

256 f

VCO Clock

Output Duty Cycle

MCLKO/XO pin

AD1939

Rev. 0 | Page 7 of 32

Parameter Condition

Comments

Min

Max

Unit

SPI PORT

See Figure 11

CCH

CCLK high

CCL

CCLK low

CCLK

CCLK frequency

CCLK

= 1/t

CCP

; only t

CCP

shown in Figure 11

MHz

CDS

CDATA setup

To CCLK rising

CDH

CDATA hold

From CCLK rising

CLS

CLATCH setup

To CCLK rising

CLH

CLATCH hold

From CCLK falling

CLHIGH

CLATCH high

Not shown in Figure 11

10 ns

COE

COUT enable

From CCLK falling

COD

COUT delay

From CCLK falling

COH

COUT hold

From CCLK falling, not shown in Figure 11

30 ns

COTS

COUT tri-state

From CCLK falling

DAC SERIAL PORT

See Figure 24

DBH

DBCLK high

Slave mode

DBL

DBCLK low

Slave mode

DLS

DLRCLK setup

To DBCLK rising, slave mode

DLH

DLRCLK hold

From DBCLK rising, slave mode

DLS

DLRCLK skew

From DBCLK falling, master mode

-8

DDS

DSDATA setup

To DBCLK rising

DDH

DSDATA hold

From DBCLK rising

ADC SERIAL PORT

See Figure 25

ABH

ABCLK high

Slave mode

ABL

ABCLK low

Slave mode

ALS

ALRCLK setup

To ABCLK rising, slave mode

ALH

ALRCLK hold

From ABCLK rising, slave mode

ALS

ALRCLK skew

From ABCLK falling, master mode

-8

ABDD

ASDATA delay

From ABCLK falling

AUXILIARY INTERFACE

AXDS

AAUXDATA setup

To AUXBCLK rising

AXDH

AAUXDATA hold

From AUXBCLK rising

DXDD

DAUXDATA delay

From AUXBCLK falling

XBH

AUXBCLK high

XBL

AUXBCLK low

DLS

AUXLRCLK setup

To AUXBCLK rising

DLH

AUXLRCLK hold

From AUXBCLK rising

AD1939

Rev. 0 | Page 8 of 32

ABSOLUTE MAXIMUM RATINGS

Table 8.

Parameter Rating

Analog (AVDD)

-0.3 V to +3.6 V

Digital (DVDD)

-0.3 V to +3.6 V

VSUPPLY

-0.3 V to +6.0 V

Input Current (Except Supply Pins)

±20 mA

Analog Input Voltage (Signal Pins)

0.3 V to AVDD + 0.3 V

Digital Input Voltage (Signal Pins)

-0.3 V to DVDD + 0.3 V

Operating Temperature Range (Case)

-40°C to +125°C

Storage Temperature Range

-65°C to +150°C

Stresses above those listed under the Absolute Maximum
Ratings may cause permanent damage to the device. This is a
stress rating only; functional operation of the device at these or
any other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.

THERMAL RESISTANCE

represents thermal resistance, junction-to-ambient;

represents the thermal resistance, junction-to-case.

All characteristics are for a 4-layer board.

Table 9. Thermal Resistance

Package Type

Unit

64-lead LQFP

11.1

°C/W

ESD CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on
the human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.

AD1939

Rev. 0 | Page 9 of 32

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

ADC2RN

ADC2RP

ADC2L

ADC1RN

ADC1RP

ADC1L

BCL

RCL

SEN

DRI

BCL

RCL

ADR0

/
S

AGND

MCLKI/XI

MCLKO/XO

AGND

AVDD

OL3P

OL3N

OR3P

OR3N

OL4P

OL4N

OR4P

OR4N

PD/RST

DSDATA4

DGND

AGND

FILTR

AGND

AVDD

AGND

OR2N

OR2P

OL2N

OL2P

OR1N

OR1P

OL1P

CLATCH/ADR1

CCLK/SCL

DGND

OL1N

AD1939

TOP VIEW

(Not to Scale)

DIFFERENTIAL

OUTPUT

NC = NO CONNECT

0
21

Figure 2. 64-Lead LQFP, Differential Output, Pin Configuration

Table 10. Pin Function Descriptions

Pin No.

In/Out

Mnemonic

Description

1 I AGND

Analog

Ground.

MCLKI/XI

Master Clock Input/Crystal Oscillator Input.

MCLKO/XO

Master Clock Output/Crystal Oscillator Output.

4 I AGND

Analog

Ground.

AVDD

Analog Power Supply. Connect to analog 3.3 V supply.

OL3P

DAC 3 Left Positive Output.

OL3N

DAC 3 Left Negative Output.

OR3P

DAC 3 Right Positive Output.

OR3N

DAC 3 Right Negative Output.

OL4P

DAC 4 Left Positive Output.

OL4N

DAC 4 Left Negative Output.

OR4P

DAC 4 Right Positive Output.

OR4N

DAC 4 Right Negative Output

14 I PD/RST

Power-Down Reset (Active Low).

I/O

DSDATA4

DAC Input 4 (Input to DAC 4 L and R)/DAC TDM Data Out 2/AUX ADC 1 Data In.

16 I DGND

Digital

Ground.

DVDD

Digital Power Supply. Connect to digital 3.3 V supply.

I/O

DSDATA3

DAC Input 3 (Input to DAC 3 L and R)/DAC TDM Data In 2/Aux DAC 2 Data Output.

I/O

DSDATA2

DAC Input 2 (Input to DAC 2 L and R)/DAC TDM Data Out 1/AUX ADC 1 Data In.

DSDATA1

DAC Input 1 (Input to DAC 1 L and R)/DAC TDM Data In 1/AUX ADC 2 Data In.

I/O

DBCLK

Bit Clock for DACs.

I/O

DLRCLK

LR Clock for DACs.

VSUPPLY

+5 V Input to Regulator, Emitter of Pass Transistor.

VSENSE

+3.3 V Output of Regulator, Collector of Pass Transistor.

AD1939

Rev. 0 | Page 10 of 32

Pin No.

In/Out

Mnemonic

Description

VDRIVE

Drive for Base of Pass Transistor.

I/O

ASDATA2

ADC Serial Data Output 2 (ADC 2 L and R)/ADC TDM Data Input/Aux DAC 1 Data Output.

ASDATA1

ADC Serial Data Output 1 (ADC 1 L and R)/ADC TDM Data Output.

I/O

ABCLK

Bit Clock for ADCs.

I/O

ALRCLK

LR Clock for ADCs.

CIN/ADR0

Control Data Input (SPI).

I/O

COUT/SDA

Control Data Output (SPI).

DVDD

Digital Power Supply. Connect to digital 3.3 V supply.

33 I DGND

Digital

Ground.

CCLK/SCL

Control Clock Input (SPI).

35 I CLATCH/ADR1

Latch Input for Control Data (SPI).

OL1P

DAC 1 Left Positive Output.

OL1N

DAC 1 Left Negative Output.

OR1P

DAC 1 Right Positive Output.

OR1N

DAC 1 Right Negative Output.

OL2P

DAC 2 Left Positive Output.

OL2N

DAC 2 Left Negative Output.

OR2P

DAC 2 Right Positive Output.

OR2N

DAC 2 Right Negative Output

44 I AGND

Analog

Ground.

AVDD

Analog Power Supply. Connect to analog 3.3 V supply.

46 I AGND

Analog

Ground.

FILTR

Voltage Reference Filter Capacitor Connection. Bypass with 10 F||100 nF to AGND.

48 I AGND

Analog

Ground.

49 NC

Connect.

50 NC

Connect.

AVDD

Analog Power Supply. Connect to analog 3.3 V supply.

52 O CM

Common-Mode Reference Filter Capacitor Connection. Bypass with
47 F||100 nF to AGND.

ADC1LP

ADC1 Left Positive Input.

ADC1LN

ADC1 Left Negative Input.

ADC1RP

ADC1 Right Positive Input.

ADC1RN

ADC1 Right Negative Input.

ADC2LP

ADC2 Left Positive Input.

ADC2LN

ADC2 Left Negative Input.

ADC2RP

ADC2 Right Positive Input.

ADC2RN

ADC2 Right Negative Input.

PLL Loop Filter, Return to AVDD.

AVDD

Analog Power Supply. Connect to analog 3.3 V supply.

63 NC

Connect.

64 NC

Connect.

AD1939

Rev. 0 | Page 11 of 32

TYPICAL PERFORMANCE CHARACTERISTICS

0.10

0.08

0.06

0.04

0.02

0.10

0.08

0.06

0.04

0.02

(

FREQUENCY (kHz)

Figure 3. ADC Pass-Band Filter Response, 48 kHz

10

20

30

40

50

60

70

80

90

100

UDE

(

FREQUENCY (kHz)

1
-
00

Figure 4. ADC Stop-Band Filter Response, 48 kHz

0.06

0.04

0.02

0.06

0.04

0.02

I
T

UDE

(

FREQUENCY (kHz)

0
04

Figure 5. DAC Pass-Band Filter Response, 48 kHz

150

100

50

UDE

(

FREQUENCY (kHz)

005

Figure 6. DAC Stop-Band Filter Response, 48 kHz

0.10

0.05

I
T

UDE

(

FREQUENCY (kHz)

0
06

Figure 7. DAC Pass-Band Filter Response, 96 kHz

150

100

50

UDE

(

FREQUENCY (kHz)

007

Figure 8. DAC Stop-Band Filter Response, 96 kHz

AD1939

Rev. 0 | Page 13 of 32

THEORY OF OPERATION

ANALOG-TO-DIGITAL CONVERTERS (ADCS)

There are four analog-to-digital converter (ADC) channels in
the AD1939 configured as two stereo pairs with differential
inputs. The ADCs can operate at a nominal sample rate of 48 kHz,
96 kHz, or 192 kHz. The ADCs include on-board digital anti-
aliasing filters with 79 dB stop-band attenuation and linear
phase response, operating at an oversampling ratio of 128
(48 kHz, 96 kHz, and 192 kHz modes). Digital outputs are
supplied through two serial data output pins (one for each
stereo pair) and a common frame clock (ALRCLK) and bit
clock (ABCLK). Alternatively, one of the TDM modes can be
used to access up to 16 channels on a single TDM data line.

The ADCs must be driven from a differential signal source for
best performance. The input pins of the ADCs connect to internal
switched capacitors. To isolate the external driving op amp from
the glitches caused by the internal switched capacitors, each in-
put pin should be isolated by using a series-connected external
100 resistor together with a 1 nF capacitor connected from
each input to ground. This capacitor must be of high quality, for
example, ceramic NPO or polypropylene film.

The differential inputs have a nominal common-mode voltage
of 1.5 V. The voltage at the common-mode reference pin (CM)
can be used to bias external op amps to buffer the input signals
(see the Power Supply and Voltage Reference section). The
inputs can also be ac-coupled and do not need an external dc
bias to CM.

A digital high-pass filter can be switched in line with the ADCs
under serial control to remove residual dc offsets. It has a 1.4 Hz,
6 dB per octave cutoff at a 48 kHz sample rate. The cutoff fre-
quency scales directly with sample frequency.

DIGITAL-TO-ANALOG CONVERTERS (DACS)

The AD1939 digital-to-analog converter (DAC) channels are
arranged as differential, four stereo pairs giving eight analog
outputs for improved noise and distortion performance. The
DACs include on-board digital reconstruction filters with 70 dB
stop-band attenuation and linear phase response, operating at an
oversampling ratio of 4 (48 kHz or 96 kHz modes) or 2 (192 kHz
mode). Each channel has its own independently programmable
attenuator, adjustable in 255 steps in increments of 0.375 dB.
Digital inputs are supplied through four serial data input pins
(one for each stereo pair) and a common frame clock (DLRCLK)
and bit clock (DBCLK). Alternatively, one of the TDM modes can
be used to access up to 16 channels on a single TDM data line.

Each output pin has a nominal common-mode dc level of 1.5 V
and swings ±1.27 V for a 0 dBFS digital input signal. A single op
amp, third-order, external, low-pass filter is recommended to
remove high frequency noise present on the output pins, as well
as to provide differential-to-single-ended conversion in the case
of the differential output. Note that the use of op amps with low

slew rate or low bandwidth can cause high frequency noise and
tones to fold down into the audio band; exercise care in
selecting these components.

The voltage at CM, the common-mode reference pin, can be
used to bias the external op amps that buffer the output signals
(see the Power Supply and Voltage Reference section).

CLOCK SIGNALS

The on-chip phase locked loop (PLL) can be selected to
reference the input sample rate from either of the LRCLK pins
or 256, 384, 512, or 768 times the sample rate, referenced to the
48 kHz mode from the MCLKI/XI pin. The default at power-up
is 256 × f

from MCLKI/XI. In 96 kHz mode, the master clock

frequency stays at the same absolute frequency; therefore, the
actual multiplication rate is divided by 2. In 192 kHz mode,
the actual multiplication rate is divided by 4. For example, if a
device in the AD1939 family is programmed in 256 × f

mode, the

frequency of the master clock input is 256 × 48 kHz = 12.288 MHz.
If the AD1939 is then switched to 96 kHz operation (by writing
to the SPI or I

C® port), the frequency of the master clock

should remain at 12.288 MHz, which is 128 × f

in this example.

In 192 kHz mode, this becomes 64 × f

The internal clock for the ADCs is 256 × f

for all clock modes.

The internal clock for the DACs varies by mode: 512 × f

(48 kHz

mode), 256 × f

(96 kHz mode), or 128 × f

(192 kHz mode). By

default, the on-board PLL generates this internal master clock
from an external clock. A direct 512 × f

(referenced to 48 kHz

mode) master clock can be used for either the ADCs or DACs if
selected in PLL and Clock Control 1 register.

Note that it is not possible to use a direct clock for the ADCs set
to the 192 kHz mode. It is required that the on-chip PLL be
used in this mode.

The PLL can be powered down in the PLL and Clock Control 0
register. To ensure reliable locking when changing PLL modes,
or if the reference clock is unstable at power-on, power down
the PLL and then power it back up when the reference clock has
stabilized.

The internal master clock (MCLK) can be disabled in the PLL
and Clock Control 0 register to reduce power dissipation when
the AD1939 is idle. The clock should be stable before it is
enabled. Unless a standalone mode is selected (see the Serial
Control Port section), the clock is disabled by reset and must be
enabled by writing to the SPI or I

C port for normal operation.

To maintain the highest performance possible, it is recommended
that the clock jitter of the internal master clock signal be limited
to less than 300 ps rms TIE (time interval error). Even at these
levels, extra noise or tones can appear in the DAC outputs if the
jitter spectrum contains large spectral peaks. If the internal PLL
is not being used, it is best to use an independent crystal oscillator

AD1939

Rev. 0 | Page 14 of 32

to generate the master clock. In addition, it is especially
important that the clock signal should not be passed through an
FPGA, CPLD, or other large digital chip (such as a DSP) before
being applied to the AD1939. In most cases, this induces clock
jitter due to the sharing of common power and ground
connections with other unrelated digital output signals. When
the PLL is used, jitter in the reference clock is attenuated above
a certain frequency depending on the loop filter.

RESET AND POWER-DOWN

Reset sets all the control registers to their default settings. To
avoid pops, reset does not power down the analog outputs.
After reset is deasserted and the PLL acquires lock condition,
an initialization routine runs inside the AD1939. This
initialization lasts for approximately 256 MCLKs.

The power-down bits in the PLL and Clock Control 0, DAC
Control 1, and ADC Control 1 registers power down the
respective sections. All other register settings are retained. The
reset pin should be pulled low by an external resistor to
guarantee proper startup.

SERIAL CONTROL PORT

The AD1939 has an SPI control port that permits programming
and reading back of the internal control registers for the ADCs,
DACs, and clock system. A standalone mode is also available for
operation without serial control; it is configured at reset using the
serial control pins. All registers are set to default, except the
internal MCLK enable is set to 1 and ADC BCLK and LRCLK
master/slave is set by the COUT/SDA pin. Standalone mode
only supports stereo mode with an I

S data format and 256 f

MCLK rate. Refer to Table 11 for details. It is recommended to
use a weak pull-up resistor on CLATCH in applications that
have a microcontroller. This pull-up resistor ensures that the
AD1939 recognizes the presence of a microcontroller.

The SPI control port of the AD1939 is a 4-wire serial control
port. The format is similar to the Motorola SPI format except
the input data-word is 24 bits wide. The serial bit clock and
latch can be completely asynchronous to the sample rate of the
ADCs and DACs. Figure 11 shows the format of the SPI signal.
The first byte is a global address with a read/write bit. For the
AD1939 the address is 0x04, shifted left one bit due to the R/W
bit. The second byte is the AD1939 register address and the
third byte is the data.

Table 11. Standalone Mode Selection

ADC Clocks

CIN/ADR0

COUT/SDA

CCLK/SCL

CLATCH/ADR1

Slave 0 0

0 0

Master 0

0 0

D22

D23

CLATCH

CCLK

CIN

COUT

CCH

CCL

CDS

CDH

CLS

CCP

CLH

COTS

COD

COE

Figure 11. Format of SPI Signal

AD1939

Rev. 0 | Page 15 of 32

POWER SUPPLY AND VOLTAGE REFERENCE

The AD1939 is designed for 3.3 V supplies. Separate power
supply pins are provided for the analog and digital sections.
To minimize noise pickup, these pins should be bypassed with
100 nF ceramic chip capacitors placed as close to the pins as
possible. A bulk aluminum electrolytic capacitor of at least
22 F should also be provided on the same PC board as the
codec. For critical applications, improved performance is
obtained with separate supplies for the analog and digital sections.
If this is not possible, it is recommended that the analog and
digital supplies be isolated by means of a ferrite bead in series
with each supply. It is important that the analog supply be as
clean as possible.

The AD1939 includes a 3.3 V regulator driver that only requires
an external pass transistor and bypass capacitors to make a 5 V
to 3.3 V regulator. If the regulator driver is not used, connect
VSUPPLY, VDRIVE, and VSENSE to DGND.

All digital inputs are compatible with TTL and CMOS levels.
All outputs are driven from the 3.3 V DVDD supply and are
compatible with TTL and 3.3 V CMOS levels.

The ADC and DAC internal voltage reference (V

REF

) is brought

out on FILTR and should be bypassed as close as possible to the
chip with a parallel combination of 10 F and 100 nF. Any
external current drawn should be limited to less than 50 A.

The internal reference can be disabled in the PLL and Clock
Control 1 register and FILTR can be driven from an external
source. This can be used to scale the DAC output to the clipping
level of a power amplifier based on its power supply voltage.
The ADC input gain varies by the inverse ratio. The total gain
from ADC input to DAC output remains constant.

The CM pin is the internal common-mode reference. It should
be bypassed as close as possible to the chip, with a parallel
combination of 47 F and 100 nF. This voltage can be used to
bias external op amps to the common-mode voltage of the input
and output signal pins. The output current should be limited to
less than 0.5 mA source and 2 mA sink.

SERIAL DATA PORTS--DATA FORMAT

The eight DAC channels use a common serial bit clock (DBCLK)
and a common left-right framing clock (DLRCLK) in the serial
data port. The four ADC channels use a common serial bit
clock (ABCLK) and left-right framing clock (ALRCLK) in the
serial data port. The clock signals are all synchronous with the
sample rate. The normal stereo serial modes are shown in
Figure 23.

The ADC and DAC serial data modes default to I

S. The ports

can also be programmed for left-justified, right-justified, and
TDM modes. The word width is 24 bits by default and can be
programmed for 16 or 20 bits. The DAC serial formats are
programmable according to the DAC Control 0 register. The

polarity of DBCLK and DLRCLK is programmable according to
the DAC Control 1 register. The ADC serial formats and serial
clock polarity are programmable according to the ADC Control 1
register. Both DAC and ADC serial ports are programmable to
become the bus masters according to DAC Control 1 register
and ADC Control 2 register. By default, both ADC and DAC
serial ports are in the slave mode.

TIME-DIVISION MULTIPLEXED (TDM) MODES

The AD1939 serial ports also have several different TDM serial
data modes. The first and most commonly used configurations
are shown in Figure 12 and Figure 13. In Figure 12, the ADC
serial port outputs one data stream consisting of four on-chip
ADCs followed by four unused slots. In Figure 13, the eight on-
chip DAC data slots are packed into one TDM stream. In this
mode, both DBCLK and ABCLK are 256 f

SLOT 1

LEFT 1

SLOT 2

RIGHT 1

SLOT 3

LEFT 2

SLOT 4

RIGHT 2

MSB

MSB1

MSB2

DATA

BCLK

LRCLK

SLOT 5

SLOT 6

SLOT 7

SLOT 8

LRCLK

BCLK

DATA

256 BCLKs

32 BCLKs

060

71-

016

Figure 12. ADC TDM (8-Channel I

S Mode)

SLOT 1

LEFT 1

SLOT 2

RIGHT 1

SLOT 3

LEFT 2

SLOT 4

RIGHT 2

MSB

MSB1

MSB2

DATA

BCLK

LRCLK

SLOT 5

LEFT 3

SLOT 6

RIGHT 3

SLOT 7

LEFT 4

SLOT 8

RIGHT 4

LRCLK

BCLK

DATA

256 BCLKs

32 BCLKs

0
607

0
17

Figure 13. DAC TDM (8-Channel I

S Mode)

The I/O pins of the serial ports are defined according to the
serial mode that is selected. For a detailed description of the
function of each pin in TDM and AUX modes, see Table 12.

The AD1939 allows systems with more than eight DAC channels
to be easily configured by the use of an auxiliary serial data port.
The DAC TDM-AUX mode is shown in Figure 14. In this mode,
the AUX channels are the last four slots of the TDM data stream.
These slots are extracted and output to the AUX serial port. It
should be noted that due to the high DBCLK frequency, this mode
is available only in the 48 kHz/44.1 kHz/32 kHz sample rate.

The AD1939 also allows system configurations with more than
four ADC channels as shown in Figure 15 (using 8 ADCs) and
Figure 16 (using 16 ADCs). Again, due to the high ABCLK fre-
quency, this mode is available only in the 48 kHz/44.1 kHz/32 kHz
sample rate.

AD1939

Rev. 0 | Page 16 of 32

Combining the AUX ADC and DAC modes results in a system
configuration of 8 ADCs and 12 DACs. The system, then, con-
sists of two external stereo ADCs, two external stereo DACs,

and one AD1939. This mode is shown in Figure 17 (combined
AUX DAC and ADC modes).

Table 12. Pin Function Changes in TDM and AUX Modes

Mnemonic

Stereo Modes

TDM Modes

AUX Modes

ASDATA1

ADC1 Data Out

ADC TDM Data Out

TDM Data Out

ASDATA2

ADC2 Data Out

ADC TDM Data In

AUX Data Out 1 (to Ext. DAC 1)

DSDATA1

DAC1 Data In

DAC TDM Data In

TDM Data In

DSDATA2

DAC2 Data In

DAC TDM Data Out

AUX Data In 1 (from Ext. ADC 1)

DSDATA3

DAC3 Data In

DAC TDM Data In 2 (Dual-Line Mode)

AUX Data In 2 (from Ext. ADC 2)

DSDATA4

DAC4 Data In

DAC TDM Data Out 2 (Dual-Line Mode)

AUX Data Out 2 (to Ext. DAC 2)

ALRCLK

ADC LRCLK In/Out

ADC TDM Frame Sync In/Out

TDM Frame Sync In/Out

ABCLK

ADC BCLK In/Out

ADC TDM BCLK In/Out

TDM BCLK In/Out

DLRCLK

DAC LRCLK In/Out

DAC TDM Frame Sync In/Out

AUX LRCLK In/Out

DBCLK

DAC BCLK In/Out

DAC TDM BCLK In/Out

AUX BCLK In/Out

LEFT

RIGHT

MSB

ALRCLK

ABCLK

DSDATA1

(TDM_IN)

DLRCLK

(AUX PORT)

DBCLK

(AUX PORT)

ASDATA2

(AUX1_OUT)

DSDATA4

(AUX2_OUT)

MSB

EMPTY

DAC L1 DAC R1 DAC L2 DAC R2 DAC L3 DAC R3 DAC L4 DAC R4 AUX L1 AUX R1 AUX L2 AUX R2

8-ON-CHIP DAC CHANNELS

AUXILIARY DAC CHANNELS

WILL APPEAR AT

AUX DAC PORTS

UNUSED SLOTS

32 BITS

-
051

Figure 14. 16-Channel DAC TDM-AUX Mode

AD1939

Rev. 0 | Page 19 of 32

DAISY-CHAIN MODE

The AD1939 also allows a daisy-chain configuration to expand
the system to 8 ADCs and 16 DACs (see Figure 18). In this
mode, the DBCLK frequency is 512 f

. The first eight slots of the

DAC TDM data stream belong to the first AD1939 in the chain
and the last eight slots belong to the second AD1939. The second
AD1939 is the device attached to the DSP TDM port.

To accommodate 16 channels at a 96 kHz sample rate, the
AD1939 can be configured into a dual-line, TDM mode as
shown in Figure 19. This mode allows a slower DBCLK than
normally required by the one-line TDM mode.

Again, the first four channels of each TDM input belong to the
first AD1939 in the chain and the last four channels belong to
the second AD1939.

The dual-line TDM mode can also be used to send data at a
192 kHz sample rate into the AD1939 as shown in Figure 20.

There are two configurations for the ADC port to work in
daisy-chain mode. The first one is with an ABCLK at 256 f

shown in Figure 21. The second configuration is shown in
Figure 22. Note that in the 512 f

ABCLK mode, the ADC

channels occupy the first eight slots; the second eight slots are
empty. The TDM_IN of the first AD1939 must be grounded in
all modes of operation.

The I/O pins of the serial ports are defined according to the
serial mode selected. See Table 13 for a detailed description of
the function of each pin. See Figure 26 for a typical AD1939
configuration with two external stereo DACs and two external
stereo ADCs.

Figure 23 through Figure 25 show the serial mode formats. For
maximum flexibility, the polarity of LRCLK and BCLK are
programmable. In these figures, all of the clocks are shown with
their normal polarity. The default mode is I

DLRCLK

DBCLK

8 DAC CHANNELS OF THE FIRST IC IN THE CHAIN

8 UNUSED SLOTS

8 DAC CHANNELS OF THE SECOND IC IN THE CHAIN

MSB

DSDATA1 (TDM_IN)

OF THE SECOND AD1939

DSDATA2 (TDM_OUT)

OF THE SECOND AD1939

THIS IS THE TDM

TO THE FIRST AD1939

DAC L1 DAC R1 DAC L2 DAC R2 DAC L3 DAC R3 DAC L4 DAC R4 DAC L1 DAC R1 DAC L2 DAC R2 DAC L3 DAC R3 DAC L4 DAC R4

DAC L1 DAC R1 DAC L2 DAC R2 DAC L3 DAC R3 DAC L4 DAC R4

32 BITS

DSP

SECOND

AD1939

FIRST

AD1939

0
54

Figure 18. Single-Line DAC TDM Daisy-Chain Mode (Applicable to 48 kHz Sample Rate, 16-Channel, Two-AD1939 Daisy Chain)

AD1939

Rev. 0 | Page 20 of 32

DLRCLK

DBCLK

8 DAC CHANNELS OF THE SECOND IC IN THE CHAIN

8 DAC CHANNELS OF THE FIRST IC IN THE CHAIN

DSDATA1

(IN)

DAC L1

DAC R1

DAC L2

DAC R2

DAC L1

DAC R1

DAC L2

DAC R2

DSDATA3

(IN)

DAC L3

DAC R3

DAC L4

DAC R4

DAC L3

DAC R3

DAC L4

DAC R4

DSDATA2

(OUT)

DAC L1

DAC R1

DAC L2

DAC R2

DSDATA4

(OUT)

DAC L3

DAC R3

DAC L4

DAC R4

32 BITS

DSP

SECOND

AD1939

FIRST

AD1939

MSB

Figure 19. Dual-Line DAC TDM Mode (Applicable to 96 kHz Sample Rate, 16-Channel, Two-AD1939 Daisy Chain); DSDATA3 and DSDATA4 Are the Daisy Chain

DLRCLK

DBCLK

DSDATA1

DAC L1

DAC R1

DAC L2

DAC R2

DSDATA2

DAC L3

DAC R3

DAC L4

DAC R4

32 BITS

MSB

0
58

Figure 20. Dual-Line DAC TDM Mode (Applicable to 192 kHz Sample Rate, 8-Channel Mode)

ALRCLK

ABCLK

ASDATA2 (TDM_IN

OF THE SECOND AD1939

IN THE CHAIN)

ADC L1

ADC R1

ADC L2

ADC R2

4 ADC CHANNELS OF FIRST IC IN THE CHAIN

4 ADC CHANNELS OF SECOND IC IN THE CHAIN

ASDATA1 (TDM_OUT

OF THE SECOND AD1939

IN THE CHAIN)

ADC L1

ADC R1

ADC L2

ADC R2

ADC L1

ADC R1

ADC L2

ADC R2

32 BITS

MSB

DSP

SECOND

AD1939

FIRST

AD1939

Figure 21. ADC TDM Daisy-Chain Mode (256 f

ABCLK, Two-AD1939 Daisy Chain)

AD1939

Rev. 0 | Page 21 of 32

ALRCLK

ABCLK

4 ADC CHANNELS OF

SECOND IC IN THE CHAIN

4 ADC CHANNELS OF

FIRST IC IN THE CHAIN

ADC L1 ADC R1 ADC L2 ADC R2 ADC L1 ADC R1 ADC L2 ADC R2

ASDATA1 (TDM_OUT

OF THE SECOND AD1939

IN THE CHAIN)

ADC L1 ADC R1 ADC L2 ADC R2

ASDATA2 (TDM_IN

OF THE SECOND AD1939

IN THE CHAIN)

32 BITS

MSB

DSP

SECOND

AD1939

FIRST

AD1939

Figure 22. ADC TDM Daisy-Chain Mode (512 f

ABCLK, Two-AD1939 Daisy Chain)

LRCLK

BCLK

SDATA

LRCLK

BCLK

SDATA

LRCLK

BCLK

SDATA

LSB

LEFT CHANNEL

RIGHT CHANNEL

LEFT CHANNEL

RIGHT CHANNEL

MSB

RIGHT-JUSTIFIED MODE--SELECT NUMBER OF BITS PER CHANNEL

DSP MODE--16 BITS TO 24 BITS PER CHANNEL

S MODE--16 BITS TO 24 BITS PER CHANNEL

LEFT-JUSTIFIED MODE--16 BITS TO 24 BITS PER CHANNEL

LRCLK

BCLK

SDATA

LSB

NOTES
1. DSP MODE DOES NOT IDENTIFY CHANNEL.
2. LRCLK NORMALLY OPERATES AT

EXCEPT FOR DSP MODE, WHICH IS 2 ×

3. BCLK FREQUENCY IS NORMALLY 64 × LRCLK BUT MAY BE OPERATED IN BURST MODE.

MSB

0
13

Figure 23. Stereo Serial Modes

AD1939

Rev. 0 | Page 23 of 32

Table 13. Pin Function Changes in TDM and AUX Modes (Replication of Table 12)

Mnemonic

Stereo Modes

TDM Modes

AUX Modes

ASDATA1

ADC1 Data Out

ADC TDM Data Out

TDM Data Out

ASDATA2

ADC2 Data Out

ADC TDM Data In

AUX Data Out 1 (to Ext. DAC 1)

DSDATA1

DAC1 Data In

DAC TDM Data In

TDM Data In

DSDATA2

DAC2 Data In

DAC TDM Data Out

AUX Data In 1 (from Ext. ADC 1)

DSDATA3

DAC3 Data In

DAC TDM Data In 2 (Dual-Line Mode)

AUX Data In 2 (from Ext. ADC 2)

DSDATA4

DAC4 Data In

DAC TDM Data Out 2 (Dual-Line Mode)

AUX Data Out 2 (to Ext. DAC 2)

ALRCLK

ADC LRCLK In/Out

ADC TDM Frame Sync In/Out

TDM Frame Sync In/Out

ABCLK

ADC BCLK In/Out

ADC TDM BCLK In/Out

TDM BCLK In/Out

DLRCLK

DAC LRCLK In/Out

DAC TDM Frame Sync In/Out

AUX LRCLK In/Out

DBCLK

DAC BCLK In/Out

DAC TDM BCLK In/Out

AUX BCLK In/Out

AUX

ADC 1

LRCLK

BCLK

DATA

MCLK

AUX

ADC 2

LRCLK

BCLK

DATA

MCLK

AUX

DAC 1

AUX

DAC 2

LRCLK
BCLK

DATA
MCLK

LRCLK
BCLK

DATA
MCLK

30MHz

12.288MHz

SHARC IS RUNNING IN SLAVE MODE

(INTERRUPT-DRIVEN)

SHARC

AD1939

TDM MASTER

AUX MASTER

-
TD

M (

)

RxCL

RxDAT

(

NC)

ASDATA2
DSDATA4

DBCLK

DLRCLK

DSDATA2

DSDATA3
MCLK

ASDATA1 ALRCLK ABCLK DSDATA1

071

-
01

Figure 26. Example of AUX Mode Connection to SHARC (AD1939 as TDM Master/AUX Master Shown)

AD1939

Rev. 0 | Page 24 of 32

CONTROL REGISTERS

DEFINITIONS

The format is the same for I

C and SPI ports. The global address for the AD1939 is 0x04, shifted left one bit due to the R/W bit. However,

in I

C, ADR0 and ADR1 are OR'ed into Bit 17 and Bit 8 to provide multiple chip addressing. All registers are reset to 0, except for the

DAC volume registers that are set to full volume.

Note that the first setting in each control register parameter is the default setting.

Table 14. Register Format

Global

Address

R/W

Register Address

Data

Bit

23:17 16

15:8

7:0

Table 15. Register Addresses and Functions

Address Function

PLL and Clock Control 0

PLL and Clock Control 1

DAC Control 0

DAC Control 1

DAC Control 2

DAC individual channel mutes

DAC 1L volume control

DAC 1R volume control

DAC 2L volume control

DAC 2R volume control

DAC 3L volume control

DAC 3R volume control

DAC 4L volume control

DAC 4R volume control

ADC Control 0

ADC Control 1

ADC Control 2

PLL AND CLOCK CONTROL REGISTERS

Table 16. PLL and Clock Control 0 Register

Bit Value Function

Description

Normal operation

PLL power-down

1 Power-down

2:1

INPUT 256 (×44.1 kHz or 48 kHz)

MCLKI/XI

INPUT 384 (×44.1 kHz or 48 kHz)

INPUT 512 (×44.1 kHz or 48 kHz)

INPUT 768 (×44.1 kHz or 48 kHz)

4:3

XTAL oscillator enabled

MCLKO/XO pin

256 × f

VCO output

512 × f

VCO output

11 Off

6:5 00

MCLKI

PLL

input

01 DLRCLK

10 ALRCLK

11 Reserved

Disable: ADC and DAC idle

Internal master clock enable

Enable: ADC and DAC active

AD1939

Rev. 0 | Page 25 of 32

Table 17. PLL and Clock Control 1 Register

Bit Value Function

Description

PLL clock

DAC clock source select

MCLK

PLL clock

ADC clock source select

MCLK

2 0

Enabled

On-chip

voltage

reference

Disabled

Not locked

PLL lock indicator (read only)

Locked

7:4 0000

Reserved

DAC CONTROL REGISTERS

Table 18. DAC Control 0 Register

Bit

Value

Function

Description

0 0

Normal

Power-down

2:1

32 kHz/44.1 kHz/48 kHz

Sample rate

64 kHz/88.2 kHz/96 kHz

128 kHz/176.4 kHz/192 kHz

Reserved

5:3

000

SDATA delay (BCLK periods)

001 0

010 8

011 12

100 16

101 Reserved

110 Reserved

111 Reserved

7:6

Stereo (normal)

Serial format

TDM

(daisy

chain)

DAC AUX mode (ADC-, DAC-, TDM-coupled)

Dual-line

TDM

Table 19. DAC Control 1 Register

Bit Value Function

Description

Latch in mid cycle (normal)

BCLK active edge (TDM in)

Latch in at end of cycle (pipeline)

2:1

64 (2 channels)

BCLKs per frame

128 (4 channels)

256 (8 channels)

512 (16 channels)

Left low

LRCLK polarity

Left

high

4 0

Slave

LRCLK

master/slave

Master

5 0

Slave

BCLK

master/slave

Master

DBCLK pin

BCLK source

Internally

generated

7 0

Normal

BCLK

polarity

Inverted

AD1939

Rev. 0 | Page 29 of 32

To relax the requirement for the setup time of the AD1939 in
cases of high speed TDM data transmission, the AD1939 can
latch in the data using the falling edge of DBCLK. This effec-
tively dedicates the entire BCLK period to the setup time. This
mode is useful in cases where the source has a large delay time
in the serial data driver. Figure 28 shows this pipeline mode of
data transmission.

ADDITIONAL MODES

The AD1939 offers several additional modes for board level
design enhancements. To reduce the EMI in board level design,
serial data can be transmitted without an explicit BCLK. See
Figure 27 for an example of a DAC TDM data transmission
mode that does not require high speed DBCLK. This configura-
tion is applicable when the AD1939 master clock is generated
by the PLL with the DLRCLK as the PLL reference frequency.

Both the BCLK-less and pipeline modes are available on the
ADC serial data port.

DLRCLK

INTERNAL

DBCLK

DSDATA

DLRCLK

INTERNAL

DBCLK

TDM-DSDATA

32 BITS

0
59

Figure 27. Serial DAC Data Transmission in TDM Format Without DBCLK

(Applicable Only If PLL Locks to DLRCLK, This Model Is Also Available in the ADC Serial Data Port)

DLRCLK

DBCLK

DSDATA

DATA MUST BE VALID

AT THIS BCLK EDGE

MSB

0
60

-
06

Figure 28. I

S Pipeline Mode in DAC Serial Data Transmission

(Applicable in Stereo and TDM, Useful for High Frequency TDM Transmission,

This Model Is Also Available in the ADC Serial Data Port)

AD1939

Rev. 0 | Page 30 of 32

APPLICATION CIRCUITS

Typical application circuits are shown in Figure 29 through Figure 32. Figure 29 shows a typical ADC input filter circuit. Recommended
loop filters for LR clock and master clock as the PLL reference are shown in Figure 30. Output filters for the DAC outputs are shown in
Figure 31 and a regulator circuit is shown in Figure 32.

OP275

120pF

600Z

AUDIO

INPUT

100pF

120pF

4.7µF

100pF

1nF

NPO

1nF

NPO

ADCxN

ADCxP

06071-

023

Figure 29. Typical ADC Input Filter Circuit

39nF

2.2nF

LRCLK

AVDD2

5.6nF

390nF

MCLK

AVDD2

0
27

Figure 30. Recommended Loop Filters for LRCLK or MCLK PLL Reference

OP275

2.2nF

NPO

AUDIO

OUTPUT

68pF

NPO

150pF

NPO

560pF

NPO

270pF

NPO

DAC

OUTN

DAC

OUTP

0
26

Figure 31. Typical DAC Output Filter Circuit (Differential)

10µF

VSUPPLY

VSENSE

3.3V

FZT953

VDRIVE

100nF

10µF

100nF

0
28

Figure 32. Recommended 3.3 V Regulator Circuit

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