BB DSP102

D SP
DSP101
DSP102
102
D SP
101
www.ti.com
DSP-Compatible Sampling Single/Dual
ANALOG-TO-DIGITAL CONVERTERS
FEATURES
DESCRIPTION
● ZERO-CHIP INTERFACE TO STANDARD
DSP ICs: AD, AT&T, MOTOROLA, TI
● SINGLE CHANNEL: DSP101
● DUAL CHANNEL: DSP102
Two Serial Outputs or Cascade to Single
32-Bit Word
● SAMPLING RATE TO 200kHz
● DYNAMIC SPECIFICATIONS:
Signal/(Noise + Distortion) = 85dB;
Spurious-Free Dynamic Range = 94dB;
THD = –91dB
● SERIAL OUTPUT DATA COMPATIBLE
WITH 16-, 24-, AND 32-BIT DSP IC
FORMATS
The DSP101 and DSP102 are high performance sampling Analog-to-Digital (A/D) converters designed for
simplicity of use with modern digital signal processing ICs. Both are complete with all interface logic for
use directly with DSP ICs, and provide full sampling
and conversion at rates up to 200kHz.
The DSP101 offers a single conversion channel, with
18 bits of serial data output, allowing the user to drive
16-bit, 24-bit, or 32-bit DSP ports. The DSP102 offers
two complete conversion channels, with either two
full 18-bit output ports, or a mode to cascade two
16-bit conversions into a 32-bit port as one word.
Both the DSP101 and DSP102 are packaged in standard, low-cost DIP-28 packages. Each is offered in
two performance grades to match application requirements.
Convert
Command
Control
Logic
Analog
Input
Channel A
Select Sync Format
Channel A User Tag In
18-Bit Sampling ADC
Channel A Data/
Cascaded Data
Sync
Reference
Bit Clock
Channel B Data
Analog
Input
Channel B
18-Bit Sampling ADC
Channel B User Tag In
Cascade
Channel B on DSP102 Only
Copyright © 1990, Texas Instruments Incorporated
SBAS003A
Printed in U.S.A. February, 2001
SPECIFICATIONS
At TA = 0°C to 70°C, ±2.75V input signal, sampling frequency (fS) = 200kHz, VA+ = VD = +5V, VA– = –5V, 16MHz external clock on OSC1, CLKOUT tied to CLKIN, 8MHz
data transfer clock on XCLK, data analysis band-limited to 20kHz, unless otherwise specified.
DSP101JP
DSP102JP
DSP102JP-1
PARAMETER
CONDITIONS
MIN
TYP
RESOLUTION
AC ACCURACY(1)
Signal-to-(Noise + Distortion) Ratio
Total Harmonic Distortion
Spurious-Free Dynamic Range
Signal-to-Noise Ratio (SNR)
DC ACCURACY
Gain Error
Gain Error Mismatch
Integral Linearity
Differential Linearity
Integral Linearity Error
Differential Linearity Error
No Missing Codes
Bipolar Zero Error (3)
Bipolar Zero Mismatch (3)
Power Supply Sensitivity
DIGITAL OUTPUTS
Format
Coding
Logic Levels (Except OSC2)
VOL
VOH
OSC2
Conversion Clock (CLKOUT)
Drive Capability
POWER SUPPLIES
Rated Voltage
VA+
VA–
VD
Power Consumption
Supply Current
IA+
IA–
ID
TEMPERATURE RANGE
Specification
Storage
TYP
Acquisition + Conversion
✻
5
76
✻
89
79
79
–86
92
82
±5
±2
DSP102 Channels
±2.75V Input Range
±2.75V Input Range
±0.7V Input Range
±0.7V Input Range
±0.7V Input Range
DSP102 Channels
–5.25V < VA– < –4.75V
+4.75V<VA+, VD+ <+5.25V
IL = ±10µA
IH = ±10µA
79
32
82
–90
92
82
MIN
✻
✻
✻
200
fIN = 1kHz
fIN = 1kHz (–60dB)
fIN = 25kHz
fIN = 1kHz
fIN = 1kHz
fIN = 1kHz
MAX
TYP
✻
±2.75V
1
20
SAMPLING DYNAMICS
Aperture Delay
Aperture Jitter
Transient Response
Overvoltage Recovery
DIGITAL INPUTS
Logic Levels (Except OSC1)
VIL
VIH
OSC1 Clock
Frequency
Data Transfer Clock (XCLK)
Frequency
Duty Cycle
Conversion Clock (CLKIN)
Frequency
Duty Cycle
MIN
18
ANALOG INPUT
Voltage Range
Impedance
Capacitance
THROUGHPUT SPEED
Complete Cycle
Throughput Rate
MAX
DSP101KP
DSP102KP
MAX
UNITS
✻
Bits
✻
✻
✻
V
kΩ
pF
✻
µs
kHz
85
✻
✻
–91
94
88
dB(2)
dB
dB
dB
dB
dB
✻
82
✻
✻
–91
94
85
82
–89
92
85
✻
✻
Sufficient to meet AC Accuracy Specifications
–89
✻
✻
%
%
±0.003
±0.002
14
±2
±2
–60
–60
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
%
%
Bits
mV
mV
dB
dB
30
100
1
5
✻
✻
✻
✻
✻
✻
✻
✻
ns
ps, rms
µs
µs
0
+2.4
+0.8
+5
✻
✻
✻
✻
✻
✻
✻
✻
V
V
74HC Compatible
16
MHz
0.1
40
50
12
60
✻
✻
0.5
25
33
5.33
55
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
MHz
%
✻
✻
MHz
%
✻
✻
V
V
Serial: MSB first; 16/18-bit and Cascaded 32-bit Mode
Binary Two’s Complement
ISINK = 4mA
ISOURCE = 4mA
0
+2.4
+0.4
+5
±2mA
+4.75
–5.25
+4.75
XCLK = OSC1 = 12MHz
XCLK = OSC1 = 12MHz
0
–65
✻
✻
✻
✻
✻
✻
Can only be used to drive crystal oscillator.
✻
+5
–5
+5
250
+5.25
–4.75
+5.25
425
30
–18
5
45
–25
15
+70
+125
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
✻
mA
✻
✻
✻
✻
✻
✻
✻
✻
V
V
V
mW
✻
✻
✻
✻
✻
✻
mA
mA
mA
✻
✻
oC
oC
NOTES: (1) All dynamic specifications are based on 2048-point FFTs, using four-term Blackman-Harris window. (2) All specifications in dB are referred to a full-scale input, ±2.75Vp-p. (3) Adjustable
to zero with external potentiometer.
2
DSP101, 102
SBAS003A
TYPICAL DSP102 FFT SETUP
DSP102
Brüel & Kjaer
6 Pole,
Model 1049 1kHz
150kHz
Digital Signal ±2.75V Low-Pass
Generator
Filter
27
REF
CASC
0.1µF
1/2
OPA2604
150Ω
VINA
OSC1
220pF
1
+
1/2
OPA2604
SSF
2
CLKOUT
VPOTA
10µF
150Ω
25
220pF
VINB
CONV
26
+
XCLK
VPOTB
10µF
CLKIN
SYNC
SOUTA
22
+5V
12
13
16MHz TTL Oscillator
11
10
÷80
21
200kHz
16
8MHz
÷2
Burr-Brown
ZPB34
DSP
Processor
15
20
FFT
Software
ELECTROSTATIC
DISCHARGE SENSITIVITY
ABSOLUTE MAXIMUM RATINGS
VA+ to Analog Common ..................................................................... +7V
VA– to Analog Common .................................................................... –7V
VD to Digital Common ........................................................................ +7V
Analog Common to Digital Common ................................................... ±1V
Control Inputs to Digital Common ................................ –0.5 to VD + 0.5V
Analog Input Voltage .......................................................................... ±5V
Maximum Junction Temperature .................................................... 150oC
Internal Power Dissipation ............................................................. 825mW
Lead Temperature (soldering, 10s) ............................................... +300oC
Thermal Resistance, θJA, Plastic DIP ............................................ 50oC/W
This integrated circuit can be damaged by ESD. Texas
Instruments recommends that all integrated circuits be handled
with appropriate precautions. Failure to observe proper
handling and installation procedures can cause damage.
Electrostatic discharge can cause damage ranging from
performance degradation to complete device failure. Texas
Instruments recommends that all integrated circuits be handled
and stored using appropriate ESD protection methods.
PACKAGE/ORDERING INFORMATION
PRODUCT
NUMBER
OF
CHANNELS
SIGNAL-TO(NOISE + DIST.)
RATIO
dB (min)
PACKAGE
PACKAGE
DRAWING
NUMBER
1
1
2
2
2
79
82
76
79
82
DIP-28
DIP-28
DIP-28
DIP-28
DIP-28
215
215
215
215
215
DSP101JP
DSP101KP
DSP102JP-1
DSP102JP
DSP102KP
DSP101, 102
SBAS003A
SPECIFICATION
TEMPERATURE
RANGE
ORDERING
NUMBER
TRANSPORT
MEDIA
–25°C
–25°C
–25°C
–25°C
–25°C
DSP101JP
DSP101KP
DSP102JP-1
DSP102JP
DSP102KP
Rails
Rails
Rails
Rails
Rails
to
to
to
to
to
+85°C
+85°C
+85°C
+85°C
+85°C
3
DSP101 PIN CONFIGURATION
DSP101 PIN ASSIGNMENTS
Top View
DIP
VPOT
1
28
AGND
VIN
2
27
REF
MSB
3
26
CAP
VOS
4
25
VA –
5
24
VA +
6
DGND
7
DGND
23
DSP101
PIN #
NAME
DESCRIPTION
1
VPOT
2
3
4
5
6
7
8
9
10
11
VIN
MSB
VOS
VA –
VA +
DGND
DGND
VD
CLKIN
CLKOUT
Trim Reference Out. 10µF Tantalum to AGND.
Voltage on this pin is approximately 2.75V.
Analog In.
MSB Adjust In.
VOS Adjust In.
–5V Analog Power.
+5V Analog Power.
Digital Ground.
Digital Ground.
+5V Digital Power.
Conversion Clock In.
Conversion Clock Out. Can drive multiple
DSP101/DSP102s to synchronize conversion.
12
SSF
22
DGND
8
21
CONV
VD
9
20
SOUT
13
OSC1
CLKIN
10
19
Oscillator Point 1 Input/External Clock In. If using
external clock, drive with 74HC logic levels.
Connect to DGND if not used.
CLKOUT
11
18
TAG
14
OSC2
SSF
12
17
Oscillator Point 2 Output. Provides drive for
crystal oscillator. Make no electrical connection if
using external clock.
15
SYNC
OSC1
13
16
XCLK
Data Synchronization Out. Active High when SSF
is HIGH; active Low when SSF is LOW.
OSC2
14
15
SYNC
16
XCLK
Data Transfer Clock In.
TAG
User Tag In. Data clocked into this pin is
appended to the conversion results on SOUT.
See timing diagram (Figure 1).
17
18
No Internal Connection.
19
4
Select Synch Format In. If HIGH, SYNC will be
active High. If LOW, SYNC will be active Low.
See timing diagram (Figure 1).
No Internal Connection.
20
SOUT
Serial Data Out. MSB first, Binary Two’s
Complement format.
21
CONV
Convert Command In. Falling edge puts converter
into hold state, initiates conversion, and transmits
previous conversion results to DSP IC with
appropriate SYNC pulse.
22
23
24
25
26
DGND
27
REF
28
AGND
Digital Ground.
No Internal Connection.
No Internal Connection.
No Internal Connection.
Bypass Capacitor. 10µF Tantalum to AGND.
Voltage on this pin is approximately 2.7V.
Reference Bypass. 0.1µF Ceramic to AGND.
Voltage on this pin is approximately 3.8V.
Analog Ground.
CAP
DSP101, 102
SBAS003A
DSP102 PIN CONFIGURATION
DSP102 PIN ASSIGNMENTS
Top View
DIP
PIN #
NAME
DESCRIPTION
1
VPOTA
VINA
MSBA
VOSA
VA –
VA +
DGND
DGND
VD
CLKIN
CLKOUT
Channel A Trim Reference Out. 10µF Tantalum to
AGND. Voltage on this pin is approximately 2.75V.
Channel A Analog In.
Channel A MSB Adjust In.
Channel A VOS Adjust In.
–5V Analog Power.
+5V Analog Power.
Digital Ground.
Digital Ground.
+5V Digital Power.
Conversion Clock In.
Conversion Clock Out. Can drive multiple DSP101/
DSP102s to synchronize conversion.
VPOTA
1
28
AGND
VINA
2
27
REF
MSBA
3
26
VPOTB
VOSA
4
25
VINB
VA–
5
24
MSBB
VA+
6
23
VOSB
2
3
4
5
6
7
8
9
10
11
12
SSF
Select Synch Format In. If HIGH, SYNC will be
active High. If LOW, SYNC will be active Low. See
timing diagram (Figure 1).
13
OSC1
Oscillator Point 1 Input / External Clock In. If using
external clock, drive with 74HC logic levels.
Connect to DGND if not used.
14
OSC2
Oscillator Point 2 Output. Provides drive for crystal
oscillator. Make no electrical connection if using
external clock.
15
SYNC
Data Synchronization Out. Active High when SSF
is HIGH; active Low when SSF is LOW.
16
XCLK
Data Transfer Clock In.
17
SOUTB
18
TAGA
Channel A User Tag In. Data clocked into this pin
is appended to the conversion results of SOUTA.
See timing diagram (Figure 1).
19
TAGB
Channel B User Tag In. Data clocked into this pin
is appended to the conversion results of SOUTB.
See timing diagram (Figure 1).
20
SOUTA
Channel A Serial Data Out. MSB first, Binary
Two’s Complement format. If CASC is HIGH, 32
bits of data output, with first 16 bits being Channel
A data.
21
CONV
Convert Command In. Falling edge puts converter
into hold state, initiates conversion, and transmits
previous conversion results to DSP IC with
appropriate SYNC pulse.
22
CASC
Select Cascade Mode In. If HIGH, DSP102
transmits a 32-bit word on SOUTA, with the first 16
bits being data on Channel A. If LOW, DSP102
transmits data for both channels simultaneously.
23
24
25
26
VOSB
MSBB
VINB
VPOTB
27
REF
28
AGND
Channel B VOS Adjust In.
Channel B MSB Adjust In.
Channel B Analog In.
Channel B Trim Reference Out. 10µF Tantalum to
AGND. Voltage on this pin is approximately 2.75V.
Reference Bypass. 0.1µF Ceramic to AGND.
Voltage on this pin is approximately 3.8V.
Analog Ground.
DSP102
DGND
7
22
CASC
DGND
8
21
CONV
9
20
SOUTA
CLKIN
10
19
TAGB
CLKOUT
11
18
TAGA
SSF
12
17
SOUTB
OSC1
13
16
XCLK
OSC2
14
15
SYNC
VD
DSP101, 102
SBAS003A
Channel B Serial Data Out. MSB first, Binary
Two’s Complement format.
5
TYPICAL PERFORMANCE CURVES
At TA = +25°C, VA+ = VD+ = +5V, VA– = VD– = –5V, Sampling Frequency fS = 200kHz; External Clock Input at OSC1 = 80fS = 16MHz, XCLK = 40fS = 8MHz; Using
2048 Point FFT; Data analysis limited to 0 to 20kHz band; Unless otherwise specified.
SINAD means Signal-to-(Noise + Distortion) Ratio.
SNR means Signal-to-Noise Ratio excluding harmonics
thru the 8th.
THD means Total Harmonic Distortion thru 8th harmonic.
SFDR means Spurious Free Dynamic Range, including
harmonics.
FREQUENCY SPECTRUM of ±2.75V, 20kHz INPUT
(Using Four-Term Blackman-Harris Window)
FREQUENCY SPECTRUM of ±2.75V, 1kHz INPUT
(Average of 12 FFTs, No Window Used)
0
0
–20
Magnitude (dB)
Magnitude (dB)
–30
–60
–40
–60
–80
–90
–100
–120
–120
0
25
50
75
0
100
25
50
75
100
Frequency (kHz)
Frequency (kHz)
FREQUENCY SPECTRUM of ±2.75V, 451kHz INPUT
(Using Four-Term Blackman-Harris Window)
INTERMODULATION DISTORTION WITH 1kHz AND 3kHz INPUTS
(Using Four-Term Blackman-Harris Window)
0
0
–20
–20
Magnitude (dB)
Magnitude (dB)
Undersampling
–40
–60
–80
–40
–60
–80
–100
–100
–120
–120
0
25
50
75
0
100
25
50
75
100
Frequency (kHz)
Frequency (kHz)
DSP102 CHANNEL SEPARATION ON CHANNEL B WITH
±2.75V, 1kHz INPUT ON CHANNEL A
DYNAMIC PERFORMANCE vs TEMPERATURE
80
0
–80
Magnitude (dB)
–20
–40
–60
–80
–100
–85
SINAD
90
0
25
50
Frequency (kHz)
75
100
–90
THD
SNR
95
–95
SFDR
100
–120
6
85
THD (dB)
SINAD, SNR and SFDR (dB)
fIN = 1kHz, ±2.75V
–55 –40 –25
0
25
70
85
–100
125
Ambient Temperature (°C)
DSP101, 102
SBAS003A
TYPICAL PERFORMANCE CURVES (Cont.)
At TA = +25°C, VA+ = VD+ = +5V, VA– = VD– = –5V, Sampling Frequency fS = 200kHz; External Clock Input at OSC1 = 80fS = 16MHz, XCLK = 40fS = 8MHz; Using
2048 Point FFT; Data analysis limited to 0 to 20kHz band; Unless otherwise specified.
DYNAMIC PERFORMANCE vs TEMPERATURE
(fS = 180kHz Asychronous to 12.288MHz
Crystal Between OSC1 and OSC2)
DYNAMIC PERFORMANCE vs TEMPERATURE
(Data Analysis Over Full 0 to 100kHz Band)
70
75
–70
–75
fIN = 1kHz, ±2.75V
80
–80
SINAD
–85
THD
90
–90
SNR
95
–95
–80
SINAD
85
90
–90
THD
95
–95
SFDR
100
0
25
70
85
SFDR
100
–100
–55 –40 –25
–55 –40 –25
125
25
70
85
–100
125
DYNAMIC PERFORMANCE vs CONVERSION RATE
(Data Analysis over Full 0 to fS/2 Band,
OSC1 = 12.288MHz, XCLK = 3.072MHz)
HISTOGRAM OF 5k CONVERSION RESULTS ON DSP102
(Both Inputs Grounded)
2500
70
fIN = 1kHz, ±2.75V (0dB)
SINAD
2000
Channel A
Channel B
1000
500
SINAD, SNR and SFDR (dB)
Number of Conversions Yielding This Code
0
Ambient Temperature (°C)
Ambient Temperature (°C)
1500
–85
SNR
0
75
–75
SNR
80
–80
85
–85
THD
90
–90
SFDR
95
–95
100
Code FFF1
Voltage –1.26mV
FFF7
–100
0
000E
1.17mV
0000
0V
–70
THD (dB)
85
80
THD (dB)
–75
SINAD, SNR and SFDR (dB)
75
THD (dB)
SINAD, SNR and SFDR (dB)
fIN = 1kHz, ±2.75V
30
60
90
120
150
180
Conversion Rate (kHz)
Output Code and Equivalent Voltage
(Binned at 16-bit level)
SINAD vs INPUT FREQUENCY
(Data Analysis over Full 0 to 100kHz Band)
TOTAL HARMONIC DISTORTION
vs INPUT FREQUENCY
100
–60
±2.75V Input (0dB)
80
±0.275V Input (–20dB)
70
SINAD (dB)
±2.75V Input (0dB)
Total Harmonic Distortion (dB)
90
60
50
40
±2.75mV Input (–60dB)
30
20
–70
–80
–90
10
–100
0
0.1
1
10
Input Frequency (kHz)
DSP101, 102
SBAS003A
100
1
10
100
1000
Input Frequency (kHz)
7
FIGURE 1. DSP101 and DSP102 Timing.
8
DSP101, 102
SBAS003A
SYMBOL
SOUTA
CONV
XCLK
186
62
84
62
10
20
83
50
24
40
t1 +40
3 t12
2000
1050
1340
0
667
2 t1
15
15
15
MAX
Channel A Data
Bit 2
t4
TAG Bit 2
Bit 2
MIN
Bit 1 (MSB)
t9
t11
t9
XCLK period. Duty Cycle 50% ±10%
Convert Command LOW Time
Convert Period (CASC = LOW on DSP102)
Convert Period (CASC = HIGH on DSP102)
SYNC Active Delay after Convert Falling Edge
SYNC LOW to HIGH Delay from XCLK Rising
SYNC HIGH to LOW Delay from XCLK Rising
SOUTA/B Data Valid Delay from XCLK Rising
SOUTA/B Data Valid After from XCLK Rising
TAGA/B Data Setup before XCLK Rising
TAGA/B Data Hold after XCLK Rising
OSC1 Period.(2) Duty Cycle 50% ± 10%
CLKOUT Period. Duty Cycle 33% ± 10%
CLKIN Period. Duty Cycle 33% ± 20%
CLKIN HIGH
CLKIN LOW
t8
TAG Bit 1
t10
Bit 1 (MSB)
DESCRIPTION (CL = 50pF)
(CASC = HIGH)
t2
t1
t8
t6
t7
t3
ns
ns
t1
t1
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
UNITS
Bit 16 (LSB)
Bit 16
NOTES: (1) When using a DSP IC in a 16-bit mode, these data bits will be ignored by the processor. (2) fOSC1 must
be at least 72 times faster than the conversion rate. (t3, t4 ≥ 72 t12)
t1
t2
t3
t4
t5
t6
t7
t8
t9
t10
t11
t12
t13
t14
t15
t16
(CASC = LOW on DSP102)
DSP102 Cascade Mode (CASC = HIGH)
TAGA/B
SOUTA/B
t7
SYNC (SSF = LOW)
t5
t6
t2
t1
SYNC (SSF = HIGH)
CONV
XCLK
(1)
CLKIN
CLKOUT
OSC1
(2)
(LSB)
Channel B Data
Bit 18
Bit 16
TAG Bit 1
t12
t15
Conversion Clock Timing (2)
Bit 1 (MSB)
Bit 17
t14
t13
t16
TAG Bit 2
t2
t2
THEORY OF OPERATION
A unique Tag feature allows additional digital data to be
appended to the conversion results, so that a single data
word contains conversion results plus other signal information, such as gain settings or multiplexer channel settings in
front of the converter.
The DSP101 and DSP102 are sampling A/D converters
optimized for handling dynamic signals. They have complete logic interface circuitry for ease of use with standard
digital signal processing ICs, and transmit data words in a
serial stream. The successive approximation conversion architecture is combined with an inherently sampling switched
capacitor array to provide maximum user flexibility over
sampling and conversion timing.
The DSP101 and DSP102 are high-resolution A/D converters complete with sampling capability and on-board references. They can acquire and convert analog signals at up to
a 200kHz sampling rate. Both operate from ±5V supplies,
and have full-scale analog input ranges of ±2.75V.
The DSP101 and DSP102 are pipelined internally. When the
user gives a convert command at time (t), two actions are
initiated. First, the internal sample/holds are switched to the
hold state, and a conversion cycle is initiated. At the same
time, the DSP101 or DSP102 transmits a synchronization
pulse and starts shifting out the conversion results from the
previous convert command at (t-1) using the system bit
clock. The data from the conversion at time (t) is shifted out
of the converter after the next convert command is received.
BASIC OPERATION
Figure 2 shows the minimum connections required to operate the DSP101. The falling edge of a convert command on
pin 21 puts the internal sampling capacitor array into the
hold state. The falling edge on pin 21 also starts the process
to initiate a conversion and transmit data from the previous
conversion, synchronizing both appropriately to the 10MHz
clock input on pin 13. Figure 1 shows the timing relationship
between the convert command, the output data, and the
synchronization pulse.
Both the DSP101 and the DSP102 are 18-bit A/Ds internally. When the DSP IC is programmed to accept 16-bit
word lengths, the processor will ignore the last two data bits
transmitted from the DSP101 or DSP102. A Cascade Mode
on the DSP102 can be invoked to transmit data for both
conversion channels over a single serial line as a 32-bit
word. In this mode, the first 16 bits of data transmitted after
the Sync pulse contain data from channel A, followed by 16
bits of information from channel B, allowing a single 32-bit
word to contain data for both channels.
In this basic system, the 10MHz clock is used both to
generate a 3.33MHz conversion clock and as the data transfer bit clock for outputting data. Per Figure 1, there must be
at least 72 clock pulses on pin 13 between convert commands, so that this circuit can sample and convert at up to
138kHz.
DSP101
+
10µF
1
VPOT
2
(1)
(1)
AGND
28
VIN
REF
27
3
MSB
CAP
26
4
VOS
NC
25
(1)
0.1µF
±2.75 Analog Input
10Ω(2)
–5V
+
–5V
+
10µF
10µF
+
5
VA–
NC
24
(1)
6
VA+
NC
23
(1)
7
DGND
DGND
22
8
DGND
CONV
21
9
VD
SOUT
20
10
CLKIN
NC
19
11
CLKOUT
TAG
18
12
SSF
NC
17
13
OSC1
XCLK
16
14
OSC2
SYNC
15
10µF
+5V
+
Convert Command
Serial Data Output
10µF
+5V
10MHz, 50%
(±10%) 74HC
Logic Level Clock Input
(1)
NOTES: (1) Leave Unconnected.
(2) Protection from power supply momentary overrange.
(1)
(1)
Synch
Pulse
= Analog Ground
Bit Clock
= Digital Ground
FIGURE 2. DSP101 Basic Operation.
DSP101, 102
SBAS003A
9
After the 18 bits of data from the previous conversion have
been transmitted, pin 20 will continue to clock out LOWs
until a new convert command restarts the process, since pin
18 (the Tag input) is grounded. If pin 18 is tied HIGH, pin
20 will clock out HIGHs between conversion cycles.
CONVERSION
A falling edge on pin 21 (CONV) puts the internal sampling
capacitors in the hold state with minimum aperture jitter,
initiates a conversion synchronized to the conversion clock,
and outputs the data from the previous conversion with an
appropriate Sync pulse. On the DSP102, a single convert
command simultaneously samples both channels. The timing relationship between the convert command, Sync and
the output data is shown in Figure 1. Both Sync and the
output data are synchronized to XCLK, the system bit clock.
Following a convert command falling edge, pin 21 must be
held LOW at least 50ns.
Convert commands can be sent to the DSP101 and DSP102
completely asynchronous to other clocks in the system. This
allows external events to be used to trigger conversions.
From Figure 1, it can be seen that two different clocking
conditions must be considered in determining the minimum
acceptable time between convert commands. First, there
need to be a minimum of 24 XCLK periods between convert
commands, to allow internal synchronization and transmission of Sync and the data. (In the Cascade Mode on the
DSP102, there need to be at least 40 XCLK periods between
convert commands, to allow transmission of the 32-bit data
words.) When used with DSP processors programmed for
data words longer than 16 bits, the transmission time to the
processor may determine the minimum time between convert commands.
The second limitation on convert commands is the requirement that the internal analog-to-digital converter be given
enough time to complete a conversion, shift the data to the
output register, and acquire a new sample. This condition is
met by having a minimum of 24 CLKIN periods between
convert commands, or a minimum of 72 clock cycles on
OSC1, if it is used to generate the conversion clock (CLKOUT
driving CLKIN).
SIGNAL ACQUISITION
After a conversion is completed, the DSP101 or DSP102
will switch back to the sampling mode. With at least 24
10
CLKIN periods between convert commands, the A/D will
have had sufficient time to acquire a new input sample to full
rated accuracy.
DATA FORMAT AND INPUT LEVELS
The DSP101 and DSP102 output serial data, MSB first, in
Binary Two’s Complement format. In the Cascade Mode on
the DSP102, the serial data will first contain 16 bits of data
for channel A, MSB-first, followed by channel B data, again
MSB-first. The analog input levels that generate specific
output codes are shown in Table I.
As with all standard A/Ds, the first output transition will
occur at an analog input voltage 1/2 LSB above negative full
scale (–2.75V + 1/2 LSB) and the last transition will occur
3/2 LSB below positive full scale (+2.75V – 3/2 LSB.) See
Figure 3.
1FFFFH
1FFFEH
Digital Output (18-bit Words)
The convert command at pin 21 causes a Sync pulse to be
output on pin 15, followed by the data from the previous
conversion output on pin 20. The Sync pulse will be HIGH
for one bit clock cycle, since pin 12 is tied HIGH. (A LOW
Sync pulse will be output on pin 15 if pin 12 is tied LOW.)
Data is serially transmitted in an MSB-first data stream, in
Binary Two’s Complement format. Both the Sync pulse (pin
15) and the data stream (pin 20) are synchronized to the bit
clock (at pins 13 and 16), with the timing relationships
shown in Figure 1.
00001H
00000H
–2.75V
–20.98µV
3FFFFH
+2.749979V
0.00V
20001H
20000H
FIGURE 3. Analog Input to Digital Output Diagram.
DIGITAL OUTPUT
(BINARY TWO’S COMPLEMENT)
DESCRIPTION
ANALOG
INPUT
16-BIT
WORDS
BINARY CODE (HEX)
18-BIT
WORDS
(HEX)
Least Significant Bit
5.5V
(LSB =
)
2n
16-bit Words
18-bit Words
Input Range
+ Full Scale
(2.75V–1LSB)
84µV
21µV
±2.75V
+2.749916V
+2.749979V
011…111
0V
000…000
One LSB below
Bipolar Zero
–84µV
–21µV
111…111
– Full Scale
–2.75V
100…000
Bipolar Zero
(Midscale)
7FFF
1FFFF
0000
00000
FFFF
3FFFF
8000
20000
TABLE I. Ideal Input Voltage vs Output Code.
DSP101, 102
SBAS003A
18-bit Shift Register
D
Channel A Conversion Results from SAR
CLKIN
CONV
Shift/Load(1)
18-bit Register
RCK
18
(LSB)
D1
16
14
12
10
8
6
4
2
1
(MSB)
SOUTA
XCLK
TAGA
D1
E D2
18-bit Shift Register
CASC
18-bit Shift Register
TAGB
D1
SOUTB
XCLK
Shift/Load(1)
(LSB)
18
CONV
16
14
12
10
8
6
4
2
(MSB)
1
18-bit Register
RCK
CLKIN
D
Channel B Conversion Results from SAR
18-bit Shift Register
NOTE: (1) Signal internal to DSP101/DSP102 which also generates SYNC pulse.
FIGURE 4. Output Structure of DSP102.
DATA TRANSFER
The internal A/Ds generate 18 bits of data, transmitting the
data MSB first. When read by a DSP IC programmed to
accept 16 bits of data, the first 16 MSB bits of data from the
DSP101, or each channel of the DSP102, will be shifted into
the processor’s input shift register, and the last two least
significant bits of data from the A/D will be ignored,
although they will still be present on the serial data line.
When the DSP processor is programmed to accept words of
more than 16-bit length (typically 24-bit or 32-bit), the
DSP101 and DSP102 will transmit the full 18-bit conversion
results, after which the information input on the TAG input
(or TAGA and TAGB on the DSP102) will be appended to
the output word. (See Tag Feature below.)
the conversion clock may also be independent of the bit
clock. The DSP101 and DSP102 internally synchronize the
output data, Sync pulse, and Tag inputs to the bit clock.
In the Cascade Mode, the DSP102 will first transmit the 16
MSBs from channel A, followed by the full 18 bits from
channel B, although DSP processors programmed to accept
32 bits of data will ignore the final two bits of information
on Channel B. See the DSP102 Cascade Mode section below
for details of the Cascade mode.
When a convert command is received, the internal logic
generates an appropriate Sync pulse, synchronized to XCLK,
as shown in Figure 1. The output Sync pulse will be active
High or active Low depending on whether a HIGH or a
LOW, respectively, is input at SSF (pin 12).
DATA SYNCHRONIZATION
A convert command both initiates a conversion and starts
the process for transmitting data from the previous conversion. Convert commands can come at any time, completely
asynchronous to the conversion clock or the bit clock, and
DSP101, 102
SBAS003A
While the convert command, conversion clock and bit clock
can be asynchronous, system performance is usually enhanced by synchronizing all of them to a system master
clock, whenever the application permits. This minimizes
changes in digital loads and currents when the critical S/H
transition and A/D bit decisions are occurring. Within the
DSP101 and DSP102 themselves, running asynchronous
convert commands, conversion clocks and bit clocks typically degrades performance only several dB, as shown in the
various typical performance curves, but the system board
design can easily have more effect.
The convert command also causes the conversion results
from the previous conversion to be loaded into the output
shift register, synchronous to XCLK. Figure 4 shows the
operation of the internal data shift registers on the DSP102.
The DSP101 is basically similar, but includes only the top of
the figure, showing the SOUTA path.
11
During the internal successive approximation conversion
process, the conversion results are shifted into the input shift
registers of the output stage on the DSP102. A new convert
command latches that data into the 18-bit parallel latches
shown. The internal signal that also generates the Sync
pulse, labeled “Shift/Load” in Figure 4, synchronously loads
the conversion data into the output shift register on the rising
edge of XCLK. The conversion results are then clocked out
of the shift register on subsequent rising edges of XCLK.
long enough for internal analog circuitry to settle sufficiently between bit decisions to insure rated accuracy. Bit
decisions in the A/D are then made on the rising edge of
CLKIN.
SAR Clock
Control
DATA TRANSFER CLOCK
XCLK is the data transfer clock, or bit clock, for the system,
and is an input for the DSP101 or DSP102. This input is
TTL- and 74HC-level compatible. The serial data and SYNC
outputs are synchronized internally to this clock, with data
valid on the rising edge of XCLK, per the timing shown in
Figure 1. Data input on pin 18 (TAG) on the DSP101, or on
pins 18 and 19 on the DSP102 (TAGA and TAGB), will be
clocked into the output shift register on the rising edge of
XCLK, as discussed in the Tag Feature section.
CONVERSION CLOCK
The analog-to-digital converter sections in the DSP101 and
DSP102 were designed to provide accurate conversions
under worst case conditions of supplies, temperatures, etc.
In order to achieve a full 200kHz sampling capability, they
were designed to use a 33% duty cycle conversion clock
(CLKIN on pin 10) as shown in Figure 1. The clock is LOW
To other
DSP102's CLKIN for
synchronous operation
DSP101 or DSP102
÷3
CLKIN
10
CLKOUT 11
OSC1
OSC2
13
14
1MΩ
12.288MHz
10pF
10pF
Crystal is CTS Knight MP122 12.288MHz,
20pF load, series resonant mode.
FIGURE 5. DSP101 or DSP102 Conversion Clock Circuit.
DSP101 or DSP102
+
(1)
AGND
28
2
REF
27
3
VPOTB
26
1
VPOTA
10µF
25
4
0.1µF
+
10µF
(1)
10Ω(2)
–5V Analog
+5V Analog
+
10µF
+
+5V Digital
10µF
5
VA –
24
6
VA +
23
7
DGND
22
8
DGND
21
9
VD
20
0.01µF
10
19
11
18
12
17
13
16
= Analog Ground
14
15
= Digital Ground
NOTES: (1) Pin 1 and pin 26 must be bypassed with 10µF tantalum capacitors, on both the DSP101 and DSP102.
(2) Protection from power supply momentary overrange.
FIGURE 6. DSP101 or DSP102 Power Supply Connections.
12
DSP101, 102
SBAS003A
When a convert command is received, the DSP101 or
DSP102 immediately switches the sampling capacitors to
the hold state, and then internally gates the conversion clock
to the A/D appropriately. Allowing a minimum of 24 CLKIN
pulses between conversions insures that there is sufficient
time for complete, accurate conversions, and allows the
input sampling capacitor to fully acquire the next sample,
regardless of the timing between the convert command and
CLKIN.
In most applications, CLKIN (pin 10) can be driven from a
50% duty cycle clock without performance degradation.
During characterization of the DSP101 and DSP102, the
performance of a number of parts was measured under
various conditions with a 4.8MHz, 50% duty cycle input to
CLKIN at a full 200kHz conversion rate without noticeable
degradation.
OSCILLATOR INPUTS AND CLKOUT
The DSP101 or DSP102 can generate a 33% duty cycle
conversion clock output on CLKOUT (pin 11). This is
accomplished by dividing by three a clock from either an
external 74HC-level clock or from a crystal oscillator.
CLKOUT can deliver ±2mA, and can be used to drive
multiple DSP101 or DSP102 CLKINs. See Figure 1 for the
timing relationship between OSC1 and CLKOUT.
To use an external 74HC-level clock, drive the clock into
OSC1 (pin 13), and leave OSC2 (pin 14) unconnected.
To use a crystal oscillator to generate the conversion clock,
refer to Figure 5. Connect the oscillator between OSC1 and
OSC2. OSC2 provides the drive for the crystal oscillator.
This pin cannot be used elsewhere in the system.
If CLKOUT is not used, both it and OSC2 should be left
unconnected, and OSC1 should be grounded.
TAG FEATURE
Figure 4 shows the implementation of the TAG feature on
the DSP101 and DSP102. When a convert command is
received, the internal Shift/Load signal loads conversion
result data into the output shift register synchronous to
XCLK. Between convert commands, the information input
on TAG (on the DSP101) or on TAGA and TAGB (on the
DSP102) will be clocked into the output shift register on the
rising edges of XCLK. Since this is an 18-bit shift register,
the data input on the Tag lines will be output on SOUT
(DSP101) or SOUTA and SOUTB (DSP102) delayed by 18
bit clocks.
The Tag Feature can be used in various ways. The Tag
inputs can be tied HIGH or LOW to differentiate between
two converters in a system. As discussed in the Applications
section below, the Tag feature can be used to append to the
serial output data word information on multiplexer channel
address, or other digital data related to the input signal (such
as the setting on a programmable gain amplifier.) Another
option would be to daisy-chain multiple DSP101 or DSP102
converters, linking the serial output of one to the Tag input
of the next. This can simplify the transmission of data from
multiple A/Ds over a single optical isolation channel.
DSP102 CASCADE MODE
If pin 22 (CASC) is tied HIGH, the DSP102 will be in the
Cascade Mode. In this mode, when a convert command is
received, the DSP102 will transmit a 32-bit data word on pin
DSP101 or DSP102(1)
+5V
Analog
Input A
3
2
–5V
+
2.2µF
1/2
8
+ OPA2604
1
–
4
+
1
VPOTA
2
VINA
28
10µF
150Ω
220pF
+
2.2µF
REF
27
3
VPOTB
26
4
VINB
25
0.1µF
+
10µF
150Ω
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
220pF
7
+
1/2
–
OPA2604
5
Analog
Input B
6
Leave out on DSP101(1)
NOTE: (1) On DSP101, pin 25 is not internally
connected. Pin 26 must still be bypassed with
the 10µF Tantalum capacitor.
FIGURE 7. DSP101 or DSP102 Input Buffering.
DSP101, 102
SBAS003A
13
20 (SOUTA) containing data for both input channels in two
16-bit words. Referring to Figure 1, the first 16 bits of data
will be the results for channel A, followed by 16 bits of
information for channel B. The data will be transferred MSB
first. A convert command at time (t) will initiate the transmission of the results of the conversion initiated at time
(t – 1).
From the descriptions above of the internal shift registers
shown in Figure 4, it can be seen that the DSP102 in the
Cascade Mode actually continues to shift out data after the
32nd bit of the data word. The next two bits clocked out will
be the last two data bits from the full 18-bit conversion on
channel B, after which the information output on SOUTA
will be the information clocked into TAGB 35 bit clock
cycles earlier.
In the Cascade mode on the DSP102, SOUTB will still
output channel B conversion data and tag data as usual.
ANALOG PERFORMANCE
LINEARITY
The DSP101 and DSP102 are optimized for signal processing applications with wide dynamic range requirements.
Linearity is trimmed for best performance in the range
around 0V, which is critical for handling low amplitude
signals. The DSP101 and DSP102 typically have integral
and differential non-linearity below ±0.003% in the input
range of ±0.7V, with there being no missing codes at the
14-bit level in this range. Over the full ±2.75V input range,
the largest non-linearities are centered around the bit #2
transition points at +1.375V and –1.375V levels.
NOISE AND BIPOLAR ZERO ERROR
The equivalent input noise and bipolar zero error of the
DSP101 and DSP102 is shown in the typical performance
section for both channels on a DSP102. The inputs to both
channels were grounded, and the results of 5,000 conversions was recorded. The data shown is binned at the 16-bit
level. The noise results from all sources in the circuit,
including clocks, reference noise, etc.
In a theoretically ideal converter with no offset and no noise,
the results of all 5,000 conversion for each channel would lie
in the bin corresponding to bipolar zero, code 0000. The
typical DSP101 or DSP102 will have offset errors in the
range of 1 to 2mV, and the two channels on the DSP102 will
be matched closer than 2mV. The DSP102 shown in the
typical performance section has the worst offset, –0.8mV,
on channel A, with channel B being less than 1mV different,
and the three sigma noise on either channel being less than
250µV.
INPUT BANDWIDTH
From the typical performance curves, it can be seen that
there is very little degradation in Signal-to-(Noise + Distortion) for input signals up to 100kHz. The wideband sampling
input typically maintains a 60dB Signal-to-(Noise + Distortion) Ratio undersampling 500kHz input signals.
LAYOUT CONSIDERATIONS
Because of the high resolution, linearity and speed of the
DSP101 and DSP102, system design problems such as
ground path resistance, contact resistance and power supply
quality become very important.
DSP101 or DSP102(1)
1
+
10µF
47kΩ
25kΩ
VPOTA
28
0.1µF
150kΩ
47kΩ
0.01µF
2
3
MSBA
4
VOSA
REF
27
VPOTB
26
25
25kΩ
5
MSBB
24
6
VOSB
23
0.01µF
+
150kΩ
47kΩ
47kΩ
10µF
25kΩ
0.01µF
25kΩ
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
0.01µF
Leave out on DSP101(1)
NOTE: (1) On DSP101, pins 23 and 24 are
not internally connected. Pin 26 must still be
bypassed with the 10µF Tantalum capacitor.
FIGURE 8. DSP101 or DSP102 Optional MSB and Offset Adjust.
14
DSP101, 102
SBAS003A
POWER SUPPLY DECOUPLING
All of the supplies should be decoupled to the appropriate
grounds using tantalum capacitors in parallel with ceramic
capacitors, as shown in Figure 6. For optimum performance
of any high resolution A/D, all of the supplies should be as
clean as possible. If separate digital and analog supplies are
available in a system, care should be taken to insure that the
difference between the analog and the digital supplies is not
more than 0.5V for more than a few hundred milliseconds,
as may occur at power-on.
Optimal dynamic performance is achieved by soldering the
parts directly into boards, to keep the A/Ds as close as
possible to ground. The use of sockets will often degrade AC
performance. Zero-Insertion-Force sockets are particularly
poor because longer lead lengths create inductance.
Short traces on the board, and bypass capacitors as close as
possible to the A/D, will further improve dynamic performance.
GROUNDS
To achieve the maximum performance from the DSP101 or
DSP102, care should be taken to minimize the effect of
changes in current flowing in the system grounds, particularly while bit decisions are being made in the successive
approximation converter’s comparator. Pin 28 (AGND) on
both the DSP101 and the DSP102 is the most critical, and
care should be taken to make this pin as close as possible to
the same potential as the system analog ground.
INPUT SIGNAL CONDITIONING
To avoid introducing distortion, the DSP101 and DSP102
analog inputs must be driven by a source with low impedance over the input bandwidth needed in the application. Op
amps such as the NE5532 or Texas Instruments OPA2604
work well over audio bandwidths. Figure 7 shows an appropriate input driver circuit. The 150Ω and 220pF shown on
the input help reduce the dynamic load on the input signal
conditioning amp in front of the A/D, since all switched
capacitor array architectures exhibit fast changes in input
current load as the input sampling switch is opened and
closed. These dynamic changes in the load can affect any
signal conditioning circuit at the input. Other R and C
Whenever possible, it is strongly recommended that separate
analog and digital ground planes be used. With an LSB level
of 84µV at the 16-bit level, and one-quarter of that at the
18-bit level, the currents switched in a typical DSP system
can easily corrupt the accuracy of the A/Ds unless great care
is taken to analyze and design for current flows.
DSP101
74HC594(1)
14
20
Serial Data
SOUT
QA
12
SSF
+5V
+5V
16
XCLK
10
13
11
9
SR CLK
QH
QH
TTL Bit
Clock
SYNC
15
RCK
14
D1
Serial Data
QA
+5V
+5V
2
9
D2
CLR
CLK
Q7
8
+5V
10
13
SR CLR
R CLR
13
11
SR CLK
QH
74HC164
1
+5V
+5V
2
9
D15 (LSB)
D14
D13
D12
D11
D10
D9
D8
12
74HC594(1)
74HC164
1
SR CLR
R CLR
15
1
2
3
4
5
6
7
RCK
15
1
2
3
4
5
6
7
D7
D6
D5
D4
D3
D2
D1
D0 (MSB)
12
D1
D2
CLR
74HC74
HC04
CLK
Q7
NOTE: (1) Substituting
74HC595s provides three
state outputs, with pin 13 (OE)
used to enable the parallel
data lines.
8
3
13
2
+5V
4
1
12
10
RD
13
CLK1
Q1
5
D1
S1
R1
D2
S2
CLK2
R2
Q2
11
9
Data Valid Signal
FIGURE 9. Driving a 16-bit Parallel Port from the DSP101.
DSP101, 102
SBAS003A
15
combinations can be used, but the resistor should not exceed
200Ω, or the output settling time of the signal conditioning
amplifier may be too long.
EXTERNAL ADJUSTMENTS
All of the specifications for the DSP101 and DSP102, plus
the typical performance curves, are based on the performance of these A/Ds without external trims. In most applications, external trims are not required.
OFFSET ADJUST
Where required by specific applications, offsets can be adjusted using the circuit of Figure 8. When not adjusted, VOS
(pin 4) on the DSP101, and VOSA (pin 4) and VOSB (pin 23)
on the DSP102, should be left open. If these pins are connected to traces on the board, they should be bypassed to
ground with 0.01µF capacitors, as close as possible to the A/D.
To trim offset, one alternative is to ground the analog input
while converting continually. Then adjust the trimpot (on
VOS for the DSP101, on VOSA and VOSB for the DSP102)
until the output code is toggling between the codes FFFF and
0000 (Hex) at the 16-bit level (3FFFF and 00000 at the
18-bit level). This will center the offset at 1/2 LSB below
0V, which is respectively –42µV or –10µV at the 16- and
18-bit levels.
The offset can also be adjusted by providing a sine wave to
the A/D input. Using FFT, or even simple averaging of
several thousand conversion results at a time, the trimpots
can be adjusted until there is no DC offset of the signal.
Grounding the input, or providing the sine wave, as far in
front of the A/D as possible allows offset from intervening
signal conditioning components to be also corrected by this
procedure.
MSB ADJUST
In most applications, adjustment of the Most Significant Bit
weight will not be required. When not adjusted, MSB (pin 3)
on the DSP101, and MSBA (pin 3) and MSBB (pin 24) on
the DSP102, should be left open. If these pins are connected
to traces on the board, they should be bypassed to ground
with 0.01µF capacitors, as close as possible to the A/D.
MSB (pin 3) on the DSP101, and MSBA (pin 3) and MSBB
(pin 24) on the DSP102, are internally connected to a
resistor divider network that is used to laser-trim the weight
DSP101
HI-508A
4
Analog Inputs(1)
5
6
7
12
11
10
9
21
In1
In2
Out
In3
In4
EN
2
2
6
OPA627
2
VIN
SOUT
TAG
+5V
20
Serial Data Out
18
C1
In5
A0
In7
A1 16
A 15
12
220pF
1
In6
In8
CONV
R1
150Ω
3
8
SSF
XCLK
SYNC
16
15
2
NOTE: (1) Must be low source impedance
with unused inputs tied to ground.
6
5
4
3
9
15
74HC163
CO
11
QD
12
C
QC
13
B
QB
14
A
QA
1
LD
CL
74HC574
D
9
8
7
6
5
CLK ET EP
2 10 7
4
+5V
3
2
8D
8Q
7D
7Q
6D
6Q
5D
4D
5Q
4Q
3D
3Q
2D
2Q
1D
1Q
CLK OE
11 1
74HC166
12
14
13
12
14
11
15
10
16
5
17
4
18
3
19
2
1
H
QH
13
G
+5V
F
4.7kΩ
E
R2
C4
D
1000pF
C
B
15
A
R/C
SI
14 74HC221
CE
2
15
S/L
1
CLK CI CL
7
6 9
B
Q
A
Q
+5V
13
4
CL
3
+5V
Convert Command
(Positive Edge Triggered)
FIGURE 10. A Complete Eight-Channel Analog Input System Using the DSP202 and the HI-508A.
16
DSP101, 102
SBAS003A
of the MSB capacitor in the CDAC. These pins are nominally at +100mV after laser-trimming during manufacturing.
They can handle external inputs up to about one diode drop
below ground (–0.6V) before internal clamping circuitry is
triggered.
(t) is valid one conversion cycle plus 17 XCLK clocks later
(at t+1 plus 17 times XCLK). A convert command at time
(t+1) generates a Sync and begins transmitting serial data
from SOUT. The serial data is shifted into the 74HC594
shift registers, and Sync is shifted through the 74HC164
shift registers. The Q1 output of the 74HC74 dual D-type
flip-flops clocks the conversion data into the output register
of the 74HC594s, and triggers a data valid signal on its Q2
output. The user can then read the data at any time before the
next conversion is started, and the Read signal will reset the
data valid output from Q2.
Figure 8 shows an appropriate circuit for adjusting the
weight of the most significant bit to minimize differential
non-linearity at the critical major-carry transition. To adjust,
provide a small amplitude sine wave to the selected A/D
input pin while converting continually, and adjust for maximum Signal-to-(Noise + Distortion) ratio, using appropriate
signal analysis software.
In many systems, galvanic isolation of signals is required.
Using opto-couplers on the serial data lines in Figure 9
allows a fully isolated system to be built using a DSP101 and
only three couplers across the barrier (for serial data, XCLK
and SYNC.)
GAIN ADJUST
If circuit gain needs to be adjusted in hardware, rather than
in system software, appropriate trimpots should be included
in the analog signal conditioning section in front of the
DSP101 or DSP102. No specific gain adjust circuitry is
included in the parts.
MULTIPLEXING INPUTS TO THE DSP101
Figure 10 shows a complete circuit for sequentially scanning
eight analog input channels with a single DSP101, and using
the Tag feature on the DSP101 to append the multiplexer
channel address to the serial output conversion results.
APPLICATIONS
The circuit in Figure 10 includes the required digital logic
and timing logic. The 74HC163 counter provides the scan
sequence to the Texas Instruments HI-508A analog multiplexer. In order to allow the HI-508A enough time to switch
to the next channel and settle before the DSP101 begins a
conversion, a 74HC221 one-shot introduces a 3µs delay for
the DSP101 convert command input.
INTERFACING DSP101 TO PARALLEL PORTS
Figure 9 shows a circuit for converting the serial output data
from the DSP101 into 16 bits of parallel data, within the
timing constraints of the serial bit-stream from the DSP101.
In many applications, this circuit can be easily incorporated
into gate arrays or other programmed logic circuits already
used in the system, since the extra gate count is not high.
The Texas Instruments OPA627 provides a low impedance
source for the DSP101, buffering it from the output imped-
This circuit adds an additional pipeline delay to the conversion data, so that the parallel data from a conversion at time
TTL Bit
Clock
Digital Signal
Processor IC
DSP101
XCLK
±2.75V
Analog Input
2
VIN
SOUT
SYNC
SSF
CONV
DSP PROCESSOR
DSP32C, DSP16
DSP56001
DSP56001
TMS320C25/C30
ADSP2101/2105
16
DATA IN
15
12
13
DATA OUT
11
SYNC
SYNC
SSF(2)
21
12
XCLK
CLKR
20
(1)
DSP201
SSF
(2)
9
SWL
(3)
10
15
Conversion Rate
Generator
SYNC FORMAT
SERIAL I/O WORD
Active Low
Active High
Active High
Active High
Active High
16
24
16
16
16
Bits
Bits
Bits
Bits
Bits
SSF(2)
SWL(3)
LOW
HIGH
HIGH
HIGH
HIGH
HIGH
LOW
HIGH
HIGH
HIGH
XCLK
SIN
VOUT
21
±3V Analog Output
SYNC
SSF
SWL
CONV
(1) See Texas Instruments
DSP201/DSP202 product data
sheet for full description of this
DAC.
FIGURE 11. Analog Input and Analog Output System.
DSP101, 102
SBAS003A
17
DSP101 shift register (discussed in another section of this
data sheet.)
ance of the multiplexer. This unity-gain buffer minimizes
distortion, taking full advantage of the resolution and bandwidth of the DSP101.
Figure 10 was developed and tested using a Texas Instruments ZPB34 DSP board, which contains an AT&T DSP32C,
so that the SYNC output is programmed to be active LOW.
The circuit needs to be modified for DSP processors from
ADI, TI, and Motorola, which use active HIGH Sync pulses.
For these processors, tie SSF (pin 12) on the DSP101 HIGH,
and use a 74HC04 hex inverter to invert the Sync signal to
the 74HC574 and 74HC166.
The 74HC574D register delays the multiplexer address data
by one conversion before appending the channel data to the
serial conversion results from the DSP101. This attaches the
channel address to the correct conversion results. Since the
channel scanning shown in Figure 10 is sequential, this
delay latch could be left out and software could recognize
that the time (t) conversion results have the MUX address
from the time (t-1) conversion appended. However, for
systems using non-sequential scan lists, this delay latch is
essential to maintain the conversion data and channel address integrity.
The same basic circuit can be duplicated to drive two
channels in a DSP102, or can be easily modified for more or
less than eight channels of analog input.
The 74HC166 synchronous loading shift register loads the
channel address tag data into the shift register on the rising
edge of the bit clock, in conjunction with the Sync output of
the DSP101. The channel address tag data is then clocked
into the DSP101 Tag input (pin 18) by the bit clock, while
the conversion data is clocked out the other end of the
USING DSP101 AND DSP102 WITH
TEXAS INSTRUMENTS DSP ICS
Figures 11 thru 17 show various ways to use the DSP101
and DSP102 with DSP ICs from the Texas Instruments
TMS320Cxx series. For simplicity, all of these circuits are
TTL Bit
Clock
DSP102
TMS320C30
XCLK
SYNC
±2.75V Analog Input
Channel A
±2.75V Analog Input
Channel B
2
25
VINA
SOUTA
VINB
SOUTB
CASC
SSF
CONV
16
CLKR
15
FSR-0
FSR-1
DR-0
20
17
DR-1
22
12
+5V
21
Conversion Rate
Generator
FIGURE 12. Using DSP102 with TMS320C30.
TTL Bit
Clock
DSP102
XCLK
SYNC
±2.75V Analog Input
Channel A
±2.75V Analog Input
Channel B
2
25
VINA
VINB
SOUTA
SOUTB
CASC
NOTE: Serial port 0 programmed
for 32-bit data.
SSF
CONV
TMS320C30
16
CLKR -0
15
FSR-0
20
17
22
12
DR-0
NC
+5V
+5V
21
Conversion Rate
Generator
FIGURE 13. Using DSP102 with TMS320C30 in Cascade Mode.
18
DSP101, 102
SBAS003A
based on using the TME320Cxx in the mode where SSF
(Select Synch Format, pin 12) is tied HIGH, so that there is
an active High synchronization pulse generated by the
DSP101 or DSP102 after receiving a convert command. The
synchronization pulse can be changed to active Low simply
by making SSF LOW, where appropriate, without changing
the basic operation of the A/Ds.
In all cases, the DSP101 and DSP102 will transmit data
MSB-first, and the TMS320Cxx needs to be programmed
for this.
Figure 11 shows a circuit for using the TMS320C25 or
TMS320C30 in a complete analog input and analog output
system using the DSP101 along with the Texas Instruments
DSP201 D/A.
TTL Bit
Clock
DSP102
XCLK
±2.75V Analog Input
Channel A
2
±2.75V Analog Input 25
Channel B
SOUTA
VINA
VINB
SOUTB
SYNC
SSF
CASC
DSP202 (3)
TMS320C30
16
CLKR-0
CLKR-1
20
DR-0
17
12
13
DX-0
DR-1
15
12
CLKX-0
CLKX-1
14
DX-1
11
FSX-0
FSX-1
FSR-0
FSR-1
+5V
+5V
22
+5V
9
10
16
CONV
21
15
Conversion Rate
Generator (1)
XCLK
SINA
SINB
SYNC
VOUTA
VOUTB
21
±3V Analog Output
Channel A
5
±3V Analog Output
Channel B
SSF
SWL
CASC
CONV
NOTES: (1) Sample rate on DSP102 and DSP202 may differ. (2) Analog Devices ADSP2101 may be used. SPORT1 and SPORT2
are used for serial MSB first communication. (3) See Burr-Brown DSP201/DSP202 product data sheet for full description of this DAC.
FIGURE 14. Two-Channel Analog Input and Output System with TMS320C30.
TTL Bit
Clock
DSP102
XCLK
SOUTA
±2.75V Analog Input
Channel A
2
±2.75V Analog Input 25
Channel B
VINA
SOUTB
VINB
SYNC
SSF
CASC
DSP202 (4)
TMS320C30
16
CLKR-0
20
17
DR-0
22
13
DX-0
14
NC
15
12
12
CLKX-0
FSR-0
11
FSX-0
+5V
+5V
+5V
+5V
+5V
CONV
21
Conversion Rate
Generator (2)
9
10
16
15
XCLK
SINA
SINB
VOUTA
SYNC
VOUTB
21
±3V Analog Output
Channel A
5
±3V Analog Output
Channel B
SSF
SWL
CASC
CONV
NOTES: (1) Program TMS320C30 for 32-bit mode. (2) Sample rate on DSP102 and DSP202 may differ. (3) DSP32C may be used in this mode.
(4) See Burr-Brown DSP201/202 product data sheet for full description of this DAC.
FIGURE 15. Two-Channel Analog Input and Output System with TMS320C30 in Cascade Mode.
DSP101, 102
SBAS003A
19
USING TMS320C31 TO GENERATE
ALL CONTROL SIGNALS
Figure 17 shows a circuit for using the TMS320C31 with a
DSP102 and a Texas Instruments DSP202 D/A to provide a
two channel analog I/O system. The flexibility of the
TMS320C31 allows it to generate the data transfer clock
(XCLK) and the Convert Command, minimizing additional
circuitry and synchronizing the timing signals to the
processor’s master clock. In this circuit, the DSP102 and
DSP202 are used in their Cascade modes, transmitting and
receiving two channels of data in a single 32-bit word. (See
the Cascade Mode section above.)
Table II shows how to set up the circuit in Figure 17 for a
44.1kHz conversion rate for both channels of the DSP102
A/D and both channels of the DSP202 D/A. Both inputs and
outputs will be simultaneously converted.
TTL Bit
Clock
DSP101
XCLK
SYNC
2
±2.75V Analog Input
VIN
SOUT
SSF
CONV
TMS320C25
16
XCLK
15
FSX
20
TXD
12
+5V
21
Conversion Rate
Generator
NOTES: (1) TMS320C25 FSR external, 16-bit data.
FIGURE 16. Using DSP101 with TMS320C25.
DSP102
±2.75V Analog Input
Channel A
XCLK
VINA
CLKR0
DR0
SOUTA
SOUTB
±2.75V Analog Input
Channel B
VINB
CLKX0
XCLK
DX0
SINA
SINB
FSX0
SYNC
NC
FSR0
SYNC
TCLK0
OSC2
DSP202
TMS3200C31
SSF
+5V
+5V
SSF
+5V
SWL
+5V
CASC
VOUTA
±3V Analog Output
Channel A
VOUTB
±3V Analog Output
Channel B
OSC1
1MΩ
CASC
+5V
CONV
CONV
12.288MHz
10pF
10pF
FIGURE 17. Two Channel Analog I/O Using TMS320C31.
SERIAL PORT
Port Global Control Register
FSX/DX/CLKX Port Control Register
FSR/DR/CLKR Port Control Register
Receive/Transmit Timer Control Register
0x0EBC040
0x00000111
0x00000111
0x0000000F
TIMER
Timer Global Control Register
Timer Period Register
0x000002C1
0x000000B5
NOTE: Assumes TMS320C31 has 32MHz Master Clock.
TABLE II. TMS320C31 Register Settings for 44.1kHz Conversion Rate in Figure 17.
20
DSP101, 102
SBAS003A
USING DSP101 AND DSP102
WITH MOTOROLA DSP ICS
Figure 18 shows how to use the DSP101 with a Motorola
DSP56001. Using the DSP102 requires using two
DSP56001s. The DSP56001 needs to be programmed to
receive data MSB-first with SYNC in the Bit Mode.
DSP102 with the DSP16 and DSP32C in different modes.
The AT&T processors need to be programmed to accept
data MSB-first, and the DSP101 or DSP102 needs to have
SSF (pin 12) tied LOW, so that an appropriate active Low
synchronization pulse will be transmitted by the A/D after a
convert command is received.
SSF (pin 12) needs to be tied HIGH for using either the
DSP101 or the DSP102 with DSP56001s. This will cause
the DSP101 or DSP102 to transmit an appropriate active
High synchronization pulse on SYNC (pin 15) after a convert command is received by the A/D. Timing is shown in
Figure 1.
Figures 19 and 20 show the DSP32C and DSP16 respectively used with the DSP101 to handle a single analog input
channel.
USING DSP101 AND DSP102 WITH AT&T DSP ICS
Figures 11, 19, 20, and 21 show how to use the DSP101 and
Figure 21 shows how to transmit to a single DSP32C
conversion results from both DSP102 channels in a single
32-bit word, using the Cascade mode on the A/D.
Figure 11 indicates how to build a complete analog input and
analog output system using a DSP32C or DSP16 with a
DSP101 and a Texas Instruments DSP201 D/A.
TTL Bit
Clock
DSP56001
DSP101
XCLK
SYNC
±2.75V Analog Input
2
SOUT
VIN
SSF
CONV
16
SCK
15
FSR (SC2)
20
12
SRD
+5V
21
Conversion Rate
Generator
NOTES: (1) DSP56001 programmed for MSB bit first data. (2) DSP56001 data may be either 16-bit or 24-bit.
FIGURE 18. Using DSP101 with DSP56001.
TTL Bit
Clock
DSP32C
DSP101
XCLK
SYNC
±2.75V Analog Input
2
VIN
SOUT
SSF
CONV
16
15
20
ICK
ILD
DATA IN
12
21
Conversion Rate
Generator
NOTE: (1) DSP32C programmed for MSB bit first 16-bit data.
FIGURE 19. Using DSP101 with DSP32C.
DSP101, 102
SBAS003A
21
USING DSP101 AND DSP102 WITH ADI DSP ICS
When using the DSP101 or DSP102 with the fixed-point
ADSP21xx series, the processors need to be programmed to
receive data MSB-first.
The same basic circuit can be used to connect a DSP101 to
the ADSP2101.
Figure 11 indicates how to build a complete analog I/O
system using either the ADSP2101 or the ADSP2105 with a
DSP101 and a Texas Instruments DSP201 D/A.
Figure 22 shows how to use the DSP102 with an ADSP2101
to provide a two-channel simultaneous sampling system.
The two serial ports on the ADSP2101 can also be used with
the DSP102 and the Texas Instruments DSP202 D/A to
make two complete analog I/O channels, as indicated in
footnote 2 of Figure 14.
Figure 23 shows the connections required to generate an
analog input channel using an ADSP2105 with the DSP101.
TTL Bit
Clock
DSP101
XCLK
SOUT
2
±2.75V Analog Input
DSP16
16
ICK
20
DATA IN
VIN
SYNC
SSF
CONV
15
ILD
12
21
Conversion Rate
Generator
NOTE: DSP16 programmed for MSB bit first, 16-bit data.
FIGURE 20. Using DSP101 with DSP16.
TTL Bit
Clock
DSP32C
DSP102
XCLK
SYNC
±2.75V Analog Input
Channel A
±2.75V Analog Input
Channel B
2
25
VINA
VINB
SOUTA
SOUTB
CASC
SSF
CONV
16
ICK
15
ILD
20
17
22
DATA IN
NC
+5V
12
21
Conversion Rate
Generator
NOTES: (1) DSP32C programmed 32-bit data MSB bit first. (2) Data format is Channel A, 16 bits, MSB first, then Channel B.
FIGURE 21. Using DSP102 with DSP32C in Cascade Mode.
22
DSP101, 102
SBAS003A
TTL Bit
Clock
DSP102
XCLK
SYNC
±2.75V Analog Input
Channel A
±2.75V Analog Input
Channel B
2
25
VINA
SOUTA
VINB
SOUTB
CASC
SSF
CONV
ADSP-2101
16
SCLK-0
SCLK-1
RFS-0
RFS-1
DR-0
15
20
17
DR-1
22
12
+5V
21
Conversion Rate
Generator
FIGURE 22. Using DSP102 with ADSP-2101.
TTL Bit
Clock
DSP101
XCLK
SOUT
±2.75V Analog Input
2
ADSP-2105
16
SCLK
20
DR
15
RFS
VIN
SYNC
SSF
CONV
12
21
+5V
Conversion Rate
Generator
FIGURE 23. Using DSP101 with ADSP-2105.
DEM-DSP102/202 EVALUATION BOARD
An evaluation fixture, the DEM-DSP102/202, is available to
simplify evaluation of the DSP101 and DSP102, and the
companion digital-to-analog converters, the single DSP201
and dual DSP202. The DEM-DSP102/202 comes complete
with a socketed DSP102 and DSP202, a breadboard area,
TTL I/O headers and differential line drivers for data trans-
DSP101, 102
SBAS003A
fer options, a complete clocking circuit for the conversion
clock and bit clock, and analog filter modules. The board
makes it easy to go from design concept to working prototype of a DSP-based system, offering two complete analog
I/O channels.
Contact your local Texas Instruments representative for a
full data sheet on the DEM-DSP102/202.
23
PACKAGE OPTION ADDENDUM
www.ti.com
30-Mar-2005
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
Lead/Ball Finish
MSL Peak Temp (3)
DSP101JP
OBSOLETE
PDIP
NTD
28
TBD
Call TI
Call TI
DSP101KP
OBSOLETE
PDIP
NTD
28
TBD
Call TI
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DSP102JP
OBSOLETE
PDIP
NTD
28
TBD
Call TI
Call TI
DSP102JP-1
OBSOLETE
PDIP
NTD
28
TBD
Call TI
Call TI
DSP102KP
OBSOLETE
PDIP
NTD
28
TBD
Call TI
Call TI
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS) or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
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Addendum-Page 1
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