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ADC12D1000, ADC12D1600
SNAS480N – MAY 2010 – REVISED AUGUST 2015
ADC12D1x00 12-Bit, 2.0/3.2 GSPS Ultra High-Speed ADC
1 Features
3 Description
•
The 12-bit, 2.0/3.2 GSPS ADC12D1x00 device is the
latest advance in TI's Ultra High-Speed ADC family
and builds upon the features, architecture, and
functionality of the 10-bit GHz family of ADCs.
1
•
•
•
•
•
•
•
•
•
Configurable to Either 2.0/3.2 GSPS Interleaved
or 1.0/1.6 GSPS Dual ADC
Pin-Compatible With ADC10D1x00 and
ADC12D1x00
Internally Terminated, Buffered, Differential
Analog Inputs
Interleaved Timing Automatic and Manual Skew
Adjust
Test Patterns at Output for System Debug
Programmable 15-bit Gain and 12-bit Plus Sign
Offset
Programmable tAD Adjust Feature
1:1 Non-demuxed or 1:2 Demuxed LVDS Outputs
AutoSync Feature for Multi-Chip Systems
Single 1.9-V ± 0.1-V Power Supply
The ADC12D1x00 provides a flexible LVDS interface
which has multiple SPI programmable options to
facilitate board design and FPGA/ASIC data capture.
The LVDS outputs are compatible with IEEE 1596.31996 and support programmable common-mode
voltage.
The ADC12D1x00 is packaged in a leaded or leadfree 292-pin thermally enhanced BGA package over
the rated industrial temperature range of –40°C to
85°C.
Device Information(1)
PART NUMBER
ADC12D1000
2 Applications
•
•
•
•
•
•
Wideband Communications
Data Acquisition Systems
RADAR and LIDAR
Set-Top Boxes
Consumer RF
Software Defined Radios
SPACE
Simplified Block Diagram
ADC12D1600
PACKAGE
BGA (292)
BODY SIZE (NOM)
27.00 mm × 27.00 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
Wideband Performance
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
ADC12D1000, ADC12D1600
SNAS480N – MAY 2010 – REVISED AUGUST 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
Features .................................................................. 1
Applications ........................................................... 1
Description ............................................................. 1
Revision History..................................................... 2
Pin Configuration and Functions ......................... 3
Specifications....................................................... 13
6.1
6.2
6.3
6.4
6.5
6.6
6.7
Absolute Maximum Ratings .................................... 13
ESD Ratings............................................................ 13
Recommended Operating Conditions..................... 14
Thermal Information ................................................ 14
Electrical Characteristics: Static Converter............. 15
Electrical Characteristics: Dynamic Converter........ 16
Electrical Characteristics: Analog Input/Output and
Reference................................................................. 21
6.8 Electrical Characteristics: I-Channel To QChannel.................................................................... 22
6.9 Electrical Characteristics: Converter and Sampling
Clock ........................................................................ 22
6.10 Electrical Characteristics: Autosync Feature ........ 22
6.11 Electrical Characteristics: Digital Control and Output
Pin ............................................................................ 23
6.12 Electrical Characteristics: Power Supply .............. 24
6.13 Electrical Characteristics: AC................................ 25
6.14 Timing Requirements: Serial Port Interface .......... 26
6.15 Timing Requirements: Calibration......................... 26
6.16 Typical Characteristics .......................................... 31
7
Detailed Description ............................................ 40
7.1
7.2
7.3
7.4
7.5
7.6
8
Overview .................................................................
Functional Block Diagram .......................................
Feature Description.................................................
Device Functional Modes........................................
Programming...........................................................
Register Maps .........................................................
40
40
41
47
48
53
Application and Implementation ........................ 59
8.1 Application Information............................................ 59
8.2 Typical Application .................................................. 67
9
Power Supply Recommendations...................... 70
9.1 System Power-On Considerations.......................... 70
9.2 Supply Voltage ........................................................ 72
10 Layout................................................................... 73
10.1 Layout Guidelines ................................................. 73
10.2 Layout Example .................................................... 75
10.3 Thermal Management ........................................... 77
11 Device and Documentation Support ................. 79
11.1
11.2
11.3
11.4
11.5
11.6
11.7
Device Support......................................................
Documentation Support ........................................
Related Links ........................................................
Community Resources..........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
79
81
81
81
81
81
82
12 Mechanical, Packaging, and Orderable
Information ........................................................... 82
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision M (March 2013) to Revision N
Page
•
Added ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation
section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and
Mechanical, Packaging, and Orderable Information section ................................................................................................. 1
•
Deleted TA ≤ from Ambient Temperature MAX column........................................................................................................ 14
•
Deleted TJ ≤ from Ambient Temperature MAX column ........................................................................................................ 14
Changes from Revision L (March 2013) to Revision M
•
2
Page
Changed layout of National Data Sheet to TI format ........................................................................................................... 53
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Copyright © 2010–2015, Texas Instruments Incorporated
Product Folder Links: ADC12D1000 ADC12D1600
ADC12D1000, ADC12D1600
www.ti.com
SNAS480N – MAY 2010 – REVISED AUGUST 2015
5 Pin Configuration and Functions
The center ground pins are for thermal dissipation and must be soldered to a ground plane to ensure rated
performance. See Layout Guidelines for more information.
NXA Package
292-Pin BGA
Top View
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
A
GND
V_A
SDO
TPM
NDM
V_A
GND
V_E
GND_E
DId0+
V_DR
DId3+
GND_DR
DId6+
V_DR
DId9+
B
Vbg
GND
ECEb
SDI
CalRun
V_A
GND
GND_E
V_E
DId0-
DId2+
DId3-
DId5+
DId6-
DId8+
DId9-
DId10+
C
Rtrim+
Vcmo
Rext+
SCSb
SCLK
V_A
NC
V_E
GND_E
DId1+
DId2-
DId4+
DId5-
DId7+
DId8-
DId10-
D
DNC
Rtrim-
Rext-
GND
GND
CAL
DNC
V_A
V_A
DId1-
V_DR
DId4-
GND_DR
DId7-
V_DR
GND_DR
E
V_A
Tdiode+
DNC
F
V_A
G
18
19
20
DId11-
GND_DR
A
DI0+
DI1+
DI1-
B
DI0-
V_DR
DI2+
DI2-
C
V_DR
DI3+
DI4+
DI4-
D
GND
GND_DR
DI3-
DI5+
DI5-
E
GND_TC Tdiode-
DNC
GND_DR
DI6+
DI6-
GND_DR
F
V_TC
GND_TC
V_TC
V_TC
DI7+
DI7-
DI8+
DI8-
G
H
VinI+
V_TC
GND_TC
V_A
GND
GND
GND
GND
GND
GND
DI9+
DI9-
DI10+
DI10-
H
J
VinI-
GND_TC
V_TC
VbiasI
GND
GND
GND
GND
GND
GND
V_DR
DI11+
DI11-
V_DR
J
K
GND
VbiasI
V_TC
GND_TC
GND
GND
GND
GND
GND
GND
ORI+
ORI-
DCLKI+
DCLKI-
K
L
GND
VbiasQ
V_TC
GND_TC
GND
GND
GND
GND
GND
GND
ORQ+
ORQ-
DCLKQ+ DCLKQ-
L
M
VinQ-
GND_TC
V_TC
VbiasQ
GND
GND
GND
GND
GND
GND
N
VinQ+
V_TC
GND_TC
V_A
GND
GND
GND
GND
GND
GND
P
V_TC
GND_TC
V_TC
R
V_A
GND_TC
V_TC
T
V_A
GND_TC GND_TC
U
GND_TC
CLK+
PDI
GND
GND
RCOut1-
V
CLK-
DCLK
_RST+
PDQ
CalDly
DES
RCOut2+ RCOut2-
W
DCLK
_RST-
GND
DNC
DDRPh
RCLK-
Y
GND
V_A
FSR
RCLK+ RCOut1+
1
2
3
GND_DR DId11+
GND_DR DQ11+
DQ11-
GND_DR
M
DQ9+
DQ9-
DQ10+
DQ10-
N
V_TC
DQ7+
DQ7-
DQ8+
DQ8-
P
V_TC
V_DR
DQ6+
DQ6-
V_DR
R
GND
V_DR
DQ3-
DQ5+
DQ5-
T
4
5
DNC
V_A
V_A
DQd1-
V_DR
DQd4-
V_E
GND_E
DQd1+
DQd2-
DQd4+
DQd5-
DQd5+
V_DR
V_DR
GND_DR
DQ3+
DQ4+
DQ4-
U
DQd7+
DQd8-
DQd10-
DQ0-
GND_DR
DQ2+
DQ2-
V
DQd6-
DQd8+
DQd9-
DQd10+
DQ0+
DQ1+
DQ1-
W
V_DR
DQd9+ GND_DR DQd11+ DQd11- GND_DR
GND_DR DQd7-
V_A
GND
GND_E
V_E
DQd0-
DQd2+
DQd3-
V_A
GND
V_E
GND_E
DQd0+
V_DR
DQd3+ GND_DR DQd6+
6
7
8
9
10
11
12
13
14
Copyright © 2010–2015, Texas Instruments Incorporated
Product Folder Links: ADC12D1000 ADC12D1600
15
16
17
18
19
Y
20
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ADC12D1000, ADC12D1600
SNAS480N – MAY 2010 – REVISED AUGUST 2015
www.ti.com
Pin Functions: Analog Front-End and Clock Balls
PIN
NAME
NO.
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VA
CLK+/-
U2/V1
I
50k
AGND
VA
100
VBIAS
50k
Differential Converter Sampling Clock. In the NonDES Mode, the analog inputs are sampled on the
positive transitions of this clock signal. In the DES
Mode, the selected input is sampled on both
transitions of this clock. This clock must be ACcoupled.
AGND
VA
Differential DCLK Reset. A positive pulse on this
input is used to reset the DCLKI and DCLKQ
outputs of two or more ADC12D1x00s to
synchronize them with other ADC12D1x00s in the
system. DCLKI and DCLKQ are always in phase
with each other, unless one channel is powered
down, and do not require a pulse from DCLK_RST
to become synchronized. The pulse applied here
must meet timing relationships with respect to the
CLK input. Although supported, this feature has
been superseded by AutoSync.
AGND
DCLK_RST+/-
V2/W1
I
100
VA
AGND
VA
RCLK+/-
Y4/W5
I
50k
AGND
VA
100
VBIAS
50k
Reference Clock Input. When the AutoSync feature
is active, and the ADC12D1x00 is in Slave Mode,
the internal divided clocks are synchronized with
respect to this input clock. The delay on this clock
may be adjusted when synchronizing multiple
ADCs. This feature is available in ECM through
Control Register (Addr: Eh).
AGND
4
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ADC12D1000, ADC12D1600
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SNAS480N – MAY 2010 – REVISED AUGUST 2015
Pin Functions: Analog Front-End and Clock Balls (continued)
PIN
NAME
NO.
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VA
100:
RCOut1+/RCOut2+/-
Y5/U6
V6/V7
100:
O
-
+
Reference Clock Output 1 and 2. These signals
provide a reference clock at a rate of CLK/4, when
enabled, independently of whether the ADC is in
Master or Slave Mode. The signals are used to
drive the RCLK of another ADC12D1x00, to enable
automatic synchronization for multiple ADCs
(AutoSync feature). The impedance of each trace
from RCOut1 and RCOut2 to the RCLK of another
ADC12D1x00 should be 100-Ω differential. Having
two clock outputs allows the auto-synchronization
to propagate as a binary tree. Use the DOC Bit
(Addr: Eh, Bit 1) to enable or disable this feature;
default is disabled.
A GND
VA
Rext+/-
C3/D3
I/O
V
External Reference Resistor terminals. A 3.3-kΩ
±0.1% resistor should be connected between
Rext+/-. The Rext resistor is used as a reference to
trim internal circuits which affect the linearity of the
converter; the value and precision of this resistor
should not be compromised.
V
Input Termination Trim Resistor terminals. A 3.3-kΩ
±0.1% resistor should be connected between
Rtrim+/-. The Rtrim resistor is used to establish the
calibrated 100-Ω input impedance of VinI, VinQ
and CLK. These impedances may be fine tuned by
varying the value of the resistor by a corresponding
percentage; however, the tuning range and
performance is not ensured for such an alternate
value.
GND
VA
Rtrim+/-
C1/D2
I/O
GND
VA
Tdiode_P
Tdiode+/-
E2/F3
GND
Passive
VA
Temperature Sensor Diode Positive (Anode) and
Negative (Cathode) Terminals. This set of pins is
used for die temperature measurements. It has not
been fully characterized.
Tdiode_N
GND
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ADC12D1000, ADC12D1600
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www.ti.com
Pin Functions: Analog Front-End and Clock Balls (continued)
PIN
NAME
NO.
VBG
B1
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VA
Bandgap Voltage Output or LVDS Common-mode
Voltage Select. This pin provides a buffered
version of the bandgap output voltage and is
capable of sourcing and sinking 100 µA and driving
a load of up to 80 pF. Alternately, this pin may be
used to select the LVDS digital output commonmode voltage. If tied to logic-high, the 1.2-V LVDS
common-mode voltage is selected; 0.8 V is the
default.
O
GND
VA
VCMO
VCMO
C2
200k
I/O
Enable AC
Coupling
8 pF
GND
Differential signal I- and Q-inputs. In the Non-Dual
Edge Sampling (Non-DES) Mode, each I- and Qinput is sampled and converted by its respective
channel with each positive transition of the CLK
input. In Non-ECM (Non-Extended Control Mode)
and DES Mode, both channels sample the I-input.
In Extended Control Mode (ECM), the Q-input may
optionally be selected for conversion in DES Mode
by the DEQ Bit (Addr: 0h, Bit 6).
VA
50k
AGND
VinI+/VinQ+/-
H1/J1
N1/M1
I
VCMO
100
Control from VCMO
VA
50k
AGND
Common-Mode Voltage Output or Signal Coupling
Select. If AC-coupled operation at the analog
inputs is desired, this pin should be held at logiclow level. This pin is capable of sourcing and
sinking up to 100 µA. For DC-coupled operation,
this pin should be left floating or terminated into
high-impedance. In DC-coupled Mode, this pin
provides an output voltage which is the optimal
common-mode voltage for the input signal and
should be used to set the common-mode voltage of
the driving buffer.
Each I- and Q-channel input has an internal
common mode bias that is disabled when DCcoupled Mode is selected. Both inputs must be
either AC- or DC-coupled. The coupling mode is
selected by the VCMO Pin.
In Non-ECM, the full-scale range of these inputs is
determined by the FSR Pin; both I- and Q-channels
have the same full-scale input range. In ECM, the
full-scale input range of the I- and Q-channel inputs
may be independently set through the Control
Register (Addr: 3h and Addr: Bh). The high and
low full-scale input range setting in Non-ECM
corresponds to the mid and minimum full-scale
input range in ECM.
The input offset may also be adjusted in ECM.
6
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ADC12D1000, ADC12D1600
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SNAS480N – MAY 2010 – REVISED AUGUST 2015
Pin Functions: Control and Status Balls
PIN
NAME
NO.
I/O
EQUIVALENT CIRCUIT
VA
CAL
D6
I
GND
DESCRIPTION
Calibration cycle initiate. The user can command
the device to execute a self-calibration cycle by
holding this input high a minimum of tCAL_H after
having held it low a minimum of tCAL_L. If this input
is held high at the time of power on, the automatic
power-on calibration cycle is inhibited until this
input is cycled low-then-high. This pin is active in
both ECM and Non-ECM. In ECM, this pin is
logically OR'd with the CAL Bit (Addr: 0h, Bit 15) in
the Control Register. Therefore, both pin and bit
must be set low and then either can be set high to
execute an on-command calibration.
VA
CalDly
V4
Calibration Delay select. By setting this input logichigh or logic-low, the user can select the device to
wait a longer or shorter amount of time,
respectively, before the automatic power-on selfcalibration is initiated. This feature is pin-controlled
only and is always active during ECM and NonECM.
I
GND
VA
CalRun
B5
Calibration Running indication. This output is logichigh while the calibration sequence is executing.
This output is logic-low otherwise.
O
GND
VA
DDRPh
W4
I
GND
VA
DES
V5
I
GND
DNC
D1, D7, E3,
F4, W3, U7
—
NONE
DDR Phase select. This input, when logic-low,
selects the 0° Data-to-DCLK phase relationship.
When logic-high, it selects the 90° Data-to-DCLK
phase relationship, that is, the DCLK transition
indicates the middle of the valid data outputs. This
pin only has an effect when the chip is in 1:2
Demuxed Mode, that is, the NDM pin is set to
logic-low. In ECM, this input is ignored and the
DDR phase is selected through the Control
Register by the DPS Bit (Addr: 0h, Bit 14); the
default is 0° Mode.
Dual Edge Sampling (DES) Mode select. In the
Non-Extended Control Mode (Non-ECM), when this
input is set to logic-high, the DES Mode of
operation is selected, meaning that the VinI input is
sampled by both channels in a time-interleaved
manner. The VinQ input is ignored. When this input
is set to logic-low, the device is in Non-DES Mode,
that is, the I- and Q-channels operate
independently. In the Extended Control Mode
(ECM), this input is ignored and DES Mode
selection is controlled through the Control Register
by the DES Bit (Addr: 0h, Bit 7); default is NonDES Mode operation.
Do Not Connect. These pins are used for internal
purposes and should not be connected, that is, left
floating. Do not ground.
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ADC12D1000, ADC12D1600
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www.ti.com
Pin Functions: Control and Status Balls (continued)
PIN
NAME
NO.
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VA
50 k:
ECE
B3
I
Extended Control Enable bar. Extended feature
control through the SPI interface is enabled when
this signal is asserted (logic-low). In this case, most
of the direct control pins have no effect. When this
signal is deasserted (logic-high), the SPI interface
is disabled, all SPI registers are reset to their
default values, and all available settings are
controlled through the control pins.
GND
VA
FSR
Y3
I
GND
NC
C7
—
NONE
Full-Scale input Range select. In Non-ECM, when
this input is set to logic-low or logic-high, the fullscale differential input range for both I- and Qchannel inputs is set to the lower or higher FSR
value, respectively. In the ECM, this input is
ignored and the full-scale range of the I- and Qchannel inputs is independently determined by the
setting of Addr: 3h and Addr: Bh, respectively. The
high (lower) FSR value in Non-ECM corresponds to
the mid (min) available selection in ECM; the FSR
range in ECM is greater.
Not Connected. This pin is not bonded and may be
left floating or connected to any potential.
VA
NDM
A5
Non-Demuxed Mode select. Setting this input to
logic-high causes the digital output bus to be in the
1:1 Non-Demuxed Mode. Setting this input to logiclow causes the digital output bus to be in the 1:2
Demuxed Mode. This feature is pin-controlled only
and remains active during ECM and Non-ECM.
I
GND
VA
50 k:
PDI
PDQ
U3
V3
I
GND
Power-down I- and Q-channel. Setting either input
to logic-high powers down the respective I- or Qchannel. Setting either input to logic-low brings the
respective I- or Q-channel to an operational state
after a finite time delay. This pin is active in both
ECM and Non-ECM. In ECM, each Pin is logically
OR'd with its respective Bit. Therefore, either this
pin or the PDI and PDQ Bit in the Control Register
can be used to power-down the I- and Q-channel
(Addr: 0h, Bit 11 and Bit 10), respectively.
VA
100 k:
SCLK
C5
I
Serial Clock. In ECM, serial data is shifted into and
out of the device synchronously to this clock signal.
This clock may be disabled and held logic-low, as
long as timing specifications are not violated when
the clock is enabled or disabled.
GND
8
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ADC12D1000, ADC12D1600
www.ti.com
SNAS480N – MAY 2010 – REVISED AUGUST 2015
Pin Functions: Control and Status Balls (continued)
PIN
NAME
NO.
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VA
100 k:
SCS
C4
I
Serial Chip Select bar. In ECM, when this signal is
asserted (logic-low), SCLK is used to clock in serial
data which is present on SDI and to source serial
data on SDO. When this signal is deasserted
(logic-high), SDI is ignored and SDO is at TRISTATE.
GND
VA
100 k:
SDI
B4
Serial Data-In. In ECM, serial data is shifted into
the device on this pin while SCS signal is asserted
(logic-low).
I
GND
VA
SDO
A3
Serial Data-Out. In ECM, serial data is shifted out
of the device on this pin while SCS signal is
asserted (logic-low). This output is at TRI-STATE
when SCS is deasserted.
O
GND
VA
TPM
A4
Test Pattern Mode select. With this input at logichigh, the device continuously outputs a fixed,
repetitive test pattern at the digital outputs. In the
ECM, this input is ignored and the Test Pattern
Mode can only be activated through the Control
Register by the TPM Bit (Addr: 0h, Bit 12).
I
GND
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ADC12D1000, ADC12D1600
SNAS480N – MAY 2010 – REVISED AUGUST 2015
www.ti.com
Pin Functions: Power and Ground Balls
PIN
I/O
EQUIVALENT CIRCUIT
A1, A7, B2,
B7, D4, D5,
E4, K1, L1,
T4, U4, U5,
W2, W7, Y1,
Y7, H8:N13
—
NONE
Ground Return for the Analog circuitry.
GNDDR
A13, A17,
A20, D13,
D16, E17,
F17, F20,
M17, M20,
U13, U17,
V18, Y13,
Y17, Y20
—
NONE
Ground Return for the Output Drivers.
GNDE
A9, B8, C9,
V9, W8, Y9
—
NONE
Ground Return for the Digital Encoder.
GNDTC
F2, G2, H3,
J2, K4, L4,
M2, N3, P2,
R2, T2, T3, U1
—
NONE
Ground Return for the Track-and-Hold and Clock
circuitry.
A2, A6, B6,
C6, D8, D9,
E1, F1, H4,
N4, R1, T1,
U8, U9, W6,
Y2, Y6
—
NONE
Power Supply for the Analog circuitry. This supply
is tied to the ESD ring. Therefore, it must be
powered up before or with any other supply.
NONE
Bias Voltage I-channel. This is an externally
decoupled bias voltage for the I-channel. Each pin
should individually be decoupled with a 100-nF
capacitor through a low-resistance, low-inductance
path to GND.
NAME
GND
VA
VbiasI
NO.
J4, K2
—
DESCRIPTION
L2, M4
—
NONE
Bias Voltage Q-channel. This is an externally
decoupled bias voltage for the Q-channel. Each pin
should individually be decoupled with a 100-nF
capacitor through a low-resistance, low-inductance
path to GND.
VDR
A11, A15,
C18, D11,
D15, D17, J17,
J20, R17, R20,
T17, U11,
U15, U16,
Y11, Y15
—
NONE
Power Supply for the Output Drivers.
VE
A8, B9, C8,
V8, W9, Y8
—
NONE
Power Supply for the Digital Encoder.
VTC
G1, G3, G4,
H2, J3, K3, L3,
M3, N2, P1,
P3, P4, R3,
R4
—
NONE
Power Supply for the Track-and-Hold and Clock
circuitry.
VbiasQ
10
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Pin Functions: High-Speed Digital Outputs
PIN
NAME
NO.
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VDR
DCLKI+/DCLKQ+/-
K19/K20
L19/L20
-
+
+
-
O
Data Clock Output for the I- and Q-channel data
bus. These differential clock outputs are used to
latch the output data and, if used, should always be
terminated with a 100-Ω differential resistor placed
as closely as possible to the differential receiver.
Delayed and non-delayed data outputs are supplied
synchronously to this signal. In 1:2 Demux Mode or
Non-Demux Mode, this signal is at ¼ or ½ the
sampling clock rate, respectively. DCLKI and
DCLKQ are always in phase with each other,
unless one channel is powered down, and do not
require a pulse from DCLK_RST to become
synchronized.
DR GND
DI11+/DI10+/DI9+/DI8+/DI7+/DI6+/DI5+/DI4+/DI3+/DI2+/DI1+/DI0+/·
DQ11+/DQ10+/DQ9+/DQ8+/DQ7+/DQ6+/DQ5+/DQ4+/DQ3+/DQ2+/DQ1+/DQ0+/-
J18/J19
H19/H20
H17/H18
G19/G20
G17/G18
F18/F19
E19/E20
D19/D20
D18/E18
C19/C20
B19/B20
B18/C17
·
M18/M19
N19/N20
N17/N18
P19/P20
P17/P18
R18/R19
T19/T20
U19/U20
U18/T18
V19/V20
W19/W20
W18/V17
VDR
-
+
+
-
O
I- and Q-channel Digital Data Outputs. In NonDemux Mode, this LVDS data is transmitted at the
sampling clock rate. In Demux Mode, these outputs
provide ½ the data at ½ the sampling clock rate,
synchronized with the delayed data, that is, the
other ½ of the data which was sampled one clock
cycle earlier. Compared with the DId and DQd
outputs, these outputs represent the later time
samples. If used, each of these outputs should
always be terminated with a 100-Ω differential
resistor placed as closely as possible to the
differential receiver.
DR GND
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Pin Functions: High-Speed Digital Outputs (continued)
PIN
NAME
NO.
DId11+/DId10+/DId9+/DId8+/DId7+/DId6+/DId5+/DId4+/DId3+/DId2+/DId1+/DId0+/·
DQd11+/DQd10+/DQd9+/DQd8+/DQd7+/DQd6+/DQd5+/DQd4+/DQd3+/DQd2+/DQd1+/DQd0+/-
A18/A19
B17/C16
A16/B16
B15/C15
C14/D14
A14/B14
B13/C13
C12/D12
A12/B12
B11/C11
C10/D10
A10/B10
·
Y18/Y19
W17/V16
Y16/W16
W15/V15
V14/U14
Y14/W14
W13/V13
V12/U12
Y12/W12
W11/V11
V10/U10
Y10/W10
I/O
EQUIVALENT CIRCUIT
DESCRIPTION
VDR
-
+
+
-
O
Delayed I- and Q-channel Digital Data Outputs. In
Non-Demux Mode, these outputs are at TRISTATE. In Demux Mode, these outputs provide ½
the data at ½ the sampling clock rate, synchronized
with the non-delayed data, that is, the other ½ of
the data which was sampled one clock cycle later.
Compared with the DI and DQ outputs, these
outputs represent the earlier time samples. If used,
each of these outputs should always be terminated
with a 100-Ω differential resistor placed as closely
as possible to the differential receiver.
DR GND
VDR
ORI+/ORQ+/-
K17/K18
L17/L18
-
+
+
-
O
Out-of-Range Output for the I- and Q-channel. This
differential output is asserted logic-high while the
over- or under-range condition exists, that is, the
differential signal at each respective analog input
exceeds the full-scale value. Each OR result refers
to the current Data, with which it is clocked out. If
used, each of these outputs should always be
terminated with a 100-Ω differential resistor placed
as closely as possible to the differential receiver.
DR GND
12
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6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted) (1)
MIN
MAX
UNIT
2.2
V
0
100
mV
Voltage on Any Input Pin
(except VIN+/-)
–0.15
VA + 0.15
V
VIN+/- Voltage Range
–0.5
2.5
V
0
100
mV
Supply Voltage (VA, VTC, VDR, VE)
Supply Difference
max(VA/TC/DR/E) - min(VA/TC/DR/E)
Ground Difference
max(GNDTC/DR/E) - min(GNDTC/DR/E)
Input Current at Any Pin (2)
50
mA
ADC12D1000 Package Power Dissipation at TA ≤ 75°C (2)
–50
4.06
W
ADC12D1600 Package Power Dissipation at TA ≤ 65°C (2)
4.37
W
150
°C
Storage Temperature, Tstg
(1)
(2)
–65
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
When the input voltage at any pin exceeds the power supply limits, that is, less than GND or greater than VA, the current at that pin
should be limited to 50 mA. In addition, overvoltage at a pin must adhere to the maximum voltage limits. Simultaneous overvoltage at
multiple pins requires adherence to the maximum package power dissipation limits. These dissipation limits are calculated using JEDEC
JESD51-7 thermal model. Higher dissipation may be possible based on specific customer thermal situation and specified package
thermal resistances from junction to case.
6.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±2500
Charged-device model (CDM), per JEDEC specification JESD22C101 (2)
±1000
Machine Model
±250
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
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6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted) (1)
MIN
TA
Ambient Temperature
TJ
Junction Temperature Range
(2)
75
°C
ADC12D1600 (Standard
JEDEC thermal model)
–40
65
°C
ADC12D1x00 (Enhanced
thermal model or heatsink)
–40
85
°C
ADC12D1000 Junction
Temperature Range
140
°C
ADC12D1600 Junction
Temperature Range
135
°C
2
V
1.8
VA
V
–0.4
2.4
V
1.8
VIN+/- Voltage Range (3)
(DC-coupled)
VIN+/- Differential Voltage (4)
VIN+/- Current Range (5)
(DC-coupled at 100% duty
cycle)
1
(DC-coupled at 20% duty
cycle)
2
(DC-coupled at 10% duty
cycle)
2.8
(AC-coupled)
VIN+/- Power
UNIT
–40
Driver Supply Voltage (VDR)
–50
50
(maintaining common-mode
voltage, AC-coupled)
15.3
(not maintaining commonmode voltage, AC-coupled)
17.1
0
CLK+/- Voltage Range
mA peak
V
0
VA
0.4
2
VP-P
VCMO – 150
VCMO +150
mV
Differential CLK Amplitude
VCMI Common Mode Input Voltage
V
dBm
Ground Difference
max(GNDTC/DR/E)
-min(GNDTC/DR/E)
(5)
MAX
ADC12D1000 (Standard
JEDEC thermal model)
Supply Voltage (VA, VTC, VE)
(1)
(2)
(3)
(4)
NOM
V
All voltages are measured with respect to GND = GNDTC = GNDDR = GNDE = 0 V, unless otherwise specified.
Applies only to maximum operating speed.
Proper common mode voltage must be maintained to ensure proper output codes, especially during input overdrive.
This rating is intended for DC-coupled applications; the voltages listed may be safely applied to VIN+/- for the life-time duty-cycle of the
part.
Proper common mode voltage must be maintained to ensure proper output codes, especially during input overdrive.
6.4 Thermal Information
ADC12D1000,
ADC12D1600
THERMAL METRIC (1)
NXA (BGA)
UNIT
292 PINS
RθJA
Junction-to-ambient thermal resistance
16
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
2.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
2.5
°C/W
(1)
14
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report, SPRA953.
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6.5 Electrical Characteristics: Static Converter
Unless otherwise specified, the following apply after calibration for VA = VDR = VTC = VE = 1.9 V; I- and Q-channels, ACcoupled, unused channel terminated to AC ground, FSR Pin = High; CL = 10 pF; Differential, AC coupled Sine Wave
Sampling Clock, fCLK = 1 or 1.6 GHz at 0.5 VP-P with 50% duty cycle (as specified); VBG = Floating; Non-Extended Control
Mode; Rext = Rtrim = 3300 Ω ± 0.1%; Analog Signal Source Impedance = 100-Ω Differential; 1:2 Demultiplex Non-DES
Mode; Duty Cycle Stabilizer on. All other limits TA = 25°C, unless otherwise noted. (1) (2) (3)
PARAMETER
TEST CONDITIONS
Resolution with No Missing
Codes
TA = TMIN to TMAX
INL
Integral Non-Linearity
(Best fit)
1-MHz DC-coupled
over-ranged sine wave
TA = 25°C
DNL
Differential Non-Linearity
1-MHz DC-coupled
over-ranged sine wave
TA = 25°C
VOFF
Offset Error
VOFF_AD Input Offset Adjustment
J
Range
MIN
TYP
MAX
12
±2.5
TA = TMIN to TMAX
±4.8
±0.4
TA = TMIN to TMAX
Extended Control Mode
(4)
±0.9
UNIT
bits
LSB
LSB
5
LSB
±45
mV
PFSE
Positive Full-Scale Error
See
. TA = TMIN to TMAX
±25
mV
NFSE
Negative Full-Scale Error
See (4). TA = TMIN to TMAX
±25
mV
Out-of-Range Output Code (5)
(1)
(VIN+) − (VIN−) > + Full Scale, TA = TMIN to TMAX
4095
(VIN+) − (VIN−) < − Full Scale, TA = TMIN to TMAX
0
The analog inputs, labeled "I/O", are protected as shown below. Input voltage magnitudes beyond the Absolute Maximum Ratings may
V
A
TO INTERNAL
CIRCUITRY
I/O
GND
(2)
(3)
(4)
(5)
damage this device). See the following figure.
To ensure accuracy, it is required that VA, VTC, VE and VDR be well-bypassed. Each supply pin must be decoupled with separate
bypass capacitors.
Typical figures are at TA = 25°C, and represent most likely parametric norms. Test limits are ensured to TI's AOQL (Average Outgoing
Quality Level).
Calculation of Full-Scale Error for this device assumes that the actual reference voltage is exactly its nominal value. Full-Scale Error for
this device, therefore, is a combination of Full-Scale Error and Reference Voltage Error. See Figure 8. For relationship between Gain
Error and Full-Scale Error, see Specification Definitions for Gain Error.
This parameter is specified by design and is not tested in production.
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6.6 Electrical Characteristics: Dynamic Converter
TA = 25°C, unless otherwise noted
PARAMETER
FPBW
Full Power Bandwidth
Gain Flatness
TEST CONDITIONS
MIN
Non-DES Mode
TYP
MAX
UNIT
2.8
GHz
DESI, DESQ Mode
1.25
GHz
DESIQ Mode
1.75
GHz
NON-DES MODE
D.C. to Fs/2
D.C. to Fs
ADC12D1000
0.35
ADC12D1600
0.5
ADC12D1000
0.5
ADC12D1600
1
ADC12D1000
2.4
ADC12D1600
4
ADC12D1000
1.9
ADC12D1600
2
dB
dB
DESI, DESQ MODE
D.C. to Fs/2
dB
DESIQ MODE
D.C. to Fs/2
CER
NPR
IMD3
10–18
Code Error Rate
Noise Power Ratio
3rd order
Intermodulation
Distortion
Noise Floor Density
See
(1)
ADC12D1000
49.5
ADC12D1600
48.5
FIN1 = 1212.52 MHz at 7dBFS
ADC12D1000
–66
ADC12D1600
–63
FIN2 = 1217.52 MHz at 7dBFS
DESIQ Mode
ADC12D1000
–59
ADC12D1600
–56
50Ω single-ended
termination, DES Mode
ADC12D1000
–152.6
ADC12D1600
–153.6
ADC12D1000
–151.6
ADC12D1600
–152.6
ADC12D1000
–151.5
ADC12D1600
–152.6
ADC12D1000
–150.5
ADC12D1600
–151.6
Wideband input, DES
Mode (2)
(1)
(2)
16
dB
Error/Sample
dB
dBFS
dBc
dBm/Hz
dBFS/Hz
dBm/Hz
dBFS/Hz
The NPR was measured using an Agilent N6030A Arbitrary Waveform Generator (ARB) to generate the input signal. See the Wideband
Performance for an example spectrum. The "noise" portion of the signal was created by tones spaced at 500 kHz and the "notch" was a
25-MHz absence of tones centered at 320 MHz. The bandwidth of this equipment is only 500 MHz, so the final reported NPR was
extrapolated from the measured NPR as if the entire Nyquist band were occupied with noise.
The Noise Floor was measured for two conditions: the analog input terminated with 50 Ω, and in the presence of a 500-MHz wideband
noise signal with total power just below the maximum input level to the ADC. In both cases, the spurs at DC, Fs/4 and Fs/2 were
removed. The power over the entire Nyquist band (except the noise signal) was integrated and the average number is reported.
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Electrical Characteristics: Dynamic Converter (continued)
TA = 25°C, unless otherwise noted
PARAMETER
NON-DES MODE
ENOB
TEST CONDITIONS
Effective Number of Bits
ADC12D1000
9.6
ADC12D1600
9.4
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
9.5
8.7
ADC12D1600
TA = TMIN to TMAX
9.4
8.6
ADC12D1000
TA = TMIN to TMAX
9.4
8.7
ADC12D1600
TA = TMIN to TMAX
9.3
8.6
MAX
UNIT
Signal-to-Noise Plus
Distortion Ratio
Signal-to-Noise Ratio
bits
bits
bits
AIN = 998 MHz at –0.5 dBFS
8.9
bits
AIN = 1448 MHz at –0.5 dBFS
8.6
bits
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
59.7
ADC12D1600
58.2
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
59
54.1
ADC12D1600
TA = TMIN to TMAX
58
53.5
ADC12D1000
TA = TMIN to TMAX
58.2
54.1
ADC12D1600
TA = TMIN to TMAX
57.8
53.5
AIN = 498 MHz at –0.5
dBFS
SNR
TYP
AIN = 125 MHz at –0.5
dBFS
AIN = 498 MHz at –0.5
dBFS
SINAD
MIN
(2) (2)
dB
dB
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
55.4
ADC12D1600
55.1
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
53.6
ADC12D1600
53.8
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
60.2
ADC12D1600
58.5
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
59.7
55.1
ADC12D1600
TA = TMIN to TMAX
58.7
54.6
ADC12D1000
TA = TMIN to TMAX
58.7
55.1
ADC12D1600
TA = TMIN to TMAX
58.5
54.6
AIN = 498 MHz at –0.5
dBFS
dB
dB
dB
ADC12D1000
56.3
ADC12D1600
56.5
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
54.1
ADC12D1600
55
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dB
dB
AIN = 998 MHz at –0.5
dBFS
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dB
dB
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Electrical Characteristics: Dynamic Converter (continued)
TA = 25°C, unless otherwise noted
PARAMETER
THD
Total Harmonic
Distortion
TEST CONDITIONS
Second Harmonic
Distortion
3rd Harm Third Harmonic
Distortion
SFDR
Spurious-Free Dynamic
Range
MAX
ADC12D1000
–68.7
ADC12D1600
–70.3
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
–67
–61
ADC12D1600
TA = TMIN to TMAX
–66.6
–60
ADC12D1000
TA = TMIN to TMAX
–67.4
–61
ADC12D1600
TA = TMIN to TMAX
–66
–60
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
–62.9
ADC12D1600
–60.8
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
–63
ADC12D1600
–60
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
–75.7
ADC12D1600
–75
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
–75.7
ADC12D1600
–80
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
–79.8
ADC12D1600
–71
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
–70
ADC12D1600
–73
AIN = 1448 MHz at –0.5 dBFS
–67
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
–71
ADC12D1600
–74
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
–68.4
ADC12D1600
–68
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
–68.7
ADC12D1600
–69
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
–66
ADC12D1600
–62
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
–67
ADC12D1600
–61
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
71
ADC12D1600
70.3
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
68.4
61
ADC12D1600
TA = TMIN to TMAX
68
60
ADC12D1000
TA = TMIN to TMAX
68.7
61
ADC12D1600
TA = TMIN to TMAX
68.2
60
AIN = 498 MHz at –0.5
dBFS
18
TYP
AIN = 125 MHz at –0.5
dBFS
AIN = 498 MHz at –0.5
dBFS
2nd
Harm
MIN
dB
dB
dB
dB
dB
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc (min)
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
66
ADC12D1600
62
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
67
ADC12D1600
61.9
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dBc
dBc
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Electrical Characteristics: Dynamic Converter (continued)
TA = 25°C, unless otherwise noted
PARAMETER
DES MODE
ENOB
SINAD
SNR
THD
TEST CONDITIONS
MIN
TYP
MAX
UNIT
(2) (2) (2)
Effective Number of Bits
Signal-to-Noise Plus
Distortion Ratio
Signal-to-Noise Ratio
Total Harmonic
Distortion
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
9.5
ADC12D1600
9.4
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
9.4
8.7
ADC12D1600
TA = TMIN to TMAX
9.2
8.6
bits
bits
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
9.2
ADC12D1600
9.1
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
8.8
ADC12D1600
8.5
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
8.6
ADC12D1600
8.5
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
59
ADC12D1600
58.2
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
58.6
54
ADC12D1600
TA = TMIN to TMAX
57
53.5
bits
bits
bits
dB
dB
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
57.3
ADC12D1600
56.9
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
54.5
ADC12D1600
52.7
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
53.9
ADC12D1600
52.7
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
59.2
ADC12D1600
58.6
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
58.9
55.3
ADC12D1600
TA = TMIN to TMAX
57.9
54.6
dB
dB
dB
dB
dB
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
58.3
ADC12D1600
57.6
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
55.9
ADC12D1600
53.6
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
54.2
ADC12D1600
53.3
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
–74
ADC12D1600
–68.2
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
–71.2
–60
ADC12D1600
TA = TMIN to TMAX
–64.6
–60
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
–63.8
ADC12D1600
–66.3
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
–60
ADC12D1600
–60
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
–65
ADC12D1600
–61.7
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dB
dB
dB
dB
dB
dB
dB
dB
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Electrical Characteristics: Dynamic Converter (continued)
TA = 25°C, unless otherwise noted
PARAMETER
2nd
Harm
Second Harmonic
Distortion
3rd Harm Third Harmonic
Distortion
SFDR
20
Spurious-Free Dynamic
Range
TEST CONDITIONS
MIN
TYP
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
–82
ADC12D1600
–77.3
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
–82
ADC12D1600
–82.7
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
–72
ADC12D1600
–71.6
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
–63.2
ADC12D1600
–63
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
–75
ADC12D1600
–75.6
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
–82
ADC12D1600
–69.8
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
–73
ADC12D1600
–65.3
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
–65
ADC12D1600
–67.3
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
–65
ADC12D1600
–63
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
–67
ADC12D1600
–62.4
AIN = 125 MHz at –0.5
dBFS
ADC12D1000
69
ADC12D1600
69.8
AIN = 248 MHz at –0.5
dBFS
ADC12D1000
TA = TMIN to TMAX
69
60
ADC12D1600
TA = TMIN to TMAX
65.3
60
UNIT
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
dBc
AIN = 498 MHz at –0.5
dBFS
ADC12D1000
65
ADC12D1600
67.3
AIN = 998 MHz at –0.5
dBFS
ADC12D1000
64
ADC12D1600
60.2
AIN = 1448 MHz at –0.5
dBFS
ADC12D1000
66
ADC12D1600
60
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MAX
dBc
dBc
dBc
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6.7 Electrical Characteristics: Analog Input/Output and Reference
TA = 25°C, unless otherwise noted
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ADC12D1000
TA = TMIN to TMAX
540
600
660
mVP-P
ADC12D1600
TA = TMIN to TMAX
540
600
660
mVP-P
ADC12D1000
TA = TMIN to TMAX
740
800
860
mVP-P
ADC12D1600
TA = TMIN to TMAX
740
800
860
mVP-P
ANALOG INPUTS
VIN_FSR
Analog Differential Input
Full Scale Range
NON-EXTENDED CONTROL MODE
FSR Pin Low
FSR Pin High
EXTENDED CONTROL MODE
CIN
RIN
FM(14:0) = 0000h
600
mVP-P
FM(14:0) = 4000h (default)
800
mVP-P
FM(14:0) = 7FFFh
1000
mVP-P
Analog Input
Capacitance,
Non-DES Mode (1) (2)
Differential
0.02
pF
1.6
pF
Analog Input
Capacitance,
DES Mode (1) (2)
Differential
0.08
pF
2.2
pF
Differential Input
Resistance
ADC12D1000
TA = TMIN to TMAX
91
100
109
Ω
ADC12D1600
TA = TMIN to TMAX
91
100
109
Ω
ADC12D1000
TA = TMIN to TMAX
1.15
1.25
1.35
V
ADC12D1600
TA = TMIN to TMAX
1.15
1.25
1.35
V
Each input pin to ground
Each input pin to ground
COMMON-MODE OUTPUT
VCMO
Common-Mode Output
Voltage
TC_VCMO
VCMO_LVL
CL_VCMO
(1)
(2)
Common-Mode Output
Voltage Temperature
Coefficient
ICMO = ±100 µA
ICMO = ±100 µA
38
VCMO input threshold to
set
DC-coupling Mode
Maximum VCMO Load
Capacitance
ppm/°C
0.63
See (3)
V
80
pF
This parameter is specified by design and is not tested in production.
The differential and pin-to-ground input capacitances are lumped capacitance values from design; they are defined as shown below
VIN+
CIN, PIN-TO-GND
CIN, DIFF
VINCIN, PIN-TO-GND
(3)
This parameter is specified by design and is not tested in production.
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Electrical Characteristics: Analog Input/Output and Reference (continued)
TA = 25°C, unless otherwise noted
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ADC12D1000
TA = TMIN to TMAX
1.15
1.25
1.35
V
ADC12D1600
TA = TMIN to TMAX
1.15
1.25
1.35
V
BANDGAP REFERENCE
VBG
Bandgap Reference
Output Voltage
TC_VBG
CL_VBG
IBG = ±100 µA
Bandgap Reference
Voltage Temperature
Coefficient
IBG = ±100 µA
Maximum Bandgap
Reference load
Capacitance
See (3)
32
ppm/°C
80
pF
6.8 Electrical Characteristics: I-Channel To Q-Channel
PARAMETER
TEST CONDITIONS
MIN
TYP
Offset Match
X-TALK
MAX
UNIT
2
LSB
Positive Full-Scale Match
Zero offset selected in
Control Register
2
LSB
Negative Full-Scale Match
Zero offset selected in
Control Register
2
LSB
Phase Matching (I, Q)
fIN = 1 GHz
(VIN-)
0.0V
+VIN/2
Differential Analog Input Voltage (+VIN/2) - (-VIN/2)
Figure 8. Input / Output Transfer Characteristic
30
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6.16 Typical Characteristics
3
3
2
2
1
1
INL (LSB)
INL (LSB)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
0
-1
-1
-2
-2
-3
-3
0
4,095
0
4,095
OUTPUT CODE
OUTPUT CODE
Figure 9. INL vs Code (ADC12D1000)
Figure 10. INL vs Code (ADC12D1600)
1.0
1.0
0.5
0.5
INL (LSB)
INL (LSB)
0
0.0
-0.5
0.0
-0.5
+INL
-INL
-1.0
-50
0
+INL
-INL
50
-1.0
-50
100
TEMPERATURE (°C)
Figure 11. INL vs Temperature (ADC12D1000)
50
100
Figure 12. INL vs Temperature (ADC12D1600)
0.75
0.75
0.50
0.50
0.25
0.25
DNL (LSB)
DNL (LSB)
0
TEMPERATURE (°C)
0.00
0.00
-0.25
-0.25
-0.50
-0.50
-0.75
-0.75
0
4,095
0
OUTPUT CODE
4,095
OUTPUT CODE
Figure 13. DNL vs Code (ADC12D1000)
Figure 14. DNL vs Code (ADC12D1600)
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Typical Characteristics (continued)
0.50
0.50
0.25
0.25
DNL (LSB)
DNL (LSB)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
0.00
-0.25
0.00
-0.25
+DNL
-DNL
-0.50
-50
0
50
+DNL
-DNL
100
-0.50
-50
0
TEMPERATURE (°C)
10
10
9
9
8
7
8
7
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
6
6
-50
0
50
100
-50
0
TEMPERATURE (°C)
50
100
TEMPERATURE (°C)
Figure 17. ENOB vs Temperature (ADC12D1000)
Figure 18. ENOB vs Temperature (ADC12D1600)
10
10
9
9
ENOB
ENOB
100
Figure 16. DNL vs Temperature (ADC12D1600)
ENOB
ENOB
Figure 15. DNL vs Temperature (ADC12D1000)
8
7
8
7
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
6
6
1.6
1.8
2.0
2.2
1.6
VA(V)
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1.8
2.0
2.2
VA(V)
Figure 19. ENOB vs Supply Voltage (ADC12D1000)
32
50
TEMPERATURE (°C)
Figure 20. ENOB vs Supply Voltage (ADC12D1600)
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Typical Characteristics (continued)
10
10
9
9
ENOB
ENOB
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
8
7
8
7
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
6
6
0
250
500
750
1,000
0
CLOCK FREQUENCY (MHz)
800
1,200
1,600
Figure 22. ENOB vs Clock Frequency (ADC12D1600)
10
10
9
9
ENOB
ENOB
Figure 21. ENOB vs Clock Frequency (ADC12D1000)
8
7
8
7
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
6
6
0
500
1,000
1,500
0
INPUT FREQUENCY (MHz)
1,000
1,500
Figure 24. ENOB vs Input Frequency (ADC12D1600)
10
9
9
ENOB
10
8
7
8
7
NON-DES MODE
DES MODE
6
0.75
500
INPUT FREQUENCY (MHz)
Figure 23. ENOB vs Input Frequency (ADC12D1000)
ENOB
400
CLOCK FREQUENCY (MHz)
1.00
1.25
NON-DES MODE
DES MODE
1.50
1.75
6
0.75
VCMI(mV)
1.00
1.25
1.50
1.75
VCMI(mV)
Figure 25. ENOB vs VCMI (ADC12D1000)
Figure 26. ENOB vs VCMI (ADC12D1600)
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Typical Characteristics (continued)
62
62
60
60
SNR (dB)
SNR (dB)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
58
56
54
58
56
54
NON-DES MODE
DES MODE
52
-50
0
NON-DES MODE
DES MODE
50
52
-50
100
0
TEMPERATURE (°C)
62
62
60
60
58
56
54
58
56
54
NON-DES MODE
DES MODE
52
1.6
1.8
NON-DES MODE
DES MODE
2.0
52
1.6
2.2
1.8
VA(V)
2.0
2.2
VA(V)
Figure 29. SNR vs Supply Voltage (ADC12D1000)
Figure 30. SNR vs Supply Voltage (ADC12D1600)
62
62
60
60
SNR (dB)
SNR (dB)
100
Figure 28. SNR vs Temperature (ADC12D1600)
SNR (dB)
SNR (dB)
Figure 27. SNR vs Temperature (ADC12D1000)
58
56
54
58
56
54
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
52
52
0
250
500
750
1,000
CLOCK FREQUENCY (MHz)
Figure 31. SNR vs Clock Frequency (ADC12D1000)
34
50
TEMPERATURE (°C)
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0
400
800
1,200
1,600
CLOCK FREQUENCY (MHz)
Figure 32. SNR vs Clock Frequency (ADC12D1600)
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Typical Characteristics (continued)
62
62
60
60
SNR (dB)
SNR (dB)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
58
56
54
58
56
54
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
52
52
0
500
1,000
1,500
0
INPUT FREQUENCY (MHz)
-40
-40
-50
-50
-60
-70
-70
0
NON-DES MODE
DES MODE
50
-80
-50
100
0
TEMPERATURE (°C)
50
100
TEMPERATURE (°C)
Figure 35. THD vs Temperature (ADC12D1000)
Figure 36. THD vs Temperature (ADC12D1600)
-40
-40
-50
-50
THD (dBc)
THD (dBc)
1,500
-60
NON-DES MODE
DES MODE
-60
-70
-60
-70
NON-DES MODE
DES MODE
-80
1.6
1,000
Figure 34. SNR vs Input Frequency (ADC12D1600)
THD (dBc)
THD (dBc)
Figure 33. SNR vs Input Frequency (ADC12D1000)
-80
-50
500
INPUT FREQUENCY (MHz)
1.8
NON-DES MODE
DES MODE
2.0
2.2
-80
1.6
VA(V)
1.8
2.0
2.2
VA(V)
Figure 37. THD vs Supply Voltage (ADC12D1000)
Figure 38. THD vs Supply Voltage (ADC12D1600)
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Typical Characteristics (continued)
-40
-40
-50
-50
THD (dBc)
THD (dBc)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
-60
-70
-60
-70
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
-80
-80
0
250
500
750
1,000
0
CLOCK FREQUENCY (MHz)
-40
-40
-50
-50
-60
-70
1,200
1,600
-60
-70
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
-80
-80
0
500
1,000
1,500
0
INPUT FREQUENCY (MHz)
1,000
1,500
Figure 42. THD vs Input Frequency (ADC12D1600)
80
70
70
SFDR (dBc)
80
60
50
60
50
NON-DES MODE
DES MODE
40
-50
500
INPUT FREQUENCY (MHz)
Figure 41. THD vs Input Frequency (ADC12D1000)
0
NON-DES MODE
DES MODE
50
100
40
-50
TEMPERATURE (°C)
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0
50
100
TEMPERATURE (°C)
Figure 43. SFDR vs Temperature (ADC12D1000)
36
800
Figure 40. THD vs Clock Frequency (ADC12D1600)
THD (dBc)
THD (dBc)
Figure 39. THD vs Clock Frequency (ADC12D1000)
SFDR (dBc)
400
CLOCK FREQUENCY (MHz)
Figure 44. SFDR vs Temperature (ADC12D1600)
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Typical Characteristics (continued)
80
80
70
70
SFDR (dBc)
SFDR (dBc)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
60
50
60
50
NON-DES MODE
DES MODE
40
1.6
1.8
NON-DES MODE
DES MODE
2.0
40
1.6
2.2
1.8
VA(V)
2.2
Figure 46. SFDR vs Supply Voltage (ADC12D1600)
80
80
70
70
SFDR (dBc)
SFDR (dBc)
Figure 45. SFDR vs Supply Voltage (ADC12D1000)
60
50
60
50
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
40
40
0
250
500
750
1,000
0
CLOCK FREQUENCY (MHz)
400
800
1,200
1,600
CLOCK FREQUENCY (MHz)
Figure 47. SFDR vs Clock Frequency (ADC12D1000)
Figure 48. SFDR vs Clock Frequency (ADC12D1600)
80
80
70
70
SFDR (dBc)
SFDR (dBc)
2.0
VA(V)
60
50
60
50
NON-DES MODE
DES MODE
NON-DES MODE
DES MODE
40
40
0
500
1,000
1,500
INPUT FREQUENCY (MHz)
Figure 49. SFDR vs Input Frequency (ADC12D1000)
0
500
1,000
1,500
INPUT FREQUENCY (MHz)
Figure 50. SFDR vs Input Frequency (ADC12D1600)
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Typical Characteristics (continued)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
0
NON-DES MODE
-25
AMPLITUDE (dBFS)
AMPLITUDE (dBFS)
0
-50
-75
-100
NON-DES MODE
-25
-50
-75
-100
0
100
200
300
400
500
0
FREQUENCY (MHz)
DES MODE
-25
AMPLITUDE (dBFS)
AMPLITUDE (dBFS)
800
0
DES MODE
-50
-75
-25
-50
-75
-100
0
250
500
750
1,000
0
FREQUENCY (MHz)
400
800
1,200
1,600
FREQUENCY (MHz)
Figure 53. Spectral Response at FIN = 498 MHz
(ADC12D1000)
Figure 54. Spectral Response at FIN = 498 MHz
(ADC12D1600)
-40
-40
NONDES MODE
NONDES MODE
-50
CROSSTALK (dBFS)
-50
CROSSTALK (dBFS)
600
Figure 52. Spectral Response at FIN = 498 MHz
(ADC12D1600)
-100
-60
-70
-80
-60
-70
-80
-90
-90
0
1,000
2,000
3,000
AGGRESSOR INPUT FREQUENCY (MHz)
Figure 55. Crosstalk vs Source Frequency (ADC12D1000)
38
400
FREQUENCY (MHz)
Figure 51. Spectral Response at FIN = 498 MHz
(ADC12D1000)
0
200
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0
1,000
2,000
3,000
AGGRESSOR INPUT FREQUENCY (MHz)
Figure 56. Crosstalk vs Source Frequency (ADC12D1600)
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Typical Characteristics (continued)
0
0
-3
-3
SIGNAL GAIN (dB)
SIGNAL GAIN (dB)
VA = VDR = VTC = VE = 1.9 V, fCLK = 1.0/1.6 GHz, fIN = 498 MHz, TA= 25°C, I-channel, 1:2 Demux Non-DES Mode (1:1 Demux
Non-DES Mode has similar performance), unless otherwise stated. For NPR plots, notch width = 25 MHz, fc = 320 MHz.
-6
-9
-12
-6
-9
-12
NONDES
DES
DESIQ
-15
NONDES
DES
DESIQ
-15
0
1,000
2,000
3,000
0
INPUT FREQUENCY (MHz)
Figure 57. Full Power Bandwidth (ADC12D1000)
5.0
5.0
4.5
4.5
4.0
4.0
3.5
3.0
2.5
3,000
3.5
3.0
2.5
DEMUX
NON-DEMUX
DEMUX
NON-DEMUX
2.0
2.0
0
250
500
750
1,000
0
400
CLOCK FREQUENCY (MHz)
1,200
1,600
Figure 60. Power Consumption vs Clock Frequency
(ADC12D1600)
60
50
50
NPR (dB)
60
40
30
20
-40
800
CLOCK FREQUENCY (MHz)
Figure 59. Power Consumption vs Clock Frequency
(ADC12D1000)
NPR (dB)
2,000
Figure 58. Full Power Bandwidth (ADC12D1600)
POWER (W)
POWER (W)
1,000
INPUT FREQUENCY (MHz)
40
30
-30
-20
-10
0
VRMSLOADING LEVEL (dB)
Figure 61. NPR vs RMS Noise Loading Level (ADC12D1000)
20
-40
-30
-20
-10
0
VRMSLOADING LEVEL (dB)
Figure 62. NPR vs RMS Noise Loading Level (ADC12D1600)
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7 Detailed Description
7.1 Overview
The ADC12D1x00 is a versatile A/D converter with an innovative architecture, which permits very high-speed
operation. The controls available ease the application of the device to circuit solutions. Optimum performance
requires adherence to the provisions discussed here and in Application Information. This section covers an
overview, a description of control modes (Extended Control Mode and Non-Extended Control Mode), and
features.
The ADC12D1x00 uses a calibrated folding and interpolating architecture that achieves a high Effective Number
of Bits (ENOB). The use of folding amplifiers greatly reduces the number of comparators and power
consumption. Interpolation reduces the number of front-end amplifiers required, minimizing the load on the input
signal and further reducing power requirements. In addition to correcting other non-idealities, on-chip calibration
reduces the INL bow often seen with folding architectures. The result is an extremely fast, high-performance,
low-power converter.
The analog input signal (which is within the converter's input voltage range) is digitized to twelve bits at speeds
of 150/150 MSPS to 2.0/3.2 GSPS, typical. Differential input voltages below negative full-scale will cause the
output word to consist of all zeroes. Differential input voltages above positive full-scale will cause the output word
to consist of all ones. Either of these conditions at the I- or Q-input will cause the Out-of-Range I-channel or Qchannel output (ORI or ORQ), respectively, to output a logic-high signal.
In ECM, an expanded feature set is available through the Serial Interface. The ADC12D1x00 builds upon
previous architectures, introducing a new DES Mode timing adjust feature, AutoSync feature for multi-chip
synchronization and increasing to 15-bit for gain and 12-bit plus sign for offset the independent programmable
adjustment for each channel.
Each channel has a selectable output demultiplexer which feeds two LVDS buses. If the 1:2 Demux Mode is
selected, the output data rate is reduced to half the input sample rate on each bus. When Non-Demux Mode is
selected, the output data rate on each channel is at the same rate as the input sample clock and only one 12-bit
bus per channel is active.
7.2 Functional Block Diagram
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7.3 Feature Description
The ADC12D1x00 offers many features to make the device convenient to use in a wide variety of applications.
Table 1 is a summary of the features available, as well as details for the control mode chosen. "N/A" means "Not
Applicable."
Table 1. Features and Modes
NON-ECM
CONTROL PIN
ACTIVE IN
ECM
ECM
DEFAULT ECM STATE
AC-DC-coupled Mode Selection
Selected through VCMO
(Pin C2)
Yes
Not available
N/A
Input Full-scale Range Adjust
Selected through FSR
(Pin Y3)
No
Selected through the Config
Reg
(Addr: 3h and Bh)
Mid FSR value
Input Offset Adjust Setting
Not available
N/A
Selected through the Config
Reg
(Addr: 2h and Ah)
Offset = 0 mV
DES/Non-DES Mode Selection
Selected through DES
(Pin V5)
No
Selected through the DES Bit
(Addr: 0h; Bit: 7)
Non-DES Mode
DES Timing Adjust
Not available
N/A
Selected through the DES
Timing Adjust Reg
(Addr: 7h)
Mid skew offset
Sampling Clock Phase Adjust
Not available
N/A
Selected through the Config
Reg
(Addr: Ch and Dh)
tAD adjust disabled
DDR Clock Phase Selection
Selected through
DDRPh (Pin W4)
No
Selected through the DPS Bit
(Addr: 0h; Bit: 14)
0° Mode
LVDS Differential Voltage
Amplitude Selection
Higher amplitude only
N/A
Selected through the OVS Bit
(Addr: 0h; Bit: 13)
Higher amplitude
LVDS Common-Mode Voltage
Amplitude Selection
Selected through VBG
(Pin B1)
Yes
Not available
N/A
Output Formatting Selection
Offset Binary only
N/A
Selected through the 2SC Bit
(Addr: 0h; Bit: 4)
Offset Binary
Test Pattern Mode at Output
Selected through TPM
(Pin A4)
No
Selected through the TPM Bit
(Addr: 0h; Bit: 12)
TPM disabled
Demux/Non-Demux Mode
Selection
Selected through NDM
(Pin A5)
Yes
Not available
N/A
AutoSync
Not available
N/A
Selected through the Config
Reg
(Addr: Eh)
Master Mode,
RCOut1/2 disabled
DCLK Reset
Not available
N/A
Selected through the Config
Reg
(Addr: Eh; Bit: 0)
DCLK Reset disabled
Time Stamp
Not available
N/A
Selected through the TSE Bit
(Addr: 0h; Bit: 3)
Time Stamp disabled
On-command Calibration
Selected through CAL
(Pin D6)
Yes
Selected through the CAL Bit
(Addr: 0h; Bit: 15)
N/A
(CAL = 0)
Power-on Calibration Delay
Selection
Selected through
CalDly
(Pin V4)
Yes
Not available
N/A
Calibration Adjust
Not available
N/A
Selected through the Config
Reg
(Addr: 4h)
tCAL
Read/Write Calibration Settings
Not available
N/A
Selected through the SSC Bit
(Addr: 4h; Bit: 7)
R/W calibration values
disabled
FEATURE
INPUT CONTROL AND ADJUST
OUTPUT CONTROL AND ADJUST
CALIBRATION
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Feature Description (continued)
Table 1. Features and Modes (continued)
NON-ECM
CONTROL PIN
ACTIVE IN
ECM
ECM
DEFAULT ECM STATE
Power-down I-channel
Selected through PDI
(Pin U3)
Yes
Selected through the PDI Bit
(Addr: 0h; Bit: 11)
I-channel operational
Power-down Q-channel
Selected through PDQ
(Pin V3)
Yes
Selected through the PDQ Bit
(Addr: 0h; Bit: 10)
Q-channel operational
FEATURE
POWER-DOWN
7.3.1 Input Control and Adjust
There are several features and configurations for the input of the ADC12D1x00 so that it may be used in many
different applications. This section covers AC-DC-coupled Mode, input full-scale range adjust, input offset adjust,
DES/Non-DES Mode, and sampling clock phase adjust.
7.3.1.1 AC-DC-Coupled Mode
The analog inputs may be AC or DC-coupled. See AC-DC-Coupled Mode Pin (VCMO) for information on how to
select the desired mode and DC-Coupled Input Signals and AC-Coupled Input Signals for applications
information.
7.3.1.2 Input Full-Scale Range Adjust
The input full-scale range for the ADC12D1x00 may be adjusted through Non-ECM or ECM. In Non-ECM, a
control pin selects a higher or lower value; see Full-Scale Input Range Pin (FSR). In ECM, the input full-scale
range may be adjusted with 15-bits of precision. See VIN_FSR in Electrical Characteristics: Analog Input/Output
and Reference for electrical specification details. The higher and lower full-scale input range settings in NonECM correspond to the mid and min full-scale input range settings in ECM. It is necessary to execute an oncommand calibration following a change of the input full-scale range. See Register Maps for information about
the registers.
7.3.1.3 Input Offset Adjust
The input offset adjust for the ADC12D1x00 may be adjusted with 12-bits of precision plus sign through ECM.
See Register Maps for information about the registers.
7.3.1.4 DES Timing Adjust
The performance of the ADC12D1x00 in DES Mode depends on how well the two channels are interleaved, that
is, that the clock samples either channel with precisely a 50% duty-cycle, each channel has the same offset
(nominally code 2047/2048), and each channel has the same full-scale range. The ADC12D1x00 includes an
automatic clock phase background adjustment in DES Mode to automatically and continuously adjust the clock
phase of the I- and Q-channels. In addition to this, the residual fixed timing skew offset may be further manually
adjusted, and further reduce timing spurs for specific applications. See the DES Timing Adjust (Addr: 7h). As the
DES Timing Adjust is programmed from 0d to 127d, the magnitude of the Fs/2-Fin timing interleaving spur will
decrease to a local minimum and then increase again. The default, nominal setting of 64d may or may not
coincide with this local minimum. The user may manually skew the global timing to achieve the lowest possible
timing interleaving spur.
7.3.1.5 Sampling Clock Phase Adjust
The sampling clock (CLK) phase may be delayed internally to the ADC up to 825 ps in ECM. This feature is
intended to help the system designer remove small imbalances in clock distribution traces at the board level
when multiple ADCs are used, or to simplify complex system functions such as beam steering for phase array
antennas.
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Additional delay in the clock path also creates additional jitter when using the sampling clock phase adjust.
Because the sampling clock phase adjust delays all clocks, including the DCLKs and output data, the user is
strongly advised to use the minimal amount of adjustment and verify the net benefit of this feature in his system
before relying on it.
7.3.2 Output Control and Adjust
There are several features and configurations for the output of the ADC12D1x00 so that it may be used in many
different applications. This section covers DDR clock phase, LVDS output differential and common-mode voltage,
output formatting, Demux/Non-demux Mode, Test Pattern Mode, and Time Stamp.
7.3.2.1 DDR Clock Phase
The ADC12D1x00 output data is always delivered in Double Data Rate (DDR). With DDR, the DCLK frequency is
half the data rate and data is sent to the outputs on both edges of DCLK; see Figure 63. The DCLK-to-Data
phase relationship may be either 0° or 90°. For 0° Mode, the Data transitions on each edge of the DCLK. Any
offset from this timing is tOSK; see Electrical Characteristics: AC for details. For 90° Mode, the DCLK transitions in
the middle of each Data cell. Setup and hold times for this transition, tSU and tH, may also be found in Electrical
Characteristics: AC. The DCLK-to-Data phase relationship may be selected through the DDRPh Pin in Non-ECM
(see Dual Data Rate Phase Pin (DDRPH)) or the DPS bit in the Configuration Register (Addr: 0h; Bit: 14) in
ECM.
Data
DCLK
0° Mode
DCLK
90° Mode
Figure 63. DDR DCLK-to-Data Phase Relationship
7.3.2.2 LVDS Output Differential Voltage
The ADC12D1x00 is available with a selectable higher or lower LVDS output differential voltage. This parameter
is VOD and may be found in Electrical Characteristics: Digital Control and Output Pin. The desired voltage may be
selected through the OVS Bit (Addr: 0h, Bit 13). For many applications, in which the LVDS outputs are very close
to an FPGA on the same board, for example, the lower setting is sufficient for good performance; this will also
reduce the possibility for EMI from the LVDS outputs to other signals on the board. See Register Maps for more
information.
7.3.2.3 LVDS Output Common-Mode Voltage
The ADC12D1x00 is available with a selectable higher or lower LVDS output common-mode voltage. This
parameter is VOS and may be found in Electrical Characteristics: Digital Control and Output Pin. See LVDS
Output Common-Mode Pin (VBG) for information on how to select the desired voltage.
7.3.2.4 Output Formatting
The formatting at the digital data outputs may be either offset binary or two's complement. The default formatting
is offset binary, but two's complement may be selected through the 2SC Bit (Addr: 0h, Bit 4); see Register Maps
for more information.
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7.3.2.5 Test Pattern Mode
The ADC12D1x00 can provide a test pattern at the four output buses independently of the input signal to aid in
system debug. In Test Pattern Mode, the ADC is disengaged and a test pattern generator is connected to the
outputs, including ORI and ORQ. The test pattern output is the same in DES Mode or Non-DES Mode. Each port
is given a unique 12-bit word, alternating between 1's and 0's. When the part is programmed into the Demux
Mode, the test pattern’s order is described in Table 2. If the I- or Q-channel is powered down, the test pattern will
not be output for that channel.
Table 2. Test Pattern By Output Port In Demux Mode
TIME
Qd
Id
Q
I
ORQ
ORI
T0
000h
004h
008h
010h
0b
0b
T1
FFFh
FFBh
FF7h
FEFh
1b
1b
T2
000h
004h
008h
010h
0b
0b
T3
FFFh
FFBh
FF7h
FEFh
1b
1b
T4
000h
004h
008h
010h
0b
0b
T5
000h
004h
008h
010h
0b
0b
T6
FFFh
FFBh
FF7h
FEFh
1b
1b
T7
000h
004h
008h
010h
0b
0b
T8
FFFh
FFBh
FF7h
FEFh
1b
1b
T9
000h
004h
008h
010h
0b
0b
T10
000h
004h
008h
010h
0b
0b
T11
FFFh
FFBh
FF7h
FEFh
1b
1b
T12
000h
004h
008h
010h
0b
0b
T13
...
...
...
...
...
...
COMMENTS
Pattern
Sequence
n
Pattern
Sequence
n+1
Pattern
Sequence
n+2
When the part is programmed into the Non-Demux Mode, the test pattern’s order is described in Table 3.
Table 3. Test Pattern By Output Port In
Non-Demux Mode
TIME
Q
I
ORQ
ORI
T0
000h
004h
0b
0b
T1
000h
004h
0b
0b
T2
FFFh
FFBh
1b
1b
T3
FFFh
FFBh
1b
1b
T4
000h
004h
0b
0b
T5
FFFh
FFBh
1b
1b
T6
000h
004h
0b
0b
T7
FFFh
FFBh
1b
1b
T8
FFFh
FFBh
1b
1b
T9
FFFh
FFBh
1b
1b
T10
000h
004h
0b
0b
T11
000h
004h
0b
0b
T12
FFFh
FFBh
1b
1b
T13
FFFh
FFBh
1b
1b
T14
...
...
...
...
COMMENTS
Pattern
Sequence
n
Pattern
Sequence
n+1
7.3.2.6 Time Stamp
The Time Stamp feature enables the user to capture the timing of an external trigger event, relative to the
sampled signal. When enabled through the TSE Bit (Addr: 0h; Bit: 3), the LSB of the digital outputs (DQd, DQ,
DId, DI) captures the trigger information. In effect, the 12-bit converter becomes an 11-bit converter and the LSB
acts as a 1-bit converter with the same latency as the 11-bit converter. The trigger should be applied to the
DCLK_RST input. It may be asynchronous to the ADC sampling clock.
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7.3.3 Calibration Feature
The ADC12D1x00 calibration must be run to achieve specified performance. The calibration procedure is exactly
the same regardless of how it was initiated or when it is run. Calibration trims the analog input differential
termination resistors, the CLK input resistor, and sets internal bias currents which affect the linearity of the
converter. This minimizes full-scale error, offset error, DNL and INL, which results in the maximum dynamic
performance, as measured by: SNR, THD, SINAD (SNDR) and ENOB.
7.3.3.1 Calibration Control Pins and Bits
Table 4 is a summary of the pins and bits used for calibration. See Pin Configuration and Functions for complete
pin information and Figure 6 for the timing diagram.
Table 4. Calibration Pins
PIN (BIT)
NAME
FUNCTION
D6
(Addr: 0h; Bit 15)
CAL
(Calibration)
Initiate calibration
V4
CalDly
(Calibration Delay)
Select power-on calibration delay
(Addr: 4h)
Calibration Adjust
Adjust calibration sequence
B5
CalRun
(Calibration Running)
Indicates while calibration is running
C1/D2
Rtrim+/(Input termination trim resistor)
External resistor used to calibrate analog and CLK inputs
C3/D3
Rext+/(External Reference resistor)
External resistor used to calibrate internal linearity
7.3.3.2 How to Execute a Calibration
Calibration may be initiated by holding the CAL pin low for at least tCAL_L clock cycles, and then holding it high for
at least another tCAL_H clock cycles, as defined in Timing Requirements: Calibration. The minimum tCAL_L and
tCAL_H input clock cycle sequences are required to ensure that random noise does not cause a calibration to
begin when it is not desired. The time taken by the calibration procedure is specified as tCAL. The CAL Pin is
active in both ECM and Non-ECM. However, in ECM, the CAL Pin is logically OR'd with the CAL Bit, so both the
pin and bit are required to be set low before executing another calibration through either pin or bit.
7.3.3.3 Power-On Calibration
For standard operation, power-on calibration begins after a time delay following the application of power, as
determined by the setting of the CalDly Pin and measured by tCalDly (see Timing Requirements: Calibration). This
delay allows the power supply to come up and stabilize before the power-on calibration takes place. The best
setting (short or long) of the CalDly Pin depends upon the settling time of the power supply.
TI strongly recommends setting CalDly Pin (to either logic-high or logic-low) before powering the device on
because this pin affects the power-on calibration timing. This may be accomplished by setting CalDly through an
external 1-kΩ resistor connected to GND or VA. If the CalDly Pin is toggled while the device is powered on, it can
execute a calibration even though the CAL Pin/Bit remains logic-low.
The power-on calibration will be not be performed if the CAL pin is logic-high at power-on. In this case, the
calibration cycle will not begin until the on-command calibration conditions are met. The ADC12D1x00 will
function with the CAL pin held high at power up, but no calibration will be done and performance will be impaired.
If it is necessary to toggle the CalDly Pin before the system power-up sequence, then the CAL Pin/Bit must be
set to logic-high during the toggling and afterwards for 109 Sampling Clock cycles. This will prevent the power-on
calibration, so an on-command calibration must be executed or the performance will be impaired.
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7.3.3.4 On-Command Calibration
In addition to the power-on calibration, TI recommends executing an on-command calibration whenever the
settings or conditions to the device are altered significantly, to obtain optimal parametric performance. Some
examples include: changing the FSR through either ECM or Non-ECM, power-cycling either channel, and
switching into or out of DES Mode. For best performance, it is also recommended that an on-command
calibration be run 20 seconds or more after application of power and whenever the operating temperature
changes significantly, relative to the specific system performance requirements.
Due to the nature of the calibration feature, TI recommends avoiding unnecessary activities on the device while
the calibration is taking place. For example, do not read or write to the Serial Interface or use the DCLK Reset
feature while calibrating the ADC. Doing so will impair the performance of the device until it is re-calibrated
correctly. Also, TI recommends not applying a strong narrow-band signal to the analog inputs during calibration
because this may impair the accuracy of the calibration; broad spectrum noise is acceptable.
7.3.3.5 Calibration Adjust
The sequence of the calibration event itself may be adjusted. This feature can be used if a shorter calibration
time than the default is required; see tCAL in Timing Requirements: Calibration. However, the performance of the
device, when using this feature is not ensured.
The calibration sequence may be adjusted through CSS (Addr: 4h, Bit 14). The default setting of CSS = 1b
executes both RIN and RIN_CLK Calibration (using Rtrim) and internal linearity Calibration (using Rext). Executing
a calibration with CSS = 0b executes only the internal linearity Calibration. The first time that Calibration is
executed, it must be with CSS = 1b to trim RIN and RIN_CLK. However, once the device is at its operating
temperature and RIN has been trimmed at least one time, it will not drift significantly. To save time in subsequent
calibrations, trimming RIN and RIN_CLK may be skipped, that is, by setting CSS = 0b.
7.3.3.6 Read/Write Calibration Settings
When the ADC performs a calibration, the calibration constants are stored in an array which is accessible
through the Calibration Values register (Addr: 5h). To save the time which it takes to execute a calibration, tCAL,
or to allow re-use of a previous calibration result, these values can be read from and written to the register at a
later time. For example, if an application requires the same input impedance, RIN, this feature can be used to
load a previously determined set of values. For the calibration values to be valid, the ADC must be operating
under the same conditions, including temperature, at which the calibration values were originally determined by
the ADC.
To
1.
2.
3.
read calibration values from the SPI, do the following:
Set ADC to desired operating conditions.
Set SSC (Addr: 4h, Bit 7) to 1.
Read exactly 240 times the Calibration Values register (Addr: 5h). The register values are R0, R1, R2...
R239 where R0 is adummy value. The contents of R should be stored.
4. Set SSC (Addr: 4h, Bit 7) to 0.
5. Continue with normal operation.
To
1.
2.
3.
write calibration values to the SPI, do the following:
Set ADC to operating conditions at which Calibration Values were previously read.
Set SSC (Addr: 4h, Bit 7) to 1.
Write exactly 239 times the Calibration Values register (Addr: 5h). The registers should be written with stored
register valuesR1, R2... R239.
4. Make two additional dummy writes of 0000h.
5. Set SSC (Addr: 4h, Bit 7) to 0.
6. Continue with normal operation.
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7.3.3.7 Calibration and Power-Down
If PDI and PDQ are simultaneously asserted during a calibration cycle, the ADC12D1x00 will immediately power
down. The calibration cycle will continue when either or both channels are powered back up, but the calibration
will be compromised due to the incomplete settling of bias currents directly after power up. Therefore, a new
calibration should be executed upon powering the ADC12D1x00 back up. In general, the ADC12D1x00 should
be recalibrated when either or both channels are powered back up, or after one channel is powered down. For
best results, this should be done after the device has stabilized to its operating temperature.
7.3.3.8 Calibration and the Digital Outputs
During calibration, the digital outputs (including DI, DId, DQ, DQd and OR) are set logic-low, to reduce noise.
The DCLK runs continuously during calibration. After the calibration is completed and the CalRun signal is logiclow, it takes an additional 60 Sampling Clock cycles before the output of the ADC12D1x00 is valid converted
data from the analog inputs. This is the time it takes for the pipeline to flush, as well as for other internal
processes.
7.3.4 Power Down
On the ADC12D1x00, the I- and Q-channels may be powered down individually. This may be accomplished
through the control pins, PDI and PDQ, or through ECM. In ECM, the PDI and PDQ pins are logically OR'd with
the Control Register setting. See Power-Down I-Channel Pin (PDI) and Power-Down Q-Channel Pin (PDQ) for
more information.
7.4 Device Functional Modes
7.4.1 DES/Non-DES Mode
The ADC12D1x00 can operate in Dual-Edge Sampling (DES) or Non-DES Mode. The DES Mode allows for a
single analog input to be sampled by both I- and Q-channels. One channel samples the input on the rising edge
of the sampling clock and the other samples the same input signal on the falling edge of the sampling clock. A
single input is thus sampled twice per clock cycle, resulting in an overall sample rate of twice the sampling clock
frequency, for example, 2.0/3.2 GSPS with a 1.0/1.6 GHz sampling clock. Because DES Mode uses both I- and
Q-channels to process the input signal, both channels must be powered up for the DES Mode to function
properly.
In Non-ECM, only the I-input may be used for the DES Mode input. See Dual Edge Sampling Pin (DES) for
information on how to select the DES Mode. In ECM, either the I- or Q-input may be selected by first using the
DES bit (Addr: 0h, Bit 7) to select the DES Mode. The DEQ Bit (Addr: 0h, Bit: 6) is used to select the Q-input,
but the I-input is used by default. Also, both I- and Q-inputs may be driven externally, that is, DESIQ Mode, by
using the DIQ bit (Addr: 0h, Bit 5). See Driving the ADC in DES Mode for more information about how to drive
the ADC in DES Mode.
The DESIQ Mode results in the best DES Mode bandwidth. In general, the bandwidth decreases from Non-DES
Mode to DES Mode (specifically, DESI or DESQ) because both channels are sampling off the same input signal
and non-ideal effects introduced by interleaving the two channels lower the bandwidth. Driving both I- and Qchannels externally (DESIQ Mode) results in better bandwidth for the DES Mode because each channel is being
driven, which reduces routing losses.
In the DES Mode, the outputs must be carefully interleaved to reconstruct the sampled signal. If the device is
programmed into the 1:4 Demux DES Mode, the data is effectively demultiplexed by 1:4. If the sampling clock is
1.0/1.6 GHz, the effective sampling rate is doubled to 2.0/3.2 GSPS and each of the 4 output buses has an
output rate of 500/800 MSPS. All data is available in parallel. To properly reconstruct the sampled waveform, the
four bytes of parallel data that are output with each DCLK must be correctly interleaved. The sampling order is as
follows, from the earliest to the latest: DQd, DId, DQ, DI. See Figure 3. If the device is programmed into the NonDemux DES Mode, two bytes of parallel data are output with each edge of the DCLK in the following sampling
order, from the earliest to the latest: DQ, DI. See Figure 4.
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Device Functional Modes (continued)
7.4.2 Demux/Non-Demux Mode
The ADC12D1x00 may be in one of two demultiplex modes: Demux Mode or Non-Demux Mode (also sometimes
referred to as 1:1 Demux Mode). In Non-Demux Mode, the data from the input is simply output at the sampling
rate on one 12-bit bus. In Demux Mode, the data from the input is output at half the sampling rate, on twice the
number of buses. Demux/Non-Demux Mode may only be selected by the NDM pin. In Non-DES Mode, the
output data from each channel may be demultiplexed by a factor of 1:2 (1:2 Demux Non-DES Mode) or not
demultiplexed (Non-Demux Non-DES Mode). In DES Mode, the output data from both channels interleaved may
be demultiplexed (1:4 Demux DES Mode) or not demultiplexed (Non-Demux DES Mode).
7.5 Programming
7.5.1 Control Modes
The ADC12D1x00 may be operated in one of two control modes: Non-extended Control Mode (Non-ECM) or
Extended Control Mode (ECM). In the simpler Non-ECM (also sometimes referred to as Pin Control Mode), the
user affects available configuration and control of the device through the control pins. The ECM provides
additional configuration and control options through a serial interface and a set of 16 registers, most of which are
available to the customer.
7.5.1.1 Non-Extended Control Mode
In Non-extended Control Mode (Non-ECM), the Serial Interface is not active and all available functions are
controlled through various pin settings. Non-ECM is selected by setting the ECE Pin to logic-high. For the control
pins, "logic-high" and "logic-low" refer to VA and GND, respectively. Nine dedicated control pins provide a wide
range of control for the ADC12D1x00 and facilitate its operation. These control pins provide DES Mode selection,
Demux Mode selection, DDR Phase selection, execute Calibration, Calibration Delay setting, Power-down Ichannel, Power-down Q-channel, Test Pattern Mode selection, and Full-Scale Input Range selection. In addition
to this, two dual-purpose control pins provide for AC-DC-coupled Mode selection and LVDS output commonmode voltage selection. See Table 5 for a summary.
Table 5. Non-ECM Pin Summary
PIN NAME
LOGIC-LOW
LOGIC-HIGH
FLOATING
DES
Non-DES Mode
DES
Mode
Not valid
NDM
Demux
Mode
Non-Demux Mode
Not valid
DDRPh
0° Mode
90° Mode
Not valid
DEDICATED CONTROL PINS
CAL
See Calibration Pin (CAL)
CalDly
Not valid
Shorter delay
Longer delay
Not valid
PDI
I-channel active
Power Down
I-channel
Power Down
I-channel
PDQ
Q-channel active
Power Down
Q-channel
Power Down
Q-channel
TPM
Non-Test Pattern Mode
Test Pattern Mode
Not valid
FSR
Lower FS input Range
Higher FS input Range
Not valid
DUAL-PURPOSE CONTROL PINS
VCMO
AC-coupled operation
Not allowed
DC-coupled operation
Not allowed
Higher LVDS common-mode
voltage
Lower LVDS common-mode
voltage
VBG
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7.5.1.1.1 Dual Edge Sampling Pin (DES)
The Dual Edge Sampling (DES) Pin selects whether the ADC12D1x00 is in DES Mode (logic-high) or Non-DES
Mode (logic-low). DES Mode means that a single analog input is sampled by both I- and Q-channels in a timeinterleaved manner. One of the ADCs samples the input signal on the rising sampling clock edge (duty cycle
corrected); the other ADC samples the input signal on the falling sampling clock edge (duty cycle corrected). In
Non-ECM, only the I-input may be used for DES Mode, a.k.a. DESI Mode. In ECM, the Q-input may be selected
through the DEQ Bit (Addr: 0h, Bit: 6), a.k.a. DESQ Mode. In ECM, both the I- and Q-inputs may be selected,
a.k.a. DESIQ Mode.
To use this feature in ECM, use the DES bit in the Configuration Register (Addr: 0h; Bit: 7). See DES/Non-DES
Mode for more information.
7.5.1.1.2 Non-Demultiplexed Mode Pin (NDM)
The Non-Demultiplexed Mode (NDM) Pin selects whether the ADC12D1x00 is in Demux Mode (logic-low) or
Non-Demux Mode (logic-high). In Non-Demux Mode, the data from the input is produced at the sampled rate at a
single 12-bit output bus. In Demux Mode, the data from the input is produced at half the sampled rate at twice
the number of output buses. For Non-DES Mode, each I- or Q-channel will produce its data on one or two buses
for Non-Demux or Demux Mode, respectively. For DES Mode, the selected channel will produce its data on two
or four buses for Non-Demux or Demux Mode, respectively.
This feature is pin-controlled only and remains active during both Non-ECM and ECM. See Demux/Non-Demux
Mode for more information.
7.5.1.1.3 Dual Data Rate Phase Pin (DDRPH)
The Dual Data Rate Phase (DDRPh) Pin selects whether the ADC12D1x00 is in 0° Mode (logic-low) or 90° Mode
(logic-high). The Data is always produced in DDR Mode on the ADC12D1x00. The Data may transition either
with the DCLK transition (0° Mode) or halfway between DCLK transitions (90° Mode). The DDRPh Pin selects 0°
Mode or 90° Mode for both the I-channel: DI- and DId-to-DCLKI phase relationship and for the Q-channel: DQand DQd-to-DCLKQ phase relationship.
To use this feature in ECM, use the DPS bit in the Configuration Register (Addr: 0h; Bit: 14). See DDR Clock
Phase for more information.
7.5.1.1.4 Calibration Pin (CAL)
The Calibration (CAL) Pin may be used to execute an on-command calibration or to disable the power-on
calibration. The effect of calibration is to maximize the dynamic performance. To initiate an on-command
calibration through the CAL pin, bring the CAL pin high for a minimum of tCAL_H input clock cycles after it has
been low for a minimum of tCAL_L input clock cycles. Holding the CAL pin high upon power-on will prevent
execution of the power-on calibration. In ECM, this pin remains active and is logically OR'd with the CAL bit.
To use this feature in ECM, use the CAL bit in the Configuration Register (Addr: 0h; Bit: 15). See Calibration
Feature for more information.
7.5.1.1.5 Calibration Delay Pin (CALDLY)
The Calibration Delay (CalDly) Pin selects whether a shorter or longer delay time is present, after the application
of power, until the start of the power-on calibration. The actual delay time is specified as tCalDly and may be found
in Timing Requirements: Calibration. This feature is pin-controlled only and remains active in ECM. TI
recommends selecting the desired delay time before power-on and not dynamically alter this selection.
See Calibration Feature for more information.
7.5.1.1.6 Power-Down I-Channel Pin (PDI)
The Power-Down I-channel (PDI) Pin selects whether the I-channel is powered down (logic-high) or active (logiclow). The digital data output pins, DI and DId, (both positive and negative) are put into a high impedance state
when the I-channel is powered down. Upon return to the active state, the pipeline will contain meaningless
information and must be flushed. The supply currents (typicals and limits) are available for the I-channel powered
down or active and may be found in Electrical Characteristics: Power Supply. The device should be recalibrated
following a power-cycle of PDI (or PDQ).
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This pin remains active in ECM. In ECM, either this pin or the PDI bit (Addr: 0h; Bit: 11) in the Control Register
may be used to power-down the I-channel. See Power Down for more information.
7.5.1.1.7 Power-Down Q-Channel Pin (PDQ)
The Power-Down Q-channel (PDQ) Pin selects whether the Q-channel is powered down (logic-high) or active
(logic-low). This pin functions similarly to the PDI pin, except that it applies to the Q-channel. The PDI and PDQ
pins function independently of each other to control whether each I- or Q-channel is powered down or active.
This pin remains active in ECM. In ECM, either this pin or the PDQ bit (Addr: 0h; Bit: 10) in the Control Register
may be used to power-down the Q-channel. See Power Down for more information.
7.5.1.1.8 Test Pattern Mode Pin (TPM)
The Test Pattern Mode (TPM) Pin selects whether the output of the ADC12D1x00 is a test pattern (logic-high) or
the converted analog input (logic-low). The ADC12D1x00 can provide a test pattern at the four output buses
independently of the input signal to aid in system debug. In TPM, the ADC is disengaged and a test pattern
generator is connected to the outputs, including ORI and ORQ. See Test Pattern Mode for more information.
7.5.1.1.9 Full-Scale Input Range Pin (FSR)
The Full-Scale Input Range (FSR) Pin selects whether the full-scale input range for both the I- and Q-channel is
higher (logic-high) or lower (logic-low). The input full-scale range is specified as VIN_FSR in Electrical
Characteristics: Analog Input/Output and Reference. In Non-ECM, the full-scale input range for each I- and Qchannel may not be set independently, but it is possible to do so in ECM. The device must be calibrated
following a change in FSR to obtain optimal performance.
To use this feature in ECM, use the Configuration Registers (Addr: 3h and Bh). See Input Control and Adjust for
more information.
7.5.1.1.10 AC-DC-Coupled Mode Pin (VCMO)
The VCMO Pin serves a dual purpose. When functioning as an output, it provides the optimal common-mode
voltage for the DC-coupled analog inputs. When functioning as an input, it selects whether the device is ACcoupled (logic-low) or DC-coupled (floating). This pin is always active, in both ECM and Non-ECM.
7.5.1.1.11 LVDS Output Common-Mode Pin (VBG)
The VBG Pin serves a dual purpose. When functioning as an output, it provides the bandgap reference. When
functioning as an input, it selects whether the LVDS output common-mode voltage is higher (logic-high) or lower
(floating). The LVDS output common-mode voltage is specified as VOS and may be found in Electrical
Characteristics: Digital Control and Output Pin. This pin is always active, in both ECM and Non-ECM.
7.5.1.2 Extended Control Mode
In Extended Control Mode (ECM), most functions are controlled through the Serial Interface. In addition to this,
several of the control pins remain active. See Table 1 for details. ECM is selected by setting the ECE Pin to
logic-low. If the ECE Pin is set to logic-high (Non-ECM), then the registers are reset to their default values. So, a
simple way to reset the registers is by toggling the ECE pin. Four pins on the ADC12D1x00 control the Serial
Interface: SCS, SCLK, SDI and SDO. This section covers the Serial Interface. The Register Definitions are
located at the end of the data sheet so that they are easy to find, see Register Maps.
7.5.1.2.1 The Serial Interface
The ADC12D1x00 offers a Serial Interface that allows access to the sixteen control registers within the device.
The Serial Interface is a generic 4-wire (optionally 3-wire) synchronous interface that is compatible with SPI type
interfaces that are used on many micro-controllers and DSP controllers. Each serial interface access cycle is
exactly 24 bits long. A register-read or register-write can be accomplished in one cycle. The signals are defined
in such a way that the user can opt to simply join SDI and SDO signals in his system to accomplish a single,
bidirectional SDI/O signal. A summary of the pins for this interface may be found in Table 6. See Figure 7 for the
timing diagram and Timing Requirements: Serial Port Interface for timing specification details. Control register
contents are retained when the device is put into power-down mode. If this feature is unused, the SCLK, SDI,
and SCS pins may be left floating because they each have an internal pullup.
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Table 6. Serial Interface Pins
PIN
NAME
C4
SCS (Serial Chip Select bar)
C5
SCLK (Serial Clock)
B4
SDI (Serial Data In)
A3
SDO (Serial Data Out)
SCS: Each assertion (logic-low) of this signal starts a new register access, that is, the SDI command field must
be ready on the following SCLK rising edge. The user is required to deassert this signal after the 24th clock. If
the SCS is deasserted before the 24th clock, no data read/write will occur. For a read operation, if the SCS is
asserted longer than 24 clocks, the SDO output will hold the D0 bit until SCS is deasserted. For a write
operation, if the SCS is asserted longer than 24 clocks, data write will occur normally through the SDI input upon
the 24th clock. Setup and hold times, tSCS and tHCS, with respect to the SCLK must be observed. SCS must be
toggled in between register access cycles.
SCLK: This signal is used to register the input data (SDI) on the rising edge; and to source the output data
(SDO) on the falling edge. The user may disable the clock and hold it at logic-low. There is no minimum
frequency requirement for SCLK; see fSCLK in Timing Requirements: Serial Port Interface for more details.
SDI: Each register access requires a specific 24-bit pattern at this input, consisting of a command field and a
data field. If the SDI and SDO wires are shared (3-wire mode), then during read operations, it is necessary to tristate the master which is driving SDI while the data field is being output by the ADC on SDO. The master must
be at TRI-STATE before the falling edge of the 8th clock. If SDI and SDO are not shared (4-wire mode), then this
is not necessary. Setup and hold times, tSH and tSSU, with respect to the SCLK must be observed.
SDO: This output is normally at TRI-STATE and is driven only when SCS is asserted, the first 8 bits of command
data have been received and it is a READ operation. The data is shifted out, MSB first, starting with the 8th
clock's falling edge. At the end of the access, when SCS is deasserted, this output is at TRI-STATE once again.
If an invalid address is accessed, the data sourced will consist of all zeroes. If it is a read operation, there will be
a bus turnaround time, tBSU, from when the last bit of the command field was read in until the first bit of the data
field is written out.
Table 7 shows the Serial Interface bit definitions.
Table 7. Command and Data Field Definitions
BIT NO.
NAME
COMMENTS
1
Read/Write (R/W)
1b indicates a read operation
0b indicates a write operation
2-3
Reserved
Bits must be set to 10b
4-7
A
16 registers may be addressed. The order is
MSB first
8
X
This is a "don't care" bit
D
Data written to or read from addressed
register
9-24
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The serial data protocol is shown for a read and write operation in Figure 64 and Figure 65, respectively.
1
2
3
4
5
6
7
8
R/W
1
0
A3
A2
A1
A0
X
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
D5
D4
D3
D2
D1
D0
25
SCSb
SCLK
SDI
SDO
*Only required to be tri-stated in 3-wire mode.
D15 D14 D13 D12 D11 D10
D9
D8
D7
D6
Figure 64. Serial Data Protocol - Read Operation
1
2
3
4
5
6
7
8
R/W
1
0
A3
A2
A1
A0
X
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
D15 D14
D13
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
25
SCSb
SCLK
SDI
SDO
Figure 65. Serial Data Protocol - Write Operation
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7.6 Register Maps
Ten read/write registers provide several control and configuration options in the Extended Control Mode. These
registers have no effect when the device is in the Non-extended Control Mode. Each register description below
also shows the Power-On Reset (POR) state of each control bit. See Table 8 for a summary. For a description of
the functionality and timing to read/write the control registers, see The Serial Interface.
Table 8. Register Addresses
A3
A2
A1
A0
Hex
Register Addressed
0
0
0
0
0h
Configuration Register 1
0
0
0
1
1h
Reserved
0
0
1
0
2h
I-channel Offset
0
0
1
1
3h
I-channel Full-Scale Range
0
1
0
0
4h
Calibration Adjust
0
1
0
1
5h
Calibration Values
0
1
1
0
6h
Reserved
0
1
1
1
7h
DES Timing Adjust
1
0
0
0
8h
Reserved
1
0
0
1
9h
Reserved
1
0
1
0
Ah
Q-channel Offset
1
0
1
1
Bh
Q-channel Full-Scale Range
1
1
0
0
Ch
Aperture Delay Coarse Adjust
1
1
0
1
Dh
Aperture Delay Fine Adjust
1
1
1
0
Eh
AutoSync
1
1
1
1
Fh
Reserved
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Table 9. Configuration Register 1
Addr: 0h (0000b)
POR state: 2000h
Bit
15
14
13
12
11
10
9
8
7
6
5
4
3
Name
CAL
DPS
OVS
TPM
PDI
PDQ
Res
LFS
DES
DEQ
DIQ
2SC
TSE
POR
0
0
1
0
0
0
0
0
0
0
0
0
0
2
1
0
Res
0
0
0
Bit 15
CAL: Calibration Enable. When this bit is set to 1b, an on-command calibration is initiated. This bit is not reset automatically
upon completion of the calibration. Therefore, the user must reset this bit to 0b and then set it to 1b again to execute another
calibration. This bit is logically OR'd with the CAL Pin; both bit and pin must be set to 0b before either is used to execute a
calibration.
Bit 14
DPS: DCLK Phase Select. In DDR, set this bit to 0b to select the 0° Mode DDR Data-to-DCLK phase relationship and to 1b to
select the 90° Mode. If the device is in Non-Demux Mode, this bit has no effect; the device will always be in 0°DDR Mode.
Bit 13
OVS: Output Voltage Select. This bit sets the differential voltage level for the LVDS outputs including Data, OR, and DCLK. 0b
selects the lower level and 1b selects the higher level. See VOD in Electrical Characteristics: Digital Control and Output Pin for
details.
Bit 12
TPM: Test Pattern Mode. When this bit is set to 1b, the device will continually output a fixed digital pattern at the digital Data
and OR outputs. When set to 0b, the device will continually output the converted signal, which was present at the analog
inputs. See Test Pattern Mode for details about the TPM pattern.
Bit 11
PDI: Power-down I-channel. When this bit is set to 0b, the I-channel is fully operational; when it is set to 1b, the I-channel is
powered-down. The I-channel may be powered-down through this bit or the PDI Pin, which is active, even in ECM.
Bit 10
PDQ: Power-down Q-channel. When this bit is set to 0b, the Q-channel is fully operational; when it is set to 1b, the Q-channel
is powered-down. The Q-channel may be powered-down through this bit or the PDQ Pin, which is active, even in ECM.
Bit 9
Reserved. Must be set to 0b.
Bit 8
LFS: Low-Frequency Select. If the sampling clock (CLK) is at or below 300 MHz, set this bit to 1b for improved performance.
Bit 7
DES: Dual-Edge Sampling Mode select. When this bit is set to 0b, the device will operate in the Non-DES Mode; when it is set
to 1b, the device will operate in the DES Mode. See DES/Non-DES Mode for more information.
Bit 6
DEQ: DES Q-input select, a.k.a. DESQ Mode. When the device is in DES Mode, this bit selects the input that the device will
operate on. The default setting of 0b selects the I-input and 1b selects the Q-input.
Bit 5
DIQ: DES I- and Q-input, a.k.a. DESIQ Mode. When in DES Mode, setting this bit to 1b shorts the I- and Q-inputs internally to
the device. If the bit is left at its default 0b, the I- and Q-inputs remain electrically separate. To operate the device in DESIQ
Mode, Bits must be set to 101b. In this mode, both the I- and Q-inputs must be externally driven; see DES/Non-DES
Mode for more information.
Bit 4
2SC: Two's Complement output. For the default setting of 0b, the data is output in Offset Binary format; when set to 1b, the
data is output in Two's Complement format.
Bit 3
TSE: Time Stamp Enable. For the default setting of 0b, the Time Stamp feature is not enabled; when set to 1b, the feature is
enabled. See Output Control and Adjust for more information about this feature.
Bits 2:0
Reserved. Must be set as shown.
Table 10. Reserved
Addr: 1h (0001b)
Bit
15
POR state: 2A0Eh
14
13
12
11
10
9
8
Name
6
5
4
3
2
1
0
0
0
0
0
1
1
1
0
Res
POR
0
Bits 15:0
54
7
0
1
0
1
0
1
0
Reserved. Must be set as shown.
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Table 11. I-Channel Offset Adjust
Addr: 2h (0010b)
Bit
POR state: 0000h
15
Name
14
13
Res
POR
0
0
12
11
10
9
8
7
6
0
0
0
0
0
0
OS
0
5
4
3
2
1
0
0
0
0
0
0
OM(11:0)
0
0
Bits 15:13
Reserved. Must be set to 0b.
Bit 12
OS: Offset Sign. The default setting of 0b incurs a positive offset of a magnitude set by Bits 11:0 to the ADC output. Setting
this bet to 1b incurs a negative offset of the set magnitude.
Bits 11:0
OM(11:0): Offset Magnitude. These bits determine the magnitude of the offset set at the ADC output (straight binary coding).
The range is from 0 mV for OM(11:0) = 0d to 45 mV for OM(11:0) = 4095d in steps of approximately 11 µV. Monotonicity is
ensured by design only for the 9 MSBs.
Code
Offset [mV]
0000 0000 0000 (default)
0
1000 0000 0000
22.5
1111 1111 1111
45
Table 12. I-Channel Full Scale Range Adjust
Addr: 3h (0011b)
Bit
15
Name
Res
POR
0
POR state: 4000h
14
13
12
11
10
9
8
1
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
FM(14:0)
0
Bit 15
Reserved. Must be set to 0b.
Bits 14:0
FM(14:0): FSR Magnitude. These bits increase the ADC full-scale range magnitude (straight binary coding.) The range is from
600 mV (0d) to 1000 mV (32767d) with the default setting at 800 mV (16384d). Monotonicity is ensured by design only for the
9 MSBs. The mid-range (low) setting in ECM corresponds to the nominal (low) setting in Non-ECM. A greater range of FSR
values is available in ECM, that is, FSR values above 800 mV. See VIN_FSR in Electrical Characteristics: Analog Input/Output
and Reference for characterization details.
Code
FSR [mV]
000 0000 0000 0000
600
100 0000 0000 0000 (default)
800
111 1111 1111 1111
1000
Table 13. Calibration Adjust
Addr: 4h (0100b)
POR state: DF4Bh
Bit
15
14
Name
Res
CSS
POR
1
1
13
12
11
10
9
8
Res
0
1
1
7
6
5
4
SSC
1
1
1
0
3
2
1
0
0
1
1
Res
1
0
0
1
Bit 15
Reserved. Must be set as shown.
Bit 14
CSS: Calibration Sequence Select. The default 1b selects the following calibration sequence: reset all previously calibrated
elements to nominal values, do RIN Calibration, do internal linearity Calibration. Setting CSS = 0b selects the following
calibration sequence: do not reset RIN to its nominal value, skip RIN calibration, do internal linearity Calibration. The calibration
must be completed at least one time with CSS = 1b to calibrate RIN. Subsequent calibrations may be run with CSS = 0b (skip
RIN calibration) or 1b (full RIN and internal linearity Calibration).
Bits 13:8
Reserved. Must be set as shown.
Bit 7
SSC: SPI Scan Control. Setting this control bit to 1b allows the calibration values, stored in Addr: 5h, to be read/written. When
not reading/writing the calibration values, this control bit should left at its default 0b setting. See Calibration Feature for more
information.
Bits 6:0
Reserved. Must be set as shown.
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Table 14. Calibration Values
Addr: 5h (0101b)
Bit
POR state: XXXXh
15
14
13
12
11
10
9
8
X
X
X
X
X
X
X
X
Name
7
6
5
4
3
2
1
0
X
X
X
X
X
X
X
SS(15:0)
POR
Bits 15:0
X
SS(15:0): SPI Scan. When the ADC performs a self-calibration, the values for the calibration are stored in this register and may
be read from/ written to it. Set SSC (Addr: 4h, Bit 7) to read/write. See Calibration Feature for more information.
Table 15. Reserved
Addr: 6h (0110b)
Bit
15
POR state: 1C20h
14
13
12
11
10
9
8
Name
7
6
5
4
3
2
1
0
0
0
1
0
0
0
0
0
4
3
2
1
0
0
0
0
0
Res
POR
0
Bits 15:0
0
0
1
1
1
0
0
Reserved. Must be set as shown.
Table 16. Des Timing Adjust
Addr: 7h (0111b)
Bit
POR state: 8140h
15
14
13
1
0
0
Name
12
11
10
9
8
7
6
5
0
0
0
1
0
1
0
DTA(6:0)
POR
0
Res
0
Bits 15:9
DTA(6:0): DES Mode Timing Adjust. In the DES Mode, the time at which the falling edge sampling clock samples relative to
the rising edge of the sampling clock may be adjusted; the automatic duty cycle correction continues to function. See Input
Control and Adjust for more information. The nominal step size is 30fs.
Bits 8:0
Reserved. Must be set as shown.
Table 17. Reserved
Addr: 8h (1000b)
Bit
15
POR state: 0000h
14
13
12
11
10
9
8
Name
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
Res
POR
0
Bits 15:0
0
0
0
0
0
0
0
Reserved. Must be set as shown.
Table 18. Reserved
Addr: 9h (1001b)
Bit
15
POR state: 0000h
14
13
12
11
10
9
8
Name
Res
POR
0
Bits 15:0
56
0
0
0
0
0
0
0
Reserved. Must be set as shown.
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Table 19. Q-Channel Offset Adjust
Addr: Ah (1010b)
Bit
POR state: 0000h
15
Name
14
13
Res
POR
0
0
12
11
10
9
8
7
6
0
0
0
0
0
0
OS
0
5
4
3
2
1
0
0
0
0
0
0
OM(11:0)
0
0
Bits 15:13
Reserved. Must be set to 0b.
Bit 12
OS: Offset Sign. The default setting of 0b incurs a positive offset of a magnitude set by Bits 11:0 to the ADC output. Setting
this bet to 1b incurs a negative offset of the set magnitude.
Bits 11:0
OM(11:0): Offset Magnitude. These bits determine the magnitude of the offset set at the ADC output (straight binary coding).
The range is from 0 mV for OM(11:0) = 0d to 45 mV for OM(11:0) = 4095d in steps of approximately 11 µV. Monotonicity is
ensured by design only for the 9 MSBs.
Code
Offset [mV]
0000 0000 0000 (default)
0
1000 0000 0000
22.5
1111 1111 1111
45
Table 20. Q-Channel Full-Scale Range Adjust
Addr: Bh (1011b)
Bit
15
Name
Res
POR
0
POR state: 4000h
14
13
12
11
10
9
8
1
0
0
0
0
0
0
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
FM(14:0)
0
Bit 15
Reserved. Must be set to 0b.
Bits 14:0
FM(14:0): FSR Magnitude. These bits increase the ADC full-scale range magnitude (straight binary coding.) The range is from
600 mV (0d) to 1000 mV (32767d) with the default setting at 800 mV (16384d). Monotonicity is ensured by design only for the
9 MSBs. The mid-range (low) setting in ECM corresponds to the nominal (low) setting in Non-ECM. A greater range of FSR
values is available in ECM, that is, FSR values above 800 mV. See VIN_FSR in Electrical Characteristics: Analog Input/Output
and Reference for characterization details.
Code
FSR [mV]
000 0000 0000 0000
600
100 0000 0000 0000 (default)
800
111 1111 1111 1111
1000
Table 21. Aperture Delay Coarse Adjust
Addr: Ch (1100b)
Bit
15
POR state: 0004h
14
13
12
11
Name
POR
10
9
8
7
6
5
4
CAM(11:0)
0
0
0
0
0
0
0
0
0
0
0
0
3
2
STA
DCC
0
1
1
0
Res
0
0
Bits 15:4
CAM(11:0): Coarse Adjust Magnitude. This 12-bit value determines the amount of delay that will be applied to the input CLK
signal. The range is 0 ps delay for CAM(11:0) = 0d to a maximum delay of 825 ps for CAM(11:0) = 2431d (±95 ps due to PVT
variation) in steps of approximately 340 fs. For code CAM(11:0) = 2432d and above, the delay saturates and the maximum
delay applies. Additional, finer delay steps are available in register Dh. The STA (Bit 3) must be selected to enable this
function.
Bit 3
STA: Select tAD Adjust. Set this bit to 1b to enable the tAD adjust feature, which will make both coarse and fine adjustment
settings, that is, CAM(11:0) and FAM(5:0), available.
Bit 2
DCC: Duty Cycle Correct. This bit can be set to 0b to disable the automatic duty-cycle stabilizer feature of the chip. This
feature is enabled by default.
Bits 1:0
Reserved. Must be set to 0b.
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Table 22. Aperture Delay Fine Adjust
Addr: Dh (1101b)
Bit
POR state: 0000h
15
14
13
0
0
0
Name
12
11
10
9
0
0
0
FAM(5:0)
POR
8
7
6
5
4
0
0
0
0
0
Res
0
3
2
1
0
0
0
0
0
Res
Bits 15:10
FAM(5:0): Fine Aperture Adjust Magnitude. This 6-bit value determines the amount of additional delay that will be applied to
the input CLK when the Clock Phase Adjust feature is enabled through STA (Addr: Ch, Bit 3). The range is straight binary from
0 ps delay for FAM(5:0) = 0d to 2.3 ps delay for FAM(5:0) = 63d (±300 fs due to PVT variation) in steps of approximately 36 fs.
Bits 9:0
Reserved. Must be set as shown.
Table 23. Autosync
Addr: Eh (1110b)
Bit
POR state: 0003h
15
14
13
12
0
0
0
0
Name
11
10
9
8
7
6
0
0
0
0
0
DRC(8:0)
POR
0
5
4
0
0
Res
3
SP(1:0)
0
2
1
0
ES
DOC
DR
0
1
1
Bits 15:7
DRC(8:0): Delay Reference Clock (8:0). These bits may be used to increase the delay on the input reference clock when
synchronizing multiple ADCs. The delay may be set from a minimum of 0s (0d) to a maximum of 1000 ps (319d). The delay
remains the maximum of 1000 ps for any codes above or equal to 319d. See Synchronizing Multiple ADC12D1x00s in a
System for more information.
Bits 6:5
Reserved. Must be set as shown.
Bits 4:3
SP(1:0): Select Phase. These bits select the phase of the reference clock which is latched. The codes correspond to the
following phase shift:
00 = 0°
01 = 90°
10 = 180°
11 = 270°
Bit 2
ES: Enable Slave. Set this bit to 1b to enable the Slave Mode of operation. In this mode, the internal divided clocks are
synchronized with the reference clock coming from the master ADC. The master clock is applied on the input pins RCLK. If this
bit is set to 0b, then the device is in Master Mode.
Bit 1
DOC: Disable Output reference Clocks. Setting this bit to 0b sends a CLK/4 signal on RCOut1 and RCOut2. The default
setting of 1b disables these output drivers. This bit functions as described, regardless of whether the device is operating in
Master or Slave Mode, as determined by ES (Bit 2).
Bit 0
DR: Disable Reset. The default setting of 1b leaves the DCLK_RST functionality disabled. Set this bit to 0b to enable
DCLK_RST functionality.
Table 24. Reserved
Addr: Fh (1111b)
Bit
15
POR state: 0018h
14
13
12
11
10
9
8
Name
POR
0
Bits 15:0
58
7
6
5
4
3
2
1
0
0
0
0
1
1
0
0
0
Res
0
0
0
0
0
0
0
Reserved. This address is read only.
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8 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
8.1 Application Information
8.1.1 The Analog Inputs
The ADC12D1x00 will continuously convert any signal which is present at the analog inputs, as long as a CLK
signal is also provided to the device. This section covers important aspects related to the analog inputs including:
acquiring the input, driving the ADC in DES Mode, the reference voltage and FSR, out-of-range indication, ACDC-coupled signals, and single-ended input signals.
8.1.1.1 Acquiring the Input
Data is acquired at the rising edge of CLK+ in Non-DES Mode and both the falling and rising edges of CLK+ in
DES Mode. The digital equivalent of that data is available at the digital outputs a constant number of sampling
clock cycles later for the DI, DQ, DId and DQd output buses, a.k.a. Latency, depending on the demultiplex mode
which is selected. See tLAT in Electrical Characteristics: AC. In addition to the Latency, there is a constant output
delay, tOD, before the data is available at the outputs. See tOD in Electrical Characteristics: AC and the timing
diagrams.
The output latency versus Demux/Non-Demux Mode is shown in Table 25 and Table 26, respectively. For DES
Mode, the I- and Q-channel inputs are available in ECM, but only the I-channel input is available in Non-ECM.
Table 25. Output Latency in Demux Mode
(1)
DATA
NON-DES MODE
DES MODE
Q-INPUT (1)
I-INPUT
DI
I-input sampled with rise of CLK,
34 cycles earlier
Q-input sampled with rise of CLK,
34 cycles earlier
I-input sampled with rise of CLK,
34 cycles earlier
DQ
Q-input sampled with rise of CLK,
34 cycles earlier
Q-input sampled with fall of CLK,
34.5 cycles earlier
I-input sampled with fall of CLK,
34.5 cycles earlier
DId
I-input sampled with rise of CLK,
35 cycles earlier
Q-input sampled with rise of CLK,
35 cycles earlier
I-input sampled with rise of CLK,
35 cycles earlier
DQd
Q-input sampled with rise of CLK,
35 cycles earlier
Q-input sampled with fall of CLK,
35.5 cycles earlier
I-input sampled with fall of CLK,
35.5 cycles earlier
Available in ECM only.
Table 26. Output Latency in Non-Demux Mode
(1)
DATA
NON-DES MODE
DES MODE
Q-INPUT (1)
I-INPUT
DI
I-input sampled with rise of CLK,
34 cycles earlier
Q-input sampled with rise of CLK,
34 cycles earlier
I-input sampled with rise of CLK,
34 cycles earlier
DQ
Q-input sampled with rise of CLK,
34 cycles earlier
Q-input sampled with rise of CLK,
34.5 cycles earlier
I-input sampled with rise of CLK,
34.5 cycles earlier
DId
No output;
high impedance.
DQd
No output;
high impedance.
Available in ECM only.
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8.1.1.2 Driving the ADC in DES Mode
The ADC12D1x00 can be configured as either a 2-channel, 1.0/1.6 GSPS device (Non-DES Mode) or a 1channel 2.0/3.2 GSPS device (DES Mode). When the device is configured in DES Mode, there is a choice for
with which input to drive the single-channel ADC. These are the 3 options:
DES – externally driving the I-channel input only. This is the default selection when the ADC is configured in DES
Mode. It may also be referred to as “DESI” for added clarity.
DESQ – externally driving the Q-channel input only.
DESIQ – externally driving both the I- and Q-channel inputs. VinI+ and VinQ+ should be driven with the exact
same signal. VinI- and VinQ- should be driven with the exact same signal, which is the differential complement to
the one driving VinI+ and VinQ+.
The input impedance for each I- and Q-input is 100 Ω differential (or 50 Ω single-ended), so the trace to each
VinI+, VinI-, VinQ+, and VinQ- should always be 50 Ω single-ended. If a single I- or Q-input is being driven, then
that input will present a 100-Ω differential load. For example, if a 50-Ω single-ended source is driving the ADC,
then a 1:2 balun will transform the impedance to 100 Ω differential. However, if the ADC is being driven in DESIQ
Mode, then the 100-Ω differential impedance from the I-input will appear in parallel with the Q-input for a
composite load of 50 Ω differential and a 1:1 balun would be appropriate. See Figure 66 for an example circuit
driving the ADC in DESIQ Mode. A recommended part selection is using the Mini-Circuits TC1-1-13MA+ balun
with Ccouple = 0.22 µF.
Ccouple
50:
Source
VINI+
100:
1:1 Balun
Ccouple
VINI-
Ccouple
VINQ+
100:
Ccouple
VINQADC1XD1X00
Figure 66. Driving DESIQ Mode
In the case that only one channel is used in Non-DES Mode or that the ADC is driven in DESI or DESQ Mode,
the unused analog input should be terminated to reduce any noise coupling into the ADC. See Table 27 for
details.
Table 27. Unused Analog Input Recommended Termination
MODE
POWER DOWN
COUPLING
RECOMMENDED TERMINATION
Non-DES
Yes
AC-DC
Tie Unused+ and Unused- to Vbg
DES/Non-DES
No
DC
Tie Unused+ and Unused- to Vbg
DES/Non-DES
No
AC
Tie Unused+ to Unused-
8.1.1.3 FSR and the Reference Voltage
The full-scale analog differential input range (VIN_FSR) of the ADC12D1x00 is derived from an internal bandgap
reference. In Non-ECM, this full-scale range has two settings controlled by the FSR Pin; see Full-Scale Input
Range Pin (FSR). The FSR Pin operates on both I- and Q-channels. In ECM, the full-scale range may be
independently set for each channel through Addr:3h and Bh with 15 bits of precision; see Register Maps. The
best SNR is obtained with a higher full-scale input range, but better distortion and SFDR are obtained with a
lower full-scale input range. It is not possible to use an external analog reference voltage to modify the full-scale
range, and this adjustment should only be done digitally, as described.
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A buffered version of the internal bandgap reference voltage is made available at the VBG Pin for the user. The
VBG pin can drive a load of up to 80 pF and source or sink up to 100 μA. It should be buffered if more current
than this is required. This pin remains as a constant reference voltage regardless of what full-scale range is
selected and may be used for a system reference. VBG is a dual-purpose pin and it may also be used to select a
higher LVDS output common-mode voltage; see LVDS Output Common-Mode Pin (VBG).
8.1.1.4 Out-of-Range Indication
Differential input signals are digitized to 12 bits, based on the full-scale range. Signal excursions beyond the fullscale range, that is, greater than +VIN_FSR/2 or less than -VIN_FSR/2, will be clipped at the output. An input signal
which is above the FSR will result in all 1's at the output and an input signal which is below the FSR will result in
all 0's at the output. When the conversion result is clipped for the I-channel input, the Out-of-Range I-channel
(ORI) output is activated such that ORI+ goes high and ORI- goes low while the signal is out of range. This
output is active as long as accurate data on either or both of the buses would be outside the range of 000h to
FFFh. The Q-channel has a separate ORQ which functions similarly.
8.1.1.5 Maximum Input Range
The recommended operating and absolute maximum input range may be found in Recommended Operating
Conditions and Absolute Maximum Ratings, respectively. Under the stated allowed operating conditions, each
Vin+ and Vin- input pin may be operated in the range from 0 V to 2.15 V if the input is a continuous 100% duty
cycle signal and from 0 V to 2.5 V if the input is a 10% duty cycle signal. The absolute maximum input range for
Vin+ and Vin- is from –0.15 V to 2.5 V. These limits apply only for input signals for which the input commonmode voltage is properly maintained.
8.1.1.6 AC-Coupled Input Signals
The ADC12D1x00 analog inputs require a precise common-mode voltage. This voltage is generated on-chip
when AC-coupling Mode is selected. See AC-DC-Coupled Mode Pin (VCMO) for more information about how to
select AC-coupled Mode.
In AC-coupled Mode, the analog inputs must of course be AC-coupled. For an ADC12D1x00 used in a typical
application, this may be accomplished by on-board capacitors, as shown in Figure 67. For the ADC12D1x00RB,
the SMA inputs on the Reference Board are directly connected to the analog inputs on the ADC12D1x00, so this
may be accomplished by DC blocks (included with the hardware kit).
When the AC-coupled Mode is selected, an analog input channel that is not used (for example, in DES Mode)
should be connected to AC ground, for example, through capacitors to ground. Do not connect an unused analog
input directly to ground.
Ccouple
VIN+
Ccouple
VINVCMO
ADC12D1XXX
Figure 67. AC-Coupled Differential Input
The analog inputs for the ADC12D1x00 are internally buffered, which simplifies the task of driving these inputs
and the RC pole which is generally used at sampling ADC inputs is not required. If the user desires to place an
amplifier circuit before the ADC, care should be taken to choose an amplifier with adequate noise and distortion
performance, and adequate gain at the frequencies used for the application.
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8.1.1.7 DC-Coupled Input Signals
In DC-coupled Mode, the ADC12D1x00 differential inputs must have the correct common-mode voltage. This
voltage is provided by the device itself at the VCMO output pin. TI recommends using this voltage because the
VCMO output potential will change with temperature and the common-mode voltage of the driving device should
track this change. Full-scale distortion performance falls off as the input common mode voltage deviates from
VCMO. Therefore, TI recommends keeping the input common-mode voltage within 100 mV of VCMO (typical),
although this range may be extended to ±150 mV (maximum). See VCMI in Electrical Characteristics: Analog
Input/Output and Reference and ENOB vs. VCMI in Typical Characteristics. Performance in AC- and DC-coupled
Mode are similar, provided that the input common mode voltage at both analog inputs remains within 100 mV of
VCMO.
8.1.1.8 Single-Ended Input Signals
The analog inputs of the ADC12D1x00 are not designed to accept single-ended signals. The best way to handle
single-ended signals is to first convert them to differential signals before presenting them to the ADC. The easiest
way to accomplish single-ended to differential signal conversion is with an appropriate balun-transformer, as
shown in Figure 68.
Ccouple
50:
Source
VIN+
100:
1:2 Balun
Ccouple
VINADC12D1XXX
Figure 68. Single-Ended to Differential Conversion Using a Balun
When selecting a balun, it is important to understand the input architecture of the ADC. The impedance of the
analog source should be matched to the on-chip 100-Ω differential input termination resistor of the ADC12D1x00.
The range of this termination resistor is specified as RIN in Electrical Characteristics: Analog Input/Output and
Reference.
8.1.2 The Clock Inputs
The ADC12D1x00 has a differential clock input, CLK+ and CLK-, which must be driven with an AC-coupled,
differential clock signal. This provides the level shifting necessary to allow for the clock to be driven with LVDS,
PECL, LVPECL, or CML levels. The clock inputs are internally terminated to 100Ω differential and self-biased.
This section covers coupling, frequency range, level, duty-cycle, jitter, and layout considerations.
8.1.2.1 CLK Coupling
The clock inputs of the ADC12D1x00 must be capacitively coupled to the clock pins as indicated in Figure 69.
Ccouple
CLK+
Ccouple
CLK-
ADC12D1XXX
Figure 69. Differential Input Clock Connection
The choice of capacitor value will depend on the clock frequency, capacitor component characteristics and other
system economic factors. For example, on the ADC12D1x00RB, the capacitors have the value Ccouple = 4.7 nF
which yields a highpass cutoff frequency, fc = 677.2 kHz.
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8.1.2.2 CLK Frequency
Although the ADC12D1x00 is tested and its performance is ensured with a differential 1.0/1.6 GHz sampling
clock, it will typically function well over the input clock frequency range; see fCLK(min) and fCLK(max) in Electrical
Characteristics: AC. Operation up to fCLK(max) is possible if the maximum ambient temperatures indicated are
not exceeded. Operating at sample rates above fCLK(max) for the maximum ambient temperature may result in
reduced device reliability and product lifetime. This is due to the fact that higher sample rates results in higher
power consumption and die temperatures. If fCLK < 300 MHz, enable LFS in the Control Register (Addr: 0h, Bit
8).
8.1.2.3 CLK Level
The input clock amplitude is specified as VIN_CLK in Electrical Characteristics: Converter and Sampling Clock.
Input clock amplitudes above the max VIN_CLK may result in increased input offset voltage. This would cause the
converter to produce an output code other than the expected 2047/2048 when both input pins are at the same
potential. Insufficient input clock levels will result in poor dynamic performance. Both of these results may be
avoided by keeping the clock input amplitude within the specified limits of VIN_CLK.
8.1.2.4 CLK Duty Cycle
The duty cycle of the input clock signal can affect the performance of any A/D converter. The ADC12D1x00
features a duty cycle clock correction circuit which can maintain performance over the 20%-to-80% specified
clock duty-cycle range. This feature is enabled by default and provides improved ADC clocking, especially in the
Dual-Edge Sampling (DES) Mode.
8.1.2.5 CLK Jitter
High speed, high performance ADCs such as the ADC12D1x00 require a very stable input clock signal with
minimum phase noise or jitter. ADC jitter requirements are defined by the ADC resolution (number of bits),
maximum ADC input frequency and the input signal amplitude relative to the ADC input full scale range. The
maximum jitter (the sum of the jitter from all sources) allowed to prevent a jitter-induced reduction in SNR is
found to be:
tJ(MAX) = ( VIN(P-P)/ VFSR) x (1/(2(N+1) x π x fIN))
where
•
•
•
•
•
tJ(MAX) is the rms total of all jitter sources in seconds
VIN(P-P) is the peak-to-peak analog input signal
VFSR is the full-scale range of the ADC
"N" is the ADC resolution in bits
fIN is the maximum input frequency, in Hertz, at the ADC analog input.
(1)
tJ(MAX) is the square root of the sum of the squares (RSS) of the jitter from all sources, including: the ADC input
clock, system, input signals and the ADC itself. Because the effective jitter added by the ADC is beyond user
control, TI recommends keeping the sum of all other externally added jitter to a minimum.
8.1.2.6 CLK Layout
The ADC12D1x00 clock input is internally terminated with a trimmed 100-Ω resistor. The differential input clock
line pair should have a characteristic impedance of 100 Ω and (when using a balun), be terminated at the clock
source in that (100 Ω) characteristic impedance.
It is a good practice to keep the ADC input clock line as short as possible, tightly coupled, keep it well away from
any other signals, and treat it as a transmission line. Otherwise, other signals can introduce jitter into the input
clock signal. Also, the clock signal can introduce noise into the analog path if it is not properly isolated.
8.1.3 The LVDS Outputs
The Data, ORI, ORQ, DCLKI and DCLKQ outputs are LVDS. The electrical specifications of the LVDS outputs
are compatible with typical LVDS receivers available on ASIC and FPGA chips; but they are not IEEE or ANSI
communications standards compliant due to the low 1.9-V supply used on this chip. These outputs should be
terminated with a 100-Ω differential resistor placed as closely to the receiver as possible. If the 100-Ω differential
resistance is built in to the receiver, then an externally placed resistor is not necessary. This section covers
common-mode and differential voltage, and data rate.
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8.1.3.1 Common-Mode and Differential Voltage
The LVDS outputs have selectable common-mode and differential voltage, VOS and VOD; see Electrical
Characteristics: Digital Control and Output Pin. See Output Control and Adjust for more information.
Selecting the higher VOS will also increase VOD slightly. The differential voltage, VOD, may be selected for the
higher or lower value. For short LVDS lines and low noise systems, satisfactory performance may be realized
with the lower VOD. This will also result in lower power consumption. If the LVDS lines are long and/or the system
in which the ADC12D1x00 is used is noisy, it may be necessary to select the higher VOD.
8.1.3.2 Output Data Rate
The data is produced at the output at the same rate it is sampled at the input. The minimum recommended input
clock rate for this device is fCLK(MIN); see Electrical Characteristics: AC. However, it is possible to operate the
device in 1:2 Demux Mode and capture data from just one 12-bit bus, for example, just DI (or DId) although both
DI and DId are fully operational. This will decimate the data by two and effectively halve the data rate.
8.1.3.3 Terminating Unused LVDS Output Pins
If the ADC is used in Non-Demux Mode, then only the DI and DQ data outputs will have valid data present on
them. The DId and DQd data outputs may be left not connected; if unused, they are internally at TRI-STATE.
Similarly, if the Q-channel is powered-down (that is, PDQ is logic-high), the DQ data output pins, DCLKQ and
ORQ may be left not connected.
8.1.4 Synchronizing Multiple ADC12D1x00s in a System
The ADC12D1x00 has two features to assist the user with synchronizing multiple ADCs in a system; AutoSync
and DCLK Reset. The AutoSync feature is new and designates one ADC12D1x00 as the Master ADC and other
ADC12D1x00s in the system as Slave ADCs. The DCLK Reset feature performs the same function as the
AutoSync feature, but is the first generation solution to synchronizing multiple ADCs in a system; it is disabled by
default. For the application in which there are multiple Master and Slave ADC12D1x00s in a system, AutoSync
may be used to synchronize the Slave ADC12D1x00(s) to each respective Master ADC12D1x00 and the DCLK
Reset may be used to synchronize the Master ADC12D1x00s to each other.
If the AutoSync or DCLK Reset feature is not used, see Table 28 for recommendations about terminating unused
pins.
Table 28. Unused Autosync and DCLK Reset Pin Recommendation
PINS
UNUSED TERMINATION
RCLK+/-
Do not connect.
RCOUT1+/-
Do not connect.
RCOUT2+/-
Do not connect.
DCLK_RST+
Connect to GND through 1-kΩ resistor.
DCLK_RST-
Connect to VA through 1-kΩ resistor.
8.1.4.1 Autosync Feature
AutoSync is a new feature which continuously synchronizes the outputs of multiple ADC12D1x00s in a system. It
may be used to synchronize the DCLK and data outputs of one or more Slave ADC12D1x00s to one Master
ADC12D1x00. Several advantages of this feature include: no special synchronization pulse required, any upset
in synchronization is recovered upon the next DCLK cycle, and the Master/Slave ADC12D1x00s may be
arranged as a binary tree so that any upset will quickly propagate out of the system.
An example system is shown below in Figure 70 which consists of one Master ADC and two Slave ADCs. For
simplicity, only one DCLK is shown; in reality, there is DCLKI and DCLKQ, but they are always in phase with one
another.
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Master
ADC12D1XXX
RCOut1
RCOut2
CLK
DCLK
Slave 2
ADC12D1XXX
RCLK
RCOut1
RCOut2
CLK
RCLK
Slave 1
ADC12D1XXX
DCLK
RCOut1
CLK
RCLK
RCOut2
DCLK
CLK
Figure 70. AutoSync Example
To synchronize the DCLK (and Data) outputs of multiple ADCs, the DCLKs must transition at the same time, as
well as be in phase with one another. The DCLK at each ADC is generated from the CLK after some latency,
plus tOD minus tAD. Therefore, in order for the DCLKs to transition at the same time, the CLK signal must reach
each ADC at the same time. To tune out any differences in the CLK path to each ADC, the tAD adjust feature
may be used. However, using the tAD adjust feature will also affect when the DCLK is produced at the output. If
the device is in Demux Mode, then there are four possible phases which each DCLK may be generated on
because the typical CLK = 1 GHz and DCLK = 250 MHz for this case. The RCLK signal controls the phase of the
DCLK, so that each Slave DCLK is on the same phase as the Master DCLK.
The AutoSync feature may only be used through the Control Registers. For more information, see AN-2132
Synchronizing Multiple GSPS ADCs in a System: The AutoSync Feature (SNAA073).
8.1.4.2 DCLK Reset Feature
The DCLK reset feature is available through ECM, but it is disabled by default. DCLKI and DCLKQ are always
synchronized, by design, and do not require a pulse from DCLK_RST to become synchronized.
The DCLK_RST signal must observe certain timing requirements, which are shown in Figure 5 of the Timing
Diagrams. The DCLK_RST pulse must be of a minimum width and its deassertion edge must observe setup and
hold times with respect to the CLK input rising edge. These timing specifications are listed as tPWR, tSR and tHR
and may be found in Electrical Characteristics: AC.
The DCLK_RST signal can be asserted asynchronously to the input clock. If DCLK_RST is asserted, the DCLK
output is held in a designated state (logic-high) in Demux Mode; in Non-Demux Mode, the DCLK continues to
function normally. Depending upon when the DCLK_RST signal is asserted, there may be a narrow pulse on the
DCLK line during this reset event. When the DCLK_RST signal is deasserted, there are tSYNC_DLY CLK cycles of
systematic delay and the next CLK rising edge synchronizes the DCLK output with those of other ADC12D1x00s
in the system. For 90° Mode (DDRPh = logic-high), the synchronizing edge occurs on the rising edge of CLK, 4
cycles after the first rising edge of CLK after DCLK_RST is released. For 0° Mode (DDRPh = logic-low), this is 5
cycles instead. The DCLK output is enabled again after a constant delay of tOD.
For both Demux and Non-Demux Modes, there is some uncertainty about how DCLK comes out of the reset
state for the first DCLK_RST pulse. For the second (and subsequent) DCLK_RST pulses, the DCLK will come
out of the reset state in a known way. Therefore, if using the DCLK Reset feature, TI recommends applying one
"dummy" DCLK_RST pulse before using the second DCLK_RST pulse to synchronize the outputs. This
recommendation applies each time the device or channel is powered-on.
When using DCLK_RST to synchronize multiple ADC12D1x00s, it is required that the Select Phase bits in the
Control Register (Addr: Eh, Bits 3,4) be the same for each Master ADC12D1x00.
8.1.5 Recommended System Chips
TI recommends these other chips including temperature sensors, clocking devices, and amplifiers to support the
ADC12D1x00 in a system design.
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8.1.5.1 Temperature Sensor
The ADC12D1x00 has an on-die temperature diode connected to pins Tdiode+/- which may be used to monitor
the die temperature. TI also provides a family of temperature sensors for this application which monitor different
numbers of external devices, see Table 29.
Table 29. Temperature Sensor Recommendation
NUMBER OF EXTERNAL DEVICES MONITORED
RECOMMENDED TEMPERATURE SENSOR
1
LM95235
2
LM95213
4
LM95214
The temperature sensor (LM95235/13/14) is an 11-bit digital temperature sensor with a 2-wire System
Management Bus (SMBus) interface that can monitor the temperature of one, two, or four remote diodes as well
as its own temperature. It can be used to accurately monitor the temperature of up to one, two, or four external
devices such as the ADC12D1x00, a FPGA, other system components, and the ambient temperature.
The temperature sensor reports temperature in two different formats for +127.875°C/-128°C range and 0°/255°C
range. It has a Sigma-Delta ADC core which provides the first level of noise immunity. For improved performance
in a noisy environment, the temperature sensor includes programmable digital filters for Remote Diode
temperature readings. When the digital filters are invoked, the resolution for the Remote Diode readings
increases to 0.03125°C. For maximum flexibility and best accuracy, the temperature sensor includes offset
registers that allow calibration for other types of diodes.
Diode fault detection circuitry in the temperature sensor can detect the absence or fault state of a remote diode:
whether D+ is shorted to the power supply, D- or ground, or floating.
In the following typical application, the LM95213 is used to monitor the temperature of an ADC12D1x00 as well
as an FPGA, see Figure 71. If this feature is unused, the Tdiode+/- pins may be left floating.
7
ADC12D1XXX
IE = IF
D1+
100 pF
IR
5
FPGA
IE = IF
D-
100 pF
6
D2+
IR
LM95213
Figure 71. Typical Temperature Sensor Application
8.1.5.2 Clocking Device
The clock source can be a PLL or VCO device such as the LMX2531LQxxxx family of products. The specific
device should be selected according to the desired ADC sampling clock frequency. The ADC12D1x00RB uses
the LMX2531LQ1910E/1570E, with the ADC clock source provided by the Aux PLL output. Other devices which
may be considered based on clock source, jitter cleaning, and distribution purposes are the LMK01XXX,
LMK02XXX, LMK03XXX and LMK04XXX product families.
8.1.5.3 Amplifiers for the Analog Input
The following amplifiers can be used for ADC12D1x00 applications which require DC coupled input or signal
gain, neither of which can be provided with a transformer coupled input circuit. In addition, several of the
amplifiers provide single-ended to differential conversion options:
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Table 30. Amplifier Recommendations
AMPLIFIER
BANDWIDTH
BRIEF FEATURES
LMH3401
7 GHz
Fixed gain, single-ended to differential conversion
LMH5401
8 GHz
Configurable gain, single-ended to differential conversion
LMH6401
4.5 GHz
Digital variable controlled gain
LMH6554
2.8 GHz
Configurable gain
LMH6555
1.2 GHz
Fixed gain
8.1.5.4 Balun Recommendations for Analog Input
The following baluns are recommended for the ADC12D1x00 for applications which require no gain. When
evaluating a balun for the application of driving an ADC, some important qualities to consider are phase error
and magnitude error.
Table 31. Balun Recommendations
BALUN
BANDWIDTH
Mini Circuits TC1-1-13MA+
4.5 - 3000MHz
Anaren B0430J50100A00
400 - 3000 MHz
Mini Circuits ADTL2-18
30 - 1800 MHz
8.2 Typical Application
The ADC12D1600 can be used to directly sample a signal in the radio frequency range for downstream
processing. The wide input bandwidth, buffered input, and high sampling rate make ADC12D1600 ideal for RF
sampling applications.
Power
Management
Memory
1:2 Balun
BPF
LVDS outputs
GSPS ADC
I-Channel
1:2 Balun
.
.
.
FPGA
USB
Port
BPF
GSPS ADC
Q-Channel
10-MHz
Reference
Clocking
Solution
Figure 72. Simplified Schematic
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Typical Application (continued)
8.2.1 Design Requirements
In this example, ADC12D1600 will be used to sample signals in DES mode and Non-DES mode. The design
parameters are listed in Table 32.
Table 32. Design Parameters
DESIGN PARAMETERS
EXAMPLE VALUES (Non-DES mode)
EXAMPLE VALUES (DES mode)
Signal center frequency
1800 MHz
1000 MHz
Signal bandwidth
100 MHz
75 MHz
ADC sampling Rate
1600 MSPS
3200 MSPS
Signal nominal amplitude
–7 dBm
–7 dBm
Signal maximum amplitude
6 dBm
6 dBm
Minimum SNR (in BW of interest)
48 dBc
48 dBc
Minimum THD (in BW of interest)
–57 dBc
–55 dBc
Minimum SFDR (in BW of interest)
53 dBc
50 dBc
8.2.2 Detailed Design Procedure
Use the step described below to design the RF receiver:
• Select the appropriate mode of operation (DES mode or Non-DES mode).
• Use the input signal frequency to select an appropriate sampling rate.
• Select the sampling rate so that the input signal is within the Nyquist zone and away from any harmonics and
interleaving tones.
• Select the system components such as clocking device, amplifier for analog input and Balun according to
sampling frequency and input signal frequency.
• See Clocking Device for the recommended clock sources.
• See Amplifiers for the Analog Input for recommended analog amplifiers.
• See Balun Recommendations for Analog Input for recommended Balun components.
• Select the bandpass filters and limiter components based on the requirement to attenuate the unwanted input
signals.
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8.2.3 Application Curves
0
0
±10
±10
±20
±20
±30
±30
Magnitude (dBFS)
Magnitude (dBFS)
Figure 73 and Figure 74 show an RF signal at 1797.97 MHz captured at a sample rate of 1600 MSPS in NonDES mode and an RF signal at 997.97 MHz sample at an effective sample rate of 3200 MSPS in DES mode.
±40
±50
±60
±70
±80
±40
±50
±60
±70
±80
±90
±90
±100
±100
±110
±110
0
100
200
300
400
500
600
700
Frequendy (MHz)
800
0
200
400
Non-DES Mode
Fin 1797.97 MHz at –7 dBFS
Fs = 1600 MHz
Figure 73. Spectrum - Non-DES MODE
600
800
1000
1200
1400
Frequency (MHz)
C002
DES Mode
Fin 997.97 MHz at –7 dBFS
1600
C001
Fs = 3200 MHz
Figure 74. Spectrum - DES Mode
Table 33. ADC12D1600 Performance for Single Tone
Signal at 1797.97 MHz in NON-DES Mode
PARAMETER
VALUE
SNR
49.7 dBc
SFDR
58.3 dBc
THD
–64.4 dBc
SINAD
49.6 dBc
ENOB
7.9 bits
Table 34. ADC12D1600 Performance for Single Tone
Signal at 997.97 MHz in DES Mode
PARAMETER
VALUE
SNR
49.3 dBc
SFDR
53.6 dBc
THD
–63.8 dBc
SINAD
49.2 dBc
ENOB
7.8 bits
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9 Power Supply Recommendations
Data-converter-based systems draw sufficient transient current to corrupt their own power supplies if not
adequately bypassed. A 10-μF capacitor must be placed within one inch (2.5 cm) of the device power pins for
each supply voltage. A 0.1-μF capacitor must be placed as close as possible to each supply pin, preferably
within 0.5 cm. Leadless chip capacitors are preferred due to their low-lead inductance.
As is the case with all high-speed converters, the ADC12D1600 device must be assumed to have little power
supply noise-rejection. Any power supply used for digital circuitry in a system where a large amount of digital
power is consumed must not be used to supply power to the ADC12D1600 device. If not a dedicated supply, the
ADC supplies must be the same supply used for other analog circuitry.
9.1 System Power-On Considerations
There are a couple important topics to consider associated with the system power-on event including
configuration and calibration, and the Data Clock.
9.1.1 Power-On, Configuration, and Calibration
Following the application of power to the ADC12D1x00, several events must take place before the output from
the ADC12D1x00 is valid and at full performance; at least one full calibration must be executed with the device
configured in the desired mode.
Following the application of power to the ADC12D1x00, there is a delay of tCalDly and then the Power-on
Calibration is executed. This is why TI recommends setting the CalDly Pin through an external pullup or pulldown
resistor. This ensures that the state of that input will be properly set at the same time that power is applied to the
ADC and tCalDly will be a known quantity. For the purpose of this section, it is assumed that CalDly is set as
recommended.
The Control Bits or Pins must be set or written to configure the ADC12D1x00 in the desired mode. This must
take place through either Extended Control Mode or Non-ECM (Pin Control Mode) before subsequent
calibrations will yield an output at full performance in that mode. Some examples of modes include DES/NonDES Mode, Demux/Non-demux Mode, and Full-Scale Range.
The simplest case is when device is in Non-ECM and the Control Pins are set by pullup and pulldown resistors,
see Figure 75. For this case, the settings to the Control Pins ramp concurrently to the ADC voltage. Following the
delay of tCalDly and the calibration execution time, tCAL, the output of the ADC12D1x00 is valid and at full
performance. If it takes longer than tCalDly for the system to stabilize at its operating temperature, TI recommends
executing an on-command calibration at that time.
Another case is when the FPGA configures the Control Pins (Non-ECM) or writes to the SPI (ECM), see
Figure 76. It is always necessary to comply with the Operating Ratings and Absolute Maximum ratings, that is,
the Control Pins may not be driven below the ground or above the supply, regardless of what the voltage
currently applied to the supply is. Therefore, it is not recommended to write to the Control Pins or SPI before
power is applied to the ADC12D1x00. As long as the FPGA has completed writing to the Control Pins or SPI, the
Power-on Calibration will result in a valid output at full performance. Once again, if it takes longer than tCalDly for
the system to stabilize at its operating temperature, TI recommends executing an on-command calibration at that
time.
Due to system requirements, it may not be possible for the FPGA to write to the Control Pins or SPI before the
Power-on Calibration takes place, see Figure 77. It is not critical to configure the device before the Power-on
Calibration, but it is critical to realize that the output for such a case is not at its full performance. Following an
On-command Calibration, the device will be at its full performance.
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System Power-On Considerations (continued)
Pull-up/down
resistors set
Control Pins
Power to
ADC
CalDly
ADC output
valid
Calibration
Power-on
Calibration
On-command
Calibration
Figure 75. Power-On With Control Pins Set by Pullup and Pulldown Resistors
FPGA writes
Control Pins
Power to
ADC
ADC output
valid
CalDly
Calibration
Power-on
Calibration
On-command
Calibration
Figure 76. Power-On With Control Pins Set by FPGA Pre Power-on Cal
FPGA writes
Control Pins
Power to
ADC
CalDly
Calibration
Power-on
Calibration
On-command
Calibration
Figure 77. Power-On With Control Pins Set by FPGA Post Power-on Cal
9.1.2 Power-On and Data Clock (Dclk)
Many applications use the DCLK output for a system clock. For the ADC12D1x00, each I- and Q-channel has its
own DCLKI and DCLKQ, respectively. The DCLK output is always active, unless that channel is powered-down
or the DCLK Reset feature is used while the device is in Demux Mode. As the supply to the ADC12D1x00
ramps, the DCLK also comes up, see this example from the ADC12D1x00RB: Figure 78. While the supply is too
low, there is no output at DCLK. As the supply continues to ramp, DCLK functions intermittently with irregular
frequency, but the amplitude continues to track with the supply. Much below the low end of operating supply
range of the ADC12D1x00, the DCLK is already fully operational.
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mV
System Power-On Considerations (continued)
Slope = 1.22V/ms
1900
1710
VA
1490
1210
660
635
520
DCLK
300
time
Figure 78. Supply and DCLK Ramping
9.2 Supply Voltage
The ADC12D1600 device is specified to operate with nominal supply voltages of 1.9 V (VA, VTC, VE and VDR).
For detailed information regarding the operating voltage minimums and maximums see Recommended Operating
Conditions.
The voltage on a pin (except VinI± and VinQ±), including a transient basis, must not have a voltage that is in
excess of the supply voltage or below ground by more than 150 mV. A pin voltage that is higher than the supply
or that is below ground can be a problem during start-up and shutdown of power. Ensure that the supplies to
circuits driving any of the input pins, analog or digital, do not rise faster than the voltage at the ADC12D1600
power pins.
The values in Absolute Maximum Ratings must be strictly observed including during power up and power down.
A power supply that produces a voltage spike at power turnon, turnoff, or both can destroy the ADC12D1600
device. Many linear regulators produce output spiking at power on unless there is a minimum load provided.
Active devices draw very little current until the supply voltages reach a few hundred millivolts. The result can be a
turnon spike that destroys the ADC12D1600 device, unless a minimum load is provided for the supply. A 100-Ω
resistor at the regulator output provides a minimum output current during power up to ensure that no turnon
spiking occurs. Whether a linear or switching regulator is used, TI recommends using a soft-start circuit to
prevent overshoot of the supply.
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10 Layout
10.1 Layout Guidelines
10.1.1 Power Planes
All supply buses for the ADC should be sourced from a common linear voltage regulator. This ensures that all
power buses to the ADC are turned on and off simultaneously. This single source will be split into individual
sections of the power plane, with individual decoupling and connection to the different power supply buses of the
ADC. Due to the low voltage but relatively high supply current requirement, the optimal solution may be to use a
switching regulator to provide an intermediate low voltage, which is then regulated down to the final ADC supply
voltage by a linear regulator. See the documentation provided for the ADC12D1x00RB for additional details on
specific regulators that are recommended for this configuration.
Power for the ADC should be provided through a broad plane which is located on one layer adjacent to the
ground planes. Placing the power and ground planes on adjacent layers will provide low impedance decoupling
of the ADC supplies, especially at higher frequencies. The output of a linear regulator should feed into the power
plane through a low impedance multi-via connection. The power plane should be split into individual power
peninsulas near the ADC. Each peninsula should feed a particular power bus on the ADC, with decoupling for
that power bus connecting the peninsula to the ground plane near each power/ground pin pair. Using this
technique can be difficult on many printed circuit CAD tools. To work around this, 0-Ω resistors can be used to
connect the power source net to the individual nets for the different ADC power buses. As a final step, the 0-Ω
resistors can be removed and the plane and peninsulas can be connected manually after all other error checking
is completed.
10.1.2 Bypass Capacitors
The general recommendation is to have one 100-nF capacitor for each power/ground pin pair. The capacitors
should be surface mount multi-layer ceramic chip capacitors similar to Panasonic part number ECJ-0EB1A104K.
10.1.3 Ground Planes
Grounding should be done using continuous full ground planes to minimize the impedance for all ground return
paths, and provide the shortest possible image/return path for all signal traces.
10.1.4 Power System Example
The ADC12D1x00RB uses continuous ground planes (except where clear areas are needed to provide
appropriate impedance management for specific signals), see Figure 79. Power is provided on one plane, with
the 1.9-V ADC supply being split into multiple zones or peninsulas for the specific power buses of the ADC.
Decoupling capacitors are connected between these power bus peninsulas and the adjacent ground planes
using vias. The capacitors are located as close to the individual power/ground pin pairs of the ADC as possible.
In most cases, this means the capacitors are located on the opposite side of the PCB to the ADC.
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Layout Guidelines (continued)
Linear
Regulator
Cross Section
Line
Switching
Regulator
HV or Unreg
Voltage
Intermediate
Voltage
1.9V ADC Main
VTC VA
VE
VDR
ADC
Top Layer ± Signal 1
Dielectric 1
Ground 1
Dielectric 2
Signal 2
Dielectric 3
Ground 2
Dielectric 4
Signal 3
Dielectric 5
Power 1
Dielectric 6
Ground 3
Dielectric 7
Bottom Layer ± Signal X
Figure 79. Power and Grounding Example
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10.2 Layout Example
Figure 80 and Figure 81 show layout example plots. Figure 82 shows a typical stackup for a 10-layer board.
Balun transformer to convert the
SE CLK signal to differential signal
CLK path with minimal
adjacent circuit
To provide best grounding and thermal
performance all the ground pins on
internal pad should be connected to all the
ground layers with vias.
Analog input path with
minimal adjacent circuit
High speed data paths and DCLK
signals should be of same length
Figure 80. ADC12D1800RF Layout Example 1 – Top Side and Inner Layers
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Layout Example (continued)
All high speed signal routing should use impedance
controlled traces, either 50-Ω single ended or 100-Ω
differential
Decoupling
capacitors near
the device
Decoupling
Capacitors near
VIN
The four holes highlighted with black squares were for the
socket version of the board and are not required for end
application.
Figure 81. ADC12D1800RF Layout Example 1 – Bottom Side and Inner Layers
L1 – SIG
0.0036''
L2 – GND
0.0060''
L3 – SIG
0.0070''
L4 – PWR
0.0030''
L5 –GND
0.0070''
0.0580''
L6 – SIG
0.0060''
L7 – PWR
0.0070''
L8 – SIG
0.0060''
L9 – GND
0.0036''
L10 – SIG
1/2 oz. Copper on L1, L3, L6, L8, L10
1 oz. Copper on L2, L4, L5, L7, L9
100 W, Differential Signaling and 50 W Single ended on SIG Layers
Low loss dielectric adjacent very high speed trace layers
Finished thickness 0.0620" including plating and solder mask
Figure 82. ADC12D1800RF Typical Stackup – 10 Layer Board
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10.3 Thermal Management
The Heat Slug Ball Grid Array (HSBGA) package is a modified version of the industry standard plastic BGA (Ball
Grid Array) package. Inside the package, a copper heat spreader cap is attached to the substrate top with
exposed metal in the center top area of the package. This results in a 20% improvement (typical) in thermal
performance over the standard plastic BGA package.
4JC_1
Copper Heat Slug
Mold Compound
Not to Scale
Cross Section Line
IC Die
Substrate
4JC_2
Figure 83. HSBGA Conceptual Drawing
The center balls are connected to the bottom of the die by vias in the package substrate, Figure 83. This gives a
low thermal resistance between the die and these balls. Connecting these balls to the PCB ground planes with a
low thermal resistance path is the best way dissipate the heat from the ADC. These pins should also be
connected to the ground plane via a low impedance path for electrical purposes. The direct connection to the
ground planes is an easy method to spread heat away from the ADC. Along with the ground plane, the parallel
power planes will provide additional thermal dissipation.
The center ground balls should be soldered down to the recommended ball pads (see AN-1126 [SNOA021]).
These balls will have wide traces which in turn have vias which connect to the internal ground planes, and a
bottom ground pad/pour if possible. This ensures a good ground is provided for these balls, and that the optimal
heat transfer will occur between these balls and the PCB ground planes.
In spite of these package enhancements, analysis using the standard JEDEC JESD51-7 four-layer PCB thermal
model shows that ambient temperatures must be limited to 70/77°C to ensure a safe operating junction
temperature for the ADC12D1x00. However, most applications using the ADC12D1x00 will have a printed-circuitboard (PCB) which is more complex than that used in JESD51-7. Typical circuit boards will have more layers
than the JESD51-7 (eight or more), several of which will be used for ground and power planes. In those
applications, the thermal resistance parameters of the ADC12D1x00 and the circuit board can be used to
determine the actual safe ambient operating temperature up to a maximum of 85°C.
Three key parameters are provided to allow for modeling and calculations. Because there are two main thermal
paths between the ADC die and external environment, the thermal resistance for each of these paths is provided.
θJC1 represents the thermal resistance between the die and the exposed metal area on the top of the HSBGA
package. θJC2 represents the thermal resistance between the die and the center group of balls on the bottom of
the HSBGA package. The final parameter is the allowed maximum junction temperature, TJ.
In other applications, a heat sink or other thermally conductive path can be added to the top of the HSBGA
package to remove heat. In those cases, θJC1 can be used along with the thermal parameters for the heat sink or
other thermal coupling added. Representative heat sinks which might be used with the ADC12D1x00 include the
Cool Innovations p/n 3-1212XXG and similar products from other vendors. In many applications, the PCB will
provide the primary thermal path conducting heat away from the ADC package. In those cases, θJC2 can be used
in conjunction with PCB thermal modeling software to determine the allowed operating conditions that will
maintain the die temperature below the maximum allowable limit. Additional dissipation can be achieved by
coupling a heat sink to the copper pour area on the bottom side of the PCB.
Typically, dissipation will occur through one predominant thermal path. In these cases, the following calculations
can be used to determine the maximum safe ambient operating temperature for the ADC12D1600, for example:
TJ = TA + PD × (θJC+θCA)
TJ = TA + PC(MAX) × (θJC+θCA)
(2)
(3)
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Thermal Management (continued)
For θJC, the value for the primary thermal path in the given application environment should be used (θJC1 or θJC2).
θCA is the thermal resistance from the case to ambient, which would typically be that of the heat sink used. Using
this relationship and the desired ambient temperature, the required heat sink thermal resistance can be found.
Alternately, the heat sink thermal resistance can be used to find the maximum ambient temperature. For more
complex systems, thermal modeling software can be used to evaluate the PCB system and determine the
expected junction temperature given the total system dissipation and ambient temperature.
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11 Device and Documentation Support
11.1 Device Support
11.1.1 Device Nomenclature
11.1.1.1 Specification Definitions
APERTURE (SAMPLING) DELAY is the amount of delay, measured from the sampling edge of the CLK input,
after which the signal present at the input pin is sampled inside the device.
APERTURE JITTER (tAJ) is the variation in aperture delay from sample-to-sample. Aperture jitter can be
effectively considered as noise at the input.
CODE ERROR RATE (CER) is the probability of error and is defined as the probable number of word errors on
the ADC output per unit of time divided by the number of words seen in that amount of time. A CER
of 10-18 corresponds to a statistical error in one word about every 31.7 years for the ADC12D1000.
CLOCK DUTY CYCLE is the ratio of the time that the clock waveform is at a logic high to the total time of one
clock period.
DIFFERENTIAL NON-LINEARITY (DNL) is the measure of the maximum deviation from the ideal step size of 1
LSB. It is measured at the relevant sample rate, fCLK, with fIN = 1MHz sine wave.
EFFECTIVE NUMBER OF BITS (ENOB, or EFFECTIVE BITS) is another method of specifying Signal-to-Noise
and Distortion Ratio, or SINAD. ENOB is defined as (SINAD − 1.76) / 6.02 and states that the
converter is equivalent to a perfect ADC of this many (ENOB) number of bits.
FULL POWER BANDWIDTH (FPBW) is a measure of the frequency at which the reconstructed output
fundamental drops to 3 dB below its low frequency value for a full-scale input.
GAIN ERROR is the deviation from the ideal slope of the transfer function. It can be calculated from Offset and
Full-Scale Errors. The Positive Gain Error is the Offset Error minus the Positive Full-Scale Error.
The Negative Gain Error is the Negative Full-Scale Error minus the Offset Error. The Gain Error is
the Negative Full-Scale Error minus the Positive Full-Scale Error; it is also equal to the Positive
Gain Error plus the Negative Gain Error.
INTEGRAL NON-LINEARITY (INL) is a measure of worst case deviation of the ADC transfer function from an
ideal straight line drawn through the ADC transfer function. The deviation of any given code from
this straight line is measured from the center of that code value step. The best fit method is used.
INTERMODULATION DISTORTION (IMD) is a measure of the near-in 3rd order distortion products (2f2 - f1, 2f1
- f2) which occur when two tones which are close in frequency (f1, f2) are applied to the ADC input.
It is measured from the input tones level to the higher of the two distortion products (dBc) or simply
the level of the higher of the two distortion products (dBFS). The input tones are typically -7dBFS.
LSB (LEAST SIGNIFICANT BIT) is the bit that has the smallest value or weight of all bits. This value is
VFS / 2N
where
•
VFS is the differential full-scale amplitude VIN_FSR as set by the FSR input and "N" is the ADC resolution
in bits, which is 10 for the ADC12D1x00.
(4)
LOW VOLTAGE DIFFERENTIAL SIGNALING (LVDS) DIFFERENTIAL OUTPUT VOLTAGE (V ID and VOD) is
two times the absolute value of the difference between the VD+ and VD- signals; each signal
measured with respect to Ground. VOD peak is VOD,P= (VD+ - VD-) and VOD peak-to-peak is VOD,P-P=
2*(VD+ - VD-); for this product, the VOD is measured peak-to-peak.
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Device Support (continued)
VD+
VDVOS
½×VOD
VD+
VD -
GND
½×VOD = | VD+ - VD- |
Figure 84. LVDS Output Signal Levels
LVDS OUTPUT OFFSET VOLTAGE (VOS) is the midpoint between the D+ and D- pins output voltage with
respect to ground; that is, [(VD+) +( VD-)]/2. See Figure 84.
MISSING CODES are those output codes that are skipped and will never appear at the ADC outputs. These
codes cannot be reached with any input value.
MSB (MOST SIGNIFICANT BIT) is the bit that has the largest value or weight. Its value is one half of full scale.
NEGATIVE FULL-SCALE ERROR (NFSE) is a measure of how far the first code transition is from the ideal 1/2
LSB above a differential −VIN/2 with the FSR pin low. For the ADC12D1x00 the reference voltage is
assumed to be ideal, so this error is a combination of full-scale error and reference voltage error.
NOISE FLOOR DENSITY is a measure of the power density of the noise floor, expressed in dBFS/Hz and
dBm/Hz. '0 dBFS' is defined as the power of a sinusoid which precisely uses the full-scale range of
the ADC.
NOISE POWER RATIO (NPR) is the ratio of the sum of the power outside the notched bins to the sum of the
power in an equal number of bins inside the notch, expressed in dB.
OFFSET ERROR (VOFF) is a measure of how far the mid-scale point is from the ideal zero voltage differential
input. Offset Error = Actual Input causing average of 8-k samples to result in an average code of
2047.5.
OUTPUT DELAY (tOD) is the time delay (in addition to Latency) after the rising edge of CLK+ before the data
update is present at the output pins.
OVER-RANGE RECOVERY TIME is the time required after the differential input voltages goes from ±1.2 V to 0
V for the converter to recover and make a conversion with its rated accuracy.
PIPELINE DELAY (LATENCY) is the number of input clock cycles between initiation of conversion and when
that data is presented to the output driver stage. The data lags the conversion by the Latency plus
the tOD.
POSITIVE FULL-SCALE ERROR (PFSE) is a measure of how far the last code transition is from the ideal 1-1/2
LSB below a differential +VIN/2. For the ADC12D1x00 the reference voltage is assumed to be ideal,
so this error is a combination of full-scale error and reference voltage error.
SIGNAL TO NOISE RATIO (SNR) is the ratio, expressed in dB, of the rms value of the fundamental for a singletone to the rms value of the sum of all other spectral components below one-half the sampling
frequency, not including harmonics or DC.
SIGNAL TO NOISE PLUS DISTORTION (S/(N+D) or SINAD) is the ratio, expressed in dB, of the rms value of
the fundamental for a single-tone to the rms value of all of the other spectral components below half
the input clock frequency, including harmonics but excluding DC.
SPURIOUS-FREE DYNAMIC RANGE (SFDR) is the difference, expressed in dB, between the rms values of
the input signal at the output and the peak spurious signal, where a spurious signal is any signal
present in the output spectrum that is not present at the input, excluding DC.
θJA
is the thermal resistance between the junction to ambient.
θJC1
represents the thermal resistance between the die and the exposed metal area on the top of the
HSBGA package.
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Device Support (continued)
θJC2
represents the thermal resistance between the die and the center group of balls on the bottom of
the HSBGA package.
TOTAL HARMONIC DISTORTION (THD) is the ratio expressed in dB, of the rms total of the first nine harmonic
levels at the output to the level of the fundamental at the output. THD is calculated as
THD = 20 x log
A 2 +... +A 2
f2
f10
A f12
where
•
Af1 is the RMS power of the fundamental (output) frequency and Af2 through Af10 are the RMS power of
the first 9 harmonic frequencies in the output spectrum.
(5)
Second Harmonic Distortion (2nd Harm) is the difference, expressed in dB, between the RMS power in the
input frequency seen at the output and the power in its 2nd harmonic level at the output.
Third Harmonic Distortion (3rd Harm) is the difference expressed in dB between the RMS power in the input
frequency seen at the output and the power in its 3rd harmonic level at the output.
11.2 Documentation Support
11.2.1 Related Documentation
For related documentation, see the following:
• AN-1126 BGA (Ball Grid Array), SNOA021
• AN-2132 Synchronizing Multiple GSPS ADCs in a System: The AutoSync Feature, SNAA073
11.3 Related Links
The table below lists quick access links. Categories include technical documents, support and community
resources, tools and software, and quick access to sample or buy.
Table 35. Related Links
PARTS
PRODUCT FOLDER
SAMPLE & BUY
TECHNICAL
DOCUMENTS
TOOLS &
SOFTWARE
SUPPORT &
COMMUNITY
ADC12D1000
Click here
Click here
Click here
Click here
Click here
ADC12D1600
Click here
Click here
Click here
Click here
Click here
11.4 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
11.5 Trademarks
E2E is a trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
11.6 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
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11.7 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
12 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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PACKAGE OPTION ADDENDUM
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30-Sep-2021
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
(3)
Device Marking
(4/5)
(6)
ADC12D1000CIUT
ACTIVE
BGA
NXA
292
40
Non-RoHS
& Green
Call TI
Level-3-220C-168 HR
-40 to 85
ADC12D1000CIUT
ADC12D1000CIUT/NOPB
ACTIVE
BGA
NXA
292
40
RoHS & Green
SNAG
Level-3-250C-168 HR
-40 to 85
ADC12D1000CIUT
ADC12D1600CIUT
ACTIVE
BGA
NXA
292
40
Non-RoHS
& Green
Call TI
Level-3-220C-168 HR
-40 to 85
ADC12D1600CIUT
ADC12D1600CIUT/NOPB
ACTIVE
BGA
NXA
292
40
RoHS & Green
SNAG
Level-3-250C-168 HR
-40 to 85
ADC12D1600CIUT
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of