NSC DS92LV040ATLQA

DS92LV040A
4 Channel Bus LVDS Transceiver
General Description
Features
The DS92LV040A is one in a series of Bus LVDS transceivers designed specifically for high speed, low power backplane or cable interfaces. The device operates from a single
3.3V power supply and includes four differential line drivers
and four receivers. To minimize bus loading, the driver outputs and receiver inputs are internally connected. The device
also features a flow through pin out which allows easy PCB
routing for short stubs between its pins and the connector.
The driver translates 3V LVTTL levels (single-ended) to differential Bus LVDS (BLVDS) output levels. This allows for
high speed operation while consuming minimal power and
reducing EMI. In addition, the differential signaling provides
common mode noise rejection greater than ± 1V.
The receiver threshold is less than +0/−70 mV. The receiver
translates the differential Bus LVDS to standard (LVTTL/
LVCMOS) levels. (See Applications Information Section for
more details.)
n Bus LVDS Signaling
n Propagation delay: Driver 2.3ns max, Receiver 3.2ns
max
n Low power CMOS design
n 100% Transition time 1ns driver typical, 1.3ns receiver
typical
n High Signaling Rate Capability (above 155 Mbps)
n 0.1V to 2.3V Common Mode Range for VID = 200mV
n 70 mV Receiver Sensitivity
n Supports open and terminated failsafe on port pins
n 3.3V operation
n Glitch free power up/down (Driver & Receiver disabled)
n Light Bus Loading (5 pF typical) per Bus LVDS load
n Designed for Double Termination Applications
n Balanced Output Impedance
n Product offered in 44 pin LLP (Leadless Leadframe
Package) package
n High impedance Bus pins on power off (VCC = 0V)
Simplified Functional Diagram
10133601
© 2002 National Semiconductor Corporation
DS101336
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DS92LV040A 4 Channel Bus LVDS Transceiver
August 2002
DS92LV040A
Absolute Maximum Ratings
θja (Note 3)
(Notes 1,
25.8˚C/W
θjc
2)
Supply Voltage (VCC)
(Soldering, 4 sec.)
260˚C
4.0V
Recommended Operating
Conditions
−0.3V to (VCC +0.3V)
Driver Input Voltage (DIN)
−65˚C to +150˚C
Lead Temperature
Enable Input Voltage
(DE, RE)
25.5˚C/W
Storage Temperature Range
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
−0.3V to (VCC +0.3V)
Min
Max
Supply Voltage (VCC)
3.0
3.6
V
Receiver Input Voltage
0.0
2.4
V
ESD (Note 4)
Operating Free Air Temperature
−40
+85
˚C
(HBM 1.5 kΩ, 100 pF)
Slowest Input Edge Rate
Receiver Output Voltage
(ROUT)
−0.3V to (VCC +0.3V)
Bus Pin Voltage (DO/RI ± )
−0.3V to +3.9V
> 4kV
> 250V
Machine Model
LLP(Note 3)
4.8 W
Derate LLP Package
∆t/∆V
(Note 7)(20% to 80%)
Maximum Package Power Dissipation at 25˚C
Units
Data
1.0
ns/V
Control
3.0
ns/V
38.8mW/˚C
DC Electrical Characteristics
Over recommended operating supply voltage and temperature ranges unless otherwise specified (Notes 2, 4)
Symbol
Parameter
Conditions
Pin
Min
Typ
Max
Units
DO+/RI+,
DO−/RI−
200
300
460
mV
5
27
mV
1.1
1.3
1.5
V
5
10
mV
1.4
1.65
V
VOD
Output Differential
Voltage
∆VOD
VOD Magnitude Change
VOS
Offset Voltage
∆VOS
Offset Magnitude Change
VOHD
Driver Output High
Voltage
RL = 27Ω
VOLD
Driver Output Low
Voltage
RL = 27Ω
IOSD
Driver Output Short
Circuit Current (Note 11)
VOD = 0V, DE = VCC, Driver outputs
shorted together
VOHR
Receiver Voltage Output
High (Note 12)
VCC−0.2
V
Inputs Open
VCC−0.2
V
Inputs Terminated,
RL = 27Ω
VCC−0.2
V
VOLR
Receiver Voltage Output
Low
IOD
Receiver Output Dynamic
Current (Note 11)
VTH
Input Threshold High
(Note 9)
VTL
Input Threshold Low
(Note 9)
VCMR
Receiver Common Mode
Range
IIN
Input Current
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RL = 27Ω, Figure 1
VID = +300 mV
0.95
IOH = −4 mA
|30|
ROUT
IOL = 4.0 mA, VID = −300 mV
0.05
VID = 300mV, VOUT = VCC−1.0V
−50
VID = −300mV, VOUT = 1.0V
DE = 0V, Over common mode range
1.1
DO+/RI+,
DO−/RI−
−70
V
| 45|
0.100
|33|
mA
V
mA
|36|
60
mA
−40
0
mV
−40
|VID|/2
mV
2.4 −
|VID|/2
V
DE = 0V, RE = 2.4V,
VIN = +2.4V or 0V
−20
±1
+20
µA
VCC = 0V, VIN = +2.4V or 0V
−20
±1
+20
µA
2
(Continued)
Over recommended operating supply voltage and temperature ranges unless otherwise specified (Notes 2, 4)
Symbol
Parameter
Conditions
Pin
Min
Typ
Max
Units
2.0
VCC
V
GND
0.8
V
+20
µA
+20
µA
VIH
Minimum Input High
Voltage
VIL
Maximum Input Low
Voltage
IIH
Input High Current
VIN = VCC or 2.4V
−20
IIL
Input Low Current
VIN = GND or 0.4V
−20
± 2.5
± 2.5
VCL
Input Diode Clamp
Voltage
ICLAMP = −18 mA
−1.5
−0.8
ICCD
Power Supply Current
Drivers Enabled,
Receivers Disabled
No Load, DE = RE = VCC,
DIN = VCC or GND
Power Supply Current
Drivers Disabled,
Receivers Enabled
DE = RE = 0V, VID = ± 300mV
Power Supply Current,
Drivers and Receivers
TRI-STATE
DE = 0V; RE = VCC,
DIN = VCC or GND
Power Supply Current,
Drivers and Receivers
Enabled
DE = VCC; RE = 0V,
DIN = VCC or GND,
RL = 27Ω
Power Off Leakage
Current
VCC = 0V or OPEN,
DIN, DE, RE = 0V or OPEN,
VAPPLIED = 3.6V (Port Pins)
ICCR
ICCZ
ICC
IOFF
DIN, DE,
RE
V
VCC
DO+/RI+,
DO−/RI−
20
40
mA
27
40
mA
28
40
mA
70
100
mA
+20
µA
−20
COUTPUT Capacitance @ Bus Pins
DO+/RI+,
DO−/RI−
5
pF
cOUTPUT Capacitance @ ROUT
ROUT
5
pF
AC Electrical Characteristics
Over recommended operating supply voltage and temperature ranges unless otherwise specified (Note 7)
Symbol
Parameter
Conditions
Min
Typ
Max
Units
DIFFERENTIAL DRIVER TIMING REQUIREMENTS
tPHLD
Differential Prop. Delay High to Low (Note 9)
tPLHD
Differential Prop. Delay Low to High (Note 9)
tSKD1
Differential Skew |tPHLD–tPLHD| (duty cycle)(Note 10),
(Note 9)
RL = 27Ω,
Figures 2, 3,
CL = 10 pF
1.0
1.5
2.3
ns
1.0
1.5
2.3
ns
80
160
ps
tCCSK
Channel to Channel Skew (all 4 channels), (Note 9)
220
400
ps
tTLH
Transition Time Low to High (20% to 80%)
0.4
0.75
1.3
ns
tTHL
Transition Time High to Low (80% to 20%)
0.4
0.75
1.3
ns
tPHZ
Disable Time High to Z
5.0
10
ns
tPLZ
Disable Time Low to Z
5.0
10
ns
tPZH
Enable Time Z to High
5.0
10
ns
tPZL
Enable Time Z to Low
5.0
10
ns
fMAXD
Guaranteed operation per data sheet up to the Min.
Duty Cycle 45/55%,Transition time ≤ 25% of period
(Note 9)
RL = 27Ω,
Figures 4, 5,
CL = 10 pF
85
3
125
MHz
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DS92LV040A
DC Electrical Characteristics
DS92LV040A
AC Electrical Characteristics
(Continued)
Over recommended operating supply voltage and temperature ranges unless otherwise specified (Note 7)
Symbol
Parameter
Conditions
Min
Typ
Max
Units
DIFFERENTIAL RECEIVER TIMING REQUIREMENTS
tPHLDR
Differential Prop. Delay High to Low (Note 9)
tPLHDR
Differential Prop Delay Low to High (Note 9)
tSDK1R
Differential Skew |tPHLD–tPLHD| (duty cycle)(Note 10),
(Note 9)
Figures 6, 7,
CL = 15 pF
tCCSKR
Channel to Channel Skew (all 4 channels)(Note 9)
tTLHR
Transition Time Low to High (10% to 90%) (Note 9)
tTHLR
Transition Time High to Low (90% to 10%) (Note 9)
tPHZ
Disable Time High to Z
tPLZ
Disable Time Low to Z
tPZH
Enable Time Z to High
tPZL
Enable Time Z to Low
fMAXR
Guaranteed operation per data sheet up to the Min.
Duty Cycle 45/55%,Transition time ≤ 25% of period
(Note 9)
1.6
2.4
3.2
ns
1.6
2.4
3.2
ns
85
160
ps
140
300
ps
0.850
1.250
2.0
ns
0.850
1.030
2.0
ns
3.0
10
ns
3.0
10
ns
3.0
10
ns
3.0
10
ns
RL = 500Ω,
Figures 8, 9,
CL = 15 pF
85
125
MHz
Note 1: “Absolute Maximum Ratings” are those values beyond which the safety of the device cannot be guaranteed. They are not meant to imply that the devices
should be operated at these limits. The table of “Electrical Characteristics” provides conditions for actual device operation.
Note 2: All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to ground unless otherwise specified except
VOD, ∆VOD and VID.
Note 3: Package must be mounted to pc board in accordance with AN-1187 to achieve thermals.
Note 4: All typicals are given for VCC = +3.3V and TA = +25˚C, unless otherwise stated.
Note 5: ESD Rating: HBM (1.5 kΩ, 100 pF) > 4 kV EIAJ (0Ω, 200 pF) > 250.
Note 6: CL includes probe and fixture capacitance.
Note 7: Generator waveforms for all tests unless otherwise specified: f = 25 MHz, ZO = 50Ω, tr, tf = < 1.0 ns (0%–100%). To ensure fastest propagation delay and
minimum skew, data input edge rates should be equal to or faster than 1ns/V; control signals equal to or faster than 3ns/V. In general, the faster the input edge rate,
the better the AC performance.
Note 8: The DS92LV040A functions within datasheet specification when a resistive load is applied to the driver outputs.
Note 9: Propagation delays, transition times, and receiver threshold are guaranteed by design and characterization.
Note 10: tSKD1 |tPHLD–tPLHD| is the worst case pulse skew (measure of duty cycle) over recommended operation conditions.
Note 11: Only one output at a time should be shorted, do not exceed maximum package power dissipation capacity.
Note 12: VOH fail-safe terminated test performed with 27Ω connected between RI+ and RI− inputs. No external voltage is applied.
Note 13: Chip to Chip skew is the difference in differential propagation delay between any channels of any devices, either edge.
function of load resistor. The current mode requires (as
discussed above) that a resistive termination be employed to
terminate the signal and to complete the loop. Unterminated
configurations are not allowed. The 12 mA loop current will
develop a differential voltage of about 300mV across a 27Ω
(double terminated 54Ω differential transmission backplane)
effective resistance, which the receiver detects with a 230
mV minimum differential noise margin neglecting resistive
line losses (driven signal minus receiver threshold (300 mV
– 70 mV = 230 mV)). The signal is centered around +1.2V
(Driver Offset, VOS ) with respect to ground. Note that the
steady-state voltage (VSS ) peak-to-peak swing is twice the
differential voltage (VOD ) and is typically 600 mV. The
current mode driver provides substantial benefits over voltage mode drivers, such as an RS-422 driver. Its quiescent
current remains relatively flat versus switching frequency.
Whereas the RS-422 voltage mode driver increases exponentially in most case between 20 MHz–50 MHz. This is due
to the overlap current that flows between the rails of the
device when the internal gates switch. Whereas the current
mode driver switches a fixed current between its output
without any substantial overlap current. This is similar to
some ECL and PECL devices, but without the heavy static
ICC requirements of the ECL/PECL designs. LVDS requires
80% less current than similar PECL devices. AC specifications for the driver are a tenfold improvement over other
Applications Information
General application guidelines and hints may be found in the
following application notes: AN-808, AN-977, AN-971, and
AN-903.
BLVDS drivers and receivers are intended to be used in a
differential backplane configuration. Transceivers or receivers are connected to the driver through a balanced media
such as differential PCB traces. Typically, the characteristic
differential impedance of the media (Zo) is in the range of
50Ω to 100Ω. Two termination resistors of ZoΩ each are
placed at the ends of the transmission line backplane. The
termination resistor converts the current sourced by the
driver into a voltage that is detected by the receiver. The
effects of mid-stream connector(s), cable stub(s), and other
impedance discontinuity as well as ground shifting, noise
margin limits, and total termination loading must be taken
into account. The DS92LV040A differential line driver is a
balanced current mode design. A current mode driver, generally speaking has a high output impedance (100 ohms)
and supplies a reasonably constant current for a range of
loads (a voltage mode driver on the other hand supplies a
constant voltage for a range of loads). Current is switched
through the load in one direction to produce a logic state and
in the other direction to produce the other logic state. The
output current is typically 12 mA. The current changes as a
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4
traces 3mm apart since magnetic field cancellation is
much better with the closer traces. Plus, noise induced
on the differential lines is much more likely to appear as
common-mode which is rejected by the receiver. Match
electrical lengths between traces to reduce skew. Skew
between the signals of a pair means a phase difference
between signals which destroys the magnetic field cancellation benefits of differential signals and EMI will result. (Note the velocity of propagation, v = c/Er where c
(the speed of light) = 0.2997mm/ps or 0.0118 in/ps). Do
not rely solely on the autoroute function for differential
traces. Carefully review dimensions to match differential
impedance and provide isolation for the differential lines.
Minimize the number of vias and other discontinuity on
the line. Avoid 90˚ turns (these cause impedance discontinuity). Use arcs or 45˚ bevels. Within a pair of traces,
the distance between the two traces should be minimized
to maintain common-mode rejection of the receivers. On
the printed circuit board, this distance should remain
constant to avoid discontinuity in differential impedance.
Minor violations at connection points are allowable.
• Stub Length: Stub lengths should be kept to a minimum.
The typical transition time of the DS92LV040A BLVDS
output is 0.75ns (20% to 80%). The extrapolated 100
percent time is 0.75/0.6 or 1.25ns. For a general approximation, if the electrical length of a trace is greater than
1/5 of the transition edge, then the trace is considered a
transmission line. For example, 1.25ns/5 is 250 picoseconds. Let velocity equal 160ps per inch for a typical
loaded backplane. Then maximum stub length is 250ps/
160ps/in or 1.56 inches. To determine the maximum stub
for your backplane, you need to know the propagation
velocity for the actual conditions (refer to application
notes AN 905 and AN 808).
PACKAGE and SOLDERING INFORMATION:
• Refer to packaging application note AN-1187. This application note details the package attachment methods to
achieve the correct solderability and thermal results.
(Continued)
existing RS-422 drivers. The TRI-STATE function allows the
driver outputs to be disabled, thus obtaining an even lower
power state when the transmission of data is not required.
There are a few common practices which should be implied
when designing PCB for Bus LVDS signaling. Recommended practices are:
• Use at least 4 PCB board layer (Bus LVDS signals,
ground, power and TTL signals).
• Keep drivers and receivers as close to the (Bus LVDS
port side) connector as possible.
• Bypass each Bus LVDS device and also use distributed
bulk capacitance between power planes. Surface mount
capacitors placed close to power and ground pins work
best. Three or more high frequency, multi-layer ceramic
(MLC) surface mount (0.1 µF, 0.01 µF, 0.001 µF) in
parallel should be used between each VCC and ground.
Multiple vias should be used to connect VCC and Ground
planes to the pads of the by-pass capacitors.
In addition, it may be necessary to randomly distribute
by-pass capacitors of different values (200pF to 1000pF)
to achieve different resonant frequencies.
• Use the termination resistor which best matches the differential impedance of your transmission line.
• Leave unused Bus LVDS receiver inputs open (floating).
Limit traces on unused inputs to < 0.5 inches.
• Isolate TTL signals from Bus LVDS signals
MEDIA (CONNECTOR or BACKPLANE) SELECTION:
• The backplane and connectors should have a matched
differential impedance. Use controlled impedance traces
which match the differential impedance of your transmission medium (ie. backplane or cable) and termination
resistor(s). Run the differential pair trace lines as close
together as possible as soon as they leave the IC . This
will help eliminate reflections and ensure noise is coupled
as common-mode. In fact, we have seen that differential
signals which are 1mm apart radiate far less noise than
5
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DS92LV040A
Applications Information
DS92LV040A
Applications Information
(Continued)
TABLE 1. Functional Table
MODE SELECTED
DE
RE
DRIVER MODE
H
H
RECEIVER MODE
L
L
TRI-STATE™ MODE
L
H
LOOP BACK MODE
H
L
TABLE 2. Transmitter Mode
INPUTS
DE
OUTPUTS
DIN
DO+
DO−
H
H
L
L
H
H
H
L
H
0.8V < DIN < 2.0V
X
X
L
X
Z
Z
TABLE 3. Receiver Mode
INPUTS
OUTPUT
RE
(RI+) – (RI−)
L
L ( < −70 mV)
L
L
H ( > 0 mV)
H
L
−70 mV < VID < 0 mV
X
H
X
Z
X = High or Low logic state
L = Low state
Z = High impedance state
H = High state
Test Circuits and Timing
Waveforms
10133603
FIGURE 1. Differential Driver DC Test Circuit
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6
DS92LV040A
Test Circuits and Timing Waveforms
(Continued)
10133604
FIGURE 2. Differential Driver Propagation Delay and Transition Time Test Circuit
10133605
FIGURE 3. Differential Driver Propagation Delay and Transition Time Waveforms
10133606
FIGURE 4. Driver TRI-STATE Delay Test Circuit
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DS92LV040A
Test Circuits and Timing Waveforms
(Continued)
10133607
FIGURE 5. Driver TRI-STATE Delay Waveforms
10133608
FIGURE 6. Receiver Propagation Delay and Transition Time Test Circuit
10133609
FIGURE 7. Receiver Propagation Delay and Transition Time Waveforms
10133610
FIGURE 8. Receiver TRI-STATE Delay Test Circuit
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8
DS92LV040A
Test Circuits and Timing Waveforms
(Continued)
10133611
FIGURE 9. Receiver TRI-STATE Delay Waveforms
Typical Bus Application
Configurations
10133612
Bidirectional Half-Duplex Point-to-Point Applications
10133613
Multi-Point Bus Applications
9
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DS92LV040A
Connection Diagram
10133602
Top View
Order Number DS92LV040ATLQA
See NS Package Number LQA44A
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10
Pin Name
Pin #
Input/Output
DO+/RI+
14, 16, 19, 21
I/O
True Bus LVDS Driver Outputs and Receiver Inputs.
DO−/RI−
13, 15, 18, 20
I/O
Complimentary Bus LVDS Driver Outputs and Receiver Inputs.
DIN
35, 37, 40, 42
I
LVTTL Driver Input. No pull up or pull down is attached to this pin
RO
36, 38, 41, 43
O
LVTTL Receiver Output.
RE12
29
I
Receiver Enable LVTTL Input (Active Low). This pin, when low,
configures receiver outputs, RO1 and RO2 active. When this pin is
high, RO1 and RO2 are TRI-STATE. If this pin is floating, a weak
current source to VCC causes RO1 and RO2 to be TRI-STATE
RE34
5
I
Receiver Enable LVTTL Input (Active Low). This pin, when low,
configures receiver outputs, RO3 and RO4 active. When this pin is
high, RO3 and RO4 are TRI-STATE. If this pin is floating, a weak
current source to VCC causes RO3 and RO4 to be TRI-STATE
DE12
26
I
Driver Enable LVTTL Input (Active High). This pin, when high,
configures driver outputs, DO1+/RIN1+, DO1−/RIN1− and
DO2+/RIN2+, DO2−/RIN2− active. When this pin is low, driver outputs
1 and 2 are TRI-STATE. If this pin is floating, a weak current source
to VCC causes driver outputs 1 and 2 to be active
DE34
8
I
Driver Enable LVTTL Input (Active High). This pin, when high,
configures driver outputs, DO3+/RIN3+, DO3−/RIN3− and
DO4+/RIN4+, DO4−/RIN4− active. When this pin is low, driver outputs
3 and 4 are TRI-STATE. If this pin is floating, a weak current source
to VCC causes driver outputs 3 and 4 to be active
GND
4, 28, 31, 39
Ground
Ground for digital circuitry (must connect to GND on PC board). These
pins connected internally.
VCC
3, 6, 30
Power
VCC for digital circuitry (must connect to VCC on PC board). These
pins connected internally.
AGND
9, 17, 25
Ground
Ground for analog circuitry (must connect to GND on PC board).
These pins connected internally.
AVCC
7, 10, 22, 27
Power
Analog VCC (must connect to VCC on PC board). These pins
connected internally.
NC
1, 2, 11, 12, 23, 24,
32, 33, 34, 44
N/A
Reserved for future use, leave open circuit.
GND
Must connect to GND plane through vias to achieve the theta ja
specified under Absolute Maximum Ratings. The DAP (die attach pad)
is the heat transfer material that is centered on the bottom of the LLP
package. Refer to application note AN-1187 for attachment details.
DAP
Descriptions
11
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DS92LV040A
Pinout Description
DS92LV040A 4 Channel Bus LVDS Transceiver
Physical
Dimensions
All dimensions are in millimeters
Physical Dimensions
inches (millimeters) unless otherwise noted
44 pin Plastic LLP Package
Order Number DS92LV040ATLQA
NS Package Number LQA44A
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