SGS Thomson Microelectronics STLVDS105BTR, STLVDS105BDR, STLVDS105BD Datasheet

4-PORT LVDS AND 4-PORT TTL-TO LVDS
RECEIVER AND DRIVERS MEET OR
EXCEED THE REQUIREMENTS OF ANSI EIA/TIA-644 STANDARD: RECEIVERS LOW-VOLTAGE TTL (LVTTL) LEVELS DESIGNED FOR SIGNALING RATES UP TO 630Mbps
OPERATES FROM A SINGLE 3.3V SUPPLY
WITH TYPICAL OUTPUT VOLTAGE OF 350mV AND A 100LOAD
PROPAGATION DELAY TIME: 2.2ns (TYP)
ELECTRICALLY COMPATIBLE WITH LVDS,
PECL, LVPECL, LVTTL, LVCOMOS, GTL, BTL, CTT, S STL, OR HSTL OUTPUTS W ITH EXTERNAL NETWORK
BUS TERMINAL ESD (HBM) EXCEEDS 7KV
SO AND TSSOP PACKAGING
DESCRIPTION
The STL VDS 105 is a differential line receiver and a LVTTL input connected to four differential line drivers that implement the electrical characteristics of low voltagedifferential signaling, for point to point baseband data transmission over controlled impedance media of approximately 100Ω. The trans mission media can be printed-circuit board traces, backplanes, or cable.
STLVDS105
REPEATERS
SOP TSSOP
LVDS, as specified in EIA/TIA-644 is a data signaling technique that offers low-power, low noise coupling, and switching s peed to transmit data at a speed up to 630Mbps at relatively long distances. The drivers integrated into t he same substra te, along with the low pulse skew of balanced signaling, allow extremely precise timing alignment of the signals repeated from the input. The device allows extremely precise timing alignment of the signal rep eated from the input. This is particularly advantageous in distribution or expansion of s ignals such as clock or serial data stream.
ORDERING CODES
Type
STLVDS105BD -40 to 85 °C SO-16 (Tube) 50parts per tube / 20tube per box STLVDS105BDR -40to 85 °C SO-16 (Tape & Reel) 2500 parts per reel STLVDS105BTR -40 to 85 °C TSSOP16 (Tape & Reel) 2500 parts per reel
Temperature
Range
Package Comments
1/8May 2003
STLVDS105
PIN CONFIGURATION
PIN DESCRIPTION
PlN N° SYMBOL NAME AND FUNCTION
1, 2, 3, 8 EN1 to EN4 Enable Driver Inputs
6 A Receiver Input 7 NC Not Connected
9, 11, 13, 15 1Z to 4Z Driver Inputs
10, 12, 14, 16 1X to 4X Driver Inputs
5 GND Ground 4
V
CC
Supply Voltage
FUNCTIONAL DIAGRAM
FUNCTIONAL TABLE
INPUT ENABLES OUTPUTS
A #EN #Y #Z
LHLH
HHHL
Open H L H
XLZZ XXZZ
L=Low level, H=High Level, Z= High Impedance
ABSOLUTE MAXIMUM RATINGS
Symbol Parameter Value Unit
V
V
ESD ESD Protection Voltage (HBM) Y, Z, to GND 7 KV
T
Absolute Maximum Ratings are those values beyond which damage to the device may occur. Functional operation under these condition is not implied. Note 1: All voltages except differential I/O bus voltage, are with respect to the network ground terminal.
2/8
Supply Voltage (Note 1)
CC
Voltage Range Enable Inputs -0.5 to 6 V
R
-0.5 to 4 V
A, Y or Z -0.5 to 4 V
All Pins 2 KV
Storage Temperature Range
stg
-65 to +150 °C
STLVDS105
RECOMMENDED OPERATING CONDITIONS
Symbol Parameter Min. Typ. Max. Unit
V
V
V
|V
V
T
Supply Voltage 3.0 3.3 3.6 V
CC
HIGH Level Input Voltage 2.0 V
IH
LOW Level Input Voltage 0.8 V
IL
| Magnitude Of Differential Input Voltage 0.1 3.6 V
ID
Common Mode Input Voltage |VID|/2 24-|VID|/2 V
IC
-0.8
V
CC
Operating Temperature Range
A
-40
85
°C
ELECTRICAL CHARACTERISTICS (T operating conditions unless otherwise noted. All typical values are at T
= -40 to 85°C, and VCC= 3.3V ±10% over recommended
A
=25°C)
A
Symbol Parameter Test Conditions Min. Typ. Max. Unit
| Differential Output Voltage
|V
OD
Magnitude
∆|V
| Change in Differential
OD
Output Voltage Magnitude
RL= 100Ω VID= ±100mV 247 340 454 mV
-50 50 mV
Between Logic State
V
OC(SS)
Change in Steady-state Common Mode Output
-50 50 mV
Voltage Between Logic State
V
OC(SS)
V
OC(PP)
I
CC
Steady-state Common Mode Output Voltage
Peak to Paek Common mode Output Voltage
Supply Current Enabled, RL=100 18 28 mA
1.125 1.2 1.375 V
25 150 mV
Disabled 0.3 1 mA
I
I
I
OC
I
OZ
I
O(OFF)
C
C
High Level Input Current VIH=2V 7 20 µA
IH
Low Level Input Current VIL= 0.8V 3 10 µA
IL
Short Circuit Output Current V
High Impedance Output
or V
O(Y)
=0 ± 10 mA
V
OD
=0V ± 10 mA
O(Z)
VO= 0 or 2.4V ± 1 µA
Current Power OFF Output Current VCC= 1.5V VO= 2.4V 0.3 ± 1 µA
Input Capacitance (A or B
IN
Inputs) Output Capacitance (Y or Z
O
Outputs)
= 0.4 sin (4e
V
I
= 0.4 sin (4e
V
I
6πt
)+0.5V
6πt
)+0.5V, Disabled
5pF
9.4 pF
3/8
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