BB PCM1704

®
PCM1704
49%
170
4
FPO
PCM
24-Bit, 96kHz
BiCMOS Sign-Magnitude
DIGITAL-TO-ANALOG CONVERTER
TM
FEATURES
DESCRIPTION
● SAMPLING FREQUENCY (fS): 16kHz to 96kHz
The PCM1704 is a precision, 24-bit digital-to-analog
converter with exceptionally high dynamic performance. The ultra-low distortion and excellent lowlevel signal performance makes the PCM1704 an ideal
candidate for high-end consumer and professional
audio applications. When used with a digital interpolation filter, the PCM1704 supports 8X oversampling
at 96kHz.
● 8X OVERSAMPLING AT 96kHz
● INPUT AUDIO DATA WORD: 20-, 24-Bit
● HIGH PERFORMANCE:
Dynamic Range: K Grade = 112dB typ
SNR: 120dB typ
THD+N: K Grade = 0.0008% typ
● FAST CURRENT OUTPUT: ±1.2mA/200ns
● GLITCH-FREE OUTPUT
● PIN-PROGRAMMABLE DATA INVERSION
● POWER SUPPLY: ±5V
● SMALL 20-LEAD SO PACKAGE
The PCM1704 incorporates a BiCMOS sign-magnitude architecture that eliminates glitches and other
nonlinearities around bipolar zero. The PCM1704 is
precision laser-trimmed at the factory to minimize
differential linearity and gain errors.
In addition to high performance audio systems, the
PCM1704 is well-suited to waveform synthesis applications requiring very low distortion and noise.
BCLK
23-Bit DAC A
WCLK
DATA
Serial Input
and
Control Logic
23-Bit DAC B
20-BIT
IOUT
INVERT
Bipolar Offset
Reference and Servo
Power Supply
REF DC SERVO DC
–VDD DGND +VDD
–VCC AGND +VCC BPO DC
International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 • Twx: 910-952-1111
Internet: http://www.burr-brown.com/ • FAXLine: (800) 548-6133 (US/Canada Only) • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132
© 1998 Burr-Brown Corporation
PDS-1454C
Printed in U.S.A. February, 1999
SPECIFICATIONS
All specifications at TA = +25°C, ±VCC = ±VDD = ±5V, fS = 768kHz (96kHz • 8), and 24-bit data, unless otherwise noted.
PCM1704U
PARAMETER
CONDITIONS
MIN
TYP
RESOLUTION
MAX
24
DATA FORMAT
Audio Data Interface Format
Audio Data Code
Sampling Frequency (fS)
Input Clock Frequency
DIGITAL INPUT/OUTPUT
Input Logic Level:
VIH(1)
VIL(1)
VIH(2)
VIL(2)
Input Logic Current:
IIH(1)
IIL(1)
IIH(2)
IIL(2)
DYNAMIC PERFORMANCE(3)
THD+N
VO = 0dB
VO =–20dB
Dynamic Range
Signal-to-Noise Ratio
Low Level Linearity
DC ACCURACY
Gain Error
Bipolar Zero Error
Gain Drift
Bipolar Zero Error Drift
ANALOG OUTPUT
Output Range
Output Impedance
Settling Time
POWER SUPPLY REQUIREMENTS
Voltage Range: +VCC = +VDD
–VCC = –VDD
Combined Supply Current:+ICC
–ICC
UNITS
Bits
20-, 24-Bit, MSB-First
Binary Two’s Complement
16
96
25
kHz
MHz
+2.0
0
–3.0
–5.0
+5.0
+0.8
0
–4.2
V
V
V
V
±10
±10
±10
–100
µA
µA
µA
µA
0.0030
0.0025
0.0015
0.020
0.015
0.01
%
%
%
%
%
%
VIH = +VDD
VIL = 0V
VIH = 0V
VIL = –VDD
PCM1704U
PCM1704U-J
PCM1704U-K
PCM1704U
PCM1704U-J
PCM1704U-K
EIAJ, A-weighted
PCM1704U, U-J
PCM1704U-K
EIAJ, A-weighted
f = 1002Hz at –90dB
0.0025
0.0015
0.0008
0.008
0.007
0.006
102
106
112
110
112
120
±0.5
0°C to 70°C
0°C to 70°C
±1.0
±0.5
±25
±5
±0.0003% of FSR, ±1.2mA Step
±1.2
1.0
200
+4.75
–4.75
+VCC = +VDD = +5.0V
–VCC = –VDD = –5.0V
TEMPERATURE RANGE
Operation
Storage
–25
–55
+5.0
–5.0
5
30
dB
dB
dB
dB
±3.0
±1.0
% of FSR
% of FSR
ppm of FSR/°C
ppm of FSR/°C
mA
kΩ
ns
+5.25
–5.25
8
45
VDC
VDC
mA
mA
+85
+125
°C
°C
NOTES: (1) BCLK, WCLK, DATA. (2) 20BIT, INVERT. (3) Dynamic performance data is tested with 5534 I/V amp with 7.5kΩ feedback resistor. THD+N data is
tested by Shibasoku 725C with 30kHz external LPF, 400Hz HPF, average mode. Input signal frequency = 1.1kHz.
®
PCM1704
2
PIN CONFIGURATION
PIN ASSIGNMENTS
TOP VIEW
SOIC
DATA
BCLK
1
20
2
19
–VCC
REF DC
PIN
NAME
I/O
1
DATA
IN
FUNCTION
Serial Audio Data Input.
2
BCLK
IN
Bit Clock Input for Serial Audio Data.
3
NC
—
No Connection.
4
–VDD
—
Digital Power, –5V.
5
DGND
—
Digital Ground.
Digital Power, +5V.
NC
3
18
NC
6
+VDD
—
–VDD
4
17
SERVO DC
7
WCLK
IN
Data Latch Enable Input.
DGND
5
16
AGND
8
NC
—
No Connection.
+VDD
6
15
AGND
9
20BIT
IN
Input Data Word Selection(1).
7
14
10
INVERT
IN
Input Data Polarity Selection(1).
WCLK
IOUT
11
+VCC
—
Analog Power, +5V.
NC
8
13
NC
12
BPO DC
—
Bipolar Offset Decoupling Capacitor.
20BIT
9
12
BPO DC
13
NC
—
No Connection.
INVERT 10
11
+VCC
14
IOUT
OUT
15
AGND
—
16
AGND
—
Analog Ground.
17
SERVO DC
—
Servo Amplifier Decoupling Capacitor.
PCM1704U
PACKAGE INFORMATION
PRODUCT
PACKAGE
TEMPERATURE
RANGE
PCM1704U
20-Lead SOIC
–25°C to +85°C
PACKAGE
DRAWING
NUMBER(1)
248
Current Output for Audio Signal.
Analog Ground.
18
NC
—
No Connection.
19
REF DC
—
Band Gap Reference Decoupling Capacitor.
20
–VCC
—
Analog Power, –5V.
NOTE: (1) Internal pull-up resistors. Input level must be a voltage from –VDD
to DGND.
NOTE: (1) For detailed drawing and dimension table, please see end of data
sheet, or Appendix C of Burr-Brown IC Data Book.
ELECTROSTATIC
DISCHARGE SENSITIVITY
ABSOLUTE MAXIMUM RATINGS
This integrated circuit can be damaged by ESD. Burr-Brown
recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling
and installation procedures can cause damage.
Supply Voltage, +VDD ,+VCC ............................................................. +6.5V
Supply Voltage Differences .............................................................. ±0.1V
GND Voltage Differences ................................................................. ±0.1V
Digital Input Voltage
(BCLK, WCLK, DATA) ............................ DGND –0.3V to (+VDD + 0.3V)
(20BIT, INVERT) .................................... –VDD – 0.3V to (DGND + 0.3V)
Input Current (any pins except supply pins) ................................... ±10mA
Power Dissipation .......................................................................... 300mW
Operating Temperature Range ......................................... –25°C to +85°C
Storage Temperature ...................................................... –55°C to +125°C
Lead Temperature (soldering, 5s) ................................................. +260°C
Package Temperature (reflow, 10s) .............................................. +235°C
ESD damage can range from subtle performance degradation
to complete device failure. Precision integrated circuits may
be more susceptible to damage because very small parametric
changes could cause the device not to meet its published
specifications.
®
3
PCM1704
SPECIFICATIONS
All specifications at +25°C, ±VCC and ±VDD = ±5.0V, unless otherwise noted.
THD+N vs LEVEL
–90dB SIGNAL SPECTRUM
0
–80
10
–20
–90
1
–40
–60
24-Bit Data
0.10
–80
Amplitude (dB)
16-Bit Data
0.1
–100
THD+N (dB)
THD+N (%)
100
–110
–120
–130
0.001
–100
0.0001
–100 –90
–140
–120
–80
–70
–60
–50
–40
–30
–20
–10
–150
20.0 2.02k 4.02k 6.01k 8.01k 10.0k 12.0k 14.0k 16.0k 18.0k 20.0k
0
Output Level (dBFS)
Output Frequency (Hz)
DAC OUTPUT
–110dB, 24-Bit, 96kHz
DAC OUTPUT
–110dB, 20-Bit, 96kHz
DAC OUTPUT
–120dB, 24-Bit, 96kHz
DAC OUTPUT
–120dB, 20-Bit, 96kHz
®
PCM1704
4
SPECIFICATIONS (CONT)
All specifications at +25°C, ±VCC and ±VDD = ±5.0V, unless otherwise noted.
POWER SUPPLY REJECTION RATIO vs FREQUENCY
Power Supply Rejection Ratio (dB)
–60
–70
–80
–VCC
–90
–100
+VCC
–110
–120
10
20
50
100
200
500
1k
Frequency (Hz)
®
5
PCM1704
THEORY OF OPERATION
For production testing, the output of the DAC is connected
to a current-to-voltage (I/V) converter. The output of the
I/V converter is then connected to a 40kHz, 3rd-order GIC
low-pass filter. The filter output is then passed on to a
programmable gain amplifier to provide gain for low-level
test signals before being fed into an analog distortion
analyzer (Shiba Soku Model 725 or equivalent).
SIGN-MAGNITUDE ARCHITECTURE
Digital audio systems have traditionally used laser-trimmed,
current-source DACs in order to achieve sufficient accuracy.
However, even the best of these suffer from potential lowlevel nonlinearity due to errors in the major carry bipolar
zero transition. Current systems have turned to oversampling
data converters, such as the popular delta-sigma architectures, to correct the linearity problems. This is done, however, at the expense of signal-to-noise performance, and the
noise shaping techniques utilized by these converters creates
a considerable amount of out-of-band noise. If the outputs
are not properly filtered, dynamic performance of the overall
system will be adversely effected.
For the audio bandwidth, the THD+N for the PCM1704 is
essentially flat for all frequencies.
DYNAMIC RANGE
Dynamic range in data converters is specified as the measure
of THD+N at an effective output signal level of –60dBFS
(conforms to EIAJ method with A-weighting applied). Resolution is commonly used as a theoretical measure of dynamic range, but it does not take into account the effects of
distortion and noise at low signal levels. The sign-magnitude
architecture of the PCM1704, with its ideal performance
around bipolar zero, provides a more usable dynamic range
(even with the strict audio definition) than any other previously available D/A converter.
The PCM1704 employs an innovative architecture which
combines the advantages of traditional DACs (e.g., excellent
full-scale performance, high signal-to-noise ratio, and ease
of use) with superior low-level performance. This architecture is referred to as sign-magnitude. Two DACs are combined in a complementary arrangement to produce an extremely linear output. The two DACs share a common
reference, and a common R-2R ladder for bit current sources.
The R-2R ladder utilizes dual balanced current segments to
ensure ideal tracking under all conditions. By interleaving
the individual bits of each DAC and employing precision
laser-trimming of resistors, a highly accurate match between
the two DACs is achieved.
IDLE CHANNEL SIGNAL-TO-NOISE RATIO (SNR)
Another important specification for a digital audio converter
is idle channel signal-to-noise ratio (Idle Channel SNR).
This is the ratio of the noise on the DAC output at bipolar
zero compared to the full-scale range of the D/A converter.
To make this measurement, the digital input is continually
fed the code for bipolar zero, while the output of the DAC
is band limited from 20Hz to 20kHz and A-weighting is
applied. The ideal channel SNR for the PCM1704 is typically greater than 120dB, making it ideal for low noise
applications.
The sign-magnitude architecture, which steps away from
zero with small steps in both directions, avoids any glitching
or large linearity errors, and provides an absolute current
output. The low-level performance of the PCM1704 is such
that true 24-bit resolution can be realized around the critical
bipolar zero point.
OFFSET GAIN AND TEMPERATURE DRIFT
DISCUSSION OF KEY
SPECIFICATIONS
Although the PCM1704’s primary application is in high
performance digital audio systems where dynamic specifications are most important, specifications are also given for
more traditional DC parameters. These include gain error,
bipolar zero offset, temperature gain and offset drift. These
specifications are important in test and measurement systems, which is the other main systems application for the
PCM1704.
TOTAL HARMONIC DISTORTION + NOISE (THD+N)
This is the key specification for the PCM1704. Digital data
words are read into the PCM1704 at eight times the standard
DVD audio sampling frequency of 96kHz (e.g., 8 x 96kHz =
768kHz) to create a sinewave output of 1100Hz. The output
of the DAC is then passed through analog signal conditioning
circuitry before being input to a distortion analyzer.
®
PCM1704
6
AUDIO DATA INTERFACE
Maximum Bit Clock (BCLK) Rate
The maximum BCLK rate is specified as 25MHz. This is
derived from the 8X oversampling of the PCM1704. Given
a 96kHz sampling rate, an 8X oversampling input and a
32-bit frame length, we get:
BASIC OPERATION
The audio interface of the PCM1704 accepts TTL-compatible input levels. The data format at the DATA input of the
PCM1704 is Binary Two’s Complement, with the most
significant bit (MSB) being first in the serial input bit steam.
Table I shows the relationship between the audio input data
and DAC output for the PCM1704. Any number of bits can
precede the 24 bits to be loaded since only the last 24 bits
will be transferred to the parallel DAC register after WCLK
(pin 7) has gone LOW (logic 0).
BINARY TWO’S COMPLEMENT
INPUT DATA (Hex)
DAC OUTPUT
7FFFFF
000000
FFFFFF
800000
+ Full Scale
Bipolar Zero
Bipoar Zero – 1 LSB
– Full Scale
96kHz • 8 • 32 = 24.576MHz
“Stopped Clock” Operation
The PCM1704 is normally operated with a continuous
BCLK input. If BCLK is stopped between input data words,
the last 24 bits shifted in are not actually transferred from the
serial register to the parallel DAC register until WCLK goes
LOW. WCLK must remain LOW until after the first BCLK
cycle of the next data word to insure proper DAC operation.
The specified setup and hold times for DATA and WCLK
must be observed.
DATA FORMAT CONTROL
Data format is controlled by two pins on the PCM1704—the
20BIT and INVERT inputs. Their functions are described in
the following paragraphs and tables.
Input Word Length
TABLE I. Digital Input/DAC Output Relationships.
Audio data is supplied to the DATA (pin 1) input. The bit
clock is used to shift data into the PCM1704 and is supplied
to BCLK (pin 2). All DAC serial input data bits are latched
into the serial input register on the rising edge of BCLK. The
serial-to-parallel data transfer to the DAC occurs on the
falling edge of WCLK. The change in the output of the DAC
occurs at the rising edge of the 2nd BCLK after the falling
edge of WCLK. Figure 1 shows the audio data input format.
Figure 2 shows the input timing relationships.
20BIT (pin 9) is used to select the input data length. Table
II shows the available selections. Pin 9 is internally pulled
up to DGND and therefore, defaults to 24-bit data.
20BIT (Pin 9)
DATA WORD LENGTH
20BIT = H (DGND)
20BIT = L (–VDD)
24-Bit Data Word
20-Bit Data Word
TABLE II. Input Word Length Selection.
B22 B23 B24
B1 B2 B3
DATA (24-Bit)
MSB
LSB
DATA (20-Bit)
B18 B19 B20
B1 B2 B3
LSB
MSB
BCK
WCLK
DAC Output
DATA
FIGURE 1. Audio Input Data Format.
tWCH
tWCL
WCLK
1.4V
tBCH
tBCL
tWH
tWS
BCLK
1.4V
tBCY
DATA
1.4V
tDS
BCLK Pulse Cycle Time
tBCY
40ns
(min)
BCLK Pulse Width HIGH
tBCH
14ns
(min)
BCLK Pulse Width LOW
tBCL
14ns
(min)
BCLK Rising Edge to WCLK Falling Edge
tWH
10ns
(min)
WCLK Falling Edge to BCLK Rising Edge
tWS
10ns
(min)
WCLK Pulse Width HIGH
t WCH
> tBCY
WCLK Pulse WIdth LOW
tWCL
> tBCY
DATA Set-up Time
tDS
10ns
(min)
DATA Hold Time
tDH
10ns
(min)
tDH
FIGURE 2. Audio Input Data Timing.
®
7
PCM1704
Input Data Inversion
supply. No advantage is gained by using separate analog and
digital power supplies. It is more important that the analog
supplies used to drive these pins are as noise and ripple free
as possible to reduce coupling of supply noise to the output.
INVERT (pin 10) is used to select the phase of the input data
presented to the DAC. Table III shows the two options. Pin
10 is internally pulled up to DGND, and therefore defaults
to normal, or non-inverting data.
INVERT (Pin 10)
PHASE
INVERT = H (DGND)
INVERT = L (–VDD)
Normal (non-inverted)
Inverted
Power supply decoupling capacitors should be used at each
supply pin to maximize power supply rejection, as shown in
Figure 3. All ground pins (AGND and DGND) should be
connected to an analog ground plane as close to the PCM1704
as possible. The PCM1704 should reside entirely over the
analog ground plane of the printed circuit board.
TABLE III. Input Data Phase Selection.
Bypass and Decoupling Capacitor Requirements
Various-sized decoupling capacitors can be used, with no
special tolerances being required. Figure 5 shows typical
values used by Burr-Brown on our evaluation fixture, which
designers can use as recommended values. All capacitors
should be located as close to the appropriate pins of the
PCM1704 as possible to reduce noise pickup from surrounding circuitry. Aluminum electrolytic capacitors are
recommended for larger values, while metal-film or monolithic ceramic capacitors are used for smaller values.
APPLICATIONS INFORMATION
POWER SUPPLIES
For this discussion, please refer to the internal connection
diagram for the PCM1704 in Figure 3. The PCM1704 only
requires a ±5V supply for operation. Both positive supplies
(+VDD and +VCC) should be tied together at a single point
and connected to a single +5V analog power supply. Similarly, both negative supplies (–VDD and –VCC) should be tied
at a single point and connected to a single –5V analog power
+5V Supply
2mA
+
3mA
+VDD
+VCC
+
SERVO DC
WCLK
Interface
Logic
and
Logic Bias
BCLK
DATA
Logic
Bias
Reference,
Servo
and
Bipolar
Offset
REF DC
+
+
Analog
Bias
BPO DC
BPO
+
23-Bit
Segment
Switches
+
DGND
IOUT
23-Bit
Current
Segments
–VDD
–VCC
20mA
10mA
+
AGND
–5V Supply
FIGURE 3. PCM1704 Internal Connection Diagram.
®
PCM1704
8
TYPICAL APPLICATION
EXAMPLES
DF1704 or Other
Digital Filter
The audio interface connections for a stereo audio application is shown in Figure 4. The audio data is input to the
digital filter, which then oversampleS the data by a factor of
8. The audio data is then filtered digitally and output to the
PCM1704 DACs.
PCM1704
DOR
DATA
WCKO
WCLK
BCKO
BCLK
24-Bit
96kHz
Data
Figure 5 shows single channel circuit connections for a
typical PCM1704 application. It shows the PCM1704 interface to the digital filter, the I/V converter, and the DAC post
filter. Selection of an appropriate op amp for the I/V converter is critical for obtaining optimum dynamic performance from the PCM1704. The OPA627 is recommended
for this application. Op amps with similar characteristics and
faster settling times may also be used.
PCM1704
DATA
DOL
WCLK
BCLK
The suggested DAC post filter is a second-order lowpass
active filter, using the multiple feedback (MFB) circuit
technique. The OPA2134 is an excellent choice for the op
amp in this circuit, since it is designed for high performance
audio applications. The post filter is used to reconstruct and
band limit the DAC output signal.
FIGURE 4. Audio Interface Connections for Stereo Audio
Application.
100µF
+
DAC
I/V
0.1µF
Post Filter
100µF
+
24-Bit
96kHz Data
–5V
0.1µF
PCM1704U
1
DATA
–VCC 20
2
BCLK
REF DC 19
+
+
C3
C4
+15V
2.5kΩ
8X
Oversampling
Interpolation
Filter
C1
C2
+
Digital
Controls
C1 = 4.7µF
C2 = 4.7µF
C3 = 4.7µF
C4 = 47µF
C5 = 47µF
C6 = 100µF
C7 = 4.7
3
NC
4
–VDD
5
DGND
AGND 16
6
+VDD
AGND 15
7
WCLK
8
NC
9
20BIT
10 INVERT
NC 18
SERVO DC 17
+
C5
47pF
4.7µF
+
IOUT 14
+VCC 11
+
560pF
4.7µF
+
4.7kΩ
U1
NC 13
BPO DC 12
4.7kΩ
2kΩ
OPA627
U2
C6
Audio
Output
1/2
OPA2134
4.7µF
+
2200pF
C7
+
4.7µF
+
+5V
Aluminum
Electrolytics
–15V
0.1µF
0.1µF
100µF
+
100µF
+
FIGURE 5. Typical Application Circuit (one channel shown).
®
9
PCM1704