LINER LTC2310-14 Octal, 12-bit sign, 1.5msps/ch simultaneous sampling adc Datasheet

LTC2320-12
Octal, 12-Bit + Sign,
1.5Msps/Ch Simultaneous
Sampling ADC
DESCRIPTION
FEATURES
1.5Msps/Ch Throughput Rate
nn Eight Simultaneously Sampling Channels
nn Guaranteed 12-Bit, No Missing Codes
nn 8V
P-P Differential Inputs with Wide Input
Common Mode Range
nn 77dB SNR (Typ) at f = 500kHz
IN
nn –90dB THD (Typ) at f = 500kHz
IN
nn Guaranteed Operation to 125°C
nn Single 3.3V or 5V Supply
nn Low Drift (20ppm/°C Max) 2.048V or 4.096V
Internal Reference
nn 1.8V to 2.5V I/O Voltages
nn CMOS or LVDS SPI-Compatible Serial I/O
nn Power Dissipation 20mW/Ch (Typ)
nn Small 52-Lead (7mm × 8mm) QFN Package
The LTC®2320-12 is a low noise, high speed octal 12‑bit
+ sign successive approximation register (SAR) ADC with
differential inputs and wide input common mode range.
Operating from a single 3.3V or 5V supply, the LTC2320‑12
has an 8VP-P differential input range, making it ideal for
applications which require a wide dynamic range with
high common mode rejection. The LTC2320-12 achieves
±0.25LSB INL typical, no missing codes at 12 bits and
77dB SNR.
nn
The LTC2320-12 has an onboard low drift (20ppm/°C max)
2.048V or 4.096V temperature-compensated reference.
The LTC2320-12 also has a high speed SPI-compatible
serial interface that supports CMOS or LVDS. The fast
1.5Msps per channel throughput with no latency makes
the LTC2320-12 ideally suited for a wide variety of high
speed applications. The LTC2320-12 dissipates only 20mW
per channel and offers nap and sleep modes to reduce the
power consumption to 26μW for further power savings
during inactive periods.
APPLICATIONS
High Speed Data Acquisition Systems
Communications
nn Remote Data Acquisition
nn Imaging
nn Optical Networking
nn Automotive
nn Multiphase Motor Control
nn
nn
TRUE DIFFERENTIAL INPUTS
NO CONFIGURATION REQUIRED
IN+, IN –
VDD
ARBITRARY
0V
VDD
VDD
DIFFERENTIAL
0V
VDD
AIN1+
S/H
AIN1–
AIN2+
S/H
AIN2–
AIN3+
S/H
AIN3–
AIN4+
S/H
AIN4–
0V
BIPOLAR
10µF
UNIPOLAR
0V
AIN5+
S/H
AIN5–
AIN6+
S/H
AIN6–
AIN7+
S/H
AIN7–
AIN8+
S/H
AIN8–
REF
EIGHT SIMULTANEOUS
SAMPLING CHANNELS
Document Feedback
1µF
1.8V TO 2.5V
3.3V OR 5V
VDD
GND
GND
MUX
12-BIT
+ SIGN
SAR ADC
CMOS/LVDS
SDR/DDR
REFBUFEN
MUX
12-BIT
+ SIGN
SAR ADC
SDO1
SDO2
SDO3
SDO4
SDO5
SDO6
SDO7
SDO8
CLKOUT
SCK
LTC2320-12
MUX
12-BIT
+ SIGN
SAR ADC
CNV
MUX
0
SAMPLE
CLOCK
10µF
–60
–80
–100
–140
232012 TA01a
10µF
SNR = 78.4dB
THD = –90.9dB
–20 SINAD = 78.2dB
SFDR = 95.2dB
–40
–120
12-BIT
+ SIGN
SAR ADC
REFOUT1 REFOUT2 REFOUT3 REFOUT4
1µF
32k Point FFT fSMPL = 1.5Msps,
fIN = 500kHz
OVDD
AMPLITUDE (dBFS)
TYPICAL APPLICATION
All registered trademarks and trademarks are the property of their respective owners.
10µF
10µF
0
0.1
0.2 0.3 0.4 0.5
FREQUENCY (MHz)
0.6
0.7
232012 TA01b
Rev B
For more information www.analog.com
1
LTC2320-12
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
SCK/SCK+
DNC/SCK–
VDD
REFOUT4
GND
AIN8–
AIN8+
GND
AIN7–
AIN7+
VDD
TOP VIEW
52 51 50 49 48 47 46 45 44 43 42 41
AIN6– 1
40 SDO8/SDOD–
AIN6+ 2
39 SDO7/SDOD+
GND 3
38 GND
AIN5– 4
37 OVDD
AIN5+ 5
36 SDO6/SDOC–
REFOUT3 6
35 SDO5/SDOC+
GND 7
34 CLKOUTEN/CLKOUT –
53
GND
REF 8
33 CLKOUT/CLKOUT+
32 GND
REFOUT2 9
AIN4– 10
31 OVDD
AIN4+ 11
30 SDO4/SDOB–
GND 12
29 SDO3/SDOB+
AIN3– 13
28 SDO2/SDOA–
AIN3+ 14
27 SDO1/SDOA+
GND
CMOS/LVDS
CNV
SDR/DDR
REFOUT1
VDD
AIN1+
GND
AIN1–
AIN2+
VDD
15 16 17 18 19 20 21 22 23 24 25 26
AIN2–
Supply Voltage (VDD)...................................................6V
Supply Voltage (OVDD).................................................3V
Analog Input Voltage
AIN+, AIN – (Note 3).................... –0.3V to (VDD + 0.3V)
REFOUT1,2,3,4........................ .–0.3V to (VDD + 0.3V)
CNV........................................ –0.3V to (OVDD + 0.3V)
Digital Input Voltage
(Note 3)........................... (GND – 0.3V) to (OVDD + 0.3V)
Digital Output Voltage
(Note 3)........................... (GND – 0.3V) to (OVDD + 0.3V)
Operating Temperature Range
LTC2320C................................................. 0°C to 70°C
LTC2320I..............................................–40°C to 85°C
LTC2320H........................................... –40°C to 125°C
Storage Temperature Range................... –65°C to 150°C
REFBUFEN
(Notes 1, 2)
UKG PACKAGE
52-LEAD (7mm × 8mm) PLASTIC QFN
TJMAX = 150°C, θJA = 31°C/W
EXPOSED PAD (PIN 53) IS GND, MUST BE SOLDERED TO PCB
ORDER INFORMATION
http://www.linear.com/product/LTC2320-12#orderinfo
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC2320CUKG-12#PBF
LTC2320CUKG-12#TRPBF
LTC2320UKG-12
52-Lead (7mm × 8mm) Plastic QFN
0°C to 70°C
LTC2320IUKG-12#PBF
LTC2320IUKG-12#TRPBF
LTC2320UKG-12
52-Lead (7mm × 8mm) Plastic QFN
–40°C to 85°C
LTC2320HUKG-12#PBF
LTC2320HUKG-12#TRPBF
LTC2320UKG-12
52-Lead (7mm × 8mm) Plastic QFN
–40°C to 125°C
Consult ADI Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/. Some packages are available in 500 unit reels through
designated sales channels with #TRMPBF suffix.
2
Rev B
For more information www.analog.com
LTC2320-12
ELECTRICAL CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL
PARAMETER
CONDITIONS
Absolute Input Range (AIN+ to AIN–)
Absolute Input Range (AIN+ to AIN–)
VIN+ – VIN–
Input Differential Voltage Range
VCM
Common Mode Input Range
VIN = VIN+ – VIN–
VCM = (VIN+ – VIN–)/2
IIN
Analog Input DC Leakage Current
+
VIN
VIN–
MIN
MAX
UNITS
0
VDD
V
0
VDD
V
l
–REFOUT1,2,3,4
REFOUT1,2,3,4
V
l
0
VDD
V
l
–1
1
μA
(Note 5)
l
(Note 5)
l
CIN
Analog Input Capacitance
CMRR
Input Common Mode Rejection Ratio
VIHCNV
CNV High Level Input Voltage
l
VILCNV
CNV Low Level Input Voltage
l
IINCNV
CNV Input Current
l
TYP
fIN = 500kHz
10
pF
102
dB
1.5
V
–10
0.5
V
10
μA
CONVERTER CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL PARAMETER
CONDITIONS
MIN
Resolution
l
12
No Missing Codes
l
12
Transition Noise
INL
Integral Linearity Error
DNL
Differential Linearity Error
BZE
Bipolar Zero-Scale Error
MAX
(Note 6)
UNITS
Bits
Bits
0.2
LSBRMS
l
–1
±0.25
1
LSB
l
–0.99
±0.4
0.99
LSB
(Note 7)
l
–1.5
0
1.5
LSB
Bipolar Full-Scale Error
VREFOUT1,2,3,4 = 4.096V (REFBUFEN Grounded) (Note 7)
l
–3
Bipolar Full-Scale Error Drift
VREFOUT1,2,3,4 = 4.096V (REFBUFEN Grounded)
Bipolar Zero-Scale Error Drift
FSE
TYP
0.005
0
LSB/°C
3
15
LSB
ppm/°C
DYNAMIC ACCURACY
The l denotes the specifications which apply over the full operating temperature range,
otherwise specifications are at TA = 25°C and AIN = –1dBFS (Notes 4, 8).
SYMBOL PARAMETER
CONDITIONS
MIN
TYP
77
dB
77
dB
77
dB
77.5
dB
SINAD
Signal-to-(Noise + Distortion) Ratio fIN = 500kHz, VREFOUT1,2,3,4 = 4.096V, Internal Reference
fIN = 500kHz, VREFOUT1,2,3,4 = 5V, External Reference
l
74
SNR
Signal-to-Noise Ratio
fIN = 500kHz, VREFOUT1,2,3,4 = 4.096V, Internal Reference
l
75
fIN = 500kHz, VREFOUT1,2,3,4 = 5V, External Reference
THD
Total Harmonic Distortion
fIN = 500kHz, VREFOUT1,2,3,4 = 4.096V, Internal Reference
–90
l
fIN = 500kHz, VREFOUT1,2,3,4 = 5V, External Reference
SFDR
dB
dB
93
dB
dB
–3dB Input Bandwidth
55
MHz
Aperture Delay
500
ps
Aperture Delay Matching
500
ps
fIN = 500kHz, VREFOUT1,2,3,4 = 5V, External Reference
Aperture Jitter
Transient Response
Full-Scale Step
l
76
–76
UNITS
93
Spurious Free Dynamic Range
fIN = 500kHz, VREFOUT1,2,3,4 = 4.096V, Internal Reference
–91
MAX
1
psRMS
30
ns
Rev B
For more information www.analog.com
3
LTC2320-12
INTERNAL REFERENCE CHARACTERISTICS
The l denotes the specifications which apply over the
full operating temperature range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL
PARAMETER
CONDITIONS
VREFOUT1,2,3,4
Internal Reference Output Voltage
4.75V < VDD < 5.25V
3.13V < VDD < 3.47V
l
l
VREF Temperature Coefficient
(Note 14)
l
MIN
TYP
MAX
UNITS
4.078
2.034
4.096
2.048
4.115
2.064
V
V
3
20
REFOUT1,2,3,4 Output Impedance
IREFOUT1,2,3,4
ppm/°C
0.25
Ω
VREFOUT1,2,3,4 Line Regulation
4.75V < VDD < 5.25V
0.3
mV/V
External Reference Current
REFBUFEN = 0V
REFOUT1,2,3,4 = 4.096V
REFOUT1,2,3,4 = 2.048V
(Notes 9, 10)
385
204
μA
μA
DIGITAL INPUTS AND DIGITAL OUTPUTS
The l denotes the specifications which apply over the
full operating temperature range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL PARAMETER
CMOS Digital Inputs and Outputs
CONDITIONS
MIN
TYP
MAX
UNITS
CMOS/LVDS = GND
VIH
High Level Input Voltage
VIL
Low Level Input Voltage
IIN
Digital Input Current
CIN
Digital Input Capacitance
VOH
High Level Output Voltage
IO = –500μA
l
VOL
Low Level Output Voltage
IO = 500μA
l
IOZ
Hi-Z Output Leakage Current
VOUT = 0V to OVDD
l
ISOURCE
Output Source Current
VOUT = 0V
l
–10
mA
ISINK
Output Sink Current
VOUT = OVDD
l
10
mA
LVDS Digital Inputs and Outputs
l
0.8 • OVDD
V
l
VIN = 0V to OVDD
l
–10
0.2 • OVDD
V
10
μA
5
l
pF
OVDD – 0.2
V
–10
0.2
V
10
μA
CMOS/LVDS = OVDD
VID
LVDS Differential Input Voltage
100Ω Differential Termination
OVDD = 2.5V
l
240
600
mV
VIS
LVDS Common Mode Input Voltage
100Ω Differential Termination
OVDD = 2.5V
l
1
1.45
V
VOD
LVDS Differential Output Voltage
100Ω Differential Termination
OVDD = 2.5V
l
220
350
600
mV
VOS
LVDS Common Mode Output Voltage
100Ω Differential Termination
OVDD = 2.5V
l
0.85
1.2
1.4
V
VOD_LP
Low Power LVDS Differential Output Voltage
100Ω Differential Termination
OVDD = 2.5V
l
100
200
350
mV
VOS_LP
Low Power LVDS Common Mode Output Voltage
100Ω Differential Termination
OVDD = 2.5V
l
0.85
1.2
1.4
V
4
Rev B
For more information www.analog.com
LTC2320-12
POWER REQUIREMENTS
The l denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL
PARAMETER
CONDITIONS
VDD
Supply Voltage
5V Operation
3.3V Operation
l
l
IVDD
Supply Current
1.5Msps Sample Rate (IN+ = IN– = 0V)
l
CMOS I/O Mode
MIN
TYP
4.75
3.13
31
UNITS
5.25
3.47
V
V
38
mA
CMOS/LVDS = GND
OVDD
Supply Voltage
IOVDD
Supply Current
1.5Msps Sample Rate (CL = 5pF)
l
4.4
INAP
Nap Mode Current
Conversion Done (IVDD)
l
ISLEEP
Sleep Mode Current
Sleep Mode (IVDD + IOVDD)
l
PD_3.3V
Power Dissipation
VDD = 3.3V, 1.5Msps Sample Rate
Nap Mode
Sleep Mode
PD_5V
Power Dissipation
VDD = 5V, 1.5Msps Sample Rate
Nap Mode
Sleep Mode
LVDS I/O Mode
MAX
1.71
l
2.63
V
7
mA
5.3
6.2
mA
20
110
µA
l
l
l
102
18
20
130
26.6
355
mW
mW
µW
l
l
l
162
27
30
208
31.2
525
mW
mW
µW
2.63
V
CMOS/LVDS = OVDD, OVDD = 2.5V
OVDD
Supply Voltage
2.37
IOVDD
Supply Current
1.5Msps Sample Rate (CL = 5pF, RL = 100Ω)
l
26
INAP
Nap Mode Current
Conversion Done (IVDD)
l
ISLEEP
Sleep Mode Current
Sleep Mode (IVDD + IOVDD)
l
PD_3.3V
Power Dissipation
VDD = 3.3V, 1.5Msps Sample Rate
Nap Mode
Sleep Mode
PD_5V
Power Dissipation
VDD = 5V, 1.5Msps Sample Rate
Nap Mode
Sleep Mode
l
34
mA
5.3
6.2
mA
20
110
µA
l
l
l
151
52
80
196
60
355
mW
mW
µW
l
l
l
214
51
30
275
68.5
525
mW
mW
µW
ADC TIMING CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL
PARAMETER
fSMPL
Maximum Sampling Frequency
tCYC
Time Between Conversions
CONDITIONS
MIN
TYP
l
(Note 11) tCYC = tCNVH + tCONV + tREADOUT
l
0.667
MAX
UNITS
1.5
Msps
1000
µs
450
ns
tCONV
Conversion Time
l
tCNVH
CNV High Time
l
tACQUISITION
Sampling Aperture
(Note 11) tACQUISITION = tCYC – tCONV
215
ns
tWAKE
REFOUT1,2,3,4 Wake-Up Time
CREFOUT1,2,3,4 = 10µF
50
ms
CMOS I/O Mode, SDR
30
ns
CMOS/LVDS = GND, SDR/ DDR = GND
tSCK
SCK Period
(Note 13)
l
9.1
ns
tSCKH
tSCKL
SCK High Time
l
4.1
ns
SCK Low Time
l
4.1
ns
tHSDO_SDR
SDO Data Remains Valid Delay from CLKOUT↓
CL = 5pF (Note 12)
l
0
1.5
ns
(Note 12)
l
tDSCKCLKOUT
SCK to CLKOUT Delay
2
4.5
ns
Rev B
For more information www.analog.com
5
LTC2320-12
ADC TIMING CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C (Note 4).
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
tDCNVSDOZ
Bus Relinquish Time After CNV↑
(Note 11)
l
3
ns
tDCNVSDOV
SDO Valid Delay from CNV↓
(Note 11)
l
3
ns
tDSCKHCNVH
SCK Delay Time to CNV↑
(Note 11)
l
0
CMOS I/O Mode, DDR
ns
CMOS/LVDS = GND, SDR/ DDR = OVDD
tSCK
SCK Period
l
18.2
ns
tSCKH
SCK High Time
l
8.2
ns
tSCKL
SCK Low Time
l
8.2
ns
tHSDO_DDR
SDO Data Remains Valid Delay from CLKOUT↓
CL = 5pF (Note 12)
l
0
1.5
ns
tDSCKCLKOUT
SCK to CLKOUT Delay
(Note 12)
l
2
4.5
ns
tDCNVSDOZ
Bus Relinquish Time After CNV↑
(Note 11)
l
3
ns
tDCNVSDOV
SDO Valid Delay from CNV↓
(Note 11)
l
3
ns
tDSCKHCNVH
SCK Delay Time to CNV↑
(Note 11)
l
0
ns
LVDS I/O Mode, SDR
CMOS/LVDS = OVDD, SDR/DDR = GND
tSCK
SCK Period
l
3.3
ns
tSCKH
SCK High Time
l
1.5
ns
tSCKL
SCK Low Time
l
1.5
ns
tHSDO_SDR
SDO Data Remains Valid Delay from CLKOUT↓
CL = 5pF OVDD = 2.5V
l
0
1.5
ns
tDSCKCLKOUT
SCK to CLKOUT Delay
OVDD = 2.5V
l
2
4
ns
tDSCKHCNVH
SCK Delay Time to CNV↑
(Note 11)
l
0
LVDS I/O Mode, DDR
ns
CMOS/LVDS = OVDD, SDR/DDR = OVDD
tSCK
SCK Period
l
6.6
ns
tSCKH
SCK High Time
l
3
ns
tSCKL
SCK Low Time
l
3
ns
tHSDO_DDR
SDO Data Remains Valid Delay from CLKOUT↓
CL = 5pF OVDD = 2.5V
l
0
1.5
ns
tDSCKCLKOUT
SCK to CLKOUT Delay
OVDD = 2.5V
l
2
4
ns
tDSCKHCNVH
SCK Delay Time to CNV↑
(Note 11)
l
0
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: All voltage values are with respect to ground.
Note 3: When these pin voltages are taken below ground, or above VDD or
OVDD, they will be clamped by internal diodes. This product can handle input
currents up to 100mA below ground, or above VDD or OVDD, without latch-up.
Note 4: VDD = 5V, OVDD = 2.5V, REFOUT1,2,3,4 = 4.096V, fSMPL = 1.5MHz.
Note 5: Recommended operating conditions.
Note 6: Integral nonlinearity is defined as the deviation of a code from a
straight line passing through the actual endpoints of the transfer curve.
The deviation is measured from the center of the quantization band.
Note 7: Bipolar zero error is the offset voltage measured from –0.5LSB
when the output code flickers between 0000 0000 0000 0 and 1111 1111
1111 1. Full-scale bipolar error is the worst-case of –FS or +FS untrimmed
6
ns
deviation from ideal first and last code transitions and includes the effect
of offset error.
Note 8: All specifications in dB are referred to a full-scale ±4.096V input
with REF = 4.096V.
Note 9: When REFOUT1,2,3,4 is overdriven, the internal reference buffer
must be turned off by setting REFBUFEN = 0V.
Note 10: fSMPL = 1.5MHz, IREFOUT1,2,3,4 varies proportionally with sample rate.
Note 11: Guaranteed by design, not subject to test.
Note 12: Parameter tested and guaranteed at OVDD = 1.71V and OVDD = 2.5V.
Note 13: tSCK of 9.1ns allows a shift clock frequency up to 105MHz for
rising edge capture.
Note 14: Temperature coefficient is calculated by dividing the maximum
change in output voltage by the specified temperature range.
Note 15: CNV is driven from a low jitter digital source, typically at OVDD
logic levels.
Rev B
For more information www.analog.com
LTC2320-12
ADC TIMING CHARACTERISTICS
0.8 • OVDD
tWIDTH
0.2 • OVDD
tDELAY
tDELAY
0.8 • OVDD
0.8 • OVDD
0.2 • OVDD
0.2 • OVDD
50%
50%
232012 F01
Figure 1. Voltage Levels for Timing Specifications
Rev B
For more information www.analog.com
7
LTC2320-12
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C, VDD = 5V, OVDD = 2.5V, REFOUT1,2,3,4
= 4.096V, fSMPL = 1.5Msps, unless otherwise noted.
Integral Nonlinearity
vs Output Code
Differential Nonlinearity
vs Output Code
1.00
DC
DC Histogram
Histogram
1.0
70000
0.5
52500
0.75
0.25
0
–0.25
–0.50
Right Click In Graph Area for Menu
Double Click In Graph Area for Data Setup
0
COUNTS
DNL ERROR (LSB)
INL ERROR (LSB)
0.50
–0.5
35000
17500
–0.75
–1.00
–4096
–2048
0
2048
OUTPUT CODE
–1.0
–4096
4096
–2048
0
2048
OUTPUT CODE
232012 G01
–80
–100
–120
–140
80.0
–80
79.5
–84
79.0
SNR
78.5
78.0
SINAD
77.5
77.0
76.5
76.0
75.5
0
0.1
0.2 0.3 0.4 0.5
FREQUENCY (MHz)
0.6
0.7
75.0
THD, Harmonics vs Input Common
0
0.1
0.2
0.3 0.4 0.5 0.6
FREQUENCY (MHz)
–96
–100
–104
–108
HD2
HD3
–112
fIN = 500kHz
HD2
–108
–112
0.7
0.8
–120
0
0.1
0.2
0.3 0.4 0.5 0.6
FREQUENCY (MHz)
72
70
68
0.8
0
32k Point FFT, IMD, fSMPL = 1.5Msps,
AININ+ = 490kHz, AININ– = 510kHz
THD = 87dB
VCM = 20kHz, 4VP-P
–20
74
0.7
232012 G06
SINAD
–40
–60
–80
–100
–120
66
–120
1.5 1.7 1.9 2.1 2.3 2.5 2.7 2.9 3.1 3.3
INPUT COMMON MODE (V)
64
0.5
8
HD3
–104
SNR
76
–116
232012 G07
–96
–100
SNR, SINAD vs Reference Voltage,
fIN = 500kHz
78
THD
2
THD
–92
AMPLITUDE (dBFS)
–92
80
fIN = 500kHz
SNR, SINAD LEVEL (dBFS)
THD, HARMONICS LEVEL (dBFS)
–88
–88
232012 G05
Mode
Mode
–84
1
–116
232012 G04
–80
0
CODE
THD, Harmonics vs Input
Frequency (1kHz to 750kHz)
THD, HARMONICS LEVEL (dBFS)
–60
–1
232012 G03
SNR, SINAD vs Input Frequency
(1kHz to 750kHz)
IN
SNR = 78.4dB
THD = –90.9dB
–20 SINAD = 78.2dB
SFDR = 95.2dB
–40
–2
232012 G02
SNR, SINAD LEVEL (dBFS)
AMPLITUDE (dBFS)
0
32k Point FFT, fSMPL = 1.5Msps,
fIN = 500kHz SMPL
0
4096
1
1.5
2
2.5
3 3.5
VREFOUT(V)
4
4.5
5
232012 G08
–140
0
0.1
0.2 0.3 0.4 0.5
FREQUENCY (MHz)
0.6
0.7
232012 G09
Rev B
For more information www.analog.com
LTC2320-12
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C, VDD = 5V, OVDD = 2.5V, REFOUT1,2,3,4
= 4.096V, fSMPL = 1.5Msps, unless otherwise noted.
CMRR
CMRRvs
vsInput
InputFrequency
Frequency
120
–90
VCM = 4VP-P
–92
100
OUTPUT CODE (LSB)
105
3072
–93
CROSSTALK (dB)
110
–94
–95
–96
–97
1024
IN+ = 1.5MHz SQUARE WAVE
IN– = 0V
–99
0
500
1000
FREQUENCY (kHz)
1500
–100
0
100
200 300 400 500
FREQUENCY (kHz)
600
–1024
–20 –10 0 10 20 30 40 50 60 70 80 90
SETTLING TIME (ns)
700
232012 G11
Step Response
(Fine Settling)
232012 G12
External Reference Supply
Current vs Sample Frequency
100
REF Output
Output vs
vs Temperature
Temperature
REF
400
1.00
REFBUFEN = 0V
350 (EXT REF BUF
80
60
SUPPLY CURRENT (uA)
DEVIATION FROM FINAL VALUE (LSB)
4.096V RANGE
0
232012 G10
40
20
0
–20
–40
4.096V RANGE
–60
IN+ = 1.5MHz
SQUARE WAVE
–80
250
200
0.50
OVERDRIVING REF BUF)
300
VREFOUT1,2,3,4 = 4.096V
150
100
VREFOUT1,2,3,4 = 2.048V
50
IN– = 0V
–100
–20 –10 0 10 20 30 40 50 60 70 80 90
SETTLING TIME (ns)
0
0
232012 G13
0.3
0.6
0.9
1.2
SAMPLE FREQUENCY (Msps)
0.250
–1.00
–2.00
–3.00
–55 –35 –15
1.5
OVDD Current vs SCK Frequency,
CLOAD = 10pF
8
OVDD CURRENT CMOS (mA)
SUPPLY CURRENT (mA)
29
VDD = 5V
25
VDD = 3.3V
23
21
5 25 45 65 85 105 125
TEMPERATURE (°C)
232012 G16
19
32
FULL SCALE SINUSOIDAL INPUT
LVDS (4 LANES)
6
24
4
CMOS(1.8V, 8 LANES)
3
0.3
0.6
0.9
1.2
SAMPLE FREQUENCY (Msps)
1.5
232012 G17
22
20
18
2
LOW POWER LVDS (4 LANES)
16
1
0
28
CMOS (2.5V, 8 LANES) 26
5
0
30
OVDD CURRENT LVDS (mA)
–0.125
CLOAD = 10pF,
7
27
5 25 45 65 85 105 125
TEMPERATURE (°C)
232012 G15
33
0
VDD = 5V
–1.50
–2.50
31
–0.250
–55 –35 –15
–0.50
Supply Current
vs
vs Sample
Sample Frequency
Frequency
0.125
VDD = 3.3V
0
232012 G14
Offset
Offset Error
Error vs
vs Temperature
Temperature
LSB
2048
–98
95
REF OUTPUT ERROR (mV)
CMRR (dB)
4096
–91
115
90
Step Response
(Large Signal Settling)
Crosstalk vs Input Frequency
14
0
50
100
150
200
250
SCK FREQUENCY (MHz)
12
300
232012 G18
Rev B
For more information www.analog.com
9
LTC2320-12
PIN FUNCTIONS
Pins that are the same for all digital I/O modes.
AIN6+, AIN6– (Pins 2, 1): Analog Differential Input Pins.
Full-scale range (AIN6+ – AIN6–) is ±REFOUT3 voltage.
These pins can be driven from VDD to GND.
GND (Pins 3, 7, 12, 18, 26, 32, 38, 46, 49): Ground.
These pins and exposed pad (Pin 53) must be tied directly
to a solid ground plane.
AIN5+, AIN5– (Pins 5, 4): Analog Differential Input Pins.
Full-scale range (AIN5+ – AIN5–) is ±REFOUT3 voltage.
These pins can be driven from VDD to GND.
REFOUT3 (Pin 6): Reference Buffer 3 Output. An onboard
buffer nominally outputs 4.096V to this pin. This pin is
referred to GND and should be decoupled closely to the
pin with a 10µF (X5R, 0805 size) ceramic capacitor. The
internal buffer driving this pin may be disabled by grounding the REFBUFEN pin. If the buffer is disabled, an external
reference may drive this pin in the range of 1.25V to 5V.
REF (Pin 8): Common 4.096V reference output. Decouple
to GND with a 1μF low ESR ceramic capacitor. May be
overdriven with a single external reference to establish a
common reference for ADC cores 1 through 4.
REFOUT2 (Pin 9): Reference Buffer 2 Output. An onboard
buffer nominally outputs 4.096V to this pin. This pin is
referred to GND and should be decoupled closely to the
pin with a 10µF (X5R, 0805 size) ceramic capacitor. The
internal buffer driving this pin may be disabled by grounding the REFBUFEN pin. If the buffer is disabled, an external
reference may drive this pin in the range of 1.25V to 5V.
AIN4+, AIN4– (Pins 11, 10): Analog Differential Input Pins.
Full-scale range (AIN4+ – AIN4–) is ±REFOUT2 voltage.
These pins can be driven from VDD to GND.
AIN3+, AIN3– (Pins 14, 13): Analog Differential Input Pins.
Full-scale range (AIN3+ – AIN3–) is ±REFOUT2 voltage.
These pins can be driven from VDD to GND.
10
VDD (Pins 15, 21, 44, 52): Power Supply. Bypass VDD to
GND with a 10µF ceramic capacitor and a 0.1µF ceramic
capacitor close to the part. The VDD pins should be shorted
together and driven from the same supply.
AIN2+, AIN2– (Pins 17, 16): Analog Differential Input Pins.
Full-scale range (AIN2+ – AIN2–) is ±REFOUT1 voltage.
These pins can be driven from VDD to GND.
AIN1+, AIN1– (Pins 20, 19): Analog Differential Input Pins.
Full-scale range (AIN1+ – AIN1–) is ±REFOUT1 voltage.
These pins can be driven from VDD to GND.
REFOUT1 (Pin 22): Reference Buffer 1 Output. An onboard
buffer nominally outputs 4.096V to this pin. This pin is
referred to GND and should be decoupled closely to the
pin with a 10µF (X5R, 0805 size) ceramic capacitor. The
internal buffer driving this pin may be disabled by grounding the REFBUFEN pin. If the buffer is disabled, an external
reference may drive this pin in the range of 1.25V to 5V.
SDR/DDR (Pin 23): Double Data Rate Input. Controls the
frequency of SCK and CLKOUT. Tie to GND for the falling
edge of SCK to shift each serial data output (Single Data
Rate, SDR). Tie to OVDD to shift serial data output on each
edge of SCK (Double Data Rate, DDR). CLKOUT will be a
delayed version of SCK for both pin states.
CNV (Pin 24): Convert Input. This pin, when high, defines
the acquisition phase. When this pin is driven low, the
conversion phase is initiated and output data is clocked
out. This input must be driven at OVDD levels with a low
jitter pulse. This pin is unaffected by the CMOS/LVDS pin.
CMOS/LVDS (Pin 25): I/O Mode Select. Ground this pin
to enable CMOS mode, tie to OVDD to enable LVDS mode.
Float this pin to enable low power LVDS mode.
OVDD (Pins 31, 37): I/O Interface Digital Power. The range
of OVDD is 1.71V to 2.63V. This supply is nominally set
to the same supply as the host interface (CMOS: 1.8V or
2.5V, LVDS: 2.5V). Bypass OVDD to GND (Pins 32 and 38)
with 0.1µF capacitors.
Rev B
For more information www.analog.com
LTC2320-12
PIN FUNCTIONS
REFBUFEN (Pin 43): Reference Buffer Output Enable. Tie
to VDD when using the internal reference. Tie to ground
to disable the internal REFOUT1–4 buffers for use with
external voltage references. This pin has a 500k internal
pull-up to VDD.
REFOUT4 (Pin 45): Reference Buffer 4 Output. An onboard
buffer nominally outputs 4.096V to this pin. This pin is
referred to GND and should be decoupled closely to the
pin with a 10µF (X5R, 0805 size) ceramic capacitor. The
internal buffer driving this pin may be disabled by grounding the REFBUFEN pin. If the buffer is disabled, an external
reference may drive this pin in the range of 1.25V to 5V.
AIN8+, AIN8– (Pins 48, 47): Analog Differential Input Pins.
Full-scale range (AIN8+ – AIN8–) is ±REFOUT4 voltage.
These pins can be driven from VDD to GND.
AIN7+, AIN7– (Pins 51, 50): Analog Differential Input Pins.
Full-scale range (AIN7+ – AIN7–) is ±REFOUT4 voltage.
These pins can be driven from VDD to GND.
Exposed Pad (Pin 53): Ground. Solder this pad to ground.
CMOS DATA OUTPUT OPTION (CMOS/LVDS = LOW)
SDO1 (Pin 27): CMOS Serial Data Output for ADC Channel 1. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO1 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH2, CH3, CH4, CH5,
CH6, CH7, CH8).
SDO2 (Pin 28): CMOS Serial Data Output for ADC Channel 2. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO2 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH3, CH4, CH5, CH6,
CH7, CH8, CH1).
SDO3 (Pin 29): CMOS Serial Data Output for ADC Channel 3. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO3 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH4, CH5, CH6, CH7,
CH8, CH1, CH2).
SDO4 (Pin 30): CMOS Serial Data Output for ADC Channel 4. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO4 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH5, CH6, CH7, CH8,
CH1, CH2, CH3).
CLKOUT (Pin 33): Serial Data Clock Output. CLKOUT
provides a skew-matched clock to latch the SDO output
at the receiver (FPGA). The logic level is determined by
OVDD. This pin echoes the input at SCK with a small delay.
CLKOUTEN (Pin 34): CLKOUT can be disabled by tying
Pin 34 to OVDD for a small power savings. If CLKOUT is
used, ground this pin.
SDO5 (Pin 35): CMOS Serial Data Output for ADC Channel 5. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO5 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH6, CH7, CH8, CH1,
CH2, CH3, CH4).
SDO6 (Pin 36): CMOS Serial Data Output for ADC Channel 6. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO6 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH7, CH8, CH1, CH2,
CH3, CH4, CH5).
Rev B
For more information www.analog.com
11
LTC2320-12
PIN FUNCTIONS
SDO7 (Pin 39): CMOS Serial Data Output for ADC Channel 7. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO7 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH8, CH1, CH2, CH3,
CH4, CH5, CH6).
SDO8 (Pin 40): CMOS Serial Data Output for ADC Channel 8. The conversion result is shifted MSB first on each
falling edge of SCK in SDR mode and each SCK edge in
DDR mode. 13 SCK edges are required for 13-bit conversion data to be read from SDO8 in SDR mode, 13 SCK
edges in DDR mode. Supplying more clocks will yield
data from subsequent channels (CH1, CH2, CH3, CH4,
CH5, CH6, CH7).
SCK (Pin 41): Serial Data Clock Input. The falling edge
of this clock shifts the conversion result MSB first onto
the SDO pins in SDR mode (DDR = LOW). In DDR mode
(SDR/DDR = HIGH) each edge of this clock shifts the
conversion result MSB first onto the SDO pins. The logic
level is determined by OVDD.
DNC (Pin 42): In CMOS mode do not connect this pin.
LVDS DATA OUTPUT OPTION (CMOS/LVDS = HIGH OR
FLOAT)
SDOA+, SDOA– (Pins 27, 28): LVDS Serial Data Output for
ADC Channels 1 and 2. The conversion result is shifted CH1
MSB first on each falling edge of SCK in SDR mode and
each SCK edge in DDR mode. 32 SCK edges are required
for 13-bit conversion data to be read from AIN1 and AIN2
on SDOA in SDR mode, 13 SCK edges in DDR mode.
Supplying more clocks will yield data from subsequent
channels (CH3, CH4, CH5, CH6, CH7, CH8).Terminate
with a 100Ω resistor at the receiver (FPGA).
SDOB+, SDOB– (Pins 29, 30): LVDS Serial Data Output for
ADC Channels 3 and 4. The conversion result is shifted CH3
MSB first on each falling edge of SCK in SDR mode and
12
each SCK edge in DDR mode. 32 SCK edges are required
for 13-bit conversion data to be read from AIN3 and AIN4
on SDOB in SDR mode, 13 SCK edges in DDR mode.
Supplying more clocks will yield data from subsequent
channels (CH5, CH6, CH7, CH8, CH1, CH2).Terminate
with a 100Ω resistor at the receiver (FPGA).
CLKOUT+, CLKOUT– (Pins 33, 34): Serial Data Clock
Output. CLKOUT provides a skew-matched clock to
latch the SDO output at the receiver. These pins echo the
input at SCK with a small delay. These pins must be differentially terminated by an external 100Ω resistor at the
receiver (FPGA).
SDOC+, SDOC– (Pins 35, 36): LVDS Serial Data Output for
ADC channels 5 and 6. The conversion result is shifted CH5
MSB first on each falling edge of SCK in SDR mode and
each SCK edge in DDR mode. 32 SCK edges are required
for 13-bit conversion data to be read from AIN5 and AIN6
on SDOA in SDR mode, 13 SCK edges in DDR mode.
Supplying more clocks will yield data from subsequent
channels (CH7, CH8, CH1, CH2, CH3, CH4).Terminate
with a 100Ω resistor at the receiver (FPGA).
SDOD+, SDOD– (Pins 39, 40): LVDS Serial Data Output
for ADC Channels 7 and 8. The conversion result is shifted
CH7 MSB first on each falling edge of SCK in SDR mode
and each SCK edge in DDR mode. 32 SCK edges are required for 13-bit conversion data to be read from AIN7 and
AIN8 on SDOA in SDR mode, 13 SCK edges in DDR mode.
Supplying more clocks will yield data from subsequent
channels (CH1, CH2, CH3, CH4, CH5, CH6).Terminate
with a 100Ω resistor at the receiver (FPGA).
SCK+, SCK– (Pins 41, 42): Serial Data Clock Input. The
falling edge of this clock shifts the conversion result MSB
first onto the SDO pins in SDR mode (SDR/DDR = LOW).
In DDR mode (SDR/DDR = HIGH) each edge of this clock
shifts the conversion result MSB first onto the SDO pins.
These pins must be differentially terminated by an external
100Ω resistor at the receiver (ADC).
Rev B
For more information www.analog.com
LTC2320-12
FUNCTIONAL BLOCK DIAGRAM
CMOS IO Mode
VDD
(15, 21, 44, 52)
24 CNV
20
19
AIN1+
AIN1–
+
17
16
AIN2
AIN2–
+
S/H
–
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
REF
+
14
13
AIN3
AIN3–
+
11
10
AIN4
AIN4–
42
5
4
SCK
DNC
AIN5+
–
AIN5
+
2
1
AIN6
AIN6–
51
50
AIN7
AIN7–
+
48
47
AIN8
AIN8–
REF
SDO2
SDO3
SDO4
REFOUT2
×1
OUTPUT
CLOCK DRIVER
CLKOUT
CLKOUTEN
27
28
22
29
30
9
33
34
SDR/DDR 23
+
S/H
–
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
250μA
×1.7
×3.4
SDO6
SDO6
REFOUT3
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
CMOS
I/O
×1
+
S/H
–
REF
8
CMOS
I/O
CMOS
RECEIVERS
REF
+
SDO1
REFOUT1
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
CMOS
I/O
×1
+
S/H
–
REF
41
GND
(3, 7, 12, 18, 26, 32, 38, 46, 49, 53)
CMOS
I/O
×1
1.2V INT REF
SDO7
SDO8
REFOUT4
35
36
6
39
40
45
OVDD (31, 37)
REFBUFEN 43
CMOS/LVDS 25
232012 BDa
Rev B
For more information www.analog.com
13
LTC2320-12
FUNCTIONAL BLOCK DIAGRAM
LVDS IO Mode
VDD
(15, 21, 44, 52)
24 CNV
20
19
AIN1+
AIN1–
+
17
16
AIN2
AIN2–
+
S/H
–
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
REF
+
14
13
AIN3
AIN3–
+
11
10
AIN4
AIN4–
42
5
4
SCK+
SCK–
AIN5+
–
AIN5
+
2
1
AIN6
AIN6–
51
50
AIN7
AIN7–
+
48
47
AIN8
AIN8–
REF
SDOB+
SDOB–
REFOUT2
×1
OUTPUT
CLOCK DRIVER
CLKOUT+
CLKOUT–
27
28
22
29
30
9
33
34
SDR/DDR 23
+
S/H
–
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
250μA
×1.7
×3.4
SDOC+
SDOC–
REFOUT3
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
LVDS
I/O
×1
+
S/H
–
REF
8
LVDS
I/O
LVDS
RECEIVERS
REF
+
SDOA+
SDOA–
REFOUT1
12-BIT + SIGN
SAR ADC
MUX
+
S/H
–
LVDS
I/O
×1
+
S/H
–
REF
41
GND
(3, 7, 12, 18, 26, 32, 38, 46, 49, 53)
LVDS
I/O
×1
1.2V INT REF
SDOD+
SDOD–
REFOUT4
35
36
6
39
40
45
OVDD (31, 37)
REFBUFEN 43
CMOS/LVDS 25
232012 BDb
14
Rev B
For more information www.analog.com
LTC2320-12
TIMING DIAGRAM
SDR Mode, CMOS (Reading 1 Channel per SDO)
SAMPLE N
CNV
SAMPLE N+1
CONVERT
ACQUIRE
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
SCK
CLKOUT
SDO1
Hi-Z
Hi-Z
Hi-Z
DONT CARE
D12
D11 D10 D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
D12
CHANNEL 1
CONVERSION N
SDO8
Hi-Z
DONT CARE
D12
D11 D10 D9
D8
D7
D6
D5
D4
Hi-Z
CHANNEL 2
CONVERSION N
D3
D2
D1
D0
0
0
0
D12
CHANNEL 8
CONVERSION N
Hi-Z
CHANNEL 1
CONVERSION N
232012 TD01
DDR Mode, CMOS (Reading 1 Channel per SDO)
SAMPLE N
CNV
SAMPLE N+1
CONVERT
ACQUIRE
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
SCK
CLKOUT
SDO1
Hi-Z
Hi-Z
Hi-Z
DONT CARE
D12
D11 D10 D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
CHANNEL 1
CONVERSION N
SDO8
Hi-Z
DONT CARE
D12
D11 D10 D9
D8
D7
D6
D5
D4
D3
CHANNEL 8
CONVERSION N
D12
Hi-Z
CHANNEL 2
CONVERSION N
D2
D1
D0
0
0
0
D12
Hi-Z
CHANNEL 1
CONVERSION N
232012 TD02
Rev B
For more information www.analog.com
15
LTC2320-12
TIMING DIAGRAM
SDR Mode, LVDS (Reading 2 Channels per SDO Pair)
SAMPLE N
CNV
SAMPLE N+1
CONVERT
ACQUIRE
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
D8
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
D12 D11 D10 D9
D8
D7
D6
D5
D4 D3
27
28
29
30
31 32
D1
D0
0
0
SCK
CLKOUT
SDOA
DONT CARE
D12
D11 D10 D9
CHANNEL 1
CONVERSION N
SDOD
DONT CARE
D12
D11 D10 D9
D8
D7
D6
D5
D4
D3
D2
0
D12
CHANNEL 2
CONVERSION N
D2
D1
D0
0
0
0
D12 D11 D10 D9
D8
D7
D6
CHANNEL 7
CONVERSION N
D5
D4 D3
CHANNEL 3
CONVERSION N
D2
D1
D0
0
0
0
D12
CHANNEL 8
CONVERSION N
CHANNEL 1
CONVERSION N
232012 TD03
DDR Mode, LVDS (Reading 2 Channels per SDO Pair)
SAMPLE N
CNV
SAMPLE N+1
ACQUIRE
CONVERT
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
D8
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
17
18
19
20
21
22 23
24
25
26
D12 D11 D10 D9
D8
D7
D5
D4 D3
27
28
29
30
31 32
D1
D0
0
0
SCK
CLKOUT
SDOA
DONT CARE
D12
D11 D10 D9
D6
CHANNEL 1
CONVERSION N
SDOD
DONT CARE
D12
D11 D10 D9
D8
D7
D6
D5
D4
D3
D2
0
D12
CHANNEL 2
CONVERSION N
D2
D1
D0
0
0
0
D12 D11 D10 D9
CHANNEL 7
CONVERSION N
D8
D7
D6
D5
D4 D3
CHANNEL 8
CONVERSION N
CHANNEL 3
CONVERSION N
D2
D1
D0
0
0
0
D12
CHANNEL 1
CONVERSION N
232012 TD04
16
Rev B
For more information www.analog.com
LTC2320-12
APPLICATIONS INFORMATION
TRANSFER FUNCTION
The LTC2320-12 is a low noise, high speed 12-bit successive approximation register (SAR) ADC with differential
inputs and a wide input common mode range. Operating
from a single 3.3V or 5V supply, the LTC2320-12 has a
4VP-P or 8VP-P differential input range, making it ideal for
applications which require a wide dynamic range. The
LTC2320-12 achieves ±0.25LSB INL typical, no missing
codes at 12 bits and 77dB SNR.
The LTC2320-12 digitizes the full-scale voltage of 2 •
REFOUT into 213 levels, resulting in an LSB size of 1mV
with REFBUF = 4.096V. The ideal transfer function is shown
in Figure 2. The output data is in 2’s complement format.
When driven by fully differential inputs, the transfer function spans 213 codes. When driven by pseudo-differential
inputs, the transfer function spans 212 codes.
The LTC2320-12 has an onboard reference buffer and low
drift (20ppm/°C max) 4.096V temperature-compensated
reference. The LTC2320-12 also has a high speed SPIcompatible serial interface that supports CMOS or LVDS.
The fast 1.5Msps per channel throughput with no latency
makes the LTC2320-12 ideally suited for a wide variety of
high speed applications. The LTC2320-12 dissipates only
20mW per channel. Nap and sleep modes are also provided
to reduce the power consumption of the LTC2320-12 during inactive periods for further power savings.
OUTPUT CODE (TWO’S COMPLEMENT)
OVERVIEW
0 1111 1111 1111
0 1111 1111 1110
0 0000 0000 0001
0 0000 0000 0000
1 1111 1111 1111
1LSB = 2 • REFOUT
8192
1 0000 0000 0001
1 0000 0000 0000
–REFOUT
CONVERTER OPERATION
–1 0 1
LSB
LSB
INPUT VOLTAGE (V)
REFOUT – 1LSB
232012 F02
Figure 2. LTC2320-12 Transfer Function
The LTC2320-12 operates in two phases. During the acquisition phase, the sample capacitor is connected to the
analog input pins AIN+ and AIN – to sample the differential
analog input voltage, as shown in Figure 3. A falling edge on
the CNV pin initiates a conversion. During the conversion
phase, the 12-bit CDAC is sequenced through a successive
approximation algorithm effectively comparing the sampled
input with binary-weighted fractions of the reference voltage (e.g., VREFOUT/2, VREFOUT/4 … VREFOUT/32768) using
a differential comparator. At the end of conversion, a CDAC
output approximates the sampled analog input. The ADC
control logic then prepares the 12-bit digital output code
for serial transfer.
VDD
RON
15Ω
AIN+
CIN
10pF
BIAS
VOLTAGE
VDD
RON
15Ω
AIN–
CIN
10pF
232012 F03
Figure 3. The Equivalent Circuit for the Differential
Analog Input of the LTC2320-12
Table 1. Code Ranges for the Analog Input Operational Modes
MODE
SPAN (VIN+ – VIN–)
MIN CODE
MAX CODE
Fully Differential
–REFOUT to +REFOUT
1 0000 0000 0000
0 1111 1111 1111
Pseudo-Differential Bipolar
–-REFOUT/2 to +REFOUT/2
1 1000 0000 0000
0 0111 1111 1111
Pseudo-Differential Unipolar
0 to REFOUT
0 0000 0000 0000
0 1111 1111 1111
Rev B
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17
LTC2320-12
APPLICATIONS INFORMATION
Analog Input
The differential inputs of the LTC2320-12 provide great
flexibility to convert a wide variety of analog signals with
no configuration required. The LTC2320-12 digitizes the
difference voltage between the AIN+ and AIN – pins while
supporting a wide common mode input range. The analog
input signals can have an arbitrary relationship to each
other, provided that they remain between VDD and GND.
The LTC2320-12 can also digitize more limited classes of
analog input signals such as pseudo-differential unipolar/
bipolar and fully differential with no configuration required.
The analog inputs of the LTC2320-12 can be modeled
by the equivalent circuit shown in Figure 3. The backto-back diodes at the inputs form clamps that provide
ESD protection. In the acquisition phase, 10pF (CIN)
from the sampling capacitor in series with approximately
15Ω (RON) from the on-resistance of the sampling switch
is connected to the input. Any unwanted signal that is
common to both inputs will be reduced by the common
mode rejection of the ADC sampler. The inputs of the
ADC core draw a small current spike while charging the
CIN capacitors during acquisition.
Single-Ended Signals
Single-ended signals can be directly digitized by the
LTC2320-12. These signals should be sensed pseudodifferentially for improved common mode rejection. By
connecting the reference signal (e.g., ground sense) of
the main analog signal to the other AIN pin, any noise or
disturbance common to the two signals will be rejected
VREF
LT1819
+
–
0V
by the high CMRR of the ADC. The LTC2320-12 flexibility
handles both pseudo-differential unipolar and bipolar
signals, with no configuration required. The wide common
mode input range relaxes the accuracy requirements of
any signal conditioning circuits prior to the analog inputs.
Pseudo-Differential Bipolar Input Range
The pseudo-differential bipolar configuration represents
driving one of the analog inputs at a fixed voltage, typically
VREF /2, and applying a signal to the other AIN pin. In this
case the analog input swings symmetrically around the
fixed input yielding bipolar two’s complement output codes
with an ADC span of half of full-scale. This configuration
is illustrated in Figure 4, and the corresponding transfer
function in Figure 5. The fixed analog input pin need not
be set at VREF /2, but at some point within the VDD rails
allowing the alternate input to swing symmetrically around
this voltage. If the input signal (AIN+ – AIN –) swings beyond
±REFOUT1,2,3,4/2, valid codes will be generated by the
ADC and must be clamped by the user, if necessary.
Pseudo-Differential Unipolar Input Range
The pseudo-differential unipolar configuration represents
driving one of the analog inputs at ground and applying a
signal to the other AIN pin. In this case, the analog input
swings between ground and VREF yielding unipolar two’s
complement output codes with an ADC span of half of
full-scale. This configuration is illustrated in Figure 6, and
the corresponding transfer function in Figure 7. If the input
signal (AIN+ – AIN –) swings negative, valid codes will be
VREF
0V
LTC2320-12
25Ω
AIN1+
REFOUT1
VREF
REF
220pF
10k
VREF /2
10k
1µF
+
–
VREF /2
25Ω
AIN1–
SDO1
CLKOUT
SCK
ONLY CHANNEL 1 SHOWN FOR CLARITY
10µF
1µF
TO CONTROL
LOGIC
(FPGA, CPLD,
DSP, ETC.)
232012 F04
Figure 4. Pseudo-Differential Bipolar Application Circuit
18
Rev B
For more information www.analog.com
LTC2320-12
APPLICATIONS INFORMATION
ADC CODE
(2’s COMPLEMENT)
4095
2047
–VREF
–VREF /2
0
VREF /2
VREF
AIN
(AIN+ – AIN–)
DOTTED REGIONS AVAILABLE
–2048
232012 F05
–4096
Figure 5. Pseudo-Differential Bipolar Transfer Function
VREF
0V
LT1818
VREF
+
–
0V
LTC2320-12
25Ω
AIN1+
REFOUT1
REF
220pF
25Ω
AIN1–
SDO1
CLKOUT
SCK
10µF
1µF
TO CONTROL
LOGIC
(FPGA, CPLD,
DSP, ETC.)
232012 F06
Figure 6. Pseudo-Differential Unipolar Application Circuit
ADC CODE
(2’s COMPLEMENT)
4095
2047
–VREF
–VREF /2
–2048
–4096
0
VREF /2
VREF
AIN
(AIN+ – AIN–)
DOTTED REGIONS AVAILABLE
BUT UNUSED
232012 F07
Figure 7. Pseudo-Differential Unipolar Transfer Function
Rev B
For more information www.analog.com
19
LTC2320-12
APPLICATIONS INFORMATION
generated by the ADC and must be clamped by the user,
if necessary.
Single-Ended-to-Differential Conversion
While single-ended signals can be directly digitized as previously discussed, single-ended to differential conversion
circuits may also be used when higher dynamic range is
desired. By producing a differential signal at the inputs of
the LTC2320-12, the signal swing presented to the ADC is
maximized, thus increasing the achievable SNR.
The LT®1819 high speed dual operational amplifier is
recommended for performing single-ended-to-differential
conversions, as shown in Figure 8. In this case, the first
amplifier is configured as a unity-gain buffer and the
single-ended input signal directly drives the high impedance input of this amplifier.
VREF
To achieve the best distortion performance of the
LTC2320‑12, we recommend driving a fully-differential
signal through LT1819 amplifiers configured as two
unity-gain buffers, as shown in Figure 9. This circuit
achieves the full data sheet THD specification of –90dB at
input frequencies up to 500kHz. A fully-differential input
signal can span the maximum full-scale of the ADC, up to
±REFOUT1,2,3,4. The common mode input voltage can
span the entire supply range up to VDD, limited by the
input signal swing. The fully-differential configuration is
illustrated in Figure 10, with the corresponding transfer
function illustrated in Figure 11.
LT1819
+
–
0V
200Ω
Fully-Differential Inputs
VREF
VREF
0V
200Ω
LT1819
0V
0V
+
–
VREF /2
VREF
VREF
0V
+
–
VREF
+
–
VREF
0V
0V
232012 F08
232012 F09
Figure 8. Single-Ended to Differential Driver
VREF
0V
LT1819
+
–
Figure 9. LT1819 Buffering a Fully-Differential Signal Source
VREF
0V
LTC2320-12
25Ω
AIN1+
REF
220pF
VREF
0V
REFOUT1
VREF
+
–
0V
25Ω
AIN1–
SDO1
CLKOUT
SCK
ONLY CHANNEL 1 SHOWN FOR CLARITY
10µF
1µF
TO CONTROL
LOGIC
(FPGA, CPLD,
DSP, ETC.)
232012 F10
Figure 10. Fully-Differential Application Circuit
20
Rev B
For more information www.analog.com
LTC2320-12
APPLICATIONS INFORMATION
ADC CODE
(2’s COMPLEMENT)
SINGLE-ENDED
INPUT SIGNAL
4095
3.3nF
2047
–VREF
–VREF /2
IN+
50Ω
0
VREF /2
VREF
–2048
–4096
BW = 1MHz
AIN
(AINn + – AINn –)
232012 F11
Figure 11. Fully-Differential Transfer Function
INPUT DRIVE CIRCUITS
A low impedance source can directly drive the high impedance inputs of the LTC2320-12 without gain error. A
high impedance source should be buffered to minimize
settling time during acquisition and to optimize the distortion performance of the ADC. Minimizing settling time
is important even for DC inputs, because the ADC inputs
draw a current spike when during acquisition.
For best performance, a buffer amplifier should be used to
drive the analog inputs of the LTC2320-12. The amplifier
provides low output impedance to minimize gain error
and allows for fast settling of the analog signal during
the acquisition phase. It also provides isolation between
the signal source and the ADC inputs, which draw a small
current spike during acquisition.
Input Filtering
The noise and distortion of the buffer amplifier and signal
source must be considered since they add to the ADC noise
and distortion. Noisy input signals should be filtered prior
to the buffer amplifier input with a low bandwidth filter to
minimize noise. The simple 1-pole RC lowpass filter shown
in Figure 12 is sufficient for many applications.
The sampling switch on-resistance (RON) and the sample
capacitor (CIN) form a second lowpass filter that limits
the input bandwidth to the ADC core to 110MHz. A buffer
amplifier with a low noise density must be selected to
minimize the degradation of the SNR over this bandwidth.
IN–
SINGLE-ENDED
TO DIFFERENTIAL
DRIVER
LTC2320
232012 F12
Figure 12. Input Signal Chain
High quality capacitors and resistors should be used in the
RC filters since these components can add distortion. NPO
and silver mica type dielectric capacitors have excellent
linearity. Carbon surface mount resistors can generate
distortion from self heating and from damage that may
occur during soldering. Metal film surface mount resistors
are much less susceptible to both problems.
ADC REFERENCE
Internal Reference
The LTC2320-12 has an on-chip, low noise, low
drift (20ppm/°C max), temperature compensated bandgap reference. It is internally buffered and is available
at REF (Pin 8). The reference buffer gains the internal
reference voltage to 4.096V for supply voltages VDD = 5V
and to 2.048V for VDD = 3.3V. The REF pin also drives
the four internal reference buffers with a current limited
output (250μA) so it may be easily overdriven with an
external reference in the range of 1.25V to 5V. Bypass
REF to GND with a 1μF (X5R, 0805 size) ceramic capacitor
to compensate the reference buffer and minimize noise.
The 1μF capacitor should be as close as possible to the
LTC2320-12 package to minimize wiring inductance. The
voltage on the REF pin must be externally buffered if used
for external circuitry.
External Reference
The internal REFOUT1,2,3,4 buffers can also be overdriven from 1.25V to 5V with an external reference at
REFOUT1,2,3,4 as shown in Figure 13 (c). To do so,
REFBUFEN must be grounded to disable the REF buffers.
A 55k internal resistance loads the REFOUT1,2,3,4 pins
when the REF buffers are disabled. To maximize the input
Rev B
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21
LTC2320-12
APPLICATIONS INFORMATION
Table 2. Table 2. Reference Configurations and Ranges
REFERENCE CONFIGURATION
Internal Reference with Internal Buffers
Common External Reference with Internal Buffer (REF Pin
Externally Overdriven)
External Reference with REF Buffers Disabled
VDD
REFBUFEN
REF PIN
REFOUT1,2,3,4
PIN
DIFFERENTIAL INPUT
RANGE PIN
5V
5V
4.096V
4.096V
±4.096V
3.3V
3.3V
2.048V
2.048V
±2.048V
5V
5V
1.25V to 5V
1.25V to 3.3V
±1.25V to ±5V
3.3V
3.3V
1.25V to 5V
1.25V to 3.3V
±1.25V to ±3.3V
5V
0V
4.096V
1.25V to 5V
±1.25V to ±5V
3.3V
0V
2.048V
1.25V to 3.3V
±1.25V to ±3.3V
VDD
3.3V TO 5V
1µF
REF
LTC2320-12
REFOUT1
10µF
LTC6655-4.096
REFBUFEN
VIN
SHDN
REF
VOUT_F
VOUT_S
10µF
LTC2320-12
10µF
0.1µF
REFOUT1
10µF
REFOUT2
10µF
VDD
+5V
5V TO
13.2V
REFBUFEN
REFOUT2
10µF
REFOUT3
REFOUT3
10µF
REFOUT4
10µF
GND
10µF
232012 F13a
REFOUT4
GND
232012 F13b
(13a) LTC2320-12 Internal Reference Circuit
(13b) LTC2320-12 with a Shared External Reference Circuit
+5V
VDD
REFBUFEN
REF
1µF
5V TO 13.2V
LTC6655-4.096
VIN
VOUT_F
SHDN VOUT_S
REFOUT1
10µF
0.1µF
5V TO 13.2V
LTC2320-12
LTC6655-2.048
VIN
VOUT_F
SHDN VOUT_S
REFOUT2
10µF
0.1µF
5V TO 13.2V
LTC6655-2.5
VIN
VOUT_F
SHDN VOUT_S
REFOUT3
10µF
0.1µF
5V TO 13.2V
LTC6655-3
VIN
VOUT_F
SHDN VOUT_S
REFOUT4
10µF
0.1µF
GND
232012 F13c
(13c) LTC2320-12 with Different External Reference Voltages
Figure 13. Reference Connections
22
Rev B
For more information www.analog.com
LTC2320-12
APPLICATIONS INFORMATION
Internal Reference Buffer Transient Response
CNV
232012 F14
Figure 14. CNV Waveform Showing Burst Sampling
3072
2048
4.096V RANGE
1024
0
IN+ = 1.5MHz SQUARE WAVE
IN– = 0V
–1024
–20 –10 0 10 20 30 40 50 60 70 80 90
SETTLING TIME (ns)
232012 F15
The REFOUT1,2,3,4 pins of the LTC2320-12 draw charge
(QCONV) from the external bypass capacitors during each
conversion cycle. If the internal reference buffer is overdriven, the external reference must provide all of this charge
with a DC current equivalent to IREF = QCONV/tCYC.
Thus, the DC current draw of IREFOUT1,2,3,4 depends
on the sampling rate and output code. In applications
where a burst of samples is taken after idling for long
periods, as shown in Figure 14 , IREFBUF quickly goes from
approximately ~75µA to a maximum of 500µA for REFOUT
= 5V at 1.5Msps. This step in DC current draw triggers a
transient response in the external reference that must be
considered since any deviation in the voltage at REFOUT
will affect the accuracy of the output code. If an external
reference is used to overdrive REFOUT1,2,3,4, the fast
settling LTC6655 reference is recommended.
IDLE
PERIOD
4096
OUTPUT CODE (LSB)
signal swing and corresponding SNR, the LTC6655-5 is
recommended when overdriving REFOUT. The LTC6655-5
offers the same small size, accuracy, drift and extended
temperature range as the LTC6655-4.096. By using a 5V
reference, a higher SNR can be achieved. We recommend
bypassing the LTC6655-5 with a 10μF ceramic capacitor
(X5R, 0805 size) close to each of the REFOUT1,2,3,4
pins. If the REF pin voltage is used as a REFOUT reference when REFBUFEN is connected to GND, it should be
buffered externally.
Figure 15. Transient Response of the LTC2320-12
DYNAMIC PERFORMANCE
Fast Fourier transform (FFT) techniques are used to test
the ADC’s frequency response, distortion and noise at the
rated throughput. By applying a low distortion sine wave
and analyzing the digital output using an FFT algorithm,
the ADC’s spectral content can be examined for frequencies outside the fundamental. The LTC2320-12 provides
guaranteed tested limits for both AC distortion and noise
measurements.
Signal-to-Noise and Distortion Ratio (SINAD)
The signal-to-noise and distortion ratio (SINAD) is the
ratio between the RMS amplitude of the fundamental input
frequency and the RMS amplitude of all other frequency
components at the A/D output. The output is bandlimited
to frequencies from above DC and below half the sampling
frequency. Figure 16 shows that the LTC2320-12 achieves
a typical SINAD of 77dB at a 1.5MHz sampling rate with
a 500kHz input.
Signal-to-Noise Ratio (SNR)
The signal-to-noise ratio (SNR) is the ratio between the
RMS amplitude of the fundamental input frequency and
the RMS amplitude of all other frequency components
except the first five harmonics and DC. Figure 16 shows
that the LTC2320-12 achieves a typical SNR of 77dB at a
1.5MHz sampling rate with a 500kHz input.
Rev B
For more information www.analog.com
23
LTC2320-12
APPLICATIONS INFORMATION
SMPL
IN
SNR = 78.4dB
THD = –90.9dB
–20 SINAD = 78.2dB
SFDR = 95.2dB
–40
–60
–80
supply voltage drops below 2V. Once the supply voltage
re-enters the nominal supply voltage range, the POR will
reinitialize the ADC. No conversions should be initiated
until 10ms after a POR event to ensure the reinitialization
period has ended. Any conversions initiated before this
time will produce invalid results.
–100
33
–120
31
–140
0
0.1
0.2 0.3 0.4 0.5
FREQUENCY (MHz)
0.6
SUPPLY CURRENT (mA)
AMPLITUDE (dBFS)
0
0.7
232012 F16
Figure 16. 32k Point FFT of the LTC2320-12
Total Harmonic Distortion (THD)
V2 2 + V3 2 + V 4 2 + …+ VN
25
VDD = 3.3V
23
19
0
0.3
0.6
0.9
1.2
SAMPLE FREQUENCY (Msps)
1.5
232012 F17
Figure 17. Power Supply Current of the LTC2320-12
Versus Sampling Rate
2
TIMING AND CONTROL
V1
where V1 is the RMS amplitude of the fundamental
frequency and V2 through VN are the amplitudes of the
second through Nth harmonics.
POWER CONSIDERATIONS
The LTC2320-12 requires two power supplies: the 3.3V
to 5V power supply (VDD), and the digital input/output
interface power supply (OVDD). The flexible OVDD supply
allows the LTC2320-12 to communicate with any digital
logic operating between 1.8V and 2.5V. When using LVDS
I/O, the OVDD supply must be set to 2.5V.
Power Supply Sequencing
The LTC2320-12 does not have any specific power supply
sequencing requirements. Care should be taken to adhere
to the maximum voltage relationships described in the
Absolute Maximum Ratings section. The LTC2320‑12
has a power-on-reset (POR) circuit that will reset the
LTC2320-12 at initial power-up or whenever the power
24
VDD = 5V
27
21
Total harmonic distortion (THD) is the ratio of the RMS sum
of all harmonics of the input signal to the fundamental itself.
The out-of-band harmonics alias into the frequency band
between DC and half the sampling frequency (fSMPL /2).
THD is expressed as:
THD = 20 log
29
CNV Timing
The LTC2320-12 sampling and conversion is controlled
by CNV. A rising edge on CNV will start sampling and the
falling edge starts the conversion and readout process. The
conversion process is timed by the SCK input clock. For
optimum performance, CNV should be driven by a clean
low jitter signal. The Typical Application at the back of the
data sheet illustrates a recommended implementation to
reduce the relatively large jitter from an FPGA CNV pulse
source. Note the low jitter input clock times the falling
edge of the CNV signal. The rising edge jitter of CNV is
much less critical to performance. The typical pulse width
of the CNV signal is 30ns with < 1.5ns rise and fall times
at a 1.5Msps conversion rate.
SCK Serial Data Clock Input
In SDR mode (SDR/DDR Pin 23 = GND), the falling edge
of this clock shifts the conversion result MSB first onto
the SDO pins. A 100MHz external clock must be applied at
Rev B
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LTC2320-12
APPLICATIONS INFORMATION
the SCK pin to achieve 1.5Msps throughput using all eight
SDO outputs. In DDR mode (SDR/DDR Pin 23 = OVDD),
each input edge of SCK shifts the conversion result MSB
first onto the SDO pins. A 50MHz external clock must be
applied at the SCK pin to achieve 1.5Msps throughput
using all eight SDO1 through SDO8 outputs.
CLKOUT Serial Data Clock Output
The CLKOUT output provides a skew-matched clock to
latch the SDO output at the receiver. The timing skew
of the CLKOUT and SDO outputs are matched. For high
throughput applications, using CLKOUT instead of SCK to
capture the SDO output eases timing requirements at the
receiver. For low throughput speed applications, CLKOUT
can be disabled by tying Pin 34 to OVDD.
Nap/Sleep Modes
Nap mode is a method to save power without sacrificing
power-up delays for subsequent conversions. Sleep mode
has substantial power savings, but a power-up delay is
incurred to allow the reference and power systems to
become valid. To enter nap mode on the LTC2320-12,
the SCK signal must be held high or low and a series of
CNV
1
two CNV pulses must be applied. This is the case for both
CMOS and LVDS modes. The second rising edge of CNV
initiates the nap state. The nap state will persist until either
a single rising edge of SCK is applied, or further CNV pulses
are applied. The SCK rising edge will put the LTC2320-12
back into the operational (full-power) state. When in nap
mode, two additional pulses will put the LTC2320-12 in
sleep mode. When configured for CMOS I/O operation, a
single rising edge of SCK can return the LTC2320-12 into
operational mode. A 10ms delay is necessary after exiting
sleep mode to allow the reference buffer to recharge the
external filter capacitor. In LVDS mode, exit sleep mode
by supplying a fifth CNV pulse. The fifth pulse will return
the LTC2320-12 to operational mode, and further SCK
pulses will keep the part from re-entering nap and sleep
modes. The fifth SCK pulse also works in CMOS mode
as a method to exit sleep. In the absence of SCK pulses,
repetitive CNV pulses will cycle the LTC2320-12 between
operational, nap and sleep modes indefinitely.
Refer to the timing diagrams in Figure 18, Figure 19,
Figure 20 and Figure 21 for more detailed timing information about sleep and nap modes.
2
FULL POWER MODE
NAP MODE
SCK
HOLD STATIC HIGH OR LOW
WAKE ON 1ST SCK EDGE
SDO1 – 8
Z
Z
232012 F18
Figure 18. CMOS and LVDS Mode NAP and WAKE Using SCK
Rev B
For more information www.analog.com
25
LTC2320-12
APPLICATIONS INFORMATION
REFOUT1 – 4
REFOUT
RECOVERY
4.096V
4.096V
tWAKE
CNV
1
2
3
4
NAP MODE
SCK
SLEEP MODE
FULL POWER MODE
HOLD STATIC HIGH OR LOW
WAKE ON 1ST SCK EDGE
SDO1 – 8
Z
Z
Z
Z
232012 F19
Figure 19. CMOS Mode SLEEP and WAKE Using SCK
REFOUT1 – 4
REFOUT
RECOVERY
4.096V
4.096V
tWAKE
CNV
1
2
3
4
NAP MODE
SCK
WAKE ON 5TH
CNV EDGE
5
SLEEP MODE
FULL POWER MODE
HOLD STATIC HIGH OR LOW
SDO1 – 8
Z
Z
Z
Z
Z
232012 F20
Figure 20. LVDS and CMOS Mode SLEEP and WAKE Using CNV
SDR MODE TIMING
DDR MODE TIMING
tCYC
tCNVH
tCYC
tCONV
tREADOUT
tCNVH
tDSCKCNVH
CNV
1
2
3
14
tREADOUT
tDSCKCNVH
CNV
tSCKH
tSCK
SCK
tCONV
tSCKH
tSCK
15
SCK
16
1
2
3
CLKOUT
1
2
3
14
15
CLKOUT
16
1
tDSCKCLKOUT
SDO
HI-Z
D15
D14
D13
15
D2
D1
D0
D15
2
3
14
tDSCKCLKOUT
tDCNVSDOZ
tHSDO
tDCNVSDOV
14
16
tSCKL
tSCKL
tDCNVSDOV
HI-Z
SDO
HI-Z
D14
D13
D2
16
tDCNVSDOZ
tHSDO
D15
15
D1
D0
D15
HI-Z
232012 F21
Figure 21. LTC2320-12 Timing Diagram
26
Rev B
For more information www.analog.com
LTC2320-12
APPLICATIONS INFORMATION
DIGITAL INTERFACE
The LTC2320-12 features a serial digital interface that
is simple and straightforward to use. The flexible OVDD
supply allows the LTC2320-12 to communicate with any
digital logic operating between 1.8V and 2.5V. In addition to a standard CMOS SPI interface, the LTC2320-12
provides an optional LVDS SPI interface to support low
noise digital design. The CMOS /LVDS pin is used to select
the digital interface mode. The SCK input clock shifts the
conversion result MSB first on the SDO pins. CLKOUT
provides a skew-matched clock to latch the SDO output
at the receiver. The timing skew of the CLKOUT and SDO
outputs are matched. For high throughput applications,
LTC2320-12
2.5V
2.5V
CMOS/LVDS
FPGA OR DSP
OVDD
SCK+
SCK–
using CLKOUT instead of SCK to capture the SDO output
eases timing requirements at the receiver. In CMOS mode,
use the SDO1 – SDO8, and CLKOUT pins as outputs. Use
the SCK pin as an input. In LVDS mode, use the SDOA+/
SDOA– through SDOD+/SDOD– and CLKOUT+/CLKOUT–
pins as differential outputs. Each LVDS lane yields two
channels worth of data: SDOA yields CH1 and CH2 data,
SDOB yields CH3 and CH4 data, SDOC yields CH5 and CH6
data and SDOD yields CH7 and CH8 data. These pins must
be differentially terminated by an external 100Ω resistor at
the receiver (FPGA). The SCK+/SCK– pins are differential
inputs and must be terminated differentially by an external
100Ω resistor at the receiver(ADC).
LTC2320-12
+
–
100Ω
2.5V
OVDD
SCK+
SCK–
SDOD+
SDOD–
100Ω
+
–
SDOD+
SDOD–
SDOC+
SDOC–
100Ω
+
–
SDOC+
SDOC–
CLKOUT+
CLKOUT –
100Ω
+
–
SDOB+
SDOB–
100Ω
+
–
SDOB+
SDOB–
SDOA+
SDOA–
100Ω
+
–
SDOA+
SDOA–
CNV
2.5V
CMOS/LVDS
RETIMING
FLIP-FLOP
CLKOUT+
CLKOUT –
CNV
232012 F22
Figure 22. LTC2320-12 Using the LVDS Interface
FPGA OR DSP
+
–
100Ω
100Ω
+
–
100Ω
+
–
RETIMING
FLIP-FLOP
232012 F23
Figure 23. LTC2320-12 Using the LVDS Interface with One Lane
Rev B
For more information www.analog.com
27
LTC2320-12
APPLICATIONS INFORMATION
SDR/DDR Modes
CMOS
The LTC2320-12 has an SDR (single data rate) and DDR
(double data rate) mode for reading conversion data from
the SDO pins. In both modes, CLKOUT is a delayed version
of SCK. In SDR mode, each negative edge of SCK shifts
the conversion data out the SDO pins. In DDR mode,
each edge of the SCK input shifts the conversion data
out. In DDR mode, the required SCK frequency is half of
what is required in SDR mode. Tie SDR/DDR to ground to
configure for SDR mode and to OVDD for DDR mode. The
CLKOUT signal is a delayed version of the SCK input and is
phase aligned with the SDO data. In SDR mode, the SDO
transitions on the falling edge of CLKOUT as illustrated
in Figure 21. We recommend using the rising edge of
CLKOUT to latch the SDO data into the FPGA register in
SDR mode. In DDR mode, The SDO transitions on each
input edge of SCK. We recommend using the CLKOUT rising and falling edges to latch the SDO data into the FPGA
registers in DDR mode. Since CLKOUT and SDO data is
phase aligned, the SDO signals will need to be digitally
delayed in the FPGA to provide adequate setup and hold
timing margins in DDR mode.
In CMOS mode, the number of possible data lanes range
from eight (SDO1 – SDO8), four (SDO1, SDO3, SDO5
and SDO7), two (SDO1 and SDO5) and one (SDO1). As
suggested in the CMOS Timing Diagrams, each SDO lane
outputs the conversion results for all analog input channels in a sequential circular manner. For example, the first
conversion result on SDO1 corresponds to analog input
channel 1, followed by the conversion results for channels 2 through 8. The data output on SDO1 then wraps
back to channel 1 and this pattern repeats indefinitely. Other
SDO lanes follow a similar circular pattern except the first
conversion result presented on each lane corresponds to
its associated analog input channel.
Multiple Data Lanes
The LTC2320-12 has up to eight SDO data lanes in CMOS
mode and four SDO lanes in LVDS mode. In CMOS mode,
the number of possible data lanes range from eight
(SDO1 – SDO8), four (SDO1, SDO3, SDO5 and SDO7), two
(SDO1 and SDO5) and one (SDO1). Generally, the more
data lanes used, the lower the required SCK frequency.
When using less than eight lanes in CMOS mode, there
is a limit on the maximum possible conversion frequency
(see Table 3). Each SDO pin will hold the MSB of the conversion data. In DDR mode you can use a SCK frequency
half the SDR mode. See Table 3 for examples of various
possibilities and the resulting SCK frequency required.
Multiple Data Lanes
The LTC2320-12 has up to eight serial data output data
lanes in CMOS mode and four serial data output lane pairs
in LVDS mode. The data on each lane consists of 12-bit
conversion results presented MSB first.
28
Applications that cannot accommodate the full eight lanes
of serial data may employ fewer lanes without reconfiguring the LTC2320-12. For example, capturing the first two
conversion results (32 SCK cycles total in SDR mode and
32 SCK edges in DDR mode) from SDO1, SDO3, SDO5,
and SDO7 provides data for analog input channels 1 and
2, 3 and 4, 5 and 6, and 7 and 8, respectively, using four
output lanes. Similarly, capturing the first four conversion
results (64 SCK cycles total in SDR mode and 64 SCK
edges in DDR mode) from SDO1 and SDO5 provides data
for analog input channels 1 to 4 and 5 to 8, respectively,
using two output lanes. If only one lane can be accommodated, capturing the first eight conversion results
(128 SCK cycles total in SDR mode and 128 SCK edges in
DDR mode) from SDO1 provides data for all analog input
channels. Generally, the more data lanes used, the lower
the required SCK frequency. When using less than eight
lanes in CMOS mode, there is a limit on the maximum
possible conversion frequency. See Table 3 for examples
of various possibilities and the resulting SCK frequency
required.
LVDS
In LVDS mode, the number of possible data lane pairs range
from four (SDOA – SDOD), two (SDOA and SDOC) and
one (SDOA). As suggested in the LVDS Timing Diagrams,
each SDO lane pair outputs the conversion results for all
analog input channels in a sequential circular manner.
Rev B
For more information www.analog.com
LTC2320-12
APPLICATIONS INFORMATION
For example, the first conversion result on SDOA corresponds to analog input channel pair 1 and 2, followed
by the conversion results for channels 3 through 8. The
data output on SDOA then wraps back to channel 1 and
this pattern repeats indefinitely. Other SDO lanes follow a
similar circular pattern except the first conversion result
presented on each lane corresponds to its associated
analog input channel pairs (SDOA: analog inputs 1 and
2, SDOB: analog inputs 3 and 4, SDOC: analog inputs 5
and 6 and SDOD: analog inputs 7 and 8).
See Table 3 for examples of various possibilities and the
resulting SCK frequency required.
BOARD LAYOUT
To obtain the best performance from the LTC2320-12,
a printed circuit board is recommended. Layout for the
printed circuit board (PCB) should ensure the digital and
analog signal lines are separated as much as possible.
In particular, care should be taken not to run any digital
clocks or signals adjacent to analog signals or underneath
the ADC.
Applications that cannot accommodate the full four lanes
of serial data may employ fewer lanes without reconfiguring the LTC2320-12. For example, capturing the first four
conversion results (64 SCK cycles total in SDR mode
and 64 SCK edges in DDR mode) from SDOA and SDOC
provides data for analog input channels 1 through 4, and
5 through 8, respectively, using two output lanes. If only
one lane can be accommodated, capturing the first eight
conversion results (128 SCK cycles total in SDR mode
and 128 SCK edges in DDR mode) from SDOA provides
data for all analog input channels. Generally, the more
data lanes used, the lower the required SCK frequency.
When using less than four lanes in LVDS mode, there is
a limit on the maximum possible conversion frequency.
Supply bypass capacitors should be placed as close as
possible to the supply pins. Low impedance common
returns for these bypass capacitors are essential to the
low noise operation of the ADC. A single solid ground
plane is recommended for this purpose. When possible,
screen the analog input traces using ground.
Recommended Layout
For a detailed look at the reference design for this converter, including schematics and PCB layout, please refer
to DC2395A, the evaluation kit for the LTC2320-12.
Table 3. Conversion Frequency for Various I/O Modes
I/O MODE
CMOS
LVDS
CMOS/
LVDS PIN
GND
(CMOS)
OVDD
(LVDS)
SDR/
DDR PIN
SDO1 – 8
LANES
GND (SDR)
SDOA – D
LANES
CONVERSION
FREQUENCY
(Msps/CH)
SCK FREQ
(MHz)
CLKOUT FREQ
(MHz)
SCK
CYCLES
SDO1 – SDO8
100
100
16
OVDD (DDR)
SDO1 – SDO8
50
50
8
OVDD (DDR)
SDO1, SDO3,
SDO5, SDO7
50
50
16
GND (SDR)
SDO1
100
100
128
0.5
1.5
GND (SDR)
SDOA – SDOD
200
200
32
OVDD (DDR)
SDOA – SDOD
100
100
16
OVDD (DDR)
SDOA, SDOC
150
150
32
GND (SDR)
SDOA
300
300
128
OVDD
1.5
1.5
1.8V to 2.5V
2.5V
1.25
1.5
1.4
1.0
Notes: Conversion Period (SDR) = tCNV_MIN + tCONV_MAX + (128/(Lanes • fSCK))
Conversion Period (DDR) = tCNV_MIN + tCONV_MAX + (64/(Lanes • fSCK))
Conversion Frequency = 1/Conversion Period
SCK Cycles (SDR) = 128/Lanes
SCK Cycles (DDR) = 64/Lanes
Rev B
For more information www.analog.com
29
LTC2320-12
PACKAGE DESCRIPTION
Please refer to http://www.linear.com/product/LTC2320-12#packaging for the most recent package drawings.
UKG Package
52-Lead Plastic QFN (7mm × 8mm)
(Reference LTC DWG # 05-08-1729 Rev Ø)
7.50 ±0.05
6.10 ±0.05
5.50 REF
(2 SIDES)
0.70 ±0.05
6.45 ±0.05
6.50 REF 7.10 ±0.05 8.50 ±0.05
(2 SIDES)
5.41 ±0.05
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
7.00 ±0.10
(2 SIDES)
0.75 ±0.05
0.00 – 0.05
R = 0.115
TYP
5.50 REF
(2 SIDES)
51
52
0.40 ±0.10
PIN 1 TOP MARK
(SEE NOTE 6)
1
2
PIN 1 NOTCH
R = 0.30 TYP OR
0.35 × 45°C
CHAMFER
8.00 ±0.10
(2 SIDES)
6.50 REF
(2 SIDES)
6.45 ±0.10
5.41 ±0.10
R = 0.10
TYP
TOP VIEW
0.200 REF
0.00 – 0.05
0.75 ±0.05
(UKG52) QFN REV Ø 0306
0.25 ±0.05
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
SIDE VIEW
NOTE:
1. DRAWING IS NOT A JEDEC PACKAGE OUTLINE
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
30
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE, IF PRESENT
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE
For more information www.analog.com
Rev B
LTC2320-12
REVISION HISTORY
REV
DATE
DESCRIPTION
A
02/17
Corrected text to specify no latency
PAGE NUMBER
17
B
03/18
Corrected max specs for PD_3.3V and PD_5V in nap mode (missing decimal point)
5
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 For
is granted
implication or
otherwise under any patent or patent rights of Analog Devices.
more by
information
www.analog.com
31
LTC2320-12
TYPICAL APPLICATION
Low Jitter Clock Timing with RF Sine Generator Using Clock Squaring/Level-Shifting Circuit and Retiming Flip-Flop
VCC
0.1µF
50Ω
1k
NC7SVUO4P5X
MASTER_CLOCK
VCC
1k
D
PRE
NC7SV74K8X Q
CLR
CONV
CONV ENABLE
CNV
LTC2320-12
SCK
CLKOUT
GND
CMOS/LVDS
GND
SDR/DDR
CONTROL
LOGIC
(FPGA, CPLD,
DSP, ETC.)
SDO1 – 8
10Ω
10Ω
NC7SVU04P5X (× 9)
232012 TA02
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DESCRIPTION
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LTC2377-16/LTC2376-16 Low Power ADCs
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32
Rev B
D16843-0-4/18(B)
www.analog.com
For more information www.analog.com
 ANALOG DEVICES, INC. 2017-18
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