ETC DSP56ADC16S

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by DSP56ADC16/D
MOTOROLA
SEMICONDUCTOR
TECHNICAL DATA
Technical Information
DSP56ADC16
Available in a 20 pin
CERDIP package
DSP56ADC16
16-bit Sigma-Delta Analog-to-Digital Converter
The DSP56ADC16 is a single chip, linear, 16-bit oversampling analog-to-digital (A/D) converter, providing output
sample rates up to 100 KHz. Third order noise shaping sigma-delta technology is employed utilizing 64 times
oversampling which yields 96 dB dynamic range and 90 dB signal-to-noise ratio for the signal bandwidths from
0 to 45.5 KHz with an in-band ripple of less than 0.001 dB. The DSP56ADC16 is an ideal choice for high performance digital audio systems, such as digital audio disks, tapes, and processors as well as voice-bandwidth communication and control applications. It does not require anti-aliasing filters and sample-and-hold circuitry
because they are an inherent part of the sigma-delta technology. Due to the scalable design principles, the effective output sampling rate can be adjusted from 8 KHz to 100 KHz without losing specified characteristics. The
DSP56ADC16 can easily be interfaced to the DSP56001/2 or other host processors using its flexible serial interface. An output is also provided before the final FIR decimation filter for applications requiring higher speed, lower group delay, and only 12-bit accuracy for AC levels. The DSP56ADC16 can also be used with an input
multiplexer at a minimum output sampling interval of 15 µs in the comb filter output mode.
DSP56ADC16 Key Features
•
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16-Bit Output Resolution (96 dB Typical Dynamic Range) at 100 KHz from the FIR Filter
12-Bit Output Resolution (72 dB Typical Dynamic Range) at 400 KHz from the Comb Filter
90 dB Signal-to-Noise Ratio (SNR)
In-Band Ripple: < 0.001 dB
Adjustable Output Sampling Rates:8 KHz to 100 KHz (FIR FIlter)
32 KHz to 400 KHz (Comb Filter)
Maximum Input Sample Rate: 6.4 MHz
Maximum Internal Clock Rate:12.8 MHz
Single +5 V ±10% Supply
On-chip voltage reference
3.5 Volt p-p full-scale differential inputs
Typical Power consumption: 300 mW at 100 KHz sampling rate
20-Pin CERDIP Package
Single Chip
Linear Phase Analog Front End and Internal Digital Filters
Simple Serial Interface to Host Microprocessors
No-glue Interface to DSP5600x/DSP561xx and Most Other General Purpose DSPs
This document contains information on a new product. Specifications and information herein are subject to change without notice.
 MOTOROLA INC., 1992
MOTOROLA
December 7, 1992
INTERNAL ARCHITECTURE
The A/D converter is a key component in data acquisition systems, such as those found in digital audio
systems, high-accuracy measurement systems, communications, and digital signal processing systems in
general. High resolution A/D converters have typically
used successive approximation techniques with complicated trimming/calibration or dual-ramp conversion
techniques which require accurate comparators and
expensive sample-and-hold (S/H) circuits to yield
over 15 bits of accuracy. In addition, the anti-aliasing
filter for these A/D converters generally sets severe
limitations on the attainable signal-to-noise ratio and
phase linearity.
The DSP56ADC16 uses an advanced third order sigma delta quantizer to implement an oversampled
noise shaping A/D converter system on a single chip.
By oversampling the input signal, the overall quantization noise spectrum expands well beyond the frequency band of interest. Third order noise shaping
insures that this expanded noise spectrum contains
very little noise power in the passband. The oversam-
pled signal is lowpass filtered, effectively removing the
out-of-band quantization noise. The lowpass filtering is
then followed by decimation to reduce the output sample rate commensurate with the frequency band of interest and to increase the resolution. In the
DSP56ADC16, the filtering and decimation are done in
two steps to reduce digital filter complexity. Since the
input signal is oversampled by a factor of 64, the need
for a high order antialiasing filter can be eliminated.
The DSP56ADC16 consists of three major sections: 1)
analog front end (AFE), 2) compensated decimation
digital filters and 3) serial interface, as shown in Figure
1. The AFE consists primarily of three differential
switched-capacitor linear integrators. These highly
stable fully differential integrators perform the noise
shaping function. The decimation digital filter section
consists of a 16:1 decimation comb filter stage followed by a 4:1 decimation lowpass/compensation FIR
filter stage which results in a total decimation ratio of
64:1. The frequency response of the decimation digital
filters is described in the “First and Second Stage
Decimation Digital Filters” section. The “Serial Interface” section provides serial communication to a host
DVCC
AVCC
Filter Select
REF Output
Serial Format
V
REF
REF Input
4:1
Decimation
Fir
Filter
Serial Clock Out
Mux
Serial
Interface
Serial Data Out
Frame Sync Out
3.2 MHz
12.8 MHz
Frame Sync
Input
6.4 MHz
-Analog
Input
16:1
Decimation
Comb
Filter
Analog
Front
End
6.4 MHz
+Analog
Input
System Timing and Control
Clock Input
(12.8 MHz)
AGND
DGND
DOE
Figure 1. Internal Block Diagram
MOTOROLA
2
DSP56ADC16
processor. This interface uses three dedicated pins
— serial data output (SDO), frame sync output (FSO),
and serial clock output (SCO). The serial interface format of operation is pin selectable. The timing diagrams for the serial interface are described in the “AC
Electrical Specifications” section.
SIGNAL DESCRIPTION
AGND
VIN+
VINCLKIN
FSI
FSEL
SFMT
DVCC
FSO
SCO
1
2
3
4
5
6
7
8
9
10
DSP56ADC16
The DSP56ADC16 is available in a 20-pin CERDIP
package. The functional pin definitions and their mnemonics are listed below and shown in Figure 2.
20
19
18
17
16
15
14
13
12
11
REFIN
REFOUT
AVCC
DGND
DGND
DGND
DGND
DGND
DOE
SDO
Figure 2. DSP56ADC16 Pin Assignment
Clock Input (CLKIN)
This pin accepts the input clock for the
DSP56ADC16. This TTL level compatible input accepts clock frequencies in the range of 1.0 to 12.8
MHz. The output sample rate is equal to the CLKIN
frequency divided by 128.
Frame Sync Input (FSI)
This active high input is used to start or reset the serial data output and synchronize internal circuits. It is
not a start conversion pulse since the DSP56ADC16
is always converting at a rate of CLKIN/128. FSI is
sampled on the falling edge of CLKIN (see the timing
diagram shown in Figure 21). When this signal goes
high, the DSP56ADC16 will begin transmitting bits via
the serial data out (SDO) pin. Frame sync input is an
optional input signal. If the FSI pin is grounded, frame
sync’s will be internally generated. The purpose of
FSI is to allow external control of the A/D conversion
process phasing. FSI should be a periodic signal occurring every 16 SCO clock periods in the comb filter
output mode and every 32 SCO clock periods in the
FIR filter output mode. In all cases FSI must be synchronized to CLKIN as defined in the timing specification. FSI allows multiple DSP56ADC16’s to be
synchronized using a common frame sync source. A
DSP56ADC16
common CLKIN signal is required when using a common frame sync signal with multiple DSP56ADC16s.
Analog + Input (VIN+)
This pin is the A/D converter analog non-inverting input. If an input anti-aliasing filter is used prior to the
VIN inputs, high quality polystyrene or equivalent capacitors must be used in order to meet the published
THD specification. See the connection diagram example in Figure 7 for a typical single pole input filter.
The maximum peak-to-peak input signal is a function
of the reference input voltage, Vrefin, which is expressed as
Maximum input range = 2 * Vrefin - 0.5 Volts p-p
The constant 0.5 Vp-p in the equation above is used
for internal dither circuitry.
Analog - Input (VIN-)
This pin is the A/D converter analog inverting input
with the same characteristics as VIN+.
Reference Input (REFIN)
This pin is the analog reference voltage (Vrefin) applied to this pin sets the analog input range. Its magnitude sets both the positive and negative full-scale
range. The maximum input is +2.0 volts. Since this input is extremely sensitive to induced noise, reference
input decoupling is suggested to achieve the maximum performance as shown in Figures 7 and 15. Failure to decouple may result in a degradation of the
SNR. The output of the DSP56ADC16 is
Vin+ - Vin Vrefin
Reference Output (REFOUT)
This pin is the on-board reference voltage output
(Vrefout) of +2.0 volts when using a +5.0 volt supply.
This pin should be connected to REFIN when an
external voltage reference is not used. When
REFOUT is loaded by REFIN as shown in Figures 15
and 16, the value Vrefout is
Vrefout =
2*AVCC
5
Serial Clock Output (SCO)
This pin provides the serial bit clock for the SDO port.
When the FIR filter output is selected by setting
FSEL= 0, the rate of this output is CLKIN divided by
MOTOROLA
3
four; when the comb filter output is selected by setting
FSEL = 1, the rate of this output is CLKIN divided by
two. See Figures 22 and 24 for more details.
Filter Select (FSEL)
A 16-bit serial data stream is output on the SDO pin
once per frame sync output cycle. This data changes
synchronously with the serial clock out (SCO) pin.
The format used is fractional 2’s complement transmitted most-significant-bit first. See Figures 22 and
24 for timing details.
This input allows selection of the FIR filter output or
the comb filter output. When FSEL is low, the SDO pin
will deliver the final lowpass/compensation FIR filter
output. When FSEL is high, the SDO will deliver the
comb filter output at a four times faster output sample
rate with a two times faster clock rate than the FIR filter output and the SFMT pin is disabled such that
SFMT=0 as shown in Figure 24. (also see SCO in this
section and Figure 22).
Serial Format (SFMT)
Data Output Enable (DOE)
This pin selects the formats of the FSO and SCO
when the FIR filter output is selected by setting
FSEL=0. The two formats of operation are shown in
Figure 22.
Serial data output three-state control pin. When DOE
bar is asserted (low), the SDO will be active. When
DOE bar is deasserted (high), the SDO will go to a
high impedance state. This can be used for multiplexing several A/D converters into one host serial input.
This pin is an asynchronous input and operates independently of input or output clocks (see Figure 25).
Serial Data Output (SDO)
Frame Sync Output (FSO)
This output is used to indicate the beginning of serial
word transmission on the SDO pin. The shape and
timing of the frame sync output pulse are controlled by
the SFMT pin. Refer to Figures 22 and 24 for timing
details of FSO.
Analog Vcc Supply (AVCC)
This pin is the positive analog power supply (+5 volts
±10%) for the analog integrator section.
NOTE
Analog Vcc and digital Vcc should be decoupled with respect to AGND and DGND, respectively, to obtain the published specifications.
This decoupling is intended to isolate digital
noise from the analog section. Decoupling capacitors should be as close as possible to their
respective analog and digital supply pins.
Digital Vcc supply (DVCC)
This pin is the positive digital power supply (+5 volts
±10%) for digital internal circuitry and pin drivers (see
AVCC).
Analog Ground (AGND)
This pin is the analog ground return for the analog
front end. This pin is NOT internally connected to digital ground (DGND).
Digital Ground (DGND)
This pin is the ground connection for digital internal
circuitry and pin drivers.
MOTOROLA
4
INPUT/OUTPUT CLOCKS AND CONTROL
The DSP56ADC16 output sample rate is defined by a
combination of the CLKIN frequency and the output
filter selected as determined by the FSEL pin. When
FSEL=0 the FIR filter is selected and the output sample rate is equal to CLKIN divided by 128. When
FSEL=1 the comb section is selected, the decimation
ratio is changed to 16:1 and the output sample rate is
equal to CLKIN divided by 32. The input sample rate
is always the CLKIN frequency divided by two. In normal mode (FSEL=0), the clock rate of the SCO is defined as the CLKIN frequency divided by four, giving
a maximum serial clock output of 3.2 MHz as shown
in Figure 22. However, when the comb filter output is
selected (FSEL=1), the rate is changed to the CLKIN
frequency divided by two which makes the maximum
rate of 6.4 MHz as shown in Figure 24. The timing relationships among CLKIN, FSI and SCO are detailed
in the “AC Electrical Specifications” section Figures 21 through 23 for when the filter selection (FSEL)
pin is set to 0 selecting the FIR filter output (see FSEL
in the “Signal Description” section).
SERIAL INTERFACE
The DSP56ADC16 has three output pins for the serial
interface: 1) serial data out (SDO), 2) frame sync out
(FSO), and 3) serial clock out (SCO). The corresponding internal block diagram is shown in Figure 3.
The serial port can interface with general purpose digital signal processors such as the DSP5600x,
DSP56ADC16
DSP561xx, NEC772x, TMS320Cxx and DSP16x
without additional interface circuitry. The format of the
fractional data output from the A/D converter is MSB
first, 16-bit serial and two’s complement. The serial
data format for interfaces is defined as:
15
1 sin ( 16πfT )
H ( f ) = ------ ----------------------------16 sin ( πfT )
4
where
1
T = ---fs
0
and f s is the input sampling rate for the AFE (maximum 6.4 MHz).
sign bit (MSB) transmitted first
LSB
The Serial Format (SFMT) pin selects between a one
clock wide high-true frame sync pulse and a one data
word wide low-true frame sync pulse as shown in Figure 22.
FIRST AND SECOND STAGE
DECIMATION
The first stage comb filter provides initial filtering of
the quantized output from the analog front end as well
as decimation of the input sample rate by a factor of
16:1. The z-domain transfer function of this stage can
be expressed as:
– 16 4
[1 – z ]
H ( z ) = --------------------------–1 4
[1 – z ]
The frequency domain (in Hz) equivalent of the transfer function is
Figure 4 shows the magnitude response of the comb
filter section. Since the comb filter has a non-flat lowpass like frequency response in the passband region,
the following second stage FIR filter should compensate for the passband droop as well as providing the
final sharp cutoff required for 16 bits of dynamic
range. Figures 5 and 6 illustrate the frequency responses of the lowpass FIR filter and the compensation, respectively. The 255-tap FIR filter coefficients
are designed for a lowpass filter with 9% transition
band and passband amplitude compensation whose
characteristics are — passband cutoff frequency:
45.5 KHz, stopband cutoff frequency: 50 KHz, passband ripple: 0.001 dB and a stopband ripple: -96 dB
when the chip is operated at a CLKIN frequency of
12.8 MHz. The 16-bit output of the first-stage comb filter is used as the input to the second-stage FIR filter.
This filter removes the out-of-band noise components
and also acts as the system anti-aliasing filter. Since
the in-band signal has been shaped by the third-order
noise-shaping integrators, the signal-to-noise ratio
achieved is more than 90 dB. It is important to note
FILTER SELECT
FROM FIR FILTER
OUTPUT (16 BITS)
FROM COMB FILTER
OUTPUT (16 BITS)
INPUT
16
THREE-STATE DRIVER
MULTIPLEXER
SERIAL
CLOCK OUT
SERIAL
DATA OUT
16-BIT SHIFT REGISTER
FRAME
SYNC OUT
FRAME SYNC INPUT
FILTER SELECT
DATA OUTPUT ENABLE
Figure 3. Block Diagram of Serial Interface
DSP56ADC16
MOTOROLA
5
that the passband and stopband frequencies of both
the comb and FIR filters scale linearly with the CLKIN
frequency.
Figure 6. Magnitude Response of FIR Filter
with Compensation
Figure 4. Magnitude Response of Comb Filter
(CLKIN = 12.8 MHz)
0.0005 dB
passband
ripple
Figure 5. Magnitude Response of
Lowpass FIR Filter
TECHNOLOGY COMPARISONS
The 38-bit FIR filter accumulator is convergently
rounded for 16-bit output to the “Serial Interface”
section. This provides 90 dB signal-to-noise ratio
(SNR), and 96 dB dynamic range in the 0 to 45.5 KHz
band which makes this device suitable for high performance digital audio applications. Three techniques
have traditionally been used in A/D converter implementation: successive approximation (SA), integrating, and flash. They are implemented using the
Nyquist sampled data criterion (set a minimum of
MOTOROLA
6
twice the signal frequency) instead of the oversampled method used by the sigma-delta technology.
Successive approximation A/D converters compare
the unknown input with sums of accurately known
fractions of the reference voltage in the successive
approximation register (SAR). Starting with the largest fraction, each sum is sequentially compared to the
input. If the sum is larger than the input, that fractional
voltage is deleted from the sum and the next smaller
fraction is added. This process is repeated until all
available fractions have been either added or rejected
from the sum. The on-chip D/A converter used to generate the sum of fractions must be very accurate and
may require external trimming. The settling time for 16
approximations in succession for 16-bit performance
must be less than 10 µs for a 100 KHz sample rate.
Allowing 5 µs to acquire the signal to the specified linear error, 5 µs is left for the 16-bit digitization process
which yields approximately 0.3 µs for each bit.
Integrating A/D converters count pulses for a period
proportional to the input. Dual slope integrating converters count the period required for the integral of the
reference to equal the average value of the input over
a fixed period of time. As with SA, external trimming is
required.
Flash A/D converters give simple and fast conversions in low resolution and high speed applications.
This method requires only one step in determining the
input voltage, a series of comparators test the input
signal against a set of voltage thresholds established
by a ladder network. Digital logic is then employed to
convert the comparator outputs to a binary number.
DSP56ADC16
To operate in such a fast manner 2B -1 comparators
are required, where B denotes the number of bits of
resolution. For 16-bit resolution, therefore, 65,535
comparators would be needed and a significant
amount of priority encoding logic would be required to
achieve performance comparable to Sigma-Delta
converters.
RC filter can be used to attenuate a high frequency input signal.
The SA, integrating and flash techniques require extremely high performance analog anti-aliasing filtering
and precise sample-and-hold (SAH) circuits to ensure
16-bit accuracy and 100 KHz sample rate. The antialiasing filter, therefore, has to be a very steep “brick
wall” filter outside the passband. A 30-pole Besselapproximated IIR filter is necessary to obtain almost
linear-phase and less than 0.0001 ripple over the entire passband, 96 dB stop band attenuation and fast
transition between passband and stop band, which is
impractical. Also, the allowable aperture jitter of the
sample-and-hold circuit is only 48.6 ps which is very
expensive to make.
Sigma Delta A/D converters use a low resolution A/D
converter (one bit quantizer) in a feedback configuration. The high resolution (96 dB SNR) is achieved by
the noise-shaper (third order for the DSP56ADC16).
The noise transfer function is essentially a high pass
filter so that the noise is shifted to higher, out-of-band
frequencies where it is then filtered out. The input
sampling rate for sigma-delta modulation is much
higher (64 times for the DSP56ADC16) than the rate
for the other three techniques for the same bandwidth. Because of the high sampling rate and the low
precision A/D conversion used on the front end of a
sigma-delta system, a sample and hold circuit is not
needed. Since the sampling rate is much higher, the
anti-aliasing filter is not required or a simple one-pole
In contrast, sigma-delta modulation based A/D technology can meet the performance goals of 16-bit resolution and 100 KHz sample rate with moderate cost.
A tutorial of sigma-delta technology can be found in
the Motorola Digital Signal Processing Operation Application Report, APR8/D, entitled “Principles of Sigma-Delta Modulation for Analog-to-Digital
+5V
C1 +
100 µF
AVCC
C2
0.1 µF
C3
0.1 µF
DSP56ADC16
8
4
CLKIN
5
FSI
12
6
19
20
7
AVCC
C5 +
100 µF
2
3
R6
2.2K
AVCC
CLKIN
FSO
FSI
DOE
SCO
SDO
FSEL
DGND
REFOUT
DGND
REFIN
DGND
SFMT
DGND
Vin+
DGND
Vin-
AGND
18
9
FSO
10
SCO
11
SDO
17
16
15
14
13
1
C6
0.0047 µF
R2
100
R1
100
R3
1K
DVCC
C4
100 µF
Vin+
C7 +
100 µF
R5
2.2K
Vin-
R4
1K
1
BNC1
Analog Ground
1
2
2
BNC2
Digital Ground
Figure 7. Functional Test Circuit
DSP56ADC16
MOTOROLA
7
Converters” which can be requested from:
Motorola Literature Distribution
P.O. Box 20912
Phoenix, Arizona 85036
or from the other Motorola literature distribution centers listed on the back cover of this data sheet.
PERFORMANCE EVALUATIONS
Figure 7 shows the input circuitry used for testing signal-to-noise and signal-to-THD ratios. A low distortion
(>96 dB SNR) signal generator is applied differentially
to the BNC inputs and an FFT with the Blackman-Harris window is performed to measure the noise and distortion. AC characteristics of digital outputs, FSO,
SDO, and SCO, are measured while connected to
one standard TTL load.
sible codes for the 16-bit converter. The distribution of
DNL codes are within ± 0.5 LSB.
Measurements of the group delay and settling time
due to the internal propagation delay and linearphase filter operation may be useful for multiplexed
applications. Figures 11 and 12 illustrate the rectangular pulse responses of the comb filter output and
FIR filter output, respectively, while Figures 13 and 14
are for a sine wave input response. Note that the output response includes not only the internal delays of
the DSP56ADC16, but also the measurement delays
for these plots such as data transfer time and D/A
conversion time of 2.5 µs and 3.0 µs, respectively.
Figure 8 shows the spectral purity of the
DSP56ADC16 with a 10 KHz, full scale, sine-wave
input when the output sampling rate is 50K samples
per second. Since the 1024-point FFT has 512
spectral bins up to Nyquist frequency, the typical
noise floor and the harmonic distortion can be
measured by summing the power of corresponding
bins; this gives -90 dB and -88 dB, respectively. The
typical spectral plot for the comb filter output is shown
in Figure 9.
Figure 9. Typical Spectrum of Comb Filter Output
(512 Bins of 1024 FFT)
Figure 8. Typical Spectrum of FIR Filter Output
(512 Bins of 1024 FFT)
Figure10 illustrates the differential non-linearity (DNL)
plots of the DSP56ADC16. It has been shown that
Sigma-Delta converters are inherently linear and do
not suffer from appreciable DNL or missing codes.
The plot shows the distributions of 216 = 65,536 pos-
MOTOROLA
8
Figure 10. Typical Differential Nonlinearity
(DNL) Plot
The DSP56ADC16 can also be used with an input
DSP56ADC16
17.0 µµs
Settling Time
13.5 µµs
Group Delay
(Average of 50 sweeps)
Figure 11. Typical Measured Group Delay and Settling Time of Comb Filter Output (CLKIN = 12.8 MHz)
Group Delay
340 µµs
Settling Time
680 µµs
Figure 12. Typical Measured Group Delay and Settling Time of FIR Filter Output (CLKIN = 12.8 MHz)
13.5 µs
Input Sinewave Frequency: 20.0 KHz
CLKIN Freuency: 12.8 MHz
(No Sweeping Average)
Figure 13. Typical Measured Group Delay of Comb Filter Output
340 µµs
Input Sinewave Frequency: 1.0 KHz
CLKIN Freuency: 12.8 MHz
Figure 14. Typical Measured Group Delay of FIR Filter Output
DSP56ADC16
MOTOROLA
9
multiplexer when the comb filter output is selected by
setting FSEL=1 (see the Signal Descriptions section). The minimum multiplex intervals which depend
on the settling time as shown in Figure 11, can be given by
synchronized, this results in the multiplex intervals of
S
τ mux ≥ 5T s and τ mux ≥ 6T s where Ts equals 32 tclk
(output sample interval). If the FSI and the multiplexer
are not synchronized, there can be one sample of
S
time uncertainty so that τ mux ≥ 6T s and τ mux ≥ 7T s .
If fclk = 12.8 MHz, the minimum multiplex intervals,
S
τ mux and τ mux , are 15 µs and 17.5 µs, respectively.
These results were verified by synchronizing a square
wave input to the DSP56ADC16 and collecting and
analyzing buffers of 32 data samples. In addition to
these synchronization aspects, the following must be
considered: 1) the response time of the multiplexer itself, 2) rolloff caused by any external anti-aliasing filter, and 3) if a DAC is used to display the output data,
its response characteristic must be considered
162
τ mux ≥ --------- ;
f clk
excluding the time required to shift the data out from
the serial interface, and
194
S
τ mux ≥ --------- ;
f clk
including the time required to shift the data out from
the serial interface.
These expressions are based on theoretical analysis.
However, there are practical aspects which need to
be considered. First, the multiplex interval must be a
multiple of 32 clock periods (i.e., the comb filter output
rate). If the FSI and the multiplexer can be perfectly
SINGLE-ENDED TO DIFFERENTIAL
INPUTS
A general system connection diagram for a single
+5 V
12.8 MHz
10
1M
1 µF
100 µF
74HCU04
33 pF
33 pF
CLKIN
2*Vref - 0.5 (V p-p)
DVCC
AVCC
FSI
+2.5 V
Vin+
+5 V
47 K
10 µF
+2.5 V
Vin-
FSO
PC5
SDO
PC7
SCO
PC6
DSP56001
DSP56ADC16
47 K
REFOUT
REFIN
AGND
SFMT
DGND FSEL DOE
100 µF
Analog Ground
Digital Ground
Figure 15. Single Ended Mode Input Circuit
MOTOROLA
10
DSP56ADC16
ended input signal is shown in Figure 15, while Figure 16 illustrates the schematic diagram for multiplexing two DSP56ADC16’s with the DSP56001.
Figure 17 shows the system interface diagrams for
popular general purpose digital signal processors.
Although a differential input is recommended to obtain the specified performance, the DSP56ADC16
can be used with a single-ended input system with a
slight SNR performance degradation of 3-4 dB. For
better performance, the recommended conversion
circuit diagram from single-ended input to differential
input is illustrated in Figure 18. Using this diagram,
the analog input voltage range can be conditioned to
utilize the maximum dynamic range of the
DSP56ADC16.
Two DSP56ADC16’s can be multiplexed on a single
serial port. Note in Figure 23 that there are 32 SCO
cycles in one FSO cycle. The SDO pin outputs valid
+5 V
AVCC
DSP56ADC16
8
2
3
7
4.7 K
19
20
100 µF
+
6
5
CH1
100 µF
INPUT
+
4
12
+5 V
1k
1k
AVCC
18
Vin+
SDO
11
Vin-
SCO
10
SFMT
AGND
1
REFOUT
DGND
REFIN
DGND
FSEL
DGND
DVCC
FSI
DGND
CLKIN
DGND
/DOE
FSO
74HCU04
SCK
17
16
SRC
15
14
13
74HCU04
9
SC2
2.2 K
+5 V
1k
1k
2.2 K
+
100 µF
AVCC
5V
CH2
INPUT
DSP56ADC16
8
100 µF
+
2
3
7
4.7 K
+
100 µF
19
20
6
5
6.144 MHz
4
12
470 K
74HCU04
74HCU04
AVCC
Vin+
SDO
Vin-
SCO
SFMT
AGND
REFOUT
DGND
REFIN
DGND
FSEL
DGND
FSI
DGND
CLKIN
DGND
FSO
/DOE
18
11
10
1
17
16
74ALS867
CLK
S1
S0
ENT
RC0
ENP
QH
H
QG
G
QF
F
QE
E
QD
D
QC
C
QB
B
QA
A
13
15
16
17
18
19
20
21
22
15
14
13
9
74HCU04
330
68 pF
DVCC
4.7 K 14
2
1
11
23
10
9
8
7
6
5
4
3
68 pF
Figure 16. Schematic Diagram for Multiplexing Two DSP56ADC16s with the DSP56001
DSP56ADC16
MOTOROLA
11
DSP56ADC16
SFMT
FS0
PC5/FSR
SD0
PC7/SRD
SC0
PC6/SCK
DSP5600x
DSP56ADC16
SFMT
DOE
DSP56ADC16
FS0
RFS1
SD0
DR1
SC0
SCLK1
ADSP21xx
SD0
PC1/SRD0
SC0
PC2/SCK0
FS0
SIEN
SD0
SI
SC0
SCK
FS0
ILD
SD0
DI
SC0
ICK
DOE
DSP56ADC16
SFMT
DOE
NEC772x
DOE
LOGIC 1
LOGIC 0
DSP56ADC16
SFMT
PC3/SC10
LOGIC 0
LOGIC 0
SFMT
DSP561xx
FS0
FS0
FSR
SD0
DR
SC0
CLKR
TMS320Cxx
DSP56ADC16
SFMT
DOE
DSP16xx
DOE
LOGIC 0
LOGIC 0
Figure 17. Connection Diagram Examples
10 K Ω
100 Ω
10 K Ω
–
+
Vin
Vin+
10 K Ω
AVCC
0.0047 µF
47 K
10 K Ω
AVCC
47 K
–
+
100 Ω
Vin-
Figure 18. Single Ended to Differential Analog Input Diagram
MOTOROLA
12
DSP56ADC16
data for the first 16 SCO cycles and then the next 16
SCO
cycles
are
zero.
SYNCHRONIZING TWO CHANNELS
For an application where the two converters must
synchronously be sampled, two 8-bit shift registers
(or one 16-bit shift register) clocked by the SCO, may
be connected to the second converter SDO pin to delay 16 SCO cycles as shown in Figure 19. A single
FSI pulse from the octal counter (74ASL867) is used
for both DSP56ADC16s to make sure that the FSIs
for both chips are occurring at the same time. The outputs of the first DSP56ADC16 and the 16-bit shift register can be combined by one OR gate to yield one
serial output to the SSI port. When more than two
channels have to be sampled synchronously, the
memory mapped addressing and direct read from the
data bus scheme can be used as shown in Figure 20.
linear with the clock frequency. The following equations show some examples of power dissipation with
respect to the CLKIN values.
12. 8 MHz → 100 + 200 = 300 mW
6.4 MHz → 100 + 200/2 = 200 mW
1.0 MHz → 100 + 200/12.8 = 116 mW
INPUT IMPEDANCES
The analog input impedance, Zin, and the minimum
reference input impedance, Zref, can be computed by
following equations:
12
10
Z in = ----------3f clk
12
10
Z ref ≥ ---------------2.5f clk
Power Dissipation
The power dissipation of the DSP56ADC16 is a function of CLKIN. The DSP56ADC16 analog section typically consumes 100 mW. This value is independent
of the clock frequency. However, the power consumption of the remaining circuitry in the DSP56ADC16 is
where fclk denotes the input clock rate. Table 1 shows
the input impedances for selected input clock rates.
Table 1: Analog and Reference Input Impedance
Input Clock Rate
(MHz)
Output Sample Rate
(KHz)
Analog Input Impedance
(KΩ)
Minimum Reference Input
Impedance (KΩ)
12.8
100.0
26.0
31.3
6.4
50.0
52.0
62.5
6.144
48.0
54.3
65.1
5.6448
44.1
59.0
70.9
1.024
8.0
325.5
390.6
DSP56ADC16
MOTOROLA
13
channel 1
DSP56ADC16
SC0
SCK
octal counter
FSI
FS0
SC2
74ALS867
clkin
SD0
SRC
QG
16
DSP56001
channel 2
system clock
DSP56ADC16
SC0
clk
FSI
FS0
clkin
SD0
clk
clk
SRI
74LS299
74LS299
SRI
Figure 19. Synchronized Two Channel Input Sampling for Stereo Applications
CS1
FSO
SDO1
CS2
SDI
LC
SDI
OE
74HC595A
SC0
SC
LC
OE
74HC595A
SD0
SC
CS3
Address
Decoder
SD0
PAL
D0-D7
D8-D15
DATA BUS
• Memory mapped structure for each channel
ADDRESS BUS
• Can be expanded to N channels
Figure 20. Block Diagram for Synchronized Sampling of more than Two Analog Channels
MOTOROLA
14
DSP56ADC16
DSP56ADC16 Electrical Characteristics
Electrical Specifications
The DSP56ADC16 is fabricated in high density HCMOS with TTL compatible inputs and CMOS compatible
outputs.
This device contains protective circuitry against damage due to high static voltage or electrical fields; however, it is advised that normal precautions be taken to avoid application of any voltages higher than maximum rated voltages to this high-impedance circuit. Reliability of operation is enhanced if unused inputs are
tied to an appropriate logic voltage level (e.g., either Vcc or GND).
Maximum Electrical Ratings (VSS = 0 Vdc)
Rating
Symbol
Value
Unit
Supply Voltage
Vcc
-0.3 to +7.0
V
All Input Voltages
Vin
- 0.5 to Vcc + 0.5
V
I
10
mA
Operating Temperature Range
TA
-40 to +85
°C
Storage Temperature
Tstg
-55 to +150
°C
Full Scale Input Voltage at VREF = 2.0V
Vpp
3.5
V
Current Drain per Pin excluding Vdd and VSS
Thermal Characteristics —CERDIP Package
Characteristics
Thermal Resistance — Ceramic
Symbol
Value
Rating
Junction to Ambient
ΘJA
68
°C/W
Junction to Case (estimated)
ΘJC
0.7
°C/W
Power Considerations
The average chip-junction temperature, TJ, in °C can be obtained from:
TJ = TA + (PD × ΘJA)
(1)
Where:
TA = Ambient Temperature, °C
ΘJA = Package Thermal Resistance, Junction-to-Ambient, °C/W
PD = PINT + PI/O
PINT = ICC × Vcc, Watts - Chip Internal Power
PI/O = Power Dissipation on Input and Output Pins - User Determined
For most applications PI/O << PINT and can be neglected. An appropriate relationship between PD and TJ
(if PI/O is neglected) is:
(2)
PD = K/(TJ + 273° C)
DSP56ADC16
MOTOROLA
15
DSP56ADC16 Electrical Characteristics
Solving equations (1) and (2) for K gives:
K = PD × (TA + 273° C) + ΘJA × PD2
(3)
Where K is a constant pertaining to the particular part. K can be determined from equation (2) by measuring
PD (at equilibrium) for a known TA. Using this value of K, the values of PD and TJ can be obtained by solving
equations (1) and (2) iteratively for any value of TA. The total thermal resistance of a package (ΘJA) can be
separated into two components, ΘJC and CA, representing the barrier to heat flow from the semiconductor
junction to the package (case) surface (ΘJC) and from the case to the outside ambient (CA). These terms
are related by the equation:
ΘJA = ΘJC + CA
(4)
ΘJC is device related and cannot be influenced by the user. However, CA is user dependent and can be
minimized by such thermal management techniques as heat sinks, ambient air cooling, and thermal
convection. Thus, good thermal management on the part of the user can significantly reduce CA so that ΘJA
approximately equals ΘJC. Substitution of ΘJC for ΘJA in equation (1) will result in a lower semiconductor
junction temperature. Values for thermal resistance presented in this document, unless estimated, were
derived using the procedure described in Motorola Reliability Report 7843, “Thermal Resistance
Measurement Method for MC68XX Microcomponent Devices”, and are provided for design purposes only.
Thermal measurements are complex and dependent on procedure and setup. User-derived values for
thermal resistance may differ.
MOTOROLA
16
DSP56ADC16
DSP56ADC16 Electrical Characteristics
Electrical Specifications(Vcc=5V ±10%, TA=-40 to +85 oC)
Characteristic
Symbol
Min
Input High Voltage
VIH
Input Low Voltage
VIL
Input Leakage Current
Typ
Max
Unit
2.0
Vcc
V
-0.3
0.8
V
Iin
1.0
µA
Hi-Z (OFF State) Input Current for SDO (Vin = 0.4 to 2.4 V)
ITSI
10
µA
Output High Voltage (IOH = -400 µA)
VOH
Output Low Voltage (IOL = 2mA)
VOL
Power Dissipation at f = 12.8 MHz: (Note 1)
PD
300
Input Impedance (Analog Input)
Zin
Note 2
Ω
Input Impedance (Reference Input)
Zref
Note 2
Ω
Input Capacitance
Cin
10
pF
2.4
V
0.5
V
400
mW
Note 1: Power dissipation is the function of CLKIN. For CLKIN less than 12.8 MHz (see Power Dissipation on
page 13).
Note 2: Impedances for the analog input and voltage reference input are functions of CLKIN (see Input Impedances on page 13).
Analog Characteristics [Vcc=5V, Vin = 1.2 VRMS (10 kHz differential sinewave), Vcm = 2.5V, TA= 25 oC,
Clkin = 6.4 MHz, FIR Mode (word wide frame sync), Internal Vref ]
Characteristic
Symbol
Resolution
Signal-to-Noise Ratio
Min
Typ
12
Max
Unit
16
Bits
SNR
88
90
dB
S/THD
80
83
dB
(Note 2)
LSBs
Gain Drift
50
ppm/°C
DC Offset Error
0.3
3.0
mV
0.4*Vcc
0.4*Vcc+ 4%
V
Signal-to-Total Harmonic Distortion Ratio (Note 1)
Differential Nonlinearity
Vrefout Voltage (Loaded by Vrefin)
DNL
0.4*Vcc - 4%
Note 1: THD performance can be improved, depending on the applications, by making slight adjustments to the DC
common mode voltage at the analog inputs.
Note 2: See Performance Evaluations on page 8 for detail.
DSP56ADC16
MOTOROLA
17
DSP56ADC16 Electrical Characteristics
AC Electrical Specifications - Clock In/Out and Frame Sync (Vcc=5V ±10%, TA=-40 to +85 oC)
Num
Characteristic
Symbol
Min
Max
Unit
f
1
12.8
MHz
Clock In Frequency (tck = 1/f)
1
Clock Period
tck
78
1000
ns
2
Duty Cycle
tPW
0.475
0.525
tck
3
Clock Rise Time
tr
5
ns
4
Clock Fall Time
tf
5
ns
5
Frame Sync Input Setup Time
tfsisu
20
1/tck
ns
6
Frame Sync Input Hold Time
tfsih
20
Note 1
ns
7
Serial Clock Output Delay Time
tscod
25
75
ns
Note 1:
The FSI input must be deasserted for at least two CLKIN periods prior to being asserted.
AC Electrical Specifications - FSO/SCO/SDO when FSEL=0 (Vcc=5V ±10%, TA=-40 to +85 oC)
Num
Characteristic
Symbol
Min
Max
Unit
9
Frame Sync Output Setup Time before Falling Edge of SCO (SFMT=0)
tfsckl
130
-
ns
10
Frame Sync Output Hold Time after Falling Edge of SCO (SFMT=0)
tclklfs
130
-
ns
11
Serial Data Output Setup Time
tdsu
130
-
ns
12
Serial Data Output Hold Time
tdh
130
-
ns
13
Frame Sync Output Setup Time before SCO Rising Edge (SFMT=1)
tfslckh
110
-
ns
14
Frame Sync Output High to SCO Rising Edge (SFMT=1)
tfshckh
110
-
ns
15
Delay from Frame Sync Input to Frame Sync Output (SFMT=0)
tfsifsob
5
-
cyc
16
Delay from Frame Sync Input to Frame Sync Output (SFMT=1)
tfsifsow
8
-
cyc
17
Serial Clock Output Period
tsckout
4
4
tck
AC Electrical Specifications - FSO/SCO/SDO when FSEL=1 (Vcc=5V ±10%, TA=-40 to +85 oC)
Characteristic
Symbol
18
Frame Sync Output Setup Time before Falling Edge of SCO
19
Typ
Max
Unit
tfsckl
65
-
ns
Frame Sync Output Hold Time after Falling Edge of SCO
tclklfs
65
-
ns
20
Serial Data Output Setup Time
tsdosu
40
-
ns
21
Serial Data Output Hold Time
tsdoh
40
-
ns
22
Delay from Frame Sync Input to Frame Sync Output
tfsifso
1.5
-
cyc
23
Serial Clock Output Period
tsckout
2
2
tck
MOTOROLA
18
Min
DSP56ADC16
DSP56ADC16 Electrical Characteristics
AC Electrical Specifications - DOE (Vcc=5V ±10%, TA=-40 to +85 oC)
Characteristic
Symbol
Min
Max
Unit
24
Serial Data Output Enable Delay Time
tdoedv
0
20
ns
25
Serial Data Output Disable Delay Time
tdoedz‡
0
20
ns
‡ tdoedz is three-state 500 mV from 2.4 V or 0.5 V level with CL=50 pF+1 TTL load.
1
2
2.0 V
50 %
CLKIN
0.8 V
3
6
0.8 V
4
*
FSI
5
SCO
7
7
17
FIR Filter Output Mode
*The FSI must be deasserted for at least two CLKIN periods prior to being asserted.
Figure 21. Timing Diagram for CLKIN/FSI/SCO When FSEL=0
DSP56ADC16
MOTOROLA
19
DSP56ADC16 Electrical Characteristics
15
1
CLKIN
FSI *
17
Serial Format SFMT = 0
SCO
9
10
FSO
11
SDO
Zero (After previous D0)
12
D15
D14
D13
D1
D0
Serial Format SFMT = 1
SCO
13
14
FSO
Low for D15-D0
16
11
12
SDO
Zero (After previous D0)
D15
D14
D13
D1
D0
*The FSI input must be deasserted for at least two CLKIN periods prior to being asserted.
Figure 22. Timing Diagram for FSO/SCO/SDO When FSEL=0
MOTOROLA
20
DSP56ADC16
DSP56ADC16 Electrical Characteristics
128 tck Cycles
CLKIN
Serial Format SFMT = 0
32 SCO Cycles
SCO
FSO
SCO
Valid for first 16 SCO cycles
Zero for last 16 SCO cycles
VALID
32 SCO cycles
Serial Format SFMT = 1
SCO
FSO
Low (asserted) for first 16 SCO cycles
Valid for first 16 SCO cycles
SDO
High (deasserted) for
last 16 SCO cycles
Zero for last 16 SCO Cycles
VALID
FIR Filter Output Mode
Figure 23. Timing Diagram for FSO/SCO/SDO When FSEL=0
DSP56ADC16
MOTOROLA
21
DSP56ADC16 Electrical Characteristics
CLKIN
22
*
FSI *
23
16 SCO Cycles
SCO
6.4 MHz (MAX)
18
19
FSO
20
SDO
D1
21
D0
D15
D14
D13
D1
D0
D15
COMB Filter Output Mode
*The FSI must be deasserted for at least two CLKIN periods prior to being asserted.
Figure 24. Timing Diagrams for FSO/SCO/SDO When FSEL=1
DOE
24
25
Data Out
Figure 25. Timing Diagrams of DOE and Data Output
MOTOROLA
22
DSP56ADC16
DSP56ADC16 Electrical Characteristics
SPECIFICATION DEFINITIONS
Vref is the voltage at the REFOUT pin, measured when the maximum Vrefin current is sourced from that
pin.
LSB is the smallest voltage change that is required at the device input to produce a one bit change in
the device output code.
SNR is the ratio of the fundamental signal power versus the total non-harmonic noise power within a
finite bandwidth. Expressed in dB, SNR represents the peak signal versus RMS noise ratio.
S/THD is the ratio of the fundamental signal power versus the total signal harmonic power. Expressed
in dB. The number of harmonics included must be specified.
S/THD+N is the ratio of the fundamental signal power versus the sum total of the band limited non-harmonic RMS noise power and the signal harmonic power. The number of harmonics and the applicable
bandwidth must be specified.
DC Offset is the differential DC input voltage required to produce a zero output code.
Offset Error is the difference between the actual and the ideal input signal voltage required to produce
a negative full-scale output code value. This is normally specified since the transfer curve is well represented by DC offset and gain error specifications.
The FIR Pass-band Frequency is the frequency at which the device response is within the ripple
specification.
The FIR Cut Off Frequency is the frequency at which the device response is -3 dB below the passband response.
The FIR Stop-band Frequency is the frequency at which the device response is - 3 dB above the
noise floor.
DNL is the width (in LSBs) of any code step, measured from code transition “n” to code transition “n+1”,
over the entire code conversion range.
Dynamic Range is the input signal range defined as the ratio of the maximum usable input signal and
the noise floor of the device in operation, expressed in dB.
Resolution is the number of serial output bits which contain useful information.
In-Band Ripple is the response variation of the converter in the defined pass-band region, specified
in dB.
DSP56ADC16
MOTOROLA
23
DSP56ADC16 Electrical Characteristics
Input Impedance is the actual input impedance (resistive and reactive) seen at the input of the device,
measured with respect to device analog ground return pin. The analog input amplitude/frequency range
and input sampling clock rate must be specified.
Input Capacitance is the actual input capacitance seen at the input of the device, measured with respect to the device analog ground return pin. The analog input amplitude/frequency range and input
sampling clock rate must be specified
Single-Ended Operation is when one of the two analog inputs is held at a fixed voltage level and the
signal to be converted is applied to the remaining input, possibly with a DC bias level included. The device still converts the voltage seen differentially across the two inputs.
Differential Operation is when both of the two analog inputs are driven with complementary signals.
D.C. bias levels may be applied to either of the input pins. The device converts the voltage seen differentially across the two inputs.
Input Analog Voltage Range is the range of input voltage over which meaningful digital output codes
are produced which properly represent the input voltage signal.
MOTOROLA
24
DSP56ADC16
DSP56ADC16 Electrical Characteristics
Package Dimensions
Ordering Information
Order this part by the part number:
DSP56ADC16S
DSP56ADC16
MOTOROLA
25
Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty, representation or guarantee regarding
the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and
specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters can and do vary in different
applications. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. Motorola does not
convey any license under its patent rights nor the rights of others. Motorola products are not designed, intended, or authorized for use as components in systems
intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Motorola
product could create a situation where personal injury or death may occur. Should Buyer purchase or use Motorola products for any such unintended or unauthorized application, Buyer shall indemnify and hold Motorola and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims,
costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such
unintended or unauthorized use, even if such claim alleges that Motorola was negligent regarding the design or manufacture of the part. Motorola and M are
registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal Opportunity/Affirmative Action Employer.
Literature Distribution Centers:
USA: Motorola Literature Distribution; P.O. Box 20912; Phoenix, Arizona 85036.
EUROPE: Motorola Ltd.; European Literature Center; 88 Tanners Drive, Blakelands, Milton Keynes, MK14 5BP, England.
JAPAN: Nippon Motorola Ltd.; 4-32-1, Nishi-Gotanda, Shinagawa-ku, Tokyo 141 Japan.
ASIA-PACIFIC: Motorola Semiconductors H.K. Ltd.; Silicon Harbor Center, No. 2 Dai King Street, Tai Po Industrial Estate, Tai Po, N.T.,
Hong Kong.
Order this document
by DSP56ADC16AD/D
Rev 2
MOTOROLA
SEMICONDUCTOR
TECHNICAL DATA
Errata to
DSP56ADC16
16-bit Sigma-Delta Analog-to-Digital Converter
The following changes apply to the DSP56ADC16 Advanced Information Data Sheet (ADI1525).
On Page 20:
Under the heading “Thermal Characteristics,” the line that reads “Thermal Resistance Plastic” should read
“Thermal Resistance Ceramic”.
Under the heading “AC Electrical Specifications”:
The maximum Clock Period, which now reads “100”, should be “1000”.
The minimum Duty Cycle, which now reads “0.473”, should read “0.475 tclk”.
The maximum Duty Cycle, which now reads “0.525”, should read “0.525 tclk”.
The Duty Cycle unit, which now reads “tclk”, should read “ns”.
The Serial Clock Output Delay Time (minimum), which now reads “30”, should read “25 ns”.
The Frame Sync Output Set-up Time before SCO Rising Edge (minimum), which now reads “130”, should
read “110 ns”.
The Frame Sync Output High to SCO Rising Edge (minimum), which now reads “130”, should read
“110 ns”.
The Input Capacitance, which now reads “10 pF maximum”, should read “10 pF typical”.
Specifications added for clarity:
Min
Typical
Max
Vrefout
(Vcc x 0.4) - 4% Volts
Vcc x 0.4 Volts
(Vcc x 0.4) + 4% Volts
Signal - to - Noise
88 dB
90 dB
-
Total Harmonic Distortion
-
-
-80 dB
Full-Scale Input Voltage
-
2 x Vref - 0.5 Volts p-p
ο
SNR and THD test conditions: Vcc = 5 Volts; Vin = 1.2 Volts RMS; Vcm = 2.5 Volts; Ta = 25 C
10 kHz Differential Sinewave; CLKIN = 6.4 MHz; FIR word-wide Mode; Using Internal Vref
This document contains information on a new product. Specifications and information herein are subject to change without notice.
 MOTOROLA INC., 1992
MOTOROLA