AD AD1859 Stereo, single-supply 18-bit integrated dac Datasheet

a
Stereo, Single-Supply
18-Bit Integrated SD DAC
AD1859
FEATURES
Complete, Low Cost Stereo DAC System in a Single Die
Package
Variable Rate Oversampling Interpolation Filter
Multibit SD Modulator with Triangular PDF Dither
Discrete and Continuous Time Analog Reconstruction
Filters
Extremely Low Out-of-Band Energy
64 Step (1 dB/Step) Analog Attenuator with Mute
Buffered Outputs with 2 kV Output Load Drive
Rejects Sample Clock Jitter
94 dB Dynamic Range, –88 dB THD+N Performance
Option for Analog De-emphasis Processing with
External Passive Components
60.18 Maximum Phase Linearity Deviation
Continuously Variable Sample Rate Support
Digital Phase Locked Loop Based Asynchronous Master
Clock
On-Chip Master Clock Oscillator, Only External Crystal
Is Required
Power-Down Mode
Flexible Serial Data Port (I2S-Justified, Left-Justified,
Right-Justified and DSP Serial Port Modes)
SPI* Compatible Serial Control Port
Single +5 V Supply
28-Pin SOIC and SSOP Packages
APPLICATIONS
Digital Cable TV and Direct Broadcast Satellite Set-Top
Decoder Boxes
Digital Video Disc, Video CD and CD-I Players
High Definition Televisions, Digital Audio Broadcast
Receivers
CD, CD-R, DAT, DCC, ATAPI CD-ROM and MD Players
Digital Audio Workstations, Computer Multimedia
Products
PRODUCT OVERVIEW
The AD1859 is a complete 16-/18-bit single-chip stereo digital
audio playback subsystem. It comprises a variable rate digital
interpolation filter, a revolutionary multibit sigma-delta (∑∆)
modulator with dither, a jitter-tolerant DAC, switched capacitor
and continuous time analog filters, and analog output drive circuitry. Other features include an on-chip stereo attenuator and
mute, programmed through an SPI-compatible serial control
port.
The key differentiating feature of the AD1859 is its asynchronous master clock capability. Previous ∑∆ audio DACs required a high frequency master clock at 256 or 384 times the
intended audio sample rate. The generation and management
of this high frequency synchronous clock is burdensome to the
board level designer. The analog performance of conventional
single bit ∑∆ DACs is also dependent on the spectral purity of
the sample and master clocks. The AD1859 has a digital Phase
Locked Loop (PLL) which allows the master clock to be asynchronous, and which also strongly rejects jitter on the sample
clock (left/right clock). The digital PLL allows the AD1859 to
be clocked with a single frequency (27 MHz for example) while
the sample frequency (as determined from the left/right clock)
can vary over a wide range. The digital PLL will lock to the
new sample rate in approximately 100 ms. Jitter components
15 Hz above and below the sample frequency are rejected by
6 dB per octave. This level of jitter rejection is unprecedented
in audio DACs.
The AD1859 supports continuously variable sample rates with
essentially linear phase response, and with an option for external
analog de-emphasis processing. The clock circuit includes an
on-chip oscillator, so that the user need only provide an external
crystal. The oscillator may be overdriven, if desired, with an external clock source.
(continued on page 7)
FUNCTIONAL BLOCK DIAGRAM
DIGITAL
SUPPLY
2
AD1859
16- OR 18-BIT 6
DIGITAL DATA
INPUT
SERIAL
DATA
INTERFACE
CONTROL
DATA
INPUT
3
SERIAL
CONTROL
INTERFACE
REFERENCE
FILTER AND
GROUND
ASYNCHRONOUS
CLOCK/CRYSTAL
2
DPLL/CLOCK
MANAGER
VOLTAGE
REFERENCE
VARIABLE RATE
INTERPOLATION
MULTIBIT
∑∆ MODULATOR
DAC
ANALOG
FILTER
ATTEN/
MUTE
OUTPUT
BUFFER
VARIABLE RATE
INTERPOLATION
MULTIBIT
∑∆ MODULATOR
DAC
ANALOG
FILTER
ATTEN/
MUTE
OUTPUT
BUFFER
DE-EMPHASIS
SWITCH LEFT
COMMON MODE
ANALOG
OUTPUTS
DE-EMPHASIS
SWITCH RIGHT
2
POWER
DOWN/RESET
MUTE
DE-EMPHASIS
ANALOG
SUPPLY
*SPI is a registered trademark of Motorola, Inc.
REV. A
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
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
© Analog Devices, Inc., 1996
One Technology Way, P.O. Box 9106, Norwood. MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
AD1859–SPECIFICATIONS
TEST CONDITIONS UNLESS OTHERWISE NOTED
Supply Voltages (AVDD, DVDD)
Ambient Temperature
Input Clock (FMCLK)
Input Signal
Input Sample Rate
Measurement Bandwidth
Input Data Word Width
Load Capacitance
Input Voltage HI (VIH)
Input Voltage LO (VIL)
+5.0
V
25
°C
27.1656
MHz
1001.2938 Hz
–0.5
dB Full Scale
44.1
kHz
10 Hz to 20 kHz
18
Bits
100
pF
2.4
V
0.8
V
NOTES
I2S-Justified Mode (Ref. Figure 3).
Device Under Test (DUT) is bypassed, decoupled and dc-coupled as shown in Figure 17 (no de-emphasis circuit).
Performance of the right and left channels are identical (exclusive of “Interchannel Gain Mismatch” and “Interchannel Phase Deviation” specifications).
Attenuation setting is 0 dB.
Values in bold typeface are tested; all others are guaranteed, not tested.
ANALOG PERFORMANCE
Min
Resolution
Dynamic Range (20 to 20 kHz, –60 dB Input)
(No A-Weight Filter)
(With A-Weight Filter)
Total Harmonic Distortion + Noise
85.7
88
Analog Outputs
Single-Ended Output Range (± Full Scale)
Output Impedance at Each Output Pin
Output Capacitance at Each Output Pin
External Load Impedance (THD +N ≤ –84 dB)
Out-of-Band Energy (0.5 × FS to 100 kHz)
CMOUT
DC Accuracy
Gain Error
Interchannel Gain Mismatch
Gain Drift
Interchannel Crosstalk (EIAJ Method)
Interchannel Phase Deviation
Attenuator Step Size
Attenuator Range Span
Mute Attenuation
De-Emphasis Switch (EMPL, EMPR) DC Resistance
Typ
Max
Units
18
Bits
91
94
–88
0.004
dB
dB
dB
%
–84
0.0063
2.8
3.0
17
750
2K
2.05
2.25
–72.5
2.45
±1
0.01
140
65
0.225
270
0.6
–61.5
–70
3
± 0.1
1.0
–62.5
–74.2
10
1.4
–63.5
50
%
dB
ppm/°C
dB
Degrees
dB
dB
dB
Ω
Min
Typ
Max
Units
1
1
0.8
6
6
20
V
V
µA
µA
pF
101
3.2
24
20
V p-p
Ω
pF
Ω
dB
V
DIGITAL INPUTS
Input Voltage HI (VIH)
Input Voltage LO (VIL)
Input Leakage (IIH @ VIH = 2.4 V)
Input Leakage (IIL @ VIL = 0.8 V)
Input Capacitance
2.4
–2–
REV. A
AD1859
DIGITAL TIMING (Guaranteed over –40°C to +105°C, AVDD = DVDD = +5.0 V ± 10%)
Min
tDBH
tDBL
tDBP
tDLS
tDLH
tDDS
tDDH
tCCH
tCCL
tCCP
tCSU
tCHD
tCLD
tCLL
tCLH
tPDRP
BCLK HI Pulse Width
BCLK LO Pulse Width
BCLK Period
LRCLK Setup
LRCLK Hold (DSP Serial Port Style Mode Only)
SDATA Setup
SDATA Hold
CCLK HI Pulse Width
CCLK LO Pulse Width
CCLK Period
CDATA Setup
CDATA Hold
CLATCH Delay
CLATCH LO Pulse Width
CLATCH HI Pulse Width
PD/RST LO Pulse Width
tMCP
FMC
tMCH
tMCL
MCLK Period
MCLK Frequency (1/tMCP)
MCLK HI Pulse Width
MCLK LO Pulse Width
Typ
25
25
50
5
0
0
5
15
15
30
0
5
15
5
10
4 MCLK Periods
(≈150 ns @ 27 MHz)
30
37
17
27
15
15
Max
Units
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
60
33
ns
MHz
ns
ns
POWER
Supplies
Voltage, Analog and Digital
Analog Current
Analog Current—Power Down
Digital Current
Digital Current—Power Down
Dissipation
Operation—Both Supplies
Operation—Analog Supply
Operation—Digital Supply
Power Down—Both Supplies
Power Supply Rejection Ratio
1 kHz 300 mV p-p Signal at Analog Supply Pins
20 kHz 300 mV p-p Signal at Analog Supply Pins
Min
Typ
Max
Units
4.5
29.5
5
36
0.5
30
6
5.5
mA
15
mA
9.5
V
265
147.5
117.5
30
330
180
150
48
mW
mW
mW
mW
23.5
55
52
µA
mA
dB
dB
TEMPERATURE RANGE
Min
Specifications Guaranteed
Functionality Guaranteed
Storage
Typ
Max
Units
+105
+125
°C
°C
°C
25
–40
–55
PACKAGE CHARACTERISTICS
SOIC θJA (Thermal Resistance [Junction-to-Ambient])
SOIC θJC (Thermal Resistance [Junction-to-Case])
SSOP θJA (Thermal Resistance [Junction-to-Ambient])
SSOP θJC (Thermal Resistance [Junction-to-Case])
REV. A
–3–
Typ
Units
120.67
13.29
190.87
15.52
°C/W
°C/W
°C/W
°C/W
AD1859
ABSOLUTE MAXIMUM RATINGS*
Min
Typ
Max
–0.3
6
–0.3
6
DGND – 0.3
DVDD + 0.3
AGND – 0.3
AVDD + 0.3
–0.3
0.3
Indefinite Short Circuit to Ground
+300
10
DVDD to DGND
AVDD to AGND
Digital Inputs
Analog Inputs
AGND to DGND
Reference Voltage
Soldering
Units
V
V
V
V
V
°C
sec
*Stresses greater than those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and 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.
DIGITAL FILTER CHARACTERISTICS
Min
Passband Ripple
Stopband1 Attenuation
48 kHz FS
Passband
Stopband
44.1 kHz FS
Passband
Stopband
32 kHz FS
Passband
Stopband
Other FS
Passband
Stopband
Group Delay
Group Delay Variation
Typ
Max
± 0.045
Units
dB
dB
0
26.688
21.312
6117
kHz
kHz
0
24.520
19.580
5620
kHz
kHz
0
17.792
14.208
4078
kHz
kHz
0
0.556
0.444
127.444
40/FS
0
FS
FS
sec
µs
Max
–0.075
Units
dB
dB
62
ANALOG FILTER CHARACTERISTICS
Min
Passband Ripple
Stopband Attenuation (at 64 × FS)
Typ
58
NOTE
1
Stopband nominally repeats itself at multiples of 128 × FS, where FS is the input word rate. Thus the digital filter will attenuate to 62 dB across the frequency
spectrum except for a range ± 0.55 × FS wide at multiples of 128 × FS.
PIN CONNECTIONS
ORDERING GUIDE
Model
AD1859JR
AD1859JRS
Temperature
Range
–40°C to +105°C
–40°C to +105°C
Package
Description
28-Lead SOIC
28-Lead SSOP
Package
Option
R-28
RS-28
CMOUT
1
28 FILT
DEEMP
2
27 FGND
EMPL
3
26 EMPR
OUTL
4
25 OUTR
NC
5
24 NC
AGND
6
MUTE
7
18/16
8
IDPM0
9
IDPM1 10
AD1859
TOP VIEW
(Not to Scale)
23 AVDD
22 NC
21 CLATCH
20 CDATA
19 CCLK
PD/RST 11
18 DGND
SDATA 12
17 DVDD
LRCLK 13
BCLK 14
16 XTALI/MCLK
15 XTALO
NC = NO CONNECT
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 the AD1859 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.
–4–
WARNING!
ESD SENSITIVE DEVICE
REV. A
AD1859
DEFINITIONS
Dynamic Range
Gain Error
With a near full-scale input, the ratio of actual output to expected output, expressed as a percentage.
The ratio of a full-scale output signal to the integrated output
noise in the passband (0 to 20 kHz), expressed in decibels (dB).
Dynamic range is measured with a –60 dB input signal and is
equal to (S/[THD+N]) + 60 dB. Note that spurious harmonics
are below the noise with a –60 dB input, so the noise level establishes the dynamic range. This measurement technique is
consistent with the recommendations of the Audio Engineering
Society (AES17-1991) and the Electronics Industries Association
of Japan (EIAJ CP-307).
Interchannel Gain Mismatch
With identical near full-scale inputs, the ratio of outputs of the
two stereo channels, expressed in decibels.
Gain Drift
Change in response to a near full-scale input with a change in
temperature, expressed as parts-per-million (ppm) per °C.
Crosstalk (EIAJ method)
Ratio of response on one channel with a zero input to a full-scale
1 kHz sine-wave input on the other channel, expressed in decibels.
Total Harmonic Distortion + Noise (THD+N)
The ratio of the root-mean-square (rms) value of a full-scale
fundamental input signal to the rms sum of all other spectral
components in the passband, expressed in decibels (dB) and
percentage.
Interchannel Phase Deviation
Difference in output sampling times between stereo channels,
expressed as a phase difference in degrees between 1 kHz inputs.
Passband
Power Supply Rejection
The region of the frequency spectrum unaffected by the attenuation of the digital interpolation filter.
With zero input, signal present at the output when a 300 mV
p-p signal is applied to power supply pins, expressed in decibels
of full scale.
Passband Ripple
The peak-to-peak variation in amplitude response from equalamplitude input signal frequencies within the passband, expressed in decibels.
Group Delay
Intuitively, the time interval required for an input pulse to appear at the converter’s output, expressed in seconds (s). More
precisely, the derivative of radian phase with respect to radian
frequency at a given frequency.
Stopband
The region of the frequency spectrum attenuated by the digital interpolation filter to the degree specified by “stopband
attenuation.”
Group Delay Variation
The difference in group delays at different input frequencies.
Specified as the difference between the largest and the smallest
group delays in the passband, expressed in microseconds (µs).
PIN DESCRIPTIONS
Digital Audio Serial Input Interface
Serial Control Port Interface
Pin Name Number
I/O
Description
Pin Name Number
I/O
Description
SDATA
12
I
Serial input, MSB first, containing two channels of 16 or 18 bits
of twos complement data per
channel.
CDATA
20
I
BCLK
14
I
Bit clock input for input data.
Need not run continuously; may
be gated or used in a burst
fashion.
Serial control input, MSB first,
containing 8 bits of unsigned
data per channel. Used for
specifying channel specific
attenuation and mute.
CCLK
19
I
Control clock input for control
data. Control input data must
be valid on the rising edge of
CCLK. CCLK may be continuous or gated.
CLATCH
21
I
Latch input for control data. This
input is rising edge sensitive.
LRCLK
13
I
Left/right clock input for input
data. Must run continuously.
IDPM0
9
I
Input serial data port mode
control zero. With IDPM1,
defines one of four serial input
modes.
IDPM1
10
I
Input serial data port mode control one. With IDPM0, defines
one of four serial input modes.
18/16
8
I
18-bit or 16-bit input data mode
control. Connect this signal HI
for 18-bit input mode, LO for
16-bit input mode.
REV. A
–5–
AD1859
PIN DESCRIPTIONS
Analog Signals
Control and Clock Signals
Pin Name
Number
I/O Description
Pin Name
Number
I/O Description
FILT
28
O
Voltage reference filter capacitor
connection. Bypass and decouple
the voltage reference with parallel 10 µF and 0.1 µF capacitors
to the FGND pin.
PD/RST
11
I
FGND
27
I
Voltage reference filter ground.
Use exclusively for bypassing and
decoupling of the FILT pin
(voltage reference).
Power down/reset. The AD1859 is
placed in a low power consumption
“sleep” mode when this pin is held
LO. The AD1859 is reset on the
rising edge of this signal. The serial
control port registers are reset to
their default values. Connect HI
for normal operation.
DEEMP
2
I
De-emphasis. An external analog deemphasis circuit network is enabled
when this input signal is HI. This
circuit is typically used to impose a
50/15 µs (or perhaps the CCITT
J.17) response characteristic on the
output audio spectrum.
MUTE
7
I
Mute. Assert HI to mute both
stereo analog outputs of the AD1859.
Deassert LO for normal operation.
XTALI/
MCLK
16
I
Crystal input or master clock input.
Connect to one side of a quartz
crystal to this input, or connect to
an external clock source to overdrive the on-chip oscillator.
XTALO
15
O
Crystal output. Connect to other
side of a quartz crystal. Do not connect if using the XTALI/MCLK
pin with an external clock source.
CMOUT
1
O
Voltage reference common-mode
output. Should be decoupled
with 10 µF capacitor to the AGND
pin or plane. This output is available
externally for dc-coupling and levelshifting. CMOUT should not have
any signal dependent load, or where
it will sink or source current.
OUTL
4
O
Left channel line level analog output.
OUTR
25
O
Right channel line level analog output.
EMPL
3
O
De-emphasis switch connection
for the left channel. Can be left
unconnected if de-emphasis is not
required in the target application.
EMPR
26
O
De-emphasis switch connection
for the right channel. Can be left
unconnected if de-emphasis is not
required in the target application.
Power Supply Connections and Miscellaneous
–6–
Pin Name
Number
I/O Description
AVDD
23
I
Analog Power Supply. Connect
to analog +5 V supply.
AGND
6
I
Analog Ground.
DVDD
17
I
Digital Power Supply. Connect
to digital +5 V supply.
DGND
18
I
Digital Ground.
NC
5, 22, 24
No Connect. Reserved. Do not
connect.
REV. A
AD1859
the fourth stage is a second-order comb filter. The FIR filter
implementation is multiplier-free, i.e., the multiplies are performed using shift-and-add operations.
(continued from page 1)
The AD1859 has a simple but very flexible serial data input port
that allows for glueless interconnection to a variety of ADCs,
DSP chips, AES/EBU receivers and sample rate converters.
The serial data input port can be configured in left-justified,
I2S-justified, right-justified and DSP serial port compatible
modes. The AD1859 accepts 16- or 18-bit serial audio data in
MSB-first, twos-complement format. A power-down mode is
offered to minimize power consumption when the device is inactive. The AD1859 operates from a single +5 V power supply. It
is fabricated on a single monolithic integrated circuit using a
0.6 µM CMOS double polysilicon, double metal process, and is
housed in 28-pin SOIC and SSOP packages for operation over
the temperature range –40°C to +105°C.
Multibit Sigma-Delta Modulator
The AD1859 employs a four-bit sigma-delta modulator. Whereas a
traditional single bit sigma-delta modulator has two levels of quantization, the AD1859’s has 17 levels of quantization. Traditional
single bit sigma-delta modulators sample the input signal at 64
times the input sample rate; the AD1859 samples the input signal at nominally 128 times the input sample rate. The additional quantization levels combined with the higher oversampling
ratio means that the AD1859 DAC output spectrum contains
dramatically lower levels of out-of-band noise energy, which is a
major stumbling block with more traditional single bit sigmadelta architectures. This means that the post-DAC analog reconstruction filter has reduced transition band steepness and
attenuation requirements, which equates directly to lower phase
distortion. Since the analog filtering generally establishes the
noise and distortion characteristic of the DAC, the reduced
requirements translate into better audio performance.
THEORY OF OPERATION
The AD1859 offers the advantages of sigma-delta conversion
architectures (no component trims, low cost CMOS process
technology, superb low level linearity performance) with the
advantages of conventional multibit R-2R resistive ladder audio
DACs (no requirement for any high frequency synchronous master
clocks [e.g., 256 or 384 × FS] continuously variable sample rate
support, jitter tolerance, low output noise, etc.).
Multibit sigma-delta modulators bring an additional benefit:
they are essentially free of stability (and therefore potential loop
oscillation) problems. They are able to use a wider range of the
voltage reference, which can increase the overall dynamic range
of the converter.
The use of a multibit sigma-delta modulator means that the
AD1859 generates dramatically lower amounts of out-of-band
noise energy, which greatly reduces the requirement on post
DAC filtering. The required post-filtering is integrated on the
AD1859. The AD1859’s multibit sigma-delta modulator is also
highly immune to digital substrate noise.
The conventional problem which limits the performance of
multibit sigma delta converters is the nonlinearity of the passive
circuit elements used to sum the quantization levels. Analog
Devices has developed (and been granted patents on) a revolutionary architecture which overcomes the component linearity
problem that otherwise limits the performance of multibit sigma
delta audio converters. This new architecture provides the
AD1859 with the same excellent differential nonlinearity and
linearity drift (over temperature and time) specifications as
single bit sigma-delta DACs.
The digital phase locked loop feature gives the AD1859 an unprecedented jitter rejection feature. The bandwidth of the first
order loop filter is 15 Hz; jitter components on the input
left/right clock are attenuated by 6 dB per octave above and below 15 Hz. Jitter on the crystal time base or MCLK input is rejected as well (by virtue of the on-chip switched capacitor filter),
but this clock should be low jitter because it is used by the DAC
to convert the audio from the discrete time (sampled) domain to
the continuous time (analog) domain. The AD1859 includes an
on-chip oscillator, so that the user need only provide an inexpensive quartz crystal or ceramic resonator as an external time base.
The AD1859’s multibit modulator has another important advantage; it has a high immunity to substrate digital noise. Substrate noise can be a significant problem in mixed-signal
designs, where it can produce intermodulation products that
fold down into the audio band. The AD1859 is approximately
eight times less sensitive to digital substrate noise (voltage reference noise injection) than equivalent single bit sigma-delta
modulator based DACs.
Serial Audio Data Interface
The serial audio data interface uses the bit clock (BCLK) simply
to clock the data into the AD1859. The bit clock may, therefore, be asynchronous to the L/R clock. The left/right clock
(LRCLK) is both a framing signal, and the sample frequency input
to the digital phase locked loop. The left/right clock (LRCLK) is
the signal that the AD1859 actually uses to determine the input
sample rate, and it is the jitter on LRCLK that is rejected by the
digital phase locked loop. The SDATA input carries the serial
stereo digital audio in MSB first, twos-complement format.
Dither Generator
The AD1859 includes an on-chip dither generator, which is intended to further reduce the quantization noise introduced by
the multibit DAC. The dither has a triangular Probability Distribution Function (PDF) characteristic, which is generally considered to create the most favorable noise shaping of the residual
quantization noise. The AD1859 is among the first low cost, IC
audio DACs to include dithering.
Digital Interpolation Filter
The purpose of the interpolator is to “oversample” the input
data, i.e., to increase the sample rate so that the attenuation requirements on the analog reconstruction filter are relaxed. The
AD1859 interpolator increases the input data sample rate by a
variable factor depending on the sample frequency of the incoming digital audio. The interpolation is performed using a multistage FIR digital filter structure. The first stage is a droop
equalizer; the second and third stages are half-band filters; and
REV. A
Analog Filtering
The AD1859 includes a second-order switched capacitor discrete time low-pass filter followed by a first-order analog continuous time low-pass filter. These filters eliminate the need for
any additional off-chip external reconstruction filtering. This
on-chip switched capacitor analog filtering is essential to reduce
the deleterious effects of any remaining master clock jitter.
–7–
AD1859
Option for Analog De-emphasis Processing
The phase detector automatically switches the loop filter into
“slow” mode as phase lock is gradually obtained. The loop
bandwidth is 15 Hz in slow mode. Since the loop filter is first
order, the digital PLL will reject jitter on the left/right clock
above 15 Hz, with an attenuation of 6 dB per octave. The jitter
rejection frequency response is shown in Figure 1.
The AD1859 includes three pins for implementing an external
analog 50/15 µs (or possibly the CCITT J. 17) de-emphasis frequency response characteristic. A control pin DEEMP (Pin 2)
enables de-emphasis when it is asserted HI. Two analog outputs, EMPL (Pin 3) and EMPR (Pin 26) are used to switch the
required analog components into the output stage of the AD1859.
An analog implementation of de-emphasis is superior to a digital
implementation in several ways. It is generally lower noise, since
digital de-emphasis is usually created using recursive IIR filters,
which inject limit cycle noise. Also the digital de-emphasis is being applied in front of the primary analog noise generation source,
the DAC modulator, and its high frequency noise contributions
are not attenuated. An analog de-emphasis circuit is downstream from the relatively “noisy” DAC modulator and thus provides a more effective noise reduction role (which was the original
intent of the emphasis/de-emphasis scheme). A final key advantage of analog de-emphasis is that it is sample rate invariant, so
that users can fully exploit the sample rate range of the AD1859
and simultaneously use de-emphasis. Digital implementations generally only support fixed, standard sample rates.
0
JITTER ATTENUATION – dB
–6
–12
–18
–24
–30
–36
–42
–48
–54
–60
0
15
30
60
120 240 480 960 1920 3840 7680 15360
Hz ABOVE OR BELOW THE SAMPLE FREQUENCY
Digital Phase Locked Loop
The digital PLL is adaptive, and locks to the applied sample rate
(on the LRCLK Pin 13) in 100 ms to 200 ms. The digital PLL
is initially in “fast” mode, with a wide lock capture bandwidth.
Figure 1. Digital PLL Jitter Rejection
OPERATING FEATURES
Serial Data Input Port
Serial Input Port Modes
The AD1859 uses the frequency of the left/right input clock to
determine the input sample rate. LRCLK must run continuously and transition twice per stereo sample period (except in
the left-justified DSP serial port style mode, when it transitions
four times per stereo sample period). The bit clock (BCLK) is
edge sensitive and may be used in a gated or burst mode (i.e., a
stream of pulses during data transmission followed by periods of
inactivity). The bit clock is only used to write the audio data
into the serial input port. It is important that the left/right clock
is “clean” with monotonic rising and falling edge transitions and
no excessive overshoot or undershoot which could cause false
clock triggering of the AD1859.
The AD1859 uses two multiplexed input pins to control the
mode configuration of the input data port. IDPM0 and IDPM1
program the input data port mode as follows:
IDPM1
LO
LO
HI
HI
Serial Input Port Mode
Right-Justified (See Figure 2)
I2S-Justified (See Figure 3)
Left-Justified (See Figure 4)
Left-Justified DSP Serial Port Style
(See Figure 5)
Figure 2 shows the right-justified mode. LRCLK is HI for the
left channel, and LO for the right channel. Data is valid on the
rising edge of BCLK. The MSB is delayed 14-bit clock periods
(in 18-bit input mode) or 16-bit clock periods (in 16-bit input
mode) from an LRCLK transition, so that when there are 64
BCLK periods per LRCLK period, the LSB of the data will be
right-justified to the next LRCLK transition.
The AD1859’s flexible serial data input port accepts data in
twos-complement, MSB-first format. The left channel data
field always precedes the right channel data field. The input
data consists of either 16 or 18 bits, as established by the 18/16
input control (Pin 8). All digital inputs are specified to TTL
logic levels. The input data port is configured by control pins.
LRCLK
INPUT
IDPM0
LO
HI
LO
HI
RIGHT CHANNEL
LEFT CHANNEL
BCLK
INPUT
SDATA
INPUT
LSB
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
Figure 2. Right-Justified Mode
–8–
REV. A
AD1859
Figure 3 shows the I2S-justified mode. LRCLK is LO for the left
channel, and HI for the right channel. Data is valid on the rising
edge of BCLK. The MSB is left-justified to an LRCLK transition
but with a single BCLK period delay. The I2S-justified mode
can be used in either the 16-bit or the 18-bit input mode.
Note that in 16-bit input mode, the AD1859 is capable of a 32
× FS BCLK frequency “packed mode” where the MSB is leftjustified to an LRCLK transition, and the LSB is right-justified
to an LRCLK transition. LRCLK is HI for the left channel,
and LO for the right channel. Data is valid on the rising edge of
BCLK. Packed mode can be used when the AD1859 is programmed in either right-justified or left-justified mode. Packed
mode is shown in Figure 6.
Figure 4 shows the left-justified mode. LRCLK is HI for the
left channel, and LO for the right channel. Data is valid on the
rising edge of BCLK. The MSB is left-justified to an LRCLK
transition, with no MSB delay. The left-justified mode can be
used in either the 16-bit or the 18-bit input mode.
Serial Control Port
The AD1859 serial control port is SPI compatible. SPI
(Serial Peripheral Interface) is a serial port protocol popularized
by Motorola’s family of microcomputer and microcontroller
products. The write-only serial control port gives the user access to channel specific mute and attenuation. The AD1859
serial control port consists of three signals, control clock CCLK
(Pin 19), control data CDATA (Pin 20), and control latch
CLATCH (Pin 21). The control data input (CDATA) must be
valid on the control clock (CCLK) rising edge, and the control
clock (CCLK) must only make a LO to HI transition when
there is valid data. The control latch (CLATCH) must make a
LO to HI transition after the LSB has been clocked into the
AD1859, while the control clock (CCLK) is inactive. The timing relation between these signals is shown in Figure 7.
Figure 5 shows the left-justified DSP serial port style mode.
LRCLK must pulse HI for at least one bit clock period before
the MSB of the left channel is valid, and LRCLK must pulse HI
again for at least one bit clock period before the MSB of the
right channel is valid. Data is valid on the falling edge of
BCLK. The left-justified DSP serial port style mode can be
used in either the 16-bit or the 18-bit input mode. Note that in
this mode, it is the responsibility of the DSP to ensure that the
left data is transmitted with the first LRCLK pulse, and that the
right data is transmitted with the second LRCLK pulse, and
that synchronism is maintained from that point forward.
LRCLK
INPUT
LEFT CHANNEL
RIGHT CHANNEL
BCLK
INPUT
SDATA
INPUT
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
MSB-1
LSB+2
MSB-2
LSB+1
LSB
MSB
Figure 3. I2S-Justified Mode
LRCLK
INPUT
RIGHT CHANNEL
LEFT CHANNEL
BCLK
INPUT
SDATA
INPUT
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
MSB-1
MSB
MSB-1
Figure 4. Left-Justified Mode
LRCLK
INPUT
RIGHT CHANNEL
LEFT CHANNEL
BCLK
INPUT
SDATA
INPUT
MSB
LSB+2
MSB-1
LSB+1
LSB
MSB
MSB-1
LSB+2
LSB+1
LSB
Figure 5. Left-Justified DSP Serial Port Style Mode
LRCLK
INPUT
RIGHT CHANNEL
LEFT CHANNEL
BCLK
INPUT
SDATA
INPUT
LSB
MSB
MSB-1
MSB-2
LSB+2
LSB+1
LSB
MSB
MSB-1
MSB-2
Figure 6. 32 × FS Packed Mode
REV. A
–9–
LSB+2
LSB+1
LSB
MSB
MSB-1
AD1859
CCLK
CDATA
D7
D6
D5
D4
D3
D2
D1
MSB
D0
D7
LSB
MSB
D5
D6
CLATCH
Figure 7. Serial Control Port Timing
MSB
DATA7
LSB
DATA6
DATA5
DATA4
DATA3
LEFT/RIGHT
Mute
Atten5
Atten4
Atten3
Right Channel = HI
Left Channel = LO
Mute = HI
Normal = LO
00
00
00
00
00
00
00
00
00
0000
0001
0010
0011
0100
0101
0110
0111
1000
=
=
=
=
=
=
=
=
=
*
*
*
11 1101 =
11 1110 =
11 1111 =
DATA2
DATA1
DATA0
Atten2
Atten1
Atten0
0.0dB
–1.0dB
–2.0dB
–3.0dB
–4.0dB
–5.0dB
–6.0dB
–7.0dB
–8.0dB
–61.0dB
–62.0dB
–63.0dB
Figure 8. Serial Control Bit Definitions
The serial control port is byte oriented. The data is MSB first,
and is unsigned. There is a control register for the left channel
and a control register for the right channel, as distinguished by
the MSB (DATA7). The bits are assigned as shown in Figure 8.
The lowest sample rate supported can be computed as follows:
Lowest Sample Rate = Master Clock Frequency ÷ 1024
AD1859
XTALI/MCLK
AD1859
XTALO
XTALI/MCLK
XTALO
NC
20-64pF
27MHz
20-64pF
27MHz CRYSTAL CONNECTION
27MHz
27MHz OSCILLATOR CONNECTION
Figure 9. Crystal and Oscillator Connections
Figure 10 illustrates these relations. As can be seen in Figure 10,
a 27 MHz MCLK or crystal frequency supports audio sample
rates from approximately 28 kHz to 52 kHz.
L/R CLOCK SAMPLE FREQUENCY – kHz
The left channel control register and the right channel control register have identical power up and reset default settings. DATA6,
the Mute control bit, reset default state is LO, which is the normal (nonmuted) setting. DATA5:0, the Atten5 through Atten0
control bits, have a reset default value of 00 0000, which is an
attenuation of 0.0 dB (i.e., full scale, no attenuation). The intent
with these reset defaults is to enable AD1859 applications without requiring the use of the serial control port. For those users
that do not use the serial control port, it is still possible to mute
the AD1859 output by using the external MUTE (Pin 7) signal.
It is recommended that the output be muted for approximately
1000 input sample periods during power-up or following any
radical sample rate change (>5%) to allow the digital phase
locked loop to settle.
Highest Sample Rate = Master Clock Frequency ÷ 512
Note that the serial control port timing is asynchronous to the
serial data input port timing. Changes made to the attenuator
level will be updated on the next edge of the LRCLK after the
CLATCH write pulse. The AD1859 has been designed to resolve the potential for metastability between the LRCLK edge
and the CLATCH write pulse rising edge. The attenuator setting is guaranteed to be valid even if the LRCLK edge and the
CLATCH rising edge occur essentially simultaneously.
On-Chip Oscillator and Master Clock
76
HIGHEST
L/R SAMPLE RATE
(MCLK/512)
68
60
52
LOWEST
L/R SAMPLE RATE
(MCLK/1024)
44
36
28
20
The asynchronous master clock of the AD1859 can be supplied
by either an external clock source applied to XTALI/MCLK or
by connecting a crystal across the XTALI/MCLK and XTALO
pins, and using the on-chip oscillator. If a crystal is used, it
should be fundamental-mode and parallel-tuned. Figure 9
shows example connections.
Mute and Attenuation
The range of audio sample rates (as determined from the
LRCLK input) supported by the AD1859 is a function of the
master clock rate (i.e., the crystal frequency or external clock
source frequency) applied. The highest sample rate supported
can be computed as follows:
The AD1859 offers two methods of muting the analog output.
By asserting the MUTE (Pin 7) signal HI, both the left channel
and the right channel are muted. As an alternative, the user can
assert the mute bit in the serial control registers HI for individual mute of either the left channel or the right channel. The
18
20
22
24
26
28
30
32
XTAL/MCLK FREQUENCY – MHz
34
36
Figure 10. MCLK Frequency vs. L/R Clock Frequency
–10–
REV. A
AD1859
AD1859 has been designed to minimize pops and clicks when
muting and unmuting the device. The AD1859 includes a zero
crossing detector which attempts to implement attenuation
changes on waveform zero crossings only. If a zero crossing is
not found within 1024 input sample periods (approximately
23 ms at 44.1 kHz), the attenuation change is made regardless.
APPLICATIONS ISSUES
Interface to MPEG Audio Decoders
Figure 11 shows the suggested interface to the Analog Devices
ADSP-21xx family of DSP chips, for which several MPEG
audio decode algorithms are available. The ADSP-21xx supports
16 bits of data using a left-justified DSP serial port style format.
Output Drive, Buffering and Loading
The AD1859 analog output stage is able to drive a 2 kΩ load. If
lower impedance loads must be driven, an external buffer stage
such as the Analog Devices SSM2142 should be used. The
analog output is generally ac coupled with a 10 µF capacitor,
even if the optional de-emphasis circuit is not used, as shown in
Figure 17. It is possible to dc couple the AD1859 output into an
op amp stage using the CMOUT signal as a bias point.
SCLK
ADSP-21xx
Power Down and Reset
12 SDATA
NC
HI
9 IDPM0
HI
10 IDPM1
LO
8 18/16
AD1859
Figure 11. Interface to ADSP-21xx
Figure 12 shows the suggested interface to the Texas Instruments TMS320AV110 MPEG audio decoder IC. The
TMS320AV110 supports 18 bits of data using a right-justified
output format.
TEXAS
INSTRUMENTS
TMS320AV110
SCLK
14 BCLK
LRCLK
13 LRCLK
PCMDATA
12 SDATA
PCMCLK
48 x FS
TO
1536 x FS
LO
9 IDPM0
LO
10 IDPM1
HI
8 18/16
AD1859
Figure 12. Interface to TMS320AV110
Figure 13 shows the suggested interface to the LSI Logic L64111
MPEG audio decoder IC. The L64111 supports 16 bits of data
using a left-justified output format.
SCLKO
LSI LOGIC
L64111
14 BCLK
13 LRCLK
LRCLKO
12 SDATA
SERO
SYSCLK
384 x FS
OR
512 x FS
LO
9 IDPM0
HI
10 IDPM1
LO
AD1859
8 18/16
Figure 13. Interface to L64111
Figure 14 shows the suggested interface to the Philips SAA2500
MPEG audio decoder IC. The SAA2500 supports 18 bits of
data using an I2S compatible output format.
PHILIPS
SAA2500
14 BCLK
SCK
WS
13 LRCLK
SD
12 SDATA
FSCLKIN
256 x FS
OR
384 x FS
Control Signals
The IDPM0, IDPM1, 18/16, and DEEMP control inputs are
normally connected HI or LO to establish the operating state of
the AD1859. They can be changed dynamically (and asynchronously to the LRCLK and the master clock) as long as they are
stable before the first serial data input bit (i.e., the MSB) is presented to the AD1859.
REV. A
13 LRCLK
TFS
DR
The PD/RST input (Pin 11) is used to control the power consumed by the AD1859. When PD/RST is held LO, the AD1859
is placed in a low dissipation power-down state. When PD/RST
is brought HI, the AD1859 becomes ready for normal operation.
The master clock (XTALI/MCLK, Pin 16) must be running for
a successful reset or power-down operation to occur. The PD/RST
signal must be LO for a minimum of four master clock periods
(approximately 150 ns with a 27 MHz XTALI/MCLK
frequency).
When the PD/RST input (Pin 11) is asserted brought HI, the
AD1859 is reset. All registers in the AD1859 digital engine (serial data port, interpolation filter and modulator) are zeroed, and
the amplifiers in the analog section are shorted during the reset
operation. The two registers in the serial control port are initialized to their default values. The user should wait 100 ms after
bringing PD/RST HI before using the serial data input port and
the serial control input port in order for the digital phase locked
loop to re-acquire lock. The AD1859 has been designed to
minimize pops and clicks when entering and exiting the powerdown state.
14 BCLK
NC
DT
On-Chip Voltage Reference
The AD1859 includes an on-chip voltage reference that establishes the output voltage range. The nominal value of this reference is +2.25 V which corresponds to a line output voltage
swing of 3 V p-p. The line output signal is centered around a
voltage established by the CMOUT (common mode) output
(Pin 1). The reference must be bypassed both on the FILT input (Pin 28) with 10 µF and 0.1 µF capacitors, and on the
CMOUT output (Pin 1) with a 10 µF and 0.1 µF capacitors, as
shown in Figures 17 and 18. The FILT pin must use the
FGND ground, and the CMOUT pin must use the AGND
ground. The on-chip voltage reference may be overdriven with
an external reference source by applying this voltage to the
FILT pin. CMOUT and FILT must still be bypassed as shown
in Figures 17 and 18. An external reference can be useful to
calibrate multiple AD1859 DACs to the same gain. Reference
bypass capacitors larger than those suggested can be used to improve the signal-to-noise performance of the AD1859.
RFS
HI
9 IDPM0
LO
10 IDPM1
HI
8 18/16
Figure 14. Interface to SAA2500
–11–
AD1859
AD1859
Figure 15 shows the suggested interface to the Zoran ZR38000
DSP chip, which can act as an MPEG audio or AC-3 audio
decoder. The ZR38000 supports 16 bits of data using a leftjustified output format.
ZR38000
WSB
13 LRCLK
SDB
12 SDATA
SCKIN
LO
9 IDPM0
HI
10 IDPM1
256 x FS
CL480
256 x FS
OR
384 x FS
LO
10 IDPM1
LO
8 18/16
AD1859
Layout and Decoupling Considerations
The recommended decoupling, bypass circuits for the AD1859
are shown in Figure 17. Figure 17 illustrates a connection diagram for systems which do not require de-emphasis support.
The recommended circuit connection for system including deemphasis is shown in Figure 18.
20-64pF
µCONTROLLER
0.1µF
20-64pF
27MHz
23
6
20
21
19
16
10µF
15
AGND CDATA CCLK CLATCH XTALI/MCLK XTALO
0.1µF
FILT 28
FGND 27
12 SDATA
CMOUT 1
14 BLCK
DSP OR
AUDIO
DECODER
9 IDPM0
Figure 16. Interface to CL480
Figure 16 shows the suggested interface to the C-Cube
Microsystems CL480 MPEG system decoder IC. The CL480
supports 16 bits of data using a right-justified output format.
AVDD
LO
AD1859
Figure 15. Interface to ZR38000
+5V ANALOG
1µF
12 SDATA
DA-DATA
DA-XCK
8 18/16
LO
13 LRCLK
DA-LRCK
14 BCLK
SCKB
ZORAN
14 BCLK
DA-BCK
C-CUBE
10µF
NC 5
13 LRCLK
AD1859
AD1859
9 IDPM0
NC 24
1kΩ
EMPL 3
8 18/16
DGND
NC
PD/RST
MUTE
DEEMP
17
18
22
11
7
2
30Ω
(CHIP RESISTOR
PREFERRED)
LEFT LINE
OUTPUT
2.2nF
10µF
OUTR 25
DVDD
BIAS VOLTAGE
FOR EXTERNAL USE
10µF
OUTL 4
10 IDPM1
0.1µF
1kΩ
EMPR 26
RIGHT LINE
OUTPUT
2.2nF
0.01µF
1µF
µCONTROLLER
+5V DIGITAL
Figure 17. Recommended Circuit Connection (Without De-emphasis)
+5V ANALOG
1µF
20-64pF
µCONTROLLER
0.1µF
23
27MHz
20
6
AVDD
20-64pF
19
21
16
0.1µF
FILT 28
FGND 27
12 SDATA
CMOUT 1
14 BLCK
DSP OR
AUDIO
DECODER
10µF
15
AGND CDATA CCLK CLATCH XTALI/MCLK XTALO
10µF
NC 5
13 LRCLK
AD1859
9 IDPM0
NC 24
1µF
OUTL 4
10 IDPM1
EMPL 3
8 18/16
OUTR 25
DVDD
DGND
18
17
30Ω
(CHIP RESISTOR
PREFERRED)
0.01µF
NC
22
PD/RST
11
0.1µF
MUTE
DEEMP
7
2
µCONTROLLER
1µF
EMPR 26
1kΩ
2.2nF
470Ω
33nF
NPO
2.2nF
470Ω
33nF
NPO
1kΩ
BIAS VOLTAGE
FOR EXTERNAL USE
LEFT LINE
OUTPUT
10MΩ
1µF
RIGHT LINE
OUTPUT
10MΩ
OPTIONAL DE-EMPHASIS
CIRCUIT SHOWN
+5V DIGITAL
Figure 18. Recommended Circuit Connection (With De-emphasis)
–12–
REV. A
AD1859
tDBH
PCB and Ground Plane Recommendations
CMOUT
1
DEEMP
2
EMPL
3
OUTL
4
NC
5
24 NC
AGND
6
23 AVDD
MUTE
7
22 NC
18/16
8
21 CLATCH
IDPM0
9
tDLS
tDBL
LRCLK
tDLH
tDDS
SDATA
LEFT-JUSTIFIED
DSP SERIAL
PORT STYLE
MODE
MSB
MSB-1
tDDH
Figure 21. Serial Data Input Port Timing DSP Serial
Port Style
The serial control port timing is shown in Figure 22. The minimum control clock HI pulse width is tCCH, and the minimum
control clock LO pulse width is tCCL. The minimum control
clock period is tCCP. The control data minimum setup time is
tCSU, and the minimum control data hold time is tCHD. The
minimum control latch delay is tCLD, the minimum control latch
LO pulse width is tCLL, and the minimum control latch HI pulse
width is tCLH.
28 FILT
27 FGND
ANALOG
GROUND PLANE
tDBP
BCLK
The AD1859 ideally should be located above a split ground
plane, with the digital pins over the digital ground plane, and
the analog pins over the analog ground plane. The split should
occur between Pins 6 and 7 and between Pins 22 and 23 as
shown in Figure 19. The ground planes should be tied together
at one spot underneath the center of the package with an approximately 3 mm trace. This ground plane strategy minimizes
RF transmission and reception as well as maximizes the AD1859’s
analog audio performance.
26 EMPR
25 OUTR
20 CDATA
IDPM1 10
PD/RST 11
18 DGND
SDATA 12
17 DVDD
LRCLK 13
16
CCLK
tCCH tCSU
XTALI/MCLK
15 XTALO
BCLK 14
tCCP
tCCL
19 CCLK
DIGITAL
GROUND PLANE
CDATA
LSB
tCLH
tCHD
Figure 19. Recommended Ground Plane
tCLD
CLATCH
tCLL
TIMING DIAGRAMS
The serial data port timing is shown in Figures 20 and 21. The
minimum bit clock HI pulse width is tDBH, and the minimum bit
clock LO pulse width is tDBL. The minimum bit clock period is
tDBP. The left/right clock minimum setup time is tDLS, and the
left/right clock minimum hold time is tDLH. The serial data minimum setup time is tDDS, and the minimum serial data hold time
is tDDH.
tDBH
tDBP
Figure 22. Serial Control Port Timing
The master clock (or crystal input) and power down/reset timing is shown in Figure 23. The minimum MCLK period is tMCP,
which determines the maximum MCLK frequency at FMC. The
minimum MCLK HI and LO pulse widths are tMCH and tMCL,
respectively. The minimum reset LO pulse width is tPDRP (four
XTALI/MCLK periods) to accomplish a successful AD1859 reset operation.
BCLK
tDBL
tDLS
tMCH
LRCLK
SDATA
LEFTJUSTIFIED
MODE
SDATA
I 2 SJUSTIFIED
MODE
SDATA
RIGHTJUSTIFIED
MODE
tDDS
MSB
tMCL
MSB-1
PD/RST
tDDH
tPDRP
tDDS
MSB
tDDH
tDDS
tDDS
Figure 23. MCLK and Power Down/Reset Timing
MSB
tDDH
LSB
tDDH
Figure 20. Serial Data Port Timing
REV. A
tMCP
XTALI/MCLK
–13–
AD1859
TYPICAL PERFORMANCE
Figures 24 through 27 illustrate the typical analog performance
of the AD1859 as measured by an Audio Precision System One.
Signal-to-Noise (dynamic range) and THD+N performance is
shown under a range of conditions. Note that there is a small
variance between the AD1859 analog performance specifications and some of the performance plots. This is because the
Audio Precision System One measures THD and noise over a
20 Hz to 24 kHz bandwidth, while the analog performance is
specified over a 20 Hz to 20 kHz bandwidth (i.e., the AD1859
performs slightly better than the plots indicate). Figure 28
shows the power supply rejection performance of the AD1859.
The channel separation performance of the AD1859 is shown in
Figure 29. The AD1859’s low level linearity is shown in Figure
30. The digital filter transfer function is shown in Figure 31.
0
0
–10
FS = 44.1kHz
–20
FFT @ –0.5dBFS
–20
–30
–40
–30
–50
–40
–50
dBFS
dBFS
–60
–70
–60
–80
–90
–70
–100
–80
–110
–90
–120
–100
–130
–140
0
2k
4k
6k
8k
10k 12k 14k
FREQUENCY – Hz
16k
18k
–110
–100
20k
–90
–80
–70
–60
–50
–40
–30
–20
–10
0
AMPLITUDE – dBFS
Figure 24. 1 kHz Tone at –0.5 dBFS (16K-Point FFT)
Figure 27. THD+N vs. Amplitude at 1 kHz
0
–40
–10
FS = 44.1kHz
FFT @ –10dBFS
–20
–45
–30
–50
–40
LEFT CHANNEL
–50
–55
–60
RIGHT CHANNEL
dBFS
dBFS
FS = 44.1kHz
THD+N vs dBFS @ 1kHz
–10
–70
–60
–80
–65
–90
–100
–70
–110
–120
–75
–130
–80
–140
0
2k
4k
6k
8k
10k 12k 14k
FREQUENCY – Hz
16k
18k
0
20k
Figure 25. 1 kHz Tone at –10 dBFS (16K-Point FFT)
4k
6k
8k
10k 12k 14k
FREQUENCY – Hz
16k
18k
20k
Figure 28. Power Supply Rejection to 300 mV p-p on AVDD
0
0
FS = 44.1kHz
THD+N vs FREQ @ –0.5dBFS
–10
–10
FS = 44.1kHz
–20
–20
–30
–30
–40
dBFS
–40
dBFS
2k
–50
–60
–50
–60
–70
–70
–80
–80
–90
–90
–100
–100
–110
–120
–110
0
2k
4k
6k
8k
10k 12k 14k
FREQUENCY – Hz
16k
18k
0
20k
Figure 26. THD+N vs. Frequency at –0.5 dBFS
2k
4k
6k
8k
10k
12k
14k
16k
18k
20k
FREQUENCY – Hz
Figure 29. Channel Separation vs. Frequency at –0.5 dBFS
–14–
REV. A
AD1859
0
–10
0
–10
–20
–30
100
90
–40
–60
dBFS
dBFS
–50
–70
10
–80
0%
–90
–100
–20
–30
–40
–50
–60
–70
–80
–90
–100
–110
–120
–130
–110
–120
–140
–150
–160
0.0
–130
–140
0
2k
4k
6k
8k
10k
12k
14k
16k
18k
20k
22k
0.5
1.0
1.5
Application Circuits
Figure 32 illustrates a 600 ohm line driver using the Analog
Devices SSM2017 and SSM2142 components. Figure 33
illustrates a “Numerically Controlled Oscillator” (NCO) that
can be implemented in programmable logic or a system ASIC to
provide the synchronous bit and left/right clocks from 27 MHz
for MPEG audio decoders. Note that the bit clock and left/right
clock outputs are highly jittered, but this jitter should be
+5VDD
+5VCC
17
23
DVDD
AVDD
14
13
12
10
9
8
21
20
19
11
2
7
16
15
OUTL
+15V
BCLK
LRCLK
EMPL
SDATA
IDPM1
IDPM0
AD1859-JR
18/16
OUTR
CLATCH
EMPR
CDATA
CCLK
PD/RST
DEEMP
MUTE
CMOUT
FILT
XTALI/MCLK
FGND
XTALO
DGND
AGND
18
6
4
1Vrms
3
1
3
R1, 2k49
8
2
C6
100n
V+
1Vrms
+V
VIN
8
+OUT
+SENSE
U2
SSM2017P
–SENSE
–OUT
3
GND
–15V
+15V
VREF
3
1
2.25V
R2, 2k49
28
27
C4
100n
8
2
+IN
RG1
V+
6
OUT
REF
RG2
V–
5
–IN
+15V
U3
SSM2017P
–
4µ7
C1
100n
C3
100n
6
+
C10
1
7
4
C9
100n
2
5
C7
100n
–15V
1
7
–V
C8
100n
26
C5
100n
U4
SSM2142P
6
4
25
4
+IN
OUT
REF
RG2
V–
5
–IN
5Vrms
4
–15V
+V
VIN
+OUT
+SENSE
U5
SSM2142P
–SENSE
–OUT
3
GND
8
7
2
1
–V
5
–15V
C2
100n
Figure 32. 600 Ohm Balanced Line Driver
REV. A
3.5
6
5Vrms
7
RG1
3.0
perfectly acceptable. MPEG audio decoders are insensitive to
this clock jitter (using these signals to clock audio data from their
output serial port, and perhaps to decrement their audio/video
synchronization timer), while the AD1859 will reject the left/right
clock jitter by virtue of its on-chip digital phase locked loop.
Contact Analog Devices Computer Products Division Customer
Support at (617) 461-3881 or [email protected] for more
information on this NCO circuit.
C12
100n
+15V
2.5
Figure 31. Digital Filter Signal Transfer Function to
3.5 × FS
Figure 30. 1 kHz Tone at –90 dBFS (16K-Point FFT) Including Time Domain Plot Bandlimited to 22 kHz
C11
100n
2.0
FS
FREQUENCY – Hz
–15–
J1 P1
P2 J2
1
2
3
4
5
1
2
3
4
5
1
2
3
4
5
1
2
3
4
5
R3
600Ω
R4
600Ω
MAX OUTPUT EACH
CHANNEL
10Vrms (166.7mV V = +22dBm)
INTO 600Ω
AD1859
T
+
N [12..0]
BCLK
Q
27 MHz
13-BIT
ADDER
MSB
SELECT K BUS WHEN K < N (MSB = 0)
SELECT R BUS WHEN K > N (MSB = 1)
13
_
13
C2123–18–4/96
13
1
R BUS
13
M [12..0]
13
13-BIT
LATCH
2 TO 1
SELECTOR
+
13-BIT
ADDER
13
RI BUS
K BUS
13
0
+
27MHz
L BUS
Figure 33. Numerically Controlled Oscillator Circuit
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
28-Lead Wide-Body SO
(R-28)
28-Lead Shrink Small Outline Package (SSOP)
(RS-28)
0.7125 (18.10)
0.6969 (17.70)
0.0118 (0.30)
0.0040 (0.10)
0.0500
(1.27)
BSC
0.020 (0.49)
0.013 (0.35)
SEATING 0.0125 (0.32)
PLANE 0.0091 (0.23)
1
14
0.029 (0.74)
x 45°
0.010 (0.25)
8°
0°
0.079 (2.0)
MAX
PIN 1
0.073 (1.85)
0.065 (1.65)
0.050 (1.27)
0.016 (0.40)
0.002 (0.05)
MIN
0.026
(0.65)
BSC
0.015 (0.38)
SEATING
0.009 (0.22)
PLANE
0.01 (0.25)
0.004 (0.09)
8°
0°
0.037 (0.95)
0.022 (0.55)
PRINTED IN U.S.A.
0.1043 (2.65)
0.0926 (2.35)
PIN 1
15
0.22 (5.60)
0.20 (5.00)
14
28
0.32 (8.20)
0.29 (7.40)
1
0.419 (10.65)
0.394 (10.00)
15
0.2992 (7.60)
0.2914 (7.40)
28
0.41 (10.50)
0.39 (9.90)
–16–
REV. A
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