Cirrus CS5126-KL 16-bit stereo a/d converter for digital audio Datasheet

CS5126
16-Bit, Stereo A/D Converter for Digital Audio
Features
Description
l Monolithic
CMOS A/D Converter
The CS5126 CMOS analog-to-digital converter is an ideal front-end for stereo or monaural digital audio systems.
The CS5126 can be configured to handle two channels
at up to 50 kHz sampling per channel, or it can be configured to sample one channel at rates up to 100 kHz.
- Inherent Sampling Architecture
- Stereo or Monaural Capability
- Serial Output
l Monaural
Sampling Rates up to 100 kHz
The CS5126 executes a successive approximation algorithm using a charge redistribution architecture. On-chip
self-calibration circuitry has 18-bit resolution thus avoiding any degradation in performance with low-level
signals. The charge redistribution technique also provides an inherent sampling function which avoids the
need for external sample/hold amplifiers.
- 50 kHz/Channel Stereo Sampling
l Signal-to-(Noise+Distortion):
l Dynamic
92 dB
Range: 92 dB
- 95 dB in 2X Oversampling Schemes
l Interchannel
Isolation: 90 dB
l 2’s Complement or Binary Coding
l Low Power Dissipation: 260 mW
- Power Down Mode for Portable Applications
l Evaluation
Board Available
Signal-to-(noise+distortion) in stereo operation is 92 dB,
and is dominated by internal broadband noise (1/2 LSB
rms). When the CS5126 is configured for 2X oversampling, digital post-filtering bandlimits this white noise to
20 kHz, increasing dynamic range to 95 dB.
ORDERING INFORMATION
CS5126-KP 0° to 70° C
CS5126-KL
0° to 70° C
28-pin Plastic DIP
28-pin PLCC
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Cirrus Logic, Inc.
Crystal Semiconductor Products Division
P.O. Box 17847, Austin, Texas 78760
(512) 445 7222 FAX: (512) 445 7581
http://www.crystal.com
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6&/.
9'
9'
Copyright  Cirrus Logic, Inc. 1997
(All Rights Reserved)
7(67
6&.02'
28702'
MAR ‘95
DS32F1
1
CS5126
ANALOG CHARACTERISTICS (TA = 25°C; VA+, VD+ = 5V; VA-, VD- = -5V;
Full-Scale Input Sinewave, 1kHz; fclk = 24.576MHz; VREF = 4.5V; Analog Source Impedance = 200Ω;
Stereo operation, L/R toggling at 48 kHz unless otherwise specified.)
Parameter*
Symbol
Min
Typ
Max
Units
-
-
16
Bits
90
70
92
72
-
dB
dB
THD
-
0.001
-
%
DR
90
-
92
95
-
dB
dB
Vn(ic)
-
1/2
-
LSBrms
Iic
88
90
-
dB
Mic
-
0.01
-
dB
Full-Scale Error
FSE
-
±4
-
LSB
Bipolar Offset Error
BPO
-
±4
-
LSB
Aperture Time
tapt
-
30
-
ns
Aperture Jitter
tajt
-
100
-
ps
(Note 2)
Cin
-
200
-
pF
(Note 3)
IA+
IAID+
ID-
-
18
-18
8
-8
23
-23
12
-12
mA
mA
mA
mA
(Notes 3, 4)
Pdo
Pds
-
260
1
350
-
mW
mW
Resolution
Dynamic Performance
Signal-to-(Noise plus Distortion)
VIN = ±FS
(10 Hz to 20 kHz)
VIN = -20dB
(f = 20 kHz)
S/(N+D)
Total Harmonic Distortion
Dynamic Range
Stereo Mode
Monaural (20 kHz BW)
Idle Channel Noise
Interchannel Isolation
(Note 1)
Interchannel Mismatch
dc Accuracy
Analog Input
Input Capacitance
Power Supplies
Power Supply Current
(SLEEP High)
Power Dissipation
Positive Analog
Negative Analog
Positive Digital
Negative Digital
(SLEEP High)
(SLEEP Low)
Power Supply Rejection
Notes: 1.
2.
3.
4.
5.
Positive Supplies
(Note 5)
PSR
84
Negative Supplies
84
One input grounded; dc to 20kHz, Full Scale input on the other channel.
Guaranteed by characterization.
Applies only in the track mode. When converting or calibrating, input capacitance will typically
be 10 pF.
All outputs unloaded. All inputs CMOS levels.
Power dissipation in sleep mode applies with no master clock applied (CLKIN high or low).
With 300mV p-p, 1kHz ripple applied to each supply separately. A plot of typical power supply
rejection appears in the Analog Circuit Connections section.
dB
dB
* Refer to Parameter Definitions at the end of this data sheet.
Specifications are subject to change without notice.
2
DS32F1
CS5126
DIGITAL CHARACTERISTICS (TA = TMIN to TMAX; VA+, VD+ = 5V±10%; VA-,VD- = -5V±10%)
Parameter
Symbol
Min
Typ
Max
Units
High-Level Input Voltage
VIH
2.0
-
-
V
Low-Level Input Voltage
VIL
-
-
0.8
V
VOH
(VD+)-1.0V
-
-
V
VOL
-
-
0.4
V
Iin
-
-
10
µA
High-Level Output Voltage
Low-Level Output Voltage
(Note 6)
Iout = 1.6 mA
Input Leakage Current
Notes: 6. IOUT = -100 µA. This specification guarantees that each digital output will drive one TTL load
(VOH = 2.4V @ IOUT = -40 µA).
RECOMMENDED OPERATING CONDITIONS (AGND, DGND = 0V, see note 7.)
Parameter
DC Power Supplies:
Positive Digital
Negative Digital
Positive Analog
Negative Analog
Analog Reference Voltage
Symbol
Min
Typ
Max
Units
VD+
VDVA+
VA-
4.5
-4.5
4.5
-4.5
5.0
-5.0
5.0
-5.0
VA+
-5.5
5.5
-5.5
V
V
V
V
VREF
2.5
4.5
(VA+)-0.5
V
-VREF
VREF
Analog Input Voltage
(Note 8) VAIN
Notes: 7. All voltages with respect to ground.
8. The CS5126 can accept input voltages up to the analog supplies (VA+, VA-). It will produce an
output of all 1’s for inputs above VREF and all 0’s for inputs below -VREF.
V
ABSOLUTE MAXIMUM RATINGS (AGND, DGND = 0V, all voltages with respect to ground.)
Parameter
DC Power Supplies:
Positive Digital
Negative Digital
Positive Analog
Negative Analog
Input Current, Any Pin Except Supplies
Analog Input Voltage
(AIN and VREF pins)
Digital Input Voltage
Ambient Temperature
(power applied)
(Note 9)
Symbol
Min
Max
Units
VD+
VDVA+
VA-
-0.3
0.3
-0.3
0.3
(VA+)+0.3
-6.0
6.0
-6.0
V
V
V
V
Iin
-
±10
mA
VINA
(VA-)-0.3
(VA+)+0.3
V
VIND
-0.3
(VD+)+0.3
V
TA
-55
125
°C
-65
150
°C
Storage Temperature
Tstg
Notes: 9. Transient currents of up to 100 mA will not cause SCR latch-up.
WARNING: Operation at or beyond these limits may result in permanent damage to the device.
Normal operation is not guaranteed at these extremes.
DS32F1
3
CS5126
SWITCHING CHARACTERISTICS (TA = 25 °C; VA+, VD+ = 5V ± 10%; VA-, VD- = -5V ± 10%;
Inputs: Logic 0 = 0V, Logic 1 = VD+; CL = 50 pF)
Parameter
Master Clock Period
HOLD to SSH2 Falling
(Note 10)
Symbol
Min
Typ
Max
Units
tclk
40
-
-
ns
tdfsh2
-
80
-
ns
HOLD to TRKL, TRKR
SSH1 Falling
tdfsh1
198tclk
-
214tclk+50
ns
HOLD to TRKL, TRKR
SSH1, SSH2 Rising
tdrsh
-
80
-
ns
RST Pulse Width
trst
150
-
-
ns
RST to STBY Falling
tdrrs
-
100
-
ns
RST Rising to STBY Rising
tcal
-
34,584,480
-
tclk
HOLD Pulse Width
thold
2tclk+50
-
192tclk
ns
tdhlri
-30
-
192tclk
ns
SCLK period
tsclk
200
-
-
ns
SCLK Pulse Width Low
tsclkl
50
-
-
ns
SCLK Pulse Width High
tsclkh
50
-
-
ns
SCLK Falling to SDATA Valid
tdss
-
100
140
ns
HOLD Falling to SDATA Valid
tdhs
-
140
200
ns
HOLD to L/R Edge
(Note 10)
Notes: 10. SSH2 only works correctly if HOLD falling edge is within ±30ns of L/R edge OR if HOLD falling edge
occurs between 30ns before HOLD rises to 192 tclk after HOLD falls.
HOLD (i)
t rst
SSH2 (o)
RST
t cal
TRKL (o)
TRKR (o)
t dfsh2
t drsh
STBY
t dfsh1
Control Output Timing
Reset and Calibration Timing
SCLK
t dss
HOLD
t hold
Channel Selection Timing
4
HOLD
t sclkl t sclkh
L/R
t dhlri
t drrs
SDATA
Serial Data Timing
t dhs
t sclk
SDATA
MSB
SCLK
Data Transmit Start Timing
DS32F1
CS5126
GENERAL DESCRIPTION
The CS5126 is a 2-channel, 100kHz A/D converter designed specifically for stereo digital
audio. The device includes an inherent sample/hold and an on-chip analog switch for stereo
operation. Both left and right channels can thus
be sampled and converted at rates up to 50kHz
per channel. Alternatively, the CS5126 can be
implemented in 2X oversampling schemes for
improved dynamic range and distortion.
Output data is available in serial form with
either binary or 2’s complement coding. Control
outputs are also supplied for use with an external
sample/hold amplifier to implement simultaneous sampling.
THEORY OF OPERATION
The CS5126 implements a standard successive
approximation algorithm using a charge-redistribution architecture. Instead of the traditional resistor network, the DAC is an array of binaryweighted capacitors. When not converting, the
CS5126 tracks the analog input signal. The input
voltage is applied across each leg of the DAC
capacitor array, thus performing a voltage-tocharge conversion.
When the conversion command is issued, the
charge is trapped on the capacitor array and the
analog input is thereafter ignored. In effect, the
entire DAC capacitor array serves as analog
memory during conversion much like a hold capacitor in a sample/hold amplifier.
The conversion consists of manipulating the binary-weighted legs of the capacitor array to the
voltage reference and analog ground. All legs
share one common node at the input to the converter’s comparator. This forms a binaryweighted capacitive divider. Since the charge at
the comparator’s input remains fixed, the voltage
at that point depends on the proportion of capacitance tied to VREF versus AGND. The sucDS32F1
cessive-approximation algorithm is used to find
the proportion of capacitance which will drive
the voltage to the comparator’s trip point. That
binary fraction of capacitance represents the converter’s digital output.
Calibration
The ability of the CS5126 to convert accurately
clearly depends on the accuracy of its DAC. The
CS5126 uses an on-chip self-calibration scheme
to insure low distortion and excellent dynamic
range independent of input signal conditions.
Each binary-weighted bit capacitor actually consists of several capacitors which can be manipulated to adjust the overall bit weight. During
calibration, an on-chip microcontroller manipulates the sub-arrays to precisely ratio the bits.
Each bit is adjusted to just balance the sum of
all less significant bits plus one dummy LSB
(for example, 16C = 8C + 4C + 2C + C + C).
The result is typical differential nonlinearity of
±1/4 LSB. That is, codes typically range from
3/4 to 5/4 LSB’s wide.
The CS5126 should be reset upon power-up,
thus initiating a calibration cycle which takes 1.4
seconds to complete. The CS5126 then stores its
calibration coefficients in on-chip SRAM, and
can be recalibrated at any later time.
SYSTEM DESIGN WITH THE CS5126
All timing and control inputs to the CS5126 can
be easily generated from a master system clock.
The CS5126 outputs serial data and a variety of
digital outputs which can be used to control an
external sample/hold amplifier for simultaneous
sampling. The actual circuit connections depend
on the system architecture (stereo or monaural
2X oversampling), and on the sampling characteristics (simultaneous or sequential sampling
between channels).
5
CS5126
System Initialization
Master Clock
Upon power up, the CS5126 must be reset to
guarantee a consistent starting condition and initially calibrate the device. Due to the CS5126’s
low power dissipation and low temperature drift,
no warm-up time is required before reset to accommodate any self-heating effects. However,
the voltage reference input should have stabilized to within 0.25% of its final value before
RST rises to guarantee an accurate calibration.
Later, the CS5126 may be reset at any time to
initiate a single full calibration. Reset overrides
all other functions. If reset, the CS5126 will
clear and initiate a new calibration cycle midconversion or midcalibration.
The CS5126 operates from an externally-supplied master clock. In stereo operation, the master clock frequency is set at 512 times the perchannel sampling rate (256 in 2X oversampling
schemes). The CS5126 can accept master clocks
up to 24.576 MHz for 48kHz stereo sampling or
96kHz monaural oversampling.
When RST is brought low all internal logic
clears. When it returns high a calibration cycle
begins which takes 34,584,480 master clock cycles to complete (approximately 1.4 seconds
with a standard 24MHz master clock). The
CS5126’s STBY output remains low throughout
the calibration sequence, and a rising transition
indicates the device is ready for normal operation.
CIRCUIT CONNECTIONS
A simple power-on reset circuit can be built using a resistor and capacitor as shown in Figure 1. The RC time constant must be long
enough to guarantee the rest of the system is
fully powered up and stable by the end of reset.
+5V
R
Stereo Operation
Figure 2 shows the standard circuit connections
for operating the CS5126 in its stereo mode. The
HOLD, L/R, and SCLK inputs are derived from
the master clock using a binary divider string. A
24.576 MHz master clock is required for a sampling rate of 48kHz per channel.
For 48kHz stereo sampling, the CS5126 must
sample and convert at a 96kHz rate to handle
both channels. The master clock is divided by
256 and applied to the HOLD input. A falling
transition on the HOLD pin places the input in
the hold mode and initiates a conversion cycle.
The HOLD input is latched internally by the
master clock, so it can return high anytime after
one master clock cycle plus 50ns.
CS5126
RST
C
Figure 1. Power-On Reset Circuit
6
All timing and control inputs for channel selection, sampling, and serial data transmission may
be divided down from the master clock. This
yields a completely synchronous system, avoiding sampling and conversion errors due to asynchronous digital noise.
In stereo operation the CS5126 alternately samples and converts the left and right input channels. This alternating channel selection is
achieved by dividing the HOLD input by two
(that is, dividing the master clock by 512) and
applying it to the L/R input. Upon completion of
each conversion cycle, the CS5126 automatically
returns to the track mode. The status of L/R as
DS32F1
CS5126
+5V
+ 1 µF
0.1µF
VA+
Left Ch.
Analog In
Right Ch.
Analog In
Anti Alias
Filter
200Ω
Anti Alias
Filter
200Ω
VD+
SLEEP
AINL
L/R
f clk /512
HOLD
f clk /256
SCLK
f clk /16
1 nF
AINR CS5126
1 nF
f clk
CLKIN
Voltage
Reference
VREF
SDATA
AGND
REFBUF
0.1µF
1 µF +
DGND
VA-
VD-
0.1µF
+ 1 µF
10Ω
0.1µF
-5V
+ 1 µF
0.1µF
10Ω
Figure 2. Stereo Mode Connection Diagram
each conversion finishes determines which channel is acquired and tracked. The L/R input must
remain valid at least until 30ns before the next
falling transition on HOLD.
STEREO MODE PERFORMANCE
As illustrated in Figure 4, the CS5126 typically
provides 92dB S/(N+D) and 0.001% THD. Unlike conventional successive-approximation
ADC’s, the CS5126’s signal-to-noise and dynamic range are not limited by differential nonlinearities (DNL) caused by calibration errors.
Rather, the dominant noise source is broadband
thermal noise which aliases into the baseband.
This white broadband noise also appears as an
idle channel noise of 1/2 LSB (rms).
As shown in the timing diagram in Figure 3, the
CS5126 uses pipelined data transmission. That
is, data from a particular conversion transmits
during the next conversion cycle. The serial
clock input, SCLK, is derived by dividing the
master clock by 16. The MSB (most-significantbit) will be stable on the first rising edge of
SCLK after a falling transition on HOLD. With
a serial clock of fclk/16, transmission of all 16
output bits will span an entire conversion and
acquisition cycle.
L/R (i)
HOLD (i)
SCLK (i)
Left Channel Data
SDATA (o)
Internal
Status
LSB
MSB
Rch Conv.
Right Channel Data
LSB
Lch Acq.
MSB
Lch Conv.
LSB
MSB
Rch Acq.
Figure 3. Stereo Mode Timing
DS32F1
7
CS5126
0dB
Sampling Rate: 48 kHz
Full Scale: 9V p-p
S/(N+D): 91.75 dB
S/(N+D): 92.53 dB
(dc to 20 kHz)
-20dB
-40dB
-60dB
Signal
Amplitude
Relative to
Full Scale
-80dB
-100dB
-120dB
24kHz
1 kHz
Input Frequency
Figure 4. FFT Plot of CS5126 in Stereo Mode
(Left Channel with 1 kHz, Full-Scale Input)
Differential Nonlinearity
The self-calibration scheme utilized in the
CS5126 features a calibration resolution of 1/4
LSB, or 18-bits. This ideally yields DNL of
±1/4 LSB, with code widths ranging from 3/4 to
5/4 LSB’s. This insures consistent sound quality
independent of signal level.
Traditional laser trimmed ADC’s have significant differential nonlinearities which are disastrous to sound quality with low-level signals.
Appearing as wide and narrow codes, DNL
often causes entire sections of the transfer func0dB
tion to be missing. Although their affect is minor
on S/(N+D) with high amplitude signals, DNL
errors dominate performance with low-level signals. For instance, a signal 80dB below fullscale will slew past only 6 or 7 codes. Half of
those codes could be missing with a conventional hybrid ADC capable of only 14-bit DNL.
The most common source of DNL errors in conventional ADC’s is bit weight errors. These can
arise due to accuracy limitations in factory trim
stations, thermal or physical stresses after calibration, and/or drifts due to aging or temperature
variations in the field. Bit-weight errors have a
drastic effect on a converter’s ac performance.
They can be analyzed as step functions superimposed on the input signal. Since bits (and their
errors) switch in and out throughout the transfer
curve, their effect is signal dependent. That is,
harmonic and intermodulation distortion, as well
as noise, can vary with different input conditions.
Differential nonlinearities in successive-approximation ADC’s also arise due to dynamic errors
in the comparator. Such errors can dominate if
the converter’s throughput/sampling rate is
driven too high. The comparator will not be allowed sufficient time to settle during each bit
decision in the successive-approximation algo0dB
Sampling Rate: 48 kHz
Full Scale: 9V p-p
S/(N+D): 83.27 dB
S/(N+D): 84.06 dB
(dc to 20 kHz)
-20dB
-40dB
-20dB
-40dB
-60dB
Signal
Amplitude
Relative to
Full Scale
Sampling Rate: 48 kHz
Full Scale: 9V p-p
S/(N+D): 13.70 dB
S/(N+D): 14.49 dB
(dc to 20 kHz)
-60dB
Signal
Amplitude
Relative to
Full Scale
-80dB
-100dB
-120dB
-80dB
-100dB
-120dB
1 kHz
24kHz
1 kHz
Input Frequency
a. Left Channel with 1 kHz, -10 dB Input
24kHz
Input Frequency
b. Left Channel with 1 kHz, -80 dB Input
Figure 5. FFT Plots of CS5126 in Stereo Mode
8
DS32F1
CS5126
0.020
0.016
THD (%)
rithm. The worst-case codes for dynamic errors
are the major transitions (1/2 FS; 1/4, 3/4 FS;
etc.). Since DNL effects are most critical with
low-level signals, the codes around in mid-scale,
(that is, 1/2 FS), are most important. Yet those
codes are worst-case for dynamic DNL errors!
0.012
0.008
With all linearity calibration performed on-chip
to 18-bits, the CS5126 maintains accurate bit
weights. DNL errors are dominated by residual
calibration errors of ±1/4 LSB rather than dynamic errors in the comparator. Furthermore, all
DNL effects on S/(N+D) are buried by white
broadband noise. This yields excellent sound
quality independent of signal level.
(See Figure 5)
Sampling Distortion
Like most discrete sample/hold amplifier designs, the CS5126’s inherent sample/hold exhibits a frequency-dependent distortion due to
nonideal sampling of the analog input voltage.
The calibrated capacitor array used during conversions is also used to track and hold the analog input signal. The conversion is not performed on the analog input voltage per se, but is
actually performed on the charge trapped on the
capacitor array at the moment the HOLD command is given. The charge on the array ideally
assumes a linear relationship to the analog input
voltage. Any deviation from this linear relationship will result in conversion errors even if the
conversion process proceeds flawlessly.
At dc, the DAC capacitor array’s voltage coefficient dictates the converter’s linearity. This variation in capacitance with respect to applied signal voltage yields a nonlinear relationship between the charge on the array and the analog input voltage and places a bow or wave in the
transfer function. This is the dominant source of
distortion at low input frequencies (Figure 4).
DS32F1
0.004
0
5kHz
10kHz
15kHz
20kHz
25kHz
Analog Input Frequency
Figure 6. THD vs Input Frequency
( 9V p-p Full-Scale Input)
The ideal relationship between the charge on the
array and the input voltage can also be distorted
at high signal frequencies due to nonlinearities
in the internal MOS switches. Dynamic signals
cause ac current to flow through the switches
connecting the capacitor array to the analog input pin in the track mode. Nonlinear on-resistance in the switches causes a nonlinear voltage
drop. This effect worsens with increased signal
frequency and slew rate as shown in Figure 6
since the magnitude of the steady state current
increases. First noticeable at 1kHz, this distortion assumes a linear relationship with input frequency. With signals 20dB or more below fullscale, it no longer dominates the converter’s
overall S/(N+D) performance.
This distortion is strictly an ac sampling phenomenon. If significant energy exists at high frequencies, the effect can be eliminated using an
external track-and-hold amplifier to allow the array’s charge current to decay, thereby eliminating any voltage drop across the switches. Since
the CS5126 has a second sampling function onchip, the external track-and-hold can return to
the track mode once the converter’s HOLD input
falls. It need only acquire the analog input by
the time the entire conversion cycle finishes.
9
CS5126
Simultaneous Sampling
AINL
S/H
The CS5126 offers four digital output signals,
SSH1, SSH2, TRKL, and TRKR which can be
used to control external sample/hold amplifiers
to achieve simultaneous sampling and/or reduce
sampling distortion.
Figure 7 shows the timing relationships for
SSH1, SSH2, TRKL, and TRKR. In the stereo
configuration shown in Figure 1 the CS5126
samples the left and right channels 180° out of
phase. Simultaneous sampling between the left
and right channels can be achieved as shown in
Figure 8a using the CS5126’s SSH2 output. The
external sample/hold will freeze the right channel analog signal as the CS5126 freezes the left
channel input at AINL. It will hold that signal
valid at AINR until the CS5126 begins a right
channel conversion. Once that conversion begins, the sample/hold returns to the sample
mode. The acquisition time for the external sample/hold amplifier must not exceed the CS5126’s
minimum conversion time of 192 master clock
cycles (7.8µs for 48kHz stereo sampling).
AINR
SSH2
a. Standard Connections
S/H
AINL
SSH1
S/H
AINR
b. High-Slew Conditions
Figure 8. Simultaneous Sampling Connections
The CS5126’s sampling distortion with high-frequency, high-amplitude input signals may be improved if a low distortion sample/hold amplifier
is used as shown in Figure 8a. The right channel
input at AINR will appear as dc to the CS5126
resulting in no ac current flowing through the
internal MOS switches. Sampling distortion can
likewise be improved for both channels using
the SSH1 output as shown in Figure 8b. Simi-
L/R (i)
HOLD (i)
Internal
Status
SSH1 (o)
SSH2 (o)
Rch Convert
Lch Acq.
Acq. & Track
Acquire & Track
Lch Convert
Rch Acq.
Rch Convert
Lch Acq.
Hold
Hold
TRKL (o)
TRKR (o)
Figure 7. External Sampling Control Output Timing
10
DS32F1
CS5126
+5V
Analog
Input
+ 1 µF
Anti Alias
Filter
200 Ω
0.1 µF
VA+
1nF
SLEEP
L/R
CS5126
AGND
SCLK
f clk /16
-5V
f clk
SDATA
DGND
REFBUF
0.1 µF
+5V*
f clk /256
CLKIN
+
+ 1 µF
HOLD
VREF
0.1 µF
1 µF
0.1 µF
VD+
AINL*
AINR
Voltage
Reference
10 Ω
VA-
+
VD-
10 Ω
0.1 µF
1 µF
* AINR can alternatively be used
with L/R grounded
Figure 9. Monaural 2X Oversampling Connections
larly, the acquisition time for the external sample/hold amplifiers must not exceed the minimum conversion time of 192 master clock cycles
(7.8µs for 48kHz stereo sampling).
Oversampling
The CS5126 can alternatively be used to oversample one channel (monaural) by 2X simply by
tying the L/R input high or low. This moves
much of the anti-alias burden from analog filters
to digital post-filtering. The analog filters’ corner can be pushed out in frequency with lower
roll-off, allowing lower passband ripple and
more linear phase in the audioband. Digital FIR
filtering, meanwhile, can be used to implement
high roll-off filters with ultra-low passband ripple and perfectly linear phase.
Oversampling not only improves system-level
filtering performance, but it also enhances the
ADC’s dynamic range and distortion characteristics. All noise energy in a sampled, digital
signal aliases into the baseband between dc and
one-half the sampling rate. For an ideal succesDS32F1
sive-approximation ADC the noise spectral content is white. Therefore, in a 2X oversampling
scheme such as 96kHz sampling the ADC’s
noise will be be spread uniformly from dc to
48kHz. Digital post-filtering then rejects noise
outside of the 20kHz or 22kHz bandwidth, resulting in improved signal-to-noise and dynamic
range. For a white noise spectrum, a 2X reduction in bandwidth yields a 3dB improvement in
dynamic range.
Due to its on-chip self-calibration scheme, the
CS5126’s dynamic range is limited only by
white broadband noise rather than signal-dependent DNL errors. Therefore, the CS5126 picks up
a full 3dB improvement in dynamic range to
95dB when implemented in 2X oversampling
schemes.
Oversampling and digital filtering also enhance
the ADC’s distortion performance. Consider for
example a full-scale 15kHz input signal to the
CS5126 sampling at 96kHz. Sampling distortion
produces THD of approximately 0.005% (86dB)
at the converter’s output. Most of the distortion
energy resides in the second and third harmonics
11
CS5126
CS5126
512 f s
CLKIN
DINL
SDATA
Left Channel
Analog In
Anti Alias
Filter
AINL
HOLD
L/R
SCLK
L/R
SCLK
AINL
HOLD
IBO
+5V
Right Channel
Analog In
Anti Alias
Filter
IBCK
256 f s
CKIN
OBCK
32 f s
WDCK
2 fs
fs
LRCK
DOL
DATA IN
DINR
SDATA
CLKIN
SM5805
Digital Filter
CS5126
System
Figure 10. Example Oversampling System Diagram
at 30kHz and 45kHz. Meanwhile, digital filters
such as the SM5805 shown in Figure 10 will
roll-off rapidly from 22kHz to 28kHz and reject
distortion energy in the second, third, and fourth
harmonics. Clearly, oversampling results in superior system-level distortion.
Still, if the CS5126’s distortion performance
with high-frequency, high-amplitude signals
must be enhanced in 2X oversampling schemes,
the TRKL or TRKR outputs can be used. Either
TRKL or TRKR will fall at the end of each conversion cycle depending on which channel is being acquired. The AINL and TRKL connections
(or AINR and TRKR) can be used as shown in
Figure 11 to control an external low-distortion
sample/hold to create an effective dc input for
the CS5126 and remove sampling distortion.
The CS5126 has a power down mode, initiated
by bringing SLEEP low. During power down,
the A/D Converter’s calibration information is
retained. The CS5126 may be used for conversion immediately after SLEEP is brought high.
S/H
Left
Analog In
AINL
TRKL
+5V
L/R
Figure 11. High-Slew Monaural Connections
0dB
Sampling Rate: 96 kHz
Full Scale: 9V p-p
S/(N+D): 91.44 dB
S/(N+D): 95.25 dB
(dc to 20 kHz)
Digital Circuit Connections
-20dB
When TTL loads are utilized the potential for
crosstalk between digital and analog sections of
the system is increased. This crosstalk is due to
high digital supply and signal currents arising
from the TTL drive current required of each
digital output. Connecting CMOS logic to the
digital outputs is recommended. Suitable logic
families include 4000B, 74HC, 74AC, 74ACT,
and 74HCT.
-40dB
-60dB
Signal
Amplitude
Relative to
Full Scale
-80dB
-100dB
-120dB
1 kHz
48kHz
Input Frequency
Figure 12. FFT Plot of CS5126 in Monaural 2X Oversampling Mode
12
DS32F1
CS5126
ANALOG CIRCUIT CONNECTIONS
Most popular successive-approximation A/D
converters generate dynamic loads at their analog connections. The CS5126 internally buffers
all analog inputs (AIN, VREF, and AGND) to
ease the demands placed on external circuitry.
However, accurate system operation still requires
careful attention to details at the design stage regarding source impedances as well as grounding
and decoupling schemes.
A large capacitor connected between VREF and
AGND can provide sufficiently low output impedance at the frequencies of interest, so the reference voltage can simply be derived as shown
in Figure 13a. Although very low cost, this reference has almost no power supply rejection
from the VA+ line.
Alternatively, a more stable and precise reference can be generated using a TL431 shunt reference from T.I. or Motorola, as shown in Figure 13b.
Reference Considerations
An application note titled "Voltage references
for the CS501X/CSZ511X Series of A/D Converters" is available which describes the dynamic
load conditions presented by the VREF input on
Crystal’s self-calibrating SAR A/D converters
(including the CS5126). As the CS5126 sequences through bit decisions it switches portions of the capacitor array to the VREF pin in
accordance with the successive-approximation
algorithm. For proper operation, the source impedance at the VREF pin must remain low at
frequencies up to 1MHz.
VA+
IN4148
10 k Ω
The magnitude of the current load on the external reference circuitry will scale to the master
clock frequency. At the full-rated 24 MHz clock
the reference must supply a maximum load current of 20µA peak-to-peak (2µA typical). An
output impedance of 2Ω will therefore yield a
maximum error of 40mV. With a 4.5V reference
and LSB size of 138mV this would insure approximately 1/4 LSB accuracy. A 10µF capacitor exhibits an impedance of less than 2Ω at frequencies greater than 16kHz. A high-quality tantalum capacitor in parallel with a smaller ceramic capacitor is recommended.
+12 or +15 V
2kΩ
100 Ω
50 Ω
VREF
0.1 µF
+
100 µF
0.1 µF
TL431
VREF
1.6 k Ω
+
2kΩ
10 µF
AGND
AGND
a. Simple Reference
0.1 µF
b. Low-cost Shunt Reference
Figure 13. Suggested Voltage Reference Circuits
DS32F1
13
CS5126
The CS5126 can operate with a wide range of
reference voltages, but signal-to-noise performance is maximized by using as wide a signal
range as possible. The recommended reference
voltage is 4.5 volts. The CS5126 can actually
accept reference voltages up to the positive analog supply. However, as the reference voltage
approaches VA+ the external drive requirements
may increase at VREF.
An internal reference buffer is used to protect
the external reference from current transients
during conversion. This internal buffer enlists
the aid of an external 0.1µF ceramic capacitor
which mu st be tied between it s output,
REFBUF, and the negative analog supply, VA-.
Analog Input Connection
Each time the CS5126 finishes a conversion cycle it switches the internal capacitor array to the
appropriate analog input pin, AINL or AINR.
This creates a minor dynamic load at the sampling frequency. All throughput specifications
apply for maximum analog source impedances
of 200Ω at AINL and AINR. In addition, the
comparator requires source impedances of less
than 400Ω around 2MHz for stability, which is
met by practically all bipolar op amps. For more
information, see our Application Note: "Input
Buffers for the CS501X/CSZ511X Series of A/D
Converters"
Analog Input Range/Coding Format
The CS5126 features a bipolar input range with
the reference voltage applied to VREF defining
both positive and negative full-scale. The coding
format is set by the state of the CODE input. If
high, coding is 2’s complement; if low, the
CS5126’s output is in offset-binary format.
14
Grounding and Power Supply Decoupling
The CS5126 uses the analog ground
connection, AGND, only as a reference voltage.
No dc power or signal currents flow through the
AGND connection, thus minimizing the potential
for interchannel crosstalk. Also, AGND is completely independent of DGND. However, any
noise riding on the AGND input relative to the
system’s analog ground will induce conversion
errors. Therefore, both analog inputs and the reference voltage should be referred to the AGND
pin, which should be used as the entire system’s
analog ground. The digital and analog supplies
are isolated within the CS5126 and are pinned
out separately to minimize coupling between the
analog and digital sections of the chip. All four
supplies should be decoupled to their respective
grounds using 0.1 µF ceramic capacitors. If significant low frequency noise is present on the
supplies, 1 µF tantalum capacitors are recommended in parallel with the 0.1 µF capacitors.
The positive digital power supply of the CS5126
must never exceed the positive analog supply by
more than a diode drop or the CS5126 could
experience permanent damage. If the two supplies are derived from separate sources, care
must be taken that the analog supply comes up
first at power-up. The system connection diagrams in figures 2 and 9 show a decoupling
scheme which allows the CS5126 to be powered
from a single set of ± 5V rails. The positive
digital supply is derived from the analog supply
through a 10Ω resistor to avoid the analog supply dropping below the digital supply. If this
scheme is utilized, care must be taken to insure
that any digital load currents (which flow
through the 10 Ω resistors) do not cause the
magnitude of digital supplies to drop below the
analog supplies by more than 0.5 volts. Digital
DS32F1
CS5126
supplies must always remain above the minimum specification.
As with any high-precision A/D converter, the
CS5126 requires careful attention to grounding
and layout arrangements. However, no unique
layout issues must be addressed to properly apply the CS5126. The CDB5126 evaluation board
is available for the CS5126, which avoids the
need to design, build, and debug a high-precision PC board to initially characterize the part.
The board comes with a socketed CS5126, and
can be quickly reconfigured to simulate any
combination of sampling and master clock conditions.
Power Supply Rejection
The CS5126 features a fully differential comparator design, resulting in superior power supply
rejection. Rejection is further enhanced by the
on-chip self-calibration and "auto-zero" process.
Figure 14 shows worst-case rejection for all
combinations of conversion rates and input con90
Confirm Optimum
Schematic & Layout
Before Building Your Board.
For Our Free Review Service
Call Applications Engineering.
C a l l : ( 5 1 2 ) 4 4 5 - 7 2 2 2
80
Power Supply Rejection (dB)
Schematic & Layout Review Service
70
60
50
40
30
20
1 kHz
10 kHz
100 kHz
1 MHz
Power Supply Ripple Frequency
Figure 14. Power Supply Rejection
ditions.
DS32F1
15
CS5126
PIN DESCRIPTIONS
NEGATIVE DIGITAL POWER
RESET & INITIATE CALIBRATION
MASTER CLOCK INPUT
NO CONNECTION
STANDBY (CALIBRATING)
DIGITAL GROUND
POSITIVE DIGITAL POWER
TRACKING LEFT CHANNEL
TRACKING RIGHT CHANNEL
SIMULTANEOUS SAMPLE/HOLD 1
SIMULTANEOUS SAMPLE/HOLD 2
HOLD & CONVERT
LEFT/RIGHT CHANNEL SELECT
SERIAL DATA CLOCK
VDRST
CLKIN
NC
STBY
DGND
VD+
TRKL
TRKR
SSH1
SSH2
HOLD
L/R
SCLK
NEGATIVE DIGITAL POWER
VD-
RESET & INITIATE CALIBRATION
RST
MASTER CLOCK INPUT
1
28
2
27
3
26
4
25
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
SLEEP
TST4
TST3
VA+
AINR
VAAGND
REFBUF
VREF
AINL
TST2
TST1
CODE
SDATA
SLEEP (LOW POWER) MODE
TEST
TEST
POSITIVE ANALOG POWER
RIGHT CHANNEL ANALOG INPUT
NEGATIVE ANALOG POWER
ANALOG GROUND
REFERENCE BUFFER
VOLTAGE REFERENCE
LEFT CHANNEL ANALOG INPUT
TEST
TEST
BINARY/2’s COMPLEMENT SELECT
SERIAL DATA OUTPUT
SLEEP
SLEEP (LOW POWER) MODE
CLKIN
TST4
TEST
NO CONNECTION
NC
TST3
TEST
STANDBY (CALIBRATING)
STBY
VA+
POSITIVE ANALOG POWER
AINR
RIGHT CHANNEL ANALOG INPUT
VA-
NEGATIVE ANALOG POWER
AGND
ANALOG GROUND
DIGITAL GROUND
DGND
5
4
3
2
1
28 27 26 25
6
POSITIVE DIGITAL POWER
TRACKING LEFT CHANNEL
VD+
TRKL
TRACKING RIGHT CHANNEL
TRKR
SIMULTANEOUS SAMPLE/HOLD 1
SSH1
24
7
8
23
top
view
22
9
21
10
20
11
19
REFBUF REFERENCE BUFFER
VREF
VOLTAGE REFERENCE
12 13 14 15 16 17 18
SIMULTANEOUS SAMPLE/HOLD 2
SSH2
AINL
LEFT CHANNEL ANALOG INPUT
HOLD & CONVERT
HOLD
TST2
TEST
LEFT/RIGHT CHANNEL SELECT
L/R
TST1
TEST
SERIAL DATA CLOCK
SCLK
CODE
BINARY/2’s COMPLEMENT SELECT
SDATA
SERIAL DATA OUTPUT
16
DS32F1
CS5126
Power Supply Connections
VD+ - Positive Digital Power, PIN 7.
Positive digital power supply. Nominally +5 volts.
VD- - Negative Digital Power, PIN 1.
Negative digital power supply. Nominally -5 volts.
DGND - Digital Ground, PIN 6.
Digital ground reference.
VA+ - Positive Analog Power, PIN 25.
Positive analog power supply. Nominally +5 volts.
VA- - Negative Analog Power, PIN 23.
Negative analog power supply. Nominally -5 volts.
AGND - Analog Ground, PIN 22.
Analog ground reference.
Oscillator
CLKIN - Clock Input, PIN 3.
All conversions and calibrations are timed from a master clock which must be externally
supplied.
Digital Inputs
HOLD - Hold, PIN 12.
A falling transition on this pin sets the CS5126 to the hold state and initiates a conversion. This
input must remain low at least one master clock cycle plus 50ns.
L/R - Left/Right Input Channel Select, PIN 13.
Status at the end of a conversion cycle determines which analog input channel will be acquired
for the next conversion cycle.
SLEEP - Sleep, PIN 28.
When brought low causes the CS5126 to enter a low-power quiescent state. All calibration
coefficients are retained in memory, so no recalibration is needed after returning to the normal
operating mode.
CODE - 2’s Complement/Binary Coding Select, PIN 16.
Determines whether data appears in 2’s complement or offset-binary format. If high, 2’s
complement; if low, offset-binary.
SCLK - Serial Clock, PIN 14.
Serial data changes status on a falling edge of this input, and is valid on a rising edge.
DS32F1
17
CS5126
RST - Reset, PIN 32.
When taken low, all internal digital logic is reset. Upon returning high, a full calibration
sequence is initiated which takes 34,584,480 master clock cycles to complete.
Analog Inputs
AINL, AINR - Left and Right Channel Analog Inputs, PINS 19 and 24.
Analog input connections for the left and right input channels.
VREF - Voltage Reference, PIN 20.
The analog reference voltage which sets the analog input range. Its magnitude sets both positive
and negative full-scale.
Digital Outputs
STBY - Standby (Calibrating), PIN 5.
Indicates calibration status after reset. Remains low throughout the calibration sequence and
returns high upon completion.
SDATA - Serial Output, PIN 15.
Presents each output data bit on a falling edge of the SCLK input. Data is valid to be latched
on the rising edge of SCLK.
SSH1, SSH2 - Simultaneous Sample/Hold 1 and 2, PINS 10 and 11.
Used to control external sample/hold amplifier(s) to achieve simultaneous stereo sampling.
TRKL, TRKR - Tracking Left, Tracking Right, PINS 8 and 9.
Indicate the end of a conversion cycle. Either TRKL or TRKR falls at the end of a conversion
cycle depending on the status of L/R and which channel is to be tracked.
Analog Outputs
REFBUF - Reference Buffer Output, PIN 21.
Reference buffer output. A 0.1 µF ceramic capacitor must be tied between this pin and VA-.
Miscellaneous
NC - No Connection, PIN 4.
Must be left floating for proper operation.
TST1, TST2, TST3, TST4 - Test, PINS 17, 18, 26, 27.
Allow access to the CS5126’s test functions which are reserved for factory use. Must be tied to
VD+.
18
DS32F1
CS5126
PARAMETER DEFINITIONS
Total Harmonic Distortion - The ratio of the rms sum of all harmonics up to 20 kHz to the rms
value of the signal. Units in percent.
Signal-to-Noise plus Distortion Ratio - The ratio of the rms value of the signal to the rms sum of all
other spectral components below the Nyquist rate (excepting dc), including distortion components. Expressed in decibels.
Dynamic Range - Full-scale Signal-to-Noise plus Distortion with the input signal 60dB below fullscale. Units in decibels.
Interchannel Isolation - A measure of crosstalk between the left and right channels. Measured for
each channel at the converter’s output with the input under test grounded and a full-scale signal applied to the other channel. Units in decibels.
Full Scale Error - The deviation of the last code transition from the ideal (VREF-3/2 LSB’s) after all
offsets have been externally compensated. Units in decibels relative to full scale.
Bipolar Offset - The deviation of the mid-scale transition (011...111 to 100...000) from the ideal
(1/2 LSB below AGND). Units in microvolts.
Interchannel Mismatch - The difference in output codes between the left and right channels with the
same analog input applied. Units expressed in decibels relative to full scale. Tested at full scale input.
Aperture Time - The time required after the hold command for the sampling switch to open fully.
Effectively a sampling delay which can be nulled by advancing the sampling signal. Units in nanoseconds.
Aperture Jitter - The range of variation in the aperture time. Effectively the "sampling window"
which ultimately dictates the maximum input signal slew rate acceptable for a given accuracy. Units in
picoseconds.
DS32F1
19
• Notes •
CDB5126
Evaluation Board for CS5126
Features
Description
l Serial to Parallel Conversion
l All Timing Signals Provided
l Adjustable Voltage Reference
l ±5 V Regulators
l Digital and Analog Patch Areas
The CDB5126 Evaluation Board allows fast evaluation of
the CS5126 2-Channel, 16-bit Analog-to-Digital
Converter.
Analog inputs are via BNC connectors. Digital outputs
are available both directly from the ADC in serial form,
and in 16 bit parallel form.
An adjustable monolithic voltage reference is included.
ORDERING INFORMATION
CDB5126
Evaluation Board
I
0V
Analog
Patch
Area
-15V
AGND
+5V Regulators
VA+
Voltage
Reference
+15V
VA-
VD-
+5V
DGND
VL+
VA-
EXT
CLKIN
AINL
Clock
Generator
CLKIN
CS5126
Digital
Patch
Area
VD+
VREF
REFBUF
AINL
0V
Sampling
Timing
Control
HOLD
L/R
HOLD
AINR
AINR
SDATA
Mode
Select
Switches
SLEEP
Serial
Clock
Switching
SCLK
TEST
TRKR
TP
TEST
TRKL
SSH1
TP
SSH2
TP
CODE
Cirrus Logic, Inc.
Crystal Semiconductor Products Division
P.O. Box 17847, Austin, Texas 78760
(512) 445 7222 FAX: (512) 445 7581
http://www.crystal.com
TP
Serial
to
Parallel
Conversion
Copyright  Cirrus Logic, Inc. 1998
(All Rights Reserved)
Header
BP/UP
MAR ‘95
DS32DB5
21
CDB5126
Power Supplies
The source driving the analog inputs should have
a low (< 200 Ω at high frequency) output impedance. Be careful not to overdrive the inputs
outside the power supplies of the ADC (± 5 V).
Figure 2 shows the buffer circuit used at the
Crystal factory to drive the ADC when performing FFT testing. See the CS5126 data sheet for
example FFT test results.
Figure 1 shows the power supply arrangements.
The analog section of the board is powered by
± 15 volts, which is regulated down to ± 5 V for
the ADC. A separate +5 V digital supply is required to power the discrete logic. Be sure to
switch on the ± 15 V at the same time as, or before, the + 5 V logic supply. This will make sure
that the CLK and other logic signal are not driving the part before it is powered.
Voltage Reference
As shown in Figure 3, an LT1019-5 voltage reference provides a stable 4.5 V reference for the
ADC. An optional OP27 buffer filters out excess
reference noise and provides a very low output
impedance. To try the unbuffered LT1019-5 directly, solder in J2 and cut the VREF trace.
Alternatively the shunt reference based reference
schematic given in the CS5126 data sheet can be
evaluated by adding it to the analog patch area.
Analog Input
The analog input range is either ± Vref in the bipolar mode or 0 V to +Vref in the unipolar mode.
The voltage reference is factory set to the recommended value of +4.5 volts, so the typical input
signal ranges become ± 4.5 volts or 0 V to +4.5
V.
+15V
+15V
IN
C20
D1 +
47 µF
0V
Analog
+ C21
D2
47 µF
78L05
U4
OUT
COM
+5VA
C22
C23
0.22 µF
0.47 µF
C24
C25
0.22 µF
J1
0.47 µF
COM
-15V
IN
-15V
+5V
Logic
OUT
U5
79L05
-5VA
+5VL
D3
+ C27
47 µF
C26
0.1 µF
0V
Digital
TP16
Figure 1. Power Supplies
22
DS32DB5
CDB5126
In A
1 nF C0G
ceramic
4.99 k
4.99 k
6.81 k
1 nF C0G
ceramic
V+
7
2 OP27
4.99 k
4.99 k
In B
1 nF C0G
ceramic
4
3
200
Vout
6
1 nF C0G
ceramic
VV+
1M
1M
50 k
Offset
ADJ
Notes:
121 k
V-
1) In B and offset adjust are optional.
2) Offset adjustment range is
+ 10 mV with values shown.
10
+15 V
V+
1 µF
tantalum
35 V
0.01 µF
ceramic
1 µF
tantalum
35 V
0.01 µF
ceramic
-15 V
V10
Figure 2. Example Input Buffer Circuit (not provided on the CDB5126 evaluation board)
+15V
+15V
2
6
IN OUT
U2
LT1019-5
GND
4
R2
1k
TRIM
5
CW
R1
25 k
3
+ C1
10 µF
C2
2
0.1 µF
7
OP27 6
4
C7
C6
0.1 µF
R3
TP1
J2
22
+ C8
16 µF
R4
TP4
0.01 µF 47 k
C9
20
U1
CS5126
VREF
0.1 µF
22
AGND
R5
1k
C4
0.1 µF
-15V
Figure 3. Voltage Reference
DS32DB5
23
CDB5126
BNC connector. R15 is an optional 75 Ω terminating resistor for the external clock BNC.
A 5 volt reference can be used provided the supplies to the ADC are elevated to ± 5.3 volts. This
can be done by inserting 22 Ω resistors in series
with the regulator (U4 and U5) common leads.
Master Clock
The CS5126 requires an external 24.576 MHz
clock for a 96 kHz sample rate. A 24.576 MHz
clock oscillator module (U6) is provided. An external clock can also be selected by P1, via a
10
3
0
R15
U7
HOLD
CLKIN
75
SCLK
L/R
4
NC
TST
TP10
U1
CS5126
RST
DGND
TST2
20
C9
22
C9
VREF
TST4
TST1
AGND
CODE
SLEEP
STBY
TP2
24
AINR
TRKL
AINR
TRKR
BNC1 TP3
19
AINL
SSH1
AINL
SSH2
BNC2
21
VA-
0.1 µF
-5VA
SDATA
REFBUF
C10
23
C18
+ 1 µF
1 µF
12
TP13
14
TP12
13
TP11
26
P2 0
1
P3
R16
R23
1k
47 k
R29
75
HOLD
P4
R8, p.4 +5VL
2
6
47 k
R14
10 k
SW7
C13
0.1 µF
18
BNC4
0
1
2
R17
10 k
+5VL
p.5
25
VA+
TP15
J4
0.1 µF
7
VD+
p.3
P1 1
BNC3
+5VL
P9
U8, U9 U7, Q9 Output
+ C16
p.6
EXT
CLKIN
R7
0.1 µF
1 µF
C14
p.7
U6
C15
+ C17
p.2
+5VA
R8
47 k
27
17
16
28
5
8
9
10
11
15
1
TP9
TP8
TP7
P8
5
4
2
3
6-way DIP switch
SW1 thru SW6
P8
TP6
TP5
TP14
U8, pin 14
VD10
1
C12
C11 R6
C19
0.1 µF 0.1 µF
+ 1 µF
Figure 4. ADC Connections
24
DS32DB5
CDB5126
ally used to toggle L/R select. This set of clocks
causes the CS5126 to continuously convert, generating a continuous stream of serial data bits. To
correctly identify the last bit of each word, U12
produces a pulse only when Q4, Q5, Q6, Q7, Q8,
and optionally Q9 are all high. This state is
latched by U10A to prevent any glitches, and the
resulting signal (attached to TP18) is used to
latch the U8-U9 shift registers.
Sampling Clock Generation Logic
The CS5126 requires an external serial clock to
clock out the data. The CDB5126 board has the
logic necessary to generate the master clock,
HOLD, L/R, and SCLK to allow fast evaluation
of the ADC. In most systems, these timing signals will be available from the main timing
section, typically generated by a logic array of
some variety. HOLD may be brought in externally via a
BNC, optionally terminated by R29. SCLK and
L/R select may be brought in externally via test
points and removing jumpers.
Serial to Parallel Conversion
Figure 6 shows the serial to parallel conversion
circuit. Two 74HC595 shift register/latches connected in series with SDATA assemble 16-bit,
parallel words, clocked by SCLK. As discussed
above, the outputs are latched inside the
74HC595 at the end of each 16-bit word. The
outputs are brought out to a 40-way header (P5).
Only low capacitance, twisted pair, ribbon cable
should be used.
Figure 5 shows the on-board clock generation
circuitry. U7 (74HC4040) produces binary divided ratios of the 24.576 MHz master clock. Q4
generates a 1.5 MHz clock, which is used for
SCLK. Q8 generates a 96 kHz clock, used for
HOLD, and Q9 generates a 48 kHz clock, option+5VL
R16
p.4
47 k
R18
47 k
R19
47 k
P4
12
U11
11
0
1
2
C31
P10
3 14
4 U12
C29
P12
0.1 µF
0
15
14
+5VL
12
16
Q12
Q11
Q10
Q9
14
U6 OUT
Crystal
0.1 µF Oscillator
Module
7
8
C28
P1
(CLKIN)
10
11
8
Q1
CLK
RST
Q2
U7
Q3
74HCT4040
1
C32
6
+5VL
U11, pin 8
0.1 µF
R16, p.3
5
13
1
R16, p.5
47 k
Q4
Q5
Q6
Q7
Q8
12
9
2
7
7
1
47 k
C30
14
2
U11
8
74HC30
1
7
14
3
74HC00
4
Q
0.1 µF
0.1 µF
2
CLR
J
U10A
74HC73
K
3
Q
12
13
11
11
6
5 R28
1
3 470
2
P7
P9
4
0
13
P2
(HOLD)
P3
U8, U9
Shift CLK
1
U8, U9
Latch CLK
Figure 5. Timing Generator
DS32DB5
25
CDB5126
+5VL
R 31
47 k
C3
0.1 µF
11
12
P7
Shift CLK
Latch CLK
U9
74HC595
8
14
DATA IN
OE
13
0.1 µF
13
OE
9
DATA OUT
+5VL
16
U8
C5 8
74HC595
12
11
14
SDATA (U1)
P6
CS
16
10
RST
P9, P3
R 22
47 k
QH 7
QG 6
QF 5
QE 4
QD 3
QC 2
QB 1
Q A 15
D15 (MSB)
D14
D13
D12
D11
D10
D9
D8
P5
QH
QG
QF
QE
Latch CLK
QD
Shift CLK
QC
QB
QA
DATA IN
RST
10
+5VL
R 30
47 k
40 way
header
7
D7
6
D6
5
D5
4
D4
3
D3
2
D2
1
D1
15
D0 (LSB)
+5VL
DACK
DRDY
R16, p.7
R16, p.6
47 k
47 k
5
4
74HC00
U11
6
+5VL
R16, p.9
47 k
TP 18
P12
TRKL (U1)
TRKR (U1)
J
5
6
RST
U10B
74HC73
Q
8
TP 17
74HC00
10 U11
9
7
P11 1
0
10
K
8
0 P8
1
2
3
4
Figure 6. Serial to Parallel Converter
26
DS32DB5
CDB5126
J1
-
Joins analog ground to digital ground on the board.
J2
-
Joins LT1019-5 reference directly to the VREF pin on the ADC. Before doing this, break the connection
between R3 and the ADC VREF pin by using a twist drill to remove the central feedthrough. This option
allows evaluation of different reference configurations.
J4
-
Connects an external clock to CLKIN on the ADC.
Table 1. Solder Link Options
P1
0 - Select external clock via BNC connector
∗
1 - Select on-board clock generated by U6.
P2
∗
0 - Select on-board generated HOLD.
1 - Select external HOLD via BNC connector.
P3
∗
Connect SCLK to on-board shift registers.
P4
∗
P6
∗
P7
∗
0 - Connects the on-board Data Ready signal to the shift registers.
1 - Connects the NAND gate outputs (U11, pin 11) to the shift registers.
P8
∗
1 - Connects the un-latched on-board Data Ready signal to P5.
2 - Connects TRKL and TRKR ANDED together to P5. This signal can be used as an "End of Convert"
indicator.
3 - Connects TRKL to P5.
4 - Connects TRKR to P5.
P9
∗
0 − Pull L/R select pin high, selecting the left channel only.
1 - Drive L/R select at 48 kHz from the on-board timing generator.
2 - Pull L/R select pin low, selecting the right channel only.
Connect the OE pins of the shift registers to ground. Permanently enables the 3-state output buffers.
Connects the on-board generated SCLK to the rest of the on-board circuitry.
P10 ∗
0 - Causes the on-board Data Ready generating circuit to flag data ready every conversion.
1 - Causes the on-board Data Ready generating circuit to flag data ready every left conversion. P4 must
be in position 1 for this to work.
2 - Causes the on-board Data Ready generating circuit to flag data ready every right conversion. P4 must
be in position 1 for this to work.
P11
0 - Connects TRKL & TRKR to U10B, the handshake flip-flop.
∗
P12 ∗
∗
1 - Connects the on-board data ready signal to U10B.
0 - Allows selection of the DRDY signals for alternate channels.
1 - Connects the TRKL & TRKR to U11, pin 13.
Factory default state for CS5126
Table 2. Shorting Plug Selectable Options
DS32DB5
27
CDB5126
Test Points
U10B (74HC73) is used as a handshake flip-flop
with the computer system attached to the evaluation board. The board brings DRDY low. The
computer reads the data and then sets DACK momentarily high. This resets U10B for the next
word. This handshake can be disabled by setting
P8 jumper to position 1.
DIP Switches
Figure 7 and Table 3 shows the DIP switch selectable options.
SLEEP mode
set at logic "1" for CS5126
set at logic "1" for CS5126
Output Encoding
No Connect
(user option)
ON
1
2
4
5
6
OPEN
Logic "0" = ON = CLOSED / Logic "1" = OFF = OPEN
Table 4 is a list of the test points provided on the
Evaluation Board.
CS5126
TP1
VREF
TP2
AINR
TP3
AINL
TP4
AGND
TP5
SSH2
TP6
SSH1
TP7
TRKR
TP8
TRKL
TP9
STBY
TP10
NC
TP11
L/R
TP12
SCLK
TP13
HOLD
TP14
SDATA
TP15
CLKIN
TP16
DGND
TP17
TRKL + TRKR
TP18
Latch Clock for the 74HC595
shift registers
Table 4. CDB5126 Test Points
Figure 7. DIP switch configuration
Switch
1
Logic
0
1
2, 3, 4
5
6
0
1
Mode
SLEEP mode
Normal mode
set to "1" for CS5126
Offset binary output code
2’s complement output code
Unconnected. Available for
user’s applications
Table 3. DIP Switch Selection Options
28
DS32DB5
CDB5126
Miscellaneous Hints on Using the Evaluation
Board
Always hit the reset button after powering-up the
board. The CS5126 is self calibrating and require
the reset signal to initiate the calibration procedure.
CDBCAPTURE Interface
Figure 8 illustrates the CDBCAPTURE interface
that can be constructed in the digital patch area.
A 2-row, 10 pin stake header is wired as shown.
P4 controls the ADC input mux. This is used to
set the mux to be continuously connected to one
channel, or to be toggling between two channels.
This is very useful for evaluating oversampled
vs. regular sampling digital audio.
P10 controls the Data Ready pulses from the onboard logic. To cause every data sample to be
read, select option 0. If you wish to read only
every alternate sample, then select option 1 or 2,
depending on whether you wish to read every left
channel value, or every right channel value. This
is useful for evaluating the part with a test system
which does not separate alternate values.
Circuit Board
(Top View)
(GND-Digital Patch) GND
+5V
(+5VL - Digital Patch)
GND
+5V
(+5VL - Digital Patch)
GND
FRAME (DRDY - P8)
GND
SCLK (SCLK - U9-11)
GND
SDATA (SDATA - U8-14)
Figure 8. CDBCAPTURE Header Signal Pattern
DS32DB5
29
CDB5126
Figure 9. CDB5126 Component Layout
30
DS32DB5
CDB5126
• Notes •
DS32DB5
31