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Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Features
s
Pin-equivalent to the general-trade 26LS31 device, with improved speed, reduced power consumption, and significantly lower levels of EMI Four line drivers per package Meets ESDI standards 2.0 ns maximum propagation delay Single 5.0 V 10% supply Operating temperature range: -40 C to +125 C (wider than the 41 Series) 400 Mbits/s maximum data rate Logic to convert TTL input logic levels to differential, pseudo-ECL output logic levels No line loading when VCC = 0 (BDG1A, BDP1A only) High output driver for 50 loads <0.2 ns output skew (typical) On-chip 220 loads available Third-state outputs available Surge-protection to 60 V for 10 ms available (BPNGA, BPNPA, BPPGA) Available in four package types ESD performance better than the 41 Series Lower power requirement than the 41 Series
equivalent to the general-trade 26LS31, but offer increased speed, decreased power consumption, and significantly lower levels of electromagnetic interference (EMI). They replace the Lucent 41 Series drivers. The BDG1A device is the generic driver in this family and requires the user to supply external resistors on the circuit board for impedance matching. The BDGLA is a low-power version of the BDG1A, reducing the power requirement by more than one half. The BDGLA features a 3-state output with a typical third-state level of 0.2 V. The BDP1A is equivalent to the BDG1A but has 220 termination resistors to ground on each driver output. This eliminates the need for external pulldown resistors when driving a 100 impedance line. The BPNGA and BPNPA are equivalent to the BDG1A and BDP1A, respectively, except that a lightning protection circuit has been added to the driver outputs. This circuit will absorb large transitions on the transmission lines without destroying the device. The BPPGA combines the features of the BPNGA and BPNPA. Two of the gates have their outputs terminated to ground through 220 resistors while the two remaining gates require external termination resistors. When the BDG1A and the BDP1A devices are powered down, the output circuit appears as an open circuit relative to the power supplies; hence, they will not load the transmission line. For those circuits with termination resistors, the line will remain impedance matched when the circuit is powered down. The BPNGA, BPNPA, BPPGA, and BDGLA will load the transmission line, because of the protection circuit, when the circuit is powered down. The packaging options that are available for these quad differential line drivers include a 16-pin DIP; a 16-pin, J-lead SOJ; a 16-pin, gull-wing SOIC; and a 16-pin, narrow-body, gull-wing SOIC.
s s s s s
s s
s
s s s s s
s s s
Description
These quad differential drivers are TTL input-topseudo-ECL-differential-output used for digital data transmission over balanced transmission lines. All devices in this family have four drivers with a single enable control in a common package. These drivers are compatible with many receivers, including the Lucent Technologies Microelectronics Group 41 Series receivers and transceivers. They are pin
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Pin Information
AI AO AO E1 BO BO BI GND
1 2 3 4 5 6 B 7 C 8 A D
16 VCC 15 DI 14 DO 13 DO 12 E2 11 CO 10 CO 9 CI
AI AO AO E1 BO BO BI GND
1 2 3 4 5 6 B 7 C 8 A D
16 VCC 15 DI 14 DO 13 DO 12 E2 11 CO 10 CO 9 CI
AI AO AO E1 BO BO BI GND
1 2 3 4 5 6 B 7 C 8 A D
16 VCC 15 DI 14 DO 13 DO 12 E2 11 CO 10 CO 9 CI
BDG1A BDGLA BPNGA
BDP1A BPNPA
BPPGA
12-2038b (F)
Figure 1. Quad Differential Driver Logic Diagrams Table 1. Enable Truth Table E1 0 1 0 1 E2 0 0 1 1 Condition Active Active Disabled Active
Absolute Maximum Ratings
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are absolute stress ratings only. Functional operation of the device is not implied at these or any other conditions in excess of those given in the operational sections of the data sheet. Exposure to absolute maximum ratings for extended periods can adversely affect device reliability. Parameter Power Supply Voltage Ambient Operating Temperature Storage Temperature Symbol VCC TA Tstg Min -- -40 -55 Max 6.5 125 150 Unit V C C
2
Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Electrical Characteristics
For electrical characteristics over the entire temperature range, see Figures 7 through 9. Table 2. Power Supply Current Characteristics TA = -40 C to +125 C, VCC = 5 V 0.5 V. Parameter Power Supply Current (VCC = 5.5 V): All Outputs Disabled: BDG1A*, BPNGA* BDP1A, BPNPA BDGLA* BPPGA* All Outputs Enabled: BDG1A*, BPNGA* BDP1A, BPNPA BDGLA* BPPGA* Symbol Min Typ Max Unit
ICC ICC ICC ICC ICC ICC ICC ICC

45 120 35 85 25 150 14 90
65 160 55 115 40 200 20 115
mA mA mA mA mA mA mA mA
* Measured with no load (BPPGA has no load on drivers C and D). The additional power dissipation is the result of integrating the termination resistors into the device. ICC is measured with a 100 resistor across the driver outputs (BPPGA has terminating resistors on drivers A and B).
Third State
These drivers produce pseudo-ECL levels, and the third-state mode is different than the conventional TTL devices. When a driver is placed in the third state, the bases of the output transistors are pulled low, bringing the outputs below the active-low levels. This voltage is typically 2 V for most drivers. In the bidirectional bus application, the driver of one device, which is in its third state, may be back driven by another driver on the bus whose voltage in the low state is lower than the third-stated device. This could come about due to differences in the drivers' independent power supplies. In this case, the device in the third state will control the line, thus clamping the line and reducing the signal swing. If the difference voltage between the independent power supplies and the drivers is small, then this consideration can be ignored. In the typical case, the difference voltage can be as much as 1 V without significantly affecting the amplitude of the driving signal.
Lucent Technologies Inc.
3
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Electrical Characteristics (continued)
Table 3. Voltage and Current Characteristics For the variation in VOH and VOL over the temperature range, see Figures 7 and 8. TA = -40 C to +125 C.* Parameter Output Voltages: Low* High*: BDG1A, BDP1A, BPNGA, BPNPA, BPPGA BDGLA Differential Voltage (VOH - VOL) Output Voltages (TA = 0 C to 85 C): Low* High*: BDG1A, BDP1A, BPNGA, BPNPA, BPPGA BDGLA Differential Voltage (VOH - VOL) Third State, IOH = -1.0 mA, VCC = 4.5 V: BDG1A, BDP1A, BPNGA, BPNPA, BPPGA BDGLA Input Voltages: Low, VCC = 5.5 V: Data Input Enable Input High, VCC = 4.5 V Clamp, VCC = 4.5 V, II = -5.0 mA Short-circuit Output Current, VCC = 5.5 V Input Currents, VCC = 5.5 V: Low, VI = 0.4 V High, VI = 2.7 V Reverse, VI = 5.5 V Output Resistors: BDP1A, BPNPA, BPPGA
*
Symbol VOL VOH VOH VDIFF VOL VOH VOH VDIFF VOZ VOZ
Min VOH - 1.4 VCC - 1.8 VCC - 2.5 0.65 VOH - 1.4 VCC - 1.5 VCC - 2.5 0.8 -- --
Typ VOH - 1.1 VCC - 1 VCC - 2 1.1 VOH - 1.1 VCC - 1 VCC - 2 1.1 VOL - 0.5 0.2
Max VOH - 0.65 VCC - 0.8 VCC - 1.6 1.4 VOH - 0.8 VCC - 0.8 VCC - 1.6 1.4 VOL - 0.2 0.5
Unit V V V V V V V V V V
VIL VIL VIH VIK IOS IIL IIH IIH RO
-- -- 2.0 -- -100 -- -- -- --
-- -- -- -- -- -- -- -- 220
0.8 0.7 -- -1.0 -- -400 20 100 --
V V V V mA A A A
Values are with terminations as per Figure 4 or equivalent. The input levels and difference voltage provide zero noise immunity and should be tested only in a static, noise-free environment. Test must be performed one lead at a time to prevent damage to the device. See Figure 1 for BPPGA terminations.
4
Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Timing Characteristics
Table 4. Timing Characteristics (See Figures 2 and 3.) For tP1 and tP2 propagation delays over the temperature range, see Figure 9. Propagation delay test circuit connected to output (see Figure 6). TA = -40 C to +125 C, VCC = 5 V 0.5 V. Parameter Propagation Delay: Input High to Output Input Low to Output Capacitive Delay Disable Time (either E1 or E2): High-to-high Impedance Low-to-high Impedance Enable Time (either E1 or E2): High Impedance to High High Impedance to Low Output Skew, |tP1 - tP2| |tPHH - tPHL|, |tPLH - tPLL| Difference Between Drivers Rise Time (20%--80%) Fall Time (80%--20%) Symbol tP1* tP2* tp tPHZ tPLZ tPZH tPZL tskew1 tskew2 tskew ttLH ttHL Min 0.8 0.8 -- 4 4 4 4 -- -- -- -- -- Typ 1.2 1.2 0.02 8 8 8 8 0.1 0.2 -- 0.7 0.7 Max 2.0 2.0 0.03 12 12 12 12 0.3 0.5 0.3 2 2 Unit ns ns ns/pF ns ns ns ns ns ns ns ns ns
* tP1 and tP2 are measured from the 1.5 V point of the input to the crossover point of the outputs (see Figure 2). CL = 5 pF. Capacitor is connected from each output to ground.
Lucent Technologies Inc.
5
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Timing Characteristics (continued)
2.4 V 1.5 V 0.4 V tP1 OUTPUTS VOL tPHH OUTPUT tPLL VOH (VOH + VOL)/2 VOL tP2 VOH
INPUT TRANSITION
OUTPUT tPHL OUTPUT tPLH
VOH (VOH + VOL)/2 VOL
80% 20% ttLH
80% 20% ttHL
VOH VOL
12-2677F
Figure 2. Driver Propagation-Delay Timing
E1*
3.0 V 1.3 V 0.0 V
E2 tPHZ tPZH
3.0 V 1.3 V 0.0 V VOH VOL + 0.2 V VOL VOL - 0.1 V
OUTPUT
OUTPUT tPLZ * E2 = 1 while E1 changes state. E1 = 0 while E2 changes state. Note: In the third state, both outputs (i.e., OUTPUT and OUTPUT) are 0.2 V below the low state. tPZL
VOL VOL - 0.1 V
12-2268.dC
Figure 3. Driver Enable and Disable Timing for a High Input 6 Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Test Conditions
Parametric values specified under the Electrical Characteristics and Timing Characteristics sections for the data transmission driver devices are measured with the following output load circuits.
100 DO(+) 200 DO(-) 200
Output Characteristics
Figure 6 illustrates typical driver output characteristics. Included are load lines for two typical termination configurations.
OUTPUT VOLTAGE (V) VCC - 2 V VCC - 1 V VCC
OUTPUT CURRENT (mA)
VOH
10
BDG1A, BPNGA, BDGLA, BPPGA (Gates A & B)
VOL
12-2271F
Y LOAD
20
30 LOAD
100 DO DO
40
12-2269F
BDP1A, BPNPA, BPPGA (Gates C & D)
12-2271.bC
A. Output Current vs. Output Voltage for Loads Shown in C and D (BDG1A, BDP1A, BPNGA, BPNPA, and BPPGA)
OUTPUT VOLTAGE (V) VCC - 3 V VCC - 2 V VOH 10 VCC - 1 V VCC OUTPUT CURRENT (mA)
Figure 4. Driver Test Circuit
+5 V 110 DUT VOL 110 +60 V SURGE 10 s DURATION 1 ms REPITITION
12-2640.aF
Y LOAD LOAD
20 30 40
+ - + -
+60 V SURGE 10 s DURATION 1 ms REPETITION
12-2818aC
B. Output Current vs. Output Voltage for Loads Shown in C and D (BDGLA)
60 DO 90
12-2270F
60 DO
Note: Surges can be applied simultaneously, but never in opposite polarities.
Figure 5. Lightning-Surge Testing Configuration (BPNGA, BPNPA, and BPPGA)
C. Y Load
100 DO(+) 200 DO(-) 200
12-2271F
D. Load Figure 6. Driver Output Current vs. Voltage Characteristics Lucent Technologies Inc. 7
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Temperature Characteristics
OUTPUT VOLTAGE RELATIVE TO VCC
0 PROPAGATION DELAY (ns)
2.3 2.1 1.9 1.7 1.5 1.3 1.1 0.9 0.7 0.5 0.3 -50 -25 0 25 50 75 100 125 150 RANGE FOR tP1 AND tP2 MAX MIN
-0.5
VOH MAX
-1.0
-1.5 VOL MAX -2.0 -2.5 -50
VOH MIN
VOL MIN -25 0 25 50 75 100 125 150
TEMPERATURE (C)
12-3467F
TEMPERATURE (C)
12-3469aF
Figure 7. VOL and VOH Extremes vs. Temperature for 100 Load
Figure 9. Min and Max for tP1 and tP2 Propagation Delays vs. Temperature
Handling Precautions
1.2 DIFFERENTIAL VOLTAGE (V) VOH - VOL TYP 1.0
0.8
VOH - VOL MIN
CAUTION: This device is susceptible to damage as a result of electrostatic discharge. Take proper precautions during both handling and testing. Follow guidelines such as JEDEC Publication No. 108-A (Dec. 1988). When handling and mounting line driver products, proper precautions should be taken to avoid exposure to electrostatic discharge (ESD). The user should adhere to the following basic rules for ESD control: 1. Assume that all electronic components are sensitive to ESD damage. 2. Never touch a sensitive component unless properly grounded. 3. Never transport, store, or handle sensitive components except in a static-safe environment.
0.6
0.4 0 -50
-25
0
25
50
75
100
125 150
TEMPERATURE (C)
12-3468F
Figure 8. Differential Voltage (VOH - VOL) vs. Temperature for 100 Load
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Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
The HBM ESD threshold voltage presented here was obtained by using these circuit parameters. Table 5. Typical ESD Thresholds for Data Transmission Drivers Device BDG1A, BDGLA BDP1A BPPGA, BPNGA, BPNPA HBM Threshold >2500 >2500 >3000 CDM Threshold >1000 >2000 >2000
ESD Failure Models
Lucent employs two models for ESD events that can cause device damage or failure. 1. A human-body model (HBM) that is used by most of the industry for ESD-susceptibility testing and protection-design evaluation. ESD voltage thresholds are dependent on the critical parameters used to define the model. A standard HBM (resistance = 1500 , capacitance = 100 pF) is widely used and, therefore, can be used for comparison purposes. 2. A charged-device model (CDM), which many believe is the better simulator of electronics manufacturing exposure. Tables 5 and 6 illustrate the role these two models play in the overall prevention of ESD damage. HBM ESD testing is intended to simulate an ESD event from a charged person. The CDM ESD testing simulates charging and discharging events that occur in production equipment and processes, e.g., an integrated circuit sliding down a shipping tube.
Table 6. ESD Damage Protection ESD Threat Controls Personnel Control Wrist straps ESD shoes Antistatic flooring Human-body model (HBM) Processes Static-dissipative materials Air ionization Charged-device model (CDM)
Model
Latch-Up
Latch-up evaluation has been performed on the data transmission drivers. Latch-up testing determines if powersupply current exceeds the specified maximum due to the application of a stress to the device under test. A device is considered susceptible to latch-up if the power supply current exceeds the maximum level and remains at that level after the stress is removed. Lucent performs latch-up testing per an internal test method that is consistent with JEDEC Standard No. 17 (previously JC-40.2) "CMOS Latch-Up Standardized Test Procedure." Latch-up evaluation involves three separate stresses to evaluate latch-up susceptibility levels: 1. dc current stressing of input and output pins. 2. Power supply slew rate. 3. Power supply overvoltage. Table 7. Latch-Up Test Criteria and Test Results dc Current Stress of I/O Pins 150 mA 250 mA Power Supply Slew Rate 1 s 100 ns Power Supply Overvoltage 1.75 x Vmax 2.25 x Vmax
Data Transmission Driver ICs
Minimum Criteria Test Results
Based on the results in Table 6, the data transmission drivers pass the Lucent latch-up testing requirements and are considered not susceptible to latch-up.
Lucent Technologies Inc.
9
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Outline Diagrams
16-Pin DIP
Dimensions are in millimeters.
L N
B
1 PIN #1 IDENTIFIER ZONE W
H SEATING PLANE 0.38 MIN 2.54 TYP 0.58 MAX
5-4410r.2 (C)
Package Description PDIP3 (Plastic Dual-In-Line Package)
Number of Pins (N) 16
Package Dimensions Maximum Length (L) 20.57 Maximum Width Without Leads (B) 6.48 Maximum Width Including Leads (W) 7.87 Maximum Height Above Board (H) 5.08
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics to assist your design efforts, please contact your Lucent Technologies Sales Representative.
10
Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Outline Diagrams (continued)
16-Pin SOIC (SONB/SOG)
Dimensions are in millimeters.
L N
B
1 PIN #1 IDENTIFIER ZONE W
H SEATING PLANE 0.10 1.27 TYP 0.51 MAX 0.28 MAX
5-4414r.3 (C)
0.61
Package Description SONB (SmallOutline, Narrow Body) SOG (SmallOutline, GullWing)
Number of Pins (N) 16
Package Dimensions Maximum Length (L) 10.11 Maximum Width Without Leads (B) 4.01 Maximum Width Including Leads (W) 6.17 Maximum Height Above Board (H) 1.73
16
10.49
7.62
10.64
2.67
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics to assist your design efforts, please contact your Lucent Technologies Sales Representative.
Lucent Technologies Inc.
11
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Outline Diagrams (continued)
16-Pin SOIC (SOJ)
Dimensions are in millimeters.
L N
B
1 PIN #1 IDENTIFIER ZONE W
H SEATING PLANE 0.10 1.27 TYP 0.51 MAX 0.79 MAX
5-4413r.3 (C)
Package Description SOJ (SmallOutline, J-Lead)
Number of Pins (N) 16
Package Dimensions Maximum Length (L) 10.41 Maximum Width Without Leads (B) 7.62 Maximum Width Including Leads (W) 8.81 Maximum Height Above Board (H) 3.18
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics to assist your design efforts, please contact your Lucent Technologies Sales Representative.
12
Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
The power dissipated in the output is a function of the:
s
Power Dissipation
System designers incorporating Lucent data transmission drivers in their applications should be aware of package and thermal information associated with these components. Proper thermal management is essential to the longterm reliability of any plastic encapsulated integrated circuit. Thermal management is especially important for surface-mount devices, given the increasing circuit pack density and resulting higher thermal density. A key aspect of thermal management involves the junction temperature (silicon temperature) of the integrated circuit. Several factors contribute to the resulting junction temperature of an integrated circuit:
s s s s s
Termination scheme on the outputs Termination resistors Duty cycle of the output
s s
Package thermal impedance depends on:
s s
Airflow Package type (e.g., DIP SOIC, SOIC/NB) ,
The junction temperature can be calculated using the previous equation, after power dissipation levels and package thermal impedances are known. Figure 10 illustrates the thermal impedance estimates for the various package types as a function of airflow. This figure shows that package thermal impedance is higher for the narrow-body SOIC package. Particular attention should, therefore, be paid to the thermal management issues when using this package type. In general, system designers should attempt to maintain junction temperature below 125 C. The following factors should be used to determine if specific data transmission drivers in particular package types meet the system reliability objectives:
s s s
Ambient use temperature Device power dissipation Component placement on the board Thermal properties of the board Thermal impedance of the package
ja and is measured in C rise in junction temperature
per watt of power dissipation. Thermal impedance is also a function of airflow present in system application. The following equation can be used to estimate the junction temperature of any device: Tj = TA + PD ja where:
Thermal impedance of the package is referred to as
System ambient temperature Power dissipation Package type Airflow
s
140 130 THERMAL RESISTANCE ja (C/W) 120 110 100 90 80 70 60 50 40 0 200 DIP 400 600 800 1000 1200 J-LEAD SOIC/GULL WING SOIC/NB
Tj is device junction temperature (C). TA is ambient temperature (C). PD is power dissipation (W).
ja is package thermal impedance (junction to ambient--C/W). The power dissipation estimate is derived from two factors:
s s
Internal device power Power associated with output terminations
Multiplying ICC times VCC provides an estimate of internal power dissipation.
AIRFLOW (ft./min.)
12-2753F
Figure 10. Power Dissipation
Lucent Technologies Inc.
13
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Data Sheet January 1999
Ordering Information
Part Number BDG1A16E BDG1A16E-TR BDG1A16G BDG1A16G-TR BDG1A16NB BDG1A16NB-TR BDG1A16P BDP1A16E BDP1A16E-TR BDP1A16G BDP1A16G-TR BDP1A16P BDGLA16E BDGLA16E-TR BDGLA16G BDGLA16G-TR BDGLA16NB BDGLA16NB-TR BDGLA16P BPNGA16E BPNGA16E-TR BPNGA16G BPNGA16G-TR BPNGA16NB BPNGA16NB-TR BPNGA16P BPNPA16E BPNPA16E-TR BPNPA16G BPNPA16G-TR BPNPA16P BPPGA16E BPPGA16E-TR BPPGA16G BPPGA16G-TR BPPGA16P Intern. Term. None None None None None None None 220 220 220 220 220 None None None None None None None None None None None None None None 220 220 220 220 220 220 220 220 220 220 Surge Prot. No No No No No No No No No No No No No No No No No No No Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Package Type 16-pin, Plastic SOJ Tape & Reel SOJ 16-pin, Plastic SOIC Tape & Reel SOIC Plastic SOIC/NB Tape & Reel SOIC/NB 16-pin, Plastic DIP 16-pin, Plastic SOJ Tape & Reel SOJ 16-pin, Plastic SOIC Tape & Reel SOIC 16-pin, Plastic DIP 16-pin, Plastic SOJ Tape & Reel SOJ 16-pin, Plastic SOIC Tape & Reel SOIC Plastic SOIC/NB Tape & Reel SOIC/NB 16-pin, Plastic DIP 16-pin, Plastic SOJ Tape & Reel SOJ 16-pin, Plastic SOIC Tape & Reel SOIC Plastic SOIC/NB Tape & Reel SOIC/NB 16-pin, Plastic DIP 16-pin, Plastic SOJ Tape & Reel SOJ 16-pin, Plastic SOIC Tape & Reel SOIC 16-pin, Plastic DIP 16-pin, Plastic SOJ Tape & Reel SOJ 16-pin, Plastic SOIC Tape & Reel SOIC 16-pin, Plastic DIP Comcode 107914186 107914194 107914160 107914178 107914202 107914210 107914004 107914293 107914301 107914319 107914327 107914335 107914228 107914236 107914244 107914251 107914269 107914277 107914285 107914343 107914350 107914368 107914376 107914384 107914392 107914400 107914418 107914426 107914434 107914442 107949745 107949752 107949760 107949778 107949786 107949794 Former Pkg. Type 1041 1041 1141 1141 1241 1241 41 1041 1041 1141 1141 41 1041 1041 1141 1141 1241 1241 41 1041 1041 1141 1141 1241 1241 41 1041 1041 1141 1141 41 1041 1041 1141 1141 41 Former Part # LG, MG, MGA LG, MG, MGA LG, MG, MGA LG, MG, MGA LG, MG, MGA LG, MG, MGA LG, MG, MGA LP MP MPA , , LP MP MPA , , LP MP MPA , , LP MP MPA , , LP MP MPA , , MGL3 MGL3 MGL3 MGL3 MGL3 MGL3 MGL3 NG NG NG NG NG NG NG NP NP NP NP NP PG PG PG PG PG
14
Lucent Technologies Inc.
Data Sheet January 1999
Quad Differential Drivers BDG1A, BDP1A, BDGLA, BPNGA, BPNPA, and BPPGA
Notes
Lucent Technologies Inc.
15
For additional information, contact your Microelectronics Group Account Manager or the following: INTERNET: http://www.lucent.com/micro E-MAIL: docmaster@micro.lucent.com N. AMERICA: Microelectronics Group, Lucent Technologies Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18103 1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106) ASIA PACIFIC: Microelectronics Group, Lucent Technologies Singapore Pte. Ltd., 77 Science Park Drive, #03-18 Cintech III, Singapore 118256 Tel. (65) 778 8833, FAX (65) 777 7495 CHINA: Microelectronics Group, Lucent Technologies (China) Co., Ltd., A-F2, 23/F, Zao Fong Universe Building, 1800 Zhong Shan Xi Road, Shanghai 200233 P R. China Tel. (86) 21 6440 0468, ext. 316, FAX (86) 21 6440 0652 . JAPAN: Microelectronics Group, Lucent Technologies Japan Ltd., 7-18, Higashi-Gotanda 2-chome, Shinagawa-ku, Tokyo 141, Japan Tel. (81) 3 5421 1600, FAX (81) 3 5421 1700 EUROPE: Data Requests: MICROELECTRONICS GROUP DATALINE: Tel. (44) 1189 324 299, FAX (44) 1189 328 148 Technical Inquiries: GERMANY: (49) 89 95086 0 (Munich), UNITED KINGDOM: (44) 1344 865 900 (Ascot), FRANCE: (33) 1 40 83 68 00 (Paris), SWEDEN: (46) 8 594 607 00 (Stockholm), FINLAND: (358) 9 4354 2800 (Helsinki), ITALY: (39) 02 6608131 (Milan), SPAIN: (34) 1 807 1441 (Madrid)
Lucent Technologies Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liability is assumed as a result of their use or application. No rights under any patent accompany the sale of any such product(s) or information.
Copyright (c) 1999 Lucent Technologies Inc. All Rights Reserved
January 1999 DS99-144HSI (Replaces DS99-044HSI)

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