STMicroelectronics ESDA14V2L, ESDA25L, ESDA5V3L, ESDA6V1L Schematic [ru]

®
ESDAxxL
Application Specific Discretes
A.S.D.
APPLICATIONS
Where transient overvoltage protection in ESD sensitive equipment is required, such as :
- COMPUTERS
- PRINTERS
- COMMUNICATION SYSTEMS It is particulary recommended for the RS232 I/O
port protection where the line interface withstands only with 2kV ESD surges.
FEATURES
2 UNIDIRECTIONAL TRANSIL FUNCTIONS.
n
LOW LEAKAGE CURRENT : IRmax. < 20µAat
n
.
V
BR
300 W PEAK PULSE POWER (8/20µs)
n
DESCRIPTION
The ESDAxxL is a dual monolithic voltage suppressordesignedtoprotectcomponentswhich are connected to data and transmission lines against ESD.
It clamps the voltage just above the logic level supply for positive transients, and to a diode drop below ground for negative transients.
It can also work as bidirectionnal suppressor by connecting only pin1 and 2.
DUAL TRANSIL ARRAY
FOR ESD PROTECTION
SOT23
FUNCTIONAL DIAGRAM
BENEFITS
High ESD protection level : up to 25 kV. High integration. Suitable for high density boards.
COMPLIESWITHTHEFOLLOWINGSTANDARDS :
IEC61000-4-2 level 4
MIL STD 883C-Method 3015-6 : class 3. (human body model)
Marchr 2000 - Ed: 4A
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ESDAxxL
ABSOLUTE MAXIMUM RATINGS (T
amb
= 25°C)
Symbol Parameter Value Unit
V
PP
P
PP
T
stg
T
j
T
L
T
op
note 1: Evolution of functional parameters is given by curves.
ELECTRICAL CHARACTERISTICS (T
Symbol Parameter
V
RM
V
BR
V
CL
I
RM
I
PP
Electrostatic discharge MIL STD 883C - Method 3015-6
IEC61000-4-2 air discharge
IEC61000-4-2 contact discharge Peak pulse power (8/20 µs) Storage temperature range
Maximum junction temperature Maximum lead temperature for soldering during 10s Operating temperature range
= 25°C)
amb
Stand-off voltage Breakdown voltage
Clamping voltage Leakage current
V
BR
V
Peak pulse current
RM
25 16
9
300 W
-55to+150 150
260 °C
-40to+125 °C
I
I
F
V
F
I
RM
kV
°C °C
V
αT
C
Rd
V
F
Types VBR@
ESDA5V3L ESDA6V1L ESDA14V2L ESDA25L
note 1 : Square pulse Ipp = 15A, tp=2.5µs. note 2 : VBR= αT* (Tamb -25°C) * VBR(25°C)
Voltage temperature coefficient Capacitance Dynamic resistance Forward voltage drop
min. max. max. typ. max. typ. max.
VVmAµAV
5.3 5.9 1 2 3 280 5 220 1.25 200
6.1 7.2 1 20 5.25 350 6 140 1.25 200
14.2 15.8 1 5 12 650 10 90 1.25 200 25 30 1 1 24 1000 10 50 1.2 10
1
Slope:
Rd
I
R
IRM@V
RM
Rd αTC V
note 1 note 2 0V bias
10-4/CpF V mA
m
I
PP
@I
F
F
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CALCULATION OF THE CLAMPING VOLTAGE USE OF THE DYNAMIC RESISTANCE
The ESDA family has been designed to clamp fast spikes like ESD. Generally the PCB designers need to calculate easily the clamping voltage V
CL
This is why we give the dynamic resistance in addition to the classical parameters. The voltage across the protection cell can be calculated with the following formula:
=VBR+RdI
V
CL
PP
WhereIpp is thepeak current throughthe ESDA cell.
DYNAMIC RESISTANCE MEASUREMENT
The short duration of the ESD has led us to prefer amore adapted test wave, as below defined, to the classical 8/20µs and 10/1000µs surges.
I
Ipp
As the value of the dynamic resistance remains stable for a surge duration lower than 20µs, the
.
2.5µs rectangular surge is well adapted. In addition both rise and fall times are optimized to avoid any parasitic phenomenon during the measurement of Rd.
ESDAxxL
2µs
tp = 2.5µs
2.5µs duration measurement wave.
t
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