DS42BR400
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SNLS221J – MARCH 2006 – REVISED APRIL 2013
DS42BR400 Quad 4.25 Gbps CML Transceiver with Transmit
De-Emphasis and Receive Equalization
Check for Samples: DS42BR400
FEATURES
DESCRIPTION
•
The DS42BR400 is a quad 250 Mbps – 4.25 Gbps
CML transceiver, or 8-channel buffer, for use in
backplane and cable applications. With operation
down to 250 Mbps, the DS42BR400 can be used in
applications requiring both low and high frequency
data rates. Each input stage has a fixed equalizer to
reduce ISI distortion from board traces. The
equalizers are grouped in fours and are enabled
through two control pins. These control pins provide
customers flexibility where ISI distortion may vary
from one direction to another.
1
2
•
•
•
•
•
•
•
250 Mbps – 4.25 Gbps Fully Differential Data
Paths
Optional Fixed Input Equalization
Selectable Output De-emphasis
Individual Loopback Controls
On-Chip Termination
Lead-less WQFN-60 Pin Package (9 mm x 9
mm x 0.8 mm, 0.5 mm Pitch)
−40°C to +85°C Industrial Temperature Range
6 kV ESD Rating, HBM
APPLICATIONS
•
•
Backplane Driver or Cable Driver
Signal Repeating, Buffering and Conditioning
Applications
All output drivers have four selectable steps of deemphasis to compensate against transmission loss
across long FR4 backplanes. The de-emphasis
blocks are also grouped in fours. In addition, the
DS42BR400 also has loopback control capability on
four channels. All CML drivers have 50Ω termination
to VCC. All receivers are internally terminated with
differential 100Ω.
OA0
OA1
OA2
OA3
OB0
OB1
OB2
OB3
IB0
IB1
IB2
IB3
PreA_0
PreA_1
PreB_0
PreB_1
Connector
FPGA
IA0
IA1
IA2
IA3
Connector
Simplified Application Diagram
IA0
IA1
IA2
IA3
OA0
OA1
OA2
OA3
OB0
OB1
OB2
OB3
IB0
IB1
IB2
IB3
PreA_0
PreA_1
PreB_0
PreB_1
Lossy Backplane
or Cable Interconnect
EQA
EQB
FPGA
EQA
EQB
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2006–2013, Texas Instruments Incorporated
DS42BR400
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Functional Block Diagram
EQB
Port 0/1
OB_0+-
EQB
IB_0+-
EQB
IB_1+-
PreB
OB_1+PreB
EQB
LB0
EQA
OA_0+IA_0+-
EQA
PreA
OA_1+-
IA_1+-
EQA
PreA
LB1
EQA
EQB
Port 2/3
OB_2+-
EQB
IB_2+-
EQB
IB_3+-
PreB
OB_3+PreB
EQB
LB2
EQA
OA_2+IA_2+-
EQA
PreA
OA_3+-
IA_3+-
EQA
PreA
LB3
EQA
PreA
PreB
EQA
EQB
VDD
PreA_0
PreA_1
PreB_0
Pre-Emphasis
Control
Equalizer
Enable
Control
RSV
PreB_1
EQA
2
GND
EQB
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EQA
RSV
IA_0+
IA_0-
VCC
OB_0+
OB_0-
GND
IB_0-
IB_0+
VCC
OA_0-
OA_0+
GND
LB0
Connection Diagram
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
PreA_1
1
45
PreB_1
GND
2
44
LB1
OB_1+
3
43
IB_1+
OB_1-
4
42
IB_1-
VCC
5
41
VCC
IA_1+
6
40
OA_1+
IA_1-
7
39
OA_1-
38
GND
37
OA_2-
GND
60 Pin WQFN
8
Top View
IA_2-
9
DAP = GND
IB_2+
GND
14
32
LB2
PreA_0
15
31
PreB_0
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
LB3
33
GND
13
OA_3+
OB_2+
OA_3-
IB_2-
VCC
34
IB_3+
12
IB_3-
OB_2-
GND
VCC
OB_3-
35
OB_3+
11
VCC
VCC
IA_3-
OA_2+
IA_3+
36
GND
10
EQB
IA_2+
Figure 1. Leadless WQFN-60 Pin Package
(9 mm x 9 mm x 0.8 mm, 0.5 mm pitch)
See Package Number NKA0060A
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PIN DESCRIPTIONS
Pin Name
Pin Number
I/O (1)
Description
DIFFERENTIAL I/O
IB_0+
IB_0−
51
52
I
Inverting and non-inverting differential inputs of port_0. IB_0+ and IB_0− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OA_0+
OA_0−
48
49
O
Inverting and non-inverting differential outputs of port_0. OA_0+ and OA_0− are connected to VCC
through a 50Ω resistor.
IB_1+
IB_1−
43
42
I
Inverting and non-inverting differential inputs of port_1. IB_1+ and IB_1− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OA_1+
OA_1−
40
39
O
Inverting and non-inverting differential outputs of port_1. OA_1+ and OA_1− are connected to VCC
through a 50Ω resistor.
IB_2+
IB_2−
33
34
I
Inverting and non-inverting differential inputs of port_2. IB_2+ and IB_2− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OA_2+
OA_2−
36
37
O
Inverting and non-inverting differential outputs of port_2. OA_2+ and OA_2− are connected to VCC
through a 50Ω resistor.
IB_3+
IB_3−
25
24
I
Inverting and non-inverting differential inputs of port_3. IB_3+ and IB_3− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OA_3+
OA_3−
28
27
O
Inverting and non-inverting differential outputs of port_3. OA_3+ and OA_3− are connected to VCC
through a 50Ω resistor.
IA_0+
IA_0−
58
57
I
Inverting and non-inverting differential inputs of port_0. IA_0+ and IA_0− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OB_0+
OB_0−
55
54
O
Inverting and non-inverting differential outputs of port_0. OB_0+ and OB_0− are connected to VCC
through a 50Ω resistor.
IA_1+
IA_1−
6
7
I
Inverting and non-inverting differential inputs of port_1. IA_1+ and IA_1− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OB_1+
OB_1−
3
4
O
Inverting and non-inverting differential outputs of port_1. OB_1+ and OB_1− are connected to VCC
through a 50Ω resistor.
IA_2+
IA_2−
10
9
I
Inverting and non-inverting differential inputs of port_2. IA_2+ and IA_2− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OB_2+
OB_2−
13
12
O
Inverting and non-inverting differential outputs of port_2. OB_2+ and OB_2− are connected to VCC
through a 50Ω resistor.
IA_3+
IA_3−
18
19
I
Inverting and non-inverting differential inputs of port_3. IA_3+ and IA_3− are internally connected to a
reference voltage through a 50Ω resistor. Refer to Figure 8.
OB_3+
OB_3−
21
22
O
Inverting and non-inverting differential outputs of port_3. OB_3+ and OB_3− are connected to VCC
through a 50Ω resistor.
CONTROL (3.3V LVCMOS)
EQA
60
I
This pin is active LOW. A logic LOW at EQA enables equalization for input channels IA_0±, IA_1±,
IA_2±, and IA_3±. By default, this pin is internally pulled high and equalization is disabled.
EQB
16
I
This pin is active LOW. A logic LOW at EQB enables equalization for input channels IB_0±, IB_1±,
IB_2±, and IB_3±. By default, this pin is internally pulled high and equalization is disabled.
PreA_0
PreA_1
15
1
I
PreA_0 and PreA_1 select the output de-emphasis levels (OA_0±, OA_1±, OA_2±, and OA_3±).
PreA_0 and PreA_1 are internally pulled high. Please see Table 2 for de-emphasis levels.
PreB_0
PreB_1
31
45
I
PreB_0 and PreB_1 select the output de-emphasis levels (OB_0±, OB_1±, OB_2±, and OB_3±).
PreB_0 and PreB_1 are internally pulled high. Please see Table 2 for de-emphasis levels.
LB0
46
I
This pin is active LOW. A logic LOW at LB0 enables the internal loopback path from IB_0± to OA_0±.
LB0 is internally pulled high. Please see Table 1 for more information.
LB1
44
I
This pin is active LOW. A logic LOW at LB1 enables the internal loopback path from IB_1± to OA_1±.
LB1 is internally pulled high. Please see Table 1 for more information.
LB2
32
I
This pin is active LOW. A logic LOW at LB2 enables the internal loopback path from IB_2± to OA_2±.
LB2 is internally pulled high. Please see Table 1 for more information.
LB3
30
I
This pin is active LOW. A logic LOW at LB3 enables the internal loopback path from IB_3± to OA_3±.
LB3 is internally pulled high. Please see Table 1 for more information.
RSV
59
I
Reserve pin to support factory testing. This pin can be left open, tied to GND, or tied to GND through
an external pull-down resistor.
(1)
4
Note: I = Input, O = Output, P = Power
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PIN DESCRIPTIONS (continued)
Pin Name
(1)
Pin Number
I/O
Description
VCC
5, 11, 20, 26,
35, 41, 50,
56
P
VCC = 3.3V ± 5%.
Each VCC pin should be connected to the VCC plane through a low inductance path, typically with a
via located as close as possible to the landing pad of the VCC pin.
It is recommended to have a 0.01 μF or 0.1 μF, X7R, size-0402 bypass capacitor from each VCC pin
to ground plane.
GND
2, 8, 14, 17,
23, 29, 38,
47, 53
P
Ground reference. Each ground pin should be connected to the ground plane through a low
inductance path, typically with a via located as close as possible to the landing pad of the GND pin.
GND
DAP
P
DAP is the metal contact at the bottom side, located at the center of the WQFN-60 pin package. It
should be connected to the GND plane with at least 4 via to lower the ground impedance and improve
the thermal performance of the package.
POWER
Functional Description
Table 1. Logic Table for Loopback Controls
LB0
Loopback Function
0
Enable loopback from IB_0± to OA_0±.
1 (default)
Normal mode. Loopback disabled.
LB1
Loopback Function
0
Enable loopback from IB_1± to OA_1±.
1 (default)
Normal mode. Loopback disabled.
LB2
Loopback Function
0
Enable loopback from IB_2± to OA_2±.
1 (default)
Normal mode. Loopback disabled.
LB3
Loopback Function
0
Enable loopback from IB_3± to OA_3±.
1 (default)
Normal mode. Loopback disabled.
Table 2. De-Emphasis Controls
Default VOD Level in mVPP (VODB)
De-Emphasis Level in mVPP
(VODPE)
00
1200
1200
0
01
1200
850
−3
10
1200
600
−6
1 1 (Default)
1200
426
−9
Default VOD Level in mVPP (VODB)
De-Emphasis Level in mVPP
(VODPE)
De-Emphasis in dB (VODPE/VODB)
00
1200
1200
0
01
1200
850
−3
10
1200
600
−6
1 1 (Default)
1200
426
−9
PreA_[1:0]
PreB_[1:0]
De-Emphasis in dB (VODPE/VODB)
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De-emphasis is the primary signal conditioning function for use in compensating against backplane transmission
loss. The DS42BR400 provides four steps of de-emphasis ranging from 0, −3, −6 and −9 dB, user-selectable
dependent on the loss profile of the backplane. Figure 2 shows a driver de-emphasis waveform. The deemphasis duration is nominal 200 ps, corresponding to 85% bit-width at 4.25 Gbps.
The high speed inputs are self-biased to about 1.3V and are designed for AC coupling allowing the DS42BR400
to be directly inserted into the datapath without any limitation. The ideal AC coupling capacitor value is often
based on the lowest frequency component embedded within the serial link. A typical AC coupling capacitor value
rages between 100 and 1000nF, some specifications with scrambled data may require a larger coupling
capacitor for optimal performance. To reduce unwanted parasitics around and within the AC coupling capacitor, a
body size of 0402 is recommended. Figure 7 shows the AC coupling capacitor placement in an AC test circuit.
Input Equalization
Each differential input of the DS42BR400 has a fixed equalizer front-end stage. It is designed to provide fixed
equalization for short board traces with transmission losses of approximately 5 dB between 375 MHz to 1.875
GHz. Programmable de-emphasis together with input equalization ensures an acceptable eye opening for a 40inch FR-4 backplane.
The differential input equalizer for inputs on Channel A and inputs on Channel B can be bypassed by using EQA
and EQB, respectively. By default, the equalizers are internally pulled high and disabled. Therefore, EQA and
EQB must be asserted LOW to enable equalization.
1-bit
1 to N bits
1-bit
1 to N bits
0 dB
-3 dB
-6 dB
VODB
-9 dB
VODPE3
0V
VODPE2
VODPE1
Figure 2. Driver De-Emphasis Differential Waveform (showing all 4 de-emphasis steps)
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.
6
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Absolute Maximum Ratings (1) (2)
−0.3V to 4V
Supply Voltage (VCC)
CMOS/TTL Input Voltage
−0.3V to (VCC +0.3V)
CML Input/Output Voltage
−0.3V to (VCC +0.3V)
Junction Temperature
+150°C
Storage Temperature
−65°C to +150°C
Lead Temperature Soldering, 4 sec
+260°C
Thermal Resistance, θJA
22.3°C/W
Thermal Resistance, θJC
3.2°C/W
Thermal Resistance, ΦJB
10.3°C/W
ESD Ratings (3)
HBM
6kV
CDM
1kV
MM
(1)
(2)
(3)
350V
“Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for
which the device is functional. For ensured specifications and the test conditions, see the Electrical Characteristics Tables. Operation of
the device beyond the maximum Operating Ratings is not recommended.
If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and
specifications.
ESD tests conform to the following standards:Human Body Model (HBM) applicable standard: MIL-STD-883, Method 3015.7Machine
Model (MM) applicable standard: JESD22-A115-A (ESD MM std. of JEDEC)Field -Induced Charge Device Model (CDM) applicable
standard: JESD22-C101-C (ESD FICDM std. of JEDEC)
Recommended Operating Ratings
Supply Voltage (VCC-GND)
Supply Noise Amplitude
Min
Typ
Max
3.135
3.3
3.465
V
100
mVPP
+85
°C
100
°C
10 Hz to 2 GHz
−40
Ambient Temperature
Case Temperature
Units
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Electrical Characteristics (1) (2)
Over recommended operating supply and temperature ranges unless otherwise specified.
Parameter
Test Conditions
Min
Typ
(3)
Max
Units
LVCMOS DC SPECIFICATIONS
VIH
High Level Input
Voltage
2.0
VCC +0.3
V
VIL
Low Level Input
Voltage
−0.3
0.8
V
IIH
High Level Input
Current
−10
10
µA
IIL
Low Level Input Current VIN = GND
RPU
Pull-High Resistance
VIN = VCC
75
94
124
35
µA
kΩ
RECEIVER SPECIFICATIONS
VID
Differential Input
Voltage Range
AC Coupled Differential Signal.
Below 1.25 Gb/s
At 1.25 Gbps–3.125 Gbps
Above 3.125 Gbps
This parameter is not production tested.
VICM
Common Mode Voltage Measured at receiver inputs reference to ground.
at Receiver Inputs
RITD
Input Differential
Termination
100
100
100
1750
1560
1200
1.3
mVP-P
mVP-P
mVP-P
V
On-chip differential termination
between IN+ or IN−.SeeFigure 8
84
100
116
Ω
Output Differential
Voltage Swing without
De-Emphasis
RL = 100Ω ±1%
PreA_1 = 0; PreA_0 = 0
PreB_1 = 0; PreB_0 = 0
Driver de-emphasis disabled.
Running K28.7 pattern at 4 Gbps.
See(Figure 7)
1000
1200
1400
mVP-P
Output De-Emphasis
Voltage Ratio
20*log(VODPE/VODB)
RL = 100Ω ±1%
Running K28.7 pattern at 4.25 Gbps
PreX_[1:0] = 00
PreX_[1:0] = 01
PreX_[1:0] = 10
PreX_[1:0] = 11
X = A/B channel de-emphasis drivers
See(Figure 2/ Figure 7)
De-Emphasis Width
Tested at −9 dB de-emphasis level, PreX[1:0] = 11
X = A/B channel de-emphasis drivers
See Figure 6 on measurement condition.
125
200
250
ps
42
50
58
Ω
DRIVER SPECIFICATIONS
VODB
VPE
tPE
ROTSE
Output Termination
On-chip termination from OUT+ or OUT− to VCC
ROTD
Output Differential
Termination
On-chip differential termination between OUT+ and
OUT−
ΔROTSE
Mis-Match in Output
Termination Resistors
Mis-match in output termination resistors
VOCM
Output Common Mode
Voltage
0
−3
−6
−9
dB
dB
dB
dB
Ω
100
5
2.7
%
V
POWER DISSIPATION
PD
(1)
(2)
(3)
8
Power Dissipation
VDD = 3.465V
All outputs terminated by 100Ω ±1%.
PreB_[1:0] = 0, PreA_[1:0] = 0
Running PRBS 27-1 pattern at 4.25 Gbps
1.3
W
IN+ and IN− are generic names that refer to one of the many pairs of complementary inputs of the DS42BR400. OUT+ and OUT− are
generic names that refer to one of the many pairs of the complementary outputs of the DS42BR400. Differential input voltage VID is
defined as |IN+ – IN−|. Differential output voltage VOD is defined as |OUT+ – OUT−|.
K28.7 pattern is a 10-bit repeating pattern of K28.7 code group {001111 1000}K28.5 pattern is a 20-bit repeating pattern of +K28.5 and
−K28.5 code groups {110000 0101 001111 1010}
Typical specifications are at TA=25 C, and represent most likely parametric norms at the time of product characterization. The typical
specifications are not ensured.
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Electrical Characteristics(1)(2) (continued)
Over recommended operating supply and temperature ranges unless otherwise specified.
Parameter
Test Conditions
Min
Typ
(3)
Max
Units
AC CHARACTERISTICS
tR
Differential Low to High
Transition Time
tF
Differential High to Low
Transition Time
Measured with a clock-like pattern at 4.25 Gbps,
between 20% and 80% of the differential output
voltage.
De-emphasis disabled.
Transition time is measured with the fixture shown in
Figure 7 adjusted to reflect the transition time at the
output pins.
tPLH
Differential Low to High
Propagation Delay
Measured at 50% differential voltage from input to
output.
tPHL
Differential High to Low
Propagation Delay
tSKP
Pulse Skew
tSKO
Output Skew (4)
tSKPP
tLB
Part-to-Part Skew (4)
Loopback Delay Time
80
ps
80
ps
1
ns
1
ns
|tPHL–tPLH|
20
ps
Difference in propagation delay between channels
on the same part
(Channel-to-Channel Skew) (4)
100
ps
Difference in propagation delay between devices
across all channels operating under identical
conditions
165
ps
4
ns
Delay from enabling loopback mode to signals
appearing at the differential outputs
SeeFigure 5
RJ
Device Random Jitter (5) At 0.25 Gbps
At 1.5 Gbps
At 4.25 Gbps
Alternating-10 pattern.
De-emphasis disabled.
See(Figure 7)
2
2
2
ps rms
ps rms
ps rms
DJ
Device Deterministic
Jitter (6)
At 0.25 Mbps, PRBS7 pattern
At 1.5 Gbps, K28.5 pattern
At 4.25 Gbps, K28.5 pattern
At 4.25 Gbps, PRBS7 pattern
De-emphasis disabled.
See(Figure 7)
25
25
25
25
ps
ps
ps
ps
DR
Data Rate (7)
Alternating-10 pattern
(4)
(5)
(6)
(7)
0.25
4.25
pp
pp
pp
pp
Gbps
tSKO is the magnitude difference in propagation delays between all data paths on one device. This is channel-to-channel skew. tSKPP is
the worst case difference in propagation delay across multiple devices on all channels and operating under identical conditions. For
example, for two devices operating under the same conditions, tSKPP is the magnitude difference between the shortest propagation
delay measurement on one device to the longest propagation delay measurement on another device.
Device output random jitter is a measurement of random jitter contributed by the device. It is derived by the equation SQRT[(RJOUT)2 –
(RJIN)2], where RJOUT is the total random jitter measured at the output of the device in ps(rms), RJIN is the random jitter of the pattern
generator driving the device. Below 400 Mbps, system jitter and device jitter could not be separated. The 250 Mbps specification
includes system random jitter. Please see Figure 7 for the AC test circuit.
Device output deterministic jitter is a measurement of the deterministic jitter contribution from the device. It is derived by the equation
(DJOUT - DJIN), where DJOUT is the total peak-to-peak deterministic jitter measured at the output of the device in ps(p-p). DJIN is the
peak-to-peak deterministic jitter at the input of the test board. Please see Figure 7 for the AC test circuit.
This parameter is specified by design and/or characterization and is not tested in production.
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TIMING DIAGRAMS
80%
80%
VODB
0V
20%
20%
tR
tF
Figure 3. Driver Output Transition Time
50% VID
IN
tPLH
tPHL
50% VOD
OUT
Figure 4. Propagation Delay
Loopback
Enable
50%
tLB
50%
Data Output
Data Input
Figure 5. Loopback Delay Timing
1-bit
1 to N bits
1-bit
1 to N bits
tPE
20%
-9 dB
80%
0V
VODB
VODPE3
Figure 6. Output De-Emphasis Duration
10
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DS42BR400 Test Fixture
Pattern
Generator
DC
Block
INPUT
TL
VCC
DS42BR400
50: TL
Oscilloscope or
Jitter Measurement
Instrument
Coax
Coax
D+
IN+
M
U
X
R
EQ
DIN-
50+-1%
OUT+
< 2"
D
OUT-
Coax
1000 mVpp
Differential
DC
Block
Coax
INPUT
TL
GND
50: TL
50 +-1%
Figure 7. AC Test Circuit
VCC
5k
IN +
50
EQ
50
IN 3.9k
180 pF
Figure 8. Receiver Input Termination
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Copyright © 2006–2013, Texas Instruments Incorporated
Product Folder Links: DS42BR400
11
DS42BR400
SNLS221J – MARCH 2006 – REVISED APRIL 2013
www.ti.com
REVISION HISTORY
Changes from Revision I (April 2013) to Revision J
•
12
Page
Changed layout of National Data Sheet to TI format .......................................................................................................... 11
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Copyright © 2006–2013, Texas Instruments Incorporated
Product Folder Links: DS42BR400
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
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)
Device Marking
(3)
(4/5)
(6)
DS42BR400TSQ/NOPB
ACTIVE
WQFN
NKA
60
250
RoHS & Green
SN
Level-3-260C-168 HR
-40 to 85
DS42BR400
TSQ
(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