a
FEATURES
Fast 12-Bit ADC with 5.9 ms Conversion Time
Eight Single-Ended Analog Input Channels
Selection of Input Ranges:
610 V for AD7890-10
0 V to 14.096 V for AD7890-4
0 V to 12.5 V for AD7890-2
Allows Separate Access to Multiplexer and ADC
On-Chip Track/Hold Amplifier
On-Chip Reference
High Speed, Flexible, Serial Interface
Single Supply, Low Power Operation (50 mW max)
Power-Down Mode (75 mW typ)
LC2MOS 8-Channel, 12-Bit
Serial, Data Acquisition System
AD7890
FUNCTIONAL BLOCK DIAGRAM
MUX SHA REF OUT/
OUT IN
REF IN
VDD
VIN1
SIGNAL
SCALING*
VIN2
SIGNAL
SCALING*
VIN3
SIGNAL
SCALING*
VIN4
SIGNAL
SCALING*
VIN5
SIGNAL
SCALING*
VIN6
SIGNAL
SCALING*
VIN7
SIGNAL
SCALING*
VIN8
SIGNAL
SCALING*
2kΩ
+2.5V
REFERENCE
AD7890
CEXT
M
U
X
CONVST
12-BIT
ADC
TRACKHOLD
OUTPUT/CONTROL REGISTER
GENERAL DESCRIPTION
The AD7890 is an eight-channel 12-bit data acquisition system.
The part contains an input multiplexer, an on-chip track/hold
amplifier, a high-speed 12-bit ADC, a +2.5 V reference and a high
speed, serial interface. The part operates from a single +5 V supply
and accepts an analog input range of ±10 V (AD7890-10), 0 V to
+4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2).
The multiplexer on the part is independently accessible. This
allows the user to insert an antialiasing filter or signal conditioning, if required, between the multiplexer and the ADC. This
means that one antialiasing filter can be used for all eight channels. Connection of an external capacitor allows the user to
adjust the time given to the multiplexer settling to include any
external delays in the filter or signal conditioning circuitry.
Output data from the AD7890 is provided via a high speed bidirectional serial interface port. The part contains an on-chip control register, allowing control of channel selection, conversion
start and power-down via the serial port. Versatile, high speed
logic ensures easy interfacing to serial ports on microcontrollers
and digital signal processors.
In addition to the traditional dc accuracy specifications such as
linearity, full-scale and offset errors, the AD7890 is also specified for dynamic performance parameters including harmonic
distortion and signal-to-noise ratio.
CLOCK
AGND AGND DGND CLK
IN
SCLK TFS RFS DATA DATA SMODE
IN
OUT
*NO SCALING ON AD7890-2
Power dissipation in normal mode is low at 30 mW typ and the
part can be placed in a standby (power-down) mode if it is not
required to perform conversions. The AD7890 is fabricated in
Analog Devices’ Linear Compatible CMOS (LC2MOS) process,
a mixed technology process that combines precision bipolar circuits with low power CMOS logic. The part is available in a
24-pin, 0.3" wide, plastic or hermetic dual-in-line package or in
a 24-pin small outline package (SOIC).
PRODUCT HIGHLIGHTS
1. Complete 12-Bit Data Acquisition System on a Chip
The AD7890 is a complete monolithic ADC combining an
eight-channel multiplexer, 12-bit ADC, +2.5 V reference and
a track/hold amplifier on a single chip.
2. Separate Access to Multiplexer and ADC
The AD7890 provides access to the output of the multiplexer
allowing one antialiasing filter for eight channels—a considerable saving over the eight antialiasing filters required if the
multiplexer was internally connected to the ADC.
3. High Speed Serial Interface
The part provides a high speed serial interface for easy
connection to serial ports of microcontrollers and DSP
processors.
REV. A
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
© Analog Devices, Inc., 1996
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
V, AGND = DGND = 0 V, REF IN = +2.5 V, f
AD7890–SPECIFICATIONS (VMUX=OUT+5connect
to SHA IN. All specifications T to T
DD
CLK IN
MIN
Parameter
DYNAMIC PERFORMANCE
Signal to (Noise + Distortion) Ratio2
Total Harmonic Distortion (THD)2
Peak Harmonic or Spurious Noise2
Intermodulation Distortion
2nd Order Terms
3rd Order Terms
Channel-to-Channel Isolation2
DC ACCURACY
Resolution
Minimum Resolution for Which
No Missing Codes Are Guaranteed
Relative Accuracy2
Differential Nonlinearity2
Positive Full-Scale Error2
Full-Scale Error Match4
AD7890-2, AD7890-4
Unipolar Offset Error2
Unipolar Offset Error Match
AD7890-10 Only
Negative Full-Scale Error2
Bipolar Zero Error2
Bipolar Zero Error Match
ANALOG INPUTS
AD7890-10
Input Voltage Range
Input Resistance
AD7890-4
Input Voltage Range
Input Resistance
AD7890-2
Input Voltage Range
Input Current
MUX OUT OUTPUT
Output Voltage Range
Output Resistance
(AD7890-10, AD7890-4)
(AD7890-2)
= 2.5 MHz external,
unless otherwise noted.)
MAX
A Versions1
B Versions
S Version
Units
Test Conditions/Comments
70
–78
–79
70
–78
–79
70
–78
–79
dB min
dB max
dB max
Using External CONVST. Any Channel
fIN = 10 kHz Sine Wave, fSAMPLE = 100 kHz3
fIN = 10 kHz Sine Wave, fSAMPLE = 100 kHz3
fIN = 10 kHz Sine Wave, fSAMPLE = 100 kHz3
fa = 9 kHz, fb = 9.5 kHz, fSAMPLE = 100 kHz3
–80
–80
–80
–80
–80
–80
–80
–80
–80
dB typ
dB typ
dB max
12
12
12
Bits
12
±1
±1
± 2.5
2
12
± 0.5
±1
± 2.5
2
12
±1
±1
± 2.5
2
Bits
LSB max
LSB max
LSB max
LSB max
±2
2
±2
2
±2
2
LSB max
LSB max
±2
±4
2
±2
±4
2
±2
±4
2
LSB max
LSB max
LSB max
± 10
20
± 10
20
± 10
20
Volts
kΩ min
0 to +4.096
11
0 to +4.096
11
0 to +4.096
11
Volts
kΩ min
0 to +2.5
50
0 to +2.5
50
0 to +2.5
200
Volts
nA max
fIN = 1 kHz Sine Wave
0 to +2.5
0 to +2.5
0 to +2.5
Volts
3/5
2
3/5
2
3/5
2
kΩ min/kΩ max
kΩ max
SHA IN INPUT
Input Voltage Range
Input Current
0 to +2.5
± 50
0 to +2.5
± 50
0 to +2.5
± 50
Volts
nA max
REFERENCE OUTPUT/INPUT
REF IN Input Voltage Range
Input Impedance
Input Capacitance5
REF OUT Output Voltage
REF OUT Error @ +25°C
TMIN to TMAX
REF OUT Temperature Coefficient
REF OUT Output Impedance
2.375/2.625
1.6
10
2.5
± 10
± 20
25
2
2.375/2.625
1.6
10
2.5
± 10
± 20
25
2
2.375/2.625
1.6
10
2.5
± 10
± 25
25
2
V min/V max
kΩ min
pF max
V nom
mV max
mV max
ppm/°C typ
kΩ nom
2.5 V ± 5%
Resistor Connected to Internal Reference Node
LOGIC INPUTS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Current, IIN
Input Capacitance, CIN5
2.4
0.8
± 10
10
2.4
0.8
± 10
10
2.4
0.8
± 10
10
V min
V max
µA max
pF max
VDD = 5 V ± 5%
VDD = 5 V ± 5%
VIN = 0 V to VDD
–2–
Assuming VIN Is Driven from Low Impedance
REV. 0
AD7890
Parameter
LOGIC OUTPUTS
Output High Voltage, VOH
Output Low Voltage, VOL
Serial Data Output Coding
AD7890-10
AD7890-4
AD7890-2
CONVERSION RATE
Conversion Time
Track/Hold Acquisition Time2, 5
POWER REQUIREMENTS
VDD
IDD (Normal Mode)
IDD (Standby Mode)6 @ +25°C
Power Dissipation
Normal Mode
Standby Mode @ +25°C
A Versions1
B Versions
S Version
Units
Test Conditions/Comments
4.0
0.4
4.0
0.4
4.0
0.4
V min
V max
ISOURCE = 200 µA
ISINK = 1.6 mA
fCLK IN = 2.5 MHz, MUX OUT
Connected to SHA IN
2s Complement
Straight (Natural) Binary
Straight (Natural) Binary
5.9
5.9
5.9
µs max
2
2
2
µs max
+5
10
15
+5
10
15
+5
10
15
V nom
mA max
µA typ
± 5% for Specified Performance
Logic Inputs = 0 V or VDD
Logic Inputs = 0 V or VDD
50
75
50
75
50
75
mW max
µW typ
Typically 30 mW
NOTES
1
Temperature ranges are as follows: A, B Versions: –40°C to –85°C; S Version: –55°C to +125°C.
2
See Terminology.
3
This sample rate is only achievable when tiling the part in external clocking mode.
4
Full-scale error match applies to positive full scale for the AD7890-2 and AD7890-4. It applies to both positive and negative full scale for the AD7890-10.
5
Sample tested @ +25°C to ensure compliance.
6
Analog inputs on AD7890-10 must be at 0 V to achieve correct power-down current.
Specifications subject to change without notice.
ABSOLUTE MAXIMUM RATINGS*
(TA = +25°C unless otherwise noted)
VDD to AGND . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +7 V
VDD to DGND . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +7 V
Analog Input Voltage to AGND
AD7890-10, AD7890-4 . . . . . . . . . . . . . . . . . . . . . . . ± 17 V
AD7890-2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . –5 V, +10 V
Reference Input Voltage to AGND . . . –0.3 V to VDD + 0.3 V
Digital Input Voltage to DGND . . . . . –0.3 V to VDD + 0.3 V
Digital Output Voltage to DGND . . . . –0.3 V to VDD + 0.3 V
Operating Temperature Range
Commercial (A, B Versions) . . . . . . . . . . . –40°C to +85°C
Extended (S Version) . . . . . . . . . . . . . . . . –55°C to +125°C
Storage Temperature Range . . . . . . . . . . . –65°C to +150°C
Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . +150°C
Plastic DIP Package, Power Dissipation . . . . . . . . . . 450 mW
θJA Thermal Impedance . . . . . . . . . . . . . . . . . . . . 105°C/W
Lead Temperature (Soldering, 10 sec) . . . . . . . . . . +260°C
Cerdip Package, Power Dissipation . . . . . . . . . . . . . . 450 mW
θJA Thermal Impedance . . . . . . . . . . . . . . . . . . . . . 70°C/W
Lead Temperature (Soldering, 10 sec) . . . . . . . . . . +300°C
SOIC Package, Power Dissipation . . . . . . . . . . . . . . . 450 mW
θJA Thermal Impedance . . . . . . . . . . . . . . . . . . . . . 75°C/W
Lead Temperature, Soldering
Vapor Phase (60 sec) . . . . . . . . . . . . . . . . . . . . . +215°C
Infrared (15 sec) . . . . . . . . . . . . . . . . . . . . . . . . . +220°C
*Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device. This is a stress rating only and functional
operation of the device at these or any other conditions above those listed in the
operational sections of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
ORDERING GUIDE
Model
Temperature
Range
Linearity
Error
Package
Option*
AD7890AN-2
AD7890BN-2
AD7890AR-2
AD7890BR-2
AD7890SQ-2
AD7890AN-4
AD7890BN-4
AD7890AR-4
AD7890BR-4
AD7890SQ-4
AD7890AN-10
AD7890BN-10
AD7890AR-10
AD7890BR-10
AD7890SQ-10
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–55°C to +125°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–55°C to +125°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–55°C to +125°C
± 1 LSB
± 1/2 LSB
± 1 LSB
± 1/2 LSB
± 1 LSB
± 1 LSB
± 1/2 LSB
± 1 LSB
± 1/2 LSB
± 1 LSB
± 1 LSB
± 1/2 LSB
± 1 LSB
± 1/2 LSB
± 1 LSB
N-24
N-24
R-24
R-24
Q-24
N-24
N-24
R-24
R-24
Q-24
N-24
N-24
R-24
R-24
Q-24
NOTE
*N = Plastic DIP; Q = Cerdip; R = SOIC.
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD7890 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
REV. A
–3–
WARNING!
ESD SENSITIVE DEVICE
AD7890
(VDD = +5 V 6 5%, AGND = DGND = 0 V, REF IN = +2.5 V, fCLK IN = 2.5 MHz external, MUX OUT
TIMING CHARACTERISTICS1, 2 connected to SHA IN.)
Parameter
fCLKIN3
tCLK IN LO
tCLK IN HI
tr4
tf4
tCONVERT
tCST
Self-Clocking Mode
t1
t2 5
t3
t4
t5 5
t6
t7 6
t8
t9
t10
t11
t12
External-Clocking Mode
t13
t145
t15
t16
t175
t18
t196
t19A6
t20
t21
t22
t23
Limit at TMIN, TMAX
(A, B, S Versions)
Units
Conditions/Comments
100
2.5
0.3 × tCLK IN
0 3 × tCLK IN
25
25
5.9
100
kHz min
MHz max
ns min
ns min
ns max
ns max
µs max
ns min
Master Clock Frequency. For Specified Performance
tCLK IN HI + 50
25
tCLK IN HI
tCLK IN LO
20
40
50
0
tCLK IN + 50
0
20
10
20
ns max
ns max
ns nom
ns nom
ns max
ns max
ns max
ns min
ns max
ns min
ns min
ns min
ns min
RFS Low to SCLK Falling Edge
RFS Low to Data Valid Delay
SCLK High Pulse Width
SCLK Low Pulse Width
SCLK Rising Edge to Data Valid Delay
SCLK Rising Edge to RFS Delay
Bus Relinquish Time after Rising Edge of SCLK
TFS Low to SCLK Falling Edge
20
40
50
50
35
20
50
90
20
10
15
40
ns min
ns max
ns min
ns min
ns max
ns min
ns max
ns max
ns min
ns min
ns min
ns min
RFS Low to SCLK Falling Edge Setup Time
RFS Low to Data Valid Delay
SCLK High Pulse Width
SCLK Low Pulse Width
SCLK Rising Edge to Data Valid Delay
RFS to SCLK Falling Edge Hold Time
Bus Relinquish Time after Rising Edge of RFS
Bus Relinquish Time after Rising Edge of SCLK
TFS Low to SCLK Falling Edge Setup Time
Data Valid to SCLK Falling Edge Setup Time
Data Valid to SCLK Falling Edge Hold Time
TFS to SCLK Falling Edge Hold Time
Master Clock Input Low Time
Master Clock Input High Time
Digital Output Rise Time. Typically 10 ns
Digital Output Fall Time. Typically 10 ns
Conversion Time
CONVST Pulse Width
Data Valid to TFS Falling Edge Setup Time (A2 Address Bit)
Data Valid to SCLK Falling Edge Setup Time
Data Valid to SCLK Falling Edge Hold Time
TFS to SCLK Falling Edge Hold Time
NOTES
1
Sample tested at –25°C to ensure compliance. All input signals are specified with tr = tf = 5 ns (10% to 90% of 5 V) and timed from a voltage level of 1.6 V.
2
See Figures 8 to 11.
3
The AD7890 is production tested with f CLK IN at 2.5 MHz. It is guaranteed by characterization to operate at 100 kHz.
4
Specified using 10% and 90% points on waveform of interest.
5
These numbers are measured with the load circuit of Figure I and defined as the time required for the output to cross 0.8 V or 2.4 V.
6
These numbers are derived from the measured time taken by the data output to change 0.5 V when loaded with the circuit of Figure 1. The measured number is then
extrapolated back to remove effects of charging or discharging the 50 pF capacitor. This means that the times quoted in the timing characteristics are the true bus relinquish times of the part and as such are independent of external bus loading capacitances.
1.6mA
TO OUTPUT
PIN
+2.1V
50pF
200µA
Figure 1. Load Circuit for Access Time and Bus Relinquish Time
–4–
REV. A
AD7890
PIN FUNCTION DESCRIPTION
Pin
Mnemonic
Description
1
AGND
Analog Ground. Ground reference for track/hold, comparator and DAC.
2
SMODE
Control Input. Determines whether the part operates in its External Clocking (slave) or Self-Clocking
(master) serial mode. With SMODE at a logic low, the part is in its Self-Clocking serial mode with
RFS and SCLK as outputs. This Self-Clocking mode is useful for connection to shift registers or to
serial ports of DSP processors. With SMODE at a logic high, the part is in its External Clocking
serial mode with SCLK and RFS as inputs. This External Clocking mode is useful for connection to
the serial port of microcontrollers such as the 8XC51 and the 68HCXX and for connection to the
serial ports of DSP processors.
3
DGND
Digital Ground. Ground reference for digital circuitry.
4
CEXT
External Capacitor. An external capacitor is connected to this pin to determine the length of the
internal pulse (see CONVST input and Control Register section). Larger capacitances on this pin
extend the pulse to allow for settling time delays through an external antialiasing filter or signal
conditioning circuitry.
5
CONVST
Convert Start. Edge-triggered logic input. A low to high transition on this input puts the track/hold
into hold and initiates conversion provided that the internal pulse has timed out (see Control
Register section). If the internal pulse is active when the CONVST goes high, the track/hold will not
go into hold until the pulse times out. If the internal pulse has timed out when CONVST goes high,
the rising edge of CONVST drives the track/hold into hold and initiates conversion.
6
CLK IN
Clock Input. An external TTL-compatible clock is applied to this input pin to provide the clock
source for the conversion sequence. In the Self-Clocking serial mode, the SCLK output is derived
from this CLK IN pin.
7
SCLK
Serial Clock Input. In the External Clocking (slave) mode (see Serial Interface section) this is an
externally applied serial clock which is used to load serial data to the control register and to access
data from the output register. In the Self-Clocking (master) mode, the internal serial clock, which is
derived from the clock input (CLK IN), appears on this pin. Once again, it is used to load serial data
to the control register and to access data from the output register.
8
TFS
Transmit Frame Synchronization Pulse. Active low logic input with serial data expected after the
falling edge of this signal.
9
RFS
Receive Frame Synchronization Pulse. In the External Clocking mode, this pin is an active low logic
input with RFS provided externally as a strobe or framing pulse to access serial data from the output
register. In the Self-Clocking mode, it is an active low output which is internally generated and
provides a strobe or framing pulse for serial data from the output register. For applications which
require that data be transmitted and received at the same time, RFS and TFS should be connected
together.
10
DATA OUT
Serial Data Output. Sixteen bits of serial data are provided with one leading zero, preceding the three
address bits of the Control register and the 12 bits of conversion data. Serial data is valid on the
falling edge of SCLK for sixteen edges after RFS goes low. Output coding from the ADC is 2s
complement for the AD7890-10 and straight binary for the AD7890-4 and AD7890-2.
11
DATA IN
Serial Data Input. Serial data to be loaded to the control register is provided at this input. The first
five bits of serial data are loaded to the control register on the first five falling edges of SCLK after
TFS goes low. Serial data on subsequent SCLK edges is ignored while TFS remains low.
12
VDD
Positive supply voltage, +5 V ± 5%.
13
MUX OUT
Multiplexer Output. The output of the multiplexer appears at this pin. The output voltage range
from this output is 0 V to +2.5 V for the nominal analog input range to the selected channel. The
output impedance of this output is nominally 3.5 kΩ. If no external antialiasing filter is required,
MUX OUT should be connected to SHA IN.
14
SHA IN
Track/Hold Input. The input to the on-chip track/hold is applied to this pin. It is a high impedance
input and the input voltage range is 0 V to +2.5 V.
15
AGND
Analog Ground. Ground reference for track/hold, comparator and DAC.
16
VIN1
Analog Input Channel 1. Single-ended analog input. The analog input range on is ± 10 V
(AD7890-10), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed break-before-make operation.
REV. A
–5–
AD7890
Pin
Mnemonic
Description
17
VIN2
Analog Input Channel 2. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
18
VIN3
Analog Input Channel 3. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
19
VIN4
Analog Input Channel 4. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
20
VIN5
Analog Input Channel 5. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
21
VIN6
Analog Input Channel 6. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
22
VIN7
Analog Input Channel 7. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
23
VIN8
Analog Input Channel 8. Single-ended analog input. The analog input range on is ± 10 V (AD789010), 0 V to +4.096 V (AD7890-4) and 0 V to +2.5 V (AD7890-2). The channel to be converted is
selected using the A0, A1 and A2 bits in the control register. The multiplexer has guaranteed
break-before-make operation.
24
REF OUT/REF IN
Voltage Reference Output/Input. The part can be used with either its own internal reference or with
an external reference source. The on-chip +2.5 V reference voltage is provided at this pin. When
using this internal reference as the reference source for the part, REF OUT should decoupled to
AGND with a 0.1 µF disc ceramic capacitor. The output impedance of this reference source is typically 2 kΩ. When using an external reference source as the reference voltage for the part, the reference source should be connected to this pin. This overdrives the internal reference and provides the
reference source for the part. The REF IN input is buffered on-chip. The nominal reference voltage
for correct operation of the AD7890 is +2.5 V.
PIN CONFIGURATION
DIP and SOIC
AGND
1
24 REF OUT/REF IN
SMODE
2
23 VIN8
DGND
3
22 VIN7
CEXT
4
21 VIN6
CONVST
5
CLK IN
6
SCLK
7
TFS
8
RFS
9
20 VIN5
AD7890
TOP VIEW
(Not to Scale) 18
VIN4
VIN3
17 VIN2
16
DATA OUT 10
DATA IN
19
VIN1
15 AGND
11
14
VDD 12
SHA IN
13 MUX OUT
–6–
REV. A
AD7890
TERMINOLOGY
Signal to (Noise + Distortion) Ratio
This is the measured ratio of signal to (noise + distortion) at the
output of the A/D converter. The signal is the rms amplitude of
the fundamental. Noise is the rms sum of all nonfundamental
signals up to half the sampling frequency (fS/2), excluding dc.
The ratio is dependent upon the number of quantization levels
in the digitization process; the more levels, the smaller the quantization noise. The theoretical signal to (noise + distortion) ratio
for an ideal N-bit converter with a sine wave input is given by:
Signal to (Noise + Distortion) = (6.02N + 1.76) dB
Channel-to-Channel Isolation
Channel-to-channel isolation is a measure of the level of
crosstalk between channels. It is measured by applying a fullscale 1 kHz signal to any one of the other seven inputs and
determining how much that signal is attenuated in the channel of interest. The figure given is the worst case across all
eight channels.
Relative Accuracy
Relative accuracy or endpoint nonlinearity is the maximum
deviation from a straight line passing through the endpoints of
the ADC transfer function.
Thus for a 12-bit converter, this is 74 dB.
Differential Nonlinearity
Total Harmonic Distortion
This is the difference between the measured and the ideal 1 LSB
change between any two adjacent codes in the ADC.
Total harmonic distortion (THD) is the ratio of the rms sum of
harmonics to the fundamental. For the AD7890, it is defined as:
THD (dB ) = 20 log
V 22 + V 32 + V 42 + V 52 + V 62
V1
Positive Full-Scale Error (AD7890-10)
This is the deviation of the last code transition (01 . . . 110 to
01 . . . 111) from the ideal (4 × REF IN – 1 LSB) after the Bipolar
Zero Error has been adjusted out.
Positive Full-Scale Error (AD7890-4)
where V1 is the rms amplitude of the fundamental and V2, V3,
V4, V5 and V6 are the rms amplitudes of the second through the
sixth harmonics.
Peak Harmonic or Spurious Noise
Peak harmonic or spurious noise is defined as the ratio of the
rms value of the next largest component in the ADC output
spectrum (up to fS/2 and excluding dc) to the rms value of the
fundamental. Normally, the value of this specification is determined by the largest harmonic in the spectrum, but for parts
where the harmonics are buried in the noise floor, it will be a
noise peak.
Intermodulation Distortion
With inputs consisting of sine waves at two frequencies, fa and
fb, any active device with nonlinearities will create distortion
products at sum and difference frequencies of mfa ± nfb where
m, n = 0, 1, 2, 3, etc. Intermodulation terms are those for which
neither m nor n are equal to zero. For example, the second order
terms include (fa + fb) and (fa – fb), while the third order terms
include (2fa + fb), (2fa – fb), (fa + 2fb) and (fa – 2fb).
The AD7890 is tested using the CCIF standard where two
input frequencies near the top end of the input bandwidth are
used. In this case, the second and third order terms are of different significance. The second order terms are usually distanced
in frequency from the original sine waves while the third order
terms are usually at a frequency close to the input frequencies.
As a result, the second and third order terms are specified separately. The calculation of the intermodulation distortion is as
per the THD specification where it is the ratio of the rms sum of
the individual distortion products to the rms amplitude of the
fundamental expressed in dBs.
REV. A
This is the deviation of the last code transition (11 . . . 110 to
11 . . . 111) from the ideal (1.638 × REF IN – 1 LSB) after the
Unipolar Offset Error has been adjusted out.
Positive Full-Scale Error (AD7890-2)
This is the deviation of the last code transition (11 . . . 110 to
11 . . . 111) from the ideal (REF IN – 1 LSB) after the Unipolar
Offset Error has been adjusted out.
Bipolar Zero Error (AD7890-10)
This is the deviation of the midscale transition (all 0s to all 1s)
from the ideal 0 V (AGND).
Unipolar Offset Error (AD7890-2, AD7890-4)
This is the deviation of the first code transition (00 . . . 000 to
00 . . . 001) from the ideal 0 V (AGND).
Negative Full-Scale Error (AD7890-10)
This is the deviation of the first code transition (10 . . . 000 to
10 . . . 001) from the ideal (–4 × REF IN + 1 LSB) after Bipolar
Zero Error has been adjusted out.
Track/Hold Acquisition Time
Track/Hold acquisition time is the time required for the output
of the track/hold amplifier to reach its final value, within ±1/2 LSB,
after the end of conversion (the point at which the track/hold
returns to track mode). It also applies to situations where a
change in the selected input channel takes place or where there
is a step input change on the input voltage applied to the selected
VIN input of the AD7890. It means that the user must wait for
the duration of the track/hold acquisition time after the end of
conversion or after a channel change/step input change to VIN
before starting another conversion, to ensure that the part operates to specification.
–7–
AD7890
CONTROL REGISTER
CONVERTER DETAILS
The Control Register for the AD7890 contains 5 bits of information as described below. Six serial clock pulses must be provided to the part in order to write data to the Control Register
(seven if the write is required to put the part in Standby Mode).
If TFS returns high before six serial clock cycles then no data
transfer takes place to the Control Register and the write cycle
will have to be restarted to write the data to the Control Register. If, however, the CONV bit of the register (see below) is set
to a Logic 1, then a conversion will be initiated whenever a
Control Register write takes place regardless of how many serial
clock cycles the TFS remains low for. The default (power-on)
condition of all bits in the Control Register is 0.
The AD7890 is an eight-channel, 12-bit, single supply, serial
data acquisition system. It provides the user with signal scaling,
multiplexer, track/hold, reference, A/D converter and versatile
serial logic functions on a single chip. The signal scaling allows
the part to handle ± 10 V input signals (AD7890-10) and 0 V to
+4.096 V input signals (AD7890-4) while operating from a
single +5 V supply. The AD7890-2 contains no signal scaling
and accepts an analog input range of 0 V to +2.5 V. The part
operates from a +2.5 V reference which can be provided from
the part’s own internal reference or from an external reference
source.
MSB
A2
A1
A0
CONV
STBY
A2
Address Input. This input is the most significant
address input for multiplexer channel selection.
A1
Address Input. This is the 2nd most significant
address input for multiplexer channel selection.
A0
Address Input. Least significant address input for
multiplexer channel selection. When the address is
written to the control register, an internal pulse is
initiated, the pulse width of which is determined by
the value of capacitance on the CEXT pin. When this
pulse is active, it ensures the conversion process
cannot be activated. This allows for the multiplexer
settling time and track/hold acquisition time before
the track/hold goes into hold and conversion is
initiated. In applications where there is an antialiasing filter between MUX OUT and SHA IN, the
filter settling time can be taken into account before
the input at SHA IN is sampled. When the internal
pulse times out, the track/hold goes into hold and
conversion is initiated.
CONV
Conversion Start. Writing a 1 to this bit initiates a
conversion in a similar manner to the CONVST
input. Continuous conversion starts do not take place
when there is a 1 in this location. The internal pulse
and the conversion process are initiated after the
sixth serial clock cycle of the write operation if a 1 is
written to this bit. With a 1 in this bit, the hardware
conversion start i.e., the CONVST input, is
disabled. Writing a 0 to this bit enables the hardware CONVST input.
STBY
Unlike other single chip data acquisition solutions, the AD7890
provides the user with separate access to the multiplexer and the
A/D converter. This means that the flexibility of separate multiplexer and ADC solutions is not sacrificed with the one-chip
solution. With access to the multiplexer output, the user can
implement external signal conditioning between the multiplexer
and the track/hold. It means that one antialiasing filter can be
used on the output of the multiplexer to provide the antialiasing
function for all eight channels.
Conversion is initiated on the AD7890 either by pulsing the
CONVST input or by writing a Logic 1 to the CONV bit of the
Control Register. When using the hardware CONVST input, on
the rising edge of the CONVST signal, the on-chip track/hold
goes from track to hold mode and the conversion sequence is
started provided the internal pulse has timed out. This internal
pulse (which appears at the CEXT pin) is initiated whenever the
multiplexer address is loaded to the AD7890 Control Register.
This pulse goes from high to low when a serial write to the part
is initiated. It starts to discharge on the sixth falling clock edge
of SCLK in a serial write operation to the part. The track/hold
cannot go into hold and conversion cannot be initiated until the
CEXT pin has crossed its trigger point of 2.5 V. The discharge
time of the voltage on CEXT depends upon the value of capacitor
connected to the CEXT pin (see CEXT Functioning section). The
fact that the pulse is initiated every time a write to the control
register takes place means that the software conversion start and
track/hold signal is always delayed by the internal pulse.
The conversion clock for the part is generated from the clock
signal applied to the CLK IN pin of the part. Conversion time
for the AD7890 is 5.9 µs from the rising edge of the hardware
CONVST signal and the track/hold acquisition time is 2 µs. To
obtain optimum performance from the part, the data read operation or Control Register write operation should not occur during
the conversion or during 500 ns prior to the next conversion.
This allows the part to operate at throughput rates up to
117 kHz in the external clocking mode and achieve data sheet
specifications. The part can operate at slightly higher throughput rates (up to 127 kHz), again in external clocking mode with
degraded performance (see Timing and Control section). The
throughput rate for self-clocking mode is limited by the serial
clock rate to 78 kHz.
Standby Mode Input. Writing a 1 to this bit places
the device in its standby or power-down mode.
Writing a 0 to this bit places the device in its normal
operating mode. The part does not enter its standby
mode until the seventh falling edge of SCLK in a
write operation. Therefore, the part requires seven
serial clock pulses in its serial write operation if it is
required to put the part into standby.
All unused inputs should be connected to a voltage within the
nominal analog input range to avoid noise pickup. On the
AD7890-10, if any one of the input channels which are not being converted goes more negative than –12 V, it can interfere
with the conversion on the selected channel.
–8–
REV. A
AD7890
CIRCUIT DESCRIPTION
Analog Input Section
The AD7890 is offered as three part types, the AD7890-10
which handles a ± 10 V input voltage range, the AD7890-4
which handles a 0 V to +4.096 V input range and the AD7890-2
which handles a 0 V to +2.5 V input voltage range.
tions occur on successive integer LSB values (i.e., 1 LSB,
2 LSBs, 3 LSBs . . . ). Output coding is straight (natural)
binary with 1 LSB = FS/4096 = 4.096 V/4096 = 1 mV. The
ideal input/output transfer function is shown in Table II.
AD7890-10
Figure 2 shows the analog input section for the AD7890-10.
The analog input range for each of the analog inputs is ± 10 V
into an input resistance of typically 33 kΩ. This input is benign
with no dynamic charging currents with the resistor attenuator
stage followed by the multiplexer and in cases where MUX
OUT is connected to SHA IN this is followed by the high input
impedance stage of the track/hold amplifier. The designed code
transitions occur on successive integer LSB values (i.e., 1 LSB,
2 LSBs, 3 LSBs...). Output coding is 2s complement binary
with 1 LSB – FS/4096 = 20 V/4096 = 4.88 mV. The ideal input/
output transfer function is shown in Table I.
2kΩ
REF OUT/
REF IN
AA
AA
REF OUT/
REF IN
6kΩ
VINX
TO ADC
REFERENCE
CIRCUITRY
200Ω*
9.38kΩ
AD7890-4
AGND
*EQUIVALENT ON-RESISTANCE OF MULTIPLEXER
Figure 3. AD7890-4 Analog Input Structure
Table II. Ideal Input/Output Code Table for the AD7890-4
TO ADC
REFERENCE
CIRCUITRY
7.5kΩ
200Ω*
VINX
10kΩ
AD7890-10
AGND
+2.5V
REFERENCE
2kΩ
MUX OUT
+2.5V
REFERENCE
30kΩ
AA
AA
MUX OUT
Analog Input1
Digital Output
Code Transition
+FSR – 1 LSB2 (4.095 V)
+FSR – 2 LSBs (4.094 V)
+FSR – 3 LSBs (4.093 V)
111 . . . 110 to 111 . . . 111
111 . . . 101 to 111 . . . 110
111 . . . 100 to 111 . . . 101
AGND + 3 LSBs (0.003 V)
AGND + 2 LSBs (0.002 V)
AGND + 1 LSB (0.001 V)
000 . . . 010 to 000 . . . 011
000 . . . 001 to 000 . . . 010
000 . . . 000 to 000 . . . 001
*EQUIVALENT ON-RESISTANCE OF MULTIPLEXER
Figure 2. AD7890-10 Analog Input Structure
Table I. Ideal Input/Output Code Table for the AD7890-10
Analog Input1
Digital Output
Code Transition
+FSR/2 – 1 LSB2 (9.995117 V)
+FSR/2 – 2 LSBs (9.990234 V)
+FSR/2 – 3 LSBs (9.985352 V)
011 . . . 110 to 011 . . . 111
011 . . . 101 to 011 . . . 110
011 . . . 100 to 011 . . . 101
AGND + 1 LSB (0.004883 V)
AGND (0.000000 V)
AGND – 1 LSB (–0.004883 V)
000 . . . 000 to 000 . . . 001
111 . . . 111 to 000 . . . 000
111 . . . 110 to 111 . . . 111
–FSR/2 + 3 LSBs (–9.985352 V)
–FSR/2 + 2 LSBs (–9.990234 V)
–FSR/2 + 1 LSB (–9.995117 V)
100 . . . 010 to 100 . . . 011
100 . . . 001 to 100 . . . 010
100 . . . 000 to 100 . . . 001
NOTES
1
FSR is full-scale range and is 20 V with REF IN = +2.5 V.
2
1 LSB = FSR/4096 = 4.883 mV with REF IN = +2.5 V.
AD7890-4
Figure 3 shows the analog input section for the AD7890-4. The
analog input range for each of the analog inputs is ± 10 V into
an input resistance of typically 15 kΩ. This input is benign with
no dynamic charging currents with the resistor attenuator stage
followed by the multiplexer and in cases where MUX OUT is
connected to SHA IN this is followed by the high input impedance stage of the track/hold amplifier. The designed code transi-
REV. A
NOTES
1
FSR is full-scale range and is 4.096 V with REF IN +2.5 V.
2
1 LSB = FSR/4096 = 1 mV with REF IN = +2.5 V.
AD7890-2
The analog input section for the AD7890-2 contains no biasing
resistors and the selected analog input connects to the multiplexer and in cases where MUX OUT is connected to SHA IN
this is followed by the high input impedance stage of the track/
hold amplifier. The analog input range is, therefore, 0 V to +2.5 V
into a high impedance stage with an input current of less than
50 nA. The designed code transitions occur on successive integer
LSB values (i.e., l LSB, 2 LSBs, 3 LSBs . . . FS-1 LSBs). Output coding is straight (natural) binary with 1 LSB = FS/4096 =
2.5 V/4096 = 0.61 mV. The ideal input/output transfer function
is shown in Table III.
Table III. Ideal Input/Output Code Table for the AD7890-2
Analog Input1
Digital Output
Code Transition
+FSR – 1 LSB2 (2.499390 V)
+FSR – 2 LSBs (2.498779 V)
+FSR – 3 LSBs (2.498169 V)
111 . . . 110 to 111 . . . 111
111 . . . 101 to 111 . . . 110
111 . . . 100 to 111 . . . 101
AGND + 3 LSBs (0.001831 V)
AGND + 2 LSBs (0.001221 V)
AGND + 1 LSB (0.000610 V)
000 . . . 010 to 010 . . . 011
000 . . . 001 to 001 . . . 010
000 . . . 000 to 000 . . . 001
NOTES
1
FSR is full-scale range and is 2.5 V with REF IN = +2.5 V.
2
1 LSB = FSR/4096 = 0.61 mV with REF IN = +2.5 V.
–9–
AD7890
Track/Hold Section
The SHA IN input on the AD7890 connects directly to the
input stage of the track/hold amplifier. This is a high impedance
input with input leakage currents of less than 50 nA. Connecting the MUX OUT pin directly to the SHA IN pin connects the
multiplexer output directly to the track/hold amplifier. The
input voltage range for this input is 0 V to +2.5 V. If external
circuitry is connected between MUX OUT and SHA IN, then
the user must ensure that the input voltage range to the SHA
IN input is 0 V to +2.5 V to ensure that the full dynamic range
of the converter is utilized.
The track/hold amplifier on the AD7890 allows the ADC to
accurately convert an input sine wave of full-scale amplitude to
12-bit accuracy. The input bandwidth of the track/hold is
greater than the Nyquist rate of the ADC even when the ADC is
operated at its maximum throughput rate of 117 kHz (i.e., the
track/hold can handle input frequencies in excess of 58 kHz).
The track/hold amplifier acquires an input signal to 12-bit accuracy in less than 2 µs. The operation of the track/hold is essentially transparent to the user. The track/hold amplifier goes from
its tracking mode to its hold mode at the start of conversion.
The start of conversion is the rising edge of CONVST (assuming the internal pulse has timed out) for hardware conversion
starts and for software conversion starts is the point where the
internal pulse is timed out. The aperture time for the track/hold
(i.e., the delay time between the external CONVST signal and
the track/hold actually going into hold) is typically 15 ns. For
software conversion starts, the time depends on the internal
pulse widths. Therefore, for software conversion starts, the sampling instant is not very well defined. For sampling systems
which require well defined, equidistant sampling, it may not be
possible to achieve optimum performance from the part using
the software conversion start. At the end of conversion, the part
returns to its tracking mode. The acquisition time of the track/
hold amplifier begins at this point.
Reference Section
The AD7890 contains a single reference pin, labelled
REF OUT/REF IN, which either provides access to the part’s
own +2.5 V reference or to which an external +2.5 V reference
can be connected to provide the reference source for the part.
The part is specified with a +2.5 V reference voltage. Errors in
the reference source will result in gain errors in the AD7890’s
transfer function and will add to the specified full-scale errors
on the part. On the AD7893-10, it will also result in an offset
error injected in the attenuator stage.
The AD7890 contains an on-chip +2.5 V reference. To use this
reference as the reference source for the AD7890, simply connect a 0.1 µF disc ceramic capacitor from the REF OUT/ REF
IN pin to AGND. The voltage which appears at this pin is internally buffered before being applied to the ADC. If this reference
is required for use external to the AD7890, it should be buffered
as the source impedance of this output is 2 kΩ nominal. The
tolerance on the internal reference is ± 10 mV at 25°C with a
typical temperature coefficient of 25 ppm/°C and a maximum
error over temperature of ± 25 mV.
If the application requires a reference with a tighter tolerance or
the AD7890 needs to be used with a system reference, then the
user has the option of connecting an external reference to this
REF OUT/REF IN pin. The external reference will effectively
overdrive the internal reference and thus provide the reference
source for the ADC. The reference input is buffered but has a
nominal 2 kΩ resistor connected to the AD7890’s internal reference. Suitable reference sources for the AD7890 include the
AD680, AD780 and REF-43 precision +2.5 V references.
Timing and Control Section
The AD7890 is capable of two interface modes, selected by the
SMODE input. The first of these is a self-clocking mode where the
part provides the frame sync, serial clock and serial data at the end
of conversion. In this mode the serial clock rate is determined by
the master clock rate of the part (at CLK IN input). The second
mode is an external clocking mode where the user provides the
frame sync and serial clock signals to obtain the serial data from the
part. In this second mode, the user has control of the serial clock
rate up to a maximum of 10 MHz. The two modes are discussed in
more detail in the Serial Interface section.
The part also provides hardware and software conversion start
features. The former provides a well-defined sampling instant
with the track/hold going into hold on the rising edge of the
CONVST signal. For the software conversion start, a write to
the CONV bit to the Control Register initiates the conversion
sequence. However, for the software conversion start an internal
pulse has to time out before the input signal is sampled. This
pulse, plus the difficult in maintaining exactly equal delays
between each software conversion start command, means that
the dynamic performance of the AD7890 may have difficulty
meeting spec when used in software conversion start mode.
The AD7890 provides separate channel select and conversion start
control. This allows the user to optimize the throughput rate of the
system. Once the track/hold has gone into hold mode, the input
channel can be updated and the input voltage can settle to the new
value while the present conversion is in progress.
Assuming the internal pulse has timed out before the CONVST
pulse is exercised, the conversion will consist of 14.5 master
clock cycles. In the self-clocking mode, the conversion time is
defined as the time from the rising edge of CONVST to the falling edge of RFS (i.e., when the device starts to transmit its conversion result). This time includes the 14.5 master clock cycles
plus the updating of the output register and delay time in outputting the RFS signal, resulting in a total conversion time of
5.9 µs maximum. Figure 4 shows the conversion timing for the
AD890 when used in the Self-Clocking (Master) Mode with
hardware CONVST. The timing diagram assumes that the
internal pulse is not active when the CONVST signal goes high.
To ensure this, the channel address to be converted should be
selected by writing to the Control Register prior to the
CONVST pulse. Sufficient setup time should be allowed
between the Control Register write and the CONVST to ensure
that the internal pulse has timed out. The duration of the internal pulse (and hence the duration of setup time) depends on the
value of CEXT.
–10–
REV. A
AD7890
CONVST (I)
TRACK/HOLD
GOES INTO HOLD
tCONVERT
RFS (O)
SCLK (O)
THREE-STATE
DATA OUT (O)
NOTE
(I) SIGNIFIES AN INPUT; (O) SIGNIFIES AN OUTPUT. PULL-UP RESISTOR ON SCLK.
Figure 4. Self-Clocking {Master) Mode Conversion Sequence
When using the device in the External-Clocking Mode, the output register can be read at any time and the most up-to-date
conversion result will be obtained. However, reading data from
the output register or writing data to the Control Register during conversion or during the 500 ns prior to the next CONVST
will result in reduced performance from the part. A read operation to the output register has most effect on performance with
the signal-to-noise ratio likely to degrade especially when higher
serial clock rates are used while the code flicker from the part
will also increase (see AD7890 Performance section).
Figure 5 shows the timing and control sequence required to
obtain optimum performance from the part in the external
clocking mode. In the sequence shown, conversion is initiated
on the rising edge of CONVST and new data is available in the
output register of the AD7890 5.9 µs later. Once the read operation has taken place, a further 500 ns should be allowed before
the next rising edge of CONVST to optimize the settling of the
track/hold before the next conversion is initiated. The diagram
shows the read operation and the write operation taking place in
parallel. On the sixth falling edge of SCLK in the write sequence
the internal pulse will be initiated. Assuming MUX OUT is
connected to SHA IN, 2 µs are required between this sixth falling edge of SCLK and the rising edge of CONVST to allow for
the full acquisition time of the track/hold amplifier. With the
serial clock rate at its maximum of 10 MHz, the achievable
throughput rate for the part is 5.9 µs (conversion time) plus
0.6 µs (six serial clock pulses before internal pulse is initiated)
plus 2 µs (acquisition time). This results in a minimum throughput time of 8.5 µs (equivalent to a throughput rate of 117 kHz).
If the part is operated with a slower serial clock, it will impact
the achievable throughput rate for optimum performance.
CONVST
SCLK
RFS
TFS
tCONVERT
CONVERSION IS
INITIATED AND
TRACK/HOLD GOES
INTO HOLD
500ns MIN
CONVERSION
ENDS 5.9µs
LATER
SERIAL READ
& WRITE
OPERATIONS
READ & WRITE
OPERATIONS SHOULD END
500ns PRIOR TO NEXT
RISING EDGE OF CONVST
Figure 5. External Clocking (Slave) Mode Timing
Sequence for Optimum Performance
REV. A
–11–
NEXT
CONVERSION
START COMMAND
AD7890
CONVST
SCLK
RFS
TFS
tCONVERT
CONVERSION IS
INITIATED AND
TRACK/HOLD GOES
INTO HOLD
500ns MIN
µP INT
CONVERSION
ENDS 5.9µs SERVICE OR
POLLING
LATER
ROUTINE
READ & WRITE
OPERATIONS SHOULD
END 500ns PRIOR TO
NEXT RISING EDGE OF
CONVST
SERIAL READ
& WRITE
OPERATIONS
NEXT CONVST
RISING EDGE
Figure 6. CONVST Used as Status Signal in External Clocking Mode
CEXT FUNCTIONING
The CEXT input on the AD7890 provides a means of determining how long after a new channel address is written to the part
that a conversion can take place. The reason behind this is
two-fold. Firstly, when the input channel to the AD7890 is
changed, the input voltage on this new channel is likely to be
very different from the previous channel voltage. Therefore, the
part’s track/hold has to acquire the new voltage before an accurate conversion can take place. An internal pulse delays any conversion start command (as well as the signal to send the track/
hold into hold) until after this pulse has timed out. The second
reason is to allow the user to connect external antialiasing or signal conditioning circuitry between MUX OUT and SHA IN.
This external circuitry will introduce extra settling time into the
system. The CEXT pin provides a means for the user to extend
the internal pulse to take this extra settling time into account.
Basically, varying the value of the capacitor on the CEXT pin varies the duration of the internal pulse. Figure 7 shows the relationship between the value of the CEXT capacitor and the
internal delay.
64
This scheme limits the throughput rate to 11.8 µs minimum.
However, depending upon the response time of the microprocessor to the interrupt signal and the time taken by the processor to read the data, this may the fastest which the system could
have operated. In any case, the CONVST signal does not have
to have a 50:50 duty cycle. This can be tailored to optimize the
throughput rate of the part for a given system.
Alternatively, the CONVST signal can be used as a normal narrow pulse width. The rising edge of CONVST can be used as an
active high or rising edge-triggered interrupt. A software delay
of 5.9 µs can then be implemented before data is read from the
part.
TA = +85 °C
56
INTERNAL PULSE WIDTH – µs
In the Self-Clocking Mode, the AD7890 indicates when conversion is complete by bringing the RFS line low and initiating a
serial data transfer. In the external clocking mode, there is no
indication of when conversion is complete. In many applications, this will not be a problem as the data can be read from the
part during conversion or after conversion. However, applications which want to achieve optimum performance from the
AD7890 will have to ensure that the data read does not occur
during conversion or during 500 ns prior to the rising edge of
CONVST. This can be achieved in either of two ways. The first
is to ensure in software that the read operation is not initiated
until 5.9 µs after the rising edge of CONVST. This will only be
possible if the software knows when the CONVST command is
issued. The second scheme would be to use the CONVST signal as both the conversion start signal and an interrupt signal.
The simplest way to do this would be to generate a square wave
signal for CONVST with high and low times of 5.9 µs (see Figure 6). Conversion is initiated on the rising edge of CONVST.
The falling edge of CONVST occurs 5.9 µs later and can be
used as either an active low or falling edge-triggered interrupt
signal to tell the processor to read the data from the AD7890.
Provided the read operation is completed 500 ns before the rising edge of CONVST, the AD7890 will operate to specification.
TA = +25 °C
48
40
32
TA = –40 °C
24
16
8
0
0
250
500
750
1000
1250
1500
1750
2000
CEXT CAPACITANCE – pF
Figure 7. Internal Pulse Width vs. CEXT
–12–
REV. A
AD7890
The duration of the internal pulse can be seen on the CEXT pin.
The CEXT pin goes from a low to a high when a serial write to
the part is initiated (on the falling edge of TFS). It starts to
discharge on the sixth falling edge of SCLK in the serial write
operation. Once the CEXT pin has discharged to crossing its
nominal trigger point of 2.5 V, the internal pulse is timed out.
The internal pulse is initiated each time a write operation to the
Control Register takes place. As a result, the pulse is initiated
and the conversion process delayed for all software conversion
start commands. For hardware conversion start, it is possible to
separate the conversion start command from the internal pulse.
If the multiplexer output (MUX OUT) is connected directly to
the track/hold input (SHA IN), then no external settling has to
be taken into account by the internal pulse width. In applications where the multiplexer is switched and conversion is not
initiated until more than 2 µs after the channel is changed (as is
possible with a hardware conversion start), the user does not
have to worry about connecting any capacitance to the CEXT
pin. The 2 µs equates to the track/hold acquisition time of the
AD7890. In applications where the multiplexer is switched and
conversion is initiated at the same time (such as with a software
conversion start), a 120 pF capacitor should be connected to
CEXT to allow for the acquisition time of the track/hold before
conversion is initiated.
If external circuitry is connected between MUX OUT and SHA
IN, then the extra settling time introduced by this circuitry will
have to be taken into account. In the case where the multiplexer
change command and the conversion start command are separated, they need to be separated by greater than the acquisition
time of the AD7890 plus the settling time of the external circuitry if the user does not have to worry about the CEXT capacitance. In applications where the multiplexer is switched and
conversion is initiated at the same time (such as with a software
conversion start), the capacitor on CEXT needs to allow for the
acquisition time of the track/hold plus the settling-time of the
external circuitry before conversion is initiated.
SERIAL INTERFACE
The AD7890’s serial communications port provides a flexible
arrangement to allow easy interfacing to industry-standard
microprocessors, microcontrollers and digital signal processors.
A serial read to the AD7890 accesses data from the output register via the DATA OUT line. A serial write to the AD7890
writes data to the Control Register via the DATA IN line.
Two different modes of operation are available, optimized for
different types of interface where the AD7890 can act either as
master in the system (it provides the serial clock and data framing signal) or acts as slave (an external serial clock and framing
signal can be provided to the AD7890). These two modes,
labelled Self-Clocking Mode and External Clocking Mode, are
discussed in detail in the following sections.
Self-Clocking Mode
The AD7890 is configured for its Self-Clocking Mode by tying
the SMODE pin of the device to a logic low. In this mode, the
AD7890 provides the serial clock signal and the serial data
framing signal used for the transfer of data from the AD7890.
This Self-Clocking Mode can be used with processors which
allow an external device to clock their serial port including most
digital signal processors.
Read Operation
Figure 8 shows a timing diagram for reading from the AD7890
in the Self-Clocking mode. At the end of conversion, RFS goes
low and the serial clock (SCLK) and serial data (DATA OUT)
outputs become active. Sixteen bits of data are transmitted with
one leading zero, followed by the three address bits of the Control Register, followed by the 12-bit conversion result starting
with the MSB. Serial data is clocked out of the device on the rising edge of SCLK and is valid on the falling edge of SCLK. The
RFS output remains low for the duration of the sixteen clock
cycles. On the sixteenth rising edge of SCLK, the RFS output is
driven high and DATA OUT is disabled.
RFS (O)
t6
t1
t3
SCLK (O)
DATA OUT (O)
3-STATE
t5
t4
t2
LEADING
ZERO
A2
A1
A0
t7
DB11
DB10
NOTE
(I) SIGNIFIES AN INPUT; (O) SIGNIFIES AN OUTPUT. PULL-UP RESISTOR ON SCLK.
Figure 8. Self-Clocking (Master) Mode Output Register Read
REV. A
–13–
DB0
3-STATE
AD7890
TFS (I)
t8
SCLK (O)
t 12
t3
t9
t11
t4
t10
DATA IN (I)
A2
A1
A0
STBY
CONV
DON'T
CARE
DON'T
CARE
DON'T
CARE
NOTE
(I) SIGNIFIES AN INPUT; (O) SIGNIFIES AN OUTPUT. PULL-UP RESISTOR ON SCLK.
Figure 9. Self-Clocking (Master) Mode Control Register Write
Write Operation
Figure 9 shows a write operation to the Control Register of the
AD7890. The TFS input is taken low to indicate to the part that
a serial write is about to occur. TFS going low initiates the
SCLK output and this is used to clock data out of the processors serial port and into the Control Register of the AD7890.
The AD7890 Control Register requires only five bits of data.
These are loaded on the first five clock cycles of the serial clock
with data on all subsequent clock cycles being ignored. However, the part requires six serial clock cycles to load data to the
Control Register. Serial data to be written to the AD7890 must
be valid on the falling edge of SCLK.
External-Clocking Mode
The AD7890 is configured for its external clocking mode by tying the SMODE pin of the device to a logic high. In this mode,
SCLK and RFS of the AD7890 are configured as inputs. This
external-clocking mode is designed for direct interface to systems which provide a serial clock output which is synchronized
to the serial data output including microcontrollers such as the
80C51, 87C51, 68HC11 and 68HC05 and most digital signal
processors.
Read Operation
Figure 10 shows the timing diagram for reading from the
AD7890 in the external-clocking mode. RFS goes low to access
data from the AD7890. The serial clock input does not have to
be continuous. The serial data can be accessed in a number of
bytes. However, RFS must remain low for the duration of the
data transfer operation. Once again, sixteen bits of data are
transmitted with one leading zero, followed by the three address
bits in the Control Register, followed by the 12-bit conversion
result starting with the MSB. If RFS goes low during the high
time of SCLK, the leading zero is clocked out from the falling
edge of RFS (as per Figure 10). If RFS goes low during the low
time of SCLK, the leading zero is clocked out on the next rising
edge of SCLK. This ensures that, regardless of whether RFS
goes low during a high time or low time of SCLK, the leading
zero is valid on the first falling edge of SCLK after RFS goes
low, provided t14 and t17 are adhered to. Serial data is clocked
out of the device on the rising edge of SCLK and is valid on the
falling edge of SCLK. At the end of the read operation, the
DATA OUT line is three-stated by a rising edge on either the
SCLK or RFS inputs, whichever occurs first. If a serial read
from the output register is in progress when conversion is complete, the updating of the output register is deferred until the
serial data read is complete and RFS returns high.
Write Operation
Figure 11 shows a write operation to the Control Register of the
AD7890. As with the Self-Clocking mode, the TFS input goes
low to indicate to the part that a serial write is about to occur.
As before, the AD7890 Control Register requires only five bits
of data. These are loaded on the first five clock cycles of the serial clock with data on all subsequent clock cycles being ignored.
However, the part requires six serial clocks to load data to the
Control Register. Serial data to be written to the AD7890 must
be valid on the falling edge of SCLK.
RFS (I)
t18
t13
t15
SCLK (I)
t16
t19
t 17
t14
DATA OUT (O)
t19A
LEADING
ZERO
A2
A1
A0
DB11
DB10
DB0
3-STATE
NOTE
(I) SIGNIFIES AN INPUT; (O) SIGNIFIES AN OUTPUT
Figure 10. External Clocking (Slave) Mode Output Register Read
–14–
REV. A
AD7890
TFS (I)
t20
t23
SCLK (I)
t22
t21
DATA IN (I)
A2
A1
A0
CONV
STBY
DON'T
CARE
DON'T
CARE
DON'T
CARE
NOTE
(I) SIGNIFIES AN INPUT; (O) SIGNIFIES AN OUTPUT.
Figure 11. External Clocking (Slave) Mode Control Register Write
SIMPLIFYING THE INTERFACE
To minimize the number of interconnect lines to the AD7890,
the user can connect the RFS and TFS lines of the AD7890
together and read and write from the part simultaneously. In
this case, new control register data should be provided on the
DATA IN line selecting the input channel and possibly providing a conversion start command while the part provides the
result from the conversion just completed on the DATA OUT
line.
In the self-clocking mode, this means that the part provides all
the signals for the serial interface. It does require that the
microprocessor has the data to be written to the Control
Register available in its output register when the part brings the
TFS line low. In the external clocking mode, it means that the
user only has to supply a single frame synchronization signal to
control both the read and write operations.
Care must be taken with this scheme that the read operation is
completed before the next conversion starts if the user wants to
obtain optimum performance from the part. In the case of the
software conversion start, the conversion command is written to
the Control Register on the sixth serial clock edge. However, the
read operation continues for another 10 serial clock cycles. To
avoid reading during the sampling instant or during conversion,
the user should ensure that the internal pulse width is sufficiently long (by choosing CEXT) so that the read operation is
completed before the next conversion sequence begins. Failure
to do this will result in significantly degraded performance from
the part, both in terms of signal-to-noise ratio and dc parameters. In the case of a hardware conversion start, the user should
ensure that the delay between the sixth falling edge of the serial
clock in the write operation and the next rising edge of
CONVST is greater than the internal pulse width.
AD7890–8051 Interface
Figure 12 shows an interface between the AD7890 and the
8XC51 microcontroller. The AD7890 is configured for its external clocking mode while the 8XC51 is configured for its
Mode 0 serial interface mode. The diagram shown in Figure 12
makes no provisions for monitoring when conversion is complete
on the AD7890 (assuming hardware conversion start is used).
To monitor the conversion time on the AD7890 a scheme such
as outlined previously with CONVST can be used. This can be
implemented in two ways. One is to connect the CONVST line
to another parallel port bit which is configured as an input. This
port bit can then be polled to determine when conversion is
complete. An alternative is to use an interrupt driven system in
which case the CONVST line should be connected to the INT1
input of the 8XC51.
Since the 8XC51 contains only one serial data line, the DATA
OUT and DATA IN lines of the AD7890 must be connected together. This means that the 8XC51 cannot communicate with
the output register and Control Register of the AD7890 at the
same time. The 8XC51 outputs the LSB first in a write operation so care should be taken in arranging the data which is to be
transmitted to the AD7890. Similarly, the AD7890 outputs the
MSB first during a read operation while the 8XC51 expects the
LSB first. Therefore, the data that is to be read into the serial
port needs to be rearranged before the correct data word from
the AD7890 is available in the microcontroller.
The serial clock rate from the 8XC51 is limited to significantly
less than the allowable input serial clock frequency with which
the AD7890 can operate. As a result, the time to read data from
the part will actually be longer than the conversion time of the
part. This means that the AD7890 cannot run at its maximum
throughput rate when used with the 8XC51.
VDD
MICROPROCESSOR/MICROCONTROLLER INTERFACE
The AD7890’s flexible serial interface allows for easy connection to the serial ports of DSP processors and microcontrollers.
Figures 12 through 15 show the AD7890 interfaced to a number of different microcontrollers and DSP processors. In some
of the interfaces shown, the AD7890 is configured as the master
in the system, providing the serial clock and frame sync for the
read operation while in others it acts as a slave with these signals
provided by the microprocessor.
SMODE
P1.0
RFS
P1.1
TFS
AD7890
8XC51
DATA OUT
P3.0
DATA IN
P3.1
SCLK
Figure 12. AD7890 to 8XC51 Interface
REV. A
–15–
AD7890
AD7890–68HC11 Interface
An interface circuit between the AD7890 and the 68HC11
microcontroller is shown in Figure 13. For the interface shown,
the AD7890 is configured for its external clocking mode while
the 68HC11’s SPI port is used and the 68HC11 is configured in
its single-chip mode. The 68HC11 is configured in the master
mode with its CPOL bit set to a logic zero and its CPHA bit set
to a logic one.
As with the previous interface, there are no provisions for monitoring when conversion is complete on the AD7890. To monitor
the conversion time on the AD7890 a scheme, such as outlined
in the previous interface with CONVST, can be used. This can
be implemented in two ways. One is to connect the CONVST
line to another parallel port bit which is configured as an input.
This port bit can then be polled to determine when conversion
is complete. An alternative is to use an interrupt driven system
in which case the CONVST line should be connected to the
IRQ input of the 68HC11.
DVDD
DVDD
In the scheme shown, the maximum serial clock frequency
which the ADSP-2101 can provide is 6.25 MHz. This allows
the AD7890 to be operated at a sample rate of 111 kHz. If it is
desirable to operate the AD7890 at its maximum throughput
rate of 117 kHz, an external serial clock of 10 MHz can be provided to drive the serial clock input of both the AD7890 and the
ADSP-2101.
To monitor the conversion time on the AD7890 a scheme, such
as outlined in previous interfaces with CONVST, can be used.
This can be implemented by connecting the CONVST line
directly to the IRQ2 input of the ADSP-2101. An alternative to
this, where the user does not have to worry about monitoring
the conversion status, is to operate the AD7890 in its SelfClocking Mode. In this scheme, the actual interface connections
would remain the same as in Figure 14 but now the AD7890
provides the serial clock and receive frame synchronization signals. Using the AD7890 in its Self-Clocking Mode, limits the
throughput rate of the system as the serial clock rate is limited
to 2.5 MHz.
AD7890–DSP56000 Interface
SS
Figure 15 shows an interface circuit between the AD7890 and
the DSP56000 DSP processor. The AD7890 is configured for
its external clocking mode. The DSP56000 is configured for
normal mode, synchronous operation with continuous clock. It
is also set up for a 16-bit word with SCK and SC2 as outputs.
The FSL bit of the DSP56000 should be set to 0.
SMODE
PC0
RFS
PC1
TFS
SCK
SCLK
68HC11
AD7890
MISO
DATA OUT
MOSI
DATA IN
Figure 13. AD7890 to 68HC11 Interface
The serial clock rate from the 68HC11 is limited to significantly
less than the allowable input serial clock frequency with which
the AD7890 can operate. As a result, the time to read data from
the part will actually be longer than the conversion time of the
part. This means that the AD7890 cannot run at its maximum
throughput rate when used with the 68HC11.
The RFS and TFS inputs of the AD7890 are connected
together so data is transmitted to and from the AD7890 at the
same time. With the DSP56000 in synchronous mode, it provides a common frame synchronization pulse for read and write
operations on its SC2 output. This is inverted before being
applied to the RFS and TFS inputs of the AD7890.
To monitor the conversion time on the AD7890 a scheme, such
as outlined in previous interface examples with CONVST, can
be used. This can be implemented by connecting the CONVST
line directly to the IRQA input of the DSP56000.
DVDD
AD7890–ADSP-2101 Interface
An interface circuit between the AD7890 and the ADSP-2101
DSP processor is shown in Figure 14. The AD7890 is configured for its external clocking mode with the ADSP-2101 providing the serial clock and frame synchronization signals. The
RFS1 and TFS1 inputs are outputs are configured for active low
operation.
SMODE
SC2
DSP56000
DVDD
RFS
TFS
AD7890
SCK
SCLK
SRD
DATA OUT
STD
DATA IN
SMODE
RFS1
RFS
TFS1
TFS
ADSP-2101
SCLK1
Figure 15. AD7890 to DSP56000 Interface
AD7890
SCLK
DR1
DATA OUT
DT1
DATA IN
Figure 14. AD7890 to ADSP-2101 Interface
AD7890–TMS320C25/30 Interface
Figure 16 shows an interface circuit between the AD7890 and
the TMS320C25/30 DSP processor. The AD7890 is configured
for its Self-Clocking Mode where it provides the serial clock and
frame synchronization signals. However, the TMS320C25/30
requires a continuous serial clock. In the scheme outlined here,
the AD7890’s master clock signal, CLK IN, is used to provide
the serial clock for the processor. The AD7890’s output SCLK,
–16–
REV. A
AD7890
to which the serial data is referenced, is a delayed version of the
CLK IN signal. The typical delay between the CLK IN and
SCLK is 20 ns and will be no more than 50 ns over supplies and
temperature. Therefore, there will still be sufficient setup time
for DATA OUT to be clocked into the DSP on the edges of the
CLK IN signal. When writing data to the AD7890, the processor’s
data hold time is sufficiently long to cater for the delay between
the two clocks. The AD7890’s RFS signal connects to both the
FSX and FSR inputs of the processor. The processor can generate its own FSX signal so if required the interface can be modified so that the RFS and TFS signals are separated and the
processor generates the FSX signal which is connected to the
TFS input of the AD7890.
In the scheme outlined here, the user does not have to worry
about monitoring the end of conversion. Once conversion is
complete, the AD7890 takes care of transmitting back its conversion result to the processor. Once the sixteen bits of data
have been received by the processor into its serial shift register,
it generates an internal interrupt. Since RFS and TFS are connected together, data is transmitted to the Control Register of
the AD7890 whenever the AD7890 transmits its conversion
result. The user just has to ensure that the word to be written to
the AD7890 Control Register is set up prior to the end of conversion. As part of the interrupt routine which recognizes that
data has been read in, the processor can set up the data which it
is going to write to the Control Register next time around.
CLK INPUT
CLK IN
TMS320C25/C30
SMODE
FSR
RFS
FSX
TFS
AD7890
CLKX
SCLK
CLKR
DR
DATA OUT
DX
DATA IN
driven from a low impedance stage. This will remove any effects
from the variation of the part’s multiplexer on-resistance with
input signal voltage and will also remove any effects of a high
source impedance at the sampling input of the track/hold. With
an external antialiasing filter in place, the additional settlingtime associated with the filter should be accounted for by using
a larger capacitance on CEXT.
AD7890 PERFORMANCE
Linearity
The linearity of the AD7890 is primarily determined by the
on-chip 12-bit D/A converter. This is a segmented DAC which
is laser trimmed for 12-bit integral linearity and differential linearity. Typical relative numbers for the part are ± 1/4 LSB while
the typical DNL errors are ± 1/2 LSB.
Noise
In an A/D converter, noise exhibits itself as code uncertainty in
dc applications and as the noise floor (in an FFT, for example)
in ac applications. In a sampling A/D converter like the
AD7890, all information about the analog input appears in the
baseband from dc to 1/2 the sampling frequency. The input
bandwidth of the track/hold exceeds the Nyquist bandwidth
and, therefore, an antialiasing filter should be used to remove
unwanted signals above fS/2 in the input signal in applications
where such signals exist.
Figure 17 shows a histogram plot for 8192 conversions of a dc
input using the AD7890. The analog input was set at the centre
of a code transition. The timing and control sequence used was
as per Figure 5 where the optimum performance of the ADC
was achieved. The same performance will be achieved in selfclocking mode where the part transmits its data after conversion
is complete. It can be seen that almost all the codes appear in
the one output bin indicating very good noise performance from
the ADC. The rms noise performance for the AD7890-2 for the
above plot was 81 µV. Since the analog input range, and hence
LSB size, on the AD7893-4 is 1.638 times what it is for the
AD7893-2, the same output code distribution results in an output rms noise of 143 µV for the AD7893-4. For the AD7890-10,
with an LSB size eight times that of the AD7890-2, the code distribution represents an output rms noise of 648 µV.
9000
Figure 16. AD7890 to TMS320C25/30 Interface
8000
OCCURRENCES OF CODE
ANTIALIASING FILTER
The AD7890 provides separate access to the multiplexer and
ADC via the MUX OUT and SHA IN pins. One of the reasons
for this is to allow the user to implement an antialiasing filter
between the multiplexer and the ADC. Inserting the antialiasing
filter at this point has the advantage that one antialiasing filter
can suffice for all eight channels rather than a separate antialiasing filter for each channel if they were to be placed prior to the
multiplexer.
7000
6000
5000
4000
3000
2000
1000
The antialiasing filter inserted between the MUX OUT and
SHA IN pins will generally be a low-pass filter to remove high
frequency signals which could possibly be aliased back in-band
during the sampling process. It is recommended that this filter is
an active filter, ideally with the MUX OUT of the AD7890 driving a high impedance stage and the SHA IN of the part being
REV. A
SAMPLING FREQUENCY = 102.4kHz
TA = +25°C
0
(X–4) (X–3) (X–2) (X–1)
X
(X+1) (X+2) (X+3) (X+4)
CODE
Figure 17. Histogram of 8192 Conversions of a DC Input
–17–
AD7890
8000
OCCURRENCES OF CODE
7000
SAMPLING FREQUENCY =
102.4kHz
TA = +25°C
5000
4000
3000
2000
1000
0
X
7000
SAMPLING FREQUENCY =
102.4kHz
TA = +25°C
6000
5000
4000
3000
2000
1000
0
(X–4) (X–3) (X–2) (X–1)
X
(X+1) (X+2) (X+3) (X+4)
CODE
Figure 19. Histogram of 8192 Conversions with Write
During Conversion
Dynamic Performance
The AD7890 contains an on-chip track/hold, allowing the part
to sample input signals up to 50 kHz on any of its input channels. Many of the AD7890’s applications will simply require it
to sequence through low frequency input signals across its eight
channels. There may be some applications, however, for which
the dynamic performance of the converter out to 40 kHz input
frequency is of interest. It is recommended for these wider band
sampling applications that the hardware conversion start method
is used for reasons outlined previously.
These applications require information on the ADC’s effect on
the spectral content of the input signal. Signal to (Noise +
Distortion), total harmonic distortion, peak harmonic or spurious and intermodulation distortion are all specified. Figure 20
shows a typical FFT plot of a 10 kHz, 0 V to +2.5 V input after
being digitized by the AD7890-2 operating at a 102.4 kHz sampling rate. The signal to (Noise + Distortion) is 71.5 dB and the
total harmonic distortion is –85 dB. It should be noted that
reading data from the part during conversion at 10 MHz serial
clock does have a significant impact on dynamic performance.
Therefore, for sampling applications, it is recommended not to
read data during conversion.
6000
(X–4) (X–3) (X–2) (X–1)
8000
OCCURRENCES OF CODE
In the external clocking mode, it is possible to write data to the
Control Register or read data from the output register while a
conversion is in progress. The same data is presented in Figure
18 as in Figure 17 except that in this case the output data read
for the device occurs during conversion. These results are
achieved with a serial clock rate of 2.5 MHz. If a higher serial
clock rate is used, the code transition noise will degrade from
that shown in the plot of Figure 18. This has the effect of injecting noise onto the die while bit decisions are being made and
this increases the noise generated by the AD7890. The histogram plot for 8192 conversions of the same dc input now shows
a larger spread of codes with the rms noise for the AD7890-2
increasing to 170 µV. This effect will vary depending on where
the serial clock edges appear with respect to the bit trials of the
conversion process. It is possible to achieve the same level of
performance when reading during conversion as when reading
after conversion depending on the relationship of the serial clock
edges to the bit trial points (i.e., the relationship of the serial
clock edges to the CLK IN edges). The bit decision points
on the AD7890 are on the falling edges of the master clock
(CLK IN) during the conversion process. Clocking out new
data bits at these points (i.e. the rising edge of SCLK) is the
most critical from a noise standpoint. The most critical bit decisions are the MSBs, so to achieve the level of performance outlined in Figure 18, reading within 1 µs after the rising edge of
CONVST should be avoided.
(X+1) (X+2) (X+3) (X+4)
CODE
F = /2
Writing data to the Control Register also has the effect of introducing digital activity onto the part while conversion is in
progress. However, since there are no output drivers active during a write operation, the amount of current flowing on the die
is less than for a read operation. Therefore, the amount of noise
injected into the die is less than for a read operation. Figure 19
shows the effect of a write operation during conversion. The histogram plot for 8192 conversions of the same dc input now
shows a larger spread of codes than for ideal conditions but
smaller than for a read operation. The resulting rms noise for
the AD7890-2 is 110 µV. In this case, the serial clock frequency
was 10 MHz.
SIGNAL AMPLITUDE – dB
0
Figure 18. Histogram of 8192 Conversions with Read
During Conversion
SAMPLE RATE = 102.4 kHz
INPUT FREQUENCY = 10 kHz
SNR = 71.5 dB
TA = +25°C
–30
–60
–90
–120
0
25.6
FREQUENCY – kHz
51.2
SNR IS SIGNAL TO (NOISE + DISTORTION) RATIO.
Figure 20. AD7890 FFT Plot
–18–
REV. A
AD7890
Effective Number of Bits
12
EFFECTIVE NUMBER OF BITS
The formula for Signal to (Noise + Distortion) Ratio (See Terminology section) is related to the resolution or number of bits
in the converter. Rewriting the formula, below, gives a measure
of performance expressed in effective number of bits (N):
N = (SNR — 1.76)/6.02
where SNR is Signal to (Noise + Distortion) Ratio
The effective number of bits for a device can be calculated
from its measured Signal to (Noise + Distortion) Ratio. Figure 21 shows a typical plot of effective number of bits versus
frequency for the AD7890-2 from dc to 40 kHz. The sampling
frequency is 102.4 kHz. The plot shows that the AD7890 converts an input sine wave of 40 kHz to an effective numbers of
bits of 11 which equates to a Signal to (Noise + Distortion)
level of 68 dB.
11.5
11
10.5
10
0
20
INPUT FREQUENCY – kHz
40
Figure 21. Effective Number of Bits vs. Frequency
REV. A
–19–
AD7890
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
C1822–6–7/93
Plastic DIP (N-24)
13
24
0.260 ± 0.001
(6.61 ± 0.03)
PIN 1
12
1
0.32 (8.128)
0.30 (7.62)
1.228 (31.19)
1.226 (31.14)
0.130 (3.30)
0.128 (3.25)
SEATING
PLANE
0.02 (0.5)
0.016 (0.41)
0.11 (2.79)
0.09 (2.28)
15 °
0
0.07 (1.78)
0.05 (1.27)
0.011 (0.28)
0.009 (0.23)
NOTES
1. LEAD NO. 1 IDENTIFIED BY DOT OR NOTCH
2. PLASTIC LEADS WILL BE EITHER SOLDER DIPPED OR TIN PLATED
IN ACCORDANCE WITH MIL-M-38510 REQUIREMENTS.
Cerdip (Q-24)
24
13
0.295 (7.493)
MAX
PIN 1
1
12
0.320 (8.128)
0.290 (7.366)
1.290 (32.77) MAX
0.180
(4.572)
MAX
0.225
(5.715)
MAX
0.125
(3.175)
MIN
0.070 (1.778)
0.020 (0.508)
0.021 (0.533)
0.015 (0.381)
TYP
0.110 (2.794)
0.090 (2.286)
TYP
0.065 (1.651)
0.055 (1.397)
TYP
0.012 (0.305)
0.008 (0.203)
TYP
15 °
0°
SEATING
PLANE
1. LEAD NO. 1 IDENTIFIED BY DOT OR NOTCH.
2. CERDIP LEADS WILL BE EITHER TIN PLATED OR SOLDER DIPPED
IN ACCORDANCE WITH MIL-M-38510 REQUIREMENTS.
SOIC (R-24)
0.419 (10.65)
0.394 (10.00)
15.6 (0.614)
15.2 (0.598)
13
24
PRINTED IN U.S.A.
0.299 (7.6)
0.291 (7.4)
12
1
0.050 (1.27)
0.019 (0.49)
0.014 (0.35)
0.104 (2.65)
0.093 (2.35)
0.03 (0.75)
0.01 (0.25)
0.013 (0.32)
0.009 (0.23)
0° - 8°
0.012 (0.3)
0.004 (0.1)
–20–
0.005 (1.27)
0.016 (0.40)
REV. A