AD AD5360 16-channel, 16-/14-bit, serial input, voltage-output dac Datasheet

16-Channel, 16-/14-Bit,
Serial Input, Voltage-Output DAC
AD5360/AD5361
FEATURES
SPI-compatible serial interface
2.5 V to 5.5 V digital interface
Digital reset (RESET)
Clear function to user-defined SIGGNDx
Simultaneous update of DAC outputs
16-channel DAC in 52-lead LQFP and 56-lead LFCSP
packages
Guaranteed monotonic to 16/14 bits
Nominal output voltage range of −10 V to +10 V
Multiple output spans available
Temperature monitoring function
Channel monitoring multiplexer
GPIO function
System calibration function allowing user-programmable
offset and gain
Channel grouping and addressing features
Data error checking feature
APPLICATIONS
Instrumentation
Industrial control systems
Level setting in automatic test equipment (ATE)
Variable optical attenuators (VOA)
Optical line cards
FUNCTIONAL BLOCK DIAGRAM
DVCC
TEMP_OUT
PEC
MON_IN0
MON_IN1
VDD
TEMP
SENSOR
8
CONTROL
REGISTER
VOUT0 TO
VOUT15
6
MUX
8
SCLK
TO
MUX 2s
n
n
n
··
·
··
·
n
·
··
·
·
·n
·
·
·
··
·
X1 REGISTER
n
n
M REGISTER
n
A/B
MUX
n
C REGISTER
n
SERIAL
INTERFACE
8
M REGISTER
BIN/2SCOMP
SDI
A/B SELECT
REGISTER
14
X1 REGISTER
2
SYNC
LDAC
n
n
GPIO
REGISTER
AGND DGND
n = 16 FOR AD5360
n = 14 FOR AD5361
n
MON_OUT
GPIO
VSS
··
·
··
·
A/B
MUX
OFS0
REGISTER
14
GROUP 0
BUFFER
OFFSET
DAC 0
BUFFER
X2A REGISTER
X2B REGISTER
MUX
2
·
·
·
·
·
·
·
·
·
·
X2A REGISTER
X2B REGISTER
n
MUX n
2
n
DAC 0
REGISTER
·
·
·
·
·
·
DAC 7
REGISTER
n
OUTPUT BUFFER
AND POWERDOWN CONTROL
VOUT0
DAC 0
·
·
·
·
·
·
·
·
·
·
·
·
VOUT2
OUTPUT BUFFER
AND POWERDOWN CONTROL
VOUT7
DAC 7
C REGISTER
BUSY
CLR
n
STATE
MACHINE
n
n
AD5360/
AD5361
n
n
8
TO
MUX 2s
n
n
X1 REGISTER
n
M REGISTER
n
·
·
··
··
·
··
·
··
n
X1 REGISTER
n
M REGISTER
C REGISTER
A/B
MUX
n
C REGISTER
··
·
··
·
n
VOUT4
VOUT5
VOUT6
SIGGND0
·
·
·
··
·
A/B
MUX
GROUP 1
OFS1
REGISTER
n
OFFSET
DAC 1
BUFFER
X2A REGISTER
X2B REGISTER
·
·
·
·
·
·
X2A REGISTER
X2B REGISTER
MUX
2
·
·
·
·
·
·
n
MUX n
2
n
DAC 0
REGISTER
·
·
·
·
·
n
DAC 7
REGISTER
OUTPUT BUFFER
AND POWERDOWN CONTROL
VOUT8
DAC 0
·
·
·
·
·
·
·
·
·
·
·
·
VOUT10
OUTPUT BUFFER
AND POWERDOWN CONTROL
VOUT15
DAC 7
VOUT9
VOUT11
VOUT12
VOUT13
VOUT14
SIGGND1
n
05761-007
n
A/B SELECT
REGISTER
VOUT3
VREF1
14
8
VOUT1
n
SDO
RESET
VREF0
Figure 1.
Rev. A
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rights of third parties that may result from its use. Specifications subject to change without notice. No
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Fax: 781.461.3113 ©2007–2008 Analog Devices, Inc. All rights reserved.
AD5360/AD5361
TABLE OF CONTENTS
Features .............................................................................................. 1
Reset Function ............................................................................ 19
Applications ....................................................................................... 1
Clear Function ............................................................................ 19
Functional Block Diagram .............................................................. 1
BUSY and LDAC Functions...................................................... 19
Revision History ............................................................................... 2
BIN/2SCOMP PIN ..................................................................... 19
General Description ......................................................................... 3
Temperature Sensor ................................................................... 19
Specifications..................................................................................... 4
Monitor Function ....................................................................... 20
AC Characteristics........................................................................ 5
GPIO Pin ..................................................................................... 20
Timing Characteristics ................................................................ 6
Power-Down Mode .................................................................... 20
Absolute Maximum Ratings............................................................ 9
Thermal Monitoring Function ................................................. 20
ESD Caution .................................................................................. 9
Toggle Mode................................................................................ 20
Pin Configuration and Function Descriptions ........................... 10
Serial Interface ................................................................................ 21
Typical Performance Characteristics ........................................... 12
SPI Write Mode .......................................................................... 21
Terminology .................................................................................... 14
SPI Readback Mode ................................................................... 22
Functional Description .................................................................. 15
Register Update Rates ................................................................ 22
DAC Architecture ....................................................................... 15
Packet Error Checking ............................................................... 22
Channel Groups .......................................................................... 15
Channel Addressing and Special Modes ................................. 23
A/B Registers Gain/Offset Adjustment ................................... 16
Special Function Mode .............................................................. 24
Offset DACs ................................................................................ 16
Power Supply Decoupling ......................................................... 25
Output Amplifier ........................................................................ 17
Power Supply Sequencing ......................................................... 25
Transfer Function ....................................................................... 17
Interfacing Examples...................................................................... 26
Reference Selection .................................................................... 17
Outline Dimensions ....................................................................... 27
Calibration ................................................................................... 18
Ordering Guide .......................................................................... 27
REVISION HISTORY
2/08—Rev. 0 to Rev. A
Added LFCSP Package ....................................................... Universal
Change to DC Crosstalk Parameter ............................................... 4
Change to Power Dissipation Unloaded (P) Parameter .............. 5
Added t23 Parameter ......................................................................... 6
Change to Figure 4 ........................................................................... 7
Change to Table 5 Summary ........................................................... 9
Added Figure 8 ................................................................................ 10
Changes to Table 6 .......................................................................... 10
Changes to Calibration Section .................................................... 18
Changes to Reset Function Section .............................................. 19
Added Packet Error Checking Section ........................................ 22
Updated Outline Dimensions ....................................................... 27
Changes to Ordering Guide .......................................................... 27
10/07—Revision 0: Initial Version
Rev. A | Page 2 of 28
AD5360/AD5361
GENERAL DESCRIPTION
The AD5360/AD5361 contain sixteen, 16-/14-bit DACs in a
single 52-lead LQFP or 56-lead LFCSP package. They provide
buffered voltage outputs with a span four times the reference
voltage. The gain and offset of each DAC can be independently
trimmed to remove errors. For even greater flexibility, the device is
divided into two groups of eight DACs, and the output range of
each group can be independently adjusted by an offset DAC.
The AD5360/AD5361 offer guaranteed operation over a wide
supply range with VSS from −4.5 V to −16.5 V and VDD from
+8 V to +16.5 V. The output amplifier headroom requirement
is 1.4 V.
The AD5360/AD5361 have a high speed 4-wire serial interface,
which is compatible with SPI, QSPI™, MICROWIRE™, and DSP
interface standards and can handle clock speeds of up to
50 MHz. All the outputs can be updated simultaneously by
taking the LDAC input low. Each channel has a programmable
gain register and an offset adjust register.
Each DAC output is amplified and buffered on-chip with
respect to an external SIGGNDx input. The DAC outputs can
also be switched to SIGGNDx via the CLR pin.
Rev. A | Page 3 of 28
AD5360/AD5361
SPECIFICATIONS
DVCC = 2.5 V to 5.5 V; VDD = 9 V to 16.5 V; VSS = −16.5 V to −4.5 V; VREF = 5 V; AGND = DGND = SIGGND = 0 V; RL = open circuit;
gain (M), offset (C), and DAC offset registers at default value; all specifications TMIN to TMAX, unless otherwise noted.
Table 1.
Parameter
ACCURACY
Resolution
AD5360
AD5361
Relative Accuracy
AD5360
AD5361
Differential Nonlinearity
Zero-Scale Error
Full-Scale Error
Gain Error
Zero-Scale Error 2
Full-Scale Error2
Span Error of Offset DAC
VOUTx 3 Temperature Coefficient
DC Crosstalk4
REFERENCE INPUTS (VREF0, VREF1)2
VREF Input Current
VREF Range2
SIGGND INPUT (SIGGND0 to SIGGND1) 4
DC Input Impedance
Input Range
SIGGND Gain
OUTPUT CHARACTERISTICS2
Output Voltage Range
Nominal Output Voltage Range
Short-Circuit Current
Load Current
Capacitive Load
DC Output Impedance
MONITOR PIN (MON_OUT)4
Output Impedance
DAC Output at Positive Full-Scale
DAC Output at Negative Full-Scale
Three-State Leakage Current
Continuous Current Limit
DIGITAL INPUTS
Input High Voltage
Input Low Voltage
Input Current
Input Capacitance4
B Version 1
Unit
16
14
Bits
Bits
±4
±1
±1
±15
±20
0.1
1
1
±75
5
180
LSB max
LSB max
LSB max
mV max
mV max
% FSR
LSB typ
LSB typ
mV max
ppm FSR/°C typ
μV max
±10
2/5
μA max
V min/max
Per input; typically ±30 nA
±2% for specified operation
50
±0.5
0.995/1.005
kΩ min
V max
Min/max
Typically 55 kΩ
VSS + 1.4
VDD − 1.4
−10 to +10
15
±1
2200
0.5
V min
V max
V nominal
mA max
mA max
pF max
Ω max
ILOAD = 1 mA
ILOAD = 1 mA
1000
500
100
2
Ω typ
Ω typ
nA typ
mA max
1.7
2.0
0.8
±1
±20
10
V min
V min
V max
μA max
μA max
pF max
Rev. A | Page 4 of 28
Test Conditions/Comments
Guaranteed monotonic by design over temperature
Before calibration
Before calibration
Before calibration
After calibration
After calibration
See the Offset DACS section for details
Includes linearity, offset, and gain drift
Typically 20 μV; measured channel at midscale, full-scale
change on any other channel
VOUTx3 to DVCC, VDD, or VSS
JEDEC compliant
DVCC = 2.5 V to 3.6 V
DVCC = 3.6 V to 5.5 V
DVCC = 2.5 V to 5.5 V
RESET, SYNC, SDI, and SCLK pins
CLR, BIN/2SCOMP, and GPIO pins
AD5360/AD5361
Parameter
DIGITAL OUTPUTS (SDO, BUSY, GPIO, PEC)
Output Low Voltage
Output High Voltage (SDO)
High Impedance Leakage Current
High Impedance Output Capacitance4
TEMPERATURE SENSOR (TEMP_OUT)4
Accuracy
Output Voltage at 25°C
Output Voltage Scale Factor
Output Load Current
Power-On Time
POWER REQUIREMENTS
DVCC
VDD
VSS
Power Supply Sensitivity4
∆ Full Scale/∆ VDD
∆ Full Scale/∆ VSS
∆ Full Scale/∆ DVCC
DICC
IDD
ISS
Power-Down Mode
DICC
IDD
ISS
Power Dissipation
Power Dissipation Unloaded (P)
Junction Temperature
B Version 1
Unit
Test Conditions/Comments
0.5
DVCC − 0.5
±5
10
V max
V min
μA max
pF typ
Sinking 200 μA
Sourcing 200 μA
SDO only
±1
±5
1.46
4.4
200
10
°C typ
°C typ
V typ
mV/°C typ
μA max
ms typ
@ 25°C
−40°C < T < +85°C
2.5/5.5
8/16.5
−4.5/−16.5
V min/max
V min/max
V min/max
−75
−75
−90
2
10
10
dB typ
dB typ
dB typ
mA max
mA max
mA max
5
35
−35
μA typ
μA typ
μA typ
245
130
mW max
°C max
Current source only
To within ±5°C
VCC = 5.5 V, VIH = DVCC, VIL = GND
Outputs unloaded
Outputs unloaded
Bit 0 in the Control Register is 1
VSS = −12 V, VDD = +12 V, DVCC = 2.5 V
TJ = TA + PTOTAL × θJA
1
Temperature range for B version: −40°C to +85°C. Typical specifications are at 25°C.
Specifications are guaranteed for a 5 V reference only.
3
VOUTx refers to any of VOUT0 to VOUT15.
4
Guaranteed by design and characterization, not production tested.
2
AC CHARACTERISTICS
DVCC = 2.5 V; VDD = 15 V; VSS = −15 V; VREF = 5 V; AGND = DGND = SIGGND = 0 V; CL = 200 pF; RL = 10 kΩ; gain (M), offset (C), and
DAC offset registers at default value; all specifications TMIN to TMAX, unless otherwise noted.
Table 2.
Parameter
DYNAMIC PERFORMANCE1
Output Voltage Settling Time
Slew Rate
Digital-to-Analog Glitch Energy
Glitch Impulse Peak Amplitude
Channel-to-Channel Isolation
DAC-to-DAC Crosstalk
Digital Crosstalk
Digital Feedthrough
Output Noise Spectral Density @ 10 kHz
1
B Version 1
Unit
Test Conditions/Comments
20
30
1
5
10
100
10
0.2
0.02
250
μs typ
μs max
V/μs typ
nV-s typ
mV max
dB typ
nV-s typ
nV-s typ
nV-s typ
nV/√Hz typ
Full-scale change
DAC latch contents alternately loaded with all 0s and all 1s
Guaranteed by design and characterization, not production tested.
Rev. A | Page 5 of 28
VREF0, VREF1 = 2 V p-p, 1 kHz
Effect of input bus activity on DAC output under test
VREF0 = VREF1 = 0 V
AD5360/AD5361
TIMING CHARACTERISTICS
DVCC = 2.5 V to 5.5 V; VDD = 9 V to 16.5 V; VSS = −8 V to −16.5 V; VREF = 5 V; AGND = DGND = SIGGND = 0 V; CL = 200 pF to GND;
RL = open circuit; gain (M), offset (C), and DAC offset registers at default values; all specifications TMIN to TMAX, unless otherwise noted.
Table 3. SPI Interface (See Figure 4 and Figure 5)
Parameter 1, 2
t1
t2
t3
t4
t5
t6
t7
t8
t9 3
t10
t11
t12
t13
t14
t15
t16
t17
t18
t19
t20
t21
t22 4
t23
Limit at TMIN, TMAX
20
8
8
11
20
10
5
5
42
1/1.5
600
20
10
3
0
3
20/30
140
30
400
270
25
80
Unit
ns min
ns min
ns min
ns min
ns min
ns min
ns min
ns min
ns max
μs typ/max
ns max
ns min
ns min
μs max
ns min
μs max
μs typ/max
ns max
ns min
μs max
ns min
ns max
ns max
Description
SCLK cycle time
SCLK high time
SCLK low time
SYNC falling edge to SCLK falling edge setup time
Minimum SYNC high time
24th SCLK falling edge to SYNC rising edge
Data setup time
Data hold time
SYNC rising edge to BUSY falling edge
BUSY pulse width low (single-channel update); see Table 8
Single-channel update cycle time
SYNC rising edge to LDAC falling edge
LDAC pulse width low
BUSY rising edge to DAC output response time
BUSY rising edge to LDAC falling edge
LDAC falling edge to DAC output response time
DAC output settling time
CLR/RESET pulse activation time
RESET pulse width low
RESET time indicated by BUSY low
Minimum SYNC high time in readback mode
SCLK rising edge to SDO valid
RESET rising edge to BUSY falling edge
1
Guaranteed by design and characterization, not production tested.
All input signals are specified with tr = tf = 2 ns (10% to 90% of DVCC) and timed from a voltage level of 1.2 V.
3
This is measured with the load circuit shown in Figure 2.
4
This is measured with the load circuit shown in Figure 3.
2
200µA
IOL
DVCC
VOL
VOH (MIN) – VOL (MAX)
2
CL
50pF
200µA
Figure 2. Load Circuit for BUSY Timing Diagram
IOH
Figure 3. Load Circuit for SDO Timing Diagram
Rev. A | Page 6 of 28
05761-009
CL
50pF
05761-008
TO
OUTPUT
PIN
TO OUTPUT
PIN
RL
2.2k Ω
AD5360/AD5361
t1
SCLK
1
24
2
t3
t4
SYNC
24
t11
t6
t5
t7
SDI
1
t2
t8
DB0
DB23
t9
t10
BUSY
t12
t13
LDAC1
t17
t14
VOUTx1
t15
t13
LDAC2
t17
VOUTx2
t16
CLR
t18
VOUTx
t19
RESET
VOUTx
t18
t20
BUSY
05761-010
t23
1 LDAC ACTIVE DURING BUSY.
2 LDAC ACTIVE AFTER BUSY.
Figure 4. SPI Write Timing
Rev. A | Page 7 of 28
AD5360/AD5361
t22
SCLK
48
t21
SYNC
DB23
DB0
DB23
DB0
NOP CONDITION
INPUT WORD SPECIFIES
REGISTER TO BE READ
DB0
SDO
DB23
DB15
DB0
SELECTED REGISTER DATA CLOCKED OUT
LSB FROM PREVIOUS WRITE
Figure 5. SPI Read Timing
OUTPUT
VOLTAGE
FULL-SCALE
ERROR
+
ZERO-SCALE
ERROR
VMAX
ACTUAL
TRANSFER
FUNCTION
IDEAL
TRANSFER
FUNCTION
0
2N – 1
DAC CODE
n = 16 FOR AD5360
n = 14 FOR AD5361
ZERO-SCALE
ERROR
05761-001
VMIN
Figure 6. DAC Transfer Function
Rev. A | Page 8 of 28
05761-011
SDI
AD5360/AD5361
ABSOLUTE MAXIMUM RATINGS
TA = 25°C, unless otherwise noted. Transient currents of up to
60 mA do not cause SCR latch-up.
Table 4.
Parameter
VDD to AGND
VSS to AGND
DVCC to DGND
Digital Inputs to DGND
Digital Outputs to DGND
VREF0, VREF1 to AGND
VOUT0 to VOUT15 to AGND
SIGGND0, SIGGND1 to AGND
AGND to DGND
MON_IN0, MON_IN1, MON_OUT to AGND
Operating Temperature (TA)
Industrial (B Version)
Storage
Junction (TJ max)
θJA Thermal Impedance
52-Lead LQFP
56-Lead LFCSP
Reflow Soldering
Peak Temperature
Time at Peak Temperature
Rating
−0.3 V to +17 V
−17 V to +0.3 V
−0.3 V to +7 V
−0.3 V to DVCC + 0.3 V
−0.3 V to DVCC + 0.3 V
−0.3 V to +5.5 V
VSS − 0.3 V to VDD + 0.3 V
−1 V to +1 V
−0.3 V to +0.3 V
VSS − 0.3 V to VDD + 0.3 V
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
130°C
38°C/W
25°C/W
230°C
10 sec to 40 sec
Rev. A | Page 9 of 28
AD5360/AD5361
CLR
LDAC
AGND
DGND
DVCC
SDO
PEC
SDI
SCLK
SYNC
DVCC
DGND
VOUT7
VOUT6
AGND
DGND
DVCC
SDO
PEC
SDI
SCLK
SYNC
DVCC
DGND
VOUT7
VOUT6
VOUT5
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
56
55
54
53
52
51
50
49
48
47
46
45
44
43
52 51 50 49 48 47 46 45 44 43 42 41 40
39 VOUT4
3
37 VOUT3
36 VOUT2
4
5
AD5360/
AD5361
6
7
TOP VIEW
(Not to Scale)
8
35 VOUT1
34 VOUT0
33 TEMP_OUT
32 MON_IN1
9
31 VREF0
10
30 NC
11
29 VSS
28 VDD
12
27 NC
13
05761-022
NC
VOUT8
VOUT9
VOUT10
VOUT11
SIGGND1
VOUT12
VOUT13
VOUT14
VOUT15
NC
NC
NC
1
2
3
4
5
6
7
8
9
10
11
12
13
14
NC = NO CONNECT
14 15 16 17 18 19 20 21 22 23 24 25 26
NC = NO CONNECT
RESET
BIN/2SCOMP
BUSY
GPIO
MON_OUT
MON_IN0
NC
NC
NC
NC
NC
VDD
VSS
VREF1
Figure 7. 52-Lead LQFP Pin Configuration
PIN 1
INDICATOR
AD5360/
AD5361
TOP VIEW
(Not to Scale)
42
41
40
39
38
37
36
35
34
33
32
31
30
29
VOUT5
VOUT4
SIGGND0
VOUT3
VOUT2
VOUT1
VOUT0
TEMP_OUT
MON_IN1
VREF0
NC
NC
VSS
VDD
05761-028
38 SIGGND0
PIN 1
INDICATOR
2
15
16
17
18
19
20
21
22
23
24
25
26
27
28
1
NC
NC
VOUT8
VOUT9
VOUT10
VOUT11
SIGGND1
VOUT12
VOUT13
VOUT14
VOUT15
NC
NC
NC
LDAC
CLR
RESET
BIN/2SCOMP
BUSY
GPIO
MON_OUT
MON_IN0
NC
NC
VDD
VSS
VREF1
Figure 8. 56-Lead LFCSP Pin Configuration
Table 5. LQFP Pin Function Descriptions
LQFP
1
Pin No.
LFCSP
55
Mnemonic
LDAC
2
56
CLR
3
4
1
2
RESET
BIN/2SCOMP
5
3
BUSY
6
4
GPIO
7
5
MON_OUT
8, 32
9, 10, 14, 24, 25,
26, 27, 30
11, 28
6, 34
7 to 11, 15, 16,
26 to 28, 31, 32
12, 29
MON_IN0, MON_IN1
NC
12, 29
13, 30
VSS
13
19
14
21
VREF1
SIGGND1
31
33
33
35
VREF0
TEMP_OUT
34 to 37, 39 to
42, 15 to 18, 20
to 23
36 to 39, 41 to
44, 17 to 20, 22
to 25
VOUT0 to VOUT15
VDD
Description
Load DAC Logic Input (Active Low). See the BUSY and LDAC Functions
section for more information.
Asynchronous Clear Input (Level Sensitive, Active Low). See the Clear
Function section for more information.
Digital Reset Input.
Data Format Digital Input. Connecting this pin to DGND selects offset binary.
Connecting this pin to logic 1 selects twos complement. This input has a weak
pull-down.
Digital Input/Open-Drain Output. BUSY is open drain when it is an output.
See the BUSY and LDAC Functions section for more information.
Digital I/O Pin. This pin can be configured as an input or output that can be
read or programmed high or low via the serial interface. When configured as
an input, it has a weak pull-down.
Analog Multiplexer Output. Any DAC output, the MON_IN0 input, or the
MON_IN1 input can be switched to this output.
Analog Multiplexer Inputs. Can be switched to MON_OUT.
No Connect.
Positive Analog Power Supply; +9 V to +16.5 V for specified performance.
These pins should be decoupled with 0.1 μF ceramic capacitors and 10 μF
capacitors.
Negative Analog Power Supply; −16.5 V to −8 V for specified performance.
These pins should be decoupled with 0.1 μF ceramic capacitors and 10 μF
capacitors.
Reference Input for DAC 8 to DAC 15. This voltage is referred to AGND.
Reference Ground for DAC 8 to DAC 15. VOUT8 to VOUT15 are referenced to
this voltage.
Reference Input for DAC 0 to DAC 7. This voltage is referred to AGND.
Provides an output voltage proportional to chip temperature. This is typically
1.46 V at 25°C with an output variation of 4.4 mV/°C.
DAC Outputs. Buffered analog outputs for each of the 16 DAC channels. Each
analog output is capable of driving an output load of 10 kΩ to ground.
Typical output impedance of these amplifiers is 0.5 Ω.
Rev. A | Page 10 of 28
AD5360/AD5361
LQFP
38
Pin No.
LFCSP
40
43, 51
45, 53
DGND
44, 50
46, 52
DVCC
45
47
SYNC
46
48
SCLK
47
49
SDI
48
50
PEC
49
51
SDO
52
54
AGND
EP
Connect to VSS
Mnemonic
SIGGND0
Description
Reference Ground for DAC 0 to DAC 7. VOUT0 to VOUT7 are referenced to
this voltage.
Ground for All Digital Circuitry. Both DGND pins should be connected to the
DGND plane.
Logic Power Supply; 2.5 V to 5.5 V. These pins should be decoupled with 0.1
μF ceramic capacitors and 10 μF capacitors.
Active Low or SYNC Input for SPI Interface. This is the frame synchronization
signal for the SPI serial interface. See Figure 4, Figure 5, and the Serial
Interface section for more details.
Serial Clock Input for SPI Interface. See Figure 4, Figure 5, and the Serial
Interface section for more details.
Serial Data Input for SPI Interface. See Figure 4, Figure 5, and the Serial
Interface section for more details.
Packet Error Check Output. This is an open-drain output with a 50 kΩ pull-up
that goes low if the packet error check fails.
Serial Data Output for SPI Interface. See Figure 4, Figure 5, and the Serial
Interface section for more details.
Ground for All Analog Circuitry. The AGND pin should be connected to the
AGND plane.
Exposed Paddle.
Rev. A | Page 11 of 28
AD5360/AD5361
TYPICAL PERFORMANCE CHARACTERISTICS
2
0.0050
0.0025
AMPLITUDE (V)
0
0
32768
49152
–0.0050
05761-012
16384
0
65535
DAC CODE
0
1
Figure 12. Digital Crosstalk
VDD = +15V
VSS = –15V
DVCC = +5V
VREF = +3V
0.5
DNL (LSB)
0.5
INL ERROR (LSB)
5
4
1.0
1.0
0
0
–0.5
–0.5
20
40
05761-013
–1.0
0
80
60
TEMPERATURE (°C)
0
16384
32768
65535
49152
DAC CODE
Figure 10. Typical INL Error vs. Temperature
Figure 13. Typical AD5360 DNL Plot
600
0
TA = 25°C
VSS = –15V
VDD = +15V
VREF = +4.096V
OUTPUT NOISE (nV/√Hz)
500
–0.01
400
300
200
–0.02
0
2
4
6
8
TIME (µs)
10
0
0
1
2
3
FREQUENCY (Hz)
Figure 14. Noise Spectral Density
Figure 11. Analog Crosstalk Due to LDAC
Rev. A | Page 12 of 28
4
5
05761-017
100
05761-014
AMPLITUDE (V)
3
TIME (µs)
Figure 9. Typical AD5360 INL Plot
–1.0
2
05761-015
–0.0025
–1
05761-016
INL (LSB)
1
–2
TA = 25°C
VSS = –15V
VDD = +15V
VREF = +4.096V
AD5360/AD5361
6
0.50
VSS = –12V
VDD = +12V
VREF = +3V
DVCC = 5V
TA = 25°C
5
NUMBER OF UNITS
DVCC = +5.5V
0.40
DVCC = +3.6V
0.35
DVCC = +2.5V
0.30
4
3
2
1
–20
0
20
40
60
80
TEMPERATURE (°C)
0
0.48
05761-018
0.25
–40
0.50
0.52
0.54
0.58
0.56
ICC (mA)
Figure 15. ICC vs. Temperature
05761-021
ICC (mA)
0.45
Figure 18. Typical ICC Distribution
8.0
2.0
1.9
1.8
7.5
1.7
VOLTAGE (V)
IDD/ISS (mA)
IDD
7.0
ISS
1.6
1.5
1.4
1.3
6.5
1.1
–20
0
20
40
60
80
TEMPERATURE (°C)
1.0
–40
05761-019
6.0
–40
5
20
35
50
65
80
1.0
FULL-SCALE
VOUTx – MON_OUT (V)
12
–10
Figure 19. TEMP_OUT Voltage vs. Temperature
VDD = 15V
VSS = 15V
TA = 25°C
14
–25
TEMPERATURE (°C)
Figure 16. IDD/ISS vs. Temperature
10
8
6
4
0.5
0
MIDSCALE
ZERO-SCALE
–0.5
0
7.00
7.25
7.50
IDD (mA)
7.75
8.00
–1.0
–1.0
–0.5
0
0.5
1.0
MON_OUT CURRENT (mA)
Figure 17. Typical IDD Distribution
Figure 20. (VOUTx − MON_OUT Voltage) vs. MON_OUT Current
Rev. A | Page 13 of 28
05761-026
2
05761-020
NUMBER OF UNITS
05761-027
1.2
VSS = –12V
VDD = +12V
VREF = +3V
AD5360/AD5361
TERMINOLOGY
Integral Nonlinearity (INL)
Integral nonlinearity, or relative accuracy, is a measure of the
maximum deviation from a straight line passing through the
endpoints of the DAC transfer function. It is measured after
adjusting for zero-scale error and full-scale error and is
expressed in least significant bits (LSB).
Differential Nonlinearity (DNL)
Differential nonlinearity is the difference between the measured
change and the ideal 1 LSB change between any two adjacent
codes. A specified differential nonlinearity of 1 LSB maximum
ensures monotonicity.
Zero-Scale Error
Zero-scale error is the error in the DAC output voltage when all
0s are loaded into the DAC register.
Zero-scale error is a measure of the difference between VOUT
(actual) and VOUT (ideal), expressed in millivolts, when the
channel is at its minimum value. Zero-scale error is mainly due
to offsets in the output amplifier.
Full-Scale Error
Full-scale error is the error in DAC output voltage when all 1s
are loaded into the DAC register.
Full-scale error is a measure of the difference between VOUT
(actual) and VOUT (ideal), expressed in millivolts, when
the channel is at its maximum value. It does not include zeroscale error.
Gain Error
Gain error is the difference between full-scale error and zeroscale error. It is expressed in millivolts.
Gain Error = Full-Scale Error − Zero-Scale Error
VOUT Temperature Coefficient
This includes output error contributions from linearity, offset,
and gain drift.
DC Output Impedance
DC output impedance is the effective output source resistance.
It is dominated by package lead resistance.
Output Voltage Settling Time
The amount of time it takes for the output of a DAC to settle to
a specified level for a full-scale input change.
Digital-to-Analog Glitch Energy
This is the amount of energy injected into the analog output at
the major code transition. It is specified as the area of the glitch
in nV-s. It is measured by toggling the DAC register data between
0x7FFF and 0x8000 (AD5360) or 0x1FFF and 0x2000 (AD5361).
Channel-to-Channel Isolation
Channel-to-channel isolation refers to the proportion of input
signal from the reference input of one DAC that appears at the
output of another DAC operating from another reference. It is
expressed in decibels and measured at midscale.
DAC-to-DAC Crosstalk
DAC-to-DAC crosstalk is the glitch impulse that appears at the
output of one converter due to both the digital change and
subsequent analog output change at another converter. It is
specified in nV-s.
Digital Crosstalk
Digital crosstalk is defined as the glitch impulse transferred to
the output of one converter due to a change in the DAC register
code of another converter and is specified in nV-s.
Digital Feedthrough
When the device is not selected, high frequency logic activity
on the device’s digital inputs can be capacitively coupled both
across and through the device to show up as noise on the
VOUTx pins. It can also be coupled along the supply and
ground lines. This noise is digital feedthrough.
Output Noise Spectral Density
Output noise spectral density is a measure of internally
generated random noise. Random noise is characterized as a
spectral density (voltage per √Hz). It is measured by loading all
DACs to midscale and measuring noise at the output. It is
measured in nV/√Hz.
DC Crosstalk
The DAC outputs are buffered by op amps that share common
VDD and VSS power supplies. If the dc load current changes in
one channel (due to an update), this can result in a further dc
change in one or more channel outputs. This effect is more
significant at high load currents and reduces as the load
currents are reduced. With high impedance loads, the effect is
virtually immeasurable. Multiple VDD and VSS terminals are
provided to minimize dc crosstalk.
Rev. A | Page 14 of 28
AD5360/AD5361
FUNCTIONAL DESCRIPTION
DAC ARCHITECTURE
CHANNEL GROUPS
The AD5360/AD5361 contain 16 DAC channels and 16 output
amplifiers in a single package. The architecture of a single DAC
channel consists of a 16-bit resistor-string DAC in the case of
the AD5360 and a 14-bit DAC in the case of the AD5361,
followed by an output buffer amplifier. The resistor-string
section is simply a string of resistors, of equal value, from
VREF0 or VREF1 to AGND. This type of architecture
guarantees DAC monotonicity. The 16-/14-bit binary digital
code loaded to the DAC register determines at which node
on the string the voltage is tapped off before being fed into
the output amplifier. The output amplifier multiplies the
DAC output voltage by 4. The nominal output span is 12 V
with a 3 V reference and 20 V with a 5 V reference.
The 16 DAC channels of the AD5360/AD5361 are arranged into
two groups of eight channels. The eight DACs of Group 0 derive
their reference voltage from VREF0. Group 1 derives its reference voltage from VREF1. Each group has its own signal
ground pin.
Table 6. AD5360/AD5361 Registers
Register Name
X1A (group) (channel)
X1B (group) (channel)
M (group) (channel)
C (group) (channel)
X2A (group) (channel)
Word Length in Bits
16 (14)
16 (14)
16 (14)
16 (14)
16 (14)
X2B (group) (channel)
16 (14)
DAC (group) (channel)
OFS0
OFS1
Control
Monitor
GPIO
14
14
5
6
2
Description
Input Data Register A, one for each DAC channel.
Input Data Register B, one for each DAC channel.
Gain trim register, one for each DAC channel.
Offset trim register, one for each DAC channel.
Output Data Register A, one for each DAC channel. These registers store the final,
calibrated DAC data after gain and offset trimming. They are not readable or directly
writable.
Output Data Register B, one for each DAC channel. These registers store the final,
calibrated DAC data after gain and offset trimming. They are not readable or directly
writable.
Data registers from which the DACs take their final input data. The DAC registers are
updated from the X2A or X2B registers. They are not readable or directly writable.
Offset DAC 0 data register, sets offset for Group 0.
Offset DAC 1 data register, sets offset for Group 1.
Control register.
Monitor enable and configuration register.
GPIO configuration register.
Table 7. AD5360/AD5361 Input Register Default Values
Register Name
X1A, X1B
M
C
OFS0, OFS1
Control
A/B Select 0 and A/B Select 1
AD5360 Default Value
0x8000
0xFFFF
0x8000
0x2000
0x00
0x00
Rev. A | Page 15 of 28
AD5361 Default Value
0x2000
0x3FFF
0x2000
0x2000
0x00
0x00
AD5360/AD5361
A/B REGISTERS GAIN/OFFSET ADJUSTMENT
X2A
REGISTER
MUX
X1B
REGISTER
MUX
X2B
REGISTER
DAC
REGISTER
DAC
05761-023
M
REGISTER
C
REGISTER
Figure 21. Data Registers Associated with Each DAC Channel
Each DAC channel also has a gain register (M) and an offset (C)
register, which allow trimming out of the gain and offset errors
of the entire signal chain. Data from the X1A register is operated on by a digital multiplier and adder by the contents of the
M and C registers. The calibrated DAC data is then stored in the
X2A register. Similarly, data from the X1B register is operated
on by the multiplier and adder and stored in the X2B register.
Although a multiplier and adder symbol are shown for each
channel, there is only one multiplier and one adder in the
device, which are shared among all channels. This has
implications for the update speed when several channels are
updated at once, as described in the Register Update Rates
section.
Each time data is written to the X1A register, or to the M or
C register with the A/B control bit set to 0, the X2A data is
recalculated and the X2A register is automatically updated.
Similarly, X2B is updated each time data is written to X1B, or
to M or C with A/B set to 1. The X2A and X2B registers are
not readable or directly writable by the user.
Data output from the X2A and X2B registers is routed to the
final DAC register by a multiplexer. An 8-bit A/B select register
associated with each group of eight DACs controls whether
each individual DAC takes its data from the X2A or X2B
register. If a bit in this register is 0, the DAC takes its data
from the X2A register; if 1, the DAC takes its data from the
X2B register (Bit 0 through Bit 7 control DAC 0 through
DAC 7, respectively).
OFFSET DACs
In addition to the gain and offset trim for each DAC, there are
two 14-bit offset DACs, one for Group 0, and one for Group 1.
These allow the output range of all DACs connected to them to
be offset within a defined range. Thus, subject to the limitations
of headroom, it is possible to set the output range of Group 0
and/or Group 1 to be unipolar positive, unipolar negative, or
bipolar (either symmetrical or asymmetrical) about 0 V. The
DACs in the AD5360/AD5361 are factory trimmed with the
offset DACs set at their default values. This gives the best offset
and gain performance for the default output range and span.
When the output range is adjusted by changing the value of
the offset DAC, an extra offset is introduced due to the gain
error of the offset DAC. The amount of offset is dependent on
the magnitude of the reference and how much the offset DAC
moves from its default value. This offset is shown in Table 1. The
worst-case offset occurs when the offset DAC is at positive full
scale or negative full scale. This value can be added to the offset
present in the main DAC of a channel to give an indication of
the overall offset for that channel. In most cases, the offset can be
removed by programming the C register of the channel with an
appropriate value. The extra offset caused by the offset DACs
needs to be taken into account only when the offset DAC is
changed from its default value. Figure 22 shows the allowable
code range that can be loaded to the offset DAC, and this is
dependent on the reference value used. Thus, for a 5 V
reference, the offset DAC should not be programmed with
a value greater than 8192 (0x2000).
5
RESERVED
4
Note that because there are 16 bits in two registers, it is possible
to set up, on a per-channel basis, whether each DAC takes its
data from the X2A register or X2B register. A global command
is also provided that sets all bits in the A/B select registers to 0
or to 1.
Rev. A | Page 16 of 28
3
2
1
0
0
4096
8192
OFFSET DAC CODE
12288
Figure 22. Offset DAC Code Range
16383
05761-005
X1A
REGISTER
All DACs in the AD5360/AD5361 can be updated simultaneously by taking LDAC low, when each DAC register is updated
from either its X2A or X2B register, depending on the setting of
the A/B select registers. The DAC register is not readable or
directly writable by the user.
VREF (V)
Each DAC channel has seven data registers. The actual DAC
data word can be written to either the X1A or X1B input
register, depending on the setting of the A/B bit in the control
register. If the A/B bit is 0, data is written to the X1A register. If
the A/B bit is 1, data is written to the X1B register. Note that
this single bit is a global control and affects every DAC channel
in the device. It is not possible to set up the device on a perchannel basis so that some writes are to the X1A register and
some writes are to the X1B register.
AD5360/AD5361
OUTPUT AMPLIFIER
Because the output amplifiers can swing to 1.4 V below the
positive supply and 1.4 V above the negative supply, this limits
how much the output can be offset for a given reference voltage.
For example, it is not possible to have a unipolar output range of
20 V because the maximum supply voltage is ±16.5 V.
OUTPUT
R5
60kΩ
R6
10kΩ
S2
R4
60kΩ
R3
20kΩ
R2
20kΩ
CLR
DAC_CODE = INPUT_CODE × (M + 1)/214 + C − 213
CLR
CLR
R1
20kΩ
AD5361 Transfer Function
The input code is the value in the X1A or X1B register that is
applied to DAC (X1A, X1B default code = 8192)
S1
DAC
CHANNEL
OFFSET_CODE is the code loaded to the offset DAC. It is
multiplied by 4 in the transfer function because this DAC is a
14-bit device. On power-up, the default code loaded to the
offset DAC is 8192 (0x2000). With a 10 V reference, this gives
a span of −10 V to +10 V.
DAC output voltage
S3
VOUT = 4 × VREF × (DAC_CODE − OFFSET_CODE)/214 +
VSIGGND
SIGGND
05761-006
SIGGND
OFFSET
DAC
Figure 23. Output Amplifier and Offset DAC
Figure 23 shows details of a DAC output amplifier and its
connections to the offset DAC. On power-up, S1 is open,
disconnecting the amplifier from the output. S3 is closed, so
the output is pulled to SIGGND. S2 is also closed to prevent
the output amplifier from being open-loop. If CLR is low at
power-up, the output remains in this condition until CLR is
taken high. The DAC registers can be programmed, and the
outputs assume the programmed values when CLR is taken
high. Even if CLR is high at power-up, the output remains
in this condition until VDD > 6 V and VSS < −4 V and the
initialization sequence has finished. The outputs then go to
their power-on default values.
OFFSET_CODE is the code loaded to the offset DAC.
On power-up, the default code loaded to the offset DAC
is 8192 (0x2000). With a 5 V reference, this gives a span of
−10 V to +10 V.
REFERENCE SELECTION
TRANSFER FUNCTION
The output voltage of a DAC in the AD5360/AD5361 is dependent
on the value in the input register, the value of the M and C
registers, and the value in the offset DAC. The transfer functions
for the AD5360/AD5361 are shown in the following sections.
AD5360 Transfer Function
The input code is the value in the X1A or X1B register that is
applied to DAC (X1A, X1B default code = 32,768)
16
DAC_CODE = INPUT_CODE × (M + 1)/2 + C − 2
15
DAC output voltage
VOUT = 4 × VREF × (DAC_CODE − (OFFSET_CODE × 4))/
216 + VSIGGND
where:
DAC_CODE should be within the range of 0 to 65,535.
VREF = 3.0 V, for a 12 V span.
VREF = 5.0 V, for a 20 V span.
M = code in gain register − default code = 216 – 1.
C = code in offset register − default code = 215.
where:
DAC_CODE should be within the range of 0 to 16,383.
VREF = 3.0 V, for a 12 V span.
VREF = 5.0 V, for a 20 V span.
M = code in gain register − default code = 214 − 1.
C = code in offset register − default code = 213.
The AD5360/AD5361 have two reference input pins. The
voltage applied to the reference pins determines the output
voltage span on VOUT0 to VOUT15. VREF0 determines the
voltage span for VOUT0 to VOUT7 (Group 0), and VREF1
determines the voltage span for VOUT8 to VOUT15 (Group 1).
The reference voltage applied to each VREF pin can be different,
if required, allowing each group of eight channels to have a
different voltage span. The output voltage range and span can
be adjusted by programming the offset register and gain register
for each channel as well as programming the offset DAC. If the
offset and gain features are not used (that is, the M and C
registers are left at their default values), the required reference
levels can be calculated as follows:
VREF = (VOUTMAX − VOUTMIN)/4
If the offset and gain features of the AD5360/AD5361 are used,
the required output range is slightly different. The chosen
output range should take into account the system offset and
gain errors that need to be trimmed out. Therefore, the chosen
output range should be larger than the actual, required range.
The required reference levels can be calculated as follows:
1.
2.
3.
Rev. A | Page 17 of 28
Identify the nominal output range on VOUT.
Identify the maximum offset span and the maximum gain
required on the full output signal range.
Calculate the new maximum output range on VOUT,
including the expected maximum offset and gain errors.
AD5360/AD5361
4.
5.
Choose the new required VOUTMAX and VOUTMIN, keeping
the VOUT limits centered on the nominal values. Note that
VDD and VSS must provide sufficient headroom.
Calculate the value of VREF as follows:
VREF = (VOUTMAX − VOUTMIN)/4
Full-scale error can be reduced as follows:
1.
2.
3.
Reference Selection Example
4.
Nominal output range = 20 V (−10 V to +10 V)
Offset error = ±100 mV
Gain error = ±3%
SIGGND = AGND = 0 V
Measure the zero-scale error.
Set the output to the highest possible value.
Measure the actual output voltage and compare it with the
required value. Add this error to the zero-scale error. This
is the span error, which includes full-scale error.
Calculate the number of LSBs equivalent to the span error
and subtract it from the default value of the M register.
Note that only positive full-scale error can be reduced.
The M and C registers should not be programmed until both
zero-scale errors and full-scale errors have been calculated.
Gain error = ±3%
Maximum positive gain error = +3%
Output range including gain error = 20 + 0.03 (20) =
20.6 V
AD5360 Calibration Example
This example assumes that a −10 V to +10 V output is required.
The DAC output is set to −10 V but is measured at −10.03 V.
This gives a zero-scale error of −30 mV.
Offset error = ±100 mV
Maximum offset error span = 2 (100 mV) = 0.2 V
Output range including gain error and offset error =
20.6 V + 0.2 V = 20.8 V
1 LSB = 20 V/65,536 = 305.176 μV
30 mV = 98 LSBs
VREF calculation
Actual output range = 20.6 V, that is, −10.3 V to +10.3 V
(centered);
VREF = (10.3 V + 10.3 V)/4 = 5.15 V
The full-scale error can now be removed. The output is set
to +10 V, and a value of +10.02 V is measured. The full-scale
error is +20 mV. The span error is +20 mV − (−30 mV) =
+50 mV.
+50 mV = 164 LSBs
If the solution yields an inconvenient reference level, the user
can adopt one of the following approaches:
The errors can now be removed.
•
1.
•
•
Use a resistor divider to divide down a convenient, higher
reference level to the required level.
Select a convenient reference level above VREF and modify
the gain and offset registers to digitally downsize the
reference. In this way, the user can use almost any convenient reference level but may reduce the performance by
overcompaction of the transfer function.
Use a combination of these two approaches.
CALIBRATION
The user can perform a system calibration on the AD5360 and
AD5361 to reduce gain and offset errors to below 1 LSB. This is
achieved by calculating new values for the M and C registers and
reprogramming them.
Reducing Zero-Scale and Full-Scale Error
Zero-scale error can be reduced as follows:
1.
2.
3.
Set the output to the lowest possible value.
Measure the actual output voltage and compare it with the
required value. This gives the zero-scale error.
Calculate the number of LSBs equivalent to the error and
add this from the default value of the C register. Note that
only negative zero-scale error can be reduced.
2.
3.
4.
98 LSBs should be added to the default C register value;
(32,768 + 98) = 32,866.
32,866 should be programmed to the C register.
164 LSBs should be subtracted from the default M register
value; (65,535 − 164) = 65,371.
65,371 should be programmed to the M register.
Additional Calibration
The techniques described in the previous section are usually
enough to reduce the zero-scale errors and full-scale errors in
most applications. However, there are limitations whereby the
errors may not be sufficiently removed. For example, the offset
(C) register can only be used to reduce the offset caused by the
negative zero-scale error. A positive offset cannot be reduced.
Likewise, if the maximum voltage is below the ideal value, that
is, a negative full-scale error, the gain (M) register cannot be
used to increase the gain to compensate for the error.
These limitations can be overcome by increasing the reference value. With a 2.5 V reference, a 10 V span is achieved.
The ideal voltage range, for the AD5360 or AD5361, is
−5 V to +5 V. Using a 2.6 V reference increases the range
to −5.2 V to +5.2 V. Clearly, in this case, the offset and gain
errors are insignificant and the M and C registers can be
used to raise the negative voltage to −5 V and then reduce
the maximum voltage down to +5 V to give the most
accurate values possible.
Rev. A | Page 18 of 28
AD5360/AD5361
RESET FUNCTION
The reset function is initiated by the RESET pin. On the rising
edge of RESET, the AD5360/AD5361 state machine initiates a
reset sequence to reset the X, M, and C registers to their default
values. This sequence typically takes 300 μs, and the user should
not write to the part during this time. On power-up, it is recommended that the user bring RESET high as soon as possible to
properly initialize the registers.
When the reset sequence is complete (and provided that CLR is
high), the DAC output is at a potential specified by the default
register settings, which are equivalent to SIGGNDx. The DAC
outputs remain at SIGGNDx until the X, M, or C register is
updated and LDAC is taken low. The AD5360/AD5361 can be
returned to the default state by pulsing RESET low for at least
30 ns. Note that, because the reset function is rising edge triggered, bringing RESET low has no effect on the operation of
the AD5360/AD5361.
high. Whenever the A/B select registers are written to, BUSY
also goes low, for approximately 600 ns.
The AD5360/AD5361 have flexible addressing that allows
writing of data to a single channel, all channels in a group, the
same channel in Group 0 and Group 1, or all channels in the
device. This means that 1, 2, 8, or 16 DAC register values may
need to be calculated and updated. Because there is only one
multiplier shared among 16 channels, this task must be done
sequentially, so the length of the BUSY pulse varies according to
the number of channels being updated.
Table 8. BUSY Pulse Widths
Action
Loading Input, C, or M to 1 Channel2
Loading Input, C, or M to 2 Channels
Loading Input, C, or M to 8 Channels
Loading Input, C, or M to 16 Channels
1
CLEAR FUNCTION
2
CLR is an active low input that should be high for normal
operation. The CLR pin has an internal 500 kΩ pull-down
resistor. When CLR is low, the input to each of the DAC output
buffer stages (VOUT0 to VOUT15) is switched to the externally
set potential on the relevant SIGGNDx pin. While CLR is low,
all LDAC pulses are ignored. When CLR is taken high again, the
DAC outputs return to their previous values. The contents of
input registers and DAC Register 0 to DAC Register 15 are not
affected by taking CLR low. To prevent glitches appearing on
the outputs, CLR should be brought low whenever the output
span is adjusted by writing to the offset DAC.
BUSY AND LDAC FUNCTIONS
The value of an X2 (A or B) register is calculated each time the
user writes new data to the corresponding X1, C, or M register.
During the calculation of X2, the BUSY output goes low. While
BUSY is low, the user can continue writing new data to the X1,
M, or C register (see the Register Update Rates section for more
details), but no DAC output updates can take place.
The BUSY pin is bidirectional and has a 50 kΩ internal pull-up
resistor. When multiple AD5360 or AD5361 devices may be
used in one system, the BUSY pins can be tied together. This is
useful when it is required that no DAC in any device be updated
until all other DACs are ready. When each device has finished
updating the X2 (A or B) register, it releases the BUSY pin. If
another device has not finished updating its X2 registers, it
holds BUSY low, thus delaying the effect of LDAC going low.
BUSY Pulse Width1
1.5 μs maximum
2.1 μs maximum
5.7 μs maximum
10.5 μs maximum
BUSY pulse width = ((number of channels + 1) × 600 ns) + 300 ns.
A single channel update is typically 1 μs.
The AD5360/AD5361 contain an extra feature whereby a DAC
register is not updated unless its X2A or X2B register has been
written to since the last time LDAC was brought low. Normally,
when LDAC is brought low, the DAC registers are filled with
the contents of the X2A or X2B registers, depending on the
setting of the A/B select register. However, the AD5360/
AD5361 update the DAC register only if the X2A or X2B data has
changed, thereby removing unnecessary digital crosstalk.
BIN/2SCOMP PIN
The BIN/2SCOMP pin determines if the output data is presented
as offset binary or twos complement. If this pin is low, the data
is straight binary. If it is high, the data is twos complement. This
affects only the X, C, and offset DAC registers; the M register
and the control and command data are interpreted as straight
binary.
TEMPERATURE SENSOR
The on-chip temperature sensor provides a voltage output
at the TEMP_OUT pin that is linearly proportional to the
Centigrade temperature scale. The typical accuracy of the
temperature sensor is ±1°C at +25°C and ±5°C over the −40°C
to +85°C range. Its nominal output voltage is 1.46 V at +25°C,
varying at 4.4 mV/°C. Its low output impedance, low selfheating, and linear output simplify interfacing to temperature
control circuitry and analog-to-digital converters.
The DAC outputs are updated by taking the LDAC input low. If
LDAC goes low while BUSY is active, the LDAC event is stored
and the DAC outputs update immediately after BUSY goes
high. A user can also hold the LDAC input permanently low. In
this case, the DAC outputs update immediately after BUSY goes
Rev. A | Page 19 of 28
AD5360/AD5361
MONITOR FUNCTION
POWER-DOWN MODE
The AD5360/AD5361 contain a channel monitor function
that consists of an analog multiplexer addressed via the serial
interface, allowing any channel output to be routed to this pin
for monitoring using an external ADC. In addition, two monitor
inputs, MON_IN0 and MON_IN1, are provided, which can also
be routed to MON_OUT. The monitor function is controlled by
the monitor register, which allows the monitor output to be
enabled or disabled, and selection of a DAC channel or one of
the monitor pins. When disabled, the monitor output is high
impedance, so several monitor outputs can be connected in
parallel and only one enabled at a time. Table 9 shows the
control register settings relevant to the monitor function.
The AD5360/AD5361 can be powered down by setting Bit 0 in
the control register to 1. This turns off the DACs, thus reducing
the current consumption. The DAC outputs are connected to
their respective SIGGND potentials. The power-down mode
does not change the contents of the registers, and the DACs
return to their previous voltage when the power-down bit is
cleared to 0.
Table 9. Control Register Monitor Functions
F5
0
1
1
1
1
1
1
F4
X
X
0
0
0
1
1
F3
X
X
0
0
1
0
0
F2
X
X
0
0
1
0
0
F1
X
X
0
0
1
0
0
F0
X
X
0
1
1
0
1
Function
MON_OUT disabled
MON_OUT enabled
MON_OUT = VOUT0
MON_OUT = VOUT1
MON_OUT = VOUT15
MON_OUT = MON_IN0
MON_OUT = MON_IN1
The multiplexer is implemented as a series of analog switches.
Because this could conceivably cause a large amount of current
to flow from the input of the multiplexer, that is, VOUTx or
MON_INx to the output of the multiplexer, MON_OUT, care
should taken to ensure that whatever is connected to the
MON_OUT pin is of high enough impedance to prevent the
continuous current limit specification from being exceeded.
Because the MON_OUT pin is not buffered, the amount of
current drawn from this pin creates a voltage drop across the
switches, which in turn leads to an error in the voltage being
monitored. Where accuracy is important, it is recommended
that the MON_OUT pin be buffered. Figure 20 shows the
typical error due to the MON_OUT current
GPIO PIN
The AD5360/AD5361 have a general-purpose I/O pin, GPIO.
This can be configured as an input or an output and read back
or programmed (when configured as an output) via the serial
interface. Typical applications for this pin include monitoring
the status of a logic signal, monitoring a limit switch, or
controlling an external multiplexer. The GPIO pin is configured
by writing to the GPIO register, which has the special function
code of 001101 (see Table 14 and Table 15 ). When Bit F1 is set,
the GPIO pin becomes an output and F0 determines whether
the pin is high or low. The GPIO pin can be set as an input by
writing 0 to both F1 and F0. The status of the GPIO pin can be
determined by initiating a read operation using the appropriate
bits in Table 16. The status of the pin is indicated by the LSB of
the register read.
THERMAL MONITORING FUNCTION
The AD5360/AD5361 can be programmed to power down the
DACs if the temperature on the die exceeds 130°C. Setting Bit 1
in the control register to 1 (see Table 15) enables this function.
If the die temperature exceeds 130°C, the AD5360/AD5361
enter a temperature power-down mode, which is equivalent to
setting the power-down bit in the control register. To indicate
that the AD5360/AD5361 have entered temperature shutdown
mode, Bit 4 of the control register is set to 1. The AD5360/AD5361
remain in temperature shutdown mode, even if the die temperature falls, until Bit 1 in the control register is cleared to 0.
TOGGLE MODE
The AD5360/AD5361 have two X2 registers per channel, X2A
and X2B, which can be used to switch the DAC output between
two levels with ease. This approach greatly reduces the overhead
required by a microprocessor, which would otherwise have to
write to each channel individually. When the user writes to
either the X1A, X2A, M, or C register, the calculation engine
takes a certain amount of time to calculate the appropriate X2A
or X2B values. If the application only requires that the DAC
output switch between two levels, such as a data generator, any
method that reduces the amount of calculation time encountered is advantageous. For the data generator example, the user
should set the high and low levels for each channel once, by
writing to the X1A and X1B registers. The values of X2A and
X2B are calculated and stored in their respective registers. The
calculation delay, therefore, only happens during the setup
phase, that is, when programming the initial values. To toggle a
DAC output between the two levels, it is only required to write
to the relevant A/B select register to set the MUX 2 register bit.
Furthermore, because there are eight MUX 2 control bits per
register, it is possible to update eight channels with a single
write. Table 17 shows the bits that correspond to each DAC
output.
Rev. A | Page 20 of 28
AD5360/AD5361
SERIAL INTERFACE
The AD5360/AD5361 contain a high speed SPI operating at
clock frequencies up to 50 MHz (20 MHz for read operations).
To minimize both the power consumption of the device and
on-chip digital noise, the interface powers up fully only when
the device is being written to, that is, on the falling edge of
SYNC. The serial interface is 2.5 V LVTTL-compatible when
operating from a 2.5 V to 3.6 V DVCC supply. It is controlled by
four pins: SYNC (frame synchronization input), SDI (serial data
input), SCLK (clocking of data in and out of the device), and
SDO (serial data output for data readback).
The serial interface works with both a continuous and a burst
(gated) serial clock. Serial data applied to SDI is clocked into
the AD5360/AD5361 by clock pulses applied to SCLK. The first
falling edge of SYNC starts the write cycle. At least 24 falling
clock edges must be applied to SCLK to clock in 24 bits of data,
before SYNC is taken high again. If SYNC is taken high before
the 24th falling clock edge, the write operation is aborted.
If a continuous clock is used, SYNC must be taken high before
the 25th falling clock edge. This inhibits the clock within the
AD5360/AD5361. If more than 24 falling clock edges are
applied before SYNC is taken high again, the input data is
corrupted. If an externally gated clock of exactly 24 pulses is
used, SYNC may be taken high any time after the 24th falling
clock edge.
SPI WRITE MODE
The AD5360/AD5361 allow writing of data via the serial interface to every register directly accessible to the serial interface,
which are all registers except the X2A, X2B, and DAC registers.
The X2A and X2B registers are updated when writing to the
X1A, X1B, M, and C registers, and the DAC registers are
updated by LDAC. The serial word (see Table 10 or Table 11)
is 24 bits long; 16 or 14 of these bits are data bits, six bits are
address bits, and two bits are mode bits that determine what
is done with the data. Two bits are reserved on the AD5361.
The input register addressed is updated on the rising edge of
SYNC. For another serial transfer to take place, SYNC must be
taken low again.
Table 10. AD5360 Serial Word Bit Assignation
I23
M1
I22
M0
I21
A5
I20
A4
I19
A3
I18
A2
I17
A1
I16
A0
I15
D15
I14
D14
I13
D13
I12
D12
I11
D11
I10
D10
I14
D12
I13
D11
I12
D10
I11
D9
I10
D8
I9
D9
I8
D8
I7
D7
I6
D6
I5
D5
I4
D4
I3
D3
I2
D2
I1
D1
I0
D0
I8
D6
I7
D5
I6
D4
I5
D3
I4
D2
I3
D1
I2
D0
I1 1
0
I01
0
Table 11. AD5361 Serial Word Bit Assignation
I23
M1
1
I22
M0
I21
A5
I20
A4
I19
A3
I18
A2
I17
A1
I16
A0
I15
D13
I9
D7
I1 and I0 are reserved for future use and should be 0 when writing the serial word. These bits read back as 0.
Rev. A | Page 21 of 28
AD5360/AD5361
SPI READBACK MODE
PACKET ERROR CHECKING
The AD5360/AD5361 allow data readback via the serial interface from every register directly accessible to the serial interface,
which is all registers except the X2A, X2B, and DAC data
registers. To read back a register, it is first necessary to tell the
AD5360/AD5361 which register is to be read. This is achieved
by writing a word whose first two bits are the Special Function
Code 00 to the device. The remaining bits then determine if the
operation is a readback and which register is to be read back, or
if it is a write to of the special function registers, such as the
control register.
To verify that data has been received correctly in noisy environments, the AD5360/AD5361 offer the option of error checking
based on an 8-bit (CRC-8) cyclic redundancy check. The device
controlling the AD5360/AD5361 should generate an 8-bit
checksum using the polynomial C(x) = x8 + x2 + x1 +1. The
checksum is added to the end of the data word, and 32 data bits
are sent to the AD5360/AD5361 before taking SYNC high. If
the AD5360/AD5361 see a 32-bit data frame, they perform the
error check when SYNC goes high. If the checksum is valid, the
data is written to the selected register. If the checksum is invalid,
the data is ignored, the packet error check output (PEC) goes
low, and Bit 3 of the control register is set. After reading the
control register, the error flag is cleared automatically and PEC
goes high again.
UPDATE ON SYNC HIGH
SYNC
SCLK
REGISTER UPDATE RATES
MSB
D23
The value of the X2A or X2B register is calculated each time the
user writes new data to the corresponding X1, C, or M register.
The calculation is performed by a three-stage process. The first
two stages take approximately 600 ns each, and the third stage
takes approximately 300 ns. When the write to a X1, C, or M
register is complete, the calculation process begins. If the write
operation involves the update of a single DAC channel, the user
is free to write to another register provided that the write
operation does not finish until the first stage calculation is
complete, that is, 600 ns after the completion of the first write
operation. If a group of channels is being updated by a single
write operation, the first stage calculation is repeated for each
channel, taking 600 ns per channel. In this case, the user should
not complete the next write operation until this time has elapsed.
LSB
D0
24-BIT DATA
SDI
24-BIT DATA TRANSFER—NO ERROR CHECKING
UPDATE AFTER SYNC HIGH
ONLY IF ERROR CHECK PASSED
SYNC
SCLK
MSB
D31
SDI
PEC
LSB
D8
24-BIT DATA
D7
D0
8-BIT CHECKSUM
PEC GOES LOW IF
ERROR CHECK FAILS
24-BIT DATA TRANSFER WITH ERROR CHECKING
Figure 24. SPI Write with and Without Error Checking
Rev. A | Page 22 of 28
05761-029
If a readback command is written to a special function register,
data from the selected register is clocked out of the SDO pin
during the next SPI operation. The SDO pin is normally threestated but becomes driven as soon as a read command is issued.
The pin remains driven until the register’s data is clocked out.
See Figure 5 for the read timing diagram. Note that, due to the
timing requirements of t22 (25 ns), the maximum speed of the
SPI interface during a read operation should not exceed 20 MHz.
AD5360/AD5361
CHANNEL ADDRESSING AND SPECIAL MODES
If the mode bits are not 00, then the data word D15 to D0
(AD5360) or D13 to D0 (AD5361) is written to the device.
Address Bit A4 to Address Bit A0 determine which channel or
channels is/are written to, while the mode bits determine to
which register (X1A, X1B, C, or M) the data is written, as
shown in Table 10 and Table 11. Data is to be written to the
X1A when the A/B bit in the control register is 0 or to the X1B
register when the bit is 1.
The AD5360/AD5361 have very flexible addressing that allows
writing of data to a single channel, all channels in a group, the
same channel in Group 0 and Group 1 or all channels in the
device. Table 13 shows all these address modes. It shows which
group(s) and which channel(s) is/are addressed for every
combination of Address Bit A4 to Address Bit A0.
Table 12. Mode Bits
M1
1
1
0
0
M0
1
0
1
0
Action
Write DAC data (X) register
Write DAC offset (C) register
Write DAC gain (M) register
Special function, used in combination with other
bits of a word
Table 13. Group and Channel Addressing
Address Bit A2 to Address Bit A0
000
001
010
011
100
101
110
111
00
All groups, all channels
Group 0, all channels
Group 1, all channels
Unused
Unused
Unused
Unused
Unused
Address Bit A4 to Address Bit A3
01
10
Group 0, Channel 0
Group 1, Channel 0
Group 0, Channel 1
Group 1, Channel 1
Group 0, Channel 2
Group 1, Channel 2
Group 0, Channel 3
Group 1, Channel 3
Group 0, Channel 4
Group 1, Channel 4
Group 0, Channel 5
Group 1, Channel 5
Group 0, Channel 6
Group 1, Channel 6
Group 0, Channel 7
Group 1, Channel 7
Rev. A | Page 23 of 28
11
Unused
Unused
Unused
Unused
Unused
Unused
Unused
Unused
AD5360/AD5361
SPECIAL FUNCTION MODE
data required for execution of the special function, for example
the channel address for data readback.
If the mode bits are 00, then the special function mode is
selected, as shown in Table 14. Bits I21 to I16 of the serial data
word select the special function, while the remaining bits are
The codes for the special functions in Table 16 show the
addresses for data readback.
Table 14. Special Function Mode
I23
0
I22
0
I21
S5
I20
S4
I19
S3
I18
S2
I17
S1
I16
S0
I15
F15
I14
F14
I13
F13
I12
F12
I11
F11
I10
F10
I9
F9
I8
F8
I7
F7
I6
F6
I5
F5
I4
F4
I3
F3
I2
F2
I1
F1
Table 15. Special Function Codes
Special Function Code
S5 S4 S3 S2 S1
0
0
0
0
0
0
0
0
0
0
S0
0
1
Data (F15 to F0)
0000 0000 0000 0000
XXXX XXXX XXXX X [F2:F0]
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
0
0
1
1
0
1
0
1
0
1
XX [F13:F0]
XX [F13:F0]
Reserved
See Table 16
XXXX XXXX [F7:F0]
XXXX XXXX [F7:F0]
0
0
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
1
1
0
1
0
1
Reserved
Reserved
Reserved
XXXX XXXX [F7:F0]
0
0
1
1
0
0
XXXX XXXX XX [F5:F0]
0
0
1
1
0
1
XXXX XXXX XXXX XX [F1:F0]
Action
NOP.
Write control register.
F4 = 1: temperature over 130°C.
F4 = 0: temperature under 130°C.
Read-only bit. This bit should be 0 when writing to the control register.
F3 = 1: PEC error.
F3 = 0: No PEC error. Reserved.
Read-only bit. This bit should be 0 when writing to the control register.
F2 = 1: select Register X1B for input.
F2 = 0: select Register X1A for input.
F1 = 1: enable temperature shutdown.
F1 = 0: disable temperature shutdown.
F0 = 1: soft power-down.
F0 = 0: soft power-up.
Write data in F13 to F0 to OFS0 register.
Write data in F13 to F0 to OFS1 register.
Select register for readback.
Write data in F7 to F0 to A/B Select Register 0.
Write data in F7 to F0 to A/B Select Register 1.
Block write A/B select registers.
F7 to F0 = 0: write all 0s (all channels use X2A register).
F7 to F0 = 1: write all 1s (all channels use X2B register).
F5 = 1: monitor enable.
F5 = 0: monitor disable.
F4 = 1: monitor input pin selected by F0.
F4 = 0: monitor DAC channel selected by F3:F0
(0000 = DAC0; 1111 = DAC15).
F3 = not used if F4 = 1.
F2 = not used if F4 = 1.
F1 = not used.
F0 = 0: MON_IN0 selected for monitoring (if F4 and F5 = 1).
F0 = 1: MON_IN1 selected for monitoring (if F4 and F5 = 1).
GPIO configure and write.
F1 = 1: GPIO is an output. Data to output is written to F0.
F1 = 0: GPIO is an input. Data can be read from F0 on readback.
Rev. A | Page 24 of 28
I0
F0
AD5360/AD5361
Table 16. Address Codes for Data Readback 1
F15
0
0
0
0
1
1
1
1
1
F14
0
0
1
1
0
0
0
0
0
1
0
0
0
0
0
1
1
1
A/B Select Register 1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
0
0
0
0
0
0
1
1
0
1
0
1
Reserved
Reserved
Reserved
GPIO Read (Data in F0) 2
1
2
F13
0
1
0
1
0
0
0
0
0
F12
F11
F10
F9
F8
Bit F12 to Bit F7 select channel to be read back,
Channel 0 = 001000 to Channel 15 = 010111
F7
0
0
0
0
0
0
0
0
0
0
1
0
1
0
0
0
0
0
0
0
0
0
0
1
1
0
1
1
0
1
Register Read
X1A Register
X1B Register
C Register
M Register
Control Register
OFS0 Data Register
OFS1 Data Register
Reserved
A/B Select Register 0
F6 to F0 are don’t cares for the data readback function.
F6 to F0 should be 0 for GPIO read.
Table 17. DACs Selected by A/B Select Registers
A/B Select
Register
0
1
1
F7
DAC7
DAC15
F6
DAC6
DAC14
F5
DAC5
DAC13
F4
DAC4
DAC12
Bits 1
F3
DAC3
DAC11
F2
DAC2
DAC10
F1
DAC1
DAC9
F0
DAC0
DAC8
If the bit is 0, Register X2A is selected. If the bit is 1, Register X2B is selected.
POWER SUPPLY DECOUPLING
In any circuit where accuracy is important, careful consideration of the power supply and ground return layout helps to
ensure the rated performance. The printed circuit board on
which the AD5360/AD5361 are mounted should be designed so
that the analog and digital sections are separated and confined
to certain areas of the board. If the AD5360/AD5361 are in a
system where multiple devices require an AGND-to-DGND
connection, the connection should be made at one point only.
The star ground point should be established as close as possible
to the device. For supplies with multiple pins (VSS, VDD, DVCC),
it is recommended to tie these pins together and to decouple
each supply once.
The AD5360/AD5361 should have ample supply decoupling of
10 μF in parallel with 0.1 μF on each supply located as close to
the package as possible, ideally right up against the device. The
10 μF capacitors are the tantalum bead type. The 0.1 μF capacitor should have low effective series resistance (ESR) and effective
series inductance (ESI), such as the common ceramic types that
provide a low impedance path to ground at high frequencies, to
handle transient currents due to internal logic switching.
Digital lines running under the device should be avoided
because these couple noise onto the device. The analog ground
plane should be allowed to run under the AD5360/AD5361 to
avoid noise coupling. The power supply lines of the AD5360/
AD5361 should use as large a trace as possible to provide low
impedance paths and reduce the effects of glitches on the power
supply line. Fast switching digital signals should be shielded
with digital ground to avoid radiating noise to other parts of the
board and should never be run near the reference inputs. It is
essential to minimize noise on all VREFx lines.
Avoid crossover of digital and analog signals. Traces on
opposite sides of the board should run at right angles to each
other. This reduces the effects of feedthrough through the
board. A microstrip technique is by far the best, but this is not
always possible with a double-sided board. In this technique,
the component side of the board is dedicated to the ground
plane, while signal traces are placed on the solder side.
As is the case for all thin packages, care must be taken to avoid
flexing the package and to avoid a point load on the surface of
this package during the assembly process.
POWER SUPPLY SEQUENCING
When the supplies are connected to the AD5360/AD5361, it is
important that the AGND and DGND pins be connected to the
relevant ground plane before the positive or negative supplies
are applied. In most applications, this is not an issue because the
ground pins for the power supplies are connected to the ground
pins of the AD5360/AD5361 via ground planes. Where the
AD5360/AD5361 are used in a hot-swap card, care should be
taken to ensure that the ground pins are connected to the
supply grounds before the positive or negative supplies are
connected. This is required to prevent currents from flowing in
directions other than toward an analog or digital ground.
Rev. A | Page 25 of 28
AD5360/AD5361
INTERFACING EXAMPLES
AD5360/
AD5361
SYNC
SCK
SCLK
MOSI
SDI
MISO
SDO
PF10
RESET
PF9
LDAC
PF8
CLR
PF7
BUSY
ADSP-21065L
05761-024
ADSP-BF531
SPISELx
The Analog Devices ADSP-21065L is a floating-point DSP with
two serial ports (SPORTs). Figure 26 shows how one SPORT
can be used to control the AD5360 or AD5361. In this example,
the transmit frame synchronization (TFS) pin is connected
to the receive frame synchronization (RFS) pin. Similarly,
the transmit and receive clocks (TCLK and RCLK) are also
connected together. The user can write to the AD5360 or
AD5361 by writing to the transmit register. A read operation
can be accomplished by first writing to the AD5360/AD5361
to tell the part that a read operation is required. A second write
operation with a NOP instruction causes the data to be read
from the AD5360/AD5361. The DSPs receive interrupt can be
used to indicate when the read operation is complete.
Figure 25. Interfacing to a Blackfin DSP
AD5360/
AD5361
TFSx
RFSx
SYNC
TCLKx
RCLKx
SCLK
DTxA
SDI
DRxA
SDO
FLAG0
RESET
FLAG1
LDAC
FLAG2
CLR
FLAG3
BUSY
Figure 26. Interfacing to an ADSP-21065L DSP
Rev. A | Page 26 of 28
05761-025
The SPI interface of the AD5360 and AD5361 is designed to
allow the parts to be easily connected to industry standard DSPs
and microcontrollers. Figure 25 shows how the AD5360/AD5361
can be connected to the Analog Devices, Inc., Blackfin® DSP. The
Blackfin has an integrated SPI port that can be connected directly
to the SPI pins of the AD5360 or AD5361, and programmable
I/O pins that can be used to set or read the state of the digital
input or output pins associated with the interface.
AD5360/AD5361
OUTLINE DIMENSIONS
0.75
0.60
0.45
12.20
12.00 SQ
11.80
1.60
MAX
52
40
39
1
PIN 1
10.20
10.00 SQ
9.80
TOP VIEW
(PINS DOWN)
1.45
1.40
1.35
0.15
0.05
0.20
0.09
7°
3.5°
0°
SEATING
PLANE
13
27
14
0.10
COPLANARITY
VIEW A
VIEW A
26
0.38
0.32
0.22
0.65
BSC
LEAD PITCH
051706-A
ROTATED 90° CCW
COMPLIANT TO JEDEC STANDARDS MS-026-BCC
Figure 27. 52-Lead Low Profile Quad Flat Package [LQFP]
(ST-52)
Dimensions shown in millimeters
8.00
BSC SQ
0.60 MAX
0.50
0.40
0.30
12° MAX
SEATING
PLANE
29
28
15 14
0.25 MIN
6.50
REF
0.80 MAX
0.65 TYP
0.50 BSC
6.25
6.10 SQ
5.95
EXPOSED
PAD
(BOTTOM VIEW)
7.75
BSC SQ
0.05 MAX
0.02 NOM
COPLANARITY
0.08
0.20 REF
COMPLIANT TO JEDEC STANDARDS MO-220-VLLD-2
112805-0
TOP
VIEW
PIN 1
INDICATOR
56 1
43
42
PIN 1
INDICATOR
1.00
0.85
0.80
0.30
0.23
0.18
0.60 MAX
Figure 28. 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
8 mm × 8 mm, Very Thin Quad (CP-56-1)
Dimensions shown in millimeter
ORDERING GUIDE
Model
AD5360BSTZ 1
AD5360BSTZ-REEL1
AD5360BCPZ1
AD5360BCPZ-REEL71
AD5361BSTZ1
AD5361BSTZ-REEL1
AD5361BCPZ1
AD5361BCPZ-REEL71
EVAL-AD5360EBZ1
EVAL-AD5361EBZ1
1
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
Package Description
52-Lead Low Profile Quad Flat Pack [LQFP]
52-Lead Low Profile Quad Flat Pack [LQFP]
56-Lead Lead Frame Chip Scale Package [LFCSP _VQ]
56-Lead Lead Frame Chip Scale Package [LFCSP _VQ]
52-Lead Low Profile Quad Flat Pack [LQFP]
52-Lead Low Profile Quad Flat Pack [LQFP]
56-Lead Lead Frame Chip Scale Package [LFCSP _VQ]
56-Lead Lead Frame Chip Scale Package [LFCSP _VQ]
Evaluation Board
Evaluation Board
Z = RoHS Compliant Part.
Rev. A | Page 27 of 28
Package Option
ST-52
ST-52
CP-56-1
CP-56-1
ST-52
ST-52
CP-56-1
CP-56-1
AD5360/AD5361
NOTES
©2007–2008 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D05761-0-2/08(A)
Rev. A | Page 28 of 28
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