DS90CR214MTDX [ROCHESTER]
TRIPLE LINE RECEIVER, PDSO48, PLASTIC, TSSOP-48;型号: | DS90CR214MTDX |
厂家: | Rochester Electronics |
描述: | TRIPLE LINE RECEIVER, PDSO48, PLASTIC, TSSOP-48 光电二极管 接口集成电路 |
文件: | 总16页 (文件大小:1386K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
August 2005
DS90CR213/DS90CR214
21-Bit Channel Link—66 MHz
General Description
The DS90CR213 transmitter converts 21 bits of CMOS/TTL
data into three LVDS (Low Voltage Differential Signaling)
data streams. A phase-locked transmit clock is transmitted in
parallel with the data streams over a fourth LVDS link. Every
cycle of the transmit clock 21 bits of input data are sampled
and transmitted. The DS90CR214 receiver converts the
LVDS data streams back into 21 bits of CMOS/TTL data. At
a transmit clock frequency of 66 MHz, 21 bits of TTL data are
transmitted at a rate of 462 Mbps per LVDS data channel.
Using a 66 MHz clock, the data throughput is 1.386 Gbit/s
(173 Mbytes/s).
width, which provides a system cost savings, reduces con-
nector physical size and cost, and reduces shielding require-
ments due to the cable’s smaller form factor.
The 21 CMOS/TTL inputs can support a variety of signal
combinations. For example, 5 4-bit nibbles (byte + parity) or
2 9-bit (byte + 3 parity) and 1 control.
Features
n 66 MHz Clock Support
n Up to 173 Mbytes/s bandwidth
<
n Low power CMOS design ( 610 mW)
<
n Power-down mode ( 0.5 mW total)
The multiplexing of the data lines provides a substantial
cable reduction. Long distance parallel single-ended buses
typically require a ground wire per active signal (and have
very limited noise rejection capability). Thus, for a 21-bit wide
data and one clock, up to 44 conductors are required. With
the Channel Link chipset as few as 9 conductors (3 data
pairs, 1 clock pair and a minimum of one ground) are
needed. This provides an 80% reduction in required cable
n Up to 1.386 Gbit/s data throughput
n Narrow bus reduces cable size and cost
n 290 mV swing LVDS devices for low EMI
n PLL requires no external components
n Low profile 48-lead TSSOP package
n Rising edge data strobe
n Compatible with TIA/EIA-644 LVDS Standard
Block Diagrams
DS90CR213
DS90CR214
01288827
Order Number DS90CR213MTD
See NS Package Number MTD48
01288801
Order Number DS90CR214MTD
See NS Package Number MTD48
TRI-STATE® is a registered trademark of National Semiconductor Corporation.
© 2005 National Semiconductor Corporation
DS012888
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Connection Diagrams
DS90CR213
DS90CR214
01288821
01288822
Typical Application
01288823
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2
Absolute Maximum Ratings (Note 1)
Package Derating:
DS90CR213
16 mW/˚C above +25˚C
15 mW/˚C above +25˚C
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
DS90CR214
ESD Rating (Note 4)
This device does not meet 2000V
Supply Voltage (VCC
)
−0.3V to +6V
−0.3V to (VCC + 0.3V)
−0.3V to (VCC + 0.3V)
−0.3V to (VCC + 0.3V)
−0.3V to (VCC + 0.3V)
CMOS/TTL Input Voltage
CMOS/TTL Output Voltage
LVDS Receiver Input Voltage
LVDS Driver Output Voltage
LVDS Output Short Circuit
Duration
Recommended Operating
Conditions
Min Nom Max Units
Supply Voltage (VCC
Operating Free Air
Temperature (TA)
)
4.75 5.0 5.25
V
Continuous
+150˚C
Junction Temperature
Storage Temperature
Lead Temperature
−10 +25 +70
˚C
V
−65˚C to +150˚C
Receiver Input Range
Supply Noise Voltage
0
2.4
(Soldering, 4 sec)
+260˚C
100
mVP-P
(VCC
)
Maximum Package Power
Dissipation Capacity
MTD48 (TSSOP) Package:
DS90CR213
@
25˚C
1.98W
1.89W
DS90CR214
Electrical Characteristics
Over recommended operating supply and temperature ranges unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
CMOS/TTL DC SPECIFICATIONS
VIH
VIL
High Level Input Voltage
Low Level Input Voltage
High Level Output Voltage
Low Level Output Voltage
Input Clamp Voltage
2.0
GND
3.8
VCC
0.8
V
V
VOH
VOL
VCL
IIN
IOH = −0.4 mA
IOL = 2 mA
4.9
0.1
V
0.3
−1.5
10
V
ICL = −18 mA
−0.79
5.1
V
Input Current
VIN = VCC, GND, 2.5V or 0.4V
VOUT = 0V
µA
mA
IOS
Output Short Circuit Current
−120
LVDS DRIVER DC SPECIFICATIONS
VOD
Differential Output Voltage
Change in VOD between
Complimentary Output States
Offset Voltage
RL = 100Ω
250
1.1
290
450
35
mV
mV
∆VOD
VOS
1.25
1.375
35
V
∆VOS
Change in Magnitude of VOS
between Complimentary Output
States
mV
IOS
IOZ
Output Short Circuit Current
Output TRI-STATE® Current
VOUT = 0V, R = 100Ω
−2.9
1
−5
10
mA
µA
L
Powerdown = 0V, VOUT = 0V or VCC
LVDS RECEIVER DC SPECIFICATIONS
VTH
VTL
IIN
Differential Input High Threshold
Differential Input Low Threshold
Input Current
VCM = +1.2V
+100
mV
mV
µA
−100
VIN = +2.4V, VCC = 5.0V
VIN = 0V, VCC = 5.0V
10
10
µA
TRANSMITTER SUPPLY CURRENT
ICCTW
Transmitter Supply Current
Worst Case
RL = 100Ω, C = 5 pF,
f = 32.5 MHz
49
51
70
63
64
84
mA
mA
mA
L
Worst Case Pattern
(Figure 1 and Figure 2 )
Powerdown = Low
f = 37.5 MHz
f = 66 MHz
ICCTZ
Transmitter Supply Current
3
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Electrical Characteristics (Continued)
Over recommended operating supply and temperature ranges unless otherwise specified.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
TRANSMITTER SUPPLY CURRENT
Power Down
Driver Outputs in TRI-STATE under
Powerdown Mode
1
25
µA
RECEIVER SUPPLY CURRENT
ICCRW
Receiver Supply Current
Worst Case
CL = 8 pF,
f = 32.5 MHz
64
70
77
85
mA
mA
mA
Worst Case Pattern
(Figure 1 and Figure 3 )
Powerdown = Low
f = 37.5 MHz
f = 66 MHz
110
140
ICCRZ
Receiver Supply Current
Power Down
Receiver Outputs in Previous State during
Power Down Mode.
1
10
µA
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 device
should be operated at these limits. The tables of “Electrical Characteristics” specify conditions for device operation.
Note 2: Typical values are given for V
= 5.0V and T = +25˚C.
A
CC
Note 3: Current into device pins is defined as positive. Current out of device pins is defined as negative. Voltages are referenced to ground unless otherwise
specified (except V and ∆V ).
OD
OD
Note 4: ESD Rating: HBM (1.5 kΩ, 100 pF)
PLL V ≥ 1000V
CC
All Other Pins ≥ 2000V
EIAJ (0Ω, 200 pF) ≥ 150V
Note 5: V
previously referred as V
.
CM
OS
Transmitter Switching Characteristics
Over recommended operating supply and temperature ranges unless otherwise specified
Symbol
LLHT
Parameter
LVDS Low-to-High Transition Time (Figure 2 )
LVDS High-to-Low Transition Time (Figure 2 )
TxCLK IN Transition Time (Figure 4 )
Min
Typ
0.75
0.75
Max
1.5
Units
ns
ns
ns
ps
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ms
ns
LHLT
1.5
TCIT
8
TCCS
TxOUT Channel-to-Channel Skew (Note 6) (Figure 5)
350
TPPos0 Transmitter Output Pulse Position for Bit 0 (Figure 16 )
TPPos1 Transmitter Output Pulse Position for Bit 1
TPPos2 Transmitter Output Pulse Position for Bit 2
TPPos3 Transmitter Output Pulse Position for Bit 3
TPPos4 Transmitter Output Pulse Position for Bit 4
TPPos5 Transmitter Output Pulse Position for Bit 5
TPPos6 Transmitter Output Pulse Position for Bit 6
−0.30
1.70
3.60
5.90
8.30
10.40
12.70
15
0
0.30
2.50
4.50
6.75
9.00
11.10
13.40
50
(1/7)Tclk
(2/7)Tclk
(3/7)Tclk
(4/7)Tclk
(5/7)Tclk
(6/7)Tclk
T
f = 66 MHz
TCIP
TxCLK IN Period (Figure 6 )
TCIH
TxCLK IN High Time (Figure 6 )
TxCLK IN Low Time (Figure 6 )
TxIN Setup to TxCLK IN (Figure 6 )
TxIN Hold to TxCLK IN (Figure 6 )
0.35T
0.35T
5
0.5T
0.65T
0.65T
TCIL
0.5T
TSTC
THTC
TCCD
TPLLS
TPDD
3.5
2.5
1.5
@
TxCLK IN to TxCLK OUT Delay 25˚C, VCC = 5.0V (Figure 8 )
3.5
8.5
10
Transmitter Phase Lock Loop Set (Figure 10 )
Transmitter Powerdown Delay (Figure 14 )
100
Note 6: This limit based on bench characterization.
Receiver Switching Characteristics
Over recommended operating supply and temperature ranges unless otherwise specified
Symbol
CLHT
Parameter
CMOS/TTL Low-to-High Transition Time (Figure 3 )
CMOS/TTL High-to-Low Transition Time (Figure 3 )
Min
Typ
2.5
2.0
Max
4.0
Units
ns
CHLT
4.0
ns
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4
Receiver Switching Characteristics (Continued)
Over recommended operating supply and temperature ranges unless otherwise specified
Symbol
Parameter
Min
700
600
15
Typ
Max
Units
ps
RSKM
RxIN Skew Margin (Note 7) V
= 5V,TA = 25˚C(Figure 17)
f = 40 MHz
f = 66 MHz
CC
ps
RCOP
RCOH
RxCLK OUT Period (Figure 7 )
T
5
50
ns
RxCLK OUT High Time (Figure 7 )
f = 40 MHz
f = 66 MHz
f = 40 MHz
f = 66 MHz
f = 40 MHz
f = 66 MHz
f = 40 MHz
f = 66 MHz
6
ns
4.3
10.5
7.0
4.5
2.5
6.5
4
ns
RCOL
RSRC
RHRC
RxCLK OUT Low Time (Figure 7 )
ns
9
ns
RxOUT Setup to RxCLK OUT (Figure 7 )
RxOUT Hold to RxCLK OUT (Figure 7 )
ns
4.2
5.2
ns
ns
ns
@
RCCD
RPLLS
RPDD
RxCLK IN to RxCLK OUT Delay 25˚C, VCC = 5.0V (Figure 9 )
6.4
10.7
10
1
ns
Receiver Phase Lock Loop Set (Figure 11 )
Receiver Powerdown Delay (Figure 15 )
ms
µs
Note 7: Receiver Skew Margin is defined as the valid data sampling region at the receiver inputs. This margin takes into account for transmitter output skew (TCCS)
and the setup and hold time (internal data sampling window), allowing LVDS cable skew dependent on type/length and source clock (TxCLK IN) jitter.
RSKM ≥ cable skew (type, length) + source clock jitter (cycle to cycle)
AC Timing Diagrams
01288802
FIGURE 1. “Worst Case” Test Pattern
01288803
01288804
FIGURE 2. DS90CR213 (Transmitter) LVDS Output Load and Transition Times
5
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AC Timing Diagrams (Continued)
01288805
01288806
FIGURE 3. DS90CR214 (Receiver) CMOS/TTL Output Load and Transition Times
01288807
FIGURE 4. DS90CR213 (Transmitter) Input Clock Transition Time
01288808
Note 8: Measurements at V = 0V
diff
Note 9: TCSS measured between earliest and latest LVDS edges.
→
Note 10: TxCLK Differential Low High Edge
FIGURE 5. DS90CR213 (Transmitter) Channel-to-Channel Skew
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6
AC Timing Diagrams (Continued)
01288809
FIGURE 6. DS90CR213 (Transmitter) Setup/Hold and High/Low Times
01288810
FIGURE 7. DS90CR214 (Receiver) Setup/Hold and High/Low Times
01288811
FIGURE 8. DS90CR213 (Transmitter) Clock In to Clock Out Delay
01288812
FIGURE 9. DS90CR214 (Receiver) Clock In to Clock Out Delay
7
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AC Timing Diagrams (Continued)
01288813
FIGURE 10. DS90CR213 (Transmitter) Phase Lock Loop Set Time
01288814
FIGURE 11. DS90CR214 (Receiver) Phase Lock Loop Set Time
01288815
FIGURE 12. Seven Bits of LVDS in Once Clock Cycle
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AC Timing Diagrams (Continued)
01288816
FIGURE 13. 21 Parallel TTL Data Inputs Mapped to LVDS Outputs
01288817
FIGURE 14. Transmitter Powerdown Delay
01288818
FIGURE 15. Receiver Powerdown Delay
9
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AC Timing Diagrams (Continued)
01288819
FIGURE 16. Transmitter LVDS Output Pulse Position Measurement
01288820
SW — Setup and Hold Time (Internal Data Sampling Window)
TCCS — Transmitter Output Skew
RSKM ≥ Cable Skew (Type, Length) + Source Clock Jitter (Cycle to Cycle)
Cable Skew — Typically 10 ps–40 ps per foot
FIGURE 17. Receiver LVDS Input Skew Margin
DS90CR213 Pin Description—Channel Link Transmitter
Pin Name
TxIN
I/O
I
No.
21
3
Description
TTL level inputs.
TxOUT+
O
O
I
Positive LVDS differential data output.
Negative LVDS differentiaI data output.
TxOUT−
3
TxCLK IN
1
TTL level clock input. The rising edge acts as data strobe.
Positive LVDS differential clock output.
TxCLK OUT+
TxCLK OUT−
O
O
1
1
Negative LVDS differential clock output.
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DS90CR213 Pin Description—Channel Link Transmitter (Continued)
Pin Name
I/O
No.
Description
TTL level input. Assertion (low input) TRI-STATES the outputs, ensuring low current at power
down.
PWR DOWN
I
1
VCC
I
I
I
I
I
I
4
5
1
2
1
3
Power supply pins for TTL inputs.
Ground pins for TTL inputs.
GND
PLL VCC
PLL GND
LVDS VCC
LVDS GND
Power supply pin for PLL.
Ground pins for PLL.
Power supply pin for LVDS outputs.
Ground pins for LVDS outputs.
DS90CR214 Pin Description—Channel Link Receiver
Pin Name
RxIN+
I/O
No.
3
Description
I
I
Positive LVDS differential data inputs.
Negative LVDS differential data inputs.
TTL level outputs.
RxIN−
3
RxOUT
O
I
21
1
RxCLK IN+
RxCLK IN−
RxCLK OUT
PWR DOWN
VCC
Positive LVDS differential clock input.
Negative LVDS differentiaI clock input.
I
1
O
I
1
TTL level clock output. The rising edge acts as data strobe.
TTL Ievel input. Locks the previous receiver output state.
Power supply pins for TTL outputs.
Ground pins for TTL outputs.
1
I
4
GND
I
5
PLL VCC
PLL GND
LVDS VCC
LVDS GND
I
1
Power supply for PLL.
I
2
Ground pin for PLL.
I
1
Power supply pin for LVDS inputs.
Ground pins for LVDS inputs.
I
3
284) requires five pairs of signal wires. The ideal cable/
connector interface would have a constant 100Ω differential
impedance throughout the path. It is also recommended that
Applications Information
The Channel Link devices are intended to be used in a wide
variety of data transmission applications. Depending upon
the application the interconnecting media may vary. For
example, for lower data rate (clock rate) and shorter cable
@
cable skew remain below 350 ps ( 66 MHz clock rate) to
maintain a sufficient data sampling window at the receiver.
In addition to the four or five cable pairs that carry data and
clock, it is recommended to provide at least one additional
conductor (or pair) which connects ground between the
transmitter and receiver. This low impedance ground pro-
vides a common mode return path for the two devices. Some
of the more commonly used cable types for point-to-point
applications include flat ribbon, flex, twisted pair and Twin-
Coax. All are available in a variety of configurations and
options. Flat ribbon cable, flex and twisted pair generally
perform well in short point-to-point applications while Twin-
Coax is good for short and long applications. When using
ribbon cable, it is recommended to place a ground line
between each differential pair to act as a barrier to noise
coupling between adjacent pairs. For Twin-Coax cable ap-
plications, it is recommended to utilize a shield on each
cable pair. All extended point-to-point applications should
also employ an overall shield surrounding all cable pairs
regardless of the cable type. This overall shield results in
improved transmission parameters such as faster attainable
speeds, longer distances between transmitter and receiver
and reduced problems associated with EMS or EMI.
<
lengths ( 2m), the media electrical performance is less
critical. For higher speed/long distance applications the me-
dia’s performance becomes more critical. Certain cable con-
structions provide tighter skew (matched electrical length
between the conductors and pairs). Twin-coax for example,
has been demonstrated at distances as great as 5 meters
and with the maximum data transfer of 1.38 Gbit/s. Addi-
tional applications information can be found in the following
National Interface Application Notes:
AN = ####
AN-1041
Topic
Introduction to Channel Link
PCB Design Guidelines for LVDS and
Link Devices
AN-1035
AN-806
AN-905
Transmission Line Theory
Transmission Line Calculations and
Differential Impedance
AN-916
Cable Information
The high-speed transport of LVDS signals has been demon-
strated on several types of cables with excellent results.
However, the best overall performance has been seen when
using Twin-Coax cable. Twin-Coax has very low cable skew
and EMI due to its construction and double shielding. All of
CABLES
A cable interface between the transmitter and receiver needs
to support the differential LVDS pairs. The 21-bit CHANNEL
LINK chipset (DS90CR213/214) requires four pairs of signal
wires and the 28-bit CHANNEL LINK chipset (DS90CR283/
11
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TERMINATION
Applications Information (Continued)
Use of current mode drivers requires a terminating resistor
across the receiver inputs. The CHANNEL LINK chipset will
normally require a single 100Ω resistor between the true and
complement lines on each differential pair of the receiver
input. The actual value of the termination resistor should be
selected to match the differential mode characteristic imped-
ance (90Ω to 120Ω typical) of the cable. Figure 18 shows an
example. No additional pull-up or pull-down resistors are
necessary as with some other differential technologies such
as PECL. Surface mount resistors are recommended to
avoid the additional inductance that accompanies leaded
resistors. These resistors should be placed as close as
possible to the receiver input pins to reduce stubs and
effectively terminate the differential lines.
the design considerations discussed here and listed in the
supplemental application notes provide the subsystem com-
munications designer with many useful guidelines. It is rec-
ommended that the designer assess the tradeoffs of each
application thoroughly to arrive at a reliable and economical
cable solution.
BOARD LAYOUT
To obtain the maximum benefit from the noise and EMI
reductions of LVDS, attention should be paid to the layout of
differential lines. Lines of a differential pair should always be
adjacent to eliminate noise interference from other signals
and take full advantage of the noise canceling of the differ-
ential signals. The board designer should also try to maintain
equal length on signal traces for a given differential pair. As
with any high speed design, the impedance discontinuities
should be limited (reduce the numbers of vias and no 90
degree angles on traces). Any discontinuities which do occur
on one signal line should be mirrored in the other line of the
differential pair. Care should be taken to ensure that the
differential trace impedance match the differential imped-
ance of the selected physical media (this impedance should
also match the value of the termination resistor that is con-
nected across the differential pair at the receiver’s input).
Finally, the location of the CHANNEL LINK TxOUT/RxIN pins
should be as close as possible to the board edge so as to
eliminate excessive pcb runs. All of these considerations will
limit reflections and crosstalk which adversely effect high
frequency performance and EMI.
DECOUPLING CAPACITORS
Bypassing capacitors are needed to reduce the impact of
switching noise which could limit performance. For a conser-
vative approach three parallel-connected decoupling capaci-
tors (Multi-Layered Ceramic type in surface mount form fac-
tor) between each VCC and the ground plane(s) are
recommended. The three capacitor values are 0.1 µF,
0.01µF and 0.001 µF. An example is shown in Figure 19. The
designer should employ wide traces for power and ground
and ensure each capacitor has its own via to the ground
plane. If board space is limiting the number of bypass ca-
pacitors, the PLL VCC should receive the most filtering/
bypassing. Next would be the LVDS VCC pins and finally the
logic VCC pins.
UNUSED INPUTS
All unused inputs at the TxIN inputs of the transmitter must
be tied to ground. All unused outputs at the RxOUT outputs
of the receiver must then be left floating.
01288824
FIGURE 18. LVDS Serialized Link Termination
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12
COMMON MODE vs. DIFFERENTIAL MODE NOISE
MARGIN
Applications Information (Continued)
The typical signal swing for LVDS is 300 mV centered at
+1.2V. The CHANNEL LINK receiver supports a 100 mV
threshold therefore providing approximately 200 mV of dif-
ferential noise margin. Common mode protection is of more
importance to the system’s operation due to the differential
data transmission. LVDS supports an input voltage range of
Ground to +2.4V. This allows for a 1.0V shifting of the
center point due to ground potential differences and common
mode noise.
POWER SEQUENCING AND POWERDOWN MODE
Outputs of the CHANNEL LINK transmitter remain in TRI-
STATE until the power supply reaches 3V. Clock and data
outputs will begin to toggle 10 ms after VCC has reached
4.5V and the Powerdown pin is above 2V. Either device may
be placed into a powerdown mode at any time by asserting
the Powerdown pin (active low). Total power dissipation for
each device will decrease to 5 µW (typical).
01288825
FIGURE 19. CHANNEL LINK
Decoupling Configuration
CLOCK JITTER
The CHANNEL LINK chipset is designed to protect itself
from accidental loss of power to either the transmitter or
receiver. If power to the transmit board is lost, the receiver
clocks (input and output) stop. The data outputs (RxOUT)
retain the states they were in when the clocks stopped.
When the receiver board loses power, the receiver inputs are
The CHANNEL LINK devices employ a PLL to generate and
recover the clock transmitted across the LVDS interface. The
width of each bit in the serialized LVDS data stream is
one-seventh the clock period. For example, a 66 MHz clock
has a period of 15 ns which results in a data bit width of 2.16
ns. Differential skew (∆t within one differential pair), intercon-
nect skew (∆t of one differential pair to another) and clock
jitter will all reduce the available window for sampling the
LVDS serial data streams. Care must be taken to ensure that
the clock input to the transmitter be a clean low noise signal.
Individual bypassing of each VCC to ground will minimize the
noise passed on to the PLL, thus creating a low jitter LVDS
clock. These measures provide more margin for channel-to-
channel skew and interconnect skew as a part of the overall
jitter/skew budget.
shorted to V
through an internal diode. Current is limited
CC
(5 mA per input) by the fixed current mode drivers, thus
avoiding the potential for latchup when powering the device.
13
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Applications Information (Continued)
01288826
FIGURE 20. Single-Ended and Differential Waveforms
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14
Physical Dimensions inches (millimeters) unless otherwise noted
48-Lead Molded Thin Shrink Small Outline Package, JEDEC
NS Package Number MTD48
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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IC LINE DRIVER, PDSO48, LOW PROFILE, PLASTIC, TSSOP-48, Line Driver or Receiver
NSC
DS90CR215MTDX/NOPB
DS90CR215/DS90CR216 3.3V Rising Edge Data Strobe LVDS 21-Bit Channel Link - 66 MHz
TI
DS90CR215MTDX/NOPB
IC LINE DRIVER, PDSO48, LOW PROFILE, PLASTIC, TSSOP-48, Line Driver or Receiver
NSC
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