CALMIRCO PACDN009MR

PACDN009
5 Channel ESD Protection Array
Features
Product Description
•
•
The PACDN009 is a diode array designed to provide 5
channels of ESD protection for electronic components
or sub-systems. Each channel consists of a pair of
diodes which steers an ESD current pulse to either the
positive (VP) or negative (VN) supply. The PACDN009
protects against ESD pulses up to ±15kV Human Body
Model (100 pF capacitor discharging through a 1.5KΩ
resistor), and ±8kV contact discharge, per International
Standard IEC 61000-4-2.
•
•
•
•
•
Five channels of ESD protection
±8 kV contact, ±15 kV air ESD protection per
channel (IEC 61000-4-2 standard)
±15 kV of ESD protection per channel (HBM)
Low loading capacitance (3pF typical)
Low leakage current is ideal for battery-powered
devices
Available in miniature 8-lead MSOP package
Lead-free version available
This device is particularly well-suited for portable electronics (e.g., cellular phones, PDAs, notebook computers) because of its small package footprint, high ESD
protection level, and low loading capacitance. It is also
suitable for protecting video output lines and I/O ports
in computers and peripherals and is ideal for a wide
range of consumer electronics products.
Applications
•
•
•
•
•
•
•
Consumer electronic products
Cellular phones
PDAs
Notebook computers
Desktop PCs
Digital cameras and camcorders
VGA (video) port protection for desktop
and portable PCs
The PACDN009 is supplied in an 8-lead MSOP package and is available with optional lead-free finishing.
Typical Application Circuit
3
PACDN009
Electrical Schematic
7
8
0.22µF*
14 5 6 8
7
6
5
3
4
VP
VN
Expansion
Connector
I/O Port
Buffers
N.C.
1
2
Handheld/PDA ESD Protection
* Capacitor should be placed
as close as possible to Pin7
© 2004 California Micro Devices Corp. All rights reserved.
09/21/04
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
1
PACDN009
PACKAGE / PINOUT DIAGRAMS
TOP VIEW
CH 1
N.C.
1
8
2
7
VN
CH 2
3
6
4
5
CH 5
VP
CH 4
CH 3
PACDN009
8-lead MSOP Package
Note: This drawing is not to scale.
PIN DESCRIPTIONS
PIN
NAME
TYPE
DESCRIPTION
1
CH 1
I/O
2
N.C.
-
3
VN
GND
4
CH 2
I/O
ESD Channel
5
CH 3
I/O
ESD Channel
6
CH 4
I/O
ESD Channel
7
VP
Supply
8
CH 5
I/O
ESD Channel
No connect
Negative voltage supply rail or ground reference rail
Positive voltage supply rail
ESD Channel
Ordering Information
PART NUMBERING INFORMATION
Standard Finish
Leads
Package
Ordering Part
Number1
8
MSOP
PACDN009M
Lead-free Finish
Part Marking
Ordering Part
Number1
Part Marking
D009
PACDN009MR
009R
Note 1: Parts are shipped in Tape & Reel form unless otherwise specified.
© 2004 California Micro Devices Corp. All rights reserved.
2
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
09/21/04
PACDN009
Specifications
ABSOLUTE MAXIMUM RATINGS
PARAMETER
RATING
UNITS
Supply Voltage (VP - VN)
6.0
V
Diode Forward DC Current (Note 1)
20
mA
Operating Temperature Range
-40 to +85
°C
Storage Temperature Range
-65 to +150
°C
(VN - 0.5) to (VP + 0.5)
V
200
mW
RATING
UNITS
-40 to +85
°C
0 to 5.5
V
DC Voltage at any channel input
Package Power Rating
MSOP Package
Note 1: Only one diode conducting at a time.
STANDARD OPERATING CONDITIONS
PARAMETER
Operating Temperature Range
Operating Supply Voltage (VP - VN)
ELECTRICAL OPERATING CHARACTERISTICS(SEE NOTE 1)
SYMBOL
PARAMETER
CONDITIONS
IP
Supply Current
(VP-VN)=5.5V
VF
Diode Forward Voltage
IF = 20mA
VESD
Channel Clamp Voltage
Positive Transients
Negative Transients
VCL
ILEAK
CIN
ESD Protection
Peak Discharge Voltage at any channel
input, in system
a) Human Body Model, MIL-STD-883,
Method 3015
b) Contact Discharge per IEC 61000-4-2
c) Air Discharge per IEC 61000-4-2
MIN
TYP
0.65
MAX
UNITS
10
µA
0.95
V
Note 3
Notes 2,4
±15
kV
Note 5
Note 5
±8
±15
kV
kV
@15kV ESD HBM
Channel Leakage Current
Channel Input Capacitance
VP + 13.0
VN - 13.0
V
V
±0.1
±1.0
µA
3
5
pF
@ 1 MHz, VP=5V, VN=0V,
VIN=2.5V; Note 2 applies
Note 1: All parameters specified at TA=25°C unless otherwise noted. VP = 5V, VN = 0V unless noted.
Note 2: These parameters guaranteed by design and characterization.
Note 3: From I/O pins to VP or VN only. VP bypassed to VN with a 0.22µF ceramic capacitor (see Application Information for more
details).
Note 4: Human Body Model per MIL-STD-883, Method 3015, CDischarge = 100pF, RDischarge = 1.5KΩ, VP = 5.0V, VN grounded.
Note 5: Standard IEC 61000-4-2 with CDischarge = 150pF, RDischarge = 330Ω, VP = 5.0V, VN grounded.
© 2004 California Micro Devices Corp. All rights reserved.
09/21/04
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
3
PACDN009
Performance Information
Input Capacitance vs. Input Voltage
5
CIN (pF)
4
3
2
1
0
0
1
2
3
4
5
VIN
Typical Variation of CIN vs. VIN
(VP = 5V, VN = 0V, 0.1 µF chip capacitor between VP and VN)
© 2004 California Micro Devices Corp. All rights reserved.
4
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
09/21/04
PACDN009
Application Information
Design Considerations
with ROUT equal to 1 ohm, we would see a 10V increment in VCL for a peak IESD of 10A.
In order to realize the maximum protection against
ESD pulses, care must be taken in the PCB layout to
minimize parasitic series inductances on the Supply/
Ground rails as well as the signal trace segment
between the signal input (typically a connector) and the
ESD protection device. Refer to Figure 1, which illustrates an example of a positive ESD pulse striking an
input channel. The parasitic series inductances back to
the power supply are represented by L1 and L2. The
voltage VCL on the line being protected is:
If the inductances and resistance described above are
close to zero, the rail-clamp ESD protection diodes will
do a good job of protection. However, since this is not
possible in practical situations, a bypass capacitor
must be used to absorb the very high frequency ESD
energy. So for any brand of rail-clamp ESD protection
diodes, a bypass capacitor should be connected
between the VP pin of the diodes and the ground plane
(VN pin of the diodes) as shown in the Application Circuit diagram below. A value of 0.22µF is adequate for
IEC-61000-4-2 level 4 contact discharge protection
(±8kV). Ceramic chip capacitors mounted with short
printed circuit board traces are good choices for this
application. Electrolytic capacitors should be avoided
as they have poor high frequency characteristics. For
extra protection, connect a zener diode in parallel with
the bypass capacitor to mitigate the effects of the parasitic series inductance inherent in the capacitor. The
breakdown voltage of the zener diode should be
slightly higher than the maximum supply voltage.
VCL = Fwd voltage drop of D1 + VSUPPLY + L1 x d(IESD ) / dt
+ L2 x d(IESD ) / dt
where IESD is the ESD current pulse, and VSUPPLY is
the positive supply voltage.
An ESD current pulse can rise from zero to its peak
value in a very short time. As an example, a level 4
contact discharge per the IEC61000-4-2 standard
results in a current pulse that rises from zero to 30
Amps in 1ns. Here d(IESD)/dt can be approximated by
∆IESD/∆t, or 30/(1x10-9). So just 10nH of series inductance (L1 and L2 combined) will lead to a 300V increment in VCL!
As a general rule, the ESD Protection Array should be
located as close as possible to the point of entry of
expected electrostatic discharges. The power supply
bypass capacitor mentioned above should be as close
to the VP pin of the Protection Array as possible, with
minimum PCB trace lengths to the power supply,
ground planes and between the signal input and the
ESD device to minimize stray series inductance.
Similarly for negative ESD pulses, parasitic series
inductance from the VN pin to the ground rail will lead
to drastically increased negative voltage on the line
being protected.
Another consideration is the output impedance of the
power supply for fast transient currents. Most power
supplies exhibit a much higher output impedance to
fast transient current spikes. In the VCL equation
above, the VSUPPLY term, in reality, is given by (VDC +
IESD x ROUT), where VDC and ROUT are the nominal
supply DC output voltage and effective output impedance of the power supply respectively. For example,
Additional Information
See also California Micro Devices Application Notes
AP209, “Design Considerations for ESD Protection”
and AP219, "ESD Protection for USB 2.0 Systems"”
L2
VP
POSITIVE SUPPLY RAIL
PATH OF ESD CURRENT PULSE IESD
D1
D2
L1
ONE
CHANNEL
OF
PAC DN009
LINE BEING
PROTECTED
SYSTEM OR
CIRCUITRY
BEING
PROTECTED
CHANNEL
INPUT
20A
VCL
0A
GROUND RAIL
VN
CHASSIS GROUND
Figure 1. Application of Positive ESD Pulse between Input Channel and Ground
© 2004 California Micro Devices Corp. All rights reserved.
09/21/04
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
5
PACDN009
Application Information (cont’d)
Implementation Examples
ESD events are very high-speed pulses with rise times
in the range of 1ns or less. To effectively use the
PACDN009, the following design guidelines must be
observed (as discussed in the application section):
1) The inductance from the VN and VP connections of
the PACDN009 to ground must be very low. This
includes the path through the VP decoupling capacitor
to ground and the path to the power supply (as discussed above).
2) The inductance between the connector pin to be
protected and the PACDN009 channel input pin must
be kept to a minimum. If there is a large inductance
here, the ESD event will find a lower impedance path
which will more likely be through the device to be pro-
tected. Figure 2 shows the implementation schematic
and Figure 3 shows a possible layout for the
PACDN009. In figure 3, notice the large VCC and
ground areas with multiple via connections to the
underlying reference planes and the positioning of the
bypass capacitor. Note how the signal lines to be protected flow from the connector to the PACDN009 and
then out to the device to be protected (Figure 3). This
daisy chaining provides a low impedance path from the
connector to the PACDN009 and a higher impedance
path from the PACDN009 to the protected device.
POSITIVE SUPPLY RAIL
DECOUPLING
CAPCITOR
0.22µF
D1
LINE BEING
PROTECTED
CHANNEL
INPUT
D2
SYSTEM OR
CIRCUITRY
BEING
PROTECTED
OPTIONAL
ZENER DIODE
FOR EXTRA
PROTECTION
ONE
CHANNEL
OF
PAC DN009
POWER SUPPLY
GROUND RAIL
Figure 2. Typical ESD protection implementation
© 2004 California Micro Devices Corp. All rights reserved.
6
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
09/21/04
PACDN009
Application Information (cont’d)
Figure 3. PCB Layout Recomendation
© 2004 California Micro Devices Corp. All rights reserved.
09/21/04
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
7
PACDN009
Mechanical Details
Mechanical Package Diagrams
MSOP Mechanical Specifications
TOP VIEW
The PACDN009 is supplied in an 8-lead MSOP package. Dimensions are presented below.
D
8
7
6
5
For complete information on the MSOP-8 package,
see the specific California Micro Devices Package
Information document.
E
H
Pin 1
Marking
PACKAGE DIMENSIONS
Package
MSOP
Leads
8
Dimensions
1
Millimeters
Max
Min
Max
A
0.87
1.17
0.034
0.046
A1
0.05
0.25
0.002
0.010
0.30 (typ)
C
4
SIDE VIEW
A
0.18
A1
SEATING
PLANE
0.012 (typ)
B
0.007
D
2.90
3.10
0.114
0.122
E
2.90
3.10
0.114
0.122
e
3
Inches
Min
B
2
0.65 BSC
e
END VIEW
0.025 BSC
H
4.78
4.98
0.188
0.196
L
0.52
0.54
0.017
0.025
# per tube
80 pieces*
# per tape
and reel
4000 pieces
C
L
Package Dimensions for MSOP-8
Controlling dimension: inches
* This is an approximate number which may vary.
© 2004 California Micro Devices Corp. All rights reserved.
8
430 N. McCarthy Blvd., Milpitas, CA 95035-5112
●
Tel: 408.263.3214
●
Fax: 408.263.7846
●
www.calmicro.com
09/21/04