4-Channel, 1.5 MSPS, 10-Bit and 12-Bit
Parallel ADCs with a Sequencer
AD7933/AD7934
FEATURES
FUNCTIONAL BLOCK DIAGRAM
VDD
AGND
AD7933/AD7934
VREFIN/
VREFOUT
2.5V
VREF
VIN0
I/P
MUX
CLKIN
12-/10-BIT
SAR ADC
AND
CONTROL
T/H
CONVST
BUSY
VIN3
SEQUENCER
VDRIVE
PARALLEL INTERFACE/CONTROL REGISTER
DB0 DB11
CS RD WR W/B
DGND
03713-001
Throughput rate: 1.5 MSPS
Specified for VDD of 2.7 V to 5.25 V
Low power
6 mW maximum at 1.5 MSPS with 3 V supplies
13.5 mW maximum at 1.5 MSPS with 5 V supplies
4 analog input channels with a sequencer
Software configurable analog inputs
4-channel single-ended inputs
2-channel fully differential inputs
2-channel pseudo differential inputs
Accurate on-chip 2.5 V reference
±0.2% maximum @ 25°C, 25 ppm/°C maximum (AD7934)
70 dB SINAD at 50 kHz input frequency
No pipeline delays
High speed parallel interface—word/byte modes
Full shutdown mode: 2 μA maximum
28-lead TSSOP package
Figure 1.
GENERAL DESCRIPTION
The AD7933/AD7934 are 10-bit and 12-bit, high speed, low
power, successive approximation (SAR) analog-to-digital
converters (ADCs). The parts operate from a single 2.7 V to
5.25 V power supply and feature throughput rates up to 1.5 MSPS.
The parts contain a low noise, wide bandwidth, differential trackand-hold amplifier that handles input frequencies up to 50 MHz.
These parts use advanced design techniques to achieve very low
power dissipation at high throughput rates. They also feature
flexible power management options. An on-chip control
register allows the user to set up different operating conditions,
including analog input range and configuration, output coding,
power management, and channel sequencing.
The AD7933/AD7934 feature four analog input channels with a
channel sequencer that allows a preprogrammed selection of
channels to be sequentially converted. These parts can accept
either single-ended, fully differential, or pseudo differential
analog inputs.
PRODUCT HIGHLIGHTS
The conversion process and data acquisition are controlled
using standard control inputs that allow for easy interfacing to
microprocessors and DSPs. The input signal is sampled on the
falling edge of CONVST, and the conversion is also initiated at
this point.
The AD7933/AD7934 has an accurate on-chip 2.5 V reference
that is used as the reference source for the analog-to-digital
conversion. Alternatively, this pin can be overdriven to provide
an external reference.
1.
2.
3.
4.
5.
6.
7.
High throughput with low power consumption.
Four analog inputs with a channel sequencer.
Accurate on-chip 2.5 V reference.
Single-ended, pseudo differential or fully differential
analog inputs that are software selectable.
Single-supply operation with VDRIVE function.
The VDRIVE function allows the parallel interface to connect
directly to 3 V or 5 V processor systems independent of VDD.
No pipeline delay.
Accurate control of the sampling instant via a CONVST
input and once-off conversion control.
Table 1. Related Devices
Device
AD7938/AD7939
AD7938-6
AD7934-6
No. of Bits
12/10
12
12
No. of Channels
8
8
4
Speed
1.5 MSPS
625 kSPS
625 kSPS
Rev. B
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 that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113 ©2005–2007 Analog Devices, Inc. All rights reserved.
�AD7933/AD7934
TABLE OF CONTENTS
Features .............................................................................................. 1
Converter Operation.................................................................. 17
Functional Block Diagram .............................................................. 1
ADC Transfer Function............................................................. 17
General Description ......................................................................... 1
Typical Connection Diagram ................................................... 18
Product Highlights ........................................................................... 1
Analog Input Structure.............................................................. 18
Revision History ............................................................................... 2
Analog Inputs ............................................................................. 19
Specifications..................................................................................... 3
Analog Input Selection .............................................................. 21
AD7933 Specifications................................................................. 3
Reference ..................................................................................... 22
AD7934 Specifications................................................................. 5
Parallel Interface......................................................................... 23
Timing Specifications .................................................................. 7
Power Modes of Operation ....................................................... 26
Absolute Maximum Ratings............................................................ 8
Power vs. Throughput Rate....................................................... 27
ESD Caution.................................................................................. 8
Microprocessor Interfacing....................................................... 27
Pin Configuration and Function Descriptions............................. 9
Application Hints ........................................................................... 29
Typical Performance Characteristics ........................................... 11
Grounding and Layout .............................................................. 29
Terminology .................................................................................... 13
Evaluating the AD7933/AD7934 Performance...................... 29
Control Register.............................................................................. 15
Outline Dimensions ....................................................................... 30
Sequencer Operation ................................................................. 16
Ordering Guide .......................................................................... 30
Circuit Information ........................................................................ 17
REVISION HISTORY
2/07—Rev. A to Rev B
Changes to Timing Specifications .................................................. 7
Changes to Figure 13...................................................................... 12
12/05—Rev. 0 to Rev. A
Replaced Figures .................................................................Universal
Changes to General Description .................................................... 1
Changes to Product Highlights....................................................... 1
Added Table 1.................................................................................... 1
Changes to Specifications Section.................................................. 3
Changes to Table 5............................................................................ 9
Changes to Terminology Section.................................................. 13
Changes to Control Register Section ........................................... 15
Changes to Circuit Information Section ..................................... 17
Changes to Application Hints Section......................................... 29
1/05—Revision 0: Initial Version
Rev. B | Page 2 of 32
�AD7933/AD7934
SPECIFICATIONS
AD7933 SPECIFICATIONS
VDD = VDRIVE = 2.7 V to 5.25 V, internal/external VREF = 2.5 V, unless otherwise noted. fCLKIN = 25.5 MHz, fSAMPLE = 1.5 MSPS; TA = TMIN to
TMAX1, unless otherwise noted.
Table 2.
Parameter
DYNAMIC PERFORMANCE
Signal-to-Noise + Distortion (SINAD)2
Total Harmonic Distortion (THD)2
Peak Harmonic or Spurious Noise (SFDR)2
Intermodulation Distortion (IMD)2
Second-Order Terms
Third-Order Terms
Channel-to-Channel Isolation
Aperture Delay2
Aperture Jitter2
Full Power Bandwidth2
DC ACCURACY
Resolution
Integral Nonlinearity2
Differential Nonlinearity2
Single-Ended and Pseudo Differential
Input
Offset Error2
Offset Error Match2
Gain Error2
Gain Error Match2
Fully Differential Input
Positive Gain Error2
Positive Gain Error Match2
Zero-Code Error2
Zero-Code Error Match2
Negative Gain Error2
Negative Gain Error Match2
ANALOG INPUT
Single-Ended Input Range
Pseudo Differential Input Range
VIN+
VIN−
Fully Differential Input Range3
VIN+ and VIN−
VIN+ and VIN−
DC Leakage Current4
Input Capacitance
Value1
Unit
61
60
−70
−72
dB min
dB min
dB max
dB max
−86
−90
−75
5
72
50
10
dB typ
dB typ
dB typ
ns typ
ps typ
MHz typ
MHz typ
10
±0.5
±0.5
Bits
LSB max
LSB max
±2
±0.5
±1.5
±0.5
LSB max
LSB max
LSB max
LSB max
±1.5
±0.5
±2
±0.5
±1.5
±0.5
LSB max
LSB max
LSB max
LSB max
LSB max
LSB max
0 to VREF
0 to 2 × VREF
V
V
RANGE bit = 0
RANGE bit = 1
0 to VREF
0 to 2 × VREF
−0.3 to +0.7
−0.3 to +1.8
V
V
V typ
V typ
RANGE bit = 0
RANGE bit = 1
VDD = 3 V
VDD = 5 V
VCM ± VREF/2
VCM ± VREF
±1
45
10
V
V
μA max
pF typ
pF typ
VCM = VREF/2, RANGE bit = 0
VCM = VREF, RANGE bit = 1
Test Conditions/Comments
fIN = 50 kHz sine wave
Differential mode
Single-ended mode
fa = 30 kHz, fb = 50 kHz
fIN= 50 kHz, fNOISE = 300 kHz
@ 3 dB
@ 0.1 dB
Guaranteed no missed codes to 10 bits
Straight binary output coding
Twos complement output coding
Rev. B | Page 3 of 32
When in track
When in hold
�AD7933/AD7934
Parameter
REFERENCE INPUT/OUTPUT
VREF Input Voltage 5
DC Leakage Current4
VREFOUT Output Voltage
VREFOUT Temperature Coefficient
VREF Noise
VREF Output Impedance
VREF Input Capacitance
LOGIC INPUTS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Current, IIN
Input Capacitance, CIN4
LOGIC OUTPUTS
Output High Voltage, VOH
Output Low Voltage, VOL
Floating-State Leakage Current
Floating-State Output Capacitance4
Output Coding
CONVERSION RATE
Conversion Time
Track-and-Hold Acquisition Time
Throughput Rate
POWER REQUIREMENTS
VDD
VDRIVE
IDD 6
Normal Mode (Static)
Normal Mode (Operational)
Autostandby Mode
Full/Autoshutdown Mode (Static)
Power Dissipation
Normal Mode (Operational)
Autostandby Mode (Static)
Full/Autoshutdown Mode
Value 1
Unit
Test Conditions/Comments
2.5
±1
2.5
25
5
10
130
10
15
25
V
μA max
V
ppm/°C max
ppm/°C typ
μV typ
μV typ
Ω typ
pF typ
pF typ
±1% specified performance
2.4
0.8
±5
10
V min
V max
μA max
pF max
2.4
0.4
±3
10
Straight (natural) binary
Twos complement
V min
V max
μA max
pF max
t2 + 13 tCLK
125
80
1.5
ns
ns max
ns typ
MSPS max
2.7/5.25
2.7/5.25
V min/max
V min/max
0.8
2.7
2.0
0.3
160
2
mA typ
mA max
mA max
mA typ
μA typ
μA max
Digital inputs = 0 V or VDRIVE
VDD = 2.7 V to 5.25 V, SCLK on or off
VDD = 4.75 V to 5.25 V
VDD = 2.7 V to 3.6 V
FSAMPLE = 100 kSPS, VDD = 5 V
Static
SCLK on or off
13.5
6
800
480
10
6
mW max
mW max
μW typ
μW typ
μW max
μW max
VDD = 5 V
VDD = 3 V
VDD = 5 V
VDD = 3 V
VDD = 5 V
VDD = 3 V
±0.2% max @ 25°C
0.1 Hz to 10 Hz bandwidth
0.1 Hz to 1 MHz bandwidth
When in track
When in hold
Typically 10 nA, VIN = 0 V or VDRIVE
ISOURCE = 200 μA
ISINK = 200 μA
CODING bit = 0
CODING bit = 1
1
Full-scale step input
Sine wave input
Temperature range is −40°C to +85°C.
See Terminology section.
3
VCM is the common-mode voltage. For full common-mode range, see Figure 25 and Figure 26. VIN+ and VIN− must always remain within GND/VDD.
4
Sample tested during initial release to ensure compliance.
5
This device is operational with an external reference in the range of 0.1 V to VDD. See the Reference section for more information.
6
Measured with a midscale dc analog input.
2
Rev. B | Page 4 of 32
�AD7933/AD7934
AD7934 SPECIFICATIONS
VDD = VDRIVE = 2.7 V to 5.25 V, internal/external VREF = 2.5 V, unless otherwise noted. fCLKIN = 25.5 MHz, fSAMPLE = 1.5 MSPS;
TA = TMIN to TMAX, unless otherwise noted.
Table 3.
Parameter
DYNAMIC PERFORMANCE
Signal-to-Noise + Distortion (SINAD) 2
Signal-to-Noise Ratio (SNR)2
Total Harmonic Distortion (THD)2
Peak Harmonic or Spurious Noise (SFDR)2
Intermodulation Distortion (IMD)2
Second-Order Terms
Third-Order Terms
Channel-to-Channel Isolation
Aperture Delay2
Aperture Jitter2
Full Power Bandwidth2
DC ACCURACY
Resolution
Integral Nonlinearity2
Differential Nonlinearity 2
Differential Mode
Single-Ended Mode
Single-Ended and Pseudo Differential Input
Offset Error2
Offset Error Match2
Gain Error2
Gain Error Match2
Fully Differential Input
Positive Gain Error2
Positive Gain Error Match2
Zero-Code Error2
Zero-Code Error Match2
Negative Gain Error2
Negative Gain Error Match2
ANALOG INPUT
Single-Ended Input Range
Pseudo Differential Input Range
VIN+
VIN−
Fully Differential Input Range 3
VIN+ and VIN−
VIN+ and VIN−
DC Leakage Current 4
Input Capacitance
Value 1
Unit
70
68
71
69
−73
−70
−73
dB min
dB min
dB min
dB min
dB max
dB max
dB max
−86
−90
−85
5
72
50
10
dB typ
dB typ
dB typ
ns typ
ps typ
MHz typ
MHz typ
@ 3 dB
@ 0.1 dB
12
±1
±1.5
Bits
LSB max
LSB max
Differential mode
Single-ended mode
±0.95
−0.95/+1.5
LSB max
LSB max
±6
±1
±3
±1
LSB max
LSB max
LSB max
LSB max
±3
±1
±6
±1
±3
±1
LSB max
LSB max
LSB max
LSB max
LSB max
LSB max
0 to VREF
0 to 2 × VREF
V
V
RANGE bit = 0
RANGE bit = 1
0 to VREF
0 to 2 × VREF
−0.3 to +0.7
−0.3 to +1.8
V
V
V typ
V typ
RANGE bit = 0
RANGE bit = 1
VDD = 3 V
VDD = 5 V
VCM ± VREF/2
VCM ± VREF
±1
45
10
V
V
μA max
pF typ
pF typ
VCM = VREF/2, RANGE bit = 0
VCM = VREF, RANGE bit = 1
Rev. B | Page 5 of 32
Test Conditions/Comments
fIN = 50 kHz sine wave
Differential mode
Single-ended mode
Differential mode
Single-ended mode
−85 dB typ, differential mode
−80 dB typ, single-ended mode
−82 dB typ
fa = 30 kHz, fb = 50 kHz
fIN = 50 kHz, fNOISE = 300 kHz
Guaranteed no missed codes to 12 bits
Guaranteed no missed codes to 12 bits
Straight binary output coding
Twos complement output coding
When in track
When in hold
�AD7933/AD7934
Parameter
REFERENCE INPUT/OUTPUT
VREF Input Voltage 5
DC Leakage Current
VREFOUT Output Voltage
VREFOUT Temperature Coefficient
VREF Noise
VREF Output Impedance
VREF Input Capacitance
LOGIC INPUTS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Current, IIN
Input Capacitance, CIN4
LOGIC OUTPUTS
Output High Voltage, VOH
Output Low Voltage, VOL
Floating-State Leakage Current
Floating-State Output Capacitance4
Output Coding
CONVERSION RATE
Conversion Time
Track-and-Hold Acquisition Time
Throughput Rate
POWER REQUIREMENTS
VDD
VDRIVE
IDD 6
Normal Mode (Static)
Normal Mode (Operational)
Autostandby Mode
Full/Autoshutdown Mode (Static)
Power Dissipation
Normal Mode (Operational)
Autostandby Mode (Static)
Full/Autoshutdown Mode
Value 1
Unit
Test Conditions/Comments
2.5
±1
2.5
25
5
10
130
10
15
25
V
μA max
V
ppm/°C max
ppm/°C typ
μV typ
μV typ
Ω typ
pF typ
pF typ
±1% specified performance
2.4
0.8
±5
10
V min
V max
μA max
pF max
2.4
0.4
±3
10
Straight (natural) binary
Twos complement
V min
V max
μA max
pF max
t2 + 13 tCLK
125
80
1.5
ns
ns max
ns typ
MSPS max
2.7/5.25
2.7/5.25
V min/max
V min/max
0.8
2.7
2.0
0.3
160
2
mA typ
mA max
mA max
mA typ
μA typ
μA max
Digital inputs = 0 V or VDRIVE
VDD = 2.7 V to 5.25 V, SCLK on or off
VDD = 4.75 V to 5.25 V
VDD = 2.7 V to 3.6 V
fSAMPLE = 100 kSPS, VDD = 5 V
Static
SCLK on or off
13.5
6
800
480
10
6
mW max
mW max
μW typ
μW typ
μW max
μW max
VDD = 5 V
VDD = 3 V
VDD = 5 V
VDD = 3 V
VDD = 5 V
VDD = 3 V
1
±0.2% max @ 25°C
0.1 Hz to 10 Hz bandwidth
0.1 Hz to 1 MHz bandwidth
When in track-and-hold
When in track-and-hold
Typically 10 nA, VIN = 0 V or VDRIVE
ISOURCE = 200 μA
ISINK = 200 μA
CODING bit = 0
CODING bit = 1
Full-scale step input
Sine wave input
Temperature range is −40°C to +85°C.
See the Terminology section.
VCM is the common-mode voltage. For full common-mode range, see Figure 25 and Figure 26. VIN+ and VIN− must always remain within GND/VDD.
4
Sample tested during initial release to ensure compliance.
5
This device is operational with an external reference in the range of 0.1 V to VDD. See the Reference section for more information.
6
Measured with a midscale dc analog input.
2
3
Rev. B | Page 6 of 32
�AD7933/AD7934
TIMING SPECIFICATIONS
VDD = VDRIVE = 2.7 V to 5.25 V, internal/external VREF = 2.5 V, unless otherwise noted. fCLKIN = 25.5 MHz, fSAMPLE = 1.5 MSPS;
TA = TMIN to TMAX, unless otherwise noted.
Table 4.
Parameter 1
fCLKIN 2
tQUIET
t1
t2
t3
t4
t5
t6
t7
t8
t9
t10
t11
t12
t13 3
t14 4
t15
t16
t17
t18
t19
t20
t21
t22
Limit at TMIN, TMAX
AD7933 AD7934
700
700
25.5
25.5
30
30
Unit
kHz min
MHz max
ns min
10
15
50
0
0
10
10
10
10
0
0
30
30
3
50
0
0
10
0
10
40
15.7
7.8
ns min
ns min
ns max
ns min
ns min
ns min
ns min
ns min
ns min
ns min
ns min
ns min
ns max
ns min
ns max
ns min
ns min
ns min
ns min
ns min
ns max
ns min
ns min
10
15
50
0
0
10
10
10
10
0
0
30
30
3
50
0
0
10
0
10
40
15.7
7.8
Description
CLKIN frequency
Minimum time between end of read and start of next conversion, that is, the time from
when the data bus goes into three-state until the next falling edge of CONVST
CONVST pulse width
CONVST falling edge to CLKIN falling edge setup time
CLKIN falling edge to BUSY rising edge
CS to WR setup time
CS to WR hold time
WR pulse width
Data setup time before WR
Data hold after WR
New data valid before falling edge of BUSY
CS to RD setup time
CS to RD hold time
RD pulse width
Data access time after RD
Bus relinquish time after RD
Bus relinquish time after RD
HBEN to RD setup time
HBEN to RD hold time
Minimum time between reads/writes
HBEN to WR setup time
HBEN to WR hold time
CLKIN falling edge to BUSY falling edge
CLKIN low pulse width
CLKIN high pulse width
1
Sample tested during initial release to ensure compliance. All input signals are specified with tRISE = tFALL = 5 ns (10% to 90% of VDD) and timed from a voltage level of
1.6 V. All timing specifications are with a 25 pF load capacitance (see Figure 34, Figure 35, Figure 36, and Figure 37).
Minimum CLKIN for specified performance; with slower SCLK frequencies, performance specifications apply typically.
3
The time required for the output to cross 0.4 V or 2.4 V.
4
t14 is derived from the measured time taken by the data outputs to change 0.5 V. The measured number is then extrapolated back to remove the effects of charging or
discharging the 25 pF capacitor. This means that the time, t14, quoted in the timing characteristics is the true bus relinquish time of the part and is independent of the
bus loading.
2
Rev. B | Page 7 of 32
�AD7933/AD7934
ABSOLUTE MAXIMUM RATINGS
TA = 25°C, unless otherwise noted.
Table 5.
Parameter
VDD to AGND/DGND
VDRIVE to AGND/DGND
Analog Input Voltage to AGND
Digital Input Voltage to DGND
VDRIVE to VDD
Digital Output Voltage to AGND
VREFIN to AGND
AGND to DGND
Input Current to Any Pin Except Supplies 1
Operating Temperature Range
Commercial (B Version)
Storage Temperature Range
Junction Temperature
θJA Thermal Impedance (TSSOP)
θJC Thermal Impedance (TSSOP)
Lead Temperature, Soldering
Reflow Temperature (10 sec to 30 sec)
ESD
1
Rating
−0.3 V to +7 V
−0.3 V to VDD + 0.3 V
−0.3 V to VDD + 0.3 V
−0.3 V to +7 V
−0.3 V to VDD + 0.3 V
−0.3 V to VDRIVE + 0.3 V
−0.3 V to VDD + 0.3 V
−0.3 V to +0.3 V
±10 mA
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
ESD CAUTION
−40°C to +85°C
−65°C to +150°C
150°C
97.9°C/W
14°C/W
255°C
1.5 kV
Transient currents of up to 100 mA do not cause SCR latch-up.
Rev. B | Page 8 of 32
�AD7933/AD7934
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
28
VIN3
27
VIN2
DB0
3
26
VIN1
DB1
4
25
VIN0
DB2
5
24
VREFIN/VREFOUT
DB3
6
23
AGND
DB4
7
DB5
8
DB6
AD7933/
AD7934
TOP VIEW
(Not to Scale)
22
CS
21
RD
9
20
WR
DB7 10
19
CONVST
VDRIVE 11
18
CLKIN
DGND 12
17
BUSY
DB8/HBEN 13
16
DB11
DB9 14
15
DB10
03713-006
VDD 1
W/B 2
Figure 2. Pin Configuration
Table 6. Pin Function Descriptions
Pin No.
1
Mnemonic
VDD
2
W/B
3 to 10
DB0 to DB7
11
VDRIVE
12
DGND
13
DB8/HBEN
14 to
16
DB9 to
DB11
17
BUSY
18
CLKIN
19
CONVST
Description
Power Supply Input. The VDD range for the AD7933/AD7934 is from 2.7 V to 5.25 V. Decouple the supply to AGND
with a 0.1 μF capacitor and a 10 μF tantalum capacitor.
Word/Byte Input. When this input is logic high, word transfer mode is enabled, and data is transferred to and from
the AD7933/AD7934 in 10-bit words on Pin DB2 to Pin DB11, or in 12-bit words on Pin DB0 to Pin DB11. When W/B
is logic low, byte transfer mode is enabled. Data and the channel ID are transferred on Pin DB0 to Pin DB7, and Pin
DB8/HBEN assumes its HBEN functionality. When operating in byte transfer mode, tie off unused data lines to
DGND.
Data Bit 0 to Data Bit 7. Three-state parallel digital I/O pins that provide the conversion result and allow
programming of the control register. These pins are controlled by CS, RD, and WR. The logic high/low voltage
levels for these pins are determined by the VDRIVE input. When reading from the AD7933, the two LSBs (DB0 and
DB1) are always 0, and the LSB of the conversion result is available on DB2.
Logic Power Supply Input. The voltage supplied at this pin determines at what voltage the parallel interface of the
AD7933/AD7934 operates. Decouple this pin to DGND. The voltage at this pin may be different to that at VDD but
should never exceed VDD by more than 0.3 V.
Digital Ground. This is the ground reference point for all digital circuitry on the AD7933/AD7934. Connect this pin
to the DGND plane of a system. The DGND and AGND voltages should ideally be at the same potential and must
not be more than 0.3 V apart, even on a transient basis.
Data Bit 8/High Byte Enable. When W/B is high, this pin acts as Data Bit 8, a three-state I/O pin that is controlled
by CS, RD, and WR. When W/B is low, this pin acts as the high byte enable pin. When HBEN is low, the low byte of
data written to or read from the AD7933/AD7934 is on DB0 to DB7. When HBEN is high, the top four bits of the
data being written to, or read from, the AD7933/AD7934 are on DB0 to DB3. When reading from the device, DB4
and DB5 contain the ID of the channel to which the conversion result corresponds (see the channel address bits in
Table 10). DB6 and DB7 are always 0. When writing to the device, DB4 to DB7 of the high byte must be all 0s.
Note that when reading from the AD7933, the two LSBs in the low byte are 0s, and the remaining six bits are
conversion data.
Data Bit 9 to Data Bit 11. Three-state parallel digital I/O pins that provide the conversion result and also allow the
control register to be programmed in word mode. These pins are controlled by CS, RD, and WR. The logic high/low
voltage levels for these pins are determined by the VDRIVE input.
Busy Output. This is the logic output indicating the status of the conversion. The BUSY output goes high following
the falling edge of CONVST and stays high for the duration of the conversion. Once the conversion is complete and
the result is available in the output register, the BUSY output goes low. The track-and-hold returns to track mode
just prior to the falling edge of BUSY, on the 13th rising edge of CLKIN (see Figure 34).
Master Clock Input. The clock source for the conversion process is applied to this pin. Conversion time for the
AD7933/AD7934 takes 13 clock cycles + t2. The frequency of the master clock input therefore determines the
conversion time and achievable throughput rate. The CLKIN signal can be a continuous or burst clock.
Conversion Start Input. A falling edge on CONVST initiates a conversion. The track-and-hold goes from track to
hold mode on the falling edge of CONVST, and the conversion process is initiated at this point. Following powerdown, when operating in the autoshutdown or autostandby mode, a rising edge on CONVST is used to power up
the device.
Rev. B | Page 9 of 32
�AD7933/AD7934
Pin No.
20
21
Mnemonic
WR
RD
22
CS
23
AGND
24
VREFIN/VREFOUT
25 to
28
VIN0 to VIN3
Description
Write Input. Active low logic input used in conjunction with CS to write data to the control register.
Read Input. Active low logic input used in conjunction with CS to access the conversion result. The conversion
result is placed on the data bus following the falling edge of RD read while CS is low.
Chip Select. Active low logic input used in conjunction with RD and WR to read conversion data or write data to
the control register.
Analog Ground. This is the ground reference point for all analog circuitry on the AD7933/AD7934. All analog input
signals and any external reference signal should be referred to this AGND voltage. The AGND and DGND voltages
should ideally be at the same potential and must not be more than 0.3 V apart, even on a transient basis.
Reference Input/Output. This pin is connected to the internal reference and is the reference source for the ADC.
The nominal internal reference voltage is 2.5 V, and this appears at this pin. It is recommended to decouple the
VREFIN/VREFOUT pin to AGND with a 470 nF capacitor. This pin can be overdriven by an external reference. The input
voltage range for the external reference is 0.1 V to VDD; however, ensure that the analog input range does not
exceed VDD + 0.3 V. See the Reference section.
Analog Input 0 to Analog Input 3. Four analog input channels that are multiplexed into the on-chip track-andhold. The analog inputs can be programmed as four single-ended inputs, two fully differential pairs, or two pseudo
differential pairs by appropriately setting the MODE bits in the control register (see Table 10). Select the analog
input channel to be converted either by writing to Address Bit ADD1 and Address Bit ADD0 in the control register
prior to the conversion, or by using the on-chip sequencer. The input range for all input channels can either be 0 V
to VREF or 0 V to 2 × VREF, and the coding can be binary or twos complement, depending on the states of the RANGE
and CODING bits in the control register. To avoid noise pickup, connect any unused input channels to AGND.
Rev. B | Page 10 of 32
�AD7933/AD7934
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C, unless otherwise noted.
–60
0
100mV p-p SINE WAVE ON VDD AND/OR VDRIVE
NO DECOUPLING
DIFFERENTIAL/SINGLE-ENDED MODE
–70
–20
AMPLITUDE (dB)
INT REF
–80
PSRR (dB)
4096 POINT FFT
VDD = 5V
FSAMPLE = 1.5MSPS
FIN = 49.62kHz
SINAD = 70.94dB
THD = –90.09dB
DIFFERENTIAL MODE
–10
–90
EXT REF
–100
–30
–40
–50
–60
–70
–80
03713-007
700
600
VDD = 5V
DIFFERENTIAL MODE
0.8
0.6
DNL ERROR (LSB)
–75
–80
–85
–90
0.4
0.2
0
–0.2
–0.4
03713-021
–0.6
0
100
200
300
400
500
600
NOISE FREQUENCY (kHz)
700
03713-010
NOISE ISOLATION (dB)
500
1.0
INTERNAL/EXTERNAL REFERENCE
VDD = 5V
–0.8
–1.0
800
0
500
1000
1500
2000 2500
CODE
3000
3500
4000
Figure 7. AD7934 Typical DNL @ VDD = 5 V
Figure 4. Channel-to-Channel Isolation
1.0
80
VDD = 5V
VDD = 5V
DIFFERENTIAL MODE
0.8
70
0.6
VDD = 3V
INL ERROR (LSB)
60
50
40
0.4
0.2
0
–0.2
–0.4
–0.6
30
0
100
200
300
400 500 600 700
FREQUENCY (kHz)
03713-008
FSAMPLE = 1.5MSPS
RANGE = 0 TO VREF
DIFFERENTIAL MODE
800
900
1000
Figure 5. AD7934 SINAD vs. Analog Input Frequency for Various Supply Voltages
Rev. B | Page 11 of 32
03713-011
SINAD (dB)
400
Figure 6. AD7934 FFT @ VDD = 5 V
–70
20
300
FREQUENCY (kHz)
Figure 3. PSRR vs. Supply Ripple Frequency Without Supply Decoupling
–95
200
–110
1010
100
210
410
610
810
SUPPLY RIPPLE FREQUENCY (kHz)
–100
0
–120
10
03713-009
–90
–110
–0.8
–1.0
0
500
1000
1500
2000 2500
CODE
3000
Figure 8. AD7934 Typical INL @ VDD = 5 V
3500
4000
�AD7933/AD7934
10000
4
SINGLE-ENDED MODE
DIFFERENTIAL MODE
9000
9997
CODES
INTERNAL
REF
8000
3
6000
2
???
DNL (LSB)
7000
1
5000
4000
POSITIVE DNL
3000
03713-012
NEGATIVE DNL
–1
0.25
0.50
0.75
1.00
1.25
1.50 1.75
VREF (V)
2.00
2.25
2.50
03713-015
2000
0
1000
0
2046
2.75
3 CODES
2047
2048
2049
2050
CODE
Figure 9. AD7934 DNL vs. VREF for VDD = 3 V
Figure 12. AD7934 Histogram of Codes for
10,000 Samples @ VDD = 5 V with Internal Reference
12
120
11
110
VDD = 5V
DIFFERENTIAL MODE
10
100
VDD = 5V
SINGLE-ENDED MODE
9
CMRR (dB)
VDD = 3V
SINGLE-ENDED MODE
8
80
VDD = 3V
DIFFERENTIAL MODE
70
03713-013
7
6
0
0.5
1.0
1.5
2.0
2.5
VREF (V)
3.0
3.5
4.0
0
VDD = 5V
–0.5
–1.0
VDD = 3V
–2.0
–2.5
–3.0
–3.5
–4.0
–4.5
SINGLE-ENDED MODE
0
0.5
1.0
1.5
2.0
VREF (V)
2.5
3.0
03713-014
OFFSET (LSB)
–1.5
60
0
200
400
600
800
RIPPLE FREQUENCY (kHz)
1000
1200
Figure 13. CMRR vs. Common-Mode Ripple with VDD = 5 V and 3 V
Figure 10. AD7934 ENOB vs. VREF
–5.0
90
03713-017
EFFECTIVE NUMBER OF BITS
DIFFERENTIAL MODE
3.5
Figure 11. AD7934 Offset vs. VREF
Rev. B | Page 12 of 32
�AD7933/AD7934
TERMINOLOGY
Integral Nonlinearity (INL)
The maximum deviation from a straight line passing through
the endpoints of the ADC transfer function. The endpoints of
the transfer function are zero scale, 1 LSB below the first code
transition, and full scale, 1 LSB above the last code transition.
Differential Nonlinearity (DNL)
The difference between the measured and the ideal 1 LSB
change between any two adjacent codes in the ADC.
Negative Gain Error
This applies when using the twos complement output coding
option, in particular to the 2 × VREF input range with −VREF to
+VREF biased about the VREF point. It is the deviation of the first
code transition (100…000) to (100…001) from the ideal (that is,
−VREFIN + 1 LSB) after the zero-code error has been adjusted out.
Negative Gain Error Match
The difference in negative gain error between any two channels.
Offset Error
The deviation of the first code transition (00…000) to (00…001)
from the ideal (that is, AGND + 1 LSB).
Offset Error Match
The difference in offset error between any two channels.
Gain Error
The deviation of the last code transition (111…110) to
(111…111) from the ideal (that is, VREF – 1 LSB) after the offset
error has been adjusted out.
Gain Error Match
The difference in gain error between any two channels.
Zero-Code Error
This applies when using the twos complement output coding
option, in particular to the 2 × VREF input range with −VREF to
+VREF biased about the VREFIN point. It is the deviation of the
midscale transition (all 0s to all 1s) from the ideal VIN voltage
(that is, VREF).
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 sine wave signal to the three nonselected input channels
and applying a 50 kHz signal to the selected channel. The
channel-to-channel isolation is defined as the ratio of the power
of the 50 kHz signal on the selected channel to the power of the
noise signal on the unselected channels that appears in the FFT
of this channel. The noise frequency on the unselected channels
varies from 40 kHz to 740 kHz. The noise amplitude is at
2 × VREF, while the signal amplitude is at 1 × VREF. See Figure 4.
Power Supply Rejection Ratio (PSRR)
PSRR is defined as the ratio of the power in the ADC output at
full-scale frequency, f, to the power of a 100 mV p-p sine wave
applied to the ADC VDD supply of frequency, fS. The frequency
of the input varies from 1 kHz to 1 MHz.
PSRR (dB) = 10 log(Pf/PfS)
where:
Zero-Code Error Match
The difference in zero-code error between any two channels.
Pf is the power at frequency f in the ADC output.
PfS is the power at frequency fS in the ADC output.
Positive Gain Error
This applies when using the twos complement output coding
option, in particular to the 2 × VREF input range with −VREF to +VREF
biased about the VREFIN point. It is the deviation of the last
code transition (011…110) to (011…111) from the ideal (that is,
+VREF – 1 LSB) after the zero-code error has been adjusted out.
Common-Mode Rejection Ratio (CMRR)
Positive Gain Error Match
The difference in positive gain error between any two channels.
CMRR is defined as the ratio of the power in the ADC output at
full-scale frequency, f, to the power of a 100 mV p-p sine wave
applied to the common-mode voltage of VIN+ and VIN− of
frequency, fS.
CMRR (dB) = 10 log(Pf/PfS)
where:
Pf is the power at frequency f in the ADC output.
PfS is the power at frequency fS in the ADC output.
Rev. B | Page 13 of 32
�AD7933/AD7934
Track-and-Hold Acquisition Time
The track-and-hold amplifier returns to track mode at the end
of conversion. The track-and-hold acquisition time is the time
required for the output of the track-and-hold amplifier to reach
its final value, within ±½ LSB, after the end of conversion.
Signal-to-(Noise + Distortion) Ratio (SINAD)
This is the measured ratio of signal-to-noise and distortion at
the output of the ADC. The signal is the rms amplitude of the
fundamental. Noise is the sum of all nonfundamental signals up
to half the sampling frequency (fSAMPLE/2), excluding dc. The
ratio is dependent on the number of quantization levels in the
digitization process; the more levels, the smaller the
quantization noise.
The theoretical signal-to-noise and distortion ratio for an ideal
N-bit converter with a sine wave input is given by
SINAD = (6.02 N + 1.76) dB
Thus, for a 12-bit converter, SINAD is 74 dB, and for a 10-bit
converter, SINAD is 62 dB.
Total Harmonic Distortion (THD)
THD is the ratio of the rms sum of harmonics to the fundamental. For the AD7933/AD7934, it is defined as
⎛ V 2 2 + V 3 2 + V 4 2 + V 5 2 + V6 2
THD (dB ) = −20 log⎜
⎜
V1
⎝
⎞
⎟
⎟
⎠
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 fSAMPLE/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
ADCs where the harmonics are buried in the noise floor, it is a
noise peak.
Intermodulation Distortion
With inputs consisting of sine waves at two frequencies, fa and
fb, any active device with nonlinearities create distortion products
at sum and difference frequencies of mfa ± nfb where m, n = 0,
1, 2, 3, and so on. Intermodulation distortion 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 AD7933/AD7934 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-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 intermodulation distortion is
calculated per the THD specification, as the ratio of the rms
sum of the individual distortion products to the rms amplitude
of the sum of the fundamentals, expressed in dB.
where:
V1 is the rms amplitude of the fundamental.
V2, V3, V4, V5, and V6 are the rms amplitudes of the second
through the sixth harmonics.
Rev. B | Page 14 of 32
�AD7933/AD7934
CONTROL REGISTER
The control register on the AD7933/AD7934 is a 12-bit, writeonly register. Data is written to this register using the CS and
WR pins. The functions of the control register bits are described
in Table 8. At power-up, the default bit settings in the control
register are all 0s. When writing to the control register between
conversions, ensure that CONVST returns high before
performing the write.
Table 7. Control Register Bits
MSB
DB11
PM1
DB10
PM0
DB9
CODING
DB8
REF
DB7
ZERO
DB6
ADD1
DB5
ADD0
DB4
MODE1
DB3
MODE0
DB2
SEQ1
DB1
SEQ0
LSB
DB0
RANGE
Table 8. Control Register Bit Function Description
Bit No.
11, 10
Mnemonic
PM1, PM0
9
CODING
8
REF
7
6, 5
ZERO
ADD1,
ADD0
4, 3
2
MODE1,
MODE0
SEQ1
1
SEQ0
0
RANGE
Description
Power Management Bits. Use these two bits to select the power mode of operation. The user can choose between
normal mode or various power-down modes of operation as shown in Table 9.
This bit selects the output coding of the conversion result. If the CODING bit is set to 0, the output coding is
straight (natural) binary. If the CODING bit is set to 1, the output coding is twos complement.
This bit selects whether the internal or external reference is used to perform the conversion. If the REF bit is
Logic 0, an external reference should be applied to the VREF pin, and if it is Logic 1, the internal reference is
selected. See the Reference section.
This bit is not used; therefore, it should always be set to Logic 0.
Use these two address bits to select which analog input channel is to be converted in the next conversion, if the
sequencer is not being used, or to select the final channel in a consecutive sequence when the sequencer is being
used (see Table 11 for more information). The selected input channel is decoded as shown in Table 10.
The two mode pins select the type of analog input on the four VIN pins. The AD7933/AD7934 have either four
single-ended inputs, two fully differential inputs, or two pseudo differential inputs (see Table 10).
The SEQ1 bit in the control register is used in conjunction with the SEQ0 bit to control the sequencer function
(see Table 11).
The SEQ0 bit in the control register is used in conjunction with the SEQ1 bit to control the sequencer function
(see Table 11).
This bit selects the analog input range of the AD7933/AD7934. If RANGE is set to 0, the analog input range
extends from 0 V to VREF. If RANGE is set to 1, the analog input range extends from 0 V to 2 × VREF. When this range
is selected, VDD must be 4.75 V to 5.25 V if a 2.5 V reference is used; otherwise, care must be taken to ensure that
the analog input remains within the supply rails. See the Analog Inputs section for more information.
Table 9. Power Mode Selection Using the Power Management Bits in the Control Register
PM1
0
0
PM0
0
1
Mode
Normal Mode
Autoshutdown
1
0
Autostandby
1
1
Full Shutdown
Description
When operating in normal mode, all circuitry is fully powered up at all times.
When operating in autoshutdown mode, the AD7933/AD7934 enters full shutdown mode at the end of
each conversion. In this mode, all circuitry is powered down.
When the AD7933/AD7934 enters this mode, the reference remains fully powered, the reference buffer is
partially powered down, and all other circuitry is fully powered down. This mode is similar to
autoshutdown mode, but it allows the part to power up in 7 μs (or 600 ns if an external reference is used).
See the Power Modes of Operation section for more information.
When the AD7933/AD7934 enters this mode, all circuitry is powered down. The information in the control
register is retained.
Rev. B | Page 15 of 32
�AD7933/AD7934
SEQUENCER OPERATION
The configuration of the SEQ0 and SEQ1 bits in the control
register allows use of the sequencer function. Table 11 outlines
the two sequencer modes of operation.
Writing to the Control Register to Program the Sequencer
The AD7933 and AD7934 need 13 full CLKIN periods to
perform a conversion. If the ADC does not receive the full 13
CLKIN periods, the conversion aborts. If a conversion is
aborted after applying 12.5 CLKIN periods to the ADC, ensure
that a rising edge of CONVST or a falling edge of CLKIN is
applied to the part before writing to the control register to
program the sequencer. If these conditions are not met, the
sequencer will not be in the correct state to handle being
reprogrammed for another sequence of conversions and the
performance of the converter is not guaranteed.
Table 10. Analog Input Type Selection
Channel Address
ADD1
ADD0
0
0
0
1
1
0
1
1
MODE0 = 0, MODE1 = 0
Four Single-Ended
Input Channels
VIN+
VIN−
VIN0
AGND
VIN1
AGND
VIN2
AGND
VIN3
AGND
MODE0 = 0, MODE1 = 1
Two Fully Differential
Input Channels
VIN+
VIN−
VIN0
VIN1
VIN1
VIN0
VIN2
VIN3
VIN3
VIN2
MODE0 = 1, MODE1 = 0
Two Pseudo Differential
Input Channels
VIN+
VIN−
VIN0
VIN1
VIN1
VIN0
VIN2
VIN3
VIN3
VIN2
MODE0 = 1, MODE1 = 1
Not Used
Table 11. Sequence Selection Modes
SEQ0
0
SEQ1
0
0
1
1
1
0
1
Sequence Type
Select this configuration when the sequence function is not used. The analog input channel selected on each individual
conversion is determined by the contents of ADD1 and ADD0, the channel address bits, in each prior write operation. This
mode of operation reflects the normal operation of a multichannel ADC, without using the sequencer function, where
each write to the AD7933/AD7934 selects the next channel for conversion.
Not used.
Not used.
Use this configuration in conjunction with ADD1 and ADD0, the channel address bits, to program continuous conversions
on a consecutive sequence of channels. The sequence of channels extends from Channel 0 through to a selected final
channel as determined by the channel address bits in the control register. When in differential or pseudo differential mode,
inverse channels (for example, VIN1, VIN0) are not converted.
Rev. B | Page 16 of 32
�AD7933/AD7934
CIRCUIT INFORMATION
The AD7933/AD7934 provide the user with an on-chip
track-and-hold, an internal accurate reference, an analog-todigital converter, and a parallel interface housed in a 28-lead
TSSOP package.
The AD7933/AD7934 have four analog input channels that
can be configured to be four single-ended inputs, two fully
differential pairs, or two pseudo differential pairs. There is
an on-chip channel sequencer that allows the user to select a
consecutive sequence of channels through which the ADC can
cycle with each falling edge of CONVST.
When the ADC starts a conversion (see Figure 15), SW3 opens
and SW1 and SW2 move to Position B, causing the comparator
to become unbalanced. Both inputs are disconnected once the
conversion begins. The control logic and charge redistribution
DACs are used to add and subtract fixed amounts of charge
from the sampling capacitor arrays to bring the comparator
back into a balanced condition. When the comparator is
rebalanced, the conversion is complete. The control logic
generates the output code of the ADC. The output impedances
of the sources driving the VIN+ and the VIN− pins must match;
otherwise, the two inputs have different settling times, resulting
in errors.
CAPACITIVE
DAC
COMPARATOR
VIN+
The analog input range for the AD7933/AD7934 is 0 V to VREF
or 0 V to 2 × VREF, depending on the status of the RANGE bit in
the control register. The output coding of the ADC can be either
binary or twos complement, depending on the status of the
CODING bit in the control register.
CS
B
A
SW1
A
B
SW2
CONTROL
LOGIC
SW3
VIN–
VREF
CS
03713-024
The AD7933/AD7934 are fast, 4-channel, 10-bit and 12-bit,
single-supply, successive approximation analog-to-digital
converters. The parts operate from a 2.7 V to 5.25 V power
supply and feature throughput rates up to 1.5 MSPS.
CAPACITIVE
DAC
Figure 15. ADC Conversion Phase
CONVERTER OPERATION
The AD7933/AD7934 are successive approximation ADCs
based around two capacitive digital-to-analog converters (DACs).
Figure 14 and Figure 15 show simplified schematics of the ADC
in acquisition and conversion phase, respectively. The ADC
comprises control logic, a SAR, and two capacitive DACs. Both
figures show the operation of the ADC in differential/pseudo
differential modes. Single-ended mode operation is similar but
VIN− is internally tied to AGND. In acquisition phase, SW3 is
closed, SW1 and SW2 are in Position A, the comparator is held
in a balanced condition, and the sampling capacitor arrays
acquire the differential signal on the input.
ADC TRANSFER FUNCTION
The output coding for the AD7933/AD7934 is either straight
binary or twos complement, depending on the status of the
CODING bit in the control register. The designed code transitions
occur at successive LSB values (1 LSB, 2 LSBs, and so on), and
the LSB size is VREF/1024 for the AD7933 and VREF/4096 for the
AD7934. The ideal transfer characteristics of the AD7933/AD7934
for both straight binary and twos complement output coding are
shown in Figure 16 and Figure 17, respectively.
111...111
111...110
ADC CODE
The AD7933/AD7934 provide flexible power management
options to allow users to achieve the best power performance
for a given throughput rate. These options are selected by
programming PM1 and PM0, the power management bits, in
the control register.
CAPACITIVE
DAC
CS
000...001
000...000
SW1
SW3
VIN–
A
B
SW2
VREF
1 LSB = VREF /4096 (AD7934)
1 LSB = VREF /1024 (AD7933)
CONTROL
LOGIC
0V
+VREF – 1 LSB
ANALOG INPUT
CS
CAPACITIVE
DAC
1 LSB
Figure 14. ADC Acquisition Phase
Rev. B | Page 17 of 32
NOTES
1. VREF IS EITHER VREF OR 2 × VREF .
Figure 16. AD7933/AD7934 Ideal Transfer Characteristic
with Straight Binary Output Coding
03713-025
A
03713-023
VIN+
011...111
000...010
COMPARATOR
B
111...000
�AD7933/AD7934
1 LSB = 2 × VREF /4096 (AD7934)
1 LSB = 2 × VREF /1024 (AD7933)
ANALOG INPUT STRUCTURE
011...111
Figure 19 shows the equivalent circuit of the analog input
structure of the AD7933/AD7934 in differential/pseudo
differential modes. In single-ended mode, VIN− is internally
tied to AGND. The four diodes provide ESD protection for the
analog inputs. Ensure that the analog input signals never exceed
the supply rails by more than 300 mV; doing so causes these
diodes to become forward-biased and start conducting into the
substrate. These diodes can conduct up to 10 mA without
causing irreversible damage to the part.
000...001
000...000
111...111
100...010
100...000
–VREF + 1 LSB
VREF
+VREF – 1 LSB
03713-026
100...001
Figure 17. AD7933/AD7934 Ideal Transfer Characteristic
with Twos Complement Output Coding and 2 × VREF Range
TYPICAL CONNECTION DIAGRAM
Figure 18 shows a typical connection diagram for the
AD7933/AD7934. The AGND and DGND pins are connected
together at the device for good noise suppression. If the internal
reference is used, the VREFIN/VREFOUT pin is decoupled to AGND
with a 0.47 μF capacitor to avoid noise pickup. Alternatively,
VREFIN/VREFOUT can be connected to an external reference source.
In this case, decouple the reference pin with a 0.1 μF capacitor.
In both cases, the analog input range can either be 0 V to VREF
(RANGE bit = 0) or 0 V to 2 × VREF (RANGE bit = 1). The
analog input configuration can be either four single-ended
inputs, two differential pairs, or two pseudo differential pairs
(see Table 10). The VDD pin is connected to either a 3 V or 5 V
supply. The voltage applied to the VDRIVE input controls the
voltage of the digital interface. As shown in Figure 18, it is
connected to the same 3 V supply of the microprocessor to
allow a 3 V logic interface (see the Digital Inputs section).
0.1µF
+ 10µF +
The C1 capacitors in Figure 19 are typically 4 pF and can
primarily be attributed to pin capacitance. The resistors are
lumped components made up of the on resistance of the
switches. The value of these resistors is typically about 100 Ω.
The C2 capacitors are the sampling capacitors of the ADC and
typically have a capacitance of 45 pF.
For ac applications, removing high frequency components from
the analog input signal is recommended by using an RC lowpass filter on the relevant analog input pins. In applications
where harmonic distortion and signal-to-noise ratio are critical,
drive the analog input from a low impedance source. Large
source impedances significantly affect the ac performance of the
ADC. This may necessitate the use of an input buffer amplifier.
The choice of the op amp is a function of the particular
application.
VDD
D
VIN+
C1
3V/5V
SUPPLY
VIN–
AD7933/AD7934
VIN0
C1
MICROCONTROLLER/
MICROPROCESSOR
CLKIN
CS
RD
VIN3
WR
BUSY
CONVST
AGND
DB0
DGND
DB11/DB9
VREFIN/VREFOUT
C2
0.1µF
+
+
10µF
3V
SUPPLY
+ 0.1µF EXTERNAL VREF
0.47µF INTERNAL VREF
D
Figure 19. Equivalent Analog Input Circuit,
Conversion Phase: Switches Open, Track Phase: Switches Closed
03713-027
2.5V
VREF
VDRIVE
R1
VDD
W/B
0 TO VREF /
0 TO 2 × VREF
C2
D
D
VDD
R1
03713-028
ADC CODE
011...110
When no amplifier is used to drive the analog input, limit the
source impedance to low values. The maximum source
impedance depends on the amount of THD that can be
tolerated. The THD increases as the source impedance increases
and performance degrades. Figure 20 and Figure 21 show a
graph of the THD vs. source impedance with a 50 kHz input
tone for both VDD = 5 V and 3 V in single-ended mode and fully
differential mode, respectively.
Figure 18. Typical Connection Diagram
Rev. B | Page 18 of 32
�AD7933/AD7934
–40
ANALOG INPUTS
FIN = 50kHz
–45
The AD7933/AD7934 have software selectable analog input
configurations. Users can choose from among the following
configurations: four single-ended inputs, two fully differential
pairs, or two pseudo differential pairs. The analog input
configuration is chosen by setting the MODE0/MODE1 bits in
the internal control register (see Table 10).
–50
VDD = 3V
THD (dB)
–55
–60
–65
–70
–75
Single-Ended Mode
VDD = 5V
03713-018
–80
–85
–90
10
100
RSOURCE (Ω)
1k
Figure 20. THD vs. Source Impedance in Single-Ended Mode
–60
FIN = 50kHz
–65
If the analog input signal to be sampled is bipolar, the internal
reference of the ADC can be used to externally bias up this
signal to make it the correct format for the ADC.
–70
–75
THD (dB)
The AD7933/AD7934 can have four single-ended analog input
channels by setting the MODE0 and MODE1 bits in the control
register to 0. In applications where the signal source has a high
impedance, it is recommended to buffer the analog input before
applying it to the ADC. An amplifier suitable for this function is
the AD8021. The analog input range of the AD7933/AD7934
can be programmed to be either 0 V to VREF, or 0 V to 2 × VREF.
–80
–85
VDD = 3V
–90
VDD = 5V
03713-019
–95
–100
10
100
RSOURCE (Ω)
1k
Figure 23 shows a typical connection diagram when operating
the ADC in single-ended mode. This diagram shows a bipolar
signal of amplitude ±1.25 V being preconditioned before it is
applied to the AD7933/AD7934. In cases where the analog
input amplitude is ±2.5 V, the 3R resistor can be replaced with a
resistor of value R. The resultant voltage on the analog input of
the AD7933/AD7934 is a signal ranging from 0 V to 5 V. In this
case, the 2 × VREF mode can be used.
Figure 21. THD vs. Source Impedance in Fully Differential Mode
R
Figure 22 shows a graph of the THD vs. the analog input frequency for various supplies, while sampling at 1.5 MHz with an
SCLK of 25.5 MHz. In this case, the source impedance is 10 Ω.
+1.25V
0V
–1.25V
VIN
+2.5V
0V
R
3R
VIN0
AD7933/
AD7934*
VIN3
VREFOUT
R
–50
VDD = 3V
SINGLE-ENDED MODE
THD (dB)
0.47µF
VDD = 5V
SINGLE-ENDED MODE
–70
–80
*ADDITIONAL PINS OMITTED FOR CLARITY.
VDD = 5V/3V
DIFFERENTIAL MODE
–90
Figure 23. Single-Ended Mode Connection Diagram
Differential Mode
–110
–120
03713-020
–100
FSAMPLE = 1.5MSPS
RANGE = 0 TO VREF
0
100
200
300
400
500
INPUT FREQUENCY (kHz)
600
The AD7933/AD7934 can have two differential analog input
pairs by setting the MODE0 and MODE1 bits in the control
register to 0 and 1, respectively.
700
Figure 22. THD vs. Analog Input Frequency for Various Supply Voltages
Differential signals have some benefits over single-ended
signals, including noise immunity based on the device’s
common-mode rejection and improvements in distortion
performance. Figure 24 defines the fully differential analog
input of the AD7933/AD7934.
Rev. B | Page 19 of 32
03713-031
–60
�AD7933/AD7934
4.5
VIN–
AD7933/
AD7934*
*ADDITIONAL PINS OMITTED FOR CLARITY.
Figure 24. Differential Input Definition
The amplitude of the differential signal is the difference
between the signals applied to the VIN+ and VIN− pins in each
differential pair (that is, VIN+ − VIN−). VIN+ and VIN− should be
simultaneously driven by two signals, each of amplitude
VREF (or 2 × VREF depending on the range chosen) that are
180° out of phase. The amplitude of the differential signal is,
therefore, −VREF to +VREF peak-to-peak (that is, 2 × VREF). This is
regardless of the common mode (CM). The common mode is
the average of the two signals (that is (VIN+ + VIN−)/2) and is,
therefore, the voltage on which the two inputs are centered.
This results in the span of each input being CM ± VREF/2. This
voltage has to be set up externally and its range varies with the
reference value, VREF. As the value of VREF increases, the
common-mode range decreases. When driving the inputs with
an amplifier, the actual common-mode range is determined by
the output voltage swing of the amplifier.
Figure 25 and Figure 26 show how the common-mode range
typically varies with VREF for a 5 V power supply using the 0 V
to VREF range or 2 × VREF range, respectively. The common
mode must be in this range to guarantee the functionality of the
AD7933/AD7934.
When a conversion takes place, the common mode is rejected,
resulting in a virtually noise-free signal of amplitude −VREF to
+VREF corresponding to the digital codes of 0 to 1024 for the
AD7933, and 0 to 4096 for the AD7934. If the 2 × VREF range is
used, the input signal amplitude extends from −2 VREF to
+2 VREF.
3.5
TA = 25°C
2.5
3.0
2.5
2.0
1.5
1.0
0.5
0
0.1
0.6
1.1
1.6
2.1
2.6
VREF (V)
Figure 26. Input Common-Mode Range vs. VREF
(2 × VREF Range, VDD = 5 V)
Driving Differential Inputs
Differential operation requires that VIN+ and VIN− be simultaneously driven with two equal signals that are 180° out of phase.
The common mode must be set up externally and has a range
that is determined by VREF, the power supply, and the particular
amplifier used to drive the analog inputs. Differential modes of
operation with either an ac or dc input provide the best THD
performance over a wide frequency range. Since not all applications have a signal preconditioned for differential operation,
there is often a need to perform single-ended-to-differential
conversion.
Using an Op Amp Pair
An op amp pair can be used to directly couple a differential
signal to one of the analog input pairs of the AD7933/AD7934.
The circuit configurations shown in Figure 27 and Figure 28
show how a dual op amp converts a single-ended signal into a
differential signal for both a bipolar and unipolar input signal,
respectively.
The voltage applied to Point A sets up the common-mode
voltage. In both diagrams, it is connected in some way to the
reference, but any value in the common-mode range can be
input here to set up the common mode. The AD8022 is a
suitable dual op amp that can be used in this configuration to
provide differential drive to the AD7933/AD7934.
Take care when choosing the op amp; the selection depends on
the required power supply and system performance objectives.
The driver circuits in Figure 27 and Figure 28 are optimized for
dc coupling applications requiring best distortion performance.
2.0
1.5
1.0
0.5
0
03713-033
COMMON-MODE RANGE (V)
3.0
3.5
03713-034
VREF
p-p
4.0
COMMON-MODE RANGE (V)
VIN+
03713-032
COMMON-MODE
VOLTAGE
TA = 25°C
VREF
p-p
0
0.5
1.0
1.5
VREF (V)
2.0
2.5
Figure 25. Input Common-Mode Range vs. VREF
(0 V to VREF Range, VDD = 5 V)
3.0
The circuit configuration shown in Figure 27 is configured to
convert and level shift a single-ended, ground-referenced
(bipolar) signal to a differential signal centered at the VREF level
of the ADC.
The circuit in Figure 28 converts a unipolar, single-ended signal
into a differential signal.
Rev. B | Page 20 of 32
�AD7933/AD7934
220Ω
VREF p-p
2 × VREF p-p
27Ω
V–
VREF
AD7933/
AD7934
220Ω
V+
20kΩ
VIN–
VIN+
220Ω
27Ω
A
AD7933/
AD7934*
V–
+
3.75V
2.5V
1.25V
VIN–
DC INPUT
VOLTAGE
VREF
Figure 29. Pseudo Differential Mode Connection Diagram
0.47µF
10kΩ
220Ω
VREF p-p
V+
27Ω
GND
V–
3.75V
2.5V
1.25V
VIN+
220Ω
AD7933/
AD7934
220Ω
V+
A
27Ω
V–
10kΩ
3.75V
2.5V
1.25V
ANALOG INPUT SELECTION
As shown in Table 10, users can set up their analog input
configuration by setting the values in the MODE0 and MODE1
bits in the control register. Assuming the configuration has been
chosen, there are two different ways of selecting the analog
input to be converted depending on the state of the SEQ0 and
SEQ1 bits in the control register.
Traditional Multichannel Operation (SEQ0 = SEQ1 = 0)
VIN–
VREF
0.47µF
03713-036
440Ω
0.47µF
*ADDITIONAL PINS OMITTED FOR CLARITY.
Figure 27. Dual Op Amp Circuit to Convert a Single-Ended
Bipolar Signal into a Unipolar Differential Signal
VREF
+
Figure 28. Dual Op Amp Circuit to Convert a Single-Ended Unipolar
Signal into a Differential Signal
Any one of four analog input channels or two pairs of channels
can be selected for conversion in any order by setting the SEQ0
and SEQ1 bits in the control register to 0. The channel to be
converted is selected by writing to the address bits, ADD1 and
ADD0, in the control register to program the multiplexer prior
to the conversion. This mode of operation is that of a traditional
multichannel ADC where each data write selects the next
channel for conversion. Figure 30 shows a flowchart of this
mode of operation. The channel configurations are shown in
Table 10.
POWER ON
Another method of driving the AD7933/AD7934 is to use the
AD8138 differential amplifier. The AD8138 can be used as a
single-ended-to-differential amplifier, or differential-to-differential
amplifier. The device is as easy to use as an op amp and greatly
simplifies differential signal amplification and driving.
WRITE TO THE CONTROL REGISTER TO
SET UP OPERATING MODE, ANALOG INPUT
AND OUTPUT CONFIGURATION
SET SEQ0 = SEQ1 = 0. SELECT THE DESIRED
CHANNEL TO CONVERT ON (ADD1 TO ADD0).
ISSUE CONVST PULSE TO INITIATE A CONVERSION
ON THE SELECTED CHANNEL.
INITIATE A READ CYCLE TO READ THE DATA
FROM THE SELECTED CHANNEL.
Pseudo Differential Mode
The AD7933/AD7934 can have two pseudo differential pairs by
setting the MODE0 and MODE1 bits in the control register to 1
and 0, respectively. VIN+ is connected to the signal source and
must have an amplitude of VREF (or 2 × VREF depending on the
range chosen) to make use of the full dynamic range of the part.
A dc input is applied to the VIN− pin. The voltage applied to this
input provides an offset from ground or a pseudo ground for
the VIN+ input. The benefit of pseudo differential inputs is that
they separate the analog input signal ground from the ADC
ground, allowing the cancellation of dc common-mode
voltages. Typically, this range can extend to −0.3 V to +0.7 V
when VDD = 3 V, or −0.3 V to +1.8 V when VDD = 5 V. Figure 29
shows a connection diagram for pseudo differential mode.
INITIATE A WRITE CYCLE TO SELECT THE NEXT
CHANNEL TO BE CONVERTED ON BY
CHANGING THE VALUES OF BITS ADD2 TO ADD0
IN THE CONTROL REGISTER. SEQ0 = SEQ1 = 0.
03713-038
220Ω
VIN+
3.75V
2.5V
1.25V
03713-035
440Ω
GND
03713-037
V+
Figure 30. Traditional Multichannel Operation Flow Chart
Using the Sequencer: Consecutive Sequence
(SEQ0 = 1, SEQ1 = 1)
A sequence of consecutive channels can be converted beginning
with Channel 0 and ending with a final channel selected by
writing to the ADD1 and ADD0 bits in the control register. This
is done by setting the SEQ0 and SEQ1 bits in the control
register both to 1. Once the control register is written to, the
next conversion is on Channel 0, then Channel 1, and so on
until the channel selected by the Address Bit ADD1 and Address
Bit ADD0 is reached. The ADC then returns to Channel 0 and
Rev. B | Page 21 of 32
�AD7933/AD7934
starts the sequence again. The WR input must be kept high to
ensure that the control register is not accidentally overwritten
and the sequence interrupted. This pattern continues until the
AD7933/AD7934 is written to. Figure 31 shows the flowchart of
the consecutive sequence mode.
The performance of the part with different reference values is
shown in Figure 9 to Figure 11. The value of the reference sets
the analog input span and the common-mode voltage range.
Errors in the reference source result in gain errors in the
AD7933/AD7934 transfer function and add to the specified
full-scale errors on the part.
POWER ON
Table 12 lists suitable voltage references available from Analog
Devices that can be used. Figure 33 shows a typical connection
diagram for an external reference.
WRITE TO THE CONTROL REGISTER TO
SET UP OPERATING MODE, ANALOG INPUT
AND OUTPUT CONFIGURATION SELECT
FINAL CHANNEL (ADD1 AND ADD0) IN
CONSECUTIVE SEQUENCE.
SET SEQ0 = 1 SEQ1 = 1.
Table 12. Examples of Suitable Voltage References
Reference
AD780
ADR421
ADR420
03713-039
CONTINUOUSLY CONVERT ON A CONSECUTIVE
SEQUENCE OF CHANNELS FROM CHANNEL 0
UP TO AND INCLUDING THE PREVIOUSLY
SELECTED FINAL CHANNEL ON ADD1 AND ADD0
WITH EACH CONVST PULSE.
Figure 31. Consecutive Sequence Mode Flow Chart
Output
Voltage (V)
2.5/3
2.5
2.048
Initial Accuracy
(% maximum)
0.04
0.04
0.05
Operating
Current (μA)
1000
500
500
REFERENCE
BUFFER
ADC
AD7933/
AD7934
03713-040
REFERENCE
VREFIN/
VREFOUT
Figure 32. Internal Reference Circuit Block Diagram
Alternatively, an external reference can be applied to the
VREFIN/VREFOUT pin of the AD7933/AD7934. An external
reference input is selected by setting the REF bit in the internal
control register to 0. The external reference input range is 0.1 V
to VDD. It is important to ensure that, when choosing the
reference value, the maximum analog input range (VIN MAX) is
never greater than VDD + 0.3 V to comply with the maximum
ratings of the device. For example, if operating in differential
mode and the reference is sourced from VDD, the 0 V to 2 × VREF
range cannot be used. This is because the analog input signal
range now extends to 2 × VDD, which exceeds the maximum
rating conditions. In the pseudo differential modes, the user
must ensure that VREF + VIN− ≤ VDD when using the 0 V to VREF
range, or when using the 2 × VREF range that 2 × VREF + VIN− ≤ VDD.
AD7933/
AD7934*
AD780
NC
VDD
0.1µF
10nF
0.1µF
1
O/P SELECT 8
2
+VIN
3
TEMP
VOUT 6
4
GND
TRIM 5
7
NC
VREF
NC
2.5V
NC
0.1µF
NC = NO CONNECT
*ADDITIONAL PINS OMITTED FOR CLARITY.
03713-041
The AD7933/AD7934 can operate with either the on-chip
reference or an external reference. The internal reference is
selected by setting the REF bit in the internal control register to 1.
A block diagram of the internal reference circuitry is shown in
Figure 32. The internal reference circuitry includes an on-chip
2.5 V band gap reference and a reference buffer. When using the
internal reference, decouple the VREFIN/VREFOUT pin to AGND with a
0.47 μF capacitor. This internal reference not only provides the
reference for the analog-to-digital conversion, but it can also be
used externally in the system. It is recommended that the
reference output is buffered using an external precision op amp
before applying it anywhere in the system.
Figure 33. Typical VREF Connection Diagram
Digital Inputs
The digital inputs applied to the AD7933/AD7934 are not
limited by the maximum ratings that limit the analog inputs.
Instead, the digital inputs applied can go to 7 V and are not
restricted by the VDD + 0.3 V limit that is on the analog inputs.
Another advantage of the digital inputs not being restricted by
the VDD + 0.3 V limit is the fact that power supply sequencing
issues are avoided. If any of these inputs are applied before VDD,
there is no risk of latch-up as there would be on the analog inputs
if a signal greater than 0.3 V was applied prior to VDD.
VDRIVE Input
The AD7933/AD7934 have a VDRIVE feature. VDRIVE controls the
voltage at which the parallel interface operates. VDRIVE allows the
ADC to easily interface to 3 V and 5 V processors.
For example, if the AD7933/AD7934 are operated with a VDD
of 5 V, and the VDRIVE pin is powered from a 3 V supply, the
AD7933/AD7934 have better dynamic performance with a
VDD of 5 V while still being able to interface to 3 V processors.
Ensure that VDRIVE does not exceed VDD by more than 0.3 V (see
the Absolute Maximum Ratings section).
In all cases, the specified reference is 2.5 V.
Rev. B | Page 22 of 32
�AD7933/AD7934
PARALLEL INTERFACE
At the end of the conversion, BUSY goes low and can be used to
activate an interrupt service routine. The CS and RD lines are
then activated in parallel to read the 10 bits or 12 bits of
conversion data. When power supplies are first applied to the
device, a rising edge on CONVST is necessary to put the trackand-hold into track. The acquisition time of 125 ns minimum
must be allowed before CONVST is brought low to initiate a
conversion. The ADC then goes into hold on the falling edge of
CONVST and back into track on the 13th rising edge of CLKIN
after this (see Figure 34). When operating the device in
autoshutdown or autostandby mode, where the ADC powers
down at the end of each conversion, a rising edge on the
CONVST signal is used to power up the device.
The AD7933/AD7934 have a flexible, high speed, parallel
interface. This interface is 10 bits (AD7933) or 12 bits (AD7934)
wide and is capable of operating in either word (W/B tied high)
or byte (W/B tied low) mode. The CONVST signal is used to
initiate conversions and, when operating in autoshutdown or
autostandby mode, it is used to initiate power-up.
A falling edge on the CONVST signal is used to initiate
conversions, and it also puts the ADC track-and-hold into
track. Once the CONVST signal goes low, the BUSY signal goes
high for the duration of the conversion. In between conversions,
CONVST must be brought high for a minimum time of t1. This
must happen after the 14th falling edge of CLKIN; otherwise, the
conversion is aborted and the track-and-hold goes back into track.
B
t1
A
CONVST
1
CLKIN
2
3
4
tCONVERT
5
12
13
14
t2
t20
BUSY
t3
t9
INTERNAL
TRACK/HOLD
tACQUISITION
CS
t10
RD
t12
t13
DB0 TO DB11
THREE-STATE
t11
t14
DATA
THREE-STATE
tQUIET
DB0 TO DB11
OLD DATA
DATA
Figure 34. AD7933/AD7934 Parallel Interface—Conversion and Read Cycle Timing in Word Mode (W/B = 1)
Rev. B | Page 23 of 32
03713-004
WITH CS AND RD TIED LOW
�AD7933/AD7934
Reading Data from the AD7933/AD7934
The CS and RD signals are gated internally and the level is
triggered active low. In either word mode or byte mode, CS and
RD can be tied together as the timing specifications for t10 and
t11 are 0 ns minimum. This means the bus is constantly driven
by the AD7933/AD7934.
With the W/B pin tied logic high, the AD7933/AD7934
interface operates in word mode. In this case, a single read
operation from the device accesses the conversion data-word on
Pin DB0 to Pin DB11 (12-bit word) and Pin DB2 to DB11
(10-bit word). The DB8/HBEN pin assumes its DB8 function.
With the W/B pin tied to logic low, the AD7933/AD7934
interface operates in byte mode. In this case, the DB8/HBEN
pin assumes its HBEN function.
The data is placed onto the data bus a time t13 after both CS and
RD go low. The RD rising edge can be used to latch data out of
the device. After a time, t14, the data lines become three-stated.
Alternatively, CS and RD can be tied permanently low, and the
conversion data is valid and placed onto the data bus a time, t9,
before the falling edge of BUSY.
Conversion data from the AD7933/AD7934 must be accessed in
two read operations with eight bits of data provided on DB0 to
DB7 for each of the read operations. The HBEN pin determines
whether the read operation accesses the high byte or the low
byte of the 12- or 10-bit word. For a low byte read, DB0 to DB7
provide the eight LSBs of the 12-bit word. For 10-bit operation,
the two LSBs of the low byte are 0s and are followed by six bits
of conversion data. For a high byte read, DB0 to DB3 provide the
four MSBs of the 12-/10-bit word. DB4 and DB5 of the high byte
provide the Channel ID. DB6 and DB7 are always 0.
Note that if RD is pulsed during the conversion time, this
causes a degradation in linearity performance of approximately
0.25 LSB. Reading during conversion, by way of tying CS and
RD low, does not cause any degradation.
Figure 34 shows the read cycle timing diagram for a 12- or
10-bit transfer. When operating in word mode, the HBEN input
does not exist and only the first read operation is required to
access data from the device. When operating in byte mode, the
two read cycles shown in Figure 35 are required to access the
full data-word from the device.
HBEN/DB8
t15
t16
t15
t16
CS
t11
RD
t13
DB0 TO DB7
t17
t12
t14
LOW BYTE
HIGH BYTE
03713-005
t10
Figure 35. AD7933/AD7934 Parallel Interface—Read Cycle Timing for Byte Mode Operation (W/B = 0)
Rev. B | Page 24 of 32
�AD7933/AD7934
Writing Data to the AD7933/AD7934
Figure 36 shows the write cycle timing diagram of the
AD7933/AD7934 in word mode. When operating in word
mode, the HBEN input does not exist and only one write
operation is required to write the word of data to the device.
Provide data on DB0 to DB11. When operating in byte mode,
the two write cycles shown in Figure 37 are required to write the
full data-word to the AD7933/AD7934. In Figure 37, the first
write transfers the lower eight bits of the data-word from DB0
to DB7, and the second write transfers the upper four bits of the
data-word.
With W/B tied logic high, a single write operation transfers the
full data-word on DB0 to DB11 to the control register on the
AD7933/AD7934. The DB8/HBEN pin assumes its DB8
function. Data written to the AD7933/AD7934 should be
provided on the DB0 to DB11 inputs, with DB0 being the LSB
of the data-word. With W/B tied logic low, the AD7933/AD7934
requires two write operations to transfer a full 12-bit word.
DB8/HBEN assumes its HBEN function. Data written to the
AD7933/AD7934 should be provided on the DB0 to DB7
inputs. HBEN determines whether the byte written is high byte
or low byte data. The low byte of the data-word has DB0 being
the LSB of the full data-word. For the high byte write, HBEN
should be high and the data on the DB0 input should be Data
Bit 8 of the 12-bit word.
When writing to the AD7933/AD7934, the top four bits in the
high byte must be 0s.
The data is latched into the device on the rising edge of WR.
The data needs to be set up a time, t7, before the WR rising
edge and held for a time, t8, after the WR rising edge. The CS
and WR signals are gated internally. CS and WR can be tied
together as the timing specifications for t4 and t5 are 0 ns
minimum (assuming CS and RD have not already been tied
together).
CS
t5
t6
t8
t7
DB0 TO DB11
03713-002
t4
WR
DATA
Figure 36. AD7933/AD7934 Parallel Interface—Write Cycle Timing for Word Mode Operation (W/B = 1)
HBEN/DB8
t18
t19
t18
t19
CS
WR
t5
t7
DB0 TO DB7
t17
t6
t8
LOW BYTE
HIGH BYTE
03713-003
t4
Figure 37. AD7933/AD7934 Parallel Interface—Write Cycle Timing for Byte Mode Operation (W/B = 0)
Rev. B | Page 25 of 32
�AD7933/AD7934
POWER MODES OF OPERATION
Autostandby (PM1 = 1; PM0 = 0)
The AD7933/AD7934 have four different power modes of
operation. These modes are designed to provide flexible power
management options. Different options can be chosen to optimize
the power dissipation/throughput rate ratio for differing applications. The mode of operation is selected by PM1 and PM0, the
power management bits, in the control register (see Table 9 for
details). When power is first applied to the AD7933/AD7934, an
on-chip, power-on reset circuit ensures the default power-up
condition is normal mode.
In this mode of operation, the AD7933/AD7934 automatically
enter standby mode at the end of each conversion, shown as
Point A in Figure 34. When this mode is entered, all circuitry
on the AD7933/AD7934 is powered down except for the
reference and reference buffer. The track-and-hold goes into
hold at this point and remains in hold as long as the device is in
standby. The part remains in standby until the next rising edge
of CONVST powers up the device. The power-up time required
depends on whether the internal or external reference is used.
With an external reference, the power-up time required is a
minimum of 600 ns, while using the internal reference, the
power-up time required is a minimum of 7 μs. The user should
ensure this power-up time has elapsed before initiating another
conversion as shown in Figure 38. This rising edge of CONVST
also places the track-and-hold back into track mode.
Note that, after power-on, track-and-hold is in hold mode, and
the first rising edge of CONVST places the track-and-hold into
track mode.
Normal Mode (PM1 = PM0 = 0)
This mode is intended for the fastest throughput rate performance
wherein the user does not have to worry about any power-up
times because the AD7933/AD7934 remain fully powered up at
all times. At power-on reset, this mode is the default setting in
the control register.
Autoshutdown (PM1 = 0; PM0 = 1)
In this mode of operation, the AD7933/AD7934 automatically
enter full shutdown at the end of each conversion, shown at
Point A in Figure 34 and Figure 38. In shutdown mode, all
internal circuitry on the device is powered down. The part
retains information in the control register during shutdown.
The track-and-hold also goes into hold at this point and remains in
hold as long as the device is in shutdown. The AD7933/AD7934
remains in shutdown mode until the next rising edge of CONVST
(see Point B in Figure 34 and Figure 38). In order to keep the
device in shutdown for as long as possible, CONVST should
idle low between conversions, as shown in Figure 38. On this
rising edge, the part begins to power up and the track-and-hold
returns to track mode. The power-up time required is 10 ms
minimum regardless of whether the user is operating with the
internal or external reference. The user should ensure that the
power-up time has elapsed before initiating a conversion.
Full Shutdown Mode (PM1 = 1; PM0 = 1)
When this mode is entered, all circuitry on the AD7933/AD7934
is powered down upon completion of the write operation, that
is, on the rising edge of WR. The track-and-hold enters hold
mode at this point. The part retains the information in the
control register while in shutdown. The AD7933/AD7934
remain in full shutdown mode, with the track-and-hold in hold
mode, until the power management bits (PM1 and PM0) in the
control register are changed. If a write to the control register
occurs while the part is in full shutdown mode, and the power
management bits are changed to PM0 = PM1 = 0 (normal
mode), the part begins to power up on the WR rising edge, and
the track-and-hold returns to track. To ensure the part is fully
powered up before a conversion is initiated, the power-up time
of 10 ms minimum should be allowed before the CONVST
falling edge; otherwise, invalid data is read.
Note that all power-up times quoted apply with a 470 nF
capacitor on the VREFIN pin.
tPOWER-UP
B
A
CONVST
1
14
1
14
03713-048
CLKIN
BUSY
Figure 38. Autoshutdown/Autostandby Mode
Rev. B | Page 26 of 32
�AD7933/AD7934
POWER vs. THROUGHPUT RATE
Figure 40 shows a plot of the power vs. the throughput rate
when operating in normal mode for both VDD = 5 V and 3 V.
In both plots, the figures apply when using the internal
reference. If an external reference is used, the power-up time
reduces to 600 ns; therefore, the AD7933/AD7934 remains in
standby for a greater time in every cycle. Additionally, the
current consumption, when converting, should be lower than
the specified maximum of 2.7 mA with VDD = 5 V, or 2.0 mA
with VDD = 3 V, respectively.
1.8
TA = 25°C
1.6
1.4
10
TA = 25°C
9
8
VDD = 5V
7
POWER (mW)
6
5
4
VDD = 3V
3
2
03713-043
A considerable advantage of powering the ADC down after a
conversion is that the power consumption of the part is
significantly reduced at lower throughput rates. When using the
different power modes, the AD7933/AD7934 are only powered
up for the duration of the conversion. Therefore, the average
power consumption per cycle is significantly reduced. Figure 39
shows a plot of power vs. throughput rate when operating in
autostandby mode for both VDD = 5 V and 3 V. For example, if
the device runs at a throughput rate of 10 kSPS, the overall cycle
time is 100 μs. If the maximum CLKIN frequency of 25.5 MHz
is used, the conversion time accounts for only 0.525 μs of the
overall cycle time while the AD7933/AD7934 remains in
standby mode for the remainder of the cycle.
1
0
0
200
400
600
800
1000
THROUGHPUT (kSPS)
1200
1400
1600
Figure 40. Power vs. Throughput in Normal Mode Using Internal Reference
MICROPROCESSOR INTERFACING
AD7933/AD7934 to ADSP-21xx Interface
Figure 41 shows the AD7933/AD7934 interfaced to the
ADSP-21xx series of DSPs as a memory-mapped device.
A single wait state may be necessary to interface the AD7933/
AD7934 to the ADSP-21xx, depending on the clock speed of
the DSP. The wait state can be programmed via the data memory
wait state control register of the ADSP-21xx (see the ADSP-21xx
family User’s Manual for details). The following instruction
reads from the AD7933/AD7934:
VDD = 5V
MR = DM (ADC)
where ADC is the address of the AD7933/AD7934.
1.0
DSP/USER SYSTEM
0.8
VDD = 3V
A0 TO A15
AD7933/
AD7934*
ADSP-21xx*
0.4
0.2
0
CONVST
ADDRESS BUS
0
20
40
60
80
100
THROUGHPUT (kSPS)
120
ADDRESS
DECODER
DMS
IRQ2
140
Figure 39. Power vs. Throughput in
Autostandby Mode Using Internal Reference
CS
BUSY
WR
WR
RD
RD
DB0 TO DB11
D0 TO D23
DATA BUS
*ADDITIONAL PINS OMITTED FOR CLARITY.
Figure 41. Interfacing to the ADSP-21xx
Rev. B | Page 27 of 32
03713-044
0.6
03713-042
POWER (mW)
1.2
�AD7933/AD7934
DSP/USER SYSTEM
AD7933/AD7934 to ADSP-21065L Interface
Figure 42 shows a typical interface between the AD7933/AD7934
and the ADSP-21065L SHARC® processor. This interface is an
example of one of three DMA handshake modes. The MSX
control line is actually three memory select lines. Internal
ADDR25 to 24 are decoded into MS3 to 0, these lines are then
asserted as chip selects. The DMAR1 (DMA Request 1) is used
in this setup as the interrupt to signal the end of the conversion.
The rest of the interface is standard handshaking operation.
A0 TO A15
TMS32020/
TMS320C25/
TMS320C50*
IS
CONVST
ADDRESS BUS
AD7933/
AD7934*
ADDRESS
EN DECODER
CS
READY
TMS320C25
ONLY
MSC
STRB
WR
R/W
DSP/USER SYSTEM
INTX
BUSY
DMD0 TO DMD15
MSX
AD7933/
AD7934*
ADDRESS
LATCH
*ADDITIONAL PINS OMITTED FOR CLARITY.
Figure 43. Interfacing to TMS32020/TMS320C25/TMS320C5x
ADDRESS BUS
ADSP-21065L*
ADDRESS
DECODER
DMAR1
CS
AD7933/AD7934 to 80C186 Interface
BUSY
Figure 44 shows the AD7933/AD7934 interfaced to the 80C186
microprocessor. The 80C186 DMA controller provides two
independent, high speed DMA channels where data transfers
can occur between memory and I/O spaces. Each data transfer
consumes two bus cycles, one cycle to fetch data and the other
to store data. After the AD7933/AD7934 finish a conversion,
the BUSY line generates a DMA request to Channel 1 (DRQ1).
Because of the interrupt, the processor performs a DMA read
operation, which also resets the interrupt latch. Sufficient
priority must be assigned to the DMA channel to ensure that
the DMA request is serviced before the completion of the next
conversion.
RD
RD
WR
WR
DATA BUS
*ADDITIONAL PINS OMITTED FOR CLARITY.
03713-045
DB0 TO DB11
D0 TO D31
DB11 TO DB0
DATA BUS
03713-046
CONVST
ADDRESS BUS
Figure 42. Interfacing to the ADSP-21065L
AD7933/AD7934 to TMS32020, TMS320C25, and
TMS320C5x Interface
Parallel interfaces between the AD7933/AD7934 and the
TMS32020, TMS320C25 and TMS320C5x family of DSPs are
shown in Figure 43. Select the memory-mapped address for the
AD7933/AD7934 to fall in the I/O memory space of the DSPs.
The parallel interface on the AD7933/AD7934 is fast enough to
interface to the TMS32020 with no extra wait states. If high
speed glue logic, such as 74AS devices, is used to drive the
RD and the WR lines when interfacing to the TMS320C25, no
wait states are necessary. However, if slower logic is used, data
accesses may be slowed sufficiently when reading from, and
writing to, the part to require the insertion of one wait state.
Extra wait states are necessary when using the TMS320C5x at
their fastest clock speeds (see the TMS320C5x User’s Guide
for details).
MICROPROCESSOR/
USER SYSTEM
AD0 TO AD15
A16 TO A19
ALE
ADDRESS/DATA BUS
CONVST
ADDRESS
LATCH
AD7933/
AD7934*
ADDRESS BUS
80C186*
ADDRESS
DECODER
DRQ1
Q
CS
R
S
BUSY
RD
RD
WR
WR
DATA BUS DB0 TO DB11
Data is read from the ADC using the following instruction:
*ADDITIONAL PINS OMITTED FOR CLARITY.
IN D, ADC
Figure 44. Interfacing to the 80C186
where:
D is the data memory address.
ADC is the AD7933/AD7934 address.
Rev. B | Page 28 of 32
03713-047
ADDR 0 TO ADDR23
RD
�AD7933/AD7934
APPLICATION HINTS
GROUNDING AND LAYOUT
Design the printed circuit board that houses the AD7933/AD7934
so that the analog and digital sections are separated and confined to certain areas of the board. This facilitates the use of
ground planes that can be easily separated. Generally, a minimum
etch technique is best for ground planes because it offers
optimum shielding. Join digital and analog ground planes in
only one place, establishing a star ground point connection as
close as possible to the ground pins on the AD7933/AD7934.
Avoid running digital lines under the device because this
couples noise onto the die. However, the analog ground plane
should be allowed to run under the AD7933/AD7934 to avoid
noise coupling. To provide low impedance paths and reduce the
effects of glitches on the power supply line, use as large a trace
as possible on the power supply lines to the AD7933/AD7934.
Shield fast switching signals, such as clocks, with digital ground
to avoid radiating noise to other sections of the board, and
never run clock signals near the analog inputs. Avoid crossover
of digital and analog signals. To reduce the effects of feedthrough
through the board, run traces on opposite sides of the board at
right angles to each other. A microstrip technique is by far the
best, but it is not always possible with a double-sided board. In
this technique, the component side of the board is dedicated to
ground planes, while signals are placed on the solder side.
Good decoupling is also important. Decouple all analog
supplies with 10 μF tantalum capacitors in parallel with 0.1 μF
capacitors to GND. To achieve the best performance from these
decoupling components, they must be placed as close as
possible to the device, ideally right up against the device. The
0.1 μF capacitors should have a low effective series resistance
(ESR) and effective series inductance (ESI), such as the
common ceramic types or surface-mount types. These types of
capacitors provide a low impedance path to ground at high
frequencies to handle transient currents due to internal logic
switching.
EVALUATING THE AD7933/AD7934
PERFORMANCE
The recommended layout for the AD7933/AD7934 is outlined
in the evaluation board documentation. The evaluation board
package includes a fully assembled and tested evaluation board,
documentation, and software for controlling the board from the
PC via the evaluation board controller. The evaluation board
controller can be used in conjunction with the AD7933/AD7934
evaluation board, as well as many other Analog Devices evaluation boards ending in the CB designator, to demonstrate and
evaluate the ac and dc performance of the AD7933/AD7934.
The software allows the user to perform ac (fast Fourier transform)
and dc (histogram of codes) tests on the AD7933/AD7934. The
software and documentation are on the CD that ships with the
evaluation board.
Rev. B | Page 29 of 32
�AD7933/AD7934
OUTLINE DIMENSIONS
9.80
9.70
9.60
28
15
4.50
4.40
4.30
1
6.40 BSC
14
PIN 1
0.65
BSC
0.15
0.05
0.30
0.19
COPLANARITY
0.10
1.20 MAX
SEATING
PLANE
0.20
0.09
8°
0°
0.75
0.60
0.45
COMPLIANT TO JEDEC STANDARDS MO-153-AE
Figure 45. 28-Lead Thin Shrink Small Outline Package [TSSOP]
(RU-28)
Dimensions shown in millimeters
ORDERING GUIDE
Model
AD7933BRU
AD7933BRU-REEL
AD7933BRU-REEL7
AD7933BRUZ 2
AD7933BRUZ-REEL72
AD7934BRU
AD7934BRU-REEL
AD7934BRU-REEL7
AD7934BRUZ2
AD7934BRUZ-REEL72
EVAL-AD7933CB 3
EVAL-AD7934CB3
EVAL-CONTROL-BRD2 4
Temperature Range
−40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
−40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
Linearity Error (LSB) 1
±1
±1
±1
±1
±1
±1
±1
±1
±1
±1
1
Package Description
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
28-Lead TSSOP
Evaluation Board
Evaluation Board
Controller Board
Package Option
RU-28
RU-28
RU-28
RU-28
RU-28
RU-28
RU-28
RU-28
RU-28
RU-28
Linearity error here refers to integral linearity error.
Z = Pb-free part.
3
This can be used as a standalone evaluation board or in conjunction with the Evaluation Board Controller for evaluation/demonstration purposes.
4
The evaluation board controller is a complete unit that allows a PC to control and communicate with all Analog Devices evaluation boards ending in the letters CB.
The following needs to be ordered to obtain a complete evaluation kit: the ADC evaluation board (for example, EVAL-AD7934CB), the EVAL-CONTROL-BRD2, and a
12 V ac transformer. See the relevant evaluation board data sheet for more details.
2
Rev. B | Page 30 of 32
�AD7933/AD7934
NOTES
Rev. B | Page 31 of 32
�AD7933/AD7934
NOTES
©2005–2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D03713-0-2/07(B)
Rev. B | Page 32 of 32
�
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